Fuji Electric FRN355VG1S-4J Инструкция по эксплуатации онлайн [1021/1046] 465071

Failure to heed the information contained under the caution title can also result in serious consequences failure to heed the information contained under the caution title can also result in serious consequences these safety precautions are of utmost importance and must be observed at all times 18

Failure to heed the information indicated by this symbol may lead to dangerous conditions possibly resulting in death or serious bodily injuries 18

Failure to heed the information indicated by this symbol may lead to dangerous conditions possibly resulting in minor or light bodily injuries and or substantial property damage 18

Read this manual thoroughly before proceeding with installation connections wiring operation or maintenance and inspection ensure you have sound knowledge of the device and familiarize yourself with all safety information and precautions before proceeding to operate the inverter 18

Safety precautions 18

Safety precautions are classified into the following two categories in this manual 18

General precautions 21

Chapter 1 overview 23

Chapter 1overview 23

Frenic vg 23

This chapter describes the overview features and the control system of the frenic vg series and the recommended configuration for the inverter and peripheral equipment 23

Broad capacity and application ranges 25

Extensive built in functionality 25

Industry best control performance 25

Overview 25

System support 25

Global support 26

Best in industry control performance 27

Features 27

Broad capacity range flexible application range 28

Support for various control methods multi drive function 28

User program functionality option upac 28

User program functionality option upac 1 28

Available inverter support loader 29

Extensive network support 29

Extensive built in functionality 30

Extensive maintenance and protective functionality 31

1 enhanced environmental resistance of the cooling fan 32

2 adoption of nickel and tin plating for copper bars 32

A environments where sulfide gas is present some applications in tire manufacturing paper manufacturing sewage treatment and fiber manufacturing 32

B environments where conductive dust or foreign matter is present metalworking extruding machine or printing press operation waste disposal etc 32

C other where the inverter would be used in an environment that differs from the standard specifications 32

Enhanced environmental resistance 32

Environmental considerations 32

Extensive service life warnings 32

If you are considering using the inverter under any of the above conditions please contact fuji in if you are considering using the inverter under any of the above conditions please contact fuji in advance 32

The inverter offers improved resistance to harsh operating environments compared to the inverter offers improved resistance to harsh operating environments compared to conventional inverter models 32

The inverter provides functionality designed to facilitate machinery maintenance the inverter provides functionality designed to facilitate machinery maintenance 32

While the frenic vg offers improved resistance to harsh operating environments compared to while the frenic vg offers improved resistance to harsh operating environments compared to conventional models special consideration concerning the operating environment is necessary in the following cases 32

Simple interactive keypad 34

Compatibility with legacy models 35

Compliance with functional safety standards 35

Compliance with overseas standards 35

Control method features and applications 36

Control methods 36

Open loop speed control 36

Closed loop speed control 38

A slip frequency control 39

Chap 1 overview 39

Control circuit 39

Control methods 39

Converter inverter 39

Figure 1 illustrates the architecture of the slip frequency control method output from the speed controller becomes the slip frequency based on the torque and the inverter compensates for speed fluctuations by adding the slip frequency to the actual speed because this method is comparatively simple it is used in applications such as speed control in general purpose inverters however since basic control is performed using v f control this method is used in applications that do not require fast response 39

Figure 1 slip frequency control architecture 39

Main circuit 39

1 good acceleration and deceleration characteristics 40

2 broad speed control range 40

3 torque control capability 40

4 fast control response 40

B vector control with a speed sensor 40

Figure 1 illustrates an example vector control architecture since the vector calculation unit uses the motor constant performance varies greatly with the accuracy with which that constant is understood performance is also significantly affected by changes to the constant caused by temperature conditions since the control method is complex this method is primarily used with combinations of dedicated inverters and dedicated motors 40

Vector control achieves performance that differs from the v f control method in the following ways making it well suited for use in applications that require fast response and high accuracy 40

Vector control is used to implement fast response for ac motors by controlling an ac motor s primary current magnetic flux current and torque current separately vector control attempts to achieve a similar level of control performance as that for dc motors 40

C vector control without a speed sensor 41

Chap 1 overview 41

Control methods 41

Figure 1 illustrates an example of vector control without a speed sensor 41

The frenic vg can use this type of control when utilized in combination with a general purpose motor however control performance and other specifications are slightly inferior to those of applications where the inverter is used in combination with a dedicated motor 41

Vector control with a speed sensor offers exceptional performance in terms of fast response and high accuracy but suffers from issues such as the need to install a speed sensor and route wiring from the sensor to the inverter by contrast vector control without a speed sensor estimates the rotational speed based on the motor s terminal voltage and primary current without relying on sensor input and uses the estimated value as the speed feedback signal vector control without a speed sensor delivers performance that is slightly inferior to vector control with a speed sensor 41

Chapter 2 specifications 43

Frenic vg 43

This chapter describes specifications of the output ratings control system dedicated motor specifications and terminal functions for the frenic vg series of inverters it also provides descriptions of the external dimensions examples of basic connection diagrams and details of the protective functions 43

Hd high duty mode inverters for heavy load 45

Standard model 1 basic type 45

Three phase 200 v class series 45

Three phase 400 v class series 46

Chap 2 specifications 47

Md medium duty mode inverters for medium load 47

Standard model 1 basic type 47

Three phase 400 v class series 47

Ld low duty mode inverters for light load 48

Three phase 200 v class series 48

Chap 2 specifications 49

Standard model 1 basic type 49

Three phase 400 v class series 49

Canceling the automatic lowering of the carrier frequency h104 hundreds digit when the inverter drives a permanent magnet synchronous motor pmsm derates the continuous rated current of the inverter according to the carrier frequency setting f26 select the inverter capacity and the carrier frequency f26 which match the motor specifications referring to the tables given below 50

Hd high duty mode inverters for heavy load 50

Rated current derating 50

Three phase 200 v class series 50

Chap 2 specifications 51

Standard model 1 basic type 51

Three phase 400 v class series 51

Md medium duty mode inverters for medium load 52

Three phase 400 v class series 52

Chap 2 specifications 53

Ld low duty mode inverters for light load 53

Standard model 1 basic type 53

Three phase 200 v class series 53

Three phase 400 v class series 53

Common specifications 54

Chap 2 specifications 55

Common specifications 55

Chap 2 specifications 57

Common specifications 57

Chap 2 specifications 59

Common specifications 59

External dimensions 60

Standard models 60

Figure c 62

Figure d figure d 62

Frn55vg1s 2 62

Note a box replaces an alphabetic letter depending on the shipping destination 62

Unit mm frn45vg1s 2 62

Chap 2 specifications 63

External dimensions 63

Figure c 63

Frn90vg1s 2 63

Note a box replaces an alphabetic letter depending on the shipping destination 63

Unit mm frn75vg1s 2 63

Figure b 64

Figure c 64

Figure c figure c 64

Frn75vg1s 4 64

Note a box replaces an alphabetic letter depending on the shipping destination 64

Unit mm frn55vg1s 4 64

Chap 2 specifications 65

External dimensions 65

Figure c 65

Frn110vg1s 4 65

Note a box replaces an alphabetic letter depending on the shipping destination 65

Unit mm frn90vg1s 4 65

Figure c 66

Frn160vg1s 4 66

Note a box replaces an alphabetic letter depending on the shipping destination 66

Unit mm frn132vg1s 4 66

Chap 2 specifications 67

External dimensions 67

Figure c 67

Frn220vg1s 4 67

Note a box replaces an alphabetic letter depending on the shipping destination 67

Unit mm frn200vg1s 4 67

Figure c 68

Figure e figure e 68

Frn315vg1s 4 68

Note a box replaces an alphabetic letter depending on the shipping destination 68

Unit mm frn280vg1s 4 68

Chap 2 specifications 69

External dimensions 69

Figure e 69

Frn400vg1s 4 69

Note a box replaces an alphabetic letter depending on the shipping destination 69

Unit mm frn355vg1s 4 69

Figure e 70

Figure f 70

Figure f figure f 70

Frn630vg1s 4 70

Note a box replaces an alphabetic letter depending on the shipping destination 70

Unit mm frn500vg1s 4 70

Keypad 71

Dedicated motor specifications 72

Induction motor im with speed sensor 72

Standard specifications for three phase 200 v series 72

Chap 2 specifications 73

Dedicated motor specifications 73

Standard specifications for three phase 400 v series 73

Common specifications 74

Chap 2 specifications 75

Dedicated motor specifications 75

Dimensions common to 200v and 400v series 75

External dimensions of dedicated motors 75

Figure a figure b 75

Figure c figure d figure e 75

Permanent magnet synchronous motor pmsm with speed sensor 76

Standard specifications for three phase 200 v series 76

Standard specifications for three phase 400 v series 76

Chap 2 specifications 77

Common specifications 77

Dedicated motor specifications 77

Dimensions common to 200v and 400v series 78

External dimensions of dedicated motors 78

Chap 2 specifications 79

Dedicated motor specifications 79

Exclusive cables to inverter connection 79

At the inverter side connector 10320 52f0 008 sumitomo 3m co ltd at the motor side connector contact terminal jn1 22 22f pkg100 japan aviation electronics industry limited 81

At the motor side straight plug connector jn2dw15sl japan aviation electronics industry limited at the motor side angle plug connector jn2fw15sl1 japan aviation electronics industry limited 81

Chap 2 specifications 81

Dedicated motor specifications 81

Reference connectors and contact terminals recommended 81

The following specifications are recommended for customers who produce inverter connection cables 81

Protective functions 82

The table below lists the name of the protective functions description alarm codes on the led monitor and presence of alarm output at terminals 30a b c if an alarm code appears on the led monitor remove the cause of activation of the alarm function referring to chapter 13 troubleshooting 82

Chap 2 specifications 83

Protective functions 83

Chap 2 specifications 85

Protective functions 85

Connection diagrams 86

Connection diagrams and terminal functions 86

Running the mvk type of an induction motor dedicated motor 86

Chap 2 specifications 87

Connection diagrams and terminal functions 87

Running the gnf2 type of a permanent magnet synchronous motor dedicated motor 88

Chap 2 specifications 89

Connection diagrams and terminal functions 89

List of terminal functions 90

Main circuit terminals and analog input terminals 90

Chap 2 specifications 91

Connection diagrams and terminal functions 91

Digital input terminals 91

Analog output terminals and transistor output terminals 92

Chap 2 specifications 93

Connection diagrams and terminal functions 93

Chapter 3 preparation and test run 95

Frenic vg 95

This chapter describes the operating and storage environments installation and wiring typical connection diagram names and functions of keypad components keypad operation and test run procedure 95

Acceptance inspection nameplates and type of inverter 97

Before use 97

1 outside and inside views 99

Before use 99

Chap 3 preparation and test run 99

External view and terminal blocks 99

2 warning plates and label 100

Fuji electric strongly recommends installing inverters in a panel for safety reasons in particular when installing the ones whose enclosure rating is ip00 101

Install the inverter in an environment that satisfies the requirements listed in chapter 2 section 2 common specifications 101

Installation environment 101

Precautions for using inverters 101

The special environments listed below require using the specially designed panel or considering the panel installation location 101

This section provides precautions in introducing inverters e g precautions for installation environment power supply lines wiring and connection to peripheral equipment be sure to observe those precautions 101

When installing the inverter in a place out of the specified environmental requirements it is necessary to derate the inverter or consider the panel engineering design suitable for the special environment or the panel installation location for details refer to the fuji electric technical information engineering design of panels or consult your fuji electric representative 101

Long term storage 102

Storage environment 102

Temporary storage 102

Wiring precautions 103

Precautions for connection of peripheral equipment 104

5 molded case circuit breaker mccb or residual current operated protective device rcd earth leakage circuit breaker elcb 105

Chap 3 preparation and test run 105

Install a recommended mccb or rcd elcb with overcurrent protection in the primary install a recommended mccb or rcd elcb with overcurrent protection in the primary circuit of the inverter to protect the wiring since using an mccb or rcd elcb with a lager capacity than recommended ones breaks the protective coordination of the power supply system be sure to select recommended ones also select ones with short circuit breaking capacity suitable for the power source impedance 105

Precautions for using inverters 105

Leakage current 108

Noise reduction 108

Precautions in driving a permanent magnet synchronous motor pmsm 108

Install the inverter in an environment that satisfies the requirements listed in table 3 1 109

Mounting and wiring the inverter 109

Operating environment 109

Installing the inverter 110

Chap 3 preparation and test run 111

Figure 3 3 changing the positions of the top and bottom mounting bases 111

For the panel cutting size refer to chapter 2 section 2 external dimensions 111

Mounting and wiring the inverter 111

Move the top mounting base to the center of the inverter and secure it to the case fixing screw holes with the base fixing screws after changing the position of the top mounting base some screws may be left unused 111

Remove all of the base fixing screws and the case fixing screws from the top of the inverter 111

Remove the base fixing screws from the bottom of the inverter move the bottom mounting base to the center of the inverter and secure it with the base fixing screws just as in step 2 inverters with a capacity of 220 kw or below have no case fixing screws on the bottom 111

Screws differ in size and count for each inverter refer to the table below 111

Table 3 4 screw size count and tightening torque 111

To utilize external cooling for inverters with a capacity of 30 kw or above change the positions of the top and bottom mounting bases from the edge to the center of the inverter as shown below figure 3 3 111

When changing the positions of the top and bottom mounting bases use only the specified screws otherwise a fire or accident could occur 111

Removing and mounting the front cover and the wiring guide 112

Wiring 112

1 main circuit terminals 113

Chap 3 preparation and test run 113

G are not exclusive to the power supply wiring primary circuit or motor wiring secondary circuit 113

Mounting and wiring the inverter 113

Screw specifications and recommended wire sizes 113

The tables and figures given below show the screw specifications and wire sizes note that the terminal arrangements differ depending on the inverter types in each of the figures two grounding terminals 113

Use crimp terminals covered with an insulation sheath or with an insulation tube the recommended wire sizes for the main circuits are examples of using a single hiv wire for 75 c at a surrounding temperature of 50 c 113

When the inverter power is on a high voltage is applied to the following terminals main circuit terminals l1 r l2 s l3 t p1 p n db u v w r0 t0 r1 t1 aux contact 30a 30b 30c y5a y5c insulation level main circuit enclosure basic insulation overvoltage category iii pollution degree 2 main circuit control circuit reinforced insulation overvoltage category iii pollution degree 2 relay output control circuit reinforced insulation overvoltage category ii pollution degree 2 an electric shock may occur 113

1 use the crimp terminal model no 38 6 manufactured by jst mfg co ltd or equivalent 2 when using 150 m 114

Table 3 6 recommended wire sizes 114

Wires for main circuit terminals of frn55vg1 2 ld mode use cb150 10 crimp terminals designed for low voltage appliances in jem1399 3 use the crimp terminal model no 8 l6 manufactured by jst mfg co ltd or equivalent 114

1 control circuit terminals common to all inverter types 115

2 control circuit terminals common to all inverter types 115

Arrangement of terminals 115

Chap 3 preparation and test run 115

Mounting and wiring the inverter 115

Table 3 7 lists the screw specifications and recommended wire size for wiring of the control circuit terminals the control circuit terminals are common to all inverter types regardless of their capacities 115

2 main circuit terminals 116

Wiring precautions 118

Connection diagram 121

Detailed functions of main circuit terminals and grounding terminals 123

Switching connectors 127

Chap 3 preparation and test run 129

Location of the switching connectors 129

Mounting and wiring the inverter 129

The switching connectors are located on the power printed circuit board power pcb as shown below 129

To remove each of the jumpers pinch its upper side between your fingers unlock its fastener and pull it up 129

When mounting it fit the jumper over the connector until it snaps into place 129

Detailed functions of control circuit terminals 130

In general the covers of the control signal wires are not specifically designed to withstand a high voltage i e reinforced insulation is not applied therefore if a control signal wire comes into direct contact with a live conductor of the main circuit the insulation of the cover might break down which would expose the signal wire to a high voltage of the main circuit make sure that the control signal wires will not come into contact with live conductors of the main circuit failure to observe these precautions could cause electric shock or an accident 130

Noise may be emitted from the inverter motor and wires take appropriate measures to prevent the nearby sensors and devices from malfunctioning due to such noise it takes a maximum of 5 seconds to establish the input output of the control circuit after the main power is turned on take appropriate measures such as external timers an accident could occur 130

Table 3 8 lists the symbols names and functions of the control circuit terminals the wiring to the control circuit terminals differs depending upon the setting of the function codes which reflects the use of the inverter route wires properly to reduce the influence of noise 130

Chap 3 preparation and test run 131

Mounting and wiring the inverter 131

Chap 3 preparation and test run 133

Mounting and wiring the inverter 133

Chap 3 preparation and test run 135

Mounting and wiring the inverter 135

An electric shock may result if this warning is not heeded as there may be some residual electric charge in the dc bus capacitor even after the power has been turned off 138

Before changing the switches or touching the control circuit terminal symbol plate turn off the power and wait at least five minutes for inverters of 22 kw or below or at least ten minutes for those of 30 kw or above make sure that the led monitor and charging lamp are turned off further make sure using a multimeter or a similar instrument that the dc link bus voltage between the terminals p and n has dropped to the safe level 25 vdc or below 138

For details on how to remove the front cover and how to open and close the keypad enclosure refer to section 3 removing and mounting the front cover and the wiring guide 138

Setting up the slide switches 138

Switching the slide switches located on the control pcb allows you to customize the operation mode of the analog output terminals digital i o terminals and communications ports the locations of those switches are shown in figure 3 18 location of the slide switches on the control pcb 138

Table 3 9 lists function of each slide switch table 3 9 lists function of each slide switch 138

To access the slide switches remove the front cover so that you can see the control pcb for inverters with a capacity of 30 kw or above open also the keypad enclosure 138

Chap 3 preparation and test run 139

Figure 3 18 shows the location of slide switches on the control pcb for the input output terminal configuration 139

Mounting and wiring the inverter 139

Sw2 and sw5 are reserved for particular manufacturers do not access them 139

Sw4 sw2 139

Sw8 sw7 139

To move a switch slider use a tool with a narrow tip e g a tip of tweezers be careful not to touch other electronic parts etc if the slider is in an ambiguous position the circuit is unclear whether it is turned on or off and the digital input remains in an undefined state be sure to place the slider so that it contacts either side of the switch 139

Mounting and connecting a keypad 140

Mounting it directly on the inverter see figure 3 19 a b 140

Mounting it on the panel see figure 3 20 140

Mounting procedure 140

Parts required for connection 140

To mount a keypad on a place other than an inverter the parts listed below are needed 140

Using it remotely in your hand see figure 3 21 140

You can install and or use the keypad in one of the following three ways 140

Usb connectivity 144

Names and functions of keypad components 145

Operation using the keypad 145

The keypad allows you to start and stop the motor view various data including maintenance information and alarm information configure function codes monitor i o signal status copy data and calculate the load factor 145

Chap 3 preparation and test run 147

Details of indicator indexes 147

Operation using the keypad 147

Figure 3 1 shows the status transition of the inverter between these three operation modes 148

Overview of operation modes 148

The frenic vg features the following three operation modes 148

1 set function code f01 at 0 this cannot be done when the keypad is in programming mode or alarm mode to enable speed setting using the 149

2 press the 149

3 press the 149

Configure speed commands 2 run or stop the motor 3 monitor the running status 4 jog inch the motor and 5 monitor light alarms 149

Configuring the speed command 149

Key again to change the frequency command the new setting can be saved into the inverter s internal memory 149

Key the lowest digit on the led monitor blinks the 7 segment led monitor displays the speed command and the lcd monitor displays the related information including the operation guide as shown below 149

Keys f01 0 factory default 149

Keys first switch the keypad to running mode 149

Running mode 149

Table 3 3 lists the available command sources and their symbols 149

When the inverter is turned on it automatically enters running mode in which you can 149

When the speed command source is other than digital setting the lcd monitor displays the when the speed command source is other than digital setting the lcd monitor displays the following 149

1 when function code f57 lcd monitor item selection 0 150

By factory default pressing the 150

Displaying the running status on the lcd monitor 150

Key decelerates the motor to stop the keypad operation is possible only in running and programming modes 150

Key in the reverse direction pressing the 150

Key starts running the motor in the forward direction and pressing the 150

Note the rotation direction of iec compliant motors is opposite to the one shown above 150

Running or stopping the motor 150

The lcd monitor displays the the lcd monitor displays the current running status the run command and the date time calendar clock the upper indicators show the unit of values shown on the led monitor and the lower indicators the running status and run command source 150

The running status and the run command are displayed as listed below 150

2 when function code f57 lcd monitor item selection 1 151

Chap 3 preparation and test run 151

Figure 3 4 bar chart 151

Operation using the keypad 151

The lcd monitor displays the motor speed output current and torque command in a bar chart the lcd monitor displays the motor speed output current and torque command in a bar chart the upper indicators show the unit of the value shown on the led monitor and the lower indicators the running status and run command source 151

Key in running mode switches between monitor items in the sequence shown in table 3 5 152

Monitoring the running status on the led monitor 152

Pressing the 152

The items listed below can be monitored on the 7 segment led monitor immediately after the power is turned on the monitor item specified by function code f55 is displayed 152

Jogging inching the motor 153

Monitoring light alarms 154

Programming mode 156

Programming mode allows you to set and check function code data and monitor maintenance information and input output i o signal status the functions can be easily selected with a menu driven system table 3 6 lists menus available in programming mode 156

Chap 3 preparation and test run 157

Operation using the keypad 157

The screen transition and hierarchy structure in running and programming modes are shown below 157

Ｓｔｏｐ 157

A function code consists of an alphabet denoting a function code group and numerals 159

Chap 3 preparation and test run 159

Keys switches the lower portion of the screen from the allowable entry range to the factory default the same simultaneous keying switches it back to the allowable entry range 159

Operation using the keypad 159

Simultaneous keying of 159

The function code data modification screen shows the function code its name its data before and after change allowable entry range and operation guides 159

An example of selecting a function code with a child directory 160

Changing validating and saving function code data when the invert is running 160

For example function codes c01 to c04 are all related with the mechanical resonance point of the load and treated as the same function so that c02 to c04 are not located in the parent directory at the right of c01 appears indicating that c01 has a child directory to access the child directory move the cursor to that function code using the 160

Function codes requiring simultaneous keying 160

Keypad directory structure 160

Keys and then press the 160

Keys is required 160

Keys or 160

Some function codes can be modified while the inverter is running whereas others cannot further depending on the function code modifications may or may not become effective immediately for details refer to the change when running column in chapter 4 section 4 160

The keypad has a directory structure that includes the related function codes in a directory to make it easy to select a target function code from many function codes 160

To modify the data for function code f00 data protection h01 auto tuning h02 full save function h03 data initialization h142 mock alarm l01 password data 1 or l02 password data 2 simultaneous keying of 160

Chap 3 preparation and test run 161

In the case of a function code group having 100 or more function codes this function jumps function codes in units of 100 for example f00 e01 e101 161

Jumping by function code group 161

Keys or 161

Keys simultaneously to jump to the previous or next function code group 161

Operation using the keypad 161

To call up a function code in a different group e to m press the 161

After a second the screen automatically switches back to the submenu 162

Key in running mode to switch to programming mode 162

Key to establish the selected language 162

Key to switch to the language selection screen 162

Keys then press the 162

Menu 0 language in programming mode is used to select the display language from a choice of four languages english japanese chinese and korean on the lcd monitor 162

Move the cursor at the left of the screen to 0 language using the 162

Move the pointer to the desired language using the 162

Press press 162

Selecting language menu 0 language 162

To display this menu screen press the 162

And and 163

Chap 3 preparation and test run 163

Configuring function codes menu 1 data set 163

Function code groups f e c p appear move the cursor to the desired function code group using the 163

Key in running mode to switch to programming mode move the cursor flashing rectangle at the left of the screen to 1 data set using the 163

Key to establish the desired function code 163

Key to move the cursor from the ten thousands place to the hundreds place 163

Key to move the cursor from the units place to the ten thousands place 163

Key to move to the lower directory 163

Key to switch to the function code configuration screen 163

Keys and then press the 163

Keys at the right of f03 appears indicating that f03 has a child directory to access the child directory move the cursor to that function code using the 163

Keys then press the 163

Menu 1 data set in programming mode is used to configure function codes 163

Move the cursor to the desired function code using the 163

Operation using the keypad 163

Press the 163

Press the press the 163

This section gives a description of the basic key operation following the example of the data changing flow shown below this example shows how to change f03 data m1 maximum speed from 1500 r min to 1200 r min 163

To display this menu screen press the 163

Change the function code data using the 164

Key to establish the function code data 164

Keys in this example change from 1500 r min to 1200 r min 164

Press the press the 164

After tuning the full save function is not performed h02 1 after changing function code data via the communications link the full save function is not specified h02 1 when terminal command lu ccl cancel undervoltage alarm on any x terminal is enabled function code data is changed 165

And and 165

Chap 3 preparation and test run 165

Checking function code data menu 2 data check 165

Function code groups f e c p appear move the cursor to the desired function code group using the 165

In any of the following cases change of function code data will be saved only into the volatile memory ram and not be saved into the non volatile memory such data is displayed with white letters on black background 165

Key in running mode to switch to programming mode move the cursor flashing rectangle at the left of the screen to 2 data check using the 165

Key to establish the desired function code 165

Key to move the changeable digit place blinking then change the function code data using the 165

Key to move to the lower directory 165

Key to switch to the function code configuration screen 165

Keys and then press the 165

Keys at the right of f03 appears indicating that f03 has a child directory to access the child directory move the cursor to that function code using the 165

Keys then press the 165

Menu 2 data check in programming mode is used to check function codes together with their data that have been changed the function codes whose data have been changed from factory defaults are marked with 165

Move the cursor to the desired function code using the 165

Operation using the keypad 165

Press the 165

The function codes whose data has been changed from factory defaults are marked with an asterisk 165

This section gives a description of the basic key operation following the example of the data checking flow shown below this example shows how to change f03 data m1 maximum speed from 1500 r min to 1200 r min 165

To display this menu screen press the 165

Key to establish the function code data 166

Chap 3 preparation and test run 167

Key in running mode to switch to programming mode move the cursor flashing rectangle at the left of the screen to 3 opr mntr using the 167

Keys then press the 167

Menu 3 opr mntr in programming mode is used to check the running status during maintenance and test running 167

Monitoring the running status menu 3 opr mntr 167

Operation using the keypad 167

To display this menu screen press the 167

Chap 3 preparation and test run 169

Operation using the keypad 169

Table 3 8 running status items 169

Checking i o signal status menu 4 i o check 170

Key in running mode to switch to programming mode move the cursor flashing rectangle at the left of the screen to 4 i o check using the 170

Keys then press the 170

Menu 4 i o check in programming mode is used to check the i o states of digital and analog signals during maintenance or test running 170

To display this menu screen press the 170

Chap 3 preparation and test run 171

Operation using the keypad 171

Chap 3 preparation and test run 173

Key in running mode to switch to programming mode move the cursor flashing rectangle at the left of the screen to 5 maintenance using the 173

Keys then press the 173

Menu 5 maintenance in programming mode shows information necessary for performing maintenance on the inverter 173

Operation using the keypad 173

Reading maintenance information menu 5 maintenance 173

To display this menu screen press the 173

The following display numbers are shown as a bus error code 174

Change the measurement period using the 175

Chap 3 preparation and test run 175

Key in running mode to switch to programming mode move the cursor flashing rectangle at the left of the screen to 6 load fctr using the 175

Key key 175

Key to start measurement 175

Keys then press the 175

Measuring load factor menu 6 load fctr 175

Menu 6 load fctr in programming mode is used to measure the maximum output current the average output current and the average braking power 175

Operation using the keypad 175

Press the 175

To display this menu screen press the 175

Key in running mode to switch to programming mode 176

Key to establish the selected alarm 176

Keys then press the 176

Keys to select the desired alarm 176

Menu 7 alm inf in programming mode shows the past four alarm codes and the related alarm information on the current inverter conditions detected when the alarm occurred 176

Move the cursor flashing rectangle at the left of the screen to 7 alm inf using the 176

Press the 176

Reading alarm information menu 7 alm inf 176

To display this menu screen press the 176

Use the 176

Chap 3 preparation and test run 177

Operation using the keypad 177

Chap 3 preparation and test run 179

If all the information for the selected alarm is not shown on the screen at a time scroll over the descriptive information using the 179

Key in running mode to switch to programming mode move the cursor flashing rectangle at the left of the screen to 8 alm cause using the 179

Key key 179

Key to establish the selected alarm 179

Keys then press the 179

Keys to select the desired alarm and press the 179

Menu 8 alm cause in programming mode shows the past four alarm codes and the related alarm information on the current inverter conditions detected when the alarm occurred 179

Operation using the keypad 179

To display this menu screen press the 179

Use the 179

Viewing causes of alarm menu 8 alm cause 179

Copying data menu 10 data copy 180

Chap 3 preparation and test run 181

Key in running mode to switch to programming mode move the cursor flashing rectangle at the left of the screen to 10 data copy using the 181

Keys then press the keys then press the 181

Keys to select read write or verify 181

Operation using the keypad 181

To display this menu screen press the 181

Use the 181

Checking changed function codes menu 11 changes 182

Just as in section 3 configuring function codes menu 1 data set the function code data can be modified 182

Key in running mode to switch to programming mode move the cursor flashing rectangle at the left of the screen to 11 changes using the 182

Key key 182

Keys then press the 182

Menu 11 changes in programming mode shows only the function codes whose data has been changed from the factory defaults 182

The function codes whose data has been changed from factory defaults are marked with an asterisk 182

To display this menu screen press the 182

After a second the screen automatically switches back to the submenu 183

After mounting a memory backup battery option for inverters of 22 kw or below attached as standard for those of 33 kw or above set the date and time when a memory backup battery is not mounted the calendar clock does not work correctly 183

Change the date and time using the change the date and time using the 183

Chap 3 preparation and test run 183

If the relationship between the changed year month day and time is invalid 183

Key in running mode to switch to programming mode 183

Key to establish the desired menu 183

Key to move the cursor to the desired item 183

Keys then press the 183

Menu 12 date time in programming mode is used to select the format of the calendar clock to be displayed in the operation guide line in running mode and set the date and time 183

Move the cursor flashing rectangle at the left of the screen to 12 data time using the 183

Operation using the keypad 183

Setting the calendar clock menu 12 date time 183

Setting the date and time 183

The calendar clock can also be set with frenic vg loader for details refer to the the calendar clock can also be set with frenic vg loader for details refer to the frenic vg loader instruction manual 183

To display this menu screen press the 183

Use the 183

Change the date format data using the 184

Key in running mode to switch to programming mode move the cursor flashing rectangle at the left of the screen to 12 data time using the 184

Key to establish the desired menu 184

Key to establish the newly specified date format 184

Keys then press the 184

Keys to the desired menu 184

Move the pointer move the pointer using the 184

Selecting the display format 184

To display this menu screen press the 184

After a second the screen automatically switches back to the submenu 185

Change the time format data using the 185

Chap 3 preparation and test run 185

Key to establish the newly specified time format 185

Operation using the keypad 185

After a second the screen automatically switches back to the submenu 186

Key in running mode to switch to programming mode move the cursor flashing rectangle at the left of the screen to 14 limited fc using the 186

Key to select limited 186

Keys then press the 186

Keys to the desired menu 186

Limiting function codes to be displayed menu 14 limited fc 186

Menu 14 limited fc in programming mode is used to display hide the directory and select whether to display all function codes or limited ones selected in loader 186

Move the pointer using the 186

Shown below is an example of selecting limited ones 186

To display this menu screen press the 186

Make a test run of the motor using the flowchart given below 187

Test run procedure 187

Checking prior to powering on 188

Checking the input state of pg pulse generator signals 189

Powering on and checking 189

Mounting direction of a pg pulse generator and pg signals 190

A recommended motor for this control is a fuji vg motor exclusively designed for vector control 191

Configure the function codes as listed below the machinery design values should match your machinery ones 191

For details on how to modify the function code data see section 3 configuring function codes menu 1 data set for details refer to chapter 4 section 4 details of function codes 191

For fuji vg motor exclusively designed for vector control 191

However driving the motor with the motor terminal voltage suppressed to the lower level cannot generate the rated torque even if the rated current originally specified for the motor is applied to ensure the rated torque it is necessary to review the rated current this also applies to vector control without speed sensor 191

Selecting a desired motor drive control 191

The desired response can be obtained by adjusting the control constants pi constants with the speed regulator pi controller 191

The frenic vg supports the following motor drive controls 191

This control enables the speed control with higher accuracy and quicker response than the vector control without speed sensor 191

Under vector control the inverter detects the motor s rotational position and speed according to pg feedback signals and uses them for speed control in addition it decomposes the motor drive current into the exciting and torque current components and controls each of components in vector 191

Vector control for im with speed sensor 191

Vector control regulating the motor current requires some voltage margin between the voltage that the inverter can output and the induced voltage of the motor usually a general purpose motor is so designed that the voltage matches the commercial power under the control therefore it is necessary to suppress the motor terminal voltage to the lower level in order to secure the voltage margin required 191

After configuring the function codes perform motor parameter auto tuning h01 3 or 4 192

After tuning be sure to perform the full save function h02 1 to save the tuned data into the inverter 192

Configure the function codes as listed below according to the motor ratings and your machinery design values the motor ratings are printed on the motor s nameplate for your machinery design values ask system designers about them 192

For details on how to modify the function code data see section 3 configuring function codes menu 1 data set for details refer to chapter 4 section 4 details of function codes 192

For motors except fuji vg motor 192

For the motor parameter auto tuning procedure h01 3 or 4 refer to chapter 4 section 4 h codes 192

Performing motor parameter auto tuning h01 3 or 4 automatically changes the data of function codes p06 through p11 and p15 through p21 for m1 a08 through a13 and a17 through a23 for m2 and a108 through a113 and a117 through a123 for m3 be careful with this data change 192

To use motors except a fuji vg motor when their motor parameters to be set to function codes are known perform auto tuning to automatically configure them 192

After tuning be sure to perform the full save function h02 1 to save the tuned data into the inverter 193

Applying vector control without speed sensor requires auto tuning regardless of the motor type even driving a fuji vg motor exclusively designed for vector control requires auto tuning 193

Configure the function codes as listed below according to the motor ratings and your machinery design values the motor ratings are printed on the motor s nameplate for your machinery design values ask system designers about them 193

Configure the function codes as listed below and perform motor parameter auto tuning h01 2 193

For details on how to modify the function code data see section 3 configuring function codes menu 1 data set for details refer to chapter 4 section 4 details of function codes 193

For fuji vg motor exclusively designed for vector control 193

For the motor parameter auto tuning procedure h01 2 refer to chapter 4 section 4 h codes 193

Performing motor parameter auto tuning h01 2 automatically changes the data of function codes p06 and p07 for m1 a08 and a09 for m2 and a108 and a109 for m3 be careful with this data change 193

The desired response can be obtained by adjusting the control constants pi constants and using the speed regulator pi controller 193

Under this control the inverter estimates the motor speed based on the inverter s output voltage and current to use the estimated speed for speed control in addition it controls the motor current and motor torque with quick response and high accuracy under vector control no pg pulse generator is required 193

Vector control for im without speed sensor 193

After tuning be sure to perform the full save function h02 1 to save the tuned data into the inverter 194

Configure the function codes as listed below and perform motor parameter auto tuning h01 3 or 4 194

For details on how to modify the function code data see section 3 configuring function codes menu 1 data set for details refer to chapter 4 section 4 details of function codes 194

For motors except fuji vg motor 194

For the motor parameter auto tuning procedure h01 3 or 4 refer to chapter 4 section 4 h codes 194

Performing motor parameter auto tuning h01 3 or 4 automatically changes the data of function codes p06 through p11 and p15 through p21 for m1 a08 through a13 and a17 through a23 for m2 and a108 through a113 and a117 through a123 for m3 be careful with this data change 194

A recommended motor for this control is fuji gnf2 series exclusively designed for vector control 195

A single motor should be connected per inverter motor parameters are properly configured 195

Chap 3 preparation and test run 195

Configure the function codes as listed below the machinery design values should match your machinery ones for details contact your fuji electric representative 195

For details on how to modify the function code data see section 3 configuring function codes menu 1 data set for details refer to chapter 4 section 4 details of function codes 195

For fuji gnf2 motor exclusively designed for vector control 195

Since vector control for a fuji gnf2 motor with speed sensor uses motor parameters the following conditions should be satisfied otherwise full control performance may not be obtained 195

Test run procedure 195

The desired response can be obtained by adjusting the control constants pi constants with the speed regulator pi controller 195

Under this control the inverter detects the motor s rotational position speed and magnetic pole position according to feedback signals sent from the speed sensor and magnetic pole position sensor for speed control in addition it decomposes the motor drive current into the exciting and torque current components and controls each of components in vector 195

Vector control for pmsm with speed sensor and magnetic pole position sensor 195

Chap 3 preparation and test run 197

Configure the function codes as listed below the machinery design values should match your machinery ones 197

For details on how to modify the function code data see section 3 configuring function codes menu 1 data set 197

For fuji vg motor exclusively designed for vector control 197

Test run procedure 197

Under this control the inverter drives a motor with the voltage and frequency according to the v f pattern specified by function codes 197

V f control for im 197

Configure the function codes as listed below according to the motor ratings and your machinery design values the motor ratings are printed on the motor s nameplate for your machinery design values ask system designers about them 198

For details on how to modify the function code data see section 3 configuring function codes menu 1 data set 198

For motors except fuji vg motor 198

In applications requiring a starting torque adjust the torque boost p35 a55 a155 within the range from 2 to 20 or perform motor parameter auto tuning h01 2 and then set the torque boost p31 a55 a155 to 0 auto torque boost 198

Running the inverter for operation check 199

Test run procedure for induction motor im 199

1 before turning the inverter power on make checking given in section 3 checking prior to powering on 200

2 check that wiring of the encoder pg is correct 200

3 turn the power on make a note of the current configuration of all function codes and then change the function code data as listed in table 3 1 200

4 check that the magnetic pole position offset o10 is set to the previously specified value or manually adjusted value 200

Before proceeding with a test run 200

For a test run using a pmsm it is recommended that the motor be disconnected from the equipment for testing it by itself if it is impossible to drive the motor by itself due to the equipment however make a test run under the conditions that cause no problems even if the motor runs continuously in one direction forward or reverse 200

For the connection diagram refer to chapter 2 section 2 in combination with a dedicated for the connection diagram refer to chapter 2 section 2 in combination with a dedicated pmsm gnf2 type 200

Preparation for a test run 200

Replacing the motor or encoder requires adjustment of the magnetic pole position offset again replacing the motor or encoder requires adjustment of the magnetic pole position offset again 200

Test run procedure for permanent magnet synchronous motor pmsm 200

This section provides a test run procedure for the configuration consisting of the frenic vg the interface card for pmpg drive opc vg1 pmpg and a pmsm using a uvw phase detection pg including gnf2 motor 200

Test run 201

Troubleshooting for motor abnormality 201

Selecting a speed command source 202

Setting up a speed command from the keypad 202

Setting up a speed command with an external potentiometer 202

1 configure the function codes as listed below 203

2 connect a multistep speed switch to an x terminal and cm 203

3 turn the multistep speed switch on short circuit the combination of those input signals switches a multistep speed command 203

Assign signals assign signals ss1 ss2 ss4 and ss8 to four out of digital input terminals x1 to x14 by four out of function codes e01 to e14 data 0 1 2 and 3 specify multistep speed commands with c05 to c19 203

Enabling a multistep speed command with a multistep speed switch on between x terminal and cm disables the speed command source n1 specified by f01 203

Follow the procedure given below 203

For details on how to modify the function code data see section 3 configuring function codes menu 1 data set 203

For precautions in wiring refer to section 3 mounting and wiring the inverter 203

Setting up a speed command with multistep speed selection 203

Terminals x11 to x14 are available only when an optional opc vg1 dioa is mounted 203

Turning digital signals turning digital signals ss1 ss2 ss4 and ss8 on off selectively switches the multistep speed commands specified beforehand 203

Selecting a run command source 204

Setting up a run command from the keypad 204

Setting up a run command with digital input signals terminals fwd and rev 204

Chapter 4 control and operation 205

Frenic vg 205

This chapter provides the main block diagrams for the control logic of the frenic vg series of inverters it also contains overview tables of function codes and details of function codes 205

Block diagrams for control logic 207

Operation command 207

Speed command selection section 208

Acceleration deceleration calculation speed limiting and position control input section 209

Block diagrams for control logic 209

Chap 4 control and operation 209

Motor speed line speed detection 210

Pulse train command input section and position detection section 211

Speed control and torque command section 212

Torque limit torque current command and magnetic flux command section 213

Current control and vector control section 214

Pid calculation section 215

Load adaptive control section 216

Motor temperature detection section 217

Function selection digital input 218

Block diagrams for control logic 219

Chap 4 control and operation 219

Function selection digital output fault output 219

Function selection analog input output 220

Block diagrams for control logic 221

Chap 4 control and operation 221

Link command function selection 221

Enabling to write to recording function codes 222

Function code groups and function codes 223

Function code tables 223

About the contents of column headers in function code tables 224

Chap 4 control and operation 225

F codes fundamental functions 225

Function code tables 225

Chap 4 control and operation 227

Function code tables 227

Chap 4 control and operation 229

Function code tables 229

E codes extension terminal functions 230

Chap 4 control and operation 231

Function code tables 231

Chap 4 control and operation 233

Function code tables 233

Chap 4 control and operation 235

Function code tables 235

C codes control functions 237

Chap 4 control and operation 237

Function code tables 237

Chap 4 control and operation 239

Function code tables 239

P codes motor parameter functions m1 239

Chap 4 control and operation 241

Function code tables 241

H codes high performance functions 241

Chap 4 control and operation 243

Function code tables 243

Chap 4 control and operation 245

Function code tables 245

Chap 4 control and operation 247

Function code tables 247

A codes alternative motor parameter functions m2 m3 249

Chap 4 control and operation 249

Function code tables 249

Chap 4 control and operation 251

Function code tables 251

Chap 4 control and operation 253

Function code tables 253

O codes option functions 253

Chap 4 control and operation 255

Function code tables 255

Chap 4 control and operation 257

Function code tables 257

L codes lift functions 258

Chap 4 control and operation 259

Function code tables 259

U codes user functions 259

Chap 4 control and operation 261

Function code tables 261

Sf codes safety functions 261

S codes serial communication functions 262

Chap 4 control and operation 263

Function code tables 263

M codes monitoring functions 263

Chap 4 control and operation 265

Function code tables 265

Data format list 267

Data type 0 to 13 267

Data type 12 to 145 267

The following data have special formats 267

You can basically exchange data in the data types from 0 to 13 267

You can use the following formats to access function codes through the link and these formats are common to the frenic vg 267

12 8 7 0 268

Alarm code 0 to 64 order of alarm occurrence 1 to 5th number of alarms 1 to 5 268

Alarm codes 268

Type 14 cause of alarm 268

Chap 4 control and operation 269

Function code tables 269

Input state 26 input state 27 output state 0 x21 y21 1 x22 y22 2 x23 y23 3 x24 y24 4 x25 y25 5 x26 y26 6 x27 y27 7 x28 y28 8 x29 y29 9 x30 y30 10 x31 11 x32 12 x33 13 x34 14 x35 15 x36 270

Off 1 on 270

The number is fixed to 1313h or 1314h for the frenic vg 270

Type 26 diob option input state 270

Type 27 diob option output state 270

Type 28 inverter capacity 270

Type 29 inverter model common to entire fuji inverter system 270

V system fixed to 1313h 270

V system fixed to 1314h 270

Chap 4 control and operation 271

Function code tables 271

Description of alarms in the communication through the link rs 485 t link sx bus e sx bus the following data is set to description of alarms in the communication through the link rs 485 t link sx bus e sx bus the following data is set to the monitor data m26 according to the communication status the codes listed in the column keypad panel display is displayed on the keypad panel as a communication error 272

Type 34 communication error codes 272

Chap 4 control and operation 273

En1 terminal en1 1 en2 terminal en2 273

Function code tables 273

Normally closed 273

Normally open 273

These types are reserved for the manufacturer users can considers these types as type 0 to use 273

Type 100 en input terminals 273

Type 35 x function normally open closed 273

Type 36 y function normally open closed 273

Type 40 to 99 273

Type 82 m1 motor selection 273

X function 36 y function 0 x1 y1 1 x2 y2 2 x3 y3 3 x4 y4 4 x5 y5 5 x6 6 x7 7 x8 8 x9 273

0 1 times 10 0 to 99 9 1 0 1 times 10 0 to 99 9 274

0 times 2 0 times 100 to 999 274

1 times 1000 to 9999 274

Exponent 0 0 01 times 0 00 to 9 99 274

Light alarm code 0 to 64 274

Light alarm codes 274

Mantissa exponent 0 0 to 9999 exponent 1 2 3 1000 to 9999 274

Type 101 power 274

Type 102 cause of alarm 274

Chap 4 control and operation 275

Function code tables 275

Chap 4 control and operation 277

Function code tables 277

Chap 4 control and operation 279

Function code tables 279

Chap 4 control and operation 281

Function code tables 281

1 current limit voltage limit and torque limit are the same as information in type 21 282

11 12 13 14 not used 15 not used 282

Type 142 operation status 2 b 282

Type 143 calendar clock year month 282

Type 144 calendar clock day hour 282

Type 145 calendar clock minute second 282

Chap 4 control and operation 283

Function code tables 283

Details of function codes 284

F codes fundamental functions 284

１２００ 284

１５００ 285

Chap 4 control and operation 289

Details of function codes 289

F14 restart mode after momentary power failure mode selection 289

F14 specifies the action to be taken by the inverter such as trip and restart in the event of a momentary power f14 specifies the action to be taken by the inverter such as trip and restart in the event of a momentary power failure you can select a function for detecting power failure and activating protective operation alarm output alarm display inverter output cutoff for undervoltage or an automatic restart function without stopping a coasting motor after the supply voltage recovery see the following table for more information on this function the restart mode related function codes include h13 to h17 restart mode after momentary power failure wait time decrease rate in speed continuous running level run command self hold setting and run command self hold time h09 starting mode auto search and e01 terminal x1 function stm data 26 enable auto search for idling motor speed at starting also be familiar with these functions to restart the inverter after momentary power failure under v f 289

Chap 4 control and operation 295

Data setting range 0 1 295

Data setting range 0 detected speed 1 reference speed 295

Data setting range 0 to 150 r min 295

Details of function codes 295

Detection mode 295

F36 30ry drive mode 295

F36 selects whether to activate excite the alarm output relay 30ry in a normal state or in an abnormal f36 selects whether to activate excite the alarm output relay 30ry in a normal state or in an abnormal state 295

F37 specifies the stop speed 295

F37 stop speed speed 295

F38 specifies whether to detect the stop speed with the reference speed reference speed 4 asr input or detected speed detected speed 1 295

F38 stop speed detection mode 295

F39 stop speed zero speed holding time 295

However under v f control or vector control without speed sensor the reference speed only takes effect irrespective of the f38 setting 295

Stop speed 295

Under v f control the inverter stops its output when it detects the output frequency m05 irrespective of the f38 setting 295

When f36 1 the contacts between 30a and 30c are connected after the inverter control voltage is established about five seconds after turning on since the relay is excited in a normal state the relay can detect a wire break in the alarm output line 295

１５００ 297

Description and application of the limiter mode 1 298

See the following pages for detailed application examples 298

2 4 level 1 level 2 switchable to all four quadrants 301

3 1 level 1 to all four quadrants 301

3 2 level 1 to driving level 2 to braking 3 2 level 1 to driving level 2 to braking 301

3 enable power limiter 3 enable power limiter 301

Both in plus and minus values you do not have to use a minus value since it is interpreted as a plus value 301

Chap 4 control and operation 301

Details of function codes 301

If you set the level 1 as the short time rated torque for driving and set a capacity corresponding to the inverter loss for braking you can use the inverter loss to enable the shortest stop without an external braking resistor 301

The short time rated torque limits the torque where the level 1 or the level 2 exceeds the short time rated torque 301

The short time rated torque limits the torque where the level 1 or the level 2 exceeds the short time rated torque as in the right figure 301

Though this setting is possible there is no such an application 301

Though you can specify the level 1 and the level 2 301

Though you can specify the level 1 and the level 2 both in plus and minus values you do not have to use a minus value since it is interpreted as a plus value 301

Use this setting for an application such as applying brake with the capacity of a braking resistor 301

When you turn on with assigning the torque limiter level 1 level 2 selection tl2 tl1 signal to a digital input signal you can switch between the level 1 and the level 2 301

Chap 4 control and operation 307

Data setting range 0 torque polarity 1 for driving for braking 307

Details of function codes 307

F51 torque command monitor polarity 307

Sets the polarity for data display related to torque ao monitor keypad panel led monitor keypad sets the polarity for data display related to torque ao monitor keypad panel led monitor keypad panel lcd monitor 307

The following table shows data related with torque these values are displayed or transmitted with sign judge the meaning of signs from the f51 set value 307

Chap 4 control and operation 309

Details of function codes 309

F55 led monitor item selection 309

F55 specifies the running status item listed below to be monitored and displayed on the led monitor f55 specifies the running status item listed below to be monitored and displayed on the led monitor 309

Values 18 19 23 to 28 display when specific control options are mounted see the corresponding option section in chapter 6 for more details 309

Values 20 to 22 display when h20 pid control mode selection is set at 1 active 2 inverse action 1 or 3 inverse action 2 respectively 309

１５００ 310

Chap 4 control and operation 311

Data setting range 0 kw 1 hp 311

Details of function codes 311

F58 lcd monitor language selection 311

F58 selects a language to be displayed on the lcd monitor f58 selects a language to be displayed on the lcd monitor 311

F59 controls the contrast of the lcd monitor increasing the data value increases the contrast and decreasing f59 controls the contrast of the lcd monitor increasing the data value increases the contrast and decreasing it decreases the contrast 311

F59 lcd monitor contrast control 311

F60 output unit hp kw 311

F60 switches the display unit of the inverter output input power shown on the led monitor and lcd f60 switches the display unit of the inverter output input power shown on the led monitor and lcd monitor and the display unit of m1 motor selection p02 between kw and hp 311

Note 1 the language in the lcd screens shown in this manual is english 311

Note 2 l codes are displayed in japanese english or chinese p a and o codes in japanese or english and u codes in english only 311

Note 3 even if korean is selected the function code names are shown in english 311

Note 4 when f58 2 to 5 the lcd screens are shown in english 311

Adjust according to the mechanical inertia inertia and mechanical constant connected to the motor shaft the factory default value 10 corresponds to the inertia of a single frenic vg motor the following table provides a guideline for setting if you drive a machine whose inertia is larger than that of the frenic vg motor when converted into a motor shaft inertia set a value larger than 10 see chapter 2 specifications for the inertia data of the standard motors 312

Constant of integration 312

Data setting range f61 0 to 500 times f62 0 00 to 10 00 s setting 0 00 disables the integral constant 312

F61 and f62 specifies the p gain and integral constant of the asr1 f61 and f62 specifies the p gain and integral constant of the asr1 312

F61 asr1 p gain 312

F62 asr1 integral constant 312

P gain 312

P gain 1 is defined such that the torque command is 100 corresponding to the maximum speed setting when the speed deviation speed command observed speed is 100 312

Sets the constant of integration of the automatic speed regulator asr you can specify a value in the range from 0 00 to 10 00 s to set the speed deviation speed command observed speed at steady state to zero setting 0 00 s disables the integration p control only the integration means to sum the deviation at a specified interval a smaller interval means a smaller summation interval that presents faster response on the other hand larger interval extends summation interval to reduce the effect on the asr set a small value to reach the speed reference faster while allowing overshoots 312

Chap 4 control and operation 315

Check the cause and the oscillation frequency of a mechanical resonance such as a vibration by gear backrush or a rope vibration in a vertical transfer you should take measures in the inverter side after you failed to investigate and fix machine devices to eliminate the resonance 315

Data setting range 0 00 to 0 00 s 315

Data setting range 0 to 50 315

Details of function codes 315

F66 asr1 output filter 315

F66 specifies the time constant for the first order lag filter applied to the torque command use this filter for a f66 specifies the time constant for the first order lag filter applied to the torque command use this filter for a mechanical resonance after you failed to adjust the asr gain or the constant of integration to eliminate it 315

F67 s curve acceleration 1 start 315

F68 s curve acceleration 1 end 315

F69 s curve deceleration 1 start 315

F70 s curve deceleration 1 end 315

Increase the asr i constant to shift the resonance point to lower frequency to restrain the high frequency resonance 315

Measures to eliminate mechanical resonance 315

Reduce response speed 315

Reduce the asr p gain to reduce the amplitude of the resonance 315

See h46 observer type selection for more details 315

Setting the s curve extends acceleration time 1 f07 and deceleration time 1 f08 according to the following expressions 315

These function codes arrange the speed reference value these function codes arrange the speed reference value to form a curve at the start and the end of acceleration and deceleration you can realize smooth acceleration and deceleration actions without shocks 315

Though you can reduce the resonance amplitude excessive filter elements may cause instability 315

Use asr output filter 315

Use oscillation suppressing observer 315

１５００ 316

１５００ 317

Chap 4 control and operation 319

Details of function codes 319

The limiter level 2 for f76 2 upper limit by the level 1 and the lower limit by the level 2 if you specify as the limiter level 1 the limiter level 2 the speed reference is fixed to the limiter level 2 in this state turning off the operation does reduce the speed reference and the operation continues 319

When f76 0 the upper and lower limit levels during fwd and rev operations switch between levels 1 and 2 319

When f76 1 or 2 the speed limiter acts as shown below 319

When you want to inhibit reverse rotation forward rotation directed by reverse rotation command while forward rotation command is directed specify as f76 0 the limiter level 1 100 and the limiter level 2 0 319

You may be injured 319

2 torque control torque command torque current command 320

Data setting range 0 limit forward and reverse individually fwd and rev switch the levels 1 level 1 limits forward and reverse 2 invalid even if specified the setting is assumed to be 0 3 individual limiters for forward and reverse rotation 12 input is added as a variable part of limiters 320

Data setting range 110 to 110 320

Level 1 2 320

Method selection 320

When f76 0 the upper and lower limit levels during fwd and rev operations switch between levels 1 and 2 320

When f76 1 the speed limiter acts as shown below 320

Answer back signals are put on the do output sw m2 and sw m3 to indicate whether the motor switch among motor set m1 m2 m3 is completed in the inverter see e15 to e27 for more information we recommend to prepare a sequence to check the do for the answer back when you use the terminal input signals mch2 and mch3 to switch motors 322

Data setting range 0 select m1 note that the terminal input has higher priority as shown below when m ch2 and m ch3 off off or on on or no m ch2 or m ch3 has been assigned m1 is selected when m ch2 and m ch3 on off m2 is selected when m ch2 and m ch3 off on m3 is selected 1 select m2 2 select m3 merits and restrictions for selecting m1 m2 or m3 322

F79 motor selection m1 m2 m3 322

If the motor set 2 is selected m2 is indicated 322

It is recommended to activate overcurrent suppression function h58 1 when m3 is selected v f control 322

The frenic vg can hold three sets of motor parameters m1 m2 and m3 which can be selected by f79 or the frenic vg can hold three sets of motor parameters m1 m2 and m3 which can be selected by f79 or x terminal functions m ch2 and m ch3 322

You can use the effective sets of motors parameters on the i o check screen of the keypad panel to check the currently selected motor set m1 m2 m3 322

１５００ 322

Data setting range 0 to 150 r min 324

Data setting range 30000 to 30000 r min 324

F81 offset for speed setting on terminal 12 324

F81 specifies an offset for analog speed input on terminal 12 use this setting for adjustment of out of offset f81 specifies an offset for analog speed input on terminal 12 use this setting for adjustment of out of offset signals sent from external equipment 324

F82 dead zone for speed setting on terminal 12 324

F82 specifies the dead zone speed for analog speed input on terminal 12 to limit the f82 specifies the dead zone speed for analog speed input on terminal 12 to limit the speed setting value within the range of f82 data to 0 r min 324

If the ld or md mode is selected for the inverter capacity not available to the mode the inverter runs in the hd mode 324

Note replacing the ht rating vg7 with the frenic vg 324

The frenic vg does not support the ht rating equivalent of the vg7 when replacing the ht rating vg7 use the frenic vg with one capacity rank higher note that the 200 v class series inverters of 7 to 22 kw and 400 v class series ones of 18 to 22 kw can be replaced with the frenic vg with the same capacity as long as the carrier frequency is 10 khz or below 324

Chap 4 control and operation 325

Data setting range 0 00 to 1 00 s 325

Data setting range 0 00 to 5 00 s 325

Data setting range 0 00 to 9999 specification of 0 00 clears the input watt hour data and stops counting 325

Details of function codes 325

F83 filter for speed setting on terminal 12 325

F83 specifies a time constant determining the first order delay of the analog speed input on terminal 12 f83 specifies a time constant determining the first order delay of the analog speed input on terminal 12 325

F84 display coefficient for input watt hour data 325

F84 specifies a display coefficient for displaying the input watt hour data m116 f84 specifies a display coefficient for displaying the input watt hour data m116 325

F85 display filter for calculated torque 325

F85 specifies a display filter for outputting the calculated torque on the led and lcd monitors f85 specifies a display filter for outputting the calculated torque on the led and lcd monitors 325

Input watt hour data m116 f84 x m115 input watt hour unit 100 kwh 325

Setting the f84 data to 1 1000 of the electric rate per 100 kwh enables the total electricity price in units of 1 000 to be displayed if the electric rate is 18 per kwh for example setting the f84 data to 1 displays 18 0 thousand yen if the input watt hour data is 10 0 100 kwh 325

E codes extension terminal functions 326

１５００ 326

Chap 4 control and operation 327

Data setting range 0 to 83 327

Details of function codes 327

Ｅ０１ｘ１ｆｕｎｃ 327

Ｅ１３ｘ１４ｆｕｎｃ 327

Function code data 0 1 2 3 select multistep speed 1 to 15 steps ss1 ss2 ss4 ss8 328

You can use external digital input signals to switch predetermined speeds specified by function codes from c05 to c19 multistep speed assign data 00 to 03 to digital terminals to select a speed by combining those terminal inputs 328

Chap 4 control and operation 329

Details of function codes 329

Example four and five are assigned to the terminals x2 and x3 329

Function code data 4 5 select asr and acc dec time 4 steps rt1 rt2 329

If you switch the acceleration deceleration times the asr constants and s curve actions are switched simultaneously you can see which set is currently selected from 1 2 3 4 on the i o check screen of the keypad panel when the data set 3 is selected para3 is indicated on the display 329

You can switch predetermined acceleration deceleration times asr constants and s curve accelerations decelerations specified by function codes through external digital input signals assign data 04 to 05 to digital terminals to select acceleration deceleration times asr constants and s curve accelerations decelerations 329

１５００ 329

Function code data 19 enable data change with keypad we kp 336

Function code data 20 cancel pid control kp pid 336

Function code data 21 switch normal inverse operation ivs 336

Function code data 22 interlock 52 2 il 336

In such a case use an external device to give a digital signal for informing the inverter of the momentary power failure 336

Note you cannot change the function codes if you set this data to a terminal by mistake if this is a case set on to the terminal and then set a correct data 336

The external digital input signal disables the pid control 336

The external digital input signal switches the direction of the motor rotation 336

The motor will restart smoothly after the power failure valid if the setting of f14 restart after momentary power failure action selection is 3 4 or 5 336

This function enables changes to the function codes through the keypad panel only when the digital input signal we kp is applied to prevent unauthorized changes you can make changes when 19 is not assigned to a terminal this function enables disables changes through the keypad panel use write enable through link to enable disable changes through the link 336

When a magnetic contactor is provided to the output of the inverter this magnetic contactor 52 2 opens to slow down the voltage drop in the dc circuit at a momentary power failure as a result the inverter may not detect the power failure to recover from the momentary power failure smoothly 336

Check the on off state of the input signal through rs 485 t link sx bus or fieldbus 338

Function code data 25 universal di u di 338

If you use rs 485 an integrated function is available see the descriptions of rs 485 for more details 338

There are following applications for this signal 338

Use for an input to software created with the upac option without affecting the inverter operation 338

When you select the operation command from the external signal fwd rev and the speed command from the analog terminal 12 input 0 10v or the rs 485 communication from master device such as a personal computer using le function the analog terminal 12 will be enabled if the terminal le is off and the rs 485 will be enabled if the terminal le is on 338

You can assign a data 25 to a digital terminal to designate it as a universal di terminal this function is provided to check the existence of an input signal through communication and does not affect the inverter operation 338

Also see e29 pg pulse output selection o12 to 19 pg pr options and the description on the pg pr options 340

Apply a pulse train signal from the external pulse generator to the pg pr options of multiple inverters to be synchronized the position command received by the option is converted into a synchronized speed command and the syc enables the speed command 340

Assign a data 27 to a desired digital input terminal and the state of the input signal applied to it selects the function 340

Function code data 27 synchronization operation command pg pr optional function syc 340

Function to be selected 340

Input signal to select specified data 340

Note that the zero speed locking command lock is disabled during the pulse train position control with syc 340

Off synchronized speed disabled other speed command enabled 340

On synchronized speed enabled 340

Synchronized operation by receiving pulse 340

This function switches between the speed command converted from a pulse train received as a position command via the position control and other speed command you can use this function for a synchronized operation you need an optional pg pr 340

About differences in methods 341

Chap 4 control and operation 341

Details of function codes 341

Pulse signal converted oscillated from an internal speed command such as 12 input or multistep speed command is also converted into a speed command through the position control and the syc enables the resulting speed command you can put the converted pulse signal to the output and apply it to the other inverters to synchronize the inverter with other inverters 341

Set e29 pg pulse output selection to 9 to directly supply the position command applied to the pg pr option to the fa and the fb of the integrated pg 341

Synchronized operation by pulse generation 341

Synchronized operation for three or more inverters 341

The complete synchronization 2 pulses or less is possible both in the application example 1 and 2 during the complete synchronization 2 pulses or less is possible both in the application example 1 and 2 during both transient and steady states 341

The motor speed of the master and the pg pulse number determines the pulse frequency when you use a pg with 1024 p r at 1500 r min the frequency is 1500 1024 60 25 khz the pulse compensation is available on the slave side see the function codes o14 and o15 or the pg pr option for more details 341

１５００ 343

Actions on detecting pg disconnection 347

Chap 4 control and operation 347

Details of function codes 347

Function code data 48 inverse pid output pid inv 347

Function code data 49 cancel pg alarm pg ccl 347

The external digital input signal cancels the pg alarm p9 this function is available when you select vector control for the function code p01 a01 or a101 347

The external digital input signal switches the pid output pidout between the normal operation and the inverse operation assign a data 48 to a desired digital input terminal and the state of the input signal applied to it selects the function 347

The inverter does not issue the alarm even when the pg wiring is disconnected during the input signal is on assign a data 49 to a desired digital input terminal and the existence of the input signal cancels the pg alarm 347

１５００ 358

１５００ 359

Data setting range 0 to 75 360

Ｅ１５ｙ１ｆｕｎｃ 360

Ｅ１６ｙ２ｆｕｎｃ 360

Ｅ１７ｙ３ｆｕｎｃ 360

Ｅ１８ｙ４ｆｕｎｃ 360

Ｅ１９ｙ５ｆｕｎｃ 360

Ｅ２０ｙ１１ｆｕｎｃ 360

Ｅ２１ｙ１２ｆｕｎｃ 360

Ｅ２２ｙ１３ｆｕｎｃ 360

Ｅ２３ｙ１４ｆｕｎｃ 360

Ｅ２４ｙ１５ｆｕｎｃ 360

Ｅ２５ｙ１６ｆｕｎｃ 360

Ｅ２６ｙ１７ｆｕｎｃ 360

Ｅ２７ｙ１８ｆｕｎｃ 360

Chap 4 control and operation 361

Details of function codes 361

Inverter running run 361

Running is defined as a state when the inverter supplies output this signal is on when the inverter is running and off when the inverter is stopping 361

See the function description of e44 speed agreement detection range off delay timer and e45 enable disable alarm for speed disagreement 361

Speed agreement 1 n ag1 361

Speed valid n ex 361

The inverter does not stop when it is decelerating after you turn off the fwd or the rev signal the inverter shuts down the output and stops when the speed becomes less than the speed specified by f37 stop speed and the zero speed continues for the time specified by f39 zero speed holding time the status is running during dc braking pre exciting and servo locking synchronized control completed 361

Turns on when motor m1 is selected and the actual speed value falls in the detection range specified by the speed command value reference speed 4 asr input 361

Turns on when the absolute value of the speed command or the actual speed is more than the value specified by the function code f37 stop speed and off when the value is less than the stop speed 361

You can use the function code f38 stop speed detection method to select either the speed command or the actual speed 361

1 at the time of start 365

2 at the time of stop 365

Adjust the braking conditions to apply brake within the zero speed control holding time f39 specifying the zero speed control f37 0 r min and the speed detection level 1 e39 0 r min enables brd brake release signal to go off after the motor machine stops completely 365

Brake application and release timings can be adjusted with the starting speed f23 f24 and stop speed f37 to f39 365

Chap 4 control and operation 365

Details of function codes 365

Starting speed stop speed 365

Starting speed with torque bias set the starting speed f23 to 0 r min and set the torque detection level 1 2 e46 e47 so that brd brake release signal comes on within the holding time f24 365

Starting speed without torque bias in order not to release brake during acceleration set the starting speed f23 to 0 r min or above and set the torque detection level 1 2 e46 e47 so that t dt1 or t dt2 torque detected 1 or 2 comes on within the holding time f24 365

22 alarm content al1 al2 al4 al8 366

Cooling fan in operation fan 366

Provides the operation status of the inverter protection function 366

Resetting try 366

This signal is associated with h06 fan stop operation and is present when the cooling fan is operating 366

This signal is issued when the protective function is conducting the retry operation if you set one or more to h04 auto reset times 366

Chap 4 control and operation 379

Data setting range 0 to 300 379

Data setting range 10 to 100 379

Details of function codes 379

E46 torque detection level 1 379

E47 torque detection level 2 379

E48 magnetic flux detection level 379

E49 to e52 e49 to e52 ai terminal function 379

E49 to e52 select functions to be assigned to analog input terminals ai1 to ai4 respectively e49 to e52 select functions to be assigned to analog input terminals ai1 to ai4 respectively 379

Note the calculated torque value is used for determination in v f control 379

Provides a detection signal when the calculated magnetic flux value exceeds a specified value the detection provides a detection signal when the calculated magnetic flux value exceeds a specified value the detection signal appears on the do to which the m dt is assigned 379

Provides a detection signal when the torque command exceeds a specified value you can specify two levels provides a detection signal when the torque command exceeds a specified value you can specify two levels of detection level level 1 and level 2 100 means a torque command of the continuous rating the detection signals appear on the do s to which the t dt1 and t dt2 are assigned 379

Some functions are not available depending upon the drive control vector control with without speed sensor v f control and synchronous motor drive for details refer to section 4 function code tables 379

Data setting range 0 to 27 380

Note that you should assign u ai to all the analog input terminals at the same time 380

Note the current input function on terminal ai2 applies only to the n refc current input speed setting the function cannot be used on terminal ai1 380

There are 19 types of analog input functions from 0 to 18 available you cannot use all of these functions at the same time you can use total of four terminals which are two terminals ai1 and ai2 as standard and two terminals ai3 and ai4 using optional aio the maximum number you can use is four unless you switch externally 380

When you assign the same function to ai1 and ai2 the input to ai2 will become effective when you install the aio option and assign the same function to ai1 ai2 ai3 and ai4 the input to ai4 will become effective priority order 1 ai1 2 ai2 3 ai3 4 ai4 380

１５００ 381

Data setting range 10 00 to 10 00 times 386

Data setting range 100 to 100 386

E53 to e56 ai gain 386

E57 to e60 e57 to e60 ai bias 386

Key at the keypad panel is valid to save to the backup memory press the 386

Key key 386

Note terminals ai3 and ai4 are available only when you install opc vg1 aio 386

The data changed with the 386

These function codes specify biases to be applied to analog input terminals ai1 to ai4 a value of 100 these function codes specify biases to be applied to analog input terminals ai1 to ai4 a value of 100 corresponds to a doubled offset value 386

These function codes specify gains to be applied to analog input terminals ai1 to ai4 these function codes specify gains to be applied to analog input terminals ai1 to ai4 386

Chap 4 control and operation 387

Data setting range 0 0 to 60 0 s 387

Data setting range 0 00 to 0 00 s 387

Details of function codes 387

E61 to e64 ai filter 387

E65 to e68 e65 to e68 up down limiter ai 387

Note terminals ai3 and ai4 are available only when the opc vg1 aio is mounted 387

Note terminals ai3 and ai4 are available only when you install opc vg1 aio 387

Since a large filter time constant decreases the response consider the response of a mechanical system to determine the time constant if the input voltage fluctuates due to noise first try hardware measures and then use this filter after you failed 387

These function codes specify a time to increase a data inside the inverter from 0v to 10v when you change the these function codes specify a time to increase a data inside the inverter from 0v to 10v when you change the input from 0 to 10v applied to analog input terminals ai1 to ai4 387

These function codes specify whether to apply a filter to analog input terminals ai1 to ai4 as well as these function codes specify whether to apply a filter to analog input terminals ai1 to ai4 as well as specifying a time constant of the filter individually the filter used here is a low pass filter the time constant means the time until the filter output data reaches 63 of the input data 387

To avoid this phenomenon though you should change the command with an external volume you can use this increment decrement limiter to specify the automatic increase and decrease of an analog command value 387

Use the function code e65 to e68 to increase or decrease a command value gradually 387

When you use the analog torque command or the analog torque bias you may not use a command that changes stepwise a step wise torque command may tear a paper in a paper rolling machine or present an elastic vibration damping when a subject matter has a large elastic modulus 387

Chap 4 control and operation 389

Data setting range 0 to 40 389

Details of function codes 389

E69 to e73 ao terminal function 389

E69 to e73 select functions to be assigned to analog output terminals ao1 to ao5 respectively e69 to e73 select functions to be assigned to analog output terminals ao1 to ao5 respectively 389

Note terminals ao4 and ao5 are available only when the opc vg1 aio is mounted 389

Some functions are not available depending upon the drive control vector control with without speed sensor v f control and synchronous motor drive for details refer to section 4 function code tables 389

To 29 are reserved do not use them 389

Ｅ６９ａｏ１ｆｕｎｃ 389

Ｅ７０ａｏ２ｆｕｎｃ 389

Ｅ７１ａｏ３ｆｕｎｃ 389

Ｅ７２ａｏ４ｆｕｎｃ 389

Ｅ７３ａｏ５ｆｕｎｃ 389

１５００ 390

Data setting range 0 00 to 0 00 s 394

Data setting range 100 0 to 100 0 394

Data setting range 100 0 to 100 0 times 394

E74 to e78 ao gain 394

E79 to e83 e79 to e83 ao bias 394

E84 ao1 ao5 filter 394

E84 specifies the time constant of the output filters for the analog output ao1 to ao5 simultaneously e84 specifies the time constant of the output filters for the analog output ao1 to ao5 simultaneously 394

Note ao4 and ao5 are available only when the opc vg1 aio is mounted 394

These function codes specify gains to be applied to analog these function codes specify gains to be applied to analog output terminals ao1 to ao5 394

These function codes specify the bias of analog output ao1 to ao5 these function codes specify the bias of analog output ao1 to ao5 394

Chap 4 control and operation 395

Data setting range 0 to 12 395

Details of function codes 395

E90 link command function selection 1 available soon 395

For details refer to the ai1 function selection 395

The e90 setting has priority over ai functions selected by e49 to e52 395

When e90 when e90 0 it is possible to set ai input data with digital data via the communications link s16 s17 395

Ｅ９０ｌｎｋｆｕｃ１ 395

Data setting range 0 0 to 10 0 396

Data setting range 0 to 12 396

Data setting range 100 0 to 100 0 396

E101 to 396

E104 ai offset 396

E105 to 396

E108 ai dead zone 396

E91 link command function selection 2 available soon 396

Keys makes the new data effective to save it into the backup memory it is necessary to press the 396

Note ai3 and ai4 are available only when the opc vg1 aio is mounted 396

The setting contents are the same as for e90 refer to the link command function selection 1 396

These function codes are functionally equivalent to e57 to e60 396

These function codes specify ai dead zones for analog these function codes specify ai dead zones for analog input entered via analog input terminals ai1 to ai4 command values below this input will be limited to 0 v 396

These function codes specify ai offsets only changing the these function codes specify ai offsets only changing the function code data with the 396

Use these function codes for adjustment of out of offset signals sent from external equipment 396

When e91 when e91 0 off it is possible to select analog data via the communications link s17 in priority to ai input made by the ai function selection 396

C codes control functions 399

C01 jump speed 1 399

C02 jump speed 2 399

C03 jump speed 3 399

C04 hysteresis width for jump speed 399

Chap 4 control and operation 399

Data setting range c01 to c03 0 to 30 000 r min c04 0 to 1 000 r min 399

Details of function codes 399

Example jump speed 100 r min jump width 300 r min 399

If the jump width is larger than twice the jump speed setting the downward jump is limited at 0 r min 399

Jumps the speed reference to avoid mechanical resonance points of a load jumps the speed reference to avoid mechanical resonance points of a load 399

When specified ranges of jump speed overlap one another the sum of them is considered as a jump range 399

You can set three jump points when you set the jump speed 1 to 3 to 0 r min this function is disabled the speed reference does not jump during acceleration deceleration 399

１５００ 402

P codes motor parameter functions 405

１５００ 405

Chap 4 control and operation 407

Details of function codes 407

List of applicable motors 407

Note when using fuji vg1 5 series motors select other for p02 and specify the motor parameters given in the user s manual chapter 12 407

P02 m1 motor selection 407

P02 specifies the motor type to be used p02 specifies the motor type to be used 407

The configuration procedure of the related function codes differs between the use of the vg dedicated motors except fuji vg1 5 series motors setting 0 5 2 to 220 4 and 30 2a to 220 4a and that of other motors setting other 407

When any other motor fuji vg1 5 series motors fuji motors vg3 etc is used select other 407

When the vg dedicated motor is used selecting the combination of capacity kw voltage 2 4 from a choice of 0 5 2 to 220 4 and 30 2a to 220 4a automatically sets the optimum values of the standard motors see the table given on the next page to f04 f05 and p03 to p27 and then write protects those function codes 407

Ｐ０２ｍ１ｓｅｌｅｃｔ 407

Function codes to be configured for im under vector control function codes to be configured for im under vector control 408

The table below lists the function codes to be configured for im when vector control is selected configure them sequentially from the top of the table 408

Chap 4 control and operation 409

Details of function codes 409

Note the vg dedicated motors are the same as the vg7 and vg5 dedicated motors in shape and motor parameters 409

Function codes to be configured for pmsm under vector control function codes to be configured for pmsm under vector control 410

The table below lists the function codes to be configured for pmsm when vector control is selected configure them sequentially from the top of the table 410

When fuji standard motors gnf2 type are used the following function codes take effect for other motors consult your fuji sales representative 410

Chap 4 control and operation 411

Details of function codes 411

Function codes to be configured for im under v f control function codes to be configured for im under v f control 411

Note the vg dedicated motors are the same as the vg7 and vg5 dedicated motors in shape and motor parameters 411

The table below lists the function codes to be configured for im when v f control is selected configure them sequentially from the top of the table 411

100 3 v voltage rated motor f05 a current rated motor p04 resistance cable r1 r1 ω ω 413

A current exciting p08 current rated p04 current torque p09 413

Data setting range 0 0 to 200 0 413

Data setting range 0 0 to 30 0 413

Data setting range 0 1 to 99 9 a 100 to 999 a 1 000 to 2 000 a 413

P06 m1 r1 413

P07 m1 x 413

P08 m1 exciting current magnetic flux weakening current id 413

P09 m1 torque current 413

Sets the current contributing torque sets the current contributing torque 413

Sets the effective current value of the motor 1 during no load operation sets the effective current value of the motor 1 during no load operation 413

Use a value corresponding to one winding of multiwinding motor 413

Use a value corresponding to the y connection for one phase to specify r1 ω 413

Use a value corresponding to the y connection to specify lσ h 413

Data setting range 0 0 to 10 0 414

Data setting range 0 01 to 10 00 hz 414

Data setting range 0 to 100 414

P10 m1 slip frequency for driving 414

P11 m1 slip frequency for braking 414

P12 m1 iron loss factor 1 414

P12 to p14 specify iron loss factors to compensate the iron loss hysteresis loss eddy current loss caused p12 to p14 specify iron loss factors to compensate the iron loss hysteresis loss eddy current loss caused inside the motor 414

P13 m1 iron loss factor 2 414

P14 m1 iron loss factor 3 414

P15 m1 magnetic saturation factor 1 414

P15 to p19 specify the magnetic saturation factors for the exciting current to apply when the magnetic flux p15 to p19 specify the magnetic saturation factors for the exciting current to apply when the magnetic flux command is 93 5 87 75 62 and 50 respectively 414

P16 m1 magnetic saturation factor 2 414

P17 m1 magnetic saturation factor 3 414

P18 m1 magnetic saturation factor 4 414

P19 m1 magnetic saturation factor 5 414

R min speed rated f04 r min speed zed synchroni numbers pole p05 hz frequency slip 414

Sets the slips of the motor at rated speed and under rated load sets the slips of the motor at rated speed and under rated load 414

Since the relationship between the exciting current that generates magnetic flux in an im and the magnetic flux is non linear to compensate it specify the factors with these function codes 414

When using motors other than fuji standard motors set the iron loss compensation at 0 0 414

Chap 4 control and operation 415

Corrects the exciting inductance do not change these settings corrects the exciting inductance do not change these settings 415

Data setting range 0 01 to 9 99 s 415

Data setting range 0 to 999 v 415

Details of function codes 415

P20 m1 secondary time constant 415

P21 m1 induced voltage factor 415

P22 m1 r2 correction factor 1 415

P23 m1 r2 correction factor 2 415

P24 m1 r2 correction factor 3 415

P25 m1 exciting current correction factor 415

Set value effective induced voltage substituted by the voltage between the windings at the rated speed 415

Set value secondary time constant s lm h r2 ω lm exciting inductance r2 resistance of secondary winding 415

The resistance of the rotor secondary resistor is used to calculate the slip frequency in vector control of slip the resistance of the rotor secondary resistor is used to calculate the slip frequency in vector control of slip frequency type the change in secondary resistance due to the temperature increase caused by the frequent operation or load may degrade the torque control accuracy the inverter detect the temperature with an ntc thermistor and use r2 correction coefficient 1 2 and 3 to estimate the rotor temperature to prevent the decrease of the torque control accuracy do not change these settings 415

The response of the magnetic flux to the exciting current is a first order lag this time constant is defined as the response of the magnetic flux to the exciting current is a first order lag this time constant is defined as secondary time constant and you should set a value determined by the motor parameters as in the following equation you can compensate the lag to lead 415

The rotating magnetic field generated by the stator primary winding sections the rotor vertically to induce the rotating magnetic field generated by the stator primary winding sections the rotor vertically to induce voltage on the secondary side in an induction machine you can add voltage larger than this induced voltage to accelerate a motor this function sets a coefficient to compensate this induced voltage 415

Data setting range 0000 to 4fff h 416

Data setting range 100 to 60 000 416

P26 m1 acr p gain 416

P26 setting range 0 to 20 p27 setting range 0 to 100 ms 416

P27 m1 acr i time 416

P28 m1 pulse resolution 416

P28 specifies the pulse resolution p r of the speed detector pg of motor 1 specification of a wrong value p28 specifies the pulse resolution p r of the speed detector pg of motor 1 specification of a wrong value unstabilizes the detection of the speed and magnetic pole position disabling accurate speed control or vector control 416

P29 m1 external pg correction factor 416

Setting procedure suppose the gear ratio is a b specify the function code p28 and p29 as indicated below 416

Vector control feeds back the motor output current to control a motor to follow the current command these vector control feeds back the motor output current to control a motor to follow the current command these functions specify the gain and the integration time for the current control acr usually you do not have to change from the factory setting 416

When a winding has a large inductance you should set a large p gain to compensate it in general when a winding has a small inductance you should set a small p gain to prevent oc overcurrent due to the overshoot of the current 416

When you do not use an external pg do not change from 4000h the value of 4000h corresponds to a gear ratio of 1 1 i e a pg directly coupled to a motor when you use a pg directly coupled to a motor if you set a value other than 4000h you cannot conduct speed and vector controls accurately 416

You need a correction coefficient to convert the output of a pg built in a machine system into the motor speed you need a correction coefficient to convert the output of a pg built in a machine system into the motor speed to control the speed set the coefficient here speed control by pg requires parameter setting at both p28 and p29 416

You should specify the integration time to reduce the steady state deviation between the current command and the actual current to zero do not specify too small value otherwise a current hunting occurs 416

A152 m3 online auto tuning 417

A52 m2 online auto tuning 417

Chap 4 control and operation 417

Data setting range 0 disable 1 enable 417

Data setting range 0 no thermistor 1 ntc thermistor for vg standard motors 2 ptc thermistor 3 ai m tmp 417

Data setting range 80 to 999 v 417

Details of function codes 417

For frenic vg motors vg7s vg5 and vg3 select an ntc thermistor if the motor has a ptc thermistor of overheat protection select a ptc thermistor 417

P30 m1 thermistor selection 417

P30 selects a thermistor type or an analog input 0 to 10 v sent from the temperature sensor for motor p30 selects a thermistor type or an analog input 0 to 10 v sent from the temperature sensor for motor protection 417

P32 a52 and a152 select whether or not to perform auto tuning for compensating constants change due to p32 a52 and a152 select whether or not to perform auto tuning for compensating constants change due to temperature rise 417

P32 m1 online auto tuning 417

P33 is provided for v f control and vector control for pmsm under v f control the p33 setting applies to the p33 is provided for v f control and vector control for pmsm under v f control the p33 setting applies to the maximum output voltage so specify the output voltage of the inverter running at high speed the voltage higher than the source voltage cannot be output 417

P33 m1 maximum output voltage maximum voltage limit 417

Perform auto tuning of motor constants be sure to test run the combination of the inverter and motor beforehand auto tuning is not available when an ntc thermistor is used 417

Setting example if pg pulse number 1 024 and the gear ratio a b 7 1 then 417

The protection level of the motor can be specified by e30 motor overheat protection temperature 417

Under vector control for pmsm the p33 setting applies to the maximum voltage limit value so specify the maximum voltage that the inverter can output do not specify the voltage less than the rated voltage 417

Ａ１５２ｍ３ｏｎｔｕｎｅ 417

Ａ５２ｍ２ｏｎｔｕｎｅ 417

Ｐ３０ｍ１ｔｈｒ 417

Ｐ３２ｍ１ｏｎｔｕｎｅ 417

Ｐ３３ｍ１ｖｍ a x 417

Compensating insufficient magnetic flux of a motor due to the voltage drop in the low frequency range and boosting torque at low speed operation boosting v f characteristic 418

Data setting range 20 00 to 5 00 hz 418

Load characteristics including automatic torque boost variable torque load proportional torque load and constant torque load 418

Note when replacing the vg7 22 kw or below with the vg1 specify the torque boost according to the torque boost conversion table in chapter 12 section 12 418

P34 is exclusive to v f control a change in the load torque will change the motor slip resulting in the motor p34 is exclusive to v f control a change in the load torque will change the motor slip resulting in the motor speed change the slip compensation control adds a frequency proportional to the motor torque to the inverter output frequency and reduces the fluctuation of the motor speed due to torque change 418

P34 m1 slip compensation 418

P35 is exclusive to v f control the following choices are available p35 is exclusive to v f control the following choices are available 418

P35 m1 torque boost 418

The slip compensation value can be calculated with the following expression 418

Torque characteristic 418

When p34 0 00 hz the slip compensation control is disabled 418

Chap 4 control and operation 419

Data setting range 0 0 to 1 0 419

Details of function codes 419

Guide for setting the torque boost 419

Note increasing the torque boost value results in overexcitation in the low speed domain keeping the inverter running with the overexcited state may cause the motor to overheat check the characteristics of the motor to be driven 419

P36 is exclusive to v f control when the inverter output current fluctuates due to the motor characteristics or p36 is exclusive to v f control when the inverter output current fluctuates due to the motor characteristics or backlash at the load side adjust the damping gain do not change the factory default unless otherwise needed 419

P36 m1 output current fluctuation damping gain 419

When adjusting the starting torque with manual boost setting data 2 to 20 since the motor characteristics are unknown use the following as a guide 419

H codes high performance functions 420

An accident or injuries could occur 421

Chap 4 control and operation 421

Details of function codes 421

The tuning type data to be tuned and tuning content differ depending upon the motor drive control select the tuning suitable for the drive control p01 421

Under vector control for im with without speed sensor 421

When motor parameters are configured at the time of shipment use those parameter values as is 421

When p01 0 or 1 vector control for im with without speed sensor go to 1 below when p01 3 vector control for pmsm with speed sensor available soon when p01 5 v f control for im go to 2 below 421

Ｈ０１ｔｕｎｍｏｄｅ 421

An accident or injuries could occur 422

At the time of shipment the torque boost function is set to auto torque boost t use the inverter in applications requiring a starting torque be sure to perform motor parameter auto tuning 422

Under v f control for im 422

Asr auto speed regulator auto tuning procedure h01 1 available soon 423

Chap 4 control and operation 423

Details of function codes 423

Motor parameter auto tuning procedure h01 2 424

Auto tuning with the motor stopped running procedure h01 3 or 4 425

Chap 4 control and operation 425

Details of function codes 425

Injuries could occur 425

When h01 1 or 4 the motor rotates during tuning make sure that there is no danger in rotating the motor 425

Chap 4 control and operation 437

Details of function codes 437

H29 communications link function data protection via link 437

H30 communications link function link operation 437

Note if run commands and control inputs are enabled on both s06 and terminal block they are ored 437

Protects code data from false writing through different types of communication systems such as integrated protects code data from false writing through different types of communication systems such as integrated rs 485 and field bus 437

Set value 437

Set value 0 write enabled 1 write protected 437

Uses different types of communication systems such as integrated rs 485 and field bus to enable disable uses different types of communication systems such as integrated rs 485 and field bus to enable disable command data such as speed command position command torque command and operation commands fwd and rev control inputs x1 x9 x11 x14 monitoring access to m area is always available the command data correspond to s01 to s05 and s08 to s12 the operation commands correspond to the lowest two bits of s06 437

When you assign le to a digital input you can connect between le and cm to enable the setting by h30 and open to disable operations specified through the link set to h30 0 regardless of the setting by h30 437

When you assign we link to a digital input you can protect from writing by short circuiting between we link and com 437

You can use the keypad panel to check the operation commands from you can use the keypad panel to check the operation commands from the link and i o check of control input 437

You should use h30 serial link to define the write operation to the s area function codes including operation commands and speed commands separately 437

１５００ 437

Chap 4 control and operation 441

Details of function codes 441

H42 torque current command source 441

H43 magnetic flux command source 441

If the ai input and link are selected magnetic flux command inputs within 10 are fixed at 10 441

Selects an element with which you provide the magnetic flux command selects an element with which you provide the magnetic flux command 441

Selects an element with which you provide the torque command see the control block diagram for more selects an element with which you provide the torque command see the control block diagram for more details 441

Setting value 0 internal asr data 1 ai input t ref 2 dia card 3 dib card 4 link s03 441

Setting value 0 internal calculated value 1 ai input mf ref 2 function code h44 3 link s04 441

Use also the speed limiter setting f76 to f78 when you use the torque command 441

H125 observer m1 m2 m3 compensation gain 442

H126 observer m1 m2 m3 i time 442

H127 observer m1 m2 m3 load inertia 442

H44 magnetic flux command value 442

H46 observer mode selection 442

H47 48 125 setting range 0 0 to 1 0 times h49 50 126 setting range 0 05 to 1 00 s h51 52 127 setting range 0 01 to 50 00 kg m2 442

H47 h48 442

H49 h50 442

H51 h52 442

Note when a load inertia specified by h51 or h52 and h127 has a large error you cannot obtain an expected performance specify an accurate value 442

Setting value 0 disabled 1 load disturbance observer 2 oscillation suppressing observer 442

Setting value 10 to 100 442

Specifies an inertia of a mechanical system or uses the asr tuning to measure the inertia operates an internal specifies an inertia of a mechanical system or uses the asr tuning to measure the inertia operates an internal machine model in the inverter estimates a load torque that becomes a disturbance element or a oscillation element adds a value to the torque command to counteract the load torque to increase the speed response against a load disturbance and to damp an oscillation generated by the mechanical resonance quickly 442

Specifies magnetic flux command value this function becomes available when you set 2 to h43 specifies magnetic flux command value this function becomes available when you set 2 to h43 442

Specifies the compensation gain the integral time and the load inertia for the observer function 442

Specify a load inertia of motor shaft conversion in kg m2 you can also use asr tuning by h01 tuning operation selection to measure the inertia 442

Chap 4 control and operation 445

Details of function codes 445

H202 h205 h208 h211 load inertia 0 01 to 50 00 kg 445

H58 overcurrent suppression 445

H60 to h66 h60 to h66 load adaptive control 445

Internal calculation of the inverter estimates the load during acceleration up to the rated base motor speed to calculate the maximum operable speed and perform speed limit control operation at the same speed in the up and down winding cycles with the same load is a major feature as well the maximum speed calculation correction function is added so that the up down winding operation at the rated load is always at the rated base motor speed the function can be used for lifting equipment equipped with a counterweight 445

Note in a multi winding system specify the quotient of the total inertia divided by the number of windings for example for a motor with two windings specify a half the total inertia 445

Note the torque generated by the motor may decrease under a suppressed voltage state do not use this function for vertical transportation applications 445

Set value 0 disabled 1 enabled 445

Specify the inertia without a load converted to the m1 motor shaft 445

The load adaptive control is valid with the m1 motor only specify the same torque limit value for driving and braking 445

The overcurrent trip occurs when the motor current changes suddenly to become more than the protection the overcurrent trip occurs when the motor current changes suddenly to become more than the protection level the overcurrent suppressing function restrains the inverter from supplying a current more than the protection level when the load changes 445

This function is related with the load adaptive control h201 to h227 refer to section 4 control block this function is related with the load adaptive control h201 to h227 refer to section 4 control block diagrams 445

This function is related with the multi limit speed pattern function h214 to h227 for load adaptive control this function is related with the multi limit speed pattern function h214 to h227 for load adaptive control and multi limit speed pattern refer to section 4 control block diagrams h51 observer setting load inertia of m1 0 01 to 50 00 kg 445

Use acceleration deceleration time 1 during operation under load adaptive control do not change the acceleration deceleration time setting during load adaptive control operation 445

Use this function to lift faster in case of small loads when compared with the speed at the rated load thereby improving the efficiency of operation of the equipment 445

After about 1 seconds the function code list screen appears after about 1 seconds the function code list screen appears 449

After stop data set appears the fwd stop key operations appear alternately 449

Change the data of the function code with the 449

Chap 4 control and operation 449

Details of function codes 449

If the diagnosis result is normal complete ok appears 449

If the polarity of the detected speed value is reversed a b phase err appears move to the function code setting screen with reset key or stop key on 449

If the speed detection circuit is abnormal pg cir err appears move to the function code setting screen with reset key or stop key on 449

Key on 449

Pg detection circuit display during self diagnosis 449

Start pg detection circuit self diagnosis with start pg detection circuit self diagnosis with 449

The h74 setting automatically returns to 0 449

When 100 appears pg detection circuit self diagnosis is finished forcible stop is possible with stop key or reset key on 449

Inverter is stopped undervoltage alarm has not occurred cooling fan is running will be forcibly stopped by the inverter when the power is shut off 451

By assigning the life prediction life signal to one of the function codes of the y function selection setting e15 to e19 a life prediction signal is output to the general purpose output y1 to y5 when all of the conditions below are met 452

Life determination cancel lf ccl is off 452

M46 main circuit capacitor capacitance is 85 or lower 452

Measurement will take place under the following conditions however the result will not be correct 452

Power is supplied from the r0 t0 auxiliary power 452

Rs 485 communication is used 452

The 10 s digit of h104 is 1 default value 452

The measurement conditions are different from the factory default standard refer to the table below 452

When a breaking unit or other inverter is connected to the p n main circuit terminals by dc bus connection 452

When the capacitor capacitance measurement method is the user measurement value standard 1 s digit of h104 is 1 452

Adds speed drop detection signal and speed setting detection signal conditions to the on off conditions of adds speed drop detection signal and speed setting detection signal conditions to the on off conditions of the break release signal brk for details on the brake release signal brk refer to the explanation of 18 brake release signal brk in function codes e01 e13 x terminal function 459

Chap 4 control and operation 459

Details of function codes 459

For normal use do not change 459

Function code h134 sets the time interval from the point that the inverter is running until the speed drop detection function starts operating 459

H112 to h118 459

H134 speed drop detection delay timer 459

M1 magnetic saturation extension coefficients 6 12 459

Only valid when vector control with speed sensor induction motor is selected only applies to the m1 motor the m2 and m3 motors do not have a function code that is equivalent to this function code 459

Set whether the led display shows l al when a light alarm occurs 459

Setting 0 to 1 0 disable l al not displayed 1 enable l al displayed 459

Setting 0 to 100 459

Setting range 0 00 to 10 00 s 459

The excitation current current that creates magnetic flux in the induction motor and magnetic flux are in a the excitation current current that creates magnetic flux in the induction motor and magnetic flux are in a non linear relationship to maintain the saturation characteristics when the saturation characteristics are significant in an application that exceeds a fixed output range of 1 2 set a correction factor 459

These become function codes that expand the characteristics of p15 to p19 459

For details refer to the explanation of functions h60 to h66 465

For multi winding systems or for synchronous driving of a load with multiple motors divide the total inertia by the number of windings or the number of motors and set the resulting value for example for a two winding motor set 1 2 the value of the total inertia 465

H201 to h213 465

H202 h205 load inertia hoisting 1 2 h208 h211 load inertia lowering 1 2 h202 h205 load inertia hoisting 1 2 h208 h211 load inertia lowering 1 2 465

H203 h206 safety factor hoisting 1 2 h209 h212 safety factor lowering 1 2 465

H204 h207 machine efficiency hoisting 1 2 h210 h213 machine efficiency lowering 1 2 h204 h207 machine efficiency hoisting 1 2 h210 h213 machine efficiency lowering 1 2 465

Load adaptive control parameter settings 1 available soon 465

Parameters used for load compensation control parameters used for load compensation control 465

Set the total efficiency of the machine 465

Setting 0 00 to 1 00 465

Setting 0 01 to 50 00 kg 465

Setting 0 to 1 0 465

Settings 0 h51 h64 h65 enabled h202 h213 disabled 1 h51 h64 h65 enabled h202 h213 disabled set the inertia for m1 motor axis conversion not including the applied load 465

A torque level setting for a limit speed point that exceeds the maximum speed will be invalid 466

H214 1 enables the multi restriction speed pattern function for the relation to the h201 h213 load h214 1 enables the multi restriction speed pattern function for the relation to the h201 h213 load compensation control function refer to the explanation of functions h60 h66 466

H214 to h227 load adaptive control parameter settings 2 available soon 466

H215 h224 multi limit speed pattern 466

H215 maximum speed h216 rated speed h217 rated speed 1 h218 rated speed 1 h219 rated speed 1 h220 rated speed 1 h221 rated speed 1 h222 rated speed 2 h223 rated speed 2 h224 rated speed 3 466

Set the torque level of each limit speed point as indicated below 466

Set the torque level tnmax for the maximum speed to a smaller value than the torque levels set for the limit speed points less than the maximum speed 466

Setting 0 to 100 466

The multi limit speed pattern bold line below is limited to within the rated motor torque pattern fine line below 466

The settings for t1 to t9 should increase in order from t1 t1 t2 t9 466

Discrimination start speed 1125 r min 1500 0 5 discrimination end speed 1405 r min 1500 0 37 calculation interval t 1405 1125 3000 5 s 0 35 s 467

H226 load compensation calculation is performed when the speed set for the discrimination end speed is reached when the discrimination interval is short or the torque command value varies widely deviations occur in the calculation results when there are wide variations in the torque command value adjust the speed control factor asr to decrease the variations in the torque command value 467

In this example operation takes place according to the speed command value if a torque restriction is triggered or the detected speed value does not accord with the speed command the time t will be different 467

The first operation after powering on is lowering 2 a limit speed was not calculated for the previous hoisting operation the previous hoisting took place at a speed under the h226 limit speed discrimination interval end speed 3 lowering was performed after pre excitation was stopped note 1 468

The initial operation after powering on is lowering 2 a limit speed was not calculated for the previous hoisting operation the previous hoisting took place at a speed under the h226 limit speed discrimination interval end speed 3 lowering was performed after pre excitation was stopped note 1 468

Chap 4 control and operation 469

Details of function codes 469

Four increments are available for the width setting a larger setting allows a wider frequency band to be covered normally a setting of 2 is recommended 469

H322 h325 notch filters 1 and 2 resonance frequency 469

H323 h326 h323 h326 notch filters 1 and 2 attenuation level 469

H324 h327 h324 h327 notch filters 1 and 2 frequency range 469

Khz 5 khz 10 khz 11 khz 10 to 2000 hz 4 khz 7 khz 8 khz 9 khz 15 khz 10 to 1500 hz 3 khz 6 khz 12 khz 13 khz 14 khz 10 to 1000 hz 469

Set a notch filter frequency attenuation and width appropriate for the resonance point in the machine 469

Set this to dampen resonance in the mechanical system a maximum of 2 resonance points can be dampened set this to dampen resonance in the mechanical system a maximum of 2 resonance points can be dampened 469

Setting 0 to 3 469

Setting 0 to 40 db 469

Setting 10 to 2 000 hz 469

Setting method setting method 469

The notch filter frequency is limited internally based on the setting of f26 carrier frequency carrier frequencies and corresponding notch filter setting ranges are shown below if the setting exceeds the upper limit the upper limit is applied 469

A codes alternative motor functions 470

A codes are motor parameters that become available when motor m2 or m3 is selected these codes are used when a single frenic vg drives two or three motors while switching them 470

A01 to a61 a01 to a61 m2 drive control 470

A01 to a61 for m2 are functionally equivalent to a101 to a161 for m3 except that codes differ by one hundred those codes are functionally equivalent to p codes m1 470

A101 to 470

A161 m3 drive control 470

Any of m1 to m3 can select vector control or v f control 470

Auto tuning initiated by h01 applies to the currently selected motor 470

Function codes to be configured for im under vector control function codes to be configured for im under vector control 470

Note 1 frenic vg dedicated motors are the same as the vg7 or vg5 standard motors in shape and electrical constants motor parameters 470

See the individual descriptions and check in menu 4 i o checking that m2 or m3 is selected indicates selected check that m2 or m3 is indicated 470

The table below lists the function codes to be configured for im when vector control is selected configure them sequentially from the top of the table for details refer to p02 m1 motor selection 470

There are no p02 equivalent code for m2 and m3 so m2 and m3 motor parameters cannot be set automatically for frenic vg dedicated motors or vg series conventional motors this manual provides motor parameters set them manually for other motors perform auto tuning 470

To select m2 or m3 use f79 motor selection and terminal input signals to select m2 or m3 use f79 motor selection and terminal input signals m ch2 and m ch3 470

１５００ 470

Chap 4 control and operation 471

Details of function codes 471

Function codes to be configured for pmsm under vector control 471

The table below lists the function codes to be configured for pmsm when vector control is selected configure them sequentially from the top of the table 471

Function codes to be configured for im under v f control 472

The table below lists the function codes to be configured for im when v f control is selected configure them sequentially from the top of the table 472

O codes option functions 473

Data setting range 0 integrated pg 15 12v complementary output pg interface card opc vg1 pmpg for pmsm drive 474

Data setting range o06 100 to 60 000 p r o07 o08 1 to 9 999 474

High resolution serial pg interface card opc vg1 spgt available soon 2 high resolution serial pg interface card opc vg1 spgt available soon 474

O05 pg pd option setting feedback pulse 474

O06 pg pd option setting digital line speed detection definition pg pulses 474

O07 pg pd option setting digital line speed detection definition detection pulse correction 1 474

O08 pg pd option setting digital line speed detection definition detection pulse correction 2 474

Pg interface card opc vg1 pg pd 5v line driver output 1 pg interface card opc vg1 pg pd 5v line driver output 474

Specify to use the pg ld option for line speed control a pg disconnection activates a protective function specify to use the pg ld option for line speed control a pg disconnection activates a protective function p9 alarm 474

Switches the source of the position detection signal between the integrated pg and the optional pg interface switches the source of the position detection signal between the integrated pg and the optional pg interface card use for synchronous operation and the position control for orientation 474

The pulse correction is for speed detection speed correction 1 correction 2 input pulse 474

When function code p01 a01 a101 m1 m2 m3 drive control 3 vector control of pmsm and the pg interface card opc vg1 pmpg for pmsm drive is mounted setting o05 at 0 enables signals to the opc vg1 pmpg 474

A159 m3 abs signal input definition 475

A160 m3 magnetic pole position offset 475

A161 m3 salient pole ratio xq xd 475

A59 m2 abs signal input definition 475

A60 m2 magnetic pole position offset 475

A61 m2 salient pole ratio xq xd 475

Chap 4 control and operation 475

Data setting range 0 1 bit terminal f0 z phase interface available soon 1 3 bits terminals f0 f1 and f2 u v w phase interface 2 4 bits terminals f0 f1 f2 and f3 gray code interface 3 to 5 not used 6 spgt 17 bit serial interface 7 to 16 not used 475

Data setting range 0 to 359 ccw 475

Data setting range 1 00 to 3 00 475

Details of function codes 475

Enter the offset value printed on the corresponding motor test report or adjust the magnetic pole position according to the adjustment procedure 475

It is necessary to calculate the salient pole ratio from the design value of each motor when the design value is unknown contact your fuji electric representative 475

O09 m1 absolute signal input definition 475

O10 m1 magnetic pole position offset 475

O11 m1 salient pole rate xq xd 475

These function codes are exclusive to pmsm they define an offset value relative to the encoder reference these function codes are exclusive to pmsm they define an offset value relative to the encoder reference position and actual motor magnetic pole position 475

These function codes are exclusive to pmsm they select the interface system of encoder abs signals these function codes are exclusive to pmsm they select the interface system of encoder abs signals 475

These function codes are exclusive to pmsm they specify the difference in reactance due to the difference these function codes are exclusive to pmsm they specify the difference in reactance due to the difference in magnetic resistance on the q axis and the d axis in terms of the ratio of the q axis value d axis value 475

To drive an spm motor set 1 000 475

Data setting range 0 90 phase difference between phases a and b 1 phase a command pulse phase b command code sign 2 phase a forward pulse phase b reverse pulse 476

Data setting range 0 pg pr option 1 internal speed command 476

Data setting range 0 to 999 476

Data setting range 1 to 9 999 476

For details see the control block diagram given in section 4 476

Internal data input pulse pulse correction 1 pulse correction 2 476

Line speed detection pg ld with 90 phase difference only can be received 476

O12 pg pr pulse train option setting command pulse 476

O13 pg pr pulse train option setting pulse train input form 476

O14 pg pr pulse train option setting command pulse correction 1 476

O15 pg pr pulse train option setting command pulse correction 2 476

O16 pg pr pulse train option setting apr gain 1 476

Select a pulse output source from the pg pr option and internal speed data select a pulse output source from the pg pr option and internal speed data 476

Select the input form of the signal supplied to the pg pr option select the input form of the signal supplied to the pg pr option 476

Set when you install the pg pr option card to conduct synchronized operation you can change the position set when you install the pg pr option card to conduct synchronized operation you can change the position command data entered into the pulse train card to change the speed ratio between the master motor and the slave motor 476

This pulse configuration choice takes effect only against the pulse train command pg pr 476

You can specify a data to improve the position control response in pulse train operation you can also reduce you can specify a data to improve the position control response in pulse train operation you can also reduce the steady state deviation in the steady state operation since too large setting may present a motor hunting increase gradually from a small value to adjust 476

Chap 4 control and operation 477

Data setting range 0 to 1 477

Data setting range 0 to 1 000 477

Data setting range 0 to 65 535 477

Data setting range 0 to 999 477

Details of function codes 477

O17 pg pr pulse train option setting feedforward gain 1 477

O18 pg pr pulse train option setting overdeviation width 477

O19 pg pr pulse train option setting zero deviation width 477

O20 and o21 are functionally equivalent to o16 apr gain 1 and o17 f f gain 1 respectively o20 and o21 are functionally equivalent to o16 apr gain 1 and o17 f f gain 1 respectively 477

O20 apr gain 2 available soon 477

O21 f f gain 2 available soon 477

The difference deviation between the internal position command and actual motor revolutions exceeds 10 the difference deviation between the internal position command and actual motor revolutions exceeds 10 folds of this setting an excessive deviation alarm d0 is caused letting the motor coast to stop 477

The setting can reduce the steady state deviation the setting of 1 provides the smallest deviation you do the setting can reduce the steady state deviation the setting of 1 provides the smallest deviation you do not have to change from 0 in general 477

When the current position of the motor comes into this range of a reference position the inverter provides the when the current position of the motor comes into this range of a reference position the inverter provides the zero deviation signal you can use the zero deviation signal to detect that the motor locates almost at the target position the inverter provides the zero deviation signal on the do to which you can assign a function 477

L codes lift functions 481

Note canceling password described above will become ineffective after you turn off the inverter 482

Setting password 482

To disable password ex password l01 10 l02 20 482

When you set non zero data to l01 or l02 and open the program menu you will not view 1 set data and 2 check data but 3 operation monitor and the rest see the figure right below 482

００ 482

１０ 482

２０ 482

Ｓｔｏｐ 482

Chap 4 control and operation 483

Details of function codes 483

To enable password again after disabled 483

００ 483

Ｓｔｏｐ 483

About the estimated travel distance on deceleration 484

Function data codes used for the estimated travel distance on deceleration 484

L03 lift rated speed 484

Setting range 0 to 999 m min 484

The estimated travel distance on deceleration appears on the option monitor 3 4 on the led monitor of the the estimated travel distance on deceleration appears on the option monitor 3 4 on the led monitor of the keypad panel 484

The estimated travel distance on deceleration is an addition of travel distance on deceleration from the lift operation speed to the creep speed and that from the creep speed to the zero speed and does not include the travel distance by the constant operation at the creep speed l1 l2 l3 in the graph below 484

This function code is necessary to calculate the estimated travel distance on deceleration this function code is necessary to calculate the estimated travel distance on deceleration 484

This function is effective when l04 1 or 2 option monitor 3 travel distance from the operation speed 1 after deceleration operation option monitor 4 travel distance from the operation speed 2 after deceleration operation 484

You can display an estimated travel distance from the deceleration start point to the stopping point to check the consistency of the decelerating pattern 484

A frenic vg standard vg7s compatible multistep speed and s curve setting 485

B lift application compatible with vg3n and vg5n 485

Chap 4 control and operation 485

Details of function codes 485

Frenic vg standard vg7s compatible multistep speed and s curve setting 485

Frenic vg vg7s compatible lift application original mode 485

Introduction to an operation example in each mode introduction to an operation example in each mode 485

L04 preset s curve pattern 485

L05 to l14 l05 to l14 s curve patterns 1 to 10 485

Lift application compatible with vg3n and vg5n 485

Set on off to the terminal functions ss1 ss2 and ss4 to switch the multistep speed as described in the following table 485

Setting range 0 to 2 485

Setting range 0 to 50 485

Since this operation mode uses the standard multistep speed and the s curve see the description of the individual function codes 485

Specifies the application of s curve setting and the multistep speed specifies the application of s curve setting and the multistep speed 485

Steps of multistep speed c05 to c11 7 steps of multistep speed c05 to c11 s curve applied to eight sections l05 to l12 485

Steps of multistep speed c05 to c11 7 steps of multistep speed c05 to c11 s curve applied to ten sections l05 to l14 485

Steps of multistep speed c05 to c19 15 steps of multistep speed c05 to c19 s curve applied to four sections f67 to f70 485

The following table shows how s curve setting is applied to the multistep speed 486

The following table shows how the acceleration deceleration times are assigned to the multistep speed 486

C frenic vg vg7s compatible lift application original mode 489

Chap 4 control and operation 489

Details of function codes 489

Set on off to the terminal functions ss1 ss2 and ss4 to switch the multistep speed as described in the following table 489

The following table shows how s curve setting is applied to the multistep speed 489

The following table shows how the acceleration deceleration times are assigned to the multistep speed 489

Chapter 5 using standard rs 485 495

Frenic vg 495

This chapter describes the use of standard rs 485 communications ports and provides an overview of the frenic vg loader 495

Chap using standard rs 485 497

Standard rs 485 communications ports 497

The rj 45 connector for the keypad is intended solely for communication using the keypad and cannot be used for rs 485 communication do not connect the inverter to a pc lan port ethernet hub or telephone line doing so may result in damage to the inverter or connected device 497

Rs 485 common specifications 498

Chap using standard rs 485 499

Standard rs 485 communications ports 499

Terminal specifications for rs 485 communications 499

Connection method 500

Use cables and converters meeting the specifications for proper connection to the rs 485 port refer to section 5 communications support devices the shield must be earthed on the host device side 500

Communications support devices 502

Converters 502

Level conversion 502

Cables 503

Chap using standard rs 485 503

Link command permission selection 503

Link functions 503

Standard rs 485 communications ports 503

The run operation may start when the le terminal is switched from off to on 503

If the system has field options t link field bus sx si upac etc writing to the s range run operation command command data via rs 485 is disabled and the options are given priority however reading and writing function code data via rs 485 is constantly enabled 504

In link command allowed mode you can use function code h30 link function to link com the command data and the run operation command and switch between remote and local at this time rem remote run operation via terminal block or loc local run operation via keypad is displayed 504

Link commands 504

Link edit 504

Link edit permission selection 504

Link edit switching 504

S range option priority 504

These functions enable a flexible system structure with run commands issued via the terminal block and speed commands issued via rs 485 504

You can use function code h29 allow link edit command to control writing to function codes f e c p h a o l u in the link edit allowed mode 504

You can write protect the function codes f e c p h a o l u as shown below by assigning 23 allow link edit command we lk to the x function input terminal 504

1 writing to volatile memory 505

2 writing via rs 485 disabled mode 505

3 continuous writing disabled mode 505

Additionally refer to the communications address 485 no in chapter 4 section 4 function code tables for details on referencing and changing function codes take note of restrictions such as data ranges and disabled changes during operation 505

Chap using standard rs 485 505

If the system does not have field options writing to the s range run operation command command data via rs 485 constantly enabled 505

In order to enable a high speed writing response when writing via rs 485 the system uses volatile memory ram random access memory memory that is discarded when the system is switched off if you need to keep the data after the system is switched off issue the h02 save all function code to write the data to non volatile memory 505

Referencing and changing data 505

Standard rs 485 communications ports 505

When using modbus rtu you can continuously write 16 pieces of data when doing so do not include the following codes in the continuous write group if you attempt to write with these codes in the group the system will return a negative response fuji general purpose inverter protocol and modbus rtu can be written individually 505

Write restrictions for function codes 505

Writing to selecting function codes f e c p h a o l u is subject to the following restrictions 505

Writing using function code h02 takes about 2 seconds do not attempt to perform another write operation while the system is writing data to the memory 505

You will receive a negative response if you attempt to write to any of the following function codes 505

Negative response and error response 506

No response 506

Chap using standard rs 485 507

Request 507

Response 1 507

Response 2 507

Response interval time h39 507

Rs 485 function codes 507

Set the time until the inverter returns a response when a request is received from an upper level device such as a computer this function enables you to match the timing by setting the response interval time even if the computer processes slowly 507

Standard rs 485 communications ports 507

T1 response interval time td inverter operation delay time 0 30 ms t1 response interval time td inverter operation delay time 0 30 ms 507

Use the h39 code to set the time within the range of 0 0 1 0 s 507

Character timeouts 508

Disconnection detection time h38 508

Timeouts on the master side 508

Chap using standard rs 485 509

For both reading and writing always confirm the response before sending the next frame if there is no response from the inverter after a certain time execute a timeout and retry if you attempt to start a retry before a timeout the request frame will not be received properly 509

Host side procedures 509

If the response is normal this indicates that some kind of temporary transmission error such as noise occurred and normal communications should be possible thereafter if there is frequent reoccurrence of this phenomenon it is necessary to investigate further to determine whether there is an error 509

If there is again no response execute further retries if the number of retries exceeds the preset value normally about 3 times there may be a problem with the hardware or the software of an upper level device as there is no response from the specified station it will be necessary to abort and investigate further 509

Please follow the flow chart for each frame transmission procedure 509

Read procedure 509

Standard rs 485 communications ports 509

When executing a retry either use a standard frame to resend the data that was sent before no response was received or execute polling m26 to enable the error details to be read and then check that the response was normal when checking the response you will need to determine whether a further timeout is necessary 509

Write procedure 510

Bad example 511

Chap using standard rs 485 511

Communication errors 511

Effect of shield 511

Effect of twist 511

Good example 511

Standard rs 485 communications ports 511

Adding inductance components 512

Caution 512

Effect of filtering 512

Chap using standard rs 485 513

Standard rs 485 communications ports 513

Communication error measures 514

Fuji general purpose communications 515

Message format 515

Transmission frame 515

Byte field ascii format hexadecimal format description 516

Request frame host inverter 516

Standard frame 516

Values 516

Ack response frame inverter host 517

Byte field ascii format hexadecimal format 517

Chap using standard rs 485 517

Description 517

Fuji general purpose communications 517

Values 517

Byte field 518

Format 518

Nak response frame inverter host 518

Byte field 519

Chap using standard rs 485 519

Format 519

Fuji general purpose communications 519

Option frame 519

Selecting request frame host inverter 519

Byte field 520

Format 520

Selecting response frame inverter host 520

Byte field 521

Chap using standard rs 485 521

Format 521

Fuji general purpose communications 521

Polling request frame host inverter 521

Byte field 522

Format 522

Polling response frame inverter host 522

Chap using standard rs 485 523

Fuji general purpose communications 523

In cases where the length of the response frame varies according to the command type if the command type character is determined properly the frame length designated for that command is generally used for the response 523

Negative response frame 523

Data field 524

Field descriptions 524

1 s01 selecting speed setting 1 write 300r min command 20000 max speed 1500 4000d 0fa0h 525

2 m09 polling output frequency read 525

3000d 30 0 525

Ack response frame inverter host 525

Ack response frame inverter host 0 0 hz 0bb 525

Chap using standard rs 485 525

Communication examples 525

Example sum result 0123h 525

Fuji general purpose communications 525

Nak response frame inverter host link priority error 525

Request frame host request frame host inverter 525

Standard frame 525

Sum check field 525

This field contains data used to check for errors in the transmission frame when sending data the data is calculated by adding all fields except for the s0h and sum check fields in 1 byte increments the lowest 1 byte of data is expressed as an ascii code 525

This section illustrates representative communication examples in all cases the station number is 12 525

1 selecting run command write 526

2 polling torque command value read 526

3 selecting run command with broadcast write 526

8500d 85 0 526

Ack response frame inverter host 526

Ack response frame inverter host 5 0 213 526

Broadcast returns no response 526

Nak response frame inverter host cause of error confirmed to be m26 send error process code 526

Option frame 526

Request frame host request frame host inverter 526

Request frame host request frame host inverter fwd command 526

Request frame host request frame host inverter rev command 526

Are unique codes specified by fuji electric for settings use binary 527

Ascii code table 527

Chap using standard rs 485 527

Example for 0 ascii code is 3 527

For 1 ascii code is 3 527

Fuji general purpose communications 527

Note 1 codes after 80 note 1 codes after 8 527

Shaded codes are used with this communication 527

Program example 528

This program is written in microsoft quickbasic ms dos qbasic and runs in accordance with fuji general purpose inverter protocol 528

Chap using standard rs 485 529

Message format 529

Modbus rtu 529

Transmission frame 530

Chap using standard rs 485 531

Function codes are 2 bytes in length and composed of an identification code and a number ex f40 f 40 the hi side corresponds to identification codes f e l the lo side corresponds to the number the setting data range is 0 9 11 f l u on the hi side and 0 99 on the lo side for example the setting data for f20 is 0014h 531

In the response read data is listed in the order of hi bytes and then lo bytes for each word of data and each word of data is listed in the order of the function code address requested with the query and then the address 1 2 etc missing function codes f09 etc will be returned as 0000 531

Interpreting normal response 531

Modbus rtu 531

Normal response 531

Reading function codes 531

Setting query 531

The byte count data range is 2 198 a byte count is twice the size of read data 1 99 for a query 531

The length of read data is 2 bytes the setting range is 1 99 words make sure to set read data so that it does not exceed the upper limit offset 99 of the function code otherwise an error response will be returned 531

This request cannot be used with broadcasts station number 0 cannot be used 531

A normal response uses the same frame as a query 532

Broadcasts can be used if the address is 0 in this case the broadcast request is processed by all inverters and no response is returned 532

For details on identification codes refer to the table in section 5 the length of read data fields is fixed at 2 bytes 532

Function codes are 2 bytes in length and composed of an identification code and a number 532

Interpreting normal response 532

Normal response 532

Setting query 532

Writing single function codes 532

Chap using standard rs 485 533

Modbus rtu 533

Writing multiple function codes 533

Maintenance code 534

Chap using standard rs 485 535

Error response 535

For example if fc 3 then exception function 3 128 131 8 535

If an incorrect query is received the query is not processed and an error response is returned error response 535

Interpreting error response 535

Modbus rtu 535

The subcode indicates the reason for the exception as shown in the table below 535

This is the same as for a station number request the exception function adds 128 to the fc of the query message 535

Crc 16 536

Error checking 536

Chap using standard rs 485 537

Crc 16 algorithm 537

Modbus rtu 537

03 03 31 00 14 538

Crc 16 calculation example 538

Station number 1 fc 03 function code p49 p code 03 49 31 hex read data size 20 items g p generating polynomial 1010 0000 0000 0001 538

The following is an example of read data that is sent 538

03 03 31 00 14 14 4e 539

Calculating frame length 539

Chap using standard rs 485 539

Following the above calculation the sent data is as follows 539

In order to calculate crc 16 it is necessary to know the message length which is variable the lengths of all message types can be determined from the table below 539

Modbus rtu 539

Send crc 4 e 1 4 539

1 m06 read speed detection value 540

10000 750 r min 540

10000d 540

2 s01 write 400r min to speed setting 1 540

Communication examples 540

Normal response inverter host 540

Query host inverter 540

Query host query host inverter 540

R min 5333d 14d 540

Reading 540

Speed detection value 271 540

This section illustrates representative communication examples in all cases the station number is 5 540

Chap using standard rs 485 541

Codes normally 541

For details refer to the frenic vg loader instruction manual 541

Frenic vg loader is a software tool that supports the operation of the inverter via a usb link it allows you to remotely run or stop the inverter edit set or manage the function codes monitor operation data as well as monitor information such as the running status and alarm history 541

Frenic vg loader overview 541

Specifications 541

Connection 542

Rs 485 connection 542

Usb connection 542

Chap using standard rs 485 543

Connection 543

Function overview 543

Setting function codes 543

Trace back 543

Chapter 6 control options 545

Frenic vg 545

This chapter describes the frenic vg s control options 545

Chap 6 control options 551

Common specifications 551

Specifications table 551

Table 6 551

Constraints when an opc control option is installed table 6 indicates which options can be used simultaneously 552

Ok can be used simultaneously ng cannot be used simultaneously 552

Table 6 552

The following table indicates which control options can be used in combination 552

1 verify that the product you received is in fact the product you ordered check the type model printed on the option 553

2 check the product for damage sustained during shipment 553

3 verify that all accessories are included in the packaging 553

Chap 6 control options 553

Common specifications 553

Example type model opc vg1 tl example type model opc vg1 tl option name tl t link interface host inverter name vg1 frenic vg 553

Inspecting options 553

Inspecting options after delivery 553

Once you receive the product you ordered check the following items 553

Table 6 accessories 553

Operating environment 554

Options are designed for use in the same operating environment as the frenic vg 554

Table 6 operating environment 554

Long term storage 555

Storing options 555

Temporary storage 555

Figure 6 removing the front cover frn22vg1s 2j 4j 22 kw or lower figure 6 removing the front cover frn30vg1s 2j 4j 30 kw or greater 556

Frn22vg1s 2j 4j 22 kw or lower frn30vg1s 2j 4j 30 kw or greater 556

Installing internal options opc vg1 556

Remove the inverter s front cover as shown in the following figures note that the method for removing the cover depends on which inverter model capacity you are using 556

Removing the front cover 556

Installing a digital 8 bit communications option card 557

Figure 6 installing a communications option card connected to cn2 figure 6 installing a communications option card connected to cn3 558

Installation method 2 when using the option at the same time as a digital 16 bit option card 558

When connecting to cn2 the lower connector 558

When connecting to cn3 the upper connector 558

Installing a digital 8 bit option card 559

Installation method 2 when using the option at the same time as a digital 16 bit option card 560

When connecting to cn2 the lower connector 560

When connecting to cn3 the upper connector 560

Installing a digital 16 bit option card 561

Pg interface expansion card 562

Product overview 562

Model and specifications 563

Failure to set the switches on the pg interface expansion card sw1 sw2 correctly will prevent the system from operating properly read information about the settings below and be sure to set the switches correctly 564

Specifications 564

Table 6 hardware specifications 564

When performing rotational positioning set the switches to pg pd use of the card in this configuration requires the separate upac option 564

2 line speed control specifications 566

Figure 6 566

Table 6 566

This configuration is used when controlling the line speed of a winding device using a pg installed on the line rather than motor speed control 566

3 pulse train and synchronous drive specifications 567

Chap 6 control options 567

Figure 6 567

Operation conforms to pulse train input master slave synchronized operation is possible 567

Pg interface expansion card 567

Table 6 567

External dimension diagram 568

Basic connection diagram 569

Terminal connections 569

Wiring 570

Chap 6 control options 571

Mode pd ld pr sd 571

On off 571

Pg interface expansion card 571

Since the speed is detected and calculated based on received pulses the pg interface expansion card must be set to sd since frequency division output can be generated using fa and fb this approach can be used with a digital speedometer or other instrument 571

Speed control 571

This connection example illustrates how to drive a motor a fuji servomotor etc to which a line driver output type encoder or open collector or complementary type encoder 571

When using a complementary output type encoder that supports 15 v and 12 v output use the inverter s pgp and pgm terminals in this configuration the common line is connected to the pg interface expansion card 571

Line speed control 572

Mode pd ld pr sd 572

On off 572

This connection example illustrates how to perform speed control after installing a line driver output type encoder on a system s winding line since motor speed feedback and line speed feedback can be detected simultaneously it is possible to prevent a runaway operation scenario resulting from a cause such as a paper tear on the line when using the pg interface expansion card in an application such as this one it must be set to ld 572

1 line driver output 573

2 open collector output 573

Chap 6 573

Control options 573

Figure 6 6 573

Figure 6 7 573

Figure 6 8 573

It is recommended to install a zero phase ferrite ring acl 40b as shown in the figure to the right in order to ensure a noise margin among other benefits 573

Open collector output can be used when driving multiple frenic vg units synchronously the open collector output fa and fb generated by the master frenic vg is connected to the slave frenic vg s pg interface expansion card the slave operates by receiving these pulse commands 573

Pg interface expansion card 573

Pulse train operation and synchronized operation 573

Since the frenic vg receiving these signals can generate open collector output fa and fb the pulse signals can be passed to the next frenic vg in this way multiple frenic vg units can be driven synchronously 573

The pg interface expansion card operates by receiving pulse commands from an external pulse generator or pg 573

When using the pg interface expansion card in this application set switch sw1 to pr 573

Figure 6 9 574

In such applications it is recommended to use the architecture shown in the figure to the right which utilizes the opc vg1 pg line driver type 574

Note as a rule shielded wires are earthed however if excessive induced noise from external sources affects the 574

Precautions 574

Recommended insulation converter shc 205c05d faith inc 574

System the effects of such noise can be reduced by connecting shielded wires to 0 v 574

The opc vg1 pgo open collector type is not suited to use in applications characterized by a challenging noise environment in which signals are routed alongside motor power lines or where wiring is run over long distances reducing the noise margin 574

1 master slave connections 575

2 cascading connections 575

Change the slave motor s direction of rotation with each slave unit s ivs contact forward operation reverse operation the rev contact cannot be used in this configuration 575

Chap 6 575

Control options 575

Pg interface expansion card 575

Synchronized operation 575

Synchronized operation system architecture 575

Systems for synchronously operating motors with a frenic vg utilize master slave connections cascading connections or pulse train commands from a plc or other external transmitter 575

This technique allows open collector pulse output from one frenic vg the master to be passed to pg card input of another frenic vg the slave that you wish to operate synchronously 575

Up to one frenic vg can be connected in this way as shown below 575

When using master slave synchronized operation the slave s synchronized operation speed is obtained by multiplying the master s speed by the pulse compensation factor function codes o14 and 15 575

1 command pulse command code 577

2 forward run pulse reverse run pulse 577

3 two signals with a 90 phase difference 577

Chap 6 577

Control options 577

During pulse train operation allocate one of the contacts x1 to x14 to 27 syc for the slave motor and manipulate syc together with the fwd signal 577

Pg interface expansion card 577

Pulse input format 577

Select the pulse input format with function code o13 577

Synchronized operation method 577

Synchronized operation signal syc 577

Table 6 1 577

Table 6 2 577

The direction of rotation for slave motors is determined by ivs and the pulse input format 577

Chap 6 579

Function codes 579

1 command pulse selection o12 580

About o12 1 operation 580

By contrast set to 1 at the master when you wish to send the same pulse to the slave while triggering pulse oscillation with an internal speed command and using pulse train operation for the master based on that signal 580

Figure 6 6 580

Internal speed commands 12 input and multi stage speed commands etc are converted into pulse signals oscillations and those pulse signals are converted back into speed commands as part of position control and enabled with syc to synchronize operation with other inverters converted pulse signals are output as is and received by the pgo pr option 580

Precautions 580

Set to 0 when performing position control using pulses input to the pg pr option normally the slave setting is 0 580

Table 6 3 580

Table 6 3 lists function codes related to pulse train operation see the control block diagrams in chapter 4 for more information 580

When internal speed commands are used to generate oscillation with a pulse train using the o12 1 technique processing is performed to correct the remainder portion of each pulse for example when using a 1024p r encoder conversion of a 1 500 r min command into a pulse generates 25 khz pulse output 580

2 2 pulse train input format selection o13 581

3 3 command pulse compensation 1 2 o14 o15 581

Chap 6 581

Control options 581

Example 581

If the gear ratio is 1 3 the actual settings would be as follows 581

In synchronized operation with a master slave connection with a slave that uses gears assume that the gear ratio is a b and that the input pulse is transformed into b a by command pulse compensation b command pulse compensation 1 a command pulse compensation 2 581

Pg interface expansion card 581

Position command data being input to the pulse train card can be changed with command pulse compensation 1 and 2 this functionality can be used to change the ratio of the speeds of the master motor and slave motor during synchronized operation 581

Set to reflect the pulse format that will be input to the a and b phases set to 0 when using a master slave connection 581

Without any problem however a speed command of 1 000 r min yields a pulse of 17 6666 khz due to the remainder in the division operation remainders are corrected one by one this correction processing causes a slight amount of speed fluctuation but smoothing by the speed command filter prevents it from becoming a problem additionally since synchronization accuracy is maintained by means of remainder correction processing the problem of missing pulses positional shifts does not occur 581

Chap 6 583

And and 584

Check functions 584

For more information see the section on keypad operation 584

From the operating mode screen go to the program menu screen and select 4 i o check use the 584

I o check 584

Keys to switch screens and check the setting on screen 15 as shown in the figure below 584

Keys to switch screens and check the setting on screen 9 as shown in the figure to the right 584

Optional equipment check 584

Protective functionality 584

Table 6 5 list of alarm protective functions 584

The figure to the right illustrates the screen that would be displayed when two pg interface expansion cards are installed and set to pg pd and pg sd 584

When the inverter s protective functionality operates the inverter immediately displays an alarm displays the alarm name on the keypad s led and allows the motor to free run when this functionality operates resume operation after clearing the cause of the malfunction avoid automatically resetting the alarm for example with an external sequence table 6 5 lists alarms related to the pg interface expansion card for more information about other alarms see protective operation in the inverter s operating manual 584

You can check on the keypad whether the pg interface expansion card is set to sd ld pr or pd 584

You can check the pg interface expansion card s digital input status on the inverter s keypad 584

Chap 6 585

Product overview 585

Synchronous motor drive pg interface card 585

Model and specifications 586

Chap 6 587

Control options 587

Specifications 587

Synchronous motor drive pg interface card 587

Table 6 hardware specifications 587

Table 6 software specifications 587

Table 6 grh type es motors 588

Table 6 grk type es motors 588

Using the card in combination with a fuji motor 588

Accessories 589

Chap 6 589

Control options 589

External dimension diagram 589

Model 10120 3000pe specifications 20 pin from sumitomo 3m limited 589

Model 10320 52a0 008 specifications 20 pin from sumitomo 3m limited 589

Plug and housing are included with the product 589

Synchronous motor drive pg interface card 589

Basic connection diagram 590

Figure 6 590

Refer to 6 installing built in options opc vg1 before performing wiring or connection work 590

Table 6 terminal function descriptions 590

Viewed from the plug s soldered terminal 590

Additionally the opc vg1 pg sd option can also be used when detecting magnetic pole positions with the z phase alone 591

Chap 6 591

Choose the opc vg1 pmpg when using a line driver output type motor encoder the following figure illustrates wiring connections used when detecting magnetic pole positions using 4 bit gray codes and 3 phase u v and w signals gnf2 series and grh series motors 591

Control options 591

Figure 6 591

Line driver type 591

Synchronous motor drive pg interface card 591

Open collector output type 592

Change the shielding connection used for pg wiring from the motor s e terminal to the inverter s pgm terminal in order to secure a noise margin to protect against improper operation of encoder signals additionally connecting shielding to the motor s e terminal is an effective way to reduce radiated noise 593

Chap 6 593

Connection diagram for fuji servos 593

Control options 593

Figure 6 593

Precautions 593

Synchronous motor drive pg interface card 593

The encoder s shielding 15 pin is not connected to the motor s earth e terminal 593

Function codes 594

Motor parameters 594

Motor parameters must be set to reflect the motors being used m1 to m3 for more information see the description of p codes and a codes in chapter 4 594

Synchronous motor drive pg interface card function codes 594

Table 6 594

The following function codes can be used when the pmpg option or pmpgo option is installed 594

Chap 6 595

Check functions 595

Optional equipment check 595

Protective functionality 595

Product overview 596

T link interface card 596

Chap 6 597

Control options 597

Inverter type 597

Model and specifications 597

Model elements opc vg1 tl name of equipped inverter vg1 frenic vg option name tl t link interface card accessories 597

Rotary switches rsw1 2 597

Rsw1 rsw2 597

Rsw1 upper x10 597

Rsw2 lower x1 597

Set the station address using the rotary switches rsw1 and rsw2 on the option board 597

Spacer x 3 m3 screw x 3 597

Specifications 597

T link interface card 597

Table 6 software specifications 598

Chap 6 599

External dimensions 599

Terminal function 599

Basic connection diagram 600

Basic connection diagram 601

Chap 6 601

Control options 601

Figure 6 601

T link interface card 601

Available soon 602

By installing the t link interface card the dedicated funciton codes of o29 to o32 will be available 602

Function code 602

Table 6 602

Chap 6 603

Control options 603

T link interface card 603

Available soon 604

Failures of the he t link interface card are classified into light and heavy alarms depending on the severity level 604

Figure 6 604

Light and heavy alarms 604

Protective operation 604

Table 6 604

Upon occurrence of this failure the inverter outputs er4 network error and the motor coasts to stop 604

Chap 6 605

Protective operation function code 605

Allocated address 607

Chap 6 607

Data allocation addresses 607

Occupied area 607

Transmission format 607

1 operate state 1 for all on 609

2 2 motor speed 609

Busy is set to 1 while writing processing data when writing consecutive data wait for busy to be cleared to 0 and write the next data a writing request made while this bit is set to 1 is ignored 609

Chap 6 609

Control options 609

Data format frenic vg micrex 609

Err is cleared to 0 when selecting writing and polling reading of the function code has been done correctly if any of selecting or polling is not performed correctly err is set to 1 the error cause in this case can be checked with the function code m26 see the table below when err is set to 1 resolve the cause and perform selecting or polling again if the operation is successful both of err and m26 are cleared to 0 609

T link interface card 609

The maximum speed is set with the function code obtain a r min value by calculating backward using the above formula if data is negative complement of 2 it is a reverse speed command 609

Transmission format 609

1 operation command di reset input 1 for all on 610

2 speed command 610

3 polling function code address and data 610

Data format micrex frenic vg 610

Format 1 format 1 610

Format 2 format 2 610

Fwd and rev are available when the link command is permitted as instructed in 6 link command permission selection x1 to x14 and rst are always available 610

Polling function code 1 to 4 eight bits each store the link number corresponding to the function code requested for polling from micrex their data are stored in polling function code 1 to 4 data 610

Polling function code address eight bits stores the link number corresponding to the function code requested for polling from micrex its data is stored in polling function code data refer to function code list for the link numbers 610

The above is the same as the motor speed the maximum speed is set with the function code provide the speed value as 16 bit data of the value calculated above handle negative data as a complement of 2 610

Chap 6 611

By assigning 24 link operation selection le to the x function input terminal the mode is switched as shown below 612

In the link command permission mode use the function code h30 link function to switch the command data and operation command between link com and remote local rem remote terminal table and loc local touch panel are shown here 612

In the link command prohibition mode command data and operation data can be written from a link but the data will not be reflected you can set data in advance in the link command prohibition mode and then switch to the link command permission mode to reflect the data 612

Link command link command 612

Link command permission selection 612

Link function 612

Link switch 612

Table 6 612

This functionality allows for flexible system construction where you can give operation commands from terminal table and speed command via communication 612

Use the function code h29 and x function 23 link edit permission command we lk to control writing of the function codes f e c p h a o u from the link also refer to the control block diagram in chapter 4 612

Use the function code h30 and x function 24 link operation selection le to switch the command data s area target rem loc com also refer to the control block diagram in chapter 4 612

1 speed setting 613

By assigning 23 link edit permission command we lk to the x function input terminal you can protect the function code f e c p h a o u from being written as shown below 613

Chap 6 613

Control options 613

Data transmission example 613

From micrex give commands to run forward fwd at 785 r min from micrex give commands to run forward fwd at 785 r min condition function code h30 link operation 3 maximum speed 1500 r min t link station address 10 8 8 words 613

Give s06 the forward running command fwd on and s01 the speed command give s06 the forward running command fwd on and s01 the speed command 613

Link edit 613

Link edit permission selection 613

Link edit switch 613

T link interface card 613

Table 6 613

The following explains a data transmission example using the transmission format 613

With the function code h29 you can control writing to the function code f e c p h a o u in the link edit permission mode 613

2 torque command monitor 614

3 function code data setting 614

Monitor the torque command value from micrex monitor the torque command value from micrex condition t link station address 24 8 8 words 614

Set the function code s08 acceleration time to 30 seconds from micrex set the function code s08 acceleration time to 30 seconds from micrex condition t link station address 58 4 4 words 614

Chap 6 615

Inverter type 616

Model and specifications 616

Product overview 616

Sx bus interface card 616

1 rotary switches rsw1 and rsw2 617

Chap 6 control options 617

Example station address 194 is c2 h and set rsw1 c and rsw2 2 617

Figure 6 617

Set the station address using the rotary switches rsw1 and rsw2 on the option board in the hexadecimal display rsw1 represents the upper 4 bits and rsw2 represents the lower 4 bits for the sx bus station address read it in decimal values 617

Specifications 617

Sx bus interface card 617

Table 6 hardware specifications 617

Figure 6 618

Run err 618

Status display led run err 618

Table 6 led display 618

Table 6 software specifications 618

The run and err leds on the option board display the status of the self station operation and error since the option itself determines the status as a slave the status may be different from run and alm shown on the cpu of micrex sx 618

Chap 6 619

External dimensions 619

Basic connection diagram 620

Chap 6 621

Chap 6 623

Control options 623

Function code 623

In addition to the standard function code you can set the optional dedicated function codes o30 o31 u01 11 u13 u60 64 623

Sx bus interface card 623

Table 6 623

1 for the details of o30 and o31 refer to 6 protective operation function code 624

2 for the details refer to 4 function code details 624

3 for the details of o160 and o161 refer to 6 4 2 function code monitor 624

4 for the details of user function code refer to 6 function code 624

For other function codes refer to chapter 4 624

Chap 6 625

Function code 625

Select whether the function codes u61 u63 can monitor the u ai universal ai or pulse data u64 is excluded from pulse data monitoring 626

The default value is u60 0 and the u ai function is not selected and u61 to u64 all act as the user function codes when u61 to u64 are set for monitoring rather than as the user function codes do not write data to them 626

U ai3 and u ai4 are only valid when opc vg1 aio or opc vg1 ai is installed 626

When the u ai function is selected the universal ai u ai is selected with ai function selection e49 e52 626

When u60 0 626

When u60 1 626

Chap 6 627

Chap 6 629

Control options 629

Keypad 629

Light and heavy alarms 629

Protective operation 629

Sx bus interface card 629

The sx bus option can encounter light and heavy alarms depending on the failure level 629

Upon occurrence of this failure the inverter outputs er4 network error and the motor coasts to stop 629

Figure 6 1 alarm subcode confirmation screen 630

２３ 630

Chap 6 631

Protective operation function code 631

Area occupied and data allocation addresses 633

Chap 6 633

Data allocation addresses 633

Transmission format 633

2 upac compatible format 634

Figure 6 8 634

Figure 6 9 634

Micrex sx frenic vg data 22 words 634

Micrex sx frenic vg data 29 words 634

Msb lsb 15 14 1 0 634

When the upac compatible format is selected u11 1 as shown in the figure below out of the i q when the upac compatible format is selected u11 1 as shown in the figure below out of the i q area of the micrex sx 51 words are used for each frenic vg with the lower 29 words are used for read and upper 22 words are used for write 634

Words micrex sx i q area 634

Chap 6 635

Control options 635

Figure 6 0 635

Sx bus interface card 635

Figure 6 1 636

3 monitoring format 637

Chap 6 637

Control options 637

Figure 6 2 637

Figure 6 3 637

Micrex sx frenic vg data 12 words 637

Micrex sx frenic vg data 4 words 637

Msb lsb 15 14 1 0 637

Sx bus interface card 637

When the monitoring format is selected u11 2 as shown in the figure below out of the i q area when the monitoring format is selected u11 2 as shown in the figure below out of the i q area of the micrex sx 16 words are used for each frenic vg with the lower 4 words are used for read and upper 12 words are used for write 637

Words micrex sx i q area 637

4 standard format 2 specified with 485no 638

Figure 6 4 638

Figure 6 5 638

Micrex sx frenic vg data 8 words 638

Msb lsb 15 14 1 0 638

When the standard format 2 is selected u11 3 as shown in the figure below out of the i q area of when the standard format 2 is selected u11 3 as shown in the figure below out of the i q area of micrex sx 16 words are used for each frenic vg with the lower 8 words are used for read and upper 8 words are used for write 638

Words micrex sx i q area 638

1 when standard format specified by link no is selected 639

Busy is set to 1 while writing processing data when writing consecutive data wait for busy to be cleared to 0 and write the next data a writing request made while this bit is set to 1 is ignored 639

Chap 6 639

Control options 639

Data format frenic vg micrex sx 639

Err is cleared to 0 when selecting writing and polling reading of the function code has been done correctly if any of selecting or polling is not performed correctly err is set to 1 the error cause in this case can be checked with the function code m26 see the table below when err is set to 1 resolve the cause and perform selecting or polling again if the operation is successful both of err and m26 are cleared to 0 639

Motor speed 639

Operate state 1 for all on 639

Sx bus interface card 639

The maximum speed is set with the inverter function code f03 obtain a r min value by calculating backward using the above formula if data is negative complement of 2 it is a reverse speed command 639

Transmission format 639

2 2 when upac compatible format is selected 640

Magnetic flux command data 0 1 1d 640

Magnetic flux command final 640

Polling function code 1 to 4 eight bits each store the link number corresponding to the function code requested for polling from micrex sx their data are stored in polling function code 1 to 4 data 640

Polling function code address and data 640

Speed setting 4 frequency command monitor actual speed detected speed setting 1 frequency command for v f line speed input 640

The maximum speed is set with the function code obtain a r min value by calculating backward using the above formula if data is negative complement of 2 it is a reverse speed command 640

Torque command 2 data torque current command data 0 1 1d 100 rated toque 640

Torque command 2 torque current command final 640

Chap 6 641

Control data cw standard dioa 16 bits 641

Control options 641

Operation status sw 641

Position command available soon 641

Pulse train position command pg pr position detection internal or pg pd position detection z phase input pg pd 641

Refer to the explanation of u61 u63 in 6 function code refer to the explanation of u61 u63 in 6 function code 641

Refer to the operation status of the standard format refer to the operation status of the standard format 641

Sx bus interface card 641

Vg di diob option 16 bits 641

Note note 642

Polling function code 1 2 address 16 bits each store the link number corresponding to the function code requested for polling from micrex sx their data are stored in polling function code 1 2 data 642

Polling function code address and data 642

The aio option opc vg1 aio or ai option opc vg1 ai is necessary to reference data for vg ai aio ai option ai3 aio ai option ai4 to enable this data you need to assign the corresponding ai terminal functions to the universal ai u ai using the function codes e49 to e52 if they are not assigned the value will be 0 642

The dio option opc vg1 dio is necessary to reference data for the vg di diob option 16 bits 642

The pg option opc vg1 pg pgo is necessary to reference data for the pulse train position command and position detection excluding internal data 642

Vg ai ai1 vg ai ai2 vg ai aio ai option ai3 vg ai aio ai option ai4 642

Vg ai data 10 v 4000 h 16384d 642

When using ai2 set the sw3 on the control board to the v side when using ai2 set the sw3 on the control board to the v side for the switch refer to 3 switch operation 642

3 when monitoring format is selected 643

Chap 6 643

Control options 643

Polling function code 1 to 8 eight bits each store the link number corresponding to the function code requested for polling from micrex sx their data are stored in polling function code 1 to 8 data 643

Polling function code address and data 643

Sx bus interface card 643

4 when standard format 2 specified with 485no is selected 644

Function code monitor 644

Function code monitor 1 2 are the constant monitor of the function code set the target function code 485no with the function code o160 for function code monitor 1 and o161 for function code monitor 2 644

Motor speed 644

Operation status 644

Polling function code 485no 1 to 2 16 bits each store the 485no corresponding to the function code requested for polling from micrex sx the corresponding link numbers are stored in polling function code 1 to 2 data 644

Polling function code address and data 644

Refer to the motor speed of the standard format refer to the motor speed of the standard format 644

Refer to the operation status of the standard format refer to the operation status of the standard format 644

1 when standard format is selected 645

Chap 6 645

Control options 645

Data format micrex sx frenic vg 645

Note 1 upon selecting be sure to write the link number and data together 645

Polling function code address 645

Selecting function code 1 to 4 eight bits each store the link number corresponding to the function code selected by micrex sx write the data to selecting function code 1 to 4 data note that writing to the function code with this selecting function is done per the tact period of micrex sx 645

Selecting function code address and selecting function code data 645

Sx bus interface card 645

Use the polling function code 1 to 4 8 bits to specify the link number corresponding to the function code number requested for polling 645

Chap 6 647

Control options 647

Magnetic flux command 647

Magnetic flux command data 0 1 1d 647

Speed setting 1 frequency command for v f speed setting 4 frequency command for v f speed supplement command actual speed simulated 647

Sx bus interface card 647

The above is the same as the motor speed the maximum speed is set with the function code provide the speed value as 16 bit data of the value calculated above handle negative data as a complement of 2 647

Torque command 1 torque command 2 torque current command torque limiting level 1 torque limiting level 2 torque bias 647

Torque command data 0 1 1d 100 rated toque 647

Acceleration deceleration time data 0 s 1d 648

Acceleration time deceleration time 648

Note upon selecting be sure to write the link number and data together 648

Selecting function code 1 2 address 16 bits each write the link number corresponding to the function code selected by micrex sx write the data to selecting function code 1 2 data 648

Selecting function code address and selecting function code data 648

Vg do1 standard dioa 13 bits 648

Writing from this frame to the s code is prohibited for a command equivalent to the s code give commands from each dedicated frame 648

Chap 6 649

Control options 649

Polling function code address 649

Sx bus interface card 649

Use the polling function code 1 2 address 16 bits to specify the link number corresponding to the function code number requested for polling 649

Vg ao ao1 vg ao ao2 vg ao ao3 vg ao aio option ao4 vg ao aio option ao5 649

Vg ao data 10v 4000h 16384d 649

Vg do2 diob option 10 bits 649

By default all dynamic switches are set to 0 disabled when the control variable by default all dynamic switches are set to 0 disabled when the control variable micrex sx vg is enabled in the upac compatible format be sure to enable the corresponding dynamic switch 650

Dynamic sw2 650

Each bit value indicates the dynamic switch number the dynamic switch for each control variable is as shown below 650

Enabled dynamic switch is enabled and the control variable data is reflected 1 enabled dynamic switch is enabled and the control variable data is reflected 0 disabled dynamic switch is disabled and the control variable data is not reflected 650

Note note 650

Note that the definition of the dynamic switch is different from the upac option 650

Refer to the upac sw shown in the control block diagram in chapter 4 for the position of each dynamic switch 650

⑪ dynamic sw1 650

Aio option opc vg1 aio is necessary to reference data for the frenic vg ao aio option ao4 aio option ao5 to output this command to the ao terminal you need to assign the corresponding ao terminal functions to the universal ao u a0 using the function codes e69 to e73 this command is effective without regard to the status of the function code h30 and link operation selection le 651

Chap 6 651

Control options 651

Sx bus interface card 651

Table 6 651

The dio option opc vg1 dio is necessary to reference data for the frenic vg do2 diob option 10 bits this command is effective without regard to the status of the function code h30 and link operation selection le 651

The dio option opc vg1 dio is necessary to reference data y11 y18 for the frenic vg do1 standard dioa 13 bits this command is effective without regard to the status of the function code h30 and link operation selection le 651

The relationship between the dynamic switch setting link function selection function code h30 and link operation selection digital input le is shown below 651

3 when monitoring format is selected 652

4 4 when standard format 2 specified with 485no is selected 652

Note 1 upon selecting be sure to write the 485no and data together 652

Note 2 when writing data 0 to the function code f00 485no 0000h first write data other than 0 or write to a function code other than f00 then write to f00 652

Note 3 when the same function code is set to the selecting function codes 1 and 2 the selecting function code 2 takes precedence 652

Operation command di reset input s06 652

Polling function code 485no 652

Polling function code address 652

Refer to 1 operation command di reset input in section 6 of the t link interface refer to 1 operation command di reset input in section 6 of the t link interface 652

Refer to 2 speed command in section 6 of the t link interface refer to 2 speed command in section 6 of the t link interface 652

Selecting function code 485no 1 2 16 bits each write the 485no corresponding to the function code selected by micrex sx write the data to selecting function code 1 2 data 652

Selecting function code 485no selecting function code data 652

Speed command s01 652

Use the polling function code 1 to 8 8 bits to specify the link number corresponding to the function code number requested for polling 652

Use the polling function code 485no 1 2 16 bits to specify the 485no corresponding to the function code number requested for polling 652

1 speed setting 653

2 torque command monitor 653

Chap 6 653

Control options 653

Data transmission example 653

From micrex sx give commands to run forward fwd at 750r min from micrex sx give commands to run forward fwd at 750r min condition function code u11 sx transmission format selection 0 h30 link operation 3 maximum speed 1500 r min sx bus station address 10 653

Give s06 the forward running command fwd on and s01 the speed command give s06 the forward running command fwd on and s01 the speed command 653

Link function 653

Monitor the torque command value from micrex sx monitor the torque command value from micrex sx condition function code u11 sx transmission format selection 0 sx bus station address 10 653

Refer to 6 link function of the t link interface 653

Sx bus interface card 653

The following explains a data transmission example using the transmission format 653

When both of the sx bus interface card and t link interface card are installed the link function targets communication via the t link 653

When only the sx bus interface card is installed and the monitoring format is selected the link function targets communication from the integrated rs 485 653

3 function code data setting 654

From micrex sx set the function code s08 acceleration time to 30 s from micrex sx set the function code s08 acceleration time to 30 s condition function code u11 sx transmission format selection 0 sx bus station address 10 654

Chap 6 655

Programming support tool expert d300win 656

System configuration definition 656

Adding a module 657

Chap 6 657

System definition window 657

Chap 6 659

Degenerate setting 659

Application program examples 660

Chap 6 661

Installed with t link interface card 662

Multiple option application examples 662

Chap 6 663

Installed with high speed serial communication capable terminal table 663

High speed serial communication capable terminal table 664

Multi winding motor drive 664

Product overview 664

Chap 6 665

Control options 665

High speed serial communication capable terminal table 665

High speed serial communication capable terminal table accessories 665

Model and specifications 665

Model elements opc vg1 tbsi 665

Plastic optical fiber cable with connector x1 5 m 665

Specifications 665

Common mode current is applied to the common mode windings this drives a motor with capacity of the summed number of inverters for example by using four n 4 200 kw inverters to drive a four winding motor up to 800 kw output is available figure 6 666

Multi winding motor specifications 666

Table 6 software specifications 666

モータ nx kw 666

Chap 6 667

Control options 667

High speed serial communication capable terminal table 667

Table 6 667

The relationship between the number of windings and the number of motor poles is as listed below because the former should be a divisor of the latter 667

External dimensions 668

Basic connection diagram 669

Chap 6 669

Connecting optical fiber cable 669

Control options 669

High speed serial communication capable terminal table 669

Use the supplied optical fiber cable to connect the inverter and the high speed serial communication capable terminal table note that the colors of the plugs at the ends of the cable are different light gray and dark gray be sure to match the colors of the plug and connector when connecting them connect the inverters in a daisy chain method for example when connecting three inverters 1 2 and 3 use three cables to connect them in a loop in such a way 1 2 3 1 669

Basic connection diagram of entire system 671

Chap 6 671

1 2 unit system set o34 1 for all systems 672

2 4 unit system set o34 3 for all systems 672

Figure 6 672

Function code setting 672

Master o50 0 slave 1 o50 2 slave 2 o50 1 slave 3 o50 3 bad setting is underlined 672

Number of units setting 672

Set the number of slave inverter units connected via the optical fiber cable using the function code note that this is not the number of all inverters including the master 672

Setting example 672

Table 6 672

Table 6 number of units and function code 672

When the o34 setting is not correct the system may not operate with no alarm indication check the setting again 672

Chap 6 673

Switching multi and single motor drive 673

1 power on 674

2 setting before operation 2 setting before operation 674

It is not required to power on the inverters simultaneously or power them on in a particular sequence since no alarm will be indicated until you start operation fwd rev you can power them on in an arbitrary order 674

Operation 674

Preparation for operation 674

Refer to chapter 3 preparation and test run for preparation 674

Set the following function codes to the same values for the master and slave s before operation while they are set to the same values at factory you need to check them again 674

Table 6 674

Chap 6 675

3 2 i o function 676

Table 6 0 676

You can use the master in the same way as the standard product the functionality of the slave is restricted as listed below 676

3 3 keypad function 677

Chap 6 677

Control options 677

High speed serial communication capable terminal table 677

Only the functions listed below are available for the slave functions not listed are disabled 0 is displayed 677

Table 6 1 led monitor 677

Table 6 2 operation status monitor 677

Table 6 3 alarm information 677

You can use the master in the same way as the standard product 677

3 4 function code f u 678

Table 6 4 f00 to f85 on slave 678

Table 6 5 e01 to e118 on slave 678

To confirm the restrictions on the slave in particular make sure to set the codes indicated as 1 to the same values between the master and slave 678

You can use the master in the same way as the standard product the functionality of the slave is restricted as listed below refer to the following 678

3 5 function code s command data 679

Chap 6 679

Control options 679

High speed serial communication capable terminal table 679

Table 6 6 h01 to h227 on slave 679

Table 6 7 o01 to o50 on slave 679

You can use the master in the same way as the standard product the functionality of the slave is restricted to s06 operation command 1 and s07 universal do however the functions listed in table 6 0 are only available 679

3 6 function code m monitor 680

Table 6 8 m01 to m222 on slave 680

You can use the master in the same way as the standard product the functionality of the slave is restricted as listed below refer to the following table to confirm the restrictions on the slave 680

Chap 6 681

Inter inverter link error erb 681

Protective function 681

Operation procedure error er6 682

Process in protective operation 682

Cc link interface card 683

Chap 6 683

Product overview 683

Cc link interface card accessories 684

Model and specifications 684

Model content opc vg1 ccl 684

Spacers 3 screws m3 3 684

Specifications 684

Table 6 hardware specifications 684

Before turning on the power supply to the inverter specify inverter station addresses in the range of 1 to 64 685

Before turning on the power supply to the inverter specify transmission baud rate in the range of 0 to 4 685

Cc link interface card 685

Chap 6 685

Control options 685

Figure 6 685

Figure 6 figure 6 685

Led status indicators 685

Rotary switch rsw1 2 685

Table 6 baud rate specification 685

The link status of cc link can be checked with four leds 685

Transmission baud rate setting switch rsw3 685

Table 6 led status indicator specifications 686

Cc link interface card 687

Chap 6 687

Control options 687

Figure 6 687

Table 6 software specifications 687

Table 6 terminal block specifications 687

Terminal block terminal block 687

External dimension drawing 688

Basic connection diagram 689

Chap 6 689

Da db dg sld 689

Da db dg sld fg 689

Common data formats s code and m code are available as communication dedicated specifications excepting standard function codes command monitor related data is defined for details on the communication dedicated function codes refer to chapter 4 however when the following communication dedicated codes are written via cc link the restrictions shown in table 6 are applied they can be read 690

Communication dedicated function codes 690

Function code 690

Note 1 when function codes are written via cc link they are all written into volatile memory ram data in memory is erased by turning off the power supply turning off the control power to the inverter therefore erases written data execute function code h02 save all function if necessary to write data into non volatile memory eeprom data in memory is not erased even by turning off the power supply 690

Standard function code 690

Standard function codes accessible from cc link differ depending on profile selection o32 they are as shown in table 6 690

Table 6 restrictions on writing of communication dedicated function codes 690

Table 6 standard function codes accessible from cc link 690

Cc link interface card 691

Chap 6 691

Control options 691

Option dedicated function codes 691

Reloading the cc link card can operate o30 to o32 not only as standard function codes but also as option dedicated function codes 691

Table 6 option dedicated function codes 691

Light alarm and heavy alarm 692

Light alarm or heavy alarm is generated in the cc link card depending on an error level occurrence of such an error makes the inverter generate er4 network error alarm resulting in coast to stop or deceleration to stop 692

Protection operation 692

Table 6 0 operation in case of light alarm cc link error 692

Table 6 1 operation in case of heavy alarm option error 692

Table 6 light alarm and heavy alarm 692

Cc link interface card 693

Chap 6 693

Control options 693

Figure 6 communication error codes 693

Without error 2 light alarm cc link error 3 heavy alarm option error 693

1 function code o30 0 o31 5 0 communication error continues for 5 or more seconds and the 694

2 function code o30 0 o31 5 0 communication error continues for 5 or more seconds and the 694

Figure 6 694

Figure 6 0 694

Motor coasts to stop 694

Motor decelerates to stop 694

Protection operation function codes 694

This section describes operation to be performed when communications link errors occur in a state where running command or speed command is given via cc link while the inverter is running 694

3 function code o30 2 o31 5 0 communication error continues for 5 or more seconds and the 695

4 function code o30 2 o31 5 0 after communication error continues for 5 or more seconds returns 695

Cc link interface card 695

Chap 6 695

Control options 695

Figure 6 1 695

Figure 6 2 695

Motor decelerates to stop 695

To communications during deceleration to stop 695

Applicable format list 697

Cc link interface card 697

Chap 6 697

Control options 697

Table 6 2 applicable format list 697

This option card supports formats shown in table 6 2 697

Frenic vg 698

Remote i o signal in the vg7 compatible mode 698

Vg7 compatible mode with 1 station occupied o32 0 698

Cc link interface card 699

Chap 6 699

Control options 699

Master 699

Frenic vg 700

Remote register in vg7 compatible mode o32 0 700

Cc link interface card 701

Chap 6 701

Control options 701

Detailed description on operation command 701

Detailed description on output terminate status 701

Figure 6 4 701

Figure 6 5 701

Monitor code command code o32 0 in vg7 compatible mode 701

Table 6 7 monitor code o32 0 701

Figure 6 6 link operation selection le with cc link used 702

Table 6 8 command code o32 0 702

Table 6 9 response code o32 0 702

1 x mode with 1 station occupied o32 0 703

Cc link interface card 703

Chap 6 703

Control options 703

Remote i o signal in 1 x mode o32 1 703

Master 704

Cc link interface card 705

Chap 6 705

Control options 705

Frenic vg 705

Remote register signal in 1 x mode o32 1 705

Detailed description on operation command 706

Detailed description on output terminate status 706

Figure 6 7 706

Figure 6 8 706

Monitor code command code o32 1 to 4 706

Table 6 4 monitor code list with o32 1 to 4 706

Cc link interface card 707

Chap 6 707

Control options 707

Table 6 5 command code list with o32 1 to 4 707

Table 6 6 response code list with o32 1 to 4 707

Table 6 7 function code selection by command code with o32 1 to 4 708

2 x mode with 1 station occupied o32 2 709

Cc link interface card 709

Chap 6 709

Control options 709

O32 1 same as the case of 1 x mode with 1 station occupied 709

Remote i o signal in 2 x mode o32 2 709

Remote register signal in 2 x mode o32 2 709

4 x mode with 1 station occupied o32 3 710

Frenic vg 710

O32 1 same as the case of 1 x mode with 1 station occupied 710

Remote i o signal in 4 x mode o32 3 710

Remote register signal in 4 x mode o32 3 710

Cc link interface card 711

Chap 6 control options 711

Master 711

8 x mode with 1 station occupied o32 4 712

Frenic vg 712

O32 1 same as the case of 1 x mode with 1 station occupied 712

Remote i o signal in 8 x mode o32 4 712

Remote register signal in 8 x mode o32 4 712

Cc link interface card 713

Chap 6 713

Control options 713

Master 713

Cc link interface card 715

Chap 6 715

Control options 715

Link command permission selection 715

Link function 715

Performing the operation of the inverter via cc link requires switching of the mode to the link command permission mode to select a command other than 0 via communications by function code h30 link operation the system configuration is so flexible that switching a value selected for link operation for example can select an operation command on the terminal block and a speed command through communications 715

The availability rem loc com of the command data s area is switched by function code h30 link operation and x function 24 link operation selection le be familiar with this together with the control block refer to chapter 4 715

Writing the standard function codes f e c p h a o u and l from a link is controlled by function code h29 link function code protection and x function 23 link edition permission command we lk be failiar with this together with the control block refer to chapter 4 715

Confirmation reading of function codes via cc link is always enabled for changing writing function codes however function code h29 link function code protection must be write enabled 0 in the link edition permission mode it is put in link edition permission mode by factory default 716

Link edition permission selection 716

Table 6 6 716

Table 6 7 716

Application program examples 717

Chap 6 717

Master unit outline 717

Setting up procedure 717

System configuration 717

17 bit high resolution abs interface card 718

Model and specifications 718

Product overview 718

Bit high resolution abs interface card 719

Chap 6 719

Control options 719

Specifications 719

Table 6 hardware specifications 719

Table 6 software specifications 720

Bit high resolution abs interface card 721

Chap 6 721

Control options 721

External dimension drawing 721

Figure 6 card outline drawing 721

Connection 722

Do not use the product that is damaged or lacking parts doing so could cause injury or damage 722

Incorrect handling in connecting job could cause an accident such as electric shock or fire qualified electricians should carry out connecting wires if connecting wires for example after the power is turned on requires any touching of an electric circuit turn off open the breaker on the power supply side to prevent electric shock 722

Incorrect handling in installation removal could result in a broken produce 722

Since the smoothing condenser has been charged although the breaker is turned off open touching an electric circuit causes an electric shock confirm with a tester etc that the charge lamp charge of the inverter is turned off and the dc voltage of the inverter has been reduced to the safety voltage 722

Basic connection diagram 723

Chap 6 723

Figure 6 724

When frequency dividing output pulse of the master axis is used for synchronous operation as a pulse command available soon 724

1 for induction motor 725

2 for synchronous motor 725

Bit high resolution abs interface card 725

Chap 6 725

Control options 725

Function code 725

Function codes related to motor control 725

Motor parameter supports the synchronous motor magnetic pole position adjustment of synchronous motor inverter s function codes 725

Motor parameters must be set according to the motor m1 to 3 in use for details refer to the explanation on p code and a code in chapter 4 725

Mounting this option board can perform driving in combinations with the induction motor or synchronous motor in addition position control can be done function code settings in each condition are as follows 725

Set p28 with m1 selected a30 with m2 selected and a130 with m3 selected according to the maximum speed of the motor 725

With the following contents set the codes 725

For magnetic pole position adjustment of synchronous motor 726

Bit high resolution abs interface card 727

Chap 6 727

Control options 727

Enter the value described in the test report of the applicable motor or make adjustments according to the magnetic pole position adjustment procedure 727

Function code for synchronous motor it defines the offset to encoder reference position and actual motor magnetic pole position 727

Function code for synchronous motor it selects an interface system for encoder abs signal 727

Function code for synchronous motor it uses a q axis d axis ratio to set a difference in reactance given by the difference in magnetic resistance between the q axis and the d axis of the ipm motor 727

Inverter s function codes 727

Setting range 0 1 bit terminal f0 z phase interface available in the near future 1 3 bits terminal f0 f1 f2 u v w phase interface 2 4 bits terminal f0 f1 f2 f3 gray code interface 3 5 not used 6 spgt 17 bit serial interface 7 16 not used 727

Setting range 0 to 359 0 to 359 ccw direction 727

Setting range 1 00 to 3 00 727

The value must be calculated based on the setting of each motor if the value is unknown contact us for the spm motor it should be set to 1 00 727

Actions to be taken for alarms 728

Alarm display list 728

Check function 728

Checking for mounting of the spgt option can be checked on the keypad 728

For details refer to the keypad operation procedure 728

If the spgt card has been mounted the screen is displayed as shown at right 728

Key to switch the screen as shown at right screen 9 is available to check for mounting of it 728

Mounting this option card adds the standard protection functions as well as the following protection functions 728

Move from the operation mode screen to the program menu screen and select 4 i o check with the 728

Option mounting check 728

Protective functions 728

Bit high resolution abs interface card 729

Chap 6 729

Connector model 729

Control options 729

Distribution cable product to be arranged independently 729

Illustration a 729

Inverter side encoder side 729

Length and model 729

Related option 729

When an applicable serial pg is incorporated into our motor pg wire can support either unfastened leads terminal block or connector 729

Connector model connector model 730

Illustration b 730

Bit high resolution abs interface card 731

Chap 6 731

Component parts component parts 731

Connector kit 731

Connector on the inverter side model wsk p06p m 731

Connector on the motor side model wsk p09p d 731

Control options 731

Outline drawing 731

Available soon 733

F v converte 733

Model and specifications 733

Product overview 733

1 hardware specifications 734

Specifications 734

Table 6 general specifications 734

Table 6 i o terminal specifications 734

Table 6 list of input terminals on mca vg1 fv motherboard printed board 734

Chap 6 735

External dimensions 735

Internal block diagram 736

1 adjust sc1 to sc3 depending on the input form and usage 2 set vr1 and vr3 as 0 notch 3 adjust vr2 so that the voltage output s4 and s5 become minimum with the minimum frequency input 4 adjust vr1 and vr3 so that the voltage output s4 and s5 become maximum with the maximum frequency input 5 repeat 3 and 4 until the settings converge for s4 the polarity of the output is reversed depending on the a and b phases when sc3 1 2 is shorted 737

Adjustment method 737

Chap 6 737

Control options 737

F v converter available soon 737

Figure 6 737

Table 6 737

Basic connection diagram 739

Chap 6 739

Model and specifications 741

Product overview 741

Synchro interface available soon 741

Specifications 742

Table 6 0 i o terminal specifications 742

Table 6 0 mca vg1 sn motherboard printed circuit board input terminals 742

The mca standalone type uses a separate power supply 15 v you will need to provide a stabilized power supply 15 v dc since power is not supplied from the frenic vg 742

External dimension diagram 743

Internal block diagram 743

Adjustment method 744

Description of adjustment locations 744

Installing and adjusting the synchro interface 745

Di interface card 746

Product overview 746

Chap 6 747

Model and specifications 747

1 printed circuit board switch 748

2 input circuits 748

Figure 6 1 748

Figure 6 1 illustrates the general position of the switches as seen from the top surface of the printed circuit board 748

Sink source 748

Specifications 748

Table 6 1 748

Table 6 1 hardware specifications 748

The following figure illustrates the circuit architecture for the sw2 sink and source settings 748

Use sw1 on the card s printed circuit board to select between the dia and dib settings 748

Use sw2 on the di interface card s printed circuit board to select between sink and source control input 748

Chap 6 749

Control options 749

Di interface card 749

Table 6 1 software specifications 749

The option supplies a 24 v power supply p24 24 v m24 ground 749

Accessories 750

External dimension drawing 750

Figure 6 1 plug figure 6 1 housing 750

Model 10120 3000pe specifications 20 pin from sumitomo 3m limited 750

Model 10320 52a0 008 specifications 20 pin from sumitomo 3m limited 750

No 1 pin 750

No 11 pin 750

Plug and housing are included with the product 750

Basic connection diagram 751

Chap 6 751

Control options 751

Di interface card 751

Figure 6 1 751

Refer to section 6 installing internal options opc vg1 before performing wiring or connection work 751

Table 6 1 terminal function descriptions 751

Data latch function 752

Di input data is normally captured internally and applied inside the inverter every 1 ms a data latch function can be used when you wish to hold di input data or reduce variation in lower bits when capturing input from an external a d converter 752

Function codes 752

Installation of the di interface card allows use of function codes o01 to o04 these function codes are not normally when the option had not been installed displayed on the keypad 752

Off di input hold data is not captured and the last data value before the contact was turned off 752

On normal capture 752

Set function codes x1 to x14 corresponding to the desired contact to 55 dia or 56 dib to assign data latch operation then set the contact in question as follows 752

Setting method 752

Table 6 1 752

1 example input when o01 and o02 are set to binary input values from 32 768 to 32 767 are valid 753

2 example input when o01 and o02 are set to bcd input values from 7 999 to 7 999 are valid 753

Chap 6 753

Control options 753

Di interface card 753

Selecting binary or bcd input 753

Table 6 1 753

1 speed settings 754

2 torque torque current and torque limit input 754

Bcd input is used in applications where the motor speed is converted to the machine speed for example when a motor operating at 1 500 r min is connected to a machinery shaft via a 5 1 gear the machinery shaft will rotate at 300 r min di input of 3 000 while using a bcd setting o03 or o04 of 3 000 with these function codes would result in rotation of 300 r min 1 500 r min for the motor 754

Card di the to b 0000_0000 1011_0000_ input 3000 bcd 300 754

Card di the to b 0101_0000 0000_0111_ input 0750 bcd 75 754

Control inputs n2 n1 are used to switch between f01 and c25 754

Controlled variable input 754

Table 6 1 754

Table 6 1 0 754

When assigning di input to torque torque commands torque current commands and torque limits it is necessary to define dia and dib use with the function codes h41 h42 f42 and f43 according to the function being used for more information see the corresponding sections of chapter 4 754

When using di input to set the speed set function code f01 or c25 whichever is to be enabled according to the switch state dia or dib for example to enable f01 on a card set to dia set f01 to 6 754

Chap 6 755

Control options 755

Di interface card 755

And and 756

Check functions 756

For example an indication of a 4000 would indicate bcd input of 4000 756

For more information see the section on keypad operation 756

From the operating mode screen go to the program menu screen and select 4 i o check use the 756

I o check 756

If the card is set to dia will change to on the lcd screen as shown in the sample to the right 756

Input data is displayed as xxxxx in the screenshot to the right 756

Keys to switch screens and check the screen corresponding to the di interface card 756

Option installation check 756

You can check on the keypad whether the di interface card is set to dia or dib 756

You can check the di interface card s digital input status on the inverter s keypad from the operating mode screen go to the program menu screen and select 4 i o check use the 756

Chap 6 757

Dio expansion card 757

Product overview 757

Models 758

Models and specifications 758

2 combinations not mountable operating procedure error 759

Chap 6 759

Control options 759

Dio expansion card 759

Figure 6 2 759

Specifications 759

Table 6 2 hardware specifications 759

The two dio expansion cards mounted cannot be both set to dioa the two dio expansion cards the two dio expansion cards mounted cannot be both set to dioa the two dio expansion cards mounted cannot be both set to diob either if such settings are made operating procedure error er6 will result 759

Sink source 760

3 output circuit 761

As shown in figure 6 2 connect a surge absorbing diode to both ends of the excitation coil when connecting the control relay 761

Chap 6 761

Control options 761

Dio expansion card 761

Figure 6 2 761

Table 6 2 software specifications 761

The output interface block allows bi directional power connections the cme is common to all contacts y11 to y30 therefore no bi directional signals can coexist 761

Dimensions 762

Basic schematic diagram dioa 763

Basic schematic diagrams 763

Chap 6 763

Control options 763

Dio expansion card 763

Refer to 6 installing internal options opc vg1 and wire and connect the frenic vg 763

Table 6 2 shows the plug pin arrangement 763

Basic schematic diagram diob 764

Figure 6 2 764

Figure 6 2 0 764

Figure 6 2 1 figure 6 2 1 764

Only the use of the opc vg1 upac as another option available soon will make it possible to operate the i o points of the dio expansion card 764

Table 6 2 shows the plug pin arrangement 764

The shielded wire should be basically earthed if strong inductive noise interferes with the frenic vg however the influence of the noise may be suppressed by connecting the shielded wire to the 0 v line 764

1 input the following functions can be set freely to four digital input pins x11 to x14 the functions are set with functions codes e10 through e13 765

Chap 6 765

Control options 765

Dio expansion card 765

Dioa selected 765

Function codes 765

2 output the following functions can be set freely to eight digital output pins y11 to y18 the functions are set with functions codes e20 through e27 766

Function codes the following function codes are used to allocate i o functions 766

Table 6 2 766

Chap 6 767

Control options 767

Dio expansion card 767

Diob functions are allocated to control variables to be specific global variables allocated to the control variables that will be available at the time of selecting a six unit frenic vg system 767

Diob selected 767

Only the use of the opc vg1 upac as another option available soon will make it possible to operate the following functions 767

Table 6 2 767

The optional opc vg1 siu module is required to operate diob options inv2 through inv6 767

To use diob functions select the corresponding control variables from the list of control variables or specify the address iq area of each diob function and register the control variable and check the box in the system definition 767

Check function 768

I o check 768

Mounting check on optional cards 768

Aio expansion card 769

Chap 6 769

Product overview 769

Models 770

Models and specifications 770

Aio expansion card 771

Chap 6 771

Control options 771

Specifications 771

Table 6 3 hardware specifications 771

Table 6 3 software specifications 771

1 input 772

2 output 772

Table 6 3 allocation of input functions 772

Table 6 3 allocation of output functions 772

The functions are set with functions codes e51 through e52 ai3 takes precedence if the same function is set to both ai3 and ai4 ai1 takes precedence if the same function is set to ai1 through ai4 772

The functions are set with functions codes e72 and e73 772

Two analog input points ai3 and ai4 can be freely set to the following functions 772

Two analog output points ao4 and ao5 can be freely set to the following functions 772

Chap 6 773

Dimensions 773

Specifications 774

Aio expansion card 775

Chap 6 775

Control options 775

Function codes 775

Function codes e51 e52 e55 e56 e59 e60 e63 e64 e67 e68 e72 e73 e77 e78 e82 e83 e103 e104 e107 and e108 will be operable with this optional expansion card mounted 775

Table 6 3 775

The keypad will display these function codes with the optional aio expansion card mounted otherwise the keypad will not display the functions 775

Check function 776

Chap 6 777

Model and specifications 777

Optional pg changeover card available soon 777

Product overview 777

Specifications 777

Dimensions 778

Installation method 778

Basic schematic diagram 779

Chap 6 779

1 the above example shows the following allocation of digital input x1 and transistor output y1 780

2 prepare a different circuit so that the main circuit wires will be switched over with the coil sel as shown 780

3 current required by 24 v power supply 70 ma coil sel driving current 780

Basic schematic diagram 780

Conformable wire size 780

Figure 6 4 schematic diagram of inverter unit 780

For the wiring of the main circuit terminals u v and w refer to the operation manual and user s manual for this inverter 780

Note note 780

Table 6 4 780

The shielded wire should be basically earthed if strong inductive noise interferes with the frenic vg however the influence of the noise may be suppressed by connecting the shielded wire to the 0 v line 780

Use wires with a thickness ranging from 0 to 1 5 m 780

Chap 6 781

Control options 781

Operation method 781

Optional pg changeover card available soon 781

Table 6 4 781

The encoder 1 and ntc thermistor 1 will be connected when the sel terminal of the terminal block and the 0 v external power supply terminal are open 781

The encoder 2 and ntc thermistor 2 will be connected when the sel terminal of the terminal block and the 0 v external power supply terminal are closed 781

E sx bus interface card 782

Model and specifications 782

Product overview 782

1 rotary switches sw1 2 783

Chap 6 783

Control options 783

E sx bus interface card 783

Example for station address 194 this is c2 h and sw1 c sw2 2 are set 783

Figure 6 5 station address setting switches 783

Specifications 783

Table 6 5 hardware specifications 783

The station address is set with rotary switches sw1 and sw2 on the option board the display is hexadecimal with sw1 corresponding to the upper 4 bits and sw2 corresponding to the lower 4 bits for the e sx bus station address read as a decimal display 783

2 status display led run err 784

Of e sx bus tact cycle and inverter control cycl 784

Operation 784

Table 6 5 led display 784

Table 6 5 software specifications 784

The status of the local station running error is indicated by the run err led on the option board the option determines the status of the local station which is a slave station and thus this may differ from the run alm status displayed on the micrex sx cpu 784

Chap 6 785

External dimension drawings 785

Basic connections 786

Chap 6 787

Control options 787

E sx bus interface card 787

Example of basic connections 787

Figure 6 5 example of basic connections 787

Inverter function codes related to the e sx bus interface card are described below 788

Related function codes 788

Table 6 5 related function codes 788

1 causes of light alarms and heavy alarms er4 789

Chap 6 789

Light alarms and heavy alarms in e sx bus communication er4 789

Protective operations 789

2 action when light alarm occurs o30 o31 790

Figure 6 5 790

Figure 6 5 alarm sub code screen 790

Function code o30 0 immediate coast to stop when communication error light alarm occurs 790

Function code o30 1 o31 5 coast to stop after 5 seconds when communication error light alarm occurs 790

Light alarm 2 heavy alarm1 4 heavy alarm2 790

The alarm sub code of 790

This section explains the control methods for er4 alarms by inverter function codes o30 o31 when a communication error light alarm state occurs while a run command is issued from the micrex sx via the e sx bus 790

Ｐａｇ 790

Chap 6 791

Alarms and heavy alarms in e sx bus communicatio 792

E sx related alarms are arf 792

Other inverter alarms 792

Table 6 5 actions when other alarms occur 792

Table 6 5 are alarm causes 792

Table 6 5 arf alarm causes 792

The card treats inverter alarms other than the above as light alarms the actions indicated in table 6 5 take place 792

The causes of e sx related alarms are and arf are shown in tables 6 5 and 6 5 792

1 standard format 2 793

1 standard format 2 u11 3 793

Basic format that allows reading writing of the motor speed operation status monitor and two basic format that allows reading writing of the motor speed operation status monitor and two function codes each specified in 485no 793

Chap 6 793

Control options 793

Data addresses iq area 793

E sx bus interface card 793

Function code u11 sx bus transmission format selection can be set to 3 to support the transmission format below 793

Input output data address assignments 793

Supported formats 793

1 standard format 2 u11 3 794

Format details 794

Function code monitor 794

Function code monitor 1 2 are constant monitors of function codes set the 485nos of the function codes to be monitored in function code o160 for function code monitor 1 and o161 for function code monitor 2 794

I area micrex sx frenic vg 794

Motor speed 794

Polling function code address polling function code data 794

The 485no corresponding to the function code in the polling request from the micrex sx is stored in polling function code 485no 1 2 16 bits the data are respectively stored in data of polling function code 1 2 794

The maximum speed is the speed set in inverter function code f03 to use r min units calculate the above equation in reverse when the data is negative 2 s complement the command becomes a reverse speed command 794

14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 795

Chap 6 795

Control options 795

E sx bus interface card 795

Msb lsb 795

Operation status 1 when all are on 795

1 standard format 2 u11 3 796

If a link command is allowed fwd and rev are valid x1 to x14 and rst are always valid for link commands refer to section 6 link function 4 polling function code 485no 796

Q area micrex sx frenic vg 796

Run command di reset input s06 796

Selecting function code 485no selecting function code data 796

Specify the 485no corresponding to the polling request function code in polling function code 485no 1 2 16 bits 796

Speed command s01 796

The 485no corresponding to the function code for selecting from the micrex sx is written to selecting function code 485no 1 2 16 bits at the same time write the data respectively to data of selecting function code 1 2 796

The maximum speed is the speed set in inverter function code f03 to use r min units calculate the above equation in reverse when the data is negative 2 s complement the command becomes a reverse speed command 796

1 speed setting run command 797

2 method of using function code monitor 797

3 function code data settings 797

Chap 6 797

Conditions function code u11 sx transmission format selection 3 h30 link operation 3 maximum speed 1500 r min e sx bus station address 10 e sx master station address 254 e sx bus used 797

Constant monitoring from the micrex sx of the calculated torque value m07 and the effective constant monitoring from the micrex sx of the calculated torque value m07 and the effective output current value m11 set o160 0807 hex and o161 080b hex in advance 485no of m07 is 0807 hex 485no of m11 is 080b hex 797

Control options 797

Data transmission examples 797

E sx bus interface card 797

Examples of data transmission using standard format 2 are described below 797

Issuing run forward fwd and 750 r min speed commands from the micrex sx issuing run forward fwd and 750 r min speed commands from the micrex sx 797

Setting 30 s in function code s08 acceleration time from the micrex sx setting 30 s in function code s08 acceleration time from the micrex sx 797

Action when synchronization is lost are 799

Chap 6 799

Checking the tact synchronization status 799

Conditions required for tact synchronization 799

Connecting the card to the e sx bus makes it possible to synchronize the e sx bus tact cycle and the inverter control cycle by doing this the control timing of multiple inverters can be synchronized making it easy to implement control that requires high accuracy timing 799

Control options 799

E sx bus interface card 799

However the processing that synchronizes the inverter control cycle and the e sx bus tact cycle requires that the following conditions 1 and 2 both be satisfied if either condition is not satisfied the tact cycle and inverter control cycle will operate asynchronously when the conditions are both satisfied synchronization is performed automatically after e sx bus communication is established 799

If synchronization is lost due to noise or other cause after the e sx bus tact cycle and inverter control cycle are synchronized the inverter operates as described below 799

Synchronization of e sx bus tact cycle and inverter control cycle 799

The tact synchronization status can be checked by the methods indicated in table 6 5 0 799

Compatible versions of the sph3000mm and support tool 800

Configuration definition method 800

Support tool interface 800

Chapter 7 application examples 801

Frenic vg 801

Application to plants 803

Control with high speed and high accuracy 803

High reliability 803

Large crane and overhead crane 803

System support 803

Position control 804

Precision synchronization control 804

Servo press large size for automobiles small size for machines such as crimping terminal processing machines 804

System support 804

Tension control 804

Winding equipment paper and metal 804

Feeding part of semiconductor manufacturing device wire saw 805

High speed response control 805

Smooth torque characteristic 805

System support 805

Test equipment for automobiles 805

Flying shear 806

High reliability and tension control 806

Position control 806

Shipboard winch 806

System support 806

Chapter 8 selecting peripheral equipment 807

Frenic vg 807

This chapter describes how to use a range of peripheral equipment and options frenic vg s configuration with them and requirements and precautions for selecting wires and crimp terminals 807

Configuring the frenic vg 809

Selecting wires and crimp terminals 810

Chap 8 selecting peripheral equipment 811

Currents flowing through inverter terminals 811

Selecting wires and crimp terminals 811

Table 8 currents flowing through inverter 811

Table 8 summarizes average effective electric currents flowing across the terminals of each inverter model for ease of reference when selecting peripheral equipment options and electric wires for each inverter including supplied power voltage and applicable motor rating 811

Table 8 currents flowing through inverter continued 812

Chap 8 selecting peripheral equipment 813

Selecting wires and crimp terminals 813

Table 8 currents flowing through inverter continued 813

If the internal temperature of your power control panel is 50 c or below 814

Recommended wires 814

Table 8 wire size for main circuit power input and inverter output 814

The following tables list the recommended wires according to the internal temperature of your power control panel 814

1 use the crimp terminal model no 8 l6 manufactured by jst mfg co ltd or equivalent 815

Chap 8 selecting peripheral equipment 815

Note 1 assuming the use of aerial wiring without rack or duct 600 v class of vinyl insulated iv wires for 60 c 600 v class of polyethylene insulated hiv wires for 75 c and 600 v cross linked polyethylene insulated wires for 90 c 815

Note 2 in the inverter model represents an alphabet 815

Recommended wires 815

S basic type s basic type 815

Table 8 wire size for main circuit power input and inverter output continued 815

1 use the crimp terminal model no 38 6 manufactured by jst mfg co ltd or equivalent 816

2 use the crimp terminal model no 60 6 manufactured by jst mfg co ltd or equivalent 816

3 use the crimp terminal model no 8 l6 manufactured by jst mfg co ltd or equivalent 816

4 use cb150 10 crimp terminals designed for low voltage appliances in jem1399 816

Note 1 assuming the use of aerial wiring without rack or duct 600 v class of vinyl insulated iv wires for 60 c 600 v class of polyethylene insulated hiv wires for 75 c and 600 v cross linked polyethylene insulated wires for 90 c 816

Note 2 in the inverter model represents an alphabet 816

S basic type s basic type 816

Table 8 wire size for dc reactor control circuit and inverter grounding continued 816

Chap 8 selecting peripheral equipment 817

Note 1 assuming the use of aerial wiring without rack or duct 600 v class of vinyl insulated iv wires for 60 c 600 v class of polyethylene insulated hiv wires for 75 c and 600 v cross linked polyethylene insulated wires for 90 c 817

Note 2 in the inverter model represents an alphabet 817

Recommended wires 817

S basic type s basic type 1 use the crimp terminal model no 8 l6 manufactured by jst mfg co ltd or equivalent 817

Table 8 wire size for dc reactor control circuit and inverter grounding continued 817

1 use the crimp terminal model no 38 6 manufactured by jst mfg co ltd or equivalent 818

2 use the crimp terminal model no 8 l6 manufactured by jst mfg co ltd or equivalent 818

3 use cb150 10 crimp terminals designed for low voltage appliances in jem1399 818

If the internal temperature of your power control panel is 40 c or below 818

Note 1 assuming the use of aerial wiring without rack or duct 600 v class of vinyl insulated iv wires for 60 c 600 v class of polyethylene insulated hiv wires for 75 c and 600 v cross linked polyethylene insulated wires for 90 c 818

Note 2 in the inverter model represents an alphabet 818

S basic type s basic type 818

Table 8 wire size for main circuit power input and inverter output 818

1 use the crimp terminal model no 8 l6 manufactured by jst mfg co ltd or equivalent 819

Chap 8 selecting peripheral equipment 819

Note 1 assuming the use of aerial wiring without rack or duct 600 v class of vinyl insulated iv wires for 60 c 600 v class of polyethylene insulated hiv wires for 75 c and 600 v cross linked polyethylene insulated wires for 90 c 819

Note 2 in the inverter model represents an alphabet 819

Recommended wires 819

S basic type s basic type 819

Table 8 wire size for main circuit power input and inverter output continued 819

1 use the crimp terminal model no 8 l6 manufactured by jst mfg co ltd or equivalent 820

2 use the crimp terminal model no 8 l6 manufactured by jst mfg co ltd or equivalent 820

3 use cb150 10 crimp terminals designed for low voltage appliances in jem1399 820

Note 1 assuming the use of aerial wiring without rack or duct 600 v class of vinyl insulated iv wires for 60 c 600 v class of polyethylene insulated hiv wires for 75 c and 600 v cross linked polyethylene insulated wires for 90 c 820

Note 2 in the inverter model represents an alphabet 820

S basic type s basic type 820

Table 8 wire size for dc reactor control circuit and inverter grounding continued 820

1 use the crimp terminal model no 8 l6 manufactured by jst mfg co ltd or equivalent 821

Chap 8 selecting peripheral equipment 821

Note 1 assuming the use of aerial wiring without rack or duct 600 v class of vinyl insulated iv wires for 60 c 600 v class of polyethylene insulated hiv wires for 75 c and 600 v cross linked polyethylene insulated wires for 90 c note 2 in the inverter model represents an alphabet s basic type 821

Recommended wires 821

Table 8 wire size for dc reactor control circuit and inverter grounding continued 821

If the internal temperature of your power control panel is 50 c or below 822

Note 1 assuming the use of aerial wiring without rack or duct 600 v class of vinyl insulated iv wires for 60 c 600 v class of polyethylene insulated hiv wires for 75 c and 600 v cross linked polyethylene insulated wires for 90 c 822

Note 2 in the inverter model represents an alphabet 822

S basic type s basic type 822

Table 8 wire size for braking resistor 822

Chap 8 selecting peripheral equipment 823

Note 1 assuming the use of aerial wiring without rack or duct 600 v class of vinyl insulated iv wires for 60 c 600 v class of polyethylene insulated hiv wires for 75 c and 600 v cross linked polyethylene insulated wires for 90 c 823

Note 2 in the inverter model represents an alphabet 823

Recommended wires 823

S basic type s basic type 823

Table 8 wire size for braking resistor continued 823

If the internal temperature of your power control panel is 40 c or below 824

Note 1 assuming the use of aerial wiring without rack or duct 600 v class of vinyl insulated iv wires for 60 c 600 v class of polyethylene insulated hiv wires for 75 c and 600 v cross linked polyethylene insulated wires for 90 c 824

Note 2 in the inverter model represents an alphabet 824

S basic type s basic type 824

Table 8 wire size for braking resistor continued 824

Chap 8 selecting peripheral equipment 825

Note 1 assuming the use of aerial wiring without rack or duct 600 v class of vinyl insulated iv wires for 60 c 600 v class of polyethylene insulated hiv wires for 75 c and 600 v cross linked polyethylene insulated wires for 90 c 825

Note 2 in the inverter model represents an alphabet 825

Recommended wires 825

S basic type s basic type 825

Table 8 wire size for braking resistor continued 825

Functional overview 826

Molded case circuit breaker or residual current operated protective device earth leakage circuit breaker magnetic contactor 826

Peripheral equipment 826

Connection example and criteria for selection of circuit breakers 828

Chap 8 selecting peripheral equipment 829

Peripheral equipment 829

Table 8 rated current of molded case circuit breaker mccb residual current operated protective device rcd earth leakage circuit breaker elcb and magnetic contactor mc 829

Table 8 rated current of molded case circuit breaker mccb residual current operated protective device rcd earth leakage circuit breaker elcb and magnetic contactor mc continued 830

Chap 8 selecting peripheral equipment 831

Peripheral equipment 831

Table 8 lists the relationship between the rated leakage current sensitivity of rcds elcbs with overcurrent protection and wiring length of the inverter output circuits note that the sensitivity levels listed in the table are estimated values based on the results obtained by the test setup in the fuji laboratory where each inverter drives a single motor 832

Table 8 rated current sensitivity of residual current operated protective devices rcds earth leakage circuit breakers elcbs 832

Surge killer for l load 833

Arrester 834

Surge absorber 835

Filter capacitor for radio noise reduction 836

1 10 ed product 20 ed product 837

Braking resistors dbrs 837

Braking resistors dbrs and braking units 837

Braking units 837

Peripheral equipment options 837

Hd mode inverters 838

Specifications and connection example 838

Table 8 a braking unit braking resistor standard ed 838

Table 8 generated loss in braking unit 838

Chap 8 selecting peripheral equipment 839

Example for the model db160v 41c quantity 2 four braking resistors are used example for the model db160v 41c quantity 2 four braking resistors are used 839

For db160v 41c db220v 41c two braking resistors are used per one unit for db160v 41c db220v 41c two braking resistors are used per one unit 839

Ld mode inverters 839

Md mode inverters 839

Note refer to notes on and procedure of selection 839

Peripheral equipment options 839

Table 8 b braking unit braking resistor standard 10 ed 839

Table 8 c braking unit braking resistor standard 10 ed 839

Example for the model db200v 42c quantity 1 two braking resistors are used example for the model db200v 42c quantity 1 two braking resistors are used 840

For db200v 42c and db220v 42c two braking resistors are used per one unit for db200v 42c and db220v 42c two braking resistors are used per one unit 840

Hd mode inverters 840

Note this option is built to order 840

Table 8 a braking unit braking resistor 20 ed 840

The braking unit requires the fan unit bu f 840

Chap 8 selecting peripheral equipment 841

Example for the model db200v 42c quantity 1 two braking resistors are used example for the model db200v 42c quantity 1 two braking resistors are used 841

For db200v 42c and db220v 42c two braking resistors are used per one unit for db200v 42c and db220v 42c two braking resistors are used per one unit 841

Ld mode inverters 841

Md mode inverters 841

Note this option is built to order 841

Peripheral equipment options 841

Table 8 b braking unit braking resistor 20 ed 841

Table 8 c braking unit braking resistor 20 ed 841

The braking unit requires the fan unit bu f 841

Note 1 when using the 20 ed braking resistor db v 2c the braking unit requires the fan unit bu f 842

Chap 8 selecting peripheral equipment 843

Note 1 for db160v 41c and db200v 42c two braking resistors are used per one unit 843

Note 1 for db200v 41c dv220v 41c db200v 42c and db220 42c two braking resistors are used per one unit 843

Note 2 when using the 20 ed braking resistor db v 2c the braking unit requires the fan unit bu f 843

Peripheral equipment options 843

Note 1 for db160v 41c two braking resistors are used per one unit example for the model db160v 41c quantity 2 four braking resistors are used 844

Note 2 when using the 20 ed braking resistor db v 2c the braking unit requires the fan unit bu f 844

Chap 8 selecting peripheral equipment 845

Note 1 when using the 20 ed braking resistor db v 2c the braking unit requires the fan unit bu f 845

Peripheral equipment options 845

Note 1 when using the 20 ed braking resistor db v 2c the braking unit requires the fan unit bu f 846

Chap 8 selecting peripheral equipment 847

Peripheral equipment options 847

Note 1 when using the 20 ed braking resistor db v 2c the braking unit requires the fan unit bu f 848

Braking resistors 10 ed models 849

Chap 8 selecting peripheral equipment 849

External dimensions 849

Peripheral equipment options 849

V series 10 ed product 849

V series 10 ed product 200v series 10 ed product 849

Braking resistor 20 ed product 850

V series 20 ed product 850

V series 20 ed product 200 v series 20 ed product 850

Approx 851

Braking unit 851

Braking unit fan unit 851

Chap 8 selecting peripheral equipment 851

Fan unit 851

Fan units for braking units 851

Peripheral equipment options 851

Using this option improves the duty cycle ed of a model using the external braking unit from 10 ed to 30 ed 851

Features 852

Power regenerative pwm converters rhc series 852

1 standard specifications 853

200 v series 853

400 v series 853

Chap 8 selecting peripheral equipment 853

Peripheral equipment options 853

Specifications 853

1 when the power supply voltage is 420v 210v or higher and the operating load is 50 or higher the power supply s power factor is reduced to approximately 0 95 during regenerative operation only 854

2 common specifications 854

1 terminal functions 855

2 communications specifications 855

Chap 8 selecting peripheral equipment 855

Function specifications 855

Peripheral equipment options 855

3 function settings 856

4 protective functions 857

Chap 8 selecting peripheral equipment 857

Peripheral equipment options 857

5 required structure and environment 858

1 ct mode 859

1 the charging box cu contains a combination of a charging resistor r0 and a fuse f if no cu is used it is necessary to prepare the charging resistor r0 and fuse f at your end 859

2 the filtering capacitor consists of two pieces of capacitors for an order of quantity 1 two pieces of capacitors are to be delivered 859

Chap 8 selecting peripheral equipment 859

Converter configuration 859

Peripheral equipment options 859

1 the charging box cu contains a combination of a charging resistor r0 and a fuse f if no cu is used it is necessary to prepare the charging resistor r0 and fuse f at your end 860

2 the filtering capacitor consists of two pieces of capacitors for an order of quantity 1 two pieces of capacitors are to be delivered 860

2 vt mode 860

1 for the 400 v class power supply connect a stepdown transformer to limit the voltage of the sequence circuit to 861

2 for frn37vg1s 2j or frn75vg1s 2j be sure to connect the fan power input terminals r1 and t1 of the 861

3 for the fan power supply switching connectors change cn r to the nc side and cn w to the fan side 861

4 construct a sequence in which a run command is given to the inverter after the pwm converter becomes ready 861

5 assign the external alarm thr to any of terminals x1 to x9 on the inverter 861

6 wiring for terminals l1 r l2 s l3 t r2 t2 r1 s1 and t1 should match with the phase sequence 861

7 remove the short circuit bar or dc reactor connected to the p1 p terminal of the inverter unit 861

An ungrounded power supply an insulated transformer is required for the details refer to the pwm converter 861

Basic connection diagrams 861

Be sure to connect the auxiliary power input terminals r0 and t0 of the pwm converter to the main power be sure to connect the auxiliary power input terminals r0 and t0 of the pwm converter to the main power 861

Cf filtering capacitor 861

Chap 8 selecting peripheral equipment 861

Charging circuit 861

F ac fuse 861

Input lines via b contacts of magnetic contactors of the charging circuit 73 or mc note that when applied to 861

Instruction manual inr hf51746 861

Inverter to the main power input lines without going through the mc s b contacts or 73 861

Lf filtering reactor 861

Lr boosting reactor 861

Magnetic contactor for 861

Peripheral equipment options 861

Power voltage 861

R0 charger resistor 861

Rf filtering resistor 861

Rhc7 2c to rhc90 2c applicable inverters frn0 5vg1s 2j to frn90vg1s 2j rhc7 4c to rhc220 4c applicable inverters frn3 vg1s 4j to frn220vg1s 4j 861

Symbol part name 861

To run 861

V or below 861

1 connect a stepdown transformer to limit the voltage of the sequence circuit to 220 v or below 862

2 be sure to connect the auxiliary power input terminals r0 and t0 of the pwm converter to the main power input 862

3 be sure to connect the fan power input terminals r1 and t1 of the inverter to the main power input lines without 862

4 for the fan power supply switching connectors change cn r to the nc side and cn w to the fan side 862

5 construct a sequence in which a run command is given to the inverter after the pwm converter becomes ready 862

6 set the timer 52t at 1 sec 862

7 assign the external alarm thr to any of terminals x1 to x9 on the inverter 862

8 wiring for terminals l1 r l2 s l3 t r2 t2 r1 s1 and t1 should match with the phase sequence 862

9 remove the short circuit bar or dc reactor connected to the p1 p terminal of the inverter unit 862

Cf filtering capacitor 862

F ac fuse 862

F magnetic contactor for filtering circuit 862

Going through the mc s b contacts or 73 862

Instruction manual inr hf51746 862

Lf filtering reactor 862

Lines via b contacts of magnetic contactors of the power supply circuit 52 note that when applied to an 862

Lr boosting reactor 862

Magnetic contactor for charging circuit 862

Magnetic contactor for power supply 862

Power voltage 862

R0 charger resistor 862

Rf filtering resistor 862

Rhc280 4c to rhc400 4c applicable inverters frn280vg1s 4j to frn630vg1s 4j 862

Symbol part name 862

To run 862

Ungrounded power supply an insulated transformer is required for the details refer to the pwm converter 862

Approx 863

Chap 8 selecting peripheral equipment 863

External dimensions 863

Peripheral equipment options 863

Approx 864

Note 1 cf4 500c to cf4 630c require two capacitors figures above are for one capacitor 864

Approx 865

Chap 8 selecting peripheral equipment 865

Peripheral equipment options 865

Approx 866

Approx 867

Chap 8 selecting peripheral equipment 867

Peripheral equipment options 867

As for 400 v class series with a capacity of 280 to 400 kw the charging resistor and the fuse are separately provided as before 868

Capacity range 868

The charging box contains a combination of a charging resistor and a fuse which is essential in the configuration of the rhc c series of pwm converters using this charging box eases mounting and wiring jobs 868

V series 7 kw to 90 kw in 10 types 400 v series 7 kw to 220 kw in 14 types total 24 types 868

Chap 8 selecting peripheral equipment 869

Peripheral equipment options 869

Approx 870

1 in ct mode 871

Chap 8 selecting peripheral equipment 871

Generated loss 871

Peripheral equipment options 871

2 in vt mode 872

Dc reactor dcr 873

V voltage average phase three v voltage min v voltage max unbalance voltage interphase 873

Table 8 0 dc reactor dcr 874

Chap 8 selecting peripheral equipment 875

Peripheral equipment options 875

Table 8 0 dc reactor dcr continued 875

Table 8 1 dc reactors dcrs external dimensions 876

Chap 8 selecting peripheral equipment 877

Peripheral equipment options 877

Table 8 1 dc reactors dcrs external dimensions continued 877

Ac reactor acr 878

Also use a dcr when there are thyristor driven loads or when phase advancing capacitors are being turned on off 878

Note 1 be sure to connect the ac rector when connecting to the dc mother line 878

Note 2 when connecting to the dc mother line use inverters of the same model and capacity 878

Use a dcr when the interphase voltage unbalance ratio of the inverter power supply exceeds 2 878

Use an acr when the converter part of the inverter should supply very stable dc power for example in dc link bus operation shared pn operation generally acrs are used for correction of voltage waveform and power factor or for power supply matching but not for suppressing harmonic components in the power lines for suppressing harmonic components use a dcr for power supply matching 878

V voltage average phase three v voltage min v voltage max unbalance voltage interphase 878

When connecting multiple inverters to dc mother line 878

Chap 8 selecting peripheral equipment 879

Figure 8 0 external view of ac reactor acr and connection example 879

Peripheral equipment options 879

Table 8 2 ac reactor acr 879

Table 8 2 ac reactor acr continued 880

Chap 8 selecting peripheral equipment 881

Peripheral equipment options 881

Table 8 3 ac reactors acrs external dimensions 881

Table 8 3 ac reactors acrs external dimensions continued 882

Surge suppression unit ssu 883

Output circuit filter ofl 884

Chap 8 selecting peripheral equipment 885

Ofl 4a 885

Peripheral equipment options 885

Table 8 4 output circuit filter ofl 885

Chap 8 selecting peripheral equipment 887

Peripheral equipment options 887

An acl is used to reduce radio frequency noise emitted by the inverter 888

An acl suppresses the outflow of high frequency harmonics caused by switching operation for the power supply lines inside the inverter pass the power supply lines together through the acl 888

Figure 8 2 dimensions of zero phase reactor for reducing radio noise acl and connection example 888

If wiring length between the inverter and motor is less than 20 m insert an acl to the power supply lines if it is more than 20 m insert it to the power output lines of the inverter 888

Radio noise reducing zero phase reactor acl 888

Table 8 6 zero phase reactors for reducing radio noise acl 888

Wire size is determined depending upon the acl size i d and installation requirements 888

External cooling attachment 889

22kw or lower option 30kw or higher standard 891

Battery 891

Chap 8 selecting peripheral equipment 891

Overview of battery 891

Used to retain the trace back memory and calendar when the inverter is not powered 891

Φ 17 55 31 891

Installing battery 892

Installing battery for 22 kw or lower 892

Installing battery for 30 kw or higher 893

Replacing battery 894

Sending battery via air transport 894

Chapter 9 selecting optimal motor and inverter capacities 895

Frenic vg 895

Motor output torque characteristics 897

Selecting motor and inverter capacities 897

Selection procedure 899

Equations for selections 903

General equation 903

Load torque during constant speed running 903

Obtaining the required force f 903

2 depending on the mass of load w kg the values of f n may be negative in both cases of lifting up and down which means the lift is in braking mode so be careful in motor and inverter selection 904

A simplified mechanical configuration is assumed as shown in figure 9 if the mass of the cage is 904

Although the mechanical configuration of an inclined lift load is similar to that of a vertical lift load unignorable friction force in the inclined lift makes a difference in an inclined lift load there is a distinct difference between the expression to calculate the lift force f n for lifting up and that for lifting down 904

Assuming the maximum load is 904

For calculation of the required output torque τ around the motor shaft apply the expression 9 or 9 depending on the driving or braking mode of the lift that is apply the expression 9 if the value of f n is positive and the 9 if negative 904

If the incline angle is θ and the friction coefficient is μ as shown in the figure 9 the driving force f n is expressed as follows 904

Kg is generally obtained with the expression 904

Kg the load is w kg and the balance weight is 904

Kg then the forces f n required for lifting the load up and down are expressed as follows 904

N g w cos sin w w f 904

N g w w w f 904

The braking mode applies to both lifting up and down as in the vertical lift load and the calculation of the required output torque τ around the motor shaft is the same as in the vertical lift load apply the expression 9 if the value of f n is positive and the 9 if negative 904

The mass of the balance weight 904

Vertical 904

Θ μ θ 904

Acceleration and deceleration time calculation 905

Calculation of moment of inertia 905

B a w 20 1 j 906

D 16 3 l w 3 1 j 906

Hollow cylinder 906

Iron 7860 copper 8940 aluminum 2700 906

L b a w 906

Main metal density at 2 906

Mass w kg mass w kg 906

Rectangular prism 906

Shape moment of inertia j kg 906

Sphere 906

Square cone pyramid rectangular base 906

Tetrahedron with an equilateral triangular base 906

Triangular prism 906

Calculation of the acceleration time 907

Calculating non linear acceleration deceleration time 908

Calculation of the deceleration time 908

Τ η τ η 908

Calculation of regenerative energy 910

Heat energy calculation of braking resistor 910

Calculating the rms rating of the motor 911

Notes on selection 912

Selecting a braking resistor 912

Selection procedure 912

Precaution in making the selection 913

Selecting an inverter drive mode hd md ld 913

A dc reactor dcr is provided as standard for the frenic vg of 75 kw or above to use the inverter in the md or ld mode specify the md ld mode inverter when placing an order and the frenic vg comes with the dcr suitable for the motor capacity to be applied in the md or ld mode if the md ld mode inverter is not specified the frenic vg comes with the dcr suitable for the motor capacity to be applied in the hd mode applying the dcr to be applied in the hd mode to the md ld mode inverters may flow the current exceeding the dcr rated current 914

Each rated current in the hd md and ld modes is used as a base for displaying or specifying the electric current data in percent of the rated current with function codes or for outputting or displaying it by analog output or communications monitor 914

Function hd mode md mode ld mode remarks 914

Guideline for selecting inverter drive mode and capacity 914

If an order for the ld mode inverter of 55 kw is placed the inverter comes with the dcr suitable for 75 kw as standard 914

If md ld mode inverters of 30 kw or above satisfy the requirements of the overload capability and functionality in your application you can select the inverter with one or two ranks lower capacity than that of the motor rating 914

Table 9 lists the differences between hd md and ld modes 914

The md ld mode inverters have no restrictions on the output frequency range 914

The md ld mode inverters have no restrictions on the setting range of function codes whose data e g dc braking level is based on the rated current 914

Chapter 10 about motors 915

Frenic vg 915

Chap 10 about motors 917

For the specifications and the external dimensions of the dedicated motors refer to chapter 2 section 2 dedicated motor specifications 917

Vibration and noise 917

Acceleration vibration value 918

Note if the actual vibration exceeds values listed above any separate anti vibration measure is required 918

Allowable radial load at motor shaft extension 919

Allowable thrust load 921

Chap 10 about motors 921

Combination list of 380v series 922

List of special combinations 922

Chap 10 about motors 923

Combination list of low base speed series 923

List of special combinations 923

V class 923

1 contact your fuji electric representative 924

V class 924

Chapter 11 operation data 925

Frenic vg 925

Frequency response characteristics 927

Rotational fluctuation measurement sample 927

Current distortion characteristics 928

Torque ripple 928

Impact load characteristics 929

Speed torque characteristics vector control with speed sensor 929

Deceleration acceleration via zero speed vector control with speed sensor 930

Inverter frn37vg1s 4j 930

Motor mvk8207a 37 kw 1500 3000 r min 930

Torque control accuracy vector control with speed sensor 930

Chapter 12 replacement data 931

Frenic vg 931

When replacing the former inverters vg vg3 vg5 with frenic vg refer to this section 931

Chap 12 replacement data 933

Classification of replacement 933

External dimensions comparison 934

Replacing vg7s 934

V series 934

Chap 12 replacement data 935

External dimensions comparison 935

V series 935

An adapter is required for replacement an adapter is required for replacement 936

Larger than vg5 936

Replacing vg5s 936

The control panel containing vg3 should be modified the control panel containing vg3 should be modified 936

V series 936

An adapter is required for replacement an adapter is required for replacement 937

Chap 12 replacement data 937

External dimensions comparison 937

Larger than vg3 937

Replacing vg3 937

The control panel containing vg3 should be modified the control panel containing vg3 should be modified 937

V series 937

Grd ground aps auxiliary power supply replacing 938

Main circuit terminal 200v series 938

Replacing vg7s 938

Terminal size 938

Chap 12 replacement data 939

Grd ground aps auxiliary power supply 939

Main circuit terminal 400v series 939

Terminal size 939

Grd ground aps auxiliary power supply 940

Main circuit terminal 200v series 940

Replacing vg5s 940

Chap 12 replacement data 941

Control circuit terminal common to 200v series and 400v series 941

Grd ground aps auxiliary power supply 941

Main circuit terminal 400v series 941

Terminal size 941

Grd ground aps auxiliary power supply 942

Main circuit terminal 200v series 942

Replacing vg3 942

Chap 12 replacement data 943

Control circuit terminal common to 200v series and 400v series 943

Grd ground aps auxiliary power supply 943

Main circuit terminal 400v series 943

Terminal size 943

Replacing vg7s 944

Terminal symbol 944

Chap 12 replacement data 945

Replacing vg5s 945

Terminal symbol 945

Chap 12 replacement data 947

Terminal symbol 947

Replacing vg3 948

Chap 12 replacement data 949

Terminal symbol 949

Chap 12 replacement data 951

For the settings for function codes refer to chapter 4 951

Function codes 951

Note that vg7s uses different function codes only for no 3 parameters dedicated for v f control as shown below 951

Replacing vg7s 951

Since the function codes for frenic vg are compatible with those for vg7s settings for vg7s are available for the settings for the same function codes of frenic vg 951

Torque boost conversion table 951

Replacing vg5s 952

Chap 12 replacement data 953

Function codes 953

Chap 12 replacement data 955

Function codes 955

Chap 12 replacement data 957

Function codes 957

Replacing vg3 957

Chap 12 replacement data 959

Function codes 959

Chap 12 replacement data 961

Function codes 961

Motor parameters 962

Replacing vg7s 962

V series 962

Cahp 12 replacement data 963

Motor parameters 963

V series 1 963

Co ef coefficient 964

Note the above table shows the setting values of frenic vg 964

V series 2 964

Cahp 12 replacement data 965

Motor parameters 965

Replacing vg5s 965

V series 965

Co ef coefficient 966

Note the above table shows the setting values of frenic vg 966

V series 966

Cahp 12 replacement data 967

Motor parameters 967

Replacing vg3 967

V series 967

Co ef coefficient 968

Note the above table shows the setting values of frenic vg 968

V series 968

Protective functions 969

Replacement data cahp 12 969

Replacing vg7s 969

Replacing vg5s 970

Protective functions 971

Replacement data cahp 12 971

Replacing vg3 971

Options 972

Replacing vg7s 972

Options 973

Replacement data cahp 12 973

Replacing vg5s 973

Replacing vg3 974

Chapter 13 troubleshooting 975

Frenic vg 975

This chapter describes troubleshooting procedures to be followed when the inverter malfunctions or detects an alarm or a light alarm condition in this chapter first check whether any alarm code or the light alarm indication l al is displayed or not and then proceed to the troubleshooting items 975

If any problem arises understand the protective functions listed below and follow the procedures given in section 13 and onwards for troubleshooting 977

Protective functions 977

The frenic vg series of inverters has various protective functions as listed below to prevent the system from going down and reduce system downtime the protective functions marked with an asterisk in the table are disabled by default enable them according to your needs 977

The protective functions include for example the heavy alarm detection function which upon detection of an abnormal state displays the alarm code and causes the inverter to trip the light alarm detection function which displays the alarm code but lets the inverter continue the current operation and other warning signal output functions 977

Before proceeding with troubleshooting 978

As listed below some alarm codes are followed by alarm sub codes that denote the detailed error causes for alarm codes not followed by alarm sub codes is written in the table below 979

Chap 13 troubleshooting 979

For the alarm sub code checking procedure refer to chapter 3 section 3 reading alarm information menu 7 alm inf for alarm codes followed by alarm sub codes listed as for particular manufacturers inform your fuji electric representative of the alarm sub code also when contacting or asking him her to repair the inverter 979

If an alarm code appears on the led monitor 979

If the inverter detects an alarm check whether any alarm code appears on the 7 segment led monitor of the keypad 979

List of alarm codes 979

Dba braking transistor error 981

Dbh braking resistor overheated 981

Dcf fuse blown 981

If the fuse has blown the internal elements may be broken never turn the power on to prevent the secondary damage contact your fuji electric representative 981

Possible causes of alarms checks and measures 981

Problem a braking transistor error is detected 981

Problem the electronic thermal protection for the braking resistor has been activated 981

Problem the fuse inside the inverter blew applicable to the inverters of 75 kw or above 200 v class series and those of 90 kw or above 400 v class series 981

D0 excessive positioning deviation 982

Dfa dc fan locked 982

Ef ground fault 982

Problem a ground fault current flew from the output terminal of the inverter 982

Problem an excessive positioning deviation has occurred 982

Problem the dc fan has stopped applicable to the inverters of 45 kw or above 200 v class series and those of 75 kw or above 400 v class series 982

Er1 memory error 983

Er2 keypad communications error 983

Note function code data can be easily reverted to the previously customized settings by using the backup data copied in the keypad memory with menu 10 data copy in programming mode refer to chapter 3 section 3 0 copying data 983

Problem a communications error occurred between the keypad and the inverter 983

Problem error occurred in writing data to the memory in the inverter 983

Be removed by pressing the 984

Er3 cpu error 984

Er4 network error 984

For sx bus option 984

For t link option 984

Problem a cpu error e g erratic cpu operation occurred 984

Problem the connected option card detected an error 984

To remove the er3 cpu error turn the power to the inverter off and then on the error cannot 984

Er5 rs 485 communications error 985

For cc link option 985

Problem a communications error occurred during rs 485 communication 985

Er6 operation error 986

Problem an incorrect operation was attempted 986

Er7 output wiring fault 987

Er8 a d converter error 987

Problem an error occurred in the a d converter circuit 987

Problem auto tuning failed 987

Er9 speed mismatch 988

Problem an excessive deviation has occurred between the speed command and the detected speed 988

Erb inter inverter communications link error 989

Erh hardware error 989

Err mock alarm 989

Problem a communications link error occurred between optical link options 989

Problem the led displays err 989

Problem the lsi on the power supply printed circuit board pcb malfunctions 989

Lin power supply phase loss 990

Loc start delay 990

Problem at the startup an excessive deviation has occurred between the speed command and the detected speed 990

Problem input phase loss occurred or interphase voltage unbalance rate was large 990

Lu undervoltage 991

Problem dc link bus voltage has dropped below the undervoltage detection level 991

0c overcurrent 992

Note a negative temperature coefficient ntc thermistor is used to protect the motor from overheat and under vector control to compensate for the temperature in the motor parameters a dedicated motor vg motor for fuji vector control has a built in ntc thermistor 992

Nrb ntc thermistor wire break error 992

Problem a wire break is found in the ntc thermistor detection circuit 992

Problem the inverter momentary output current exceeded the overcurrent level 992

0h1 heat sink overheat 994

0h2 external alarm 994

Problem external alarm was inputted thr when the enable external alarm trip thr has been assigned to any of digital input terminals 994

Problem temperature around heat sink has risen abnormally 994

0h3 inverter internal overheat 995

0h4 motor overheat ptc ntc thermistor 995

Problem temperature inside the inverter has exceeded the allowable limit 995

Problem temperature of the motor has risen abnormally 995

0ln overload of motor 1 through 3 996

L1 0l1 motor 1 overload 0l2 motor 2 overload 0l3 motor 3 overload 996

Problem electronic thermal protection for motor 1 2 or 3 activated 996

0lu inverter overload 997

Problem electronic thermal overload protection for inverter activated 997

05 overspeed 998

0pl output phase loss 998

Problem output phase loss occurred 998

Problem the motor rotates in an excessive speed when motor speed maximum speed setting h90 100 998

0u overvoltage 999

Problem the dc link bus voltage exceeded the overvoltage detection level 999

P9 pg wire break 1000

Problem the pulse generator pg wire has been broken somewhere in the circuit 1000

Pbf charger circuit fault 1001

Problem the magnetic contactor for short circuiting the charging resistor failed to work for 200 v class series of 37 kw or above and those of 75 kw or above 1001

If the light alarm indication l al appears on the led monitor 1002

Abnormal motor operation 1003

If neither an alarm code nor light alarm indication l al appears on the led monitor 1003

The motor does not rotate 1003

The motor rotates but the speed does not change 1005

Speed fluctuation or current oscillation e g hunting occurs during running at constant speed 1007

The motor runs in the opposite direction to the command 1007

Grating sound is heard from the motor or the motor sound fluctuates 1008

The motor does not accelerate or decelerate within the specified time 1008

The motor does not restart even after the power recovers from a momentary power failure 1009

The motor abnormally heats up 1010

The motor does not run as expected 1010

When the motor accelerates or decelerates the speed is not stable 1010

The motor stalls during acceleration 1011

When the t link communications option is in use neither a run command nor a speed command takes effect 1011

When the cc link communications option is in use neither a run command nor a speed command takes effect 1012

When the sx bus communications option is in use neither a run command nor a speed command takes effect 1012

Key or entered a run forward command fwd or a run reverse command rev the motor did not start and an under bar _ _ _ _ appeared on the led monitor 1013

Problem although you pressed the 1013

_ _ _ _ under bar appears 1013

Nothing appears on the monitors 1014

Problems with inverter settings 1014

The desired function code does not appear 1014

Data of function codes cannot be changed from the keypad 1015

Data of function codes cannot be changed via the communications link 1015

Appendices 1017

A effect of inverters on other devices 1019

App a advantageous use of inverters notes on electrical noise 1019

A noise 1020

A noise prevention 1022

Implementation of noise prevention measures 1023

Separating the main circuit wiring from the control circuit wiring avoiding noise effect 1023

Table a lists the noise prevention measures their purposes and targeted propagation routes 1023

The basic measures for lessening the effect of noise at the generating side include 2 inserting a noise filter that reduces the noise level 3 applying a metal conduit pipe or metal control panel that will confine noise and 4 applying an insulated transformer for the power supply that cuts off the noise propagation route 1023

The basic measures for lessening the effect of noise at the receiving side include 1023

There are two types of noise prevention measures one for noise propagation routes and the other for noise receiving sides 1023

Noise prevention examples 1026

Table a lists examples of the measures to prevent noise generated by a running inverter 1026

App b japanese guideline for suppressing harmonics by customers receiving high voltage or special high voltage 1030

B application to general purpose inverters 1030

B compliance to the harmonic suppression for customers receiving high voltage or special high voltage 1031

1 value of input fundamental current 1032

2 values of ki conversion factor depending on whether an optional acr ac reactor or dcr dc reactor is used apply the appropriate conversion factor specified in the appendix to the guideline the values of the conversion factor are listed in table b 1032

Apply the appropriate value shown in table b based on the kw rating of the motor irrespective of the inverter type or whether a reactor is used 1032

Calculation of harmonic current 2 calculation of harmonic current 1032

Elevators 1032

General purpose inverters 1032

If the input voltage is different calculate the input fundamental current in inverse if the input voltage is different calculate the input fundamental current in inverse proportion to the voltage 1032

Other general appliances 1032

Refrigerators air conditioning systems 1032

Some models are equipped with a reactor as a standard accessory 1032

2 calculation of harmonic current usually calculate the harmonic current according to the sub table 3 three phase bridge rectifier with the smoothing capacitor in table 2 of the guideline s appendix table b lists the contents of the sub table 3 1033

Acr 3 dcr accumulated energy equal to 0 8 to 0 5 ms 100 load conversion smoothing capacitor accumulated energy equal to 15 to 30 ms 100 load conversion load 100 1033

Calculate the harmonic current of each degree using the following equation 1033

3 maximum availability factor for a load for elevators which provides intermittent operation or a load with a sufficient designed motor rating reduce the current by multiplying the equation by the maximum availability factor of the load 1034

Correction coefficient according to contract demand level since the total availability factor decreases if the scale of a building increases calculating reduced harmonics with the correction coefficient β defined in table b is permitted 1034

In general the maximum availability factor is calculated according to this definition but the standard values shown in table b are recommended for inverters for building equipment 1034

Note if the contract demand is between two specified values listed in table b calculate the value by interpolation 1034

Note the correction coefficient β is to be determined as a matter of consultation between the customer and electric power company for the customers receiving the electric power over 2000 kw or from the special high voltage lines 1034

The maximum availability factor of an appliance means the ratio of the capacity of the harmonic generator in operation at which the availability reaches the maximum to its total capacity and the capacity of the generator in operation is an average for 30 minutes 1034

1 equivalent capacity 1035

2 harmonic current every degrees 1035

4 degree of harmonics to be calculated the higher the degree of harmonics the lower the current flows this is the property of harmonics generated by inverters so that the inverters are covered by the case not causing a special hazard of the term 3 in the above appendix for the 9th or higher degrees of the harmonics 1035

Examples of calculation 1035

Therefore it is sufficient that the 5th and 7th harmonic currents should be calculated 1035

App c effect on insulation of general purpose motors driven with 400 v class inverters 1036

C generating mechanism of surge voltages 1036

C countermeasures against surge voltages 1037

C effect of surge voltages 1037

C regarding existing equipment 1038

App d inverter generating loss 1039

Hd specification generating loss 1039

The table below lists the inverter generating loss 1039

Ld specification generating loss 1040

Md specification generating loss 1040

1 force 1041

2 torque 1041

3 work and energy 1041

4 power 1041

5 rotation speed 1041

6 inertia constant 1041

7 pressure and stress 1041

All expressions given in chapter 3 selecting optimal motor and inverter capacities are based on si units the international system of units this section explains how to convert expressions to other units 1041

App e conversion from si units 1041

Conversion of units 1041

1 torque power and rotation speed 1042

2 kinetic energy 1042

3 torque of linear moving load driving mode 1042

4 acceleration torque driving mode 1042

5 acceleration time 1042

6 deceleration time 1042

Braking mode 1042

Calculation formula 1042

App f allowable current of insulated wires 1043

600 v cross linked polyethylene insulated wires 1044

First edition july 2012 1045

High performance vector control inverter 1045

User s manual 1045

Fuji Electric FRN355VG1S-4J Инструкция по эксплуатации онлайн [1021/1046] 465071

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