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Daikin EUW(*)80КХ [8/40] Leaving water condenser
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LEAVING WATER
CONDENSER
40 45 50
LWE
MODEL
CC HC PI CC HC PI CC HC PI
4 40 100 131 31.6 95 128 34.4 89 125 37.1
60 159 208 51 145 199 55.7 128 187 60.8
80 208 274 67.6 195 266 73 182 259 79.1
100 241 315 76.8 226 308 84.2 210 300 92.8
120 318 417 102 290 398 111 256 374 122
140 367 482 119 340 465 129 310 446 140
160 416 547 135 390 532 146 364 517 158
180 449 589 144 421 573 157 392 559 172
200 482 631 154 452 615 168 420 600 186
7 40 115 147 32.6 109 143 35.1 102 138 37.6
60 180 231 52.7 167 222 57.2 152 212 62.3
80 235 303 70.2 221 294 75.5 207 286 81.5
100 274 352 80 258 343 87.3 242 335 95.8
120 360 462 105 334 445 114 304 425 125
140 415 534 123 388 517 133 359 499 144
160 470 606 140 442 588 151 414 572 163
180 509 655 150 479 637 163 449 621 177
200 548 703 160 516 686 175 484 670 192
10 40 130 163 33.8 123 158 36 115 152 38.2
60 197 250 55.1 186 244 59.5 173 236 64.5
80 262 334 74.5 247 324 79.2 232 314 84.9
100 307 388 83.8 291 379 91 275 371 99
120 394 501 110 372 487 119 346 471 129
140 459 585 130 433 568 139 405 550 149
160 524 669 149 494 647 158 464 629 170
180 569 725 161 538 703 170 507 685 184
200 614 777 168 582 759 182 550 742 198
16 40 159 194 35.6 150 186 37.4 141 179 39.1
60 239 296 58.4 231 292 62.8 221 287 67.6
80 315 395 82.2 299 383 86.4 283 372 92.1
100 372 461 92.2 356 452 98.8 339 442 106
120 477 590 117 461 583 126 442 573 135
140 554 691 141 530 675 149 504 659 160
160 630 789 164 598 766 173 566 744 184
180 687 856 174 655 826 176 622 814 198
200 744 922 184 712 904 198 678 884 212
SYMBOLS
CC : Cooling capacity (kW)
HC : Heating capacity (kW)
PI : Power input (kW)
LWE : Leaving Water Evaporator (°C)
LWC : Leaving water condenser (°C)
NOTES
1 Cooling capacity (CAP)
CAP = Cooling capacity from table (kW)
Capacity is for chilled water range Dt = 2∼5°C
2 Power input (PC)
PI = Power input from table (kW)
Power input is total input kW: compressor + control circuit
+ pumps (kW)
3 Water flow rate (WFR)
WFR = (860 x CAP)/(60 x Dt) (l/min)
CAP = From above calculation
Dt = Dt = Chilled water temperature rise within 2-5°C
WFR should always be within the limits
4 No pumps are supplied with the unit, so the added power
input for the pumps is calculated as (WFR x Dp)/0.3 as fixed
by 6/C/003 (Dp = pressure drop from pressure drop curves).
This is for cooled and cooling water.
5 Heating capacity has been calculated as follows:
CC+PIx0.97
•
Water-cooled • R-134a • EUW*40-200KX
3
Capacity tables
3-1
Cooling / heating capacities for air conditioning applications
6
3
3-1
188
• Hydronic Systems • Chillers
Содержание
- Table of contents euw 40 200kx 1
- Features 2
- Specifications 3
- Specifications 4
- Specifications 5
- Compressor phase 6
- Control circuit phase 6
- Frequency hz 6
- Maximum running current a 6
- Nominal distribution system voltage 6
- Nominal running current a 6
- Recommended fuses according to iec standard 269 2 am 6
- Recommended fuses am 6
- Specifications 6
- Starting current a 6
- Starting method 6
- Unit nominal running current a 6
- Units euw 120kx euw 140kx euw 160kx euw 180kx euw 200kx power supply y1 t1 y1 t1 y1 t1 y1 t1 y1 t1 6
- Voltage tolerance 6
- Voltage v 6
- Capacity tables 7
- Cc cooling capacity kw 7
- Cooling capacity cap cap cooling capacity from table kw capacity is for chilled water range dt 2 5 c 7
- Hc heating capacity kw 7
- Heating capacity has been calculated as follows cc pi x 0 7 7
- Leaving water condenser 7
- Lwc leaving water condenser c 7
- Lwe leaving water evaporator c 7
- No pumps are supplied with the unit so the added power input for the pumps is calculated as wfr x dp 0 as fixed by 6 c 003 dp pressure drop from pressure drop curves this is for cooled and cooling water 7
- Pi power input kw 7
- Power input pc pi power input from table kw power input is total input kw compressor control circuit pumps kw 7
- Water flow rate wfr wfr 860 x cap 60 x dt l min cap from above calculation dt chilled water temperature rise within 2 5 c wfr should always be within the limits 7
- Capacity tables 8
- Cc cooling capacity kw 8
- Cooling capacity cap cap cooling capacity from table kw capacity is for chilled water range dt 2 5 c 8
- Hc heating capacity kw 8
- Heating capacity has been calculated as follows cc pi x 0 7 8
- Leaving water condenser 8
- Lwc leaving water condenser c 8
- Lwe leaving water evaporator c 8
- No pumps are supplied with the unit so the added power input for the pumps is calculated as wfr x dp 0 as fixed by 6 c 003 dp pressure drop from pressure drop curves this is for cooled and cooling water 8
- Pi power input kw 8
- Power input pc pi power input from table kw power input is total input kw compressor control circuit pumps kw 8
- Water flow rate wfr wfr 860 x cap 60 x dt l min cap from above calculation dt dt chilled water temperature rise within 2 5 c wfr should always be within the limits 8
- Capacity tables 9
- Cc cooling capacity kw 9
- Cooling capacity cap cap cooling capacity from table kw capacity is for chilled water range dt 2 5 c 9
- Leaving water condenser 9
- Lwc leaving water condenser c 9
- Lwe leaving water evaporator c 9
- No pumps are supplied with the unit so the added power input for the pumps is calculated as wfr x dp 0 as fixed by 6 c 003 dp pressure drop from pressure drop curves this is for cooled and cooling water 9
- Out of range 9
- Pi power input kw 9
- Power input pc pi power input from table kw power input is total input kw compressor control circuit pumps kw 9
- Water flow rate wfr wfr 860 x cap 60 x dt l min cap from above calculation dt dt chilled water temperature rise within 2 5 c wfr should always be within the limits 9
- Capacity tables 10
- Glycol 10
- Legend 10
- Tw50689 8 10
- 2 4tw51569 7b 11
- Water pressure drop curve 11
- Operation range 12
- Dimensional drawings 13
- Dimensional drawings 14
- Dimensional drawings 15
- Dimensional drawings 16
- Dimensional drawings 17
- Dimensional drawings 18
- Piping diagrams 19
- Piping diagrams 20
- Euw 40 100kxy1 21
- Hydronic systems chillers 21
- Wiring diagrams 21
- Euw 40 100kxt1 22
- Hydronic systems chillers 22
- Wiring diagrams 22
- Euw 120 200kxy1 switchbox 1 23
- Hydronic systems chillers 23
- Wiring diagrams 23
- Euw 120 200kxy1 switchbox 2 24
- Hydronic systems chillers 24
- Wiring diagrams 24
- Euw 120 200kxt1 switchbox 1 25
- Hydronic systems chillers 25
- Wiring diagrams 25
- Euw 120 200kxt1 switchbox 2 26
- Hydronic systems chillers 26
- Wiring diagrams 26
- Wiring diagrams 27
- Sound power spectrum 28
- Sound power spectrum 29
- Sound power spectrum 30
- Installation 31
- Installation 32
- Installation 33
- Accessories options 34
- Tw51539 3a 34
- Accessories options 35
- Tw51549 3a 35
- Accessories options 36
- Tw51569 3b 36
- Accessories options 37
- Tw51579 3a 37
- Accessories options 38
- Tw51589 3a 38
- Accessories options 39
- Tw51619 3a 39
- Accessories options 40
- Number 40
- Option 40
- Std standard on unit model type for ispesl approval pressure vessels b model type for rlk approval dutch d model type for ttk approval finland k model type for sdm approval pressure vessels m model type for udt approval q model type for sa approval s model type for tu v approval pressure vessels t basic model 40
- V available not available std standard impossible option combinations zh zl 40
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