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Single-Stage Positive-Pressure Compressor Chlorine-Free HFC-134a RefrigerantFlooded EvaporatorAutomatic Refrigerant PurifierAdvanced PLC Control SystemOption with Variable Frequency Device
Performance Features
DCLCDunham-BushCentrifugal Liquid Chiller
Refrigeration Capacity1055-5274kW300-1500 Tons
50Hz R134a
1
Dunham-BushCentrifugal
Liquid Chiller
DCLC 46 47 F53 CM 51 B
Evaporator
Design Level
Motor
Motor Voltage&Hertz
Condenser
Compressor
Chiller Refrigeration Cycle
Enthalpy,Btu/lbm
Condenser In
Condenser Out
Cooler Out
Cooler In
Pres
sure
, psi
140
120
100
80
60
40
2020 40 60 80 100 120 140
4 3
51
2
Introduction The Dunham-Bush DCLC Water-Cooled Centrifugal Liquid Chillers
are available from 300 to 1500 tons. These units are supplied with single
stage centrifugal compressors that have high performance and stability,
and the performance of the chillers accord with ARI550/590 “Performance
rating of water-chilling packages using the vapor compression
cycle”. The side by side evaporator/condenser arrangement makes a
spl i t design optional for ease of movement throughany standard
commercial doorway.
All units are factory run tested before shipment.
High Efficient Refrigeration CycleThe refrigeration process is shown in a (P.h)-diagram
1-2 Vapor Compression
2-3 Vapor Condensing
3-4 Subcooling
4-5 Throttle Process
5-1 Cooling Liquid Vaporization
Chiller FeaturesDesigned to operate with environmentally safe and economically
smart HFC-134a with proven efficiency and reliability
Optimal structure configuration
Convenient for installation and maintenance
Excellent Part Load Performance
Centrifugal Water Chillers combine the efficient operation of the
compressor with variable refrigerant management and microprocessor
control to yield the best total energy efficiency and significant operating
savings under any load.
Adjustable orifice plate and level sensor controls the evaporator liquid le-
vel to insure high efficient partial load performance of the chiller, and insure
the chillers running stably even the inlet water temperature of condenser being
down to 55°F.
Optimal Automatic Refrigerant Purifier
Double-loop design and special automatic oil recovery device insures
oil circulation and refrigerant purification
Advanced PLC Microcomputer Control System
Fuzzy logic control theory is used in the PLC microcomputer control
system. Key variable detection forecasts operational trends, realize the
accurate control of the chiller, besides, The microcomputer comes complete
with RS232 and RS485.
·DCLC
Chiller Nomenclature
2
100%90%
80%70%
60%
Hea
dFr
actio
n
Flow Fraction.25 .50 .75 1.0
.8
.6
.4
Design point
40%30%
20%
50%
.2
1.
.0.0
IGV
=90d
seer
ge
IGed
07=
Vrg
see
IGV
=50degrees
IGV
=30degrees
IGV
=20degrees
IGV
=10degrees
Surge Line(guide vane and adjustable diffuser)
Surge Line (guide vane)
ARI Cooling Water Temperature
Cooling Water Temperature
New Design High Precision
High Efficency and High
Intensity
communications ports and all hardware and software necessary to
remotely monitor and control the packaged chiller up to 50 feet away
(hard wired) or by optional phone modem for extended distances by the
phone system. This valuable enhancement to the chiller system allows
the ultimate in serviceability.
Easy InstallationNo need for vacuum equipment and frequent refrigerant replacment
Compact structure and small floor area
Easy installation and maintenance
Installation Flexibility Modularization design allows the centrifugal chiller to optimally
meet customer requirement.
Load Regulation Scope Both the guide vanes and the adjustable diffuser ensure safe running
from 10 to 100 percent loading.
Hermetic Motor Cooled by RefrigerantRefrigerant cooling of the hermetic motor realizse more efficiency and
more reliability
Muti-startup modes decrease the starting current and insure safe condi-
tions and coefficient of performance (COP)
Compressor Characteristic Single Stage design provides unmatchable advantages over other
kinds of compressors, such as low vibration level of and noise, light
weight, high efficiency, high reliability and low energy consumption.
High Efficient Impeller of 3-D Flow Design High efficient semi-open impeller designed by 3-D flow theory.
Special aluminum alloy impeller precision casted by integer mould.
Precise dynamic balance and 125% over speed testing ensures high
efficiency of the chiller at any load of the power network.
Reliable Oil Circulation Special babbitt alloy bearings, forced oil cooling system and
double protection mode with rich-oil design pattern and high-level
oil tank, ensures reliable oil circulation whether the chiller is run-
ning or stops suddenly.
Simple Configuration and Convenient MaintenanceLow voltage control circuits
Heat Exchanger Feature Flooded Coolers employ the most advanced vessel technology avail-
able today. Special internal and external enhanced tubing provides
excellent unit efficiency. These coolers are designed and constructed to
meet the requirements of the ASME Code, Section VIII, Division 1 for
unfired
·DCLC
Compressor, motor, oil pump and transmission hermetically sealed. Oil cooler and oil filter located outside the compressor.Replaceable oil filter and oil cooler cores arestandard.Automated controls selftest on startup.
3
pressure vessels and are stamped accordingly. The tubing is rollexpand-
ed into the tubesheets and the heads are removable and inter-changeable
from end to end for ease of tube maintenance. Vent and drain plugs are
provided in each head. Two-pass coolers are standard with optional one
and three-pass designs.Victaulic connections are standard.
The microcomputer control system has two main functions which are Screen function and control and protection function.
Display Information
The alphanumeric liquid crystal display utilizes easy-to-understand
menu-driven software.Inexperienced operators can quickly work through
these menus to obtain the information they require or to modify control
parameters. More experienced operators can bypass the menu systems, if
desired, and move directly to their requested control function. Easily
accessible measurements include:
Leaving chilled water temperature
Evaporator pressure
Condenser pressure
System voltage
Guide vane opening degree
Compressor contactor status
Water temperature reset value
Water flow switch status
External start/stop command status
Oil temperature
Oil tank temperature
Oil tank pressure
Gears temperature
Oil pressure difference
Freeze protection
High oil temperature
High motor temperature
Low pressure difference
Compressor surge
Sensor error
Compressor over-current
Anti-recycle
Compressor starter failure
Oil pump overload
Oil pump starter failure
Low pressure difference of oil
Power loss
Chilled water flow loss
The microcomputer retains the latest thirty alarm conditions
complete with time of failure in its alarm history. This tool aids service
technicians in troubleshooting tasks enabling downtime and nuisance
trip-outs to be minimized.
Remote Monitoring(Option) The standard RS232 communications port remote monitoring and control
from a simple terminal and optional phone modem. This valuable enhancement
to the refrigeration system allows the ultimate in serviceability. The microcom-
puter comes standard with history files which may be used to take logs which
are retrievable via the phone modem periodically. Now owners of multiple build-
ings have a simple and inexpensive method of investigating potential problems
quickly and in a highly cost effective manner. Dunham-Bush has open protocol
on its microcomputer to allow direct interface with Building Management
Systems.
·DCLC
System Protection
The following system protection controls will automatically act to
insure system reliability:
Low suction pressure
High discharge pressure
4
Started by set time
·DCLC
Remote controller (Option)
5
DC
LC
Tec
hnic
al D
ata
Not
e:
1.W
ork
Cond
ition
:Coo
ler W
ater
12/7,
Foul
ing
Fact
or 0
.017
6(m
2-°K
)/kW
; Con
dens
er W
ater
32/3
7,F
oulin
g Fa
ctor
0.0
43(m
2-°K
)/kW
2.A
bove
Chi
ller S
elec
tion
acco
rdin
g to
380
V v
olta
ge,
if th
ere
are
othe
r req
uire
men
ts ,p
leas
e co
ntac
t with
DU
NH
AN
-BU
SH.
Uni
t Mod
el
Coo
ling
Cap
acity
RT kW kW A A
CO
P
rotoM DimensionCondenserEvaporaotr
Rat
ed C
urre
nt
Star
ting
Cur
rent
Coo
ling
Mod
e
Cod
e
Flow
Rat
e
Pres
sure
Los
s
Noz
zle P
ipe S
ize
Cod
e
Flow
Rat
e
Len
gth
A
Wid
thB
Hei
ght
C
Rig
ging
Wei
ght
Ope
ratin
g Weig
ht
R13
4a W
eigt
h
kW/kW
kW/RT l/s l/skPa
mm
kPa
mm
mm
mm
mm kg kg
DC
LC
300
1055
210
5.02 0.7
T07
357
893
350
1231
231
5.33
0.66 T16
392
980
400
1406
266
5.29
0.67 T27
451
1128
450
1582
298
5.31
0.66 T36
509
1273
500
1758
326
5.39
0.65
T66
555
1388
550
1934
340
5.69
0.62 F16
578
1445
600
2110
393
5.37
0.66 F27
667
1668
650
2285
421
5.43
0.65 F27
719
1798
700
2461
429
5.74
0.61 F36
731
1828
750
2637
479
5.51
0.64 F47
819
2048
800
2813
511
5.50
0.64 F47
876
2190
850
2989
524
5.70
0.62 S05
897
2243
900
3164
550
5.75
0.61 S25
944
2360
1000
3516
613
5.74
0.61
S35
1054
2635
1100
3868
675
5.73
0.61
S35
1157
2893
1200
4219
716
5.89 0.6
S65
1226
3065
1300
4571
772
5.92
0.59
S65
1328
3320
1400
4922
849
5.80
0.61
S75
1457
3643
1500
5274
898
5.87 0.6
S85
1542
3855
20 50 86
21 59 83
22 67 81
30 76 80
36 84 89
40 92 70
45 101
93
46 109
90
47 118
94
55 126
82
55 134
93
65 143
92
65 151
103
66 168
102
67 185
105
75 202
109
76 218
109
76 235
126
77 252
125
4173
1670
2000
6984
7717
277
4173
1670
2000
7157
7988
308
4173
1670
2000
7245
8140
340
4388
1879
2100
8760
9841
381
4909
1879
2100
9529
1089
4
477
4423
1994
2250
9918
1139
2
521
4944
1994
2250
1038
7
1201
8
617
4944
1994
2250
1072
0
1250
8
648
4944
1994
2250
1080
0
1263
6
666
4959
2096
2270
1157
0
1353
6
693
4959
2096
2270
1167
2
1367
7
693
5675
2426
2903
1904
3
2189
1
1039
5675
2426
2903
1926
5
2219
9
1039
5675
2426
2903
1770
4
2086
4
1103
5675
2426
2903
1986
6
2314
3
1157
5737
2712
2965
2234
8
2588
7
1156
5737
2712
2965
2254
3
2621
2
1215
5737
2712
2965
2276
5
2652
0
1215
5737
2712
2965
2296
6
2685
0
1270
380/
6000
/100
00V
Ref
riger
ant
053N
D003
ND
052N
D002
ND
053N
D003
ND
052N
D002
ND
·DCLC
Inpu
t Pow
er
300
350
400
450
500
550
600
650
700
750
800
850
900
1000
1100
1200
1300
1400
1500
Com
pres
sor C
ode
Pow
er S
uppl
y
Pres
sure
Los
s
Noz
zle P
ipe S
ize
kPa
mm
21 60 68
22 71 67
45
121
88
41
111
54
37
101
72
30 91 87
22 81 87
47
131
74
47
141
86
55
151
86
56
161
87
65
171
90
66
181
82
67
202
84
67
222
101
76
242
91
76
262
106
77
282
105
77
302
120
Weights
6
Code of Evaporator and Condenser
Frame
2
3
4
5
6
7
20 22
25 27
30 32
35 37
40 42
45 47
50 52
55 57
60 62
65 ~ 67
70 ~ 72
75 77
Length “A” Width “B” Heigth “C” Space “D”
mm
Dimension Data
"A"
"C"
RecommendationLength "D"
Min Space
635mm
375mm
"B"
Recommendation Space1350mm
Maintenance Space1250mm
Maintenance Space
Notes 1 The length of A including flanges, where: evaporator and condenser are two passes close to the switch box in the standard chillers).
2 The above dimensions are based on the pressure bearing at water side, which is 1.0Mpa, and the length A will be changed according to it.
3 The above dimensions are for the standard chillers, if you need non-standard ones, please connect with Dunham-bush.
·DCLC
Min Space
4173
4694
4388
4909
4423
4944
4438
4959
5065
5675
5127
5737
1670
1670
1879
1879
1994
1994
2096
2096
2426
2426
2712
2712
2000
2000
2100
2100
2250
2250
2270
2270
2782
2903
2965
2965
3750
4350
3750
4350
3750
4350
3750
4350
4270
4880
4270
4880
7
Configuration Data
Notes 1 Water pipelines of standard chillers are at motor side (Model A), and the inlet and outlet of water are at underside and upside, respectively.
2 The above dimensions are based on the pressure bearing at water side, which is 1.0Mpa, and the length A will be changed according to it.
Code of Evaporator and Condenser
Frame 220 ~ 22
25 ~ 27
Code of Evaporator and Condenser
Frame
3
4
5
6
7
30 ~ 32
35 ~ 37
40 ~ 42
45 ~ 47
50 ~ 52
55 ~ 57
60 ~ 62
65 ~ 67
70 ~ 72
75 ~ 77
A B C D E F G H
606
747
799
1030
1044
976
1117
1169
1538
1602
478
463
500
787
737
848
833
870
1295
1295
DN200
DN200
DN250
DN300
DN350
DN200
DN250
DN250
DN300
DN350
940
997
1045
1213
1356
464
489
521
610
678
A
611 881 390 660 212 212 387 387
B C D E F G H
DN200
Water Chamber Close to the Motor (Model A Water Chamber Close to the Compressor (Model B
7
8
6
5
Condenser
Evaporator
A
B
F F
G
E EH
CD
Condenser
Evaporator7
86
5
A
B
D
C
H G
Condenser
Evaporator
1
23
4
AD
C
G H
B
Condenser
Evaporator
1
2
3
4
A
FF
G
EEH
CD
B
·DCLC
8
The Requirements of Connection and Pipelines:
1 All the cables must be set and marked correctly
2 Filters must be set in the cooling water pipelines
3 Temperature gauge (0-50 and pressure gauge 0-1MPa or 2MPa should be set in the inlet/out pipelines
4 It’s recommended that vent of the relief valve(R1-1/4”,Internal thread should be led to outside by an steel tube (Outer Diameter:42mm, Thickness:4mm
5 In order to protect personal safety and health,It’s recommended that an oxygen detector should be set in the machine room.
1 Air Switch
6 Air Vent
11
2 Non-airborne Starting Cabinet
7) Pressure Gauge
12)Cooling Tower Starter
3 Motor Terminal Box
8 Cooled Water Pump
13 Air Switch
4 Oil Pump Control Box
9 Cooling Water Pump
14 Air Switch of Oil Pump
5 Switch Box
10 Cooled Water Pump Starter
Line No.
1#
2#
3#
4#
5#
6#
7#
Application Specification
From Starting Cabinent to Control Box
From Starting Cabinent to Main Motor
380V AC: Three Phase, One Neutral Line, One Earth Line. 6300V, 10000V: Three Phase, One Earth Line
Two Control Lines Option
Two Control Lines Option
Two Control Lines Option
380V AC: Three Phase, One Neutral Line, One Earth Line.
220V AC: Single Phase,One Neutral Line, One Earth Line. 10 Shield Control Lines, 600V, 80 Grounding in the starting Cabinent
380V AC 6 Motor Lead lines the minimum current of it is 0.721 times of rated current) Two Earth Lines
6300V/10kV AC 3 Motor Lead Lines,One Earth Lines
Classical Pipelines and Connection Figue
2
4
6
78
9
3
5
·DCLC
Power
Connected with Cooled Water PumpConnected with Cooling Water Pump
Connected with Cooling Tower Blower
Passed to Cooling Tower
From Cooling Tower
From Terminals
Passed to
Terminals
Drain
Cooling Water Pump Starter
Main Power Entering Starting Cabinent
From Switch Box to Cooling Tower Starter
From Switch Box to Cooling Pump Starter
From Switch Box to Cooled Pump Starter
From Main Power to Oil Pump Control Box
9
Note
1 There are 4 pieces of bottom plates 16 adjustable bolts and
16 pieces of correction level backing plates in each chiller
2 After pouring concrete, the adjustable bolts should be taken out
3 Based on the requirement of horizonal adjustment, the thickness
of sceondary pouring concrete should be determined according
to the actual condition
Foundation and Damper
Foundation Dimension
Standard Damper Model
Simple Damper Model
B-B
Code of Evaporator and Condenser
Frame
2
3
4
5
6
7
20 22
25 27
30 32
35 37
40 42
45 47
50 52
55 57
60 62
65 67
70 72
75 77
A
3960
4480
3960
4480
3960
4480
3960
4480
4658
5268
4658
5268
B
1670
1670
1879
1879
1994
1994
2096
2096
2426
2426
2712
2712
C
92
92
92
92
92
92
92
92
176
176
176
176
D
387
387
387
387
387
387
387
387
559
559
559
559
E
229
229
229
229
229
229
229
229
406
406
406
406
F
540
540
540
540
540
540
540
540
711
711
711
711
G
464
464
464
464
464
464
464
464
635
635
635
635
H
254
254
254
254
254
254
254
254
432
432
432
432
J
178
178
178
178
178
178
178
178
356
356
356
356
Tube Plate
Support Plate
High Elastic Damper
1076
B
C
D
E
Condenser Centerline
Evaporator CenterlineFoundation
A
A
A
B B
A-A
Tube Plate
Horizonal Datum Line25mm Bottom Plate
Ajustable BoltSupport Plate
Correction Level Backing Plate
Chiller Support Plate
High Elastic Damper
Adjustable Bolts
Bottom Plate
HJ38
F G38 4-M22
·DCLC
Correction Level Backing Plate
10
Starter Modes
Voltage
50Hz
Switch
Solid State Starter
Low
380-415
-
-
45
Star-delta Starter
Low
346-415
Enclosed
-
33
Low
346-415
Enclosed
57.7
33
Low/High
346-10000
Enclosed
65
42.3
Low/High
346-10000
Enclosed
80
64
High
2300-10000
Enclosed
65
65
High
2300-10000
Enclosed
80
80
Direct Starter
-
-
-
-
100
50HZ Motor Data
Motor Starter
Note 1 Symbol Description RLA-Rated Current LRYA-Star Type Stopping-turning Current LRDA-Delta Stopping-turning Current
2 If the voltage that you need is differnt, Please connect with Dunham-bush
Motor Code
Input Power
Input Power
Voltage
Voltage
380V
380V
kW
RLA
LRYA
LRDA
kW
RLA
LRYA
LRDA
Motor Code
Current (A)
Current (A)
CB
194
332
604
1903
CQ
597
968
1365
4457
CC
215
367
609
1916
CR
634
1082
2135
6775
CD
241
419
778
2441
CS
681
1133
2049
6530
CE
272
457
707
2208
CT
738
1243
2343
7450
CF
304
538
877
2741
DB
597
1018
1870
5933
CG
335
571
938
2929
DC
634
1082
2135
6775
CH
366
597
917
2990
DD
681
1133
2049
6530
CJ
398
650
984
2158
DE
738
1243
2343
7450
CK
429
695
1234
4013
DF
806
1349
2359
7503
CL
461
747
1231
4007
DG
856
1477
3150
9745
CM
492
797
1351
4398
DH
916
1562
3240
10286
CN
523
848
1469
4775
DJ
966
1648
3417
10847
CP
560
908
1280
4181
DK
1015
1731
3590
11397
Self Coupling Voltage Transformation Starter Primary Reactance Starter
·DCLC
Ratio of Starting Current OccupiedStopping Turning Current
11
Model Selection Discription
Code of evaporator and condenser
45 47
A B C D E F G H J
Code of evaporator and condenser
45 47
A B C D G H
747 1117 463 838 DN200 DN250 489 997
Code of evaporator and condenserA-Length mm
(Including FlangesB-Width mm C-Heigth mm D-Pipeline Space mm
4944 1994 2250 435045 47
Evaportor design pressure at water side: the standard bearing
pressure at water side is 1.0MPa,and option with 2.0MPa
Condenser design pressure at water side: the standard bearing
pressure at water side is 1.0MPa,and option with 2.0MPa
Damping Device: the centrifugal chillers are standard with rubber
damper, and option with spring damper
Noise Control mode: the chillers are option with noise control jacket
at the discharge of the centrifugal compressor, as can decrease the noise
about 1-2dB A
Dimension Data Discription
The dimension data of the chillers can be refered to the lookup table.
As a case of DCLC4647F53, where the code of evaporator and condenser
is 46 and 47, respectively, the dimension data of it can be determined by
the following method:
·DCLC
Refering to page 6 and from the row of 46~47, the dimension data of it can be obtained
Refering to page 7 and from the row of 46~47, the size of pipeline and flanges can be obtained
Refering to page 9 and from the row of 46~47, the foundation data of it can be obtained
4480 1670 92 387 229 540 464 254 178
12
FLA
0 ~ 495A
496 ~ 741A
742 ~ 1150A
1151 ~ 1350A
1700
2000
2100
2200
800
900
1100
1200
450
550
550
550
D
265
300
350
250
E
240
250
250
250
F
335
435
435
435
G
500
600
800
900
H
380
440
440
490
I
92
92
142
142
J
235
325
325
325
K
636
726
926
926
L
480
480
480
530
M
82
82
82
82
N
600
670
810
880
AHeight
BWidth
CThickness
380V Low Voltage Star-delta Starting Cabinent
50A
B
ED
C
Outgoing Wiring Column
T1-T6
Incoming Wiring ColumnL1 L2 L3
GHI
260 F
4-1130
Outgoing Wiring Hole
J260
N
M L
K
The front door
can be open 135°4-Lifting RingsInner Diameter 35mm
Control Wiring Terminal
Outgoing Wiring Cable fixed mount
L1 L2 L3
T1 T2 T3 T4 T5 T6 XB
Lifting Ring Lifting Ring
Left View
PV PA
Front View Components Arrangement Diagram in the Cabinent
Top View
·DCLC
Incoming Wiring Cable fixed mount
Top View
Outgoing Wiring Hole
13
Enclosed Star-Delta Starter Cabinent Wiring Diagram
PE
PE
3N~50HZ 380V/220V
QM1
N L2L1PE L3
L12
L13
2W 2U 2V
3~M
1U 1V 1W
KM1
L11
KM4
KM2L21
L22L23
KM3
TA1
TA2
135
7
264
8
SB1
APA
PV
KM2
FR
7
531
264
8
SB2
V
X1:5
X1:1
X1:2
X1:3
L31
L32L33
R
2523
27
29
31
33
35
37
39
19
17
15
13
11
9753
L1N
1
21
X1:4
HL3
KT1
KM3
KM1
KM2
KM1
KM3
FR14MK2MK
KT1
HL4
KM2
KM1
KM4
KM3
HL1
YW
GN
WH
KT2
KA5Starting Command
KM4KT2
Starting Indirector
Resistor
Main contactor
Running Indrector
Starting Time
Transfer Resistance Timeout
KA1 Alarm Director
RD HL2
Power Indirector
FR1
·DCLC
Products that perform...By people who care
Tel: (0535) 6588999 Fax: (0535) 6581999Post Code: 264003
www.dunham-bush.com.cn
Dunham-bush Yantai Co.LtdNo.1,Dunham-bush Road,Laishan District,Yantai,Shandong,China
F48A410001G
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