30gtn gtr

8/20/2019 30GTN GTR

1/94Copyright 2003 Carrier Corporation Form 30GTN-5P

Features/BenefitsComfort Link control

Your link to a world of simple and easyto use air-cooled chillers that offer out-standing performance and value. The30GTN,GTR liquid chillers employmore than the latest advanced micro-processor controls, they utilize anexpandable platform that grows as youneeds change. From stand-alone opertion to remotely monitored and oper-ated multi-chiller plants, ComfortLinkcontrols can keep you plugged in.

ComfortLink controls are fully communicating, and are cable ready forconnection to a Carrier Comfort Net-work (CCN). Occupancy scheduling,temperature and pressure read-outs,and the ComfortLink scrolling mar-quee clear language display compli-ment the standard features, linking yoto a world of carefree comfort. The30GTN,GTR chillers are built on thelegendary performance of the Carriermodel 30G Flotronic™ chiller andshare many of the same time-provenfeatures and technologies providingeasy operation, quick installation andstart-ups that save you money!

Superior temperature controlequals potential for greaterproductivity

Whether in the classroom, on the production floor, or in the office,ComfortLink controls can help you toadapt to changing weather and busi-ness conditions. Accurate temperaturcontrol provided by the Carrier Com-

fortLink system helps to maintainhigher levels of indoor air quality, thermal comfort, and productivity space.

While many air-cooled chillers useonly leaving fluid temperature controlthe 30GTN,GTR chillers utilize leavinfluid temperature control with a stan-dard entering fluid temperature com-pensation. This Carrier exclusive

30GTN,GTRAir-Cooled Reciprocating

Liquid Chillerswith Comfort Link™ Controls

50/60 HzNominal Capacities: 60 to 410 Tons

205 to 1445 kW

ProductData

8/20/2019 30GTN GTR

2/94

2

provides smart control and intelligentmachine capacity staging. Unlike manychillers, Carrier model 30GTN,GTRchillers do not require constant fluidflow. The ability to operate with vari-able flow also allows building owners torealize even greater overall systemenergy savings in the chilled waterpumping system of up to 85%, and not just at the chiller.

Energy management madeeasy

While 30GTN,GTR chillers have manystandard features such as networkcommunications capability and temper-ature reset based on return fluid tem-perature, they can also expand asneeds change. Supply temperaturereset based on outside air or spacetemperature is as easy as adding a ther-mistor. The Energy Managementoption can allow you to take advantageof changing utility rate structures with

easy to use load shedding, demand lim-iting and temperature reset capabilities.Reset triggered via 4 to 20 mA signalmakes integrating from an existingbuilding management system simple.

The ComfortLink™ platform can beexpanded further with the ServiceOption which has all of the features ofthe Energy Management option, alongwith an additional hand-heldComfortLink Navigator™ display,remote service connection port, andGFCI convenience outlet (60 Hz only).While providing additional informationin a clear language format, the Naviga-

tor display can be plugged into the unitat either the control panel or at theremote service port, allowing the ser-vice technician to operate the unit fromwhere the maintenance or service workis being performed, thereby minimizingdowntime to ensure the system is readyfor operation in the shortest amount oftime. Both the Energy Managementand Service Options can be factory-supplied or can be added in the field ata later date as needs change.

Full and part load efficiencyadvantage

The 30GTN,GTR chillers with

ComfortLink control offer outstandingefficiencies (EER [Energy EfficiencyRatio], COP [coefficient of perfor-mance], and IPLV [integrated part loadvalue]) in both full (up to 9.96 EER)and part load operation (IPLVs up to14.7). Increased part load efficiency isprovided by dual independentrefrigeration circuits, suction cutoffunloading, and return fluid temperaturecompensation. All 30GTN,GTR chillerefficiencies are ASHRAE 90.1-1999compliant.

The fully integrated ComfortLinkcontrol system maintains efficient con-trol over the compressors, unloaders,expansion valves, and condenser fansto optimize performance as conditionschange. The Carrier exclusive long-stroke electronic expansion valve(EXV) operates at reduced condensingpressures, thereby allowing the controlto operate the fans down to lower out-door temperatures. By utilizing valveposition information, the control main-tains the highest possible evaporatorpressure and minimizes the excessivesuperheat that conventional thermalexpansion valve (TXV) systems require.Wider operating ranges equalincreased efficiencies and lowerinstalled costs.

Building design flexibility

Design and consulting engineers willappreciate the broad selection of sizesand wide operating range offered by

the 30GTN,GTR chillers. With built-indual chiller control, imaginative largetonnage systems can be easily engi-neered and controlled with smaller,easier to handle modules. Modulardesign allows engineers to considerside by side, offset, or angled place-ment to fit the awkward spaces that thearchitect sometimes leaves for mechan-ical systems. Or, in the case of plannedexpansion, additional cooling can bebrought on-line and controlled from thesame system.

In some places facility managers mayfind that the cash flow provided by

building up large air-cooled multi-chillerplants can easily offset any efficiencylosses when compared to large water-cooled centrifugal type chilled waterplants.

Quality and reliability

To assure long life and quality perfor-mance, every chiller (both 50 and60 Hz) is factory run tested at full load.Individual components are also testedat many levels to assure that only the

best parts make it into 30GTN,GTRchillers. Long life and reliability are alsoa function of design. While some man-ufacturers like to talk about movingparts, Carrier’s engineers recognizedthe potential dangers to chiller systemscaused by problems in the power distri-bution system. Low voltage and phaseimbalances are but a few of the condi-tions that can hurt the compressor’smotor. Model 30G chillers were one ofthe first to offer ground current sensingto prevent compressor motor burn-outthat would contaminate the system andpotentially threaten the life of futurereplacement compressors. The 06Esemi-hermetic compressors are builtfor performance and have proventhemselves in commercial refrigerationequipment worldwide.

With tens of thousands of chillersoperating in all corners of the world,end-users count on the reliability ofCarrier 30G chillers. The Carrier

McMinnville, Tennessee (U.S.A.) plantis an ISO 9001:2000 registered facilityas are many of Carrier’s other compo-nent and assembly plants throughoutthe world.

Features

• Simple and easy to useComfortLink communicatingcontrols.

• Wide operating envelope from –28to 52 C (–20 to 125 F).

• Accurate temperature control withreturn fluid compensation.

• Value added features built-in; dual

chiller control, reset from return.• Superior full and part-loadefficiency.

• Precise multiple-step capacity.• Low noise operation (quieter than

many screw chillers).• Dual independent refrigerant

circuits.• Full load factory run tested.• Wide range of sizes available from

stock.• History of proven performance and

reliability.

Table of contentsPageFeatures/Benefits. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-3

Model Number Nomenclature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4Physical Data. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-24Factory-Installed Options. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25Field-Installed Accessories . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26Base Unit Dimensions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27-42Application Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43-51Selection Procedure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52,53Performance Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53-76Electrical Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 77-84Controls . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85-87Typical Piping and Wiring . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88,89Guide Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 90-93

→

104

8/20/2019 30GTN GTR

3/94

3

Features/Benefits (cont)

R

Run Status

Service Test

Temperature

Pressures

Setpoints

Inputs

Outputs

Configuration

Time ClockOperating Modes

Alarms

Alarm Status

ENTER

MODE

ESCAPE

06E COMPRESSOR

ELECTRONIC EXPANSION VALVE (EXV)

SCROLLING MARQUEE DISPLAY

PART-LOAD EFFICIENCY28% GAIN

FACTORY TEST

Pe rform ance Assu r ance

Rated in accordance withARI Standard 550/590-98(60 Hz only).

8/20/2019 30GTN GTR

4/94

4

UNIT SIZES AND MODULAR COMBINATIONS

*60-Hz units/50-Hz units.

UNIT MODEL30GTN,GTR

NOMINALTONS

SECTIONA UNIT

30GTN,GTR

SECTIONB UNIT

30GTN,GTR

60 60 — —70 70 — —

80 80 — —

90 90 — —

100 100 — —

110 110 — —

130 125 — —

150 145 — —

170 160 — —

190 180 — —

210 200 — —

230 220 150 080

245 230 150 090

255 240 150 100

270 260 170 100290 280 190 110

315 300 210 110

330 325 170 170

360 350 190 190/170*

390 380 210 190

420 410 210 210

Model number nomenclature

30GT N 130 - E C 9 2 3 - -

30GT – Air-Cooled Liquid Chiller

Compressor StartN – Across-The-Line Start with Comfort Link™ ControlsR – Part-Wind Start with Comfort Link Controls

Unit Sizes*060 100 170 245 315 420070 110 190 255 330080 130 210 270 360090 150 230 290 390

Module Designation (230-420 Unit Sizes Only)*AB

Convenience Group Options

- – Standard Marquee DisplayE – Standard Marquee Display withEnergy Management Option

S – Service Option with Navigator Display (208/230,460,575v)V – Service Option with Navigator Display (380,380/415v)

Options- - – NOTE: Contact your Carrier representative

for details on available factory-installed options.

Packaging1 – Domestic3 – Export

V-Ph-Hz1 – 575-3-602 – 380-3-60†5 – 208/230-3-606 – 460-3-609 – 380/415-3-50†

Not Used

Condenser Coil Options- – Copper Tube, Aluminum FinsC – Copper Tube, Copper FinsE – Copper Tube, Aluminum E-Coated FinsF – Copper Tube, Copper E-Coated FinsK – Copper Tube, Pre-Coated Aluminum Fins

LEGEND

EXV — Electronic Expansion Valve

*Refer to Unit Sizes and Modular Combinations below.†Export only — not for U.S. domestic sale.

® I S O

9 0 0 1 :2 0 0 0 # A 2 2

6 0

Quali t y Assu r ance

Approvals:

ISO 9001EN 9000:2000

8/20/2019 30GTN GTR

5/94

5

Physical data

6 0

H z E N G L I S H

L E G E N D

* 0 6 E 2 5 0 c o m p r e s s o r h a v e 4 c y l i n d e r s ; a l l o t h e r s h a v e 6 .

N O T E : F a c i n g t h e c o m p r e s s o r s ,

C i r c u i t A i s o n t h e r i g h t a n d C i r c u i t B i s o n t h e l e f t .

3 0 G T N , G

T R U N I T

S I Z E

0 6 0

0 7 0

0 8 0

0 9 0

1 0 0

1 1 0

S Y

S T E M M

O D U L E

S

—

—

—

—

—

—

A P P R O X

O P E R A T

I N G W E I G H T ( l b )

C u - A l

4 7 4 0

5 0 2 8

6 6 3 0

7 0 1 5

8 6 1 0

8 6 6 0

C u - C u

5 1 5 7

5 6 5 6

7 3 5 5

7 7 4 0

9 5 6 0

9 6 1 0

R E F R I G E R A N T T Y

P E

R - 2 2

C h a r g e ,

T o t a l / O v e r C l e a r G l a s s ( l b )

C k t A

5 2 / 1 4

7 0 / 1 5

7 8 / 1 5

7 8 / 1 5

9 8 / 2 0

9 8 / 2 0

C k t B

5 4 / 1 4

6 9 / 1 5

7 8 / 1 5

7 8 / 1 5

1 0 5 / 2 0

1 0 5 / 2 0

C O M P R E

S S O R S

R e c i p r o c a t i n g ,

S e m i - H e r m e t i c

S p e e d ( r p m )

1 7 5 0

0 6 E *

( Q t y )

C k t A

( 1 ) 2 7 5

( 1 ) 2 9 9

( 1 ) 2 5 0 ,

( 1 ) 2 7 5

( 1 ) 2 5 0 , (

1 ) 2 6 5

( 1 ) 2 6 5 ,

( 1 ) 2 7 5

( 1 ) 2 6 5 ,

( 1 ) 2 9 9

( Q t y )

C k t B

( 1 ) 2 9 9

( 1 ) 2 9 9

( 1 ) 2 9 9

( 2 ) 2 6

5

( 1 ) 2 6 5 ,

( 1 ) 2 7 5

( 1 ) 2 6 5 ,

( 1 ) 2 7 5

O i l C h a r g e ( C o m

p r e s s o r / p t )

2 5 0 / 1 4 . 0 ,

2 6 5 / 1 9 . 0 ,

2 7 5 / 1 9 . 0 ,

2 9 9 / 1 9 . 0

N o

. C a p a c i t y C o

n t r o l S t e p s

4

4

7

1 1

1 1

1 1

C a p a c i t y ( % )

C k t A

4 3 . 3

5 0 . 0

5 6 . 0

4 7 . 0

5 0 . 0

5 4 . 0

C k t B

5 6 . 7

5 0 . 0

4 4 . 0

5 3 . 0

5 0 . 0

4 6 . 0

M i n i m u m

C a p a c

i t y

S t e p ( % )

2 8 . 8

3 3 . 3

2 2 . 0

1 8 . 0

1 5 . 0

1 4 . 0

C O N D E N S E R F A N

S

P r o p e l l e r , D i r e c t

D r i v e

S t a n d a r d

F a n

S p e e d ( r p

m )

1 1 4 0

N o

. B l a d e s .

. . D

i a .

( i n

. )

4 . . . 3

0

N o

. F a n s

. . . H p

/ k W

( e a c h )

6 . . . 1

/ 0 . 7

4 6

6 . . . 1

/ 0 . 7

4 6

6 . . . 1

/ 0 . 7

4 6

6 . . . 1

/ 0 . 7 4 6

8 . . . 1

/ 0 . 7

4 6

8 . . . 1

/ 0 . 7

4 6

T o t a l A i r f l o w ( c f m )

5 2 , 0

0 0

5 1 , 0

0 0

5 7 , 0

0 0

5 7 , 0 0

0

7 6 , 0

0 0

7 6 , 0

0 0

C O N D E N S E R C O I

L S

3 / 8 - i n . O D V e r t i c a l a n d H o r i z o n t a l , P l a t e F i n , E n h a n c e d C o p p e r T u b i n g

F i n s / i n

.

1 7

1 7

1 7

1 7

1 7

1 7

N o

. R o w s ( C k t A

o r B )

2

3

3

3

3

3

F a c e A r e a ,

C k t A a n d B T o t a l ( s q f t )

1 1 6 . 7

1 1 6 . 7

1 2 8 . 3

1 2 8 . 3

1 6 8 . 0

1 6 8 . 0

M a x

W o r k i n g P r

e s s u r e R e f r i g e r a n t ( p s i g )

4 5 0

C O O L E R

O n e . . . D

i r e c t E x p a n s i o n , S h e l l a n d T u b e

W e i g h t ( e m p t y , l b )

6 2 0

6 2 0

7 4 5

7 4 5

8 6 0

8 6 0

N o

. R e f r i g e r a n t

C i r c u i t s

2

N e t W a t e r V o l u m

e ,

i n c l u d e s n o z z l e s ( g a l . )

1 8 . 0

1 8 . 0

2 4 . 5

2 4 . 5

3 0 . 3

3 0 . 3

M a x

W o r k i n g P r

e s s u r e R e f r i g e r a n t S i d e ( p s i g )

2 7 8

2 7 8

2 7 8

2 7 8

2 7 8

2 7 8

M a x

W o r k i n g P r

e s s u r e F l u i d S i d e ( p s i g )

3 0 0

3 0 0

3 0 0

3 0 0

3 0 0

3 0 0

F L U I D C O N N E C T I O N S ( i n

. )

V i c t a u l i c T y p

e

I n l e t a n d O u t l e t

4

4

4

4

5

5

D r a i n ( N P T )

3 / 4

C u - A l

—

C o p p e

r T u b i n g — A l u m i n u m F i n s C o n d e n s e r C o i l

C u - C u

—

C o p p e

r T u b i n g — C o p p e r F i n s C o n d e n s e r C o i l

O D

—

O u t s i d

e D i a m e t e r

8/20/2019 30GTN GTR

6/94

6

Physical data (cont)

6 0

H z E N G L I S H (

c o n t )

L E G E N D

* 0 6 E 2 5 0 c o m p r e s s o r h a v e 4 c y l i n d e r s ; a l l o

t h e r s h a v e 6 .


C i r c u i t A i s

o n t h e r i g h t a n d C i r c u i t B i s o n t h e l e f t .

3 0 G T N , G

T R U N I T

S I Z E

1 3 0

1 5 0

1 7 0

1 9 0

2 1 0

2 3 0

S Y

S T E M M

O D U L E

S

—

—

—

—

—

A

B

T o t a l

A P P R O X

O P E R A T I N G W E I G H T ( l b )

C u - A l

1 0 , 0

4 6

1 0 , 4

8 1

1 1 , 2

9 3

1 2 , 6

7 6

1 3 , 3

8 0

1 0 , 4

8 1

6 6 3 0

1 7 , 1

1 1

C u - C u

1 1 , 3

1 8

1 1 , 7

5 3

1 2 , 5

6 5

1 4 , 1

9 5

1 4 , 8

9 9

1 1 , 7

5 3

7 3 5 5

1 9 , 1

0 8

R E F R I G E R A N T T Y P E

R - 2 2

C h a r g e ,

T o t a l / O

v e r C l e a r G l a s s ( l b )

C k t A

1 3 3 / 2 8

1 4 3 / 3 5

1 5 3 / 4 5

1 7 8 / 3 0

1 9 0 / 4 0

1 4 3 / 3 5

7 8 / 1 5

— / —

C k t B

1 3 3 / 2 8

1 4 3 / 3 5

1 6 2 / 4 5

1 7 8 / 3 0

1 8 5 / 4 0

1 4 4 / 3 5

7 8 / 1 5

— / —

C O M P R E

S S O R S

R e c i p r o c a t i n g , S e

m i - H e r m e t i c

S p e e d ( r p m )

1 7 5 0

0 6 E *

( Q t y ) C k t A

( 1 ) 2 7 5 ,

( 1 ) 2 9 9

( 3 ) 2 6 5

( 3 ) 2 7 5

( 1 ) 2 6 5 ,

( 1 ) 2 7 5 ,

( 1 ) 2 9 9

( 3

) 2 6 5 ,

( 1 ) 2 7 5

( 3 ) 2 6 5

( 1 ) 2 5 0 , ( 1

) 2 7 5

— / —

( Q t y ) C k t B

( 1 ) 2 7 5 ,

( 1 ) 2 9 9

( 2 ) 2 9 9

( 3 ) 2 7 5

( 1 ) 2 6 5 ,

( 1 ) 2 7 5 ,

( 1 ) 2 9 9

( 1

) 2 7 5 ,

( 2 ) 2 9 9

( 2 ) 2 9 9

( 1 ) 2 9 9

— / —

O i l C h a r g e ( C o m p r e s s o r / p t )

2 5 0 / 1 4 . 0 ,

2 6 5 / 1 9 . 0 , 2 7

5 / 1 9 . 0 ,

2 9 9 / 1 9 . 0

N o

. C a p a c i t y C o n t r o l S t e p s

1 1

1 4

1 7

6

7

1 4

8

—

C a p a c i t y ( % )

C k t A

5 0

5 0

5 0

5 0

5 0

5 0

5 6

—

C k t B

5 0

5 0

5 0

5 0

5 0

5 0

4 4

—

M i n i m u m

C a p a c i t y

S t e p ( % )

1 4

1 1

1 1

1 4

1 2

1 1

2 2

—

C O N D E N S E R F A N S

P r o p e l l e r , D i r e c t D r i v e

S t a n d a r d

F a n

S p e e d ( r p m )

1 1 4 0

1 1 4 0

1 1 4 0

1 1 4 0

1 1 4 0

1 1 4 0

1 1 4 0

—

N o

. B l a d e s .

. . D i a

. ( i n

. )

4 . . . 3

0

4 . . . 3

0

4 . . . 3

0

4 . . . 3

0

4 . . . 3

0

4 . . . 3

0

4 . . . 3 0

—

N o

. F a n s

. . . H p / k W

( e a c h )

1 0 . . . 1

/ 0 . 7

4 6

1 0 . . . 1

/ 0 . 7

4 6

1 0 . . . 1

/ 0 . 7

4 6

1 2 . . . 1

/ 0 . 7

4 6

1 2 . . . 1

/ 0 . 7

4 6

1 0 . . . 1

/ 0 . 7

4 6

6 . . . 1

/ 0 . 7

4 6

1 6 . . . 1

/ 0 . 7

4 6


1 0 0 , 0

0 0

1 0 0 , 0

0 0

1 0 0 , 0

0 0

1 2 0 , 0

0 0

1 2 0 , 0

0 0

1 0 0 , 0

0 0

5 7 , 0 0

0

1 5 7 , 0

0 0

C O N D E N S E R C O I L

S

3 / 8 - i n . O D , V e r t i c a l a n d H o r i z o n t a l , P l a

t e F i n , E n h a n c e d C o p p e r T u b i n g

F i n s / i n

.

1 7

1 7

1 7

1 7

1 7

1 7

1 7

—

N o

. R o w s ( C k t A o r B )

3

3

3

3

3

3

3

—

F a c e A r e a ,


2 2 5 . 1

2 2 5 . 1

2 2 5 . 1

2 6 8 . 9

2 6 8 . 9

2 2 5 . 1

1 2 8 . 3

3 5 3 . 4

M a x

W o r k i n g P r e s s u r e R e f r i g e r a n t ( p s

i g )

4 5 0

4 5 0

4 5 0

4 5 0

4 5 0

4 5 0

4 5 0

—

C O O L E R

O n e

. . . D

i r e c t E x p a n s i o n ,

S h e l l a n d T u b e

O n e P e r M o d u l e . . . D

i r e c t E x p

a n s i o n ,


W e i g h t ( e m p t y ,

l b )

1 3 2 0

1 3 2 0

1 6 3 0

1 6 3 0

1 8 6 5

1 3 2 0

7 4 5

2 0 6 5

N o

. R e f r i g e r a n t C i r c u i t s

2

2

2

2

2

2

2

4

N e t W a t e r V o l u m e ,

i n c l u d e s n o z z l e s ( g

a l . )

5 2 . 0

5 2 . 0

6 1 . 0

6 1 . 0

7 0 . 4

5 2 . 0

2 4 . 5

7 6 . 5

M a x

W o r k i n g P r e s s u r e R e f r i g e r a n t S i d

e ( p s i g )

2 7 8

2 7 8

2 7 8

2 7 8

2 7 8

2 7 8

2 7 8

—

M a x

W o r k i n g P r e s s u r e F l u i d S i d e ( p s i g )

3 0 0

3 0 0

3 0 0

3 0 0

3 0 0

3 0 0

3 0 0

—


. )

V i c t a u l i c T y p e


6

6

6

6

6

6

4

—

D r a i n ( N P T )

3 / 4

C u - A l

—

C o p p e r T u b i n g — A l u m i n u m F

i n s C o n d e n s e r C o i l

C u - C u

—

C o p p e r T u b i n g — C o p p e r F i n s C o n d e n s e r C o i l

O D

—

O u t s i d e D i a m e t e r

8/20/2019 30GTN GTR

7/94

7

6 0

H z E N G L I S H (

c o n t )

L E G E N D




3 0 G T N , G

T R U N I T

S I Z E

2 4 5

2 5 5

2

7 0

S Y

S T E M M

O D U L E

S

A

B

T o t a l

A

B

T o t a l

A

B

T o t a l

A P P R O X


C u - A l

1 0 , 4

8 1

7 0 1 5

1 7 , 4

9 6

1 0 , 4

8 1

8 6 1 0

1 9 , 0

9 1

1 1 , 2

9 3

8 6

1 0

1 9 , 9

0 3

C u - C u

1 1 , 7

5 3

7 7 4 0

1 9 , 4

9 3

1 1 , 7

5 3

9 5 6 0

2 1 , 3

1 3

1 2 , 5

6 5

9 5

6 0

2 2 , 1

2 5


R - 2 2

C h a r g e ,

T o t a l / O v e r C l e a r G l a s s ( l b )

C k t A

1 4 3 / 3 5

7 8 / 1 5

— / —

1 4 3 / 3 5

9 8 / 2

0

— / —

1 5 3 / 4 5

9 8 / 2 0

— / —

C k t B

1 4 4 / 3 5

7 8 / 1 5

— / —

1 4 4 / 3 5

1 0 5 / 2

0

— / —

1 6 2 / 4 5

1 0 5 / 2 0

— / —

C O M P R E

S S O R S

R e c i p r o c a t i n g , S e m i - H e r m e t i c

S p e e d ( r p m )

1 7 5 0

0 6 E *

( Q t y ) C k t A

( 3 ) 2 6 5

( 1 ) 2 6 5 ,

( 1 ) 2 5 0

—

( 3 ) 2 6 5

( 1 ) 2 6 5 , (

1 ) 2 7 5

—

( 3 ) 2 7 5

( 1 ) 2 6 5

, ( 1 ) 2 7 5

—

( Q t y ) C k t B

( 2 ) 2 9 9

( 2 ) 2 6 5

—

( 2 ) 2 9 9

( 1 ) 2 6 5 , (

1 ) 2 7 5

—

( 3 ) 2 7 5

( 1 ) 2 6 5

, ( 1 ) 2 7 5

—


2 5 0 / 1 4 . 0 ,

2 6 5 / 1 9 . 0 , 2

7 5 / 1 9 . 0 ,

2 9 9 / 1 9 . 0

N o


1 4

1 1

—

1 4

1 1

—

1 7

1

1

—

C a p a c i t y ( % )

C k t A

5 0

4 7

—

5 0

5 0

—

5 0

5

0

—

C k t B

5 0

5 3

—

5 0

5 0

—

5 0

5

0

—

M i n i m u m

C a p a c i t y

S t e p ( % )

1 1

1 8

—

1 1

1 5

—

1 1

1

5

—



S t a n d a r d

F a n

S p e e d ( r p m )

1 1 4 0

1 1 4 0

—

1 1 4 0

1 1 4 0

—

1 1 4 0

1 1

4 0

—

N o

. B l a d e s

. . . D

i a .

( i n

. )

4 . . . 3

0

4 . . . 3

0

—

4 . . . 3

0

4 . . . 3

0

—

4 . . . 3

0

4 . . .

3 0

—

N o

. F a n s

. . . H p / k W

( e a c h )

1 0 . . . 1

/ 0 . 7

4 6

6 . . . 1

/ 0 . 7 4

6

1 6 . . . 1

/ 0 . 7

4 6

1 0 . . . 1

/ 0 . 7

4 6

8 . . . 1

/ 0 . 7 4 6

1 8 . . . 1

/ 0 . 7

4 6

1 0 . . . 1

/ 0 . 7

4 6

8 . . . 1

/ 0 . 7

4 6

1 8 . . . 1

/ 0 . 7

4 6


1 0 0 , 0

0 0

5 7 , 0

0 0

1 5 7 , 0

0 0

1 0 0 , 0

0 0

7 6 , 0 0

0

1 7 6 , 0

0 0

1 0 0 , 0

0 0

7 6 , 0

0 0

1 7 6 , 0

0 0


S

3 / 8 - i n . O D , V e r t i c a l a n d H o r i z o n t a l , P l a t e F i n , E n h a n c e d C o p p e r T u b i n g

F i n s / i n

.

1 7

1 7

—

1 7

1 7

—

1 7

1

7

—

N o


3

3

—

3

3

—

3

3

—

F a c e A r e a ,


2 2 5 . 1

1 2 8 . 3

3 5 3 . 4

2 2 5 . 1

1 6 8 . 0

3 9 3 . 1

2 2 5 . 1

1 6

8 . 0

3 9 3 . 1

M a x W o r k i n g P r e s s u r e R e f r i g e r a n t ( p

s i g )

4 5 0

4 5 0

—

4 5 0

4 5 0

—

4 5 0

4 5 0

—

C O O L E R





l b )

1 3 2 0

7 4 5

2 0 6 5

1 3 2 0

8 6 0

2 1 8 0

1 6 3 0

8 6 0

2 4 9 0

N o


2

2

4

2

2

4

2

2

4


i n c l u d e s n o z z l e s ( g a l . )

5 2 . 0

2 4 . 5

7 6 . 5

5 2 . 0

3 0 . 3

8 2 . 3

6 1 . 0

3 0 . 3

9 1 . 3

M a x W o r k i n g P r e s s u r e R e f r i g e r a n t S i d e ( p s i g )

2 7 8

2 7 8

—

2 7 8

2 7 8

—

2 7 8

2 7 8

—

M a x W o r k i n g P r e s s u r e F l u i d S i d e ( p s

i g )

3 0 0

3 0 0

—

3 0 0

3 0 0

—

3 0 0

3 0 0

—


. )

V i c t a u l i c

T y p e


6

4

—

6

5

—

6

5

—

D r a i n ( N P T )

3 / 4

3 / 4

—

3 / 4

3 / 4

—

3 / 4

3 / 4

—

C u - A l

—

C o p p e r T u b i n g — A l u m i n u m F i n s C o n d e n s e r C o i l

C u - C u

—

C o p p e r T u b i n g — C o p p e r F i n

s C o n d e n s e r C o i l

O D

—


8/20/2019 30GTN GTR

8/94

8

Physical data (cont)

6 0

H z E N G L I S H (

c o n t )

L E G E N D

* 0 6 E 2 5 0 c o m p r e s s o r h a v e 4 c y l i n d e r s ; a l l o

t h e r s h a v e 6 .


C i r c u i t A i s

o n t h e r i g h t a n d C i r c u i t B i s o n t h e l e f t .

3 0 G T N , G

T R U N I T

S I Z E

2 9 0

3 1 5

3 3 0

S Y

S T E M M

O D U L E

S

A

B

T o t a l

A

B

T o t a l

A

B

T o t a l

A P P R O X


C u - A l

1 2 , 6

7 6

8 6 6 0

2 1 , 3

3 6

1 3 , 3

8 0

8 6 6 0

2 2 , 0

4 0

1 1 , 2

9 3

1 1 , 2

9 3

2 2 , 5

8 6

C u - C u

1 4 , 1

9 5

9 6 1 0

2 3 , 8

0 5

1 4 , 8

9 9

9 6 1 0

2 4 , 5

0 9

1 2 , 5

6 5

1 2 , 5

6 5

2 5 , 1

3 0


R - 2 2

C h a r g e ,

T o t a l O


C k t A

1 7 8 / 3 0

9

8 / 2 0

— / —

1 9 0 / 4 0

9 8 / 2 0

— / —

1 5 3 / 4 5

1 5 3 / 4 5

— / —

C k t B

1 7 3 / 3 0

1 0

5 / 2 0

— / —

1 8 5 / 4 0

1 0 5 / 2 0

— / —

1 6 2 / 4 5

1 6 2 / 4 5

— / —

C O M P R E

S S O R S



S p e e d ( r p m )

1 7 5 0

0 6 E *

( Q t y ) C k t A

( 1 ) 2 6 5 ,

( 1 ) 2 7 5 ,

( 1 ) 2 9 9

( 1 ) 2 6 5

, ( 1 ) 2 9 9

—

( 3 ) 2 6 5 ,

( 1 ) 2 7 5

( 1 ) 2 6 5 ,

( 1 ) 2 9 9

—

( 3 ) 2 7 5

( 3 ) 2 7 5

—

( Q t y ) C k t B

( 1 ) 2 6 5 ,

( 1 ) 2 7 5 ,

( 1 ) 2 9 9

( 1 ) 2 6 5

, ( 1 ) 2 7 5

—

( 1 ) 2 7 5 ,

( 2 ) 2 9 9

( 1 ) 2 6 5 ,

( 1 ) 2 7 5

—

( 3 ) 2 7 5

( 3 ) 2 7 5

—


2 6 5 / 1 9 . 0 ,

2 7 5 / 1 9 . 0 ,

2 9 9 / 1 9 . 0

N o


6

1 1

—

7

1 1

—

1 7

1 7

—

C a p a c i t y ( % )

C k t A

5 0

5 4

—

5 0

5 4

—

5 0

5 0

—

C k t B

5 0

4 6

—

5 0

4 6

—

5 0

5 0

—

M i n i m u m

C a p a c i t y

S t e p ( % )

1 4

1 4

—

1 2

1 4

—

1 1

1 1

—



S t a n d a r d

F a n

S p e e d ( r p m )

1 1 4 0

1 1 4 0

—

1 1 4 0

1 1 4 0

—

1 1 4 0

1 1 4 0

—

N o

. B l a d e s

. . . D

i a .

( i n

. )

4 . . . 3

0

4 . . . 3

0

—

4 . . . 3

0

4 . . . 3

0

—

4 . . . 3

0

4 . . . 3

0

—

N o

. F a n s

. . . H p / k W

( e a c h )

1 2 . . . 1

/ 0 . 7

4 6

8 . . . 1

/ 0 . 7

4 6

2 0 . . . 1

/ 0 . 7

4 6

1 2 . . . 1

/ 0 . 7

4 6

8 . . . 1

/ 0 . 7

4 6

2 0 . . . 1

/ 0 . 7

4 6

1 0 . . . 1

/ 0 . 7

4 6 1 0

. . . 1

/ 0 . 7

4 6

2 0 . . . 1

/ 0 . 7

4 6


1 2 0 , 0

0 0

7 6

, 0 0 0

1 9 6 , 0

0 0

1 2 0 , 0

0 0

7 6 , 0

0 0

1 9 6 , 0

0 0

1 0 0 , 0

0 0

1 0 0 , 0

0 0

2 0 0 , 0

0 0


S

3 / 8 - i n . O D , V e r t i c a l a n d H o r i z o n t a l , P l a t e F

i n , E n h a n c e d C o p p e r T u b i n g

F i n s / i n

.

1 7

1 7

—

1 7

1 7

—

1 7

1 7

—

N o


3

3

—

3

3

—

3

3

—

F a c e A r e a ,


2 6 8 . 9

1 6 8 . 0

4 3 6 . 9

2 6 8 . 9

1 6 8 . 0

4 3 6 . 9

2 2 5 . 1

2 2 5 . 1

4 5 0 . 2

M a x

W o r k i n g P r e s s u r e R e f r i g e r a n t ( p s

i g )

4 5 0

4

5 0

—

4 5 0

4 5 0

—

4 5 0

4 5 0

—

C O O L E R





l b )

1 6 3 0

8

6 0

2 4 9 0

1 8 6 5

8 6 0

2 7 2 5

1 6 3 0

1 6 3 0

3 2 6 0

N o


2

2

4

2

2

4

2

2

4


i n c l u d e s n o z z l e s ( g

a l . )

6 1 . 0

3

0 . 3

9 1 . 3

7 0 . 4

3 0 . 3

1 0 0 . 7

6 1 . 0

6 1 . 0

1 2 2 . 0

M a x

W o r k i n g P r e s s u r e R e f r i g e r a n t S i d

e ( p s i g )

2 7 8

2

7 8

—

2 7 8

2 7 8

—

2 7 8

2 7 8

—

M a x

W o r k i n g P r e s s u r e F l u i d S i d e ( p s i g )

3 0 0

3

0 0

—

3 0 0

3 0 0

—

3 0 0

3 0 0

—


. )

V i c t a u l i c T y p e


6

5

—

6

5

—

6

6

—

D r a i n ( N P T )

3 / 4

3 / 4

—

3 / 4

3 / 4

—

3 / 4

3 / 4

—

C u - A l

—

C o p p e r T u b i n g — A l u m i n u m F

i n s C o n d e n s e r C o i l

C u - C u

—

C o p p e r T u b i n g — C o p p e r F i n s C o n d e n s e r C o i l

O D

—


8/20/2019 30GTN GTR

9/94

9

6 0

H z E N G L I S H (

c o n t )

L E G E N D




3 0 G T N , G

T R U N I T

S I Z E

3 6 0

3 9 0

4 2 0

S Y

S T E M M

O D U L E

S

A

B

T o t a l

A

B

T o t a l

A

B

T o t a l

A P P R O X


C u - A l

1 2 , 6

7 6

1 2 , 6 7

6

2 5 , 3

5 2

1 3 , 3

8 0

1 2 , 6

7 6

2 6 , 0

5 6

1 3 , 3

8 0

1 3 , 3

8 0

2 6 , 7

6 0

C u - C u

1 4 , 1

9 5

1 4 , 1 9

5

2 8 , 3

9 0

1 4 , 8

9 9

1 4 , 1

9 5

2 9 , 0

9 4

1 4 , 8

9 9

1 4 , 8

9 9

2 9 , 7

9 8


R - 2 2

C h a r g e ,

T o t a l / O


C k t A

1 7 8 / 3 0

1 7 8 / 3

0

— / —

1 9 0 / 4 0

1 7 8 / 3 0

— / —

1 9 0 / 4 0

1 9 0 / 4 0

— / —

C k t B

1 7 3 / 3 0

1 7 3 / 3

0

— / —

1 8 5 / 4 0

1 7 3 / 3 0

— / —

1 8 5 / 4 0

1 8 5 / 4 0

— / —

C O M P R E

S S O R S



S p e e d ( r p m )

1 7 5 0

0 6 E *

( Q t y ) C k t A

( 1 ) 2 6 5 ,

( 1 ) 2 7 5 ,

( 1 ) 2 9 9 ( 1 ) 2 6 5 ,

( 1 ) 2 7

5 ,

( 1 ) 2 9 9

—

( 3 ) 2 6 5 ,

( 1 ) 2 7 5 ( 1 ) 2 6 5 ,

( 1 ) 2 7 5 ,

( 1 ) 2 9 9

—

(

30gtn gtr

Documents