EWS CTO SEP 2012

Simon Ho – IR CS ANZ 1

EarthWise HVAC

Chiller – Tower Systems

Simon Ho (IR CS ANZ)e: Simon.Ho@irco.com

2012

HIGH PERFORMANCE CHILLED WATER SYSTEMS

2

EarthWise Menu

• Low Flow Low Temperature Systems

• Variable Flow Systems

– Variable CHW

– Variable CDW

• Chillers Piping Configurations

• Chiller Tower Optimization

• Free Cooling

• Heat Recovery

• Ice Thermal Storage

• Advanced Air Systems

EWS CTO SEP 2012

Simon Ho – IR CS ANZ 2

3

• Chiller efficiency have seen good improvements

– Minimum code requirements: MEPS compliant

– AHRI or Eurovent certified; assurance of performance

• CHW Plant Ancillaries

– CHW and CDW pumps: low flow, variable flow

– Cooling Tower performance: CTI certified

• CHW Plant System Efficiency [COP] defined by:

– Total Power Input includes power input of chillers and ancillaries

CHW Plant Efficiency

COOLING CAPACITY [kW]

TOTAL POWER INPUT [kW]

4

CHW Plant Efficiency Scale

Source: Thomas Hartman, 2001

EWS CTO SEP 2012

Simon Ho – IR CS ANZ 3

5

OPTIMIZING HEAT REJECTION CHILLER – TOWER SYSTEMS

6

Cooling Towers in HVAC Preliminaries

• Sizing vs performance

– Balance cost vs performance

– Economizing in cooler climates

• Design conditions

– Design WB and tower water temps

– What’s the correct approach temperature ? 3 to 9K !?

– Standard rating conditions 29.5ºC with 5.5K range may not be optimal !

• Operational efficiency

– How do I control to best system efficiency ?

EWS CTO SEP 2012

Simon Ho – IR CS ANZ 4

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Chiller – Tower Key Parameters

�Cooling Load

�Condenser watertemperature

�Chiller design –fixed or vary speed

�Wet-bulb

�Condenser watertemperature

�Heat Rejection Load

�Tower Design

CH

CT

8

Condenser water controlAt Part Load

• Warm or Hot ?

– 26 to 29ºC minimizes tower fan power, increases chiller power

– Works well with older equipment requiring higher lift

• Cold ?

– 15 to 18ºC or less minimizes chiller power, increases tower fan power

– Efficient chiller operation but what about the overall system ?

• Wet-bulb + 3K approach ?

– Assumption that Load ∝ WB ... Tends to drives to coldest

– Approach is NOT fixed at part load

• Optimized ?

– Dynamic reset based on load & ambient to minimize overall system energy

EWS CTO SEP 2012

Simon Ho – IR CS ANZ 5

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Tower Control

• On/Off

• Two-speed fan

• VSD/VFD

• Tower performance ∝ φ(WB, Load, Fan speed, Flow)

• Optimization involves multi-dimensional sub-system

that must be integrated with chiller performance as a

system

– Manual / trial and error or,

– Dynamic monitoring and reset optimization

� Predictive

� Dynamic feedback

10

Tower fan power

FAN SPEED

% F

AN

kW

100%50%

100%

50%

0%

ON/OFF

2-SPEED

VFD

EWS CTO SEP 2012

Simon Ho – IR CS ANZ 6

11

CT performance: Load & WB

10

15

20

25

30

35

5 10 15 20 25 30

100% Load

75% Load

50% Load

25% Load

WET BULB, °C

CO

LD

WA

TE

R, °C

Note: Cooling tower with constant flow and 100% fan speed, 4K design approach

12

CT performance: WB & Fan Speed

0

5

10

15

20

25

30

35

40

30% 40% 50% 60% 70% 80% 90% 100%

26 CWB

20 CWB

14 CWB

10 CWB

Fan kW

Note: Cooling tower with constant flow and 50% load

CO

LD

WA

TE

R, °C

FA

N k

W

FAN SPEED

EWS CTO SEP 2012

Simon Ho – IR CS ANZ 7

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Cooling Load & WB

LD

WB

Design Load

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Chiller – Tower Optimization (CTO)Concept

condenser water temperature, °C

19

en

erg

y c

on

su

mp

tio

n, k

W

21 23 25 27170

29

tower

chiller

total

optimalcontrol point

Note: Chiller at part load and low ambient WB

EWS CTO SEP 2012

Simon Ho – IR CS ANZ 8

15

Chiller – Tower Parametric Study

• Chiller matched to cooling tower at fixed design flow

rate, 54 L/s/MW

• Cooling tower selected at 4K approach to WB

• Compare chillers with fixed speed and variable speed

drive (AFD)

• CT with variable speed fan motor

• Part load analysis (75%, 50% and 25% loads) at

varying WB (20°C, 17°C, 14°C, 10°C)

• Observe equipment temperature limits

– Min CT temperature to maintain lift

– Max CT temperature to avoid surge

• Assess overall power input of heat rejection system

16

High Load, High WB75% Load, 20°CWB

CT Cold Basin, °C

Po

wer

Inp

ut,

kW

0

20

40

60

80

100

120

140

160

180

200

20 22 24 26 28 30

CT kW

CH AFD kW

Total

CH non-AFD kW

Total

EWS CTO SEP 2012

Simon Ho – IR CS ANZ 9

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High Load, Low WB75% Load, 14°CWB

CT Cold Basin, °C

Po

wer

Inp

ut,

kW

0

20

40

60

80

100

120

140

160

180

200

14 19 24 29

CT kW

CH AFD kW

Total

CH non-AFD kW

Total

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Low Load, High WB25% Load, 20°CWB

CT Cold Basin, °C

Po

wer

Inp

ut,

kW

0

10

20

30

40

50

60

70

80

90

100

20 22 24 26 28 30

CT kW

CH AFD kW

Total

CH non-AFD kW

Total

EWS CTO SEP 2012

Simon Ho – IR CS ANZ 10

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Low Load, Low WB25% Load, 14°CWB

CT Cold Basin, °C

Po

wer

Inp

ut,

kW

0

10

20

30

40

50

60

70

80

90

14 16 18 20 22 24

CT kW

CH AFD kW

Total

CH non-AFD kW

Total

20

Low Load, Low WB25% Load, 10°CWB

CT Cold Basin, °C

Po

wer

Inp

ut,

kW

0

10

20

30

40

50

60

70

80

90

10 12 14 16 18 20 22 24

CT kW

CH AFD kW

Total

CH non-AFD kW

Total

EWS CTO SEP 2012

Simon Ho – IR CS ANZ 11

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Chiller – Tower Optimization (CTO)

• At part load neither the coldest or warmest tower

water is best for overall efficiency

• “Near optimal point” a moving target

• Fixed flows and single system

– Trend towards colder water when loads are high and warmer water when loads are low

– Plant configuration and climatic condition dependent

• Need to consider chiller equipment

– Constant or vari-speed

– Equipment limits

22

CTO - Necessities

• System Level Controls

– Knowledge of chiller performance at various loads and ambient; know chiller limits

– Tower fan power characteristics

– Pump motor power characteristics if variable flow

– Drives tower fans to “near optimal CT set point”

• VFD on tower fan motors

• Good quality ambient RH sensor

• Commissioning M&V

TRACER

SYSTEM LEVEL

CONTROLS

EWS CTO SEP 2012

Simon Ho – IR CS ANZ 12

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System Options and Analysis

• No one size fits all

– There is a trend of lower operating costs with chiller-tower optimization

• Need comprehensive analysis, not spreadsheet

24

CTO comparisons

-

200,000

400,000

600,000

800,000

1,000,000

1,200,000

15C 18C 20C 22C 25C CTO

Towers

Pumps

Chillers

CT Minimum Temp Set Point [ºC]

CH

W P

lan

t A

nn

ual

En

erg

y C

on

s [

kW

h]

Sydney Commercial Office Application; BCA Class 5 schedules

2,200 kW cooling, water-cooled screw chillers, VAV, Econ cycle,

~ 6%

2 2 –– 3 yr 3 yr paybackpayback40% ROI40% ROI

EWS CTO SEP 2012

Simon Ho – IR CS ANZ 13

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Chiller – Tower Optimization

TRACER

SYSTEM LEVEL

CONTROLS

TRH

FF

FF

TT

26

HVAC Systems Heat-Cool

MECHANICAL COOLINGMECHANICAL COOLING

35251505

EVAPEVAP COOLINGCOOLING

AIRSIDEAIRSIDE ECONECON

CT PL HXCT PL HX

FC CHLRFC CHLR

EE--A HEAT RECA HEAT REC

CHILLER HEAT RECCHILLER HEAT REC

Ambient Temperature ºCAmbient Temperature ºC

COOLING CALLCOOLING CALL

GAS HEATGAS HEAT

HEATING CALLHEATING CALL

•• Minimize activeMinimize activecooling & cooling & heatingheating

•• HeatHeat RecoveryRecovery•• FreeFree CoolingCooling

EE--A HEAT RECA HEAT REC

EWS CTO SEP 2012

Simon Ho – IR CS ANZ 14

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Waterside Free Cooling

• Waterside free cooling is the cooling of supply air

indirectly with water which is itself cooled by the

environmental heat sink without mechanical cooling

• When CT water temperature is cool enough, it can be

used to minimize or switch OFF mechanical cooling

– Strainer Cycle

– Air-cooled free cooling chiller

– Plate and Frame HX with CT

– Water-cooled free cooling chiller (refrigerant migration)

28

Waterside Plate and Frame

• Sizing of CT to design WB

– Close approach at low loads and low WB

• Piping options

– “Side car” on the distribution side of CHW loop to supplement cooling; sees warmest return water

– Parallel on distribution or production side; “all or nothing”

• HX sized 2 to 3K approach to

tower water

• Maintenance

(to CT)

LOADLOAD

EWS CTO SEP 2012

Simon Ho – IR CS ANZ 15

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Free Cooling WC Chiller

refrigerantvapor

gravity fed liquid refrigerant

compressor

economizereconomizer

evaporatorevaporator

condensercondenser

• Refrigerant migration cycle

– Operates when CT water is cool enough; e.g. less than 13ºC

– 45 to 60% design capacity with CHW reset

– Minimizes reheat

• No change in CHW pipe work

• No additional maintenance

• Available with centrifugal chillers > 700kW

30

Free Cooling Chiller

Free Cooling valves

EWS CTO SEP 2012

Simon Ho – IR CS ANZ 16

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Free-cooling Chiller1MW chiller (FC mode)

Capacity [kW]

1.7°C 4.4°C 7.2°C 10°C

545 6.3/10.1 9.0/12.8 11.7/15.5 14.4/18.2

408 5.3/8.1 8.0/10.8 10.7/13.6 13.4/16.3

271 4.2/6.1 7.0/8.9 9.7/11.6 15.2/17.1

134 3.1/4.0 5.9/6.8 8.6/9.6 14.2/15.1

7.0/8.97.0/8.9 Supply/return CHW temp, °C

No CHW reset CHW reset, trim chiller or warm CHW applications

32

EarthWise Free Cooling

LOADLOAD

• Parallel piping

• Switchover

free cooling /

mechanical

cooling

• Mixing issue – “all or

nothing”

EWS CTO SEP 2012

Simon Ho – IR CS ANZ 17

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EarthWise Free Cooling

• “Sidecar” piping resolves

mixing issue

• Supplement to cooling

chillers

• CT may be dedicated to

free cooling chiller for cold

climate operation

Free cooling chiller

34

EarthWise Free Cooling

• Series CHW piping takes advantage of low flow CHW system efficiency

• Supplement to cooling chillers; electric trim chiller

• CT may be dedicated to free cooling chiller for cold

climate operation

6oC17oC

CHWP

CDWP

Free Cooling

Centrifugal

Conventional

non-FC Chiller

EWS CTO SEP 2012

Simon Ho – IR CS ANZ 18

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EarthWise Free Cooling Controls

TRACER

SYSTEM LEVEL

CONTROLS

FF

TT

TT

TT RR

• System Level integration of controls ensures

optimal control and efficiency

TTTT