RefrigerationPrint

Principles of Refrigeration

MAE 554 Professor H. Ezzat Khalifa Syracuse University

P-h Chart for R134a (SI Units)

1

Psychrome Psychrometric tric Chart Chart (ASHRAE) (ASHRAE)

Psychrome Psychrometric tric Processe Processes s

Air Conditioning Systems Cool & Dehumidify Air

Humidify

Cool

Heat

Cool & Dehumidify Dehumidify

2

Psychrome Psychrometric tric Chart Chart (ASHRAE) (ASHRAE)

Psychrome Psychrometric tric Processe Processes s

Air Conditioning Systems Cool & Dehumidify Air

Humidify

Cool

Heat

Cool & Dehumidify Dehumidify

2

A/C System Psychrome Psychrometric tric Processe Processes s

Coil temperature  must be cooler than  room dew point (DP) to dehumidify the air 

Outdoor Air Room DP Coil Inlet Room Return Air

Coil Exit

Room Condition Line

Reversed Carnot Cycle T

TH

TC

s

3

Carnot Cycle Performance 30.0

Sat Cond T, °C 25.0

20.0 30.0 40.0

20.0

50.0 60.0

  c

   P    O 15.0    C

70.0

10.0

5.0

0.0 -40.0

-35.0

-30.0

-25.0

-20.0

-15.0

-10.0

-5.0

0.0

5.0

10.0

Cold-Side Cold-Side Temperature - TC, C

Reversed Carnot Vapor Compression Cycle T

TH

TC

s

4

Reversed Rankine Vapor Compression Cycle T

Superheat Horn  Increased Work 

TH

TC

s

Ideal Practical Vapor Compression Cycle T

Superheat Horn  Increased Work 

TH Throttling Loss  In Work 

TC Throttling Loss  in Refrigeration 

s

5

Simple Vapor Compression Cycle

3

2

4

1

Single-Stage Vapor Compression Cycle P

TSC

PC

PE hWo TSH hE

hW

h

6

Ideal VCC Performance 10

25

R22 Ideal VCC 10 CFM Compressor

8

20

Cond. Sat. Temp., ºC 15    W    k

6

 ,   y    t    i   c   a   p 10   a    C

   C

   P    O    C 4

2

50.0 COP 35.0 Q 50.0 Q

5

0 -40.0

35.0 COP

0 -30.0

-20.0

-10.0

0.0

10.0

Evap. Sat. Temp., C

Comparison of Ideal VCC with Carnot Cycle 1.0

1.0

0.9

0.9

   P    O0.8    C   e   v    i    t   a    l   e 0.7    R

0.8

35.0 50.0 0.7

0.6

0.6

0.5 -40.0

Cond. Sat. Temp., ºC

0.5 -30.0

-20.0

-10.0

0.0

10.0

Evap. Sat. Temp., C

7

P-h Diagram for Real Vapor Compression Cycle P 2d

PD PC

PE PS

3

2

1a 4

1

1b 1c

h

Effect of the Gas Specific Heat Ratio,  γ

8

Two-Stage VCC with Flash Economizer

5

4

3 2

6

7

8

1

P-h Diagram for 2-Stage VCC with Flash Economizer P

TSC

PC PI PE

hW2

5

7

3

4

2

6

8

1

hW1

TSH hE

h

9

Two-Stage VCC with Subcooler Economizer

5

5

4

3 2

6

7

8

1

P-h Diagram for 2-Stage VCC with Subcooler P

PC

TSC

7

3

PI PE

hW2

5

4

2

6

8

1

hW1

TSH hE

h

10

Optimum Intermediate Temperature for 2-Stage VCC 2.4 2.2

COP C 2.0 1.8   r    C

   P    O 1.6    C  ,    C    P 1.4    O    C

COP Cr

1.2 1.0

Geometric-Mean Intermediate

0.8 0.6 -40

-30

-20

-10

0

10

20

30

40

50

Intermediate Sat. Temp., C

Comparison of Two-Stage and Single-Stage VCCs 10

R22 Ideal VCC

8

Cond. Sat. Temp., ºC 35/COP 1

6    C

50/COP 1

   P    O    C

35/COP 2 4

50/COP 2

2

0 -40.0

-30.0

-20.0

-10.0

0.0

10.0

Evap. Sat. Temp., C

11

Performance of Multi-stage VCCs 1.8

1.6

R22 Ideal VCC

1.4

  y    t    i   a 1.2   p   a    C    d   n 1.0   a

Rel. COP Rel. Capacity

   C

   P    O 0.8    C   e   v    i    t   a 0.6    l   e    R 0.4

0.2

0.0 1

2

3

4

Number of Stages

Cascade System

High-Temperature Refrigerant

Low-Temperature Refrigerant

12

Desirable Characteristics of Refrigerants • • • • •

Thermally stable Safe (toxicity and flammability) Low cost and widely available Compatible with materials of construction High performance  –  –  –  –

High latent heat Low compression superheat Low throttling losses High heat transfer properties

• Environmentally benign (ODP and GWP)

Refrigerant Classification Refrigerants

Pure

Mixtures

Natural

CFC

HCFC

HFC

Zeotropes

Azeotropes

Ammonia

R12

R22

R134a

R407C

R502

Propane

R114

R123

R32

R290-R600a

R507

Iso-Butane

R11

R125

Propane/Iso-Butane

R410A*

CO2

R143a

R404A* *Near-Azeotropes

Used in or considered for Refrigeration

13

Mixture Phase Diagrams P2

  e   r   u    t   a   r   e   p   m   e    T  .    t   a    S

P1 Tsat

Liquid Mole-Fraction 0.0

0.1

0.2

Vapor Mole-Fraction 0.3

0.4

0.5

0.6

0.7

0.8

0.9

1.0

Mole Fraction, x

Mixture Phase Diagrams P2

  e   r   u    t   a   r   e   p   m   e    T  .    t   a    S

P1 Tsat

Liquid Mole-Fraction 0.0

0.1

0.2

Azeotrope 0.3

0.4

0.5

Vapor Mole-Fraction 0.6

0.7

0.8

0.9

1.0

Mole Fraction, x

14

NIST Refrigerant Properties

ASHRAE Refrigerant Safety Classification

No Flammability

Low Flammability

High Flammability

Low/No Toxicity

High Toxicity

A1

B1

R11, R12, R22, R125, R134a, R407C, R507, R404A, R410A, R744

R123, R764, R21

A2

B2

R32, R142b, R143a, R152a

NH3

A3

B3

R170, R290, R600a, R1150

R1140

Refrigerants marked in Red are ozone depleting substances that are no longer  used in new equipment. Refrigerants marked in Green are natural refrigerants that have low GWP, as well as no ODP.

15

Refrigerants: Methane Group

Refrigerants: Ethane Group

16

ODP and GWP for Various Refrigerants Refrigerant

ODP

GWP

Refrigerant

ODP

GWP

CFC-11 CFC-12 CFC-13 HCFC-22 HFC-23 HFC-32 CFC-113 CFC-114 HCFC-123 HCFC-123a HCFC-124

1.0 1.0 N/A 0.051 0.0 0.0 0.87 0.74 0.016 0.016 0.018

1.0 3.05 N/A 0.370 N/A 0.130 1.300 4.150 0.019 0.019 0.095

HFC-125 HFC-134 HFC-134a HFC-143a HFC-152a R500 R502 R503 R410A R507

0.0 0.0 0.0 0.0 0.0 0.78 0.245 N/A 0.0 0.0

0.84 0.25 0.25 1.2 0.029 2.39 5.10 N/A 0.49 0.96

ODP (Ozone Depletion Potential), and GWP (Greenhouse Warming Potential) are  calculated relative to CFC R11.

Refrigerant Comparison

Refrigerant

CO2

R12

R22

R134a

R404A

R410A

C3H8

NH3

Natural?

Yes

No

No

No

No

No

Yes

Yes

Flammable?

No

No

No

No

No

No

Yes

Yes

Toxic?

No

No

No

No

No

No

No

Yes

Relative Cost

0.1

-

(1.0)

4.0

5.0

5.0

0.3

0.2

Volum. Capacity

4.8

0.6

(1.0)

0.7

1.2

1.5

0.9

1.0

Critical Temp.(F)

88

234

205

214

163

158

206

270

P @ 70F (psia)

852

85

136

86

165

216

125

129

ODP

0

1.0

0.05

0

0

0

0

0

(1.0)

7100

1500

1300

3750

1730

3

0

GWP (100yr)

(1.0) means reference value

17

Refrigerant Pressure-Capacity Relationship 1.0

  m    f   c    /   n   o    T    [    I    R    A    @   y    t    i   c   a   p   a    C   c    i   r    t   e   m   u    l   o    V

R22 & its near neighbors

0.8

Best Fit R123 R11 R245fa R114 R600a R12 R134a R290 R22 R407C R717 R507 R410A

R410A

NH3

0.6

R22 R404A/R507

Propane

R407C

0.4 R134a

0.2

0.0 0

100

200

300

400

500

Pressure Difference @ ARI [psi]

Comparison of Simple Cycle EER 1.10

 EER Relative to R22

1.05

1.00 ARI 0.95 CHEER 0.90

0.85

0.80 R22

R134a

R290

R407C

R507

R410A

18

Relative ARI Capacity [Same Displacement] 2.0

Capacity relative to R22

1.5

1.0

0.5

0.0

Relative Compressor Displacement [Same Capacity] 3.0

 Displacement relative to R22

2.5

2.0

1.5

1.0

0.5

0.0

19

Low Temperature Capacity Comparison 1.0    I    R    A   o    t   e   v    i    t   a    l   e    R   y    t    i   c   a   p   a    C

R22 R507 R134a R410A

0.1 -50 -40 -30 -20 -10

0

10

20

30

40

50

Saturated Evaporator Tem perature [F] SCT=130F; SH=20F; SC=15F; No LSHX; No Quench 

Low Temperature EER Comparison 1.0    I    R    A    @    2    2    R   o    t   e   v    i    t   a    l   e    R    R    E    E

R22 R507 R134a R410A

0.1 -50 -40 -30 -20 -10

0

10

20

30

40

50

Saturated Evaporator Tem perature [F] SCT=130F; SH=20F; SC=15F; No LSHX; No Quench 

20

Discharge Superheat Comparison 300 250    ]    F    [   r   a 200   e    h   r   e   o   u    S 150   e   g   r   a    h 100   c   s    i    D 50

R22 R507 R134a R410A

0 -50 -40 -30 -20 -10

0

10

20

30

40

50

Saturated Evaporator Temperature [F] SCT=130F; SH=20F; SC=15F; No LSHX; No Quench 

Total Equivalent Warming Impact (TEWI)

Medium Temperature Refrigeration From DoE's ORNL Report, 1997

21

Fluid Comparison - R134a vs. R744 (CO 2) R134a

R744 (CO2)

Region of Operational Interest

Region of Operationa l Interest

Critical Point Low Pressure High Pressure

R134a 214 F 10-50 psi 100-250 psi

R744 88 F 110 - 500 psi 750-2000 psi

Other CO2 Properties: High throttling losses Solid CO2 (Dry Ice) at -80F (70 psi) Transcritical Cycle (typical) Much Higher heat transfer potential (2-3x) Temperature ‘glide’ on heat rejection HX

Refrigerant-Lubricant Viscosity

22

Vapor Compressors

Classification of Vapor Compressors Positive Displacement Machines [PD]: • Reciprocating Piston, Rolling Piston, Scroll, Screw, Sliding Vane … Rotodynamic (Turbo) Machines [RD]: • Radial, Mixed-flow Centrifugal; Single and Multi-stage

23

Positive Displacement Vapor Compressors

Compressor Application Range Centrifugal [HVAC] 

Screw [HVAC] 

SH Recip [HVAC] 

H Recip [HVAC] 

Scroll [HVAC] 

Rotary [HVAC] 

0.1

1.0

10.0

100.0

1000.0

10000.0

ARI Capacity, Tons

24

Positive Displacement Compressors

Piston (Reciprocating)

25

Comparison of P-V Diagrams Clearance Volume 

     e      r     u      s      s      e      r       P

Up to 60%  More Capacity  Recip. Refrig. Recip. AC  Scroll/Screw (AC & Refrig.)

Volume Displacement 

Piston Compressor Volumetric Efficiency 1.0

n = 1.15

  y   c 0.8   n   e    i   c    i    f    f    E   c    i   r 0.6   e    t   e   m   u    l   o    V 0.4    l   a   c    i    t   e   r   o   e    h 0.2    T

C 0.000 0.010 0.015 0.020 0.030 0.050 0.070 0.100

0.0 0

10

20

30

40

50

60

Pressure Ratio

26

Rolling Piston (Rotary) Compressor Pump

Typical Rolling Piston Compressor

ASHRAE Handbook of Systems and Equipment, 2004

27

Hermetic Scroll Compressor

Scroll Compressor

28

Scroll Compressor Operation

Scroll Operation (DTU)

Typical Scroll Compressor Performance

ASHRAE Handbook of Systems and Equipment, 2004

29

Twin Screw (Lysholm) Compressor

Single Screw Compressor

ASHRAE Handbook of Systems and Equipment, 2004

30

Typical Screw Compressor Performance

ASHRAE Handbook of Systems and Equipment, 2004

Over/Under-compression Loss 100%

  s   s   o    L   n   o    i   s   s   e   r   p   m   o   c     r   e    d   n    U    /   r   e   v    O   e   g   a    t   n   e   c   r   e    P

80%

VR Under-compression

60%

3.0 3.5 4.0 5.0 6.0

40%

20%

0% 0.0

1.0

2.0

3.0

4.0

5.0

Relative Di scharge Pressure (P d/Pd*)

31

Screw Compressors Efficiency Improvement 2.0

1.0

1.8

Close Close leakage leakage gaps gaps & & reduce reduce oil oil injection  injection 

0.9

1.6

0.8

1.4

0.7   n

  s   s   o 1.2    L   e   v 1.0    i    t   a    l 0.8   e    R

Pump Efficiency

  y   c

  e    i

  c 0.6    i    f    f

0.5    E 0.4 Leakage Losses

0.6

Flow & Viscous Losses

0.3

0.4

0.2

0.2

0.1

0.0

0.0 0

10

20

30

40

50

60

70

80

  c    i   p   o   r    t   n   e   s    I

90

Male Rotor Tip Spe ed [m/s]

Sliding Vane Compressor

32

Centrifugal Compressors

Centrifugal Compressor

33

Typical Centrifugal Compressor Impeller

ASHRAE Handbook of Systems and Equipment, 2004

Ns-Ds Diagram for Single-Stage Compressors From O. E. Balje: Turbomachines - A Guide to Design Selection and Theory, Wiley, NY, '81

34

2-Stage Centrifugal Compressor

ASHRAE Handbook of Systems and Equipment, 2004

Polytropic Efficiency 0.850 0.848

p

= 0.85;

= 1.1

0.846

  y 0.844   c   n   e 0.842    i   c    i    f    f    E 0.840   c    i   p   o   r 0.838    t   n   e   s 0.836    I 0.834 0.832 0.830 1.0

2.0

3.0

4.0

5.0

6.0

7.0

8.0

9.0

10.0

Pressure Ratio

35

Typical Centrifugal Compressor Performance

Variable-Speed Control

IGV Control – Fixed Speed

ASHRAE Handbook of Systems and Equipment, 2004

Centrifugal Chiller Part-Load Performance

ASHRAE Handbook of Systems and Equipment, 2004

36

Comparison of Chiller Compressors

ASHRAE Handbook of Systems and Equipment, 2004

Expansion Devices

37

Short Restrictor Expansion Device

ASHRAE Handbook of Refrigeration, 2004

Thermostatic Expansion Valve

ASHRAE Handbook of Refrigeration, 2004

38

Constant-Pressure Expansion Valve

ASHRAE Handbook of Refrigeration, 2004

Float-controlled Expansion Valve

ASHRAE Handbook of Refrigeration, 2004

39

Thermally Activated Heat Pump Concept

ASHRAE Handbook of Refrigeration, 2004

Single-Effect LiBr-H2O Absorption Cycle Condenser

Generator 4"

6

3

4'

Solution HX

Pump 7

2

5

1

Evaporator

Absorber

40

Practical Configuration of LiBr-H 2O System

ASHRAE Handbook of Refrigeration, 2004

Mixture Phase Diagrams P2

  e   r   u    t   a   r   e   p   m   e    T  .    t   a    S

P1 Tsat

Liquid Mole-Fraction 0.0

0.1

0.2

Vapor Mole-Fraction 0.3

0.4

0.5

0.6

0.7

0.8

0.9

1.0

Mole Fraction, x

41

Single-Effect LiBr-H2O Cycle Duhring Diagram P 6

PC

Pure H2O; x=0

3

x=xw

4', 4"

x=xs

Crystallization  PE

1, 7

2

TE

TC~TA

5

TG

T

Double-Effect LiBr-H 2O Absorption Cycle [1] Condenser

4"

Generator 2 8

9

Generator 1 6

4'

7"

7'

3'

6

3

Solution HX

Solution HX

Pump 5

10

Pump

2

8

4

1

Evaporator

Absorber 3'

42

Double-Effect LiBr-H2O Absorption Cycle [2] Condenser

Generator 1

Generator 2 8'

8

4"

10

3'

3

4'

9"

4 5

9'

Solution HX 6

Pump 12

2

6'

1

Evaporator

Absorber

Single-Effect LiBr-H2O Cycle Duhring Diagram P 7

PC

Pure H2O; x=0

3

x=xw

4, 6

x=xs

Crystallization  PE

1, 8

2

TE

TC~TA

5

TG

T

43

Pumpless Aqua-Ammonia System

Bubble Pump

ASHRAE Handbook of Refrigeration, 2004

Simple and Regenerative Reversed Brayton Cycle T 2

2

3

3

1

4 6, 1 5 S

44

Regenerative Air Cycle Ambient air Recuperator

Gas Cooler

Power

Exp.

Comp.

Conditioned Space

Simple Air Cycle Performance 0.6

Load Temp. ºC

0.5

22.0 12.0 0.4

2.0 -8.0

   P    O0.3    C

-18.0 -38.0 -58.0 -78.0

0.2

-98.0 -118.0 0.1

0.0 1.0

2.0

3.0

4.0

5.0

6.0

7.0

8.0

9.0

10.0

Expander Pressure Ratio

Ta = 35 ºC; ε R  = 0.9; η′ E = 0.88; η′ C  = 0.87; δ P/P = 0.05; ΔT A = 10 ºC 

45

Regenerative Air Cycle Performance 0.6

Load Temp. ºC

0.5

22.0 12.0 0.4

2.0 -8.0

   P    O0.3    C

-18.0 -38.0 -58.0 -78.0

0.2

-98.0 -118.0 0.1

0.0 1.0

2.0

3.0

4.0

5.0

6.0

Expander Pressure Ratio

Ta = 35 ºC; ε R  = 0.9; η′ E = 0.88; η′ C  = 0.87; δ P/P = 0.05; ΔT A = 10 ºC 

Comparison of Air Liquefaction Cycles 12000

10000

  r 8000    i    A    d    i   u   q 6000    i    L   g    k    /    J    k 4000

2000

0 Revrsible (Ideal)

Linde

Linde + VC Precooler (-45 C)

DualPressure Linde

DualPressure Linde + VC Precooler

Claude

46