Lec 10-11 - Refrigeration cycle
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Thermodynamics II course taught at air university Islamabad by Sijal Ahmed Vapor compression cycle : Heat pump and refrigeration.
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Lec 10-11 - Refrigeration cycle
- 1. THERMODYNAMICS II LECTURE 10-11 VAPOR COMPRESSION CYCLE (VCR) 1
- 2. Contents • Introduction • Heat pump and refrigeration cycle • Vapor compression cycle • Solved example and home work • Refrigerants 2
- 3. Introduction • Refrigeration : Transfer of heat from lower temperature to higher temperature • Heat pump : Transfer of heat from lower temperature to higher temperature! • Well known cycle is vapour compression cycle, in which the refrigerant (working fluid) is vaporized and condensed alternatively, and is compressed in vapor phase • Performance is measured using coefficient of performance (COP) 3
- 4. Introduction • Because, we are just transferring the energy from one place to another, so we need less energy to accomplish the task of refrigeration or heat pump. • Ideal vapor compression cycle dates back to 1834 by Jacob Perkins 4
- 5. Refrigerators and Heat Pumps • Heat flows from high temperature to lower temperature, reverse is possible with the help of external device • Working fluid is refrigerant • Heat pump and refrigerators are same devices, only difference is objective • at worst heat pumps = resistance heaters 5
- 6. Refrigerators and Heat Pumps 6 R = Refrigeration HP = Heat Pump
- 7. Refrigerators and Heat Pumps • Cooling capacity is measured in tons of refrigeration • 1 ton = can freeze 1 ton of liquid water at 0 oC into ice at 0 oC in 24 h • 1 ton = 211 KJ/min (3.5 kW) or 200 Btu/min (12000 Btu/h) • Cooling load of typical 200-m2 is 3 ton (~ 10 KW) 7
- 9. Ideal Vapor Compression Cycle 9
- 10. Ideal Vapor Compression Cycle 10 Non Ideal process, enthalpy is constant
- 11. Ideal Vapor Compression Cycle • Steady flow energy equation (SFEE) 11
- 15. Solved Example (Heat Pump) 15 Example: A vapor-compression heat pump cycle with R-134a as the working fluid maintains a building at 20oC when the outside temperature is 5oC. The refrigerant mass flow rate is 0.086 kg/s. Additional steady state operating data are provided in the table. Determine the (a) compressor power, in kW, (b) heat transfer rate provided to the building, in kW, (c) coefficient of performance. TC = 278 K (5oC)TH = 293 K (20oC) TC = 278 K (5oC)TH = 293 K (20oC) State h (kJ/kg) 1 244.1 2 272.0 3 93.4
- 16. Solved Example (Heat Pump) 16 (a) The compressor power is )( 12c hhmW kJ/s1 kW1 kg kJ )1.2440.272( s kg 086.0cW 2.4 kW (b) The heat transfer rate provided to the building is )( 32out hhmQ kJ/s1 kW1 kg kJ )4.930.272( s kg 086.0outQ 15.4 kW State h (kJ/kg) 1 244.1 2 272.0 3 93.4 TC = 278 K (5oC)TH = 293 K (20oC) TC = 278 K (5oC)TH = 293 K (20oC)
- 17. Solved Example (Heat Pump) 17 State h (kJ/kg) 1 244.1 2 272.0 3 93.4 TC = 278 K (5oC)TH = 293 K (20oC) TC = 278 K (5oC)TH = 293 K (20oC) (c) The coefficient of performance is c out W Q COP kW.42 kW5.41 COP 6.4 Comment: Applying Eq. 10.9, the maximum theoretical coefficient of performance of any heat pump cycle operating between cold and hot regions at TC and TH, respectively is K872K932 K932 maxCOP 19.5
- 19. Home Work 19
- 20. Home Work 20
- 21. Refrigerants 21 Most refrigerants are halogenated hydrocarbons. The naming convention adopted by ASHRAE is, R(a-1)(b+1)d = CaHbClcFd c = 2(a – 1) – b – d 1 0 1 1 2 1 2 2 1 2 1 1 1 2 1 a a b b d c a b d c Example: R22 (R022) C H F Cl F chlorodifluoromethane
- 22. Refrigerants • Refrigerant selection is based on several factors: ►Performance: provides adequate cooling capacity cost-effectively. ►Safety: avoids hazards (i.e., toxicity). ►Environmental impact: minimizes harm to stratospheric ozone layer and reduces negative impact to global climate change. • Global warning potential is based on Co2 (GWP = 1) 22
- 23. Refrigerant Types and Characteristics 23 Global Warming Potential (GWP) is a simplified index that estimates the potential future influence on global warming associated with different gases when released to the atmosphere.