Abstract
The current energy generation and utilization patterns can directly lead to considerable wasted energy either at medium or high availabilities. For example, power plants utilize the high-grade portion of fossil-derived energy and reject a large amount of medium-grade thermal energy. Meanwhile, these fossil fuels are also used more ubiquitously in residential water heaters, in which almost all of the high-grade thermal availability is wasted, with the water being heated to a relatively low 60 °C. With energy consumption having been accordingly increased, energy conservation becomes increasingly essential. Vapor compression refrigeration technology has dominated in refrigeration field because of its simple in structure and satisfactory performance, while vapor compression refrigeration consumes power and its working fluids (CFCs, HCFC, HFC) usually have high ODP or GWP. Compared to compression refrigeration, thermally activated refrigeration technologies can utilize low-grade heat, such as solar energy heat and waste heat from the production process. Furthermore, it can use natural refrigerants, such as H2O and NH3. As an important way of energy conservation, thermally activated refrigeration technologies have attracted more attention in recent years. A detailed analysis is made on the thermally activated refrigeration technologies in this chapter, including vapor absorption refrigeration, adsorption refrigeration, and vapor ejector expansion refrigeration. Specifically, the working principles of various refrigeration cycles, the development and classification, research interests as well as the advantages and disadvantages of these refrigeration cycles in recycling low-grade heat are talked about.
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References
Little AB, Garimella S (2009) Comparative assessment of alternative cycles for waste heat recovery and upgrade. Energy 36(7):4492–4504
Erickson DC (2007) Extending the boundaries of ammonia absorption chillers. Am Soc Heat Refrigerat Air Cond Eng 49(4):32–35
Iversen SB et al (1997) Characterization of microporous membranes for use in membrane contactors. J Membr Sci 130(1–2):205–217
Asfand F, Bourouis M (2015) A review of membrane contactors applied in absorption refrigeration systems. Renew Sustain Energy Rev 45:173–191
Perez-Blanco H (1984) Absorption heat pump performance for different types of solutions. Int J Refrig 7(2):115–122
Fong KF et al (2011) Solar hybrid cooling system for high-tech offices in subtropical climate – radiant cooling by absorption refrigeration and desiccant dehumidification. Energy Conv Manag 52(8–9):2883–2894
Kong X (2011) Combined cooling heat and power. National Defence Industry Press, Beijing, p 240
Wang SG, Wang RZ (2005) Recent developments of refrigeration technology in fishing vessels. Renew Energy 30(4):589–600
Fernández-Seara J, Vales A, Vázquez M (1998) Heat recovery system to power an onboard NH 3 -H 2 O absorption refrigeration plant in trawler chiller fishing vessels. Appl Therm Eng 18(12):1189–1205
Salmi W et al (2017) Using waste heat of ship as energy source for an absorption refrigeration system. Appl Therm Eng
Wang DC et al (2010) A review on adsorption refrigeration technology and adsorption deterioration in physical adsorption systems. Renew Sustain Energy Rev 14(1):344–353
Wang LW, Wang RZ, Oliveira RG (2009) A review on adsorption working pairs for refrigeration. Renew Sustain Energy Rev 13(3):518–534
Ullah KR et al (2013) A review of solar thermal refrigeration and cooling methods. Renew Sustain Energy Rev 24(10):499–513
Askalany AA et al (2013) An overview on adsorption pairs for cooling. Renew Sustain Energy Rev 19(1):565–572
Ron M (1984) A hydrogen heat pump as a bus air conditioner. J Less Common Metal 104(2):259–278
Saha BB et al (2007) Study on an activated carbon fiber–ethanol adsorption chiller: part I – system description and modelling. Int J Refrig 30(1):86–95
Oosumi Y (1991) The characteristics and application of metal hydrides. Publishing House of Chemical Industry, Beijing
T, K (1991) Metal oxides and their catalysis. Publishing House of Chemical Industry, China
Kato Y et al (2001) Thermal analysis of a magnesium oxide/water chemical heat pump for cogeneration. Appl Therm Eng 21(10):1067–1081
Kato Y, Sasaki Y, Yoshizawa Y (2005) Magnesium oxide/water chemical heat pump to enhance energy utilization of a cogeneration system. Energy 30(11–12):2144–2155
Wang D et al (2014) Progress in silica gel–water adsorption refrigeration technology. Renew Sustain Energy Rev 30(6):85–104
Chang WS, Wang CC, Shieh CC (2007) Experimental study of a solid adsorption cooling system using flat-tube heat exchangers as adsorption bed. Appl Therm Eng 27(13):2195–2199
Boelman EC, Saha BB, Kashiwagi T (1995) Computer simulation of a silica gel-water adsorption refrigeration cycle – the influence of operating conditions on cooling output and COP. ASHRAE Trans 101:358–366
Green adsorption chiller. Available from: http://www.greenchiller.biz/homeofgreenchiller.html
Liu YL, Wang RZ, Xia ZZ (2005) Experimental study on a continuous adsorption water chiller with novel design. Int J Refrig 28(2):218–230
Núñez T, Mittelbach W, Henning HM (2007) Development of an adsorption chiller and heat pump for domestic heating and air-conditioning applications. Appl Therm Eng 27(13):2205–2212
Wang DC et al (2005) Study of a novel silica gel–water adsorption chiller. Part I. Design and performance prediction. Int J Refrig 28(7):1073–1083
Wang DC et al (2005) Study of a novel silica gel–water adsorption chiller. Part II. Experimental study. Int J Refrig 28(7):1084–1091
Wang DC et al (2007) Experimental research on novel adsorption chiller driven by low grade heat source. Energy Conv Manag 48(8):2375–2381
Wang RZ, Keletigui D, Wang DC (2006) Research on a compact adsorption room air conditioner. Energy Conv Manag 47(15):2167–2177
Chen CJ et al (2010) Study on a silica gel–water adsorption chiller integrated with a closed wet cooling tower. Int J Therm Sci 49(3):611–620
Chen CJ et al (2010) Study on a compact silica gel–water adsorption chiller without vacuum valves: design and experimental study. Appl Energy 87(8):2673–2681
Lu ZS et al (2011) An analysis of the performance of a novel solar silica gel–water adsorption air conditioning. Appl Therm Eng 31(17–18):3636–3642
Saha BB, Akisawa A, Kashiwagi T (2001) Solar/waste heat driven two-stage adsorption chiller: the prototype. Renew Energy 23(1):93–101
Saha BB et al (2006) Study on a dual-mode, multi-stage, multi-bed regenerative adsorption chiller. Renew Energy 31(13):2076–2090
Wang SG et al (2003) Experimental results and analysis for adsorption ice-making system with consolidated adsorbent. Adsorption 9(4):349–358
Wang RZ (2001) Performance improvement of adsorption cooling by heat and mass recovery operation. Int J Refrig 24(7):602–611
Shu G et al (2013) A review of waste heat recovery on two-stroke IC engine aboard ships. Renew Sustain Energy Rev 19(1):385–401
Cao T et al (2015) Performance investigation of engine waste heat powered absorption cycle cooling system for shipboard applications. Appl Therm Eng 90:820–830
Kong XQ et al (2008) Experimental investigation of a micro-combined cooling, heating and power system driven by a gas engine. Energy Conv Manag 28(7):977–987
Li S, Wu JY (2009) Theoretical research of a silica gel–water adsorption chiller in a micro combined cooling, heating and power (CCHP) system. Appl Energy 86(6):958–967
Grisel RJH, Smeding SF, Boer RD (2010) Waste heat driven silica gel/water adsorption cooling in trigeneration. Appl Therm Eng 30(8–9):1039–1046
Zhai H et al (2009) Energy and exergy analyses on a novel hybrid solar heating, cooling and power generation system for remote areas. Appl Energy 86(9):1395–1404
Tangkengsirisin V, Kanzawa A, Watanabe T (1998) A solar-powered adsorption cooling system using a silica gel–water mixture. Energy 23(5):347–353
Luo HL et al (2007) An efficient solar-powered adsorption chiller and its application in low-temperature grain storage. Sol Energy 81(5):607–613
Zhai XQ et al (2008) Design and performance of a solar-powered air-conditioning system in a green building. Appl Energy 85(5):297–311
Lu Z, Wang R, Xia Z (2013) Experimental analysis of an adsorption air conditioning with micro-porous silica gel–water. Appl Therm Eng 50(1):1015–1020
Santori G, Sapienza A, Freni A (2012) A dynamic multi-level model for adsorptive solar cooling. Renew Energy 43:301–312
Lu ZS et al (2013) Study of a novel solar adsorption cooling system and a solar absorption cooling system with new CPC collectors. Renew Energy 50(3):299–306
Chang WS, Wang CC, Shieh CC (2009) Design and performance of a solar-powered heating and cooling system using silica gel/water adsorption chiller. Appl Therm Eng 29(10):2100–2105
Wang D et al (2012) Investigation of adsorption performance deterioration in silica gel–water adsorption refrigeration. J Eng Thermophys 58(9):157–162
Freni A et al (2007) An advanced solid sorption chiller using SWS-1L. Appl Therm Eng 27(13):2200–2204
Ahamat MA, Tierney MJ (2012) Calorimetric assessment of adsorbents bonded to metal surfaces: application to type a silica gel bonded to aluminium. Appl Therm Eng 40(40):258–266
Rezk A et al (2013) Effects of contact resistance and metal additives in finned-tube adsorbent beds on the performance of silica gel/water adsorption chiller. Appl Therm Eng 53(2):278–284
Li J et al (2004) Optimal Design of a fin-Type Silica gel Tube Module in the silica gel/water adsorption heat pump. J Chem Eng Jpn 37(4):551–557
Kubota M et al (2008) Cooling output performance of a prototype adsorption heat pump with fin-type silica gel tube module. Appl Therm Eng 28(2):87–93
Niazmand H, Talebian H, Mahdavikhah M (2012) Bed geometrical specifications effects on the performance of silica/water adsorption chillers. Int J Refrig 35(8):2261–2274
Khan MZI et al (2007) Study on a re-heat two-stage adsorption chiller – the influence of thermal capacitance ratio, overall thermal conductance ratio and adsorbent mass on system performance. Appl Therm Eng 27(10):1677–1685
Miyazaki T, Akisawa A (2009) The influence of heat exchanger parameters on the optimum cycle time of adsorption chillers. Appl Therm Eng 29(13):2708–2717
Alam KCA et al (2000) Heat exchanger design effect on the system performance of silica gel adsorption refrigeration systems. Int J Heat Mass Tran 43(24):4419–4431
Farid SK et al (2011) A numerical analysis of cooling water temperature of two-stage adsorption chiller along with different mass ratios. Int Comm Heat Mass Tran 38(8):1086–1092
Hamamoto Y et al (2005) Performance evaluation of a two-stage adsorption refrigeration cycle with different mass ratio. Int J Refrig 28(3):344–352
Wang L et al (2005) Research on the chemical adsorption precursor state of CaCl2-NH3 for adsorption refrigeration. SCIENCE CHINA Technol Sci 48(1):70–82
Wu JY, Li S (2009) Study on cyclic characteristics of silica gel–water adsorption cooling system driven by variable heat source. Energy 34(11):1955–1962
Zhang G et al (2011) Simulation of operating characteristics of the silica gel–water adsorption chiller powered by solar energy. Sol Energy 85(7):1469–1478
Liu Y, Wang R (2003) Pore structure of new composite adsorbent SiO2·xH2O· yCaCl2 with high uptake of water from air. SCIENCE CHINA Technol Sci 46(5):551–559
Aristov YI et al (2007) Sorption equilibrium of methanol on new composite sorbents “CaCl 2 /silica gel”. Adsorption 13(2):121–127
Zhang XJ, Qiu LM (2007) Moisture transport and adsorption on silica gel–calcium chloride composite adsorbents. Energy Conv Manag 48(1):320–326
Chen J et al (2015) A review on versatile ejector applications in refrigeration systems. Renew Sustain Energy Rev 49:67–90
He S, Li Y, Wang RZ (2009) Progress of mathematical modeling on ejectors. Renew Sustain Energy Rev 13(8):1760–1780
Chen X et al (2013) Recent developments in ejector refrigeration technologies. Renew Sustain Energy Rev 19(1):629–651
Zhu Y, Jiang P (2014) Experimental and numerical investigation of the effect of shock wave characteristics on the ejector performance. Int J Refrig 40:31–42
Angelino G, Invernizzi C (2008) Thermodynamic optimization of ejector actuated refrigerating cycles. Int J Refrig 31(3):453–463
Chen YM, Sun CY (1997) Experimental study of the performance characteristics of a steam-ejector refrigeration system. Exper Therm Fluid Sci 15(4):384–394
Al-Khalidy N (1998) An experimental study of an ejector cycle refrigeration machine operating on R113: Etude expérimentale d'une machine frigorifique à éjecteur au R113. Int J Refrig 21(8):617–625
Yu J, Zhao H, Li Y (2008) Application of an ejector in autocascade refrigeration cycle for the performance improvement. Int J Refrig 31(2):279–286
Elakdhar M, Nehdi AE, Kairouani L (2007) Analysis of a compression/ejection cycle for domestic refrigeration. Ind Eng Chem Res 46(13):4639–4644
Palm B (2008) Hydrocarbons as refrigerants in small heat pump and refrigeration systems – a review. Int J Refrig 31(4):552–563
Sarbu I (2014) A review on substitution strategy of non-ecological refrigerants from vapour compression-based refrigeration, air-conditioning and heat pump systems. Int J Refrig 46:123–141
Selvaraju A, Mani A (2004) Analysis of an ejector with environment friendly refrigerants. Appl Therm Eng 24(5–6):827–838
Sirwan R et al (2013) Evaluation of adding flash tank to solar combined ejector–absorption refrigeration system. Sol Energy 91(3):283–296
Alexis GK, Katsanis JS (2004) Performance characteristics of a methanol ejector refrigeration unit. Energy Conv Manag 45(17):2729–2744
Jiang L et al (2002) Thermo-economical analysis between new absorption–ejector hybrid refrigeration system and small double-effect absorption system. Appl Therm Eng 22(9):1027–1036
Li D, Groll EA (2005) Transcritical CO2 refrigeration cycle with ejector-expansion device. Int J Refrig 28(5):766–773
Yari M, Sirousazar M (2008) Cycle improvements to ejector-expansion transcritical CO2 two-stage refrigeration cycle. Int J Energy Res 32:677–687
Ahammed ME, Bhattacharyya S, Ramgopal M (2014) Thermodynamic design and simulation of a CO2 based transcritical vapour compression refrigeration system with an ejector. Int J Refrig 45:177–188
Pridasawas W, Lundqvist P (2004) An exergy analysis of a solar-driven ejector refrigeration system. Sol Energy 76(4):369–379
Li CH, Wang RZ, Lu YZ (2002) Investigation of a novel combined cycle of solar powered adsorption–ejection refrigeration system. Renew Energy 26(4):611–622
Zhang XJ, Wang RZ (2002) A new combined adsorption–ejector refrigeration and heating hybrid system powered by solar energy. Appl Therm Eng 22(11):1245–1258
Dorantes R, Estrada CA, Pilatowsky I (1996) Mathematical simulation of a solar ejector-compression refrigeration system. Appl Therm Eng 16(8–9):669–675
Sokolov M, Hershgal D (1990) Enhanced ejector refrigeration cycles powered by low grade heat. Part 1. Systems characterization. Int J Refrig 13(6):351–356
Sokolov M, Hershgal D (1990) Enhanced ejector refrigeration cycles powered by low grade heat. Part 2. Design procedures. Int J Refrig 13(6):357–363
Sokolov M, Hershgal D (1991) Enhanced ejector refrigeration cycles powered by low grade heat. Part 3. Experimental results. Int J Refrig 14(1):24–31
Hernández JI et al (2004) The behaviour of a hybrid compressor and ejector refrigeration system with refrigerants 134a and 142b. Appl Therm Eng 24(13):1765–1783
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Li, J., Kong, X. (2018). Thermally Activated Refrigeration Technologies. In: Wang, R., Zhai, X. (eds) Handbook of Energy Systems in Green Buildings. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-662-49120-1_38
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