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2012 | OriginalPaper | Buchkapitel

A Review and New Design Options to Minimize the Capital and Operational Cost of Single Effect Solar Absorption Cooling System for Residential Use

verfasst von : V. Boopathi Raja, V. Shanmugam

Erschienen in: Emerging Trends in Science, Engineering and Technology

Verlag: Springer India

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Abstract

Solar energy is an alternative energy source for cooling systems where electricity is demand or expensive. Many solar assisted cooling systems have been installed in different countries for domestic purpose. Many researches are going on to achieve economical and efficient thermal systems when compared with conventional systems. This paper reviews the past efforts of solar assisted-single effect vapor absorption cooling system using LiBr-H₂O mixture for residential buildings. Solar assisted single-effect absorption cooling systems were capable of working in the driving temperature range of 70–100 °C. In this system LiBr-H₂O are the major working pairs and has a higher COP than any other working fluids. Besides the review of the past theoretical and experimental investigations of solar single effect absorption cooling systems, some new ideas were introduced to minimize the capital and operational cost, to reduce heat loss from generator and thus to increase COP to get effective cooling.

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Henning H-M (2007) Solar assisted air conditioning of buildings—an overview. Appl Therm Eng 27(10):1734–1749CrossRef

Hassan HZ, Mohamad AA (2012) A review on solar cold production through absorption technology. Renew Sustain Energy Rev 16:5331–5348CrossRef

Jaruwongwittaya T, Chen G (2010) A review: renewable energy with absorption chillers in Thailand. Renew Sustain Energy Rev 14:1437–1444CrossRef

Altamush Siddiqui M (1997) Economic analyses of absorption systems: part-B-optimization of operating parameters. Energy Convers Mgmt 38(9):905–918CrossRef

Deng J, Wang RZ, Han GY (2011) A review of thermally activated cooling technologies for combined cooling, heating and power systems. Progress Energy Combust Sci 37:172–203

Jaruwongwittaya T, Chen G (2010) A review: renewable energy with absorption chillers in Thailand. Renew Sustain Energy Rev 14(5):1437–1444CrossRef

Fong KF, Chow TT, Lee CK, Lin Z, Chan LS (2010) Comparative study of different solar cooling systems for buildings in subtropical city. Sol Energy 84(2):227–244CrossRef

Gomri R (2010) Investigation of the potential of application of single effect and multiple effect absorption cooling systems. Energy Convers Manage 51(8):1629–1636CrossRef

Otanicar T, Robert A, Taylor B, Patrick EP (2012) Prospects for solar cooling—an economic and environmental assessment. Solar Energy 86:1287–1299CrossRef

10.

Berhane HG, Gonzalo GG, Laureano J, Dieter B (2012) Solar assisted absorption cooling cycles for reduction of global warming: a multi-objective optimization approach. Solar Energy 86:2083–2094CrossRef

11.

Rosiek S, Batlles FJ (2009) Integration of the solar thermal energy in the construction: analysis of the solar-assisted air-conditioning system installed in CIESOL building. Renew Energy 34(6):1423–1431CrossRef

12.

Ortiz M, Barsun H, He H, Vorobieff P, Mammoli A (2010) Modeling of a solar-assisted HVAC system with thermal storage. Energy Build 42(4):500–509CrossRef

13.

Mammoli A, Vorobieff P, Barsun H, Burnett R, Fisher D (2010) Energetic economic and environmental performance of a solar-thermal-assisted HVAC system. Energy Build 42(9):524–1535CrossRef

14.

Syed A, Izquierdo M, Rodríguez P, Maidment G, Missenden J, Lecuona A et al (2005) A novel experimental investigation of a solar cooling system in Madrid. Int J Refrig 28(6):859–871CrossRef

15.

Praene JP, Marc O, Lucas F, Miranville F (2011) Simulation and experimental investigation of solar absorption cooling system in Reunion Island. Appl Energy 88(3):831–839CrossRef

16.

Li ZF, Sumathy K (2001) Experimental studies on a solar powered air conditioning system with partitioned hot water storage tank. Sol Energy 71(5):285–297CrossRef

17.

Agyenim F, Knight I, Rhodes M (2010) Design and experimental testing of the performance of an outdoor LiBr/H2O solar thermal absorption cooling system with a cold store. Sol Energy 84(5):735–744CrossRef

18.

Rodríguez Hidalgo MC, Rodríguez Aumente P, Izquierdo Millán M, Lecuona Neumann A, Salgado RM (2008) Energy and carbon emission savings in Spanish housing air-conditioning using solar driven absorption system. Appl Therm Eng 28(14–15):1734–1744

19.

Izquierdo M, Lizarte R, Marcos JD, Gutierrez G (2008) Air conditioning using an air cooled single effect lithium bromide absorption chiller: results of a trial conducted in Madrid in August 2005. Applied Thermal Engg 28:1074–1081CrossRef

20.

Al-Dadah RK, Jackson G, Ahmed R (2011) Solar powered vapor absorption system using propane and alkylated benzene AB300 oil. Appl Thermal Eng 31:1936–1942CrossRef

21.

Zhai XQ, Qu M, Li Y, Wang RZ (2011) A review for research and new design options of solar absorption cooling systems. Renew Sustain Energy Rev 15:4416–4423CrossRef

22.

Balghouthi M, Chahbani MH, Guizani A (2008) Feasibility of solar absorption air conditioning in Tunisia. Build Environ 43(9):1459–1470CrossRef

23.

Florides GA, Kalogirou SA, Tassou SA, Wrobel LC (2002) Modelling, simulation and warming impact assessment of a domestic-size absorption solar cooling system. Appl Therm Eng 22(12):1313–1325CrossRef

24.

Assilzadeh F, Kalogirou SA, Ali Y, Sopian K (2005) Simulation and optimization of a LiBr solar absorption cooling system with evacuated tube collectors. Renew Energy 30(8):1143–1159CrossRef

25.

Atmaca I, Yigit A (2003) Simulation of solar-powered absorption cooling system. Renew Energy 28(8):1277–1293CrossRef

26.

Joudi KA, Abdul-Ghafour QJ (2003) Development of design charts for solar cooling systems. Part I: computer simulation for a solar cooling system and development of solar cooling design charts. Energy Convers Manage 44(2):313–339CrossRef

27.

Sun J, Lin F, Zhang Shigang, Hou W (2010) A mathematical model with experiments of single effect absorption heat pump using LiBr-H₂O. Appl Therm Eng 30:2753–2762CrossRef

28.

Liao X, Radermacher R (2007) Absorption chiller crystallization control strategies for integrated cooling heating and power systems. Int J Refrig 30:904–911CrossRef

29.

Bakhtiari B, Fradette L, Legros R, paris J (2011) A model for analysis and design of H₂O-LiBr absorption heat pumps. Energy Convers Manage 52:1439–1448CrossRef

30.

Wang Z, Zhaolin G, Feng S, Li Y (2009) Application of vacuum membrane distillation to Lithium Bromide absorption refrigeration system. Intl J Refrig 32:1587–1596CrossRef

31.

Mazloumi M, Naghashzadegan M, Javaherdeh K (2008) Simulation of solar lithium bromide–water absorption cooling system with parabolic trough collector. Energy Convers Manage 49(10):2820–2832CrossRef

32.

Mittelman G, Kribus A, Dayan A (2007) Solar cooling with concentrating photovoltaic/thermal (CPVT) systems. Energy Convers Manage 48(9):2481–2490CrossRef

33.

Calise F (2010) Thermoeconomic analysis and optimization of high efficiency solar heating and cooling systems for different Italian school buildings and climates. Energy Build 42(7):992–1003CrossRef

34.

Calise F, Palombo A, Vanoli L (2010) Maximization of primary energy savings of solar heating and cooling systems by transient simulations and computer design of experiments. Appl Energ 87(2):524–540CrossRef

35.

Pongtornkulpanich A, Thepa S, Amornkitbamrung M, Butcher C (2008) Experience with fully operational solar-driven 10-ton LiBr/H2O single-effect absorption cooling system in Thailand. Renew Energy 33(5):943–949CrossRef

36.

Prasartkaew B, Kumar S (2010) A low carbon cooling system using renewable energy resources and technologies. Energy Build 42(9):1453–1462CrossRef

37.

Ahmed Hamza HA, Noeres P, Pollerberg C (2008) Performance assessment of an integrated free cooling and solar powered single-effect lithium bromide-water absorption chiller. Solar Energy 82(11):1021–1030CrossRef

38.

Li J, Bai N, Ma W (2006) Large solar powered air conditioning-heat pump system. Acta Energiae Solaris Sinica 27(2):152–8 (in Chinese)

39.

Marc O, Lucas F, Sinama F, Monceyron E (2010) Experimental investigation of a solar cooling absorption system operating without any backup system under tropical climate. Energy Build 42(6):774–782CrossRef

40.

Monné C, Alonso S, Palacín F, Serra L (2011) Monitoring and simulation of an existing solar powered absorption cooling system in Zaragoza (Spain). Appl Therm Eng 31(1):28–35CrossRef

41.

Helm M, Keil C, Hiebler S, Mehling H, Schweigler C (2009) Solar heating and cooling system with absorption chiller and low temperature latent heat storage: energetic performance and operational experience. Int J Refrig 32(4):596–606CrossRef

42.

Qu M, Yin H, David HA (2010) A solar thermal cooling and heating system for a building: experimental and model based performance analysis and design. Sol Energy 84(2):166–182CrossRef

43.

Elsafty A, Al-Daini AJ (2002) Economical comparison between a solar powered vapor absorption air-conditioning system and a vapor compression system in the middle east. Renew Energy 25:569–583CrossRef

Titel: A Review and New Design Options to Minimize the Capital and Operational Cost of Single Effect Solar Absorption Cooling System for Residential Use
verfasst von: V. Boopathi Raja
V. Shanmugam
Verlag: Springer India
Buch: Emerging Trends in Science, Engineering and Technology
Print ISBN: 978-81-322-1006-1

Electronic ISBN: 978-81-322-1007-8

Copyright-Jahr: 2012
DOI: https://doi.org/10.1007/978-81-322-1007-8_1

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