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Potential of Adsorption Refrigeration System for Off-Grid Cooling Applications

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Renewable Energy and Sustainable Buildings

Part of the book series: Innovative Renewable Energy ((INREE))

Abstract

Lack of cold-storage facilities for food products, vaccines, medicines and artificial insemination services is a serious problem in many developing countries. FAO estimated that 32% of food produced in the world was wasted in the year 2009 while the IEA reported that more than 20% of the world’s population lacked access to electricity in the year 2010. Among them 57% lived in rural areas in sub-Saharan Africa. Water-ammonia kerosene and gas-driven absorption systems have been used to store vaccines. However, they do not meet the minimum standards established by WHO on Performance, Quality and Safety for the required +2 °C to +8 °C temperatures. PV-powered cooling systems preserve vaccines more efficiently and in an environmental friendly manner. However, batteries are needed. Batteries live shorter than refrigerators, implying extra costs. Also, PV systems have low possibility of being manufactured in most developing countries. Adsorption refrigeration systems have shown great potential to meet cooling needs in off-grid locations. They can utilise low-temperature waste heat and renewable energy sources like solar thermal energy to providing cooling.

A single-bed water-cooled condenser adsorption refrigerator prototype, which utilises CaCl2-ammonia pair has been developed and tested in the laboratory. Experiments have been conducted for desorption temperatures ranging between 75 °C and 100 °C and desorption time of 1–4 h using an electric tape heater. The effect of desorption temperature and desorption time on the cold chamber temperature have been analysed and discussed. At desorption temperatures of 85 °C and higher and desorption time greater than 1 h, the cold chamber of the prototype attained temperatures between 2 °C and 8 °C, which is a suitable range for storage of food products and vaccines. Temperatures below 0 °C, which are suitable for ice production, were obtained at desorption temperatures greater than 95 °C and desorption times of 2 h and higher. Desorption temperature lower than 85 °C can be used for air conditioning applications as they have attained cold chamber temperatures below 15 °C for desorption time greater than 1 h. The tested desorption temperatures are common temperatures, which can be attained by flat plate and evacuated tube solar collectors.

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References

  1. Anupam K, Palodkar AV, Halder G (2016) Experimental study on activated carbon-nitrogen pair in a prototype pressure swing adsorption refrigeration system. Heat Mass Transf 52(4):753–761

    Article  Google Scholar 

  2. Allouhi A, Kousksou T, Jamil A, Agrouaz Y, Bouhal T, Saidur R, Benbassou A (2016) Performance evaluation of solar adsorption cooling systems for vaccine preservation in sub-Saharan Africa. Appl Energy 170:232–241

    Article  Google Scholar 

  3. WHO (2006) Temperature sensitivity of vaccines. WHO, Geneva, pp 1–62

    Google Scholar 

  4. McCarney S, Robertson J, Arnaud J, Lorenson K, Lloyd J (2013) Using solar-powered refrigeration for vaccine storage where other sources of reliable electricity are inadequate or costly. Vaccine 31(51):6050–6057

    Article  Google Scholar 

  5. Tina GM, Grasso AD (2014) Remote monitoring system for stand-alone photovoltaic power plants: the case study of a PV-powered outdoor refrigerator. Energy Convers Manag 78:862–871

    Article  Google Scholar 

  6. Axaopoulos PJ, Theodoridis MP (2009) Design and experimental performance of a PV ice-maker without battery. Sol Energy 83(8):1360–1369

    Article  Google Scholar 

  7. Anyanwu EE, Ezekwe CI (2003) Design, construction and test run of a solid adsorption solar refrigerator using activated carbon/methanol, as adsorbent/adsorbate pair. Energy Convers Manag 44(18):2879–2892

    Article  Google Scholar 

  8. Lipinski B, Hanson C, Lomax J, Kitinoja L, Waite R, Searchinger T (2013) Reducing food loss and waste: working paper. World Resources Institute, Washington, DC

    Google Scholar 

  9. El-Sharkawy II, Saha BB, Koyama S, He J, Ng KC, Yap C (2008) Experimental investigation on activated carbon–ethanol pair for solar powered adsorption cooling applications. Int J Refrig 31(8):1407–1413

    Article  Google Scholar 

  10. Ullah KR, Saidur R, Ping HW, Akikur RK, Shuvo NH (2013) A review of solar thermal refrigeration and cooling methods. Renew Sust Energ Rev 24:499–513

    Article  Google Scholar 

  11. Tamainot-Telto Z, Metcalf SJ, Critoph RE, Zhong Y, Thorpe R (2009) Carbon-ammonia pairs for adsorption refrigeration applications: ice making, air conditioning and heat pumping. Int J Refrig 32(6):1212–1229

    Article  Google Scholar 

  12. Allouhi A, Kousksou T, Jamil A, Bruel P, Mourad Y, Zeraouli Y (2015) Solar driven cooling systems: an updated review. Renew Sust Energ Rev 44:159–181

    Article  Google Scholar 

  13. Zhong Y (2006) Studies on equilibrium and dynamic characteristics of new adsorption pairs. PhD thesis, University of Warwick

    Google Scholar 

  14. Critoph RE (1989) Activated carbon adsorption cycles for refrigeration and heat pumping. Carbon 27(1):63–70

    Article  Google Scholar 

  15. Boubakri A, Arsalane M, Yous B, Ali-Moussa L, Pons M, Meunier F, Guilleminot J (1992) Experimental study of adsorptive solar-powered ice makers in Agadir (Morocco)-1. Performance in actual site. Renew Energy 2(1):7–13

    Article  Google Scholar 

  16. Li M, Wang RZ, Xu Y, Wu J, Dieng A (2002) Experimental study on dynamic performance analysis of a flat-plate solar solid-adsorption refrigeration for ice maker. Renew Energy 27(2):211–221

    Article  Google Scholar 

  17. Tamainot-Telto Z, Critoph R (1997) Adsorption refrigerator using monolithic carbon-ammonia pair. Int J Refrig 20(2):146–155

    Article  Google Scholar 

  18. Lu Z, Wang RZ, Wang LW, Chen C (2006) Performance analysis of an adsorption refrigerator using activated carbon in a compound adsorbent. Carbon 44(4):747–752

    Article  Google Scholar 

  19. Hildbrand C, Dind P, Pons M, Buchter F (2004) A new solar powered adsorption refrigerator with high performance. Sol Energy 77(3):311–318

    Article  Google Scholar 

  20. Bouzeffour F, Khelidj B (2016) Experimental investigation of a solar adsorption refrigeration system working with silicagel/water pair: a case study for Bou-Ismail solar data. Sol Energy 131:165–175

    Article  Google Scholar 

  21. Brites GJVN, Costa JJ, Costa VAF (2016) Influence of the design parameters on the overall performance of a solar adsorption refrigerator. Renew Energy 86:238–250

    Article  Google Scholar 

  22. Frazzica A, Palomba V, Dawoud B, Gullì G, Brancato V, Sapienza A, Vasta S, Freni A, Costa F, Restuccia G (2016) Design, realization and testing of an adsorption refrigerator based on activated carbon/ethanol working pair. Appl Energy 174:15–24

    Article  Google Scholar 

  23. Lemmini F, Errougani A (2005) Building and experimentation of a solar powered adsorption refrigerator. Renew Energy 30(13):1989–2003

    Article  Google Scholar 

  24. Vasta S, Freni A, Sapienza A, Costa F, Restuccia G (2012) Development and lab-test of a mobile adsorption air-conditioner. Int J Refrig 35(3):701–708

    Article  Google Scholar 

  25. Magnetto D, de Boer R, Taklanti A (2011) A mobile air conditioning system operated by the engine waste heat. SAE Technical Paper, No. 2011-01-0135

    Google Scholar 

  26. Xia ZZ, Wang RZ, Wang DC, Liu YL, Wu JY, Chen CJ (2009) Development and comparison of two-bed silica gel–water adsorption chillers driven by low-grade heat source. Int J Therm Sci 48(5):1017–1025

    Article  Google Scholar 

  27. Kubota M, Ueda T, Fujisawa R, Kobayashi J, Watanabe F, Kobayashi N, Hasatani M (2008) Cooling output performance of a prototype adsorption heat pump with fin-type silica gel tube module. Appl Therm Eng 28(2):87–93

    Article  Google Scholar 

  28. Alahmer A, Wang X, Al-Rbaihat R, Alam KA, Saha BB (2016) Performance evaluation of a solar adsorption chiller under different climatic conditions. Appl Energy 175:293–304

    Article  Google Scholar 

  29. Critoph RE, Tamainot-Telto Z, Davies GL (2000) A prototype of a fast cycle adsorption refrigerator utilizing a novel carbon-aluminium laminate. Proc Inst Mech Eng A 214:439–448

    Article  Google Scholar 

  30. Wang RZ, Li M, Xu YX, Wu JY (2000) An energy efficient hybrid system of solar powered water heater and adsorption ice maker. Sol Energy 68(2):189–195

    Article  Google Scholar 

  31. Li TX, Wang RZ, Li H (2014) Progress in the development of solid-gas sorption refrigeration thermodynamic cycle driven by low-grade thermal energy. Prog Energy Combust Sci 40:1–58

    Article  Google Scholar 

  32. Askalany AA, Salem M, Ismael IM, Ali AHH, Morsy MG, Saha BB (2013) An overview on adsorption pairs for cooling. Renew Sust Energ Rev 19:565–572

    Article  Google Scholar 

  33. Wang L, Chen L, Wang HL, Liao DL (2009) The adsorption refrigeration characteristics of alkaline-earth metal chlorides and its composite adsorbents. Renew Energy 34(4):1016–1023

    Article  Google Scholar 

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Authors and Affiliations

  1. Department of Mechanical and Industrial Engineering, University of Dar es Salaam, Dar es Salaam, Tanzania

    Michael John, Cuthbert Z. M. Kimambo & Joseph Kihedu

  2. Department of Energy and Process Engineering, Norwegian University of Science and Technology, Trondheim, Norway

    Trygve M. Eikevik & Ole J. Nydal

Authors
  1. Michael John
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  2. Cuthbert Z. M. Kimambo
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  3. Trygve M. Eikevik
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  4. Ole J. Nydal
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  5. Joseph Kihedu
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Editors and Affiliations

  1. World Renewable Energy Congress, Brighton, UK

    Ali Sayigh

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John, M., Kimambo, C.Z.M., Eikevik, T.M., Nydal, O.J., Kihedu, J. (2020). Potential of Adsorption Refrigeration System for Off-Grid Cooling Applications. In: Sayigh, A. (eds) Renewable Energy and Sustainable Buildings. Innovative Renewable Energy. Springer, Cham. https://doi.org/10.1007/978-3-030-18488-9_78

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  • DOI: https://doi.org/10.1007/978-3-030-18488-9_78

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  • Publisher Name: Springer, Cham

  • Print ISBN: 978-3-030-18487-2

  • Online ISBN: 978-3-030-18488-9

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