Renewable and Sustainable Energy Reviews 15

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3978 B.F. Tchanche et al. / Renewable and Sustainable Energy Reviews 15 (2011) 3963–3979 [82] Facao J, Palmero-Marrero A, Oliveira AC. Analysis of a solar assisted micro- cogeneration ORC system. International Journal of Low-Carbon Technology 2008;3:254–64. [83] Kane M, Larrain D, Favrat D, Allani Y. Small hybrid solar power system. Energy 2003;28:1427–43. [84] http://www.nrel.gov/csp/solarpaces/project detail.cfm/projectID=24. [85] http://keaholesolarpower.com/news/farming the sun/. [86] http://www.power-technology.com/projects/holanikuatkeaholepoi/. [87] Trieb F, Langni O, Klai H. Solar electricity generation – a comparative view of technologies, costs and environmental impact. Solar Energy 1997;59:89–99. [88] Bronicki LY, Robert AM. Solar ponds, encyclopedia of physical science and technology. New York: Academic Press; 2001. p. 149–66. [89] Fritzmann C, Lowenberg J, Wintgers T, Melin T. State-of-the-art of reverse osmosis desalination. Desalination 2007;216:1–76. [90] Delgado-Torres AM. Solar thermal heat engines for water pumping: an update. Renewable and Sustainable Energy Reviews 2009;13:462–72. [91] Wong YW, Sumathy K. Solar thermal water pumping systems: a review. Renewable and Sustainable Energy Reviews 1999;3:185–217. [92] Maurel A. Dessalement et energies renouvelables. Desalination 1979;31: 489–99. [93] Voros NG, Kiranoudis CT, Maroulis ZB. Solar energy exploitation for reverse osmosis desalination plants. Desalination 1998;115:83–101. [94] Bouzayani N, Galanis N, Orfi J. Comparative study of power and water cogen- eration systems. Desalination 2007;205:243–53. [95] Manolakos D, Papadakis G, Mohamed ES, Kyritsis S, Bouzianas K. Design of an autonomous low-temperature solar Rankine cycle system for reverse osmosis desalination. Desalination 2005;183:73–80. [96] Manolakos D, Papadakis G, Kyritsis S, Bouzianas K. Experimental evaluation of an autonomous low-temperature solar Rankine cycle system for reverse osmosis desalination. Desalination 2007;203:366–74. [97] Manolakos D, Mohamed ES, Karagiannis I, Papadakis G. Technical and eco- nomic comparison between PV–RO system and RO–Solar Rankine system. Case study: Thirasia island. Desalination 2008;221:37–46. [98] Kosmadakis G, Manolakos D, Papadakis G. Parametric theoretical study of a two-stage solar organic Rankine cycle for RO desalination. Renewable Energy 2009;35:989–96. [99] Henning HM. Solar assisted air conditioning of buildings – an overview. Applied Thermal Engineering 2007;27:1734–49. [100] Kim DS, Infante Ferreira CA. Solar refrigeration options – a state-of-the-art review. International Journal of Refrigeration 2008;31:3–15. [101] Lior N. Solar energy and the steam Rankine cycle for driving and assisting heat pumps in heating and cooling modes. Energy Conversion 1977;16:111–23. [102] Prigmore D, Barber R. Cooling with the sun’s heat design considerations and test data for a Rankine cycle prototype. Solar Energy 1975;17:185–92. [103] Xu F, Goswami DY, Bhagwat SS. A combined power/cooling cycle. Energy 2000;25:233–46. [104] Wang J, Dai Y, Gao L, Ma S. A new combined cooling, heating and power system driven by solar energy. Renewable Energy 2009;34:2780–8. [105] Oliveira AC, Afonso C, Matos J, Riffat S, Nguyen M, Doherty P. A combined heat and power system for buildings driven by solar energy and gas. Applied Thermal Engineering 2002;22:587–93. [106] http://www.nrel.gov/otec/what.html. [107] Finney KA. Ocean thermal energy conversion. Guelph Engineering Journal 2008;1:17–23. [108] Takahashi PK, Trenka A. Ocean thermal energy conversion: its promise as a total resource system. Energy 1992;17:657–68. [109] www.seao2.com/otec/. [110] Uehara H. History and the future of OTEC. Renewable Energy, Japan 2006. [111] Bonilla JJ, Blanco JM, L􏴭pez L, Sala JM. Technological recovery potential of waste heat in the industry of the Basque Country. Applied Thermal Engineer- ing 1997;17:283–8. [112] Latour SR, Menningmann JG, Blanney BL. Waste heat recovery potential in selected industries. Environmental Protection Agency (EPA) USA 1982. [113] Quoilin S, Lemort V. Technological and economical survey of organic Rankine cycle systems. In: 5th European conference on economics and management of energy in industry, Algarve-Portugal. 2009. [114] Galanis N, Cayer E, Roy P, Denis ES, Desilets M. Electricity generation from low temperature soures. Journal of Applied Fluid Mechanics 2009;2:55–67. [115] BCS Inc. Waste heat recovery: technologies and opportunities in U.S. industry, US Dept. of Energy (DOE); 2008. [116] Bios-bionergiesysteme Gmbh . [117] Energy Efficiency Guide for Industry in Asia . [118] Bohl R. Waste heat recovery from existing simple cycle gas turbine plants – a case study. In: 18th Symposium on industrial application of gas turbines (IAGT). 2009. [119] Tchanche BF. Low-grade heat conversion into power using small scale organic Rankine cycles. Ph.D. Thesis. Agricultural University of Athens, Athens. Greece; 2010. p. 200. [120] Vanslambrouck B, Vankeirsbilck I, Gusev S, De Paepe M. Turn waste heat into electricity by using an Organic Rankine Cycle. In: 2nd European Confernce on Polygeneration, Tarragona, Spain. 2011. [121] Bundela PS, Chawla V. Sustainable development through waste heat recovery. American Journal of Environmental Sciences 2010;6: 83–9. [122] [123] [124] [125] [126] [127] [128] [129] [130] [131] [132] [133] [134] [135] [136] [137] [138] [139] [140] [141] [142] [143] [144] [145] [146] [147] [148] [149] [150] [151] [152] [153] [154] [155] [156] Sanchez D, Munoz de Escalona JM, Monje B, Chacartegui R, Sanchez T. Pre- liminary analysis of compound systems based on high temperature fuel cell, gas turbine and Organic Rankine Cycle. Journal of Power Sources 2011;196:4355–63. Al-Sulaiman FA, Hamdullahpur F, Dincer I. Greenhouse gas emission and exergy assessments of an integrated organic Rankine cycle with a biomass combustor for combined cooling, heating and power production. Applied Thermal Engineering 2011;31:439–46. Chacartegui R, S􏴮nchez D, Mu􏴯oz JM, S􏴮nchez T. Alternative ORC bot- toming cycles FOR combined cycle power plants. Applied Energy 2009;86: 2162–70. Srinivasan KK, Mago PJ, Krishnan SR. Analysis of exhaust waste heat recov- ery from a dual fuel low temperature combustion engine using an organic Rankine cycle. Energy 2010;35:2387–99. Casci C, Angelino G, Ferrari P, Gaia M, Giglioli G, Macchi E. Heat recovery in a ceramic kiln with an organic rankine cycle engine. Journal of Heat Recovery Systems 1981;1:125–31. Walsh C, Thornley P. Cost effective greenhouse gas reductions in the stell industry from an organic Rankine cycle. Chemical Engineering Transactions 2011;25:905–10. Vescovo R. ORC recovering industrial heat – power generation from waste energy streams. Cogeneration and On-Site Power Production 2009;(March–April). Nowak W, Borsukiewicz-Gozdur A, Stachel AA. Using the low-temperature Clausius-Rankine cycle to cool technical equipment. Applied Energy 2008;85:582–8. El Chalmas R, Clodic D. Combined cycle for hybrid vehicles. In: SAE world congress. 2005. Endo T, Kawajiri S, Kojima Y, Takahashi K, Baba T, Ibaraki S, Takahashi T, Shinorama M. Study on maximizing exergy in automotive engines, SAE world Congress, Detroit. Michigan 2007. Wen Kuo Tien, Rong Hua Yeh, Hong JM. Theoretical analysis of cogeneration system for ships. Energy Conversion and Management 2007;48:1965–74. Sogut Z, Otkay Z, Karakoc H. Mathematical modeling of heat recovery from a rotary kiln. Applied Thermal Engineering 2010;30:817–25. Hasanbeigi A, Price L, Lu H, Lan W. Analysis of energy-efficiency opportuni- ties for the cement industry in Shandong Province China: a case study of 16 cement plants. Energy 2010;35:3461–73. Rasul MG, Widianto W, Mohanty B. Assessment of the thermal performance and energy conservation opportunities of a cement industry in Indonesia. Applied Thermal Engineering 2005;25:2950–65. Engin T, Ari V. Energy auditing and recovery for dry type cement rotary kiln systems – a case study. Energy Conversion and Management 2005;46:551–62. Freymann R, Strobl W, Obieglo A. The turbosteamer: a system introducing the principle of cogeneration in automotive applications. MTZ05/2008 2008;69. www.greenship.org. Schmid H. Less emissions through waste heat recovery. Warstila Corporation; 2004. http://www.greencarcongress.com/2010/04/opcon-20100407.html#more/. Lai NA, Wendland M, Fischer J. Working fluids for high-temperature organic Rankine cycles. Energy 2011;36:199–211. Hung T-C. Waste heat recovery of organic Rankine cycle using dry fluids. Energy Conversion and Management 2001;42:539–53. Invernizzi C, Iora P, Silva P. Bottoming micro-Rankine cycles for micro-gas turbines. Applied Thermal Engineering 2007;27:100–10. Hung TC, Wang SK, Kuo CH, Pei BS, Tsai KF. A study of organic working flu- ids on system efficiency of an ORC using low-grade energy sources. Energy 2010;35:1403–11. Hung TC, Shai TY, Wang SK. A review of organic Rankine cycles (ORCs) for the recovery of low-grade waste heat. Energy 1998;22:661–7. Dai Yiping, Wang Jiangfeng, Gao Lin. Parametric optimization and compara- tive study of organic Rankine cycle (ORC) for low grade waste heat recovery. Energy Conversion and Management 2009;50:576–82. Liu B-T, Chien K-H, Wang C-C. Effect of working fluids on organic Rankine cycle for waste heat recovery. Energy 2004;29:1207–17. Nguyen TQ, Slawnwhite JD, Boulama KG. Power generation from residual industrial heat. Energy Conversion and Management 2010;51:2220–9. Chen Y, Lundqvist P, Johansson A, Platell P. A comparative study of the carbon dioxide transcritical power cycle compared with an organic rankine cycle with R123 as working fluid in waste heat recovery. Applied Thermal Engi- neering 2006;26:2142–7. Aljundi IH. Effect of dry hydrocarbons and critical point temperature on the efficiencies of organic Rankine cycle. Renewable Energy 2011;36:1196–202. Schuster A, Karellas S, Aumann R. Efficiency optimization potential in super- critical Organic Rankine Cycles. Energy 2009;35:1033–9. Vaja I, Gambarotta A. Internal Combustion Engine (ICE) bottoming with Organic Rankine Cycles (ORCs). Energy 2010;35:1084–93. Sun J, Li W. Operation optimization of an organic rankine cycle (ORC) heat recovery power plant. Applied Thermal Engineering 2011;31:2032–41. Desai NB, Bandyopadhyay S. Process integration of organic Rankine cycle. Energy 2009;34:1674–86. Karellas S, Schuster A. Supercritical fluid parameters in organic Rankine cycle applications. International Journal of Thermodynamics 2008;11:101–8. Cayer E, Galanis N, Nesreddine H. Parametric study and optimization of a transcritical power cycle using a low temperature source. Applied Energy 2010;87:1349–57.

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