REVIEW OF ORGANIC RANKINE CYCLE USED IN SMALL- SCALE APPLICATION
DOI:
https://doi.org/10.29121/ijetmr.v7.i1.2020.496Keywords:
ORC, Working Fluids, Expander, Application, Rotary VaneAbstract
Organic Rankine cycle an alternative way of generating energy from waste heat, fuel and gases at low-temperature. Method (ORC) proved successful and high efficiency to reduce environmental pollution, fuel consumption and convert low to medium heat sources. The paper will be presenting a review investigation on the organic Rankine cycle(ORC), cycle Background, (ORC) configuration, and selecting of working fluids and experimental studied of expansion apparatuses, which are classified into two type volumetric type such as (expander of rotary vane, scroll, reciprocating piston expander and screw) velocity kind (for example axial and radial turbine). Heat exchanger and expander apparatuses are considered economically expensive parts in (ORC).
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References
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[3] Fredy Vélez, Farid Chejne and, Ana Quijano, “Thermodynamic analysis of R134a in an Organic Rankine Cycle for power generation from low temperature sources”, DYNA, 2014.
[4] Ngoc Anh Lai, Martin Wendland, Johann Fischer, “Working fluids For High-temperature Organic Rankine Cycles”, Elsevier- Energy 36 (2011) 199-211, 2010
[5] Bala V. Datla, Joost J. Brasz, “Comparing R1233zd and R245fa for Low Temperature ORC applications”, International Refrigeration and Air Conditioning Conference, 2014
[6] X. R. Zhang, H. Yamaguchi and D. Uneno. "Thermodynamic analysis of the CO2-based Rankine cycle powered by solar energy". INTERNATIONAL JOURNAL OF ENERGY RESEARCH Int. J. Energy Res. 2007; 31:1414–14.
[7] M. Chys, M. van den Broek, B. Vanslambrouck, M. De Paepe. "Potential of zeotropic mixtures as working fluids in organic Rankine cycles". Energy 44 (2012) 623-632
[8] MostafaMostafavi- Sani, Sajad Behzadipour, and Pouria Jalilnia" THERMODYNAMIC MODELING AND EXERGY ANALYSIS OF ORGANIC RANKINE CYCLE WITH THE RECEIVER OF THE SUN" International Journal of Latest Research in Science and Technology ISSN (Online):2278-5299 Volume 4, Issue 1: Page No.81-84, January-February 2015
[9] Galloway E, Hebert L. History and progress of the steam engine; with a practical investigation of its structure and application. London: Printed for Kelly; 1836.
[10] Shuman F. The direct acting solar engine - the prime mover of the immediate Future; 1907.
[11] Tabor h, Bronicki L. Small turbine for solar energy power package: Tabor, H. and L. Bronicki, National Physical Laboratory of Israel, United Nations Conference on New Sources of Energy, Rome, 1961, 24 p., Illus... Sol Energy 1963; 7(2):82.
[12] Pytilinski JT. Solar energy installations for pumping irrigation water. Sol Energy 1978; 21(4):255–62.
[13] Curran HM. Organic working fluids in Rankine engines. J Energy 1981; 5 (4):218–23
[14] http://theenergylibrary.com/node/10537
[15] http://gasengine.farmcollector.com/Gas-Engines/The-Naphtha-Engine.aspx
[16] http://www.kgraenergy.com/projects/worldwide-orc-installations
[17] Quoilin S. Sustainable energy conversion through the use of Organic Rankine Cycles for waste heat recovery and solar applications Doctor of Applied Sciences. Liège, Belgium: University of Liège; 2011.
[18] Wang EH, Zhang HG, Fan BY, Ouyang MG, Zhao Y, Mu QH. Study of working Fluid selection of organic Rankine cycle (ORC) for engine waste heat recovery. Energy 2011; 36(5):3406–18.
[19] Wang W, Wu Y-T, Ma C-F, Liu L-D, Yu J. Preliminary experimental study of Single screw expander prototype. Apple Therm Eng. 2011; 31(17–18):3684–8.
[20] Schuster A, Karellas S, Kakaras E, Spliethoff H. Energetic and economic Investigation of Organic Rankine Cycle applications. Apple Therm Eng. 2009; 29 (8–9):1809–17.
[21] Stoppato A. Energetic and economic investigation of the operation Management of an Organic Rankine Cycle cogeneration plant. Energy 2012; 41(1):3–9.
[22] Bao J, Zhao L. A review of working fluid and expander selections for organic Rankine cycle. Renew Sustain Energy Rev 2013; 24:325–42.
[23] Kiyarash Rahbar a,⇑, Saad Mahmoud a, Raya K. Al-Dadah a, Nima Moazami a, Seyed A. Mirhadizadeh b"Review of organic Rankine cycle for small-scale applications"Energy Conversion and Management 134 (2017) 135–155.
[24] Wang W, Wu Y-T, Ma C-F, Liu L-D, Yu J. Preliminary experimental study of Single screw expander prototype. Apple Therm Eng. 2011; 31(17–18):3684–8.
[25] Schuster A, Karellas S, Kakaras E, Spliethoff H. Energetic and economic Investigation of Organic Rankine Cycle applications. Apple Therm Eng. 2009; 29 (8–9):1809–17.
[26] Stoppato A. Energetic and economic investigation of the operation Management of an Organic Rankine Cycle cogeneration plant. Energy 2012; 41(1):3–9.
[27] Bao J, Zhao L. A review of working fluid and expander selections for organic Rankine cycle. Renew Sustain Energy Rev 2013; 24:325–42.
[28] Kiyarash Rahbar a,⇑, Saad Mahmoud a, Raya K. Al-Dadah a, Nima Moazami a, Seyed A. Mirhadizadeh b"Review of organic Rankine cycle for small-scale applications"Energy Conversion and Management 134 (2017) 135–155.
[29] Larjola J. Electricity from industrial waste heat using high-speed organic Rankine cycle (ORC). Int J Prod Econ 1995; 41(1–3):22
[30] Invernizzi C, Iora P, Silva P. Bottoming micro-Rankine cycles for micro-gas Turbines. Appl Therm Eng. 2007; 27(1):100–10.
[31] Tchanche BF, Papadakis G, Lambrinos G, Frangoudakis A. Fluid selection for a Low-temperature solar organic Rankine cycle. Appl Therm Eng 2009; 29(11-12):2468–76-
[32] Li J, Pei G, Li Y, Ji J. Evaluation of external heat loss from a small-scale Expander used in organic Rankine cycle. Appl Therm Eng 2011; 31(1-15):2694–701.
[33] McMahan A. Design and optimization of organic Rankine cycle solar thermal Power plants MSc Thesis. University of Wisconsin-Madison; 200
[34] Qiu G, Liu H, Riffat S. Expanders for micro-CHP systems with organic Rankine Cycle. Appl Therm Eng 2011; 31(16):3301-7
[35] Song P, Wei M, Shi L, Danish SN, Ma C. A review of scroll expanders for Organic Rankine cycle systems. Appl Therm Eng 2015; 75:54–64. Part A: J Power Energy 2012; 226(1):126–36.
[36] Saitoh T, Yamada N, Sakishima S-I. Solar Rankine cycle system using scroll Expander; 2007
[37] Quoilin S, Lemort V, Lebrun J. Experimental study and modeling of an Organic
[38] Leibowitz H, Smith I, Stosic N. Cost-effective small-scale ORC systems for Power recovery from low grade heat sources. In: ASME International Power recovery from low grade heat sources. In: ASME International.
[39] Glavatskaya Y, Podevin P, Lemort V, Shonda O, Descombes G. Reciprocating Expander for an exhaust heat recovery Rankine Cycle for a passenger car Application. Energies 2012; 5(6):1751–65.
[40] Clemente S, Micheli D, Reini M, Taccani R. Bottoming organic Rankine cycle For a small scale gas turbine: a comparison of different solutions. Appl Energy 2013; 106:355–64.
[41] Qiu G, Shao Y, Li J, Liu H, Riffat SB. Experimental investigation of a biomass fired ORC-based micro-CHP for domestic applications. Fuel 2012; 96:374–82.
[42] Rahbar K, Mahmoud S, Al-Dadah R. Mean-line modeling and CFD analysis of a
miniature radial turbine for distributed power generation systems. Int J LowCarbon Technol 2014. Doi: http://dx.doi.org/10.1093/ijlct/ctu028
[43] Kang SH. Design and experimental study of ORC (organic Rankine cycle) a
radial turbine using R245fa working fluid. Energy 2012; 41(1):51
[44] Clemente S, Micheli D, Reini M, Taccani R. Bottoming organic Rankine cycle
for a small-scale gas turbine: a comparison of different solutions. Appl Energy 2013; 106:355–6 4–24
[45] Zhejiang Turbine Import & Export Trade Co., L; 2011. Retrieved 19/07/2014, From <http://www.chinaztc.com/en/productdatils.aspx?id=80&tid= D06B21DFEFB2B52
[46] Zanelli R, Favrat D. Experimental investigation of a hermetic scroll expander generator. In: The 12th international compressor engineering conference, Purdue, US
[47] Kane M, Larrain D, Favrat D, Allani Y. Small hybrid solar power system. Energy 2003; 28(14):1427–43
[48] Peterson RB, Wang H, Herron T. Performance of a small-scale regenerative
Rankine power cycle employing a scroll expander. Proc Inst Mech Eng, Part A: J Power Energy 2008;222(3):271–82
[49] Saitoh T, Yamada N, Wakashima S-I. Solar Rankine cycle system using scroll expander; 200
[50] Mathias JA, Johnston JJR, Cao J, Priedeman DK, Christensen RN. Experimental
testing of gerotor and scroll expanders used in, and energetic and exergetic
modeling of an organic Rankine cycle. J Energy Res Technol 2009; 131(1). 012201-012201
[51] Lemort V, Quoilin S, Cuevas C, Lebrun J. Testing and modeling a scroll
expander integrated into an Organic Rankine Cycle. Appl Therm Eng 2009; 29 (14–15):3094–102
[52] Wang H, Peterson RB, Herron T. Experimental performance of a compliant
scroll expander for an organic Rankine cycle. Proc Inst Mech Eng, Part A: J Power Energy 2009; 223(7):863–72
[53] Lemort V, Declaye S, Quoilin S. Experimental characterization of a hermetic
scroll expander for use in a micro-scale Rankine cycle. Proc Inst Mech Eng, Part A: J Power Energy 2012;226(1):126–36
[2] Sylvain Quoilin, Martijn Van Den Broek, Se ´Bastien Declaye, Pierre Dewallef, Vincent LeMort, “Techno-economic Survey Of Organic Rankine Cycle (ORC) Systems”, ELSEVIER- Renewable And Sustainable Energy Reviews 22 (2013) 168-186, 2013
[3] Fredy Vélez, Farid Chejne and, Ana Quijano, “Thermodynamic analysis of R134a in an Organic Rankine Cycle for power generation from low temperature sources”, DYNA, 2014.
[4] Ngoc Anh Lai, Martin Wendland, Johann Fischer, “Working fluids For High-temperature Organic Rankine Cycles”, Elsevier- Energy 36 (2011) 199-211, 2010
[5] Bala V. Datla, Joost J. Brasz, “Comparing R1233zd and R245fa for Low Temperature ORC applications”, International Refrigeration and Air Conditioning Conference, 2014
[6] X. R. Zhang, H. Yamaguchi and D. Uneno. "Thermodynamic analysis of the CO2-based Rankine cycle powered by solar energy". INTERNATIONAL JOURNAL OF ENERGY RESEARCH Int. J. Energy Res. 2007; 31:1414–14.
[7] M. Chys, M. van den Broek, B. Vanslambrouck, M. De Paepe. "Potential of zeotropic mixtures as working fluids in organic Rankine cycles". Energy 44 (2012) 623-632
[8] MostafaMostafavi- Sani, Sajad Behzadipour, and Pouria Jalilnia" THERMODYNAMIC MODELING AND EXERGY ANALYSIS OF ORGANIC RANKINE CYCLE WITH THE RECEIVER OF THE SUN" International Journal of Latest Research in Science and Technology ISSN (Online):2278-5299 Volume 4, Issue 1: Page No.81-84, January-February 2015
[9] Galloway E, Hebert L. History and progress of the steam engine; with a practical investigation of its structure and application. London: Printed for Kelly; 1836.
[10] Shuman F. The direct acting solar engine - the prime mover of the immediate Future; 1907.
[11] Tabor h, Bronicki L. Small turbine for solar energy power package: Tabor, H. and L. Bronicki, National Physical Laboratory of Israel, United Nations Conference on New Sources of Energy, Rome, 1961, 24 p., Illus... Sol Energy 1963; 7(2):82.
[12] Pytilinski JT. Solar energy installations for pumping irrigation water. Sol Energy 1978; 21(4):255–62.
[13] Curran HM. Organic working fluids in Rankine engines. J Energy 1981; 5 (4):218–23
[14] http://theenergylibrary.com/node/10537
[15] http://gasengine.farmcollector.com/Gas-Engines/The-Naphtha-Engine.aspx
[16] http://www.kgraenergy.com/projects/worldwide-orc-installations
[17] Quoilin S. Sustainable energy conversion through the use of Organic Rankine Cycles for waste heat recovery and solar applications Doctor of Applied Sciences. Liège, Belgium: University of Liège; 2011.
[18] Wang EH, Zhang HG, Fan BY, Ouyang MG, Zhao Y, Mu QH. Study of working Fluid selection of organic Rankine cycle (ORC) for engine waste heat recovery. Energy 2011; 36(5):3406–18.
[19] Wang W, Wu Y-T, Ma C-F, Liu L-D, Yu J. Preliminary experimental study of Single screw expander prototype. Apple Therm Eng. 2011; 31(17–18):3684–8.
[20] Schuster A, Karellas S, Kakaras E, Spliethoff H. Energetic and economic Investigation of Organic Rankine Cycle applications. Apple Therm Eng. 2009; 29 (8–9):1809–17.
[21] Stoppato A. Energetic and economic investigation of the operation Management of an Organic Rankine Cycle cogeneration plant. Energy 2012; 41(1):3–9.
[22] Bao J, Zhao L. A review of working fluid and expander selections for organic Rankine cycle. Renew Sustain Energy Rev 2013; 24:325–42.
[23] Kiyarash Rahbar a,⇑, Saad Mahmoud a, Raya K. Al-Dadah a, Nima Moazami a, Seyed A. Mirhadizadeh b"Review of organic Rankine cycle for small-scale applications"Energy Conversion and Management 134 (2017) 135–155.
[24] Wang W, Wu Y-T, Ma C-F, Liu L-D, Yu J. Preliminary experimental study of Single screw expander prototype. Apple Therm Eng. 2011; 31(17–18):3684–8.
[25] Schuster A, Karellas S, Kakaras E, Spliethoff H. Energetic and economic Investigation of Organic Rankine Cycle applications. Apple Therm Eng. 2009; 29 (8–9):1809–17.
[26] Stoppato A. Energetic and economic investigation of the operation Management of an Organic Rankine Cycle cogeneration plant. Energy 2012; 41(1):3–9.
[27] Bao J, Zhao L. A review of working fluid and expander selections for organic Rankine cycle. Renew Sustain Energy Rev 2013; 24:325–42.
[28] Kiyarash Rahbar a,⇑, Saad Mahmoud a, Raya K. Al-Dadah a, Nima Moazami a, Seyed A. Mirhadizadeh b"Review of organic Rankine cycle for small-scale applications"Energy Conversion and Management 134 (2017) 135–155.
[29] Larjola J. Electricity from industrial waste heat using high-speed organic Rankine cycle (ORC). Int J Prod Econ 1995; 41(1–3):22
[30] Invernizzi C, Iora P, Silva P. Bottoming micro-Rankine cycles for micro-gas Turbines. Appl Therm Eng. 2007; 27(1):100–10.
[31] Tchanche BF, Papadakis G, Lambrinos G, Frangoudakis A. Fluid selection for a Low-temperature solar organic Rankine cycle. Appl Therm Eng 2009; 29(11-12):2468–76-
[32] Li J, Pei G, Li Y, Ji J. Evaluation of external heat loss from a small-scale Expander used in organic Rankine cycle. Appl Therm Eng 2011; 31(1-15):2694–701.
[33] McMahan A. Design and optimization of organic Rankine cycle solar thermal Power plants MSc Thesis. University of Wisconsin-Madison; 200
[34] Qiu G, Liu H, Riffat S. Expanders for micro-CHP systems with organic Rankine Cycle. Appl Therm Eng 2011; 31(16):3301-7
[35] Song P, Wei M, Shi L, Danish SN, Ma C. A review of scroll expanders for Organic Rankine cycle systems. Appl Therm Eng 2015; 75:54–64. Part A: J Power Energy 2012; 226(1):126–36.
[36] Saitoh T, Yamada N, Sakishima S-I. Solar Rankine cycle system using scroll Expander; 2007
[37] Quoilin S, Lemort V, Lebrun J. Experimental study and modeling of an Organic
[38] Leibowitz H, Smith I, Stosic N. Cost-effective small-scale ORC systems for Power recovery from low grade heat sources. In: ASME International Power recovery from low grade heat sources. In: ASME International.
[39] Glavatskaya Y, Podevin P, Lemort V, Shonda O, Descombes G. Reciprocating Expander for an exhaust heat recovery Rankine Cycle for a passenger car Application. Energies 2012; 5(6):1751–65.
[40] Clemente S, Micheli D, Reini M, Taccani R. Bottoming organic Rankine cycle For a small scale gas turbine: a comparison of different solutions. Appl Energy 2013; 106:355–64.
[41] Qiu G, Shao Y, Li J, Liu H, Riffat SB. Experimental investigation of a biomass fired ORC-based micro-CHP for domestic applications. Fuel 2012; 96:374–82.
[42] Rahbar K, Mahmoud S, Al-Dadah R. Mean-line modeling and CFD analysis of a
miniature radial turbine for distributed power generation systems. Int J LowCarbon Technol 2014. Doi: http://dx.doi.org/10.1093/ijlct/ctu028
[43] Kang SH. Design and experimental study of ORC (organic Rankine cycle) a
radial turbine using R245fa working fluid. Energy 2012; 41(1):51
[44] Clemente S, Micheli D, Reini M, Taccani R. Bottoming organic Rankine cycle
for a small-scale gas turbine: a comparison of different solutions. Appl Energy 2013; 106:355–6 4–24
[45] Zhejiang Turbine Import & Export Trade Co., L; 2011. Retrieved 19/07/2014, From <http://www.chinaztc.com/en/productdatils.aspx?id=80&tid= D06B21DFEFB2B52
[46] Zanelli R, Favrat D. Experimental investigation of a hermetic scroll expander generator. In: The 12th international compressor engineering conference, Purdue, US
[47] Kane M, Larrain D, Favrat D, Allani Y. Small hybrid solar power system. Energy 2003; 28(14):1427–43
[48] Peterson RB, Wang H, Herron T. Performance of a small-scale regenerative
Rankine power cycle employing a scroll expander. Proc Inst Mech Eng, Part A: J Power Energy 2008;222(3):271–82
[49] Saitoh T, Yamada N, Wakashima S-I. Solar Rankine cycle system using scroll expander; 200
[50] Mathias JA, Johnston JJR, Cao J, Priedeman DK, Christensen RN. Experimental
testing of gerotor and scroll expanders used in, and energetic and exergetic
modeling of an organic Rankine cycle. J Energy Res Technol 2009; 131(1). 012201-012201
[51] Lemort V, Quoilin S, Cuevas C, Lebrun J. Testing and modeling a scroll
expander integrated into an Organic Rankine Cycle. Appl Therm Eng 2009; 29 (14–15):3094–102
[52] Wang H, Peterson RB, Herron T. Experimental performance of a compliant
scroll expander for an organic Rankine cycle. Proc Inst Mech Eng, Part A: J Power Energy 2009; 223(7):863–72
[53] Lemort V, Declaye S, Quoilin S. Experimental characterization of a hermetic
scroll expander for use in a micro-scale Rankine cycle. Proc Inst Mech Eng, Part A: J Power Energy 2012;226(1):126–36
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Published
2020-01-31
How to Cite
Al-Hamadani , A. A. F., & Kareem, A. H. A. (2020). REVIEW OF ORGANIC RANKINE CYCLE USED IN SMALL- SCALE APPLICATION. International Journal of Engineering Technologies and Management Research, 7(1), 52–63. https://doi.org/10.29121/ijetmr.v7.i1.2020.496
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