A novel approach to improve the performance of solar-driven Stirling engine using solar-driven ejector cooling cycle
Moh'd Al-Nimr
Department of Mechanical & Industrial Engineering, College of Engineering, Qatar University, Doha, Qatar
Search for more papers by this authorCorresponding Author
Suhil Kiwan
Department of Mechanical Engineering, Jordan University of Science and Technology, Irbid, Jordan
Correspondence
Suhil Kiwan, Department of Mechanical Engineering, Jordan University of Science and Technology, P.O. Box 3030, Irbid 22110, Jordan.
Email: [email protected]
Search for more papers by this authorAshraf Keewan
Department of Mechanical Engineering, Jordan University of Science and Technology, Irbid, Jordan
Search for more papers by this authorMoh'd Al-Nimr
Department of Mechanical & Industrial Engineering, College of Engineering, Qatar University, Doha, Qatar
Search for more papers by this authorCorresponding Author
Suhil Kiwan
Department of Mechanical Engineering, Jordan University of Science and Technology, Irbid, Jordan
Correspondence
Suhil Kiwan, Department of Mechanical Engineering, Jordan University of Science and Technology, P.O. Box 3030, Irbid 22110, Jordan.
Email: [email protected]
Search for more papers by this authorAshraf Keewan
Department of Mechanical Engineering, Jordan University of Science and Technology, Irbid, Jordan
Search for more papers by this authorSummary
In this paper, a novel system to enhance the performance of a solar-driven finite speed alpha-type Stirling engine is proposed and evaluated. Part of the concentrated solar energy is used to drive an ejector refrigeration system. The cooling produced in the ejector cooling cycle is used to cool the Stirling engine to enhance its efficiency. Model equations to describe the systems are proposed and solved numerically. The results indicate that the new system produces averagely 3.3 times electrical power more than the conventional one. Moreover, the proposed system improves the Stirling engine efficiency by up to 46% in comparison with 19.15% for the conventional Stirling engine under solar radiation intensity of (1 kW/m2). Also, the results showed that the solar radiation intensity and wind speed are the most influential parameters that affect the proposed system efficiency. The new system is recommended to use in desert climates where high average daily solar radiation intensity, low wind speeds, and water shortage exist. Economic analysis is carried out to determine the feasibility of the proposed system under different economic parameters. It is found that, for instance, the simple payback period is 4.64 years for the new system when the selling price of electricity is 0.35 $/kWh.
REFERENCES
- 1Kabir E, Kumar P, Kumar S, Adelodun AA, Kim KH. Solar energy: potential and future prospects. Renew Sustain Energy Rev. 2017; 82: 894-900.
- 2Kongtragool B, Wongwises S. A review of solar-powered Stirling engines and low temperature differential Stirling engines. Renew Sustain Energy Rev. 2003; 7(2): 131-154.
- 3Meijer R. A. Arbor and Mich., “Solar powered Stirling engine,” U.S patent 4,707,990, Nov. 24, 1987.
- 4Karabulut H, Yücesu HS, Çinar C, Aksoy F. An experimental study on the development of a β-type Stirling engine for low and moderate temperature heat sources. Appl Energy. 2009; 86(1): 68-73.
- 5Yaqi L, Yaling H, Weiwei W. Optimization of solar-powered Stirling heat engine with finite-time thermodynamics. Renew Energy. 2011; 36(1): 421-427.
- 6Khan J, Arsalan MH. Solar power technologies for sustainable electricity generation—a review. Renew Sustain Energy Rev. 2016; 55: 414-425.
- 7Cheng CH, Yang HS. Theoretical model for predicting thermodynamic behavior of thermal-lag Stirling engine. Energy. 2013; 49(1): 218-228.
- 8Cheng C, Yang H. Optimization of geometrical parameters for Stirling engines based on theoretical analysis. Appl Energy. 2012; 92: 395-405.
- 9Çınar C, Aksoy F, Solmaz H, Yılmaz E, Uyumaz A. Manufacturing and testing of an Α-type Stirling engine. Appl Therm Eng. 2018; 130: 1373-1379.
- 10Lai X, Yu M, Long R, Liu Z, Liu W. Dynamic performance analysis and optimization of dish solar Stirling engine based on a modified theoretical model. Energy. 2019; 183: 573-583.
- 11Martaj N, Rochelle P. 1D modelling of an alpha type Stirling engine. Int J Simul Multidiscip Des Optim. 2014; 5: A07.
10.1051/smdo/2013019 Google Scholar
- 12Almajri AK, Mahmoud S, Al-Dadah R. Modelling and parametric study of an efficient alpha type Stirling engine performance based on 3D CFD analysis. Energy Conver Manag. 2017; 145: 93-106.
- 13Kerdchang P, MaungWin M, Teekasap S, Hirunlabh J, Khedari J, Zeghmati B. Development of a new solar thermal engine system for circulating water for aeration. Sol Energy. 2005; 78(4 SPEC ISS): 518-527.
- 14Cheng CH, Yu YJ. Numerical model for predicting thermodynamic cycle and thermal efficiency of a beta-type Stirling engine with rhombic-drive mechanism. Renew Energy. 2010; 35(11): 2590-2601.
- 15Hooshang M, Askari Moghadam R, AlizadehNia S. Dynamic response simulation and experiment for gamma-type Stirling engine. Renew Energy. 2016; 86: 192-205.
- 16Alfarawi S, Al-Dadah R, Mahmoud S. Enhanced thermodynamic modelling of a gamma-type Stirling engine. Appl Therm Eng. 2016; 106: 1380-1390.
- 17Aksoy F, Karabulut H. Performance testing of a Fresnel/Stirling micro solar energy conversion system. Energy Conver Manag. 2013; 75: 629-634.
- 18Abdollahpour A, Ahmadi MH, Mohammadi AH. Thermodynamic model to study a solar collector for its application to Stirling engines. Energy Conver Manag. 2014; 79: 666-673.
- 19Reddy SR, Ebadian MA, Lin CX. A review of PV-T systems: thermal management and efficiency with single phase cooling. Int J Heat Mass Trans. 2015; 91: 861-871.
- 20Açıkkalp E, Kandemir SY, Ahmadi MH. Solar driven Stirling engine—chemical heat pump—absorption refrigerator hybrid system as environmental friendly energy system. J Environ Manage. 2018; 232: 455-461.
- 21Sheykhi M, Chahartaghi M, Balakheli MM, Kharkeshi BA, Miri SM. Energy, exergy, environmental, and economic modeling of combined cooling, heating and power system with Stirling engine and absorption chiller. Energy Convers Manag. 2018; 180: 183-195.
- 22Marefati M, Mehrpooya M, Mousavi SA. Introducing an integrated SOFC, linear Fresnel solar field, Stirling engine and steam turbine combined cooling, heating and power process. Int J Hydrogen Energy. 2019; 44(57): 30256-30279.
- 23 IIFIIR. 38th Note on Refrigeration Technologies: The Role of Refrigeration in the Global Economy, 2019. p. 12.
- 24Zhai XQ, Qu M, Li Y, Wang RZ. A review for research and new design options of solar absorption cooling systems. Renew Sustain Energy Rev. 2011; 15(9): 4416-4423.
- 25Tashtoush BM, Al-Nimr MA, Khasawneh MA. A comprehensive review of ejector design, performance, and applications. Appl Energy. 2019; 240: 138-172. no May 2018.
- 26Selvaraju A, Mani A. Analysis of an ejector with environment friendly refrigerants. Appl Therm Eng. 2004; 24(5-6): 827-838.
- 27Sun DW. Experimental investigation of the performance characteristics of a steam jet refrigeration system. Energy Source. 1997; 19(4): 349-367.
- 28Huang BJ, Chang JM, Wang CP, Petrenko VA. 1-D analysis of ejector performance. Int J Refrig. 1999; 22(5): 354-364.
- 29Megdouli K, Tashtoush BM, Nahdi E, Elakhdar M, Kairouani L, Mhimid A. Analyse thermodynamique d'un nouveau cycle frigorifique à éjecteur- en cascade pour la congélation et le conditionnement d'air. Int J Refrig. 2016; 70: 108-118.
- 30Tashtoush B, Alshare A, Al-rifai S. Performance study of ejector cooling cycle at critical mode under superheated primary flow. Energy Conver Manag. 2015; 94: 300-310.
- 31Cardemil JM, Colle S. A general model for evaluation of vapor ejectors performance for application in refrigeration. Energy Conver Manag. 2012; 64: 79-86.
- 32Petrenko VO, Volovyk OS. Theoretical study and design of a low-grade heat-driven pilot ejector refrigeration machine operating with butane and isobutane and intended for cooling of gas transported in a gas-main pipeline. Int J Refrig. 2011; 34(7): 1699-1706.
- 33Tashtoush BM, Al-nimr MA, Khasawneh MA. Investigation of the use of nano-refrigerants to enhance the performance of an ejector refrigeration system. Appl Energy. 2017; 206: 0-1. no September.
- 34Rusly E, Aye L, Charters WWS, Ooi A. CFD analysis of ejector in a combined ejector cooling system. Int J Refrig. 2005; 28(7): 1092-1101.
- 35Riffat SB, Omer SA. CFD modelling and experimental investigation of an ejector refrigeration system using methanol as the working fluid. Int J Energy Res. 2001; 25(2): 115-128.
- 36Al-Nimr MA, Tashtoush B, Hasan A. A novel hybrid solar ejector cooling system with thermoelectric generators. Energy. 2020; 198:117318.
- 37Al-Nimr MA, Khashan S, and Omar I, A hybrid integrated solar system, 2020. Submitted for publication
- 38Philibert C. The Present and Future Use of Solar Thermal Energy as a Primary Source of Energy. International Energy Agency, Paris, France: The InterAcademy Council, 2005; 2018. http://www.iea.org/textbase/papers/2005/solarthermal.pdf.
- 39Jamil U, Ali W. Performance tests and efficiency analysis of Solar Invictus 53S-A parabolic dish solar collector for direct steam generation. AIP Conf Proc. 2016; 1734: 231-295.
- 40Al-Dafaie AMA, Dahdolan ME, Al-Nimr MA. Utilizing the heat rejected from a solar dish Stirling engine in potable water production. Sol Energy. 2016; 136: 317-326.
- 41Harrod J, Mago PJ, Luck R. Sizing analysis of a combined cooling, heating, and power system for a small office building using a wood waste biomass-fired Stirling engine. Int J Energy Res. 2012; 36: 64-74.
- 42In S, Jeong S, Kim H. Investigation on liquid helium pressurization process using a heater in a liquid propellant rocket. Cryogenics (Guildf). 2004; 44(6-8): 467-474.
- 43Demir ME, Dincer I. Development and analysis of a new integrated solar energy system with thermal storage for fresh water and power production. Int J Energy Res. 2018; 42(9): 2864-2874.
- 44Micheli L, Reddy KS, Mallick TK. Thermal effectiveness and mass usage of horizontal micro-fins under natural convection. Appl Therm Eng. 2016; 97: 39-47.
- 45Jakob M, Hawkins GA. Elements of Heat Transfer. 3rd ed. New York, NY & London: John Wiley & Sons Inc. & Chapman and Hall Ltd.; 1957: xxv + 317.
- 46Bellos E, Tzivanidis C, Antonopoulos KA, Gkinis G. Thermal enhancement of solar parabolic trough collectors by using nanofluids and converging-diverging absorber tube. Renew Energy. 2016; 94: 213-222.
- 47Aidoun Z, Ouzzane M. The effect of operating conditions on the performance of a supersonic ejector for refrigeration. Int J Refrig. 2004; 27(8): 974-984.
- 48Abdulateef JM, Murad NM, Alghoul MA, Zaharim A, and Sopian K. Economic analysis of combined solar-assisted ejector absorption refrigeration system. Recent Res. Geogr. Geol. Energy, Environ. Biomed.—Proc. 4th WSEAS Int. Conf. EMESEG'11, 2nd Int. Conf. WORLD-GEO'11, 5th Int. Conf. EDEB'11, no. April 2015; 2011. pp. 157–161.
- 49Etier I, Al A, Ababne M. Analysis of solar radiation in Jordan. Jordan J Mech Ind Eng. 2010; 4(6): 733-738.
