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Assessment of the Stirling engine performance comparing two renewable energy sources: Solar energy and biomass

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  • Ferreira, Ana Cristina
  • Silva, João
  • Teixeira, Senhorinha
  • Teixeira, José Carlos
  • Nebra, Silvia Azucena

Abstract

The paper addresses the assessment of the Stirling engine performance by comparing biomass and solar energy as external renewable energy sources. A program-code was developed in the MatLab® to solve the thermal model of an alpha-Stirling engine, accounting for the limitations in the heat transfer processes in the regenerator and the losses due to pumping effects. The solar energy source was modelled as a concentric solar dish collector, considering a receiver located at the focal point and designed to absorb the maximum possible of the solar radiation. Regarding the biomass system, the temperature of the flue gases leaving the bed is computed through an energy balance, considering the fuel energy introduced into the bed, the energy that is provided by the bed and the incident radiation in the bed. The simulation results show that the biomass-fuelled Stirling engine provided 87.5% more power output than the solar energy source, with an efficiency of 46.67%. Also, the average receiver temperature from the solar source is about 775 K, whereas, in the boiler bed, the temperature reaches the value of 1288 K. In the solar-dish modelling, the reflected radiation that passes into the cavity receiver depends on the aperture ratio and rim angle. It was proved that a rim angle of at least 45° is required to ensure lower focal distances. Otherwise, the Stirling receiver needs to be far from the surface of the dish, resulting in higher thermal losses and lower temperature inside the receiver cavity. In biomass-fuelled system, it was shown that the temperature of the flue gases increases with the increasing the radiation flux, and decreases for higher split percentages between the primary and secondary air. The study also revealed the need to investigate the combustion stability regarding the particle emission in the flue gas, which can reduce the temperature close to the hot cylinder of the Stirling engine. The LCoE for the solar-power system is of about 1658 €/kWh, which is 52% higher when compared with the biomass-fuelled system (0.109 €/kWh). In conclusion, biomass-fuelled Stirling engines are able to provide a higher power output with higher thermal efficiency, avoiding the problems usually related to solar energy intermittency.

Suggested Citation

  • Ferreira, Ana Cristina & Silva, João & Teixeira, Senhorinha & Teixeira, José Carlos & Nebra, Silvia Azucena, 2020. "Assessment of the Stirling engine performance comparing two renewable energy sources: Solar energy and biomass," Renewable Energy, Elsevier, vol. 154(C), pages 581-597.
    • Handle: RePEc:eee:renene:v:154:y:2020:i:c:p:581-597
    DOI: 10.1016/j.renene.2020.03.020
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    1. Kongtragool, Bancha & Wongwises, Somchai, 2006. "Thermodynamic analysis of a Stirling engine including dead volumes of hot space, cold space and regenerator," Renewable Energy, Elsevier, vol. 31(3), pages 345-359.
    2. Connolly, D. & Lund, H. & Mathiesen, B.V., 2016. "Smart Energy Europe: The technical and economic impact of one potential 100% renewable energy scenario for the European Union," Renewable and Sustainable Energy Reviews, Elsevier, vol. 60(C), pages 1634-1653.
    3. Campos, M.C. & Vargas, J.V.C. & Ordonez, J.C., 2012. "Thermodynamic optimization of a Stirling engine," Energy, Elsevier, vol. 44(1), pages 902-910.
    4. Ahmadi, Mohammad H. & Ahmadi, Mohammad-Ali & Pourfayaz, Fathollah, 2017. "Thermal models for analysis of performance of Stirling engine: A review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 68(P1), pages 168-184.
    5. Timoumi, Youssef & Tlili, Iskander & Ben Nasrallah, Sassi, 2008. "Design and performance optimization of GPU-3 Stirling engines," Energy, Elsevier, vol. 33(7), pages 1100-1114.
    6. Alanne, Kari & Saari, Arto, 2004. "Sustainable small-scale CHP technologies for buildings: the basis for multi-perspective decision-making," Renewable and Sustainable Energy Reviews, Elsevier, vol. 8(5), pages 401-431, October.
    7. Huang, Junpeng & Fan, Jianhua & Furbo, Simon & Chen, Daochuan & Dai, Yanjun & Kong, Weiqiang, 2019. "Economic analysis and optimization of combined solar district heating technologies and systems," Energy, Elsevier, vol. 186(C).
    8. Kongtragool, Bancha & Wongwises, Somchai, 2003. "A review of solar-powered Stirling engines and low temperature differential Stirling engines," Renewable and Sustainable Energy Reviews, Elsevier, vol. 7(2), pages 131-154, April.
    9. Puech, Pascal & Tishkova, Victoria, 2011. "Thermodynamic analysis of a Stirling engine including regenerator dead volume," Renewable Energy, Elsevier, vol. 36(2), pages 872-878.
    10. Thombare, D.G. & Verma, S.K., 2008. "Technological development in the Stirling cycle engines," Renewable and Sustainable Energy Reviews, Elsevier, vol. 12(1), pages 1-38, January.
    11. Maraver, Daniel & Sin, Ana & Royo, Javier & Sebastián, Fernando, 2013. "Assessment of CCHP systems based on biomass combustion for small-scale applications through a review of the technology and analysis of energy efficiency parameters," Applied Energy, Elsevier, vol. 102(C), pages 1303-1313.
    12. Rogdakis, E.D. & Antonakos, G.D. & Koronaki, I.P., 2012. "Thermodynamic analysis and experimental investigation of a Solo V161 Stirling cogeneration unit," Energy, Elsevier, vol. 45(1), pages 503-511.
    13. Wang, Kui & Zhang, Yuanyuan & Sekelj, Gasper & Hopke, Philip K., 2019. "Economic analysis of a field monitored residential wood pellet boiler heating system in New York State," Renewable Energy, Elsevier, vol. 133(C), pages 500-511.
    14. Ferreira, Ana C. & Nunes, Manuel L. & Teixeira, José C.F. & Martins, Luís A.S.B. & Teixeira, Senhorinha F.C.F., 2016. "Thermodynamic and economic optimization of a solar-powered Stirling engine for micro-cogeneration purposes," Energy, Elsevier, vol. 111(C), pages 1-17.
    15. Barbieri, Enrico Saverio & Spina, Pier Ruggero & Venturini, Mauro, 2012. "Analysis of innovative micro-CHP systems to meet household energy demands," Applied Energy, Elsevier, vol. 97(C), pages 723-733.
    16. Ehtiwesh, Ismael A.S. & Coelho, Margarida C. & Sousa, Antonio C.M., 2016. "Exergetic and environmental life cycle assessment analysis of concentrated solar power plants," Renewable and Sustainable Energy Reviews, Elsevier, vol. 56(C), pages 145-155.
    17. González, Arnau & Riba, Jordi-Roger & Puig, Rita & Navarro, Pere, 2015. "Review of micro- and small-scale technologies to produce electricity and heat from Mediterranean forests׳ wood chips," Renewable and Sustainable Energy Reviews, Elsevier, vol. 43(C), pages 143-155.
    18. Bianchi, Michele & De Pascale, Andrea & Spina, Pier Ruggero, 2012. "Guidelines for residential micro-CHP systems design," Applied Energy, Elsevier, vol. 97(C), pages 673-685.
    19. Timoumi, Youssef & Tlili, Iskander & Ben Nasrallah, Sassi, 2008. "Performance optimization of Stirling engines," Renewable Energy, Elsevier, vol. 33(9), pages 2134-2144.
    20. Podesser, Erich, 1999. "Electricity production in rural villages with a biomass Stirling engine," Renewable Energy, Elsevier, vol. 16(1), pages 1049-1052.
    21. Badami, M. & Camillieri, F. & Portoraro, A. & Vigliani, E., 2014. "Energetic and economic assessment of cogeneration plants: A comparative design and experimental condition study," Energy, Elsevier, vol. 71(C), pages 255-262.
    22. Salomón, Marianne & Savola, Tuula & Martin, Andrew & Fogelholm, Carl-Johan & Fransson, Torsten, 2011. "Small-scale biomass CHP plants in Sweden and Finland," Renewable and Sustainable Energy Reviews, Elsevier, vol. 15(9), pages 4451-4465.
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    3. Krzysztof Sornek, 2020. "Prototypical Biomass-Fired Micro-Cogeneration Systems—Energy and Ecological Analysis," Energies, MDPI, vol. 13(15), pages 1-16, July.
    4. Mahdavi, Navid & Mojaver, Parisa & Khalilarya, Shahram, 2022. "Multi-objective optimization of power, CO2 emission and exergy efficiency of a novel solar-assisted CCHP system using RSM and TOPSIS coupled method," Renewable Energy, Elsevier, vol. 185(C), pages 506-524.
    5. David García & María-José Suárez & Eduardo Blanco & Jesús-Ignacio Prieto, 2022. "Experimental and Numerical Characterisation of a Non-Tubular Stirling Engine Heater for Biomass Applications," Sustainability, MDPI, vol. 14(24), pages 1-17, December.
    6. Li, Jie & Chang, Guozhang & Song, Ke & Hao, Bolun & Wang, Cuiping & Zhang, Jian & Yue, Guangxi & Hu, Shugang, 2023. "Influence of coal bottom ash additives on catalytic reforming of biomass pyrolysis gaseous tar and biochar/steam gasification reactivity," Renewable Energy, Elsevier, vol. 203(C), pages 434-444.
    7. Shulin Wang & Baiao Liu & Gang Xiao & Mingjiang Ni, 2021. "A Potential Method to Predict Performance of Positive Stirling Cycles Based on Reverse Ones," Energies, MDPI, vol. 14(21), pages 1-25, October.
    8. İncili, Veysel & Karaca Dolgun, Gülşah & Georgiev, Aleksandar & Keçebaş, Ali & Çetin, Numan Sabit, 2022. "Performance evaluation of novel photovoltaic and Stirling assisted hybrid micro combined heat and power system," Renewable Energy, Elsevier, vol. 189(C), pages 129-138.
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