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Comparison of the dynamic characteristics and performance of beta-type Stirling engines operating with different driving mechanisms

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  • Yang, Hang-Suin
  • Zhu, Hao-Qiang
  • Xiao, Xian-Zhong

Abstract

In 1816, Robert Stirling proposed the first beta-type Stirling engine (BTSE) which have been extensively used in renewable energy. In BTSEs, the displacer and piston are coaxially arranged, resulting in a more compact design and a higher power density. In this study, the dynamic characteristics and performance of BTSEs with five driving mechanisms, namely, slider crank, rhombic drive, Ross yoke, bell crank, and Scotch yoke mechanisms, were investigated. Variations in the thermal properties of the working fluid in BTSEs were predicted using a thermodynamic model. The dynamic models of the five mechanisms were presented, and friction losses due to the piston rings, sliders, bearings, and seals were considered. The thermal properties of the working fluid and the dynamic behavior of the driving mechanisms were investigated. The instantaneous variations in the displacement of the moving components and engine speed were obtained, and the indicated power, shaft power, total friction loss, and mechanical efficiency of BTSEs with the five mechanisms were compared. The results indicated that the trajectories of the piston and displacer considerably affected the performance of BTSEs. Additionally, BTSEs with the bell crank mechanism produced the highest shaft power (1533 W) at 550 rpm, with a mechanical efficiency of 80.5%.

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  • Yang, Hang-Suin & Zhu, Hao-Qiang & Xiao, Xian-Zhong, 2023. "Comparison of the dynamic characteristics and performance of beta-type Stirling engines operating with different driving mechanisms," Energy, Elsevier, vol. 275(C).
    • Handle: RePEc:eee:energy:v:275:y:2023:i:c:s0360544223009295
    DOI: 10.1016/j.energy.2023.127535
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    References listed on IDEAS

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    1. Sripakagorn, Angkee & Srikam, Chana, 2011. "Design and performance of a moderate temperature difference Stirling engine," Renewable Energy, Elsevier, vol. 36(6), pages 1728-1733.
    2. Cheng, Chin-Hsiang & Yang, Hang-Suin, 2011. "Analytical model for predicting the effect of operating speed on shaft power output of Stirling engines," Energy, Elsevier, vol. 36(10), pages 5899-5908.
    3. Yang, Hang-Suin & Cheng, Chin-Hsiang & Huang, Shang-Ting, 2018. "A complete model for dynamic simulation of a 1-kW class beta-type Stirling engine with rhombic-drive mechanism," Energy, Elsevier, vol. 161(C), pages 892-906.
    4. DeLaquil, Pascal, 1996. "Progress commercializing solar-electric power systems," Renewable Energy, Elsevier, vol. 8(1), pages 489-494.
    5. Zhu, Shunmin & Yu, Guoyao & Liang, Kun & Dai, Wei & Luo, Ercang, 2021. "A review of Stirling-engine-based combined heat and power technology," Applied Energy, Elsevier, vol. 294(C).
    6. Schneider, T. & Müller, D. & Karl, J., 2020. "A review of thermochemical biomass conversion combined with Stirling engines for the small-scale cogeneration of heat and power," Renewable and Sustainable Energy Reviews, Elsevier, vol. 134(C).
    7. Rokni, Masoud, 2014. "Thermodynamic and thermoeconomic analysis of a system with biomass gasification, solid oxide fuel cell (SOFC) and Stirling engine," Energy, Elsevier, vol. 76(C), pages 19-31.
    8. Karabulut, Halit & Yücesu, Hüseyin Serdar & ÇInar, Can & Aksoy, Fatih, 2009. "An experimental study on the development of a [beta]-type Stirling engine for low and moderate temperature heat sources," Applied Energy, Elsevier, vol. 86(1), pages 68-73, January.
    9. Cheng, Chin-Hsiang & Yang, Hang-Suin, 2012. "Optimization of geometrical parameters for Stirling engines based on theoretical analysis," Applied Energy, Elsevier, vol. 92(C), pages 395-405.
    10. Cinar, Can & Yucesu, Serdar & Topgul, Tolga & Okur, Melih, 2005. "Beta-type Stirling engine operating at atmospheric pressure," Applied Energy, Elsevier, vol. 81(4), pages 351-357, August.
    11. Altin, Murat & Okur, Melih & Ipci, Duygu & Halis, Serdar & Karabulut, Halit, 2018. "Thermodynamic and dynamic analysis of an alpha type Stirling engine with Scotch Yoke mechanism," Energy, Elsevier, vol. 148(C), pages 855-865.
    12. Rokni, Masoud, 2014. "Biomass gasification integrated with a solid oxide fuel cell and Stirling engine," Energy, Elsevier, vol. 77(C), pages 6-18.
    Full references (including those not matched with items on IDEAS)

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