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Isobaric Expansion Engines: New Opportunities in Energy Conversion for Heat Engines, Pumps and Compressors

Author

Listed:
  • Maxim Glushenkov

    (Encontech B.V. ET/TE, P.O. Box 217, 7500 AE Enschede, The Netherlands)

  • Alexander Kronberg

    (Encontech B.V. ET/TE, P.O. Box 217, 7500 AE Enschede, The Netherlands)

  • Torben Knoke

    (Chair of Fluid Process Engineering, Paderborn University, Pohlweg 55, 33098 Paderborn, Germany)

  • Eugeny Y. Kenig

    (Chair of Fluid Process Engineering, Paderborn University, Pohlweg 55, 33098 Paderborn, Germany
    Chair of Thermodynamics and Heat Engines, Gubkin Russian State University of Oil and Gas, Leninsky Prospekt 65, Moscow 119991, Russia)

Abstract

Isobaric expansion (IE) engines are a very uncommon type of heat-to-mechanical-power converters, radically different from all well-known heat engines. Useful work is extracted during an isobaric expansion process, i.e., without a polytropic gas/vapour expansion accompanied by a pressure decrease typical of state-of-the-art piston engines, turbines, etc. This distinctive feature permits isobaric expansion machines to serve as very simple and inexpensive heat-driven pumps and compressors as well as heat-to-shaft-power converters with desired speed/torque. Commercial application of such machines, however, is scarce, mainly due to a low efficiency. This article aims to revive the long-known concept by proposing important modifications to make IE machines competitive and cost-effective alternatives to state-of-the-art heat conversion technologies. Experimental and theoretical results supporting the isobaric expansion technology are presented and promising potential applications, including emerging power generation methods, are discussed. It is shown that dense working fluids with high thermal expansion at high process temperature and low compressibility at low temperature make it possible to operate with reasonable thermal efficiencies at ultra-low heat source temperatures (70–100 °C). Regeneration/recuperation of heat can increase the efficiency notably and extend the area of application of these machines to higher heat source temperatures. For heat source temperatures of 200–600 °C, the efficiency of these machines can reach 20–50% thus making them a flexible, economical and energy efficient alternative to many today’s power generation technologies, first of all organic Rankine cycle (ORC).

Suggested Citation

  • Maxim Glushenkov & Alexander Kronberg & Torben Knoke & Eugeny Y. Kenig, 2018. "Isobaric Expansion Engines: New Opportunities in Energy Conversion for Heat Engines, Pumps and Compressors," Energies, MDPI, vol. 11(1), pages 1-22, January.
    • Handle: RePEc:gam:jeners:v:11:y:2018:i:1:p:154-:d:125923
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    References listed on IDEAS

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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. Yanbo Xie & Diederik Bos & Lennart J. de Vreede & Hans L. de Boer & Mark-Jan van der Meulen & Michel Versluis & Ad J. Sprenkels & Albert van den Berg & Jan C. T. Eijkel, 2014. "High-efficiency ballistic electrostatic generator using microdroplets," Nature Communications, Nature, vol. 5(1), pages 1-5, May.
    3. Oyewunmi, Oyeniyi A. & Kirmse, Christoph J.W. & Haslam, Andrew J. & Müller, Erich A. & Markides, Christos N., 2017. "Working-fluid selection and performance investigation of a two-phase single-reciprocating-piston heat-conversion engine," Applied Energy, Elsevier, vol. 186(P3), pages 376-395.
    4. Bao, Junjiang & Zhao, Li, 2013. "A review of working fluid and expander selections for organic Rankine cycle," Renewable and Sustainable Energy Reviews, Elsevier, vol. 24(C), pages 325-342.
    5. Tom Krupenkin & J. Ashley Taylor, 2011. "Reverse electrowetting as a new approach to high-power energy harvesting," Nature Communications, Nature, vol. 2(1), pages 1-8, September.
    6. Kirmse, Christoph J.W. & Oyewunmi, Oyeniyi A. & Taleb, Aly I. & Haslam, Andrew J. & Markides, Christos N., 2017. "A two-phase single-reciprocating-piston heat conversion engine: Non-linear dynamic modelling," Applied Energy, Elsevier, vol. 186(P3), pages 359-375.
    7. Quoilin, Sylvain & Broek, Martijn Van Den & Declaye, Sébastien & Dewallef, Pierre & Lemort, Vincent, 2013. "Techno-economic survey of Organic Rankine Cycle (ORC) systems," Renewable and Sustainable Energy Reviews, Elsevier, vol. 22(C), pages 168-186.
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    Cited by:

    1. Sander Roosjen & Maxim Glushenkov & Alexander Kronberg & Sascha Kersten, 2022. "Waste Heat Recovery Systems with Isobaric Expansion Technology Using Pure and Mixed Working Fluids," Energies, MDPI, vol. 15(14), pages 1-14, July.
    2. Alexander Kronberg & Maxim Glushenkov & Sander Roosjen & Sascha Kersten, 2023. "Isobaric Expansion Engines–Compressors: Thermodynamic Analysis of Multistage Vapor Driven Compressors," Energies, MDPI, vol. 16(19), pages 1-15, September.

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