The condensing engine: A heat engine for operating temperatures of 100 ℃ and below

The cost-effective utilisation of low-grade thermal energy with temperatures below 150 ℃ for electricity generation still constitutes an engineering challenge. Existing technology, e.g. the organic Rankine cycle machines, are complex and only economical for larger power outputs. At Southampton Unive...

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Bibliographic Details
Published in:Proceedings of the Institution of Mechanical Engineers. Part A, Journal of power and energy Journal of power and energy, 2018-06, Vol.232 (4), p.437-448
Main Authors: Müller, Gerald, Chan, Chun Ho, Gibby, Alexander, Nazir, Muhammad Zubair, Paterson, James, Seetanah, Joshua, Telfer, Matthew, Tsuzaki, Toru, Walker, Caleb, Yusof, Faris
Format: Article
Language:English
Subjects:
Condensation
Pressure loss
Rankine cycle
Steam electric power generation
Thermal energy
Thermal utilization
Working fluids
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Summary:The cost-effective utilisation of low-grade thermal energy with temperatures below 150 ℃ for electricity generation still constitutes an engineering challenge. Existing technology, e.g. the organic Rankine cycle machines, are complex and only economical for larger power outputs. At Southampton University, the steam condensation cycle for a working temperature of 100 ℃ was analysed theoretically. The cycle uses water as working fluid, which has the advantages of being cheap, readily available, non-toxic, non-inflammable and non-corrosive, and works at and below atmospheric pressure, so that leakage and sealing are not problematic. Steam expansion will increase the theoretical efficiency of the cycle from 6.4% (no expansion) to 17.8% (expansion ratio 1:8). In this article, the theoretical development of the cycle is presented. A 40 Watt experimental engine was built and tested. Efficiencies ranged from 0.02 (no expansion) to 0.055 (expansion ratio 1:4). The difference between theoretical and experimental efficiencies was attributed to significant pressure loss in valves, and to difficulties with heat rejection. It was concluded that the condensing engine has potential for further development.
ISSN:0957-6509
2041-2967
DOI:10.1177/0957650917736455