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Assessment of the Newcomen engine’s development potential as heat engine for low temperature waste heat

Assessment of the Newcomen engine’s development potential as heat engine for low temperature waste heat
Assessment of the Newcomen engine’s development potential as heat engine for low temperature waste heat
There is a large but mostly unused energy resource available from low temperature waste heat with temperatures of 80 to 150 °C. The lack of a cost-effective technology prevents the generation of power from this potential. Recently, the Condensing Engine, which employs the condensation of steam and the arising vacuum as the driving force, had been developed to address this problem. Its simplicity and the use of water as working fluid promises cost-effectiveness. In the context of this work, it was decided to investigate the Newcomen Engine to assess its potential. This engine is usually neglected because of is low efficiency, thought to be caused by the continuous cooling and re-heating of the cylinder. A thermodynamic model of the engine was developed. Surprisingly, the model indicated that 78 % of the heat losses are caused by the re-heating of the injection water and only 22 % by the cooling and re-heating of the cylinder. This finding allowed to conceptualise a new engine, the Internal Condensation Engine, where plastic material for the cylinder and the forced ejection of the water minimise losses. The engine would have a similar or better efficiency than competitive technologies whilst being simpler, and therefore more cost-effective.
Energy conversion / recovery, Condensing Engine, Atmospheric Engine
0957-6509
1577-1584
Muller, Gerald
f1a988fc-3bde-429e-83e2-041e9792bfd9
Mereš, Branislav
ca6cdca9-2883-4331-bdab-ca22c7af3670
Muller, Gerald
f1a988fc-3bde-429e-83e2-041e9792bfd9
Mereš, Branislav
ca6cdca9-2883-4331-bdab-ca22c7af3670

Muller, Gerald and Mereš, Branislav (2023) Assessment of the Newcomen engine’s development potential as heat engine for low temperature waste heat. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy, 237 (7), 1577-1584. (doi:10.1177/09576509231173476).

Record type: Article

Abstract

There is a large but mostly unused energy resource available from low temperature waste heat with temperatures of 80 to 150 °C. The lack of a cost-effective technology prevents the generation of power from this potential. Recently, the Condensing Engine, which employs the condensation of steam and the arising vacuum as the driving force, had been developed to address this problem. Its simplicity and the use of water as working fluid promises cost-effectiveness. In the context of this work, it was decided to investigate the Newcomen Engine to assess its potential. This engine is usually neglected because of is low efficiency, thought to be caused by the continuous cooling and re-heating of the cylinder. A thermodynamic model of the engine was developed. Surprisingly, the model indicated that 78 % of the heat losses are caused by the re-heating of the injection water and only 22 % by the cooling and re-heating of the cylinder. This finding allowed to conceptualise a new engine, the Internal Condensation Engine, where plastic material for the cylinder and the forced ejection of the water minimise losses. The engine would have a similar or better efficiency than competitive technologies whilst being simpler, and therefore more cost-effective.

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Muller Meres 2023 - Accepted Manuscript
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More information

Accepted/In Press date: 17 April 2023
Published date: 16 May 2023
Keywords: Energy conversion / recovery, Condensing Engine, Atmospheric Engine

Identifiers

Local EPrints ID: 499736
URI: http://eprints.soton.ac.uk/id/eprint/499736
ISSN: 0957-6509
PURE UUID: d13cf204-ed90-4400-9964-949902a04bb5
ORCID for Gerald Muller: ORCID iD orcid.org/0000-0003-1631-7777

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Date deposited: 01 Apr 2025 16:50
Last modified: 02 Apr 2025 01:41

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Contributors

Author: Gerald Muller ORCID iD
Author: Branislav Mereš

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