Flexible energy conversion and storage via high-temperature gas-phase reactions: The piston engine as a polygeneration reactor

Piston engines are typically considered devices converting chemical energy into mechanical power via internal combustion. But more generally, their ability to provide high-pressure and high-temperature conditions for a limited time means they can be used as chemical reactors where reactions are init...

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Bibliographic Details
Published in:Renewable & sustainable energy reviews 2020-11, Vol.133, p.110264, Article 110264
Main Authors: Atakan, Burak, Kaiser, Sebastian A., Herzler, Jürgen, Porras, Sylvia, Banke, Kai, Deutschmann, Olaf, Kasper, Tina, Fikri, Mustapha, Schießl, Robert, Schröder, Dominik, Rudolph, Charlotte, Kaczmarek, Dennis, Gossler, Hendrik, Drost, Simon, Bykov, Viatcheslav, Maas, Ulrich, Schulz, Christof
Format: Article
Language:English
Subjects:
Engine
HCCI
Kinetics
Methane
Polygeneration
Thermodynamics
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Summary:Piston engines are typically considered devices converting chemical energy into mechanical power via internal combustion. But more generally, their ability to provide high-pressure and high-temperature conditions for a limited time means they can be used as chemical reactors where reactions are initiated by compression heating and subsequently quenched by gas expansion. Thus, piston engines could be “polygeneration” reactors that can flexibly change from power generation to chemical synthesis, and even to chemical-energy storage. This may help mitigating one of the main challenges of future energy systems – accommodating fluctuations in electricity supply and demand. Investments in devices for grid stabilization could be more economical if they have a second use. This paper presents a systematic approach to polygeneration in piston engines, combining thermodynamics, kinetics, numerical optimization, engineering, and thermo-economics. A focus is on the fuel-rich conversion of methane as a fuel that is considered important for the foreseeable future. Starting from thermodynamic theory and kinetic modeling, promising systems are selected. Mathematical optimization and an array of experimental kinetic investigations are used for model improvement and development. To evaluate technical feasibility, experiments are then performed in both a single-stroke rapid compression machine and a reciprocating engine. In both cases, chemical conversion is initiated by homogeneous-charge compression-ignition. A thermodynamic and thermo-economic assessment of the results is positive. Examples that illustrate how the piston engine can be used in polygeneration processes to convert methane to higher-value chemicals or to take up carbon dioxide are presented. Open issues for future research are addressed. •Piston engines can be efficiently used for polygeneration of chemicals, work, and heat.•Methods of combustion science were used to address new targets.•Combining kinetics, thermodynamics, optimization, and thermo-economics yields new synergies.•Chemical energy storage and reforming processes are feasible with piston engines.•The low reactivity of methane as a base fuel can be increased with additives.
ISSN:1364-0321
1879-0690
DOI:10.1016/j.rser.2020.110264