LAPSE:2026.0244
Published Article
LAPSE:2026.0244
Development of a methodology for heat pump-based heat integration in batch processes
June 12, 2026
Abstract
Heat pumps offer the possibility of reducing CO2-emissions in the chemical industry. However, the integration of heat pumps, especially in non-continuous processes, faces several challenges. Energy storage facilitates a way to enhance heat integration by providing a continuous supply of heat flows. By doing so, the question arises as to whether this implementation should be applied to the process or to the utility level. At the process level, there is usually more freedom, as one is not bound by the existing temperature levels of the utility system, which are mostly difficult to retrofit. Therefore, this study presents an approach that generates heat integration concepts at the process level based on two different criteria. These criteria influence which process streams are grouped for a storage implementation and therefore influence the heat integration. The aim is to maintain the heat flows as continuous as possible by integrated heat storages. Finally, the possible heat integration concept is evaluated in terms of energy efficiency by a know method for continuous process streams, here the pinch analysis.
Heat pumps offer the possibility of reducing CO2-emissions in the chemical industry. However, the integration of heat pumps, especially in non-continuous processes, faces several challenges. Energy storage facilitates a way to enhance heat integration by providing a continuous supply of heat flows. By doing so, the question arises as to whether this implementation should be applied to the process or to the utility level. At the process level, there is usually more freedom, as one is not bound by the existing temperature levels of the utility system, which are mostly difficult to retrofit. Therefore, this study presents an approach that generates heat integration concepts at the process level based on two different criteria. These criteria influence which process streams are grouped for a storage implementation and therefore influence the heat integration. The aim is to maintain the heat flows as continuous as possible by integrated heat storages. Finally, the possible heat integration concept is evaluated in terms of energy efficiency by a know method for continuous process streams, here the pinch analysis.
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Wloch J, Grünewald M, Riese J. Development of a methodology for heat pump-based heat integration in batch processes. Systems and Control Transactions 5:334-341 (2026) https://doi.org/10.69997/sct.140728
Author Affiliations
Wloch J: Ruhr University Bochum, Laboratory of Fluid Separations, Bochum, Germany [ORCID]
Grünewald M: Ruhr University Bochum, Laboratory of Fluid Separations, Bochum, Germany [ORCID]
Riese J: Paderborn University, Fluid Process Engineering, Paderborn, Germany [ORCID]
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Grünewald M: Ruhr University Bochum, Laboratory of Fluid Separations, Bochum, Germany [ORCID]
Riese J: Paderborn University, Fluid Process Engineering, Paderborn, Germany [ORCID]
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Journal Name
Systems and Control Transactions
Volume
5
First Page
334
Last Page
341
Year
2026
Publication Date
2026-06-12
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Original Submission
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PII: 0334-0341-185-SCT-5-2026, Publication Type: Journal Article
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LAPSE:2026.0244
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LAPSE:2026.0028
Development of a methodology for he...
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https://doi.org/10.69997/sct.140728
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References Cited
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