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Heat exchanger network design of an organic Rankine cycle integrated waste heat recovery system of a marine vessel using pinch point analysis

Heat exchanger network design of an organic Rankine cycle integrated waste heat recovery system of a marine vessel using pinch point analysis
Heat exchanger network design of an organic Rankine cycle integrated waste heat recovery system of a marine vessel using pinch point analysis

The coexistence of different kinds of waste heat sources on marine vessels with various temperature ranges increases the need for an optimal heat exchanger network (HEN) design for the heat collection process to reduce the unutilizable heat that needs to be discharged to overboard. The optimal HEN design has not been taken into consideration by using pinch point analysis in previous studies of marine organic Rankine cycle (ORC) systems that utilize from different kinds of waste heat sources. The objective of the study is to determine the optimal HEN design for an ORC integrated waste heat recovery system of a marine vessel by utilizing the pinch point analysis to improve the overall energy efficiency. Lubricating oil, high-temperature cooling water and scavenge air of the main engine, and the exhaust gas emitted from the boiler plant were identified as the major waste heat sources of a reference container ship. A heat collection stream, in which thermal oil is used as the heat transfer fluid that transfers the collected heat to an ORC system, was proposed. The pinch point analysis showed that the optimum waste heat recovery could be gained by separating the scavenge air cooler into three stages and the lubricating oil cooler into two stages. The results of the parametric study for the varying evaporator inlet pressure between 1000 and 3000 kPa showed that R1234ze(Z) yields the best performance among nine different organic working fluids with the thermal efficiency and exergy efficiency of 15.24% and 86.47% for the ORC system, respectively. For the proposed configuration, the unavailable waste heat that cannot be transferred to thermal oil was found as 23.71%, 16.56%, 13.17%, and 7.81% of the total waste heat produced by the heat sources, and also 8.24%, 9.80%, 11.55%, and 12.93% of the net power output produced by the main engine can be recovered for 25%, 50%, 76%, and 100% maximum continuous rating (MCR), respectively.

exergy, marine engineering, organic Rankine cycle, pinch point analysis, thermodynamic analysis, waste heat recovery
0363-907X
12312-12328
Konur, Olgun
4d099dab-c4ae-4baa-a93a-cf6471c304e6
Saatcioglu, Omur Yasar
08731fb2-f9d9-4aa6-8d84-d66e9a4fd30b
Korkmaz, Suleyman Aykut
959074e1-2ec0-405c-b1ec-eeababef216b
Erdogan, Anil
44025ece-41a7-44a9-ae20-b441af3fa2d7
Colpan, Can Ozgur
b3fce544-afd7-4815-a5cb-d947797a9dbc
Konur, Olgun
4d099dab-c4ae-4baa-a93a-cf6471c304e6
Saatcioglu, Omur Yasar
08731fb2-f9d9-4aa6-8d84-d66e9a4fd30b
Korkmaz, Suleyman Aykut
959074e1-2ec0-405c-b1ec-eeababef216b
Erdogan, Anil
44025ece-41a7-44a9-ae20-b441af3fa2d7
Colpan, Can Ozgur
b3fce544-afd7-4815-a5cb-d947797a9dbc

Konur, Olgun, Saatcioglu, Omur Yasar, Korkmaz, Suleyman Aykut, Erdogan, Anil and Colpan, Can Ozgur (2020) Heat exchanger network design of an organic Rankine cycle integrated waste heat recovery system of a marine vessel using pinch point analysis. International Journal of Energy Research, 44 (15), 12312-12328. (doi:10.1002/er.5212).

Record type: Article

Abstract

The coexistence of different kinds of waste heat sources on marine vessels with various temperature ranges increases the need for an optimal heat exchanger network (HEN) design for the heat collection process to reduce the unutilizable heat that needs to be discharged to overboard. The optimal HEN design has not been taken into consideration by using pinch point analysis in previous studies of marine organic Rankine cycle (ORC) systems that utilize from different kinds of waste heat sources. The objective of the study is to determine the optimal HEN design for an ORC integrated waste heat recovery system of a marine vessel by utilizing the pinch point analysis to improve the overall energy efficiency. Lubricating oil, high-temperature cooling water and scavenge air of the main engine, and the exhaust gas emitted from the boiler plant were identified as the major waste heat sources of a reference container ship. A heat collection stream, in which thermal oil is used as the heat transfer fluid that transfers the collected heat to an ORC system, was proposed. The pinch point analysis showed that the optimum waste heat recovery could be gained by separating the scavenge air cooler into three stages and the lubricating oil cooler into two stages. The results of the parametric study for the varying evaporator inlet pressure between 1000 and 3000 kPa showed that R1234ze(Z) yields the best performance among nine different organic working fluids with the thermal efficiency and exergy efficiency of 15.24% and 86.47% for the ORC system, respectively. For the proposed configuration, the unavailable waste heat that cannot be transferred to thermal oil was found as 23.71%, 16.56%, 13.17%, and 7.81% of the total waste heat produced by the heat sources, and also 8.24%, 9.80%, 11.55%, and 12.93% of the net power output produced by the main engine can be recovered for 25%, 50%, 76%, and 100% maximum continuous rating (MCR), respectively.

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More information

Accepted/In Press date: 13 January 2020
Published date: 30 January 2020
Additional Information: Funding Information: the authors acknowledge the Pinch Team, the Competence Center for Thermal Energy Systems and Process Engineering (CC TEVT) at Hochschule Luzern, for their support on providing the PinCH 3.0 software free of charge for 1 year.
Keywords: exergy, marine engineering, organic Rankine cycle, pinch point analysis, thermodynamic analysis, waste heat recovery

Identifiers

Local EPrints ID: 487094
URI: http://eprints.soton.ac.uk/id/eprint/487094
DOI: doi:10.1002/er.5212
ISSN: 0363-907X
PURE UUID: 1c001e68-39ec-42c9-8a78-94b39c2617cf
ORCID for Suleyman Aykut Korkmaz: ORCID iD orcid.org/0000-0001-5972-6971

Catalogue record

Date deposited: 13 Feb 2024 17:32
Last modified: 18 Mar 2024 04:15

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Contributors

Author: Olgun Konur
Author: Omur Yasar Saatcioglu
Author: Suleyman Aykut Korkmaz ORCID iD
Author: Anil Erdogan
Author: Can Ozgur Colpan

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