Converting low-temperature waste heat into hydrogen energy through four different organic cycle setups: A comparative techno-economic analysis

Converting low-temperature waste heat into hydrogen energy through four different organic cycle setups: A comparative techno-economic analysis

A large amount of low-temperature heat is wasted in industrial processes and energy conversion systems, which can be converted into useful energy by utilizing various technologies. Hence, the present study provides a comparison among four low-temperature organic cycles to convert such waste heat int...

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Main Authors: Chou-Yi Hsu, Shaikh Hasibul Majid, Ali G. Alkhathami, Hitmi Khalifa Alhitmi, T. Ramachandran, Munthir Abdulwahid Abdulhussain, Aman Shankhyan, A. Karthikeyan, Dhirendra Nath Thatoi, Hamed Habibi
Format: Article
Language:English
Published: Elsevier 2025-09-01
Series:Case Studies in Thermal Engineering
Subjects:
Low-temperature waste heat
Clean hydrogen
Partial evaporating organic Rankine cycle
Organic flash cycle
Trilateral cycle
Organic flash regenerative cycle
Online Access:http://www.sciencedirect.com/science/article/pii/S2214157X25008718
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Summary:A large amount of low-temperature heat is wasted in industrial processes and energy conversion systems, which can be converted into useful energy by utilizing various technologies. Hence, the present study provides a comparison among four low-temperature organic cycles to convert such waste heat into hydrogen energy. Partial evaporating organic Rankine cycle (PEORC), organic flash cycle (OFC), trilateral cycle (TLC), and organic flash regenerative cycle (OFRC) are compared at the optimal operating point from thermodynamic and economic viewpoints. A thermoelectric generator is employed in the four cycles to recover the heat lost during the condensation process into electricity. The total electricity generated by each cycle is converted into hydrogen through a proton exchange membrane electrolyzer. Exergy efficiency (ηex), specific cost of hydrogen production (chydrogen), and levelized cost of hydrogen (LCOH) are the output parameters in the comparative analysis. The OFRC-based system has the highest ηex (30.77 %) and the second-lowest LCOH (4.66 $kg−1). The PEORC-based system brings about an acceptable ηex (27.39 %), the lowest LCOH (4.08 $kg−1), and the lowest chydrogen (157.8 $GJ−1). The TLC-based system causes the second-highest ηex (30.21 %) and the second-lowest chydrogen (169.1 $GJ−1). The OFC-based system has the weakest performance among the four configurations.
ISSN:2214-157X

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