Highly energy-eﬃcient combination of dehydrogenation of methylcyclohexane and hydrogen-based power generation

Juangsa, Firman Bagja and Prananto, Lukman Adi and Mufrodi, Zahrul and Budiman, Arief and Oda, Takuya and Aziz, Muhammad (2018) Highly energy-eﬃcient combination of dehydrogenation of methylcyclohexane and hydrogen-based power generation. Applied Energy, 226 (-). pp. 31-38. ISSN ISSN 0306-2619

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Abstract

Hydrogen (H2) has been well studied for its potential use in energy storage, which is particularly related with the intermittent characteristic of renewable energy sources. However, the gas form of H2 at standard pressure and temperature (STP) poses a challenging problem in terms of storage, transportation, and low volumetric energy density. An eﬀective and reversible method for H2 storage is chemically bonded H2 used in the toluene (C7H8)/ methylcyclohexane (MCH, C7H14) cycle. This study investigates a power generation system from H2 storage in MCH, involving the dehydrogenation process and the combined cycle as a power generation process. An ade- quate analysis of the heat circulation was performed through an enhanced process integration (EPI) to ensure the high energy-eﬃciency of the proposed system. A highly endothermic reaction of dehydrogenation was supplied by utilizing the energy/heat from air-fuel combustion to ensure the eﬀective heat recovery of the system. The proposed system was analyzed through an adjustment of the main operating parameters, namely, the GT inlet pressure, GT inlet temperature, and the condenser pressure, to observe their eﬀects on the eﬃciency of the system. It was found that these parameters have a signiﬁcant inﬂuence on the system performance and provide the possibility of further improvement. Under optimum conditions, the proposed system can realize a very high system eﬃciency of 54.6%. Moreover, the proposed system is also compared to a Graz cycle-based system, which has been reported to achieve an excellent power generation cycle from H2. This result implies that the proposed integrated system leads to a signiﬁcantly higher power-generating eﬃciency. Numerically, the proposed system demonstrated a system eﬃciency of 53.7% under similar conditions as the Graz cycle based system, which achieved a system eﬃciency of 22.7%.

Item Type:	Artikel Umum
Subjects:	T Technology > T Technology (General)
Divisi / Prodi:	Faculty of Industrial Technology (Fakultas Teknologi Industri) > S1-Chemical Engineering (S1-Teknik Kimia)
Depositing User:	S.T Zulia Arifah
Date Deposited:	27 Feb 2023 06:33
Last Modified:	27 Feb 2023 06:34
URI:	http://eprints.uad.ac.id/id/eprint/40277

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