4.7 Article Proceedings Paper

Dynamic optimization of a cogeneration plant for an industrial application with two different hydrogen embedding solutions

Journal

INTERNATIONAL JOURNAL OF HYDROGEN ENERGY
Volume 47, Issue 24, Pages 12204-12218

Publisher

PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.ijhydene.2021.10.118

Keywords

Hydrogen; Natural gas; ICE; Cogeneration; Fuel cells

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This paper presents a numerical study and optimization of a cogeneration plant installed in an industrial site, focusing on seasonal storage of hydrogen to meet energy needs and reduce environmental impact. Two alternatives are analyzed, and the dynamic response and economic analysis are conducted to evaluate their performance.
Seasonal storage of hydrogen is a valuable option today increasingly considered in order to optimize cogeneration plants under continuous operation in an incentive framework where electricity sale to the national grids is becoming less economically profitable than in the past. The paper concerns the numerical study and optimization of a cogeneration plant installed in an industrial site having an availability of hydrogen over a continuous time scale, to meet the energy needs and mitigating the environmental impact of the plant operation by reducing the energy withdrawal from traditional sources. Two alternatives are analyzed into detail: the former regards energy production through an internal combustion engine, this last properly controlled to be fueled with blends of natural gas and increasing percentages of hydrogen, the latter concerning the addition of fuel cells to the proposed layout to further reduce the electricity integration by the grid. The dynamic response of the cogeneration system under examination is dynamically evaluated to efficiently fulfill the industrial loads to be fulfilled. First, optimization is performed by implementing a PID controller to better track the industrial demand of electric energy. The main results of this solution reveal a-81% reduction of excess electricity, a-7% reduction of natural gas consumed but a 47% raise of CO2 emissions due to the increase in thermal integration. Then, an additional energy generation from fuel cells is assumed. An economic analysis is carried out for each of the implemented configurations. The adoption of fuel cells, despite requiring a greater initial investment, allows obtaining a SPB of 1,4 years (-16%), 1,17 Mln V of avoided costs (-18,5%) and 1320 t/year of CO2 emissions avoided (-95%) with respect to the initial layout. (c) 2021 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.

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