Thermal Modeling of Solid Hydrogen Storage in a LaNi5 Metal Hydrid Tank

Mohand Ouyahia Bousseksou; Yucai Lin

doi:10.29228/eng.pers.75265

Thermal Modeling of Solid Hydrogen Storage in a LaNi5 Metal Hydrid Tank

Abstract

This paper presents a detailed 3D model of a solid hydrogen storage tank based on metal hydride LaNi5 technology, utilizing COMSOL Multiphysics 6.1 software. The model takes into account the coupling of momentum, heat, mass and energy transfer within the LaNi5 metal hydride during hydrogen absorption. The main objective of the study is to analyze the temporal evolution of temperature and pressure within the tank as hydrogen is absorbed. In addition, the paper investigates the effectiveness of a cooling strategy involving the integration of cooling tubes into the tank configuration. This approach aims to enhance the thermal management of the storage system by dissipating excess heat generated during hydrogen absorption. Simulation results demonstrate the changes in temperature and pressure occurring within the LaNi5 metal during the process of hydrogen absorption. The implementation of an air-based cooling system emerges as an effective means of regulating the temperature of the storage tank, thus creating optimal conditions for hydrogen absorption processes. This understanding is essential to the development of efficient thermal management solutions for solid hydrogen storage technologies. By comprehensively analyzing the thermal behavior of the LaNi5 metal hydride tank, this numerical study suggests that the efficient design of storage system is very important for rapid absorption of hydrogen.

Keywords

References

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Details

Primary Language

English

Subjects

Electrical Energy Storage, Hybrid and Electric Vehicles and Powertrains

Journal Section

Research Article

Authors

Mohand Ouyahia Bousseksou ^*
France

Yucai Lin This is me
France

Publication Date

March 31, 2024

Submission Date

January 7, 2024

Acceptance Date

March 14, 2024

Published in Issue

Year 2024 Volume: 4 Number: 1

DOI

https://doi.org/10.29228/eng.pers.75265

IZ

https://izlik.org/JA43GX85RU

Cite

RIS / Bibtex

APA

Bousseksou, M. O., & Lin, Y. (2024). Thermal Modeling of Solid Hydrogen Storage in a LaNi5 Metal Hydrid Tank. Engineering Perspective, 4(1), 32-39. https://doi.org/10.29228/eng.pers.75265

AMA

1.Bousseksou MO, Lin Y. Thermal Modeling of Solid Hydrogen Storage in a LaNi5 Metal Hydrid Tank. engineeringperspective. 2024;4(1):32-39. doi:10.29228/eng.pers.75265

Chicago

Bousseksou, Mohand Ouyahia, and Yucai Lin. 2024. “Thermal Modeling of Solid Hydrogen Storage in a LaNi5 Metal Hydrid Tank”. Engineering Perspective 4 (1): 32-39. https://doi.org/10.29228/eng.pers.75265.

EndNote

Bousseksou MO, Lin Y (March 1, 2024) Thermal Modeling of Solid Hydrogen Storage in a LaNi5 Metal Hydrid Tank. Engineering Perspective 4 1 32–39.

IEEE

[1]M. O. Bousseksou and Y. Lin, “Thermal Modeling of Solid Hydrogen Storage in a LaNi5 Metal Hydrid Tank”, engineeringperspective, vol. 4, no. 1, pp. 32–39, Mar. 2024, doi: 10.29228/eng.pers.75265.

ISNAD

Bousseksou, Mohand Ouyahia - Lin, Yucai. “Thermal Modeling of Solid Hydrogen Storage in a LaNi5 Metal Hydrid Tank”. Engineering Perspective 4/1 (March 1, 2024): 32-39. https://doi.org/10.29228/eng.pers.75265.

JAMA

1.Bousseksou MO, Lin Y. Thermal Modeling of Solid Hydrogen Storage in a LaNi5 Metal Hydrid Tank. engineeringperspective. 2024;4:32–39.

MLA

Bousseksou, Mohand Ouyahia, and Yucai Lin. “Thermal Modeling of Solid Hydrogen Storage in a LaNi5 Metal Hydrid Tank”. Engineering Perspective, vol. 4, no. 1, Mar. 2024, pp. 32-39, doi:10.29228/eng.pers.75265.

Vancouver

1.Mohand Ouyahia Bousseksou, Yucai Lin. Thermal Modeling of Solid Hydrogen Storage in a LaNi5 Metal Hydrid Tank. engineeringperspective. 2024 Mar. 1;4(1):32-9. doi:10.29228/eng.pers.75265