Development of hydrogen storage reactor using composite of metal hydride materials with ENG

Autor:	Young-Sik Park, Kyoung Soo Kang, Seong Uk Jeong, Yong Hyun Lee, Kwangjin Jung, Byung Heung Park, Chu Sik Park
Rok vydání:	2020
Předmět:	Energy carrier Materials science Hydrogen Renewable Energy Sustainability and the Environment Hydride business.industry Nuclear engineering Energy Engineering and Power Technology chemistry.chemical_element Context (language use) 02 engineering and technology 010402 general chemistry 021001 nanoscience & nanotechnology Condensed Matter Physics 01 natural sciences Isothermal process 0104 chemical sciences Hydrogen storage Fuel Technology chemistry Hydrogen economy Water cooling 0210 nano-technology business
Zdroj:	International Journal of Hydrogen Energy. 45:27434-27442
ISSN:	0360-3199
DOI:	10.1016/j.ijhydene.2020.07.062
Popis:	Hydrogen is widely accepted as a promising energy carrier replacing fossil fuels. In this context hydrogen storage is one of the critical challenges in realizing hydrogen economy which relies on hydrogen as the commercial fuel. Due to very low volumetric energy density of pure hydrogen, it is highly compressed as a gas phase or liquified at extremely low temperature. However, chemically combined state in other materials has advantages in terms of storage conditions and associated safety concerns. The present study focuses on a development of a hydrogen storage applicable to special fuel cell (FC) mobilities such as forklift but not limited to. We adopts a solid-state storage method using metal hydride composite prepared by processing La0.9Ce0.1Ni5 and extended natural graphite (ENG). The isothermal hydrogen absorption/desorption behavior of the composite is measured at 20–80 °C. The results suggest that around 10 bar is sufficient to store 1.2 wt% of hydrogen. A cylindrical reactor is manufactured and experiments are carried out with the fabricated hydrogen storage material by changing operation conditions. The results of satisfaction are obtained in terms of the amount of hydrogen storage (>83 standard liter) and the absorption time (~10 min) under relatively moderate conditions of temperature (~19 °C) and pressure (~11 bar). As for scaling-up, a reactor of 2.0 kWh is designed based on the experimental results. CFD analysis is performed based on the hottest operation conditions focusing on a cooling water flow. The flow pattern and the temperature distribution of the cooling water are expected to be adequate not deviating from the stable operating conditions. CFD would be further applied to optimize the incorporated modular reactors.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_________::ca4c88cea11c9855cc75270766ca2ba4 https://doi.org/10.1016/j.ijhydene.2020.07.062 Zobrazit plný text záznamu Full Text from ScienceDirect