Design of a metalhydride compressor for a hydrogen technology lab

The article describes the necessity of developing an energy source suitable for domestic applications such as photovoltaic panels. Since photovoltaic panels have the highest efficiency during lunch when at least people are present in the home, a suitable energy carrier is needed to store them in hou...

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Hauptverfasser:	Bednárová, Ľubica, Brestovič, Tomáš
Format:	Tagungsbericht
Sprache:	eng
Schlagworte:	Compressing Electrolysis Heat Heat pumps Hydrogen Hydrogen production Hydrogen storage Metal hydrides Panels Photovoltaic cells Residential energy
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creator	Bednárová, Ľubica Brestovič, Tomáš
description	The article describes the necessity of developing an energy source suitable for domestic applications such as photovoltaic panels. Since photovoltaic panels have the highest efficiency during lunch when at least people are present in the home, a suitable energy carrier is needed to store them in household. The paper describes a hydrogen technology laboratory equipped with a photovoltaic system connected to hydrogen production by electrolysis of water. Subsequently, this hydrogen is deposited. In order to increase the amount of deposited hydrogen, a heat pump hydrogen compressor was developed to use the waste heat to absorb hydrogen into the metal hydride. This heat is used to increase the pressure in the absorbed hydrogen reservoir to compress it and release it to a higher degree of compression. Hydralloy C0 and TiCrMn0.55Fe0.3V0.15, whose properties and PCT curves show the desired properties for successful hydrogen compression, are considered in the construction of the compressor. By using the Hydralloy C0 - TiCrMn0.55Fe0.3V0.15 combination, it is possible to increase the hydrogen pressure from about 20 bar to about 200 bar in a temperature range of about from 15 to 65°C. Hydrogen compression with metal hydrides in temperature swing operation is a promising component for future hydrogen systems, as they have the capability of compressing hydrogen to high pressures without moving parts and do not require mechanical energy, but only heat.
doi_str_mv	10.1063/1.5114732
format	Conference Proceeding
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By using the Hydralloy C0 - TiCrMn0.55Fe0.3V0.15 combination, it is possible to increase the hydrogen pressure from about 20 bar to about 200 bar in a temperature range of about from 15 to 65°C. 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source	AIP Journals Complete
subjects	Compressing Electrolysis Heat Heat pumps Hydrogen Hydrogen production Hydrogen storage Metal hydrides Panels Photovoltaic cells Residential energy
title	Design of a metalhydride compressor for a hydrogen technology lab
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