Skip to Main content Skip to Navigation
Journal articles

A 70 MPa hydrogen thermally driven compressor based on cyclic adsorption-desorption on activated carbon

Abstract : In this study, we compressed hydrogen up to 70 MPa in a non-mechanical device based on cyclic, thermally driven, hydrogen adsorption/desorption on activated carbon (AC). Hydrogen compression comes from the desorption of a pre-adsorbed amount of hydrogen at 77 K on a bed of AC closely packed in high-pressure reservoir. A prototype of 0.5 L containing an AC (MSC-30, Kansai, Japan) having a BET area higher than 3000 m2 g−1 and a volume of micropores around 1 cm3 g−1, was used. The effect of the AC amount, the hydrogen charging pressure and the temperature of desorption on the compression performances was investigated, both experimentally and numerically. Hydrogen was introduced at 8 MPa and pre-adsorbed on 0.135 kg of MSC-30 at 77K. A high-pressure hydrogen flow, up to 28 NL h−1 at 70 MPa, was obtained in a single step when heating the compressor from 77 to 315 K. We proved that high surface area, large volume of micropores, as well as very narrow pores, are the essential requirements for any AC to be used in such compressor. The use of microporous AC in a thermally driven device for hydrogen compression, based on cyclic adsorption/desorption, had never been investigated before. This innovative system might solve several issues hindering the development of the hydrogen supply chain
Complete list of metadatas

https://hal.univ-lorraine.fr/hal-02484434
Contributor : Giuseppe Sdanghi <>
Submitted on : Sunday, December 6, 2020 - 12:09:22 PM
Last modification on : Thursday, February 25, 2021 - 11:05:04 AM

File

70MPa_manuscript_CARBON_revise...
Files produced by the author(s)

Licence


Distributed under a Creative Commons Attribution - NonCommercial - NoDerivatives 4.0 International License

Identifiers

Citation

Giuseppe Sdanghi, Nicolas Vincent, Kevin Mozet, Sébastien Schaefer, Gaël Maranzana, et al.. A 70 MPa hydrogen thermally driven compressor based on cyclic adsorption-desorption on activated carbon. Carbon, Elsevier, 2020, 161, pp.466-478. ⟨10.1016/j.carbon.2020.01.099⟩. ⟨hal-02484434⟩

Share

Metrics

Record views

109

Files downloads

73