Metal hydride hydrogen and heat storage systems as enabling technology for spacecraft applications

Alexander Reissner; Roland H. Pawelke; Stefan Hummel; Dusan Cabelka; Joachim Gerger; Jarle Farnes; Arild Vik; Ivar Wernhus; Tjalve Svendsen; Max Schautz; Xavier Geneste

doi:10.1016/j.jallcom.2015.03.130

Metal hydride hydrogen and heat storage systems as enabling technology for spacecraft applications

Alexander Reissner
, Roland H. Pawelke
, Stefan Hummel
, Dusan Cabelka
, Joachim Gerger
, Jarle Farnes
, Arild Vik
, Ivar Wernhus
, Tjalve Svendsen
, Max Schautz
, Xavier Geneste

Publikation: Beitrag in Fachzeitschrift › Artikel › peer-review

Abstract

The next generation of telecommunication satellites will demand a platform payload performance in the range of 30+kW within the next 10years. At this high power output, a Regenerative Fuel Cell Systems (RFCS) offers an efficiency advantage in specific energy density over lithium ion batteries. However, a RFCS creates a substantial amount of heat (60–70kJ per mol H2) during fuel cell operation. This requires a thermal hardware that accounts for up to 50% of RFCS mass budget. Thus the initial advantage in specific energy density is reduced. A metal hydride tank for combined storage of heat and hydrogen in a RFCS may overcome this constraint. Being part of a consortium in an ongoing European Space Agency project, FOTEC is building a technology demonstrator for such a combined hydrogen and heat storage system.

Originalsprache	undefiniert/unbekannt
Seiten (von - bis)	S9-S13
Fachzeitschrift	Journal of Alloys and Compounds
Jahrgang	645
DOIs	https://doi.org/10.1016/j.jallcom.2015.03.130
Publikationsstatus	Veröffentlicht - 2015

Zugriff auf Dokument

10.1016/j.jallcom.2015.03.130

https://www.sciencedirect.com/science/article/pii/S0925838815008439

Dieses zitieren

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title = "Metal hydride hydrogen and heat storage systems as enabling technology for spacecraft applications",

abstract = "The next generation of telecommunication satellites will demand a platform payload performance in the range of 30+kW within the next 10years. At this high power output, a Regenerative Fuel Cell Systems (RFCS) offers an efficiency advantage in specific energy density over lithium ion batteries. However, a RFCS creates a substantial amount of heat (60–70kJ per mol H2) during fuel cell operation. This requires a thermal hardware that accounts for up to 50\% of RFCS mass budget. Thus the initial advantage in specific energy density is reduced. A metal hydride tank for combined storage of heat and hydrogen in a RFCS may overcome this constraint. Being part of a consortium in an ongoing European Space Agency project, FOTEC is building a technology demonstrator for such a combined hydrogen and heat storage system.",

keywords = "Metal hydride tank, Hydrogen storage, Reversible fuel cell system, Satellite energy system",

author = "Alexander Reissner and Pawelke, \{Roland H.\} and Stefan Hummel and Dusan Cabelka and Joachim Gerger and Jarle Farnes and Arild Vik and Ivar Wernhus and Tjalve Svendsen and Max Schautz and Xavier Geneste",

note = "Supplement Issue: Proceedings from the 14th International Symposium on Metal-Hydrogen Systems: Fundamentals and Applications, 2014 (MH2014)",

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TY - JOUR

T1 - Metal hydride hydrogen and heat storage systems as enabling technology for spacecraft applications

AU - Reissner, Alexander

AU - Pawelke, Roland H.

AU - Hummel, Stefan

AU - Cabelka, Dusan

AU - Gerger, Joachim

AU - Farnes, Jarle

AU - Vik, Arild

AU - Wernhus, Ivar

AU - Svendsen, Tjalve

AU - Schautz, Max

AU - Geneste, Xavier

N1 - Supplement Issue: Proceedings from the 14th International Symposium on Metal-Hydrogen Systems: Fundamentals and Applications, 2014 (MH2014)

PY - 2015

Y1 - 2015

N2 - The next generation of telecommunication satellites will demand a platform payload performance in the range of 30+kW within the next 10years. At this high power output, a Regenerative Fuel Cell Systems (RFCS) offers an efficiency advantage in specific energy density over lithium ion batteries. However, a RFCS creates a substantial amount of heat (60–70kJ per mol H2) during fuel cell operation. This requires a thermal hardware that accounts for up to 50% of RFCS mass budget. Thus the initial advantage in specific energy density is reduced. A metal hydride tank for combined storage of heat and hydrogen in a RFCS may overcome this constraint. Being part of a consortium in an ongoing European Space Agency project, FOTEC is building a technology demonstrator for such a combined hydrogen and heat storage system.

AB - The next generation of telecommunication satellites will demand a platform payload performance in the range of 30+kW within the next 10years. At this high power output, a Regenerative Fuel Cell Systems (RFCS) offers an efficiency advantage in specific energy density over lithium ion batteries. However, a RFCS creates a substantial amount of heat (60–70kJ per mol H2) during fuel cell operation. This requires a thermal hardware that accounts for up to 50% of RFCS mass budget. Thus the initial advantage in specific energy density is reduced. A metal hydride tank for combined storage of heat and hydrogen in a RFCS may overcome this constraint. Being part of a consortium in an ongoing European Space Agency project, FOTEC is building a technology demonstrator for such a combined hydrogen and heat storage system.

KW - Metal hydride tank

KW - Hydrogen storage

KW - Reversible fuel cell system

KW - Satellite energy system

U2 - 10.1016/j.jallcom.2015.03.130

DO - 10.1016/j.jallcom.2015.03.130

M3 - Article

SN - 0925-8388

VL - 645

SP - S9-S13

JO - Journal of Alloys and Compounds

JF - Journal of Alloys and Compounds

ER -