Summary
For space missions, the energy density of batteries is a key factor of systems mass.
A recent battery technology, based on this Lithium-Sulfur chemistry and developed by OXIS Energy, has shown promising results, particularly in terms of specific energy and cycling performances. Lithium-Sulfur batteries could become the next breakthrough technology for space batteries, with a factor of two on the specific energy compared to the current Lithium-Ion products.
ECLIPSE ambition is to channel the research activities in Europe and, as a spinning-in effort, ensure that the harsh space constraints are taken into account for the further improvements of the Li-S technology. This research action aimed at developing Li-S technology for space applications focusing on three levels:
- Cell level studies, including research to optimise the four main cells components: anode, cathode, separator and electrolyte to achieve 400Wh/kg cells compatible with space cycling profiles.
- Battery and encapsulation level, including prototyping and theoretical studies.
- System level studies for integration in satellite and launcher architectures, taking into account the economic constraints and the future technical challenges.
The expected outcomes of ECLIPSE are:
- Mass reduction of batteries by a factor two.
- Costs reduction at all levels: subsystem, system and launching costs.
- Maturation of the technology (TRL 5 expected at the end of the project).
The main impacts of this research are related to competitiveness (lighter is cheaper), non-dependency and innovation: beyond current markets, this breakthrough can enable new challenging missions.
The impact of the project is secured by the composition of the consortium led by Airbus Defence and Space with the main European actors of the Lithium-Sulfur electrochemistry and space batteries: ECLIPSE will contribute to the consolidation of an independent European industrial supply chain for Lithium-Sulfur batteries.
Project duration is 24 months.
A recent battery technology, based on this Lithium-Sulfur chemistry and developed by OXIS Energy, has shown promising results, particularly in terms of specific energy and cycling performances. Lithium-Sulfur batteries could become the next breakthrough technology for space batteries, with a factor of two on the specific energy compared to the current Lithium-Ion products.
ECLIPSE ambition is to channel the research activities in Europe and, as a spinning-in effort, ensure that the harsh space constraints are taken into account for the further improvements of the Li-S technology. This research action aimed at developing Li-S technology for space applications focusing on three levels:
- Cell level studies, including research to optimise the four main cells components: anode, cathode, separator and electrolyte to achieve 400Wh/kg cells compatible with space cycling profiles.
- Battery and encapsulation level, including prototyping and theoretical studies.
- System level studies for integration in satellite and launcher architectures, taking into account the economic constraints and the future technical challenges.
The expected outcomes of ECLIPSE are:
- Mass reduction of batteries by a factor two.
- Costs reduction at all levels: subsystem, system and launching costs.
- Maturation of the technology (TRL 5 expected at the end of the project).
The main impacts of this research are related to competitiveness (lighter is cheaper), non-dependency and innovation: beyond current markets, this breakthrough can enable new challenging missions.
The impact of the project is secured by the composition of the consortium led by Airbus Defence and Space with the main European actors of the Lithium-Sulfur electrochemistry and space batteries: ECLIPSE will contribute to the consolidation of an independent European industrial supply chain for Lithium-Sulfur batteries.
Project duration is 24 months.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/687306 |
| Start date: | 01-12-2015 |
| End date: | 30-11-2017 |
| Total budget - Public funding: | 999 953,75 Euro - 999 953,00 Euro |
Cordis data
Original description
For space missions, the energy density of batteries is a key factor of systems mass.A recent battery technology, based on this Lithium-Sulfur chemistry and developed by OXIS Energy, has shown promising results, particularly in terms of specific energy and cycling performances. Lithium-Sulfur batteries could become the next breakthrough technology for space batteries, with a factor of two on the specific energy compared to the current Lithium-Ion products.
ECLIPSE ambition is to channel the research activities in Europe and, as a spinning-in effort, ensure that the harsh space constraints are taken into account for the further improvements of the Li-S technology. This research action aimed at developing Li-S technology for space applications focusing on three levels:
- Cell level studies, including research to optimise the four main cells components: anode, cathode, separator and electrolyte to achieve 400Wh/kg cells compatible with space cycling profiles.
- Battery and encapsulation level, including prototyping and theoretical studies.
- System level studies for integration in satellite and launcher architectures, taking into account the economic constraints and the future technical challenges.
The expected outcomes of ECLIPSE are:
- Mass reduction of batteries by a factor two.
- Costs reduction at all levels: subsystem, system and launching costs.
- Maturation of the technology (TRL 5 expected at the end of the project).
The main impacts of this research are related to competitiveness (lighter is cheaper), non-dependency and innovation: beyond current markets, this breakthrough can enable new challenging missions.
The impact of the project is secured by the composition of the consortium led by Airbus Defence and Space with the main European actors of the Lithium-Sulfur electrochemistry and space batteries: ECLIPSE will contribute to the consolidation of an independent European industrial supply chain for Lithium-Sulfur batteries.
Project duration is 24 months.
Status
CLOSEDCall topic
COMPET-03-2015Update Date
27-10-2022
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Organisations
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| AIRBUS DEFENCE AND SPACE SAS (Coördinator)
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| ARIANEGROUP SAS
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| COMMISSARIAT A L ENERGIE ATOMIQUE ET AUX ENERGIES ALTERNATIVES (CEA)
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| FRAUNHOFER GESELLSCHAFT ZUR FOERDERUNG DER ANGEWANDTEN FORSCHUNG E.V.
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| IMPERIAL COLLEGE OF SCIENCE, TECHNOLOGY AND MEDICINE
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| OXIS ENERGY LIMITED
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| SAFT
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| SOLVAY SA
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| SOLVAY SPECIALTY POLYMERS ITALY SPA
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| SPACETEC CAPITAL GMBH
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| SPACETEC PARTNERS SRL
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| Vysoke uceni technicke v Brne