• Acronym:
    HY-SPIRE
  • Call Id:
    Horizone Europe (HORIZON-JTI-CLEANH2-2023-1)
  • Project No:
    101137866
  • Coordinator:
    Prof. Jakub Kupecki, Full Professor
  • Duration:
    2024-02-01 - 2027-01-31

Partners

  1. Institute of Power Engineering (PL) - koordynator
  2. Technical University of Denmark (DK)
  3. SolydEra SPA (IT)
  4. Deutsches Zentrum fur Luft - und Raumfahrt EV (DE)
  5. EPFL (École polytechnique fédérale de Lausanne) (CH)
  6. Fondazione Bruno Kessler (IT)
  7. Fundacio Institut de Recerca de l’Energia de Catalunya

Description

Optimization of the design and materials of solid oxide cells to reduce start-up time and downtime. Decreasing cell degradation rates through the use of new materials and innovative, easily scalable manufacturing methods, as well as reducing Critical Raw Materials (CRM) content and creating a compact design for SOE stacks.

  • Action towards reducing LCOH to 3 EUR/kg H2 by the year 2030
  • Reduction in electrolyzer size (improving compactness by 15%) for better integrationwith technological processes
  • Significant improvement in the prefomrance dynamics of high-temperaturę electrolyzers
  • Optimalization of the design and materials of solid oxide cells to reduce start-up time and downtime
  • Modification of electrodes to enable operation in electrolysis mode under nominal conditions at a current density > 1,2 A/cm2
  • Decrease in degradation rate below 0,75%/1000 hoursthrough the use of new materials and innovative, easily scalable manufacturing methods
  • Application of thin electrolytes while simultaneously reducing the content of rare earth metals
  • Creating of a compact design for SOE stacks, imporving the heat flow control system and, consequently, its operational dymanics
  • Development of low-temperaturę operating stacks for their integration with renewable energy sources and industrial processes.
  • Demonstration of the full-scale potential of ultra-fast sintering technology, which will shorten manufacturing time and reduce Energy consumption in the production of electrochemical SOE components.
  • Life Cycle Assessment (LCA) of the technology based on two alternative designs of cells and stacks, two types of electrolytes (proton-contuction or anion-conductiong), and manufacturing techniques, as well as innovations applied in SOE stacks.
  • Adaptation of existing and newly developed high-temperaturę electrolyzer testing protocols (e.g., SUSTAINCELL, New SOC, FCTESQA, SOCTESQA) and harmonized testing protocols for the EU (EU harmonized testing protocols for high-temperaturę steam electrolysis, 2023).
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