Game changer High Temperature Steam Electrolysers
High temperature electrolysers (HTE) can potentially replace fossil energy input with renewable electricity for the generation of hydrogen, for example in refineries and chemical industry, whereby available waste heat from the plant improves the efficiency of the electrolysis process.
This topic is aimed at a step change improvement in high temperature electrolyser technology to enable future commercial introduction.
This improvement can be on the level of the cell, stack or system layout. To develop a wider market, medium term targets for this technology are in relationship with step change and improvement in performances of the technology, trying to overcome some of the actual limiting factors and / or introducing novelties in the cell, stack and system layout able to catch better performances (e.g. current densities, cells and stacks dimensions, stack pressurization).
The improved high temperature electrolyser technology must be tested in a relevant environment.
In agreement to the MAWP, targets related to efficiency, OPEX, pressure, lifetime and cost of hydrogen need to be addressed and fulfilled by the high temperature steam electrolysers covered by that topic.
Proposals should focus on the development, and testing in a relevant environment, of a low-cost, high-temperature electrolyser system, targeting the following improvements which are in line with the MAWP targets, without compromising the other targets included in the MAWP:
- Larger cells and stacks compared with the state of the art, for both atmospheric or pressurized operation: for atmospheric operation a value of at least 50 kW (electrical) per stack is targeted; for pressurized operation, a value of 10 kW (electrical) per stack is targeted;
- Improve total electrical efficiency to above 75% based on higher heating value, in agreement with the MAWP KPI (> 2023 value);
- Cost reduction through use of standard industry components (power electronics, heat exchangers,..), to decrease the cost of the hydrogen produced below 6.9 €/kg, in agreement with the MAWP KPI (2020 value);
- All these improvements being done in conjunction with extended dynamic operation without decreasing the durability.
In addition, the proposal should address at least one of the following optional targets:
- higher flexibility in start / stop, increasing 10 times the SoA performances;
- high pressure electrolysis with hydrogen output pressure of at least 30 bars;
- other step-change improvement in high temperature electrolysis.
The expected electrolysis system, including stack, balance of plant and power electronics, should be developed at a relevant scale. If an atmospheric system is considered, a minimum value of 50 kW electrical is considered, while it should exceed 10 kW in the case of a pressurized system.
Projects should feature:
- Integration of the targeted improvement in a complete electrolyser system;
- Coupling, including thermal management, of the system with a (waste) heat source;
- Demonstration of the system in a relevant environment for at least 2000 hours.
Projects should further include the following analyses:
- a techno-economic analysis of the technology, including projected hydrogen production cost as function of relevant parameters (electricity price, capital cost, stack lifetime, utilisation);
- a life-cycle analysis including CO2 footprint in using the electrolyser;
- recommendations for further development needs for commercialisation.
Testing should be done in accordance to the FCH JU harmonised testing procedures developed by the JRC in collaboration with European industry and researchers.
It is expected that the technology starts at TRL 3 and reaches TRL 5 at the end of the project.
The consortium should include at least one SOEC stack/module manufacturer, research institutions and academic groups.
Termin nadsyłania zgłoszeń
20 kwiecień 2017