ECo delivered four improved cell versions and verified them at cell & stack level. They take advantage of existing materials and manufacturing paths, which facilitates implementation into large-scale production. ECo results paved the way for further improvements not only by developing better cells but also by increasing the understanding of the detailed durability behavior of cells & stacks under relevant conditions. The project showed that operating windows exist that allow for low degradation rates of less than 1% per 1000 h on cell/stack level, and in some cases rates of zero. The ECo project demonstrated that going from ideal laboratory to more realistic operating modes does not increase degradation. A system test integrating improved ECo cells reached an exceptional high efficiency of 94% (based on higher heating value).
A Power-to-Methane plant design allows identifying SOE system parameters to achieve a given output like gas production or efficiency. Three types of industrial plants were identified for integration with the modelled Power-to-Methane process (“ECo concept”) with the aid of main players in the respective sectors:
- Cement plant with oxy combustion CO2 capture:
The ECo concept supplies the needed oxygen. Methane formed through the ECo concept substitutes part of the fossil fuel needed for cement production. The benefits are thus reduction of fossil fuel use and of CO2 emissions.
- Biomass gasification plant:
The ECo concept boosts the methane production of this plant through using the CO2 bi-product.
- Biogas plant for methane production:
The methane output is doubled by using the ECo concept because the inherent CO2 in the biogas mixture is converted into methane. CO2 is thus valorized and emission avoided.
A techno-economic assessment used these three specific cases. Access to cheap and CO2-lean electricity is crucial for the economic viability. Some European countries already have a high share of renewable electricity in the grid and an integration with the ECo concept is thus attractive. Moving – as planned - to fossil-free electricity production will enhance the economic advantages.
The LCA compared the three cases mentioned above with the base case (the plants without the ECo system). The ECo concept yields benefits in all three cases, granted the right local context. The highest benefits arise in the cement plant case study with savings of up to 240.000 tons CO2-eqivalent annually. These savings will only increase with the increasing decarbonization of the electricity grid.
The ECo concept and results were lively disseminated to a broad community, including the public, the industry, and the scientific community (19 conference contributions, 13 peer-review articles), as well as the policy makers (popular articles). The used media involved public events, the Hannover Fair, visits, posters and oral presentations, website, brochure, social media, workshops, video and more. In that way, the communication has reached a large variety of audience at different knowledge and influential levels.
Exploitation of the results is within reach for a number of SOE players. In particular, a workshop jointly organized by EU ECo and the EU GrInHy projects illustrates the immense attention by attracting 40 experts from 8 European countries, from 9 research and 8 industrial players, who exchanged views on status, progress, and critical issues on the path of SOE towards the market.