The exploitation of renewable energy sources such as wind, water, and solar energy has become one of the priorities of the modern energy sector across the globe. However, renewable sources cannot solely be used due to their intermittent nature, meaning that there are periods when supply exceeds demand and vice versa. Solid Oxide Electrolysis Cell (SOEC) systems are electrochemical energy conversion devices capable of converting electrical energy into carbon-free hydrogen. Hydrogen can be stored and potentially re-used as fuel for fuel cells to be re-converted into electrical energy. SOEC systems operate at high temperatures and have a unique property that the same device can operate in the reverse mode, i.e. as a Solid Oxide Fuel Cell (the so-called rSOC).
Despite their attractive features, SOC systems (a common term for SOEC, SOFC, and rSOC) are still not massively present in in-field applications. To ensure that SOC systems operate reliably, and efficiently and deliver hydrogen or electric power when required, an accurate assessment of their performance, health, and life span is necessary. That was the topic at the heart of the REACTT project (Figure 1).
The overall objectives of the REACTT project were the following:
1. Improve durability, reliability, and maintainability of SOEC and rSOC stacks by developing innovative algorithms for diagnostics and prognostics of lifetime;
2. Develop the advanced control strategy with self-optimizing and fault-tolerant features;
3. Develop the hardware module for implementation of the monitoring, diagnostics, prognostics, and control functions; and
4. Perform characterization of stacks and systems in SOE and rSOC nominal and faulty conditions and validation of the product prototype.