Abstract
One of the key issues in the energy production sector worldwide is the efficient way to storage energy. Currently- more and more attention is focused on Power-to-Gas (P2G) installations- where excess electric power from the grid or various renewable energy sources is used to produce different kind of fuels- such as hydrogen. In such cases- generated fuels are treated as energy carriers which- in contrast to electricity- can be easy stored and transported. Currently- high temperature electrolysers- based solid oxide cells (SOC)- are treated as an interesting alternative for P2G systems. Solid oxide electrolysers (SOE) are characterized as highly efficient (~90%) and long-term stable technologies- which can be coupled with stationary power plants. In the current work- the solid oxide cell stack was operated in electrolysis mode in the endothermic conditions. Based on the gathered experimental data- the numerical model of the SOC stack was created and validated. The prepared and calibrated model was used for generation of stack performance maps for different operating conditions. The results allowed to determine optimal working conditions for the tested stack in the electrolysis mode- thus reducing potential costs of expensive experimental analysis and test campaigns.
Highlights
More attention in power and energy sector is focused on minimizing the wide usage of fossil fuels, mainly due to their negative impact on the environment
The numerical model of the stack has undergone a validation process, based on the data gathered during measurements on the Solid oxide electrolysers (SOE) module with two 30-cell stacks connected electrically in series
The experiments were performed in the electrolysis mode, operating mainly in the endothermic conditions
Summary
More attention in power and energy sector is focused on minimizing the wide usage of fossil fuels, mainly due to their negative impact on the environment. The most commonly used technologies world-wide are solar and wind based power systems. Many specialists treats hydrogen as the gas of the future, which can be used as one of the main substrates in creating different and more calorific fuels, or directly convert it as the main power source for production of energy. This technologies are highly suggested for application in systems aiming to minimize pollution emissions to the atmosphere
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