Abstract

This paper reviews the work in the areas of optimization and efficiency enhancement of multi-energy systems (MES) for power-to-X conversion. The first study delves into the deployment of Power-to-Hydrogen (PtH2) within district-scale MES, emphasizing the role of PtH2 in achieving zero operational CO2 emissions, especially in systems with high renewable energy generation. The study also highlights the significance of heat pump efficiency, battery capital cost, and lifetime in influencing PtH2 implementation. The second investigation focuses on the integration of energy strategies for the transport and building sectors. It introduces a multi-objective optimization model that considers both sectors, aiming to minimize costs and life-cycle emissions. The findings suggest a potential transition from internal combustion engines to battery electric vehicles and a shift from gas boilers to heat pumps, leading to substantial emission reductions by 2050. Lastly, the third research explores the potential of power-to-gas (P2G) technology in enhancing the integration of renewable energy. By coordinating P2G with CO2-based electrothermal energy storage (ETES), the study demonstrates a significant improvement in the recovery efficiency of surplus wind power. Collectively, these studies underscore the importance of optimizing MES for sustainable and efficient energy conversion.