Optimization design of an adiabatic compressed air energy storage system with sliding pressure operation and packed bed thermal energy storage based on a one-dimensional loss model

In compressed air energy storage systems, the finite volume of the storage cavern leads to substantial variations in the pressure of the compressed air throughout the operational process. Operating the compressor and expander in sliding pressure mode can effectively reduce exergy losses associated with throttling, thereby improving the overall efficiency of the system. However, in sliding pressure operation mode, the increase in the compressor's outlet temperature introduces substantial exergy losses in traditional dual-tank thermal energy storage due to the mixing of fluids at different temperatures. This study proposes an adiabatic compressed air energy storage system that integrates sliding pressure operation with packed bed thermal energy storage. A onedimensional loss model for the compressor is developed, enabling an analysis of the coupling characteristics under sliding pressure conditions. The developed one-dimensional loss model demonstrates significantly improved accuracy over the general performance model. The optimized compressor, employing inlet guide vane adjustment, mass flow control, and speed regulation, achieves an adiabatic efficiency of over 84.4% under offdesign conditions. Furthermore, the packed bed thermal energy storage in sliding pressure mode has higher efficiency compared to constant pressure operation. Among the various configurations analyzed, the integration of sliding pressure operation with packed bed thermal energy storage demonstrates the highest round trip efficiency of 72.6%, achieving an improvement of 11.6%.