液态空气与压缩空气储能结合固体/液体/混合储热

Abstract Present study undertakes a comprehensive thermoeconomic evaluation of Liquid Air Energy Storage (LAES) and Compressed Air Energy Storage (CAES), with a focus on cost implications concerning exergy and energy storage, material containment, and TES units. By addressing previous uncertainties, we aim to enable informed decision-making in the energy sector. The investigation unveils a significant spatial disparity between CAES and LAES systems. CAES allocates considerable space to Compressed Air Storage (CAS), while LAES dedicates a similar volume to TES unit containment as Liquid Air Tanks (LAT). When considering all spatial factors affecting energy density, LAES demonstrates an impressive energy density advantage, surpassing CAES by a factor of 6.9. In the assessment of air storage, we emphasized the importance of cushion gas analysis for underground storage (UG), highlighting the cost-effectiveness of salt caverns, especially for short-term power generation in CAES. In contrast, our analysis of LAES shows that costs increase significantly in systems with lower power capacities, particularly those below 400 MW. Regarding the cost impact of various TES materials, our findings reveal distinct patterns. For CAES, solid TES materials are cost-effective for pressures below 110 bar, while liquid TES materials are more suitable beyond this threshold. In LAES, the dynamics differ. Solid TES materials exhibit considerably higher costs, making hybrid TES, especially at charging and discharging pressures of 150/90 bar, an attractive option, offering a 14 % cost reduction. Our comprehensive evaluation highlights substantially higher storage costs for LAES due to extensive TES material and air storage requirements. Economic analysis indicates that non-storage equipment costs are similar for both technologies, but LAES faces a 3.1 times higher cost for material containment, resulting in a 65 % higher total cost than CAES. The choice between CAES and LAES depends on project-specific needs and budget constraints, with LAES showing exceptional potential, particularly in areas where geological limitations affect CAES feasibility.