世界上第一个并网UWCAES设施的瞬态热力学分析

M. Ebrahimi, R. Carriveau, D. Ting, A. McGillis, Davin Young
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引用次数: 2

摘要

多伦多水下压缩空气储能(UWCAES)设施的经验表明,该技术比最初预期的更加通用。除了典型的稳态运行之外,在其运行的暂态阶段可以承担潜在的有价值的辅助网格服务角色。本研究探讨了在UWCAES斜坡事件期间有效运行所面临的挑战。在这里,对位于加拿大多伦多的世界上第一个并网UWCAES设施进行了传统和先进的火用分析。常规的火用分析表明,在实际工况下,电厂启动时的火用效率较低。在不可避免的条件下,暂态阶段开始后2分钟的火用破坏率为42%,渐近降低至25%。通过完整的充放电循环对火用效率进行的高级分析表明,首先要优先考虑热交换器组。其次是辅助、压缩机、涡轮机、电机、发电机和管道组。在火能破坏率方面,分析表明压缩机组的改进优先级高于热交换器组,其次是辅助设备组、电动机和发电机组、涡轮机组和管道组。先进的火用分析还显示,67%的火用破坏是内生的和可避免的,突出了性能改进的巨大潜力。此外,研究还表明,随着系统各组成部分效率的提高,电厂的火用效率可以得到外源提高。这种效果可以进一步减少总火能破坏76%,其中只有9%是由于组件-组件相互作用。
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Transient Thermodynamic Assessment of the World's First Grid Connected UWCAES Facility by Exergy Analysis
Experience with Toronto's Underwater Compressed Air Energy Storage (UWCAES) facility has shown the technology to be more versatile than originally anticipated. Beyond typical steady-state operations, potentially valuable ancillary grid service roles can be assumed in the transient phase of its operation. This study examines the challenge to operate efficiently during UWCAES ramping events. A conventional and advanced exergy analysis is here conducted for the world's first grid connected UWCAES facility located in Toronto, Canada. A conventional exergy analysis showed that under real working conditions, the exergy efficiency of the plant is low during start-up. The exergy destruction rate, under unavoidable conditions, 2 minutes after the start of the transient phase is 42%, and this decreases asymptotically to 25%. An advanced analysis of exergy efficiency through a complete charge/discharge cycle suggested that the first improvement priority be given to the Heat Exchangers group. This should then be followed by the Ancillary, Compressor, Turbine, Motors and Generator and Pipelines groups. In terms of the rate of exergy destruction the analysis indicated that improvement priority for the Compressor group was higher than that for Heat Exchangers followed by Ancillary, Motors and Generator, Turbine and Pipelines groups. The advanced exergy analysis also revealed that 67% of the exergy destruction was endogenous and avoidable, highlighting the significant potential for performance improvement. Moreover, it was shown that with improvement in the system's component efficiencies, the plant exergy efficiency could be exogenously improved. This effect could further reduce the total exergy destruction to 76%, where only 9% is due to component-component interaction.
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