Research review and engineering case analysis of geological compressed air energy storage
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摘要: 压缩空气地质储能可为大规模部署风能、太阳能等间歇性清洁能源提供灵活、高效的储能方案,从而促进能源结构转型,加快碳达峰、碳中和战略目标的实现。在介绍压缩空气地质储能概念与分类的基础上,从理论分析、技术方法、经济成本等方面总结了该领域的研究现状与发展趋势,详细叙述了利用盐腔、含水层、枯竭油气田作为储气库的典型储能工程案例及关键参数与经验,分析了压缩空气地质储能在我国的应用前景和不同储气库的特性及其关键影响因素,指出不同类型储气库地质储能的适宜条件,为促进清洁能源可持续开发利用提供科学参考。Abstract: Geological Compressed Air Energy Storage (GCAES) can provide a flexible and efficient energy storage scheme for the large-scale deployment of intermittent clean energy, such as wind energy and solar energy, which could promote the rapid transformation of energy structure and accelerate the realization of carbon emission peak and carbon neutrality strategy. Based on the introduction of the concept and classification of GCAES, the authors have summarized the research status and development trend of GCAES from aspects of theoretical analysis, technical methods and economic cost, and described the key parameters and experience of typical engineering cases of GCAES, including salt caverns, aquifers and exhausted oil and gas fields, in order to analyze the application prospect of GCAES. With the increasing proportion of clean and renewable energy in the power grid, the authors have also explored the characteristics and influence factors of different storage tanks, and put forward their suitable conditions, which could provide some scientific reference for the sustainable development and utilization of clean energy.
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