Combining Wind-Driven Air Compression with Underwater Compressed Air Energy Storage

L. Swinfen-Styles, S. Garvey, D. Giddings
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引用次数: 4

Abstract

Energy storage is quickly becoming a priority in the energy sector as inflexible renewables penetrate further into the energy mix. The opportunity for novel energy storage solutions has therefore never been greater. Generation-Integrated Energy Storage (GIES) holds several key advantages over systems that separate electricity generation and energy storage. Primarily, a reduced number of energy transformations gives rise to the possibility of greatly improved all-round efficiencies. This paper discusses some existing and proposed technologies for energy generation and storage, as well as the potential for integration between them. A GIES system is then presented that takes advantage of the complimentary natures of wind-driven air compression and underwater compressed air energy storage (UWCAES). It is proposed that an adiabatic, liquid-piston air compressor be powered by an offshore wind turbine floating over deep water. The exergy generated by this compression is then stored in two forms: heat in a gravel packed bed and compressed air in a flexible underwater bag. Both of these forms of energy storage are expected to be relatively low-cost, and the system therefore has the opportunity to be considerably cheaper than if the electricity generation and energy storage were separate, such as with conventional wind turbines and battery plants. Using direct-drive compression also removes the need for an expensive geared transmission. However, to prevent the necessarily large swept volumes involved with direct-drive compression of air from ambient pressure, an initial stage of isothermal air compression is used. Consideration is given to several compression technologies in order to achieve this, including the possibility of wave-powered hydraulic air compression. A medium-pressure compressed air energy bag is also employed prior to the adiabatic compression stage to store this medium-pressure air. This has the added advantage of supplying air to the turbine during times of peak demand, reducing the requirement for electric compression during these otherwise expensive periods.
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风力空气压缩与水下压缩空气储能相结合
随着不灵活的可再生能源进一步渗透到能源结构中,能源储存正迅速成为能源部门的优先事项。因此,新型能源存储解决方案的机会从未如此之大。与分离发电和储能的系统相比,发电集成储能(ges)具有几个关键优势。首先,减少能源转换的次数有可能大大提高全方位的效率。本文讨论了一些现有的和拟议的能源生产和存储技术,以及它们之间的集成潜力。然后提出了一种利用风力驱动空气压缩和水下压缩空气储能(UWCAES)互补特性的gis系统。提出了一种由漂浮在深水上的海上风力涡轮机提供动力的绝热液活塞空压机。这种压缩产生的能量以两种形式储存:在砾石充填床中的热量和在柔性水下袋中的压缩空气。这两种形式的能源储存预计都相对低成本,因此该系统有机会比发电和能源储存分开的情况下便宜得多,比如传统的风力涡轮机和电池厂。使用直接驱动压缩也消除了昂贵的齿轮传动的需要。然而,为了防止从环境压力中直接驱动空气压缩所涉及的必然的大扫气量,使用了等温空气压缩的初始阶段。为了实现这一目标,考虑了几种压缩技术,包括波浪动力液压空气压缩的可能性。在绝热压缩阶段之前,还采用中压压缩空气能量袋来储存该中压空气。这样做还有一个额外的好处,就是在需求高峰时向涡轮机提供空气,从而减少了在这些昂贵的时期对电力压缩的需求。
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