A study of working fluids for transcritical pumped thermal energy storage cycles

2019 Offshore Energy and Storage Summit (OSES) Pub Date : 2019-07-01 DOI:10.1109/OSES.2019.8867217

A. Koen, Pau Farres Antunez, A. White

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引用次数: 6

Abstract

Electricity storage is widely regarded as critical to a sustainable energy future, and currently deployed technologies such as pumped hydroelectric storage have drawbacks which limit the scale to which they can be implemented. Pumped thermal energy storage (PTES) has recently started to attract interest as an alternative. This article focuses on transcritical cycles and aims to identify the best working fluids, in a configuration with a single hot store and no cold store. Three different storage media were considered for the hot store: water, Therminol D12, and Therminol 66. For the transcritical cycle, 176 different working fluids were screened for thermodynamic, environmental and safety suitability, and the resulting list of 8 fluids was tested with cycles at a range of storage temperatures. The optimal round-trip efficiency is a trade-off between heat exchanger losses and turbomachinery losses. Pareto fronts were used to rank the fluids for efficiency, power density, and heat to work ratio. The most promising fluid was found to be trifluoroiodomethane (R13I1) with a peak round-trip efficiency of 57.6%.

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跨临界抽水蓄能循环工质研究

电力储存被广泛认为是可持续能源未来的关键，而目前部署的技术，如抽水蓄能，存在限制其实施规模的缺点。抽水蓄能(PTES)作为一种替代方案最近开始引起人们的兴趣。本文的重点是跨临界循环，旨在确定最佳的工作流体，在一个单一的热库，没有冷库的配置。热存储考虑了三种不同的存储介质:水，Therminol D12和Therminol 66。对于跨临界循环，对176种不同的工作流体进行了热力学、环境和安全适用性筛选，并在一系列存储温度下对8种流体进行了循环测试。最佳往返效率是热交换器损失和涡轮机械损失之间的权衡。帕累托前沿被用来对流体的效率、功率密度和热功比进行排序。发现最有希望的流体是三氟碘甲烷(R13I1)，峰值往返效率为57.6%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2019 Offshore Energy and Storage Summit (OSES)

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