Off-Design of a Pumped Thermal Energy Storage Based on Closed Brayton Cycles

Volume 4: Controls, Diagnostics, and Instrumentation; Cycle Innovations; Cycle Innovations: Energy Storage; Education; Electric Power Pub Date : 2021-06-07 DOI:10.1115/gt2021-60185

G. F. Frate, Luigia Paternostro, L. Ferrari, U. Desideri

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引用次数: 2

Abstract

The growth of renewable energy source requires reliable, durable and cheap storage technologies. In this field, the Pumped Thermal Energy Storage (PTES), is drawing some interest as it appears not to be affected by geographical limitations and use very cheap materials. PTES is less efficient than pumped hydro and batteries, but it could achieve satisfactory efficiencies, show better economic performance and be characterized by negligible environmental impacts. A PTES stores the electric energy as thermal exergy in solid packed beds, by operating two closed Brayton cycles, one for charging and the other one for discharging. Although PTES thermodynamical behavior is well understood, the interaction between the components is rarely investigated. This study investigates the impact of packed-bed behavior on turbomachines operating conditions. In this way, PTES off-design and part-load performance are estimated. A control strategy especially suited for closed Brayton cycles, i.e. the inventory control, is used to control the system. As it resulted, PTES is characterized by an excellent part-load performance, which might be a significant advantage over the competing technologies. However, the off-design operation induced by the packed-bed thermal behavior might significantly reduce the system performance and, in particular, that of the discharge phase.

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基于封闭布雷顿循环的抽水蓄能系统的非设计

可再生能源的发展需要可靠、耐用和廉价的存储技术。在这一领域，抽水蓄能(PTES)由于不受地理限制和使用非常便宜的材料而引起了一些兴趣。PTES的效率低于抽水蓄能和电池，但可以达到令人满意的效率，表现出更好的经济效益，并且对环境的影响可以忽略不计。PTES通过运行两个封闭的布雷顿循环(一个用于充电，另一个用于放电)，将电能以热能的形式存储在固体填充床中。虽然PTES的热力学行为被很好地理解，但组分之间的相互作用很少被研究。研究了填料床性能对涡轮机组运行工况的影响。通过这种方法，可以估计PTES的非设计性能和部分负载性能。采用一种特别适用于封闭布雷顿循环的控制策略，即库存控制来控制系统。因此，PTES的特点是具有出色的部分负载性能，这可能是与竞争技术相比的显着优势。然而，由填充床热行为引起的非设计操作可能会显著降低系统性能，特别是放电阶段的性能。

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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来源期刊

Volume 4: Controls, Diagnostics, and Instrumentation; Cycle Innovations; Cycle Innovations: Energy Storage; Education; Electric Power

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