Dynamic modeling and simulation of advanced nuclear reactor with thermal energy storage

Energy Storage Pub Date : 2024-06-25 DOI:10.1002/est2.672
Seth J. Dana, Aiden S. Meek, Jacob A. Bryan, Manjur R. Basnet, Hailei Wang
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引用次数: 0

Abstract

The increasing installment of solar and wind renewable energy systems create a volatile energy demand to be met by electricity providers. A nuclear hybrid energy system is a nuclear reactor with energy storage that integrates into the grid with renewable energy sources. The Natrium design by TerraPower and GE Hitachi is a sodium fast reactor with molten salt energy storage. The Natrium design operates at steady state of 345 MWe and can boost up to 500 MWe for 5.5 hours. This study uses Dymola and the Modelica language to model the Natrium-based nuclear-renewable hybrid energy system. The dynamic system model is tested using hourly historical data from the state of Texas 2021 to show how renewables affect the electricity demand and how energy storage affects the Natrium system response to the demand. According to the results, while the available storage will allow the Natrium design to boost electricity production when the demand and electricity price is high making it more economically viable, the current molten salt storage is slightly undersized for the ERCOT market.

带热能储存的先进核反应堆的动态建模与模拟
太阳能和风能可再生能源系统的安装量不断增加,导致电力供应商需要满足不稳定的能源需求。核电混合能源系统是一种带有储能装置的核反应堆,与可再生能源一起并入电网。TerraPower 公司和通用电气日立公司设计的 Natrium 是一种带熔盐储能的钠快堆。Natrium 设计的稳态运行功率为 345 兆瓦,可在 5.5 小时内将功率提升至 500 兆瓦。本研究使用 Dymola 和 Modelica 语言对基于 Natrium 的核能-可再生能源混合能源系统进行建模。利用德克萨斯州 2021 年的每小时历史数据对动态系统模型进行了测试,以说明可再生能源如何影响电力需求,以及储能如何影响 Natrium 系统对需求的响应。结果表明,虽然可用的储能将使 Natrium 设计在需求和电价较高时提高发电量,使其更具经济可行性,但目前的熔盐储能在 ERCOT 市场上略显不足。
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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CiteScore
2.90
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0.00%
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