FUEL CYCLE IMPLICATIONS OF DEPLOYING HTGRS IN HYBRID ENERGY SYSTEMS AS RESERVE POWER GENERATION IN ONTARIO

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CNL Nuclear Review Pub Date : 2021-01-01 DOI:10.12943/cnr.2020.00002

D. Wojtaszek, S. Golesorkhi

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Abstract

Nuclear power plants could potentially be deployed in a type of nuclear hybrid energy system (NHES) in which their power is used primarily to drive an industrial process but can be diverted to meet demands for electricity when needed. The purpose of this study is to analyze the effects of deploying NHESs as reserve power for the transmission grid in Ontario on the overall Canadian fuel cycle. In this scenario, the fuel cycle demands of 2 high-temperature gas-cooled reactor (HTGR) concepts are analyzed with respect to costs, resource consumption, and enrichment requirements. One HTGR concept is a 30 MW-thermal (MWth) reactor that is based on the UBattery concept, and the other is the Xe-100, which is a 200 MWth reactor. Calculations indicate that such a deployment of HTGRs would have a substantial effect on the fuel cycle in Canada. In particular, NU and enrichment demands would be greatly affected. Beginning this HTGR deployment in the year 2030 would more than double the annual NU demands in Canada, and deplete the uranium resources with extraction costs of <$80/kgU by the year 2142. The uranium enrichment demands of this fleet would be >35% of the US capacity for uranium enrichment.

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安大略省在混合能源系统中部署HTGRS作为备用发电的燃料循环影响

核电站可能部署在一种核混合能源系统(NHES)中，其中它们的电力主要用于驱动工业过程，但可以在需要时转移以满足电力需求。本研究的目的是分析部署NHESs作为安大略省输电网的备用电源对整个加拿大燃料循环的影响。在这种情况下，从成本、资源消耗和浓缩要求方面分析了2种高温气冷堆(HTGR)概念的燃料循环需求。一个HTGR概念是基于UBattery概念的30兆瓦热(MWth)反应堆，另一个是x -100，这是一个200兆瓦的反应堆。计算表明，这种htgr的部署将对加拿大的燃料循环产生重大影响。特别是铀浓缩需求将受到很大影响。在2030年开始HTGR部署将使加拿大每年的NU需求增加一倍以上，并且以美国铀浓缩能力的35%的开采成本耗尽铀资源。

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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CNL Nuclear Review NUCLEAR SCIENCE & TECHNOLOGY-

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