核电站与化石燃料发电装置相结合的热循环回路研究

IF 0.9 Q4 ENERGY & FUELS
V. O. Kindra, I. A. Maksimov, D. V. Patorkin, I. I. Komarov, O. V. Zlyvko
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引用次数: 0

摘要

为使世界工业和经济适应不断收紧的气候标准,以及能源消耗的持续增长,促进了无碳发电技术的发展。可再生能源和核电站指的是向大气中几乎零排放二氧化碳的能源。然而,鉴于用电大户附近的可再生能源资源不足,核电站在俄罗斯向无碳经济过渡的潜在过程中发挥着最重要的作用。然而,它们也有一些缺点,如能效相对较低、可操作性差,以及具体资本支出较高。核燃料和化石燃料的联合使用可能是部分消除这些缺点的方法之一。文章对核电厂在外部蒸汽过热器中使用化石燃料,并随后在高温涡轮机中膨胀部分蒸汽进行了热力学分析。文章提出了一种工艺回路解决方案,使用该方案可以扩大功率单位负荷调节范围。热力学分析结果表明,通过对蒸汽发生器中的一定量蒸汽进行外部过热,可以提高核电机组的功率输出和效率:在蒸汽过热温度分别为 560、600 和 640°С时,电力输出的最大增幅分别为 338、382 和 426 兆瓦,净电力效率分别为 0.73、1.08 和 1.43%。与独立的核电厂和蒸汽轮机热电厂相比,根据拟议的工艺循环回路运行的采用核燃料和碳氢化合物燃料的混合机组的主要设备数量较少,负荷调节范围较宽:与参考工艺循环回路相比,在蒸汽过热温度等于 560、600 和 640°С 时,负荷调节范围分别为 102.3-132.7、103.0-136.9 和 103.6-141.2%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A Study of Thermal Cycle Circuits of NPPs Combined with Fossil Fueled Power Installations

A Study of Thermal Cycle Circuits of NPPs Combined with Fossil Fueled Power Installations

The need to adapt the world’s industry and economy to constantly tightening climatic standards, as well as a constant growth of energy consumption, facilitate the development of carbon-free electricity generation technologies. Renewable energy and nuclear power plants are referred to energy sources having almost zero carbon dioxide emissions into the atmosphere. However, in view of an insufficient amount of renewable energy resources near large electricity consumers, NPPs play the most important role in the potential transition to the carbon-free economy of Russia. However, they do have certain drawbacks, such as comparatively low energy efficiency, poor maneuverability, and also high specific capital outlays. Combined use of nuclear and fossil fuel may become one of ways for partially removing these drawbacks. The article addresses a thermodynamic analysis of using fossil fuel at an NPP in an external steam superheater with subsequently expanding a part of the steam in a high-temperature turbine. A process circuit solution is proposed whose use makes it possible to obtain an expanded power unit load adjustment range. It has been shown from thermodynamic analysis results that, by subjecting a certain amount of steam from the steam generator to external superheating, it becomes possible to increase the nuclear power unit’s power output and efficiency: the maximal increase in the electric power output can total 338, 382, and 426 MW and that of net electrical efficiency of 0.73, 1.08, and 1.43% at steam superheating temperatures equal to 560, 600, and 640°С, respectively. The hybrid unit employing nuclear and hydrocarbon fuel that operates according to the proposed process cycle circuit includes a smaller amount of main equipment and features wider load adjustment ranges in comparison with standalone NPP and steam turbine thermal power plant: 102.3–132.7, 103.0–136.9, and 103.6–141.2% with respect to the reference process cycle circuit at steam superheating temperatures equal to 560, 600, and 640°С, respectively.

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来源期刊
CiteScore
1.30
自引率
20.00%
发文量
94
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