Water Chemistries of VVER-SCW Nuclear Power Plants: The Choice and Justification (Review)

IF 0.9 Q4 ENERGY & FUELS Thermal Engineering Pub Date : 2024-08-23 DOI:10.1134/S0040601524700204
N. L. Kharitonova, V. F. Tyapkov
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Abstract

The article discusses the potential problems that have to be solved in the framework of development and justification of the water chemistry (WC) conditions required to ensure corrosion resistance of the structural materials used in the core and coolant circuit of the power-generating reactor used in the supercritical water cooled VVER-SCW nuclear power plant (NPP). In reactors cooled with water at supercritical temperature and pressure, the integrity of their physical barriers (fuel-rod claddings and reactor coolant circuit boundaries) depends in many respects on the possibility of maintaining the necessary water chemistry conditions that will guarantee the corrosion resistance of equipment and pipeline structural materials for the power unit’s entire service life. The most complex challenge in this regard is to inhibit corrosion and flow-accelerated corrosion processes and to minimize the formation of deposits on the surface of equipment operating in the domain of near-critical and supercritical conditions. The article formulates the limitations that are suggested to be considered in transferring the experience gained from the standardization of water chemistry in supercritical pressure (SCP) power units at thermal and nuclear power plants to the VVER-SCW NPPs. An analysis is carried out that makes it possible to estimate the effect the chemical composition of a supercritical water coolant has on the corrosion state of candidate structural materials for fuel-rod claddings with the aim to get better insight in the main processes occurring in aqueous solutions and for developing (elaborating) a WC conduction technology as applied to ensuring the integrity of the VVER-SCW NPP physical safety barriers.

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VVER-SCW 核电站的水化学成分:选择与理由(综述)
摘要 本文讨论了在开发和论证水化学(WC)条件框架内必须解决的潜在问题,这些条件是确保超临界水冷 VVER-SCW 核电站(NPP)发电反应堆堆芯和冷却剂回路所用结构材料耐腐蚀性的必要条件。在超临界温度和压力下用水冷却的反应堆中,其物理屏障(燃料棒包壳和反应堆冷却剂回路边界)的完整性在许多方面取决于能否维持必要的水化学条件,以保证设备和管道结构材料在整个机组使用寿命内的耐腐蚀性。这方面最复杂的挑战是如何抑制腐蚀和流动加速腐蚀过程,并最大限度地减少在近临界和超临界条件下运行的设备表面沉积物的形成。文章提出了在将火电厂和核电厂超临界压力 (SCP) 机组水化学标准化经验应用于 VVER-SCW 核电站时应考虑的限制因素。通过分析,可以估计超临界水冷却剂的化学成分对燃料棒包壳候选结构材料腐蚀状态的影响,目的是更好地了解水溶液中发生的主要过程,并开发(制定)适用于确保 VVER-SCW 核电站物理安全屏障完整性的 WC 传导技术。
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来源期刊
CiteScore
1.30
自引率
20.00%
发文量
94
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