VENTILATION CONTROL OF THE NEW SAFE CONFINEMENT OF THE CHORNOBYL NUCLEAR POWER PLANT BASED ON NEURO-FUZZY NETWORKS

Petro Loboda, I. Starovit, O. Shushura, Yevhen Havrylko, M. Saveliev, Natalia Sachaniuk-Kavets’ka, Oleksandr Neprytskyi, Dina Oralbekova, D. Mussayeva
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Abstract

The accident at the Chornobyl Nuclear Power Plant (ChNPP) in Ukraine in 1986 became one of the largest technological disasters in human history. During the accident cleanup, a special protective structure called the Shelter Object was built to isolate the destroyed reactor from the environment. However, the planned operational lifespan of the Shelter Object was only 30 years. Therefore, with the assistance of the international community, a new protective structure called the New Safe Confinement (NSC) was constructed and put into operation in 2019. The NSC is a large and complex system that relies on a significant number of various tools and subsystems to function. Due to temperature fluctuations and the influence of wind, hydraulic processes occur within the NSC, which can lead to the release of radioactive aerosols into the environment. The personnel of the NSC prevents these leaks, including through ventilation management. Considering the long planned operational term of the NSC, the development and improvement of information technologies for its process automation is a relevant task. The purpose of this paper is to develop a method for managing the ventilation system of the NSC based on neuro-fuzzy networks. An investigation of the current state of ventilation control in the NSC has been conducted, and automation tools for the process have been proposed. Using an adaptive neuro-fuzzy inference system (ANFIS) and statistical data on the NSC's operation, neuro-fuzzy models have been formed, which allows to calculate the expenses of the ventilation system using the Takagi-Sugeno method. The verification of the proposed approaches on a test data sample demonstrated sufficiently high accuracy of the calculations, confirming the potential practical utility in decision-making regarding NSC’s ventilation management. The results of this paper can be useful in the development of digital twins of the NSC for process management and personnel training.
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基于神经模糊网络的切尔诺贝利核电站新安全封闭空间的通风控制
1986 年乌克兰切尔诺贝利核电站(ChNPP)事故成为人类历史上最大的技术灾难之一。在事故清理期间,人们建造了一个名为 "掩蔽物 "的特殊保护结构,将被摧毁的反应堆与环境隔离开来。然而,防护罩的计划运行寿命只有 30 年。因此,在国际社会的协助下,建造了一个名为 "新安全壳"(NSC)的新保护结构,并于 2019 年投入使用。NSC 是一个庞大而复杂的系统,依靠大量的各种工具和子系统来运行。由于温度波动和风的影响,NSC 内部会发生液压过程,这可能导致放射性气溶胶释放到环境中。国家航天中心的工作人员通过通风管理等措施防止这些泄漏。考虑到核安全中心的计划运营期限较长,开发和改进其流程自动化信息技术是一项相关任务。本文旨在开发一种基于神经模糊网络的国家航天中心通风系统管理方法。对国家航天中心通风控制的现状进行了调查,并提出了该过程的自动化工具。利用自适应神经模糊推理系统(ANFIS)和有关国家航天中心运行的统计数据,建立了神经模糊模型,从而可以利用高木-菅野法计算通风系统的费用。在一个测试数据样本上对所提出的方法进行的验证表明,计算的准确性足够高,证实了在有关国家航天中心通风管理决策方面的潜在实用性。本文的结果可用于开发用于过程管理和人员培训的国家航天中心数字孪生系统。
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