Construction of Reax FF Force Field for SF6 Gas Insulation Medium under Over-thermal Fault

Y. Miao, Mingxuan Zhang, F. Zeng, Ju Tang, Haotian Li, Liangjun Dai, Q. Yao
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Abstract

The SF6 gas insulation medium will decompose under the partial over-thermal fault (POF) inside the GIS equipment, which declines the insulation performance, thereby endangering the safety of the equipment. Although the decomposition characteristics under several degrees of POF are obtained, the problem of describing the continuous process of SF6 decomposition under POF has not been solved. The difficulty lies in the lack of a force field that can effectively describe the decomposition process of SF6. To this end, this paper first calculates the main molecular systems of fluoride-sulfides based on density functional theory, and obtains a training set for establishing a force field file. Based on the training set, the Reax FF force field is optimized using a fitting algorithm, and the correctness of the force field is verified. Then, the molecular dynamic simulations of SF6 under the over-thermal state is studied. The breaking and bonding process of SF6, SF5, SF4, SF3, and SF2 is clarified and compared with the macro experimental data of SF6 decomposition under partial over-thermal fault. The results show that the established force field can accurately describe the breaking and bonding process of SF6, SF5, SF4, SF3 and SF2 molecules. The simulation data is in good agreement with the actual experiments, and the research work in this paper lays a foundation for the systematic study of over-thermal decomposition of SF6.
过热故障下SF6气体绝缘介质松弛FF力场的构建
SF6气体绝缘介质在GIS设备内部局部过热故障(POF)作用下会发生分解,导致绝缘性能下降,危及设备安全。虽然得到了不同POF程度下SF6的分解特性,但没有解决描述POF下SF6分解连续过程的问题。难点在于缺乏一个能有效描述SF6分解过程的力场。为此,本文首先基于密度泛函理论计算了氟化物-硫化物的主要分子体系,并得到了建立力场文件的训练集。在训练集的基础上,利用拟合算法对Reax FF力场进行优化,并验证了该力场的正确性。然后,研究了SF6在过热状态下的分子动力学模拟。阐明了SF6、SF5、SF4、SF3、SF2的断裂键合过程,并与局部过热断裂下SF6分解的宏观实验数据进行了对比。结果表明,所建立的力场能够准确描述SF6、SF5、SF4、SF3和SF2分子的断裂和成键过程。仿真数据与实际实验吻合较好,本文的研究工作为SF6过热分解的系统研究奠定了基础。
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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