非转移直流电弧等离子体炬的三维稳态数值模拟

doi:10.19595/j.cnki.1000-6753.tces.L11026

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摘要非转移直流电弧等离子体炬是放射性废物等离子体熔融处理系统中的核心设备,射流的物理场参数不仅是设计和优化等离子体炬的重要指标,也是提高系统能量利用率和玻璃体生成物质量的关键。该文针对一款级联阳极结构的等离子体炬,基于磁流体力学理论,采用有限元仿真软件COMSOL对氮气热等离子体射流流入冷氮气域现象进行三维稳态数值模拟,建立电-磁-流-热的多物理场耦合模型,计算射流物理场参数,将计算结果与相关实验数据进行对比,并分析固定电流强度工况下改变输入气流量对等离子体炬性能的影响。结果显示模型能够较好地预测实际情况,所得到的射流温度场、速度场数据以及电极表面的温度、电流密度分布数据可为等离子体炬的设计和优化提供参考。

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关键词 ：非转移直流电弧等离子体炬, 放射性废物处理, 数值模拟, 多物理场耦合

Abstract：The non-transfered DC arc plasma torch is the core equipment in the radioactive waste plasma melting treatment system. The physical field parameters of the jet are not only an important index for the design and optimization of the plasma torch, but also the key to improve the system energy utilization rate and the quality of the vitreous products. Aiming at a plasma torch with cascade anode structure, based on the theory of magnetohydrodynamics, this paper uses the finite element software COMSOL to conduct three-dimensional steady-state numerical simulation of the phenomenon of nitrogen hot plasma jet flowing into the cold nitrogen domain, establishes a multi-physical field coupling model of electric-magnetic-flow-heat, calculates the physical field parameters of the jet, and compares the calculated results with relevant experimental data. The effect of changing the input gas flow rate on the performance of plasma torch under the condition of fixed current intensity is analyzed. The results show that the model can predict the actual situation well, and the obtained data of jet temperature field, velocity field, electrode surface temperature and current density distribution can provide reference for the design and optimization of plasma torch.
Firstly, the 3D structure diagram of the plasma torch is accurately drawn in COMSOL, and the materials are defined in different areas. Secondly, based on the theory of magnetohydrodynamics, relevant assumptions and mathematical equations are listed, which include electromagnetic field, fluid and heat transfer. Thirdly, the boundary conditions of the model and the artificial conductivity of nitrogen plasma in different regions are introduced in detail, and some specific Settings are explained. Finally, the experimental platform is built, and the data obtained by a series of continuous experiments are compared with the simulation results.
Comparing the experimental data with the simulation data, it is found that the calculated average voltage is very close to the actual measurement results but a little lower, and the error comes from the steady-state hypothesis. Thermal efficiency calculation is reliable; The temperature changes of the torch tube surface and section are very obvious, which indicates that the calculation accuracy can be improved by adding the "cooling water" calculation area to replace a class of boundary conditions in the model. The prediction accuracy of the datum point of jet temperature 3 410℃ is slightly higher than that of the two-dimensional model. By analyzing the simulation data, it is found that the pressure gradient and radial Lorentz force between the cold gas and the plasma are obvious. There are two maximum values of speed under all conditions. In the torch tube, the higher the gas flow rate, the lower the temperature, and the opposite is true outside the torch tube. The electrode boundary can be regarded as a "balanced discharge boundary heat source" to predict the electrode performance synchronously, and the temperature distribution data of the electrode is consistent with the ablation test results.
The model can provide a reference for the design and optimization of DC arc plasma torches, and subsequent studies will be carried out on this basis, mainly focusing on the analysis of the influence of different variables on jet characteristics and thermal efficiency, including different types of working gases, intake modes, the combination of current intensity and gas flow conditions, and the combination of electrode structures with different shapes.

Key words： Non-transfered DC arc plasma torches radioactive waste treatment numerical simulation multi-physics coupling

收稿日期: 2024-07-11

PACS:	O53
	V439.2

通讯作者: 吴楠男,1989年生,讲师,研究方向为放电等离子体及其应用。E-mail：245803598@qq.com

作者简介: 程文博男,2000年生,硕士研究生,研究方向为中低放射性废物等离子体熔融处理技术。E-mail：624946939@qq.com

引用本文:

程文博, 武瑾, 吴楠, 黄齐平, 范俊鑫. 非转移直流电弧等离子体炬的三维稳态数值模拟[J]. 电工技术学报, 2024, 39(zk1): 14-24. Cheng Wenbo, Wu Jin, Wu Nan, Huang Qiping, Fan Junxin. Three-Dimensional Steady State Numerical Simulation of Non-Transferred DC Arc Plasma Torch. Transactions of China Electrotechnical Society, 2024, 39(zk1): 14-24.

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[1] 马中洋, 李淩豪, 孙红梅, 等. 大尺寸电弧等离子体的产生、控制及应用[J]. 力学学报, 2023, 55(12): 2876-2890.
Ma Zhongyang, Li Linghao, Sun Hongmei, et al.Generation of large volume arc plasma, control and its application[J]. Chinese Journal of Theoretical and Applied Mechanics, 2023, 55(12): 2876-2890.
[2] 陈思邈, 程昌明, 李平川, 等. 等离子体熔融技术在核电站放射性废物处理中的研究应用现状[J]. 真空科学与技术学报, 2022, 42(7): 483-490.
Chen Simiao, Cheng Changming, Li Pingchuan, et al.Application progress of plasma melting technology for disposal of radioactive waste in nuclear power plants[J]. Chinese Journal of Vacuum Science and Technology, 2022, 42(7): 483-490.
[3] Ma Yuheng, Chu Haoran, Zheng Bowen.Research progress of plasma melting technology in radioactive waste treatment of nuclear power plants[J]. Annals of Nuclear Energy, 2024, 198: 110307.
[4] 曹亚文, 韩先伟, 谭畅, 等. 双弧室磁控空气等离子体炬电弧特性的实验研究[J]. 高电压技术, 2021, 47(3): 832-839.
Cao Yawen, Han Xianwei, Tan Chang, et al.Characteristic researches on arc generated by magnetic double-chamber air plasma torch[J]. High Voltage Engineering, 2021, 47(3): 832-839.
[5] 赵明波, 曹修全, 郭文钰, 等. 氮氩直流电弧等离子体射流特性实验研究[J]. 高电压技术, 2023, 49(5): 2206-2215.
Zhao Mingbo, Cao Xiuquan, Guo Wenyu, et al.Experimental study on the characteristics of nitrogen-argon DC arc plasma jet[J]. High Voltage Engineering, 2023, 49(5): 2206-2215.
[6] Li Kuan, Zhu Cheng, Zhang Yunfei, et al.Experimental study of the discharge characteristics of a stepped-nozzle arc plasma torch[J]. Plasma Chemistry and Plasma Processing, 2024, 44(4): 1469-1492.
[7] 姚聪林, 朱红春, 姜周华, 等. 电弧炉内长电弧等离子体的数值模拟[J]. 工程科学学报, 2020, 42(增刊1): 60-67.
Yao Conglin, Zhu Hongchun, Jiang Zhouhua, et al.Numerical simulation of a long arc plasma in an electric arc furnace[J]. Chinese Journal of Engineering, 2020, 42(S1): 60-67.
[8] 徐云聪, 张逸, 林才华, 等. 基于电气特性-物理参数耦合的交流电弧炉模型[J]. 电工技术学报, 2024, 39(6): 1643-1655.
Xu Yuncong, Zhang Yi, Lin Caihua, et al.AC arc furnace model based on coupling of electrical and physical parameters[J]. Transactions of China Electrotechnical Society, 2024, 39(6): 1643-1655.
[9] 赵梦静, 王勇, 杨树峰, 等. 电弧等离子体多物理场分布特征[J]. 机械工程学报, 2022, 58(8): 153-159.
Zhao Mengjing, Wang Yong, Yang Shufeng, et al.Distribution characteristics of multi-physics fields in arc plasma[J]. Journal of Mechanical Engineering, 2022, 58(8): 153-159.
[10] 崔建, 孙帅, 张国钢, 等. 基于双温度磁流体电弧仿真改进Mayr电弧模型的特快速暂态过电压仿真方法[J]. 电工技术学报, 2024, 39(16): 5149-5161.
Cui Jian, Sun Shuai, Zhang Guogang, et al.The very fast transient overvoltage simulation method based on two-temperature MHD arc simulation to improve Mayr arc model[J]. Transactions of China Electrotechnical Society, 2024, 39(16): 5149-5161.
[11] 张在秦, 刘志远, 王闯, 等. 大电流真空电弧中阳极熔化过程的实验与仿真研究[J]. 电工技术学报, 2024, 39(7): 2143-2152, 2160.
Zhang Zaiqin, Liu Zhiyuan, Wang Chuang, et al.Experimental and numerical study on anode melting in high current vacuum arcs[J]. Transactions of China Electrotechnical Society, 2024, 39(7): 2143-2152, 2160.
[12] 王飞, 曹亚文, 林榕, 等. 一种小功率孔形阳极喷嘴等离子体炬的研究[J]. 推进技术, 2021, 42(11): 2600-2609.
Wang Fei, Cao Yawen, Lin Rong, et al.Low-power plasma torch with hole-mouthed anode[J]. Journal of Propulsion Technology, 2021, 42(11): 2600-2609.
[13] Tao Jing, Li Changpeng, Cao Xiuquan, et al.Modeling of the arc characteristics inside a thermal laminar plasma torch with different gas components[J]. Processes, 2024, 12(6): 1207.
[14] 师浩阳, 王平阳, 王淑. 直流电弧等离子体炬数值模拟与诊断[J]. 上海航天(中英文), 2024, 41(1): 122-129.
Shi Haoyang, Wang Pingyang, Wang Shu.Numerical simulation and diagnostic analysis on DC arc plasma torch[J]. Aerospace Shanghai (Chinese & English), 2024, 41(1): 122-129.
[15] Liu Senhui, Trelles J P, Murphy A B, et al.Numerical simulation of the flow characteristics inside a novel plasma spray torch[J]. Journal of Physics D: Applied Physics, 2019, 52(33): 335203.
[16] Zhukovskii R, Chazelas C, Rat V, et al.Predicted anode arc attachment by LTE (local thermodynamic equilibrium) and 2-T (two-temperature) arc models in a cascaded-anode DC plasma spray torch[J]. Journal of Thermal Spray Technology, 2022, 31(1): 28-45.
[17] Boulos M I, Fauchais P L, Pfender E.Thermodynamic Properties of Plasmas[M]//Handbook of Thermal Plasmas. Cham: Springer International Publishing, 2023: 211-256.
[18] Pan Zihan, Ye Lei, Qian Shulou, et al.Comparison of Reynolds average Navier-Stokes turbulence models in numerical simulations of the DC arc plasma torch[J]. Plasma Science and Technology, 2020, 22(2): 025401.
[19] Zhukovskii R, Chazelas C, Vardelle A, et al.Effect of electromagnetic boundary conditions on reliability of plasma torch models[J]. Journal of Thermal Spray Technology, 2020, 29(5): 894-907.
[20] Boulos M I, Fauchais P L, Pfender E.Electrode Phenomena in Plasma Sources[M]//Handbook of Thermal Plasmas. Cham: Springer International Publishing, 2023: 553-594.
[21] 孙强. 电弧等离子体全域数值模拟[D]. 合肥: 中国科学技术大学, 2019.
Sun Qiang.A global numerical simulation of arc plasmas[D]. Hefei: University of Science and Technology of China, 2019.
[22] 盛德杰, 王尧, 邢云琪, 等. 基于磁流体动力学仿真的低压交流串联故障电弧致火风险研究[J/OL]. 电工技术学报, 2024: 1-13[2024-10-11]. https://doi.org/10.19595/j.cnki.1000-6753.tces.240786.
Sheng Dejie, Wang Yao, Xing Yunqi, et al. Research on fire risk of low voltage AC series fault arc based on magnetohydrodynamics simulation[J/OL]. Transac-tions of China Electrotechnical Society, 2024: 1-13[2024-10-11]. https://doi.org/10.19595/j.cnki.1000-6753.tces.240786.
[23] 边晨曦, 何柏娜, 姜仁卓, 等. C₄F₇N二元混合气体电弧温度特性研究[J]. 高压电器, 2024, 60(9): 53-60.
Bian Chenxi, He Baina, Jiang Renzhuo, et al.Research on arc temperature characteristics of C₄F₇N binary gas mixture[J]. High Voltage Apparatus, 2024, 60(9): 53-60.
[24] 陈默, 陆宁懿, 翟国富. 基于电弧磁流体仿真的DC 1500 V两极塑壳断路器气道优化设计[J]. 电工技术学报, 2023, 38(8): 2222-2232.
Chen Mo, Lu Ningyi, Zhai Guofu.Arc chamber optimization of DC 1 500 V two-pole circuit breakers based on arc magneto hydro dynamics simulation[J]. Transactions of China Electrotechnical Society, 2023, 38(8): 2222-2232.
[25] 周旭. 热等离子体流动特性的数值研究[D]. 合肥: 中国科学技术大学, 2022.
Zhou Xu.Numerical study on flow characteristics of thermal plasma[D]. Hefei: University of Science and Technology of China, 2022.
[26] Stone J M, Tomida K, White C J, et al.The Athena++ adaptive mesh refinement framework: design and magnetohydrodynamic solvers[J]. The Astrophysical Journal Supplement Series, 2020, 249(1): 4.
[27] Wang J, Duan J M, Ma Z W, et al.An adaptive moving mesh finite difference scheme for tokamak magneto-hydrodynamic simulations[J]. Computer Physics Communications, 2024, 294: 108951.