Tesla型脉冲源力学结构设计方法

Mechanical structure design method for Tesla-type pulse power generators

  • 摘要: Tesla型脉冲源由于绝缘需要常充有较高内压的绝缘气体,在工程应用中还会经历各种振动工况,因而在结构设计时需同时满足静力学和动力学的强度要求。本文结合工程实例归纳了Tesla型脉冲源的力学结构设计方法:静态承压设计中,区分内筒和外筒的失效模式,承受外压的内筒以稳定性校核为主,并给出临界压力的工程计算方法;建立基于垫片应力法与变形一致原则的螺栓预紧力计算方法,推导出具有上下限的量化选取公式;采用接触应力评判密封可靠性,通过仿真获得不同规格密封圈对应的密封槽面间隙阈值;静力学与动力学校核中,提出以沿厚度贯穿的最大应力值作为静强度评判基准,振动工况下,应将静应力与动应力矢量叠加,以获得真实总应力用于强度评估。该设计方法对同类型脉冲源的力学结构设计具有指导意义。

     

    Abstract:
    Background Tesla-type pulse power generators are generally filled with high-pressure insulating gas to achieve internal insulation and are subjected to diverse vibration loads during service, thereby requiring their structural design to satisfy both static and dynamic strength requirements.
    Purpose Based on practical engineering cases, this study summarizes a mechanical structure design method for Tesla-type pulse power generators, aiming to provide guidance for the structural optimization and reliability evaluation of relevant equipment.
    Methods In the static pressure design, the failure modes of inner and outer conductors are distinguished, and the stability performance is taken as the primary evaluation index for inner conductors under external pressure. A bolt preload calculation method is established based on the gasket stress method and deformation compatibility principle. Numerical simulation is adopted to evaluate sealing reliability through contact stress analysis, and the vector superposition of static and dynamic stresses is applied to evaluate the structural strength under vibration conditions.
    Results An engineering calculation method for the critical external pressure of inner conductors is presented, and a quantitative bolt preload selection formula with upper and lower limits is derived. The critical groove clearance thresholds corresponding to different O-ring specifications are determined. Moreover, the maximum through-thickness stress is validated as a feasible benchmark for static strength evaluation, and the actual total stress under vibration conditions can be accurately obtained through the vector superposition of static and dynamic stresses.
    Conclusions The proposed integrated design and verification method can effectively meet the static and dynamic service requirements of pulse power generators, offering a reliable reference for the mechanical structural design of similar equipment.

     

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