A simulation analysis method for strength and fatigue design of prestressed wound ultra-high pressure vessels

Lida Che, Peng Wang, Liliang Ma, Yuqi Feng, Jie Zhao, Xiangyang Li
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Abstract

Pre-stressed steel wire-wound ultra-high-pressure vessels (PSWUPV) are commonly used in engineering to transport ultra-high-pressure media. However, the complex structure of these containers and the frequent pressure changes pose challenges in designing their structural and fatigue strength. Three simulation design methods were compared and analyzed: the two-dimensional force method, the two-dimensional cooling method, and the three-dimensional force method. The results showed that all three methods met the stress analysis requirements. The three-dimensional surface mass force method was chosen as the preferred method for engineering applications, specifically for the process of steel wire-winding loaded with mass force. The combined load case method was used to examine the influence of steel wires on the stress of the thick-walled cylinder when wound layer-by-layer. The study also focused on the changes in stress relaxation within the steel wire layer. The results demonstrated that the residual stresses of the core cylinder and the winding layer exhibited quasi-linear superposition during the winding and preloading process. The preloading effect of the steel wire weakened with increasing friction coefficient. Simulation results showed larger errors with excessively large or small normal stiffness coefficients. Based on theoretical solutions and verification studies, the optimal friction and normal stiffness coefficients were determined to be 0.02 and 1, respectively. By achieving a reasonable distribution of residual stress in the thick-walled cylinder of the ultra-high-pressure vessel through fatigue analysis, the fatigue life of the cylinder was significantly improved.
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预应力缠绕式超高压容器强度和疲劳设计的模拟分析方法
预应力钢丝缠绕超高压容器(PSWUPV)通常用于输送超高压介质。然而,这些容器结构复杂,压力变化频繁,给其结构和疲劳强度设计带来了挑战。我们比较分析了三种模拟设计方法:二维受力法、二维冷却法和三维受力法。结果表明,这三种方法都能满足应力分析的要求。三维表面质量力法被选为工程应用中的首选方法,特别是对于加载质量力的钢丝绕线过程。综合载荷情况法用于研究逐层缠绕时钢丝对厚壁圆柱体应力的影响。研究还关注了钢丝层内应力松弛的变化。结果表明,在缠绕和预加载过程中,芯筒和缠绕层的残余应力呈现准线性叠加。钢丝的预紧效果随着摩擦系数的增大而减弱。模拟结果表明,法向刚度系数过大或过小都会导致误差增大。根据理论求解和验证研究,确定最佳摩擦系数和法向刚度系数分别为 0.02 和 1。通过疲劳分析实现了超高压容器厚壁圆筒内残余应力的合理分布,从而显著提高了圆筒的疲劳寿命。
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