M Saboori, J Gholipour, H Champliaud, P Wanjara, A Gakwaya, J Savoie
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引用次数: 5
摘要
爆裂是管材液压成形过程中的一种不可逆失效,其主要原因是管材在成形过程中所受的双轴应力超过材料的成形极限应变时产生了局部塑性失稳。为了预测破裂压力,在动态非线性商业三维有限元软件ls-dyna中,将Oyan和Brozzo的解耦韧性断裂准则(DFC)作为用户材料模型实现。选取了圆形到v形的四极流场作为航天部件的通用代表,进行了有限元模拟和试验研究。为了验证模拟结果,使用厚度为0.9 mm的Inconel 718 (IN 718)管进行了直至爆破的THF实验,以测量该过程中的内部压力。对比实验结果和模拟结果,发现基于Oyane解耦损伤准则预测的破裂压力比基于Brozzo断裂准则预测的破裂压力更符合IN 718的实测数据。
Prediction of Burst Pressure in Multistage Tube Hydroforming of Aerospace Alloys.
Bursting, an irreversible failure in tube hydroforming (THF), results mainly from the local plastic instabilities that occur when the biaxial stresses imparted during the process exceed the forming limit strains of the material. To predict the burst pressure, Oyan's and Brozzo's decoupled ductile fracture criteria (DFC) were implemented as user material models in a dynamic nonlinear commercial 3D finite-element (FE) software, ls-dyna. THF of a round to V-shape was selected as a generic representative of an aerospace component for the FE simulations and experimental trials. To validate the simulation results, THF experiments up to bursting were carried out using Inconel 718 (IN 718) tubes with a thickness of 0.9 mm to measure the internal pressures during the process. When comparing the experimental and simulation results, the burst pressure predicated based on Oyane's decoupled damage criterion was found to agree better with the measured data for IN 718 than Brozzo's fracture criterion.
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