Hery Setiawan, Ichsan Setya Putra, Latif Nurrahman, I. M. Wiragunarsa, Intan Sibarani, Annisa Jusuf, Bambang Raharjo
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引用次数: 0
摘要
印度尼西亚设计和建造的高速列车将使用铝合金 Al 6061-T6 作为结构材料。由于铝合金材料没有耐久极限,很容易发生疲劳失效,因此必须进行疲劳寿命预测。疲劳裂纹可能在焊接接头的缺陷处产生。分析列车结构关键位置的疲劳载荷谱对于预测疲劳寿命至关重要。这些关键位置选自高静态应力和应力集中的区域。载荷分析采用多体动力学,并根据 UIC 标准规范 518 进行刚体假设和轨道粗糙度分析。有限元法用于计算多体动力学产生的应力。利用雨流计数法进一步分析了荷载序列,并构建了荷载超限曲线。最后,使用 Miner 线性累积损伤模型预测疲劳寿命。
Fatigue load spectrum generation of Indonesian high-speed trains
The high-speed trains designed and constructed in Indonesia will use Aluminum alloy Al 6061-T6 as a structural material. Aluminum alloys are prone to fatigue failure due to the absence of endurance limit of the material, hence fatigue life prediction has to be carried out. Fatigue cracks could initiate at the defects of welded joints. Analyzing the fatigue load spectrum of critical locations in the train structures is crucial to predicting fatigue life. These critical locations are selected from areas with high static stress and stress concentration. The loads are analyzed using the multibody dynamic with rigid body assumptions and track roughness following UIC Standard Code 518. The finite element method is used to calculate the stresses from the loads generated by the multibody dynamic. The load sequence is further analyzed with rainflow counting method, and the load exceedance curve can be constructed. Finally, the Miner Linear Cumulative Damage Model is used to predict fatigue life.
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