牵引杆对轨道车辆车体垂直振动特性的影响

Mădălina Dumitriu, Ioana Izabela Apostol
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摘要

虽然已有研究表明,牵引杆通过在二次悬架中引入的附加刚度会影响轨道车辆的垂直动力性能,但该领域的研究较少。本文利用数值模拟结果,分析了牵引杆对轨道车辆车体垂直振动特性的影响。基于车辆模型开发了数值模拟应用程序,其中车辆车体采用自由-自由等效梁欧拉-伯努利模型,转向架底盘和轮对由由Kelvin-Voigt系统连接在一起的刚体表示,该系统对副悬架和主悬架进行建模。在牵引杆模型中发现了本文的新颖元素。这包括牵引杆阻尼,这在以前的研究中被忽略了。牵引杆的刚度和阻尼由纵向Kelvin-Voigt系统集成到二级悬架模型中。基于加速度功率谱密度、加速度均方根和平顺性指数,对无牵引杆、有牵引杆-加阻尼和无牵引杆三种情况进行了分析,分析了牵引杆对车体垂直振动特性的影响。本文的结论突出了牵引杆的刚度和阻尼对车体振动水平的影响,特别是在车体中部。根据牵引杆的刚度,获得了乘坐舒适性指数的显着增加,在高速行驶时可以超过300%。牵引力杆的阻尼降低了乘坐舒适性指数高达10%。
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The Effect of the Traction Rod on the Vertical Vibration Behavior of the Railway Vehicle Carbody
Although research has shown that through the additional rigidity introduced in the secondary suspension, traction rods can affect the vertical dynamic performance of railway vehicles, this topic has been less studied by researchers in the field. In this paper, the effect of a traction rod on the vertical vibration behavior of a carbody of a railway vehicle is analyzed, using the results obtained through numerical simulations. Numerical simulation applications are developed based on a vehicle model, where the vehicle carbody is modeled using a free-free equivalent beam Euler–Bernoulli, and the bogie chassis and wheelsets are represented by rigid bodies linked together by Kelvin-Voigt systems that model the secondary suspension and the primary suspension. The novelty element of this paper is found in the model of the traction rod. This includes traction rod damping, which has been neglected in previous research. The stiffness and damping of the traction rod are represented by a longitudinal Kelvin–Voigt system integrated into a secondary suspension model. The effect of the traction rod on the vertical vibration behavior of the vehicle carbody is analyzed based on the power spectral density of the acceleration, the root mean square of acceleration, and the ride comfort index, for three cases for analysis: a ‘without traction rod’ case, a ‘with traction rod—with damping’ case, and a ‘with traction rod—without damping’ case. The conclusions of the paper highlight the influence of the stiffness and damping of the traction rod on the vibration level of the carbody, especially in its middle. Depending on the stiffness of the traction rod, significant increases in the ride comfort index are obtained, which at high velocities can exceed 300%. Damping of the traction rod reduces the ride comfort index by up to 10%.
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