There has been renewed interest in rail transportation driven by the need for alternatives to congested highways and environmental concerns. The conventional railway truck designed for operation at high speed of approximately 200 km/hr makes use of stiff primary suspension elements to provide good dynamic stability. The curving performance of such a vehicle is poor because of wheelset misalignment in curves resulting in increased wheel and rail wear. This increases the maintenance cost. The wheelset misalignment also leads to increased lateral forces which raises the potential for derailment due to wheel climb. One of the aspects of the railway truck design that needs improvement is better compatibility between dynamic stability at high speeds and the ability of the vehicle to steer around curves.; In this thesis, modified truck designs are considered with an objective to improve both the high speed stability and curving behaviour. The performance of the following designs are compared: (i) Conventional truck ( C truck); (ii) Radial truck (R Truck); (iii) Conventional truck with yaw damper (CD truck) and (iv) Unsymmetric Suspension truck with yaw damper (USD truck). The USD truck has longitudinal asymmetry in the suspension according to direction of motion i.e. the primary stiffness in the leading axle is different from the trailing axle. Another truck considered for evaluation is the Unsymmetric Wheelset truck (UW truck) in which the trailing axle is an Independently Rotating Wheelset (IRW).; By choosing suitable values of primary yaw dampers, it is possible for CD truck and USD truck to achieve higher critical speed in comparison to C truck and US truck for a given bending stiffness The non-linear curving analysis has shown that USD truck achieves better curving performance in comparison to other truck designs on curvatures up to 12 degrees. Thus it is possible for a properly designed USD truck to achieve near perfect steering as well as maintain good dynamic stability.; Validation of the results from this study has been carried out using the software New and Untried Car Analytic Regime Simulation (NUCARS). NUCARS is a multi-body dynamic program for railway vehicle design and performance evaluation and is an industry-wide standard in North America. The analysis of performance using NUCARS also shows that USD truck has better curving behaviour compared to other truck designs for curvatures up to 12 degrees.
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机译:由于对拥堵的高速公路和环境问题的替代需求,对铁路运输产生了新的兴趣。设计用于以大约200 km / hr的高速度运行的常规铁路卡车利用坚硬的主悬架元件来提供良好的动态稳定性。由于轮对在曲线上未对准,导致车轮和轨道磨损增加,因此这种车辆的弯曲性能很差。这增加了维护成本。轮对未对准还会导致增加横向力,这会增加由于轮爬而导致脱轨的可能性。铁路卡车设计中需要改进的方面之一是高速动态稳定性与车辆绕弯道转向的能力之间的更好兼容性。本文以改进卡车设计为目标,以提高高速稳定性和弯曲性能。比较了以下设计的性能:(i)常规卡车( C卡车); (ii)子午线卡车( R Truck ); (iii)带有偏航阻尼器的常规卡车( CD卡车)和(iv)带有偏航阻尼器的非对称悬挂卡车( USD卡车)。 美元卡车根据运动方向在悬架中具有纵向不对称性,即前桥的主刚度与后桥的主刚度不同。另一种考虑进行评估的卡车是非对称轮对卡车( UW truck ),其后轴为独立旋转轮对(IRW)。通过选择合适的主偏航阻尼器值,与 C卡车和 CD卡车和 USD卡车相比,可以实现更高的临界速度。在给定的弯曲刚度下,美国卡车非线性弯曲分析表明,与其他卡车设计(最大曲率不超过12度)相比, USD卡车具有更好的弯曲性能。因此,设计合理的 USD卡车有可能实现接近完美的转向,并保持良好的动态稳定性。这项研究结果的验证已使用软件“ New and Untried Car Analytic Regime Simulation(NUCARS)”进行。 NUCARS是一个用于铁路车辆设计和性能评估的多体动力学程序,是北美的行业标准。使用NUCARS进行的性能分析还显示,与其他卡车设计相比,USD卡车在弯曲度高达12度时具有更好的弯曲性能。
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