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介绍了应用Pro/E机构运动仿真模块进行运动仿真的工作流程.通过应用Pro/E机构运动仿真模块对双前轴转向传动机构进行匹配设计的实例,论述了商用车双前轴转向传动机构的设计理论要求、初步的传动机构实体建模方法以及转角特性分析方法、理论模型与实体模型的转角特性数据处理与分析,以及实体模型的优化设计方法,并简要介绍了转向传动机构与悬架系统的运动十涉分析方法. 相似文献
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双横臂式独立悬架系统匹配的转向传动系统,通常转向梯形机构中的梯形横拉杆采用断开式,及所谓的断开式转向梯形机构。断开式转向传动机构的重难点就是确定断开点及转向传动系统的各个硬点,以保证转向和独立悬架系统运动的协调性。文章从设计指标项入手,借助转向与悬架系统DMU运动仿真分析,得出转向传动系统的最优布置方案。同时,也从分析要点引出了独立断开式转向传动机构在设计过程中需要考虑的诸多因素,为类似车辆转向传动系统设计提供理论参考。 相似文献
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具有断开式转向梯形的转向传动机构运动分析 总被引:2,自引:0,他引:2
由于断开式转向梯形转向传动机构的运动是空间运动,因此用传统的作图法和投影计算法进行运动分析和参数确定,就显得不够精确。为此,以一种典型的具有断开式转向梯形的转向传动机构为例,利用空间解析几何,对转向臂与车轮的转角关系和内外轮实际转角关系,进行了分析计算。 相似文献
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EQ1141液压助力转向系统主要由转向操纵机构、转向器、转向加力装置和转向传动机构组成。转向操纵机构是驾驶员操纵转向器工作的机构,转向器是把方向盘传来的转矩按一定传动比放大并输出,转向传动机构是把转向器输出的力矩传递给转向车轮的机构,包括从转向摇臂到转向车轮的零部件。 相似文献
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汽车转向传动机构的数学模型及其优化设计 总被引:1,自引:0,他引:1
本文应用最优化理论研究解决了汽车转向传动机构的优化设计方法。其基本内容分三部分:1.推导转向传动机构的数学模型;2.建立转向传动机构优化设计的目标函数;3.提供一种寻优计算的方法及其计算机计算程序。试验验证表明本文提供的方法是有效的且适用于任何型式转向传动机构的优化设计。 相似文献
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基于ADAMS的某车型转向特性分析 总被引:1,自引:0,他引:1
用ADAMS软件建立了某车型转向传动机构的虚拟样机模型,分析了转向机构中的关键点改变对阿克曼转向特性的影响,为新车型开发过程中转向梯形的选择提供了最佳方向。 相似文献
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应用ADAMS/Tire模块对平板车原地转向过程中的阻力变化情况进行动态分析,得出转向阻力与转向速度之间的关系,为机构的传动设计和控制设计提供了参考. 相似文献
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本文以某款牵引列车的动力匹配为主线,分析该车的动力性能和燃油经济性能,建立这种牵引车的优化匹配框架,为其他牵引车的匹配提供参考。主要是对动力传动系统的调整,包括发动机、变速器、驱动桥主传动比,配合对用户实际用车环境的数据采集及分析,使用户的车辆在满足动力性能的情况下获得较为完美合理的经济性能。 相似文献
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G. M. Owen 《Vehicle System Dynamics: International Journal of Vehicle Mechanics and Mobility》1982,11(4):215-240
Agricultural tractors are relatively slow moving vehicles but a good steer response under all working conditions is generally required. This paper evaluates the effect of ground slope, axle load, ground speed, tyres and ground surface on yaw rate response to steer input. 相似文献
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Zhiwei Wang Zhonghui Yin Yao Cheng Guanhua Huang Hangyu Zou 《Vehicle System Dynamics: International Journal of Vehicle Mechanics and Mobility》2019,57(4):543-563
In this study, we developed a comprehensive three-dimensional vehicle–track coupled dynamics model considering the traction drive system and axle box bearing. In this model, dynamic interactions between the axle box bearing and other components, such as the wheelset and bogie frame, are considered based on a detailed analysis of the structural properties and working mechanism of the axle box bearing. A few complicated dynamic excitations, such as the time-varying mesh stiffness of gears, time-varying stiffness of bearing, bearing gaps and track irregularities, are considered. Then, the dynamic responses of the vehicle–track system are demonstrated via numerical simulations based on the established dynamics model. The results indicate that the traction drive system and track irregularities can significantly influence the dynamic interactions of the axle box bearing. The necessity of considering the excitation caused by gear meshing and track irregularities when assessing the dynamic performance of the axle box bearing is demonstrated. 相似文献
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《Vehicle System Dynamics: International Journal of Vehicle Mechanics and Mobility》2012,50(4):215-240
SUMMARY Agricultural tractors are relatively slow moving vehicles but a good steer response under all working conditions is generally required. This paper evaluates the effect of ground slope, axle load, ground speed, tyres and ground surface on yaw rate response to steer input. 相似文献
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以国内某新型轻客驱动桥的NVH性能为研究对象,根据整车噪声测试结果,结合驱动桥的噪声测量数据,并运用ABAQUS软件进行模态有限元分析。针对主减齿轮啮合噪声和驱动桥的整车共振提出相应改进措施,并进行试验验证。试验结果表明,理论分析计算和改进措施有效,为后期驱动桥的设计和改进提供了参考。 相似文献
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《Vehicle System Dynamics: International Journal of Vehicle Mechanics and Mobility》2012,50(4):504-521
The classic two-degree-of-freedom yaw-plane or ‘bicycle’ vehicle model is augmented with two additional states to describe lane-keeping behaviour and further augmented with an additional control input to steer the rear axle. A simple driver model is hypothesised where the driver closes a loop on a projected lateral lane position. The driver can select the preview distance to compensate driver/vehicle dynamics, consistent with the ‘cross-over’ model found in the literature. A rear axle steer control law is found to be a function of the front axle steering input and vehicle speed that exhibits stability similar to a positive-real system, while at the same time improving the ability of the driver/vehicle system to track a complex curved lane and improving steady-state manoeuvrability. The theoretically derived control law bears similarity to practical embodiments allowing a deeper understanding of the functional value of steering a rear axle. 相似文献