An Air Suspension System With Adjustable Height, Damping and Stiffness Using No Viscous Dampers

R. Kashani
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Abstract

Air suspension is gaining more and more popularity with both the auto industry and drivers. Traditionally the height adjustability aspect of air suspension systems has been their main attracting attribute. More recently, resolving the classic conflict of combining comfortable ride with sport handling in a single suspension setup has become the main attraction of air suspension. An air suspension system has been developed which in addition to height adjustment, can adjust its damping and stiffness in real time with using neither viscous dampers nor any additional actuators. This is done by real-time adjustment air flow to and from the air springs using proportional valves. Measured relative displacement and acceleration as well as estimated velocity of the sprung mass with respect to unspring mass at each corner are fedback, thru their corresponding gains, to create the control signal that adjusts the proportional valve with the goal of controlling the height, stiffness, and damping at that corner. In a numerical study followed by laboratory testing, the effectiveness of the proposed air suspension system in terms of its ability to vary the damping and stiffness as well as the height of the suspension system is demonstrated.
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无粘性阻尼器的可调高度、阻尼和刚度空气悬架系统
空气悬架越来越受到汽车工业和驾驶员的欢迎。传统上,空气悬架系统的高度可调性一直是其主要的吸引特性。最近,在一个单一的悬架设置中,解决了将舒适驾驶与运动操控相结合的经典冲突已成为空气悬架的主要吸引力。研制了一种空气悬架系统,该系统在不使用粘性阻尼器和任何附加作动器的情况下,除了高度调节外,还可以实时调节其阻尼和刚度。这是通过使用比例阀实时调节进出空气弹簧的气流来实现的。测量到的相对位移和加速度,以及弹簧质量相对于每个角的非弹簧质量的估计速度,通过相应的增益进行反馈,以产生调节比例阀的控制信号,目标是控制该角的高度、刚度和阻尼。在随后的数值研究和实验室测试中,所提出的空气悬架系统在其改变阻尼和刚度以及悬架系统高度的能力方面的有效性得到了证明。
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