双弹簧电液激振缸振幅补偿性能的研究

传统的电液激振缸随着激振频率的提高，振动幅值急剧衰减，振幅补偿性能变差。为了解决这一问题，设计了一种双弹簧电液激振缸结构。分析了双弹簧电液激振缸的工作原理，建立了其数学模型和AMESim仿真模型，研究了激振频率、补偿弹簧刚度对其活塞杆位移的影响。结果表明：当激振频率为28 Hz、补偿弹簧刚度为31 N/mm时，激振缸活塞杆的位移增大6.24 mm，相比同一条件下的传统电液激振缸增大了15倍多；在双弹簧电液激振缸的工作过程中，其活塞杆位移振幅存在振荡区和稳定区，稳定区内的振幅大小直接决定了振幅补偿效果的优劣；在补偿弹簧刚度一定的情况下，活塞杆位移振幅不与激振频率呈简单的正相关或负相关关系，而在某一激振频率下谐振现象最明显，能使振幅补偿效果达到最优；激振频率不同，则补偿弹簧最优刚度不同，随着激振频率的提高，补偿弹簧刚度应相应增大。相比于传统的电液激振缸，双弹簧电液激振缸的振动幅值有较大提升，在工程应用中能取得更好的振幅补偿效果。

Research on amplitude compensation performance of double spring electro-hydraulic vibration cylinder

With the increase of excitation frequency, the vibration amplitude of traditional electro-hydraulic vibration cylinder decreases sharply, and the amplitude compensation performance becomes worse. A double spring electro-hydraulic vibration cylinder structure was designed to solve this problem. The working principle of double spring electro-hydraulic vibration cylinder was studied, its mathematical model and AMESim simulation model were established, and the effects of excitation frequency and compensation spring stiffness on displacement of its piston rod were analyzed. The results showed that when the excitation frequency was 28 Hz and the compensation spring stiffness was 31 N/mm, the displacement of piston rod of the vibration cylinder could be increased by 6.24 mm, which was more than 15 times higher than that of the traditional electro-hydraulic vibration cylinder under the same conditions; in the working process of the double spring electro-hydraulic vibration cylinder, the displacement amplitude of piston rod had an oscillation region and a stable region. The amplitude in the stable region directly determined the quality of the amplitude compensation effect; when the compensation spring stiffness was certain, the displacement amplitude of piston rod did not have a simple positive or negative correlation with the excitation frequency, and the resonance phenomenon was the most obvious at a certain excitation frequency, which could optimize the amplitude compensation effect; there were different compensation spring optimal stiffness at different excitation frequencies, with the increase of excitation frequency, the compensation spring stiffness should increase accordingly. Compared with the traditional electro-hydraulic vibration cylinder, the vibration amplitude of the double spring electro-hydraulic vibration cylinder is greatly improved and can achieve better amplitude compensation effect in engineering applications.