Research of transient processes in a two-way pneumatic drive with vacuum gripping devices

Serhii Nosko, O. Haletskyi, Dmytro Kostiuk
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Abstract

An assessment of the current state of research on transient processes in pneumatic actuators is presented. The advantages and disadvantages of pneumatic drives with vacuum gripping devices and their connection with practical design tasks are shown. It has been established that the calculation of parameters and the design of high-speed, typical pneumatic actuators and actuators with vacuum grippers differ significantly. The expediency of using vacuum gripping devices in manipulation drives is shown. It was established that, unlike pneumatic cylinders of mechanical gripping devices, for which the final phase of the actuation cycle is important, in which the piston at the end of the stroke is already stationary, but the pressure in the working cavity increases and, accordingly, the force on the rod increases, for actuators with vacuum gripping devices, this phase is not is taken into account. The choice of a mathematical model and a methodology for calculating the transient processes of double-acting pneumatic actuators is substantiated. The model involves recording the equation of motion of the cylinder piston, supplemented by equations describing pressure changes in the working and exhaust cavities of the cylinder, followed by computer simulation. As part of the mathematical model, a study of transient processes was carried out, therefore, all simulation results are shown in the time interval limited by the period of piston movement (ie, preparatory and final periods were not considered). The effect of the effective areas of the input and output pneumolines of the pneumocylinder on dynamic processes in the actuator was studied. It was established that the change in the diameter of the inlet opening and, accordingly, the area of the inlet opening of the working or exhaust cavity leads to a change in the flow rate and capacity factor of the communication lines, is characterized by a change in the kinetic energy of the output link, limits its working speed and ensures the smoothness of the movement of the output link of the drive.
带真空抓取装置的双向气动驱动装置的瞬态过程研究
本文对气动执行器瞬态过程的研究现状进行了评估。说明了带有真空抓取装置的气动驱动器的优缺点及其与实际设计任务的联系。研究表明,高速、典型的气动执行器和带真空抓取装置的执行器在参数计算和设计上有很大不同。说明了在操纵驱动中使用真空抓取装置的便利性。与机械抓取装置的气缸不同的是,机械抓取装置的气缸在执行周期的最后阶段非常重要,在这一阶段,活塞在冲程结束时已经静止,但工作腔中的压力会增加,相应地,杆上的力也会增加,而真空抓取装置的执行器则不考虑这一阶段。计算双作用气动执行器瞬态过程的数学模型和方法的选择已得到证实。该模型包括记录气缸活塞的运动方程,辅以描述气缸工作腔和排气腔压力变化的方程,然后进行计算机模拟。作为数学模型的一部分,对瞬态过程进行了研究,因此,所有模拟结果都显示在活塞运动周期所限定的时间间隔内(即不考虑准备期和结束期)。研究了气缸输入和输出气路的有效面积对执行器动态过程的影响。结果表明,进气口直径的变化,以及工作腔或排气腔进气口面积的变化,会导致通信线路的流速和容量因子的变化,其特点是输出链路动能的变化,限制其工作速度,并确保驱动器输出链路运动的平稳性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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