Abstract
Pneumatic cylinders are widely used in highly dynamic processes, such as handling and conveying tasks. They must work both reliably and accurately. The positioning accuracy suffers from the stick-slip effect due to strong adhesive forces during the seal contact and the associated high breakaway forces. To achieve smooth motion of the piston rod and increased position accuracy despite highly variable position dynamics, sliding friction and breakaway force must be reduced. This contribution presents a specially designed linear tribometer that has two types of control. Velocity control allows the investigation of sliding friction mechanisms. Friction force control allows investigation of the breakaway force. Due to its bearing type, the nearly disturbance-free detection of stick-slip transients and the dynamic contact behavior of the sliding friction force was possible. The reduction of the friction force was achieved by a superposition of the piston rod’s movement by longitudinal ultrasonic vibrations. This led to significant reductions in friction forces at the rubber/metal interface. In addition, the effects of ultrasonic frequency and vibration amplitude on the friction reduction were investigated. With regard to the breakaway force, significant success was achieved by the excitation. The force control made it possible to identify the characteristic movement of the sealing ring during a breakaway process.
Highlights
Accepted: 1 July 2021The versatile use of pneumatic cylinders in various industrial positioning tasks requires increased efficiency and process quality, the demand for the realization of preset velocity profiles
The force control was implemented for the identification of the breakaway force as a function of the ultrasonic amplitude and the sealing ring material
The introduced tribometer enables the precise quantitative identification of frictional characteristics of seals exposed to ultrasonic vibrations with high reproducibility
Summary
The versatile use of pneumatic cylinders in various industrial positioning tasks requires increased efficiency and process quality, the demand for the realization of preset velocity profiles. The friction induced stick-slip effects occurring in the sealing contacts significantly restrict the positioning accuracy. Used concepts to reduce friction in pneumatic sealing contacts consist either of adapting sealing parameters, such as the materials and geometry, or of parametrizing the contact partners by lubricating or coating the contact surfaces. The reduction of contact-friction by applying piezoelectrically excited ultrasonic vibrations is used in many processes of ultrasonic machining, and recently made inroads into pneumatic servo systems [1,2,3,4,5]. In [7], an explanation of macroscopic friction reduction in the presence of ultrasonic vibrations was given using
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