The Effect of Spool Displacement Control to the Flow Rate in the Piezoelectric Stack-Based Valve System Subjected to High Operating Temperature

This work investigates the effect of spool displacement control of the piezoelectric stack actuator (PSA) based valve system on the flow motion of the pressure drop and flow rate. As a first step, the governing equations of the structural parts of the displacement amplifier and spool are derived, fo...

Full description

Saved in:
Bibliographic Details
Published inActuators Vol. 10; no. 9; p. 239
Main Authors Park, Yu-Jin, Kim, Bo-Gyu, Jeon, Jun-Cheol, Jung, Dongsoo, Choi, Seung-Bok
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.09.2021
Subjects
Accuracy
Actuators
Adhesives
compact valve system
Control algorithms
Displacement
Energy consumption
Feedback control
flow rate
Flow velocity
Hydraulics
Investigations
Medical equipment
Operating temperature
piezoelectric stack actuator
Piezoelectricity
Pneumatics
Pressure drop
Proportional integral derivative
Sine waves
spool displacement
spool sleeve
Steady flow
Temperature effects
Tracking control
Tracking errors
Trajectories
Online AccessGet full text

Cover

More Information
Summary:This work investigates the effect of spool displacement control of the piezoelectric stack actuator (PSA) based valve system on the flow motion of the pressure drop and flow rate. As a first step, the governing equations of the structural parts of the displacement amplifier and spool are derived, followed by the governing equation of the fluid part considering control volume and steady flow force. Then, an appropriate size of the valve is designed and manufactured. An experimental apparatus to control the spool displacement is set up in the heat chamber and tracking control for the spool displacement is evaluated at 20 °C and 100 °C by implementing a proportional-integral-derivative (PID) feedback controller. The tracking controls of the spool displacement associated with the sinusoidal and triangular trajectories are realized at 20 °C and 100 °C. It is demonstrated that the tracking controls for the sinusoidal and triangular trajectories have been well carried out showing the tracking error less than 3 μm at both temperatures. In addition, the flow motions for the pressure drop and the flow rate of the proposed valve system are experimentally investigated. It is identified from this investigation that both pressure drop and flow rate evaluated 20 °C have been decreased up to 18% at 100 °C. This result directly indicates that the temperature effect to control performance of the structural part and fluid part in the proposed PSA based valve system is different and hence careful attention is required to achieve the successful development of advanced valve systems subjected to a wide range of the operating temperature.
ISSN:2076-0825
2076-0825
DOI:10.3390/act10090239