Oscillation Damping With Input Shaping in Individual Metering Hydraulic Systems

Gerhard Rath, Emil Zaev, Darko Babunski

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Abstract

Motion of heavy loads with hydraulic or electrical drive systems cause oscillations, which reduce the position accuracy and cause wear to the mechanical system. Input shaping of the control input signal can avoid the excitation of the resonant frequency. A common technique is to use a notch-filter that is tuned to suppress this frequency. In this work the possibility to synthesize a notch filter with an all-pass filter is used. Splitting the filter into two parts allows to control two separate inputs of a push/pull system, in the actual case a hydraulic system with individual meter-in and meter-out valves (or separate meter-in/meter-out, SMISMO). An additional design parameter allows to tune for specific property of the drive, in our case avoiding low pressure and reduce the danger of cavitation. Furthermore, it is demonstrated how to replace the all-pass filter with a simple time delay, which enables the processing on a low-cost embedded system without numeric processor. The results are demonstrated in simulation.

Original languageEnglish
Title of host publication2019 8th Mediterranean Conference on Embedded Computing, MECO 2019 - Proceedings
EditorsRadovan Stojanovic, Lech Jozwiak, Budimir Lutovac, Drazen Jurisic
PublisherInstitute of Electrical and Electronics Engineers
ISBN (Electronic)9781728117393
DOIs
Publication statusPublished - 1 Jun 2019
Event8th Mediterranean Conference on Embedded Computing, MECO 2019 - Budva, Montenegro
Duration: 10 Jun 201914 Jun 2019

Publication series

Name2019 8th Mediterranean Conference on Embedded Computing, MECO 2019 - Proceedings

Conference

Conference8th Mediterranean Conference on Embedded Computing, MECO 2019
Country/TerritoryMontenegro
CityBudva
Period10/06/1914/06/19

Keywords

  • hydraulic system
  • individual metering
  • input shaping
  • notch filter
  • oscillation damping

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