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Modeling and testing for hydraulic shock regarding a valve-less electro-hydraulic servo steering device for ships

  • Jian, Liao (Institute of Noise & Vibration, Naval University of Engineering) ;
  • Lin, He (Institute of Noise & Vibration, Naval University of Engineering) ;
  • Rongwu, Xu (Institute of Noise & Vibration, Naval University of Engineering)
  • Received : 2015.03.25
  • Accepted : 2015.11.30
  • Published : 2015.12.31

Abstract

A valve-less electro-hydraulic servo steering device (short: VSSD) for ships was chosen as a study object, and its mathematic model of hydraulic shock was established on the basis of flow properties and force balance of each component. The influence of system structure parameters, changing rate of motor speed and external load on hydraulic shock strength was simulated by the method of numerical simulation. Experiment was designed to test the hydraulic shock mathematic model of VSSD. Experiment results verified the correctness of the model, and the model provided a correct theoretical method for the calculation and control of hydraulic shock of valve-less electro-hydraulic servo steering device.

Keywords

References

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