6533b82cfe1ef96bd128ebea

RESEARCH PRODUCT

Full- and Reduced-order Model of Hydraulic Cylinder for Motion Control

Michael Ruderman

subject

Physics0209 industrial biotechnologyFrequency response020208 electrical & electronic engineeringOrifice plateSystems and Control (eess.SY)02 engineering and technologyMechanicsMotion controlSystem dynamicsPhysics::Fluid DynamicsNonlinear systemHydraulic cylinder020901 industrial engineering & automationFOS: Electrical engineering electronic engineering information engineering0202 electrical engineering electronic engineering information engineeringCylinderComputer Science - Systems and ControlBody orifice

description

This paper describes the full- and reduced-order models of an actuated hydraulic cylinder suitable for system dynamics analysis and motion control design. The full-order model incorporates the valve spool dynamics with combined dead-zone and saturation nonlinearities - inherent for the orifice flow. It includes the continuity equations of hydraulic circuits coupled with the dynamics of mechanical part of cylinder drive. The resulted model is the fifth-order and nonlinear in states. The reduced model neglects the fast valve spool dynamics, simplifies both the orifice and continuity equations through an aggregation, and considers the cylinder rod velocity as output of interest. The reduced model is second-order that facilitates studying the system behavior and allows for direct phase plane analysis. Dynamics properties are addressed in details, for both models, with focus on the frequency response, system damping, and state trajectories related to the load pressure and relative velocity.

yearjournalcountryeditionlanguage
2017-05-02
http://hdl.handle.net/11250/2451021