Pressure-Drop Coefficients for Cushioning System of Hydraulic Cylinder With Grooved Piston: A Computational Fluid Dynamic Simulation

Cushioning is an important aspect in hydraulic cylinder performance. The piston has to be decelerated before it strikes the end cap in order to avoid stresses in the cylinder components and reduce vibration that can be transmitted to the machine. One of the least-studied methods is internal cushioning by grooves in the piston. In this method, the flow is throttled with adequately designed grooves when the piston reaches the outlet port position. The purpose of the present work is to present a method to estimate the pressure-drop coefficients for a certain design of piston grooves in order to provide a model to develop a dynamic system simulation of the cushion system. The method is based on a computational fluid dynamic simulation of flow through piston grooves to the outlet port for each piston’s static position. The results are compared with experimental measurements, and a correction, based on Reynolds number, is proposed. Good agreement, below 16%, was obtained for all the positions but particularly for the last grooves, for which the numerical result’s deviation to the experimental measurements was less than 10%. In general, the numerical simulation tended to underestimate the pressure drop for the first grooves and overestimate the calculation for the last grooves.

[1]  Xiaohua Wang,et al.  Optimization design on step-shape cushioning for hydraulic operating mechanism of high voltage circuit breakers , 2016, 2016 International Conference on Condition Monitoring and Diagnosis (CMD).

[2]  Massimo Borghi,et al.  Mechanical Cushion Design Influence on Cylinder Dynamics , 2005 .

[3]  Nils T. Basse,et al.  Scaling of turbulence intensity for low-speed flow in smooth pipes , 2016 .

[4]  Tomasz Zawistowski,et al.  Gap Flow Simulation Methods in High Pressure Variable Displacement Axial Piston Pumps , 2017, Archives of computational methods in engineering : state of the art reviews.

[5]  J. Watton,et al.  The hydrostatic/hydrodynamic behaviour of an axial piston pump slipper with multiple lands , 2010 .

[6]  Sushil Kumar,et al.  The effect of piston grooves performance in an axial piston pumps via CFD analysis , 2013 .

[7]  Ch. Prahallad,et al.  Modeling and Optimization of Cushioning System in Hydraulic Cylinder to achieve Performance Characteristics , 2016 .

[8]  Kern E. Kenyon Flow past a Groove , 2015 .

[9]  Rana Saha,et al.  Actuation dynamic modeling and characterization of an electrohydraulic system , 2016, J. Syst. Control. Eng..

[10]  Patrick J. Roache,et al.  Verification and Validation in Computational Science and Engineering , 1998 .

[11]  V. J. De Negri,et al.  Modeling and Analysis of an Auto- Adjustable Stroke End Cushioning Device for Hydraulic Cylinders , 2005 .

[12]  D. Wilcox Turbulence modeling for CFD , 1993 .

[13]  T. Virvalo On the damping of a hydraulic cylinder drive , 1999 .

[14]  J. Watton,et al.  A complete analysis of axial piston pump leakage and output flow ripples , 2012 .

[15]  Xiaoye Qi,et al.  Modeling Analysis and Simulation of Hydraulic Axial Piston Pump , 2012 .

[16]  Monika Ivantysynova,et al.  INVESTIGATION OF THE GAP FLOW IN DISPLACEMENT MACHINES CONSIDERING ELASTOHYDRODYNAMIC EFFECT , 2002 .

[17]  Hassan Zahouani,et al.  The effect of groove texture patterns on piston-ring pack friction , 2012 .

[18]  Esteban Codina,et al.  Experimental Study of 3D Movement in Cushioning of Hydraulic Cylinder , 2017 .

[19]  S. R. Majumdar,et al.  Oil Hydraulic Systems : Principles and Maintenance , 2002 .

[20]  Florian,et al.  Improved Two-Equation k- Turbulence Models for Aerodynamic Flows , 2022 .