In this paper, we report an experimental approach to examine a fast-developing flow in a thin fluid gap. The phenomenon is widely observed in industrial applications, e.g., squeeze dampers, and in biological systems, e.g., joints lubrication. However, experimental investigations that capture the transient nature of the flow during the process are lacking. An experimental setup, consisting of a piston equipped with a laser displacement sensor and a pressure transducer, was developed. The loading surface was released from rest, creating a fast compaction on the fluid. The motion of the piston and the resulting changes of fluid pressure were recorded and compared to four representative theoretical models. The results show that the maximum pressure increases with gap height and/or the applied loading. A higher fluid viscosity leads to a lower maximum pressure but significantly extends the fluid pressure relaxation time. It is clearly demonstrated that the pressure response is governed by both the inertial effect due to the local acceleration, and the viscous effect due to the stokes resistance, revealing fundamental physics during the fast-developing squeezing flow process.
Skip Nav Destination
Article navigation
August 2019
Research-Article
Experimental Study of Transient Squeezing Film Flow
Ji Lang,
Ji Lang
Cellular Biomechanics and
Sports Science Laboratory,
Department of Mechanical Engineering,
Villanova University,
800 Lancaster Avenue,
Villanova, PA 19085
e-mail: jlang8@villanova.edu
Sports Science Laboratory,
Department of Mechanical Engineering,
Villanova University,
800 Lancaster Avenue,
Villanova, PA 19085
e-mail: jlang8@villanova.edu
Search for other works by this author on:
Rungun Nathan,
Rungun Nathan
Division of Engineering,
Pennsylvania State University,
Berks 1801 Broadcasting Road,
Reading, PA 19610
e-mail: rungun.nathan@psu.edu
Pennsylvania State University,
Berks 1801 Broadcasting Road,
Reading, PA 19610
e-mail: rungun.nathan@psu.edu
Search for other works by this author on:
Qianhong Wu
Qianhong Wu
Cellular Biomechanics and
Sports Science Laboratory,
Department of Mechanical Engineering,
Villanova University,
800 Lancaster Avenue,
Villanova, PA 19085
e-mail: qianhong.wu@villanova.edu
Sports Science Laboratory,
Department of Mechanical Engineering,
Villanova University,
800 Lancaster Avenue,
Villanova, PA 19085
e-mail: qianhong.wu@villanova.edu
Search for other works by this author on:
Ji Lang
Cellular Biomechanics and
Sports Science Laboratory,
Department of Mechanical Engineering,
Villanova University,
800 Lancaster Avenue,
Villanova, PA 19085
e-mail: jlang8@villanova.edu
Sports Science Laboratory,
Department of Mechanical Engineering,
Villanova University,
800 Lancaster Avenue,
Villanova, PA 19085
e-mail: jlang8@villanova.edu
Rungun Nathan
Division of Engineering,
Pennsylvania State University,
Berks 1801 Broadcasting Road,
Reading, PA 19610
e-mail: rungun.nathan@psu.edu
Pennsylvania State University,
Berks 1801 Broadcasting Road,
Reading, PA 19610
e-mail: rungun.nathan@psu.edu
Qianhong Wu
Cellular Biomechanics and
Sports Science Laboratory,
Department of Mechanical Engineering,
Villanova University,
800 Lancaster Avenue,
Villanova, PA 19085
e-mail: qianhong.wu@villanova.edu
Sports Science Laboratory,
Department of Mechanical Engineering,
Villanova University,
800 Lancaster Avenue,
Villanova, PA 19085
e-mail: qianhong.wu@villanova.edu
1Corresponding author.
Contributed by the Fluids Engineering Division of ASME for publication in the JOURNAL OF FLUIDS ENGINEERING. Manuscript received October 9, 2018; final manuscript received January 14, 2019; published online March 4, 2019. Assoc. Editor: Arindam Banerjee.
J. Fluids Eng. Aug 2019, 141(8): 081110 (7 pages)
Published Online: March 4, 2019
Article history
Received:
October 9, 2018
Revised:
January 14, 2019
Citation
Lang, J., Nathan, R., and Wu, Q. (March 4, 2019). "Experimental Study of Transient Squeezing Film Flow." ASME. J. Fluids Eng. August 2019; 141(8): 081110. https://doi.org/10.1115/1.4042758
Download citation file:
Get Email Alerts
Related Articles
Extending Classical Friction Loss Modeling to Predict the Viscous Performance of Pumping Devices
J. Fluids Eng (October,2019)
Parametric Study of Motor/Shroud Heat Transfer Performance in an Electrical Submersible Pump (ESP)
J. Energy Resour. Technol (September,2000)
Pure Squeeze Motion in a Magneto-Elastohydrodynamic Lubricated Spherical Conjunction
J. Tribol (October,2010)
Advanced Geothermal Wellbore Hydraulics Model
J. Energy Resour. Technol (September,2000)
Related Chapters
Boundary Layer Analysis
Centrifugal Compressors: A Strategy for Aerodynamic Design and Analysis
Dynamic Behavior of Pumping Systems
Pipeline Pumping and Compression Systems: A Practical Approach
Introduction
Axial-Flow Compressors