The magnetohydrodynamic squeeze film

The present work advances experimental results and analytical predictions on the dynamic performance of an integral squeeze film damper (ISFD) for application in a high-speed super-critical CO2 (sCO2) expander. The test campaign focused on conducting controlled orbital motion mechanical impedance testing aimed at extracting stiffness and damping coefficients for varying end seal clearances, excitation frequencies, and vibration amplitudes. In addition to the measurement of stiffness and damping; the testing revealed the onset of cavitation for the ISFD. Results show damping behavior that is constant with vibratory velocity for each end seal clearance case until the onset of cavitation/air ingestion, while the direct stiffness measurement was shown to be linear. Measurable added inertia coefficients were also identified. The predictive model uses an isothermal finite element method to solve for dynamic pressures for an incompressible fluid using a modified Reynolds equation accounting for fluid inertia effects. The predictions revealed good correlation for experimentally measured direct damping, but resulted in grossly overpredicted inertia coefficients when compared to experiments.

Download Full-text

Squeeze-Film Damper Technology: Part 1 — Prediction of Finite Length Damper Performance

Volume 5: Ceramics; Structures and Dynamics; Controls, Diagnostics and Instrumentation; Education; Process Industries ◽

10.1115/83-gt-247 ◽

1983 ◽

Cited By ~ 4

Author(s):

J. W. Lund ◽

A. J. Smalley ◽

J. A. Tecza ◽

J. F. Walton

Keyword(s):

Finite Length ◽

Gas Turbines ◽

Squeeze Film ◽

Fluid Inertia ◽

Inertia Effects ◽

Strongly Coupled ◽

Squeeze Film Damper ◽

Rotor Systems ◽

Squeeze Film Dampers ◽

Calculation Results

Squeeze-film dampers are commonly used in gas turbine engines and have been applied successfully in a great many new designs, and also as retrofits to older engines. Of the mechanical components in gas turbines, squeeze-film dampers are the least understood. Their behavior is nonlinear and strongly coupled to the dynamics of the rotor systems on which they are installed. The design of these dampers is still largely empirical, although they have been the subject of a large number of past investigations. To describe recent analytical and experimental work in squeeze-film damper technology, two papers are planned. This abstract outlines the first paper, Part 1, which concerns itself with squeeze-film damper analysis. This paper will describe an analysis method and boundary conditions which have been developed recently for modelling dampers, and in particular, will cover the treatment of finite length, feed and drain holes and fluid inertia effects, the latter having been shown recently to be of great importance in predicting rotor system behavior. A computer program that solves the Reynolds equation for the above conditions will be described and sample calculation results presented.

Download Full-text

Fluid Inertia Effects in a Non-Newtonian Squeeze Film Between Two Plane Annuli

Journal of Tribology ◽

10.1115/1.1288928 ◽

1999 ◽

Vol 122 (4) ◽

pp. 872-875 ◽

Cited By ~ 11

Author(s):

R. Usha and ◽

P. Vimala

Keyword(s):

Carrying Capacity ◽

Integral Method ◽

Squeeze Flow ◽

Squeeze Film ◽

Load Carrying Capacity ◽

Fluid Inertia ◽

Inertia Effects ◽

Load Carrying ◽

Analytical Expressions ◽

Plastic Fluids

An analysis is presented for the laminar squeeze flow of an incompressible powerlaw fluid between parallel plane annuli using the modified lubrication theory and energy integral method. The local and the convective inertia of the flow are considered in the investigation. Analytical expressions for the load carrying capacity of the squeeze film are obtained using both the methods and are compared with those based on the assumption of inertialess flow. It is observed that the inertia correction in the load carrying capacity is more significant for pseudo-plastic fluids, n<1.[S0742-4787(00)00504-X]

Download Full-text

Squeeze Film Dampers Executing Small Amplitude Circular-Centered Orbits in High-Speed Turbomachinery

International Journal of Aerospace Engineering ◽

10.1155/2016/5127096 ◽

2016 ◽

Vol 2016 ◽

pp. 1-16 ◽

Cited By ~ 4

Author(s):

Sina Hamzehlouia ◽

Kamran Behdinan

Keyword(s):

Pressure Distribution ◽

Small Amplitude ◽

High Speed ◽

Fluid Film ◽

Distribution Model ◽

Squeeze Film ◽

Fluid Inertia ◽

Inertia Effects ◽

Squeeze Film Dampers ◽

Reaction Forces

This work represents a pressure distribution model for finite length squeeze film dampers (SFDs) executing small amplitude circular-centered orbits (CCOs) with application in high-speed turbomachinery design. The proposed pressure distribution model only accounts for unsteady (temporal) inertia terms, since based on order of magnitude analysis, for small amplitude motions of the journal center, the effect of convective inertia is negligible relative to unsteady (temporal) inertia. In this work, the continuity equation and the momentum transport equations for incompressible lubricants are reduced by assuming that the shapes of the fluid velocity profiles are not strongly influenced by the inertia forces, obtaining an extended form of Reynolds equation for the hydrodynamic pressure distribution that accounts for fluid inertia effects. Furthermore, a numerical procedure is represented to discretize the model equations by applying finite difference approximation (FDA) and to numerically determine the pressure distribution and fluid film reaction forces in SFDs with significant accuracy. Finally, the proposed model is incorporated into a simulation model and the results are compared against existing SFD models. Based on the simulation results, the pressure distribution and fluid film reaction forces are significantly influenced by fluid inertia effects even at small and moderate Reynolds numbers.

Download Full-text

A simple expression for fluid inertia force acting on micro-plates undergoing squeeze film damping

Proceedings of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rspa.2010.0216 ◽

2010 ◽

Vol 467 (2126) ◽

pp. 522-536 ◽

Cited By ~ 5

Author(s):

Shujuan Huang ◽

Diana-Andra Borca-Tasciuc ◽

John A. Tichy

Keyword(s):

Separation Distance ◽

Simple Expression ◽

Squeeze Film ◽

Inertia Force ◽

Viscous Damping ◽

Fluid Inertia ◽

Inertia Effects ◽

Viscous Forces ◽

Squeeze Film Damping ◽

Micro Plates

Squeeze film damping in systems employing micro-plates parallel to a substrate and undergoing small normal vibrations is theoretically investigated. In high-density fluids, inertia forces may play a significant role affecting the dynamic response of such systems. Previous models of squeeze film damping taking inertia into account do not clearly isolate this effect from viscous damping. Therefore, currently, there is no simple way to distinguish between these two hydrodynamic effects. This paper presents a simple solution for the hydrodynamic force acting on a plate vibrating in an incompressible fluid, with distinctive terms describing inertia and viscous damping. Similar to the damping constant describing viscous losses, an inertia constant, given by ρL 3 W / h (where ρ is fluid density, L and W are plate length and width, respectively, and h is separation distance), may be used to accurately calculate fluid inertia for small oscillation Reynolds numbers. In contrast with viscous forces that suppress the amplitude of the oscillation, it is found that fluid inertia acts as an added mass, shifting the natural frequency of the system to a lower range while having little effect on the amplitude. Dimensionless parameters describing the relative importance of viscous and inertia effects also emerge from the analysis.

Download Full-text

Effects of Fluid Inertia and Turbulence on the Force Coefficients for Squeeze Film Dampers

Journal of Engineering for Gas Turbines and Power ◽

10.1115/1.3239908 ◽

1986 ◽

Vol 108 (2) ◽

pp. 332-339 ◽

Cited By ~ 38

Author(s):

L. San Andre´s ◽

J. M. Vance

Keyword(s):

Squeeze Film ◽

Fluid Inertia ◽

High Eccentricity ◽

Small Eccentricity ◽

Inertia Effects ◽

Force Coefficients ◽

Inertia Coefficient ◽

Squeeze Film Dampers ◽

Order Of Magnitude ◽

Large Eccentricity

The effects of fluid inertia and turbulence on the force coefficients of squeeze film dampers are investigated analytically. Both the convective and the temporal terms are included in the analysis of inertia effects. The analysis of turbulence is based on friction coefficients currently found in the literature for Poiseuille flow. The effect of fluid inertia on the magnitude of the radial direct inertia coefficient (i.e., to produce an apparent “added mass” at small eccentricity ratios, due to the temporal terms) is found to be completely reversed at large eccentricity ratios. The reversal is due entirely to the inclusion of the convective inertia terms in the analysis. Turbulence is found to produce a large effect on the direct damping coefficient at high eccentricity ratios. For the long or sealed squeeze film damper at high eccentricity ratios, the damping prediction with turbulence included is an order of magnitude higher than the laminar solution.

Download Full-text

Fluid inertia effects in a squeeze film. Evaluation of various approximate solutions in a large sinusoidal squeezing motion.

TRANSACTIONS OF THE JAPAN SOCIETY OF MECHANICAL ENGINEERS Series C ◽

10.1299/kikaic.54.919 ◽

1988 ◽

Vol 54 (500) ◽

pp. 919-926

Author(s):

Yoshio HARUYAMA ◽

Atsunobu MORI ◽

Haruo MORI ◽

Fusao MIKAMI ◽

Tsuneji KAZAMAKI ◽

...

Keyword(s):

Approximate Solutions ◽

Squeeze Film ◽

Fluid Inertia ◽

Inertia Effects

Download Full-text

Forced Response of a Flexible Rotor With Squeeze Film Damper Under Parametric Change

Volume 7A: Structures and Dynamics ◽

10.1115/gt2013-95861 ◽

2013 ◽

Author(s):

Feng He ◽

Paul E. Allaire ◽

Saeid Dousti ◽

Alexandrina Untaroiu

Keyword(s):

Harmonic Balance Method ◽

Forced Response ◽

Squeeze Film ◽

Flexible Rotor ◽

Fluid Inertia ◽

Inertia Effects ◽

Squeeze Film Damper ◽

Vibrational Response ◽

Parametric Change ◽

Gyroscopic Effects

Squeeze film dampers play an important role in the dynamics of modern turbomachinery by improving vibrational response and stability. The present paper develops an effective tool for evaluating the forced response of these systems under parametric changes. A flexible rotor with multiple masses supported on a squeeze film damper at one end is investigated. The forced response of this asymmetrically supported system is obtained using the harmonic balance method with a predictor-corrector procedure. This response is examined with various parameters including unbalance forces with and without fluid inertia effects, unidirectional loads, stiffness of centering spring of the damper and the gyroscopic effects of the disks. The developed tool predicts the nonlinear jump phenomenon of the damper with large unbalance forces, indicates the present of multiple harmonics within the response with high damper eccentricity and shows the insensitivity of the damper to surrounding gyroscopic variation.

Download Full-text

Experimental Pressures and Film Forces in a Squeeze Film Damper

Journal of Tribology ◽

10.1115/1.2920966 ◽

1993 ◽

Vol 115 (1) ◽

pp. 134-140 ◽

Cited By ~ 13

Author(s):

G. L. Arauz ◽

L. A. San Andres

Keyword(s):

Tangential Force ◽

Radial Force ◽

Squeeze Film ◽

Radial Clearance ◽

Fluid Inertia ◽

Damping Force ◽

Inertia Effects ◽

Squeeze Film Dampers ◽

Tangential Forces ◽

Lubricant Viscosity

The effect of whirl frequency and lubricant viscosity on the dynamic pressures and force response of an open end and a partially sealed squeeze film dampers (SFD) with a radial clearance of 0.38 mm is determined experimentally. The experiments are carried out in a damper test rig executing circular centered orbits and for whirl frequencies ranging from 33 to 83 Hz. The experimental results show that the sealed SFD configuration produces larger tangential forces than the open end SFD. The tangential (damping) force increases linearly with increasing whirl frequency. For this radial clearance fluid inertia effects in the damper are found to be negligible since the squeeze film Reynolds number is less than 1.20. Cavitation was observed in both damper configurations at high frequencies and high lubricant viscosities. This condition limited the rate of increment of the damping (tangential) force with increasing frequency and reduced the radial force when lubricant viscosity increased.

Download Full-text

Magnetohydrodynamic lubrication flow between parallel plates

Journal of Fluid Mechanics ◽

10.1017/s002211206600137x ◽

1966 ◽

Vol 26 (3) ◽

pp. 537-543 ◽

Cited By ~ 38

Author(s):

E. Roland Maki ◽

Dennis C. Kuzma ◽

Russell J. Donnelly

Keyword(s):

Thrust Bearing ◽

Lubrication Theory ◽

Parallel Plates ◽

Fluid Inertia ◽

Inertia Effects ◽

Theory And Experiment ◽

Good Agreement

The magnetohydrodynamic lubrication flow in an externally pressurized thrust bearing is investigated both theoretically and experimentally. The ordinary magnetohydrodynamic lubrication theory for this bearing is extended to include fluid inertia effects. Very good agreement is obtained between theory and experiment.

Download Full-text