The bulk-flow equations used for inertia dominated thin-film flows is an attractive model for the analysis of circumferentially grooved annular seals because the solutions based on the numerical integration of the complete Navier-Stokes equations can be very time-consuming. By using three types of control volumes and some user-tuned constants, the bulk-flow model can be used for calculating the static and the dynamic characteristics. Until now, this has been carried out for centered seals where the flow is governed by ordinary differential equations but no solutions have yet been given for eccentric working conditions. In this latter case, the model is governed by partial differential equations of an elliptic type. The main problem is that for describing the groove effects, the pressure field must incorporate the concentrated drop or recovery effects that occur at the interface between the groove and the land zone. This means that the numerical procedure used for solving the elliptic equations should be able to handle a pressure field having discontinuous values and discontinuous first order derivatives. In the present work, the method used for integrating the system of bulk-flow equations is the SIMPLE algorithm. The algorithm is extended for handling pressure jumps by adding two pressure values on each side of the discontinuity. These values are then expressed in terms of cell centered pressures by imposing the mass conservation and the generalized Bernoulli equation at the discontinuity. This numerical solution is original and has never previously been presented in the finite volume related literature. Comparisons between the numerical predictions (leakage flow rate and rotordynamic coefficients) and experimental data taken from the literature Marquette and Childs (1997) are subsequently presented for an eccentric ten-groove annular seal.
[1]
Jean Frene,et al.
A Triangle Based Finite Volume Method for the Integration of Lubrication’s Incompressible Bulk Flow Equations
,
2001
.
[2]
Dara W. Childs,et al.
Analysis for Rotordynamic Coefficients of Helically-Grooved Turbulent Annular Seals
,
1987
.
[3]
Dara W. Childs,et al.
An Extended Three-Control-Volume Theory for Circumferentially-Grooved Liquid Seals
,
1996
.
[4]
S. Patankar.
Numerical Heat Transfer and Fluid Flow
,
2018,
Lecture Notes in Mechanical Engineering.
[5]
D. L. Rhode,et al.
Three-dimensional computations of rotordynamic force distributions in a labyrinth seal
,
1993
.
[6]
G. G. Hirs.
A Bulk-Flow Theory for Turbulence in Lubricant Films
,
1973
.
[7]
Michael A. Leschziner,et al.
Flow in Finite-Width, Thrust Bearings Including Inertial Effects: I—Laminar Flow
,
1978
.
[8]
G. N. Abramovich.
The Theory of Turbulent Jets
,
2003
.
[9]
Luis San Andrés,et al.
Analysis of Variable Fluid Properties, Turbulent Annular Seals
,
1991
.
[10]
Mihai Arghir,et al.
The finite volume solution of the Reynolds equation of lubrication with film discontinuities
,
2002
.