Oil seals in centrifugal compressors reduce leakage of the process gas into the support bearings and ambient. Under certain operating conditions of speed and pressure, oil seals lock, becoming a source of hydrodynamic instability due to excessively large cross coupled stiffness coefficients. It is a common practice to machine circumferential grooves, breaking the seal land, to isolate shear flow induced film pressures in contiguous lands, and hence reducing the seal cross coupled stiffnesses. Published tests results for oil seal rings shows that an inner land groove, shallow or deep, does not actually reduce the cross-stiffnesses as much as conventional models predict. In addition, the tested grooved oil seals evidenced large added mass coefficients while predictive models, based on classical lubrication theory, neglect fluid inertia effects. This paper introduces a bulk-flow model for groove oil seals operating eccentrically and its solution via the finite element (FE) method. The analysis relies on an effective groove depth, different from the physical depth, which delimits the upper boundary for the squeeze film flow. Predictions of rotordynamic force coefficients are compared to published experimental force coefficients for a smooth land seal and a seal with a single inner groove with depth equaling 15 times the land clearance. The test data represent operation at 10 krpm and 70 bar supply pressure, and four journal eccentricity ratios (e/c= 0, 0.3, 0.5, 0.7). Predictions from the current model agree with the test data for operation at the lowest eccentricities (e/c= 0.3) with discrepancies increasing at larger journal eccentricities. The new flow model is a significant improvement towards the accurate estimation of grooved seal cross-coupled stiffnesses and added mass coefficients; the latter was previously ignored or largely under predicted.

References

1.
Childs
,
D. W.
,
Rodriguez
,
L. E.
,
Cullotta
,
V.
,
Al-Ghasem
,
A.
, and
Graviss
,
M.
, 2006, “
Rotordynamic-Coefficients and Static (Equilibrium Loci and Leakage) Characteristics for Short, Laminar-Flow Annular Seals
,”
ASME J. Tribol.
128
(
2
), pp.
378
387
.
2.
Kirk
,
R.
, 1986, “
Oil Seal Dynamic Considerations for Analysis of Centrifugal Compressors
,” Proc. 15th Turbomachinery Symposium, Houston, TX, pp.
25
34
.
3.
Semanate
,
J.
, and
San Andrés
,
L.
, 1993, “
Analysis of Multi-Land High Pressure Oil Seals
,”
STLE Tribol. Trans.
36
(
4
), pp.
661
669
.
4.
Baheti
,
S.
and
Kirk
,
R.
, 1995, “
Finite Element Thermo-Hydrodynamic Solution of Floating Ring Seals for High Pressure Compressors Using the Finite-Element Method
,”
STLE Tribol. Trans.
,
38
, pp.
86
97
.
5.
Allaire
,
P. E.
, and
Kocur
,
J. A.
Jr.
, 1985, “
Oil Seal Effects and Subsynchronous Vibrations in High-Speed Compressors
,”
Proc. Symposium on Instability in Rotating Machinery
, Carson City, Nevada, June 10–14, NASA Conf. Publ. 2409, pp.
205
223
.
6.
Childs
,
D. W.
,
Graviss
,
M.
, and
Rodriguez
,
L. E.
, 2007, “
The Influence of Groove Size on the Static and Rotordynamic Characteristics of Short, Laminar-Flow Annular Seals
,”
ASME J. Tribol.
129
(
2
), pp.
398
406
.
7.
Graviss
,
M.
, 2005, “
The Influence of a Central Groove on Static and Dynamic Characteristics of an Annular Liquid Seal with Laminar Flow
,” M.S. thesis, Texas A&M University, College Station, TX.
8.
Childs
,
D. W.
, 1993,
Turbomachinery Rotordynamics
,
John Wiley & Sons, New York
, Chap. 3.
9.
Wilcox
,
E.
, 1999, “
Unexpected Rotordynamic Instability in a ‘Proven’ FCC Wet Gas Compressor
,”
Proc. of the 28th Turbomachinery Symposium
, Texas A&M University, Houston (September),
28
, pp.
41
49
.
10.
Kaneko
,
S.
,
Hori
,
Y.
, and
Tanaka
,
M.
, 1984, “
Static and Dynamic Characteristics of Annular Plain Seals
,”
Proc. Third IMechE Int. Conf. Vibrations in Rotating Machinery
, York, England, pp.
205
214
.
11.
Zirkelback
,
N.
, and
San Andrés
,
L.
, 1996, “
Bulk-Flow Model for the Transition to Turbulence Regime in Annular Seals
,”
STLE Tribol. Trans.
,
39
(
4
), pp.
835
842
.
12.
Reinhardt
,
F.
, and
Lund
,
J. W.
, 1975, “
The Influence of Fluid Inertia on the Dynamic Properties of Journal Bearings
,”
ASME J. Lubr. Technol.
,
97
(
1
), pp.
154
167
.
13.
Delgado
,
A.
, and
San Andrés
,
L.
, 2010, “
A Model for Improved Prediction of Force Coefficients in Grooved Squeeze Film Dampers and Oil Seal Rings
,”
ASME J. Tribol.
,
132
(
3
),
032202
.
14.
Gehannin
,
J.
,
Arghir
,
M.
, and
Bonneau
O.
, 2010, “
Complete Squeeze-Film Damper Analysis Based on the ‘Bulk Flow’ Equations
,”
STLE Tribol. Trans.
,
53
, pp.
84
96
.
15.
Arghir
,
M.
, and
Frene
,
J.
, 2004, “
A Bulk-flow Analysis of Static and Dynamic Characteristics of Eccentric Circumferentially-Grooved Liquid Annular Seals
,”
ASME J. Tribol.
126
(
2
), pp.
316
326
.
16.
San Andrés
,
L.
, and
Vance
,
J.
, 1986, “
Effect of Fluid Inertia on Squeeze-Film Damper Forces for Small-Amplitude Circular-Centered Motions
,”
ASLE Trans.
30
(
1
), pp.
63
68
.
17.
San Andrés
,
L.
, 2009, “
Thermal Analysis of Finite Length Journal Bearings Including Fluid Inertia, Modern Lubrication Theory
,” Notes 7,
Texas A&M University, Virtual Library System
, https://repository.tamu.edu/handle/1969.1/93197
18.
Reddy
,
J. N.
, and
Gartling
,
D. K.
, 2001,
The Finite Element Method in Heat Transfer and Fluid Dynamics
,
CRC Press
,
Boca Raton, FL
, Chap. 2.
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