Abstract

A semi-empirical procedure has been developed for predicting erosion rates in pipe geometries, such as elbows and tees. The procedure can be used to estimate safe operating conditions and velocities in oil and gas production where sand is present. In the proposed procedure, a concept is introduced that allows determination of erosion rate for different pipe geometries. In the procedure, based on empirical observations, the erosion rate is related to the impact velocity of sand particles on a pipe fitting wall. A simplified particle tracking model is developed and is used to estimate the impact velocity of sand particles moving in a stagnation region near the pipe wall. A new concept of equivalent stagnation length allows the simplified procedure to be applicable to actual pipe geometries. The “equivalent stagnation regions” of an elbow and a tee geometry of different sizes are obtained from experimental data for small pipe diameters, and a computational model is used to extend the procedure to larger pipe diameters. Currently, the prediction method applies to mild steel and accounts for the effects of sand size, shape, and density; fluid density, viscosity, and flow speed; and pipe size and shape. The proposed method has been verified for gas and liquid flows through several comparisons with experimental data reported in the literature. The results of the model accurately predict the effects of sand size and fluid viscosity observed in the experiments. Furthermore, predicted erosion rates showed good agreement with experimental data for gas, liquid, and gas-liquid flows in several 50.8-mm (2-in.) elbows and tees.

Issue Section:
Research Papers
Topics:
Erosion, Particulate matter, Pipes, Sands, Flow (Dynamics), Shapes, Viscosity, Computer simulation, Density, Fluid density, Fluids, Geometry, Pipe fitting, Pipe sizes, Steel
1.
Andrews
D. R.
,
1981
, “
An Analysis of Solid Particle Erosion Mechanisms
,”
Journal of Physics and Dynamics: Applied Physics
, Vol.
14
, pp.
1979
1991
.
2.
API Recommended Practice for Design and Installation of Offshore Production Platform Piping Systems, 1981, API RP 14E, American Petroleum Institute, Third Edition, Washington DC, Dec. 1981.
3.
Beal
S. K.
,
1970
, “
Deposition of Particles in Turbulent Flow on Channel or Pipe Walls
,”
Nuclear Science and Engineering
, Vol.
40
, pp.
1
11
.
4.
Besnard
D. C.
, and
Harlow
F. H.
,
1986
, “
Nonspherical Particles in Two-Phase Flow
,”
International Journal of Multiphase Flow
, Vol.
12
, pp.
891
912
.
5.
Bitter
J. G. A.
,
1963
a, “
A Study of Erosion Phenomena, Part I
,”
Wear
, Vol.
6
, pp.
5
21
.
6.
Bitter
J. G. A.
,
1963
b, “
A Study of Erosion Phenomena, Part II
,”
Wear
, Vol.
6
, pp.
169
190
.
7.
Bourgoyne, A. T., Jr., 1989, “Experimental Study of Erosion in Diverter Systems Due to Sand Production,” presented at the SPE/IADC Drilling Conference, New Orleans, LA, SPE/IADC 18716.
8.
Chase
D. P.
,
Rybicki
E. F.
, and
Shadley
J. R.
,
1992
, “
A Model for the Effect of Velocity on Erosion of N80 Steel Tubing Due to the Normal Impingement of Solid Particles
,”
ASME Journal of Energy Resources Technology
, Vol.
114
, pp.
54
64
.
9.
Clark
H. McI.
,
1991
, “
On the Impact Rate and Impact Energy of Particles in a Slurry Pot Erosion Tester
,”
Wear
, Vol.
146
, pp.
165
183
.
10.
Crowe
C. T.
, and
Stock
D. E.
,
1976
, “
A Computer Solution for Two-Dimensional Fluid-Particle Flows
,”
International Journal for Numerical Methods in Engineering
, Vol.
10
, pp.
185
196
.
11.
Finnie, I., 1958, “The Mechanism of Erosion of Ductile Metals,” Proceedings, 3rd U.S. National Congress of Applied Mechanics, pp. 527–532.
12.
Flemmer
C. L.
,
Flemmer
R. L. C.
,
Means
K. H.
, and
Johnson
E. K.
,
1988
, “
The Erosion of Pipe Bends
,”
Design and Analysis of Piping, Pressure Vessels, and Components
, ASME PVP-Vol.
139
, pp.
93
98
.
13.
Glaeser, W. A., and Dow, A., 1977, “Mechanisms of Erosion in Slurry Pipelines,” Proceedings of the Second International Conference on Slurry Transportation, Las Vegas, NV, March 2-4, pp. 136–140.
14.
Gore
R. A.
, and
Crowe
C. T.
,
1989
, “
Effect of Particle Size on Modulating Turbulent Intensity
,”
International Journal of Multiphase Flow
, Vol.
15
, pp.
279
285
.
15.
Govan
A. H.
,
Hewitt
G. F.
, and
Ngan
C. F.
,
1989
, “
Particle Motion in a Turbulent Pipe Flow
,”
International Journal of Multiphase Flow
, Vol.
15
, pp.
471
481
.
16.
Hetsroni
G.
,
1989
, “
Particles-Turbulence Interaction
,”
International Journal of Multiphase Flow
, Vol.
15
, pp.
735
746
.
17.
Hinze, J. O., 1975, Turbulence, Second Edition, McGraw-Hill, New York, NY.
18.
Hutchings
I. M.
,
Winter
R. E.
, and
Field
J. E.
,
1976
, “
Solid Particle Erosion of Metals: the Removal of Surface Material by Special Projectiles
,”
Proceedings, Royal Society London A
, Vol.
348
, pp.
379
392
.
19.
Hutchings, I. M., 1980, “Some Comments on the Theoretical Treatment of Erosive Particle Impacts,” Proceedings, 5th International Conference on Erosion by Solid and Liquid Impact, pp. 36–1, 36–6.
20.
Hutchings, I. M., 1983, Monograph on the Erosion of Materials by Solid Particle Impact, Materials Technology Institute of the Chemical Process Industries, Inc., MTI Publication No. 10.
21.
Jahanmir
S.
,
1980
, “
The Mechanics of Subsurface Damage in Solid Particle Erosion
,”
Wear
, Vol.
61
, pp.
309
338
.
22.
Kallio
G. A.
, and
Reeks
M. W.
,
1989
, “
A numerical Simulation of Particle Deposition in Turbulent Boundary Layers
,”
International Journal of Multiphase Flow
, Vol.
15
, pp.
433
446
.
23.
Nesic
S.
, and
Postlethwaite
J.
,
1990
, “
Relationship Between the Structure of Disturbed Flow and Erosion-Corrosion
,”
Corrosion
, Vol.
46
, pp.
874
880
.
24.
Patankar, S. V., 1980, Numerical Heat Transfer and Fluid Flow, Hemisphere Publishing Corp., New York, NY.
25.
Postlethwaite
J.
,
Tinker
E. B.
, and
Hawrylak
M. W.
,
1974
, “
Erosion-Corrosion in Slurry Pipelines
,”
Corrosion
, Vol.
30
, pp.
285
290
.
26.
Rochester, M. C., and Brunton, J. H., 1974, “Influence of Physical Properties of the Liquid on the Erosion of Solids,” Erosion, Wear, and Interfaces with Corrosion, ASTM STP 567, American Society for Testing and Materials, pp. 128–151.
27.
Roco
M. C.
,
Nair
P.
,
Addie
G. R.
, and
Dennis
J.
,
1984
, “
Erosion of Concentrated Slurries in Turbulent Flow
,”
Journal of Pipelines
, Vol.
4
, pp.
213
221
.
28.
Rybicki, et al., 1992, Advisory Board Report for the Erosion/Corrosion Research Center, The University of Tulsa, OK, May.
29.
Salama, M. M., and Venkatesh, E. S., 1983, “Evaluation of Erosional Velocity Limitations in Offshore Gas Wells,” 15th Annual OTC, Houston, TX, May 2–5, OTC No. 4485.
30.
Sargent, G. A., Mehrotra, P. K., and Conrad, H., 1980, “A model for the Multiparticle Erosion of Brittle Solids by Spherical Particles,” Proceedings, 5th International Conference on Erosion by Solid and Liquid Impact, pp. 28-1–28-7.
31.
Shook, C. A., McKibben, M, and Small M., 1987, “Experimental Investigation of Some Hydrodynamics Factors Affecting Slurry Pipeline Wall Erosion,” ASME Paper No. 87-PVP-9.
32.
Smeltzer, C. E., Gulden, M. E., McElmury, S. S. and Compton, W. A., 1970, “Mechanisms of Sand and Dust Erosion in Gas Turbine Engines,” USAAMLABS Tech. Rep. 70-36, U.S. Army Air Mobility Research and Development Laboratory, Eustis Directorate, Fort Eustis, VA, Aug.
33.
Tilly
G. P.
,
1973
, “
A Two Stage Mechanism of Ductile Erosion
,”
Wear
, Vol.
23
, pp.
87
96
.
34.
Tolle, G. C., and Greenwood, D. R., 1977, “Design of Fittings to Reduce Wear Caused by Sand Erosion,” API OSAPER Project No. 6, American Petroleum Institute, Texas A&M Research Foundation, May.
35.
True, M. E., and Weiner, P. D., 1976, “A Laboratory Evaluation of Sand Erosion of Oil and Gas Well Production Equipment,” Annual API Production Division Meeting, Los Angeles, CA, pp. I-1–I-27.
36.
Venkatesh, E. S., 1986, “Erosion Damage in Oil and Gas Wells,” SPE Paper 15183, Rocky Mountain Regional Meeting of the Society of Petroleum Engineers, Billings, MT.
37.
Wei, B., 1991, “A Study of Solid Particle Erosion: Data Interpretation, Model Development, and Field Applications,” M.S. thesis, University of Tulsa, OK.
This content is only available via PDF.
Copyright © 1995
 by The American Society of Mechanical Engineers
You do not currently have access to this content.