Many of the investigations dealing with the determination of the time-to-failure of high-density polyethylene (HDPE) pipes involve internal pressure tests. HDPE pipe, however, can also be subjected to external pressure such as from underwater laying, vacuum, or burial. For the particular case of uniform external pressure, only a small amount of data detailing the time-to-failure of such pipes is available, and no definitive testing procedure exists. Here, an experimental apparatus and corresponding testing procedure are developed to explore remedies for this situation. On the basis of the data thus obtained, a three-coefficient equation relating time, temperature, and pressure is generated. The failure predictions from this design basis equation are in good agreement with the available data existing in the literature.

1.
ASTM, 1991, “D 1598 Time to Failure of Plastic Under Constant Internal Pressure,” American Society for Testing and Material, Philadelphia, PA.
2.
ASTM, 1993, “D 2837 Standard Test Method For Obtaining Hydrostatic Design Basis for Thermoplastic Pipe Materials,” American Society for Testing and Material, Philadelphia, PA.
3.
PPI, 1992, PPI Technical Report, TR-3/92, “Policies and Procedures for Developing Recommended Hydrostatic Design Stress for Thermoplastic Pipe Materials,” Part W, p. 35.
4.
Widera, G. E. O., Shi, J., and Leon, G. F., 1996, “Development of a Reliable Procedure for Obtaining Design Coefficients for Thermoplastic Pipe under Internal Pressure,” Proc. Fourth International Conference on Fluid Sealing, Cannes, France.
5.
ASTM, 1993, “D 2924 Standard Test Method For External Pressure Resistance of Fiberglass (Glass-Fiber-Reinforced Thermosetting-Resin) Pipe,” American Society for Testing and Material, Philadelphia, PA.
6.
Short, II, W. E., Leon, G. F., Widera, G. E. O., Ziu, C. G., 1996, “Literature Survey and Interpretive Study on Thermoplastic and Reinforced-Thermosetting-Resin Piping and Component Standards,” Weld. Res. Counc. Bull., 415, New York, NY.
7.
Deutscher Verlag fuer Schweisstechnik, DVS, 1989, “Schweissen und Kleben von Kunstoffen R2205,” DVS-Verlag GmbH, Duesseldorf, Germany.
8.
ASTM, 1991, “D 2412 Determination of External Loading Characteristics of Plastic Pipe by Parallel Plate Loading,” American Society for Testing and Material, Philadelphia, PA.
9.
Farchad
,
M.
, and
Flueler
,
P.
,
1995
, “
Buckling Resistance of Polymer Pipes under Hydrostatic Pressure
,”
Plastics, Rubber and Composites Processing and Applications
,
25
, No.
8
, pp.
373
379
.
10.
Jenkins, C. F., and Kroll, D., 1981, “External Hydrostatic Loading of Polyethylene Pipe,” Proc. Int. Conference on Underground Plastic Pipe, New Orleans, LA, pp. 527–531.
11.
PHILIPS DRISCOPIPE, 1991, “System Design,” Philips Driscopipe, Richardson, TX, pp. 37, 48–49.
12.
Widera, G. E. O., and Zhao, L., 1999, “On the Determination of Long Term Hydrostatic Strength of Plastic (HDPE) Pipe,” WRC Bulletin 99-WRCB-06, “Plastic Pipe: Burst and Fatigue Testing of PVC and HDPE Pipe,” Welding Research Council, New York, NY.
13.
Widera, G. E. O., Qin, S. J., and Shi, J., 1994, “On the Use of Reliability Analysis in the Testing of Plastic Pipe,” Marquette University Report to PVRC, Milwaukee, WI.
14.
Labview Manual, National Instruments, Inc., 1998.
15.
O’Donnell, Hugh W., 1996, “Investigation of Pipeline Buckle Failure in a Horizontally Directionally Drilled Installation,” Pipeline Crossings, Proc., ASCE Specialty Conference. New York, NY, pp. 163–172.
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