Investigating peak stresses in fitting and repair patches of buried polyethylene gas pipes

Nowadays, polyethylene composes a large number of natural gas distribution pipelines installed under the ground. The focus of the present contribution is two fold. One of the objectives is to investigate the applicability of polyethylene fittings in joining polyethylene gas pipes which are electrofu...

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Bibliographic Details
Published in:Frontiers of Structural and Civil Engineering 2020-02, Vol.14 (1), p.147-168
Main Authors: KHADEMI ZAHEDI, Reza, ALIMOURI, Pouyan, KHADEMI ZAHEDI, Hooman, SHISHESAZ, Mohammad
Format: Article
Language:English
Subjects:
Ansys software
buried pipelines
Buried pipes
CAD
Cities
Civil Engineering
Columnar structure
Computer aided design
Computer applications
Computer simulation
Countries
Engineering
Finite element method
Fittings
Gas pipelines
Gas pipes
Hot climates
Internal pressure
Jointing
Loads (forces)
Mathematical models
Natural gas
Natural gas distribution
Natural gas industry
Oil and gas industry
Patches (structures)
peak von Mises stress
Pipe fittings
Pipe joints
Pipelines
Pipes
Polyethylene
polyethylene joints
polyethylene patches
Polyethylenes
Regions
Repair
Research Article
soil-pipe interaction
Soil-structure interaction
Soils
Stress concentration
Stress distribution
temperature variation
Thermal analysis
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Summary:Nowadays, polyethylene composes a large number of natural gas distribution pipelines installed under the ground. The focus of the present contribution is two fold. One of the objectives is to investigate the applicability of polyethylene fittings in joining polyethylene gas pipes which are electrofused onto the pipe ends and buried under the ground, by estimating stress distribution using finite element method. The second objective is to study the effectiveness of polyethylene repair patches which are used to mend the defected pipelines by performing a finite element analysis to calculate peak stress values. Buried polyethylene pipelines in the natural gas industry, can be imposed by sever loadings including the soil-structure interaction, traffic load, soil's column weight, internal pressure, and thermal loads resulting from daily and/or seasonal temperature changes. Additionally, due to the application of pipe joints, and repair patches local stresses superimposed on the aforementioned loading effects. The pipe is assumed to be made of PE80 resin and its jointing socket, and the repair patch is PE100 material. The computational analysis of stresses and the computer simulations are performed using ANSYS commercial software. According to the results, the peak stress values take place in the middle of the fitting and at its internal surface. The maximum stress values in fitting and pipe are below the allowable stresses which shows the proper use of introduced fitting is applicable even in hot climate areas of Ahvaz, Iran. Although the buried pipe is imposed to the maximum values of stresses, the PE100 socket is more sensitive to a temperature drop. Furthermore, all four studied patch arrangements show significant reinforcing effects on the defected section of the buried PE gas pipe to transfer applied loads. Meanwhile, the defected buried medium density polyethylene gas pipe and its saddle fused patch can resist the imposed mechanical and thermal loads of 22°C temperature increase. Moreover, increasing the saddle fusion patch length to 12 inches reduces the maximum stress values in the pipe, significantly.
ISSN:2095-2430
2095-2449
DOI:10.1007/s11709-019-0587-6