An analytical model was proposed in this paper to predict the burst pressure of a pipe with geometric eccentricity. With application of the complex elastic potential function method in a bipolar coordinate system, the authors first derived an analytical solution of stresses in an eccentric pipe and then obtained the formula of predicting burst pressure by combining the solution with the Tresca criterion. Finally, the effect of eccentricity and the ratio of thickness to diameter of pipe on burst pressure were discussed. Our results show that a slight eccentricity can significantly decrease the burst pressure. In the special case of zero-eccentricity for a concentric pipe, our model yields results that are consistent with experiments data published by others and theoretical results predicted by models proposed by other researchers without considering the effect of eccentricity. In the case of eccentricity for an eccentric pipe, the calculating results of our model are also consistent with that of finite element model (FEM). The theoretical model and results presented in this paper have a broader application in predicting the burst pressure for pipes commonly used in oil and gas industry.
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December 2015
Research-Article
Prediction of Burst Pressure of Pipes With Geometric Eccentricity
Zhanfeng Chen,
Zhanfeng Chen
Shanghai Institute of Applied Mathematics
and Mechanics,
and Mechanics,
Shanghai University
,Shanghai 200072
, China
Shanghai Key Laboratory
of Mechanics in Energy Engineering,
of Mechanics in Energy Engineering,
Shanghai University
,Shanghai 200072
, China
Search for other works by this author on:
Weiping Zhu,
Weiping Zhu
1
Shanghai Institute of Applied Mathematics
and Mechanics,
and Mechanics,
Shanghai University
,Shanghai 200072
, China
Shanghai Key Laboratory
of Mechanics in Energy Engineering,
e-mail: wpzhu@shu.edu.cn
of Mechanics in Energy Engineering,
Shanghai University
,Shanghai 200072
, China
e-mail: wpzhu@shu.edu.cn
1Corresponding authors.
Search for other works by this author on:
Qinfeng Di,
Qinfeng Di
1
Shanghai Institute of Applied Mathematics
and Mechanics,
and Mechanics,
Shanghai University
,Shanghai 200072
, China
Shanghai Key Laboratory of
Mechanics in Energy Engineering,
e-mail: qinfengd@sina.com
Mechanics in Energy Engineering,
Shanghai University
,Shanghai 200072
, China
e-mail: qinfengd@sina.com
1Corresponding authors.
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Wenchang Wang
Wenchang Wang
Shanghai Institute of
Applied Mathematics and Mechanics,
Applied Mathematics and Mechanics,
Shanghai University
,Shanghai 200072
, China
Shanghai Key Laboratory of
Mechanics in Energy Engineering,
Mechanics in Energy Engineering,
Shanghai University
,Shanghai 200072
, China
Search for other works by this author on:
Zhanfeng Chen
Shanghai Institute of Applied Mathematics
and Mechanics,
and Mechanics,
Shanghai University
,Shanghai 200072
, China
Shanghai Key Laboratory
of Mechanics in Energy Engineering,
of Mechanics in Energy Engineering,
Shanghai University
,Shanghai 200072
, China
Weiping Zhu
Shanghai Institute of Applied Mathematics
and Mechanics,
and Mechanics,
Shanghai University
,Shanghai 200072
, China
Shanghai Key Laboratory
of Mechanics in Energy Engineering,
e-mail: wpzhu@shu.edu.cn
of Mechanics in Energy Engineering,
Shanghai University
,Shanghai 200072
, China
e-mail: wpzhu@shu.edu.cn
Qinfeng Di
Shanghai Institute of Applied Mathematics
and Mechanics,
and Mechanics,
Shanghai University
,Shanghai 200072
, China
Shanghai Key Laboratory of
Mechanics in Energy Engineering,
e-mail: qinfengd@sina.com
Mechanics in Energy Engineering,
Shanghai University
,Shanghai 200072
, China
e-mail: qinfengd@sina.com
Wenchang Wang
Shanghai Institute of
Applied Mathematics and Mechanics,
Applied Mathematics and Mechanics,
Shanghai University
,Shanghai 200072
, China
Shanghai Key Laboratory of
Mechanics in Energy Engineering,
Mechanics in Energy Engineering,
Shanghai University
,Shanghai 200072
, China
1Corresponding authors.
Contributed by the Pressure Vessel and Piping Division of ASME for publication in the JOURNAL OF PRESSURE VESSEL TECHNOLOGY. Manuscript received January 4, 2013; final manuscript received February 1, 2015; published online April 16, 2015. Assoc. Editor: Spyros A. Karamanos.
J. Pressure Vessel Technol. Dec 2015, 137(6): 061201 (8 pages)
Published Online: December 1, 2015
Article history
Received:
January 4, 2013
Revision Received:
February 1, 2015
Online:
April 16, 2015
Citation
Chen, Z., Zhu, W., Di, Q., and Wang, W. (December 1, 2015). "Prediction of Burst Pressure of Pipes With Geometric Eccentricity." ASME. J. Pressure Vessel Technol. December 2015; 137(6): 061201. https://doi.org/10.1115/1.4029792
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