CLC number: TQ320
On-line Access: 2024-08-27
Received: 2023-10-17
Revision Accepted: 2024-05-08
Crosschecked: 0000-00-00
Cited: 8
Clicked: 6656
Jin-yang ZHENG, Yong-jian GAO, Xiang LI, Xiu-feng LIN, Yu-bin LU, Yan-cong ZHU. Investigation on short-term burst pressure of plastic pipes reinforced by cross helically wound steel wires[J]. Journal of Zhejiang University Science A, 2008, 9(5): 640-647.
@article{title="Investigation on short-term burst pressure of plastic pipes reinforced by cross helically wound steel wires",
author="Jin-yang ZHENG, Yong-jian GAO, Xiang LI, Xiu-feng LIN, Yu-bin LU, Yan-cong ZHU",
journal="Journal of Zhejiang University Science A",
volume="9",
number="5",
pages="640-647",
year="2008",
publisher="Zhejiang University Press & Springer",
doi="10.1631/jzus.A071476"
}
%0 Journal Article
%T Investigation on short-term burst pressure of plastic pipes reinforced by cross helically wound steel wires
%A Jin-yang ZHENG
%A Yong-jian GAO
%A Xiang LI
%A Xiu-feng LIN
%A Yu-bin LU
%A Yan-cong ZHU
%J Journal of Zhejiang University SCIENCE A
%V 9
%N 5
%P 640-647
%@ 1673-565X
%D 2008
%I Zhejiang University Press & Springer
%DOI 10.1631/jzus.A071476
TY - JOUR
T1 - Investigation on short-term burst pressure of plastic pipes reinforced by cross helically wound steel wires
A1 - Jin-yang ZHENG
A1 - Yong-jian GAO
A1 - Xiang LI
A1 - Xiu-feng LIN
A1 - Yu-bin LU
A1 - Yan-cong ZHU
J0 - Journal of Zhejiang University Science A
VL - 9
IS - 5
SP - 640
EP - 647
%@ 1673-565X
Y1 - 2008
PB - Zhejiang University Press & Springer
ER -
DOI - 10.1631/jzus.A071476
Abstract: Plastic pipes reinforced by cross helically wound steel wires (PSP), which have exhibited excellent mechanical performance, consist of inner polyethylene (PE) layer, winding layer and outer PE layer. The winding layer is composed of two monolayers where steel wires are cross helically wound. An analytical procedure is developed to predict the short-term burst pressure of PSP as the monolayer is assumed to be elastic and orthotropic. The 3D anisotropic elasticity and Maximum Stress Failure Criterion are employed in the formulation of the elasticity problem. Good agreement between the theoretical results and the experimental data shows that the proposed approach can well predict the short-term burst pressure of PSP.
[1] Chinese Standards GB/T15560-1995, 1995. Standard Test Method for Short-time Hydraulic Failure and Resistance to Constant Internal Pressure of the Plastics Pipes for the Transport of Fluids (in Chinese).
[2] Chinese Standards GB/T228-2002, 2002. Metallic Materials-tensile Testing at Ambient Temperature (in Chinese).
[3] Chinese Standards GB/T8804.3-2003, 2003. Test Methods of Tensile Properties for Thermoplastic Pipes−Polyolefin Pipes (in Chinese).
[4] Chinese Standards GB6111-2003, 2003. Thermoplastics Pipes for the Conveyance of Fluids-resistance to Internal Pressure-test Method (in Chinese).
[5] Chou, P.C., Carleone, J., Hsu, C.M., 1972. Elastic constants of layered media. Journal of Composite Materials, 6(1):80-93.
[6] Hwang, T.K., Hong, C.S., Kim, C.G., 2003. Probabilistic deformation and strength prediction for a filament wound pressure vessel. Composites Part B: Engineering, 34:481-497.
[7] Kobayashi, S., Imai, T., Wakayama, S., 2007. Burst strength evaluation of the FW-CFRP hybrid composite pipes considering plastic deformation of the liner. Composites Part A: Applied Science and Manufacturing, 38(5):1344-1353.
[8] Kruijer, M.P., Warnet, L.L., Akkerman, R., 2006. Modelling of the viscoelastic behaviour of steel reinforced thermoplastic pipes. Composites Part A: Applied Science and Manufacturing, 37(2):356-367.
[9] Lu, Y.B., Ma, X., Fang, X.B., Chen, Z.W., Zheng, J.Y., Qiu, S.L., 2005. The research advances in plastic-matrix metal composite pipe. Chemical Engineering and Machinery, 32(2):125-128 (in Chinese).
[10] Parnas, L., Katirci, N., 2002. Design of fiber-reinforced composite pressure vessels under various loading conditions. Composite Structures, 58(1):83-95.
[11] Qiao, S.R., 1997. Micro Mechanics Property of Composite Meterial. Northwesten Polytechnical University Press, Xi’an, p.20-37 (in Chinese).
[12] Takayanagi, H., Xia, M., Kemmochi, K., 2002. Stiffness and strength of filament-wound fiber-reinforced composite pipes under internal pressure. Advanced Composite Materials, 11(2):137-149.
[13] Uemura, M., Fukunaga, H., 1981. Probabilistic burst strength of filament wound cylinders under internal pressure. Journal of Composite Materials, 15(5):462-480.
[14] Xia, M., Kemmochi, K., Takayanagi, H., 2001. Analysis of filament-wound fiber-reinforced sandwish pipe under combined internal pressure and thermomechanical loading. Composite Structures, 51(3):273-283.
[15] Xia, M., Takayanagi, H., Kemmochi, K., 2001. Analysis of multi-layered filament-wound composite pipes under internal pressure. Composite Structures, 53(4):483-491.
[16] Zheng, J.Y., Dong, Q.W., Sang, Z.F., 2001. Process Equipment and Design. Chemical Industry Press, Beijing, p.43-48 (in Chinese).
[17] Zheng, J.Y., Lin, X.F., Lu, Y.B., Li, X., Zhu, Y.C., Xu, P., Sun, G.Y., 2006. Stress Analysis of Plastic Pipe Reinforced by Cross Helically Wound Steel Wires. ASME Pressure Vessel and Piping Division Conference.
[18] Zheng, J.Y., Lu, Y.B., Li, X., Lin, X.F., Zhu, Y.C., Xu, P., Chen, D.F., He, X.L., Shao, T.Q., 2007. Experimental investigation on mechanical properties of plastic pipes reinforced by cross helically wound steel wires. Pressure Vessel and Technology (in Press).
Open peer comments: Debate/Discuss/Question/Opinion
<1>