A Study on Hydraulic Autofrettage Gun Tube Dynamic Stress by Finite Element Analysis

Zhan, Yan-mou; Huang, Guo-rui; Cheng, Hao

doi:10.1007/978-3-642-37270-4_4

Yan-mou Zhan⁴,
Guo-rui Huang⁴ &
Hao Cheng⁴

1276 Accesses

Abstract

Gun tube dynamic strength design, first of all, is to enable the identification of dynamic stress on each section of tube, and the dynamic stress calculation in analytical method or numerical method is relatively complex. For most non mechanical professional design staff, the use of finite element soft- ware interactively in the general structure of the model has certain difficulty. Therefore, the realization of gun tube dynamic strength design is an urgent need to develop a general engineering program, so that the designer can easily use this program to achieve the dynamic stress on every section of tube, and truly realize the dynamic strength design of tube. With the APDL language of ANSYS finite element analysis software platform, a suitable program for tube dynamic stress calculation procedures is developed. This program provides an engineering foundation to realize the tube dynamic strength design.

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References

Bahre D, Brunnet H (2011) Simulation of removing autofrettage-induced residual stress loaded layers by finite element analysis. Procedia Eng 19:9–15
Article Google Scholar
Cao LN, Han XQ, Zhang YG, Cao YX (2011) Finite element analysis of detonation wave interference among perforating bullets. Baozha Yu Chongji/Explos Shock Waves 31:220–224
Google Scholar
Coco S, Laudani A, Pollicino G, Dionisio R, Martorana R (2007) 3-D finite-element analysis of TWT grid electron guns. IEEE Trans Magn 43:1233–1236
Article Google Scholar
Huang XP, Cui WC (2006) Effect of Bauschinger effect and yield criterion on residual stress distribution of autofrettaged tube. J Press Vessel Technol Trans ASME 128:212–216
Article Google Scholar
Li ZY, Cheng SK, Zheng P, Feng M, Cao YJ (2005) Finite-element analysis for the active electromagnetic armor projectile interceptor. IEEE Trans Magn 41:453–455
Article Google Scholar
Liu SB, Ruan JJ, Du ZY, Huang DC (2010) Analysis of inductive coil gun performance based on field coupling circuit method. Diangong Jishu Xuebao/Trans China Electro Tech Soc 25:1–7
Google Scholar
Maleki M, Farrahi GH, Haghpanah JB, Hosseinian E (2010) Residual stress analysis of autofrettaged thick-walled spherical pressure vessel. Int J Press Vessels Piping 87:396–401
Article Google Scholar
Nelson EM, Petillo JJ (2004) An analysis of the basic space-charge-limited emission algorithm in a finite-element electrostatic gun code. IEEE Trans Plasma Sci 32:1223–1235
Article Google Scholar
Shi LP, Zhong YS, Yu J, He XD (2008) Finite element modeling of residual stress of Ti/TiAl multilayer composites prepared by electron beam physical vapor deposition technology. J Comput Theor Nanosci 5:1704–1707
Article Google Scholar
Shim WS, Kim JH, Lee YS, Cha KU, Hong SK (2010) A study on hydraulic autofrettage of thick-walled cylinders incorporating bauschinger effect. Exp Mech 50:621–626
Article Google Scholar
Sunwall DA, Speece MA, Pekar SF (2012) Advances in on-sea-ice seismic reflection methods using an air gun: McMurdo sound, Antarctica. Geophysics 77:19–30
Article Google Scholar
Swardt D, Rolf R (2006) Material models for the finite element analysis of materials exhibiting a pronounced Bauschinger effect. J Press Vessel Technol Trans ASME 128:201–207
Article Google Scholar
Tan LB, Cai L, Yuan RS (2010) Finite element analysis and test research for dynamic strength of thick-wall cylinder. Dandao Xuebao/J Ballist 22:86–88
Google Scholar
Zeng ZY, Ning BF, Wang ZS (2007) A finite element solution for barrel dynamic stress. J China Ordnance 3:11–14
Google Scholar
Zhang QM, Wang XY, Huang FL, Chen L, Guo XH (2009) An experimental and numerical study of the dynamic response of a free-free aluminum beam under high velocity transverse impact. Int J Impact Eng 36:1385–1393
Article Google Scholar

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Authors and Affiliations

New Star Research Institute of Applied Technology, Hefei, China
Yan-mou Zhan, Guo-rui Huang & Hao Cheng

Authors

Yan-mou Zhan
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Guo-rui Huang
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Hao Cheng
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Correspondence to Yan-mou Zhan .

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Editors and Affiliations

Industrial Engineering Institution of CM, 92 Wenjin Road, Nankai District, Tianjin, 300072, China, People's Republic
Ershi Qi
Industrial Engineering Institution of CM, 92 Wenjin Road, Nankai District, Tianjin, 300072, China, People's Republic
Jiang Shen
, College of Management and Economics, Tianjin University, 92 Wenjin Road, Tianjin, 300072, China, People's Republic
Runliang Dou

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Zhan, Ym., Huang, Gr., Cheng, H. (2013). A Study on Hydraulic Autofrettage Gun Tube Dynamic Stress by Finite Element Analysis. In: Qi, E., Shen, J., Dou, R. (eds) The 19th International Conference on Industrial Engineering and Engineering Management. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-37270-4_4

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DOI: https://doi.org/10.1007/978-3-642-37270-4_4
Published: 17 April 2013
Publisher Name: Springer, Berlin, Heidelberg
Print ISBN: 978-3-642-37269-8
Online ISBN: 978-3-642-37270-4
eBook Packages: Business and EconomicsBusiness and Management (R0)

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