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A Study on Welding-Induced Initial Deflections and Residual Stresses in Steel-Stiffened Plate Structures = 용접 보강판의 초기 처짐과 잔류응력에 관한 연구' 의 주제별 논문영향력
논문영향력 요약
주제
용접
용접 열 좌굴 해석법
잔류응력
초기처짐
동일주제 총논문수
논문피인용 총횟수
주제별 논문영향력의 평균
42
0
0.0%
주제별 논문영향력
논문영향력
주제
주제별 논문수
주제별 피인용횟수
주제별 논문영향력
주제어
용접
14
0
0.0%
용접 열 좌굴 해석법
1
0
0.0%
잔류응력
25
0
0.0%
초기처짐
2
0
0.0%
계
42
0
0.0%
* 다른 주제어 보유 논문에서 피인용된 횟수
0
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A Study on Welding-Induced Initial Deflections and Residual Stresses in Steel-Stiffened Plate Structures = 용접 보강판의 초기 처짐과 잔류응력에 관한 연구' 의 참고문헌
Yi, M.S., Hyun, C.M., Paik, J.K., 2018a. Three-dimensional thermo-elastic-plastic finite element method modeling for predicting weld-Induced residual stresses and distortions in steel stiffened-plate structures, World Journal of Engineering and Technology, 6: 176- 200.
Yi, M.S., Hyun, C.M, Yoo, J.S., 2016, Development of new thermal buckling analysis technique caused by welding, International Welding/Joining Conference, GyeongJu, Korea.
Yi, M.S., 2006. The effect of geometry non-linearity in welding deformation. MS.D. Thesis, Pusan National University, Busan. Korea. (in Korean).
Yi, M.S, Hyun, C.M, Cho, S.H., Jang, T.W., 2009. A study of correction effect in T-bar according to cooling method, Proceeding of the 2009 Spring Annual Meeting of Korea Welding Society (in Korean).
Woo, W.C., Kim, D.G., An, G.B., 2015. Residual stress measurements using neutron diffraction, Journal of Welding and Joining, 33(1): 30-34. (in Korean)
Wenchun Jiang, Zibai Liu, J.M. Gong, Shan-Tung Tu, 2010. Numerical simulation to study the effect of repair width on residual stresses of a stainless steel clad plate. International Journal of Pressure Vessels and Piping, 87(8): 457-463.
Wenchun Jiang, Yun Luo, Guodong Zhang, Shan-Tung Tu, 2013. Experimental to study the effect of multiple weld-repairs on microstructure, hardness and residual stress for a stainless steel clad plate. Materials & Design, 51(10): 1052-1059.
Wenchun Jiang, X.P. Xu, J.M. Gong, Shan-Tung Tu, 2012. Influence of repair length on residual stress in the repair weld of a clad plate. Nuclear Engineering and Design, 246(5): 211-219.
Wang, R., Zhang, J.X., Serizawa, H., Murakawa, H., 2009. Study of welding inherent deformations in thin plates based on finite analysis using interactive substructure method. Materials & Design, 30(9): 3474-3481.
Wang, J., Yuan, H., Ma, N., Murakawa, H., 2016. Recent research on welding distortion prediction in thin plate fabrication by means of elastic FE computation. Marine Structures. 47: 42-59.
Wang, J., Han, J., Domblesky, J.P., Li, W., Yang, Z., Zhao. Y., 2015, Predicting distortion in butt welded plates using an equivalent plane stress representation based on inherent shrinkage volume, Journal of Manufacturing Science and Engineering, 138(1): 011012
Vhanmane, S., Bhattacharya, B., 2008. Estimation of ultimate hull girder strength with initial imperfections, Ships and Offshore Structures, 3(3): 149-158.
Ueda, Y., Yamakawa, T., 1971. Analysis of thermal elastic-plastic stress and strain during welding by finite element method. Transactions of Japan Welding Research Institute, 2(2): 90–100.
Ueda, Y., 1999. Computational Welding Mechanics (A volume of selected papers in the commemoration of the retirement from Osaka University). Joining and Welding Research Institute, Osaka University, Osaka, Japan.
Tsai, C.L., Park, S.C., Chueng, W.T., 1999. Welding distortion of a thin-plate panel structure. Welding research supplement, American Welding Society: 156-165.
Teresa, M., Craig, F., 2013. Effect of weld-induced imperfections on the ultimate strength of an aluminium patrol boat determined by the ISFEM rapid assessment method, Ships and Offshore Structures, 9(2): 218-235.
Smith, C.S., Davidson, P.C., Chapman, J.C., Dowling, P.J., 1988. Strength and stiffness of ships’ plating under in-plane compression and tension, Transactions of the Royal Institution of Naval Architects, 130: 277-296.
Shin, S.B., Kim, K.K., You, J.G., 2006. A study on control of buckling distortion at the thin panel during welding. International Offshore and Polar Engineering Conference: 236- 242.
Seo, J.K., Yi, M.S., Kim, S.H., Kim, B.J., Kim, S.J., 2018. Welding distortion design formulae of thin-plate panel structure during the assembly process, Ships and Offshore Structures, 13:sup1: 364-377.
Rosenthal, D., 1941. Mathmatical theory of heat distribution during welding and cutting. Welding Journal, 20(5): 220-234.
Radaj, D., 1992. Heat effects of welding: temperature field, residual stress and distortion. Berlin Heidelberg: Springer Verlag Publishing.
Park, J.U., Park, S.C. and Lee, C.H., 2009. Control of longitudinal bending distortion of built-up beams by high-frequency induction heating, Welding Journal, 88 : 29–34.
Paik, J.K., Yi, M.S., 2006. Experimental and Numerical Investigations of Welding-Induced Distortions and Stresses in Steel Stiffened Plate Structures. The Korea Ship and Offshore Research Institute, Pusan National University, Busan, South Korea.
Paik, J.K., Thayamballi, A.K., Ryu, J.Y., Jang, J.H., Seo, J.K., Park, S.W., Seo, S.K., Andrieu, C., Cojeen, H.P., Kim, N.I., 2006. The statistics of weld induced initial imperfections in aluminum stiffened plate structures for marine applications, International Journal of Maritime Engineering, 148(Part A1): 19-63.
Paik, J.K., Thayamballi, A.K., Park, Y.I., Hwang, J.S., 2003b. A time-dependent corrosion wastage model for bulk carrier structures, International Journal of Maritime Engineering, 145(A2): 61-87.
Paik, J.K., Thayamballi, A.K., 2007. Ship-Shaped Offshore Installations: Design, Building, and Operation. Cambridge University Press, Cambridge.
Paik, J.K., Pedersen, P.T., 1996. A simplified method for predicting the ultimate compressive strength of ship panels, International Shipbuilding Progress, 43: 139-157.
Paik, J.K., Melchers, R.E., 2008. Condition assessment of aged structures. CRC Press, New York.
Paik, J.K., Lee, J.M., Hwang, J.S., Park, Y.I., 2003a. A time-dependent corrosion wastage model for the structures of single- and double-hull tankers and FSOs and FPSOs, Marine Technology, 40(3): 201-217. Paik, J.K., & Melchers, R.E. (2008). Condition Assessment of Aged Structures. CRC Press, New York.
Paik, J.K., Kim, K.J., Lee, J.H., Jung, B.G., Kim, S.J., 2017. Test database of the mechanical properties of mild, high-tensile and stainless steel and aluminum alloy associated with cold temperatures and strain rates, Ships and Offshore Structures, 12(sup1): 1-27.
Paik, J.K., Kim, D.K., 2012. Advanced method for the development of an empirical model to predict time-dependent corrosion wastage, Corrosion Science, 63: 51-58.
Paik, J.K., Kim, B.J., Sohn, J.M., Kim, S.H., Jeong, J.M., Park, J.S., 2012. On buckling collapse of a fusion-welded aluminum stiffened plate structure: An experimental and numerical study, Journal of Offshore Mechanics and Arctic Engineering, 134: 021402.1-8.
Paik, J.K., Frieze, P.A., 2001. Ship structural safety and reliability, Progress in Structural Engineering and Materials, 3: 198-210.
Paik, J.K., 2018. Ultimate limit state analysis and design of plated structures, 2nd Edition, John Wiley & Sons, Chichester, UK.
Paik, J.K., 2008. Mechanical collapse testing on aluminum stiffened panels for marine applications. Ship Structure Committee, SSC-451, Washington, DC.
Paik, J.K., 2007c. Characteristics of welding induced initial deflections in welded aluminum plates, Thin-Walled Structures, 45: 493-501.
Paik, J.K., 2007b. Practical techniques for finite element modeling to simulate structural crashworthiness in ship collisions and grounding (Part II: Verification), Ships and Offshore Structures, 2(1): 81-85.
Paik, J.K., 2007a. Practical techniques for finite element modeling to simulate structural crashworthiness in ship collisions and grounding (Part I: Theory), Ships and Offshore Structures, 2(1): 69-80.
Murakawa, H., Luo, Y., Ueda, Y., 1996. Prediction of welding deformation and residual stress by elastic FEM based on inherent strain (first report) – mechanism of inherent strain production. J Soc Naval Architects Jpn. 18: 739–51 [in Japanese].
Michaleris, P., DeBiccari, A., 1997. Prediction of welding distortion. Welding Journal. 76(4): 172-179.
Michaleris, P., 2011. Minimization of welding distortion and buckling: modelling and implementation. England Cambridge: Woodhead Publishing Limited.
Matsui, S., 1983. Control of weld distortion in thin-skin welded structures, Journal of Welding and Joining, 53(5): 58-66.
Masubuchi, K., 1980. Analysis of Welded Structures: Residual Stresses, Distortion and Their Consequences. Pergamon Press, England & Oxford, U.K.
MSC, 2013. Online User’s Guide. MSC Software Corporation, California, USA.
Luo, Y., Deng, D., Xie, L., Murakawa, H., 2004. Prediction of deformation for large welded structures based on inherent strain. Trans JWRI. 33(1): 65-70.
Lu s, R.M., Soares, C.G., Nikolov, P.I., 2009. Collapse strength of longitudinal plate assemblies with dimple imperfections, Ships and Offshore Structures, 3(4): 359-370.
Lindgren, L.E., Karlsson, L., 1988. Deformations and stresses in welding of shell structures. International Journal of Numerical Methods Eng. 25: 635–655.
Lindgren, L.E., 2007. Computational welding mechanics: thermos- mechanical and microstructural simulations. England Cambridge: Woodhead Publishing Limited.
Lillem e, I., Liinalampi, S., Remes, H., It vuo, A., Niemel , A., 2017. Fatigue strength of thin laser-hybrid welded full-scale deck structure, International Journal of Fatigue, 95: 282- 292.
Lee, D.J., Shin, S.B., 2003. A study on the prediction of shrinkage during the manufacturing of a deckhouse of RIG. International Offshore and Polar Engineering Conference: 166- 171.
Khedmati, M.R., Pedram, M., Rigo, P., 2012. The effects of geometrical imperfections on the ultimate strength of aluminium stiffened plates subject to combined uniaxial compression and lateral pressure, Ships and Offshore Structures, 9(1): 88-109.
Khan, I., Zhang, S., 2011. Effects of welding-induced residual stress on ultimate strength of plates and stiffened panels, Ships and Offshore Structures, 6(4): 297-309.
Kenno, S.Y., Das, S., Rogge, R.B., Gharghouri, M., 2017. Changes in residual stresses caused by an interruption in the weld process of ships and offshore structures, Ships and Offshore Structures, 12(3): 341–359.
Kenno, S.Y., Das, S., Kennedy J, Rogge, R., Gharghouri, M., 2010. Distributions of residual stresses in stiffened plates with one and two stiffeners, Ships and Offshore Structures, 5(3): 211–225.
Kavanagh, B.F., Glenn Bird, S.J., 1996. Surveying Principles and Applications (4 Ed.). Prentice Hall, pp. 257-264.
Jang, C.D., Seo, S.I., Ko, D.E., 1997. Study on the prediction of deformations of plates due to line heating using simplified thermal elasto-plastic analysis. Journal of Ship Research. 143(1), 22-27.
Iranmanesh, M., Azad, N., Zabihpoor, M., 2014. A new algorithm on welding process of Tshaped plates in ship hull structure to minimize distortion based on thermal simulation. Ships and Offshore Structures, 9(5): 489-497.
Ha, Y.S., Cho, S.H., Jang, T.W., 2008. Development of welding distortion analysis method using residual strain as boundary condition. Material Science Forum: 649-654.
Ha, Y.S., 2011. A study on weldment boundary condition for elasto-plastic thermal distortion analysis of large welded structures. Journal of Welding and Joining. 29(4): 410-415.
Guangming, F., Marcelo, I.L., Menglan, D., Segen, F.E., 2016. Influence of the welding sequence on residual stress and distortion of fillet welded structures. Marine Structures. 46: 30-55.
Guangming, F., Marcelo, I.L., Menglan, D., Segen, F.E., 2014. Effect of boundary conditions on residual stress and distortion in T-joint welds. Journal of Constructional Steel Research. 102: 121-135.
Gray, T., Camilleri, D., McPherson, N., 2014. Control of welding distortion in thin-Plate fabrication: design support exploiting computational simulation. England Cambridge: Woodhead Publishing Limited.
Goldak, J.A., Chakravarti, A., Bibby, M., 1984. A new finite-element model for welding heatsources. Metall. Trans. B 15: 299–305.
Goldak, J.A., Akhlaghi, M., 2005. Computational welding mechanics. U.S.A New York: Springer Science & Business Media.
Gannon, L.G., Pegg, N.G., Smith, M.J., Liu, Y., 2012b. Effect of residual stress shakedown on stiffened plate strength and behaviour, Ships and Offshore Structures, 8(6): 638-652.
Gannon, L.G., Liu, Y., Pegg, N.G., Smith, M.J., 2012a. Effect of three-dimensional weldinginduced residual stress and distortion fields on strength and behaviour of flat-bar stiffened panels, Ships and Offshore Structures, 8(5): 565-578.
Gannon, L., Liu, Y., Pegg, N., Smith, M.J., 2015. Nonlinear collapse analysis of stiffened plates considering welding-induced residual stress and distortion, Ships and Offshore Structures, 11(3): 228-244.
Fu, G., Estefen, S.F., Gurova, T., Lourenco, M.I., 2017. Effect of material model on residual stress and distortion in T-joint welding. Ships and Offshore Structures, 13(1): 56-64.
Feng, Z., 2005. Processes and mechanisms of welding residual stress and distortion. England Cambridge: Woodhead Publishing Limited.
Farajkhah, V., Liu, Y., Gannon, L., 2016. Finite element study of 3D simulated welding effect in aluminium plates, Ships and Offshore Structures, 12(2): 196-208.
Eggert, L., Fricke, W., Paetzhold, H., 2012. Fatigue strength of thin-plated block joints with typical shipbuilding imperfections. Welding in the World, 56(11-12): 119-128.
Deng, D., Murakawa, H., Liang, W., 2007. Numerical simulation of welding distortion in large structures. Comput Methods Appl Mech Eng. 196(45-48): 4613-4627.
Daniewicz, S.R., McAninch, M.D., Mc-Farland, B., Knoll, D., 1993. Application of distortion control technology during fabrication of large offshore structures. Proc. Of AWS/ORNL Inter-national Conference on Modeling and Control of Joining Processes.
Cheng, J.J.R., Elwi, A.E., Grodin, G.Y., Kulak, G.L., 1996. Material testing and residual stress measurements in a stiffened steel plate. In: Strength and Stability of Stiffened Plate Components. Ship Structure Committee, SSC-399, Washington, DC.
Chen, B.Q., Hashemzadeh, M., Guedes, Soares C., 2018. Validation of numerical simulations with X-ray diffraction measurements of residual stress in butt-welded steel plates, Ships and Offshore Structures, 13(3): 273-282.
Chen, B. Q., Hashemzadeh, M., Garbatov, Y., Soares, C. Guedes, 2015. Numerical and parametric modeling and analysis of weld-induced residual stresses. International Journal of Mechanical and Material in Design, 11(4): 439-453.
Chaithanya, P.P., Das, P.K., Crow, A., Hunt, S., 2009. The effect of distortion on the buckling strength of stiffened panels. Ships and Offshore Structures, 5(2): 141-153.
Bruno, G., Yordan. G., Soares, C.G., 2011. Effect of weld shape imperfections on the structural hot-spot stress distribution, Ships and Offshore Structures, 6(1-2): 145-159.
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A Study on Welding-Induced Initial Deflections and Residual Stresses in Steel-Stiffened Plate Structures = 용접 보강판의 초기 처짐과 잔류응력에 관한 연구'
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