1 |
Production Standard of the German Shipbuilding Industry (Revised Edition with the First Edition - November 1974 and Second Edition - August 1977).
|
2 |
Remes, H., Varsta, P., 2010. Statistics of weld geometry for laser-hybrid welded joints and its application within notch stress approach. Weld. World 54 (7-8), 189-207. https://doi.org/10.1007/BF03263505.
DOI
|
3 |
Shin, S.B., Lee, D.J., 2011. Control technology for excessive welding distortion of the deck house during manufacturing process. Met. Mater. Int. 17 (1), 123-130. https://doi.org/10.1007/s12540-011-0217-x.
DOI
|
4 |
Shin, S.B., Lee, D.J., Youn, J.G., 2012. A structural design approach for controlling welding distortion at the upper deck of a hull structure in the erection stage. Weld. World 56 (3-4), 51-63. https://doi.org/10.1007/BF03321335.
DOI
|
5 |
Okerblom, N.O., 1955. The Calculations of Deformations of Welded Metal Structures. HUSO, London.
|
6 |
Verhaeghe, G., 1999. Predictive Formula for Weld Distortion - A Critical Review. Abington Publishing, Cambridge, UK.
|
7 |
Company instruction: IP27-80, 1965. Recommendation about Proper Design and Manufacturing of the Welded Naval Structures. Gdansk Shipyard.
|
8 |
Wang, R., Zhang, J., Serizawa, H., Murakawa, H., 2009. Study of welding inherent deformations in thin plates based on finite element analysis using interactive substructure method. Mater. Des. 30 (9), 3474-3481. https://doi.org/10.1016/j.matdes.2009.03.015.
DOI
|
9 |
Yang, Y.P., Castner, H., Dull, R., Dydo, J., Fanguy, D., 2013. Uniform-panel weld shrinkage data model for neat construction ship design engineering. J. Ship Prod. Des. 29 (1), 1-16. https://doi.org/10.5957/JSPD.29.1.120011.
DOI
|
10 |
Yang, Y.P., Castner, H., Dull, R., Dydo, J., Huang, T.D., Fanguy, D., Dlugokecki, V., Hepinstall, L., 2014. Complex-panel weld shrinkage data model for neat construction ship design engineering. J. Ship Prod. Des. 30 (1), 15-38. https://doi.org/10.5957/JSPD.30.1.130027.
DOI
|
11 |
Company standard: T081-02, 2001. Gas-shielded Metal-Arc Welding, Part II - Welding Procedure Specifications WPS. Szczecin Shipyard Inc.
|
12 |
Adak, M., Mandal, N.R., 2010. Numerical and experimental study of mitigation of welding distortion. Appl. Math. Model. 34 (1), 146-158. https://doi.org/10.1016/j.apm.2009.03.035.
DOI
|
13 |
Birk-Sorensen, M., 1999. Simulation of Welding Distortions in Ship Sections. Industrial PhD Thesis. ATV, Odense Steel Shipyard Ltd.
|
14 |
Company standard: T081-03, 2001. Submerged Arc Welding, Part II - Welding Procedure Specifications WPS. Szczecin Shipyard Inc.
|
15 |
Company standard: T100-01, 2001. Steel Ship Hull. The hull structure accuracy. Szczecin Shipyard Inc.
|
16 |
Handbook, Welding, 2001. Welding Science and Technology, ninth ed., vol. 1. American Welding Society, Miami.
|
17 |
Deng, D., Murakawa, H., 2008. FEM prediction of buckling distortion induced by welding in thin plate panel structures. Comput. Mater. Sci. 43 (4), 591-607. https://doi.org/10.1016/j.commatsci.2008.01.003.
DOI
|
18 |
Deng, D., Murakawa, H., Shibahara, M., 2010. Investigations on welding distortion in an asymmetrical curved block by means of numerical simulation technology and experimental method. Comput. Mater. Sci. 48 (1), 187-194. https://doi.org/10.1016/j.commatsci.2009.12.027.
DOI
|
19 |
Draper, N.R., Smith, H., 1998. Applied Regression Analysis. John Wiley & Sons, Inc., New York.
|
20 |
Hashemzadeh, M., Garbatov, Y., Guedes Soares, C., 2017. Analytically based equations for distortion and residual stress estimations of thin butt-welded plates. Eng. Struct. 137, 115-124. https://doi.org/10.1016/j.engstruct.2017.01.041.
DOI
|
21 |
ISO 4063, 1990. Welding, Brazing, Soldering and Braze Welding of Metals - Nomenclature of Processes and Reference Numbers for Symbolic Representation on Drawings.
|
22 |
Iwankowicz, R.R., 2016. An efficient evolutionary method of assembly sequence planning for shipbuilding industry. Assemb. Autom. 36 (1), 60-71. https://doi.org/10.1108/AA-02-2015-013.
DOI
|
23 |
Liang, W., Deng, D., Sone, S., Murakawa, H., 2005. Prediction of welding distortion by elastic finite element analysis using inherent deformation estimated through inverse analysis. Weld. World 49 (11-12), 30-39. https://doi.org/10.1007/BF03266500.
DOI
|
24 |
Jakubiec, M., Lesinski, K., Czajkowski, H., 1987. Technology of Welded Structures. WNT (Publishers), Warsaw (in Polish).
|
25 |
Kang, M., Seo, J., Chung, H., 2018. Ship block assembly sequence planning considering productivity and welding deformation. Int. J. Naval Archit. Ocean Eng. 10 (4), 450-457. https://doi.org/10.1016/j.ijnaoe.2017.09.005.
DOI
|
26 |
Lazarson, E.V., 2007. Calculation of the cross-sectional area of the welded joints in arc welding. Weld. Int. 21 (6), 451-453. https://doi.org/10.1080/09507110701455616.
DOI
|
27 |
Lee, J.Y., Inose, K., Kim, Y.C., 2010. Verification of validity and generality of dominant factors in high accuracy prediction of welding distortion. Weld. World 54 (9-10), 279-285. https://doi.org/10.1007/BF03266740.
DOI
|
28 |
Leggatt, R.H., 1980. Distortion in Welded Steel Plates. Dissertation, Magdalene College, Cambridge.
|
29 |
Masubuchi, K., 1980. Analysis of Welded Structures. Pergamon Press, Oxford, UK.
|
30 |
Metschkow, B., Graczyk, T., 1997. Laser welded joints in shipbuilding. In: Graczyk, T., Jastrze˛bski, T., Brebbia, C.A. (Eds.), Marine Technology, second ed. Computational Mechanics Publications, Southampton & Boston, pp. 171-181.
|
31 |
Montgomery, D.C., 2001. Design and Analysis of Experiments. John Wiley & Sons, Inc., New York.
|
32 |
Murakawa, H., Okumoto, Y., Rashed, S., Sano, M., 2013. A practical method for prediction of distortion produced on large thin plate structures during welding assembly. Weld. World 57 (6), 793-802. https://doi.org/10.1007/s40194-013-0071-1.
DOI
|
33 |
Myers, R.H., Montgomery, D.C., Anderson-Cook, C.M., 2009. Response Surface Methodology: Process and Product Optimization Using Designed Experiments. John Wiley & Sons, Inc., New York.
|
34 |
Neter, J., Wasserman, W., Kutner, M.H., 1985. Applied Linear Statistical Models: Regression, Analysis of Variance, and Experimental Design. Irwin, Homewood, IL.
|
35 |
Niebylski, J., Bobrowicz, A., Chmielewski, K., Dutkiewicz, J., Zajac, P., 1998. The Applicative Model of Design and Construction of Ship in Limited Tolerances, Technical Report No. 9 T12C 060 97 C/3480. Szczecin University of Technology and Szczecin Shipyard Inc.
|
36 |
Spraragen, W., Ettinger, W.G., 1950. Shrinkage distortion in welding. Weld. J. 29 (6), 292-294.
|
37 |
Shipbuilding and Repair Quality Standard IACS, 1996. Part A. Shipbuilding and Repair Quality Standard for New Construction, Part B. Repair Quality Standard for Existing Ships, London.
|
38 |
Sikstrom, F., Ericson Oberg, A., 2017. Prediction of penetration in one-sided fillet welds by in-process joint gap monitoring-an experimental study. Weld. World 61 (3), 529-537. https://doi.org/10.1007/s40194-017-0448-7.
DOI
|
39 |
Slovacek, M., Divis, V., Junek, L., Ochodek, V., 2005. Numerical simulation of the welding process - distortion and residual stress prediction, heat source model determination. Weld. World 49 (11-12), 15-29. https://doi.org/10.1007/BF03266499.
DOI
|
40 |
Urbanski, T., 2015. Analysis of assembly suitability of the hybrid node based on weld distortion prediction models. Adv. Sci. Technol. Res. J. 9 (27), 28-34. https://doi.org/10.12913/22998624/59081.
DOI
|
41 |
Polanski, Z., 1984. Design of Experiments in Engineering. PWN (Publishers), Warsaw (in Polish).
|
42 |
Park, J., An, G., 2017. Prediction of the welding distortion of large steel structure with mechanical restraint using equivalent load methods. Int. J. Naval Archit. Ocean Eng. 9 (3), 315-325. https://doi.org/10.1016/j.ijnaoe.2016.11.002.
DOI
|