1 |
Zacke, S. and Fricke, W., 2011. Welding of large gaps of block joints in ships using different techniques. In: Advances in Marine Structures (Eds.: C. Guedes Soares & W. Fricke). London : Taylor & Francis Group.
|
2 |
Fricke, W. and Zacke, S., 2011. Application of welding simulation to block joints in shipbuilding and assessment of welding-induced residual stresses (in German). Jahrb. der Schiffbautechnischen Gesellschaft 105. Hamburg: Schiffahrts- Verlag‚'Hansa'.
|
3 |
Bollinghaus, T., 1995. Determination of crack-critical shrinkage restraints and hydrogen distribution in welded joints by numerical simulation (in German). Hamburg: Dissertation, Universität der Bundeswehr.
|
4 |
Choo, R.T. and Szekely, J., 1994. The possible role of turbulence in GTA weld pool behavior. Welding Journal Research Supplement, 74(2), pp.25s-31s.
|
5 |
Goldak, M., Bibby, A. and Chakravarti, 1984. A new finite element model for welding heat sources. Metallurgical Transaction B, 15B, pp.299-305.
|
6 |
Haibach, E., 2002. Betriebsfestigkeit - Verfahren und Daten zur Bauteilberechnung (Fatigue strength - procedures and data for analysis of components). Berlin, Heidelberg: Springer-Verlag.
|
7 |
Hoffmeister, H., 1986. Concept and procedure description of the IRC test for assessing hydrogen assisted weld cracking. Steel Research (AEW), 57(7), pp.345-347.
|
8 |
Huismann, G. and Savu, D., 2001. Welding of large gaps at butt joints of shipbuilding blocks (in German), Final Report of BMBF Research Project 03SX133B/Teilprojekt P3.1. Hamburg: Universität der Bundeswehr.
|
9 |
Karlsson, L. and Lindgren, L.E., 1990. Modeling of Casting, Welding and Advanced Solidification Processes V: 5th International conference on modeling of casting and welding processes. Rappaz , M. (ed.). Warrendale, Pa: Minerals, Metals & Materials Society.
|
10 |
Lancaster, J.F., 1986. The physics of welding. 2rd Ed. Oxford: Pergamon Press.
|
11 |
Lowke, J.J., Kovitya, P. and Schmidt H.P., 1992. Theory of free-burning arc columns including the influence of the cathode. Journal of Physics D Applied Physics, 25(11), pp.1600-1606.
DOI
ScienceOn
|
12 |
Rorup, J., 2003. Influence of compressive mean stresses on the fatigue strength of welded ship structures (in German). Report 619, Schriftenreihe Schiffbau. Hamburg: TU Hamburg-Harburg.
|
13 |
Osawa, N., Hashimoto, K., Sawamura, J., Nakai, T. and Suzuki, S., 2007. Study on shell-solid coupling FE analysis for fatigue assessment of ship structure. Marine Structures, 20(3), pp.143-163.
DOI
ScienceOn
|
14 |
Radaj, D., 2003. Welding residual stresses and distortion: calculation and measurement. Dusseldorf: DVS-Verlag.
|
15 |
Radaj, D., Sonsino, C.M. and Fricke, W., 2006. Fatigue assessment of welded joints by local approaches. 2nd Ed. Cambridge: Woodhead Publishing.
|
16 |
Rosenthal, D., 1941. Mathematical theory of heat distribution during welding and cutting. Transactions ASME Supplement, 20(5), pp.220s-234s.
|
17 |
Ruyter, E., 1993. Development and assessment of welding procedures for avoiding weld joint cracking in highly restrained offshore steel structures. Hamburg: Dissertation, Universitat der Bundeswehr.
|
18 |
Rykalin, N., 1952. Die Warmegrundlagen des Schweivorganges (Thermal fundamentals of the welding process), Band 1. Berlin : Verlag Technik.
|
19 |
VSM, 2006. Production standard of the german shipbuilding industry. 7rd Ed. Hamburg: Verband fur Schiffbau und Meerestechnik e.V.
|
20 |
Wichers, M., 2006. Welding under uniaxial cyclic loading - experimental and numerical investigations (in German). Dissertation. Germany: Universität Braunschweig, Braunschweig.
|