An Investigation of Ductility Dip Cracking in Nickel-Based Weld Metals - Part II

Welding Journal (Miami, Fla)

Volumn 82, Issue 12, 2003, Pages

  Collins, M G ^a   Ramirez, A J ^a   Lippold, J C ^a  

^a OHIO STATE UNIVERSITY   (United States)

Author keywords

Ductility Dip Cracking; Fracture Morphology; Grain Boundary Characteristics; Nickel Based Filler Metals; Stain to Fracture Test

Indexed keywords

DIP TEMPERATURE RANGE (DTR); DUCTILITY DIP CRACKING; FRACTURE MORPHOLOGY; NICKEL-BASED FILLER METALS; STRAIN-TO-FRACTURE (STF) TESTS;

CRACK INITIATION; DUCTILITY; ETHANOL; FRACTURE MECHANICS; GRAIN BOUNDARIES; MICROSTRUCTURE; MORPHOLOGY; NICKEL; SCANNING ELECTRON MICROSCOPY; THERMAL EFFECTS;

WELDING;

EID: 1042277516     PISSN: 00432296     EISSN: None     Source Type: Journal    
DOI: None     Document Type: Review

References (13)

1. Collins, M. G., and Lippold, J. C. 2003. An investigation of ductility dip cracking in nickel-based filler materials - Part 1. Welding Journal 82(10): 288-s to 295-s.
2. Hemsworth, B., Boniszewski, T., and Eaton, N. F. 1969. Classification and definition of high-temperature welding cracks in alloys. Metal Construction and British Welding Journal, pp. 5-16.
3. Honeycombe, J., and Gooch, T. G. 1970. Microcracking in fully austenitic stainless steel weld metal. Metal Construction and British Welding Journal (9): 375-380.
4. Zhang, Y., Nakagawa, H., and Matsuda, F. 1985. Weldability of Fe-36%Ni alloy (Report V) - Behaviors of grain boundary sliding and cavity formation preceding reheat hot cracking in weld metal. Transactions of JWRI, 14/2(12):2 (12): 119-124.
5. Zhang, Y., Nakagawa, H., and Matsuda, F. 1985. Weldability of Fe-36%Ni Alloy (Report VI) - Further investigation on mechanism of reheat hot cracking in weld metal. Transactions of JWRI 14/2 (12).
6. Ramirez, A. J. 2002. Unpublished research performed at Ohio State University.
7. Estman, J., Matsumoto, T., Narita, N., Heubaum, F., and Birnbaun, H. K. 1980. Hydrogen effects in nickel - embrittlement or enhanced ductility. Hydrogen Effects in Metals, Warrendale, Pa.: TMS, pp. 397-409.
8. Symons, D. M. 1999. The effect of hydrogen in the fracture toughness of Alloy X-750 at elevated temperatures. Journal of Nuclear Materials 265: 225-231.
9. Troiano, A. R. 1960. The role of hydrogen and other interstitials in the mechanical behavior of metals. Trans. ASM 52(1): 54-80.
10. Savage, W. F., Nippes, E. F., and Szekeres, E. S. 1976. Hydrogen-induced cracking in a low alloy steel. Welding Journal 55: 276-s to 283-s.
11. Jones, D. A. 1996. Principles and Prevention of Corrosion, 2d ed. Upper Saddle River, N.J.: Prentice & Hall, Inc.
12. Mills, W. J., and Brown, C. M. 2001. Fracture toughness of Alloy 600 and EN82H weld in air and water. Metallurgical Transactions A 32A(5): 1161-1174.
13. Matsuda, F. 1990. Hot crack susceptibility of weld metal. Proceedings of the 1st U.S.-Japan Symposium on Advances in Welding Metallurgy. Miami, Fla.: American Welding Society, pp. 19-36.