Modeling flat to slant fracture transition using the computational cell methodology

Engineering Fracture Mechanics

Volumn 104, Issue , 2013, Pages 80-95

  Besson, J ^a   McCowan, C N ^b   Drexler, E S ^b  

^a PSL RESEARCH UNIVERSITY   (France)

^b NATIONAL INSTITUTE OF STANDARDS AND TECHNOLOGY   (United States)

Author keywords

CTOA specimen; Ductile rupture; Slant fracture; X100 steel

Indexed keywords

COMPUTATIONAL CELL; COMPUTATIONAL CELL METHODOLOGY; CRACK TIP OPENING ANGLE; CTOA SPECIMEN; DUCTILE RUPTURE; ENERGY DISSIPATION RATE; LOADING DIRECTION; SLANT FRACTURE;

CRACK TIPS; PLASTIC DEFORMATION; STRAIN; STRAIN HARDENING;

CRACKS;

EID: 84878149451     PISSN: 00137944     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.engfracmech.2013.02.032     Document Type: Article

References (47)

1. Xia L., Shih C.F. Ductile crack growth - I. A numerical study using computational cells with microstructurally-based length scales. J Mech Phys Solids 1995, 43:233-259.
2. Mahgoub E., Deng X., Sutton M. Three-dimensional stress and deformation fields around flat and slant cracks under remote Mode I loading conditions. Engng Fract Mech 2003, 70:2527-2542.
3. Bron F., Besson J., Pineau A. Ductile rupture in thin sheets of two grades of 2024 aluminum alloy. Mater Sci Engng A 2004, 380:356-364.
4. Asserin-Lebert A., Besson J., Gourgues A.-F. Fracture of 6056 aluminum sheet materials: effect of specimen thickness and hardening behavior on strain localization and toughness. Mater Sci Engng A 2005, 395:186-194.
5. Lan W., Deng X., Sutton M., Cheng C.-S. Study of slant fracture in ductile materials. Int J Fract 2006, 141(3-4):469-496.
6. Morgeneyer T.F., Helfen L., Sinclair I., Proudhon H., Xu F., Baumbach T. Ductile crack initiation and propagation assessed via in situ synchrotron radiation-computed laminography. Scr Mater 2011, 65(11):1010-1013.
7. Shterenlikht A., Hashemi S., Howard I., Yates J., Andrews R. A specimen for studying the resistance to ductile crack propagation in pipes. Engng Fract Mech 2004, 71:1887-2013.
8. Rivalin F., Pineau A., Di Fant M., Besson J. Ductile tearing of pipeline-steel wide plates - I. Dynamic and quasi-static experiments. Engng Fract Mech 2000, 68(3):329-345.
9. Pardoen T., Marchal Y., Delannay F. Essential work of fracture compared to fracture mechanics - towards a thickness independent plane stress toughness. Engng Fract Mech 2002, 69:617-631.
10. Pardoen T., Hachez F., Marchioni B., Blyth P., Atkins A. Mode I fracture of sheet metal. J Mech Phys Solids 2004, 52(2):423-452.
11. Hara T, Shinohara Y, Terada Y, Asahi H. DWTT properties for high strength line pipe steels. In: Proc. Eighteenth Int. Offshore and Polar Engineering Conf., Vancouver, Canada, ISOPE; 2008. p. 189-93.
12. Gurson A.L. Continuum theory of ductile rupture by void nucleation and growth: Part I - Yield criteria and flow rules for porous ductile media. J Engng Mater Technol 1977, 99:2-15.
13. Tvergaard V., Needleman A. Analysis of the cup-cone fracture in a round tensile bar. Acta Metall 1984, 32:157-169.
14. Besson J., Steglich D., Brocks W. Modeling of crack growth in round bars and plane strain specimens. Int J Solids Struct 2001, 38(46-47):8259-8284.
15. Besson J., Steglich D., Brocks W. Modeling of plane strain ductile rupture. Int J Plast 2003, 19(10):1517-1541.
16. Huespe A.E., Needleman A., Oliver J., Sánchez P.J. A finite thickness band method for ductile fracture analysis. Int J Plast 2009, 25(12):2349-2365.
17. Huespe A.E., Needleman A., Oliver J., Sanchez P.J., Strain A finite finite band method for modeling ductile fracture. Int J Plast 2012, 28(1):53-69.
18. Scheider I., Brocks W. Simulation of cup-cone fracture using the cohesive model. Engng Fract Mech 2003, 70(14):1943-1961.
19. Mathur K., Needleman A., Tvergaard V. Three dimensional analysis of dynamic ductile crack growth in a thin plate. J Mech Phys Solids 1996, 44(3):439-464.
20. Besson J., Brocks W., Chabanet O., Steglich D. Ductile rupture of aluminum sheet materials. Eur J Finite Elem 2001, 10:401-415.
21. Xue L., Wierzbicki T. Ductile fracture initiation and propagation modeling using damage plasticity theory. Engng Fract Mech 2008, 75(11):3276-3293.
22. Xue L., Wierzbicki T. Numerical simulation of fracture mode transition in ductile plates. Int J Solids Struct 2009, 49:1423-1435.
23. Morgeneyer T.F., Besson J. Flat to slant ductile fracture transition: tomography examination and simulations using shear-controlled void nucleation. Scripta Metall Mater 2011, 65:1002-1005.
24. Xia L., Shih C.F., Hutchinson J.W. A computational approach to ductile crack growth under large scale yielding conditions. J Mech Phys Solids 1995, 43(3):389-413.
25. Ruggieri C., Panontin T., Dodds R.H. Numerical modeling of ductile crack growth in 3-d using computational cell elements. Int J Fract 1996, 82:67-95.
26. Gullerud A.S., Dodds R.H., Hampton R.W., Dawicke D.S. Three dimensional modeling of ductile crack growth in thin sheet metals: computational aspects and validation. Engng Fract Mech 1999, 63:347-373.
27. Gullerud A.S., Gao X., Dodds R.H., Haj-Ali R. Simulation of ductile crack growth using computational cells: numerical aspects. Engng Fract Mech 2000, 66:65-92.
28. Qian X. An out-of-plane length scale for ductile crack extensions in 3-D SSY models for X65 pipeline materials. Int J Fract 2011, 167:249-265.
29. Siegmund T., Brocks W. Prediction of the work of separation and implications to modelling. Int J Fract 1999, 99:97-116.
30. Herynk M.D., Kyriakides S., Onoufriou A., Yun H.D. Effects of the UOE/UOC pipe manufacturing processes on pipe collapse pressure. Int J Mech Sci 2007, 49(5):533-553.
31. Shinohara Y., Madi Y., Besson J. A combined phenomenological model for the representation of anisotropic hardening behavior in high strength steel line pipes. Eur J Mech/A 2010, 29(6):917-927.
32. Tanguy B., Luu T., Perrin G., Pineau A., Besson J. Plastic and damage behavior of a high strength X100 pipeline steel: experiments and modelling. Int J Press Vess Pip 2008, 85(5):322-335.
33. Darcis P., McCowan C., Windhoff H., McColskey J., Siewert T. Crack tip opening angle optical measurement methods in five pipeline steels. Engng Fract Mech 2008, 75:2453-2468.
34. Sowards J., McCowan C., Drexler E. Interpretation and significance of reverse chevron-shaped markings on fracture surfaces of API X100 pipeline steels. Mater Sci Engng A 2012, 551:140.
35. Tvergaard V. Material failure by void growth to coalescence. Adv Appl Mech 1990, 27:83-151.
36. Chu C., Needleman A. Void nucleation effects in biaxially stretched sheets. J Engng Mater Technol 1980, 102:249-256.
37. Besson J., Foerch R. Large scale object-oriented finite element code design. Comput Meth Appl Mech Engng 1997, 142:165-187.
38. Foerch R., Besson J., Cailletaud G., Pilvin P. Polymorphic constitutive equations in finite element codes. Comput Meth Appl Mech Engng 1997, 141:355-372.
39. Sidoroff F., Dogui A. Some issues about anisotropic elastic-plastic models at finite strain. Int J Solids Struct 2001, 38:9569-9578.
40. Hughes T. Generalization of selective integration procedures to anisotropic and nonlinear media. Int J Numer Meth Engng 1980, 15:1413-1418.
41. Bron F., Besson J. Simulation of the ductile tearing for two grades of 2024 aluminum alloy thin sheets. Engng Fract Mech 2006, 73:1531-1552.
42. Needleman A., Rice J. Limits to ductility set by plastic flow localization. Mechanics of Sheet Metal Forming 1978, 237-267. Plenum Publishing Corporation. E.D.P. Koistinen (Ed.).
43. Lan W., Deng X., Sutton M. Investigation of crack tunneling in ductile materials. Engng Fract Mech 2010, 77(14):2800-2812.
44. Faleskog J., Gao X., Shih C. Cell model for nonlinear fracture analysis - I. Micromechanics calibration. Int J Fract 1998, 89:355-373.
45. Bai Y., Wierzbicki T. A new model of metal plasticity and fracture with pressure and Lode dependence. Int J Plast 2008, 24(6):1071-1096.
46. Bai Y., Wierzbicki T. Application of extended Mohr-Coulomb criterion to ductile fracture. Int J Fract 2010, 161(1):1-20.
47. Nahshon K., Hutchinson J. Modification of the Gurson model for shear failure. Eur J Mech/A 2008, 27A:1-17.