Sage Journals: Discover world-class research

Abstract

Fracture often occurs in the spin forming process of thin-walled metal sheets, due to the limited fracture strain and local large plastic deformation of the sheets during the process. However, the accurate fracture prediction is a huge challenge due to the combinations of material anisotropy, complex deformation history and contact boundary conditions in the process. Though there are scattered uncoupled ductile fracture criteria proposed with various deformation mechanisms, reasons for their different fracture prediction abilities remain unclear. Thus in this study, eight popular uncoupled ductile fracture criteria i.e., Freudenthal, C-L, R-T, Brozzo, Oh, Oyane, MMC4 and DF2016, are embedded into an anisotropic constitutive model through VUMAT interface in the ABAQUS simulation software and then realized their fracture prediction in the spin forming process of an anisotropic metal sheet. The results show that the damage accumulation in the spin forming process occurs in a wide range of stress triaxiality, and the most damage accumulation occurs in the stress triaxiality range of 0–1/2. Furthermore, the eight fracture criteria have different prediction abilities in the process and a new deformation history related equivalent fracture strain is proposed to explain these differences. In addition, there exists the abnormal phenomenon that some simple damage models, as Oyane, Oh, etc. provide the more accurate fracture prediction ability than the complex and advanced MMC4 and DF2016 models in the process, and reasons for this phenomenon are explained.

Keywords

Metal sheets spin forming fracture prediction uncoupled ductile fracture criteria accuracy evaluation

Get full access to this article

View all access options for this article.

References

Lin

Wang

, et al. Numerical investigation of effects of deformation allocation on multi-pass conventional spinning process of curvilinear generatrix parts. Proc IMechE, Part C: J Mechanical Engineering Science 2015; 229: 3299–3307.

Hao

Luo

Jin

, et al. Finite element simulation of the one-pass inner spinning process of curved generatrix cone cylindrical parts and analysis of their microstructure. Proc IMechE, Part C: J Mechanical Engineering Science 2020; 234: 1786–1796.

Zhan

Jiang

, et al. Application of ductile fracture criteria in spin-forming and tube-bending processes. Comp Mater Sci 2009; 47: 353–365.

Beni

Biglari

FR.

An experimental–numerical investigation of spinning process. Proc IMechE, Part C: J Mechanical Engineering Science 2011; 225: 509–519.

Zhan

Guo

, et al. Formability limits and process window based on fracture analysis of 5A02-O aluminium alloy in splitting spinning. J Mater Process Technol 2018; 257: 15–32.

, et al. Ductile fracture: experiments and computations. Int J Plast 2011; 27: 147–180.

Wang

Zhan

Guo

, et al. Evaluating the applicability of GTN damage model in forward tube spinning of aluminum alloy. Met -Open Access Metall J 2016; 6: 2–14.

Shan

, et al. An extended GTN model for low stress triaxiality and application in spinning forming. J Mater Process Technol 2019; 263: 112–128.

Khan

Liu

A new approach for ductile fracture prediction on Al 2024-T351 alloy. Int J Plast 2012; 35: 1–12.

10.

Xia

Zhou

Xiao

, et al. Research on ductile fracture criterion for metal shear spinning. J Mech Eng 2018; 14: 66–73.

11.

Shan

, et al. Damage evaluation in tube spinnability test with ductile fracture criteria. Int J Mech Sci 2015; 100: 99–111.

12.

, et al. Damage evolution and ductile fracture prediction during tube spinning of titanium alloy. Int J Mech Sci 2018; 135: 226–239.

13.

Barlat

Lian

Plastic behavior and stretchability of sheet metals. Part I: a yield function for orthotropic sheets under plane stress conditions. Int J Plast 1989; 5: 51–66.

14.

Lou

Huh

Prediction of ductile fracture for advanced high strength steel with a new criterion: experiments and simulation. J Mater Process Technol 2013; 213: 1284–1302.

15.

Xue

Constitutive modeling of void shearing effect in ductile fracture of porous materials. Eng Fract Mech 2008; 75: 3343–3366.

16.

Cao

Gachet

Montmitonnet

, et al. A lode-dependent enhanced Lemaitre model for ductile fracture prediction at low stress triaxiality. Eng Fract Mech 2014; 124-125: 80–96.

17.

Freudenthal

FA.

The inelastic behavior of solids. New York: Wiley, 1950, pp.641–672.

18.

Cockcroft

Latham

DJ.

Ductility and the workability of metals. J Inst Metals 1968; 96: 33–39.

19.

Chen

Kobayashi

Ductile fracture in axisymmetric extrusion and drawing: part 2, workability in extrusion and drawing. Trans ASME J Eng Ind 1979; 101: 36–44.

20.

Brozzo

DeLuca

Rendina

A new method for the prediction of formability limits in metal sheets. In: Proceedings of the seventh biennial conference of the International Deep Drawing Research Group, Amsterdam, 9–13 October 1972.

21.

Rice

Tracey

On the ductile enlargement of voids in triaxial stress fields. J Mech Phys Solids 1969; 17: 201–217.

22.

Oyane

Sato

Okimoto

, et al. Criteria for ductile fracture and their applications. J Mech Work Technol 1980; 4: 65–81.

23.

Bao

Wierzbicki

On fracture locus in the equivalent strain and stress triaxiality space. Int J Mech Sci 2004; 46: 81–98.

24.

Xue

Damage accumulation and fracture initiation in uncracked ductile solids subject to triaxial loading. Int J Solids Struct 2007; 44: 5163–5181.

25.

Brünig

Albrecht

Gerke

Modeling of ductile damage and fracture behavior based on different micromechanisms. Int J Damage Mech 2011; 20: 558–577.

26.

Bai

Wierzbicki

Application of extended Mohr-Coulomb criterion to ductile fracture. Int J Fract 2010; 161: 1–20.

27.

Lou

Huh

Lim

, et al. New ductile fracture criterion for prediction of fracture forming limit diagrams of sheet metals. Int J Solids Struct 2012; 49: 3605–3615.

28.

Lou

Yoon

Huh

Modeling of shear ductile fracture considering a changeable cut off value for the stress triaxiality. Int J Plast 2014; 54: 56–80.

29.

Lou

Chen

Clausmeyer

, et al. Modeling of ductile fracture from shear to balanced biaxial tension for sheet metals. Int J Solids Struct 2017; 112: 169–184.

30.

Lou

Yoon

JW.

Anisotropic ductile fracture criterion based on linear transformation. Int J Plast 2017b; 93: 3–25.

31.

Lou

Yoon

JW.

Alternative approach to model ductile fracture by incorporating anisotropic yield function. Int J Solids Struct 2019; 164: 12–24.

32.

Luo

Dunand

Mohr

Experiments and modeling of anisotropic aluminum extrusions under multi-axial loading – part II: ductile fracture. Int J Plast 2012; 32–33: 36–58.

33.

Mohr

Anisotropic Hosford-Coulomb fracture initiation model: theory and application. Eng Fract Mech 2015; 147: 480–497.

34.

Park

Huh

Lim

, et al. Fracture-based forming limit criteria for anisotropic materials in sheet metal forming. Int J Plast 2017; 96: 1–35.

35.

Park

Huh

Yoon

JW.

Anisotropic fracture forming limit diagram considering non-directionality of the equi-biaxial fracture strain. Int J Solids Struct 2018; 151: 181–194.

36.

Basak

Panda

SK.

Failure strains of anisotropic thin sheet metals: experimental evaluation and theoretical prediction. Int J Mech Sci 2019; 151: 356–374.

37.

Basak

Panda

SK.

Necking and fracture limit analyses of different pre-strained sheet materials in polar effective plastic strain locus using Yld2000-2d yield model. J Mater Process Technol 2019; 267: 289–307.

38.

Martínez-Donaire

Borrego

Morales-Palma

, et al. Analysis of the influence of stress triaxiality on formability of hole-flanging by single-stage SPIF. Int J Mech. Sci 2019; 151: 76–84.

39.

López-Fernández

Centeno

Martínez-Donaire

, et al. Stretch-flanging of AA2024-T3 sheet by single-stage SPIF. Thin-Walled Struct 2021; 160: 107338.

40.

Soeiro

JMC

Silva

CMA

Silva

, et al. Revisiting the formability limits by fracture in sheet metal forming. J Mater Process Technol 2015; 217: 184–192.

41.

Mirnia

Shamsari

Numerical prediction of failure in single point incremental forming using a phenomenological ductile fracture criterion. J Mater Process Technol 2017; 244: 17–43.

42.

Mirnia

Vahdani

Shamsari

Ductile damage and deformation mechanics in multistage single point incremental forming. Int J Mech. Sci 2018; 136: 396–412.

43.

Lou

Yoon

Huh

, et al. Correlation of the maximum shear stress with micro-mechanisms of ductile fracture for metals with high strength-to-weight ratio. Int J Mech Sci 2018; 146–147: 583–601.

44.

Zeng

Fan

, et al. Heterogeneous microstructure and mechanical property of thin-walled tubular part with cross inner ribs produced by flow forming. Mat Sci Eng A 2020; 790: 139702.

45.

Zhan

Zheng

, et al. A constitutive model coupling damage and material anisotropy for wide stress triaxiality. Chin J Aeronaut 2020; 33: 3509–3525.

46.

Papasidero

Doquet

Mohr

Ductile fracture of aluminum 2024-T351 under proportional and non-proportional multi-axial loading: Bao–wierzbicki results revisited. Int J Solids Struct 2015; 69–70: 459–474.

47.

Baral

Korkolis

YP.

Ductile fracture under proportional and non-proportional multiaxial loading. Int J Solids Struct 2021; 210–211: 88–108.

48.

Chen

Gao

Zhan

, et al. Determination of formability considering wrinkling defect in first pass conventional spinning with linear roller path. J Mater Process. Technol 2019; 265: 44–55.

49.

Zhao

, et al. Study on flange-constrained spinning process for hemispherical aluminum alloy part. J Mater Process Technol 2020; 278: 116515.

50.

Morales-Palma

Vallellano

García-Lomas

FJ.

Assessment of the effect of the through-thickness strain/stress gradient on the formability of stretch-bend metal sheets. Mater Des 2013; 50: 798–809.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.18 MB

Fracture prediction in spin forming of anisotropic metal sheets

Abstract

Keywords

Get full access to this article

References

Supplementary Material