Flange Wrinkling in Deep-Drawing: Experiments, Simulations and a Reduced-Order Model

Chen, Kelin; Carter, Adrian J.; Korkolis, Yannis P.

doi:10.3390/jmmp6040076

Cited by 11 publications

(9 citation statements)

References 24 publications

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“…In stamping processes, the use of an edge holder is imperative to prevent the flange edge from wrinkling. Additionally, the reliability of the simulation optimization results is verified by experiments, as shown in Figure 15 b. Chen et al [ 185 ] conducted experiments, simulations and reduced-order calculations on flange wrinkling in the deep drawing process of the AA1100 aluminum alloy. The flange wrinkle height and wrinkle numbers predicted by the FE model and reduced-order model are consistent with experimental results, as shown in Figure 15 c. Based on the established sheet deformation instability model, Wang et al [ 186 ] undertook the FE model to compare the prediction results of FLC, maximum stress and strain instability criteria; they found that a new FLC instability criterion can be more accurately predicted and verified for wrinkling.…”

Section: Analytical Methods Of Deformation Instabilitymentioning

confidence: 83%

“… Research results of deformation instability by finite element simulation and experimental methods: ( a ) flange forming of the spinning thin-walled plate [ 171 ]; ( b ) stamping forming of a titanium alloy mechanical handle [ 184 ]; ( c ) deep drawing of the AA1100 aluminum alloy [ 185 ]; ( d ) 304 steel plate shear wrinkling test [ 187 ]; ( e ) various buckling modes of tube compression instability [ 140 ]. …”

Section: Figurementioning

confidence: 99%

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Theory, Method and Practice of Metal Deformation Instability: A Review

Wan

Yao

et al. 2023

Materials

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Deformation instability is a macroscopic and microscopic phenomenon of non-uniformity and unstable deformation of materials under stress loading conditions, and it is affected by the intrinsic characteristics of materials, the structural geometry of materials, stress state and environmental conditions. Whether deformation instability is positive and constructive or negative and destructive, it objectively affects daily life at all times and the deformation instability based on metal-bearing analysis in engineering design has always been the focus of attention. Currently, the literature on deformation instability in review papers mainly focuses on the theoretical analysis of deformation instability (instability criteria). However, there are a limited number of papers that comprehensively classify and review the subject from the perspectives of material characteristic response, geometric structure response, analysis method and engineering application. Therefore, this paper aims to provide a comprehensive review of the existing literature on metal deformation instability, covering its fundamental principles, analytical methods, and engineering practices. The phenomenon and definition of deformation instability, the principle and viewpoint of deformation instability, the theoretical analysis, experimental research and simulation calculation of deformation instability, and the engineering application and prospect of deformation instability are described. This will provide a reference for metal bearing analysis and deformation instability design according to material deformation instability, structural deformation instability and localization conditions of deformation instability, etc. From the perspective of practical engineering applications, regarding the key problems in researching deformation instability, using reverse thinking to deduce and analyze the characteristics of deformation instability is the main trend of future research.

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Section: Analytical Methods Of Deformation Instabilitymentioning

confidence: 83%

Section: Figurementioning

confidence: 99%

Theory, Method and Practice of Metal Deformation Instability: A Review

Wan

Yao

et al. 2023

Materials

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“…6) and then finding the corresponding punch displacement. Wrinkling is determined by simulating the blank with and without wrinkling imperfection and measuring the punch and blank holder displacements, as in our earlier work by Chen et al (1).…”

Section: Simulation Resultsmentioning

confidence: 99%

Experiments and simulations of the drawing envelope of commercially pure aluminum

Carter

Chen

Korkolis

2023

IOP Conf. Ser.: Mater. Sci. Eng.

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The range of blank-holding force (BHF) for which deep drawing of AA1100-H24 is successful is investigated using a combination of experiments and simulations. The experiments involve circular blanks of three different diameters: 35 mm, 37 mm and 40 mm. The thickness of the blanks is 0.51 mm. These are drawn with a punch of 20 mm diameter, i.e., at drawing ratios of 1.75, 1.85 and 2.0, respectively, using a custom, modular forming apparatus where the BHF can be controlled at will, between 0 and 2,400 N. The experiments are performed in an Instron 8872 servo-hydraulic frame that allows precise measurements of the punch force and displacement. The working envelopes are determined experimentally in the space of BHF and draw depth, which can be categorized into three regimes: wrinkling, safe and tearing. It is found that grey zones exist between the three regimes. These experiments are then simulated in Abaqus/Standard, using two types of elements: axisymmetric and shell. In the latter case, plastic anisotropy is introduced, using the Yld2000-2D anisotropic yield function. Wrinkling and tearing failure are triggered by inducing suitable geometric imperfections. It is shown that the models are able to reproduce the experiments well. This serves as a verification of the modelling framework, which can then be used for the simulations of more complex forming processes.

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“…In the past, many investigations were conducted to identify influencing factors of the deep drawing process, e.g., friction, blank holder force, blank shape, and punch velocity [20]. Most of the work is aimed at producing a component that is free of defects at the macroscopic level for instance considering wrinkling [21,22], sheet thinning [23], and springback [24,25]. Besides that, efforts have been made to numerically predict damage occurrence during deep drawing.…”

Section: Damage Evolution During Deep Drawingmentioning

confidence: 99%