Numerical and experimental analysis of wrinkling during the cup drawing of an AA5042 aluminium alloy

Neto, Diogo M.; Oliveira, M. C.; Dick, Robert E.; Barros, P. D.; Alves, J. L.; Menezes, L.F.

doi:10.1007/s12289-015-1265-4

Cited by 25 publications

(12 citation statements)

References 43 publications

(69 reference statements)

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“…The dimensions of tools were consistent with experimental setups. The mesh of blank is extremely important for guaranteeing the accuracy of simulation [28]. In this study, the mesh of test-piece material was selected as shell element, Belytschko-Tsay, with a fixed size at 4 mm.…”

Section: Fe Simulation Analysis 41 Fe Simulation Programmementioning

confidence: 99%

An analytical investigation on the wrinkling of aluminium alloys during stamping using macro-scale structural tooling surfaces

Zheng

Lee

Politis

et al. 2017

Int J Adv Manuf Technol

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Structural surface texturing is believed to be a promising approach to modify tribological and thermal performances of tooling for sheet-stamping processes. However, a fundamental study on the surface-texturing design and resulting material deformation is currently lacking. In this paper, an advanced analytical buckling model specifically for the utilisation of textured tools at macro-scale, comprising dislocation-driven material model, isotropic yield criteria, bifurcation theory and Donnell-Mushtari-Vlasov (DMV) shell structure theory, was established. The developed analytical buckling model was validated by cylindrical deep-drawing experiments. Further finite element (FE) simulations with the implementation of material model via user-defined subroutine were also used to validate the bucking model for large surface texture designs. Effects of theoretical assumptions, such as yield criterion, boundary condition and test-piece geometry, on the accuracy of model prediction for wrinkling were investigated. It was found that the von Mises yield criterion and hinged boundary condition exhibited more accurate predictions. In addition, the DMV shell theory made this model most representative for large structural texturing designs. Furthermore, the implementation of induced shear strain component has an important effect on precisely predicting the wrinkling occurrence. The advanced analytical models developed in this study combine various classical mechanics, structure stability and material modelling together, which provides a useful tool for tooling engineers to analyse structural designs.

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Section: Fe Simulation Analysis 41 Fe Simulation Programmementioning

confidence: 99%

An analytical investigation on the wrinkling of aluminium alloys during stamping using macro-scale structural tooling surfaces

Zheng

Lee

Politis

et al. 2017

Int J Adv Manuf Technol

View full text Add to dashboard Cite

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“…Since the prediction of wrinkling phenomena in sheet metal forming simulation requires a fine mesh [6], a regular mesh is adopted in the Oxy plane (element size of 1.0 mm in the central region), as shown in Figure 5. The discretization of the blank comprises two layers of finite elements through the thickness, which enable an accurate prediction of the forming forces and the springback [13].…”

Section: Sheet and Tools Discretizationmentioning

confidence: 99%

“…Nevertheless, these material are more prone to develop geometrical defects, namely springback [5]. Another important geometrical defect arising in sheet metal forming is the wrinkling behaviour, which results from the instability under compressive stresses [6].…”

Section: Introductionmentioning

confidence: 99%

“…Despite the many advances in the numerical simulation tools development, the accurate prediction of geometrical defects still represents a challenge for the simulation [12]. For instance, it is known that wrinkling prediction is strongly affected by the finite element discretization [6]. Also, springback prediction is influenced by the model selected to describe the material kinematic hardening behaviour [13].…”

Section: Introductionmentioning

confidence: 99%

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Prediction of wrinkling and springback in sheet metal forming

et al. 2016

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Abstract. The finite element simulation is currently a powerful tool to optimize forming processes in order to produce defect-free products. Wrinkling and springback are main geometrical defects arising in sheet metal forming. Nevertheless, the prediction of such defects requires accurate numerical models. This study presents the experimental and numerical analysis of a rail with high tendency to develop both wrinkling (top surface of geometry) and springback (flange). The punch force evolution and the final geometry of the rail, evaluated in four different cross-sections, are the main variables analysed. Globally, the numerical results are in good agreement with the experimental measurements. However, the shape of the wrinkle is significantly influenced by the symmetry conditions considered in the model (1/4 of the blank). In fact, considering the full model of the blank, the numerical results are in better agreement with the experimental ones. On the other hand, the computational cost of the numerical simulation considering the full blank is approximately 12 times higher than using 1/4 of the blank.

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“…The main defects in deep drawing are wrinkling, fracture (or tearing), earring, and surface scratches. Generally, wrinkling occurs due to compressive stress in the circumferential direction, fracture occurs because of high tensile stresses that cause thinning and failure of the metal in the cup wall [3], earring caused by materials anisotropy [4] which is due to the directionality of plastic properties produced by rolling and other primary working process, and surface scratches can be seen on the drawn part if the punch and die are not smooth or if the lubrication of the process is poor. Therefore, in order to achieve drawn parts in desired shape and without defects, process parameters should be appropriately chosen and set, which can be obtained through simulation and optimization strategy [5].…”

Section: Introductionmentioning

confidence: 99%

Uncertainty analysis of deep drawing using surrogate model based probabilistic method

Huang

Radi

Hami

2016

Int J Adv Manuf Technol

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Deep drawing is an important manufacturing process in industry. In order to obtain high-quality products produced by deep drawing, the set of design variables used in forming operation is designed through deterministic optimization. However, in real forming process, the design variables show variability and randomness which will affect the product quality. These uncertainties are an inherent characteristic of nature and cannot be avoided. This paper focuses on uncertainty analysis of deep drawing with the consideration of uncertainties in material parameters and friction. An uncertainty analysis approach which combines the finite element method (FEM) simulation, surrogate modeling, and Monte Carlo simulation (MCS) is presented in this work. The constructed surrogate models are validated and compared by cross validation and error measures. Then Monte Carlos Simulation is conducted by the use of the constructed surrogate model. The surrogate model based probabilistic method used in this paper is an approach with high-efficiency and sufficient accuracy for uncertainty analysis in deep drawing.

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Numerical and experimental analysis of wrinkling during the cup drawing of an AA5042 aluminium alloy

Cited by 25 publications

References 43 publications

An analytical investigation on the wrinkling of aluminium alloys during stamping using macro-scale structural tooling surfaces

An analytical investigation on the wrinkling of aluminium alloys during stamping using macro-scale structural tooling surfaces

Prediction of wrinkling and springback in sheet metal forming

Uncertainty analysis of deep drawing using surrogate model based probabilistic method

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