An experimental and numerical study of micro deep drawing of SUS304 circular cups

Luo, Liang; Jiang, Zhengyi; Wei, Dongbin; Manabe, Ken‐ichi; Sato, Hideki; He, X. Q.; Li, Pengfei

doi:10.1051/mfreview/2015029

Cited by 12 publications

(9 citation statements)

References 12 publications

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“…figure 3(a) shows that the grains are gradually broken up, and the grain boundaries become blurred at the annealing temperature of 750 ℃. Meanwhile, recrystallized grains appear and gradually grow up by consuming the heavily deformed region around them [14]. When the temperature is increased to 950 ℃ (figure 3(b)), the microstructure is dominated by recrystallized grains with clear grain boundaries, indicating that recrystallization process has completed at this temperature [15].…”

Section: Microstructurementioning

confidence: 98%

A study of the formability of stainless steel foils during micro deep drawing

et al. 2022

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

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Stainless steel foils are extensively used in the manufacture of micro-metallic products for their excellent corrosion resistance, high mechanical strength and superior ductility. In the present work, stainless steel foils with 50 μm thickness were annealed at temperatures ranging from 750 to 1150 °C for 5 min and then cupped at drawing speeds ranging from 0.1 to 2 mm/min. The formability of metal foils was systematically investigated and the quality of drawn cups via micro deep drawing (MDD) was discussed. The results show that the total elongation of metal foils appears a gradual increase when annealing temperature rises from 750 to 950 °C. With a further increase of annealing temperature from 950 to 1150 °C, both the ultimate tensile strength and the total elongation decline sharply, while the scatter of stress increases. The results of MDD tests show that wrinkling problem becomes increasingly significant on the drawn cups whilst thickness distribution on the drawn cup mouth become quite nonuniform with the increase of drawing speed from 0.1 to 2 mm/min. Overall, optimal annealing temperature and drawing speed are obtained with the purpose of manufacturing high quality micro circular cups.

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Section: Microstructurementioning

confidence: 98%

A study of the formability of stainless steel foils during micro deep drawing

et al. 2022

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

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“…With respect to the finite element modelling for materials with size effect, Voronoi tessellation is a prevailing technique exploited to construct a polycrystalline microstructure comprising grains that have different properties equipped with them. Cao et al [32,33], Jiang et al [34] and Luo et al [35,36] produced numerical studies on the micro extrusion, micro hydroforming, micro cross wedge rolling, micro deep drawing and micro hydro deep drawing processes of polycrystalline materials generated by the Voronoi algorithm, respectively; all these results showcased that the mechanical properties and formability of the materials as well as the final product quality had strong affiliations with the properties of individual grains such as its size, morphology and orientation. In the wake of the uneven distribution of heterogeneous grains within these materials, the scatter effect of their general flow curves has been recognised and modelled with a normal bell-shaped distribution [37].…”

Section: Introductionmentioning

confidence: 99%

“…Additionally, in most cases of metal forming, the products are unlikely to be manufactured exactly to the specifications like size, shape, etc., as the deformed regions are prone to a certain amount of elastic recovery after release of the loading. Material behaviour of this type is termed springback, e.g., a slight decrease in the bending angle after the V-bending process, a slight increase in the flange angle after the deep drawing process, etc., which are affected by the factors such as process parameters, material properties and tooling geometries and have a chance of being compensated by overbending the material [29,35,[42][43][44][45]. Whilst for the strip rolling process springback may refer to the elastic recovery in the thickness after the strip exits the roll bite, and it is likely to be rectified by dint of increasing the rolling speed, adding tensions to the strip, decreasing the roll gap for a supplementary amount of reduction, and so forth [46][47][48][49][50].…”

Section: Introductionmentioning

confidence: 99%

Study of micro flexible rolling based on grained inhomogeneity

Jiang

Wei

et al. 2017

International Journal of Mechanical Sciences

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This paper shows an analytical, numerical and experimental investigation to comprehend the role of grained inhomogeneity which plays in micro flexible rolling in terms of the average rolling force and the thickness directional springback of the workpiece after it exits the roll bite zone. Miniature tensile tests and micro hardness tests are accomplished to identify the scattered stress-strain curves for 500 ¿m thick aluminium alloy 1060 samples with grain size of approximately 23-71 µm and to determine the weighted heterogeneity coefficient for each sample separately, according to which the theoretical calculations and numerical simulations based upon 3D Voronoi tessellation technique have been performed under actual experimental conditions where reductions of 25 to 50 % are selected. The scattering effect associated with the anisotropic nature of single grains has been perceived in the micro flexible rolling process and both the analytical and finite element models developed have been validated via experimental data to hold promise for predicting the rolling force and the thickness directional springback of the workpiece, as well as boosting the thickness profile control performance of the micro flexible rolling mill.

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“…As shown in Figure 26b, the information of grains and individual closed subareas, including single grain's area, geometrical center and geometrical orientation, was detected and sorted in MATLAB. The blue ports in Figure 26b are the grain's geometrical centers [9,20,21]. After annealed at 1100°C, the 50 μm thick blanks, with equiaxed crystals microstructure and average grain size of 40 μm, were drawn into micro cups.…”

Section: Application Of Finite Element Analysis In Multiscale Metal Fmentioning

confidence: 99%

“…Open and closed lubricate pocket (OCLP) theory and size-dependent friction coefficient are proposed in micro deep drawing (MDD) and micro hydromechanical deep drawing (MHDD) [17][18][19]. Real microstructures and Voronoi structures are applied in microstructural models through the image-based modeling method [20,21].…”

Section: Introductionmentioning

confidence: 99%

Application of Finite Element Analysis in Multiscale Metal Forming Process

Jiang¹,

Xie²

2018

Finite Element Method - Simulation, Numerical Analysis and Solution Techniques

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The application of finite element analysis has been presented in multiscale metal forming process. A 3D finite element method (FEM) has first been proposed to analyze the deformation mechanism of thin strip cold rolling with the consideration of friction variation in deformation zone. The crystal plasticity finite element method (CPFEM) is applied on the simulation of surface asperity flattening in the uniaxial planar compressing process. 3D Voronoi tessellation and frictional modeling have been applied in microforming processes. All simulation results from the proposed modeling have been validated by the related experimental results.

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An experimental and numerical study of micro deep drawing of SUS304 circular cups

Cited by 12 publications

References 12 publications

A study of the formability of stainless steel foils during micro deep drawing

A study of the formability of stainless steel foils during micro deep drawing

Study of micro flexible rolling based on grained inhomogeneity

Application of Finite Element Analysis in Multiscale Metal Forming Process

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