Micro-Drawing of Circular Cups with Thin Stainless Steel Sheets

Hong Syuan Su; Fuh Kuo Chen; Kun Min Huang

doi:10.4028/www.scientific.net/MSF.920.114

Paper Titles

Investigation of a Two-Step Rotary Rim-Thickening Process of Disc-Like Blanks
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Study on Thickness Distribution and Spring Back Phenomena of Sheet-Bulk Forming for Aluminum Alloy
p.95

Investigation on Dynamic Impact Effect of Ultrasonic-Assisted Compression Test
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Study on Multi-Step Spinning Process for Disk-Like Part with Thickened Rim
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Micro-Drawing of Circular Cups with Thin Stainless Steel Sheets
p.114

Optimizing Design of the Cutting Tool in Cutting of Ultra-High Strength Steel Beam Part
p.120

Geometric Design of Rectangular Cross-Sectional Springs
p.126

The Numerical Simulation and Experiment Verification of the Large Aluminum Alloy Covering Part of Car Using Sequential Coupling Technology
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Evolution of White Layer during Wire-Cutting and Comparison of Several Methods to Improve Surface Integrity for Fineblanking Tools
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HomeMaterials Science ForumMaterials Science Forum Vol. 920Micro-Drawing of Circular Cups with Thin Stainless...

Micro-Drawing of Circular Cups with Thin Stainless Steel Sheets

Abstract:

With the ongoing development of product process, there is a growing demand on micro products. Though the macro-drawing process has been well-developed, the design concepts may not be directly applicable to the micro-drawing due to the size effect occurred in the micro-forming processes. In the present study, experiments were conducted first to establish the stress-strain curves, r-values and work hardening exponents of 304 stainless steel sheets with different grain sizes. The experiment results reveal that the stress-strain and r-value become smaller and the work hardening exponent increases for larger grain sizes. The difference between stress-strain curves in various directions of 0°, 45° and 90°, respectively, is significant when the grain size increases. The stamping of a vibration motor shell of cell phone, which bears a circular cylindrical shape, was also examined in the present study. The finite element simulations were performed to evaluate the formability of the multi-stage drawing process with initial die design. The forming characteristics were identified and an optimum die design was then developed with the use of the finite element analysis. The stamping process with multi-stage tooling design based on the finite element analysis was implemented and the actual stamping experiments were conducted to verify finite element analysis. The experimental results confirm the validity of the modified tooling design and the efficiency of the finite element analysis.

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Periodical:

Materials Science Forum (Volume 920)

Pages:

114-119

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.920.114

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Online since:

April 2018

Authors:

Hong Syuan Su, Fuh Kuo Chen*, Kun Min Huang

Keywords:

304 Stainless Steel, Finite Element Analysis, Grain Size, Micro-Drawing, Multi-Stage, Size Effect

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