Forming limits and constitutive modeling of steel tube for automotive parts
Project/Area Number |
17560628
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Research Category |
Grant-in-Aid for Scientific Research (C)
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Allocation Type | Single-year Grants |
Section | 一般 |
Research Field |
Material processing/treatments
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Research Institution | Tokyo University of Agriculture and Technology |
Principal Investigator |
KUWABARA Toshihiko Tokyo University of Agriculture and Technology, Institute of Symbiotic Science and Technology, Professor, 大学院共生科学技術研究院, 教授 (60195609)
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Project Period (FY) |
2005 – 2006
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Project Status |
Completed (Fiscal Year 2006)
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Budget Amount *help |
¥3,500,000 (Direct Cost: ¥3,500,000)
Fiscal Year 2006: ¥1,100,000 (Direct Cost: ¥1,100,000)
Fiscal Year 2005: ¥2,400,000 (Direct Cost: ¥2,400,000)
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Keywords | material processing / yield surface / plastic anisotropy / yield function / constitutive model / non-normality flow rule / forming limit / combined loading / チューブハイドロフォーミング / 鋼管 / 異方性降伏関数 / 成形限界ひずみ / 成形限界応力 / 材料試験 |
Research Abstract |
The present study aims to clarify the nature of the path-dependence of forming limit stresses from a view point of the phenomenological plasticity analysis. In this analysis we use a non-normality flow rule proposed by Kuroda and Tvergaard (2001). This flow rule assumes a non-linear dependence of the plastic strain rate D^P on the total strain rate D, where D is decomposed as D=D^e +D^P=D^e+^^・ΦN^P (1) where e and p indicate the elastic and plastic part of strain. N^P defines the direction of D^P, ^^・Φ is a non-negative overstress function for rate-dependent cases. State variables of the material are assumed to be Cauchy stress tensor, σ, and the orthonormal vectors n, defined along the axes of orthotropy, and equivalent strain ^^-ε. These variable are calculated using following equations: ^^。σ=^^・σ-ω・σ+σ・ω=C^<+e>:D^e=C:D-^^・ΦC^e : N^P (2) ^^・n_i=ω・n_i (3) ^^-ε=∫^^<・->εdt, ^^<・->ε=√<2/3>^^・Φ (4) where C^e is the fourth order elastic moduli tensor. With a superposed o denoting an objective rat
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e with respect to the spin ω and the superposed dot denoting a material time derivative, the elasticity relation is assumed to be given by Hooke's law. The limits to formability are simulated using the M-K model both for proportional loading and two types of combined loadings : one type includes unloading between the first and second loadings while the other type does not include unloading. The strain paths for each combined loading are almost identical, while the resulting stress paths are significantly different. The effects of changing stress/strain paths on the FLC and FLSC are discussed in detail by observing the strain localization process for each case. A basic question is: Is the forming limit stress always path-independent, irrespective of stress/strain paths? If so, why? If not, what makes the forming limit stress path-dependent? The forming limit stresses calculated for combined loading A agree well with those calculated for the linear stress paths, while the forming limit curves in strain space depend strongly on the strain paths. The forming limit stresses calculated for the combined loading B do not, however, coincide with those calculated for the linear stress paths. Less
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Report
(3 results)
Research Products
(12 results)