Visco-plastic and Large Deformation Analysis by FEM : Investigation of Numerical Analysis and Collapse of a Beam by Transverse Impact Load
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概要
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This paper is the third part of our visco-plastic and large deformation analysis by the finite element method. Algorithm to be used in this study was investigated. As the result, fundamental equations of this study were expressed by Newmark β(1/4) method. Visco-plastic matrix of constitutive equations was reformed. The result of calculation was compared with the experiment. The dynamic characteristics of collapsing of a beam were investigated. The experimental values were shown to be in good agreement with the theoretical results. Thus, this method was found appropriate and useful to deal with this kind of problems.
- 一般社団法人日本機械学会の論文
著者
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Nishimura Tohru
Meijo University
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Nishimura Tohru
Meijo University Faculty Of Science And Engineering
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Murase Katsuhiko
Meijo University
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Katori Hiroaki
High School Affiliated To Meijo University
関連論文
- Finite Bending of Curved Beam with Thin Wall Cross Section
- Visco-plastic Large Deformation Analysis by Finite Element Method and Its Applications : Inextensional Deformation of Thin-walled Square Tube
- Visco-plastic and Large Deformation Analysis by FEM : Investigation of Numerical Analysis and Collapse of a Beam by Transverse Impact Load
- A Static and a Dynamic Stress Intensity Factor of a Lug with Cracks : Series A : Solid-Mechanics, Strength of Materials
- The Collapse of Stepped Circular Tubes Subjects to an Impact Axial Load : Series A : Solid-Mechanics, Strength of Materials
- A Simple Procedure for the Determination of Dynamic Stress Intensity Factors by Finite Element Method : An Investigation of its Availability for the Mode I Deformation
- A Method for Obtaining Stress Intensity Factor by F.E.M. and Its Application to Dynamic Problem : Part 2,A treatment for Mixed Mode Cracks
- A Method for Obtaining Stress Intensity Factor by F. E. M. and Its Application to Dynamic Problem
- Strength Evaluation for Dissimilar Adhesive Shaft Joints Subjected to Impact Tensile Load