The design of steel frames using plastic theory

Leinster, James Carson

January 1988

No description available.

624.1

Elastic-plastic analysis

[en] POTENTIAL WIDESPREAD AND OPTIMIZATION IN ELASTIC-PLASTIC ANALYSIS / [pt] POTENCIAIS GENERALIZADOS E OTIMIZAÇÃO NA ANÁLISE ELASTO-PLÁSTICA

MILDRED BALLIN HECKE

09 March 2018

[pt] Este trabalho focaliza a análise elasto-plástica de componentes mecânicos e estruturais. Especial atenção é dada a formulação da equação constitutiva. A relação constitutiva em taxas é equacionada na forma de potenciais generalizados onde utiliza-se o conceito de subgradientes. Para tal, são introduzidos conceitos básicos da termodinâmica sendo usadas variáveis internas para descrever os mecanismos dissipativos. São apresentados pseudo-potenciais em incrementos finitos de tensões e deformações que incorporam a admissibilidade plástica e são capazes de descrever o descarregamento elástico local desde que não haja plastificação seguida de descarregamento no passo. Esta forma é utilizada na obtenção-de Princípios de Mínimo para a análise elasto-plástica. A discretização espacial é feita utilizando o Método dos Elementos Finitos. São considerados algoritmos para a solução de tal problema. São incluídas aplicações numéricas a problemas planos e a flexão de placas. / [en] The elastic-plastic analysis of structural components is considered. The formulation of the constitutive equations is specially focused. The constitutive relation for rates is derived from pseudo-potentials by using the sub-gradient concept. Internal variables are introduced to describe dissipation mechanisms and thermodynamical concepts are used in order, to obtain the corresponding potential relationships. Generalized potentials are also presented for the approximate constitutive relation in terms of finite increments of strain and stress. This formulation incorporate plastic admissibility constraínts and it is also able to describe local elastic unloading except the case when it follows plastic yielding in the true incremental process. This form of the constitutive equation is used next to obtain minimum principles for the elastic-plastic analysis. Spatial discretization is performed by means of the Finíte Element Method. Some algorithms are discussed for the solution of the variational formulations considered. Numerical applications are presented for plane problems and plate bending.

[pt] OTIMIZACAO

[en] OPTIMIZATION

[pt] POTENCIAIS GENERELIZADOS

[en] POTENTIAL WIDESPREAD

[pt] ANALISE ELASTO-PLASTICA

[en] ELASTIC- PLASTIC ANALYSIS

モードⅡ荷重を受ける長繊維強化複合材料の層間マトリックスき裂先端での塑性領域

來海, 博央, KIMACHI, Hirohisa, 田中, 拓, TANAKA, Hiroshi, 佐藤, 敏弘, SATOH, Toshihiro, 田中, 啓介, TANAKA, Keisuke

06 1900

No description available.

Composite Material

Fracture Mechanics

Finite Element Method

Crack-Tip Plastic Zone

Elastic-Plastic Analysis

Inhomogeneous Composite Model

Mode Ⅱ

Matrix Stress Distribution

モードⅠき裂を有する長繊維強化複合材料における塑性領域の弾塑性有限要素法解析

來海, 博央, KIMACHI, Hirohisa, 田中, 拓, TANAKA, Hiroshi, 佐藤, 敏弘, SATOH, Toshihiro, 田中, 啓介, TANAKA, Keisuke

01 1900

No description available.

Composite Material

Finite Element Method

Stress Intensity Factor

Crack-Tip Plastic Zone

Elastic-Plastic Analysis

Inhomogeneous Composite Model

Mode Ⅰ

Matrix Stress Distribution

Experimental And Finite Element Study Of Elastic-Plastic Indentation Of Rough Surfaces

Bhowmik, Krishnendu

07 1900

Most of the surfaces have roughness down to atomic scales. When two surfaces come into contact, the nature of the roughness determines the properties like friction and wear. Analysis of the rough surface contacts is always complicated by the interaction between the material size effects and the micro-geometry. Contact mechanics could be simplified by decoupling these two effects by magnifying the scale of roughness profile. Also, tailoring the roughness at different scale could show a way to control the friction and wear through surface micro-structure modifications. In this work, the mechanics of contact between a rigid, hard sphere and a surface with a well defined roughness profile is studied through experiments and finite element simulation. The well defined roughness profile is made up of a regular array of pyramidal asperities. This choice of this geometry was mainly dictated by the fabrication processes. The specimens were made out of an aluminium alloy (6351-T6) such that there could be a direct application of the results in controlling the tribological properties during aluminium forming. Experiments on the pyramidal aluminium surface is carried out in a 250 kN Universal Testing Machine (INSTRON 8502 system) using a depth sensing indentation setup. A strain gauge based load cell is used to measure the force of the indentation and a LVDT (Linear Variable Differential Transformer) is used to measure the penetration depth. The load and the displacement were continuously recorded using a data acquisition system. A 3-D finite element framework for studying the elastic-plastic contact of the rough surfaces has been developed with the commercial package (ABAQUS). Systematic studies of indentation were carried out in order to validate the simulations with the experimental observations. The simulation of indentation of flat surface is carried out using the implicit/standard (Backward Euler) procedure, whereas, the explicit finite element method (Forward Euler) is used for simulating rough surface indentation. It is found that the load versus displacement curves obtained from experiments match well with the finite element results (except for the error involved in determining the initial contact point). At indentation depths higher than a value that is determined mainly by the asperity height, the load-displacement characteristics are similar to that pertaining to indentation of a flat, smooth surface. From the finite element results, it is found that at this point, the elastic-plastic boundary is more or less hemispherical as in the case of smooth surface indentation. For certain geometries, it is found that there could exist an elastic island in the sub-surface surrounded by plastically deformed material. This could have interesting applications.

Elasticity

Contact Mechanics

Surfaces - Indentation

Finite Element Analysis

Surfaces - Elastic-Plastic Analysis

Surface Topography

Nanoindentation

Elastic Contact

Plastic Contact

Smooth Surface

Rough Surface

Indentation Analysis

Applied Mechanics