Formulação do método dos elementos de contorno para análise de cascas abatidas / Boundary element formulation for shallow shell analysis

Lima Junior, Eduardo Toledo de

12 July 2006

O presente trabalho trata da análise numérica de cascas abatidas com o uso do método dos elementos de contorno (MEC). A formulação é desenvolvida a partir do acoplamento entre as equações integrais para flexão de placas delgadas e para estado plano de tensão. No esquema implementado, os termos sobre o contorno são avaliados a partir de processos analíticos e numéricos de integração. No caso das integrais de domínio, aplica-se um procedimento semi-analítico de cálculo sobre células discretas. A validação do modelo computacional desenvolvido é feita com base em resultados da literatura, obtidos com uso do método dos elementos finitos e dos elementos de contorno, além de soluções analíticas. / The present work deals with the numerical analysis of shallow shells using boundary element method (BEM). The formulation is developed by coupling integral equations of plate bending and plane stress elasticity. In the implemented scheme, the boundary terms are evaluated with analytical and numerical processes of integration. In the case of domain integrals, a semi-analytical calculation procedure is applied on discrete cells. The validation of developed computational model is made with results from other works, obtained by use of BEM or finite element method, besides analytical solutions.

boundary element method

cascas abatidas

computational mechanics

domain integrals

integrais de domínio

mecânica computacional

mecânica das estruturas

método dos elementos de contorno

shallow shells

structural mechanics

The finite element method simulation of active optimal vibration attenuation in structures

Baweja, Manish

30 April 2004

The Finite Element Method (FEM) based computational mechanics is applied to simulate the optimal attenuation of vibrations in actively controlled structures. The simulation results provide the forces to be generated by actuators, as well as the structures response. Vibrations can be attenuated by applying either open loop or closed loop control strategies. In open loop control, the control forces for a given initial (or disturbed) configuration of the structure are determined in terms of time, and can be preprogrammed in advance. On the other hand, the control forces in closed loop control depend only on the current state of the system, which should be continuously monitored. Optimal attenuation is obtained by solving the optimality equations for the problem derived from the Pontryagins principle. These equations together with the initial and final boundary conditions constitute the two-point-boundary-value (TPBV) problem. <p>Here the optimal solutions are obtained by applying an analogy (referred to as the beam analogy) between the optimality equation and the equation for a certain problem of static beams in bending. The problem of analogous beams is solved by the standard FEM in the spatial domain, and then the results are converted into the solution of the optimal vibration control problem in the time domain. The concept of the independent-modal-space-control (IMSC) is adopted, in which the number of independent actuators control the same number of vibrations modes. <p>The steps of the analogy are programmed into an algorithm referred to as the Beam Analogy Algorithm (BAA). As an illustration of the approach, the BAA is used to simulate the open loop vibration control of a structure with several sets of actuators. Some details, such as an efficient meshing of the analogous beams and effective solving of the target condition are discussed. <p> Next, the BAA is modified to handle closed loop vibration control problems. The algorithm determines the optimal feedback gain matrix, which is then used to calculate the actuator forces required at any current state of the system. The methods accuracy is also analyzed.

feedback gain

Optimal gains

Modal space

Open loop control

Finite Elements

Actuators

Optimal vibration control

Computational mechanics

Simulation

Beam Analogy

observability

Sensors

Controllability

The finite element method simulation of active optimal vibration attenuation in structures

Baweja, Manish

30 April 2004

The Finite Element Method (FEM) based computational mechanics is applied to simulate the optimal attenuation of vibrations in actively controlled structures. The simulation results provide the forces to be generated by actuators, as well as the structures response. Vibrations can be attenuated by applying either open loop or closed loop control strategies. In open loop control, the control forces for a given initial (or disturbed) configuration of the structure are determined in terms of time, and can be preprogrammed in advance. On the other hand, the control forces in closed loop control depend only on the current state of the system, which should be continuously monitored. Optimal attenuation is obtained by solving the optimality equations for the problem derived from the Pontryagins principle. These equations together with the initial and final boundary conditions constitute the two-point-boundary-value (TPBV) problem. <p>Here the optimal solutions are obtained by applying an analogy (referred to as the beam analogy) between the optimality equation and the equation for a certain problem of static beams in bending. The problem of analogous beams is solved by the standard FEM in the spatial domain, and then the results are converted into the solution of the optimal vibration control problem in the time domain. The concept of the independent-modal-space-control (IMSC) is adopted, in which the number of independent actuators control the same number of vibrations modes. <p>The steps of the analogy are programmed into an algorithm referred to as the Beam Analogy Algorithm (BAA). As an illustration of the approach, the BAA is used to simulate the open loop vibration control of a structure with several sets of actuators. Some details, such as an efficient meshing of the analogous beams and effective solving of the target condition are discussed. <p> Next, the BAA is modified to handle closed loop vibration control problems. The algorithm determines the optimal feedback gain matrix, which is then used to calculate the actuator forces required at any current state of the system. The methods accuracy is also analyzed.

feedback gain

Optimal gains

Modal space

Open loop control

Finite Elements

Actuators

Optimal vibration control

Computational mechanics

Simulation

Beam Analogy

observability

Sensors

Controllability

位相最適化と形状最適化の統合による多目的構造物の形状設計(均質化法と力法によるアプローチ)

井原, 久, Ihara, Hisashi, 下田, 昌利, Shimoda, Masatoshi, 畔上, 秀幸, Azegami, Hideyuki, 桜井, 俊明, Sakurai, Toshiaki

04 1900

No description available.

Optimum Design

Computational Mechanics

Structural Analysis

Finite-Element Method

Shape Optimization

Topology Optimization

Traction Method

Homogenization Method

Multiobjective Optimization

Multiobjective Structure

応力分布を規定した連続体の境界形状決定

下田, 昌利, Shimoda, Masatoshi, 畔上, 秀幸, Azegami, Hideyuki, 桜井, 俊明, Sakurai, Toshiaki

10 1900

No description available.

Optimum Design

Computational Mechanics

Finite-Element Method

Shape Identification

Shape Optimization

Stress Control

Traction Method

Adjoint Method

von Mises Stress

Uniform Stress

Material Derivative

ホモロガス変形を目的とする連続体の形状決定

下田, 昌利, Shimoda, Masatoshi, 畔上, 秀幸, Azegami, Hideyuki, 桜井, 俊明, Sakurai, Toshiaki

12 1900

No description available.

Optimum Design

Computational Mechanics

Finite-Element Method

Structural Analysis

Shape Identification

Shape Optimization

Homologous Deformation

Homology Design Displacement Control

Traction Method

Adjoint Variable Method

Material Derivative

ポテンシャル流れ場の領域最適化解析

片峯, 英次, Katamine, Eiji, 畔上, 秀幸, Azegami, Hideyuki

01 1900

No description available.

Optimum Design

Computer-Aided Design

Numerical Analysis

Computational Mechanics

Computational Fluid Dynamics

Finite-Element Method

Domain Optimization

Potential Flow

Inverse Problem

Traction Method

Domain Optimization Analysis in Linear Elastic Problems (Approach Using Traction Method)

AZEGAMI, Hideyuki, WU, Zhi Chang

15 April 1996

No description available.

Optimum Design

Computer-Aided Design

Numerical Analysis

Computational Mechanics

Finite-Element Method

Domain Optimization

Linear Elastic Problem

Gradient Method

Traction Method

領域最適化問題の一解法

畔上, 秀幸, Azegami, Hideyuki

06 1900

No description available.

Optimum Design

Computer-Aided Design

Numerical Analysis

Computational Mechanics

Finite-Element Method

Domain Optimization

Elliptic Boundary Value Problem

Gradient Method

Traction Method

線形弾性問題における領域最適化解析（力法によるアプローチ）

畔上, 秀幸, Azegami, Hideyuki, 呉, 志強, Wu, Zhi Chang

10 1900

No description available.

Optimum Design

Computer-Aided Design

Numerical Analysis

Computational Mechanics

Finite-Element Method

Domain Optimization

Linear Elastic Problem

Gradient Method

Traction Method