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Evolutionary Topology Optimization of Continuum Structures. Methods and Applications. Edition No. 1

  • ID: 2171170
  • Book
  • March 2010
  • 240 Pages
  • John Wiley and Sons Ltd
Evolutionary Topology Optimization of Continuum Structures treads new ground with a comprehensive study on the techniques and applications of evolutionary structural optimization (ESO) and its later version bi-directional ESO (BESO) methods. Since the ESO method was first introduced by Xie and Steven in 1992 and the publication of their well-known book Evolutionary Structural Optimization in 1997, there have been significant improvements in the techniques as well as important practical applications. The authors present these developments, illustrated by numerous interesting and detailed examples. They clearly demonstrate that the evolutionary structural optimization method is an effective approach capable of solving a wide range of topology optimization problems, including structures with geometrical and material nonlinearities, energy absorbing devices, periodical structures, bridges and buildings.

Evolutionary Topology Optimization of Continuum Structures will appeal to researchers and graduate students working in structural design and optimization, and will also be of interest to civil and structural engineers, architects and mechanical engineers involved in creating innovative and efficient structures.
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1 Introduction

1.1 Structural Optimization

1.2 Topology Optimization of Continuum Structures

1.3 ESO/BESO and the Layout of the Book


2 Evolutionary Structural Optimization Method

2.1 Introduction

2.2 ESO Based on Stress Level

2.3 ESO for Stiffness or Displacement Optimization

2.4 Conclusion


3 Bi-directional Evolutionary Structural Optimization Method

3.1 Introduction

3.2 Problem Statement and Sensitivity Number

3.3 Filter Scheme and Improved Sensitivity Number

3.4 Element Removal/Addition and Convergence Criterion

3.5 Basic BESO Procedure

3.6 Examples of BESO Starting from Initial Full Design

3.7 Examples of BESO Starting from Initial Guess Design

3.8 Example of a 3D Structure

3.9 Mesh-independence Studies

3.10 Conclusion


4 BESO Utilizing Material Interpolation Scheme with Penalization

4.1 Introduction

4.2 Problem Statement and Material Interpolation Scheme

4.3 Sensitivity Analysis and Sensitivity Number

4.4 Examples

4.5 Conclusion


Appendix 4.1

5 Comparing BESO with Other Topology Optimization Methods

5.1 Introduction

5.2 The SIMP Method

5.3 Comparing BESO with SIMP

5.4 Discussion on Zhou and Rozvany (2001) Example

5.5 Conclusion


6 BESO for Extended Topology Optimization Problems

6.1 Introduction

6.2 Minimizing Structural Volume with a Displacement or Compliance Constraint

6.3 Stiffness Optimization with an Additional Displacement Constraint

6.4 Stiffness Optimization of Structures with Multiple Materials

6.5 Topology Optimization of Periodic Structures

6.6 Topology Optimization of Structures with Design-dependent Gravity Load

6.7 Topology Optimization for Natural Frequency

6.8 Topology Optimization for Multiple Load Cases

6.9 BESO Based on von Mises Stress

6.10 Conclusion


7 Topology Optimization of Nonlinear Continuum Structures

7.1 Introduction

7.2 Objective Functions and Nonlinear Analysis

7.3 Sensitivity Analysis and Sensitivity Number for Force Control

7.4 Sensitivity Analysis and Sensitivity Number for Displacement Control

7.5 BESO Procedure for Nonlinear Structures

7.6 Examples of Nonlinear Structures under Force Control

7.7 Examples of Nonlinear Structures under Displacement Control

7.8 Conclusion


8 Optimal Design of Energy Absorption Structures

8.1 Introduction

8.2 Problem Statement for Optimization of Energy Absorption Structures

8.3 Sensitivity Number

8.4 Evolutionary Procedure for Removing and Adding Material

8.5 Numerical Examples and Discussions

8.6 Conclusion


9 Practical Applications

9.1 Introduction

9.2 Akutagwa River Side Project in Japan

9.3 Florence New Station Project in Italy

9.4 Sagrada Familia Church in Spain

9.5 Pedestrian Bridge Project in Australia

9.6 Conclusion


10 Computer Program BESO2D

10.1 Introduction

10.2 System Requirements and Program Installation

10.3 Windows Interface of BESO2D

10.4 Running BESO2D from Graphic User Interface

10.5 The Command Line Usage of BESO2D

10.6 Running BESO2D from the Command Line

10.7 Files Produced by BESO2D

10.8 Error messages


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Xiaodong Huang RMIT University.

Mike Xie RMIT University, Australia.
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