Topology optimization of compliant mechanisms with desired structural stiffness

•A new and simple BESO method is proposed for designing compliant mechanisms.•Various 2D and 3D mechanism designs with or without hinge regions are obtained.•The study reveals the formation of hinges associated with structural stiffness.•The detail recommends are given for the design of compliant me...

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Bibliographic Details
Published inEngineering structures Vol. 79; pp. 13 - 21
Main Authors Huang, X., Li, Y., Zhou, S.W., Xie, Y.M.
Format Journal Article
LanguageEnglish
Published Kidlington Elsevier Ltd 15.11.2014
Elsevier
Subjects
Applied sciences
Bi-directional evolutionary structural optimization (BESO)
Buildings. Public works
Compliant mechanisms
Computation methods. Tables. Charts
Exact sciences and technology
Mean compliance
Project management. Process of design
Stresses. Safety
Structural analysis. Stresses
Topology optimization
Topology optimization
Bi-directional evolutionary structural optimization (BESO)
Mean compliance
Compliant mechanisms
Compliant mechanism
Structural design
Topology
Algorithm
Optimization
Design
Formulation
Example
Numerical simulation
Structural analysis
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Summary:•A new and simple BESO method is proposed for designing compliant mechanisms.•Various 2D and 3D mechanism designs with or without hinge regions are obtained.•The study reveals the formation of hinges associated with structural stiffness.•The detail recommends are given for the design of compliant mechanisms. This paper develops a bi-directional evolutionary structural optimization (BESO) method for topological design of compliant mechanisms. The design problem is reformulated as maximizing the flexibility of the compliant mechanism subject to the mean compliance and volume constraints. Based on the finite element analysis, a new BESO algorithm is established for solving such an optimization problem by gradually updating design variables until a convergent solution is obtained. Several 2D and 3D examples are presented to demonstrate the effectiveness of the proposed BESO method. A series of optimized mechanism designs with or without hinge regions are obtained. Numerical results also indicate that the flexibility and hinge-related property of the optimized compliant mechanisms can be controlled by the desired structural stiffness.
ISSN:0141-0296
1873-7323
DOI:10.1016/j.engstruct.2014.08.008