Topology Optimization of Compliant Mechanisms [electronic resource] / by Xianmin Zhang, Benliang Zhu.
By: Zhang, Xianmin [author.]
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Contributor(s): Zhu, Benliang [author.]
| SpringerLink (Online service)
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Background -- Topology Optimization of Flexure Hinges -- Topology Optimization of Distributed Compliant Mechanisms -- Topology Optimization of Compliant Parallel Mechanisms -- Extensions -- Appendices.
This book covers various topics regarding the design of compliant mechanisms using topology optimization that have attracted a great deal of attention in recent decades. After comprehensively describing state-of-the-art methods for designing compliant mechanisms, it provides a new topology optimization method for finding new flexure hinges. It then presents several attempts to obtain distributed compliant mechanisms using the topology optimization method. Further, it discusses a Jacobian-based topology optimization method for compliant parallel mechanisms, and introduces readers to the topology optimization of compliant mechanisms, taking into account geometrical nonlinearity and reliability. Providing a systematic method for topology optimization of flexure hinges, which are essential for designing compliant mechanisms, the book offers a valuable resource for all readers who are interested in designing compliant mechanism-based positioning stages. In addition, the methods for solving the de facto hinges in topology optimized compliant mechanisms will benefit all engineers seeking to design micro-electro-mechanical system (MEMS) structures.
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