Concurrent multiscale and multi‐material optimization method for natural vibration design of porous structures

Shimoda, Masatoshi; Fujita, Junpei; Al Ali, Musaddiq; Kamiya, Ayu

doi:10.1002/nme.7424

Cited by 2 publications

(1 citation statement)

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“…Tackling these obstacles has catalyzed continual research endeavors aimed at investigating novel design methodologies and harnessing sophisticated modeling and simulation techniques to augment the efficiency and dependability of compliant mechanisms in high-precision contexts. Within this realm of innovative design methodologies, topology optimization emerges as a prominent solution [10][11][12]. Topology optimization is a robust strategy for creating compliant mechanisms, characterized by its ability to systematically and efficiently navigate vast design possibilities.…”

Section: Introductionmentioning

confidence: 99%

Laser-Activated Lightweight Porous Linear Actuation Micro Mechanisms through Multiscale Topology Optimization with Considering Radiation

Ali,

Shimoda

2024

Preprint

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This study applies multi-physics concurrent multiscale topology optimization to develop a lightweight porous linear actuation mechanism activated by laser energy. It meticulously explores thermal dissipation mechanisms, incorporating conduction, convection, and radiation dynamics. By examining various numerical cases, the study reveals a substantial 45% performance improvement in porous designs compared to solid actuators. The investigation extends to simultaneous optimization of multiscale porous displacement actuators, achieving a remarkable 75% weight reduction and demonstrating significant performance enhancements over single-scale designs. The increased freedom in micro-scale design allows more efficient material distribution, optimizing both macro and overall layouts. Sequential optimization of macro and micro-scale actuators is contrasted with concurrent multiscale optimization, showing inferior performance for separate optimizations. The study also delves into topology optimization under energy dissipation, focusing on multiple-rate thermal convection and revealing adaptive design behaviors in response to thermal stresses. Macro-scale designs influenced by convection exhibit perpendicular links and adaptive microstructures to enhance resilience and elasticity. The investigation also includes thermal radiation and convection, highlighting intricate design considerations for effective thermal dissipation. Ultimately, this study advances the understanding of multiscale effects in topology optimization, paving the way for more efficient and lightweight laser-activated porous actuators.

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Section: Introductionmentioning

confidence: 99%