双稳态
材料科学
咬合
能量(信号处理)
能量密度
纳米技术
光电子学
工程物理
计算机科学
数学
统计
计算机图形学(图像)
工程类
作者
Haohang Li,Zhixin Su,Zhixiang Rao,Ying Yang,Helong Liu,Yao Xiao,Jie Chen,Shuke Huang,Lishan Cui,Shiyu Hao
标识
DOI:10.1002/adfm.202514272
摘要
Abstract Traditional bistable actuators triggered by external mechanical load generally exhibit low energy density, severely restricting their applications in autonomous systems. This study presents a novel integration of thermally induced phase transformation in shape memory alloys (SMAs) with the rapid deformation mechanisms of bistable structures, creating an intelligent bistable actuator. It is self‐triggered via thermal activation, without the need for an external mechanical actuator to initiate snap‐through, exhibiting high energy density. The synergy of thermally induced martensitic reverse transformation and structural constraints allows the actuator to achieve a volumetric energy density of 1.19 × 10⁴ J m − 3 , surpassing the highest reported values for bistable actuators. By controlling local strain distribution and martensite orientation through geometric parameters ( t/l , h/l ), the actuator is able to launch a payload with a mass of 1176 times that of the actuating element, achieving a jumping height of 265 mm (30 times its own height), with a snap‐through response completed in 4 ms. Extended structural designs enable multimodal actuation capabilities, including horizontal catapulting, torque‐driven rotation, and temperature‐programmed multi‐step grab‐and‐jump operations. The proposed material–structure synergistic design paradigm advances the development of programmable thermally triggered actuation systems with high energy density, demonstrating potential for applications in robotics, micro‐automation systems, and smart actuators.
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