Internal Liquid Metal Channels to Enable High Power Additively Manufactured SMA Actuators

Jacob Mingear, Brady K. Allen, Jessica J. Zamarripa, D. Hartl
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引用次数: 1

Abstract

Shape memory alloys are capable of producing some of the highest actuation stresses (~300 MPa) of any active material. However, large monolithic SMA actuators, which can induce the tremendous forces required in some applications, are currently limited to low cyclic actuation frequencies due to their associated high thermal masses coupled with innate low thermal diffusivities of the material. An increase in the effective thermal diffusivity of an SMA actuator system will result in an increase in actuation frequency; accordingly, this would lead to the ability to perform more cycles over a given time interval and subsequently yield an overall higher actuator power density (energy density with time). This current work presents ongoing research in the design, manufacturing, enabling surface engineering (such as chemical etching and anodization), and testing of internal channel additively manufactured SMA actuator designs, including a tensile bar variation and planned testing of an optimized cantilever beam.
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内部液态金属通道实现高功率增材制造SMA致动器
形状记忆合金能够产生任何活性材料中最高的一些驱动应力(~ 300mpa)。然而,大型单片SMA致动器在某些应用中可以产生所需的巨大力,由于其相关的高热质量加上材料固有的低热扩散率,目前仅限于低循环致动频率。SMA致动器系统有效热扩散系数的增加会导致致动频率的增加;因此,这将导致能够在给定的时间间隔内执行更多的循环,随后产生更高的执行器功率密度(随时间的能量密度)。目前的工作展示了正在进行的设计、制造、表面工程(如化学蚀刻和阳极氧化)和内部通道增材制造SMA致动器设计测试方面的研究,包括拉伸杆的变化和优化悬臂梁的计划测试。
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