Sonja S. Sparks, Alejandro G. Obando, Yizong Li, Si Chen, Shanshan Yao, Kaiyan Qiu
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引用次数: 0
摘要
科学研究的一个主要目的是复制在自然空间中观察到的行为。在机器人学中,这可以通过设备中的生物仿生运动和从自然界的各种行为中获得灵感来实现,这也被称为生物启发功能。实现这两种功能的一个有趣途径是制造软致动器。具体来说,三维打印技术已被视为开发仿生物和生物启发软致动器的一种潜在方法。从蕨类植物的运动到器官的收缩,大量的应用和技术被用来制造这些设备,从而凸显了这种方法的广泛性。本综述将深入讨论不同的 3D 打印制造方法、材料、软致动器类型及其各自的应用。最后,还讨论了它们在当前操作中的应用范围以及未来的技术进步。
3D-printed biomimetic and bioinspired soft actuators
A major intent of scientific research is the replication of the behaviour observed in natural spaces. In robotics, these can be through biomimetic movements in devices and inspiration from diverse actions in nature, also known as bioinspired features. An interesting pathway enabling both features is the fabrication of soft actuators. Specifically, 3D-printing has been explored as a potential approach for the development of biomimetic and bioinspired soft actuators. The extent of this method is highlighted through the large array of applications and techniques used to create these devices, as applications from the movement of fern trees to contraction in organs are explored. In this review, different 3D-printing fabrication methods, materials, and types of soft actuators, and their respective applications are discussed in depth. Finally, the extent of their use for present operations and future technological advances are discussed.
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