Flytrap-inspired robot using structurally integrated actuation based on bistability and a developable surface

• Published in: Bioinspiration & biomimetics Vol. 9; no. 3; p. 036004
• Main Authors: Kim, Seung-Won, Koh, Je-Sung, Lee, Jong-Gu, Ryu, Junghyun, Cho, Maenghyo, Cho, Kyu-Jin
• Format: Journal Article
• Language: English
• Published: England IOP Publishing 01.09.2014
• Subjects: Actuation; Actuators; Bending; bioinspiration; Biomimetics - instrumentation; Biomimetics - methods; Bistability; Droseraceae - anatomy & histology; Droseraceae - chemistry; Droseraceae - physiology; Elastic Modulus; Equipment Design; Equipment Failure Analysis; flytrap; Mathematical analysis; Morphing; Motion; Plant Leaves - anatomy & histology; Plant Leaves - chemistry; Plant Leaves - physiology; Robotics - instrumentation; Robots; Shape memory alloys; soft robotics; structurally integrated actuation; Surface Properties; Systems Integration; Transducers
• ISSN: 1748-3182; 1748-3190
• DOI: 10.1088/1748-3182/9/3/036004

The Venus flytrap uses bistability, the structural characteristic of its leaf, to actuate the leaf's rapid closing motion for catching its prey. This paper presents a flytrap-inspired robot and novel actuation mechanism that exploits the structural characteristics of this structure and a developable surface. We focus on the concept of exploiting structural characteristics for actuation. Using shape memory alloy (SMA), the robot actuates artificial leaves made from asymmetrically laminated carbon fiber reinforced prepregs. We exploit two distinct structural characteristics of the leaves. First, the bistability acts as an implicit actuator enabling rapid morphing motion. Second, the developable surface has a kinematic constraint that constrains the curvature of the artificial leaf. Due to this constraint, the curved artificial leaf can be unbent by bending the straight edge orthogonal to the curve. The bending propagates from one edge to the entire surface and eventually generates an overall shape change. The curvature change of the artificial leaf is 18 m−1 within 100 ms when closing. Experiments show that these actuation mechanisms facilitate the generation of a rapid and large morphing motion of the flytrap robot by one-way actuation of the SMA actuators at a local position.