Sage Journals: Discover world-class research

Abstract

To realize walking and working in complex terrain or narrow space, a small legged robot with a mass of 5.6 g and a size of 70 mm × 60 mm × 30 mm is proposed. Piezoelectric and shape memory alloy actuators are combined for fast response and high flexibility. Six piezoelectric bimorphs serving as driving legs realize fast linear and turning motions in the forward and backward directions. Four shape memory alloy springs are excited for raising and dropping different legs to generate multiple motion modes. A dynamic model is built to guarantee the lifting motions of the designated legs. The experimental results show that it achieves linear moving and turning speeds as fast as 24.8 and 16.5 cm/s, respectively, whereas its startup time is only 0.1 s. Moreover, this robot lifts different legs up to 1 cm high with response time of 6, 8, and 6 s under the current of 1.5 A, respectively, which can recover to initial status. Hence, this robot is capable of fulfilling manipulation tasks, such as terrain detection, material transportation, obstacle crossing, and object capturing, thanks to the characteristics of small size, simple structure, good flexibility, and multi-functional locomotion.

Keywords

Piezoelectric actuator shape memory alloy miniature robot legged locomotion multiple motion modes

Get full access to this article

View all access options for this article.

References

Canh

Hoa

Phi

, et al. (2018) Development of an insect-inspired hexapod robot actuated by soft actuators. Journal of Mechanisms and Robotics 10: 0610166.

Chan

Liu

(2016) Towards a walking, turning, and jumping quadruped robot with compliant mechanisms. In: IEEE international conference on advanced intelligent mechatronics, Banff, AB, Canada, 12–15 July, pp. 614–620. New York: IEEE.

DeMario

Zhao

(2018) Development and analysis of a three-dimensional printed miniature walking robot with soft joints and links. Journal of Mechanisms and Robotics 10: 041005.

Doroftei

Adăscălitei

(2012) A hexapod walking micro-robot with compliant legs. Applied Mechanics and Materials 162: 234–241.

Goldberg

Zufferey

Doshi

, et al. (2018) Power and control autonomy for high-speed locomotion with an insect-scale legged robot. IEEE Robotics and Automation Letters 3: 987–993.

Hariri

Soh

Foong

, et al. (2017) Locomotion study of a standing wave driven piezoelectric miniature robot for bi-directional motion. IEEE Transactions on Robotics 33: 742–747.

Hoover

Steltz

Fearing

(2008) RoACH: an autonomous 2.4g crawling hexapod robot. In: IEEE/RSJ international conference on intelligent robots and systems, Nice, 22–26 September, pp. 26–33. New York: IEEE.

Jin

Dong

, et al. (2016) Soft and smart modular structures actuated by shape memory alloy (SMA) wires as tentacles of soft robots. Smart Materials and Structures 25: 85026.

Kim

Park

J-O

(2009) Microrobots for a capsule endoscope. In: IEEE/ASME international conference on advanced intelligent mechatronics, Singapore, 14–17 July, pp. 729–734. New York: IEEE.

10.

Kim

Jung

Kim

, et al. (2014) Wheel transformer: a wheel-leg hybrid robot with passive transformable wheels. IEEE Transactions on Robotics 30: 1487–1498.

11.

Mao

Dong

Jin

, et al. (2014) Gait study and pattern generation of a starfish-like soft robot with flexible rays actuated by SMAs. Journal of Bionic Engineering 11: 400–411.

12.

Rios

Fleming

Yong

(2017) Miniature resonant ambulatory robot. IEEE Robotics and Automation Letters 2: 337–343.

13.

Rios

Fleming

Yong

(2018) Monolithic piezoelectric insect with resonance walking. IEEE/ASME Transactions on Mechatronics 23: 524–530.

14.

Rodrigue

Wang

Han

, et al. (2017) An overview of shape memory alloy-coupled actuators and robots. Soft Robotics 4: 3–15.

15.

Rus

Tolley

(2015) Design, fabrication and control of soft robots. Nature 521: 467–475.

16.

Semini

Barasuol

Goldsmith

, et al. (2017) Design of the hydraulically actuated, torque-controlled quadruped robot HyQ2Max. IEEE-ASME Transactions on Mechatronics 22: 635–646.

17.

Shen

(2008) Study of RAINBOW actuator and its integration with SMA. Journal of Intelligent Material Systems and Structures 19: 277–281.

18.

Smits

Ballato

(1994) Dynamic admittance matrix of piezoelectric cantilever bimorphs. Journal of Microelectromechanical Systems 3: 105–112.

19.

Spröwitz

Tuleu

Vespignani

, et al. (2013) Towards dynamic trot gait locomotion: design, control, and experiments with Cheetah-cub, a compliant quadruped robot. The International Journal of Robotics Research 32: 932–950.

20.

Sun

Zhao

(2019) An adaptive walking robot with reconfigurable mechanisms using shape morphing joints. IEEE Robotics and Automation Letters 4: 724–731.

21.

Yan

Zhang

Qin

, et al. (2006) A 3-DOFs mobile robot driven by a piezoelectric actuator. Smart Materials and Structures 15: N7–N13.

22.

Zhong

Wang

Feng

, et al. (2019) Analysis and research of quadruped robot’s legs: a comprehensive review. International Journal of Advanced Robotic Systems 16. DOI: 10.1177/1729881419844148.

23.

Zhou

Zhang

Cao

, et al. (2019) Fabrication and modeling of dielectric elastomer soft actuator with 3D printed thermoplastic frame. Sensors and Actuators A: Physical 292: 112–120.

24.

Zhu

Fei

(2018) Stability analysis of a wheel-track-leg hybrid mobile robot. Journal of Intelligent & Robotic Systems 91: 515–528.