Palm-top jumping and crawling robot using snap-through buckling of arched elastica supported by &amp;#x2126;-shaped frame

Fukamachi, Naofumi; Mochiyama, Hiromi

doi:10.1109/aim.2015.7222687

Cited by 7 publications

(3 citation statements)

References 15 publications

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“…In order to generate such instantaneous power, a soft material such as a spring is required rather than a hard actuator such as a motor. In our laboratory, we have developed a number of instantaneous force generating mechanisms and applications that focus on snap-through buckling of elastic strip [2], [11]- [16]. The instantaneous force generation mechanism using buckling of a flexible material functions well as a jumping mechanism [2], [11]- [13], [16].…”

Section: Literature Reviewmentioning

confidence: 99%

“…In our laboratory, we have developed a number of instantaneous force generating mechanisms and applications that focus on snap-through buckling of elastic strip [2], [11]- [16]. The instantaneous force generation mechanism using buckling of a flexible material functions well as a jumping mechanism [2], [11]- [13], [16]. This jumping mechanism has a characteristic that the repetition cycle is particularly fast (at least 1.5 Hz).…”

Section: Literature Reviewmentioning

confidence: 99%

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Hopping Robot

2023

IRJMETS

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While exploring complex environments, conventional mobile robots can overcome obstacles of limited height and jumping robots can overcome obstacles several times their own size. When jumping motion and wheeled or tracked motion are combined to form a composite motion, robots have even better ability to traverse rugged terrain. This project aims to design and build a small-scale robot inspired by the froghopper, a jumping insect that can leap up to half a meter. The robot will be capable of vertical jumping using a spring actuation system, and will be controlled using a microcontroller. Our studies will show that the robot will have a significant jumping advantage in terms of energy efficiency, and we will present our findings in this review. However, the project will not be without challenges, and we will discuss some of the design and fabrication challenges we anticipate encountering, as well as ideas for future work to improve the robot or expand upon our findings.

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Section: Literature Reviewmentioning

confidence: 99%

Section: Literature Reviewmentioning

confidence: 99%

Hopping Robot

2023

IRJMETS

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“…When the motor rotates, the tendon-like wire pulls the bottom part of the leg and thus stores elastic energy in the torsional springs. Snapthrough buckling is a strategy sometimes used to generate the reaction force for jumping robots [15,16]. However, most of these jumping robots are actuated with DC motors and composed of a relatively large number of rigid components.…”

Section: Introductionmentioning

confidence: 99%

Miniature soft jumping robots made by additive manufacturing

Tsai,

Wang,

Wang

et al. 2023

Smart Mater. Struct.

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Fleets of insect-scale robots could navigate space-constrained environments for future applications in agriculture and maintenance. Long distance jumping expands the mobility of small robots. However, the performance of miniature jumpers is hindered by small-scale manufacturing processes and the limited library of design rules, materials, and actuators available at that scale. The intricate components in these robots are produced by manual assembly of miniature components, which imposes design constraints and causes mass inefficiency, reducing the overall system performance. Here, we combine bioinspired kinematic design, coiled artificial muscle actuators, and projection additive manufacturing (AM) to produce a monolithic elastomeric robot design. The fully elastomeric design, inspired by the kinematics of the locust jumping mechanism, can store elastic energy throughout the robot body before releasing it in the form of jumping kinetic energy, thus offering high energy storage density, miniaturization, and lightweight. Enabled by high-speed, production-grade AM, we designed and tested a fleet of 108 robot designs. The smallest tested robot has a length of 7.5 mm, a mass of 0.216 g, and jumps 60 times its body size in horizontal distance. A reduced-order model is developed to predict the compliant robot jumping distance, which agrees well with the experimental results. The jumping is driven by onboard coiled artificial muscles connected to a latch-triggering mechanism. Moreover, the robot can jump while carrying an integrated control system and power source to enable self-triggered jumping. A proof-of-concept motor-driven launch base is used to store large elastic energy in the robot. Overall, the combination of elastomeric AM, coiled artificial muscles, and an integrated triggering mechanism enables the production of fleets of high-performing miniature jumping robots.

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Aerial Attitude Control of Hopping Robots Using Reaction Wheels: Evaluation of Prototype II in the Air

Nomura

Ishikawa

2017

Lecture Notes in Electrical Engineering

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Palm-top jumping and crawling robot using snap-through buckling of arched elastica supported by Ω-shaped frame

Cited by 7 publications

References 15 publications

Hopping Robot

Hopping Robot

Miniature soft jumping robots made by additive manufacturing

Aerial Attitude Control of Hopping Robots Using Reaction Wheels: Evaluation of Prototype II in the Air

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