Your search keyword '"ionic polymer metal composite (IPMC) actuators"' showing total 7 results

1. A Multifunctional Underwater Biomimetic Microrobot

Author

Guo, Shuxiang, Shi, Liwei, Du, Ruxu, editor, Li, Zheng, editor, Youcef-Toumi, Kamal, editor, and Valdivia y Alvarado, Pablo, editor

Published

2015

2. Structural modeling of actuation of IPMC in dry environment: effect of water content and activity.

Author

Swarrup, J. Sakthi, Ranjan, Ganguli, and Giridhar, Madras

Subjects

ACTUATORS, MICRO air vehicles, CONDUCTING polymers, FLEXURAL strength, CATIONS, STIFFNESS (Mechanics)

Abstract

Structural modeling of unencapsulated ionic polymer metal composite (u-IPMC) actuators that are used for flapping the insect scale-flapping wing of micro air vehicles (FMAV) in dry environmental conditions is carried out. Structural modeling for optimization of design parameters for retention of water, maximize actuation performance and to study the influence of water activity on the actuation characteristics of u-IPMC is explored for use in FMAV. The influence of equivalent weight of Nation polymer, cations, concentration of cations, pre-treatment procedures on retention of water of u-IPMCs and on actuation parameters, flapping angle, flexural stiffness and actuation displacement are investigated. IPMC designed with Nation having equivalent weight 900-1100, pre-heated at 30°C and with sodium as the cations is promising for optimum retention of water and actuation performance. The actuation parameters while in operation in dry and humid environment with varying water activity can be tuned to desirable frequency, deflection, flap angle and flexural stiffness by changing the water activity and operational temperature of the environment. [ABSTRACT FROM AUTHOR]

Published

2017

3. A Novel Soft Biomimetic Microrobot with Two Motion Attitudes

Author

Liwei Shi, Shuxiang Guo, Maoxun Li, Shilian Mao, Nan Xiao, Baofeng Gao, Zhibin Song, and Kinji Asaka

Subjects

ionic polymer metal composite (IPMC) actuators, biomimetic underwater microrobot, motion attitudes, micromechanism, shape memory alloy (SMA) actuators, Chemical technology, TP1-1185

Abstract

A variety of microrobots have commonly been used in the fields of biomedical engineering and underwater operations during the last few years. Thanks to their compact structure, low driving power, and simple control systems, microrobots can complete a variety of underwater tasks, even in limited spaces. To accomplish our objectives, we previously designed several bio-inspired underwater microrobots with compact structure, flexibility, and multi-functionality, using ionic polymer metal composite (IPMC) actuators. To implement high-position precision for IPMC legs, in the present research, we proposed an electromechanical model of an IPMC actuator and analysed the deformation and actuating force of an equivalent IPMC cantilever beam, which could be used to design biomimetic legs, fingers, or fins for an underwater microrobot. We then evaluated the tip displacement of an IPMC actuator experimentally. The experimental deflections fit the theoretical values very well when the driving frequency was larger than 1 Hz. To realise the necessary multi-functionality for adapting to complex underwater environments, we introduced a walking biomimetic microrobot with two kinds of motion attitudes: a lying state and a standing state. The microrobot uses eleven IPMC actuators to move and two shape memory alloy (SMA) actuators to change its motion attitude. In the lying state, the microrobot implements stick-insect-inspired walking/rotating motion, fish-like swimming motion, horizontal grasping motion, and floating motion. In the standing state, it implements inchworm-inspired crawling motion in two horizontal directions and grasping motion in the vertical direction. We constructed a prototype of this biomimetic microrobot and evaluated its walking, rotating, and floating speeds experimentally. The experimental results indicated that the robot could attain a maximum walking speed of 3.6 mm/s, a maximum rotational speed of 9°/s, and a maximum floating speed of 7.14 mm/s. Obstacle-avoidance and swimming experiments were also carried out to demonstrate its multi-functionality.

Published

2012

4. Development of a Lobster-Inspired Underwater Microrobot.

Author

Liwei Shi, Shuxiang Guo, Shilian Mao, Maoxun Li, and Kinji Asaka

Subjects

CONDUCTING polymers, REMOTE submersibles, PROTOTYPES, ROBOT design & construction, ACTUATORS, ROBOT control systems

Abstract

Biomimetic underwater microrobots are of great interest for underwater monitoring operations, such as pollution detection and video mapping in restricted underwater environments. Generally speaking, compact structure, multi-functionality, flexibility and precise positioning are considered incompatible characteristics for underwater microrobots. Nevertheless, we have designed several novel types of bio-inspired locomotion, using ionic polymer metal composite (IPMC) and shape memory alloy (SMA) actuators. We reviewed a number of previously developed underwater microrobot prototypes that were constructed to demonstrate the feasibility of these types of biomimetic locomotion. Based on these prototypes, we summarized the implemented techniques and available results for efficient and precise underwater locomotion. In order to combine compact structure, multi-functionality, flexibility and precise positioning, we constructed a prototype of a new lobster-like microrobot and carried out a series of experiments to evaluate its walking, rotating, floating and grasping motions. Diving/surfacing experiments were performed by electrolyzing the water around the surfaces of the actuators. Three proximity sensors were installed on the microrobot to detect an object or avoid an obstacle while walking. [ABSTRACT FROM AUTHOR]

Published

2013

5. A biomimetic underwater microrobot with multifunctional locomotion

Author

Guo, Shuxiang, Shi, Liwei, Xiao, Nan, and Asaka, Kinji

Subjects

*BIOMIMETIC chemicals, *MICROROBOTS, *PROXIMITY detectors, *PERFORMANCE evaluation, *ADDITION polymerization, *ACTUATORS

Abstract

Abstract: Underwater microrobots are in urgent demand for applications such as pollution detection and video mapping in limited space. Compact structure, multi-functionality, and flexibility are normally considered incompatible characteristics for underwater microrobots. Nevertheless, to accomplish our objectives, we designed a novel inchworm-inspired biomimetic locomotion prototype with ionic polymer metal composite (IPMC) actuators, and conducted experiments to evaluate its crawling speed on a flat underwater surface. Based on this type of biomimetic locomotion, we introduced a new type of underwater microrobot, using ten IPMC actuators as legs or fingers to implement walking, rotating, floating, and grasping motions. We analysed the walking mechanism of the microrobot and calculated its theoretical walking speed. We then constructed a prototype of the microrobot, and carried out a series of experiments to evaluate its walking and floating speeds. Diving/surfacing experiments were also performed by electrolysing the water around the surfaces of the actuators. The microrobot used six of its actuators to grasp small objects while walking or floating. To implement closed-loop control, we employed three proximity sensors on the microrobot to detect an object or avoid an obstacle while walking. [Copyright &y& Elsevier]

Published

2012

6. A Camera Based Method for the Measurement of Motion Parameters of IPMC Actuators.

Author

Tsiakmakis, Kyriakos, Brufau-Penella, Jordi, Puig-Vidal, Manel, and Laopoulos, Theodore

Subjects

*ACTUATORS, *METALLIC composites, *CHEMICAL structure, *MICROELECTROMECHANICAL systems, *BIOELECTRONICS

Abstract

A visual measurement technique that is specifically developed to monitor the movements of ionic polymer metal composite (IPMC) materials in underwater conditions is presented. The proposed method is based on the extraction of appropriate information about the movement of an IPMC strip from subsequent picture frames. Since the time difference between these pictures is known, the system calculates both, the displacement and the speed of the moving part. The processing algorithm implements a fully automated procedure for the localization of the point of interest (i.e., the edge of a microrobotic wing) and calculates the distance (displacement) between subsequent frames. This method is particularly useful for rather large and slow movements Of the IPMC strips, as found in underwater microrobotic applications. The experimental results are compared with concurrent reference measurements by a high-accuracy laser-positioning system. A setup based on a low-cost camera offers a resolution of 0.5 mm or better, which is quite good for the specific application. [ABSTRACT FROM AUTHOR]

Published

2009

7. A novel soft biomimetic microrobot with two motion attitudes

Author

Kinji Asaka, Baofeng Gao, Maoxun Li, Shuxiang Guo, Liwei Shi, Nan Xiao, Zhibin Song, and Shilian Mao

Subjects

Engineering, Cantilever, shape memory alloy (SMA) actuators, Polymers, Mechanical engineering, lcsh:Chemical technology, Biochemistry, Displacement (vector), Article, Analytical Chemistry, ionic polymer metal composite (IPMC) actuators, biomimetic underwater microrobot, motion attitudes, micromechanism, Motion, Biomimetics, Alloys, Animals, lcsh:TP1-1185, Electrical and Electronic Engineering, Underwater, Instrumentation, business.industry, Robotics, Rotational speed, Extremities, Equipment Design, Atomic and Molecular Physics, and Optics, Control system, Computer-Aided Design, Artificial intelligence, Actuator, business

Abstract

A variety of microrobots have commonly been used in the fields of biomedical engineering and underwater operations during the last few years. Thanks to their compact structure, low driving power, and simple control systems, microrobots can complete a variety of underwater tasks, even in limited spaces. To accomplish our objectives, we previously designed several bio-inspired underwater microrobots with compact structure, flexibility, and multi-functionality, using ionic polymer metal composite (IPMC) actuators. To implement high-position precision for IPMC legs, in the present research, we proposed an electromechanical model of an IPMC actuator and analysed the deformation and actuating force of an equivalent IPMC cantilever beam, which could be used to design biomimetic legs, fingers, or fins for an underwater microrobot. We then evaluated the tip displacement of an IPMC actuator experimentally. The experimental deflections fit the theoretical values very well when the driving frequency was larger than 1 Hz. To realise the necessary multi-functionality for adapting to complex underwater environments, we introduced a walking biomimetic microrobot with two kinds of motion attitudes: a lying state and a standing state. The microrobot uses eleven IPMC actuators to move and two shape memory alloy (SMA) actuators to change its motion attitude. In the lying state, the microrobot implements stick-insect-inspired walking/rotating motion, fish-like swimming motion, horizontal grasping motion, and floating motion. In the standing state, it implements inchworm-inspired crawling motion in two horizontal directions and grasping motion in the vertical direction. We constructed a prototype of this biomimetic microrobot and evaluated its walking, rotating, and floating speeds experimentally. The experimental results indicated that the robot could attain a maximum walking speed of 3.6 mm/s, a maximum rotational speed of 9°/s, and a maximum floating speed of 7.14 mm/s. Obstacle-avoidance and swimming experiments were also carried out to demonstrate its multi-functionality.

Published

2012