Your search keyword '"soft actuator"' showing total 17 results

1. Motion sensor-based haptic master controller with finger band soft actuator for surgical robots.

Author

Soga, Yuta, Hano, Soichiro, and Haraguchi, Daisuke

Subjects

*ROBOT hands, *MOTION capture (Human mechanics), *FINGERS, *ACTUATORS, *OPERATIVE surgery, *SURGICAL robots, *AIR pressure, *DEGREES of freedom

Abstract

This paper presents a motion sensor-based haptic master controller capable of static and dynamic force presentation by the newly invented Finger Band Soft Actuator (FBSA). The master controller operates a surgical assist robot using the $ 6 $ 6 degrees of freedom position and posture data tracked by an optical motion capture. The haptic force presentation can be realized by the pneumatic pressure of FBSA, which can be highly integrated into the controller mechanism to maintain precise manipulability. The FBSA can present a pressing force of 3.7 N for a small-sized finger and 5.1 N for a large-sized finger at an internal pressure of 60 kPa, and there is a monotonically increasing and decreasing relationship between the air pressure and the pressing force. The effectiveness of haptic force presentation by the FBSA was experimentally evaluated in the master-follower operation of a surgical assist robot. Ten subjects performed the task of pulling a suture thread and controlled the manipulation to achieve the directed tension. The experimental result shows that with the four levels of force presentation scheme by the FBSA, the error between suture tension and target operating force is significantly smaller than without force presentation. [ABSTRACT FROM AUTHOR]

Published

2024

2. Active textile: woven-cloth-like mechanisms consist of thin McKibben actuators.

Author

Hiramitsu, Tatsuhiro, Suzumori, Koichi, Nabae, Hiroyuki, and Endo, Gen

Subjects

*ARTIFICIAL muscles, *ACTUATORS, *UNIFORM spaces, *TEXTILES, *ELECTROTEXTILES

Abstract

Pneumatic artificial muscles have some advantages. Especially, the flexibility of artificial muscles contributes to compose novel mechanisms. Authors succeeded in manufacturing novel soft mechanisms that are composed of only woven artificial muscles and strings. We called this mechanism active textile. The structure is uniformed with woven artificial muscles; nevertheless, the forms and movements of mechanisms are diverse. We aim to establish a design method for these active textiles. We reported that deformations of active textiles are changed by woven structures. In addition to that, wefts' characteristics such as cross-sectional shape, bending stiffness and elasticity determine the characteristic of a textile. Deformations of active textiles are caused by the contraction and the expansion of thin McKibben muscles. In this paper, authors focus on the contraction and curvature deformation of the active textile due to the drive of the artificial muscles.We fabricated active textiles with different wefts and different weave structures.Contraction and bending deformations of active textiles in the warp and weft directions are assumed geometrically. In addition, we verified the validity by experiments. [ABSTRACT FROM AUTHOR]

Published

2023

3. Large force actuator using an electro-adhesive gel super multi-disk.

Author

Koyanagi, Ken'ichi, Takata, Yudai, Kakinuma, Yasuhiro, Anzai, Hidenobu, Sakurai, Koji, and Oshima, Toru

Subjects

*ACTUATORS, *ELECTRICITY pricing, *POWER resources, *ELECTRIC fields, *ELECTROHYDRAULIC effect

Abstract

Actuators with clutch mechanisms have advantages in safety, backdriveability, and controllability for human-coexistence robots. This paper presents a large force actuator using electro-adhesive gels, which are functional materials controlled by the magnitude of an electric field. The developed actuator can generate and continuously control a force over 560 N and resist with a small force when de-energized. The number of electro-adhesive gel disks is drastically increased to increase the generative force. This paper reports the structural plan for the new actuator and experiments to investigate its basic characteristics. Based on the experimental results, an actuator model is identified for the future design of its control system. This paper contributes to the development of a clutch-type linear actuator with a large generative force, maintaining safety and a high force-to-weight ratio. It also addresses the problem of high-voltage power supply costs for electro-rheological and electro-adhesive materials. [ABSTRACT FROM AUTHOR]

Published

2022

4. Development of a pneumatic soft actuator with pleated inflatable structures.

Author

Nishioka, Yasutaka, Uesu, Megumi, Tsuboi, Hisae, Kawamura, Sadao, Masuda, Wataru, Yasuda, Toshihiko, and Yamano, Mitsuhiro

Subjects

*PNEUMATIC actuators, *ACTUATOR design & construction, *MEDICAL robotics, *SOFT robotics, *INDUSTRIAL robots, *AIR-supported structures

Abstract

Many soft actuators have been studied for use in robots that come into contact with humans, including communication, entertainment, and medical/health care robots. One reason for this is that soft robots are expected to exhibit intrinsic safety in case an accident occurs. This paper proposes a plastic-film pneumatic actuator with a pleated structure that do not undergo the elastic deformation typical of rubber materials. By utilizing thin plastic films, the mass of an actuator can be significantly reduced, even if the actuators are the same size as a human arm. If the mass of the actuator is reduced, the kinetic energy when contacts with humans mechanically can be reduced considerably without reducing the working speed. More specifically, we propose a pleated structure made of plastic to achieve structural deformation generated from a two-dimensional pleated film. The pleated structure easily generates various bending motions. In this paper, a design method for determining the shape parameters of the pleated actuator structure using approximate models with considering measurement results of generating force is presented. We evaluated the adequacy of our approach in experiments using sample actuators. Furthermore, we show the constraints required to determine the necessary parameters. Thus, this paper provides an easy method for designing a lightweight and flexible plastic-film actuator. [ABSTRACT FROM AUTHOR]

Published

2017

5. Robot Finger Using Electro-Conjugate Fluid.

Author

Yamaguchi, Akihiro, Takemura, Kenjiro, Yokota, Shinichi, and Edamura, Kazuya

Subjects

*ROBOTS, *ELECTRODES, *ELECTRIC fields, *ACTUATORS, *PERFORMANCE evaluation, *DIAMETER

Abstract

An electro-conjugate fluid (ECF) is a kind of functional fluid, which produces a jet flow (ECF jet) when subjected to high DC voltage. It is known that a strong ECF jet is generated under a non-uniform electric field (e.g., a field with a pair of needle and ring electrodes (a needle–ring electrode pair)). This study introduces the ECF jet to develop a novel flexible robot finger. First, we propose a concept for a novel robot finger. The robot finger mainly consists of a bending actuator, an ECF tank and ECF jet generators, which could be a micro fluid pressure source of the robot finger. Second, we characterize each component of the robot finger (i.e., the bending actuator and the ECF jet generator). We investigate the influences of electrode parameters on ECF jet generator performance in order to design the finger prototype. Finally we clarify the characteristics of the robot finger. The length, the diameter and the mass of the robot finger are 34.2 mm, 12 mm and 3.8 g, respectively. The robot finger can generate a force of 0.28 N and bend approximately 70°. [ABSTRACT FROM PUBLISHER]

Published

2012

6. Miniature Pneumatic Curling Rubber Actuator Generating Bidirectional Motion with One Air-Supply Tube.

Author

Wakimoto, Shuichi, Suzumori, Koichi, and Ogura, Keiko

Subjects

*MINIATURE electronic equipment, *PNEUMATIC control, *ACTUATORS, *AIRDROP, *LIFE sciences, *MECHANICAL impedance, *NONLINEAR theories, *FINITE element method

Abstract

Soft actuators driven by pneumatic pressure are promising actuators for mechanical systems in medical, biological, agriculture, welfare fields and so on, because they can ensure high safety for fragile objects from their low mechanical impedance. In this study, a new rubber pneumatic actuator made from silicone rubber was developed. Composed of one chamber and one air-supply tube, it can generate curling motion in two directions by using positive and negative pneumatic pressure. The rubber actuator, for generating bidirectional motion, was designed to achieve an efficient shape by nonlinear finite element method analysis, and was fabricated by a molding and rubber bonding process using excimer light. The fabricated actuator was able to generate curling motion in two directions successfully. The displacement and force characteristics of the actuator were measured by using a motion capture system and a load cell. As an example application of the actuator, a robotic soft hand with three actuators was constructed and its effectiveness was confirmed by experiments. [ABSTRACT FROM AUTHOR]

Published

2011

7. Two Tendon-Driven Systems Using Pneumatic Balloons.

Author

Nagase, Jun-Ya and Saga, Norihiko

Subjects

*PNEUMATIC control, *TENDONS, *ROBOTS, *REHABILITATION, *NURSING, *MEDICAL care, *MOTOR ability, *ACTUATORS

Abstract

In recent years, Japanese society has been aging, creating a shortage of young workers. Robots are expected to be useful to perform tasks such as rehabilitation therapy, nursing elderly people and day-to-day work support for elderly people. In particular, robots that are designed for use in the fields of medical care and welfare must be safe for the human environment because they often come into contact with humans. Furthermore, robots must have dexterity that is similar to that of humans. Under these circumstances, tendon-driven systems of two types using flexible silicone rubber materials have been developed. They are lightweight and have characteristics resembling those of human muscle. This paper describes the basic features and mechanisms of two tendon-driven systems that we have developed as a soft actuator. Furthermore, basic properties of the system are evaluated and compared with those of human muscles. [ABSTRACT FROM AUTHOR]

Published

2011

8. Electro-Conjugate Fluid Jet-Driven Micro Artificial Antagonistic Muscle Actuators and their Integration.

Author

Yokota, Shinichi, Yajima, Fumiya, Takemura, Kenjiro, and Edamura, Kazuya

Subjects

*ROBOT hands, *ACTUATORS, *ELECTRODES, *AUTOMATIC control systems, *ROBOTICS

Abstract

An electro-conjugate fluid (ECF) is a type of dielectric and functional fluid that generates a powerful jet flow when subjected to high DC voltage. Although a high voltage is needed to generate the jet flow, the current is quite low at several microamperes, resulting in a total power consumption of several milliwatts. Using this smart fluid, we can develop micro fluid-driven mechanical components without any bulky pumps. Also, it is clarified that the power density of the ECF jet is higher when the electrode pair is miniaturized; therefore, it is suitable for micro actuators. Here, we propose and fabricate three types of soft actuators with an antagonistic configuration: (i) micro artificial muscle cells, (ii) a McKibben-type micro artificial muscle actuator using the ECF effect and (iii) a micro finger actuator with two chambers to bend. The actuators basically consist of a silicone rubber tube covered with a fiber sleeve and a micro pressure source using the ECF effect. Next, we apply and integrate these actuators into a micro robot hand, driven with ECF jets. The driving characteristics of the micro artificial muscle actuator and the integrated micro ECF hand with ECF fingers were fabricated and experimentally investigated. The experimental results show that this ECF jet actuation is effective for driving soft micro hands. [ABSTRACT FROM AUTHOR]

Published

2010

9. Electrorheological Gel Linear Actuator for Human-Coexistence Robots.

Author

Koyanagi, Ken'ichi, Kakinuma, Yasuhiro, Anzai, Hidenobu, and Yamaguchi, Tomoya

Subjects

*ACTUATORS, *ROBOTS, *RHEOLOGY, *ROBOTICS, *MECHATRONICS

Abstract

Robots manipulated by humans are being aggressively researched and developed. Such robots have requirements such as a large generative force, high-speed response, good controllability, high safety, low friction and backdriveability. We focused on backdriveability and created a prototype for a novel linear actuator with a new structure that includes an electrorheological (ER) gel, which is a recently designed functional material. The device is an all-purpose actuator that satisfies the demands for application in a human-coexistence welfare robot, such as power-assist systems. This paper presents the original plan for the linear actuator, shows the actuator as currently manufactured and presents the basic characteristics of the actuator as investigated experimentally. We obtained larger force from the linear actuator than the initial target. Additionally, the linear actuator shows possibilities of further improvement of the force-weight ratio by an increase of the ER gel structures. With regard to stabilizing the response of the linear actuator, spring elements contributed to its improvement. However, further stabilization remains as a future issue for practical use in human-coexistence robots. [ABSTRACT FROM AUTHOR]

Published

2010

10. Printing Fabrication of a Bucky Gel Actuator/Sensor and Its Application to Three-Dimensional Patterned Devices.

Author

Kamamichi, Norihiro, Maeba, Toshiharu, Yamakita, Masaki, and Mukai, Toshiharu

Subjects

*CONDUCTING polymers, *ACTUATORS, *PRINTING, *SOLID freeform fabrication, *MACHINE design, *ROBOTICS

Abstract

A bucky gel actuator is a novel electro-active polymer (EAP), which is a low-voltage-driven dry soft actuator. In addition, the bucky gel device generates electromotive force when bending and then it can also be used as a sensor. Its device has a bimorph structure with polymer-supported bucky gel electrodes and a polymer-supported ionic gel electrolyte. It can be fabricated by layer-by-layer casting to easily form any shape. In this paper, we demonstrate an automatic fabrication method of bucky gel devices based on a printing method. By using a dispensing machine, we construct the printing system and the manual forming process is replaced with automatic printing. We investigate the printing of complicated shapes and three-dimensional electrode patterns through experiments. [ABSTRACT FROM AUTHOR]

Published

2010

11. Integrated Design of an Ionic Polymer–Metal Composite Actuator/Sensor.

Author

Yamakita, Masaki, Sera, Akio, Kamamichi, Norihiro, and Asaka, Kinji

Subjects

*ROBOTS, *ROBOTICS, *POLYMERS, *DETECTORS, *AUTOMATIC control systems

Abstract

We are studying the robotic application of ionic polymer–metal composite (IPMC). The characteristics of IPMC greatly depend on the type of counterions, and it is considered that the performance of the actuators can be improved by combining the actuators with several types of counterions and applying an integrated control. IPMC also has a sensor function, as the IPMC film generates an electromotive force when it is deformed. It has the possibility to be integrated into an IPMC actuator with soft actuation. In this paper, we consider an integrated design of an IPMC actuator/sensor, and investigate control of the combined IPMC actuators using H∞ control and the construction of an IPMC sensor system. [ABSTRACT FROM AUTHOR]

Published

2008

12. Development of an artificial muscle linear actuator using ionic polymer–metal composites.

Author

Yamakita, Masaki, Kamamichi, Norihiro, Kaneda, Yasuaki, Asaka, Kinji, and Zhi-Wei Luo

Subjects

*ACTUATORS, *AUTOMATIC control systems, *ROBOTICS, *ROBOT control systems, *WALKING

Abstract

We are developing an artificial muscle linear actuator using ionic polymer-metal composites (IPMC)—electro-active polymers that bend in response to electric stimuli—and the goal of our study is applying the actuator to robotic applications, especially to a biped walking robot. In this paper, we will describe the structure of the actuator and an empirical model of the actuator which has two inputs and one output, and whose parameters are identified from input-output data. Based on the empirical model, basic experiments and position control of the linear actuator are demonstrated. Then, we consider walking control of a small-sized biped walking robot. In the application we assume that the developed actuators are connected both in series and in parallel to a joint of the walking robot so that the actuators supply enough torque to the robot, and that they are stretched and compressed enough. It is shown throughout simulations that the biped walking robot with the actuators can walk on level ground with a period synchronized with the period of the input signal. [ABSTRACT FROM AUTHOR]

Published

2004

13. Miniature Pneumatic Curling Rubber Actuator Generating Bidirectional Motion with One Air-Supply Tube

Author

Koichi Suzumori, Shuichi Wakimoto, and Keiko Ogura

Subjects

Materials science, Pneumatic actuator, Soft actuator, Mechanical impedance, Mechanical engineering, Rotary actuator, Linear actuator, Load cell, Computer Science Applications, Curling, Human-Computer Interaction, Mechanical system, Hardware and Architecture, Control and Systems Engineering, Control theory, pneumatic actuator, nonlinear analysis, Actuator, bidirectional motion, Software

Abstract

Soft actuators driven by pneumatic pressure are promising actuators for mechanical systems in medical, biological, agriculture, welfare fields and so on, because they can ensure high safety for fragile objects from their low mechanical impedance. In this study, a new rubber pneumatic actuator made from silicone rubber was developed. Composed of one chamber and one air-supply tube, it can generate curling motion in two directions by using positive and negative pneumatic pressure. The rubber actuator, for generating bidirectional motion, was designed to achieve an efficient shape by nonlinear finite element method analysis, and was fabricated by a molding and rubber bonding process using excimer light. The fabricated actuator was able to generate curling motion in two directions successfully. The displacement and force characteristics of the actuator were measured by using a motion capture system and a load cell. As an example application of the actuator, a robotic soft hand with three actuators was constructed and its effectiveness was confirmed by experiments.

Published

2011

14. Two Tendon-Driven Systems Using Pneumatic Balloons

Author

Norihiko Saga and Jun-ya Nagase

Subjects

Engineering, Human environment, business.industry, Soft actuator, Work support, technology, industry, and agriculture, Economic shortage, Medical care, Computer Science Applications, Human-Computer Interaction, Human muscle, Hardware and Architecture, Control and Systems Engineering, Human–computer interaction, Robot, Elderly people, business, Software, Simulation

Abstract

In recent years, Japanese society has been aging, creating a shortage of young workers. Robots are expected to be useful to perform tasks such as rehabilitation therapy, nursing elderly people and day-to-day work support for elderly people. In particular, robots that are designed for use in the fields of medical care and welfare must be safe for the human environment because they often come into contact with humans. Furthermore, robots must have dexterity that is similar to that of humans. Under these circumstances, tendon-driven systems of two types using flexible silicone rubber materials have been developed. They are lightweight and have characteristics resembling those of human muscle. This paper describes the basic features and mechanisms of two tendon-driven systems that we have developed as a soft actuator. Furthermore, basic properties of the system are evaluated and compared with those of human muscles.

Published

2011

15. Electrorheological Gel Linear Actuator for Human-Coexistence Robots

Author

Ken'ichi Koyanagi, Hidenobu Anzai, Tomoya Yamaguchi, and Yasuhiro Kakinuma

Subjects

Engineering, business.industry, Soft actuator, Mechanical engineering, Linear actuator, Low friction, Computer Science Applications, Human-Computer Interaction, Controllability, Hardware and Architecture, Control and Systems Engineering, Control theory, Robot, Actuator, business, Software

Abstract

Robots manipulated by humans are being aggressively researched and developed. Such robots have requirements such as a large generative force, high-speed response, good controllability, high safety, low friction and backdriveability. We focused on backdriveability and created a prototype for a novel linear actuator with a new structure that includes an electrorheological (ER) gel, which is a recently designed functional material. The device is an all-purpose actuator that satisfies the demands for application in a human-coexistence welfare robot, such as power-assist systems. This paper presents the original plan for the linear actuator, shows the actuator as currently manufactured and presents the basic characteristics of the actuator as investigated experimentally. We obtained larger force from the linear actuator than the initial target. Additionally, the linear actuator shows possibilities of further improvement of the force–weight ratio by an increase of the ER gel structures. With regard to stabilizi...

Published

2010

16. Integrated Design of an Ionic Polymer–Metal Composite Actuator/Sensor

Author

Norihiro Kamamichi, Kinji Asaka, Akio Sera, and Masaki Yamakita

Subjects

Sensor system, Integrated design, Materials science, Electromotive force, Soft actuator, Composite number, Mechanical engineering, Ionic bonding, Polymer metal, Computer Science Applications, Human-Computer Interaction, Hardware and Architecture, Control and Systems Engineering, Control theory, Actuator, Software

Abstract

We are studying the robotic application of ionic polymer–metal composite (IPMC). The characteristics of IPMC greatly depend on the type of counterions, and it is considered that the performance of the actuators can be improved by combining the actuators with several types of counterions and applying an integrated control. IPMC also has a sensor function, as the IPMC film generates an electromotive force when it is deformed. It has the possibility to be integrated into an IPMC actuator with soft actuation. In this paper, we consider an integrated design of an IPMC actuator/sensor, and investigate control of the combined IPMC actuators using H ∞ control and the construction of an IPMC sensor system.

Published

2008

17. A skeletal framework artificial hand actuated by pneumatic artificial muscles

Author

Isao Shimoyama and Yong Kwun Lee

Subjects

Human-Computer Interaction, Pneumatic artificial muscles, Hardware and Architecture, Control and Systems Engineering, Computer science, Soft actuator, Frame (artificial intelligence), Control engineering, Artificial muscle, Artificial hand, Software, Computer Science Applications

Abstract

Describes a method and a process for developing a soft artificial hand similar to a real human hand and its small-size soft actuator. For the soft actuator, we took a pneumatic artificial muscle and succeeded in reducing it to a diameter of 3.5 mm. The pneumatic artificial muscle allows the artificial hand not only to move softly and powerfully by pneumatic power but also works as a sensor. As a frame for the artificial hand, we used the skeleton model of human hand in order to make the hand similar to real human hand in structure as well as motion.

Published

1998