Your search keyword '"soft actuator"' showing total 1,344 results

1. Design of a Soft Exoskeleton with Motion Perception Network for Hand Function Rehabilitation

Author

Li, Xiaodong, Duanmu, Dehao, Wang, Junlin, Hu, Yong, Magjarević, Ratko, Series Editor, Ładyżyński, Piotr, Associate Editor, Ibrahim, Fatimah, Associate Editor, Lackovic, Igor, Associate Editor, Rock, Emilio Sacristan, Associate Editor, Wang, Guangzhi, editor, Yao, Dezhong, editor, Gu, Zhongze, editor, Peng, Yi, editor, Tong, Shanbao, editor, and Liu, Chengyu, editor

Published

2024

2. Intrinsically Multistable Soft Actuator Driven by Mixed‐Mode Snap‐Through Instabilities.

Author

Luo, Yichi, Patel, Dinesh K., Li, Zefang, Hu, Yafeng, Luo, Hao, Yao, Lining, and Majidi, Carmel

Subjects

*SHAPE memory alloys, *ACTUATORS, *MAXIMUM power point trackers, *LIGHT sources, *INSPECTION & review, *ENERGY harvesting

Abstract

Actuators utilizing snap‐through instabilities are widely investigated for high‐performance fast actuators and shape reconfigurable structures owing to their rapid response and limited reliance on continuous energy input. However, prevailing approaches typically involve a combination of multiple bistable actuator units and achieving multistability within a single actuator unit still remains an open challenge. Here, a soft actuator is presented that uses shape memory alloy (SMA) and mixed‐mode elastic instabilities to achieve intrinsically multistable shape reconfiguration. The multistable actuator unit consists of six stable states, including two pure bending states and four bend‐twist states. The actuator is composed of a pre‐stretched elastic membrane placed between two elastomeric frames embedded with SMA coils. By controlling the sequence and duration of SMA activation, the actuator is capable of rapid transition between all six stable states within hundreds of milliseconds. Principles of energy minimization are used to identify actuation sequences for various types of stable state transitions. Bending and twisting angles corresponding to various prestretch ratios are recorded based on parameterizations of the actuator's geometry. To demonstrate its application in practical conditions, the multistable actuator is used to perform visual inspection in a confined space, light source tracking during photovoltaic energy harvesting, and agile crawling. [ABSTRACT FROM AUTHOR]

Published

2024

3. Magneto-responsive liquid crystalline elastomer nanocomposites.

Author

Yang, Yang, Zhang, Shuai, Ji, Yan, Wei, Yen, Wang, Jianlong, and He, Xiangming

Subjects

*MAGNETIC control, *SMART materials, *ELASTOMERS, *MAGNETISM, *NANOCOMPOSITE materials, *MAGNETIC nanoparticles

Abstract

[Display omitted] As ideal and smart stimuli-responsive materials for soft actuators, artificial muscles, etc., liquid crystalline elastomers (LCEs) can respond to external stimuli, including heat, light, electricity, magnetism, humidity, etc., and make corresponding deformations. Among these external stimuli, magnetic stimulus is featured by remote and contactless control, fast, precise, extremely strong penetration, safe, easy tunability, and so on. By doping magnetic nanoparticles into LCEs, their actuation and motion can be triggered by magnetic fields or forces untetheredly, remotely, and highly precisely. Therefore, the magnetic nanoparticles endow LCEs with magneto-responsiveness, opening doors to LCEs for many unique potential uses, such as magnetic read-out, magnetic valves, magnetic switches, and so on. This review summarizes recent advances in magneto-responsive LCE nanocomposites. Their fabrication is comprehensively discussed. New properties of magneto-responsive LCEs brought by magnetic nanoparticles are also thoroughly reviewed. Their promising applications are subsequently summarized and explored. [ABSTRACT FROM AUTHOR]

Published

2024

4. Dielectric Elastomer Actuators with Enhanced Durability by Introducing a Reservoir Layer.

Author

Jung, Sumin, Kang, Minchae, and Han, Min-Woo

Abstract

A Dielectric Elastomer Actuator (DEA) consists of electrodes with a dielectric layer between them. By controlling the design of the electrodes, voltage, and frequency, the operating range and speed of the DEA can be adjusted. These DEAs find applications in biomimetic robots, artificial muscles, and similar fields. When voltage is applied to the DEA, the dielectric layer undergoes compression and expansion due to electrostatic forces, which can lead to electrical breakdown. This phenomenon is closely related to the performance and lifespan of the DEA. To enhance stability and improve dielectric properties, a DEA Reservoir layer is introduced. Here, stability refers to the ability of the DEA to perform its functions even as the applied voltage increases. The Reservoir layer delays electrical breakdown and enhances stability due to its enhanced thickness. The proposed DEA in this paper is composed of a Reservoir layer and electrode layer. The Reservoir layer is placed between the electrode layers and is independently configured, not subjected to applied voltage like the electrode layers. The performance of the DEA was evaluated by varying the number of polymer layers in the Reservoir and electrode designs. Introducing the Reservoir layer improved the dielectric properties of the DEA and delayed electrical breakdown. Increasing the dielectric constant through the DEA Reservoir can enhance output characteristics in response to electrical signals. This approach can be utilized in various applications in wearable devices, artificial muscles, and other fields. [ABSTRACT FROM AUTHOR]

Published

2024

5. Moisture‐Driven Cellulose Actuators with Directional Motion and Programmable Shapes.

Author

Wei, Shuzhen and Ghosh, Tushar K.

Subjects

ACTUATORS, CELLULOSE, CENTER of mass

Abstract

The hygroscopic motion of plants has inspired the development of moisture‐activated soft actuators. These actuators driven by ambient moisture sources are of great research interest in robotics and self‐regulating textiles. However, these actuators often have slow motion and can only perform bending and twisting motions. Herein, a cellulose film‐based fast‐morphing and motion‐programmable soft actuator is presented that can generate caterpillar‐like movement. The cellophane films reported here bend almost instantaneously under changing humidity, with a large bending curvature, high repeatability, and negligible hysteresis. Different actuation modes are studied using both coated and uncoated cellophane films. The uncoated cellophane film can continuously move on a moist substrate through autonomous bending–rolling–flipping (or oscillating) cycles. A facile strategy is used here to control the rolling direction and facilitate the flipping motion by offsetting its center of gravity during deformation by adding appropriate weights on the end of the actuator. The coated cellophane film is used to fabricate motion‐programmable actuators through heat‐laminating. Several actuator structures are designed and fabricated and their diverse moisture‐induced motions are demonstrated. [ABSTRACT FROM AUTHOR]

Published

2024

6. Ultrafast Biomimetic Untethered Soft Actuators with Bone‐In‐Flesh Constructs Actuated by Magnetic Field.

Author

Yue, Wei, Xu, Renxiao, Sui, Fanping, Gao, Yuan, and Lin, Liwei

Abstract

Soft actuators with unique mechanics have gained significant interests for unique capabilities and versatile applications. However, their actuation mechanisms (usually driven by light, heat, or chemical reactions) result in long actuation times. Reported magnetically actuated soft actuators can produce rapid and precise motions, yet their complex manufacturing processes may constrain their range of applications. Here, the “bone‐in‐flesh” is proposed that constructs combining rigid magnetic structures encapsulated within soft polymers to create untethered magnetic soft actuators. This approach enables these soft, impact‐resistant, agile actuators with a significantly simplified fabrication process. As demonstration examples, multiple soft actuators are fabricated and tested, including actuators for auxetic properties, 2D–3D transformations, and multi‐stable states. As such, this work offers a promising solution to challenges associated with soft actuators to potentially expand their applications in various domains. [ABSTRACT FROM AUTHOR]

Published

2024

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

Author

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

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

8. Fluid-Driven Soft Actuators for Soft Robots.

Author

Nakamura, Taro

Subjects

*ACTUATORS, *HYDRAULIC control systems

Abstract

This paper focuses on soft actuators that utilize fluid power to drive soft robots and describes their features and applications. First, it discusses how soft actuators function as elemental technology in robots. This is followed by an introduction to the driving principle and features of fluid-driven soft actuators. It also classifies these soft actuators based on the fluid power source and the active mode of operation. Furthermore, an overview is provided on the materials employed in soft actuators and the control and evaluation methods for them. Finally, currently reported applications of these soft actuators, such as wearable devices, grippers, and bio-inspired robots, are presented. [ABSTRACT FROM AUTHOR]

Published

2024

9. Multifunctional Soft Actuator Based on Dielectric Liquid with Simultaneous Luminance and Weight Lifting Capabilities.

Author

Han, Dong Jin, Kim, Hea Ji, and Lee, Byung Yang

Subjects

*WEIGHT lifting, *LIQUID dielectrics, *ELECTROLUMINESCENT devices, *ACTUATORS, *ZINC sulfide, *FUNCTION spaces, *COPPER

Abstract

Soft robots require soft actuators for mobility and functionality. To integrate multiple functions in a limited space, researchers are developing multifunctional soft actuators with several functions integrated in one device. This study successfully demonstrates an electroluminescent (EL) soft actuator, a single device with both light‐emitting and actuating capabilities, using liquid dielectric and uniformly dispersed EL phosphor particles. EL phosphor particles are copper‐doped zinc sulfide (ZnS) particles doped with copper. The work is able to disperse the ZnS particles uniformly in the oil by coating the ZnS particles with silica, ensuring consistent luminescence across the device's active area. The performance of the soft actuator is notable, with a strain of 25% and a maximum EL intensity of 23 cd m−2 for a single actuator. When stacking multiple actuators, the intensity exceeds 29 cd m−2. The findings suggest that EL actuator devices will be valuable smart components for soft robots and interactive sensors. They can effectively represent external stimuli through color signals, expanding the capabilities of these systems. [ABSTRACT FROM AUTHOR]

Published

2024

10. A Porous Multi‐Stimuli‐Responsive Liquid Crystal Elastomer Actuator Enabled by Mof Loading.

Author

Jiang, Jie, Ma, Yaru, Cheng, Ruidong, and Zhao, Yue

Subjects

*LIQUID crystals, *ACTUATORS, *PHASE transitions, *ORDER-disorder transitions, *ELASTOMERS, *PHOTOTHERMAL effect

Abstract

A porous actuator is prepared using a liquid crystal elastomer (LCE) loaded with metal‐organic framework (MOF) nanoparticles (MIL‐88A). While the swellable MOF additive endows the LCE actuator with nanoscale pores, after its removal by chemical etching, macroporous LCE actuator is obtained. This LCE‐MOF actuator displays several interesting features. 1) Selective etching allows the actuator in water to curl in one direction and then reverse the curling direction owing to differential water absorption of the nano‐ and macroporous layers. 2) The stretching‐induced alignment of mesogens in the actuator is little affected by the presence of MOF and substantially retained after water uptake, so that an actuation deformation can be generated either by water absorption or thermally induced order‐disorder phase transition. 3) Assisted by the UV irradiation used for polymer cross‐linking, magnetic iron oxide FeO appears to be formed after chemical etching, which allows the actuator to gain the ability to move on water surface guided by a magnet. 4) The in situ formation of magnetic iron oxide in the macroporous actuator also provides an enhanced photothermal effect, making light‐driven locomotion of the actuator more effective. The use of active porogen like MOF opens a new way to explore porous LCE actuators. [ABSTRACT FROM AUTHOR]

Published

2024

11. Design and characterization of electro-active soft actuator based on phase transition of microencapsulated silicon-ethanol composite.

Author

Ebrahimi, Amir Hossein, Zamyad, Hojjat, Safaei, Javad, and Sahebian, Samaneh

Subjects

*PHASE transitions, *ACTUATORS, *ETHANOL

Abstract

In this study, we demonstrate the development of a fast-response soft composite actuator fabricated by mechanical mixing of silicone elastomer (matrix) and ethanol (as phase-change fluid). Joule heating generated by electrical actuation causes a liquid-vapor transition of ethanol embedded in silicone microcapsules; provides the required pressure for mimicking the natural movements. We discuss the critical design variables to improve the temperature response, chemical composition, mechanical properties, force generated, and microstructure of soft actuator. Our soft actuator produces a high load-to-weight ratio (1000 times greater than its own) using a low-voltage source (˂20V). The stability of the soft actuator under multiple working cycles would bring the application to different robotic areas. The actuator using the mechanism presented here is easy to manufacture, automate, and recyclable. It can be used in a range of robotic applications. [ABSTRACT FROM AUTHOR]

Published

2024

12. ポリマー上における銀ナノ粒子含有金属有機構造体薄膜の形成による 光応答ソフトアクチュエータの作製.

Author

小関友香, 真下理彩, 深津亜里紗, 岡田健司, and 髙橋雅英

Abstract

Soft actuators are gaining attention as flexible components for soft robotics. Responsive materials that respond to external stimuli such as light are often used as the driving part of the soft actuator. For example, thermoresponsive soft actuators are fabricated by bilayer polymer films of different thermal expansion coefficients. Heating of such bilayer polymer films by plasmon heating enables the soft actuators to be driven remotely by light. In the present study, we report the fabrication of plasmonic heating driven responsive soft actuators by using metal-organic framework (MOF) thin films as supports of plasmonic nanoparticles. The thin films of Cu2(bpydc)2 (bpydc = 2,2’-bipyridine-5,5’-dicarboxylate) of which metal ion adsorption capacity is high were fabricated on Cu2(bpdc)2 (bpdc = 4,4’-biphenyldicarboxylate) which grown on ceramics precursor, Cu(OH)2. The actuating was operated by plasmon heating of Ag nanoparticles contained in MOF thin films inserted in between the two polymers, PDMS (poly(dimethylsiloxane)) and PVDC (poly(vinylidene chloride)). Two polymers have different thermal expansion coefficient so that they work as soft actuators by plasmon heating. Such fabrication process of soft actuators would pave the way for development of advanced devices in the field of soft robotics. [ABSTRACT FROM AUTHOR]

Published

2024

13. Resistance Feedback of a Ni-Ti Alloy Actuator at Room Temperature in Still Air.

Author

Durante, Francesco, Raparelli, Terenziano, and Beomonte Zobel, Pierluigi

Subjects

SHAPE memory alloys, ACTUATORS, PULSE width modulation, ATMOSPHERIC temperature, ALLOYS, ELECTRIC currents

Abstract

This paper illustrates an experimental activity for the closed-loop position control of an actuator made using shape memory alloy (SMA) wire. A solution with the self-sensing effect was implemented to miniaturize the systems, i.e., without external sensors. A proportional control algorithm was initially used, demonstrating the idea's feasibility; the wire can behave simultaneously as an actuator and sensor. An experimental investigation was subsequently conducted for the optimization of the developed actuator. As for the material, a Flexinol wire, Ni-Ti alloy, with a diameter of 0.150 mm and a length of 200 mm, was used. Preliminarily, characterization of the SMA wire at constant and variable loads was carried out; the characteristics detected were elongation vs. electric current and elongation vs. electrical resistance. The control system is PC based with a data acquisition card (DAQ). A drive board was designed and built to read the wire's electrical resistance and power it by pulse width modulation (PWM). A notable result is that the actuator works with good precision and in dynamic conditions, even when it is called to support a load up to 65% different from that for which the electrical resistance–length correlation has previously been experimentally obtained, on which the control is based. This opens up the possibility of using the actuator in a counteracting configuration with a spring, which makes hardware implementation and control management simple. [ABSTRACT FROM AUTHOR]

Published

2024

14. Recent Advances in Microrobots Powered by Multi-Physics Field for Biomedical and Environmental Applications.

Author

Teng, Xiangyu, Qiao, Zezheng, Yu, Shuxuan, Liu, Yujie, Lou, Xinyu, Zhang, Huanbin, Ge, Zhixing, and Yang, Wenguang

Subjects

MICROROBOTS, ENVIRONMENTAL protection, PROBLEM solving

Abstract

Microrobots powered by multi-physics fields are becoming a hotspot for micro–nano manufacturing. Due to the small size of microrobots, they can easily enter small spaces that are difficult for ordinary robots to reach and perform a variety of special tasks. This gives microrobots a broad application prospect in many fields. This paper describes the materials, structures, and driving principles of microrobots in detail and analyzes the advantages and limitations of their driving methods in depth. In addition, the paper discusses the detailed categorization of the action forms of microrobots and explores their diversified motion modes and their applicable scenarios. Finally, the article highlights the wide range of applications of microrobots in the fields of biomedicine and environmental protection, emphasizing their great potential for solving real-world problems and advancing scientific progress. [ABSTRACT FROM AUTHOR]

Published

2024

15. Human–Material Interaction Enabled by Fused Filament Fabrication 4D Printing.

Author

Lalegani Dezaki, Mohammadreza, Zolfagharian, Ali, Demoly, Frédéric, and Bodaghi, Mahdi

Subjects

FIBERS, SMART devices, WOOD products, SHAPE memory polymers, COMPUTERS, SUSTAINABILITY, SOCIAL interaction

Abstract

In this review, 4D printing (4DP) is delved into through fused filament fabrication (FFF) and its implications for human–material interaction (HMI). FFF 4DP's emergence in HMI represents a nascent and evolving concept worthy of deeper exploration. In this article, FFF 4DP's fundamental principles, methodologies, materials, and associated benefits and challenges are introduced. Herein, the primary focus is the intersection between FFF 4DP and HMI, investigating the potential of employing FFF 4D‐printed objects as interactive interfaces. Various HMI scenarios are examined, including applications in soft actuators, smart toys, household devices, smart consumer products, 4D textiles, and customizable wood‐based items. Moreover, in this article, the current state of the art and development in the field are discussed, highlighting notable projects that integrate FFF 4DP into HMI to advance environmental sustainability. Also, key challenges/limitations requiring attention for the widespread adoption of 4DP in HMI applications are identified. In this work, an in‐depth analysis of FFF 4DP within the HMI context is offered, underscoring its potential to transform human interactions with machines and smart devices. Innovative features for dynamic and adaptable interfaces are introduced, promising to revolutionize user experiences. The article serves as a valuable resource for researchers, practitioners, and designers interested in exploring the exciting possibilities of FFF 4DP in the realm of HMI. [ABSTRACT FROM AUTHOR]

Published

2024

16. Soft Actuator Based on a Novel Variable Stiffness Compound Extensor Bending-Pneumatic Artificial Muscle (CEB-PAM): Design and Mathematical Model.

Author

Al-Mayahi, Wafaa and Al-Fahaam, Hassanin

Subjects

ARTIFICIAL muscles, ACTUATORS, MATHEMATICAL models

Abstract

Soft Actuator Based on a Novel Variable Stiffness Compound Extensor Bending-Pneumatic Artificial Muscle (CEB-PAM): Design and Mathematical Model [ABSTRACT FROM AUTHOR]

Published

2024

17. Towards Nanomaterial-Incorporated Soft Actuators: from Inorganic/Organic Material-Based Soft Robot to Biomaterial-Based Biohybrid Robot.

Author

Shin, Minkyu, Kim, Seewoo, Melvin, Ambrose Ashwin, and Choi, Jeong-Woo

Abstract

Soft actuators have played an indispensable part in the field of biosensors and soft robotics as such systems offer solutions that cannot be addressed with rigid actuators due to the lack of both flexibility and sensitivity. However, soft actuators have certain limitations when it comes to their durability and longevity. In recent years, quite a few versatile fabrication techniques and innovative solutions have been developed that have played an essential role in the development of soft robotics. An exemplary innovation involves the integration of nanomaterials into polymers that act as a host in the fabrication of inorganic/organic actuators. These actuators have shown significant enhancement both in their physical and chemical properties. Consequently, it paves the way for the development of sophisticated soft actuator-based devices that can find broader applications in the field of biomedical sciences. However, biocompatibility has been a matter of concern for inorganic/organic soft actuators. Addressing this issue, studies on the development of biomaterial-based soft actuators that incorporate nanomaterials have been conducted for biohybrid robots. This review aims to provide a comprehensive understanding of diverse stimulus-trigger actuation alongside exploring the influence of nanomaterials in inorganic/organic actuators. Further, it gives valuable insights into the implication of biomaterials in soft actuators for the development of biohybrid robot. [ABSTRACT FROM AUTHOR]

Published

2024

18. Drive Characteristics of Air-Cylinder-Type Artificial Muscle in Annular Bending.

Author

Hiramitsu, Tatsuhiro, Miyake, Yuuki, Seki, Hiroaki, and Tsuji, Tokuo

Subjects

AIR cylinders, AIR pressure, TUBES, ARTIFICIAL muscles, ACTUATORS

Abstract

Air cylinders are actuators that slide a piston inside cylinders by applying air pressure. We propose an air-cylinder-type artificial muscle that can be flexibly bent by using a flexible tube for the cylindrical part. The actuator output was a string connected to a piston. When the air-cylinder-type artificial muscle bends, the inner wall of the tube and the string come into contact, causing output fluctuations owing to friction. In this study, we investigated the output when an artificial muscle was bent. After describing the structure of the air-cylinder-type artificial muscle, the measurement results of the resistance force at each part of the actuator are presented. A theoretical output inspired by the capstan equation was derived, and its validity was verified by comparison with experimental results. [ABSTRACT FROM AUTHOR]

Published

2024

19. Bidirectional Support for Individual Finger Joints in Soft Rehabilitation Gloves: Integration of Foldable Pouch Actuators With Modular Elastomeric Actuators

Author

Shota Kokubu, Pablo E. Tortos Vinocour, and Wenwei Yu

Subjects

Soft robotics, soft actuator, hand rehabilitation, finger-motion assistance, active extension support, bidirectional support, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

In recent years, a proliferation of soft actuators tailored for hand rehabilitation has been observed. In particular, modular soft actuators have garnered particular interest due to their capacity for individual customization and joint-specific support, a feature often lacking in whole-finger soft actuators. Despite these advancements, a significant limitation persists: the majority of these actuators facilitate only finger flexion, neglecting the equally vital extension movements required for comprehensive hand rehabilitation. Traditional approaches to achieving multi-degree-of-freedom or bidirectional motion have relied on the integration of multiple chambers within soft actuators. However, this strategy has proven impractical for modular soft actuators, primarily due to spatial constraints within the finger joint. To address this challenge, we introduce a foldable pouch actuator (FPA). Designed as a flat, foldable structure composed of a single sheet, the FPA expands solely upon pressurization, generating the requisite force for finger extension. Notably, the FPA seamlessly integrates with existing modular soft actuators without compromising their structural integrity or functional capabilities, thereby enabling bidirectional support for individual joints. Evaluations using a synthetic finger model achieved a joint flexion torque of 0.17 Nm and estimated an overall extension torque of 0.12 Nm. These advancements were accomplished without compromising the traditional flexion functionality, adding individual joint extension support to the existing capabilities. This study constitutes a substantive leap forward in the utilization of soft actuators for clinical hand rehabilitation applications.

Published

2024

20. Deriving Design Rules for Personalization of Soft Rehabilitation Gloves

Author

Shota Kokubu, Reiji Nishimura, and Wenwei Yu

Subjects

Soft robotics, soft actuator, hand rehabilitation, finger-motion assistance, personalization, individual differences, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Soft actuators developed for hand rehabilitation show promise, but their practical application requires addressing individual differences and establishing suitable design rules. While joint modular soft actuators offer flexibility for diverse hand dimensions, existing performance validations have only examined a limited number of actuator sizes and neglected crucial factors like joint alignment. Customization efforts have lacked standardization, relying on a trial-and-error approach. Therefore, this study systematically evaluates the impact of actuator design parameters (size and mounting position) on joint range of motion (ROM) and torque, proposing novel design rules based on linear optimization. Experimental assessments, conducted on dummy fingers emulating human biomechanics, provide profound insights into the intricate interplay of design parameters and support performance. The findings strongly advocate maintaining a reference position for stable support, irrespective of actuator size, emphasizing the need to align the actuator with the joint center. The proposed design rules incorporate user-specific finger information, offering customized design rules. Proportionate actuator lengths to single-phalangeal length (PsPL), Proportionate actuator lengths to multi-phalangeal length (PmPL), Proportionate actuator lengths to Range of Motion (PROM), and the Traditional Method are systematically compared. Assistive performances (ROM and torque) and trajectory analysis reveal that the PsPL-designed actuator exhibits the most stable and natural assistive performance. This study emphasizes the importance of understanding actuator deformations for personalized adaptation, providing valuable insights for advancements in assistive and rehabilitative technologies.

Published

2024

21. Multi-Structure Parameter Optimization Analysis of Soft Actuator Based on Numerical Calculation

Author

Wang Songtao, Yu Yimeng, Jiang Shiyu, and Chen Sisi

Subjects

Numerical calculation, parameter optimization, regression analysis, soft actuator, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

To optimize the performance of the soft actuator, numerical simulation and regression analysis of the multi-structure parameter are presented based on the numerical calculation method. Firstly, numerical simulation and regression analysis were performed on the parameters of different driving channel shapes, including equilateral triangle, square, regular pentagon, regular hexagon, and circle, to determine the driving performance under different channel cross-sections. Secondly, numerical simulation and regression analysis were conducted on the parameters of fiber winding diameter and winding angle of the soft actuator, and qualitative analysis was performed on the failure states of the numerical calculations. Lastly, numerical simulation and regression analysis were carried out on the parameters of wall thickness and driving channel length of the soft actuator to determine the influence of these parameters on the driving performance. Through the numerical simulation and regression analysis, this study provides a necessary theoretical foundation for the optimization design of soft actuator, effectively improving the development efficiency and dynamic performance of soft actuators.

Published

2024

22. Dynamic Shape Change of Liquid Crystal Polymer Based on An Order‐Order Phase Transition.

Author

Yang, Rong, Wang, Yahui, Yao, Hongjing, Li, Yanqing, Chen, Li, Zhao, Yue, and Wang, Yu‐Zhong

Subjects

*POLYMER liquid crystals, *PHASE transitions, *ANNEALING of metals, *ORDER-disorder transitions, *LIQUID crystals, *PHENYL group

Abstract

Liquid crystal actuators conventionally undergo shape changes across an order‐disorder phase transition between liquid crystal (LC) and isotropic phases. In this study, we introduce an innovative Liquid Crystal Polymer (LCP) actuator harnessing an order‐order LC phase transition mechanism. The LCP film is easily stretchable within the LC phase, facilitated by the π–π stacking of phenyl groups serving as robust physical crosslinking points, and thereby transforms to a stable monodomain structure. The resultant monodomain LCP actuator shows a distinctive reversible dynamic shape change, exhibiting extension followed by contraction along the LC director on cooling. The extension is propelled by the reversible smectic C to smectic A phase transition, and the contraction is attributed to the re‐entry to the smectic C phase from smectic A phase. Thermal annealing temperature determines this peculiar dynamic shape change, which occurs during both heating and cooling processes. This pivotal attribute finds manifestation in gripper and flower‐shaped actuators, adeptly executing grabbing and releasing as well as blooming and closure motions within a single thermal stimulation. In essence, our study introduces an innovative approach to the realm of LCP actuators, ushering in a new avenue for the design and fabrication of versatile and dynamically responsive LCP actuators. [ABSTRACT FROM AUTHOR]

Published

2024

23. Manufacture and Deformation Angle Control of a Two-Direction Soft Actuator Integrated with SMAs.

Author

Acevedo-Velazquez, Aline Iobana, Wang, Zhenbi, Winkler, Anja, Modler, Niels, and Röbenack, Klaus

Subjects

*ACTUATORS, *SHAPE memory alloys, *COMPUTER systems, *COMPUTER vision, *SYSTEM identification, *ANGLES

Abstract

In this contribution, the development of a 3D-printed soft actuator integrated with shape memory alloys (SMA) wires capable of bending in two directions is presented. This work discusses the design, manufacturing, modeling, simulation, and feedback control of the actuator. The SMA wires are encased in Polytetrafluoroethylene (PTFE) tubes and then integrated into the 3D-printed matrix made of thermoplastic polyurethane (TPU). To measure and control the deformation angle of the soft actuator, a computer vision system was implemented. Based on the experimental results, a mathematical model was developed using the system identification method and simulated to describe the dynamics of the actuator, contributing to the design of a controller. However, achieving precise control of the deformation angle in systems actuated by SMA wires is challenging due to their inherent nonlinearities and hysteretic behavior. A proportional-integral (PI) controller was designed to address this challenge, and its effectiveness was validated through real experiments. [ABSTRACT FROM AUTHOR]

Published

2024

24. Fabrication and Characterization of Pneumatic Unit Cell Actuators.

Author

Kommuri, Krishna Dheeraj, Van Beek, Femke E., and Kuling, Irene A.

Subjects

HAPTIC devices, UNIT cell, ACTUATORS, AUGMENTED reality, STIMULUS intensity, TASK performance, PNEUMATIC actuators

Abstract

In the realm of virtual and augmented reality (VR/AR) and teleoperation applications, haptic feedback plays a role in enhancing task performance. One of the main goals of this study is to simplify haptic device hardware while improving its capacity to provide various stimuli at different intensities. In response to these challenges, this research introduces the Pneumatic Unit Cell (PUC), a soft pneumatically driven device—a hollow silicone cylinder with the ability to provide both static-pressure and vibrotactile feedback. Furthermore, the Pneumatic Unit Cell's design simplicity has the potential for scalability, modularity, and the flexibility to mount the device on any part of the human body. The focus of the current paper is to study PUCs as actuators and lay the foundation for future perceptual studies. The characterization studies encompass the fabrication and verification of the fabrication accuracy through dimensional measurements, characterizing PUCs under static-pressure conditions (measuring the free deflection and blocking force) and frequency conditions (measuring the free deflection). In the static-pressure conditions, we applied pressures ranging from 0 to 40 kPa to measure the free deflection and from 0 to 30 kPa to measure the blocking force. In the frequency conditions, we applied pressures of 10, 20, and 30 kPa with inflation/deflation rates varying between 0.5 Hz and 100 Hz. The measurements of free deflection under static-pressure conditions revealed that 0.9 mm and 1.2 mm PUCs exhibit a linear increase in free deflection with an increase in inflation pressure. The results of free-deflection measurements under the frequency conditions indicate a direct relationship between the free-deflection magnitude and applied pressure. The results also demonstrate an inverse relationship to the frequency of inflation/deflation. The characterization results demonstrate a broad range of free deflection observed under both static-pressure and frequency conditions, encouraging the potential application of Pneumatic Unit Cell actuators as haptic devices. [ABSTRACT FROM AUTHOR]

Published

2024

25. Versatile vacuum-powered artificial muscles through replaceable external reinforcements.

Author

Mendoza, Mijafl Jaen, Cancan, Sergio, Surichaqui, Steve, Centeno, Esteban, Vilchez, Ricardo, Bertoldi, Katia, Vela, Emir A., Zhang, Hongying, Assaf, Tareq, and Paterno, Linda

Subjects

ARTIFICIAL muscles, SOFT robotics, LIFT (Aerodynamics)

Abstract

Soft pneumatic artificial muscles are a well actuation scheme in soft robotics due to its key features for robotic machines being safe, lightweight, and conformable. In this work, we present a versatile vacuum-powered artificial muscle (VPAM) with manually tunable output motion. We developed an artificial muscle that consists of a stack of air chambers that can use replaceable external reinforcements. Different modes of operation are achieved by assembling different reinforcements that constrain the output motion of the actuator during actuation. We designed replaceable external reinforcements to produce single motions such as twisting, bending, shearing and rotary. We then conducted a deformation and lifting force characterization for these motions. We demonstrated sophisticated motions and reusability of the artificial muscle in two soft machines with different modes of locomotion. Our results show that our VPAM is reusable and versatile producing a variety and sophisticated output motions if needed. This key feature specially benefits unpredicted workspaces that require a soft actuator that can be adjusted for other tasks. Our scheme has the potential to offer new strategies for locomotion in machines for underwater or terrestrial operation, and wearable devices with different modes of operation. [ABSTRACT FROM AUTHOR]

Published

2024

26. 一种可变直径软体机器人的设计.

Author

赵玉侠, 万学锋, 多会晓, and 钮乾坤

Abstract

To solve the problem of low safety and poor adaptability of rigid robots, design a soft robot with grasping function, a soft robot with grasping function was designed. The soft robot consists of three soft body actuators distributed at 120 degrees around the circumference and a fixture, which can change the diameter automatically to adapt to the grasping of objects of different sizes, and it is measured that the soft robot can grasp objects with a diameter range of 45 ~ 97 mm. Both the fixture and the soft actuator are manufactured by 3D printing, which has the advantages of low cost, simple manufacturing, and easy mass production. The soft robot is driven by pneumatic pressure, and when the actuator is inflated, three fingers bend simultaneously to grasp the object with good stability. The corresponding mechanical model was established for the soft body actuator, and the relationship between the bending angle and the input air pressure was obtained, and the bending characteristics of the actuator were simulated by using ABAQUS finite element simulation software. In comparison, it is found that the theoretical modeling and simulation analysis have a high agreement in the bending angle of the actuator. [ABSTRACT FROM AUTHOR]

Published

2024

27. Finger joint aligned flat tube folding structure for robotic glove design.

Author

Liu, Hao, Wu, Changchun, Lin, Senyuan, and Chen, Yonghua

Abstract

Pneumatic soft actuators have been widely considered the safest actuation technology for use in wearable rehabilitation robots. For soft robotic gloves, researchers commonly put soft extending or bending actuators on dorsal fingers to assist hand flexion. In this research, we propose a novel pre-folded flat tube actuator (PFTA) to assist finger flex into a pre-set bending angle or contact force. The PFTA has three folds, aligned with each of the finger joint. Different from other soft actuators, the PFTA exerts bending torque directly on each finger joint without large actuator deformation. The PFTA made of heat shrink flat tube has a small profile, with low cost, easy fabrication, and high safety. When actuated, the PFTA has the tendency to unfold as well, we call this effect as unfolding flat tube actuation. This effect is characterized by a range of bending angles and input air pressures in which four distinct response regimes were observed. They are defined as shearing, collapsing, creasing, and flattening regimes. Similarly, experimental characterization of PFTAs is also conducted to evaluate the level of joint flexion assistance based on which design guidelines for robotic gloves are recommended. Finally, we build PFTAs on a soft wearable glove and demonstrate their capability in assisting the grasping operations of various object shapes. [ABSTRACT FROM AUTHOR]

Published

2024

28. Design, Manufacturing, and Open-Loop Control of a Soft Pneumatic Arm.

Author

García-Samartín, Jorge Francisco, Rieker, Adrián, and Barrientos, Antonio

Subjects

PNEUMATIC control, MULTI-degree of freedom, DEGREES of freedom, MANUFACTURING processes, INVESTMENT casting

Abstract

Soft robots distinguish themselves from traditional robots by embracing flexible kinematics. Because of their recent emergence, there exist numerous uncharted territories, including novel actuators, manufacturing processes, and advanced control methods. This research is centred on the design, fabrication, and control of a pneumatic soft robot. The principal objective is to develop a modular soft robot featuring multiple segments, each one with three degrees of freedom. This yields a tubular structure with five independent degrees of freedom, enabling motion across three spatial dimensions. Physical construction leverages tin-cured silicone and a wax-casting method, refined through an iterative processes. PLA moulds that are 3D-printed and filled with silicone yield the desired model, while bladder-like structures are formed within using solidified paraffin wax-positive moulds. For control, an empirically fine-tuned open-loop system is adopted. This paper culminates in rigorous testing. Finally, the bending ability, weight-carrying capacity, and possible applications are discussed. [ABSTRACT FROM AUTHOR]

Published

2024

29. Minimal Bio-Inspired Crawling Robots with Motion Control Capabilities.

Author

Wu, Jintian, Liu, Mingyi, and Padovani, Damiano

Subjects

ROBOT control systems, BIOLOGICALLY inspired computing, ROBOT design & construction, ANIMAL locomotion, MOTION, ROBOTS, ACTUATORS, ROBOT motion

Abstract

Nonskeletal animals such as worms achieve locomotion via crawling. We consider them as an inspiration to design robots that help underline the mechanisms of crawling. In this paper, we aim to identify an approach with the simplest structure and actuators. Our robots consist of cut-and-fold bodies equipped with pneumatically-driven soft actuators. We have developed fabrication techniques for coin-sized robots. Experiments showed that our robots can move up to 4.5 mm/s with straight motion (i.e., 0.1 body lengths per second) and perform cornering and U-turns. We have also studied the friction characteristics of our robots with the ground to develop a multistate model with stick–slip contact conversions. Our theoretical analyses depict comparable results to experiments demonstrating that simple and straightforward techniques can illustrate the crawling mechanism. Considering the minimal robots' structure, this result is a critical step towards developing miniature crawling robots successfully. [ABSTRACT FROM AUTHOR]

Published

2024

30. Near-infrared photo-responsive Ti3C2Tx MXene/LCN film for soft actuators.

Author

Ge, Shimeng, Yin, Shiwen, Li, Xiaoshuai, Zhao, Yunlu, Ma, Hongmei, and Sun, Yubao

Subjects

*POLYMER liquid crystals, *ACTUATORS, *PHOTOTHERMAL effect, *NEAR infrared radiation, *BIOMIMETIC materials, *PHOTOTHERMAL conversion, *COMPOSITE coating

Abstract

Soft actuators have attracted a lot of attention because of their impressive performance and wide range of applications. Liquid crystalline networks (LCNs) are a combination of liquid crystals and polymers, and they are considered to be the most promising materials for creating soft actuators. MXene has a high photothermal conversion efficiency, and it can be a heat-source under near-infrared light. In this paper, we fabricated a MXene/LCN composite film by coating a solution of Ti3C2Tx MXene onto an LCN film with orientation direction and then followed by drying. We observed different types of deformations when we cut the composite film in different directions. We also measured the influence of the near-infrared light intensity on the bending angle, response time, and recovery time of the composite films with different deformations. Finally, we used this composite film to fabricate various biomimetic devices such as biomimetic flowers, artificial irises, mechanical fixtures, and crawling robots. These results demonstrate the great potential of this composite film in soft actuator applications. [ABSTRACT FROM AUTHOR]

Published

2023

31. Soft Finger Rehabilitation Exoskeleton of Biomimetic Dragonfly Abdominal Ventral Muscles: Center Tendon Pneumatic Bellows Actuator.

Author

Duanmu, Dehao, Li, Xiaodong, Huang, Wei, and Hu, Yong

Subjects

*ROBOTIC exoskeletons, *PNEUMATIC actuators, *ABDOMINAL muscles, *TENDONS (Prestressed concrete), *INDUSTRIAL robots, *BIOMIMETICS

Abstract

The development of soft robotics owes much to the field of biomimetics, where soft actuators predominantly mimic the movement found in nature. In contrast to their rigid counterparts, soft robots offer superior safety and human–machine interaction comfort, particularly in medical applications. However, when it comes to the hand rehabilitation exoskeletons, the soft devices have been limited by size and material constraints, unable to provide sufficient tensile strength for patients with high muscle tension. In this paper, we drew inspiration from the muscle structure found in the tail of dragonflies and designed a novel central tendon-based bellows actuator. The experimental results demonstrated that the central tendon-based bellows actuator significantly outperforms conventional pneumatic bellows actuators in terms of mechanical output. The tensile strength of the central tendon-based bellows actuator exceeded that of pneumatic actuators more than tenfold, while adding only 2 g to the wearable weight. This finding suggests that the central tendon-based bellows actuator is exceptionally well-suited for applications demanding substantial pulling force, such as in the field of exoskeleton robotics. With tensile strength exceeding that of pneumatic bellows actuators, this biomimetic design opens new avenues for safer and more effective human–machine interaction, revolutionizing various sectors from healthcare to industrial automation. [ABSTRACT FROM AUTHOR]

Published

2023

32. Vacuum-powered soft actuator with oblique air chambers for easy detachment of artificial dry adhesive by coupled contraction and twisting.

Author

Yoo, Seung Hoon, Kim, Minsu, Park, Han Jun, Lee, Ga In, Lee, Sung Ho, and Kwak, Moon Kyu

Subjects

*ACTUATORS, *INTERMOLECULAR forces, *ADHESIVES, *ADHESIVE wear, *ROBOT hands, *GECKOS

Abstract

A gecko foot-inspired, mushroom-shaped artificial dry adhesive exploiting intermolecular forces between microstructure and surface has drawn research attention for its strong adhesive force. However, the high pull-off strength corresponding to the adhesive force matters when detaching fragile substrates. In this study, we report a vacuum-powered soft actuator having oblique air chambers and a dry adhesive. The soft actuator performs coupled contraction and twisting by applying negative pneumatic pressure inward and exhibits not only high pull-off strength but also easy detachment. This effective detachment can be achieved thanks to the twisting motion of the soft actuator. The detachment performances of the actuator models are assessed using a 6-degrees-of-freedom robot arm. Results show that the soft actuators exhibit remarkable pull-off strength decrement from ~20 N cm−2 to ~2 N cm−2 due to the twisting. Finally, to verify a feasible application of this study, we utilize the inherent compliance of the actuators and introduce a glass transfer system for which a glass substrate on a slope is gripped by the flexibility of the soft actuators and delivered to the destination without any fracture. Vacuum-powered soft actuator with oblique air chambers for easy detachment of artificial dry adhesive by coupled contraction and twisting In this work, we report a vacuum-powered soft actuator with artificial dry adhesive. We used a vacuum for the easy detachment of the dry adhesive and verified a feasibility for the real-industrial fields. The highlights and novelty of this work are as follows: • Vacuum-powered soft actuator with Gecko inspired dry adhesive • High adhesion with an easy detachment by twisting motion • Mechanical analysis of the easy detachment • Novel glass transfer system with the 6-DOF robot arm based on the soft actuator [ABSTRACT FROM AUTHOR]

Published

2023

33. 3D‐Architected low melting point alloys foam microstructure‐reinforced polymer composite with superior stiffness‐switchable for soft actuator.

Author

Liu, Yahao, Wang, Yuansheng, Yang, Xue, Zheng, Jian, Huang, Wei, Zhang, Yu, Zhang, Xiao, and Wang, Xuan

Subjects

*FOAM, *MELTING points, *CARBON foams, *ACTUATORS, *SELF-healing materials, *WATER currents, *POLYMERS, *SMART devices

Abstract

Stiffness variable materials have aroused extensive research interest in smart devices, especially in soft actuators. However, achieving materials with high stiffness switch range remains challenging. Here, a novel three‐dimensional (3D) lightweight Field's metal (FM) foam was developed. Meanwhile, the polymer composite (SUFF) with superior stiffness switchable capacity was fabricated by embedding FM foam into a kind of designed stiffness variable polymer. The SUFF shows outstanding conductivity under relatively low FM volume fraction of 20.6%. Impressively, because of the extremely high modulus and fast transition of FM foam, the stiffness switch ratio of the SUFF are able to reach an ultra‐high value of 6987.5‐folds. Apart from its exceptional stiffness switchable capacity, the SUFF also possesses remarkable shape memory and self‐healing characteristics. Next, the SUFF was then fastened to a soft actuator as the stiffness changing units. The obtained actuator was able to exhibit a short heating–cooling cycle time of 44 s while using 10 A of current and 4°C water for cooling. Moreover, the actuator can reach remarkable values of 973 mN/mm and 4729 mN, respectively, for its stiffness and net force. Then, a soft robot gripper made up of three obtained actuators mounted on a base demonstrates its excellent load and stiffness switchable ability. It can lift a variety of objects with various forms with weights up to more than 3 kg. This study might provide a reference for application of stiffness variable materials in soft actuators. Highlights: The FM foam were designed and synthetized by lost‐wax casting method.The polymer composite exhibits large stiffness switching range.The polymer composite achieves 6987.5‐folds rigid/soft stiffness ratio.A 3D‐printing soft actuator was fabricated using obtained polymer composite.The assembled robotic gripper can lift weights up to more than 3 kg. [ABSTRACT FROM AUTHOR]

Published

2023

34. Programmable and Variable‐Stiffness Robotic Skins for Pneumatic Actuation.

Author

Gao, Weinan, Kang, Jingtian, Wang, Guohui, Ma, Haoxiang, Chen, Xueyan, Kadic, Muamer, Laude, Vincent, Tan, Huifeng, and Wang, Yifan

Subjects

WEIGHT lifting, PNEUMATIC actuators, ROBOT hands, ROBOTS, ROBOTICS, DEGREES of freedom, IRON, GRAIN

Abstract

Pneumatic soft actuators possess relatively fast response, inherent high flexibility, and achieve extraordinary shape morphing under large deformations. Conventionally, the entire body of soft pneumatic robots needs to be designed for specific applications. Herein, a soft pneumatic actuator design with structured fabrics as actuator skins, which has high bending stiffness variation that can accomplish multiple tasks and different deformation modes in a single body, is proposed. By adjusting the structured skin, the developed soft actuator can be tailored to achieve various deformations. It is experimentally shown that the bending stiffness of the actuator can be adjusted from 108 to 5654 N m−1. The blocking force of the actuator in bending is comparable with that of conventional fabric‐reinforced pneumatic actuators, while the actuator skins are reusable and programmable. In application, the actuators are used to construct a bionic soft gripper with multiple degrees of freedom. By switching between three grasping modes, the gripper successfully fulfills a series of tasks including lifting weights up to 1 kg and grasping objects ranging from a grain of grape to a large iron basin. This work opens up an avenue for designing structured skins for pneumatic robots with programmable deformation modes and versatile functions. [ABSTRACT FROM AUTHOR]

Published

2023

35. Sarcomere‐Inspired Multilayer Artificial Muscle Units for Hyperconfigurable Robotic Applications.

Author

Ambrose, Jonathan William, Tan, Gavril Yong En, Chiang, Nicholas Zhang Rong, Cheah, Dylan Sin You, Xiong, Quan, and Yeow, Chen-Hua

Subjects

ARTIFICIAL muscles, BIOMIMETICS, ROBOTICS, PNEUMATIC actuators, MUSCLE strength, ARM muscles

Abstract

Soft pneumatic biomimetic robotic systems excel at the specific application they are designed for, often to interact or navigate unstructured environments safely. However, redeployment to new purposes requires substantial resources, from redesign to revalidation. Despite most pneumatic artificial muscles surpassing the power and contraction performance of natural muscles, natural muscles largely remain unmatched in terms of their versatility and complex performance. This is likely due to artificial muscle's low effective strain and high radial expansion, limiting parallel operating efficiencies. To address these challenges, a class of compact versatile pneumatic actuators, called multilayer artificial muscle (MAM), that are capable of deployment to different applications through configurable modularity, is presented. The MAMs are biomimetically inspired by the sarcomere, the building block for natural muscle architecture. Similarly, MAM can extend and contract as well as be rearranged to mimic muscle‐like actions and functions, such as a caterpillar locomotion robot and an entire robotic arm. The MAMs are fabricated through multilayer, multimaterial, low‐cost additive manufacturing, which offers certain advantages such as higher extension, contraction force, and durability. MAMs have the potential to provide a crucial fundamental building block toward future versatile reconfigurable architecture. [ABSTRACT FROM AUTHOR]

Published

2023

36. Lightweight Robotic Joint with Thermally Activated Paraffin Actuator in the Deep Sea.

Author

Ning, Dayong, He, Xiaokang, Hou, Jiaoyi, Liang, Gangda, and Zhang, Kang

Subjects

PARAFFIN wax, PHASE transitions, ALKANES, ACTUATORS, FINITE element method

Abstract

The abundance of resources in the deep sea continues to inspire mankind's desire for exploration. However, the extreme environments pose a huge challenge for designing deep-sea mechanical devices that are primarily driven by hydraulic and electric motor technology. Researchers are beginning to explore more flexible and innovative drive methods suitable for the deep-sea environment. This paper presents a simple joint mechanism based on a paraffin phase change thermal expansion drive. Its unique design combines a flexible cell with an open structure that allows it to adapt to different pressures at different water depths. Paraffin is enclosed in multiple sets of smaller paraffin cells, which act as thermal expansion material for generating hydraulic pressure. The software comsol was used to perform a finite element analysis of the phase change process in paraffin. By fabricating the mechanical structure, the displacement generated by the thermal expansion is amplified and converted, thus enabling a bi-directional rotational displacement output from the joint while reducing the complexity of the structure. The joints in this paper provide a reliable reference for the design of small deep-sea robot drive systems. [ABSTRACT FROM AUTHOR]

Published

2023

37. Design of Soft Pneumatic Actuator with Two Oblique Chambers for Coupled Bending and Twisting Movements.

Author

Shahabi, Ebrahim, Kamare, Behnam, Visentin, Francesco, Mondini, Alessio, and Mazzolai, Barbara

Subjects

FINITE element method, PNEUMATIC actuators, ROBOT hands, ACTUATORS

Abstract

Soft pneumatic network (Pneu-net) actuators are frequently used to achieve sophisticated movements, but they face challenges in producing both bending and twisting motions concurrently. In this paper, we present a new Pneu-net twisting and bending actuator (PTBA) design that enables them to perform complex motions. We achieved this by adjusting the chamber angle, ranging from 15 to 75 degrees, to optimize the bending and twisting movements through finite element analysis and experimental verification. We also investigated the variation trends in bending and twisting motions and determined the actuator's workspace and maximum grasping force for a variety of objects with different shapes, materials, and sizes. Our findings suggest that PTBA is a promising candidate for advanced applications requiring intricate and bioinspired movements. This new design method offers a path toward achieving these goals. [ABSTRACT FROM AUTHOR]

Published

2023

38. 形状记忆合金变刚度软作动器设计.

Author

任旭, 杨书吉, 文浩, and 金栋平

Abstract

Copyright of Journal of Vibration, Measurement & Diagnosis is the property of Nanjing Hangkong Daxue and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

39. Moisture‐Driven Cellulose Actuators with Directional Motion and Programmable Shapes

Author

Shuzhen Wei and Tushar K. Ghosh

Subjects

moisture‐driven actuator, programmable motions, self‐walking actuator, soft actuator, Computer engineering. Computer hardware, TK7885-7895, Control engineering systems. Automatic machinery (General), TJ212-225

Abstract

The hygroscopic motion of plants has inspired the development of moisture‐activated soft actuators. These actuators driven by ambient moisture sources are of great research interest in robotics and self‐regulating textiles. However, these actuators often have slow motion and can only perform bending and twisting motions. Herein, a cellulose film‐based fast‐morphing and motion‐programmable soft actuator is presented that can generate caterpillar‐like movement. The cellophane films reported here bend almost instantaneously under changing humidity, with a large bending curvature, high repeatability, and negligible hysteresis. Different actuation modes are studied using both coated and uncoated cellophane films. The uncoated cellophane film can continuously move on a moist substrate through autonomous bending–rolling–flipping (or oscillating) cycles. A facile strategy is used here to control the rolling direction and facilitate the flipping motion by offsetting its center of gravity during deformation by adding appropriate weights on the end of the actuator. The coated cellophane film is used to fabricate motion‐programmable actuators through heat‐laminating. Several actuator structures are designed and fabricated and their diverse moisture‐induced motions are demonstrated.

Published

2024

40. Intrinsically Multistable Soft Actuator Driven by Mixed‐Mode Snap‐Through Instabilities

Author

Yichi Luo, Dinesh K. Patel, Zefang Li, Yafeng Hu, Hao Luo, Lining Yao, and Carmel Majidi

Subjects

multistability, soft actuator, snap‐through instability, Science

Abstract

Abstract Actuators utilizing snap‐through instabilities are widely investigated for high‐performance fast actuators and shape reconfigurable structures owing to their rapid response and limited reliance on continuous energy input. However, prevailing approaches typically involve a combination of multiple bistable actuator units and achieving multistability within a single actuator unit still remains an open challenge. Here, a soft actuator is presented that uses shape memory alloy (SMA) and mixed‐mode elastic instabilities to achieve intrinsically multistable shape reconfiguration. The multistable actuator unit consists of six stable states, including two pure bending states and four bend‐twist states. The actuator is composed of a pre‐stretched elastic membrane placed between two elastomeric frames embedded with SMA coils. By controlling the sequence and duration of SMA activation, the actuator is capable of rapid transition between all six stable states within hundreds of milliseconds. Principles of energy minimization are used to identify actuation sequences for various types of stable state transitions. Bending and twisting angles corresponding to various prestretch ratios are recorded based on parameterizations of the actuator's geometry. To demonstrate its application in practical conditions, the multistable actuator is used to perform visual inspection in a confined space, light source tracking during photovoltaic energy harvesting, and agile crawling.

Published

2024

41. Multifunctional Soft Actuator Based on Dielectric Liquid with Simultaneous Luminance and Weight Lifting Capabilities

Author

Dong Jin Han, Hea Ji Kim, and Byung Yang Lee

Subjects

dielectric elastomer actuator, electroactive, electroluminescent device, phosphor, soft actuator, Materials of engineering and construction. Mechanics of materials, TA401-492, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Abstract Soft robots require soft actuators for mobility and functionality. To integrate multiple functions in a limited space, researchers are developing multifunctional soft actuators with several functions integrated in one device. This study successfully demonstrates an electroluminescent (EL) soft actuator, a single device with both light‐emitting and actuating capabilities, using liquid dielectric and uniformly dispersed EL phosphor particles. EL phosphor particles are copper‐doped zinc sulfide (ZnS) particles doped with copper. The work is able to disperse the ZnS particles uniformly in the oil by coating the ZnS particles with silica, ensuring consistent luminescence across the device's active area. The performance of the soft actuator is notable, with a strain of 25% and a maximum EL intensity of 23 cd m−2 for a single actuator. When stacking multiple actuators, the intensity exceeds 29 cd m−2. The findings suggest that EL actuator devices will be valuable smart components for soft robots and interactive sensors. They can effectively represent external stimuli through color signals, expanding the capabilities of these systems.

Published

2024

42. Modelling of parallel and series inflatable actuators for sequential activation control

Author

Kiyohiro ARAKI, Diego PAEZ-GRANADOS, Modar HASSAN, and Kenji SUZUKI

Subjects

soft actuator, pneumatic actuator, control model, passive flow control, pneumatic flow model, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

Soft robotics technology has the potential for a wide range of applications; however, their implementation is hindered by the lack of accurate mathematical models and control methods. For example, a method to control multiple pneumatic inflatable actuators in turn by a passive mechanism has been proposed in a literature, but no mathematical model was presented to develop control laws for the system. This study proposes a mathematical model for the inflation characteristics of sequential soft actuators, and theoretical control law for passive sequential control of the inflation of multiple actuators by using flow resistors. The model is constructed from the physical requirements of the actuators based on fluid dynamics and thermodynamics. The study shows that the pressure change characteristics can be derived from the differential equations even for complex parallel and series circuits. The model mathematically represents the physical principle by which the actuators' inflation order depends on the relationship between changes in the input pressure and internal pressure with time. Experiments with real circuits of simple and complex layouts are presented. The actuators are inflated in sequence from a single air pressure source, and the mathematical model was able to describe the pressure and flow rate change characteristics at each point in the circuit.

Published

2024

43. Controlling a peristaltic robot inspired by inchworms

Author

Yanhong Peng, Hiroyuki Nabae, Yuki Funabora, and Koichi Suzumori

Subjects

McKibben artificial muscles, Bionics, Soft robotics, Soft actuator, Bio-inspired robotics, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Electronic computers. Computer science, QA75.5-76.95

Abstract

This study presents an innovative approach in soft robotics, focusing on an inchworm-inspired robot designed for enhanced transport capabilities. We explore the impact of various parameters on the robot’s performance, including the number of activated sections, object size and material, supplied air pressure, and command execution rate. Through a series of controlled experiments, we demonstrate that the robot can achieve a maximum transportation speed of 8.54 mm/s and handle loads exceeding 100 g, significantly outperforming existing models in both speed and load capacity. Our findings provide valuable insights into the optimization of soft robotic design for improved efficiency and adaptability in transport tasks. This research not only contributes to the advancement of soft robotics but also opens new avenues for practical applications in areas requiring precise and efficient object manipulation. The study underscores the potential of biomimetic designs in robotics and sets a new benchmark for future developments in the field.

Published

2024

44. Structural analysis of bending soft pneumatic network actuators for various designs using the finite element method

Author

V., Venkatesan, S., Shanmugam, and A.R., Veerappan

Published

2023

45. Locomotion control of a rigid-soft coupled snake robot in multiple environments

Author

Xuanyi Zhou, Yuqiu Zhang, Zhiwei Qiu, Zhecheng Shan, Shibo Cai, and Guanjun Bao

Subjects

Snake robot, Rigid–flexible coupled, Soft actuator, Motion gait analysis, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Electronic computers. Computer science, QA75.5-76.95

Abstract

The versatile motion capability of snake robots offers themselves robust adaptability in varieties of challenging environments where traditional robots may be incapacitated. This study reports a novel flexible snake robot featuring a rigid–flexible coupling structure and multiple motion gaits. To better understand the robot’s behavior, a bending model for the soft actuator is established. Furthermore, a dynamic model is developed to map the relationship between the input air pressure and joint torque, which is the model base for controlling the robot effectively. Based on the wave motion generated by the joint coupling direction function in different planes, multiple motion gait planning methods of the snake-like robot are proposed. In order to evaluate the adaptability and maneuverability of the developed snake robot, extensive experiments were conducted in complex environments. The results demonstrate the robot’s effectiveness in navigating through intricate settings, underscoring its potential for applications in various fields.

Published

2024

46. 变刚度柔性夹持装置的研究进展.

Author

陆玄鸣, 白 敬, and 王保升

Abstract

Compliant gripper not only retains the compliance of soft actuator, but also lifts up the gripping force efficiently. Compliant gripper with adjustable stiffness can be mainly classified into three categories according to different structure and actuation pattern including endoskeleton or exoskeleton based, jamming effect based, and low-melting alloy or polymer based. Flexible adjustment of stiffness cannot be realized by endoskeleton or exoskeleton-based gripper. For the two typical structures of jamming effect-based gripper, the range of stiffness adjustment of layer jamming based structure is larger than that of granular jamming-based structure; however, the structure of layer jamming based gripper is more complicated leading to more complicated fabrication process. The major defect of low-melting alloy or polymer-based gripper is its long movement response time as well as the required high insulativity and heat resistance for the actuator. By analyzing and concluding state-of-the-art of compliant gripper, the key questions which have been neglected in this research field are raised mainly including three aspects as follows: the lack of deep research in the theory of adjustable stiffness mechanism, the lack of research in the reliability and lifetime of compliant gripper with adjustable stiffness, and the lack of research in the application of compliant gripper with adjustable stiffness. [ABSTRACT FROM AUTHOR]

Published

2023

47. Self-sensing actuators with programmable actuation performances for soft robots.

Author

Jiao, ZhongDong, Ye, ZhiQiu, Zhu, PingAn, Tang, Wei, Yang, HuaYong, and Zou, Jun

Abstract

Designing soft robots that are able to perceive unstructured, dynamic environments and their deformations has been a long-term goal. Previously reported self-sensing soft actuators were mostly constructed via integrating separate actuators and sensors. The actuation performances and the sensing reliability are affected owing to the unmatched materials and weak connections. Realizing a seamless integration of soft actuators and sensors remains a grand challenge. Here, we report a fabrication strategy to endow soft actuators with sensing capability and programmable actuation performances. The foam inside the actuator functions as actuator and sensor simultaneously, effectively addressing the conformability and connection reliability issues that existed in current self-sensing actuators. The actuators are lightweight (a decrease of 58% in weight), powerful (lifting a load of 433 times of its own weight), and versatile (coupling twisting and contraction motions). Furthermore, the actuators are able to detect multiple physical stimuli with high reliability, demonstrating their exteroception and proprioception capability. Two self-sensing soft robotic prototypes, including a bionic bicep and a bionic neck, are constructed to illustrate their multifunctionality. Our study opens up new possibilities for the design of soft actuators and has promising potential in a variety of applications, ranging from human-robot interaction, soft orthotics, to wearable robotics. [ABSTRACT FROM AUTHOR]

Published

2023

48. Programmable and Self‐Healable Liquid Crystal Elastomer Actuators Based on Halogen Bonding.

Author

Guo, Hongshuang, Liang, Chen, Ruoko, Tero‐Petri, Meteling, Henning, Peng, Bo, Zeng, Hao, and Priimagi, Arri

Subjects

*LIQUID crystals, *ELASTOMERS, *ACTUATORS, *HALOGENS, *DENTAL adhesives, *PROOF of concept, *SOFT robotics

Abstract

Shape‐changing polymeric materials have gained significant attention in the field of bioinspired soft robotics. However, challenges remain in versatilizing the shape‐morphing process to suit different tasks and environments, and in designing systems that combine reversible actuation and self‐healing ability. Here, we report halogen‐bonded liquid crystal elastomers (LCEs) that can be arbitrarily shape‐programmed and that self‐heal under mild thermal or photothermal stimulation. We incorporate halogen‐bond‐donating diiodotetrafluorobenzene molecules as dynamic supramolecular crosslinks into the LCEs and show that these relatively weak crosslinks are pertinent for their mechanical programming and self‐healing. Utilizing the halogen‐bonded LCEs, we demonstrate proof‐of‐concept soft robotic motions such as crawling and rolling with programmed velocities. Our results showcase halogen bonding as a promising, yet unexplored tool for the preparation of smart supramolecular constructs for the development of advanced soft actuators. [ABSTRACT FROM AUTHOR]

Published

2023

49. MXene‐Based Soft Actuators with Multiresponse and Diverse Applications by a Simple Method.

Author

Xu, Mengjie, Li, Lin, Zhang, Wei, Ren, Zhen, Liu, Jinquan, Qiu, Changwen, Chang, Longfei, Hu, Ying, and Wu, Yucheng

Subjects

*ACTUATORS, *BIONICS, *PHOTOTHERMAL conversion, *MECHANICAL energy, *SMART devices, *ELECTRIC conductivity

Abstract

Smart actuators that can convert external energy stimuli into mechanical energy output have great potential in industrial, biomedical, and military applications. However, the existed disadvantage such as complex fabrication process, single stimulus source, and the requirement of artificial energy restrict their further development. Herein, a MXene/polyethylene (PE)‐based soft actuator with multistimulus response and the ability to be driven by natural sunlight and human humidity is proposed through a simple method. Owing to the excellent electrical conductivity, high photothermal conversion capability, and surface hydrophilicity of MXene, the MXene/PE actuator exhibits rapid and large bending deformation in response to external multistimuli such as light, electricity, heat, and humidity. Owing to the simple preparation, and anisotropic, tailorable and programmable properties of the MXene/PE actuator, a soft robot that can crawl directionally under light conditions is constructed. In addition, based on the high sensitivity response of the actuator to light and humidity, smart clothing that can generate reversible bending deformation under natural sunlight as well as sweat conditions is developed. These results provide a new inspiration for the design of high‐performance soft actuators with multistimulus response, and demonstrate the potential applications of the MXene/PE actuators in smart devices, bionic robots, and wearable clothing. [ABSTRACT FROM AUTHOR]

Published

2023

50. Analysis of Mechanical Characteristics of Stereolithography Soft-Picking Manipulator and Its Application in Grasping Fruits and Vegetables.

Author

Zhuang, Yu, Guo, Yanling, Li, Jian, Shen, Liuyang, Wang, Zhentao, Sun, Maoxiang, and Wang, Jinfeng

Subjects

*STEREOLITHOGRAPHY, *FRUIT, *FINITE element method, *MANUFACTURING processes

Abstract

Aiming at the issues of complex manufacturing processes and unstable bonding after individual manufacturing in current soft manipulator forming methods, this study investigated the mechanical characteristics of a pneumatically driven soft-picking manipulator formed by the stereolithography (SLA) process and evaluated its application in grasping fruits and vegetables. The soft-picking manipulator mainly consists of three soft actuators designed in an integrated folded structure to simplify the manufacturing process compared to a conventional one. A finite element model (FEM) of the actuator was created to analyze the bending deformation capability under different pressures, and the simulated results match well with the experimental ones. Under the 60 kPa pressure, the maximum grasping force for fingertip- and envelope-grasping is 3.94 N and 8.87 N, respectively. The grasping tests of several fruits and vegetables of different weights and sizes by the soft manipulator were examined, and the results showed that the manipulator has strong adaptability. For spherical and elongated fruits and vegetables, the completion time for grasping is approximately 8.59 ± 1.26 s and 10.99 ± 1.79 s, respectively, and for irregularly shaped ones, the pressure is increased accordingly to the increased grasping stability. This study may provide a basis for the development of a soft manipulator for sorting and picking fruits and vegetables. [ABSTRACT FROM AUTHOR]

Published

2023