Design of Track-Based Climbing Robots Using Dry Adhesives

2017 ◽  
Author(s):  
Matthew W. Powelson ◽  
Stephen L. Canfield
Keyword(s):  
Contact Surface ◽  
Climbing Robot ◽  
Complete Model ◽  
Climbing Robots ◽  
Dry Adhesive ◽  
Full Contact ◽  
Robot Systems ◽  
Dry Adhesives ◽  
Adhesion Model ◽  
Track Surface

This paper focuses on the design of track-type climbing robots using dry adhesives to generate tractive forces between the robot and climbing surface to maintain equilibrium while in motion. When considering the design of these climbing robots, there are two primary elements of focus: the adhesive mechanisms at the track-surface interface and the distribution of these forces over the full contact surface (the tracks). This paper will present an approach to integrate a generic adhesion model and a track suspension system into a complete model that can be used to design general climbing robot systems utilizing a broad range of dry adhesive technologies.

Integrating Dry Adhesives and Compliant Suspension for Track-Type Climbing Robots

2019 ◽  
Author(s):  
Matthew W. Powelson ◽  
Wesley A. Demirjian ◽  
Stephen L. Canfield
Keyword(s):  
Design Procedure ◽  
Light Weight ◽  
Adhesion Forces ◽  
Climbing Robots ◽  
Adhesive Material ◽  
Full Contact ◽  
Dry Adhesives ◽  
Track Surface ◽  
Vehicle Size ◽  
Adhesive Forces

Abstract Climbing robots using dry adhesives in the literature typically exhibit minimal payload and are considered useful for tasks involving light-weight sensors, such as surveillance or exploration. Existing designs demonstrate small payloads primarily because they either employ minimal adhesion area or fail to distribute the adhesion forces over the adhering region of these robots. Further, existing design methods do not demonstrate scalability of payload-to-vehicle size and, in fact, indicate that such robots are not scalable. However, dry adhesives routinely demonstrate adhering pressures in the range of 20–50 kPa which suggests that a 30 × 30 cm robot could have a payload on the order of 20–50 kg. This paper presents a step-by-step approach for designing track-type dry adhesive climbing robots to achieve high payloads. The aforementioned design steps are then experimentally validated, showing that high payloads should theoretically be possible when using dry adhesives to climb. By integrating a general adhesion model with a suspension system, this design procedure can be used to design climbing robots that distribute the payload over a large adhesive area. The models behind the design procedure (developed previously [1] but summarized here) simultaneously consider the behavior of both the adhesive material at the track-surface interface and the distribution of the adhesive forces over the full contact surface. When each of these criteria are satisfied, track-type climbing robots can be designed to carry high payloads, thus enabling applications previously thought to be impossible.

Design of Track-Type Climbing Robots Using Dry Adhesives and Compliant Suspension for Scalable Payloads

2020 ◽  
Vol 12 (3) ◽  
Author(s):  
Wesley Demirjian ◽  
Matthew Powelson ◽  
Stephen Canfield
Keyword(s):  
Design Procedure ◽  
Adhesive Tape ◽  
Adhesion Forces ◽  
Climbing Robots ◽  
Full Contact ◽  
Dry Adhesives ◽  
Track Surface ◽  
Small Robot ◽  
Vehicle Size ◽  
Robotic Applications

Abstract Climbing robots offer advanced motion capabilities to perform inspection, manufacturing, or rescue tasks. Climbing requires the robot to generate adhering forces with the climbing surface. Dry adhesives present a category of adhesion that could be advantageous for climbing a variety of surfaces. Current literature shows climbing robots using dry adhesives typically exhibit minimal payloads and are considered useful for tasks involving lightweight sensors, such as surveillance. However, dry adhesives routinely demonstrate adhering pressures in the range of 20–50 kPa, suggesting that a small robot (3 × 30 cm footprint, for example) could theoretically have a significant payload (in the order of 18–45 kg). Existing designs demonstrate small payloads primarily because they fail to distribute the adhesion forces over the entire adhering region available to these robots. Further, existing design methods do not demonstrate scalability of payload-to-vehicle size but, in fact, indicate such robots are not scalable (Gorb et al., 2007, “Insects Did It First: A Micropatterned Adhesive Tape for Robotic Applications,” Bioinspir. Biomim., 2(4), pp. 117–125.). This paper presents a design procedure for track-type climbing robots that use dry adhesives to generate tractive forces and a passive suspension that distributes the climbing loads over the track in a preferred manner. This procedure simultaneously considers the behavior of both the adhesive material at the track-surface interface and the distribution of the adhesive forces over the full contact surface. The paper will demonstrate that dry-adhesive-based climbing robots can be designed to achieve high payloads and are scalable, thus enabling them to be used in applications previously thought to be impossible with dry adhesives.

scholarly journals A Maugis–Dugdale cohesive solution for adhesion of a surface with a dimple

2017 ◽  
Vol 14 (127) ◽  
pp. 20160996 ◽  
Author(s):  
A. Papangelo ◽  
M. Ciavarella
Keyword(s):  
Adhesive System ◽  
Theoretical Strength ◽  
Air Entrapment ◽  
Qualitative Comparison ◽  
Cohesive Model ◽  
Full Contact ◽  
Dry Adhesives ◽  
Simple Equations ◽  
Scale Roughness ◽  
Tabor Parameter

We study the adhesion of a surface with a ‘dimple’ which shows a mechanism for a bi-stable adhesive system in surfaces with spaced patterns of depressions, leading to adhesion enhancement, high dissipation and hysteresis. Recent studies were limited mainly to the very short range of adhesion (the so-called JKR regime), while we generalize the study to a Maugis cohesive model. A ‘generalized Tabor parameter’, given by the ratio of theoretical strength to elastic modulus, multiplied by the ratio of dimple width to depth has been found. It is shown that bistability disappears for generalized Tabor parameter less than about 2. Introduction of the theoretical strength is needed to have significant results when the system has gone in full contact, unless one postulates alternative limits to full contact, such as air entrapment, contaminants or fine scale roughness. Simple equations are obtained for the pull-off and for the full contact pressure in the entire set of the two governing dimensionless parameters. A qualitative comparison with results of recent experiments with nanopatterned bioinspired dry adhesives is attempted in light of the present model.

Highly flexible and self-adaptive dry adhesive end-effectors for precision robotics

Soft Matter ◽  
2019 ◽  
Vol 15 (29) ◽  
pp. 5827-5834 ◽  
Author(s):  
Sung Ho Lee ◽  
Insol Hwang ◽  
Bong Su Kang ◽  
Hoon Eui Jeong ◽  
Moon Kyu Kwak
Keyword(s):  
Structural Design ◽  
Dry Adhesive ◽  
Dry Adhesives ◽  
Adhesion Performance ◽  
End Effectors ◽  
Self Adaptive

For wide application of dry adhesives, we have realized the improvement of adhesion performance on inclined target substrate through structural design in macroscale. The improved dry adhesives exhibit stable properties in inclined targets.

scholarly journals A Pressing Attachment Approach for a Wall-Climbing Robot Utilizing Passive Suction Cups

Robotics ◽  
2020 ◽  
Vol 9 (2) ◽  
pp. 26
Author(s):  
Dingxin Ge ◽  
Yongchen Tang ◽  
Shugen Ma ◽  
Takahiro Matsuno ◽  
Chao Ren
Keyword(s):  
Experimental Test ◽  
Experimental Results ◽  
Climbing Robot ◽  
Guide Rail ◽  
Test Bed ◽  
Climbing Robots ◽  
Pressing Method ◽  
Suction Cup ◽  
Suction Cups

This paper proposes a pressing method for wall-climbing robots to prevent them from falling. In order to realize the method, the properties of the utilized suction cup are studied experimentally. Then based on the results, a guide rail is designed to distribute the attached suction cup force and implement the pressing method. A prototype of a wall-climbing robot that utilizes passive suction cups and one motor is used to demonstrate the proposed method. An experimental test-bed is designed to measure the force changes of the suction cup when the robot climbs upwards. The experimental results validate that the suction cup can completely attach to the surface by the proposed method, and demonstrate that the robot can climb upwards without falling.

A Three-Row Opposed Gripping Mechanism With Radial Configuration for Wall-Climbing Robots

2019 ◽  
Author(s):  
Chao Xie ◽  
Xuan Wu ◽  
Xiaojie Wang
Keyword(s):  
Rough Surface ◽  
Motor Drives ◽  
Rough Wall ◽  
Climbing Robot ◽  
Climbing Robots ◽  
Single Motor

Abstract This paper presents a three-row opposed gripping mechanism with radial configuration for wall-climbing robots inspired by the structure of the gripper of LEMUR IIB. The mechanism builds upon a kind of microspines for climbing robots. This work utilizes an opposed spoke configuration with 3 rows of 31 microspines on each linkage array, splayed around a central bracket. A single motor drives the 3 linkage arrays by a set of gears to achieve attachment and detachment procedures, and the trajectory of each linkage array tip makes the miniature spines easy to penetrate in and pull off the surfaces. The mechanism designed as a foot of climbing robots can vertically resist at least 1kg of load on rough surface. The findings provide a foundation for constructing a system for a rough-wall-climbing robot.

scholarly journals Optimal Collision-Free Grip Planning for Biped Climbing Robots in Complex Truss Environment

2018 ◽  
Vol 8 (12) ◽  
pp. 2533 ◽  
Author(s):  
Shichao Gu ◽  
Haifei Zhu ◽  
Hui Li ◽  
Yisheng Guan ◽  
Hong Zhang
Keyword(s):  
Path Planning ◽  
Optimization Model ◽  
Mathematic Model ◽  
Planning Method ◽  
Climbing Robot ◽  
Climbing Robots ◽  
Kinematic Constraint ◽  
Anchor Points ◽  
Effectiveness And Efficiency ◽  
Original Point

Biped climbing robots (BiCRs) can overcome obstacles and perform transition easily thanks to their superior flexibility. However, to move in a complex truss environment, grips from the original point to the destination, as a sequence of anchor points along the route, are indispensable. In this paper, a grip planning method is presented for BiCRs generating optimal collision-free grip sequences, as a continuation of our previous work on global path planning. A mathematic model is firstly built up for computing the operational regions for negotiating obstacle members. Then a grip optimization model is proposed to determine the grips within each operational region for transition or for obstacle negotiation. This model ensures the total number of required climbing steps is minimized and the transition grips are with good manipulability. Lastly, the entire grip sequence satisfying the robot kinematic constraint is generated by a gait interpreter. Simulations are conducted with our self-developed biped climbing robot (Climbot), to verify the effectiveness and efficiency of the proposed methodology.

The Structure Design of Gait Pole Climbing Robot

2015 ◽  
Vol 740 ◽  
pp. 171-174
Author(s):  
Xiao Jin Fu ◽  
Zhao Yang Sun ◽  
Ran Zhao ◽  
Jian Cheng Yin
Keyword(s):  
Slow Motion ◽  
Structure Design ◽  
The Body ◽  
Industrial Robots ◽  
Climbing Robot ◽  
Climbing Robots ◽  
Robot Arms ◽  
Maintenance Work ◽  
Industrial Software

The theory of gait is one of walking ways which is efficient, fast and stable in a variety of industrial robots, offering a structure of climbing robots in a way of gait and climbing with the gait motion in paper. Through the results of analysis by various industrial software, the presented structure of climbing robots which is composed of two terminal parts and two robot arms that is the part of pedestal and climbing mechanism. In the process of climbing, realizing gripping, Swing work, turning work, an orderly motion and get to the aimed place finally through alternate between the upper and lower part of the body by the control of SCM. The presented method has not only improved many problems like complicated climbing structure, controlling rough, slow-motion and unable thronging obstacles, but also accomplished the subsequent operations like tools delivering, pole testing, clearing, maintenance work, furthermore, there has more comprehensive benefits.

Contacting Surface-Transfer Control for Reconfigurable Wall-Climbing Robot Gunryu III

2013 ◽  
Vol 25 (3) ◽  
pp. 439-448 ◽  
Author(s):  
Woosub Lee ◽  
◽  
Shigeo Hirose ◽  
Keyword(s):  
High Stability ◽  
Control Strategies ◽  
High Mobility ◽  
Climbing Robot ◽  
Climbing Robots ◽  
Simulation Experiments ◽  
Contact Mode ◽  
Magnetic Device ◽  
New Type ◽  
Motion Strategy

For the wall-climbing robots, high mobility as well as stability on the surface of the walls are the most important features. To achieve these features, this paper proposes a new type of reconfigurable arm equipped multi module wall-climbing robot named Gunryu III. Gunryu III has the potential ability to generate high stability and high mobility by using its arm to connect multiple mobile modules together and a magneticforce-changeable adsorption device. One of the important motions of the reconfigurable wall-climbing robot Gunryu III is surface-transfer motion, which is to change from one moving surface to another, such as from floor to wall and wall to ceiling. In this paper, we propose a new surface-transfer motion strategy named Contact Mode. It is to make surface-transfer motion by contacting some part of the moving module to one of the surfaces. As for the Contact Mode surfacetransfer motion, we first conduct several fundamental discussions, such as the five basic types of motion, conditions for making contact between the mobile module and the wall, effective way of using the magnetic device and two criteria of the evaluation. We then quantitatively evaluate the effectiveness of the proposed Contact Mode surface-transfer motion using simulation experiments, and clarify basic optimized control strategies.

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