A Crawler Climbing Robot Integrating Electroadhesion and Electrostatic Actuation
Previous electroadhesive climbing robots generally employed typical electromagnetic motors, which spoiled some of the advantages of electroadhesion such as it being light, thin and flexible. To improve these, an integration of electrostatic actuation and adhesion was utilized in this work. By using...
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| Format: | Article |
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SAGE Publishing
2014-12-01
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| Series: | International Journal of Advanced Robotic Systems |
| Online Access: | https://doi.org/10.5772/59118 |
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doaj-527d9a1379a54c2aa3c061344f026c212020-11-25T03:28:47ZengSAGE PublishingInternational Journal of Advanced Robotic Systems1729-88142014-12-011110.5772/5911810.5772_59118A Crawler Climbing Robot Integrating Electroadhesion and Electrostatic ActuationHongqiang Wang0Akio Yamamoto1Toshiro Higuchi2 The Department of Precision Engineering, The University of Tokyo, Tokyo, Japan The Department of Precision Engineering, The University of Tokyo, Tokyo, Japan The Department of Precision Engineering, The University of Tokyo, Tokyo, JapanPrevious electroadhesive climbing robots generally employed typical electromagnetic motors, which spoiled some of the advantages of electroadhesion such as it being light, thin and flexible. To improve these, an integration of electrostatic actuation and adhesion was utilized in this work. By using FEM analyses, the present paper analysed the effect of design parameters on adhesive and driving forces respectively, and examined the possible interference between electrostatic actuation and adhesion inside the integration. Then this article discussed the driving force, payload capacity and torque balance of the robot with the integration. Based on these analyses, we designed and fabricated a lightweight (94 g) and low-height (15 mm) prototype with electrode films made by screen printing. Experiments on the prototype demonstrated that it can adhere to a vertical wall stably and move at a maximum speed of 35.3 mm/s.https://doi.org/10.5772/59118 |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Hongqiang Wang Akio Yamamoto Toshiro Higuchi |
| spellingShingle |
Hongqiang Wang Akio Yamamoto Toshiro Higuchi A Crawler Climbing Robot Integrating Electroadhesion and Electrostatic Actuation International Journal of Advanced Robotic Systems |
| author_facet |
Hongqiang Wang Akio Yamamoto Toshiro Higuchi |
| author_sort |
Hongqiang Wang |
| title |
A Crawler Climbing Robot Integrating Electroadhesion and Electrostatic Actuation |
| title_short |
A Crawler Climbing Robot Integrating Electroadhesion and Electrostatic Actuation |
| title_full |
A Crawler Climbing Robot Integrating Electroadhesion and Electrostatic Actuation |
| title_fullStr |
A Crawler Climbing Robot Integrating Electroadhesion and Electrostatic Actuation |
| title_full_unstemmed |
A Crawler Climbing Robot Integrating Electroadhesion and Electrostatic Actuation |
| title_sort |
crawler climbing robot integrating electroadhesion and electrostatic actuation |
| publisher |
SAGE Publishing |
| series |
International Journal of Advanced Robotic Systems |
| issn |
1729-8814 |
| publishDate |
2014-12-01 |
| description |
Previous electroadhesive climbing robots generally employed typical electromagnetic motors, which spoiled some of the advantages of electroadhesion such as it being light, thin and flexible. To improve these, an integration of electrostatic actuation and adhesion was utilized in this work. By using FEM analyses, the present paper analysed the effect of design parameters on adhesive and driving forces respectively, and examined the possible interference between electrostatic actuation and adhesion inside the integration. Then this article discussed the driving force, payload capacity and torque balance of the robot with the integration. Based on these analyses, we designed and fabricated a lightweight (94 g) and low-height (15 mm) prototype with electrode films made by screen printing. Experiments on the prototype demonstrated that it can adhere to a vertical wall stably and move at a maximum speed of 35.3 mm/s. |
| url |
https://doi.org/10.5772/59118 |
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AT hongqiangwang acrawlerclimbingrobotintegratingelectroadhesionandelectrostaticactuation AT akioyamamoto acrawlerclimbingrobotintegratingelectroadhesionandelectrostaticactuation AT toshirohiguchi acrawlerclimbingrobotintegratingelectroadhesionandelectrostaticactuation AT hongqiangwang crawlerclimbingrobotintegratingelectroadhesionandelectrostaticactuation AT akioyamamoto crawlerclimbingrobotintegratingelectroadhesionandelectrostaticactuation AT toshirohiguchi crawlerclimbingrobotintegratingelectroadhesionandelectrostaticactuation |
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1724582906847821824 |