Vertical contact position detection and grasping force monitoring for micro-gripper applications

This paper presents a novel fingertip system with a two-layer structure for robotic hands. The outer part of the structure consists of a rubber bag filled with fluid, called the “fluid fingertip,” while the inner part consists of a rigid link mechanism called a “microgripper.” The fingertip thus is a rigid/fluid hybrid system. The fluid fingertip is effective for grasping delicate objects, that is, it can decrease the impulsive force upon contact, and absorb uncertainties in object shapes and contact force. However, it can only apply a small grasping force such that holding a heavy object with a robotic hand with fluid fingertips is difficult. Additionally, contact uncertainties including inaccuracies in the contact position control cannot be avoided. In contrast, rigid fingertips can apply considerable grasping forces and thus grasp heavy objects effectively, although this makes delicate grasping difficult. To maintain the benefits of the fluid fingertip while overcoming its disadvantages, the present study examines passively operable microgripper-embedded fluid fingertips. Our goal is to use the gripper to enhance the positioning accuracy and increase the grasping force by adding geometrical constraints to the existing mechanical constraints. Grasping tests showed that the gripper with the developed fingertips can grasp a wide variety of objects, both fragile and heavy.

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A Microassembly System with Coaxial Alignment Function

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.487.678 ◽

2014 ◽

Vol 487 ◽

pp. 678-681 ◽

Cited By ~ 4

Author(s):

Xin Ye ◽

Jun Gao ◽

Zhi Jing Zhang

Keyword(s):

Image Processing ◽

Vision System ◽

Processing Technique ◽

Image Processing Technique ◽

Laser Ranging ◽

Micro Gripper ◽

Position Detection ◽

Assembly Accuracy ◽

System Module ◽

Special Prism

This paper proposes a microassembly system with coaxial alignment function (MSCA). The system is comprised of vision system module, micro gripper module, motion module, and laser ranging module. The image processing technique is applied in the position detection procedure. A special prism is integrated in this system to capture the two parts simultaneously. The assembly accuracy of the system can reach micrometer lever.

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Vacuum Switch Contact Position Detection Based on Labview

IOP Conference Series Materials Science and Engineering ◽

10.1088/1757-899x/562/1/012160 ◽

2019 ◽

Vol 562 ◽

pp. 012160

Author(s):

Liting Ma ◽

Zhengqi Wang ◽

Chong Su

Keyword(s):

Vacuum Switch ◽

Position Detection ◽

Contact Position

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A new robot skin for force and position detection

Industrial Robot the international journal of robotics research and application ◽

10.1108/ir-07-2014-0369 ◽

2014 ◽

Vol 41 (6) ◽

pp. 534-542 ◽

Cited By ~ 3

Author(s):

Haibin Wu ◽

Yixian Su ◽

Jinjin Shi ◽

Jinwen Li ◽

Jinhua Ye

Keyword(s):

Contact Force ◽

Low Cost ◽

Force Sensor ◽

Viscoelastic Layer ◽

Position Sensor ◽

Content Type ◽

Position Detection ◽

Sensor Module ◽

Contact Position ◽

Robot Skin

Purpose – The aim of the research is to achieve a robot skin which is easy to use, and can detect both position and force interacted between robot and environments. Design/methodology/approach – The new type of robot skin proposed in this paper includes two functional modules – contact position sensor and contact force sensor. The contact position sensor module is based on the resistor divider principle, which consists of two perpendicular conductive fiber layers and insulated dot spacer between them. The contact force sensor module is based on capacitance change theory, which consists of two soft conductive plates and a viscoelastic layer between them. By combining the two modules, the soft robot skin was designed. Findings – Simulation and experiment results demonstrate that the proposed robot skin design is feasible and effective enough to sense contact position and contact force simultaneously. Practical implications – This robot skin is low-cost and easy to make and use, which provides safety solutions for most of the robot. Originality/value – For the first time, an integrated robot skin which can get contact position and force information simultaneously is designed. Unlike general tactile sensor matrices, this robot skin has only six leads. Furthermore, the number of leads does not increase with the enlarging of sensor area. Soft and simple structure of the robot skin makes it possible to cover any region of the robot body.

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A Flexible Tactile Sensor with Irregular Planar Shape Based on Uniform Electric Field

Sensors ◽

10.3390/s18124445 ◽

2018 ◽

Vol 18 (12) ◽

pp. 4445 ◽

Cited By ~ 6

Author(s):

Youzhi Zhang ◽

Jinhua Ye ◽

Haomiao Wang ◽

Shuheng Huang ◽

Haibin Wu

Keyword(s):

Electric Field ◽

Tactile Sensor ◽

Uniform Electric Field ◽

Conductive Layer ◽

Conducting Plane ◽

Ito Film ◽

Position Detection ◽

Conductive Line ◽

Plane Shape ◽

Contact Position

Tactility is an essential perception for intelligent equipment to acquire external information. It can improve safety and performance during human-machine interactions. Based on the uniqueness theorem of the electrostatic field, a novel flexible film tactile sensor that can detect contact position and be made into any plane shape is proposed in this paper. The tactile sensor included an indium tin oxide (ITO) film, which was uniformly coated on the polyethylene terephthalate (PET) substrate. A specially designed strong conductive line was arranged along the edge of the flexible ITO film, which has weak conductivity. A bias excitation was applied to both ends of the strong conductive line. Through the control of the shape of the strong conductive line, a uniform electric field can be constructed in the whole weak conductive plane. According to the linear relationship between position and potential in the uniform electric field, the coordinate of the contact position can be determined by obtaining the potential of the contact point in the weak conducting plane. The sensor uses a three-layer structure, including an upper conductive layer, an intermediate isolation layer, and a lower conductive layer. A tactile sensor sample was fabricated. The experiment results showed that the principle of the tactile sensor used for the contact position detection is feasible and has certain precision of position detection. The sensor has good flexibility, and can be made into any plane shape, and has only four wires. It is capable of covering large areas of robot arms, and provides safety solutions for most robots.

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