In this study, we designed and manufactured a 3-axis force sensor for an intelligent gripper that safely grips an unknown object. The 3-axis force sensor consists of an Fx force sensor, an Fy force sensor, and an Fz force sensor in one body, and is manufactured by attaching a strain gauge. The characteristics evaluation showed that the rated output error was within 0.2, the nonlinearity error was within 0.05, and the reproducibility error was within 0.06%. Therefore, the 3-axis force sensor designed and manufactured in this study can be used to measure weight and control the force used to grip an unknown object by attaching it to the intelligent gripper.
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Control Method of Electric Gripper Using Current Control System Ji-Hye Min, Gab-Soon Kim Journal of the Korean Society for Precision Engineering.2023; 40(9): 725. CrossRef
Development of an Intelligent Gripper that Determines the Gripping Force According to the Weight of the Object Han-Sol Kim, Gab-Soon Kim International Journal of Precision Engineering and Manufacturing.2023; 24(12): 2259. CrossRef
We describe the design and fabrication of a three-axis force sensor with parallel plate beams (PPBs) for measuring the force of a patient’s thigh in a wearable walking robot. The thigh link three-axis force sensor is composed of Fx force sensor, Fy force sensor, Fz force sensor and a pulley, which detect the x, y and z direction forces, respectively. The threeaxis force sensor was designed using the Finite Element Method (FEM), and manufactured using strain-gages. Experiments to evaluate the characteristics of the three-axis force sensor were carried out. The results of the characteristics experiment indicate that the repeatability error and the non-linearity of the three-axis force sensor was less than 0.04%, and the results for calibration showed that the errors of the sensor was less than 0.1%. Therefore, the fabricated thigh link three-axis force sensor can be used to measure the patient’s thigh force of the wearable walking robot.
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Development of 5-axis Force/Moment Sensor of Gripper to Recognize the Position of an Object within the Gripper Jin Kim, Gab-Soon Kim Journal of the Korean Society for Precision Engineering.2023; 40(5): 415. CrossRef
Development of a 3-Axis Force Sensor for an Intelligent Gripper that Safely Grips Unknown Objects Han-Sol Kim, Gab-Soon Kim Journal of the Korean Society for Precision Engineering.2022; 39(3): 193. CrossRef
Development of Gripping Force Sensor for a Spindle Tool of BT50 Dae-Geon Lee, Gab-Soon Kim JOURNAL OF SENSOR SCIENCE AND TECHNOLOGY.2021; 30(1): 42. CrossRef
Design of Integrated Ankle Torque Sensor and Mechanism for Wearable Walking Aid Robot Han-Sol Kim, Gab-Soon Kim Journal of the Korean Society for Precision Engineering.2020; 37(9): 667. CrossRef
Design and Manufacture of Calf-Link with Knee Joint Torque Sensor for a Tendon-Driven Walking Assistant Robot Jun-Hwan An, Gab Soon Kim Journal of the Korean Society for Precision Engineering.2019; 36(11): 1009. CrossRef
Development of Hip Joint Torque Sensor for Measuring Hip Rotation Force of Walking Assist Robot of Leg Patient Jae-Hoon Park, Gab Soon Kim Journal of the Korean Society for Precision Engineering.2018; 35(8): 753. CrossRef
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