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Francisco Yumbla,Meseret Abayebas,June-Sup Yi,Jeongmin Jeon,Hyungpil Moon 한국정밀공학회 2021 International Journal of Precision Engineering and Vol.22 No.4
In this study, we propose the use of a distribute manipulator for repositioning and alignment process of cable connectors to obtain the accurate pose of the connector. The accurate pose is critical for a successful mating process in wiring harness assembly tasks. Conventional actuators such as robotics grippers rely on active manipulations; for example, they uses belts and, rollers for the repositioning of the cables, and others such as parallel grippers used directly to grasping the connector. However, all these systems need a lot of many pieces and mechanisms to manipulate the cables or high accuracy control process for grasping the connector in a certain position, thus increasing the difficulty when the cables and connectors are smaller. Therefore, we present a vibrating plate to perform in-hand manipulation to reposition the cable and align the connector. We modeled and analyzed the relationship between the vibration frequency and the velocity of the cable. Furthermore, we experimentally show that the moving velocity of the cable is proportional to the vibration system frequency, and the proposed vibrating plate can reliably move the connector to the desired pose.
Analysis of the mating process of plug-in cable connectors for the cable harness assembly task
Francisco Yumbla,June-Sup Yi,Meseret Abayebas,Hyungpil Moon 제어로봇시스템학회 2019 제어로봇시스템학회 국제학술대회 논문집 Vol.2019 No.10
In this paper, we analyze the mating process of plug-in cable connectors for wiring harness assembly tasks by showing the challenging difficulties around this task including the possible solutions: a new gripper design concept and analyzing the permissible error range (tolerance) between the connectors. For wiring harness assembly tasks, knowing the accurate pose of the grasped cable connector in the gripper is very critical for the successful mating process, and conventional mating processes rely on force control or mechanical passive compliance. Nowadays, we notice that collaboration robotic manipulators or small size industrial robotic manipulators attain high accuracy and repeatability levels (sub-millimeter) thus demonstrate very precise position control capacities. Using those capacities of the robotic manipulator, we analyze the permissible error range of connector for the mating process. For that reason, we propose a new design of a gripper for an accurate alignment and holding of the position between the cable and the gripper. Therefore, if we know the exact position of the connector in reference to the gripper, and the tolerance between the connectors is larger than error position of the robot arm, the mating process can be achieved by just using position control of conventional industrial robots.
Nabih Pico,Hong-ryul Jung,Juan Medrano,Meseret Abayebas,Dong Yeop Kim,황정훈,Hyungpil Moon 대한기계학회 2022 JOURNAL OF MECHANICAL SCIENCE AND TECHNOLOGY Vol.36 No.2
The objective of this work is to control a delivery robot equipped with a passive bogie that can successfully climb up steps of various sizes and move on uneven terrain in outdoor environments. The kinematic model of a six-wheel mobile robot is described in detail. Jacobian matrices and inverse kinematics are obtained to get the velocity of each wheel based on the desired velocity of the robot center of mass in conjunction with the terrain information obtained by the onboard sensors according to the contact angle estimation between the wheel and ground. A slip control is implemented based on slip ratio to adjust the wheel velocity when the slip is detected. Simulation and experimental results verify the effectiveness of the approach that enables the robot autonomously climbing up on different steps and uneven terrain.
Nabih Pico,Eui-Chan Kim,Sang-Hyeon Park,Meseret Abayebas Tadese,Huy Nguyen Tran,Beomjoon Lee,Hyungpil Moon 제어로봇시스템학회 2022 제어로봇시스템학회 국제학술대회 논문집 Vol.2022 No.11
Wheeled robots are involved in different applications due to their adaptability to different terrains. The stability of the robot is related to the permanent contact of the wheels with the ground. This paper presents the method to recognize the geometry terrains in real-time when the wheel has contact at one or multiple contact points with the soil by using laser scanning sensors and measuring the contact angle between the wheel-ground. Furthermore, the robot can recognize when its wheel loses contact with the terrain. Thus, we can create a proper robot control by obtaining the Jacobian matrix and its inverse related to the terrain information. In consequence, the robot can overcome diverse terrains and move safely. The method is validated in experimental results when the six-wheeled robot recognizes a rocky terrain and a slope with a step.