Development of a Three-Finger Adaptive Robotic Gripper to Assist Activities of Daily Living

• Published in: Designs Vol. 8; no. 2; p. 35
• Main Authors: Rahman, Mahbubur, Shahria, Tanzil, Sunny, Samiul Haque, Khan, Mahafuzur Rahaman, Islam, Emroze, Swapnil, Asif Al Zubayer, Bedolla-Martínez, David, Rahman, Mohammad H
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 01.04.2024
• Subjects: 3D printing; Activities of daily living; Adaptability; ADLs; assistive grippers; Caregivers; Centroids; Design; Design and construction; Fingers; Grippers; Load tests; Methods; Polyethylene terephthalate; Quality of life; Robot arms; robotic hands; Robotics; Self-help devices for the disabled; Service robots; Technology application; Three dimensional printing; Usability; Usability testing; Wheelchairs; United States; ADLs; robotic hands; assistive grippers
• ISSN: 2411-9660; 2411-9660
• DOI: 10.3390/designs8020035

A significant number of individuals in the United States use assistive devices to enhance their mobility, and a considerable portion of those who depend on such aids require assistance from another individual in performing daily living activities. The introduction of robotic grippers has emerged as a transformative intervention, significantly contributing to the cultivation of independence. However, there are few grippers in the fields, which help with mimicking human hand-like movements (mostly grasping and pinching, with adoptive force control) to grasp and carry objects. Additionally, the data are not available even on how many Activities of Daily Living (ADL) objects they can handle. The goal of the research is to offer a new three-fingered gripper for daily living assistance, which can both grasp and pinch with adaptive force, enabling the capabilities of handling wide-ranging ADL objects with a minimal footprint. It is designed to handle 90 selective essential ADL objects of different shapes (cylindrical, irregular, rectangular, and round), sizes, weights, and textures (smooth, rough, bumpy, and rubbery). The gripper boasts a meticulously engineered yet simple design, facilitating seamless manufacturing through 3D printing technology without compromising its operational efficacy. The gripper extends its functionality beyond conventional grasping, featuring the capability to pinch (such as holding a credit card) and securely hold lightweight objects. Moreover, the gripper is adaptable to grasping various objects with different shapes and weights with controlled forces. In evaluation, the developed gripper went through rigorous load tests and usability tests. The results demonstrated that the users picked and placed 75 objects out of 90 daily objects. The gripper held and manipulated objects with dimensions from 25 mm to 80 mm and up to 2.9 kg. For heavy-weight objects (like books) where the centroid is far apart from the grasping areas, it is difficult to hold them due to high torque. However, objects' textures have no significant effect on grasping performance. Users perceived the simplicity of the gripper. Further investigation is required to assess the utility and longevity of grippers. This study contributes to developing assistive robots designed to enhance object manipulation, thereby improving individuals' independence and overall quality of life.