Design and Development of a Robotic Exoskeleton Device for use in Glove Boxes - 20374
Conference
·
OSTI ID:23028003
- Florida International University's Applied Research Center (United States)
- Florida International University's Electrical and Computer Engineer Department (United States)
Glovebox operators in nuclear facilities often operate under radioactive environment and typically perform monotonous, dull and repetitive work. This can result in muscle fatigue leading to increased levels of accidents. Current research work aims in assisting the glovebox operators by designing a novel upper limb exoskeleton device to reduce injuries and increase worker efficiency. Almost none of the commercially available hand and upper body exoskeletons are directly suitable for use in gloveboxes. This explains the novelty of the present work in developing a wearable powered robotic exoskeleton device. The device consists of electronics, motors and spring systems mounted on adjustable plates and is supported by a stationary frame behind the worker. The device is intended to be portable and adjustable according to the operator height. The elbow has a flexion movement assisted with motor control by way of a Bowden cable system. The system is floated on a spring and pulley combination that allows for extra safety and smoothness of operation. The end points are fixed near the pivot points to help minimize unwanted movement/torque. The extension movement of the upper and lower arm are assisted by gravity and a counter spring. The shoulder and upper arm movement are held in a neutral position with a spring system for counter balance allowing small movements within the glovebox. This initial concept considers only the vertical movement of the arm. The abduction and adduction movement will not be assisted or impeded by the over shoulder plate or at the forearm plate allowing for full range of motion. Several glovebox aspects such as the level of task assistance, ergonomic design, minimum hindrance in dexterity/operator movements and tear resistance for hazardous safety reasons will be considered in the design of the exoskeleton. Computer models will be simulated to test the load levels and stress conditions on the exoskeleton to enhance the designs. The exoskeleton focusses on major muscular involvement reduction through weight offset and active assistance with minimal parts and hence the device is derived with several joint links and contains both passive and active joints. The paper details the various stages in the design development and prototype testing of the exoskeleton device. Upon successful prototype device development, human testing will be conducted in a replica of the SRS-235F hot cell facility constructed at FIU-ARC. The final stage of the project will be potential testing/deployment of the exoskeleton device in one of the glovebox facilities in Savannah River Nuclear Waste site. (authors)
- Research Organization:
- WM Symposia, Inc., PO Box 27646, 85285-7646 Tempe, AZ (United States)
- OSTI ID:
- 23028003
- Report Number(s):
- INIS-US--21-WM-20374
- Country of Publication:
- United States
- Language:
- English
Similar Records
Human-Centered Exoskeleton: Upper Extremity Strength Augmentation in Occupational Settings - 17297
Empowering Lineworkers: The Case for Active Exoskeletons in Utility Work
Wearable Robotics and Exoskeletons for WM Workers: Potential Benefits and Challenges - 18506
Conference
·
Sat Jul 01 00:00:00 EDT 2017
·
OSTI ID:22802332
Empowering Lineworkers: The Case for Active Exoskeletons in Utility Work
Journal Article
·
Tue Dec 31 19:00:00 EST 2024
· International Research Journal of Engineering and Technology
·
OSTI ID:2538036
Wearable Robotics and Exoskeletons for WM Workers: Potential Benefits and Challenges - 18506
Conference
·
Sun Jul 01 00:00:00 EDT 2018
·
OSTI ID:22977784