The impact of an increase in work rate on task demands for a simulated industrial hand tool assembly task

Abstract Global competition in the manufacturing sector has created an environment for continuous improvement resulting in methods to increase capacity while lowering cost. Speed Fastening (SF) is one manufacturing assembly method currently being modified to improve its production capacity. This semi-automated riveting process is limited by a lack of continuous feed of fasteners supplied to the tool. One path to productivity improvement that has been identified for improving productivity in SF is the development of a continuous feed tool, which would eliminate non-value added time currently scheduled for reloading. In preparation for the design of a new tool, a proactive investigation was conducted to characterize the influence of work rate (i.e. frequency of fastener insertion) on task demands (e.g. muscular effort, posture, etc.) for manual SF work. Twelve healthy female subjects participated in simulated SF work over four test sessions. The first test session was used to familiarize subjects with the task, as well as the data collection protocol. Subsequent test days were block randomized to one of three work rates (7, 14 and 21 fasteners per minute) with subjects required to complete 120 min of simulated SF work at waist and shoulder height. Overall, an increase in work rate imposed a significant increase (p  Relevance to industry Repetitive work performed with a powered hand tool is considered a risk factor for the development upper extremity musculoskeletal injury. This investigation contributes to an improved understanding of the impact that an increased pace of work has on the physical demands of operators during a simulated industrial task.

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