Haluk Ay scite author profile

Purpose The purpose of this study is to design and develop a testing device to simulate interaction between human hand–arm dynamics, right-angle (RA) computer-controlled power torque tools and joint-tightening task-related variables. Design/methodology/approach The testing rig can simulate a variety of tools, tasks and operator conditions. The device includes custom data-acquisition electronics and graphical user interface-based software. The simulation of the human hand–arm dynamics is based on the rig’s four-bar mechanism-based design and mechanical components that provide adjustable stiffness (via pneumatic cylinder) and mass (via plates) and non-adjustable damping. The stiffness and mass values used are based on an experimentally validated hand–arm model that includes a database of model parameters. This database is with respect to gender and working posture, corresponding to experienced tool operators from a prior study. Findings The rig measures tool handle force and displacement responses simultaneously. Peak force and displacement coefficients of determination (R2) between rig estimations and human testing measurements were 0.98 and 0.85, respectively, for the same set of tools, tasks and operator conditions. The rig also provides predicted tool operator acceptability ratings, using a data set from a prior study of discomfort in experienced operators during torque tool use. Research limitations/implications Deviations from linearity may influence handle force and displacement measurements. Stiction (Coulomb friction) in the overall rig, as well as in the air cylinder piston, is neglected. The rig’s mechanical damping is not adjustable, despite the fact that human hand–arm damping varies with respect to gender and working posture. Deviations from these assumptions may affect the correlation of the handle force and displacement measurements with those of human testing for the same tool, task and operator conditions. Practical implications This test rig will allow the rapid assessment of the ergonomic performance of DC torque tools, saving considerable time in lineside applications and reducing the risk of worker injury. DC torque tools are an extremely effective way of increasing production rate and improving torque accuracy. Being a complex dynamic system, however, the performance of DC torque tools varies in each application. Changes in worker mass, damping and stiffness, as well as joint stiffness and tool program, make each application unique. This test rig models all of these factors and allows quick assessment. Social implications The use of this tool test rig will help to identify and understand risk factors that contribute to musculoskeletal disorders (MSDs) associated with the use of torque tools. Tool operators are subjected to large impulsive handle reaction forces, as joint torque builds up while tightening a fastener. Repeated exposure to such forces is associated with muscle soreness, fatigue and physical stress which are also risk factors for upper extremity injuries (MSDs; e.g. tendinosis, myofascial pain). Eccentric exercise exertions are known to cause damage to muscle tissue in untrained individuals and affect subsequent performance. Originality/value The rig provides a novel means for quantitative, repeatable dynamic evaluation of RA powered torque tools and objective selection of tightening programs. Compared to current static tool assessment methods, dynamic testing provides a more realistic tool assessment relative to the tool operator’s experience. This may lead to improvements in tool or controller design and reduction in associated musculoskeletal discomfort in operators.

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Design and development of a torque tool testing rig that simulates human operator-tool-task interactions

Ay¹,

Luscher²,

Sommerich³

2010

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Design and Development of a Torque Tool Testing Rig that Simulates Human Operator-Tool-Task Interactions

Ay¹,

Luscher²,

Sommerich

2010

Proceedings of the Human Factors and Ergonomics Society Annual

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For some time now, automobile manufacturers, torque tool manufacturers, and biomechanics researchers have shared a common objective to reduce musculoskeletal injuries associated with DC torque tool use. To attain that goal, a better understanding of factors that contribute to these injuries has been pursued through human subjects laboratory testing, field research, and biomechanical modeling. A testing rig was recently developed that builds upon much of this prior research. The rig provides a means to simulate the effects experienced by an operator using a right angle torque tools, in part, by controlling the stiffness and mass properties of the rig. The rig also uses a database of human biomechanical properties and responses to interpret measured handle force and displacement. This rig will be used to objectively evaluate new tools and identify appropriate tool settings for specific task conditions, such as joint hardness and target torque.

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Haluk Ay

Linear Modeling of Human Hand-Arm Dynamics Relevant to Right-Angle Torque Tool Interaction

A dynamic simulator for the ergonomics evaluation of powered torque tools for human assembly

Design and development of a torque tool testing rig that simulates human operator-tool-task interactions

Design and Development of a Torque Tool Testing Rig that Simulates Human Operator-Tool-Task Interactions

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