Abstract
Recently, many industrial exoskeletons for supporting workers in heavy physical tasks have been developed. However, the efficiency of exoskeletons with regard to physical strain reduction has not been fully proved, yet. Several laboratory and field studies have been conducted, but still more data, that cannot be obtained solely by behavioral experiments, are needed to investigate effects on the human body. This paper presents an approach to extend laboratory and field research with biomechanical simulations using the AnyBody Modeling System. Based on a dataset recorded in a laboratory experiment with 12 participants using the exoskeleton Paexo Shoulder in an overhead task, the same situation was reproduced in a virtual environment and analyzed with biomechanical simulation. Simulation results indicate that the exoskeleton substantially reduces muscle activity and joint reaction forces in relevant body areas. Deltoid muscle activity and glenohumeral joint forces in the shoulder were decreased between 54 and 87%. Simultanously, no increases of muscle activity and forces in other body areas were observed. This study demonstrates how a simulation framework could be used to evaluate changes in internal body loads as a result of wearing exoskeletons. Biomechanical simulation results widely agree with experimental measurements in the previous laboratory experiment and supplement such by providing an insight into effects on the human musculoskeletal system. They confirm that Paexo Shoulder is an effective device to reduce physical strain in overhead tasks. The framework can be extended with further parameters, allowing investigations for product design and evaluation.
Highlights
Many industrial exoskeletons for supporting workers in heavy physical tasks have been developed
Biomechanical analysis focused on body areas that are most relevant for the overhead task in the experiment and areas with possible adverse side effects
Results for infraspinatus muscle were divergent: they showed a significant increase of muscle activity on the left side (ΔNE–with exoskeleton” (WE) = À4.9%, p < .01) and a decrease of muscle activity on the right side (ΔNE–WE = 15.1%, p < .01) in the WE condition with relatively high baseline activity in the NE condition (37% on average)
Summary
Many industrial exoskeletons for supporting workers in heavy physical tasks have been developed. Biomechanical simulation results widely agree with experimental measurements in the previous laboratory experiment and supplement such by providing an insight into effects on the human musculoskeletal system They confirm that Paexo Shoulder is an effective device to reduce physical strain in overhead tasks. Approaches to evaluate feasibility and analyze effects of exoskeletons in industrial applications (Looze de et al, 2016) and other use cases (Settembre et al, 2020) This kind of research is necessary to get valuable and real-world insights into objective measures of physical strain (e.g., surface electromyography [sEMG], oxygen consumption [VO2], and motion patterns) as well as subjective comfort and user acceptance. Field studies with real workers are utterly costly and may disrupt ongoing work, which often leads to a very small and nonrepresentative sample In both cases, it is hard to systematically analyze effects on certain user populations due to a limited range and/or number of study participants
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