Analyzing the kinematic and kinetic contributions of the human upper body’s joints for ergonomics assessment

Menychtas, Dimitrios; Glushkova, Alina; Manitsaris, Sotiris

doi:10.1007/s12652-020-01926-y

Cited by 13 publications

(10 citation statements)

References 21 publications

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“…Based on the identified range and the imposed implementation constraints, the joint range of 116 • (θ max ) was considered. This range was also in accordance with former studies on occupational ergonomics [19], [20]. For this joint range, the necessary tendon length (l f ) for the flexion and the extension movements was approximately 178 mm using (4):…”

Section: A Torque and Motion Range Of The Elbowsupporting

confidence: 88%

A Soft Assistive Device for Elbow Effort-Compensation

Mobedi

Kim

Momi

et al. 2021

2021 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

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The use of assistive technologies in industrial environments to improve human ergonomics and comfort in repetitive and high effort tasks have increased considerably in the last decade. Predominantly, the goal is to provide additional physical support through lightweight and wearable devices, without posing major constraints to the human body movements. Towards achieving this objective, in this work we present a novel actuation mechanism for a soft assistive device, by taking into account the human elbow torque-angle profile. The proposed design integrates a single motor coupled with an elastic bungee and a cam-spool mechanism to enable energy exchange during the elbow flexion movement, while allowing for free-motions during the extension of the joint. A cable-driven transmission with passive elastic attachments is employed to implement compliant couplings with the wearer and to achieve easy donning/doffing. Experiments are conducted on two 3D printed functional prototypes. Results suggest that the assistive elbow torque is effectively transmitted with an average 90% success for balancing a 5N payload, and the free-motion range of 108 • is measured for both flexion and extension.

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Section: A Torque and Motion Range Of The Elbowsupporting

confidence: 88%

A Soft Assistive Device for Elbow Effort-Compensation

Mobedi

Kim

Momi

et al. 2021

2021 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)

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“…An ergonomic analysis using such an approach can result in over-simplicity and ignore other potential risks workers are exposed to (e.g., external forces and dangerous movements). Menytchas [ 17 ] expanded such ergonomic analysis by examining the kinematics and kinetics of professional movements to identify joints that accumulate the most strain. The kinetic descriptors used in that study, however, did not allow for accurate discrimination between dangerous motions with small variations in the posture; moreover, they do not analyze the dynamics of movements, unlike the present study, which allowed for a good recognition performance and distinction between motions of different ergonomic risk.…”

Section: Discussionmentioning

confidence: 99%

“…Most previous studies have used biomechanical modeling to extract the kinematic and kinetic contributions of the joints, in diverse motor tasks, then investigate the mechanical loading of the joints and their response to ergonomic interventions. To analyze the ergonomic impact of different postures on human joints, Menychtas et al [ 17 ] applied the Newton–Euler algorithm for the computation of upper body joint torques. The normalized integral of joint angles and joint torques was then calculated to describe the kinematic and kinetic contribution of the body joints when awkward poses are assumed.…”

Section: State-of-the-artmentioning

confidence: 99%

Stochastic-Biomechanic Modeling and Recognition of Human Movement Primitives, in Industry, Using Wearables

Padilla

Manitsaris

Menychtas

et al. 2021

Sensors

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In industry, ergonomists apply heuristic methods to determine workers’ exposure to ergonomic risks; however, current methods are limited to evaluating postures or measuring the duration and frequency of professional tasks. The work described here aims to deepen ergonomic analysis by using joint angles computed from inertial sensors to model the dynamics of professional movements and the collaboration between joints. This work is based on the hypothesis that with these models, it is possible to forecast workers’ posture and identify the joints contributing to the motion, which can later be used for ergonomic risk prevention. The modeling was based on the Gesture Operational Model, which uses autoregressive models to learn the dynamics of the joints by assuming associations between them. Euler angles were used for training to avoid forecasting errors such as bone stretching and invalid skeleton configurations, which commonly occur with models trained with joint positions. The statistical significance of the assumptions of each model was computed to determine the joints most involved in the movements. The forecasting performance of the models was evaluated, and the selection of joints was validated, by achieving a high gesture recognition performance. Finally, a sensitivity analysis was conducted to investigate the response of the system to disturbances and their effect on the posture.

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“…For example, Malik et al [10] utilized a DH simulation for ergonomic assessment of the workspace layout based on visual and grasp analyses. Furthermore, Menychtas et al [35] demonstrated the effectiveness of joint torque analysis for evaluating the physical load on industrial workers.…”

Section: Ergonomic Assessment In Industry Fieldsmentioning

confidence: 99%

Digital Twin-Driven Human Robot Collaboration Using a Digital Human

Maruyama

Ueshiba

Tada

et al. 2021

Sensors

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Advances are being made in applying digital twin (DT) and human–robot collaboration (HRC) to industrial fields for safe, effective, and flexible manufacturing. Using a DT for human modeling and simulation enables ergonomic assessment during working. In this study, a DT-driven HRC system was developed that measures the motions of a worker and simulates the working progress and physical load based on digital human (DH) technology. The proposed system contains virtual robot, DH, and production management modules that are integrated seamlessly via wireless communication. The virtual robot module contains the robot operating system and enables real-time control of the robot based on simulations in a virtual environment. The DH module measures and simulates the worker’s motion, behavior, and physical load. The production management module performs dynamic scheduling based on the predicted working progress under ergonomic constraints. The proposed system was applied to a parts-picking scenario, and its effectiveness was evaluated in terms of work monitoring, progress prediction, dynamic scheduling, and ergonomic assessment. This study demonstrates a proof-of-concept for introducing DH technology into DT-driven HRC for human-centered production systems.

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Analyzing the kinematic and kinetic contributions of the human upper body’s joints for ergonomics assessment

Cited by 13 publications

References 21 publications

A Soft Assistive Device for Elbow Effort-Compensation

A Soft Assistive Device for Elbow Effort-Compensation

Stochastic-Biomechanic Modeling and Recognition of Human Movement Primitives, in Industry, Using Wearables

Digital Twin-Driven Human Robot Collaboration Using a Digital Human

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