Biomechanical models of the human hand-arm to simulate distributed biodynamic responses for different postures

Adewusi, S.<sup>1</sup>; Rakheja, S.<sup>1</sup>; Marcotte, P.<sup>1</sup>

Affiliations

¹Research Laboratory in Machine, Process and Structural Dynamics (DYNAMO), Ecole de Technologie Superieure, 1100 Notre-Dame Street West, Montreal, Quebec H3C 1K3, Canada

²CONCAVE Research Center, Concordia University, 1455 de Maisonneuve West, Montréal, Québec H3G 1M8, Canada

³Institut de recherche Robert-Sauvé en santé et en sécurité du travail 505 de Maisonneuve West, Montréal, Québec H3A 3C2, Canada

Abstract and keywords

Hand-transmitted vibration and the associated potential injuries are dependent on hand-arm posture, hand forces and other factors. This study presents biomechanical models consisting different substructures of the hand-arm system and the trunk of the body in different postures subject to z_h-axis vibration. The trunk was considered in order to account for observed and reported considerable vibration at the shoulder and of the head. The models parameters were derived through error minimization using three different target biodynamic functions namely: driving-point mechanical impedance alone; localized vibration transmissibility responses alone; and combined simultaneously measured impedance and transmissibility responses. The results showed that the models’ parameters and responses are strongly dependent on the type of the target function. The models derived using impedance or transmissibility responses target function yield good comparisons with measured impedance or transmissibility responses, respectively, but none adequately characterize both the impedance and transmissibility responses. The models based on combined impedance and transmissibility target functions yield reasonably good comparisons with both measured biodynamic responses and characteristic frequencies. The results suggest that the transmissibility responses characterize the dynamics of the local tissues/muscles of the human hand-arm at different locations, while impedance characterizes the entire hand-arm system with emphasis around the driving-point. The results showed a strong coupling between the human hand-arm system and the whole-body.

Relevance to industry: Occupational exposure to hand-transmitted vibration has caused health problems in some operators of hand-held power tools. This has resulted in loss of manpower and costs in terms of compensations paid to affected workers. The existing International guidelines (ISO 5349-1, 2001) could not adequately predict some components of the hand-arm vibration syndrome due to lack of knowledge about hand-arm injury mechanism and probably due to neglect of the effect of posture adopted by workers in the assessment method. The biomechanical models for different postures presented in this study could be used to estimate distributed biodynamic responses (vibration power, dynamic forces, vibration intensity and deformation of joints) of the human hand-arm system exposed to vibration. Potential injury assessment based on these distributed biodynamic responses may yield better prediction of different components of the hand-arm injury and enhance understanding of injury mechanism.

Keywords: Hand-arm biomechanical models; Biodynamic responses; Coupled hand-arm-trunk system; Hand-arm resonance frequencies; Hand-arm mechanical properties

Links

DOI: 10.1016/j.ergon.2012.01.005

WoS: 000302512900008

History

Received: 2010-01-26

Revised: 2011-12-20

Accepted: 2021-01-24

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2019	Goggins KA, Tarabini M, Lievers WB, Eger TR. Biomechanical response of the human foot when standing in a natural position while exposed to vertical vibration from 10–200 Hz. Ergonomics. May 2019;6(5):644-656.
2015	Welcome DE, Dong RG, Xu XS, Warren C, McDowell TW, Wu JZ. An examination of the vibration transmissibility of the hand-arm system in three orthogonal directions. Int J Ind Ergon. February 2015;45:21-34.
2020	Chadefaux D, Goggins K, Cazzaniga C, Marzaroli P, Marelli S, Katz R, Eger T, Tarabini M. Development of a two-dimensional dynamic model of the foot-ankle system exposed to vibration. J Biomech. January 23, 2020;99:109547.
2013	Dong RG, Welcome DE, McDowell TW, Wu JZ. Modeling of the biodynamic responses distributed at the fingers and palm of the hand in three orthogonal directions. J Sound Vibrat. February 2013;332(4):1125-1140.
2013	Dong RG, Welcome DE, McDowell TW, Wu JZ. Theoretical relationship between vibration transmissibility and driving-point response functions of the human body. J Sound Vibrat. November 25, 2013;332(24):6193-6202.
2015	Dong RG, Welcome DE, McDowell TW, Wu JZ. Theoretical foundation, methods, and criteria for calibrating human vibration models using frequency response functions. J Sound Vibrat. November 10, 2015;256:195-216.
2015	Dobry MW, Hermann T. A comparison of human physical models based on the distribution of power in a dynamic structure in the case of hand-arm vibrations. J Theo Appl Mech. 2015;53(1):3-13.
2015	Xu XS, Dong RG, Welcome DE, Warren C, McDowell TW. An examination of an adapter method for measuring the vibration transmitted to the human arms. Measurement. September 2015;73:318-334.
2019	Goggins KA. Measuring and Modelling Human Response to Foot-Transmitted Vibration Exposure [PhD thesis]. Sudbury, ON: Laurentian University; 2019.