A comparison of biodynamic models of the human hand–arm system for applications to hand-held power tools

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Rakheja, S.¹; Wu, J. Z.¹; Dong, R. G.¹; Schopper, A. W.¹; Boileau, P.-É.²

A comparison of biodynamic models of the human hand–arm system for applications to hand-held power tools

J Sound Vibrat. January 3, 2002;249(1):55-82

©2002 Academic Press

Affiliations

¹Engineering & Control Technology Branch, NIOSH, 1095 Willowdale Road, MS 2027, Morgantown, WV, 26505, U.S.A.

²IRSST, 505 boul. de Maisonneuve West Montreal, Que. Canada, H3A 3C2
Abstract

The biodynamic response characteristics of various mechanical models of the human hand and arm system, reported in the literature, are evaluated in terms of their driving-point mechanical impedance modulus and phase responses. The suitability of the reported models for applications in realizing a mechanical simulator and assessment of vibration behavior of hand-held power tools is examined using three different criteria. These include the ability of the model to characterize the driving-point mechanical impedance of the human hand–arm system within the range of idealized values presented in ISO-10068 (1998); the magnitude of model deflection under a static feed force; and the vibration properties of the human hand and arm evaluated in terms of natural frequencies and damping ratios. From the relative evaluations of 12 different models, it is concluded that a vast majority of these models cannot be applied for the development of a mechanical hand–arm simulator or the assessment of dynamic behavior of the coupled hand–tool system. The higher order models, with three and four degrees of freedom, in general, yield impedance characteristics within the range of idealized values, but exhibit excessive static deflections. Moreover, these models involve very light masses (in the 1.2–4.8 g range), and exhibit either one or two vibration modes at frequencies below 10 Hz. The majority of the lower order models yield reasonable magnitudes of static deflections but relatively poor agreement with idealized values of driving-point mechanical impedance.
Links

DOI: 10.1006/jsvi.2001.3831

WoS: 000173412400004
History

Received: 2000-12-15

Accepted: 2001-05-29

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Year	Entry
2006	Aldien Y, Rakheja S, Marcotte P, Boileau P-E. Hand force-dependent modeling of the hand-arm under z_h-axis vibration. In: Proceedings of the 1st American Conference on Human Vibration. June 5-7, 2006; Morgantown, MV.40-41.
2010	Adewusi S, Rakheja S, Marcotte P. Biomechanical model of the hand-arm system to simulate distributed biodynamic responses. In: Proceedings of the 3rd American Conference on Human Vibration. June 1-4, 2010; Iowa City, IA.56-57.
2010	DeJager-Kennedy R, Kim J. Semi-analytic estimation of the response of hand-held tools and its applications. In: Proceedings of the 3rd American Conference on Human Vibration. June 1-4, 2010; Iowa City, IA.58-59.
2004	Dong RG, Warren C, Welcome DE, McDowell TW, Wu JZ. A comparison and evaluation of reported mechanical impedance data of the human hand-arm system. In: Proceedings of the 10th International Conference on Hand-Arm Vibration. June 7-11, 2004; Las Vegas, NV.221-227.
2004	Wasserman DE, Reynolds DD. A unique historical perspective of occupational hand-arm vibration in the U.S from 1918-2004. In: Proceedings of the 10th International Conference on Hand-Arm Vibration. June 7-11, 2004; Las Vegas, NV.3-10.
2015	Matthiesen S, Mangold S, Schäfer T, Schmidt S. A method to develop hand-arm models for single impulse stimulation. In: Proceedings of the 13th International Conference on Hand-Arm Vibration. October 13-15, 2015; Beijing, China.77-78.
2019	Khalil HH, Rongong JA, Carré MJ. The effect of grip force on an upper arm under both continuous and shock vibration using the MDOF model. In: 54th UK Conference on Human Response to Vibration. September 24-26, 2019; Edinburgh, UK.
2005	Dong RG, Wu JZ, Welcome DE. Recent advances in biodynamics of human hand-arm system. Ind Health. July 2005;43(3):449-471.
2012	Adewusi S, Rakheja S, Marcotte P. Biomechanical models of the human hand-arm to simulate distributed biodynamic responses for different postures. Int J Ind Ergon. March 2012;42(2):249-260.
2005	Dong RG, Wu JZ, McDowell TW, Welcome DE, Schopper AW. Distribution of mechanical impedance at the fingers and the palm of the human hand. J Biomech. May 2005;38(5):1165-1175.
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.
2006	Dong RG, Welcome D., McDowell TW, Wu JZ. Measurement of biodynamic response of human hand–arm system. J Sound Vibrat. July 2006;294(3):807-827.
2008	Dong JH, Dong RG, Rakheja S, Welcome DE, McDowell TW, Wu JZ. A method for analyzing absorbed power distribution in the hand and arm substructures when operating vibrating tools. J Sound Vibrat. April 8, 2008;311(3-5):1286-1304.
2009	Dong RG, McDowell TW, Welcome DE, Warren C, Wu JZ, Rakheja S. Analysis of anti-vibration gloves mechanism and evaluation methods. J Sound Vibrat. March 20, 2009;321(1-2):435-453.
2010	Adewusi SA, Rakheja S, Marcotte P, Boutin J. Vibration transmissibility characteristics of the human hand–arm system under different postures, hand forces and excitation levels. J Sound Vibrat. July 5, 2010;329(14):2953-2971.
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.
2021	Dong RG, Wu JZ, Xu XS, Welcome DE, Krajnak K. A review of hand–arm vibration studies conducted by US NIOSH since 2000. Vibration. 2021;4(2):482-528.
2009	Adewusi SA. Distributed Biodynamic Characteristics of the Human Hand-Arm System Coupled With Vibrating Handles and Power Tools [PhD thesis]. Concordia University; August 2009.
2019	Goggins KA. Measuring and Modelling Human Response to Foot-Transmitted Vibration Exposure [PhD thesis]. Sudbury, ON: Laurentian University; 2019.