A modal analysis of whole-body vertical vibration, using a finite element model of the human body

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Kitazaki, S.¹; Griffin, M. J.¹

A modal analysis of whole-body vertical vibration, using a finite element model of the human body

J Sound Vibrat. February 13, 1997;200(1):83-103

©1997 Academic Press Limited

Affiliations

¹Human Factors Research Unit, Institute of Sound and Vibration Research, University of Southampton, Southampton, SO17 1BJ, England
Abstract

A two-dimensional model of human biomechanical responses to whole-body vibration has been developed, by using the finite element method. Beam, spring and mass elements were used to model the spine, viscera, head, pelvis and buttocks tissue in the mid-sagittal plane. The model was developed by comparison of the vibration mode shapes with those previously measured in the laboratory. At frequencies below 10 Hz, the model produced seven modes which coincided well with the measurements. The principal resonance of the driving point response at about 5 Hz consisted of an entire body mode, in which the head, spinal column and the pelvis move almost rigidly, with axial and shear deformation of tissue beneath the pelvis occurring in phase with a vertical visceral mode. The second principal resonance at about 8 Hz corresponded to a rotational mode of the pelvis, with a possible contribution from a second visceral mode. A shift of the principal resonance of the driving point response, when changing posture, was achieved only by changing the axial stiffness of the buttocks tissue. It is suggested that an increase in contact area between the buttocks and the thighs and the seat surface, when changing posture from erect to slouched, may decrease the axial stiffness beneath the pelvis, with a non-linear force–deflection relationship of tissue resulting in decreases in the natural frequencies. A change in posture from erect to slouched also increased shear deformation of tissue beneath the pelvis in the entire body mode, and the natural frequency was decreased as a result of the much lower shear stiffness of tissue compared to the axial stiffness.
Links

DOI: 10.1006/jsvi.1996.0674

WoS: A1997WH59500007
History

Received: 1995-12-12

Accepted: 1996-07-30

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Cited By (22)

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2009	Tamaoki G, Yoshimura T. Modeling of seated human body with spinal column supported by abdomen and muscle of back for evaluation of exposure to whole-body vibration. In: 4th International Conference on Whole Body Vibration (WBV2009). June 2-4, 2009; Montreal, QC.53-54.
2019	Yin W, Qiu Y. Effect of backrest inclination on the nonlinearity of the apparent mass at the seat pan and backrest during vertical vibration. In: 54th UK Conference on Human Response to Vibration. September 24-26, 2019; Edinburgh, UK.
2001	Seidel H, Griffin MJ. Modelling the response of the spinal system to whole-body vibration and repeated shock. Clin Biomech (Bristol, Avon). 2001;16(suppl 1):S3-S7.
2001	Matsumoto Y, Griffin MJ. Modelling the dynamic mechanisms associated with the principal resonance of the seated human body. Clin Biomech (Bristol, Avon). 2001;16(suppl 1):S31-S44.
2014	Zhou Z, Griffin MJ. Response of the seated human body to whole-body vertical vibration: biodynamic responses to sinusoidal and random vibration. Ergonomics. May 2014;57(5):693-713.
2005	Seidel H. On the relationship between whole-body vibration exposure and spinal health risk. Ind Health. July 2005;43(3):361-377.
2008	Liang C-C, Chiang C-F. Modeling of a seated human body exposed to vertical vibrations in various automotive postures. Ind Health. April 2008;46(2):125-137.
2001	Cho Y, Yoon Y-S. Biomechanical model of human on seat with backrest for evaluating ride quality. Int J Ind Ergon. May 2001;27(5):331-345.
2000	Mansfield NJ, Griffin MJ. Non-linearities in apparent mass and transmissibility during exposure to whole-body vertical vibration. J Biomech. August 2000;33(8):933-941.
2002	Matsumoto Y, Griffin MJ. Non-linear characteristics in the dynamic responses of seated subjects exposed to vertical whole-body vibration. J Biomech Eng. October 2002;124(5):527-532.
1998	Wei L, Griffin MJ. Mathematical models for the apparent mass of the seated human body exposed to vertical vibration. J Sound Vibrat. May 21, 1998;212(5):855-874.
2002	Matsumoto Y, Griffin MJ. Effect of muscle tension on non-linearities in the apparent masses of seated subjects exposed to vertical whole-body vibration. J Sound Vibrat. May 23, 2002;253(1):77-92.
2008	Subashi GHMJ, Matsumoto Y, Griffin MJ. Modelling resonances of the standing body exposed to vertical whole-body vibration: effects of posture. J Sound Vibrat. October 2008;317(1-2):400-418.
2011	Zheng G, Qiu Y, Griffin MJ. An analytic model of the in-line and cross-axis apparent mass of the seated human body exposed to vertical vibration with and without a backrest. J Sound Vibrat. December 19, 2011;330(26):6509-6525.
2016	Goggins K, Godwin A, Lariviere C, Eger T. Study of the biodynamic response of the foot to vibration exposure. Occup Ergon. 2016;13(1):53-66.
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2013	Goggins KA. Foot-Transmitted Vibration: Exposure Characteristics and the Biodynamic Response of the Foot [Master's thesis]. Sudbury, ON: Laurentian University; 2013.
2016	Killen W. Evaluation of a Vibration Measurement Tool as Part of a Whole-Body Vibration Management Program in Underground Hard-Rock Mining [Master's thesis]. Sudbury, ON: Laurentian University; 2016.
2007	Bazrgari B. Biodynamic of the Human Spine [PhD thesis]. École polytechnique de Montréal; February 2007.
2002	Giacomin JA. An Experimental Investigation of the Vibrational Comfort of Child Safety Seats [PhD thesis]. University of Sheffield; December 2002.
1999	Matsumoto Y. Dynamic Response of Standing and Seated Persons to Whole-Body Vibration: Principal Resonance of the Body [PhD thesis]. Southampton, England: University of Southampton; June 1999.
2015	Ji X. Evaluation of Suspension Seats Under Multi-Axis Vibration Excitations: A Neural Net Model Approach to Seat Selection [PhD thesis]. University of Western Ontario; 2015.