Characterisation of the human-seat coupling in response to vibration

Characterising the coupling between the occupant and vehicle seat is necessary to understand the transmission of vehicle seat vibration to the human body. In this study, the vibration characteristics of the human body coupled with a vehicle seat were identified in frequencies up to 100 Hz. Transmissibilities of three volunteers seated on two different vehicle seats were measured under multi-axial random vibration excitation. The results revealed that the human-seat system vibration was dominated by the human body and foam below 10 Hz. Major coupling between the human body and the vehicle seat-structure was observed in the frequency range of 10–60 Hz. There was local coupling of the system dominated by local resonances of seat frame and seat surface above 60 Hz. Moreover, the transmissibility measured on the seat surface between the human and seat foam is suggested to be a good method of capturing human-seat system resonances rather than that measured on the human body in high frequencies above 10 Hz.Practitioner Summary: The coupling characteristics of the combined human body and vehicle seat system has not yet been fully understood in frequencies of 0.5–100 Hz. This study shows the human-seat system has distinctive dynamic coupling characteristics in three different frequency regions: below 10 Hz, 10–60 Hz, and above 60 Hz.

[1]  David J. Ewins,et al.  Modal Testing: Theory, Practice, And Application , 2000 .

[2]  Michael J. Griffin,et al.  Apparent mass of the human body in the vertical direction: Inter-subject variability , 2011 .

[3]  G. Arakere,et al.  Seat-cushion and soft-tissue material modeling and a finite element investigation of the seating comfort for passenger-vehicle occupants , 2009 .

[4]  Michael J. Griffin,et al.  Nonlinearity in the vertical transmissibility of seating: the role of the human body apparent mass and seat dynamic stiffness , 2013 .

[5]  M J Griffin,et al.  The apparent mass of the seated human body: vertical vibration. , 1989, Journal of biomechanics.

[6]  M. Griffin,et al.  Non-linearities in apparent mass and transmissibility during exposure to whole-body vertical vibration. , 2000, Journal of biomechanics.

[7]  Michael J. Griffin,et al.  The transmission of vertical vibration through seats: Influence of the characteristics of the human body , 2011 .

[8]  M. J. Griffin,et al.  5 – Whole-body Vibration and Health , 1990 .

[9]  Michael J. Griffin,et al.  Effect of seating on exposures to whole-body vibration in vehicles , 2002 .

[10]  Douglas E. Adams,et al.  Data Analysis Strategies for Characterizing Helmet-Head Performance , 2011 .

[11]  Michael J. Griffin,et al.  Finite element modelling of human-seat interactions: vertical in-line and fore-and-aft cross-axis apparent mass when sitting on a rigid seat without backrest and exposed to vertical vibration , 2015, Ergonomics.

[12]  M. Griffin,et al.  MOVEMENT OF THE UPPER-BODY OF SEATED SUBJECTS EXPOSED TO VERTICAL WHOLE-BODY VIBRATION AT THE PRINCIPAL RESONANCE FREQUENCY , 1998 .

[13]  Jin-Kwan Suh,et al.  A Study on the Characteristics of Vibration in Seat System , 2003 .

[14]  N. Mansfield,et al.  The apparent mass of the seated human exposed to single-axis and multi-axis whole-body vibration. , 2007, Journal of Biomechanics.

[15]  Subhash Rakheja,et al.  Whole-body vertical biodynamic response characteristics of the seated vehicle driver: measurement and model development , 1998 .

[16]  Mohammad Fard,et al.  Structural dynamic characterization of a vehicle seat coupled with human occupant , 2013 .

[17]  Jongwan Kim,et al.  Dynamic modeling of seated human body based on measurements of apparent inertia matrix for fore-and-aft/vertical/pitch motion , 2011 .

[18]  Michael J. Griffin,et al.  Apparent mass of the human body in the vertical direction: Effect of seat backrest , 2009 .

[19]  Bart Peeters,et al.  A New Procedure for Modal Parameter Estimation , 2004 .

[20]  Niklas Gloeckner,et al.  Handbook Of Human Vibration , 2016 .

[22]  Joshua J Gooley,et al.  Sustained attention performance during sleep deprivation associates with instability in behavior and physiologic measures at baseline. , 2014, Sleep.

[23]  H. Van der Auweraer Structural dynamics modeling using modal analysis: applications, trends and challenges , 2001, IMTC 2001.

[24]  Setsuo Maeda,et al.  Comparison of the apparent mass during exposure to whole-body vertical vibration between Japanese subjects and ISO 5982 standard. , 2005, Industrial health.

[25]  M. Griffin,et al.  A MODAL ANALYSIS OF WHOLE-BODY VERTICAL VIBRATION, USING A FINITE ELEMENT MODEL OF THE HUMAN BODY , 1997 .

[26]  Greg A Jamieson,et al.  Situation awareness acquired from monitoring process plants – the Process Overview concept and measure , 2016, Ergonomics.

[27]  Subhash Rakheja,et al.  ANALYSES OF BIODYNAMIC RESPONSES OF SEATED OCCUPANTS TO UNCORRELATED FORE-AFT AND VERTICAL WHOLE-BODY VIBRATION , 2011 .

[28]  Michael J Griffin,et al.  Biodynamic responses of the seated human body to single-axis and dual-axis vibration. , 2010, Industrial health.

[29]  Mohammad Fard,et al.  Effects of seat structural dynamics on current ride comfort criteria , 2014, Ergonomics.

[30]  Michael J. Griffin,et al.  Transmission of fore–aft vibration to a car seat using field tests and laboratory simulation , 2003 .

[31]  Michael J. Griffin,et al.  Fore-and-aft transmissibility of backrests : Variation with height above the seat surface and non-linearity , 2007 .

[32]  Neil J Mansfield,et al.  Impedance methods (apparent mass, driving point mechanical impedance and absorbed power) for assessment of the biomechanical response of the seated person to whole-body vibration. , 2005, Industrial health.

[33]  Michael J. Griffin,et al.  The apparent mass of the seated human body in the fore-and-aft and lateral directions , 1990 .

[34]  Hikaru Inooka,et al.  Dynamics of the head-neck complex in response to the trunk horizontal vibration: modeling and identification. , 2003, Journal of biomechanical engineering.

[35]  Rémy Willinger,et al.  Coupled head-neck-torso and seat model for car seat optimization under rear-end impact , 2008 .

[36]  K. Yacoub Relationship between multiple and partial coherence functions , 1970, IEEE Trans. Inf. Theory.