Effect of vibration magnitude, vibration spectrum and muscle tension on apparent mass and cross axis transfer functions during whole-body vibration exposure.

Twelve seated male subjects were exposed to 15 vibration conditions to investigate the nature and mechanisms of the non-linearity in biomechanical response. Subjects were exposed to three groups of stimuli: Group A comprised three repeats of random vertical vibration at 0.5, 1.0 and 1.5 ms(-2) r.m.s. with subjects sitting in a relaxed upright posture. Group B used the same vibration stimuli as Group A, but with subjects sitting in a 'tense' posture. Group C used vibration where the vibration spectrum was dominated by either low-frequency motion (2-7 Hz), high-frequency motion (7-20 Hz) or a 1.0 ms(-2) r.m.s. sinusoid at the frequency of the second peak in apparent mass (about 10-14 Hz) added to 0.5 ms(-2) r.m.s. random vibration. In the relaxed posture, frequencies of the primary peak in apparent mass decreased with increased vibration magnitude. In the tense posture, the extent of the non-linearity was reduced. For the low-frequency dominated stimulus, the primary peak frequency was lower than that for the high-frequency dominated stimulus indicating that the frequency of the primary peak in the apparent mass is dominated by the magnitude of the vibration encompassing the peak. Cross-axis transfer functions showed peaks of about 15-20% and 5% of the magnitudes of the peaks in the apparent mass for x- and y-direction transfer functions, respectively, in the relaxed posture. In the tense posture, cross-axis transfer functions reduced in magnitude with increased vibration, likely indicating a reduced fore-aft pitching of the body with increased tension, supporting the hypothesis that pitching contributes to the non-linearity in apparent mass.

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

[2]  Michael J. Griffin,et al.  EFFECT OF MUSCLE TENSION ON NON-LINEARITIES IN THE APPARENT MASSES OF SEATED SUBJECTS EXPOSED TO VERTICAL WHOLE-BODY VIBRATION , 2002 .

[3]  C. H. Lewis,et al.  Evaluating the Vibration Isolation of Soft Seat Cushions Using AN Active Anthropodynamic Dummy , 2002 .

[4]  Suzanne D. Smith Nonlinear Resonance Behavior in the Human Exposed to Whole-Body Vibration , 1994 .

[5]  Neil J. Mansfield,et al.  Human Response to Vibration , 2004 .

[6]  Michael J. Griffin,et al.  Tri-axial forces at the seat and backrest during whole-body vertical vibration , 2004 .

[7]  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.

[8]  R Lundström,et al.  Absorption of energy during vertical whole-body vibration exposure. , 1998, Journal of biomechanics.

[9]  Setsuo Maeda,et al.  Evaluation of whole-body vibration by the category judgment method. , 2005, Industrial health.

[10]  Ronnie Lundström,et al.  ABSORPTION OF ENERGY DURING WHOLE-BODY VIBRATION EXPOSURE , 1998 .

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

[12]  R Lundström,et al.  Mechanical impedance of the human body in vertical direction. , 2000, Applied ergonomics.

[13]  Setsuo Maeda,et al.  Comparison of the apparent mass of the seated human measured using random and sinusoidal vibration. , 2005, Industrial health.

[14]  J. Bendat,et al.  Random Data: Analysis and Measurement Procedures , 1971 .

[15]  N J Mansfield,et al.  The apparent mass of the human body exposed to non-orthogonal horizontal vibration. , 1999, Journal of biomechanics.

[16]  N J Mansfield,et al.  Models of the apparent mass of the seated human body exposed to horizontal whole-body vibration. , 1999, Aviation, space, and environmental medicine.

[17]  Michael J. Griffin,et al.  Effects of posture and vibration magnitude on apparent mass and pelvis rotation during exposure to whole-body vertical vibration , 2002 .

[18]  B Hinz,et al.  The nonlinearity of the human body's dynamic response during sinusoidal whole body vibration. , 1987, Industrial health.

[19]  R R COERMANN,et al.  The passive dynamic mechanical properties of the human thorax-abdomen system and of the whole body system. , 1960, Aerospace medicine.