Intraspinal forces and health risk caused by whole-body vibration—Predictions for European drivers and different field conditions

The extent of intraspinal forces under whole-body vibration (WBV) depends on several factors like multiple excitations of different body parts, stature and posture. The effects of these forces are determined by individual tolerances. Hence, there is no direct and simple relationship between WBV and health risk of the lumbar spine. The current evaluation methods with respect to health cover only part of the WBV input to the human body and do not consider all associated factors. A set of 50 finite element (FE) models was developed, based on human anatomy and adapted to different typical postures of European drivers and their anthropometric parameters. Three-dimensional matrices of transfer functions simulate these models and permit a practicable routine computation by a Matlab program with graphical user interface to predict intraspinal compressive and shear forces caused by WBV-input in x-, y- and z-directions at the seat, backrest, feet and hands, measured on mobile machinery. The effects of posture and stature on predicted WBV-related internal loads are demonstrated, for example, of numerous WBV-measurements under field conditions. The predicted static and vibration-related peak-to-peak dynamic compressive forces are processed with a method of risk assessment based on cumulative fatigue failure and implemented as a Matlab-program. The resulting risk factors of the new assessment method are compared with existing evaluation procedures of ISO 2631-1 and ISO 2631-5. They reveal significant differences.

[1]  M. Morlock,et al.  The size of lumbar vertebral endplate areas—Prediction by anthropometric characteristics and significance for fatigue failure due to whole-body vibration , 2008 .

[2]  B Hinz,et al.  Application of finite-element models to predict forces acting on the lumbar spine during whole-body vibration. , 2001, Clinical biomechanics.

[3]  C. Leboeuf‐Yde,et al.  Whole-body vibration and low back pain: a systematic, critical review of the epidemiological literature 1992–1999 , 2000, International archives of occupational and environmental health.

[4]  Bernhard Buck Modell für das Schwingungsverhalten des sitzenden Menschen mit detaillierter Abbildung der Wirbelsäule und Muskulatur im Lendenbereich , 1997 .

[5]  Michael J. Griffin,et al.  A comparison of standardized methods for predicting the hazards of whole-body vibration and repeated shocks , 1998 .

[6]  M J Griffin,et al.  Modelling the response of the spinal system to whole-body vibration and repeated shock. , 2001, Clinical biomechanics.

[7]  Helmut Seidel,et al.  On the relationship between whole-body vibration exposure and spinal health risk. , 2005, Industrial health.

[8]  J. Sandover The fatigue approach to vibration and health : Is it a practical and viable way of predicting the effects on people? , 1998 .

[9]  H P Wölfel,et al.  Determination of vibration-related spinal loads by numerical simulation. , 2001, Clinical biomechanics.

[10]  Horst Peter Wölfel Numerical models and hardware dummies for simulating whole-body vibration of human: an overview , 2006 .

[11]  M J Griffin,et al.  Minimum health and safety requirements for workers exposed to hand-transmitted vibration and whole-body vibration in the European Union; a review , 2004, Occupational and Environmental Medicine.

[12]  Ralph Blüthner,et al.  ON THE HEALTH RISK OF THE LUMBAR SPINE DUE TO WHOLE-BODY VIBRATION—THEORETICAL APPROACH, EXPERIMENTAL DATA AND EVALUATION OF WHOLE-BODY VIBRATION , 1998 .

[13]  S. Pankoke,et al.  DYNAMIC FE MODEL OF SITTING MAN ADJUSTABLE TO BODY HEIGHT, BODY MASS AND POSTURE USED FOR CALCULATING INTERNAL FORCES IN THE LUMBAR VERTEBRAL DISKS , 1998 .