Wang et al., 2006 - Google Patents
The role of seat geometry and posture on the mechanical energy absorption characteristics of seated occupants under vertical vibrationWang et al., 2006
- Document ID
- 7638436835092655786
- Author
- Wang W
- Rakheja S
- Boileau P
- Publication year
- Publication venue
- International Journal of Industrial Ergonomics
External Links
Snippet
The power absorption characteristics of 27 male and female seated subjects, exposed to vertical vibration in the 0.5–40Hz frequency range, are characterized under different sitting postures. The measurements are performed for a total of 36 different sitting postural …
- 238000010521 absorption reaction 0 title abstract description 53
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Wang et al. | The role of seat geometry and posture on the mechanical energy absorption characteristics of seated occupants under vertical vibration | |
| Wang et al. | Effects of sitting postures on biodynamic response of seated occupants under vertical vibration | |
| Kim et al. | The effect of a multi-axis suspension on whole body vibration exposures and physical stress in the neck and low back in agricultural tractor applications | |
| Xu et al. | Vibrations transmitted from human hands to upper arm, shoulder, back, neck, and head | |
| Basri et al. | Predicting discomfort from whole-body vertical vibration when sitting with an inclined backrest | |
| Lundström et al. | Absorption of energy during vertical whole-body vibration exposure | |
| Li et al. | Biomechanical response of the musculoskeletal system to whole body vibration using a seated driver model | |
| Basri et al. | The application of SEAT values for predicting how compliant seats with backrests influence vibration discomfort | |
| Boileau et al. | A body mass dependent mechanical impedance model for applications in vibration seat testing | |
| Mansfield | 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 | |
| Wang et al. | Relationship between measured apparent mass and seat-to-head transmissibility responses of seated occupants exposed to vertical vibration | |
| Liu et al. | Dynamic forces over the interface between a seated human body and a rigid seat during vertical whole-body vibration | |
| Toward et al. | Apparent mass of the human body in the vertical direction: Effect of seat backrest | |
| Eksioglu et al. | Steering-wheel grip force characteristics of drivers as a function of gender, speed, and road condition | |
| Rakheja et al. | Seated occupant interactions with seat backrest and pan, and biodynamic responses under vertical vibration | |
| Rützel et al. | Modal description—A better way of characterizing human vibration behavior | |
| Dewangan et al. | Seated body apparent mass response to vertical whole body vibration: Gender and anthropometric effects | |
| Hinz et al. | Apparent mass of seated men—Determination with single-and multi-axis excitations at different magnitudes | |
| Hamouda et al. | Fingers vibration transmission performance of vibration reducing gloves | |
| Mirakhorlo et al. | Effects of seat back height and posture on 3D vibration transmission to pelvis, trunk and head | |
| Dewangan et al. | Comparisons of apparent mass responses of human subjects seated on rigid and elastic seats under vertical vibration | |
| Rakheja et al. | Whole-body vibration biodynamics-a critical review: I. Experimental biodynamics | |
| Cardoso et al. | Ergonomic evaluation of a new truck seat design: a field study | |
| Lin et al. | Biodynamic response of seated human body to roll vibration: Effect of armrest support | |
| Rakheja et al. | Energy absorption of seated occupants exposed to horizontal vibration and role of back support condition |