Modeling of a seated human body exposed to vertical vibrations in various automotive postures

Liang, Cho-Chung; Chiang, Chi-Feng

Affiliations

¹Department of Mechanical and Automation Engineering, Dayeh University, 112 Shanjiau Rd., Datsuen, Changhua, Taiwan 515, R.O.C.

Abstract and keywords

Although much research has been devoted to constructing specific models or to measuring the response characteristics of seated subjects, investigations on a mathematical human model on a seat with a backrest to evaluate vehicular riding comfort have not yet attracted the same level of attention. For the responses of a seated body to vertical vibrations, mathematical models of the mechanisms must be at least two-dimensional in the sagittal plane. In describing the motions of a seated body, two multibody models representative of the automotive postures found in the literature were investigated, one with and the other without a backrest support. Both models were modified to suitably represent the different automotive postures with and without backrest supports, and validated by various experimental data from the published literature pertaining to the same postural conditions. On the basis of the analytical study and the experimental validation, the fourteen-degrees-of-freedom model proposed in this research was found to be best fitted to the test results; therefore, this model is recommended for studying the biodynamic responses of a seated human body exposed to vertical vibrations in various automotive postures.

Keywords: Multibody models, Sagittal plane, Backrest support, Biodynamic responses, Automotive postures

Links

DOI: 10.2486/indhealth.46.125

PubMed: 18413965

WoS: 000254472100005

History

Received: 2007-05-25

Accepted: 2007-11-02

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Cited By (8)

Year	Entry
2014	Adamo F, Attivissimo F, Lanzolla AML, Saponaro F, Cervellera V. Assessment of the uncertainty in human exposure to vibration: an experimental study. IEEE Sens J. February 2014;14(2):474-481.
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2021	Jalali P, Ettefagh MM, Hassannejad R. Recognizing the viscoelastic safe area of work shoe sole in the sitting posture with vibration transmissibility in the vertical direction. Int J Ind Ergon. January 1, 2021;81:103053.
2023	Pradhan NC, Sahoo PK, Kushwaha DK, Makwana Y, Mani I, Kumar M, T N A, V SK. A finite element modeling-based approach to predict vibrations transmitted through different body segments of the operator within the workspace of a small tractor. J Field Robot. September 2023;40(6):1543-1561.
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.
2014	Książek MA, Tarnowski J. Experimental studies of the influence of human standing positions on the feet-to-head transmission of vibrations. J Theo Appl Mech. 2014;52(4):1107-1114.
2019	Goggins KA. Measuring and Modelling Human Response to Foot-Transmitted Vibration Exposure [PhD thesis]. Sudbury, ON: Laurentian University; 2019.
2014	De Bruijn E. Isometric and Dynamic Control of Neck Muscles: Reflexive Contributions and Muscle Synergies [PhD thesis]. Delft, The Netherlands: Technische Universiteit Delft; 2014.