Experimental investigation of biodynamic human body models subjected to whole-body vibration during a vehicle ride

Taşkın, Yener; Hacioğlu, Yüksel; Örteş, Faruk; Karabulut, Derya; Arslan, Yunus Ziya

doi:10.1080/10803548.2017.1418487

Cited by 11 publications

(7 citation statements)

References 38 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Computational models have been developed to examine the effects of the various mechanical forces of hand-transmitted vibration on the development of and back pain and injury in workers exposed to WBV. These models have included variables to examine the effects of vibration and mechanical stressors, including load, mass and posture on the hips, spine and intervertebral disks with exposure to WBV (Zhang, Qiu,Griffin 2015; Wang et al 2010; Taskin et al 2018), and grip strength, vibration frequency and amplitude in workers exposed to HTV (Wu et al 2006; Wu et al 2007; Wu et al 2008). The published computational models are consistent with data collected in humans showing that the resonant frequency of the human body is between 5–10 Hz (Zeeman et al 2015; Matsumoto,Griffin 2002; Qiu,Griffin 2010; Basri,Griffin 2011), and that the resonant frequency of the human hand-arm system is between 100–300 Hz depending on the location of the measurement (Dong, Welcome, et al 2004; Dong, Welcome,Wu 2005; Dong et al 2006; Wu et al 2007; Wu et al 2008).…”

Section: Models For Assessing Health Effectsmentioning

confidence: 99%

Health effects associated with occupational exposure to hand-arm or whole body vibration

Krajnak

2018

Journal of Toxicology and Environmental Health, Part B

100

View full text Add to dashboard Cite

Workers in a number of different occupational sectors are exposed to workplace vibration on a daily basis. This exposure can come through use of powered-hand tools or hand-transmitted vibration (HTV). Workers can also be exposed to whole body vibration (WBV) by driving delivery vehicles, earth moving equipment, or through the use of tools that generate vibration at low dominant frequencies and high amplitudes, such as jack hammers. Occupational exposure to vibration has been associated with an increased risk of musculoskeletal pain in the back, neck, hands, shoulders and hips. It may also contribute to the development of peripheral and cardiovascular disorders and gastrointestinal problems. In addition, there are more recent data suggesting that occupational exposure to vibration may increase the risk of developing certain cancers. This paper provides a review of the occupations where exposure to vibration is most prevalent, and a description of the health effects associated with occupational exposure to vibration. The various experimental methods used to measure and describe the characteristics of vibration generated by various tools and vehicles, the etiology of vibration-induced disorders, and how these data have been used to assess and improve intervention strategies and equipment that reduces the transmission of vibration to the body. Finally, there is a discussion of the research gaps that need to be investigated to further reduce the incidence of vibration-induced illnesses and injuries.

show abstract

Section: Models For Assessing Health Effectsmentioning

confidence: 99%

Health effects associated with occupational exposure to hand-arm or whole body vibration

Krajnak

2018

Journal of Toxicology and Environmental Health, Part B

100

View full text Add to dashboard Cite

show abstract

“…[10][11][12] Vibrational analysis is a key component of digital twin models used to monitor the health of complex industrial systems, 13 and this concept has recently been extended to the development of human digital twin models that can monitor patient health, 14 for example by determining stroke severity from head vibration. 15 Important related industrial medicine applications include reducing risks of physiological impairments due to human/machine interactions, 9 riding in motor vehicles 16 or industrial equipment, 17 and determining causes of motion sickness. 18 In sports medicine, headmounted and body-worn accelerometers have been used to compare measured and simulated responses of the human body to external mechanical excitations such as simulated sub-concussive head impacts 19 and to investigate the transmissibility of vibrations from the skis to lower back and head in alpine skiing.…”

Section: Introductionmentioning

confidence: 99%

“…ASD is the standard engineering analysis tool for quantifying random vibrations in many different complex physical systems, 9 including the human body. [10][11][12][15][16][17][18][19][20][21][22][23][24][25][26] In addition to revealing significant details related to sensory reweighting, time-resolved ASD analyses also address the fact that postural sway signals are non-stationary, by capturing the significant time varying spectral changes 100,142 that result from intermittent balance control processes that utilize multiple physiological system inputs and outputs. Ensemble-average ASD analyses have been utilized to identify statistically significant spectral features that can distinguish patients vs. control groups.…”

mentioning

confidence: 99%

<p>Physiological Vibration Acceleration (Phybrata) Sensor Assessment of Multi-System Physiological Impairments and Sensory Reweighting Following Concussion</p>

Ralston¹,

Raina

Benson³

et al. 2020

MDER

View full text Add to dashboard Cite

“…Professional bus drivers, as occupants operating vehicles for a considerable amount of driving hours, and passengers experience unwanted vibrations particularly because of the road surface excitations [1]. The unwanted vibrations in vehicles are concentrated in relatively low frequencies (0.5-25 Hz), exposing the driver and the passengers to a whole-body-vibration (WBV) condition [2][3][4].…”

Section: Introductionmentioning

confidence: 99%

Design of optimum vibration absorbers for a bus vehicle to suppress unwanted vibrations against the harmonic and random road excitations

Rezazadeh

Moradi

2020

Scientia Iranica

View full text Add to dashboard Cite

Unwanted vibrations of the vehicles are regarded as harmful threats to the human health from various biomechanical and psychophysical aspects. Road roughness has been considered as the main cause of unwanted vibrations in bus vehicles. Vertical seat vibrations have been found via simulation of a ten degree of freedom (10-DOF) model of an intercity bus vehicle under harmonic and random excitations caused by road roughness. To suppress undesirable vibrations, mass-spring-damper passive absorbers are proposed in a thirteen degrees of freedom (13-DOFs) model of the bus. By optimizing the characteristics of the embedded passive absorbers under each seat, and implementation of the designed absorbers, it is observed that the vertical displacement amplitudes in the frequency response of the seats are reduced especially near the bus resonant frequencies. In addition, the vertical displacement and acceleration amplitudes are decreased in the random excitation of the road roughness. According to the results, optimized mass-spring-damper absorbers are suggested as a practical solution to suppress the unwanted vibration effects in the bus vehicle.

show abstract

Experimental investigation of biodynamic human body models subjected to whole-body vibration during a vehicle ride

Cited by 11 publications

References 38 publications

Health effects associated with occupational exposure to hand-arm or whole body vibration

Health effects associated with occupational exposure to hand-arm or whole body vibration

<p>Physiological Vibration Acceleration (Phybrata) Sensor Assessment of Multi-System Physiological Impairments and Sensory Reweighting Following Concussion</p>

Design of optimum vibration absorbers for a bus vehicle to suppress unwanted vibrations against the harmonic and random road excitations

Contact Info

Product

Resources

About