Parametric analysis of an anti-whiplash system composed of a seat suspension arrangement

Date

2015-03-01

Author

Ozdemir, Mustafa
İDER, SITKI KEMAL
Gökler, Mustafa İlhan

Metadata

Show full item record

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

Item Usage Stats

168
views

0
downloads

Neck injuries frequently seen in low-speed rear-end collisions are referred to as whiplash injuries. Most of the proposed anti-whiplash systems in the literature rely on reducing the backset. A relatively new and promising alternative concept is a slideable seat. This study aimed to parametrically analyze an anti-whiplash vehicle seat that can slide backward against a horizontal suspension arrangement composed of a spring and a damper in response to a rear-end collision, and to investigate the effects of the suspension parameters on the injury risk. A simplified model of a slideable vehicle seat is developed, and simulations are conducted in LS-DYNA (R) environment using this slideable seat model and the commercially available finite element model of the BioRID II dummy. The maximum value of the Neck Injury Criterion (NICmax) is used as the measure of the injury risk. As a result, a strong linear inverse correlation is observed between NICmax and the maximum seat sliding distance, while the stiffness and damping coefficients of the suspension are varied. This result is also verified by obtaining the same NICmax value for the same maximum seat sliding distance (although the stiffness and damping coefficients are different). It is also shown that, for a given backset value as large as 60 mm, a slideable seat with the suspension parameters selected to yield a reasonable maximum seat sliding distance such as 100 mm significantly improves NICmax compared to a standard seat. As the maximum seat sliding distance is increased, the injury risk becomes smaller.

Subject Keywords

Whiplash, Safety, Neck injury, Rear impact

URI

https://hdl.handle.net/11511/36654

Journal

JOURNAL OF THE BRAZILIAN SOCIETY OF MECHANICAL SCIENCES AND ENGINEERING

DOI

https://doi.org/10.1007/s40430-014-0192-5

Collections

Department of Mechanical Engineering, Article

Suggestions

OpenMETU
Core

Experimental and numerical investigation of comparability of whiplash sled test results ÖZDEMİR, MUSTAFA; İDER, SITKI KEMAL; Gökler, Mustafa İlhan (2016-02-01) Whiplash-associated neck injuries represent an important health and socioeconomic problem attracting more and more attention of the vehicle safety community. Sled tests are conducted for the dynamic whiplash assessment of seats. However, reproducibility of the initial backset distances and of the sled pulses in every test plays an important role on the comparability of these results. In this study, in order to investigate these aspects, three different driver seat types are considered with three identical a...
Experimental whiplash analysis with hybrid III 50 percentile test dummy Göçmen, Ulaş; Gökler, Mustafa İlhan; Department of Mechanical Engineering (2009) Whiplash injuries as a result of rear impact are among the most common injuries in traffic accidents. This is why whiplash injuries have reached a high priority in the research area. In this study, the effects of head restraint position and impact pulse to the whiplash injury have been analyzed by performing whiplash tests using the sled test facility of METU-BILTIR Center Vehicle Safety Unit. Although there are many whiplash test protocols, the test sample has been prepared according to the most recent one...
Analysis of whiplash during rear crash and development of an anti-whiplash seat mechanism Özdemir, Mustafa; İder, Sıtkı Kemal; Gökler, Mustafa İlhan; Department of Mechanical Engineering (2013) Whiplash injury is one of the most important types of injuries when its resulting longterm pain is considered. This neck injury is frequently seen in the motor vehicle collisions, especially in the low-speed rear collisions. In this thesis, it is aimed to analyze the whiplash syndrome in low-speed rear-end impacts and develop an antiwhiplash seat mechanism that reduces the risk of occurrence of whiplash injuries. Firstly, using the commercially available finite element model of the BioRID II dummy, backset ...
A comparison of roadside design approaches in terms of road safety to improve Turkish roadside safety standards Betus, Yakup; Tüydeş Yaman, Hediye; Department of Civil Engineering (2022-5-31) When an errant vehicle runs off the road, crashing into objects/ reaching places in the vicinity creates “run-off-road (ROR)” accidents, which may result in severe injuries or fatalities. Roadside designs with proper Road Restraint Systems (RRS) ideally should cause neither hazards to the third parties nor threats to the vehicle users. The major components of the RRSs are the Vehicle Restraint Systems (VRS), including the safety barriers (i.e., guardrails) designed to i) either stop the errant vehicle fully...
Development and characterization of (carbonated) hydroxyapatite, akermanite involving polycaprolactone scaffolds Altunordu, Gerçem; Keskin, Dilek; Department of Biomedical Engineering (2019) Bone tissue loss or damage can occur due to accidents, injuries and diseases (osteomyelitis, osteosarcaoma, osteoporosis, etc.). Bone tissue engineering (BTE) aims to develop biomaterials that enhance the regeneration of bone tissue. Therefore, scaffolds for BTE should be biocompatible and bioactive; enabling strong communication with bone tissue. Bioceramics are a group of biomaterials that resemble to native bone mineral and improve bioactivity of BTE scaffolds. Considering these hydroxyapatite (HA), carb...

Citation Formats

M. Ozdemir, S. K. İDER, and M. İ. Gökler, “Parametric analysis of an anti-whiplash system composed of a seat suspension arrangement,” JOURNAL OF THE BRAZILIAN SOCIETY OF MECHANICAL SCIENCES AND ENGINEERING, pp. 777–784, 2015, Accessed: 00, 2020. [Online]. Available: https://hdl.handle.net/11511/36654.