• Title/Summary/Keyword: Rear-impact

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실차시험을 통한 저속 추돌시 목상해 연구 (A Study on the Neck Injury in Low Speed Rear Impact through the Real Car Test)

  • 조휘창;박인송
    • 한국기계기술학회지
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    • 제13권1호
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    • pp.49-56
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    • 2011
  • The neck injury occupies the most of injury that happened by the rear impact car accident. This study was analyzed about influence of the neck injury in low speed rear impact and car crash accident investigation. There is no neck injury in low speed side rear impact. On the other hand, there is initial neck injury symptom of 10 % but no long-term neck injury symptom in low speed offset rear impact. It appeared that the possibility of neck injury in low speed rear impact is low. For the more study about the neck injury, it should be evaluate the effects of the car body structure, frame structure and rear crash pattern.

저속 추돌시 충돌방향에 따른 목상해 해석 (A Study on Influence of the Impact Direction on the Neck Injury during Low Speed Rear Impacts)

  • 조휘창;김영은
    • 한국자동차공학회논문집
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    • 제15권2호
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    • pp.135-142
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    • 2007
  • MADYMO human model with the detail neck was used to investigate the reaction force of neck and neck injury from rear impact directions. In the validation simulation, head acceleration, thorax acceleration and the global kinematics of the head and neck were correlated well with experimental data. Acceleration data from three 15 km/h low speed car rear impact pendulum tests(rear-end, offset, oblique) were used to simulate the model. In the simulation results, the reaction force on the facet joint and discs in the oblique rear impact were higher than rear-end, offset rear impacts. Further research is still needed in order to neck injury analysis about different crash parameters.

자동차 충돌 해석에 관한 기초 연구 (Basic Study on Impact Analysis of Automobile)

  • 조재웅;민병상;한문식
    • 한국기계가공학회지
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    • 제8권1호
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    • pp.64-70
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    • 2009
  • This study is to analyze the impact of automotive body with computer simulation. The total deformation, equivalent strain and strain and principal stress are analyzed respectively in case of front, rear and side impacts. The maximum total deformation of side impact is more than 6 times as large as that of rear impact. The maximum equivalent strain or stress of side impact is more than 4 times as large as that of rear impact. These deformation, strain and stress of front impact are a little more than those of rear impact. The maximum principal stress of side impact is more than 4.5 times as large as that of rear impact. This stress of front impact is a little more than that of rear impact.

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충돌 접촉에 있어서의 차체와 승객의 손상 (Damage of Car Body and Passenger at Impact Contact)

  • 한문식;조재웅
    • 한국생산제조학회지
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    • 제20권3호
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    • pp.280-283
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    • 2011
  • This study investigates the durability of car body and the safety of passenger inside car body in the case of the impact contact at passenger and car body. In case of front impact contact, maximum von Mises equivalent stress and principal stress become 3240.7MPa and 1634MPa respectively at the rear part of car body and the neck of dummy. And maximum total deformation occurred with 14.145mm at the hand of dummy. In case of side impact contact, maximum von Mises equivalent stress and principal stress become 7687.9MPa and 1690.7MPa respectively at the front part of car body and the lap of dummy. And maximum total deformation occurred with 16.414 mm at the foot of dummy. In case of rear impact contact, maximum von Mises equivalent stress and principal stress become 2366.6MPa and 1447MPa respectively at the front part of car body and the neck of dummy. And maximum total deformation occurred with 7.548mm at the rear part of car body. As the maximum von-Mises stress at side impact is shown with more than 700MPa as over two times at front or rear impact the danger of car body is increased. The great possibility of damage is shown at neck and hand of dummy with more than total displacement of 10mm.

저속 후면 추돌 시 목부상해 예방을 위한 연구 (Stildy on the Methodology to Prevent Neck Injury at tow Speed Rear-End Impact)

  • 박인송;전용범;김관희;임종훈
    • 한국자동차공학회논문집
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    • 제13권5호
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    • pp.29-34
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    • 2005
  • 141,841 car-to-car collision had occurred in 2003, and among the accidents 51,796 were rear-end impact. According to insurance company for loss or damage, more than $60\%$ of rear-end impact victims suffer neck injury. This means at least 31,000 neck injury victims have happened in 2003. More than $97\%$ of the neck injury victims have low severity injury than A.I.S 2. Head restraint, which is designed to limit rearward head movement and equipped on seat, can considerably protect neck from rear-end impact. In this paper we evaluated head restraint geometry and drivers' sitting position according to RCAR standard and carried out low speed volunteer crash test. The crash speed is 4km/h and N.I.C value is used to determine injury probability. Through these research results we can introduce the method to prevent neck injury at rear-end impact.

SIMULATION OF AUTOMOTIVE SEAT FOR REDUCING NECK INJURY IN LOW-SPEED REAR IMPACT

  • CRO H. C.
    • International Journal of Automotive Technology
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    • 제6권2호
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    • pp.161-169
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    • 2005
  • Neck injuries sustained during low speed rear impact are the most commonly sustained traffic injury. Therefore, the analysis of neck injury mechanisms and methods for mitigating and reducing neck injuries during low speed rear impact are a very important issue in the vehicle safety field. In order to find a method to absorb the shock that is transmitted to the occupant, the response of frontal and rear dummy due to the motion of the struck vehicle and the rotational angular displacements of dummies' necks during rear impact at 12km/h speed were investigated using a Working Model 2D. The results suggest that the shock absorption system should be equipped in the bottom of the seat of the vehicle to reduce shock and mitigate neck injury to the occupants.

후방 충돌 펄스와 NCAP 펄스 차이로 인한 목상해 특성 비교 (Compare Characteristics of Neck Injuries between Rear Impact Pulse and NCAP Pulse)

  • 김종곤;박종호
    • 자동차안전학회지
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    • 제9권3호
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    • pp.7-12
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    • 2017
  • The whiplash is the most important issue of low speed rear-impact. So auto makers are committed to developing a seat to improve whiplash injury. Most NCAP tests have been used by same pulse (Mid Velocity 16kph). Only Euro NCAP uses different pulse that consists of Low, Mid, High velocity. But Euro NCAP also uses same pulse in Mid velocity as other NCAP test. That Mid velocity NCAP pulse was made by rear impact that has 90's vehicle structure properties. That pulse was used until now days. However these days, auto maker use more high tensile steel than 90's as customer and society demand more fuel efficiency and light vehicle with good safety structure. So modern vehicles have different pulse patterns of rear impact than NCAP pulse and 90's vehicle crash properties. In this paper, the test was conducted by following condition. Target car was impacted by the rigid barrier with certain velocity. Finally target vehicle gained delta V 16kph which was same velocity as NCAP Mid Velocity pulse. It is critical velocity which occur long period neck injury. It is very different pulse that was gained by real car impact from NCAP pulse. And it has higher peak G with high fluctuation and short duration than NCAP pulse.

고속충격을 받는 외장 UHPC 패널의 내충격성능 (Impact Resistance of UHPC Exterior Panels under High Velocity Impact Load)

  • 강현구;김상희;김민수;홍성걸
    • 콘크리트학회논문집
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    • 제28권4호
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    • pp.455-462
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    • 2016
  • 본 실험적 연구는 고속 비상체 충돌 시 UHPC 외장재의 내충격성을 파악하는데 그 목적이 있다. 이 연구에서는 두께를 주요 변수로 UHPC과 화강암 패널 실험체에 고속충격을 가하여 실험체의 성능을 비교하였으며, 배면의 변형률을 기록하였다. UHPC는 외관이 우수하였으며, 내충격성도 화강암에 비해 우수하여 외장재로 사용하기에 적당하다고 판단된다. 비상체가 시험체에 충돌한 후 압축파가 배면에 도달하고 그 후 자유단 지점을 중심으로 인장파가 발생하여서 배면파괴를 일으킨 것으로 사료된다. 이러한 배면파괴 발생 메커니즘은 변형률 기록이 압축파구간, 보합구간, 인장구간으로 나누어지는 것을 통해 알 수 있다. 관통파괴 형태를 살펴보면 고속 충돌 시 전단력이 배면에 작용하여 파괴가 발생되는 shear plug 현상이 나타난 것으로 판단된다. 즉 충격하중에 대하여 배면의 파괴는 전단력과 인장응력에 의해 동시에 영향을 끼쳐 발생한 것으로 사료된다.

차량 저속 추돌의 연속 접촉력 모델 (Continuous Contact Force Model for Low-Speed Rear-End Vehicle Impacts)

  • 한인환
    • 한국자동차공학회논문집
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    • 제14권4호
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    • pp.181-191
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    • 2006
  • The most common kind of vehicular accident is the low-speed rear-end impact that result in high portion of insurance claims and Whiplash Associated Disorders(WAD). The low-speed collisions have specific characteristics that differ from high speed collisions and must be treated differently This paper presents a simple continuous contact force model for the low-speed rear-end impact to simulate the accelerations, velocities and the contact force as functions of time. A smoothed Coulomb friction force is used to represent the effect of braking, which was found to be significant in simulating low-speed rear end impact. The intervehicular contact force is modeled using nonlinear damping and spring elements with coefficients and exponents. This paper presents how to estimate analytically stiffness and damping coefficients. The exponent of the nonlinear contact force model was determined to match the overall acceleration pulse shape and magnitude. The model can be used to determine ${\Delta}Vs$ and peak accelerations for the purpose of accident reconstruction and for injury biomechanics studies.

Statistical Model of Effective Impact Speed based on Vehicle Damages in Case of Rear-End Collisions

  • Kang, Sung-Mo;Kim, Joo-Hwan
    • Journal of the Korean Data and Information Science Society
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    • 제19권2호
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    • pp.463-473
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    • 2008
  • In this study, we measure damage depth and calculate effective impact speed in case of rear-end collision using real car insurance data. We study the relationship between demage depth and effective impact speed, and present statistical model for these two variables. In our real data study, 3-degree polynomial equation model is better fit to effective impact speed and demage depth than the simple linear model that are estimated in previous other studies. Damage depth is a major factor to see the extent of impact in a car collision, and by using this equation, it is possible to evaluate the severity of driver's injury.

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