• Computational Structural Engineering
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• v.10 no.4
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• pp.12-21
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• 1997

차량충돌에 대하여 운전자의 안전확보를 위하여 새로 개발한 철재 중앙분리대에 대한 안전성 분석을 위하여 인체모형을 탑재한 실물차량 충돌실험을 실시하였다. 인체모형의 두부와 흉부, 대퇴부 및 차량의 무게중심점에서 가속도와 충격하중을 계측하여 철재 중앙분리대 방호울타리에 차량충돌시 운전자의 안전성을 검증한 결과 다음과 같은 결론을 도출하였다. 1) 철재 중앙분리대 방호울타리는 콘크리트 중앙분리대 방호울타리에 비해 운전자의 신체 상해치와 차량파괴 등에 있어서 뛰어난 충격흡수성능을 보여주었다. 2) 철재 중앙분리대 방호울타리는 콘크리트 중앙분리대 방호울타리의 경우 빈번히 발생하는 차량전복과 같은 2차사고의 유발 가능성이 전혀 없는 구조적 안정성을 보여주었다. 3) 경량의 차량충돌에 대하여 자체 탄성영역내에서 충격을 흡수하여 유지보수 측면에서 유리함을 나타냈다. 4) 충돌 수 충돌차량에 대한 차량유도성능이 뛰어났으며, 차량의 충돌후 이탈각도는 충돌각도의 60% 이내로 나타났다. 5) 철재 중앙분리대 방호울타리로부터 분리된 파편이 거의 없어 도로소통에 지장을 초래하지 않는다.

• Proceedings of the KAIS Fall Conference
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• 2004.06a
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• pp.47-49
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• 2004

본 연구는 자동차 충돌 시험에 관련된 항목 중 현재 많은 연구를 하고 있는 측면 충돌 시험 평가에 대한 법규를 지원해주기 위한 시스템 구축에 관한 것이다. 2003년 상반기 국내 최초 충돌 시험을 실시한 바 있고 전 세계적으로 측면 충돌 시험은 자동차 안전성 평가의 기본이 사항이다. 측면 충돌 시험은 각 국가별 상이한 법규와 시험 방법을 가지고 있기 때문에 각각의 내용을 인지하는 것은 자동차 충돌안전에 있어서는 필수 사항이다. 이번 연구는 측면 충돌 시험과 관련된 법규와 측면 충돌 시험 평가 결과값(별의 개수)을 가지고 평가에 대한 내용을 설명하고 이해를 지원해주는데 목적을 두고 있다.

• Journal of Auto-vehicle Safety Association
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• v.15 no.4
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• pp.48-57
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• 2023

With the advance of autonomous vehicle technology various sitting posture is possible like relax position (inclined seating posture). Parametric study was done with MADYMO, a mutibody dynamics solver, to investigate the effect of sitting posture in different frontal crash modes, full frontal, 40% offset, and angled rigid barrier crash as well as various impact speeds. Hybrid III 50th male and 5th female dummies were used to figure out the difference induced by occupant weight and dimension. Restraint system parameters complying to current safety protocols like NCAP are studied if they still work effectively in relax position which is feasible with autonomous vehicles.

• Korean Journal of Applied Biomechanics
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• v.13 no.1
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• pp.205-221
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• 2003

본 연구는 축구화 겉창의 스터드개발시 운동역학적 연구가 스터드개발에 어떻게 영향을 끼치었는가를 국외 선행연구문헌을 고찰함으로서 그 과정을 발견하는데 그 목적을 두었다. 지난 70년간 축구화 스터드가 연구개발되는 과정에서 압력분포측정 실험 및 기타 상해유발요인을 분석함으로서 스터드의 형태을 변화시키는 과정에 있어서 축구장 바닥과 축구화 겉창과의 마찰력이 중요한 변수로 작용하였다. 징이 선수들의 미끄럼을 방지하고 순발력을 향상시켜 경기력 향상에 결정적인 도움을 준 것이다. 이후 징박힌 축구화가 보편화하면서 선수들은 공격수냐 수비수냐 또는 잔디 상태에 따라 징의 개수와 길이가 다른 축구화를 신게 되었는데, 그라운드 컨디션에 따라 신발이 개발되었다. 축구화는 징의 종류에 따라 길고 푹신한 잔디($5{\sim}7$월 잔디)에 신는 50(soft ground)형, 짧고 단단한 잔디(가을철 잔디)에 적합한 FG(firm ground)형, 인조잔디나 아주 짧은 잔디에 좋은 터프(Turf)형, 맨땅에 쓰는 HG(hard ground)형으로 대별되는데, SG형은 15mm가 넘는 마그네슘 징을 6개 박는데 순발력과 파워를 극대화하기 때문에 수비수에 어울리는 스타일이다. 짧은 플리우레탄 징 12개를 다는 FG형은 넓은 그라운드 접촉면을 이루면서도 잔디에 깊게 박히지 않아 유연성을 필요로 하는 공격수와 미드필더들에게 애용된다. 그라운드 상황이 좋지 않은 곳에서 뛰는 국내 고교, 대학 선수들은 12개의 징이 달린 축구화를 선호한다. 스터드가 많을 수록 그라운드에 닿는 면적이 넓어 안정감도 있고 발목이 꺾이는 현상을 줄여주기 때문이다. 지금까지의 연구현황은 압력분포 및 지면반력실험을 이용한 결과치를 이용하여 새로운 타입의 축구화 스터드의 개발결과를 기존결과와 비교 분석하여 상해유발발생요인이 적은 스타일의 스터드를 선호하였다. 이에 향후 연구개발시 운동역학적 연구의 디자인 시 상해유발요인분석과 운동역학적 연구결과의 조합을 결과를 비교분석해서 국내에서도 축구화 겉창 스터드 연구개발시 경기력을 향상시키고, 상해유발요인을 감소시킬 수 있는 연구디자인이 지속되는 것이 중요하다고 사료된다.

• The Journal of the Institute of Internet, Broadcasting and Communication
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• v.15 no.4
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• pp.239-247
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• 2015

Recently, various research studies on frontal collision and rear-ender which occur more frequently compared to others are underway as the public interest on them is growing. This study analyzes scientifically the relationship between effective impact speed and injury incidence for vehicle crash accident reconstruction and presents a relevant model formula. Because real vehicle experiments have certain limitations such as possible injuries, this study efforts to collect and analyze as many materials as possible to substitute real vehicle experiments, including data from various collision tests and human experiments. As a result, this study present a threshold in which head-on collisions and rear impacts do not cause injuries under 7 km/h of effective impact speed, and suggests a model formula showing that injury extent is linearly proportional to effective impact speed through collision speed and amount of plastic deformation. In conclusion, a model formula for estimating effective impact speed and injury incidence newly proposed in this study is expected to be used as a minimum standard of judgment in disputes on the injury extent of passenger in head-on collisions and rear impacts. Furthermore its availability in terms of technological analysis in legal arguments is expected to be very high if this study will be enhanced by referring to scientific analyses of various real accidents so as to apply it in various types of collision accidents.

• Journal of Auto-vehicle Safety Association
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• v.8 no.1
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• pp.31-37
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• 2016

The Child Occupant Safety Assessment was first introduced and carried out by Euro NCAP in 2003, with the goal of ensuring manufacturers to develop safe vehicles for passengers of all ages; the objective was to evaluate the safety and protection offered by different Child Restraint Systems (CRS) in the event of a crash. In 2013, the formerly used P child dummy series was replaced by newer and more biofidelic Q1.5 and Q3 child dummies, representing 1.5 and 3 year old children respectively. The frontal and side impact dynamic performances of the Q1.5 and Q3 were tested within all classes of vehicles assessed by Euro NCAP at the time. As an extension to that initiative, Q6 and Q10 child dummies were later developed representing children of 6 and 10 years old. Since the protection of larger children during vehicle crashes relies greatly on the interaction of vehicle restraint systems such as seat belt and the CRS, instrumented Q6 and Q10 dummies will be used to assess the protection offered in the event of front and side impact crashes. In this paper, we focused on injury criteria of Q6 and Q10 child dummies at 64 kph 40% offset frontal crash test. The whole procedure was designed with DFSS analysis. The full vehicle sled test results of both dummies were conducted with different restraint systems settled through previous sled test. It showed that several injury criteria and image data were collected as the result of the full vehicle sled test. Based on the results of these investigations, this paper describes which factor is most important and combination shows the best performance when evaluating rear seat occupant protection for Q6 and Q10 child dummies.

• Journal of Auto-vehicle Safety Association
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• v.7 no.3
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• pp.7-13
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• 2015

Occupant protection performance in frontal crashes has been developed and assessed for mainly front seat occupants over many years, and in recent years protection of rear seat occupants has also been extensively discussed. Unlike the front seats, the rear seats are often occupied by children seated in rear-facing or forward - facing child restraint systems, or booster seats. In the ENCAP, child occupant protection assessments using 18-month-old(P1.5) and 3-year-old(P3) test dummies in the rear seat have already been changed to new type of 18-month-old (Q1.5)and 3-year-old(Q3) test dummies. In addition, ENCAP are scheduled with the development and introduction of test dummies of 6-year-old (Q6) and 10.5-year-old children(Q10) starting 2016. In KNCAP, Q6 and Q10 child dummies will be introduced in 2017 as well. Automobile manufacturers need to develop safety performance for new child dummies closely. In this paper, we focused on Q6 and Q10 child dummies sitting in child restraint system. Offset frontal crash tests were conducted using two types of test dummies, Q6 and Q10 child dummies, positioned in the rear seat. Q6 and Q10 were used to compare dummy kinematics in rear seating positions between Q6 behind the driver's seat and Q10 behind the front passenger's seat. The full vehicle sled test results of both dummies were conducted with different restraint systems. It showed that several injury and image data was collected as the result of the full vehicle sled test. Based on the results of these investigations, this paper describes which factor is most important and combination is the best performance when evaluating rear seat occupant protection for Q6 and Q10 child dummies.

• Journal of Environmental Health Sciences
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• v.24 no.3
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• pp.18-21
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• 1998

Bromobenzene 투여에 의한 간조직중 ATPase 활성을 관찰할 목적으로 흰쥐에 bromobenzene을 체중 kg당 400 mg을 복강으로 투여한 다음 4시간 후에 처치하여 다음과 같은 결과를 얻었다. Bromobenzene 투여로 인한 체중당 간무게는 유의하게 증가되었으나 간조직중 단백질 함량은 감소되었다. 혈청중 alanine aminotransferase 활성은 대조군과 별다른 차이를 볼수 없었다. 따라서 본 실험조건에서 Bromobenzene 처치 실험동물에서 간조직은 가역적상해로 생각되며 이러한 실험동물모델에 $Na^+/K^+$-ATPase 활성은 유의하게 (p<0.05)증가되었으며 이때 V$_{max}$ 치역시 대조군에 비하여 증가 되었다. 이때 간조직중 glutathione 함량은 감소되었으며 glutathione S-transferase 활성 및 cytochrome P-450 함량치는 증가되는 경향을 보였다.

• Journal of Biomedical Engineering Research
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• v.24 no.1
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• pp.15-21
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• 2003

In this study, for a safetv assessment of light weight wheelchair occupant in frontal crash, we tested a dynamic sled impact test. we carried out total 6 times test and impact speed was 20g/48 km/h. By using Hybrid III 50%ile male dummy, head injury criteria(HIC), neck flexion moment, neck axial tension force, neck shear force. chest acceleration, head, wheelchair and knee excursion were measured, we evaluated light weight wheelchair occupant safety by motion criteria(MC) which proposed in SAE J2249 and combined injury criteria(CIC) which is a voluntary standard(GM-IARV) of General Motors Co.. when we assumed that the maximum injury value in frontal crash was 100%, the result of motion criteria(MC) of wheelchair occupant was 52%, occupant upper body injury index(CIC) was 60.1%.

• Transactions of the Korean Society of Mechanical Engineers A
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• v.38 no.4
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• pp.385-391
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• 2014

A wheeled armored vehicle is a military vehicle that has been developed to enhance combat capabilities and mobility for the army. The wheeled armored vehicle has a high center of gravity, and it operates on unpaved and sloped roads. Therefore, this vehicle has a high risk of rollover crashes. To design the interior of the military vehicle, the crew's safety during rollover crashes is an important factor. However, actual vehicle tests for design are extremely expensive. In this paper, nonlinear dynamic analysis is performed to simulate the rollover crashes and the passenger injury is assessed for a wheeled armored vehicle. The scope of this research is the rollover condition, FE modeling of the wheeled armored vehicle and the dummy, arrangement of dummies, assessment of passenger injuries, and simulation model for rollover crashes.