PURPOSES : This study aims to perform a quantitative analysis of Forward Collision Warning and crash frequency using heavy vehicle driving data collected in expressway driving environments, and to classify the driving environments where Forward Collision Warnings of heavy vehicles occur for accident-prone areas and analyze their occurrence characteristics. METHODS : A bivariate Gaussian mixture model based on inter-vehicle distance gap and speed-acceleration parameters is used to classify the environment in which Forward Collision Warning occurs for heavy vehicles driving on expressways. For this analysis, Probe Vehicle Data of 80 large trucks collected by C-ITS devices of Korea Expressway Corporation from May to June 2022. Combined with accident information from the past five years, a detailed analysis of the classified driving environments is conducted. RESULTS : The results of the clustering analysis categorizes Forward Collision Warning environments into three groups: Group I (highdensity, high-speed), Group II (high-density, low-speed), and Group III (low-density, high-speed). It reveals a positive correlation between Forward Collision Warning frequency and accident rates at these points, with Group I prevailing. Road characteristics at sites with different accident incidences showed that on-ramps and toll gates had high occurrences of both accidents and warnings. Furthermore, acceleration deviation at high-accident sites was significant across all groups, with variable speed deviations noted for each warning group. CONCLUSIONS : The Forward Collision Warning of heavy vehicles on expressways is classified into three types depending on the driving environment, and the results of these environmental classifications can be used as a basis for building a road environment that reduces the risk of crashes for heavy vehicles.

A bond-based peridynamic model has been reported dynamic fracture characteristic of brittle materials through a simple constitutive model. In the model, each bond is assumed to be a simple spring operating independently. As a result, this simple bond interaction modeling restricts the material behavior having a fixed Poisson’s ratio of 1/4 and not being capable of expressing shear deformation. We consider a state-based peridynamics as a generalized peridynamic model. Constitutive models in the state-based peridynamics are corresponding to those in continuum theory. In state-based peridynamics, thus, the response of a material particle depends collectively on deformation of all bonds connected to other particles. So, a state-based peridynamic theory can represent the volume and shear changes of the material. In this paper, the perfect plasticity is considered to express plastic deformation of material by the state-based peridynamic constitutive model with perfect plastic flow rule. The elastic-plastic behavior of the material is verified through the stress-strain curves of the flat plate example. Furthermore, we simulate the high-speed impact on 3D granite model with a nonlocal contact modeling. It is observed that the damage patterns obtained by peridynamics are similar to experimental observations.

25% offset high speed frontal impact is the vehicle will crash left 25%(Quarter of the width of the vehicle). 47.6% of drivers killed in vehicle alone and car to car frontal impact occurred in frontal impact small overlap. Study on the occupant protection performance of 25% offset(small overlap) high speed frontal impact results are as follows. In terms of vehicle occupant protection performance, body structure was excessive intrusion into the passenger room and showed such improvement is needed for the design. This is due to a collision risk with the passenger and the solid body increases the risk of injury, showed that improvement is needed. To strengthen the safety of the future, propose improvements on the evaluation results of a statistical analysis and test of the industry and the policy makers.

Bulk nanostructured copper was fabricated by a shock compaction method using the planar shock wavegenerated by a single gas gun system. Nano sized powders, average diameter of 100 nm, were compacted into the cap-sule and target die, which were designed to eliminate the effect of undesired shock wave, and then impacted with analuminum alloy target at 400 m/s. Microstructure and mechanical properties of the shock compact specimen were ana-lyzed using an optical microscope (OM), scanning electron microscope (SEM), and micro indentation. Hardness resultsshowed low values (approximately 45~80 Hv) similar or slightly higher than those of conventional coarse grained com-mercial purity copper. This result indicates the poor quality of bonding between particles. Images from OM and SEMalso confirmed that no strong bonding was achieved between them due to the insufficient energy and surface oxygenlayer of the powders.

Experimental measurements of flame shape and heat transfer characteristics were performed for impinged inverse diffusion flame(IDF) using propane as a fuel. The purpose of this study is to identify the favorable co-axial inverse diffusion flame structure for impingement heating. The flame consisted of an entrainment zone and mixing and combustion zone. The heat flux which represents heat transfer rate is measured by using a heat flux sensor that is located at the center of the impingement plate. The inverse diffusion flame structure has been classified into six modes. In these modes, several favorable flames for impingement heating were identified. In this study, the parameters are overall equivalent ratio(Φ), nozzle to impingement plate distance(h/d), vertical distance from the stagnation point and Reynolds number(Re) of combustion air.

충격흡수시설의 충돌거동은 보통 0.4초 미만의 짧은 순간에 일어나므로 삼차원의 매우 복잡한 거동을 수치적으로 계산한다는 것은 쉽지 않다. 따라서 새로운 충격흡수시설을 개발할 때 특별한 설계단계를 거치지 않고 실물차량 충돌시험에만 의존하고 있는 실정이다. 충돌시험에서 탑승자 안전도를 평가하기 위해서 계측기를 통해 가속도와 각속도를 추출하여 계산하고 있으며 고속카메라를 이용해 차량과 충격흡수시설의 충돌거동을 촬영한다. 하지만 고속카메라 영상의 활용범위는 제한적으로 사용되고 있으며, 탑승자 안전도 분석이나 충격흡수시설의 에너지소산 메커니즘을 분석하기위해 활용된 사례가 없다. 본 연구에서는 계측기로부터 획득한 데이타와 고속카메라 영상분석을 통해 추출된 데이타를 비교해 적합성 여부를 판단하고 탑승자 안전도 해석이나 충돌거동을 분석 에 활용할 수 있는 방안을 모색하였다.

The microstructure of the reagion of carters, created by Cu and W-Cu shaped charge jets, in a 1020 mild steel target has been intestiaged. The region ahead of the crater created by the Cu shaped charge jet, reveals dramatic grain refinement implying the occurrence of a dynamic recrystallization, while that of W-Cu one dose a martensitic transformation indicative of heating up to an austenitic region followed by rapid cooling.The impacting pressure calculated when the W-Cu shaped charge jet encounters the target is higher than that of the Cu one. The micro-hardness of the region ahead of the crater created by the W-Cu shaped charge jet is also higher than that of the Cu one. The microstructure of W-Cu slug remained in the inside of the craters depicts the occurrence of the remarkable elongation of W particles during the liner collaphse. From these results, the microstructural variation of the region ahead of the crater with Cu and W-Cu shaped charge jets is discussed in trems of the pressure dependency of the transformation region of ferrite and austenite phases.

During the last 10 years, the various type of high speed craft have been greatly developed, and since around of 1990 the large size of high speed passenger and/or cargo vessels are also introduced and took into the service in the various routes over the world. In a marine traffic way some bridge need to build across a rivers, cannals or a waterways. This one will be an obstruction and potential risk of collision in the way of high speed craft. Accordingly some of collision accident have been reported, which were caused by a lost control, wind and hydrodynamic forces, fog or human errors. In this paper a high speed craft having 40 m length is assumed to be collided with a circular type of bridge piers at right angle. The mode of deformation, penetration depth of collapse, impact forces, reduction of speed, loss of kinetic energy, and influence of scantlings, etc. have been calculated in each speed with a time variation to find a maximum values within a limit, and are graphically presented.

In this study, computer simulation was conducted to evaluate the vulnerability of bridge columns under vehicle impact loading. Firstly, the Preliminary Risk Analysis was conducted to determine if the next step is necessary. In the next step, the Simplified Risk Analysis was conducted to determine the level of risk. According to SRA, if the bridge is confirmed in the category of high risk level, the bridge columns were classified into five types based on the slenderness ratios. Finally, using the five types of bridge columns, the deformation of bridge columns were predicted by conducted collision simulations.

차량충돌은 가장 빈도가 높은 교량 붕괴의 원인 중 하나로 알려져 있으며, 최근 재해에 대하여 대책 수립 및 관리의 필요성이 공익 안전을 위해 제기되고 있다. 본 연구에서는 차량 충돌로 인한 교량 피해에 대하여 위험도 분석을 실시하였다. 위험도 분석 단계는 세 단계로 구 분하였고, 예비위험분석 단계에서는 충돌의 발생가능성을 확인하며, 기본위험분석 단계에서는 발생가능성, 취약성, 중요도에 대한 위험도 점 수평가를 통한 위험도 등급을 산정하였다. 마지막 상세위험분석 단계에서는 위험도가 높은 등급에 대하여 상세분석을 실시한다. 본 연구에서 는 예비위험분석과 기본위험 단계에 집중하여 위험도 등급 구분을 위한 네 가지의 급간분류법을 적용하였다. 충돌 사례와 분석 결과를 비교하 여 적절한 급간분류법을 결정하고자 하였다. 본 연구에서 사용된 위험도 분석법은 유사한 재난에 대한 대책수립을 위해 사용될 수 있을 것이다.

Bridges have been collapsed due to disaster, and this has required much of expenses. Vehicle collision cause critical damage on Bridges. This paper focus on vehicle collision risk level for highway bridges. In this study use 4 classification, Natural Break based Interval, Equal Interval, Standard Deviation based Interval and Reliability based Interval.

To assess the protection performance and the applicability as protective materials of high performance fiber reinforced cementitious composites(HPFRCC), this study performed the impact tests with 40 mm gas-gun propelled projectile crash machine. From this study, it has observed that both high compressive strength of cement matrix and fiber reinforcement are beneficial for the improvement of impact resistance.

Tensile stress and strain of rear by shock wave become the cause of rear side scabbing of concrete subjected to high-velocity impact. Improvement of flexural and tensile performance by fiber reinforcement has great effect on the suppression of the rear scabbing.