• 한국전산유체공학회:학술대회논문집
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• 한국전산유체공학회 2008년도 춘계학술대회논문집
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• pp.80-83
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• 2008

The characteristics of the spread of a forest fire are generally related to the attributes of combustibles, geographical features, and meteorological conditions, such as wind conditions. The most common methodology used to create a prediction model for the spread of forest fires, based on the numerical analysis of the development stages of a forest fire, is an analysis of heat energy transmission by the stage of heat transmission. When a forest fire breaks out, the analysis of the transmission velocity of heat energy is quantifiable by the spread velocity of flame movement through a physical and chemical analysis at every stage of the fire development from flame production and heat transmission to its termination. In this study, the formula used for the 1-dimensional surface forest fire behavior prediction model, derived from a numerical analysis of the surface flame spread rate of solid combustibles, is introduced. The formula for the 1-dimensional surface forest fire behavior prediction model is the estimated equation of the flame spread velocity, depending on the condition of wind velocity on the ground. Experimental and theoretical equations on flame duration, flame height, flame temperature, ignition temperature of surface fuels, etc., has been applied to the device of this formula. As a result of a comparison between the ROS(rate of spread) from this formula and ROSs from various equations of other models or experimental values, a trend suggesting an increasing curved line of the exponent function under 3m/s or less wind velocity condition was identified. As a result of a comparison between experimental values and numerically analyzed values for fallen pine tree leaves, the flame spread velocity reveals has a error of less than 20%.

• Journal of the Korean Wood Science and Technology
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• 제30권3호
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• pp.18-25
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• 2002

Research to discuss the fire performance of materials requires tools for measuring their burning characteristics and validated fire growth models to predict fire behavior of the materials under specific tire scenarios using the measured properties as input for the models. In this study, burning characteristics such as time to ignition, weight loss rate, flame spread, heat release rate, total heat evolved, and effective heat of combustion for four types of wood-based materials were evaluated using the cone calorimeter and inclined panel tests. Time to ignition was affected by not only surface condition and specific gravity of the tested materials but also the type and magnitude of heat source. Results of weight loss rate, measured by inclined panel tests, indicated that heat transfer from the contacted flame used as the heat source into the inner part of the specimen was inversely proportional to specific gravity of material. Flame spread was closely related with ignition time at the near part of burning zone. Under constant and severe external heat flux, there was little difference in weight loss rate and total heat evolved between four types of wood-based panels. More applied heat flux caused by longer ignition time induced a higher first peak value of heat release rate. Burning characteristics data measured in this study can be used effectively as input for fire growth models to predict the fire behavior of materials under specific fire scenarios.

• 한국화재소방학회:학술대회논문집
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• 한국화재소방학회 1997년도 International Symposium on Fire Science and Technology
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• pp.193-200
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• 1997

Flame spread and heat release properties and incident heat flux of interior materials subject to an igniter heat flux in a compartment are investigated and compared by using computer model. A comer fire ignition source is maintained for 10 minutes at 100 kw and subsequently increased to 300kw. In executing the model, base-line material properties are selected and one is changed for each run. Also 4 different igniter heat flux conditions and examined. Results are compared for the 12 different materials tested by the ISO Room Comer Test (9705). The time for total energy release rate to reach 1MW is examined. The parameters considered include flame heat flux and thermal inertia, lateral flame spread parameter, heat of combustion and effective heat of gasfication. The model can show the importance of each property in causing fire growth on interior Hnish materials in a compartment. The effect of ignitor heat flux and material property effects were demonstrated by using dimensionless parameters a, b and Tb. Results show that for b greater than about zero, flashover time in the ISO Room-Corner test is principally proportional to ignition time and nothing more.

• 한국화재소방학회논문지
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• 제12권2호
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• pp.17-28
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• 1998

건물 화재시 예상되는 내장재의 실째 화재성농올 기준으로 한 위험성 명가방법올 제시하였다. 이률 위해 ISO Room Corner Test. (9705)를 기준으로 Qui ntie re의 화재확산 모델을 이용하여 내장재의 열 적 특성과 플래쉬 오버 도달시간과의 상관성을 유도하고 스쩨덴의 실제 시험결과와 비교 분석하였다. 이 결과, 내장재의 상대척인 화재위험성은 화재확산 변수 b륨 기준으로 명가될 수 있었다.

• 방재기술
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• 통권24호
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• pp.32-39
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• 1998

A room-corner fire scenario of ISO 9705 with flame spread model developed by Quintiere is applied to the interior finish materials to show the sensitivity of properties derived from AST, E-1321 and ASTM E-1354 is investigated and various range of thermal properties by the author were analyzed in the model. There are including flame heat flux and thermal inertia, lateral flame spread parameter, heat of combustion and effective heat of gasfication. The time for total energy release rate to reach 1MW is examined. Though some areas are neede for improvements, The model appears to predict good results with all the range of input properties and could be

• 한국화재소방학회논문지
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• 제22권2호
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• pp.63-69
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• 2008

산불의 확산특성은 일반적으로 가연물의 특성, 지형, 바람조건과 같은 기상 상태등과 관련이 있다. 산불의 발달과정에 있어 수치해석을 통한 확산예측 모델은 열전달 과정에 기본을 둔 열에너지 전달에 대한 해석이 가장 일반적인 방법론이다. 산불의 발생시 열에너지의 전파속도를 해석하는 것은 화염의 생성과 열전달, 그리고 소멸에 이르는 전 과정에 대한 물리적, 화학적 해석을 통해 화염의 이동에 따른 전파속도로 추정할 수 있다. 본 논문에서는 고체연소물질의 표면화염전파에 대한 수치해석을 통해 1차원 지표화 확산모델식을 제시하였다. 1차원 확산모델식은 평지상태에서 풍속조건에 따른 화염의 전파속도 산정식으로써 지표연료의 화염유지시간, 화염의 높이, 화염의 온도, 지표연료의 착화온도 등에 대한 실험 및 이론식을 적용하였다. 실험값 및 다른 모델식과의 ROS 비교 결과, 풍속 3 m/s 이하의 조건에서는 지수함수식의 증가곡선을 나타내는 경향을 보였다. 침엽수종인 소나무 낙엽에 대한 수치해석값과 실험값을 비교한 결과, 풍속 1-2m/s 조건에서는 확산속도가 약 10% 상향예측이 되었고 풍속 3m/s 조건에서는 약 20% 하향예측 되었다. 따라서 앞으로 지표화 확산 예측을 위해 본 연구결과에서 얻어진 화염확산 알고리즘을 이용한 초기 산불확산 예측 적용이 가능할 것으로 사료된다.

• 한국건축시공학회:학술대회논문집
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• 한국건축시공학회 2020년도 봄 학술논문 발표대회
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• pp.216-217
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• 2020

As the fire inside the building grows rapidly, ejected flame from an opening occurs due to flashover. As a result, the number of cases where the flame spreads to the exterior of the building and rapidly expands to the upper floor is increasing. In particular, in the case of the fire in the Daebong Green Apartment, Uijeongbu in 2015, it was a case where the flame spread to adjacent buildings due to the opening eruption flame from the first ignited building, causing great damage to three apartments. Therefore, this study is to introduce an international standard under development that estimates the shape and properties of the ejected flame from an opening and quantitatively evaluates the radiant heat flux received by the exterior wall of the building by assuming the occurrence of the ejected flame from an opening.

• 대한기계학회논문집B
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• 제28권9호
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• pp.1093-1100
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• 2004

Numerical analysis of the heat transfer associated with droplet impact on a hot solid surface is performed by solving the equations governing conservation of mass, momentum and energy in the liquid and gas phases. The deformed droplet shape is tracked by a level set method which is modified to achieve volume conservation and to include the effect of contact angle at the wall. The numerical method is validated through the calculations for the cases reported in the literature. Based on the numerical results, the heat transfer rate is found to depend strongly on the droplet spread radius. Decreased advancing/receding contact angles enlarge the splat radius and in turn enhance the wall heat flux. The effect of impact velocity on the droplet spread is reduced as the droplet size decreases. Also, droplet atomization is observed to significantly enhance the heat transfer rate and the effect is pronounced for a smaller size of droplet. An existing model equation to predict the maximum spread radius is improved for application to a micro droplet.

• 한국전기전자재료학회논문지
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• 제26권2호
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• pp.158-163
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• 2013

In this paper, thermal analysis of heatsink for 30 W class Chip-on-Board (COB) LED light source is performed by using SolidWorks Flow Simulation package. In order to increase the convection heat transfer, number of fin and shape of the heatsink is optimized. Furthermore, a copper spread is applied between the COB LED light source and the heatsink to mitigate the heat concentration on the heatsink. With the copper spread, the junction temperature between the COB LED light source and the heatsink is $50.9^{\circ}C$, which is $5.4^{\circ}C$ lower than the heatsink without the copper spread. Due to the improvement of the junction temperature, the light output is improved by 5.8% when the LED light source is stabilized. The temperature difference between the simulation and measured result of the heatsink with the copper spread is within $2^{\circ}C$, which verifies the validity of the thermal design method using a simulation package.

• 한국재난정보학회 논문집
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• 제17권3호
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• pp.617-626
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• 2021

연구목적: 본 연구는 도심지 인접에서 발생하는 산불의 불티로 인한 건축물 외장재 및 지붕재의 화재확산 위험성 평가를 목적으로 한다. 연구방법: 이러한 연구목적을 달성하기 위해서 건축물의 외장재와 지붕재로 사용되는 건축자재를 선별하여 착화시간, 총 방출열량, 열방출률을 확인하고 산불 불티 비화 시스템을 구축하여 산불 불티로 인한 각각의 재료에 대한 화재 확산 가능성을 확인하였다. 연구결과: 콘칼로리미터 실험결과 지붕재는 철판이 외부에 노출된 외장재에 비해 복사열로 인한 착화시간이 비슷하거나 빨랐으며 외장재보다 높은 열방출률과 총 방출열량을 나타냈으며, 불티 비화 실험에서 외장재는 하부에 가연물이 착화함에 따라 영향을 받았으나 제한된 가연물의 양으로 쉽게 확산하지 않고 내부에서 탄화흔이 나타난 것을 확인할 수 있었으나 지붕재의 경우 사용 재료에 따라 불티로 인한 가연물 착화로 쉽게 녹고 주변으로의 확산에 기여하는 것을 확인할 수 있었다. 결론: 콘칼로리미터 실험 방법은 복사열로 건축자재의 연소 특성을 파악하는데 유용한 것으로 나타났으나 산불에서 불티로 인한 화재확산은 주변 가연물의 착화로 직접 화염에 영향을 받아 콘칼로리미터 방법과 직접적인 연관성을 찾는 것은 어려움이 있고 외장재에 비해 지붕재가 불티로 인한 화재 확산에 더 취약할 수 있는 것으로 판단된다.