• 제목/요약/키워드: Droplet Lifetime

검색결과 19건 처리시간 0.026초

내부순환유동을 고려한 연소하는 액적들의 상호작용 (Interaction of burning droplets with internal circulation)

  • 조종표;김호영;정진택
    • 한국연소학회:학술대회논문집
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    • 한국연소학회 2004년도 제28회 KOSCO SYMPOSIUM 논문집
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    • pp.183-191
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    • 2004
  • The burning characteristics of interacting droplets with internal circulation in a convective flow are numerically investigated at various Reynolds numbers. The transient combustion of 2-dimensionally arranged droplets, both the fixed droplet distances of 5 radii to 40 radii horizontally and 4 radii to 24 radii vertically, is studied. The results obtained from the present numerical analysis reveal that the transient flame configuration and retardation of droplet internal motion with the horizontal or vertical droplet spacing substantially influence lifetime of interacting droplets. At a low Reynolds number, lifetime of the two droplets with decreasing horizontal droplet spacing increases monotonically, whereas their lifetime with decreasing vertical droplet spacing decreases due to flow acceleration. This flow acceleration effect is reversed when the vertical droplet spacing is smaller than 5 radii in which decreasing flame penetration depth causes the reduction of heat transfer from flame to droplets. At a high Reynolds number, however, lifetime of the first droplet is hardly affected by either the horizontal droplet spacing or flow acceleration effect. Lifetime with decreasing vertical droplet spacing increases due to reduction of flame penetration depth. Lifetime of interacting droplets exhibits a strong dependence on Reynolds number, the horizontal droplet spacing and the vertical droplet spacing and can be con-elated well with these conditions to that of single burning droplet.

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액체 연료 액적들의 배열 및 크기차이가 증발 및 연소특성에 미치는 영향 (The Effects of Droplets Arrangement and Size Difference on the Vaporization and Combustion Characteristics of Liquid Fuel Droplets)

  • 이동조;김호영;조종표;윤석구
    • 한국연소학회:학술대회논문집
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    • 한국연소학회 2007년도 제34회 KOSCO SYMPOSIUM 논문집
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    • pp.107-113
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    • 2007
  • The burning characteristics of interacting droplets with internal circulation in a convective flow are numerically investigated at various particle arrangement and size difference. In this simulation some conditions are fixed, surround gas temperature is 1250K, pressure is 10 atm and drolet's initial temperature is 300K. The transient combustion of arranged droplets, the fixed droplet distances of 4 radii to 20 radii horizontally, is studied. And the range of size of droplet is 75${\mu}m$ to 100${\mu}m$. The results obtained from the present numerical analysis reveal that the transient flame configuration and retardation of droplet internal motion with the horizontal spacing substantially influence lifetime of interacting droplets. At a Reynolds number 10, lifetime of the three droplets with decreasing horizontal droplet spacing increases monotonically. But when droplet spacing decreases further to 4radii, Lifetime of interacting droplets are increase. So Lifetime of interacting droplets exhibits a strong dependence on the horizontal droplet spacing and size difference. It can be investigated well with these conditions to that of single burning droplet.

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탄화수소 연료 액적의 연소 특성에 관한 수치해석 (A Numerical Study of Combustion Characteristics of Hydrocarbon Fuel Droplet)

  • 이봉수;이경재;김종현;구자예
    • 대한기계학회논문집B
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    • 제27권11호
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    • pp.1595-1603
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    • 2003
  • Droplet combustion at high ambient pressures is studied numerically by formulating one dimensional combustion model in the mixture of n-heptane fuel and air. The ambient pressure is supercritical conditions. The modified Soave-Redlich-Kwong state equation is used in the evaluation of thermophysical properties to account for the real gas effect on fluid p-v-T properties in high pressure conditions. Non-ideal thermodynamic and transport property at near critical and supercritical conditions are also considered. Several parametric studies are performed by changing ambient pressure and initial droplet diameter. Droplet lifetime decreased with increasing pressure. Surface temperature increased with increasing pressure. Ignition time increased with increasing initial droplet diameter. Temporal or spatial distribution of mass fraction, mass diffusivity, Lewis number, thermal conductivity, and specific heat were presented.

액적배열연소의 상호간섭에 관한 실험적 연구 (An Experimental Study About Interaction of Droplet Array Combustion)

  • 김흥식;백승욱;박준성
    • 대한기계학회논문집B
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    • 제26권10호
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    • pp.1355-1363
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    • 2002
  • An experimental study was conducted to investigate the interaction phenomena of droplet array combustion in ambient environment. The droplet with 1 mm in diameter was supported from an optical fiber and ignited with a hot wire. Combustion lifetimes and burning rate constants were measured for fuel of nheptane according to parameters, which were junction and suspender spacings, and array configuration. Results show that the burning process considerably depends on the initial away configuration. The d$^2$-law is found to be correct when applied to both of the droplets in away and the single droplet. For separation distance of about 5mm, there exists a critical state. So the transition from a merged flame to separated flames occurs and burning velocity is much faster than before. Combustion lifetime of the lower droplet is shorter than that of the upper droplet in the two-dimensional arrays combustion. Burning rate constants of the droplets in arrays are smaller than that of the single droplet, while they become higher as separation distance increases. Combustion lifetimes of the droplets in arrays are longer than that of the single droplet and decrease as separation distance increase. It is concluded that the array configuration and the mergedness of the flame are the most important factors governing multi-droplet combustion.

고압 환경하에서 탄화수소 연료 액적의 기화특성 연구 (Vaporization of Hydrocarbon Fuel Droplet in High Pressure Environments)

  • 김성엽;윤웅섭
    • 대한기계학회:학술대회논문집
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    • 대한기계학회 2003년도 추계학술대회
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    • pp.127-132
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    • 2003
  • A study of high-pressure n-heptane droplet vaporization is conducted with emphasis placed on equilibrium at vapor-liquid interface. General frame of previous rigorous model[1] is retained but tailored for flash equilibrium calculation of vapor-liquid interfacial thermodynamics. The model is based on complete time-dependent conservation equations with a full account of variable properties and vapor-liquid interfacial thermodynamics. The influences of high-pressure phenomena, including ambient gas solubility, thermodynamic non-ideality, and property variation on the droplet evaporation are investigated. The governing equations and associated moving interfacial boundary conditions are solved numerically using a implicit scheme with the preconditioning method and the dual time integration technique. And a parametric study of entire droplet vaporization history as a function of ambient pressure, temperature has been conducted. Some computational results are compared with Sato's experimental data for the validation of calculations. For low ambient temperatures, the droplet lifetime first increases with pressures, then decreases for high pressures. For higher ambient temperatures, the droplet lifetime increase with less amplitude than that of low ambient temperatures, which then decreases with more amplitude than that of low temperatures. The solubility of nitrogen can not be neglected in the high pressure and it becomes higher as the pressure goes up.

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고온 고압 유동장에서 햅탄 액적의 기화 특성 (Characteristics of Heptane Droplet Vaporization in High-Pressure and Temperature Flow Field)

  • 고정빈;구자예
    • 한국분무공학회지
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    • 제9권4호
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    • pp.83-89
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    • 2004
  • Vaporization characteristics of a liquid heptane droplet in high-pressure and temperature flow field are numerically studied. Variable thermodynamic and transport properties and high-pressure effects are taken into account in order to consider real gas effects. Droplet Vaporization in convective environments was investigated on the basis of droplet vaporization in quiescent and convective environment. In quiescent environments, droplet lifetime is directly proportional to pressure at the subcritical temperature range but it is inversely proportional to pressure at the supercritical temperature range. In convective environment, droplet deformation becomes stronger by increasing Reynolds number due to increase of velocity while droplet deformation is relatively weak at a higher pressure for the same Reynolds number cases.

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실린더내의 연료 액적의 기화 과정에 관한 수치 연구 (Simulation for Fuel Droplet Evaporation in Cylinder)

  • 전흥신;김형택
    • 에너지공학
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    • 제11권1호
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    • pp.74-80
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    • 2002
  • 본 연구는 불꽃 점화 기관의 실린더내의 연료 액적의 기화과정에 대한 수치 해석이다. 본 연구의 특징은 무차원 임계 액적 수명시간을 정의하여 가솔린엔진의 흡입 및 압축행정동안 연료 액적의 가열 및 기화과정을 모델화한 것이다. 수치해석 결과는 압축행정동안 기체 온도 및 압력의 동시적 증가는 액적의 기화율에 서로 보상적인 영향을 미치려는 경향을 보이고 있다. 즉 실린더 내 환경의 변화는 연료 액적의 기화과정에 민감하지 않다는 것을 보이고 있다. 이 프로그램은 압축행정 말기에 완전히 기화할 수 있는 액적의 크기를 예측할 수 있다.

가열된 표면에 고착된 한 쌍의 액적 증발 특성 (Evaporation Characteristics of Paired Sessile Droplets on a Heated Substrate)

  • 이형주;황원영;김정호;최창경;이성혁
    • 한국분무공학회지
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    • 제28권3호
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    • pp.113-118
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    • 2023
  • This study investigates the evaporation characteristics of paired sessile droplets on a heated substrate. In particular, the evaporation time and contact line behaviors were analyzed based on the droplet-to-droplet distance and substrate temperature. The contact line behavior and volume variations were visualized using the shadowgraph method. It was observed that the contact diameter and contact angle exhibited similar behavior for both single and paired droplets regardless of the droplet-to-droplet distance and substrate temperature. The paired droplets demonstrated a longer evaporation time than the single droplet due to the vapor accumulation between the droplets. Furthermore, the scaled lifetime, defined as the ratio of evaporation time between paired and single droplets, increased as the droplet-to-droplet distance decreased and decreased as the substrate temperature increased, attributed natural convection.

상압에서 부탄올 젤 연료액적의 증발특성 (Evaporation Characteristics of a Butanol Gel-Fuel Droplet in Atmospheric Pressure Condition)

  • 남시욱;김혜민
    • 한국분무공학회지
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    • 제26권2호
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    • pp.73-80
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    • 2021
  • Evaporation characteristics of single butanol gel fuel were investigated in different mass ratios of gellant and ambient temperatures. Gel fuel was made by adding the pure water and hydroxypropylmethyl cellulose (HPMC) into the 1-butanol. Increase of viscosity was observed when the loading of HPMC increased. The evaporation process of gel droplet could be divided into three stages: droplet heating, micro-explosion and crust formation. Elevation of ambient temperature helped boost the evaporation in all experimental cases, but the effect was mitigated when the mass ratio of HPMC increased. Increase of HPMC weight ratio reduced the evaporation rate.

진동하는 유동장하에서 내부 순환 유동을 고려한 액적의 증발에 관한 수치적 연구 (A numerical study on the vaporization of a droplet considering internal circulating flow in the presence of an oscillating flow)

  • 하만영
    • 대한기계학회논문집B
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    • 제20권5호
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    • pp.1700-1716
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    • 1996
  • The two-dimensional, unsteady, laminar conservation equations for mass, momentum, energy and species transport in the gas phase and mass, momentum and energy in the liquid phase are solved simultaneously in spherical coordinates in order to study heating and vaporization of a droplet entrained in the oscillating flow. The numerical solution gives the velocity and temperature distribution in both gas and liquid phase as a function of time. When the gas flow oscillates around an vaporizing droplet, the liquid flow circulates in the clockwise or counterclockwise direction and the temperature distribution in the liquid phase changes its shapes, depending on the gas fow direction. When the gas flow changes its direction of circulating liquid flow is opposite to the gas flow, forming two vortex circulating in the opposite direction. During the heating period, the difference in the maximum and minimum temperature is large, followed by the almost uniform temperature slightly below the boiling temperature. The mass and heat transfer from the droplet depend on the droplet temperature, droplet diameter and the magnitude of relative velocity, giving the droplet lifetime different from the d$^{2}$-law.