竖直微槽道内沸腾换热CHF实验研究

对于沸腾换热,一个主要的约束条件就是临界热流密度(Critical Heat Flux,简称CHF)。这个约束条件对沸腾换热量有一个最高值的限制。文中对矩形微槽道中的流动沸腾临界热流密度进行了实验研究。实验数据是在不同尺寸(0.15mm;0.4mm;1mm)微槽道中,在较大范围的面积质量流速和不同进口过冷度下,以去离子水为工质得到的。实验过程中发现,达到CHF时,靠近出口壁面温度会突然升高,此时传热效率迅速下降。实验数据分析结果表明:CHF随质量流量的增加而增加;进口过冷度对CHF没有明显影响;CHF随着出口干度的增加而降低。     

微槽道纳米流体饱和沸腾CHF特性研究

以水和三种不同质量分数(0.2%、0.5%和1.0%)的Al2O3纳米流体作为实验工质,在三种不同尺寸微槽道中进行饱和沸腾传热实验,研究沸腾传热过程中临界热流密度(Critical Heat Flux,简称CHF)的变化特性。主要分析了微通道水力半径、纳米流体浓度、进口过冷度和临界热力学干度等因素对CHF的影响。实验结果发现:在水力半径较小的槽道内CHF发生得比较早;CHF随纳米流体浓度的增大而增大;CHF随进口过冷度增大有细微增大的趋势;CHF随临界热力学干度的增大而减小。文中还将实验结果与现有的、工况条件与本实验相近的理论模型进行了拟合比较,发现理论模型能较好预测本实验。     

滞止区内过冷液体喷流沸腾的临界热流密度

本文对高温平板滞止区内三种过冷液体的圆形喷流冲击沸腾的临界热流密度进行了系统的稳态实验研究。考察了过冷度、流速、喷流直径等流动条件对喷流沸腾临界热流密度的影响。建立了预示液体临界热流密度的半经验型方程。     

卧式螺旋管内过冷沸腾起始点的实验研究

本文对卧式螺旋管内R134a过冷流动沸腾的起始点进行实验研究,根据壁面温度的变化规律判定过冷沸腾起始点。在热流密度逐渐增大的情况下,对过冷沸腾发生时相关参数的不同变化进行了研究,得到了过冷沸腾起始点上壁面过热度和热流密度随位置的变化规律。分析了入口参数对过冷沸腾起始点的热流密度的影响趋势。对实验数据进行回归分析,发展了适用于卧式螺旋管内过冷沸腾起始点热流密度的经验关联式。     

方柱微结构表面上FC-72的流动沸腾强化换热实验研究

为了提高电子器件的冷却效率,研究了不导电介质FC-72在表面加工有方柱微结构的模拟芯片上的流动沸腾强化换热性能.采用了两种方柱微结构,其边长均为30μm,但高度分别为60μm和120 μm.方柱微结构芯片与光滑芯片相比显示出较好的强化沸腾换热效果,且增加方柱高度可有效提高流动沸腾强化换热性能.方柱微结构芯片的临界热流密度随着流速和过冷度的增大而增大,且到达临界热流密度(CHF)时芯片的表面温度低于芯片回路正常工作的上限温度85℃.     

微液层模型预测过冷沸腾的临界热流密度

本文利用微液层模型对过冷沸腾的临界热流密度（CHF）进行了理论预测。过冷沸腾的强化换热主要是通过单个气泡的形成和消失造成的对流换热强化而引起的。对等热流面,CHF在高过冷区趋近于常数;对等温面,CHF随过冷度的增加而增加。过冷度增加时,蒸发换热量减少,总热流密度主要由蒸发区外的导热引起。     

流动不稳定性对沸腾临界触发机制的实验研究

本文以D_(in)=2.15 mm的带旁通小流道为对象,分别在不同液相质量流速以及不同入口水温条件下开展沸腾临界实验,结合汽泡动力学行为以及两相界面形态特征,探讨流动不稳定性对沸腾临界的触发机制。在本文工况范围内,在流动状态由稳定阶段转变为不稳定阶段后,进一步增大热流密度会触发沸腾临界,且所有沸腾临界均属于DO型沸腾临界。当液相质量流速较高时,环状流近壁液膜主要在汽芯强烈的扰动作用下迅速破裂;当入口水温较低时,近壁液膜主要由于强烈的蒸发现象迅速破裂;因此沸腾临界与流动不稳定性几乎同步被触发。本文分别通过引入受限系数(N_(conf))、过冷数(N_(sub))、以及Weber数(We)来反映壁面的限制作用、入口过冷度、以及惯性力与表面张力对沸腾临界的影响,建立了适用于D_(in)=2.15 mm带旁通小流道的CHF模型。     

表面活性剂对池沸腾换热的影响

本文以SDS(十二烷基硫酸钠)为表面活性剂,研究了在不同过冷度下SDS浓度对池沸腾换热的影响.结果表明在低SDS浓度下,沸腾换热在一定热流密度范围内得到显著强化.在不同过冷度下.均存在相应的最佳SDS浓度值,最大换热系数可达纯水的2～4倍.在饱和沸腾状态下,临界热流密度(CHF)随SDS浓度的增加而减小,沸腾曲线呈现三类分歧,且存在"S"型沸腾曲线及较明显的沸腾滞后现象.     

高热流条件下过冷沸腾CHF试验及神经网络预测研究

本文试验研究了10～15 MW/m²高热流条件下过冷水流动沸腾的临界热流密度(CHF),并聚焦其预测方法。分析了热力学干度、质量流速和压力等参数对过冷沸腾CHF的影响。结果表明,随着热力学干度的增加,CHF近似线性降低。CHF随着质量流速增加而增加,但当靠近饱和点时,增加趋势逐渐减弱。在本文试验数据的基础上,搜集了文献中公开的实验数据,构建了高热流过冷沸腾CHF数据集(共709组),采用经验关联式和神经网络模型两种方法进行了预测,并定量评估了7个经验关联式和3个神经网络模型(BP,GA-BP和MEA-BP)的预测性能。结果显示,神经网络算法的预测性能相较于传统关联式有显著提升,其中,MEA-BP神经网络的预测效果最优,其平均绝对误差为15.61%,均方根误差为21.56%。     

竖直矩形窄缝内流动沸腾压降实验与模型研究

本文实验研究了水在间隙为2.1、2.2、3.6 mm的垂直矩形窄通道内流动沸腾压降,包括入口过冷的情况,得到了在不同操作条件下压降随热流密度的变化曲线,同时分析了曲线变化的原因.实验结果发现:在实验参数范围内,流动沸腾的压降随着质量流速、热流密度和入口干度增加而增大;随着窄缝间隙的增大而减小.窄通道内的压降计算与大通道有显著不同,本文针对窄通道的特点,修正了传统的压降计算模型,模型预测值与实验结果比较,误差在±15.4%之内.     

过冷沸腾起始点和净蒸汽产生点的实验研究

本文报告了使用Ｒ－１２作工质进行的自然循环过冷沸腾起始点和净蒸汽产生点的实验结果。实验过程中使用可视化方法观察确定过冷沸腾起始点和净蒸汽产生点。在相当宽广的工质压力、入口过冷度及加热功率范围内研究了上述参数对过冷沸腾起始点和净蒸汽产生点的影响,在此基础上提出了计算自然循环过冷沸腾起始点和净蒸汽产生点的计算方法。     

微米线结构表面的过冷流动沸腾实验研究

以去离子水为工质,配合高速摄像观测,研究了截面为0.5 mm×5 mm的微细窄矩形通道内氧化锌微米线结构表面的竖直流动过冷沸腾。流量范围200~400 kg·m^-2·s^-1,过冷度为10 K,热流密度最高为200 kW·m^-2。分析了不同工况下过冷沸腾的沸腾曲线、平均换热系数、局部换热系数和流型特征。     

Heat transfer and force balance approaches in bubble dynamic study during subcooled flow boiling of water–ethanol mixture

In this paper, the subcooled flow boiling heat transfer coefficient of pure water, water–ethanol mixture and pure ethanol is determined experimentally in horizontal rectangular channels for various parameters like heat flux, mass flux and channel inlet temperatures. Flow visualization is carried out using high speed camera. The bubble departure diameter, growth period and waiting period of bubbles are determined. Correlations are developed for subcooled flow boiling Nusselt number of water–ethanol mixture based on force balance approach and heat transfer approach. The parameters considered for correlation are grouped as dimensionless numbers by Buckingham π-theorem. The significance of each dimensionless number on heat transfer coefficient is discussed. The correlations developed for subcooled flow boiling heat transfer coefficient are validated with the experimental data. They are found to be in good agreement with the experimental data. It is found that the correlation based on force balance approach predicts the subcooled flow boiling Nusselt number well when compared with that of heat transfer approach correlation.     

浮升力对管内水过冷流动沸腾传热特性的影响研究

基于已知的2087组水的过冷流动沸腾传热实验数据,通过努塞尔数(Nu)和格拉晓夫数(Gr)的关系探讨了不同流动方向和加热方式下浮升力对过冷流动沸腾传热性能的影响。对上壁面单边加热水平矩形管内过冷流动沸腾传热进行了实验研究。实验结果表明,向上的浮升力阻碍了气泡向流体中的扩散,使得传热恶化。在增加流速、增大压力和减小过冷度的条件下,Nu均随Gr增加,使过冷流动沸腾传热得到强化。     

Experimental and numerical study of swirling subcooled flow boiling of water in a vertical annulus

In this paper, the effect of making swirling flow inside an annulus on the subcooled boiling heat transfer has been studied and discussed both experimentally and numerically. The Eulerian-Eulerian model and control volume technique have been used for numerical modeling of the problem. The experimental results show that the critical heat flux values are enhanced by making swirling flow. The experimental and numerical results also indicate that by making swirling flow inside the annulus, the subcooled boiling heat transfer coefficients are increased. Moreover, the experimental and numerical values of the boiling heat transfer coefficients show good agreement with each other.     

过冷沸腾气泡行为的实验研究

本文采用拍摄速度为10000帧/秒的高速摄影仪对不锈钢箔表面的过冷沸腾现象进行了可视化实验研究。实验结果与用微液层模型理论预测的结果一致。高过冷度区域的沸腾换热机理主要是由气泡生长、消失过程中温度边界层的强制排除(所谓强制对流)引起的。气泡周期主要由等待时间构成,这在过冷度高的情况下尤为显著。对等热流密度换热面,微液层模型预测的气泡周期与实验值比较吻合。     

Subcooled Flow Boiling Heat Transfer to Water and Ethylene Glycol/Water Mixtures in a Bottom-heated Tube

Subcooled flow boiling heat transfer experiments were performed with water and ethylene glycol/water mixtures at five flow velocities and four fluid inlet temperatures. Both turbulent flow and laminar flow were tested in a special test facility with its experimental test section heated from the bottom surface only. Boiling curves and subcooled flow boiling heat transfer coefficients of the tested fluids were determined from the experimental measurements. Predictive correlations of the subcooled flow boiling heat transfer coefficients were developed based on the experimental data. Comparisons are presented of wall temperatures between the experimental measurements and the correlation predictions.     

Numerical investigation of subcooled boiling characteristics of magnetic nanofluid under the effect of quadrupole magnetic field

This paper investigates numerically the characteristics of subcooled flow boiling of a magnetic nanofluid (refrigerant-113 and 4 vol% Fe₃O₄) in a vertical annulus, which is exposed to a nonuniform transverse magnetic field generated by the quadrupole magnet. A control volume technique and SIMPLEC algorithm have been used for discretizing the governing equations and pressure-velocity coupling, respectively. The two-fluid model has been used to simulate subcooled flow boiling of the refrigerant-113. The results indicate that subcooled flow boiling characteristics change not only by using nanofluid as the working fluid, but also by applying the nonuniform transverse magnetic field. In the presence of the aforementioned magnetic field due to the Kelvin force, the fluid attracted to the outer wall. This leads to higher bubble detachment frequency so that the heat pumping is increased and the void fraction on the heated wall is decreased. Thus, the critical heat flux as one of the most important parameters in boiling processes will be increased.