结霜工况冷风机传热系数实验研究

本文介绍了对冷风机传热系数的实验研究,得到了几点结论：一是蒸发温度对传热系数的影响;二是结霜工况对传热系数的影响;三是制造翅片管的材料对传热系数的影响。     

R290在水平微细圆管内沸腾换热特性研究

本文研究了R290在内径为1 mm、2 mm和4 mm水平微细圆管内的沸腾流动换热特性,在饱和温度为15℃条件下,质量流速为50～600 kg/(m~2·s)、干度为0～1、热流密度为5～20 k W/m~2时,对沸腾传热系数的影响进行了分析。通过实验发现,增大质量流速对传热系数具有增强作用,质量流速对传热系数的影响在低干度区域比高干度区域小。在热流密度方面,传热系数随着热流密度的增大而增大,且在1 mm和2 mm管内观察到了临界干度对传热系数的影响,这时传热系数有断崖式下降的趋势。在管径对于传热系数的影响方面,通过对不同管径换热特性的横向对比,发现在一定工况下传热系数随着管径的减小有所上升。此外本文还对R290已有的部分关联式进行了适配性验证。     

铝合金隔热型材隔热性能检测方法及测量不确定度评定

传热系数测试是评价铝合金隔热型材隔热性能指标的重要途径,建立了铝合金隔热型材检测方法,分析了影响铝合金隔热型材传热系数测量的不确定度来源,对隔热型材传热系数测量不确定度进行评定分析,结果表明在（2．90—0．06）至（2．90＋0．06）W·m-2·K-1的区间包含了传热系数K测量结果可能值的95％,并提出了测量传热系数的注意事项。     

微圆管内R1234ze(E)流动沸腾的环状流特性模拟研究

本文建立了制冷剂R1234ze(E)在微圆管内流动沸腾过程中的环状流模型,对传热和气液两相流动压降进行了模拟研究。综合考虑重力、表面张力及气液界面剪切力的影响,模拟分析了周向液膜不均匀分布特性及该特性对流动与换热的影响,经验证,计算结果与已有实验结果吻合较好,此外还研究了不同因素对环状流区域表面传热系数与压降的影响。模拟结果表明：在流动起始区域,截面液膜厚度的分布受重力作用影响,随着流动沸腾过程的进行,该影响作用开始减弱,且有重力作用时的环状流平均表面传热系数高于无重力作用时的环状流平均表面传热系数,随着重力加速度的增加,环状流的平均表面传热系数不断增大;随着质量流速的增大,表面传热系数与压降均随之增大;随着管径增大,表面传热系数与压降均随之减小。     

大型速冻设备蒸发器高效传热技术的试验研究

不同结构型式蒸发器的传热系数不同,选择7种不同结构的蒸发器模型,分析比较翅片形状、管径大小以及管子排列方式对蒸发器传热系数的影响,得出在不结霜工况下,传热系数最高的蒸发器结构是连续整体带波纹翅片叉排变节距结构的结论。对这种结构的蒸发器进行试验测试,得到与理论计算相符的传热系数值。     

确定金属型铸造界面传热系数方法的研究

铸造凝固过程数值模拟中通常用界面传热系数表示热阻的影响,在诸多影响模拟精度的因素中,该系数起主导作用。为提高模拟精度,以ANSYS软件为平台,在测温试验的基础上,考虑铸件与铸型的不同接触位置以及不同界面传热系数对模拟结果的影响,采用0.618黄金分割法选取了该系数;应用最小二乘法建立起界面传热系数与时间关系的数学模型,并对金属型铸造凝固过程的温度场进行了模拟,将模拟结果与试验结果做了对比分析,得到了合理的温度分布。研究的结果为获得精确的界面传热系数提供了一种研究方法。     

R32水平单管内的蒸发换热特性

本文对2根不同孔径单管在饱和温度分别为0℃、5℃和10℃工况下进行水平管内R32蒸发换热的实验研究。采用热阻分离法得到管内制冷剂侧蒸发传热系数,以质量流量、饱和温度为影响因子,对实验结果进行单管热阻分析及综合性能评价。结果表明:管内传热系数及压降均随着质量流量的增加而增加,管径对传热系数影响较大,1#传热系数约为2#的1.1~1.3倍,不同质量流量下温度对传热系数及压降的影响比重不同;随着质量流量的增加,管外水侧热阻占总热阻的比例逐渐增大,管内制冷剂侧热阻占总阻值的比例逐渐减小;两根单管单位压降传热系数均随质量流量的增加而减小,在不同质量流量下饱和温度对参数的影响比重不同。     

结霜工况下强制循环空气冷却器传热系数影响因素的研究

本文介绍了在结霜工况下的强制循环空气冷却器总传热系数计算公式，对影响其总传热系数的因素进行了分析，还讨论了在低温试验室检测时的几年问题。     

冷风机传热系数影响因素的研究

本文介绍了强制循环空气冷却器(简称冷风机)传热热阻大致估计值,并对影响其传热系数的各种因素进行了分析.得到了下述结论首先,如果采取有效措施降低空气侧的传热热阻,即可明显提高传热系数;其次,如果在制冷剂侧采用选择供液方式、控制供液量,或采用高效传热管等措施,还可以进一步提高传热系数.     

竖直矩形通道内不凝性气体对凝结换热特性的影响

本文以去离子水为工质,实验研究了竖直矩形窄通道内少量残余不凝性气体对蒸汽凝结换热特性的影响。采用热阻分离法得到凝结侧换热表面传热系数,分析了不凝性气体的含量、冷却水质量流速、进口温度和热流密度对蒸汽凝结侧表面传热系数的影响。结果表明:当热流密度为1.668 kW/m~2,即蒸汽质量流速较小时,2%体积分数的不凝性气体使凝结侧表面传热系数下降了33%,但当热流密度为3.887 kW/m~2,蒸汽质量流速较大时,2%体积分数的不凝性气体仅使凝结侧表面传热系数降低了14%,此外,凝结换热表面传热系数随冷水质量流速和不凝性气体分数的增加而变小,随冷水进口温度和热流密度的增加而变大。     

矩形微通道内制冷剂流动沸腾传热特性及可视化研究

为了探究微通道内流动沸腾及传热现象的机理,以制冷剂R22为工质在矩形微通道内进行了流动沸腾及可视化实验。结果表明,在核态沸腾下传热系数受质量流率的影响较小,却随着热流密度的增加而快速增加;微通道的尺寸越小,传热效果越好,水力直径为0.92 mm和1.33 mm微通道内的传热系数比2 mm微通道内的传热系数分别提高约25%、12%;根据实验值与预测值的对比情况,在Oh H K等[15]和Yun R等[7]模型基础上拟合得到新的传热系数预测关联式,平均绝对误差降至8.8%;通过可视化实验发现,在临界热流密度下微通道内出现波浪式气体层的现象。     

Development of a slug flow absorber working with ammonia–water mixture: part II—data reduction model for local heat and mass transfer characterization

This study deals with a data reduction model for clarifying experimental results of a counter-current slug flow absorber, working with ammonia–water mixture, for significantly low solution flow rate conditions. The data reduction model to obtain the local heat and mass transfer coefficient on the liquid side is proposed by using the drift flux model to analyze the flow characteristics. The control volume method and heat and mass transfer analogy are employed to solve the combined heat and mass transfer problem. As a result, it is found that the local heat and mass transfer coefficient on the liquid side of the absorber is greatly influenced by the flow pattern. The heat and mass transfer coefficient at the frost flow region is higher than that at the slug flow region due to flow disturbance and random fluctuation. The solution flow rate and gas flow rate have influence on the local heat and mass transfer coefficient at the frost flow region. However, it is insignificant at the slug flow region.     

Effect of melt superheat on heat transfer coefficient for aluminium solidifying against copper chill

Solidification of metal castings inside moulds is mainly dependent on the heat flow from the metal to the mould which is in turn proportional to an overall heat transfer coefficient h which includes all resistances to heat flow such as the presence of an air gap. In the present work the heat transfer coefficient is determined using a directional solidification set-up with end chill for solidifying commercial-purity aluminium with different superheats (40 K and 115 K) against copper chill. A computer program solving the heat conduction and convection in the solidifying metal is used together with the experimental temperature history in order to determine the heat transfer coefficient at the interface. The variation of h as a function of time, surface temperature and gap temperature for each melt superheat is found. The results indicate that h reaches a maximum value for surface temperature close to the liquidus. The analysis of heat flux from the metal to the mould indicates that it is mainly by conduction. The air gap size is evaluated with time, surface temperature and with melt superheat. It is found that higher h values and smaller gap sizes are obtained with higher superheats.     

Condensation of R407C in a horizontal microfin tube

This paper describes experimental results that show the effects of mass velocity and condensation temperature difference on the local heat transfer characteristics during condensation of R407C in a horizontal microfin tube. The experiments were performed at the saturation temperature of 40 °C, the refrigerant mass velocity of 50, 100, 200 and 300 kg m⁻² s⁻¹, and the condensation temperature difference of 1.5, 2.5 and 4.5 K. A superficial heat transfer coefficient for the vapor phase was obtained by subtracting the heat transfer resistance of condensate film estimated by using a previously developed theoretical model of film condensation of pure vapor from the overall heat transfer resistance. On the basis of the analogy between heat and mass transfer, an empirical equation for the superficial vapor phase heat transfer coefficient was developed. The heat transfer coefficient predicted by the combination of the previously developed theoretical model of film condensation of pure vapor and the empirical equation of the superficial vapor phase heat transfer coefficient agreed with the measured values with the r.m.s. error of 9.2%.     

Effect of gravity on pool boiling heat transfer on thermal spray coating

This study deals with heat transfer enhancement surface manufactured by thermal spraying. Two thermal spraying methods using copper as a coating material, wire flame spraying (WFS) and vacuum plasma spraying (VPS), were applied to the outside of copper cylinder with 20 mm OD. The surface structure by WFS was denser than that by VPS. The effect of gravity on boiling heat transfer coeffcient and wall superheat at the onset of boiling were experimentally evaluated under micro- and hyper-gravity condition during a parabolic trajectory flight of an airplane. Pool boiling experiments in saturated liquid of HCFC123 were carried out for heat fluxes between 1.0 and 160 kW/m² and saturated temperature of 30 °C. As a result, the surface by VPS produced higher heat transfer coefficient and lower superheat at the onset of boiling under microgravity. For the smooth surface, the effect of gravity on boiling heat transfer coefficient was a little. For the coating, a large difference in heat transfer coefficient to gravity was observed in the moderate heat flux range. The heat transfer coefficinet decreased as gravity changed from the normal to hypergravity, and was improved as gravity changed from the hyperto microgravity. The difference in heat transfer coefficient between the normal and microgravity was a little. Heat transfer enhancement factor was kept over the experimental range of heat flux. It can be said that boiling behavior on thermal spray coating might be influenced by flow convection velocity.     

Experimental research on heat transfer coefficients for cryogenic cross-counter-flow coiled finned-tube heat exchangers

The aim of present experimental research is to find out the suitable correlations for designing the coiled finned-tube heat exchangers used in cryogenic applications. In order to conduct above experimental study, cross-counter-flow coiled finned-tube heat exchangers were developed in our lab and used in actual refrigeration cycle. The experiments were conducted in the range of effective Reynolds number 500–1900. The effect of diametrical clearance on the prediction of overall heat transfer coefficient is also investigated experimentally. The results from present study were compared in the form of overall heat transfer coefficient. Results of present experimental research indicate that different correlations selected in the study can be used with reasonable accuracy for designing the coiled finned-tube heat exchangers, if they are applied with suitable method of calculation of free-flow cross-sectional area. A more accurate new correlation has also been proposed that fitted experimental data within ±10% error band.     

The effect of varying chill surface roughness on interfacial heat transfer during casting solidification

Experiments to investigate interfacial heat transfer mechanisms during casting solidification were carried out by varying the surface roughness of a Cu chill used to bring about unidirectional solidification of an Al-4.5 wt.% Cu alloy. Little variation in interfacial heat transfer coefficient with varying chill surface roughness was found, confirming previously published results. Examination of the as-cast surface of the casting showed the presence of predendritic contact areas, and also that the casting surface roughness did not form as a replica of the chill surface, as has often been proposed. Rather, the casting surface roughness was consistently greater than that of the chill, but varied little in the experiments. A sum surface roughness parameter was devised to characterise the casting–chill interface that included the roughness of both surfaces. The value of this parameter was strongly influenced by the greater roughness of the casting surface, rather than the chill surface roughness, and therefore also varied little in the experiments. This lack of variation in the casting surface roughness and hence the sum surface roughness parameter showed how interfacial heat transfer should be more strongly influenced by the greater roughness of the casting surface than of the chill surface, and explains why the interfacial heat transfer coefficient was not strongly influenced by the chill surface roughness in these types of experiments. At the time the work was carried out the authors were in the Manchester Materials Science Centre, University of Manchester and UMIST, Manchester M1 7HS, UK.     

Prediction of evaporation heat transfer coefficient and pressure drop of refrigerant mixtures in horizontal tubes

A study on the prediction of heat transfer coefficient and pressure drop of refrigerant mixtures is reported. Heat transfer coefficients and pressure drops of prospective mixtures to replace R12 and R22 are predicted on the same cooling capacity basis assuming evaporation in horizontal tubes. Results indicate that nucleate boiling is suppressed at qualities greater than 20% for all mixtures, and evaporation becomes the main heat transfer mechanism. For the same capacity, some mixtures containing R32 and R152a show 8–10% increase in heat transfer coefficients. Some mixtures with large volatility difference exhibit as much as 55% reduction compared to R12 and R22, caused by mass transfer resistance and property degradation due to mixing (32%) and reduced mass flow rates (23%). Other mixtures with moderate volatility difference exhibit 20–30% degradation due mainly to reduced mass flow rates. The overall impact of heat transfer degradation, however, is insignificant if major heat transfer resistance exists in the heat transfer fluid side (air system). If the resistance in the heat transfer fluid side is of the same order of magnitude as that on the refrigerant side (water system), considerable reduction in overall heat transfer coefficient of up to 20% is expected. A study of the effect of uncertainties in transport properties on heat transfer shows that transport properties of liquid affect heat transfer more than other properties. Uncertainty of 10% in transport properties causes a change of less than 6% in heat transfer prediction.     

两种CPU散热器换热特性的数值研究

对整体平直翅片与分段开缝平直翅片两种不同结构的CPU散热器，在不同加热功率和不同风速下的散热特性进行了数值模拟。采用商业软件FLUENT6．0进行计算，结果显示：对流换热表面传热系数和热阻主要与风速有关，与加热功率关系不大，对流换热表面传热系数的计算结果和实验数据趋势一致。在低风速下，加热功率对这两种散热器压降的影响也不大。采取数值模拟的方法对CPU散热器进行研究是实验方法的可靠补充，计算所得的结果有助于分析CPU散热器的换热过程，并可为电子设备的设计和改进提供参考。     

R134a表面增强型蒸发强化传热管的实验研究

介绍了国外空调冷冻设备中采用的一种新型商用表面增强型蒸发强化传热管,并对其进行了实验研究.发现对使用R134a环保制冷工质,在低热流密度的条件下,表面增强型蒸发强化传热管具有十分优异的强化效果.在实验的换热工况下,保持进口水温不变而改变管内水流速,这种强化管的总换热性能是普通低翅蒸发强化管的 2.2到2.6倍,管外换热系数是普通低翅蒸发强化管的1.3～1.9倍.