钛椭圆低肋横槽管外降膜蒸发流热特性

为提高钛椭圆低肋横槽管外降膜蒸发器传热效率,在试验验证基础上对椭圆系数E在1.0~2.0内管外液膜流热特性进行多相流数值模拟。结果表明:管外液膜分布均存在不同程度干斑,且液膜在临近干斑处较其他区域增厚明显,当E为1.2时液膜覆盖率最高;液膜沿轴/周向均减速铺展,当E为1.0和1.8时管上端液膜速度在无量纲轴向长度Z*为-0.25~-0.375及0.25~0.375之间骤减,液膜厚度沿轴向从喷淋口正下方位置向喷淋口远端变化趋势为先减小后增大;最大传热系数随着E增大而增大,管壁在液膜与干斑交界区域附近传热系数最高;平均传热系数先增大后减小,相较圆管,E为1.2和2.0时平均传热系数分别增大34.5%和15.7%;槽内汽含率分布与液膜分布呈相反规律,液膜整体汽含率随E的增大先增大后减小,槽内/外平均汽含率差值随E增加而增大。

Numerical Study on Flow Heat Transfer Characteristics of Horizontal Tube Falling-Film Evaporator

As an efficient and energy-saving heat exchange technology, horizontal tube falling film evaporation has a great application prospect in refrigeration and air conditioning. The three-dimensional models of falling film flow evaporation outside horizontal single tube and inside evaporator were established, and the accuracy of flow and heat transfer simulation process was verified by comparison. For horizontal single tube, the results showed that total heat transfer coefficient was low and increased with larger spray density and evaporation temperature. The thickness of liquid film outside tube decreased gradually with the increase of tube diameter, and the total heat transfer coefficient of small tube diameter was significantly greater than that of the large tube diameter. The total heat transfer coefficient presented an increasing trend with larger liquid distribution height and density. In addition, the fluctuation of tube axial liquid film thickness distribution decreased with larger liquid distribution density. For evaporator, the results indicated that part of liquid refrigerant was carried into the vapor outlet. The temperature of tube wall and fluid presented a gradually rising trend in vertical downward direction, while tube wall temperature within the same horizontal and transverse row had little difference. The high-temperature zone on the outer wall of heat exchange tube moved towards the inlet and gradually decreased, and the outlet temperature of water in the tube also gradually decreased with the increase of refrigerant spray density. The local heat transfer coefficient of heat exchanger tube in the vertical direction presented a downward trend which was more obvious with the smaller spray density and it was obviously higher located in the middle of upper tube row and both sides of lower tube row for horizontal tube rows.

板管型降膜式蒸发器换热特性数值模拟

降膜式蒸发器兼有满液式蒸发器换热效果好及干式蒸发器制冷剂充灌量小的特点。对板管型降膜式蒸发器进行了数值模拟,得出了其在使用R410A为制冷工质时,条缝宽度、喷淋密度及板面温度对蒸发器换热性能的影响。结果表明,当工质入口条缝宽度为1.5mm时,板面的液膜覆盖率及换热系数最大,条缝宽度小于或大于1.5mm时,板面的液膜覆盖率及换热系数均有所降低;板面的液膜覆盖率及其换热系数随着液膜雷诺数的增加而增加,但当液膜雷诺数达到10000以上时,增加幅度明显减小并趋于零;板片温度升高可以增强蒸发器的换热性能,但雷诺数较小时的影响很小,只有雷诺数足够大时板片温度的影响才得到明显的体现。

重力热管技术研究与应用概述

重力热管是一种高效的传热元件,因其结构简单、等温性良好、换热性能优异、不含有能动部件等特点,被广泛应用于各个领域。本文全面总结讨论了重力热管的传热机制,包括膜状冷凝和努塞尔理论、降膜蒸发和降膜沸腾等机理,并对相关的理论模型进行了讨论分析,给出了比较合适可靠的理论模型选择建议。此外还介绍了重力热管在工程领域的应用现状,指出了重力热管技术应用所面临的问题和发展方向。

基于分布参数模型的降膜式蒸发器性能智能仿真研究

为对大型水平管降膜式蒸发器进行高精度的设计计算和优化分析,建立了降膜式蒸发器的智能换热仿真模型,并分析研究了蒸发器的性能。首先,采用分布参数法建立了单出口水平管降膜式蒸发器的换热仿真模型;其次,通过贝叶斯优化算法利用蒸发器实验数据对模型进行参数辨识,使得换热仿真模型的预测精度和适应性有所提高;最后,探究了传热系数和热流密度沿管长方向的变化情况,以及满液区换热面积所占比例对蒸发器换热量的影响规律。仿真结果表明:结合分布参数法和贝叶斯优化算法的智能换热仿真模型对大型水平管降膜式蒸发器19个工况换热量的预测误差不超过±6%;在较大的换热量范围内,单出口水平管降膜式蒸发器的最优池沸腾换热面积比例维持不变;从管内对流换热和二次布液两个角度优化降膜式蒸发器能有效提升其换热性能。

氯代碳酸乙烯酯降膜纯化方法研究

以工业级氯代碳酸乙烯酯(CEC)为原料,利用Aspen Plus软件模拟计算CEC、HCl在不同压力、不同温度下的饱和分压,根据模拟计算结果以降膜刮板蒸发器为主要设备闪蒸纯化CEC,去除CEC中HCl、活性氯及其他活性杂质。根据实验结果调整纯化参数,并以碳酸亚乙烯酯(VC)合成收率作为纯化效果评价标准,确定降膜刮板蒸发器纯化CEC最佳工艺条件为闪蒸温度70℃、5 kPa,CEC气相纯度由82%提高至85.3%,VC合成收率由65.2%提高至75.5%。

苯乙烯生产工艺的节能优化和经济分析

在中石化自主研发的苯乙烯生产工艺中,乙苯脱氢反应需要加入大量过热蒸汽作为脱氢介质,水蒸气和乙苯流量的比值是影响脱氢反应的一个重要因素。随着低水比催化剂工业应用取得进展,可以减少进入反应器的蒸汽量,而降低水比的关键就在于减少乙苯/苯乙烯塔顶冷凝器共沸蒸出的乙苯和蒸汽的量。控制恒沸蒸发量后,会导致乙苯/苯乙烯塔塔顶物料携带的热量不能完全回收。为合理利用这部分热量,对原工艺流程进行优化、热量进行耦合。此次节能优化主要涉及9台换热器,其中2台为新增。优化过程中还降低了预分塔塔压,提高了尾气压缩机出口温度。经过优化,可减少综合能耗11.364 kg标油(以1 t苯乙烯计),静态投资回收期约为2个月。

新型旋流布液器成膜性能实验研究

布液器是降膜蒸发器的关键部件。文章针对现有布液器存在的不足,开发了一种新型旋流布液器。该布液器为切向开槽结构,槽一侧与管内壁相切,另一侧延伸一定长度与管内壁形成导流结构,下端与换热管通过螺纹连接。在有机玻璃实验装置内对新型旋流布液器和切向槽型布液器形成液膜等性能进行了系统的对比研究。实验结果表明:只要合理控制流量,两种布液器均能连续稳定成膜,不会出现“干管”现象;新型旋流布液器的最小成膜流量更小,成膜的流量范围更广,说明其操作弹性更大;在相同流量下,新型旋流布液器比切向槽型布液器形成的液膜厚且流速小,因此液膜稳定性更好,同时液膜在换热管内的停留时间更长,换热效果更好。

降膜再沸器液体布膜器性能研究

对降膜再沸器上常用的双切口液体布膜器进行单管布膜试验研究,测得最小成膜液体量和不同流量工况下的液膜厚度,为降膜再沸器工程设计提供了基础数据。进一步,利用有限元软件模拟该布膜器的流场分布情况,发现在切口附近液体分布不均;针对这个问题,提出在切口处增加引流挡板,并模拟改进后液体布膜器的流场分布情况,发现切口处液体局部汇聚情况得到明显改善,为后续降膜再沸器优化设计提供指导。

微正压条件下板式降膜MVR蒸发装置的工艺设计与应用

传统负压蒸发技术存在传热效率低、设备投资大、真空稳定性差、水质不稳定、最终乏汽冷凝成本高等问题。深入研究微正压蒸发理论依据及应用条件,提出热能平衡因子Δqz是控制微正压蒸发系统稳定运行的关键因素,不凝气外排所携蒸汽热能及冷凝水、外排浓水热能的回收是保障微正压工况下MVR系统平稳运行的重要措施。MVR板式降膜蒸发工艺在微正压条件下运行,装置产水矿化度小于等于30 mg/L,降膜蒸发板换热系数相较于微负压蒸发提高10%以上,总体设备投资减少约6%~8%,消泡剂、pH调节剂加药量大幅减少。通过对比微负压与微正压两种工况下的运行数据表明:微正压控制蒸发工艺参数具有产水水质更优、换热系数更大、投资更省、能耗更低、降低药剂耗量等优势。

Mathematical Simulation of Lithium Bromide Solution Laminar Falling Film Evaporation in Vertical Tube

For utilization of the residual heat of flue gas to drive the absorption chillers,a lithium-bromide falling film in vertical tube type generator is presented.A mathematical model was developed to simulate the heat and mass coupled problem of laminar falling film evaporation in vertical tube.In the model,the factor of mass transfer was taken into account in heat transfer performance calculation.The temperature and concentration fields were calculated.Some tests were conducted for the factors such as Re number,heating flux,the inlet concentration and operating pressure which can affect the heat and mass transfer performance in laminar falling film evaporation.The heat transfer performance is enhanced with the increasing of heat flux.An increasing inlet concentration can weaken the heat transfer performance.The operating pressure hardly affects on heat and mass transfer.The bigger inlet Re number means weaker heat transfer effects and stronger mass transfer.The mass transfer obviously restrains the heat transfer in the falling film solution.The relation between dimensionless heat transfer coefficient and the inlet Re number is obtained.

Interfacial Evaporation of Falling Liquid Films with Wall Heating

The interfacial evaporation of falling water films with wall heating was experimentally studied and analyzed. The results presented in this paper showed that the capillary induced interfacial evaporation played an important role in heat transfer of a falling liquid film. It would be independent of the wall heat flux and somewhat lower than that without wall heating for impure fluids such as water air system. The thermodynamic analysis conducted gave a theoretical basis for the experimental observations. The effective capillary radius was correlated with the mass flow rate. The experimental results and analysis showed that the interfacial evaporation should be taken into account in the study of falling liquid film heat transfer.

The effect of interfacial evaporation on heat and mass transfer of falling liquid film

Analysis of experimental data and estimation of the order of magnitude for interfacial mass diffusion have demonstrated that considerable excess evaporation exists on the free interface of falling liquid film, and that the capillary pressure caused by surface tension is the driving force of this excess interfacial evaporation, which we called the “capillarity-induced interfacial evaporation”. By correlating the experimental data, an empirical expression of the effective capillary radius, r\-e, is obtained with which the evaporative rate formula we derived and reported previously has been modified to improve the prediction of the critical heat flux for film breakdown. Comparisons with the available predicting models show that our modified equation can predict the experimental results with much lower relative deviation.

油基钻井液高温乳化剂连续化生产装置研究

为降低安全风险和生产成本,以油基钻井液高温乳化剂室内合成工艺参数为基础,将微通道反应精馏原理与降膜蒸发技术耦合设计了一套高温乳化剂连续化生产装置,考察了出料温度、停留时间和真空度等参数对产物转化率的影响。研究结果表明,相比于釜式间歇生产过程,采用本套连续化生产装置进行高温乳化剂的生产,可以使吨产品的生产时间由240 min降到60 min,电耗由800 kW·h降低到180 kW·h。此外,采用该套装置生产的乳化剂与釜式生产装置生产的乳化剂理化性能相当,配制的钻井液具有良好的体系稳定性,高温高压滤失量低于3 mL。连续化装置可用于高温乳化剂的生产,其高效、低成本特点为油基钻井液高温乳化剂的推广应用奠定了基础。

水平波纹管外降膜蒸发的液膜流动与换热特性分析

针对低温制冷剂R134a(C2H2F4)在水平管外存在降膜蒸发问题,运用流体体积(volume of fluid, VOF)模型与用户自定义函数(user-defined functions, UDF)数值模拟管外液膜流动与换热特性,包括液膜沿换热管(波纹管与光管)的轴向和圆周方向的流动、液膜厚度分布、液膜内气泡成核及分布等.计算结果表明:在恒热流(qw=2×104W·m-2)的波纹管与光管外壁上,R134a液膜在轴向和周向上的流动与换热均存在一定差异,波纹管外液膜在轴向上的铺展速度比光管快2.0 ms,而在周向上铺展较为均衡,且铺展速度稍慢于光管;波纹管外液膜平均厚度为0.120 mm,比光管薄7.00%,其中迎面区液膜厚度为0.119 mm,较光管薄13.14%;与光管相比,波纹管外液膜内气泡成核的起始时间提早2.6 ms,成核点数多15.32%,且分布较广,多见于周向角为55°~135°的区域;波纹管外平均换热系数比光管提高10.17%,迎面区换热系数为背面区的3.53倍.

水平管束降膜蒸发中CO_(2)解吸的微观特性

水平管降膜蒸发中释放的不凝气严重降低了管内冷凝传热速率,会使海水淡化的能耗成本显著增加,因此研究水平管束降膜蒸发中CO_(2)解吸的微观过程具有重要意义。文章建立了耦合水平管束降膜蒸发传热和CO_(2)解吸的理论模型,计算得到CO_(2)解吸单元体、碳酸盐组分浓度,分析了CO_(2)解吸量的微观特性。结果表明:传热系数的模拟值与实验值吻合良好;化学反应时间沿竖直管排方向减小且其速率逐渐降低,而沿水平管长方向随竖直管排节点数的增加而变长;主导CO_(2)解吸速率的HCO^(-)_(3)和CO^(2-)_(3)在微元内的浓度显著高于CO_(2)和H+浓度;单位面积的蒸发速率和每吨海水CO_(2)解吸量沿竖直管排、水平管长方向均减少。

基于GA-BP神经网络的横管降膜蒸发传热系数预测

由于横管降膜蒸发过程中传热系数的影响因素众多,依靠传统的关联式难以描述其复杂的非线性关系,因此提出利用BP神经网络强大的函数拟合能力构建模型以实现对传热系数的预测,并采用遗传算法进一步优化,建立了GA-BP预测模型,其中输入神经网络的参数包括喷淋密度、蒸发温度、管径、管间距和工质盐度。将模型的预测结果与真实值进行对比,同时引入传热关联式作为对照。结果表明,GA-BP模型的平均绝对百分比误差(MAPE)仅为8.10%,相比原始BP神经网络降低了31.93%,预测精度较传统的传热关联式提升70%左右。可见神经网络方法在非线性系统建模方面具有较大优势,能够有效预测横管降膜蒸发传热系数,为进一步优化工况参数、提高蒸发器的传热性能提供了可靠依据。

基于仿生结构对水平管降膜蒸发换热的模拟

水平管降膜蒸发器是广泛应用于海水淡化和化学工业等方面的换热设备。建立了三维数值模型,采用VOF(volume of fluid)方法结合UDF(user defined function)程序对水平管外降膜蒸发过程的换热特性进行了数值模拟研究,深入研究了光管和强化管针对不同管间距、喷淋密度、蒸发温度和管径对液膜厚度以及平均传热系数的影响。模拟结果表明:在相同条件下,强化管的平均传热系数要明显高于光管,可见基于仿生学原理优化换热表面结构能有效提高水平管外降膜蒸发的换热效率。光管和强化管的平均传热系数随着蒸发温度的升高都呈上升趋势,随喷淋密度的增加呈先上升后减少的趋势。光管和强化管的平均换热系数随管间距的增大而增大,随喷淋密度的增加呈先增加后减少的趋势;换热管的平均传热系数随着蒸发温度升高而升高,随喷淋密度的增加呈先上升后下降的趋势。

MVR蒸发技术在废水处理中的应用研究

随着环境污染和水资源短缺的加剧,对于工业废水的排放要求日趋严格,常规的废水处理技术已无法满足废水的处理要求,尤其是高含盐、高有机物、高毒性的难降解废水,其有效处理仍然是难点。为满足国内对高难度废水的处理要求,采用MVR蒸发技术,通过卧式降膜蒸发装置,分别对高盐废水、焦化废水RO浓缩液和垃圾渗滤液NF浓缩液进行中试处理。结果表明,该技术可对上述废水进行10~20倍的有效浓缩处理,减量化效果明显,且蒸馏水出水水质良好,可满足排放或回用的要求。废水处理产出1 t蒸馏水的最高电耗为25.1 kW·h,电价按0.6元(/kW·h)计,运行成本可控制在15.1元以下,与管网式反渗透(STRO)工艺处理焦化废水的运行成本(吨水处理成本为10.48元,按最佳水回收率55%折算,产水成本为19.05元/t)相比,具有一定的节能优势。采用MVR卧式降膜蒸发技术作为废水的深度处理技术是可行的,具有广阔的应用前景,值得深入研究和推广。

三维变形管内降膜蒸发特性

为了提高降膜蒸发器的传热性能,将三维变形管用于MVR降膜蒸发器中,利用FLUENT软件探究了管内液膜的分布特点,分析了长、短轴比对三维变形管的传热性能的影响。结果表明:相比圆管,三维变形管内液膜的厚度会逐渐减小,流体速度场与温度场的协同性相对来说也更好;随着长、短轴比的增大,三维变形管内液膜的厚度会逐渐减小,液膜速度更为缓慢,而且进一步提高了速度场与温度场的协同性,还增强了液膜的扰动性,最终努塞尔数从0.249提高到0.276。将三维变形管应用于MVR蒸发器中,具有良好的换热效果,可节省换热材料。