Phase distribution in horizontal gas-liquid two-phase bubbly flow

An investigation on phase distribution in air-water two-phase flow in horizontal circular channel was conducted by using the double-sensor resistivity probe.The variations of phase distribution with variations of gas and liquid volumetric fluxes were analyzed and the present data were compared with some of other researcher’s data and existing models. It was found there exists more complicated phase distribution pattern in horizontal flow system than in vertical flow. The radial local void fraction profiles are similar at the same measurement angle with various gas and liquid flow rates. However, an asymmetric profile can be observed at a given slice of the pipe cross-section.

Numerical simulation of the effect of void fraction and inlet velocity on two-phase turbulence in bubble-liquid flows

There are contradicted opinions on whether bubbles enhance or reduce the liquid turbulence. In this paper, the effect of void fraction and inlet velocity on the bubble-liquid two-phase turbulence of the multiple bubble-liquid jets in a two-dimensional channel is studied by using the two-phase second-order moment turbulence model. The results confirm the phenomena observed in experiments and reported in references that at a low void fraction and low inlet velocities the bubbles enhance the liquid turbulence, whereas at a high void fraction and high inlet velocities the bubbles reduce the liquid turbulence.

ASTUDYONTHEDEVELOPMENTOFTHENUMERICALMETHODTOTRACKTHEMULTI┐FREESURFACESINLIQUID┐GASPHASEFLOW

This paper is concerned with a remedy for interface smearing,which is usable when fixed (i.e. non moving and so non conforming) grids are employed. It is simple to employ and has been found to be rather effective. The paper explains its principle, describes how it has been implemented and presents some results obtained with its assistance. The results are compared both with those of earlier methods of interface motion calculation and with experimental data.

Simple Model for Gas Holdup and Liquid Velocity of Annular Photocatalytic External-Loop Airlift Reactor Under both Bubble and Developing Slug Flow

Based on the momentum conservation approach, a theoretical model was developed to predict the superficial liquid velocity, and a correlation equation was established to calculate the gas holdup of an annular external-loop airlift reactor(AELAR)in the bubble flow and developing slug flow pattern. Experiments were performed by using tap-water and silicone oil with the viscosity of 2.0 mm^2/s(2cs-SiO)and 5.0 mm^2/s(5cs-SiO)as liquid phases. The effects of liquid viscosity and flow pattern on the AELAR performance were investigated. The predictions of the proposed model were in good agreement with the experimental results of the AELAR. In addition, the comparison of the experimental results shows that the proposed model has good accuracy and could be used to predict the gas holdup and liquid velocity of an AELAR operating in bubble and developing flow pattern.

Numerical simulation of gas–liquid flow in the bubble column using Wray–Agarwal turbulence model coupled with population balance model

In this paper,an improved computational fluid dynamic(CFD)model for gas-liquid flow in bubble column was developed using the one-equation Wary-Agarwal(WA)turbulence model coupled with the population balance model(PBM).Through 18 orthogonal test cases,the optimal combination of interfacial force models,including drag force,lift force,turbulent dispersion force.The modified wall lubrication force model was proposed to improve the predictive ability for hydrodynamic behavior near the wall of the bubble column.The values simulated by optimized CFD model were in agreement with experimental data,and the errors were within±20%.In addition,the axial velocity,turbulent kinetic energy,bubble size distribution,and the dynamic characteristic of bubble plume were analyzed at different superficial gas velocities.This research work could provide a theoretical basis for the extension of the CFD-PBM coupled model to other multiphase reactors..

Two-phase slug flow in vertical and inclined tubes

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A Model on the Void Fraction in Liquid Slugs for Vertical Slug Flow

Aim To develop a hydrodynamic model on the void fraction in liquid slugs for gas liquid slug flow in vertical tubes. Methods Developing the model by considering the gas exchange between the Taylor bubble and the following liquid slug. Results Some experimental data are obtained to check the model. In comparison with previous published results, the predictions from this model are better and in good agreement with the experimental data. The error is within ±20%. Conclusion The proposed model can correctly predict the void fraction in liquid slugs for gas liquid two phase slug flow in vertical tubes.

THE FRICTIONAL RESISTANCE CHARACTERISTICS OF GAS LIQUID TWO PHASE FLOW IN HELICAL COILED TUBES

This paper deal with the frictional resistance characteristics of gas liquid two phase flow in vertical upward helical coiled tubes under the system pressure 0.1 0.6MPa. By means of dimension analysis and π theorem, the correlation formulas were obtained for calculating the frictional resistance coefficients of gas liquid two phase flow in helical coiled tubes. The calculated results agree well with the experimental results.

气泡运移特征可视化观测装置研制及应用

气液两相流动过程中,气泡的形态变化时刻影响着流动的发展。为分析气泡在运移过程中的形态变化,该文研制了一套气泡运移特征可视化观测装置,包括管道模块、动力模块及数据采集模块。为了验证装置的可靠性,开展了不同液相黏度、不同液速及不同管道倾角下的气泡运移实验。实验结果表明,该装置操作简单、功能多样,可清晰地展示并记录气泡在不同液相环境下的运移轨迹及状态,并得到气泡的速度变化数据,实验结果直观可靠。结果证明该装置可解决因气泡运移特征复杂、影响因素多而难以获取直观数据的问题,对研究气液两相流动及气泡动力学领域的相关问题具有一定意义,可推广应用。

基于LBM的低导热材料板强化沸腾换热机理分析

为进一步强化沸腾换热,通过在固体加热器的上壁面附近嵌入多段低导热材料板,实现了沸腾换热的受热面上的温度随空间的交替变化。采用单组分多相LBM,考察了低导热材料板的数量和间隙间距对沸腾换热性能和气泡动力学的影响,从微观角度揭示了添加低导热材料板强化沸腾换热的机理。结果表明:气泡动态行为随间隙间距的增大而发生变化,会出现气泡合并、独立生长等气泡脱离过程。结合气泡动态行为、温度场和流场分析,发现气泡首先会在间隙受热面处成核生长,脱离气泡的涡流可以促进生长气泡在受热面的横向迁移和合并过程,在一定间隙间距范围,气泡会相互融合形成较大的液桥,液桥的存在能够促进受热面气泡根部周围微层的蒸发,推动了间隙受热面处的冷流体再润湿过程。添加多段低导热材料板,间隙处热量积聚、气泡合并形成液桥、间隙受热面的再润湿、气泡横向迁移和多气泡的快速合并等这些过程的共同作用强化了沸腾换热性能。

基于高速摄像技术的气液两相流型分析实验设计

针对流体力学教学中难以观察流体动态运动过程的问题,通过调整课程结构,将高速摄像技术与传统的气液两相流实验平台相结合,使流体力学抽象概念得到具象化呈现。实验结果表明,借助该可视化实验教学平台,能够研究气泡的运移特征,研究旋流场内气泡的破碎和聚并行为,分析不同工况条件下的气泡形态,得出旋流场内气液两相流型。对培养学生分析和解决问题能力,提升实验教学效果有很好的促进作用。

旋流器内气泡聚并与破碎行为

为了探究旋流器内气泡聚并与破碎行为的影响因素,采用高速摄像实验研究旋流器内的气液两相流。通过实验分析了气泡在旋流场中的聚并和破碎行为,考察不同工况条件对气泡聚并与破碎的影响,同时运用数值模拟进行验证。结果表明,入口速度提升会导致气泡的破碎频率增加,生成子气泡也越多,但同时加剧了气泡的聚并性能,促使气泡聚并成气核朝着溢流口方向运移,因此入口速度提升对气泡直径变化的影响呈正向作用。气体体积分数提升会导致旋流器内气泡直径和气核长度增大,降低了流场的旋流强度,使更多气泡聚并成气核从底流口流出,故气体体积分数对气泡直径变化的影响呈反向作用。

V槽的偏斜度及其分布对微通道流动沸腾特性的影响

运用VOF模型与用户自定义函数,数值模拟水在V槽微通道内的流动沸腾过程,分析V槽的偏斜度及其分布对通道内气泡的生长、脱离及气液两相流流型变化的影响.研究结果表明:V槽偏斜度会影响微气泡的脱离直径和脱离时间;偏斜度为1.0的V槽对应的气泡脱离直径较偏斜度为0和0.5的V槽分别减小0.063、0.025 mm,脱离时间分别缩短5.20、2.40 ms,气液两相流由泡状流向受限气泡流的转变沿流动方向往后推移2.7 mm,且片段环状流占据区间有所减小;对于偏斜度为1.0的V槽,当其沿流动方向的分布不同时,微通道内气液两相流动呈现不同特征,前疏后密的V槽分布能更好地抑制通道内气泡聚并,通道全程未见片段环状流发生,近壁区液膜可以避免受热面局部干涸,提升微通道流动沸腾换热的稳定性和可靠性.

亚毫米气泡和常规尺寸气泡气液两相流流动与传质特性对比

通过实验和数值模拟系统研究了亚毫米气泡鼓泡塔与常规鼓泡塔在流动和传质特性上的区别,并建立了适用于亚毫米气泡气液两相流流动和传质过程的数值模拟方法。研究结果表明,相比常规鼓泡塔,相同操作条件下亚毫米气泡鼓泡塔的气泡尺寸分布更窄,平均尺寸降至前者3%左右,气含率提高2倍以上,比表面积提高2个数量级。另外亚毫米气泡气液两相流中气液径向分布更均匀,轴向返混程度更小。亚毫米气泡鼓泡塔的相界面积是强化传质的关键控制因素,其液相传质系数虽低于常规鼓泡塔,但依靠巨大的相界面积,其体积传质系数是常规鼓泡塔的10倍左右。针对大规模鼓泡塔反应器的模拟结果也表明,亚毫米气泡可使反应器达到更均匀的气含率分布,受初始气液分布的影响小。

电场作用下气泡上升和破碎特性

利用数值模拟方法研究均匀垂直电场下单个气泡在液体中的上升和破碎特性。采用相场方法捕捉气泡形状变化,考察电场强度对气泡上升速度、液体射流速度和破碎时间的影响。结果表明:电场对气泡运动有显著影响,电场强度越大,气泡上升速度和液体射流速度越大。考察电场作用下气泡初始形状对上升和破碎特性的影响。结果表明:在电邦德数Bo_(e)为0—20内,初始水平轴与竖直轴比为1.3和1.0的椭球形气泡,电场强度的增大缩短了其破碎时间,而初始水平轴与竖直轴比为0.8的椭球形气泡,破碎时间随电场强度增大而变长。

气泡在液态铅铋金属中的运动特性及曳力系数模型研究

当铅铋快堆发生蒸汽发生器传热管破裂(Steam Generator Tube Rupture,SGTR)事故后,一回路高温液态铅铋合金(Lead-Bismuth Eutectic,LBE)与二回路高压过冷水相互作用产生大量蒸汽,这些气泡在LBE的携带作用下可能进入堆芯,引起局部传热恶化和功率瞬变,严重影响反应堆的安全运行。掌握气泡在液态LBE中的运动特性及其动力学行为,开发适用于LBE中气泡迁移的曳力系数模型,是开展SGTR事故堆芯安全评估的基础。基于CLSVOF(Coupled Level-Set and Volume-Of-Fluid)方法建立了气泡在高温液态LBE中迁移运动的三维数值模型,通过分析气泡的运动轨迹、速度和粒径的变化规律,结合气泡受力平衡方程,获得了气泡曳力系数的模拟值。在此基础上,对比分析了现有曳力模型对LBE中气泡迁移的适用性,优选了最佳曳力系数模型并进行了进一步优化,优化后的模型对于液态LBE中气泡曳力系数的计算误差在15%之内。研究结果可为后续SGTR事故安全分析程序的开发提供理论支持。

硅基微柱簇阵列微通道流动沸腾实验研究

为实现硅基微通道流动沸腾换热强化,分别设计并加工了具有并联微通道、稀疏微柱簇和致密微柱簇结构的微通道换热器,以丙酮为工质开展热通量200~650 kW·m^(-2)的流动沸腾实验。结果表明,相较于并联微通道,稀疏微柱簇和致密微柱簇微通道具有更强的两相换热性能;在质量流速43 kg·m^(-2)·s^(-1)的条件下,稀疏微柱簇微通道与致密微柱簇微通道的平均传热系数分别可达到18.6和17.8 kW·m^(-2)·K^(-1),稀疏微柱簇微通道PEC最大可达到1.49。微柱簇阵列随热通量的增加呈现出三种不同流型,可视化研究表明,稀疏微柱簇内产生的汽相更倾向发生微柱簇绕流,而致密微柱簇内产生的汽相更倾向包裹住微柱簇,这使得前者表现出更强的两相换热性能。

天然气储层裂隙中气-液两相流的流态转变条件数学模型

气-液两相在储层裂隙中流动时可能存在气泡流、段塞流、环雾流等流态,查明流动时流态转变条件能为气-液两相流流态形成机理研究提供依据,有助于天然气井的生产管控。根据气-液两相流不同流态的流动特点,结合连续介质控制理论和动量守恒原理,构建了气泡流-段塞流-环雾状流等流态之间转变的数学模型,确定了各流态间变化的临界条件和主控因素,通过气-液运移产出微观流动物理模拟试验验证了所建数学模型的准确性。结果表明:气-液两相在裂隙中的流态转变是气/液相的物理性质、注气通道孔径、裂隙流动通道孔径、气相流体流速、液相流体流速等因素耦合作用的结果。气泡流与段塞流能否转变主要取决于初生气泡大小、流动通道空间、液相界面波高度;段塞流与环雾流间能否转变取决于气相流体能否击碎液相流体并使之悬浮。不同流态间转变的主要控制因素不同:气泡流与段塞流相互转变的主控因素为裂隙系统的孔径,注气通道孔径越大、流动通道孔径越小,越容易发生段塞流;段塞流与环雾流相互转化的主控制因素为流体流速、气/液相流体的物理性质,气/液相对速度越大、气/液密度差越小、液相表面张力越小,越容易发生环雾流。研究成果能够为天然气储层裂隙中气-液两相流态形成机理和天然气运移产出研究提供理论依据。

基于GBDT的气液两相流相分布测量模型

双波长透射法是一种高精度的多相流相分布参数检测方法,为了进一步提高相分布测量的精度,本文提出用梯度提升决策树(GBDT)算法建立相分布测量模型。利用光学仿真,模拟气泡在不同相分布下波长为445nm和635nm的光线在气液两相流中的传播过程,采集检测平面的光强分布,分析不同相分布情况下气泡中心位置和气泡半径对光强分布曲线的影响;用GBDT建立测量模型,以光强缺失宽度和缺失偏移为特征参数,建立特征参数与气泡相分布之间的对应数据库,利用数据库对GBDT模型进行训练;用训练好的模型预测气泡的相分布。建立的测量模型对气泡相分布预测的均方误差小于0.0008mm,均方误差减小了33.33%,证明了测量模型更适用于相分布的测量。搭建了实验平台,对竖直上升气泡流相分布参数进行预测,实现了对气泡中心位置运动轨迹的追踪。

CO_(2)多气泡上升过程传质特性的数值分析

为了揭示CO_(2)多气泡上升行为和气液传质过程的相互作用机制,通过VOF(流体体积法)多相流模型结合自定义程序,实现气泡流动与传质的耦合,数值模拟结果表明:CO_(2)多气泡上升过程出现了聚并、破碎、自由上升和排斥等相互作用现象,气泡尾流经历对称脱落、过渡态和周期性脱落3个阶段,气泡初始间距、气泡初始大小和液相物性等因素共同影响着多气泡的运动和传质过程。初始间距较小时气泡易聚并,聚并过程减小了气液接触面积,不利于传质;初始直径较小时气泡运动越不稳定,停留时间长,可以促进气液传质;液相黏度越大阻力越大,抑制了气相在尾流的扩散,不利于传质。