矩形导流管喷动床下行区的床层压降

带导流管的矩形喷动床是传统喷动床的改进型式,矩形床内设置的与床同厚的垂直导流管,可以控制固体颗粒的内循环速率,同时使下行区中的气固移动床维持平推流.本文实验测定了不同表观气速、床层重量、不同固体颗粒与气体入口形式与尺寸时,矩形导流管喷动床下行区的床层压降,以考察其流动特征.实验结果表明,下行区存在床层压降的轴向分布,气固流动处于负压差下移上流区,且气固滑移速度自下而上是逐渐下降的.下行区颗粒床层的压降以及颗粒的移动下输,受到喷动床表观气速、床高、喷嘴尺寸、物料种类和颗粒直径的不同影响.     

喷动床内气固两相流动纵向涡流效应数值模拟

为了深入了解纵向涡流对喷动床内气固两相流动特性的影响规律,采用计算流体力学方法对喷动床内气固两相流动的纵向涡流效应进行三维数值模拟。采用RUC曳力系数模型描述气、固相间作用力,通过欧拉-欧拉双流体模型和颗粒动力学理论对气固两相流动进行模型处理。分别对无扰流件、加入一对小球扰流件及加入一对纵向涡流发生器喷动床结构进行了模拟分析及对比。研究表明:加入球体扰流件及纵向涡流发生器之后,喷泉区的喷动高度明显下降,并在球形扰流件及纵向涡流发生器附近产生了二次漩涡。纵向涡流的存在显著地增加了喷动床内环隙区颗粒相的径向速度,增加了喷射区及喷泉区内颗粒体积分数及其密集度,有效增强了喷动床内气体、颗粒沿径向与轴向的湍动能及拟温度值,进而强化了环隙区与喷射区内颗粒、流体两相的横向混合效果及颗粒间的动量交换过程。     

整体式多喷嘴喷动-流化床内气固两相流动规律数值模拟

采用双流体模型(TFM)对一种新型整体式多喷嘴喷动-流化床内气固两相流动进行了数值模拟,在喷动床锥体两侧开若干侧喷嘴形成辅助多喷嘴结构,使其在喷动床锥体处产生喷动-流化效果,从而对环隙区锥体边界处堆积颗粒层产生扰流作用。通过CFD数值模拟获得了喷动床内颗粒速度及浓度的分布情况,并与单喷嘴喷动床模拟结果进行对比。研究并优化分析了不同侧喷嘴数量以及侧喷嘴宽度等关键参数对喷动床气固两相流动的影响规律。研究表明,与常规喷动床相比,整体式多喷嘴喷动-流化床结构能有效增强喷动床内环隙区颗粒相运动,特别是强化了喷动床环隙区底部流动死区的颗粒运动,使得锥体边界层颗的粒体积分数显著下降,颗粒体积分数沿径向分布变得更为均匀,同时省略了旁路供气辅助设备。     

二维导流管喷动床的流动特征

带导流管的二维喷动床(2-DSBDP)是传统喷动床的改进型式,矩形床内设置的与床同厚的垂直导流管可以控制固体颗粒的循环速率, 同时使下行区中的气固移动床维持平推流. 本文实验测定了不同表观气速、床层高度、固体颗粒与气体入口尺寸时, 二维导流管喷动床的床压降及相应的空隙率,藉以阐述2-DSBDP的流动特征.     

喷动床内气固两相流体动力行为的数值模拟

引　言喷动床被广泛应用于不同工业领域中 ,如石油裂解反应 -再生器、煤和农业废弃物气化和燃烧 ,喷动床还被应用于粮食和药品的干燥等[1] .因此 ,喷动床设计应满足不同应用的要求 .喷动床内气相反应物的反应时间和停留时间依赖于床体几何结构和运行参数 .尽管已有许多的实验对喷动床内气固两相流动进行了研究 ,得到了喷射区、环形区和喷泉区内的气固两相流动流体动力特性 ,然而由于喷动床内气固两相流动的复杂性 ,人们对床体几何结构和运行参数对喷动床动力学的影响至今并不清楚 .因此 ,床体几何结构和运行参数等对喷动床动力学的影响成为…     

喷动床内气固两相流动进口旋流效应数值模拟

为了研究喷嘴进口气体旋流效应对喷动床内气固两相流动特性的影响规律,采用数值模拟方法进行研究分析。通过欧拉-欧拉双流体模型和颗粒动力学理论对气固两相流动进行模型处理,分别对常规喷动床及带旋流器喷嘴喷动床进行模拟分析与对比。研究表明:喷嘴进口气体旋流效应显著地强化了喷动床内颗粒的径向运动,能有效消除柱锥区的颗粒堆积现象,扩大了低床层区气体喷射区的影响范围,增加了喷动床内气体的湍动能值,从而提高喷动床内颗粒处理的整体效率。存在最佳η(旋流器内径与外径比值)值,即η为0.526时,旋流气体对喷动床环隙区内颗粒堆积的消除作用及气体湍动能值的提升最为显著,同时旋流器喷动床的总体压降达到了峰值。     

喷动床内气固二相流动行为的计算模拟

采用双流体模型结合颗粒动理学理论对喷动床内气固二相流体流动行为进行了计算模拟研究。模型中运用颗粒动理学理论描述颗粒相应力封闭流体控制方程,使用Gidaspow曳力模型描述气固相间作用。喷动床内颗粒在浓相区的体积分数很大,采用Schaeffer′s模型描述颗粒间的摩擦应力。模拟计算结果表明,喷动床内分喷射区、喷泉区、环隙区3个区域,在射流入口处形成一个瓶颈。模拟计算得到的颗粒速度和空隙度分布与实验数据进行比较,计算结果与实验结果吻合较好。     

三维整体式喷动-流化床结构优化与流动数值模拟

为了对环隙区内的颗粒堆积层产生局部流化作用,提出了一种在喷动床锥体处开一定数量侧喷嘴的整体式多喷嘴喷动-流化床结构,并采用双流体模型(TFM)对三维整体式多喷嘴喷动-流化床内的气固两相流动行为进行了数值模拟。通过计算流体力学(CFD)模拟获得了喷动床内颗粒体积分数、颗粒速度及流场均匀度分布情况,并将模拟结果与传统喷动床进行了对比,同时对锥体处开孔直径等关键参数进行了优化分析。结果表明:与常规喷动床相比,三维整体式多喷嘴喷动-流化床结构能有效增强喷动床环隙区与喷射区颗粒的径向混合,特别是流化了喷动床环隙区底部颗粒的流动死区。颗粒流场均匀度(CV)值随着床层高度的增加而上升,表明多喷嘴对颗粒流场的均匀化效应主要体现在喷动床柱锥区,当A_i/A_z=0.67时,侧喷嘴对喷动-流化床内整体的颗粒流化作用达到最佳。     

循环流态化：（Ⅲ）气,固流动模型

根据气、固两相流动的基本特征,循环流态化气、固两相流动模型可分为局部流动结构模型及整体流动结构模型两类。局部流动结构模型主要描述床内稀相及絮状物相的局部分布及变化,而整体流动结构模型主要描述床中空隙率。颗粒速度以及气体速度轴、径向分布及变化,其中根据实用层次不同,整体流动结构模型可分为一维、一维两区及两维模型。本文对循环流态化气、固流动模型进行了分类评述,供循环流化床反应器设计时参考。     

基于信息熵分析的喷动流化床流动特性

建立了300 mm×30 mm×2000 mm的喷动流化床煤气化炉冷态实验装置和多通道压力信号采集系统,引入压力波动时间序列的Shannon信息熵分析,讨论了不同喷动气速度和流化气流率下各床层区域的Shannon 信息熵,并结合高分辨率数码CCD相机所记录的流动状态,建立了Shannon信息熵与流型之间的联系.床层不同区域的Shannon 信息熵具有较大的差异,不同流型的Shannon 信息熵区分度较好.在较高的喷动气速度或流化气流率下,喷动流化床气固运动周期特性消失,呈现出明显的混沌特性,表现为床层各区域Shannon信息熵的急剧增长和床内不稳定的流动状态的发生.结果表明,Shannon信息熵分析有助于认识喷动流化床复杂的流型及其转变和床内气固两相流动的混沌动力学特性.     

利用途泄流量和输转流量确定天然气分配管道计算流量的研究

在城市天然气管道的输送中,管道建筑用户相连,中途有流量分出,从途泄流量和输转流量的角度研究,利用计算公式来计算管段的计算流量,确定其压力降,并进行了举例说明,为输气管道的设计工作提供了参考。     

Numerical modeling of three-phase stratified flow in pipes

The simultaneous flow of water, oil and gas is of practical importance for the oil and gas industry. These three phases are present in varying degrees of concentration in many oil and gas pipelines. In this work, a model has been developed to predict the values of the hold-up and pressure gradient for three-phase stratified flow prevailing in a horizontal pipeline. This information is usually the first step for analyzing the stability of stratified flow and developing transition criteria. The concept of extended velocity has been applied to compute the wall shear stresses in three-phase flow. The effect of process variables such as gas to liquid ratio, pipe diameter, oil viscosity and non-Newtonian character of oil on hold-up and pressure gradient has been studied to simulate the oil well conditions. Structural stability analysis was also carried out to check for the sensitivity of the model.     

NUMERICAL SIMULATION OF DRYING IN A CYCLONE

ABSTRACT

This work presents a complete improved mathematical model of drying in cyclone. The slip condition of the particles on the wall, the heat transfer wall-panicle and the shrinkage of the panicles during the drying process were considered. The mathematical model considers a two-dimensional turbulent gas-particle flow where the panicle phase is treated as a continuum. The momentum equations of both particle and gas phases were written in cylindrical coordinates. The discretized equations were solved by the SIMPLE algorithm. Considering the slip condition to the panicle phase and the shrinkage of the material during the drying process it was revealed a better fitness between numerical and experimental results than the previous model.     

NUMERICAL SIMULATION OF DRYING IN A CYCLONE

This work presents a complete improved mathematical model of drying in cyclone. The slip condition of the particles on the wall, the heat transfer wall-panicle and the shrinkage of the panicles during the drying process were considered. The mathematical model considers a two-dimensional turbulent gas-particle flow where the panicle phase is treated as a continuum. The momentum equations of both particle and gas phases were written in cylindrical coordinates. The discretized equations were solved by the SIMPLE algorithm. Considering the slip condition to the panicle phase and the shrinkage of the material during the drying process it was revealed a better fitness between numerical and experimental results than the previous model.     

Flow characteristics of blade unit of a tridimensional rotational flow sieve tray under concurrent gas–liquid flow

The flow characteristics of the blade unit of a tridimensional rotational flow sieve tray were investigated. First, the flow patterns are defined under different liquid arrangement methods. They are bilateral film flow, continuous perforated flow, and dispersion-mixing flow in overflow distribution, film and jet flow and jet and mixed flow in spray distribution. Second, the time and frequency domain analysis of the differential pressure pulsation signal in the blade unit is carried out, the main frequencies range is 2.0−5.5 Hz. The influence of perforation and mixing intensity on the flow pattern transition is clarified. Third, the rotational flow ratio of the gas–liquid phase is measured, the gas phase rotational flow range is 0.55–0.78, and the liquid phase range is 0.15–0.42. The influence of the operating conditions on the distribution of the rotational and perforated flow is investigated. Finally, a prediction model for the rotational flow ratio is proposed.     

利用一维波和段塞稳定性模型预测分层流向段塞流的转变

利用气液二相流一维波模型和段塞稳定性模型,对直径2.54 cm水平管内空气-水二相流出现段塞流时的各相临界表观速度和临界液层高度进行了理论预测。计算中发现,2种模型分别适用于不同的流速区域,在较低的气相流速下,一维波模型的预测结果比较理想,但是在较高的气速条件下不太适合,而利用段塞稳定性模型可以较好地获得高流速下分层流向段塞流的流型转变条件。因此,结合这2种模型对发生流型转变时的临界参数作了分析,并且应用于40 mm和50 mm水平管道的油气二相流实验。将理论计算的结果和实验测得的流型数据进行了对比,并且对影响流型的管径、流速等因素作了分析,结果表明计算得到的特征参数和实验数据比较吻合。     

Transitional packed bed flow in standpipes

A quantitative criterion distinguishing stable from unstable transitional packed bed flow in standpipes is presented. This criterion can be used as an working guideline in actual standpipe operation. A fundamental and simple model based on stress free surface (SFS) theory has been developed. This model also provides a quantitative prediction method for the standpipe voidage.     

高粘假塑性流体流动沸腾流型

<正>在流动沸腾传热两相流研究中,流型研究一直是众多研究者的兴趣所在。目前有关流型研究的报道均为低粘物系,但高粘流体两相流流型研究,对高聚物生产、食品、轻工等工业有重要应用价值。 浅尾芳久等在透明玻璃管中研究了流动沸腾的流型,表明Mishima等提出的流型划分判据可以较好地区分泡状流、弹状流、环状流。Kamiel等分析比较了大量低粘物系两相流实验数据和几种流型判别式,表明Weisman等提出的判别式可以较好地区分弹状流与环状流。     

水平管内油水两相流流型转换特性

以高黏度的油和水为工质,在内径为25.7 mm,长52 m的水平不锈钢油水两相流实验环道内对油水两相流流型及其转换特性进行了实验研究.根据实验结果定义了不同流动条件下出现的流型,绘制了流型图.对影响油水两相管流流型转换的各种因素进行了综合分析,利用量纲分析的方法得出了流型转换的准则关系式,并提出了一个较为准确的有关油水两相管流中反相临界含水率的计算相关式.     

气液两相流流量测量方法的研究进展

总结气液两相流流量测量方法的研究进展。介绍节流法、直接法、速度法和分离法的测量原理,并指出对两相流的物性进行全面、详细的实验研究和理论计算将是后续研究工作的重点。