COUPLED SIMULATION OF 3D ELECTRO-MAGNETO-FLOW FIELD IN HALL-HEROULT CELLS USING FINITE ELEMENT METHOD

Two full 3D steady mathematical models are developed by finite element method （FEM） to calcalate coupled physics fields. the electro-magnetic model is built and solved first and so is the fluid motion model with the acquired electromagnetic force as source body forces in Navier-Stokes equations. Effects caused by the ferromagnetic shell, busbar system around, and open boundary problem as well as inside induced current were considered in terms of the magnetic field. Furthermore, a new modeling method is found to set up solid models and then mesh them entirely with so-called structuralized grids, namely hex-mesh. Examples of 75kA prebaked cell with two kinds of busbar arrangements are presented. Results agree with those disclosed in the literature and confirm that the coupled simulation is valid. It is also concluded that the usage of these models facilitates the consistent analysis of the electric field to magnetic field and then flow motion to the greater extent, local distributions of current density and magnetic flux density are very much dependent on the cell structure, the steel shell is a shield to reduce the magnetic field and flow pattern is two dimensional in the main body of the metal pad.

Numerical Investigation on the Flow and Temperature Fields in an Inductively Coupled Plasma Reactor

This paper gives a numerical study on the flow and temperature fields in an induced plasma reactor, which worked in 0.5 ATM with air as a working gas. We employed a two-dimensional mode of an inductively coupled plasma to calculate the temperature and flow field of the reactor as well as the generator. The algorithm is based on the solutions of the two-dimensional continuity, momentum, and energy equations in term of vorticity, stream function and enthalpy. An upwind finite-difference scheme was adopted to solve those equations with appropriate boundary conditions. The computed results show that there is a flat region with little parameter change in the reactor, that the diameter of the region is not much larger than that of the generator and that a deep change of parameter exists in the outer side of the region.

Fluid Flow and Solidification Simulation in Beam Blank Continuous Casting Process With 3D Coupled Model

Based on turbulent theory, a 3D coupled model of fluid flow and solidification was built using finite difference method and used to study the influence of superheating degree and casting speed on fluid flow and solidification, analyze the interaction between shell and molten steel, and compare the temperature distribution under different technological conditions. The results indicate that high superheating degree can lengthen the liquid-core depth and make the crack and breakout possible, so suitable superheating should be controlled within 35℃ according to the simulation results. Casting speed which is one of the most important technological parameters of improving production rate, should be controlled between 0. 85 m/min and 1.05 m/min and the caster has great potential in the improvement of blank quality.

Development and application of coupling model of aluminum thin-gauge high-speed casting

Based on the analyses of aluminum melt flow, solidification, heat transfer during the process of twin-roll casting, a coupling mathematical model of aluminum thin-gauge high-speed casting was developed, which included the casting roller shell. At the same time, Galerkin method was adopted to solve the coupling model. The fluid field and temperature field of aluminum melt in casting zone, the temperature field and thermal stress field of roller shells were simulated by the coupling model. When the casting velocity is 7m/min, and the thickness of strip is 2mm, the circumfluent area comes into being in the casting zone, and the mushy zone dominates the casting zone, while the temperature of melt decreases rapidly as it approaches the rollers. The temperature of the roller shell varies periodically with the rotation of roller, and reaches the highest temperature in the casting zone, while the temperature of roller shell decreases gradually as it leaves the casting zone. The difference of thermal stress between the inner surface and outer surface of the roller shell is very large, and the outer surface suffers tensile-compressive stress.

Coupled Modeling of Electromagnetic Fleld,Fluid Flow,Heat Transfer and Solidification During Conventional DC Casting and Low Ftequency Electrmagnetic Casting of 7xxx Aluminum Alloys

A comprehensive mathematical model has been developed to describe the interaction of the multiple physics fields during the conventional DC casting and LFEC (low frequency electromagnetic casting) process. The model is based on a combination of the commercial finite element package ANSYS and the commercial finite volume package FLUENT, with the former for the calculation of the electromagnetic field and the latter for the calculation of the magnetic driven fluid flow, heat transfer and solidification. Moreover, the model has been verified against the temperature measurements obtained from two 7XXX aluminum alloy billets of 200mm diameter, cast during the conventional DC casting and the LFEC casting processes. In addition, a measurement of the sump shape of the billets were carried out by using addition melting metal of Al-30%Cu alloy into the billets during casting process. There was a good agreement between the calculated results and the measured results. Further, comparison of the calculated results during the LFEC process with that during the conventional DC casting process indicated that velocity patterns, temperature profiles and the sump depth are strongly modified by the application of a low frequency electromagnetic field during the DC casting.

超深层裂缝性致密砂岩气藏多尺度耦合流动数值模拟

塔里木盆地克拉苏气田白垩系气藏是罕见的超深层裂缝性致密砂岩气藏,该类气藏的储渗空间具有显著的多尺度特征,基质与多尺度裂缝、断层介质的渗透率级差相差5~6个数量级,常规渗流理论难以准确描述其流动规律和开发机理。为此,基于单裂缝流动物理实验结果及流体力学理论,结合多尺度裂缝几何信息,应用均化理论和体积平均尺度升级方法,将多尺度介质划分为5个流动系统,建立了考虑介质间的非稳态窜流多尺度耦合流动数学模型,并应用有限体积法对耦合流动模型进行了数值求解和数值试井分析。研究结果表明:(1)不同尺度裂缝中具有不同的流动特征,随缝宽增加流速加快,流动模态发生变化;(2)多尺度耦合流动模型与双重介质模型结果存在较大差异,导数曲线具有不同趋势特征;(3)应用所建立的多尺度耦合流动模型成功解释了气藏实际试井数据,模型能够反映实际地层中的流动过程。结论认为,超深层裂缝性致密砂岩气藏多尺度耦合流动模型揭示了多尺度裂缝以及致密基质间逐级动用、协同供气的开发机理,可为类似气藏制订合理开发技术政策及气藏提高采收率提供理论和技术支撑。

球状风化花岗岩类土质边坡土-岩界面优势流潜蚀特性研究

受降雨作用,球状风化花岗岩类土质边坡的土-岩差异风化界面极易演化为优势渗流通道而发生渗流潜蚀,进而加速该类边坡的变形失稳,然而当前有关其渗流潜蚀作用特征、细颗粒迁移规律等的研究仍鲜见开展。基于多孔介质非饱和渗流理论,综合考虑细颗粒运移、潜蚀启动响应与非饱和渗流的耦合关系,提出一种可准确描述土-岩界面渗流潜蚀过程的数值计算框架。采用有限元方法,构建优势流作用下非饱和花岗岩残积土的渗流潜蚀模型,并以均质土柱的渗流潜蚀过程为参考,系统研究3种典型土-岩界面埋藏状态下的优势流潜蚀特性。结果表明:球状风化花岗岩类土质边坡的土-岩界面与基质渗透性存在高度差异性,湿润锋形成向下凹陷的渗透漏斗,且随着降雨的持续,湿润锋的凹陷程度愈发明显;细颗粒流失程度与土-岩界面的埋藏状态相关,其中下填土体工况的优势流潜蚀最为显著,其界面处甚至出现超孔隙水压力,最不利于该类边坡的稳定性。研究成果可为降雨条件下球状风化花岗岩类土质边坡稳定性的准确评价提供科学依据。

一种基于线性零磁场的动脉血管扫描成像方法仿真

基于磁电耦合效应的血流检测及血管成像是实现心血管疾病早期诊疗的有效方法之一。该文基于磁场与血流耦合电效应,设计一种用于动脉血管扫描成像的组合线圈结构,产生带有零磁场线(FFL)区域的线性梯度磁场;在此结构的基础上,通过控制激励电流驱动FFL实现成像区域双向扫描;结合卷积神经网络(CNN)实现磁电耦合信号与血管信息的非线性映射,进而提出一种基于线性零磁场的动脉血管扫描成像新方法。采用多物理场仿真软件COMSOL对基于线性零磁场的血管扫描成像方法进行建模,求解磁电耦合信号,验证了所提出方法的合理性和有效性。结果表明,线性梯度磁场模式下的磁电耦合信号含有血管位置、半径等信息;CNN重建血管位置误差平均值为1.5694 mm,重建血管半径的方均误差(MSE)和相关系数(CC)平均值分别为0.0548和0.9870。研究结果可用于血管成像装置设计及后续相关临床应用提供研究支撑。

电场耦合垂直流人工湿地对农村污水的净化效果及细菌群落结构变化特征

为进一步提高人工湿地处理农村污水效果,构建了耦合电场垂直流人工湿地系统(E-VFCW系统),以昆明市盘龙区长地梗城中村东干渠的原水为处理对象,探究其稳定性及净化效果,通过微生物群落演变特征,揭示其污染物去除的生物学化学机制.结果表明:①与垂直流人工湿地系统(VFCW系统)相比,E-VFCW系统对农村污水的净化效果更高,化学需氧量(COD)、总磷(TP)、氨氮(NH_(4)^(+)-N)、总氮(TN)处理效果分别提高了7.94%、5.67%、51.14%、27.54%,其中NH_(4)^(+)-N去除率存在显著差异(P<0.05).②E-VFCW系统中,相对丰度排序前三的优势菌门为变形菌门(Proteobacteria)、拟杆菌门(Bacteroidetes)和放线菌门(Actinobacteria),其相对丰度之和约为80%;优势菌属包括脱氯单胞菌属(Dechloromonas)、黄杆菌属(Flavobacterium)和假单胞菌属(Pseudomonas)等.③冗余分析表明,E-VFCW系统中变形菌门(Proteobacteria)、酸杆菌门(Acidobacteria)、绿菌门(Chlorobi)、放线菌门(Actinobacteria)、硝化螺旋菌门(Nitrospirae)是COD、TN、TP、NH_(4)^(+)-N净化的主要驱动因素.④秩相关分析表明,电场施加能促进E-VFCW系统中产电细菌假单胞菌(增加4.76%)、氢噬胞菌(增加2.02%)、黄杆菌(增加12.54%)等的富集和积累.研究显示,将电场与垂直流人工湿地进行耦合后,可使产电细菌相对丰度显著增加,可为农村污水治理提供理论指导和科学依据.

小型垂直轴风力机叶片流固耦合分析

这里选取旋转直径为2m的垂直轴风力机叶片为研究对象,该研究对象为参考某1000W垂直轴风力机叶片,叶片翼型为NACA0021,采用数值模拟计算与实验相互验证的方法。对垂直轴风力机叶片进行实验位移测试分析,并使用ANSYS Workbench对叶片进行流固耦合分析,调用系统耦合器实现数据的相互传递,完成对叶片的双向耦合计算。研究风力机叶片在不同工况下的位移、应力应变。研究结果表明:风载使叶片产生变形,且沿叶片展向有较大幅度的位移;随着风速的增加,叶片位移增加明显。叶片来流方向压力大于背流方向压力,沿叶片展向叶片位移变形曲线上下波动。

电流体雾化双液滴电聚结行为研究

电流体喷印技术具有分辨率高,溶液参数适应性广等优点,是新型显示制造工艺创新突破的重要载体之一,可用于OLED微米厚度有机TFE膜高效制造。为深入探索电流体雾化技术制备微纳液膜过程,解决现阶段对液膜制备过程中各因素作用机理了解不清的问题,基于相场方法建立了液滴电聚结两相流耦合模型,分析了制备过程中“双液滴电聚结”单元。研究外加电压、基板接触角、液滴间隙和直径对液滴聚结的影响,并总结了液滴可聚结工艺参数相图。研究结果表明,外加电压越大、液滴隙径比越小,聚结后液滴高径比越大,聚结越快;基板接触角越大,聚结后高径比越大,聚结越慢,甚至可能使液滴无法聚结。在亲水基板上外加适当电压或增加液滴密度缩短液滴间隙有助于促成基板上液滴电聚结.该研究结论和工艺相图可应用与电流体雾化制膜时工艺参数调控。

基于声学层析成像的温度场和流速场重构

为有效重构三维管道内液体的温度场和流速场,提出了一种超声飞渡时间计算表征,并基于此求解温度场和流速场反演模型。同时考虑温度梯度导致的声线弯曲效应,采用正四面体前向展开法,追踪超声弯曲路径;开展“华龙一号”反应堆主管道冷却剂温度场和流速场重构实验。实验结果表明,所提方法能有效重构管道冷却剂温度场和流速场,且考虑弯曲效应能进一步提高重构精度。

基于电-热流场双向耦合的直流继电器温升特性仿真研究

高压直流继电器体积小、散热能力有限,长期工作下存在局部过热的风险,发热严重时甚至影响到接触稳定性和继电器工作寿命。针对200 A直流继电器,综合考虑导体回路通电下欧姆损耗发热,在大空间的自然热对流、热传导以及热辐射、材料电阻率随温度变化等因素,建立继电器在额定工况下电-热流场双向耦合模型,设置电阻率随温度变化函数,进行耦合计算。最后,搭建对应的样机测温平台,对仿真正确性进行验证。结果表明双向耦合结果比单向耦合结果高约5.1%,与实验测量值误差小于6.2%,验证了电热流场双向耦合的有效性。

直通调节阀内流场流道分析

随着油田的大量开发,油气井的工作情况更加复杂,一些出砂井常用螺杆泵,为了满足不同井深和产液量的需求,需要对压力调节阀进行检测。此次设计一种直通调节阀,在进出口压力一定的情况下,模拟仿真所设计的调节阀是否具有一定的稳定调节性能。调节阀又称控制阀,基于SOLIDWORKS三维模型,利用Fluent软件对其进行数值模拟,通过不同开度下的阀芯进行对比,通过分析压力云图、速度云图和流线图分析其流动规律。结果表明:(1)随着阀门开度的增大,阀芯阀座间流通面积变大,流速随着阀门开度的增加而减小。(2)随着阀门开度的不断增大,内流场压力会出现明显的变化。(3)随着阀门开度的增加,调节阀内流场会出现明显的漩涡。利用ANASYS软件进行流-固耦合,联合使用流场模块、静力场模块和温度场模块对调节阀内流场进行应力形变,当流体进入时,调节阀内流场发生应力形变比较稳定。以上所有模拟结果均符合实际情况,具有良好的稳定调节性能。

基于FEM、CFD和DEM耦合的三产品磁选柱磁选过程模拟

为探明磁铁矿颗粒在三产品磁选柱中的运动规律和影响因素,采用FEM、CFD和DEM耦合的方法对其磁选过程进行模拟,并通过实际分选试验进行验证。基于磁铁矿粒度分布、矿物组成、磁化特性和力学特性,建立了磁铁矿重叠球体颗粒模型,采用ANSYS有限元软件模拟三产品磁选柱的磁场分布,采用Fluent软件模拟三产品磁选柱的流场分布,采用EDEM-API技术在离散元软件EDEM中实现矿石颗粒、磁场和流场的耦合,模拟三产品磁选柱的磁感应强度、励磁周期以及上升水流速对分选过程的影响。在给矿TFe品位为61.42%的情况下,模拟试验得到的精矿、中矿和尾矿的TFe品位分别为63.60%、58.44%和29.63%。采用?159型三产品磁选柱在与模拟条件相同的情况下进行分选试验。结果表明,精矿、中矿和尾矿的TFe品位分别为65.55%、42.58%和24.23%,模拟试验与实际试验的相对误差在3%以内。

基于CFD-DEM耦合的装车站溜槽设计参数优化

为提高装车站溜槽的物料分布均匀性,降低粉尘质量浓度,提出基于CFD-DEM耦合的装车站溜槽设计参数优化方法。分析装车站溜槽的工作流程,采用CFD-DEM耦合的方法建立装车站溜槽有限元模型;建立卸料方程、物料与溜槽、挡板的撞击方程、滑行方程和运动方程,同时结合有限元模型展开颗粒运动分析和压力流场分析;根据分析结果优化装车站溜槽物料对应的动堆积角参数、流线控制参数、物料入射角参数、挡板与物料之间的摩擦角参数,实现优化物料流、物料速度、溜槽横截面积和物料重力分布。实验结果表明:所提方法设计溜槽的物料分布均匀性高,并且粉尘质量浓度降低至912 mg/m 3。

基于COMSOL的工作面瓦斯场与流动场耦合分析

针对工作面和采空区内风流的不稳定运动,使用COMSOL Multiphysic多物理场耦合模拟软件和气体运移的相关原理,模拟分析工作面及采空区的空气和瓦斯的运移和浓度变化。结果表明,进风风速增大,采空区内的空气含量增大;通风时间越长,采空区空气含量越高;自然通风很难解决瓦斯的上隅角积聚。模拟结果可以有效地指导矿井瓦斯抽放,为火灾爆炸事故预防提供理论依据。

盆山耦合机制下库车坳陷砂岩型铀成矿的构造约束作用

库车坳陷处于的塔里木盆地北部,其局部地区已有新的找矿发现,但整体而言仍未获得实质性找矿突破。文章依据区域地质和勘查钻孔资料,结合野外地质调查和样品采集测试,通过综合分析,探讨了库车坳陷在构造-地形地貌的盆山耦合过程中,上新统库车组区域成矿流场的迁移、汇聚过程,区域氧化带及砂岩型铀矿的构造改造特点和分类,并分析了不同构造改造型氧化带的铀成矿潜力。主要认识有:库车坳陷新生代以来的盆山耦合体制有利于“盆地”尺度初始氧化带及铀成矿流场的发育,上新统库车组中的含氧含铀成矿流体总体具自北向南渗流趋势。在库车坳陷内,东西向构造带限定了库车组成矿流场和大规模氧化带的发育空间和南部边界。随着同生长性质的秋里塔格构造带的逐步褶皱抬升,在拜城凹陷南部形成大型“拦水坝”(构造阻水带)和区域性排泄区,库车组区域成矿流场和氧化带被“阻拦”在秋里塔格构造带北翼,“新”“老”两套铀成矿系统在此处叠加,从而形成库车组最具规模的工业铀成矿带。库车组的构造改造型氧化带可划分为3类:早期铀成矿系统被后续氧化成矿流体进一步叠加改造型,铀成矿规模最大并最具找矿潜力,代表区段为日达里克—赛里木一带;早期铀成矿系统后期被构造阻断型,具备一定的成矿潜力,代表区段为温宿、东阿瓦特及却勒一带;早期铀成矿系统被后期氧化再迁移型,成矿潜力有限,代表区段为吐孜塔格及克拉苏构造带。

离心力场-移动床耦合气固分离装备的研究进展

气固分离装备的发展对于实现高温烟气的高效除尘净化具有重要意义。基于单一气固分离机制的除尘装备难以实现精细除尘的目标。将离心分离和移动床分离耦合在同一装备中,实现两种分离机制的协同强化无疑是一种解决方案。在该耦合装备中,旋风壳体和移动床内气相、捕集颗粒、粉尘的运动较之常规单体旋风分离器、移动床均具有一些独特的特性。通过压降-时间响应曲线发现该新型耦合分离装备具有自清洁功能。该装备对黏附性微细粉尘的捕集效率在95%以上;旋风壳体分离了10μm以上颗粒物,而内置颗粒床捕集到的粉尘粒径在10μm以下,验证了二者在同一装备中的协同强化。但是,强化自清洁效应和提高捕集效率构成了一对矛盾。研究表明,该新型耦合分离装备仍具有很大的性能提升空间。

熔盐集热塔风致响应研究

为研究熔盐集热塔风荷载作用下的结构响应,基于计算流体动力学(Computational fluid dynamics,CFD)技术建立了熔盐集热塔结构数值风洞,开展了单向和双向流固耦合分析。通过风场计算域尺寸、湍流模型及初始风速条件的合理设置,获得了风场速度、风场压力和集热塔响应分布规律。集热塔在风荷载作用下以第一振型为主。集热塔位移、速度和加速度前期变化幅度较大,后期呈现稳定衰减趋势。顺风向基底剪力是结构总剪力的主导部分。分析结果可以为集热塔的设计和相关研究提供依据。