A HYBRID FEM ALGORTHM FOR FLUID FLOW IN A VISCO-ELASTIC PIPE

A variational principle of hybrid FEM is proposed to solve the flow in a visco-elaslic pipe. As an example, the influence of an axisymmetrical stenosis on an artery vibrating flow with a single frequency is calculated.

Influences of double diffusion upon radiative flow of thin film Maxwell fluid through a stretching channel

This work explores the influence of double diffusion over thermally radiative flow of thin film hybrid nanofluid and irreversibility generation through a stretching channel.The nanoparticles of silver and alumina have mixed in the Maxwell fluid(base fluid).Magnetic field influence has been employed to channel in normal direction.Equations that are going to administer the fluid flow have been converted to dimension-free notations by using appropriate variables.Homotopy analysis method is used for the solution of the resultant equations.In this investigation it has pointed out that motion of fluid has declined with growth in magnetic effects,thin film thickness,and unsteadiness factor.Temperature of fluid has grown up with upsurge in Brownian motion,radiation factor,and thermophoresis effects,while it has declined with greater values of thermal Maxwell factor and thickness factor of the thin film.Concentration distribution has grown up with higher values of thermophoresis effects and has declined for augmentation in Brownian motion.

Stress-Blended Eddy Simulation of the Turbulent Flow Around Circular Cylinder with Dynamic Hybrid RANS/LES Model

In order to verify the effectiveness and superiority of the dynamic hybrid RANS/LES(DHRL)model,the flow around a cylinder with sinusoidal fluctuating velocity at the inlet was used as the test case.The latest computational fluid dynamics(CFD)model can flexibly choose any existing large-eddy simulation(LES)method combined with RANS method to calculate the flow field.In addition,the DLES model and DDES model are selected as typical representatives of the turbulence model to compare the capture ability of the flow field mechanism.The internal flow field including the y+value,velocity distribution,turbulent kinetic energy and vortex structures is comprehensively analyzed.Finally,the results show that the new model has enough sensitivity to capture the information of the flow field and has more consistent velocity distribution with the experimental value,which shows its potential in practical engineering applications to some extent.

A Review of the Recent PIV Studies —From the Basics to the Hybridization with CFD

The purpose of this article is to review recent PIV Studies from the basic to hybrid analysis, focusing on explaining epoch-making development of PIV. The overwhelming advantage of PIV over other velocity measurement methods is that it enables instantaneous and simultaneous velocity measurement of whole flow fields. We roughly classify PIV development and/or progress into the following five categories; A) Basics of PIV and post-processing. B) Simultaneous measurement of velocity and temperature, and 3D-PIV. C) Application to multiphase turbulent flows. D) Application to fluid machinery. E) Hybridization of PIV and CFD. This paper introduces the epoch-making research results from papers published in international journals as milestones related to (A) to (E), and concludes with additional forecast of future development of PIV research.

Navier-Stokes Computation of Grid Fin Missile Using Hybrid Structured-Unstructured Grids

Viscous CFD computations are performed to predict the aerodynamic coefficients and flowfield for a missile with grid fins by using hybrid grids. The computations arc made at Math numbvrs of 0.7 and 2.0. Full N-S equations arc discretized into finite volume form and solved by an algorithm in LU-SGS. The comparisons between computation and experimental data are made, and the detailed flow structure near grid fin is shown and examined.

Mathematical analysis of the role of recoil pressure in weld pool dynamics during laser-MIG hybrid welding

A mathematical model was established to simulate the weld pool development and dynamic process in stationary iaser-MlG hybrid welding. Surface tension and buoyancy were considered to calculate liquid metal flow patter, moreover, typical phenomena of MIG welding, such as filler droplets impinging weld pool, electromagnetic force in the weld pool, and typical phenomena of laser beam welding, such as recoil pressure, Inverse Bremsstrahlung absorption, Fresnel absorption were all considered in the model. The laser beam and arc couple effect were introduced into this model by the plasma width during hybrid welding. The role of recoil pressure in the weld formation was discussed. Transient weld pool shape and complicated liquid metal velocity distribution from two kinds weld pool to an unified weld pool were calculated. The simulated weld bead geometry with consideration recoil pressure was in good agreement with experimental measurement.

混合流动式磁流变阀结构设计与压降性能分析

针对目前磁流变阀结构单一且体积大的不足,设计了一种结构紧凑的混合流动式磁流变阀,该磁流变阀阻尼间隙液流通道由单个轴向圆环流动、单个径向圆盘流动和单个中心小孔流动串联组合而成。阐述了混合流动式磁流变阀结构及工作原理;分析了励磁线圈作用下有效阻尼间隙处的磁路分布,同时建立了其压降数学模型。采用有限元法对混合流动式磁流变阀电磁场进行了建模仿真,对阻尼间隙处的磁场强度和剪切屈服应力的分布规律进行了分析;仿真结果表明轴向圆环阻尼间隙厚度为1.0 mm,径向圆盘阻尼间隙厚度为0.5 mm,加载电流为1.2 A时磁流变阀压降最大,为3 342 k Pa。对混合流动式磁流变阀压降性能进行了试验测试,具体分析了加载电流以及径向圆盘阻尼间隙厚度对磁流变阀压降的影响,试验结果表明轴向圆环阻尼间隙厚度为1.0 mm,径向圆盘阻尼间隙厚度为0.5 mm,加载电流为1.2 A时磁流变阀压降最大,为2 650 k Pa,试验结果与仿真结果变化趋势基本一致。

激光+GMAW复合热源焊流体流动数值分析模型

基于FLUENT软件,建立了适用、高效的激光+GMAW复合焊流体流动数值分析模型.将电弧热输入视为双椭球热源模型,采用基于小孔尺寸的锥体热源模型描述激光热流分布;将金属填充过程视为液态金属从熔池上部边界以一定速度流入熔池过程,并通过对液态金属流速施加时间脉冲函数,模拟熔滴的过渡频率;模型简化了小孔的计算过程,主要考虑熔池中存在的弯曲小孔对流体的影响.利用FLUENT软件,对激光+GMAW复合热源焊熔池流体流动及小孔形态进行了模拟计算和分析.结果表明,模型能够合理反映小孔及复合焊流体流动模式的主要特征,且提高了计算效率.

基于Delaunay背景网格插值和局部网格重构的变形体动态混合网格生成技术

建立了一种基于Delaunay背景网格插值方法和局部网格重构方法相结合的变形体动态混合网格生成方法。首先利用作者发展的定态混合网格生成技术生成变形体初始网格,即变形体附近利用结构化的四边形网格,外场采用自适应Cartesian网格,中间由三角形网格过渡。当物体运动或变形时,首先利用Liu和Qin提出的基于Delaunay背景网格的插值方法对变形体附近的网格进行变形;当物体运动或变形位移很大导致局部网格质量急剧下降、甚至网格相交时,则在局部重新生成网格。利用该方法生成了多种变形体外形的动态混合网格,如单个鱼体、双鱼串列巡游,昆虫单翼、双翼扑动,多段翼型变形等,并在鱼体巡游的非定常数值模拟中得到了应用。

磁流变复合液压执行器及其效率研究

介绍了一种可同时实现定位(驱动)与可控阻尼的磁流变复合液压执行器的原理及系统结构,研究了在入口压力较高时磁流变阀不可能完全理想关闭情况下桥式磁流变阀路的效率问题,建立了基于桥式磁流变阀路的磁流变复合液压执行器定位(驱动)时的效率模型。

对光伏热水墙体光电光热性能的数值模拟研究

采用数值模拟的方法动态地分析了光伏热水墙体的光电光热特性,并就系统中电池覆盖率、工作流体质量流率对系统热效率和电力输出的影响进行了研究,得到了系统优化设计的性能参数。

三鱼群游流动干扰及其减阻机理的数值研究

观察研究发现,在鱼类的群游中,鱼体可以有效利用相互之间有益的干扰,减少游动阻力,增强自己的推力和游动效率。文中作者基于以往建立的动态混合网格生成方法以及不可压缩流非定常计算方法,对三鱼呈"三角"阵型排列的群游进行了数值模拟,通过对不同横向间距、不同流向间距、不同相位差等游动状态下的流场结构、力学特性的比较,分析了鱼体之间的横向干扰和流向干扰,研究了流动干扰减阻的机理。

鱼类“钻石”状群游流动干扰及其减阻机理的数值研究

观察研究发现,在鱼类的群游中,鱼体可以有效利用相互之间有益的干扰,减少游动阻力,增强自己的推力和游动效率。本文基于作者以往建立的动态混合网格生成方法以及不可压缩流非定常计算方法,对四鱼呈"钻石"阵型排列的群游进行了数值模拟,通过不同横向间距、不同流向间距、不同相位差等游动状态下流场结构、力学特性的比较,分析了鱼体之间的横向干扰和流向干扰,对其降低阻力、减少功耗的流动机理进行了探讨。

T型三通水管路噪声特性数值研究

水管路系统工作运行中会产生较大的管路振动和流噪声。作为偶极子声源,充液管路内湍流激发的脉动压力会形成流噪声,且激励管壁产生流激振动噪声。为了揭示水管道系统的流激振动噪声与流噪声特性的区别,基于有限元方法对不同厚度的充液管路声学模态、结构模态以及耦合模态进行计算;基于计算流体力学联合声学边界元的混合计算方法探讨变流速下流噪声与管路声学特性之间的关系;并计算分析变流速下流噪声与流激振动噪声特性,变厚度下流激振动噪声特性;将变流速及变厚度管路的流噪声和流激振动噪声进行对比。结果表明:流噪声的峰值频率受管路声学模态的影响,随着流速的增加流噪声能量会增加但峰值频率不变;而流激振动噪声的峰值受管路耦合模态的影响,厚度增加导致模态变化,峰值频率改变;流噪声幅值要大于流激振动噪声幅值。

流体在纳米通道中流动分子动力学研究进展

分子动力学方法及分子动力学和计算流体力学混合的模拟方法是研究纳米通道中流体流动的重要手段。简要分析了纳米通道中流体流动的各种新特性及其出现的原因;针对不同流体模型的建立、不同流动过程的实现、不同模拟方法的使用和相近模拟过程结果的比较四个方面,介绍了应用分子动力学方法或混合方法模拟流体在纳米管道中流动的研究现状;最后从作用势函数、计算简化和模拟软件角度展望了分子动力学模拟技术的发展趋势,并从模拟方法、流体模型、热边界和势函数角度总结了分子动力学方法在模拟纳米通道中流体流动方面的改进趋势。

激光-TIG复合热源焊保护气体动力学特征数值分析

从流体动力学及传热学角度出发,基于FLUENT软件建立了激光-电弧复合热源焊保护气体流场的数值分析模型,对不同条件下保护气体流态进行模拟计算,分析其流体动力学特征及不同保护模式对熔池保护效果的影响。结果表明,对于激光前置复合焊过程,无保护气室时,保护气体对熔池前部保护稍好,而对熔池后部则保护效果较差;当采用保护气室时,熔池前部保护有较大改善,但由于空气回流,熔池后部同样保护较差;而当改进保护气室后部结构后,较好地抑制了空气回流,实现了对整个熔池及其附近焊缝的有效保护,为增强复合焊熔池保护效果及保护气室的优化设计提供基础数据。

宽速域RANS-LES混合方法的发展及应用

传统的雷诺平均方法(RANS)已经不能满足大范围分离、激波振荡、压力脉动、动载荷等极端工况下的流动预测需求;大涡模拟(LES)、直接数值模拟(DNS)等方法资源耗费多、效率低,离工程湍流问题仍较为遥远。RANSLES混合方法结合了RANS高效率和LES高精度的特点,近期有望大规模应用到工程湍流问题中。首先对现有的RANS-LES混合方法进行了归类,对各自的构造思想、特点进行了分析。然后报告了脱体涡模拟(DES)类方法的发展历程和现状,讨论了使用DES类方法计算分离流动时,对流项离散格式对分离特性、小尺度结构及频谱特性等的影响,并构造了自适应耗散函数。最后介绍了近年来国内外RANS-LES混合方法在宽马赫数范围(马赫数从0.1到20)内的机理研究和工程应用。现有的以DES类方法为代表的RANS-LES混合方法能够较为精细地模拟非定常大分离流动中的复杂现象,但在计算效率等方面还有较大的改进空间;植入式DES方法在模拟全机带部件流动上具有较高的效率和模拟精度,是重要的发展方向。RANS-LES混合方法在动态失速、燃烧、气动弹性、气动噪声、气动光学等与非定常流动密切相关的方面也有广阔的应用前景。

永磁-感应子式混合励磁电机转子油摩损耗

以充油运行永磁-感应子式混合励磁电机为对象,对电机转子油摩损耗进行了研究。根据电机结构特点,将电机中光滑转子与齿槽转子分开考虑,采用不同方法分别计算两部分的油摩损耗。基于流体力学理论,采用流体场数值计算方法,重点分析齿槽转子油摩损耗的影响因素,得到了油摩损耗与电机转速和定子内径的数值关系,揭示了温度对转子油摩损耗的影响规律。样机实验结果与计算结果基本一致,验证了计算方法的有效性。

刚柔混合输流管的流致振动稳定性研究

弹性管和刚性管串联而成的混合输流管是典型的刚柔耦合系统。基于Hamilton原理,建立了刚柔混合输流管的动力学模型,利用悬臂梁的模态函数对方程进行Galerkin离散,分析了混合管的流致振动稳定性问题,讨论了两管连接处转动弹簧的刚度、刚性管与弹性管的质量比和长度比对系统临界流速的影响。结果表明,刚性管长度比的增加能显著降低混合管的临界流速,并且主要发生2阶模态失稳。当刚度和质量比取某些值时,随着内流流速的增加,混合管可能出现“失稳(2阶模态)-稳定-再失稳(3阶模态)”的变化过程。此外,随着弹性管质量比的增加,还观察到了混合管由2阶模态过渡到4阶模态的失稳模式。

混合流动式磁流变阻尼器设计及阻尼性能分析

针对传统磁流变阻尼器磁场利用率不高的问题,文中设计了一种混合流动式磁流变阻尼器,该阻尼器液流通道由4段轴向流道和2段径向流道串联组成,通过设置隔磁零件引导磁力线蜿蜒通过全部流道,使该阻尼器在体积限制下能产生良好的阻尼性能。阐述了混合流动式磁流变阻尼器的结构和工作原理,并对其进行磁路分析;建立了输出阻尼力数学模型。此外,采用有限元法对阻尼器进行电磁场仿真,分析了施加不同电流时各液流通道处磁感应强度和切应力的分布规律。对磁流变阻尼器两个重要阻尼性能指标,即输出阻尼力和阻尼力可调范围进行了分析。结果表明,外加电流为2 A时,输出阻尼力可达59.4 kN,阻尼力可调范围由1增加到44.137 4。