An acoustic bending waveguide designed by anisotropic density-near-zero metamaterial

Anisotropic metamaterial with only one component of the mass density tensor near zero （ADNZ） is proposed to control the sound wave propagation. We find that such an anisotropic metamaterial can be used to realize perfect bending waveguides. According to a coordinate transformation, the surface waves on the input and output interfaces of the ADNZ metamaterial induces the sound energy flow to be redistributed and match smoothly with the propagating modes inside the metamaterial waveguide. According to the theory of bending waveguide, we realize the ＂T＂-type sound shunting and convergence, as well as acoustic channel selection by embedding small-sized defects. Numerical calculations are performed to confirm the above effects.

Numerical Simulation of Turbulent Flow of Hydraulic Oil through 90° Circular-sectional Bend

Oil flow through pipe bends is found in many engineering applications. However, up to now, the studies of oil flow field in the pipe bend appear to be relatively sparse, although the oil flow field and the associated losses of pipe bend are very important in practice. In this paper, the relationships between the turbulent flow of hydraulic oil in a bend and the Reynolds number Re and the curvature ratio δare studied by using computational fluid dynamics （CFD）. A particular emphasis is put on hydraulic oil, which differs from air or water, flowing through 90° circular-sectional bend, with the purpose of determining the turbulent flow characteristics as well as losses. Three turbulence models, namely, RNG κ-ε model, realizable k-ε model, and Reynolds stress model （RSM）, are used respectively. The simulation results in the form of contour and vector plots for all the three turbulence models for pipe bends having curvature ratio of δ=0.5, and the detailed pressure fields and total pressure losses for different Re and δ for RSM are presented. The RSM can predict the stronger secondary flow in the bend better than other models. As Re increases, the pressure gradient changes rapidly, and the pressure magnitude increases at inner and outer wall of the bend. When δ decreases, two transition points or transition zones of pressure gradient arise at inner wall, meanwhile, the transition point moves towards the inlet at outer wall of the bend. Owing to secondary flow, the total pressure loss factor k increases as the bend tightens, on the contrary, as Re increases, factor k decreases due to higher velocity heads, and the rapid change of pressure gradient on the surface of the bend leads to increasing of friction and separation effects, and magnified swirl intensity of secondary flow. A new mathematical model is proposed for predicting pressure loss in terms of Re and δ in order to provide support to the one-dimensional simulation software. The proposed research provides reference for the analysis of oil flow with higher Re in the large bends.

TWO-PHASE FLOW PATTERNS IN A 90° BEND AT MICROGRAVITY

Bends are widely used in pipelines carrying single-and two-phase fluids in both ground and space applications.In particular,they play more important role in space applications due to the extreme spatial constraints.In the present study,a set of experimental data of two-phase flow patterns and their transitions in a 90°bend with inner diameter of 12.7 mm and curvature radius of 76.5 mm at microgravity conditions are reported.Gas and liquid superficial velocities are found to range from (1.0～23.6)m/s for gas and(0.09～0.5)m/s for liquid,respectively.Three major flow patterns, namely slug,slug-annular transitional,and annular flows,are observed in this study.Focusing on the differences between flow patterns in bends and their counterparts in straight pipes,detailed analyses of their characteristics are made.The transitions between adjoining flow patterns are found to be more or less the same as those in straight pipes,and can be predicted using Weber number models satisfactorily. The reasons for such agreement are carefully examined.

The Effect of the Variation of the Downstream Region Distance and Butterfly Valve Angle on Flow Characteristics in a 90 Degree Bended Elbow

This study presents the numerical evaluation about the impact of flow disturbance near the intrados and extrados regions of the 90 degree bended elbow using CFX for several practical cases where the 90 degree bended upward elbow is located in a proximity to the butterfly valve and the butterfly valve open angle is changed. For the change of a butterfly valve open angle from 60% to 100% and the increase of the distance between a valve and a 90 degree bended elbow, the effect of FAC (Flow-Accelerated Corrosion) in the 90 degree bended elbow may be neglected because the value and distribution of the velocity and shear stress is rapidly decreased comparing with the present status installed in an industry, and the data of 100% valve open (Case 3) and L/D ≈ 5 (Case 4) are very good agreement comparing with the reference data, L/D ≈ 8 (Case 2). The reasons are that flow already maintains a fully developed condition and a steady state in spite of less distance than the reference case, L/D = 8. Therefore, smooth flow fields have approached at a 90 degree bended elbow. Then, the effect of shear stress and vortex is hardly investigated around the intrados area of 90 degree bended elbow.

Fluid−Structure Interaction of Two-Phase Flow Passing Through 90° Pipe Bend Under Slug Pattern Conditions

Numerical simulations of evolution characteristics of slug flow across a 90°pipe bend have been carried out to study the fluid−structure interaction response induced by internal slug flow.The two-phase flow patterns and turbulence were modelled by using the volume of fluid(VOF)model and the Realizable k−εturbulence model respectively.Firstly,validation of the CFD model was carried out and the desirable results were obtained.The different flow patterns and the time-average mean void fraction was coincident with the reported experimental data.Simulations of different cases of slug flow have been carried out to show the effects of superficial gas and liquid velocity on the evolution characteristics of slug flow.Then,a one-way coupled fluid-structure interaction framework was established to investigate the slug flow interaction with a 90°pipe bend under various superficial liquid and gas velocities.It was found that the maximum total deformation and equivalent stress increased with the increasing superficial gas velocity,while decreased with the increasing superficial liquid velocity.In addition,the total deformation and equivalent stress has obvious periodic fluctuation.Furthermore,the distribution position of maximum deformation and stress was related to the evolution of slug flow.With the increasing superficial gas velocity,the maximum total deformation was mainly located at the 90°pipe bend.But as the superficial liquid velocity increases,the maximum total deformation was mainly located in the horizontal pipe section.Consequently,the slug flow with higher superficial gas velocity will induce more serious cyclical impact on the 90°pipe bend.

Experimental and Numerical Study of Dilute Gas-Solid Flow inside a 90°Horizontal Square Pipe Bend

A pneumatic test rig is built to test a curved 90° square bend in an open-circuit horizontal-to-horizontal suction wind tunnel system. Sand particles are used to represent the solid phase with a wide range of particle diameters. Velocity profiles are constructed by measuring the gas velocity using a 3-hole probe. Flow patterns inside the bend duct are introduced using sparks caused by burning sticks of incense with the air flow inside the piping system for flow visualization purpose. Numerical calculations are performed by Lagrangian-particle tracking model for predicting particle trajectories of dispersed phase, and standard k-ε model for predicting the turbulent gas-solid flows in bends. Comparisons made between the theoretical results and experimental data for the velocity vectors and particle trajectories show good agreement.

Numerical Simulation of Single Bubble Deformation in Straight Duct and 90°Bend Using Lattice Boltzmann Method

The paper aims to give a comprehensive investigation of the two dimensional deformation of a single bubble in a straight duct and a 90° bend under the zero gravity condition. For this, the two phase flow lattice Boltzmann equation (LBE) model is used. An averaging scheme of boundary condition implementation has been applied and validated. A generalized deformation benchmark has been introduced. By presenting and analyzing the shape of the bubbles moving through the channels, the effects of the all important nondimensional numbers on the bubble deformation are examined thoroughly. It is seen that by increasing the Weber number the rate of the deformation enhances. Besides, because of the velocity dissimilarity between the particles constructing the bubble, the initial coordinates and the diameter of the bubble play a great role in the future behavior of the bubble. The density ratio has a little effect on the shape of the bubble within the assumed range of the density ratio. Moreover, as the Reynolds number or the viscosity ratio is decreased, higher rate of deformation is exhibited. Finally it is found that there is an inverse proportionality between the amplitude and frequency of the bubble deformation.

CVBEM and FVM Computational Model Comparison for Solving Ideal Fluid Flow in a 90-Degree Bend

While finite volume methodologies (FVM) have predominated in fluid flow computations, many flow problems, including groundwater models, would benefit from the use of boundary methods, such as the Complex Variable Boundary Element Method (CVBEM). However, to date, there has been no reporting of a comparison of computational results between the FVM and the CVBEM in the assessment of flow field characteristics. In this work, the CVBEM is used to develop a flow field vector outcome of ideal fluid flow in a 90-degree bend which is then compared to the computational results from a finite volume model of the same situation. The focus of the modelling comparison in the current work is flow field trajectory vectors of the fluid flow, with respect to vector magnitude and direction. Such a comparison is necessary to validate the development of flow field vectors from the CVBEM and is of interest to many engineering flow problems, specifically groundwater modelling. Comparison of the CVBEM and FVM flow field trajectory vectors for the target problem of ideal flow in a 90-degree bend shows good agreement between the considered methodologies.

工业弯管泄爆口位置对爆炸湍流的影响分析

为研究弯管泄爆对气体爆炸的影响,基于试验测试和数值模拟(FLACs软件)分析管道泄爆状态下湍流的变化规律。结果表明:在试验条件下,封闭管道弯管内4.8 m处监测点湍流动能峰值为5 745.42 m^(2)/s^(2),开口泄爆后该点湍流动能增幅为8.4%;当改变泄爆口位置时,弯道处监测点测得最大湍流动能相较于封闭管道该处最大湍流动能增幅为20.84%,弯管处湍流动能比直管最大增加了314%,影响因素主要为管道结构和泄爆口产生的排放和诱导作用;不同工况下内径0.125 m管道上泄爆口处最大湍流动能随着泄爆口位置和点火点之间的距离的增大而先增大后减小,二者的关系可拟合为一维高斯函数(Gauss Amp),拟合结果显示湍流动能最大为13 352.55m^(2)/s^(2),此时泄爆口的孔口效应和流量限制都增大了湍流强度,导致更快的爆炸气流流出速度及更高的气体燃烧率,冲出气流携带的能量较大,对周围设施的危害影响最大。

90°弯曲管道对丙烷-空气预混火焰传播的影响

为了揭示90°弯曲管道结构对预混火焰传播特性的影响,以丙烷-空气预混火焰为研究对象,运用高速纹影摄像、微细热电偶以及离子探针等测试手段对火焰在90°弯曲管道内的传播过程进行了实验研究.结果表明,预混火焰结构在水平管道内发生了明显变化,由规则的球形层流火焰转变为具有轴对称结构向内凹陷的湍流火焰,并伴随火焰阵面的皱褶分层.火焰进入90°弯曲管道后,受几何形状影响,火焰阵面发生畸变,对称结构被破坏,下壁面处的火焰阵面逐渐超过上壁面处的火焰阵面.由于弯管内部多波叠加作用以及湍流的影响最终使得火焰速度呈现脉动振荡.

可燃气体非稳定爆轰波通过90°圆弯管传播特性的实验研究

对丙烷-氧气-空气的混合气体非稳定爆轰波通过90°圆弯管传播特性的变化进行了初步的实验研究.同时实验研究了预混气体的初始浓度和初始压力对非稳定爆轰波经过弯管前后传播特性的影响.实验结果表明,可燃气体非稳定爆轰波经过90°圆弯管后传播速度和压力与直管中相比有了显著地提高.这一研究结果对于工业上安全使用管道阻火器具有重要的实际意义.

90°方形弯管内部流场PIV试验

为了揭示不同进口流速情况下90°方形弯管内部流动特征,在构建90°方形弯管专用PIV试验台的基础之上,对弯管内不同断面以及不同半径上的流速分布情况进行了PIV测试试验。试验结果表明:采用PIV技术能较好地获得弯管内部流动情况;流体未进入弯曲段时,各断面流速分布变化不大;而进入弯曲段后,由于受到弯管壁的约束形成旋转流动,弯管内侧流速增大,外侧流速降低;当转过60°位置后,弯管内侧流速降低,外侧流速增加;到达90°位置后,各断面的流速基本趋于一致。不同半径处的流速分布不相同,弯管内侧流速较大,外侧较小,在50°、60°处流速达到最大值;弯管不同的进口流速对于速度峰值的位置有一定的影响,而对于弯管内其他的流动情况影响较小。

90°弯管内流体流动特点数值模拟

采用标准k-ε模型对90°弯管内部流场进行了三维数值模拟研究。模拟中弯管曲率半径与管径之比β=R/d分别为2.0、2.5、3.0和3.5,表观液速为0.5m/s。通过建模和数值计算,研究了弯管内流场分布、压力分布以及速度矢量和流动轨迹等规律,并重点分析了不同β情况下的弯管中流场流动特点。结果表明:流体速度在弯管内不同截面内是逐渐变化的。由于离心力的作用,在流动后段出现二次流,加强了流体的扰动。同时,流体进入弯道后管道内部不同半径处压力不同,弯管内壁面附近处压力较小,弯管外壁面处压力较大。不同曲率半径与直径之比对管内流速分布有较大影响。β由小增大时,内侧流速逐渐变小,实际的管道设计与施工中尽量使用β较大的弯头附件以降低对管道内壁的冲击。

不同重力下90°弯管内气液两相流流型及流动特性研究

研究了不同重力条件下90°弯管内气液两相流流型分布形态及流动特性.通过建立90°弯管内气液两相流流动的三维数学物理模型,采用VOF方法,对10-6g0,10-4g0,10-2g0,1g0(g0=9.8 m/s2)重力下的90°弯管内气液两相流流型分布特征、截面空隙率、滑速比及气相尾部最大斜向角进行了比较分析.研究结果表明:所建立的模型能够正确模拟不同重力条件下90°弯管内气液两相流流型和截面空隙率,并得到气液两相弯管二次流与单相二次流的不同特性.随着重力水平的提高,90°弯管对气相流型的影响作用减弱,气相整体向弯管内侧积聚靠拢,弯管对尾部的斜向作用减弱.

大口径90°弯管内三维水力特性数值模拟研究

采用fluent软件,选择标准k-ε紊流模型对大口径90°竖直弯管内的流动进行了三维数值模拟。在上游水箱断面自编程序使用了水位边界条件,对4种恒压水头下的上游竖管、弯管、下游水平管内的速度场和压力场进行计算,得到各水头下弯管内二次流动现象(迪恩涡)。对比相同水头下网格疏密性对二次流计算的差异,分析了弯管管道内的压力场、速度场的分布规律和各水头下弯管不同角度内外壁面的空化数。结果表明:疏密网格均能模拟出迪恩涡,但计算精度偏差值较大;各工况下空化数最低值均在10°截面上的内壁面出现,但均大于工程要求的0.3;各工况下,弯管内压强和速度变化规律相似,弯管段内壁压强均低于外壁压强,该压差维持着弯管内的二次流动。

90°方形通风弯头内颗粒物沉积的模拟研究

采用拉格朗日随机轨道模型,模拟追踪了不同送风速度下粒径1～100μm的颗粒在90°方形通风弯头内的运动轨迹.考虑了弯头尺寸、湍流强度以及壁面粗糙度等因素对沉积率的影响,结果表明:当处于紊流过渡区(5<K+<30)时,壁面粗糙度对颗粒沉积率有明显的影响,沉积率随着Stk数和弯曲比的增大而不断增大,且弯曲比为4的弯头比较利于颗粒的输运.

90°弯管气固两相流磨损研究

天然气在管道输送过程中,夹带的微小固体颗粒会对管道产生冲蚀磨损,进而引发管道失效。利用计算流体力学(CFD)软件能够模拟管内气固两相流流动预测壁面磨损量,但过往的(模拟)研究未能区分出磨损的不同阶段,仅采用单一的冲蚀磨损量预测模型。为此利用气固两相流流场结果,通过分界角β将磨损过程分为两个阶段:颗粒对壁面的冲击与颗粒对壁面的滑动或滚动。并将上述两个阶段采用不同的磨损量预测模型(Tulsa模型与疲劳磨损模型)作为用户自定义函数(UDF)加入计算软件中。计算结果表明:磨损量随着颗粒直径、颗粒密度、气体流速、弯径比的增加而增加。磨损量随不同影响因素的变化趋势,与分界角的变化趋势相似,证明了分界角是一个能综合评价弯管冲蚀磨损特征的参数。利用拉格朗日法分析了颗粒的碰撞特征,结果表明:二次碰撞位置更加靠近弯管出口,极易位于弯管焊缝的热影响区内,磨损情况将会加剧,甚至加速焊缝热影响区内的微裂纹扩展。

稀相气固两相流90°圆截面弯管流动特性

针对工业中常见的圆截面90°弯管中的稀相气固两相流的流动特征难于观测,以及由此造成的对其流动特性缺乏认识的问题,以天津大学的气固装置具备的实验条件为基础,以压力测量值作为模型有效性的评价依据,建立了适用于圆截面管道的计算流体力学(Computational Fluid Dynamics,CFD)模型。针对FLUENT中通过定义反射系数设置颗粒-壁面碰撞关系不能反映实际过程的问题,建立了考虑颗粒与壁面接触过程中的不同运动状态的颗粒一壁面碰撞模型,并引入计算。以此为基础,对不同固气质量比、流量和管道曲率情况下的流动特性进行了研究。发现:两相流体在流经90°弯管后,速度分布的恢复长度与固气质量比、管道曲率半径等有密切关系,曲率半径为2的管道整体压损最小,过小或过大均会导致较大压损,与Mason弯管磨损试验的结论规律相近。

微重力条件下90°弯管气液两相流型研究

本文报道了微重力条件下90°弯管内气液两相流型实验结果。弯管内径12.7 mm,弯曲半径76.5mm,气、 液两相表观流速分别为1.0—23.6 m/s和0.09—0.5 m/s。本文分析了观测到的弹状流、弹-环过渡流和环状流的典型特 征,比较了与微重力直管内相应流型间及常重力弯管两相流型间的异同。

90°弯管存在下的供水管道泄漏定位研究

90°弯管的存在会影响管道泄漏检测定位的性能,针对金属材质的管道,基于ANSYS平台分别以泄漏管和90°弯管为研究对象,利用数值方法对管道的流致振动进行计算和分析,在此基础上提出一种结合经验模态分解(Empirical Mode Decomposition,EMD)和样本熵的噪声抑制方法去除管道泄漏检测信号中的弯管噪声,以提高泄漏检测定位的精度。仿真分析及实验结果表明,EMD和样本熵结合去噪的方法能很好地抑制弯管噪声。