Finite element analysis of fluid-structure interaction in buried liquid-conveying pipeline

Long distance buried liquid-conveying pipeline is inevitable to cross faults and under earthquake action,it is necessary to calculate fluid-structure interaction(FSI) in finite element analysis under pipe-soil interaction.Under multi-action of site,fault movement and earthquake,finite element model of buried liquid-conveying pipeline for the calculation of fluid structure interaction was constructed through combinative application of ADINA-parasolid and ADINA-native modeling methods,and the direct computing method of two-way fluid-structure coupling was introduced.The methods of solid and fluid modeling were analyzed,pipe-soil friction was defined in solid model,and special flow assumption and fluid structure interface condition were defined in fluid model.Earthquake load,gravity and displacement of fault movement were applied,also model preferences.Finite element research on the damage of buried liquid-conveying pipeline was carried out through computing fluid-structure coupling.The influences of pipe-soil friction coefficient,fault-pipe angle,and liquid density on axial stress of pipeline were analyzed,and optimum parameters were proposed for the protection of buried liquid-conveying pipeline.

An explicit finite element method for dynamic analysis in three-medium coupling system and its application

In this paper, an explicit finite element method to analyze the dynamic responses of three-medium coupled systems with any terrain is developed on the basis of the numerical simulation of the continuous conditions on the bounda-ries among fluid saturated porous medium, elastic single-phase medium and ideal fluid medium. This method is a very effective one with the characteristic of high calculating speed and small memory needed because the formulae for this explicit finite element method have the characteristic of decoupling, and which does not need to solve sys-tem of linear equations. The method is applied to analyze the dynamic response of a reservoir with considering the dynamic interactions among water, dam, sediment and basement rock. The vertical displacement at the top point of the dam is calculated and some conclusions are given.

NUMERICAL SIMULATION OF COUPLED STRUCTURAL- ACOUSTIC PROBLEMS USING FEM/IBEM

The numerical method of a coupled finite element and indirect boundary element equation for computing both the structural vibration and the acoustic radiation was presented. The coupling matrices were discussed and physical degrees of freedom of the structure were treated in terms of its modal basis in vacuum to decouple the computation from the entire coupled structural acoustic equations. The numerical results for the ellipsoidal shell immersed in two different fluids indicate that heavy fluid changes greatly structural and acoustic behavior. This method can be applied to analyze acoustic and vibration for arbitrary complex structures in fluids.

Methodology for Comparing Coupling Algorithms for Fluid-Structure Interaction Problems

The multi-physics simulation of coupled fluid-structure interaction problems, with disjoint fluid and solid domains, requires one to choose a method for enforcing the fluid-structure coupling at the interface between solid and fluid. While it is common knowledge that the choice of coupling technique can be very problem dependent, there exists no satisfactory coupling comparison methodology that allows for conclusions to be drawn with respect to the comparison of computational cost and solution accuracy for a given scenario. In this work, we develop a computational framework where all aspects of the computation can be held constant, save for the method in which the coupled nature of the fluid-structure equations is enforced. To enable a fair comparison of coupling methods, all simulations presented in this work are implemented within a single numerical framework within the deal.ii [1] finite element library. We have chosen the two-dimensional benchmark test problem of Turek and Hron [2] as an example to examine the relative accuracy of the coupling methods studied;however, the comparison technique is equally applicable to more complex problems. We show that for the specific case considered herein the monolithic approach outperforms partitioned and quasi-direct methods;however, this result is problem dependent and we discuss computational and modeling aspects which may affect other comparison studies.

RESEARCH ON SOLID-LIQUID COUPLING DYNAMICSOF PIPE CONVEYING FLUID

On the basis of Hamilton principle. the equation of sonlid-liquid coupling vibration of pipe conveying fluid is deduced. An asymmetrical sonlid-liquid coupling damp matrix and a symmetrical solid-liquid coupling Stiffness matrix are obtained. Using QR method , pipe’s nature frequencies are calculated. The curves of the first four orders of natural frequency-flow velocity of pipe waw given .The influence of flowing velocity ,pressure, solid-liquid coupling damp and solid-liquid coupling stiffness on natural frequency are discussed respectively.The dynamic respondence of the pipes for stepload with different flow velocity are calculated by Newmark method .It is found that,with the flow velocity increased, the nature frequency of the pipes reduced, increased,reduced again and so on.

水压与动载耦合作用下高铁隧底结构裂损机理分析

高速铁路隧道底部结构隆起变形开裂是多方面影响因素叠加作用的结果。综合利用扩展有限元方法、流固耦合理论和现场实测结果,采用激振力荷载拟合函数施加于轨面模拟列车振动荷载作用效果,分析在水压和列车动荷载耦合作用下的高铁隧道底部结构不协调变形机理,揭示水压与动荷载作用下隧道底部结构的变形特征与水压力变化规律。研究结果表明:在既有隧底结构型式与排水条件下,水压变化是隧道底部结构变形与开裂的诱发原因,列车动荷载导致的裂缝水压交替变化是隧道底部结构持续性隆起裂损的间接原因。隧道底部结构开裂一般首先发生在仰拱填充层中央排水沟处,然后在轨道板、仰拱填充层与衬砌仰拱结构存在刚度差异的各交界面上出现裂缝。高速列车动荷载周期性的上下振动与水压力耦合作用下隧道底部结构界面和各裂缝过水处产生超静水压力,其周期性抽吸变化将对裂缝产生水力压裂效应,加剧隧道底部结构的裂损。高水压高铁隧道底部结构隆起开裂的整治措施应综合考虑泄水降压、裂缝封堵以及底部多层结构体系的层间锚固。

建立基于浸入边界有限元法的三维静脉瓣流固耦合数值模型

目的 探究静脉内血液与瓣膜之间的流固耦合动态过程和保证血液单向回流的生理机制。方法 基于浸入边界有限元法,结合人体下肢静脉医学图像及牛大隐静脉的解剖结构和尺寸,采用超弹性本构模型描述静脉瓣膜在生理条件下不可压缩、非线性和超弹性力学响应,构建静脉血管和静脉瓣膜的三维数值模型。结果 研究结果可视化地展示静脉动态运输血液的过程以及静脉瓣膜防止反流的功能机制,再现静脉内瓣膜运动和血液流动的周期性特点,讨论和量化了整个心动周期内的重要生理数据,包括静脉内血液的压力、流速和流量以及静脉瓣膜的开口面积、静脉瓣膜表面的应力和应变分布等。结论 三维流固耦合模型可数值再现静脉内生理动态过程,为进一步揭示静脉疾病相关机制提供重要的参考和指导意义。

二尖瓣运动的流固耦合仿真

目的 建立包含左心和血液的二尖瓣理想模型,用流固耦合仿真研究二尖瓣在血流中的运动特性。方法 基于解剖学参数建立二尖瓣、左心和血液模型,流固耦合仿真采用有限元结合浸没边界法,使用有限元软件LS-DYNA模拟二尖瓣运动,获取形态学、力学和血液动力学参数,并与结构仿真结果进行对比。结果 两种仿真下二尖瓣形态学结果差异较大,流固耦合结果与超声影像吻合。流固耦合仿真和结构仿真的瓣叶应力分布结果一致,最大第一主应力分别为1.48、1.53 MPa,相对误差为3.27%。左心流场有较为复杂的涡旋结构,舒张期二尖瓣最大流速为1.02 m/s,与健康人体生理数据(0.89±0.15) m/s相吻合。结论 二尖瓣流固耦合仿真可以获取更贴近于生理的形态学结果;流固耦合仿真可以提供临床诊断不可或缺的流场参数信息;单研究瓣叶应力分布问题时,结构仿真更高效。

海流作用下坠物沉降及撞击海底管道数值模拟研究

采用基于浸入边界有限元法的流固耦合数值模拟方法,对海流作用下坠物撞击海底管道完整过程进行了数值模拟研究。数值结果表明:在自由沉降时,坠物的流向速度与海流速度基本一致,不同海流速度下相同质量的坠物垂向速度基本一致,但在较低的坠物质量和海流速度下会出现冲跃现象,球形坠物的垂向阻力系数比立方形坠物小,并且阻力系数随坠物质量的变化而变化,坠物沉降角度随海流速度的增加而增大;在坠物接近海底管道时,流向速度逐渐减小,垂向速度均为先增大后减小,立方形坠物减小程度要比球形坠物大,质量大的坠物垂向速度减小的程度也要比质量小的大;在坠物撞击管道时,球形坠物撞击速度比立方形大,撞击速度比自由沉降速度大,撞击角度比自由沉降角度小,最大应力和凹痕均比无海流作用时小,球形坠物应力减小幅度为4.44%~16.71%,立方形坠物应力减小幅度为9.29%~12.14%,球形坠物凹痕减小幅度为4.17%~30.58%,立方形坠物凹痕减小幅度为10.41%~14.44%。

大变幅加卸载下特厚煤层底板断层突水机理模拟研究

特厚煤层采场空间大、扰动范围广,强烈大变幅荷载易导致底板断层破裂加剧并诱发水害。数值模拟是揭示特厚煤层底板断层活化与突水机理的重要方法,准确反映大变幅加卸载下岩体破裂与裂隙水耦合特征是其合理性的关键。构建损伤变量与塑性应变、应力之间的相关关系,得到完整岩块的拉、加压卸载损伤演化方程;以平方拉剪应力与Benzeggagh-Kenane为初始、完全断裂准则,建立塑性位移与强度劣化关系,建立加卸载韧性断裂本构关系;基于实验数据建立贯通裂隙加卸载剪切本构关系。以基本方程与状态方程为基础,结合浸没边界方法,形成裂隙岩体水力学模拟理论。由此编制流体动力学-有限离散元CFD-FDEM耦合程序,模拟研究特厚煤层底板断层活化突水过程。结果表明:CFD-FDEM耦合程序可数值实现特厚煤层底板断层从(准)连续体到离散体转化,以及断层带裂隙水运移过程。底板断层采动破坏包络线呈W形,最深位于断层及其上盘(48.6m),最浅位于断层下盘(23m)。特厚煤层采场底板断层及其上盘受到较大超前集中应力,而后在采空区内大幅卸载,导致该位置出现显著二次破坏,并形成主要导水通道。研究成果为特厚煤层工作面底板断层水害防治提供理论支撑。

盾构机主轴承润滑特性影响因素研究

盾构机主轴承作为一种大型重载机械,其工作环境恶劣,轴承损坏会造成极大的经济损失,为了保证较高的可靠性,其润滑性能极为关键。采用Fluent对轴承进行流固耦合模型的建模仿真,研究轴承转速、负载、润滑油黏度、润滑油流量和润滑方式对轴承温升影响。结果表明:润滑油分布少的区域温度较高;盾构机主轴承的转速是影响温升最关键的因素,温升随着转速的增大而急剧增大;轴承温升随着负载的增加而增加;润滑油在黏度等级为320附近的温度最低;不同转速下流量对轴承温升的影响不同,转速低时,温升随着流量增大先减小后增大,转速高时反之;通过仿真将类似于油气原理的润滑方法应用在盾构机主轴承的润滑上改善了润滑状态。

基于双向流固耦合的旋翼振动响应及噪声仿真分析

为精确预估流固耦合效应对旋翼桨叶振动响应及噪声计算的影响,本文建立了计算流体力学(Computational fluid dynamics,CFD)模型和高精度结构有限元模型,基于弱流固耦合方法完成了旋翼单向及双向流固耦合计算,并采用基于Kirchhoff方法对FW⁃H方程进行求解,分析了旋翼近场旋转噪声。首先,基于地面模态分析试验对桨叶结构有限元模型进行高精度建模,同时完成旋翼旋转状态的CFD计算,并采用两种网格映射方式和四点插值法进行流场与结构的数据传递,完成了旋翼单向稳态及单向瞬态流固耦合分析。然后采用双向弱流固耦合方法计算结构动响应及非定常流场,分析比较单、双向流固耦合计算方法下桨叶振动响应的差异。最后,基于单、双向流固耦合计算得到桨叶表面的时变气动压强,计算旋翼旋转噪声,分析比较单、双向流固耦合计算方法的旋转噪声大小及分布特征。结果表明,文中基于高精度桨叶模型及双向流固耦合方法计算出的桨叶动响应及噪声分布符合悬停旋转噪声规律,可为未来桨叶结构设计、强度校核及噪声预估提供参考。

多级水力压裂应力阴影效应的数值分析

多级水力压裂作为储层改造的主要技术手段,广泛用于提高致密油气藏的气体产量。裂缝在扩展过程中的应力阴影效应对于有效连通储层的天然裂缝并形成有利于油、气体流动的复杂裂缝网络至关重要。本研究采用了自适应的有限元-离散元方法,通过改进网格自动细化和识别多个裂缝扩展模拟含天然裂缝储层的多级水力压裂。数值模型中考虑了水力裂缝、天然裂缝和微观孔隙结构的相互作用,整合了非线性的Carter滤失模型来描述多级压裂过程中压裂液的滤失效应。引入了理想平行板流的支撑剂运输方程,并采用了达西定律来分析裂缝网络中的流体渗透效应。通过比较无裂缝均质模型和天然裂缝模型的裂缝网络和流体流动,评估了天然裂缝对多级压裂裂缝行为和气体产量的影响。研究为确定和优化致密气藏中压裂簇间距提供了一种新的方法。

不同温度LBE对主容器振动特性的影响分析

采用流固耦合的方法,利用ANSYS软件对铅基快堆主容器在空气中和不同温度铅铋共晶(Lead-BismuthEutectic,LBE)介质中的振动特性进行了研究。主容器采用实体建模,铅铋共晶介质流体采用FLUID30单元进行模拟,考虑铅铋共晶介质附加质量对主容器振动特性的影响。计算结果表明,主容器在空气中的两种模型前六阶模态均为一阶梁式振型以及低阶壳式振型。由于两种模型约束条件的差异,振型出现的顺序有所不同。铅铋共晶环境中的前六阶振型与空气中相比,没有出现更高阶的振型,但由于附加质量的影响,其各阶频率计算值大幅下降,下降幅度在80%左右,同时伴随着振型互换的现象出现;随着温度的升高,主容器的各阶振型频率均呈现降低的趋势,当温度从150℃上升至390℃时,频率降低大约27.3%。

关于阀门流固耦合仿真模拟的研究综述

阀门作为流体输送系统中的核心控制元件,其性能的优劣直接关系到整个流体系统的运行安全、稳定性和效率。随着计算机硬件技术的迅猛进步和数值计算方法的不断创新,流固耦合仿真模拟技术在近年来取得了显著的发展,为阀门的设计优化和性能提升提供了强大的理论支持和实践指导。本文旨在全面梳理和深入剖析当前阀门流固耦合仿真模拟领域的研究成果,系统阐述理论基础,详细介绍仿真模拟的关键技术环节。同时,通过实际案例的分析,总结流固耦合仿真模拟的应用以及存在的问题。最后,对未来的发展趋势进行展望。

某轨道车辆箱体结构强度仿真分析

本文以某轨道车辆箱体为研究对象,基于有限元理论及流固耦合理论对箱体进行静强度分析、疲劳分析和基于流固耦合的-冲击响应分析,根据计算应力及箱体变形对箱体整体结构强度进行评价及分析。

Transient Hydroelastic Response of VLFS by FEM with Impedance Boundary Conditions in Time Domain

A time-dependent finite element method (FEM) is developed to analyze the transient hydroelastic responses of very large floating structures (VLFS) subjected to dynamic loads. The hydrodynamic problem is formulated based on the linear theory of fluid and the structural response is analyzed based on the thin plate theory. The FEM truncates the unbounded fluid domain by introducing an artificial boundary surface, thus defining a finite computational domain. At this boundary surface an impedance boundary conditions are applied so that no wave reflections occur. In the proposed scheme, all of the procedures are processed directly in time domain, which is efficient for nonlinear analyses of structure floating on unbounded fluid. Numerical results indicate acceptable accuracy of the proposed method.

径向井立体压裂裂缝扩展数值模拟

基于有限元-无网格法,考虑压裂液流动与岩石基质变形的耦合作用,建立了径向井压裂裂缝扩展数值模型,模拟了径向井压裂裂缝形态,定量表征了径向井对裂缝的诱导作用,揭示了方位夹角、水平主应力差与岩石基质渗透率等对裂缝形态演化的影响机制。研究表明,同层双分支径向井压裂时径向井间存在挤压作用,当径向井沿最小水平主应力方向对称分布且方位夹角大于15°时,挤压作用减小了径向井的裂缝引导长度,当径向井沿最大水平主应力方向对称分布时,挤压作用增大了径向井的裂缝引导长度。裂缝形态由径向井的纠偏作用、径向井间的挤压作用与最大水平主应力的偏转作用共同控制。当径向井沿最小水平主应力方向对称分布时,径向井的裂缝引导长度随着方位夹角的增大逐渐减小,当径向井沿最大水平主应力方向对称分布时,径向井的裂缝引导长度随着方位夹角的增大先减小后增大。径向井的裂缝引导长度随水平主应力差的增大而减小。岩石基质渗透率增大,径向井周围基质的孔隙压力增大,对裂缝的诱导作用增强。

基于流固耦合的骨架膜结构优化

为了实现骨架膜结构的优化设计,基于ANSYS平台考虑了膜结构在风荷载作用下的结构变形对建筑表面风压分布的影响,采用双向流固弱耦合的方法对某低矮类膜建筑在不同风向角下的定常风场特性与其围护骨架膜结构的风致结构受力进行了研究,并以此为依据采用响应面法对骨架膜结构中各杆件的截面尺寸进行了优化.结果表明:仿真所得建筑表面风压分布与同类模型风压实测数据、风洞试验数据以及国家相应规范吻合较好;不同风向角下骨架膜结构的受力状态不同,其中90°风向为该结构的最不利工况;采用响应面法得到了该骨架膜结构中各杆件的截面尺寸对结构受力的影响关系,并将该结构整体质量降低了14.73%.

基于流固耦合的弧形闸门-闸墩体系的流激振动研究

实际工程中弧形闸门与闸墩联系紧密,在水流脉动压力下二者相互影响,形成一个体系。为了揭示闸门与闸墩的相互影响规律,采取流固耦合理论对弧形闸门-闸墩体系开展流激振动研究。以某水利工程弧形工作闸门为例,针对弧形闸门单体和弧形闸门-闸墩体系分别建立三维有限元模型,计算两种模型的自振频率,基于模态分析的结果对两种模型进行动力响应分析,总结闸门和闸墩在动力特性和流激振动响应方面的相互影响规律。结果表明:闸墩对闸门动力特性及动力响应具有较大影响,考虑闸墩影响时,弧形闸门自振频率下降,其中以支臂振动为主的第4阶自振频率下降幅度最大,为61.45%,面板及支臂顺河向动位移分别减小44.58%及增大37.93%,面板及支臂动应力分别下降41.70%及增加30.71%;闸门流激振动对闸墩应力有显著影响,相较于闸墩按动力系数计算的最大应力增大了4.713 MPa。采用弧形闸门-闸墩体系模型可以更加准确而全面地评估弧形闸门及闸墩在流激振动下的安全特性。