狭窄通道红细胞跨膜传质特性数值分析

随着对血液微流动过程的不断探索,红细胞在微通道中的运动微观特性备受关注,利用流体力学特性的低损伤手段调控细胞体积并完成跨膜传药也逐渐成为研究热点.为了分析红细胞在微通道中的传质和力学特性及其影响因素,采用浸入式边界法研究细胞穿越狭窄通道的整个运动过程,并考虑细胞膜表面透水传质效应,完成细胞跨膜传质过程的数值建模,实现对狭窄通道中红细胞跨膜传质过程微观的传质特性数值分析.研究表明,细胞在挤入、排出狭缝的运动过程中,体积先损失、后恢复,在这个过程中,细胞头部和尾部以向外的渗透流出为主,中间部位则以向内的渗透流入为主.文章的研究进一步表明,狭缝挤压过程中的体积净变化是由向内和向外渗透速度的大小差异引起的,而与向内和向外渗透的膜面积差异并无明显关系.对体积变化的影响因素探究后发现,更狭窄的通道和更大的入口出口角均会引起细胞发生更多的体积损失和体积恢复,且出口角的变化会引起细胞体积恢复后所达到的体积稳定值:在固定入口角时,狭缝出口角越大,细胞离开狭缝后的稳定体积越小;细胞的硬度越大、细胞膜通透性(渗透系数)越大,细胞在狭缝中运动过程中的体积损失和体积恢复程度越高.

大型薄壁输水渡槽流固耦合振动台试验研究

地震高烈度区大型高架渡槽的抗震安全是我国西南地区长距离调水工程建设及运行过程中难以回避的重大挑战。渡槽结构与槽内水体动力相互作用是地震响应分析及安全评价的关键问题。目前使用较多的将水体以附加质量方式计入其对结构动力响应影响的方法是基于刚性壁与流体相互作用假定下推导建立的。大型渡槽多为薄壁结构,柔性结构与水体间的动力相互作用与刚性壁假定存在明显的不同。本研究采用几何比尺1/10的大型薄壁渡槽物理模型,通过振动台试验研究渡槽与水体的动力相互作用。通过深入分析稳态白噪声激励和11组双方向地震波激励下渡槽结构的动态响应,确定大型薄壁渡槽中水体对结构自振频率及渡槽两端支座力产生的重要影响,并给出了试验对象渡槽结构槽内水体与渡槽动态相互作用的等价质量定量关系。为实际工程抗震设计准确分析评价渡槽抗震安全提供可靠依据。

Zonal Coupling Analysis Method of Seismic Response of Offshore Monopile Wind Turbine

The seismic safety of offshore wind turbines is an important issue that needs to be solved urgently.Based on a unified computing framework,this paper develops a set of seawater-seabed-wind turbine zoning coupling analysis methods.A 5 MW wind turbine and a site analysis model are established,and a seismic wave is selected to analyze the changes in the seismic response of offshore monopile wind turbines under the change of seawater depth,seabed wave velocity and seismic wave incidence angle.The analysis results show that when the seawater increases to a certain depth,the seismic response of the wind turbine increases.The shear wave velocity of the seabed affects the bending moment and displacement at the bottom of the tower.When the angle of incidence increases,the vertical displacement and the acceleration of the top of the tower increase in varying degrees.

横向受迫振荡圆柱低雷诺数绕流问题数值模拟

对雷诺数Re=200的圆柱在均匀来流中横向受迫振荡的问题进行数值模拟分析。通过改变运动圆柱的振荡频率和振幅,分析圆柱所受作用力及圆柱尾流泻涡结构的变化特性,振荡圆柱在非锁定状态和锁定状态下作用力曲线和圆柱尾流泻涡结构的变化情况,以及不同圆柱振荡频率和振幅情况下单个振荡周期内圆柱尾流泻涡结构模式之间的转换特征。

湿度应力场理论的证明

在某些工作环境下,多孔介质中流体同固体骨架之间可能发生复杂的物理化学相互作用,吸附就是各种相互作用的表观现象之一。各种相互作用都伴随能量的转化或转移。吸附引起的固体骨架的膨胀是由于固体和流体之间复杂的能量转化或转移引起的,在此认识基础上,从热力学第一定律和建立本构方程的一般方法出发,将湿度(吸附量)当作系统的状态变量,对缪协兴提出的湿度应力场理论作了严格证明,并详细分析了该理论模型的适用条件及其力学意义。认为湿度应力场本构模型同经典弹性本构模型一样,确定了一种理想物质模型,它也只是实际材料本构关系的一种理想化。

基于大涡模拟改进的移动粒子半隐式法模拟平底结构的入水冲击及破坏问题（英文）

移动粒子半隐式方法(MPS)在解决船舶入水冲击和结构大变形等不连续性问题上具有非常明显的优势.大涡模拟(LES)是近十多年来发展起来的研究湍流运动的一种重要手段,本文采用MPS-LES方法模拟平底结构入水冲击的流固耦合问题,并将该数值模拟的结果与实验结果做了对比分析.模拟研究了设置不同的肋板结构对平底结构冲击变形的影响.最后,根据该方法的粒子特性,模拟平底结构大变形破坏现象,为下一步模拟更加复杂的船体结构破坏问题做了理论探索.

基于OpenFOAM重力式采样器自由下落姿态数值分析

为了提高深水重力式沉积物采样器在海流、缆绳等外力作用下的采样效率,基于Open FOAM程序并通过动态重叠网格方法,模拟静水中采样器在触底前较大范围内自由下落时的姿态。首先构建采样器与流体相互作用三维时域耦合计算模型,并采用Newmark法对结构在流场中的运动方程进行迭代求解;验证网格收敛性,分别对初始倾角为0°和5°的采样器自由下落姿态进行时域模拟,分析下落距离、下落速度以及采样器偏转角之间的相互关系并研究采样器的偏转角对取样效率的影响。研究结果表明:本文构建的结构与流体相互作用的三维时域计算模型可以精确模拟采样器自由下落姿态;采样器的初始偏转角对采样器下落姿态以及取样效率均有较大影响。

二维重力式采样器触地姿态及采样率分析

为了提高深水重力式沉积物采样器的采样效率,本文基于OpenFOAM程序并通过动态重叠网格方法,模拟静水中采样器触底前较大范围自由下落时的姿态。通过计算球体自由下落并与文献结果对比,验证了方法的准确性和可行性。构建了采样器与流体相互作用二维时域耦合计算模型,分别对0°、5°、8°初始倾角的采样器自由下落姿态进行时域模拟,分析下落距离、下落速度以及采样器偏转角之间的相互关系。最终讨论了采样器的偏转角对取样效率的影响。研究结果表明:采样器的初始偏转角对下落姿态以及取样效率均有较大影响,所得数据及结论可为实际海测提供指导。

固壁上液滴动力学的LBM建模与计算

本文采用Shan-Chen多相格子Boltzmann方法建立液滴在固壁上的动力学模型。并根据该模型模拟了液滴在水平固壁上的铺展行为以及在垂直固壁上的滑移行为。

Analysis of ink flow channel between two rotating ink rollers

In order to research how the size of the ink flow channel is affected by the interaction of adjacent ink areas,according to the method of fluid-solid interaction,this paper analyzes the size of the ink flow channel of two ink rollers' rotation.Firstly,this paper simulates the situation of only one ink area.Secondly,this paper simulates the situation of five adjacent ink areas.Then,through comparing the simulation results of two above situations,it' s obvious that the interaction of adjacent ink areas has big effects on the ink pressure and the size of ink flow channel.At last,this paper gets the main factor that affects the size of ink flow channel in the different situations.

Changes in Coupled Vibration Frequencies and Modes of Wall-Cavity Systems Induced by Stiffness Variation in the Structure

Problems of fluid structure interactions are governed by a set of fundamental parameters. This work aims at showing through simple examples the changes in natural vibration frequencies and mode shapes for wall-cavity systems when the structural rigidity is modified. Numerical results are constructed using ANSYS software with triangular finite elements for both the fluid （2D acoustic elements） and the solid （plane stress） domains. These former results are compared to proposed analytical expressions, showing an alternative benchmark tool for the analyst. Very rigid wall structures imply in frequencies and mode shapes almost identical to those achieved for an acoustic cavity with Neumann boundary condition at the interface. In this case, the wall behaves as rigid and fluid-structure system mode shapes are similar to those achieved for the uncoupled reservoir case.

晶格Boltzmann方法中流体力的计算

晶格Boltzmann方法是起源于动理学理论和元胞自动机的介观数值模拟方法,在模拟复杂流体运动,特别是颗粒悬浮运动和多相流等领域取得了显著的成功.在计算流体与结构之间的相互作用力时,通过引入相对速度,提出了伽利略不变的动量交换法.该方法简单、精确、高效,而且与边界的几何形状无关;它只使用局部数据,方便实施并行计算和三维模拟;它具有良好的稳定性,流体力计算结果的波动非常小,甚至不需要进行时间平滑处理.在数值模拟多相流的研究中,基于热力学自由能理论计算非理想力,提出了同时满足热力学一致性和伽利略不变性的多相流模型.该模型物理清晰、易于实施,可以方便地配合不同的状态方程用于模拟各种多相流系统.化学势是驱动相分离和表达润湿性的有效途径,在进一步的研究中,借助化学势计算非理想力,提出了基于化学势的多相流模型.它在数学上等价于基于压力张量计算非理想力的模型,但是避免了计算压力张量和张量散度,获得了更高的计算效率.该模型配合化学势边界条件,可以有效地模拟润湿现象,其接触角可以通过表面化学势进行线性调节.

混流式水轮机转轮的模态分析和裂纹扩展寿命的估计

透平机械运行时，叶片受到载荷作用可以产生振动、疲劳、断裂，因而影响机械的完整性。混流式水轮机的转轮在叶片和上冠连接处曾出现裂纹。本文介绍了混流式水轮机转轮的模态分析和裂纹扩展的寿命分析。首先，介绍了转轮在空气和水中的模态分析，计算了在这两种情况时的固有频率和模态振型。转轮在水中时考虑了流固相互作用的附加质量效应。其次，依照寿命估计的要求计算了静应力和动应力。对于静应力计算，转轮上作用有水的压力分布和离心力。估计了导叶和转轮的相互作用引起的动应力。最后对裂纹扩展的寿命进行了估计。寿命预测乃是基于局部应变方法以预测其扩展寿命。弹塑性应变用Neurber法则确定，对塑性应变用材料迟滞线来解。求解应变寿命方程则可估算裂纹扩展寿命。

Numerical simulation of deposit in confluence zone of debris flow and mainstream

Abundant solid materials were formed as a result of landslide and collapse due to Wenchuan earthquake.The solid source around mountains would form a debris flow when appropriate rain condition occurs.Such a debris flow is structurally very large and strong,and the river flow can hardly wash away the deposit when the debris flow enters into the mainstream.As a result,the deposit on the river bed due to debris flow will cause a series of hazards.Based on the previous researches and relevant data,this paper simplified the interaction between debris flow and current of the main river,and adopted the finite element characteristic-based-split algorithm which is favorable to the stabilization of dealing with the convection.Finally,the numerical model of the confluence of debris flow deposit and main river was developed,and the deposit progress of the mega-debris flow from Wenjiagou in Mianyuan river was reproduced.Furthermore,the influence of the deposit on the flow route of the main river,and distribution of velocity and water depth were analyzed.The results showed that the simulation deposit terrain qualitatively agreed with the field data through comparison,including the deposit area and depth distribution.Furthermore,the improvement of the model in future was discussed.

Dynamic modeling of micro- and nano-sized particles impinging on the substrate during suspension plasma spraying

Suspension plasma spraying （SPS） can be utilized to manufacture finely structured coatings. In this process, liquid suspended with microor nano-sized solid particles is injected into a plasma jet. It involves droplet injection, solvent evaporation, and discharge, acceleration, heating, and melting of the solid particles. The high-speed and high-temperature particles final- ly impact on the substrate wall, to form a thin layer coating. In this study, a comprehensive numerical model was developed to simulate the dynamic behaviors of the suspension droplets and the solid particles, as well as the interactions between them and the plasma gas. The plasma gas was treated as compressible, multi-component, turbulent jet flow, using Navier-Stokes equations solved by the Eulerian method. The droplets and solid particles were treated as discrete Lagrangian entities, being tracked through the spray process. The drag force, Saffman lift force, and Brownian force were taken into account for the aerodynamic drag force, aerodynamic lift force, and random fluctuation force imposed on the particles. Spatial distributions of the micro- and nano-sized particles are given in this paper and their motion histories were observed. The key parameters of spray distribution, including particle size and axial spray distance, were also analyzed. The critical size of particle that follows well with the plasma jet was deduced for the specified operating conditions. Results show that in the downstream, the substrate influences the flow field structure and the particle characteristics. The appropriate spray distances were obtained for different microand nano-sized particles.

Gas Turbulence Modulation Model for Gas-Solid Flows in Two-Fluid Approach

Turbulence enhancement by particle wake effect is studied by numerical simulation of gas turbulent flows passing over particle under various particle sizes, inlet gas velocities, gas viscosity, gas density and the distance of particles. By performing dimension analysis and using the form of gas-particle interaction source term for reference, a new semi-empirical turbulence enhancement model by the particle-wake effect is proposed. The turbulence model is then incorporated into second-order moment model for simulating gas-particle flows in a horizontal channel with different wall roughness and a sudden-expansion chamber. The results show that this model is with higher calculating accuracy than another two turbulence models in comparison with the experimental results.