Non-linear analysis of creeping flow on the inclined permeable substrate plane subjected to an electric field

The effect of an externally applied electric field on the stability of a thin fluid film over an inclined porous plane is analyzed using linear and non-linear stability analysis in the long wave limit. The principle aim of this study is to illustrate the influence of electric field on the non-linear stability of a thin liquid layer flow down incline substrate when the plane is porous. The driving force for the instability under an electric field is an electrostatic force exerted on the free charges accumulated at the dividing interface. The coupled non-linear evolution equations for the local film thickness and the interfacial charge for two-dimensional disturbances are derived to analyze the effect of long-wave instabilities. The method of multiple scales is applied to obtain approximate solutions and analyze the stability criteria. Numerical simulations of this system of non-linear evolution equations are performed. It is found that the permeability parameter as well as the inclination of the plane plays a destabilizing role in the stability criteria, while the damping influence is observed for increasing of the electrical conductivity in both linear and non-linear behavior.     

Stability of wave forms of motion of a viscous fluid layer under tangential stress

We study the stability of wave flow of a viscous incompressible fluid layer subjected to tangential stress and an inclined gravity force with respect to long-wave disturbances.An asymptotic solution is constructed for the equations of the disturbed motion and the problem is reduced to the study of a second-order ordinary differential equation. It is shown that after loss of stability by a Poiseuille flow the laminar nature of the flow is not destroyed, but the form of the free surface acquires a wave-like profile. The Poiseuille regime is stable for low Reynolds numbers. The critical Reynolds number for wave flow is found, and the stability and instability regions are determined.     

动电学效应下微流动近壁面带电离子受力分析

应用离子分布的Boltzmann定律和Poisson方程研究了微流动中通道近壁面电势的分布,采用Derjaguin理论计算了动电学效应下带电离子受到的双电层作用力,应用Hamaker-De Boer 近似式得到了离子与壁面间的范德瓦尔力,同时也考虑到离子重力的影响,揭示了三种力对带电离子流动特性的影响.研究结果表明:无量纲间距d~*≤0.2时,离子重力的影响可以忽略,带电离子主要受范德瓦尔力和双电层作用力的作用,且二力均随d~*增大而减小,d~*≤0.02时,范德瓦尔力起主要作用,当0.020.2时,重力、范德瓦尔力及双电层作用力都趋于零,均可忽略.     

MHD控制超声速边界层的理论研究和数值分析

对MHD(mechanisms of magnetohy drodynamics)控制超声速平板湍流边界层的机理进行了理论研究和数值模拟. 理论上,采用等离子体低频近似碰撞频率模型,建立等离子体中电子和离子的力平衡方程,得到等离子体速度、极化电场以及边界层速度. 数值上,通过空间HLLE格式、LU--SGS时间推进求解时均磁流体动力学湍流方程,其中湍流模型采用sst--k\omega双方程模型. 研究结果表明:(1)边界层速度的理论结果和数值结果误差在7%范围内;(2)只有磁场而电场为零时,洛仑兹力起到减小摩阻的作用. 施加电场后,洛仑兹力能够加速边界层低速区流体;(3) 在边界层外层,越靠近壁面,作用参数越小;而在边界层近壁区黏性底层,虽然惯性力减小, 但黏性力却迅速增加,因此越靠近壁面,作用参数反而越大,加速低速流的代价增加.      

Inclined circular flat punch on a transversely isotropic piezoelectric half-space

Summary Utilizing the general solution of transversely isotropic piezoelectricity, the paper analyzes the problem of an inclined rigid circular flat punch indenting a transversely isotropic piezoelectric half-space. The potential theory method is employed and generalized to take into account the effect of the electric field in piezoelectric materials. Assuming that the punch is maintained at a constant electric potential, exact expressions for the elastoelectric field are derived in terms of elementary functions. It is noted that the solution corresponding to a flat circular punch centrally loaded by a concentrated force can be obtained as a special case. Received 15 December 1998; accepted for publication 9 March 1999     

Periodical streaming potential and electro-viscous effects in microchannel flow

This paper presents an analytical solution to periodical streaming potential, flow-induced electric field and velocity of periodical pressure-driven flows in twodimensional uniform microchannel based on the Poisson-Boltzmann equations for electric double layer and Navier-Stokes equation for liquid flow. Dimensional analysis indicates that electric-viscous force depends on three factors： （1） Electric-viscous number representing a ratio between maximum of electric-viscous force and pressure gradient in a steady state, （2） profile function describing the distribution profile of electro-viscous force in channel section, and （3） coupling coefficient reflecting behavior of arnplitude damping and phase offset of electro-viscous force. Analytical results indicate that flow-induced electric field and flow velocity depend on frequency Reynolds number （Re = wh^2/v）. Flow-induced electric field varies very slowly with Re when Re 〈 1, and rapidly decreases when Re 〉 1. Electro-viscous effect on flow-induced electric field and flow velocity are very significant when the rate of the channel width to the thickness of electric double layer is small.     

Periodical streaming potential and electro-viscous effects in microchannel flow

This paper presents an analytical solution to periodical streaming potential,flow-induced electric field and velocity of periodical pressure-driven flows in twodimensional uniform microchannel based on the Poisson.Boltzmann equations for electric double layer and Navier-Stokes equation for liquid flow.Dimensional analysis indicates that electric-Viscous force depends on three factors:(1)Electric-viscous number representing a ratio between maximum of electric-viscous force and pressure gradient in a steady state,(2)profile function describing the distribution profile of electro-viscous forcein channel section,and(3)coupling coefficient reflecting behavior of amplitude damping and phase Offset of electro-viscous force.Analytical results indicate that flow-induced electric field and flow velocity depend on frequency Reynolds number(Re=wh2/v).Flow-induced electric field varies very slowly with Re when Re＜1.and rapidly decreases when Re＞1.Electro-viscous effect on flow-induced electric field and flow velocity are very significant when the rate of the channel width to the thickness of electric double layer is small.     

三维电动力绳系子卫星轨道转移的最优控制

考虑复杂状态和控制约束的作用,研究了倾斜轨道上三维电动力绳系子卫星轨道转移的最优控制问题.借助Gauss伪谱算法,将绳系子卫星轨道转移的连续时间最优控制问题离散为大规模动态规划问题,并利用非线性规划方法进行求解.通过数值仿真计算了最优控制时间、子星最优转移轨道及最优控制张力和电流,同时讨论了轨道倾角对最优控制量的影响....     

Modeling of vibrational impact motion of mobile-based body

The paper deals with vibrational impact motion of a mobile-based body on an inclined plane, which is a characteristic for vibrational alignment of components subjected to an automated assembly. The alignment model is presented by a two-degree-of-freedom vibro-impact system in which the moving body is impacting the plane obliquely. Properties of the vibrational impact motion under kinematical excitement of the moving body and under the excitement of the plane in two perpendicular directions were investigated by numerical methods. It was determined that impact displacement occurs under transient regimes of motion from static to dynamic state of equilibrium. Dependencies of maximum displacement of the body and average displacement velocity on force of elastic resistance, amplitude of plane vibration in the direction of the displacement, and phase angle between the perpendicular members of vibration components were established. Zones of system and excitement parameter combination when the vibrational impact motion occurs were defined.     

Cavitation-induced particle–wall interaction in Newtonian and non-Newtonian fluids

A novel hydrodynamic effect, namely, slow contactless motion of a heavy spherical particle along an inclined wall, accompanied by the formation of a finite particle–wall clearance under the action of a cavitation-induced lift force, is investigated. Similarity parameters controlling the particle motion, determined using the dimensionality theory, are validated experimentally. These parameters are related to the atmospheric pressure, the surface tension on the liquid–air interface, the density of the air dissolved in the fluid, the particle weight in the fluid, and the viscoelastic properties of the fluid.This paper was presented at the AERC 2005.     

Effects of supported angle on stability and dynamical bifurcations of cantilevered pipe conveying fluid

The effects of the supported angle on the stability and dynamical bifurcations of an inclined cantilevered pipe conveying fluid are investigated. First, a theoretical model of the pipe is developed through the force balance and stress-strain relationship. Second, the response surfaces, stability, and critical lines of the typical hanging system (H-S) and standing system (S-S) are discussed based on the modal analysis. Last, the bifurcation diagrams of the pipe are presented for different supported angles. It is shown that pipes will undergo a series of bifurcation processes and show rich dynamic phenomena such as buckling, Hopf bifurcation, period-doubling bifurcation, chaotic motion, and divergence motion.     

Modeling of vibrational non-impact motion of mobile-based body

The paper deals with vibrational non-impact displacement of a mobile-based body on an inclined plane. Two cases are considered: when the body is subjected to kinematical excitement, and when the plane is excited in two perpendicular directions. This phenomenon is used in vibratory assembly devices, where vibration excitement compensates interdependent orientation errors of the components subjected to assembly. Transient and periodic regimes of the body motion from static to dynamic equilibrium are investigated. Dependencies of maximum displacement and average creeping displacement speed upon the elastic resistance force, body pressure to the plane force, the ratio of mutually perpendicular vibration amplitudes, and the phase of these vibrations are presented. The possibilities and conditions of automatic components assembling by applying vibration displacement are characterized.     

Effect of the atmospheric electric field under a thundercloud on tornado funnel formation

The effect of the atmospheric electric field under a thundercloud on the formation and motion of a tornado funnel is considered. It is shown that the electric force may cause the descent of the developing funnel to the Earth’s surface or its ascent back to the thundercloud.     

Influence of induced magnetic field on the peristaltic flow of nanofluid

This article investigates the effects of an induced magnetic field on the mixed convection peristaltic motion of nanofluid in a vertical channel. Transport equations involve the combined effects of Brownian motion and thermophoretic diffusion of nanoparticles. Analysis has been addressed subject to long wavelength and low Reynolds number assumptions. Explicit expressions of stream function, magnetic force function, temperature and nanoparticles concentration are developed. Analytic expressions are validated with the obtained numerical solutions. Peristaltic pumping rate is found to increase upon increasing the strengths of electric and magnetic fields and the buoyancy force due to temperature gradient. Moreover temperature rises and nanoparticles concentration decreases with an intensification in the Brownian motion effect.     

Bending-torsional stability analysis of aerodynamically covered pipes with inclined terminal nozzle and concurrent internal and external flows

Stability analysis of a cantilevered pipe with an inclined terminal nozzle as well as simultaneous internal and external fluid flows is investigated in this study. The pipe is embedded in an aerodynamic cover with negligible mass and stiffness simply to streamline the external flow and avoid vortex induced vibrations. The structure of pipe is modeled as an Euler–Bernoulli beam and effects of internal fluid flow including flow-induced inertia, Coriolis and centrifugal forces and the follower force induced by the exhausting jet are taken into account. In addition, neglecting the compressibility effect and using the unsteady Wagner model, aerodynamic loading is determined as a distributed lateral load for any generic structural state. The integral form of coupled equations of motion are obtained using the Hamilton’s principle. Solution to the coupled flexural–torsional equations of motion is realized via the extended Galerkin method. After discretization of the equations of motion, an eigenvalue representation of the problem is obtained. Several parameter studies are then conducted to examine the effects of concurrent fluid flows and other related parameters on the stability margins of the system.     

Stability of the convective flow in an inclined layer with heat release at its center

The flow of a viscous incompressible fluid in a plane infinite inclined layer in the presence of internal heat sources concentrated on its axis is considered. The stability of the plane-parallel motion is investigated, the neutral curves are plotted, and the stability regions are determined. The results are compared with the case of uniform distribution of the heat sources. Supercritical fluid flows are calculated numerically.     

HYDRODYNAMIC RESISTANCE EFFECT OF FLUID LAYER BETWEEN TWO IMMERSED APPROACHING PARTICLES

1. Introduction The mechanisms of impact and rebound of solid parti- cles in particulate flow systems are of interest over a wide range of application areas such as fluidized beds, pneu- matic transport, filtration processes, erosion and pollution control of suspended particles. In many cases, the colli- sions of particles against themselves and against walls may affect the properties of the mixture. Efforts have been made to describe the fundamental mechanics of particle collisions. The conta…     

The energy momentum tensor in the presence of body forces and the Peach–Koehler force on a dislocation

A modified energy momentum tensor, in the presence of body forces, is introduced and used to construct the nonconserved J, M, and L integrals, and to derive the energetic forces associated with a defect motion within the material. The J integral is then applied to evaluate the Peach–Koehler force on an inclined edge dislocation within a large block due to its own weight. The equilibrium position of the dislocation is determined for different boundary conditions of interest in geomechanics.     

Interaction of a one-dimensional unloading wave with an elastoplastic boundary in an elastoviscoplastic medium

This paper presents a solution of the boundary-value problem of the theory of large elastoviscoplastic strains for the development of viscoplastic flow in a heavy layer of material located on an inclined plane and subjected to loading at the free surface with subsequent instantaneous removal of the load. This discontinuous change in the boundary conditions gives rise to a surface of strain discontinuity propagating in the medium and called an unloading wave. The reflection of the wave from the elastoviscoplastic boundary and its motion after reflection from the fixed plane and the free surface are considered.     

A continuum analysis of the driving force of ferroelectric/ferroelastic domain wall motions

First, Eshelby's driving force for the motion of a sharp interface is rederived from general thermodynamic principles. Ferroelectric and ferroelastic domain walls represent a special class of such interfaces in mechanically stressed crystals subject also to an electric field. The corresponding bulk contributions to the driving force are caused by variations of the ferroelectric/ferroelastic anisotropy energy, whereas the interface contributions arise from variations of the intrinsic surface energy of the domain wall and domain wall bending. The general expressions for the local driving force per unit area of such domain walls are specialized then to domain walls in piezoelectric crystals.