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当含金属颗粒的粘性流体(即纳米流体)流过非线性伸展平面时,分析其边界层流动及其热交换.假设伸展速度是到原点距离的幂函数.将偏微分的控制方程及其相应的边界条件,简化为耦合的非线性常微分方程及其相应的边界条件.数值地求解所得到的非线性常微分方程.讨论了各相关参数(即Eckert数Ec,纳米颗粒的固体体积率和非线性伸展参数n)对问题结果的影响,并与先前文献所报道的结果进行了对比.研究了不同类型的纳米颗粒.发现纳米流体的流动特性随着纳米颗粒类型的改变而变化. 相似文献
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流经有热源多孔平板并伴有化学反应的传热传质混合对流MHD流动 总被引:1,自引:1,他引:0
对流经无限竖直多孔平板的不可压缩粘性导电流体,稳定的传热传质混合对流MHD流动问题,给出了精确解和数值解.假定均匀磁场横向作用于流动方向,考虑了感应磁场及其能量的粘性和磁性损耗.多孔平板有恒定的吸入速度并均匀地混入流动速度.用摄动技术和数值方法求解控制方程.得到了平板上速度场、温度场、感应磁场、表面摩擦力和传热率的分析表达式.相关参数取不同数值时,用图形表示出问题的数值结果.讨论了从平板到流体的Hartmann数、化学反应参数、磁场的Prandtl数,以及包括速度场、温度场、浓度场和感应磁场等其它参数的影响.可以发现,热源/汇或Eckert数的增大,极大地提高了流体的速度值.x-方向的感应磁场随着Hartmann数、磁场的Prandtl数、热源/汇和粘性耗散的增大而增大.但是,研究表明,随着破坏性化学反应(K0)的增大,流动速度、流体温度和感应磁场将减小.对色谱分析系统和材料加工的磁场控制,该研究在热离子反应堆模型、电磁感应、磁流体动力学传输现象中得到了应用. 相似文献
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在横向磁场作用下,研究Hall电流对竖直可渗透平板上MHD自然对流的影响,平板具有均匀的热通量.和外部磁场相比,假设感应磁场可以忽略不计.利用自由变量公式化(FVF)和流函数公式化(SFF),将边界层方程简化为适当的形式.对局部蒸发系数ζ的整个取值范围,由FVF得到的抛物型方程,用简明的有限差分法进行数值积分;另一方面,由SFF得到的非相似方程,采用局部非相似法求解.有些区域,如局部蒸发系数ζ值足够大或足够小时,用正规的摄动法求解.对低值Prandtl数Pr,例如Pr=0.005,0.01,0.05时,用图形表示磁场参数M和Hall参数m,对局部表面摩擦因数和局部Nusselt数的影响.最后对不同的局部蒸发系数ζ值,给出流体的速度和温度分布. 相似文献
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平面射流中纳米粒子积聚的矩方法 总被引:1,自引:1,他引:0
应用大涡模拟方法求解平面湍射流场,矩方法求解纳米粒子的一般动力学方程.通过对每种情况3 000个时间步的平均,得到了Schmidt数和Damkohler数对纳米粒子动力学特性的影响.结果发现, 当气体参数不变时,Schmidt数的变化只对直径小于1 nm的颗粒数密度的分布产生影响.直径小的颗粒其颗粒数密度沿流动方向下降迅速,而具有大Schmidt数的颗粒,沿横向的分布较窄.较小的颗粒容易发生积聚和扩散,并且体积增长较快,因而颗粒多分散性较为明显.小的颗粒积聚时间尺度能增强颗粒的碰撞和积聚频率,导致颗粒尺寸迅速增大.Damkohler数越大,颗粒的多分散也越明显. 相似文献
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均匀自由流动的非牛顿流体中连续表面上的磁流体动力学流动和热传递 总被引:1,自引:1,他引:0
分析在平行自由流动的非牛顿黏弹性导电流体中,连续平展表面移动时的稳态流和热传递特性,该流动处于横向均匀磁场作用下.以二阶流体构建它的本构方程,得到了速度分布和温度断面图的数值结果.讨论了诸如黏弹性参数、磁场参数和Prandtl数等不同物理参数对诸种动量和热传递特性的影响,并给出相关图示. 相似文献
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《数学的实践与认识》2017,(16)
对周期性温度边界条件下方腔内Copper-水纳米流体的对流传热问题建立了完全四阶高精度紧致差分格式,并探讨了该格式高效算法设计,同时引入伪时间导数项采用Von Neumann方法证明了格式的绝对稳定性.研究了不同Ri数下纳米颗粒体积分数、左右边界温度的正弦振幅比和相位偏差对纳米流体传热效率的影响.数值结果表明,对于给定的Ri数,随着纳米颗粒体积分数的增大和边界温度的正弦振幅比的增加,纳米流体的传热效果会显著增强,而相位偏差只影响方腔右侧的温度分布. 相似文献
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就两类以水为基本流体的Newton纳米流体:内含金属颗粒铜(Cu),或者非金属颗粒二氧化钛(TiO2),研究粘性耗散和Newton传热对移动平板边界层流动的组合影响.利用相似变换,将偏微分的控制方程转换为常微分方程组,并用Runge-Kutta-Fehlberg法和打靶法,对其进行数值求解.由此得到结论,随着纳米颗粒体积分数和Newton传热的增加,移动平板表面的热交换率也增加,但是,随着Brinkmann数的增加,移动平板表面的热交换率反而减小.此外,纳米工作流体Cu-水的移动平板表面热交换率,高于纳米工作流体TiO2-水. 相似文献
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K. N. Venkatasiva Murthy 《Proceedings Mathematical Sciences》1980,89(2):103-112
The MHD Couette flow of a viscous stratified fluid of large electrical conductivity with suction and injection at the plane
boundaries is studied when the plane boundaries are maintained at different temperatures. The Oseen type governing equations
are formulated using the method suggested by Greenspan for stratified fluids. Introducing the similarity variables, the linearised
equations are solved to obtain the velocity and temperature distributions. The results show that the behaviour of velocity
and temperature in fluids of large conductivity is different from the behaviour of velocity and temperature for fluids of
finite conductivity. The effect of the magnetic field on the load capacity is investigated for the case when the width of
the channel is small. 相似文献
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An unsteady free convective flow through porous media of viscous, incompressible, electrically conducting fluid through a vertical porous channel with thermal radiation is studied. A magnetic field of uniform strength is applied perpendicular to the vertical channel. The magnetic Reynolds number is assumed very small so that the induced magnetic field effect is negligible. The injection and suction velocity at both plates is constant and is given by v 0. The pressure gradient in the channel varies periodically with time along the axis of the channel. The temperature difference of the plates is high enough to induce the radiative heat. Taking Hall current and Soret effect into account, equations of motion, energy, and concentration are solved. The effects of the various parameters, entering into the problem, on velocity, temperature and concentration field are shown graphically. 相似文献
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S. Bandyopadhyay G.C. Layek 《Communications in Nonlinear Science & Numerical Simulation》2012,17(6):2434-2446
The present work reports the study of steady and pulsatile flows of an electrically conducting fluid in a differently shaped locally constricted channel in presence of an external transverse uniform magnetic field. The governing nonlinear magnetohydrodynamic equations simplified for low conducting fluids are solved numerically by finite difference method using stream function-vorticity formulation. The analysis reveals that the flow separation region is diminished with increasing values of magnetic parameter. It is noticed that the increase in the magnetic field strength results in the progressive flattening of axial velocity. The variations of wall shear stress with increasing values of the magnetic parameter are shown for both steady and pulsatile flow conditions. The streamline and vorticity distributions in magnetohydrodynamic flow are also shown graphically and discussed. 相似文献
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Z. Ziabakhsh G. Domairry 《Communications in Nonlinear Science & Numerical Simulation》2009,14(4):1284-1294
In this paper, the problem of laminar viscous flow in a semi-porous channel in the presence of a transverse magnetic field is presented and the homotopy analysis method (HAM) is employed to compute an approximation to the solution of the system of nonlinear differential equations governing the problem. It has been attempted to show the capabilities and wide-range applications of the homotopy analysis method in comparison with the numerical method in solving this problem. The obtained solutions, in comparison with the numeric solutions admit a remarkable accuracy. A clear conclusion can be drawn from the numerical method’s (NM) results that the HAM provides highly accurate solutions for nonlinear differential equations. 相似文献
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Inclined magnetic field and Soret effects on mixed convection flow between vertical parallel plates 下载免费PDF全文
Kolla Kaladhar K. Madhusudhan Reddy D. Srinivasacharya 《Journal of Applied Analysis & Computation》2019,9(6):2111-2123
This present paper investigates the influence of thermal diffusion and inclined magnetic field effects on mixed convection flow through a channel. Spectral Quasilinearization Method (SQLM) is used to solve the dimensionless governing equations, those were obtained by using sutable transformations from the system of governing partial differential equations. The influence of the variation of different parameters like magnetic parameter, Hall parameter, Soret parameter and the intensity of angle of inclination on velocities, temperature and concentration are investigated and presented through plots. According to acquired results, under the influence of magnetic field (in an inclined direction) the velocity profiles were amplified and the temperature profile got diminished, where as there is a reverse tendency under the effect of Hall parameter. Finally the nature of the physical parameters were displayed in table form. 相似文献
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Fatemeh Shakeri Mehdi Dehghan 《Applied Numerical Mathematics》2011,61(1):1-23
In this paper, the coupled equations in velocity and magnetic field for unsteady magnetohydrodynamic (MHD) flow through a pipe of rectangular section are solved using combined finite volume method and spectral element technique, improved by means of Hermit interpolation. The transverse applied magnetic field may have an arbitrary orientation relative to the section of the pipe. The velocity and induced magnetic field are studied for various values of Hartmann number, wall conductivity and orientation of the applied magnetic field. Comparisons with the exact solution and also some other numerical methods are made in the special cases where the exact solution exists. The numerical results for these sample problems compare very well to analytical results. 相似文献
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Combined free and forced convection effects on the magnetohydrodynamic flow through a porous channel
The combined effect of free and forced convection on the flow of an electrically conducting liquid between two horizontal parallel porous walls has been studied. There is a transverse magnetic field at the walls. The equations of motion and energy have been solved by a small perturbation method. The flow phenomenon has been characterized by the non-dimensional numbers like R (cross-flow Reynolds number), K (Brinkman number), G (Grashof number), M (magnetic number) and the effects of these numbers on the velocity and temperature fields, induced magnetic field, electric field and shearing stress at the walls have been studied. 相似文献
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The interaction of an externally imposed magnetic and electric field on the laminar flow of a conducting fluid in a channel is studied using computational techniques. The Navier-Stokes equations and the equations describing the electromagnetic field are solved simultaneously in a single control volume-type computational fluid dynamic code, in a moderate Hartmann number and interaction parameter regime. The flow considered is two-dimensional, with an imposed magnetic field acting in the third dimension over the central region of the channel and decaying exponentially in the remainder. A pair of electrodes placed at right angles to the magnetic field exercises control over the resultant Lorentz force and hence the velocity profile shape. This configuration has application in direct-current electromagnetic pumps or, conversely, electromagnetic brakes. The initial parabolic flow profile acquires an M-shape / W-shape mode in the magnetic field fringe regions, corresponding to a pump / brake. A novel coupled procedure is described to model magnetohydrodynamic phenomena and is used to explore the effects of the Reynolds number, interaction parameter, and applied voltage on the pump / brake configuration. 相似文献