孔隙介质非达西渗流Forchheimer方程量化评价

Forchheimer方程作为非达西渗流中广泛应用的基本方程之一,方程中A、B系数的确定一直是孔隙介质渗流领域中的热点及难点,不同学者根据渗流试验结果提出了不同的Forchheimer方程A、B系数的经验公式,但对于均质以及混合粒径的非均质条件下评价各经验公式适用性的研究较少。因此在渗流阻力试验的基础上,采用归一化目标函数和线性回归法评价了Forchheimer方程经验公式的适用性,为不同孔隙介质条件下Forchheimer方程经验公式的选取提供参考。结果表明:对于均质孔隙介质,Sidiropoulou公式对水力梯度有着很好的预测效果;对于2种混合粒径孔隙介质,在使用平均粒径的基础上,还应考虑混合粒径的质量比和大小因素,Macdonald公式的预测效果受混合粒径的质量比和大小影响较小,Kadlec and Knight公式对于水力梯度的预测结果较为稳定;对于5种混合粒径孔隙介质,使用d60作为特征粒径进行预测的效果较好,Kadlec and Knight公式对于系数A的预测效果较好,Ergun公式对于系数B的预测效果较好。研究结果能够为工程中均质及非均质松散砂砾石孔隙介质渗流计算的Forchheimer方程的选取提供依据。

Couple stress and Darcy Forchheimer hybrid nanofluid flow on a vertical plate by means of double diffusion Cattaneo-Christov analysis

A three-dimensional Darcy Forchheimer mixed convective flow of a couple stress hybrid nanofluid flow through a vertical plate by means of the double diffusion Cattaneo-Christov model is presented in this study.The influence of highorder velocity slip flow,as well as a passive and active control,is also considered.The motive of the research is to develop a computational model,using cobalt ferrite(Co Fe_(2)O_(4))and copper(Cu)nanoparticles(NPs)in the carrier fluid water,to magnify the energy and mass communication rate and boost the efficiency and performance of thermal energy conduction for a variety of commercial and biological purposes.The proposed model becomes more significant,with an additional effect of non-Fick's mass flux and Fourier's heat model to report the energy and mass passage rate.The results are obtained through the computational strategy parametric continuation method.The figures are plotted to reveal the physical sketch of the obtained solution,while the statistical assessment has been evaluated through tables.It has been observed that the dispersion of Cu and Co Fe_(2)O_(4)NPs to the base fluid significantly enhances the velocity and thermal conductivity of water,which is the most remarkable property of these NPs from the industrial point of view.

The coupled deep neural networks for coupling of the Stokes and Darcy–Forchheimer problems

We present an efficient deep learning method called coupled deep neural networks(CDNNs) for coupling of the Stokes and Darcy–Forchheimer problems. Our method compiles the interface conditions of the coupled problems into the networks properly and can be served as an efficient alternative to the complex coupled problems. To impose energy conservation constraints, the CDNNs utilize simple fully connected layers and a custom loss function to perform the model training process as well as the physical property of the exact solution. The approach can be beneficial for the following reasons: Firstly, we sample randomly and only input spatial coordinates without being restricted by the nature of samples.Secondly, our method is meshfree, which makes it more efficient than the traditional methods. Finally, the method is parallel and can solve multiple variables independently at the same time. We present the theoretical results to guarantee the convergence of the loss function and the convergence of the neural networks to the exact solution. Some numerical experiments are performed and discussed to demonstrate performance of the proposed method.

Forchheimer型非Darcy渗流系统的滞后分岔

在对Forchheimer型非Darcy渗流系统的控制方程进行简化的基础上,分析了系统平衡态的存在性、稳定性及其跳跃,详细讨论了系统的滞后分岔.研究表明:当非Darcy流β因子由负变为正时,平衡态的一支可能失去稳定性,或者跳到另一支,系统发生滞后分岔;当系统的空参量和边界压力发生变化时,稳定的平衡态和不稳定的平衡态合为一个鞍结点,系统发生切分岔.

裂隙-孔隙双重介质Darcy-Forchheimer耦合流动模拟方法及工程应用

针对裂隙-孔隙双重介质非线性渗流问题,采用压力交换函数描述孔隙Darcy渗流和裂隙Forchheimer渗流耦合特性,推导了渗流方程有限体积的数值格式,并编制了相应的计算程序。通过与单裂隙和相交裂隙渗流的Frih和Arraras解对比,验证了新方法的合理性。对富水深埋裂隙型围岩隧道非线性渗流问题的计算表明,所提算法对复杂裂隙系统问题具有很强的适用性。进一步分析隧道围岩渗流特征:越接近隧道位置,水压梯度越大,流量也越大;隧道周围水压梯度呈现“底部大,顶部小”的特点,最大相差2.5倍,因此隧道底部的流量大于顶部流量;裂隙方向均匀性和密度是影响隧道围岩水力特性的重要因素。在一定水力梯度下,裂隙方向越集中于水力梯度方向且密度越大时,围岩导水性越大,隧道流量越大,越容易发生涌水事故。研究成果为裂隙型围岩隧道防水设计及工程实践提供参考。

有界区域内相互作用的Forchheimer-Darcy流体方程组解的结构稳定性

研究了在R3中有界区域内相互作用的Forchheimer-Darcy流体方程组解的结构稳定性。假设黏性流体在Ω1中满足Forchheimer方程组,在Ω2中满足Darcy方程组,借助于一些先验估计,构造了微分不等式,证明了对Forchheimer系数b,Forchheimer-Darcy方程组的解是收敛的。

有界区域内Forchheimer流体对接Darcy流体的连续依赖性

研究Forchheimer系数b在有界区域内,关于粘性流体对接的多孔介质的连续依赖性。假设在1?中,粘性流体是缓慢流动的,所控制的方程是Forchheimer方程;在2?的多孔介质中,我们假设流体所控制的方程是Darcy方程。首先进行先验假设得到关于u和v的L2范数的界的估计;然后利用杨氏不等式,散度定理还有其他的微分不等式,经过一定的放缩,构造出恰当的辅助函数;最后我们利用Gronwall不等式处理辅助函数,得到解关于Forchheimer系数b的连续依赖性。

多孔介质中相互作用的Brinkman-Forchheimer流与Darcy流的空间衰减估计

研究了多孔介质中一类相互作用的Brinkman-Forchheimer流与Darcy流的空间衰减估计.首先定义一个加权的能量表达式,然后借助一些有用的引理推导出该能量表达式所满足的微分不等式,最后得到解的空间衰减估计结果.

Darcy-Forchheimer flow of variable conductivity Jeffrey liquid with Cattaneo-Christov heat flux theory

The role of the Cattaneo-Christov heat flux theory in the two-dimensional laminar flow of the Jeffrey liquid is discussed with a vertical sheet. The salient feature in the energy equation is accounted due to the implementation of the Cattaneo-Christov heat flux. A liquid with variable thermal conductivity is considered in the Darcy-Forchheimer porous space. The mathematical expressions of momentum and energy are coupled due to the presence of mixed convection. A highly nonlinear coupled system of equations is tackled with the homotopic algorithm. The convergence of the homotopy expressions is calculated graphically and numerically. The solutions of the velocity and temperature are expressed for various values of the Deborah number, the ratio of the relaxation time to the retardation time, the porosity parameter, the mixed convective parameter, the Darcy-Forchheimer parameter, and the conductivity parameter. The results show that the velocity and temperature are higher in Fourier＇s law of heat conduction cases in comparison with the Cattaneo-Christov heat flux model.

多孔介质中一类Darcy-Forchheimer流的结构稳定性

研究多空介质中的一类Darcy-Forchheimer流的结构稳定性.首先,在Forchheimer系数发生变化的条件下,证明了其解对Forchheimer系数的连续依赖,亦即求证了当Forchheimer系数发生微小变化时,不会引起解的急剧变化.然后,通过类似的方法分别证明了其解对Darcy系数,和重力系数的连续依赖.

Features of Darcy-Forchheimer flow of carbon nanofluid in frame of chemical species with numerical significance

Present work reports chemically reacting Darcy-Forchheimer flow of nanotubes.Water is utilized as base liquid while carbon nanotubes are considered nanomaterial.An exponential stretchable curved surface flow is originated.Heat source is present.Xue relation of nanoliquid is employed to explore the feature of CNTs (single and multi-wall).Transformation technique is adopted in order to achieve non-linear ordinary differential systems.The governing systems are solved numerically.Effects of involved parameters on flow,temperature,concentration,heat transfer rate (Nusselt number) with addition of skin friction coefficient are illustrated graphically.Decay in velocity is noted with an increment in Forchheimer number and porosity parameter while opposite impact is seen for temperature.Moreover,role of MWCNTs is prominent when compared with SWCNTs.

Numerical treatment for Darcy-Forchheimer flow of carbon nanotubes due to an exponentially stretching curved surface

This article gives a numerical report to two dimensional(2D)Darcy-Forchheimer flow of carbon-water nanofluid.Flow is instigated by exponential extending curved surface.Viscous liquid in permeable space is described by Darcy-Forchheimer.The subsequent arrangement of partial differential equations is changed into ordinary differential framework through proper transformations.Numerical arrangements of governing frameworks are set up by NDSolve procedure.Outcomes of different sundry parameters on temperature and velocity are examined.Skin friction and heat transfer rate are also shown and inspected.

Upshot of ohmically dissipated Darcy-Forchheimer slip flow of magnetohydrodynamic Sutterby fluid over radiating linearly stretched surface in view of Cash and Carp method

The present work concerns the momentum and heat transmission of the electro-magnetohydrodynamic (E-MHD) boundary layer Darcy-Forchheimer flow of a Sutterby fluid over a linear stretching sheet with slip. The nonlinear equations for the proposed model are analyzed numerically. Suitable techniques are used to transform the coupled nonlinear partial differential equations (PDEs) conforming to the forced balance law, energy, and concentration equations into a nonlinear coupled system of ordinary differential equations (ODEs). Numerical solutions of the transformed nonlinear system are obtained using a shooting method, improved by the Cash and Carp coefficients. The influence of important physical variables on the velocity, the temperature, the heat flux coefficient, and the skin-friction coefficient is verified and analyzed through graphs and tables. From the comprehensive analysis of the present work, it is concluded that by intensifying the magnitude of the Hartmann number, the momentum distribution decays, whereas the thermal profile of fluid increases. Furthermore, it is also shown that by aug- menting the values of the momentum slip parameter, the velocity profile diminishes. It is found that the Sutterby fluid model shows shear thickening and shear thinning behaviors. The momentum profile shows that the magnitude of velocity for the shear thickening case is dominant as compared with the shear thinning case. It is also demonstrated that the Sutterby fluid model reduces to a Newtonian model by fixing the fluid parameter to zero. In view of the limiting case, it is established that the surface drag in the case of the Sutterby model shows a trifling pattern as compared with the classical case.

Navier’s slip condition on time dependent Darcy-Forchheimer nanofluid using spectral relaxation method

In industrial applications involving metal and polymer sheets, the flow situation is strongly unsteady and the sheet temperature is a mixture of prescribed surface temperature and heat flux. Further, a proper choice of cooling liquid is also an important component of the analysis to achieve better outputs. In this paper, we numerically investigate Darcy-Forchheimer nanoliquid flows past an unsteady stretching surface by incorporating various effects, such as the Brownian and thermophoresis effects, Navier’s slip condition and convective thermal boundary conditions. To solve the governing equations, using suitable similarity transformations, the nonlinear ordinary differential equations are derived and the resulting coupled momentum and energy equations are numerically solved using the spectral relaxation method. Through the systematically numerical investigation, the important physical parameters of the present model are analyzed. We find that the presence of unsteadiness parameter has significant effects on velocity, temperature, concentration fields, the associated heat and mass transport rates. Also, an increase in inertia coefficient and porosity parameter causes an increase in the velocity at the boundary.

Numerical simulation for Darcy-Forchheimer 3D rotating flow subject to binary chemical reaction and Arrhenius activation energy

Three-dimensional Darcy-Forchheimer nanoliquid flow in the presence of rotating frame and activation energy is inspected.Flow is developed through linearly stretching of the surface.Convection of heat and mass exchange is given due consideration.The novel characteristics in regards to Brownian dispersion and thermophoresis are retained.The variation in partial differential framework (PDEs) to nonlinear ordinary differential framework (ODEs) is done through reasonable transformations.Governing differential frameworks have been computed in edge of NDSolve.Discussion regarding thermal field and concentration distribution for several involved parameters is pivotal part.Physical amounts like surface drag coefficients,transfer of heat and mass rates are portrayed by numeric esteems.It is noticed that impacts of porosity parameter and Forchheimer number on the thermal and concentration fields are quite similar.Both temperature and associated thermal layer thickness are enhanced for larger porosity parameter and Forchheimer number.Temperature and concentration fields exhibit similar trend for the higher values of rotational parameter.Effects of thermal and concentration Biot numbers on the temperature and concentration fields are qualitatively similar.Higher Prandtl and Schmidt numbers correspond to stronger temperature and concentration fields.Larger nondimensional activation energy,temperature difference parameter and fitted rate constant yield weaker concentration field.Brownian motion parameter for temperature and concentration has reverse effects while similar trend is observed via thermophoresis parameter.

Forchheimer型非达西渗流参数特征分析

针对目前Forchheimer方程中研究渗流参数较少的问题,运用数值模拟对比分析了Forchheimer型非达西渗流和达西渗流,验证了高渗流速度下Forchheimer型非达西渗流的正确性,进而通过非达西效应分析了Forchheimer型非达西渗流参数特征。结果表明,非达西流影响系数与渗流速度为反比关系;发生非达西渗流时,渗透系数会降低;非达西效应越明显,渗透系数越低。

Forchheimer方程参数量化及达西—非达西转变临界点

为探究岩体裂隙中水流的运动规律,基于真实岩体材料建立裂隙渗流模型,对裂隙中的渗流状态及渗流参数进行了研究.区别于水泥、玻璃、亚克力、钢材等常见非石材类材质,选用天然大理石岩块为基材构建单裂隙渗流模型,开展不同隙宽(0.77、1.18、1.97、2.73 mm)的渗流试验,考察压力损失与流量的关系,探讨达西—非达西流转变的临界点及Forchheimer方程的参数量化问题.研究结果表明:隙宽为0.77 mm时压力梯度与流量基本呈线性达西关系,随着隙宽和流量的增大,二者呈现出明显的非达西特征,可用Forchheimer方程描述;Forchheimer方程的粘滞项和惯性系数均可表达为隙宽的幂函数,引入雷诺数对惯性项系数进行修正可以减少误差;提出以压力梯度-流量曲线的斜率变化特征来判断达西—非达西流临界点的方法,并在本试验中得到了验证.

含瓦斯煤Forchheimer型非达西渗流实验研究

针对目前非达西渗流在含瓦斯煤三轴应力状态下研究较少的问题,基于Forchheimer型非达西渗流理论,采用自行研制的含瓦斯煤准三轴渗流试验装置,研究了2个煤矿的贫煤煤样在不同围压、轴压条件下Forchheimer型非达西渗流特性并计算了相关参数。研究结果表明,三轴应力状态下煤样中瓦斯气体流速随瓦斯压力梯度的变化而出现明显的Forchheimer型效应。相同介质和流体下,瓦斯压力和三轴应力状态成为煤体瓦斯渗透规律的主要影响因素。不同围压、轴压条件下,瓦斯渗透速度会随瓦斯压力的增大而增大,但其渗透速度的增大速率最终会趋于恒定。相同围压下,非达西渗流因子β随轴压的增大而增大,且β越大,压力梯度与渗流速度之间的非线性关系越明显,而非达西渗透系数K值会有减小的趋势。

单裂隙中开度及粗糙度对Forchheimer公式特征参数的影响

Forchheimer公式已广泛应用于高速非达西渗流计算中,但裂隙开度与粗糙度对公式中的特征参数k和β的影响研究尚不够明确。为此,应用Fluent计算软件,用标准J_(JRC)曲线模拟裂隙结构表面粗糙度,研究了裂隙开度b与裂隙粗糙度(J_(JRC))对渗透率k和非达西系数β的影响。结果表明,粗糙裂隙中发生高速渗流时,渗透率与J_(JRC)呈负相关关系,与裂隙开度呈正相关线性关系,裂隙开度是影响渗透率的主要因素;β随着J_(JRC)的增大而增大,随着裂隙开度的增大而减小;非达西系数与渗透率之间存在着负相关关系,这种关系可用幂函数来较好表达。

相互作用的Brinkman-Forchheimer方程组与Darcy方程组的结构稳定性

研究了在R^(3)中有界区域内的多孔介质中相互作用的Brinkman-Forchheimer流体与Darcy流体方程组解的结构稳定性,假设在Ω_(1)中流体速度较慢,满足BrinkmanForchheimer方程组,而在Ω_(2)中,饱和流体满足Darcy方程组.借助于温度的四阶范数估计以及Sobolev不等式,构造能量表达式,推出该表达式所满足的微分不等式,积分得到了相互作用Brinkman-Forchheimer与Darcy流体方程组的解对Brinkman系数的连续依赖性结果.