ABSTRACT
In this paper, a second order Adams-Bashforth method is proposed to simulate four-sided square lid-driven cavity flow. The convective term and diffusive term in Navier-Stokes equations are solved using a finite central difference scheme and the unsteady term is solved using the Adams-Bashforth method. All of the flow is simulated at below critical Reynolds numbers in a square cavity with an isothermal condition and the same speed for all walls. In this study, the flow structure for a four-sided lid-driven cavity with its four vortices and a graph of the velocity profile along the center of the cavity are presented. In addition, we also study the effect of the Reynolds number on the development of vortices in the cavity. We find that the Reynolds number has a dominant effect on the flow structure in the cavity. The computed results also show good agreement with the published data.
Keywords: Four-sided lid-driven cavity; Adams-Bashforth Method; Reynolds numbers, time splitting method.
(ProQuest: ... denotes formulae omitted.)
INTRODUCTION
The flow inside a square cavity has been widely used to demonstrate fluid flow using simple geometry. The flow structure in a one-sided lid-driven cavity problem has been reported by many researchers (Ghia, Ghia, & Shin, 1982; Idris, Ammar, Tuan Ya, & Amin, 2013; Idris, Irwan, & Ammar, 2012; Musa, Abdullah, Azwadi, & Zulkifli, 2011; Rosdzimin, Zuhairi, & Azwadi, 2010; Sidik & Attarzadeh, 2011). Later, research on different cavity geometries has been reported, such as a deep cavity (Patil, Lakshmisha, & Rogg, 2006), semi-circular cavity (Yang, Shi, Guo, & Sai, 2012), trapezoidal cavity (Zhang, Shi, & Chai, 2010) and triangular cavity (González, Ahmed, Kühnen, Kuhlmann, & Theofilis, 2011). Recently, two-sided lid-driven cavity flow (Mendu & Das, 2012; Oueslati, Ben Beya, & Lili, 2011) has been analyzed in order to study possible applications in industry, such as in the paper coating industry (Cao & Esmail, 1995), polymer processing (Gaskell, Summers, Thompson, & Savage, 1996) and drying technologies (Alleborn, Raszillier, & Durst, 1999). For the case of a four-sided lid-driven cavity flow, Wahba (2009) studied the bifurcation of the flow and found that four-sided lid-driven cavity flow generates bifurcation at Re = 219. Recently, Perumal and Dass (2011) and Cadou, Guevel, and Girault (2012) tested the stability of the Lattice Boltzmann method by simulating the flow structure in a four-sided lid-driven cavity. In order to solve the Navier-Stokes equation without having a checkerboard problem, a staggered grid arrangement should be used, where pressure will be located at the center of the staggered grid and velocity will be placed at the cell face. The Adams- Bashforth method is a famous method that implements a staggered grid for time advancement calculation. A higher order of accuracy analysis for the Adams-Bashforth method has been applied by many researchers, such as Man and Tsai (2008) in their work on the vorticity-stream function equation, as well as work by Lo, Murugesan, and Young (2005). A similar formulation has been used, combining the Adams-Bashforth scheme with the Crank-Nicolson scheme to create a semi-implicit scheme in three-dimensional analysis (Hansen, Sørensen, & Shen, 2003). To solve the Adams- Bashforth scheme, a method called the time-splitting method needs to be used to reduce the number of variables in the momentum equation. Such work has already been done by many researchers (Boersma, 2011; Choi & Balaras, 2009; Perot, 1993).
It appears from the aforementioned investigations that numerous investigations have been conducted on the lid-driven cavity flow. However, no attempt has been made to investigate four-sided lid-driven cavity flow with a high order and stable numerical scheme such as the Adams-Bashforth Crank-Nicolson scheme. Different values of Reynolds number such as at 10, 100 and 127 will be reported. This study is focused on a low Reynolds number as the critical Reynolds number for the four-sided cavity problem is 129 (Wahba, 2009). In the present study, the top wall is moving to the right, the bottom wall is moving to the left, the right wall is moving upwards and the left wall is moving downwards with equal speed. Before presenting the results, the validation of codes will be presented at Re = 1000, with the streamline patterns on a four-sided lid-driven cavity, together with the location of the vortices, and a comparison with the work of Perumal and Dass (2011). Later, their normalized velocity along the center of the cavity will be presented.
MATHEMATICAL MODEL
The incompressible Navier-Stokes equations and continuity equation are written in non-dimensional form. The flow is considered as incompressible and in an isothermal condition.
Continuity equation:
... (1)
Momentum equation:
... (2)
... (3)
where Re = UL/v is the Reynolds number and
U = speed of the wall
L = length of the wall
v = dynamic viscosity of the fluid inside the cavity
These equations are solved by using the central difference on the convective and diffusive term to get better accuracy. To avoid a checkerboard problem from using the central difference, a staggered grid arrangement is used in this study. For time advancement using the Adams-Bashforth method, the popular method used to remove the pressure term is the time-splitting method. This method is also called the pressure correction method, projection approach, fractional step method or time stepping method. The principle of this method is to remove the pressure term from the equation and to introduce an intermediate velocity. A second order Adams-Bashforth method is used and the equation can be written as
... (4)
In this equation, H represents the convective term with a viscous term in the momentum equation and intermediate velocity will be solved first. In this calculation, the viscous and convective term are discretized by using the central difference. All of the velocity component that is not located exactly on the grid will be calculated by using averaging, as will be discussed later in the boundary condition section. During the intermediate step, the pressure term will be decoupled in the equation. Pressure correction will then be calculated by using the pressure Poisson equation in Eq. (5), using the intermediate velocity earlier. The pressure should then be used to get the corrected velocity at time step n+1 by including the intermediate velocity using Eq. (6).
... (5)
... (6)
For the horizontal wall, the boundary condition for v-velocity (vertical velocity) can be used directly because the point of vertical velocity is located at the staggered grid, as in Figure 1. But for u-velocity (horizontal velocity), the velocity is not located exactly on the wall and averaging is therefore used at that position. The procedure is the same at the top wall, but the velocity at the top wall is not zero.
... (7)
Figure 2 shows the boundary condition for v-velocity at the vertical wall. The boundary condition for u-velocity (horizontal velocity) is now different at the vertical wall, where its node is located on the vertical wall, so it can be used directly. The procedure for averaging the v-velocity is the same as in Eq. (7). The walls of the square cavity are moved at the same speed. The top wall moves to the right but the bottom wall moves to the left. On the other hand, the right wall is moving upwards but the left wall is moving downwards, as in Figure 3. Four vortices will developed, where the top vortex is called the Top Primary Vortex (TPV), the vortex at the bottom of the cavity is the Bottom Primary Vortex (BPV), and the right and the left vortices are called the Right Primary Vortex (RPV) and Left Primary Vortex (LPV) respectively. The simulation was done using MATLAB and the grid size is 161×161 in a staggered grid arrangement.
VALIDATION
Ghia et al. (1982) used a vorticity-stream function formulation to simulate the flow of a one-sided lid-driven cavity from low to high Reynolds number. Figure 4(a) shows a comparison of the v-velocity profile along the center of the cavity and Figure 4(b) shows the u-velocity. It shows good agreement with the reference.
RESULTS AND DISCUSSION
This section presents the numerical results of a four-sided lid-driven cavity at Re = 10, 100 and 127. The streamlines inside the cavity, the locations of the vortices, and the graph of the velocity profile along the x-axis and y-axis will be discussed. Figure 5 shows the streamline patterns of the four-sided lid-driven cavity: (a) for Re = 10, (b) Re = 100 and (c) Re = 127. Four vortices are generated at the end of the simulation, namely, one vortex each at the top of the cavity, bottom of the cavity, left side of the cavity and right side of the cavity. Generally, the centers of the vortices are seen coming closer to the diagonal joining edges of the moving wall as the Reynolds number increases. Table 1 shows the location of the centers of the vortices for the four-sided lid-driven cavity flow at various Reynolds numbers. In general, the vortices move nearer to the diagonal joining edge of the cavity as the Reynolds numbers increase. For comparison of the locations of the vortices from Re = 10 to Re = 100, the TPV is moving to the right and slightly downwards which is at (0.559,0.845) and the RPV is moving upwards and slightly to the left at (0.845,0.559). On the other hand, the BPV and LPV are moving in opposite directions to the TPV and RPV respectively.
Table 2 shows the values of the dimensionless streamfunction at the centers of the vortices at various Reynolds numbers. The table shows that at certain Reynolds numbers, the streamfunction values are the same in magnitude but may have positive or negative values. A negative value indicates that the vortex is moving in a clockwise direction, while a positive value indicates the anti-clockwise direction. The streamfunction values at the TPV are -0.06553,-0.07046 and -0.07273 for Re = 10, Re = 100 and Re = 127 respectively. This shows that the magnitude increases as the Reynolds numbers increase.
Figure 6 shows the velocity profile along the centerline of the cavity for Re=10, 100 and 127. Generally, it can be said that as the Reynolds number increases, the pattern of the profile is the almost the same, with only a slight quantitative difference. The maximum velocity magnitude is at the wall of the cavity due to the movement. As we move to the center, the magnitude and direction of the velocity change as the flow circulation happens. The present work is then compared to Perumal and Dass (2011) with respect to the centers of the vortices, and shows good agreement. Table 3 shows a comparison of the centers of the vortices at TPV, BPV, LPV and RPV from the present work with Perumal and Dass (2011) at various Reynolds numbers. For the whole range of Reynolds numbers, the locations of the vortices show good comparison results.
CONCLUSIONS
A four-sided lid-driven cavity was studied numerically by using the Adams-Bashforth scheme with a time splitting method. It shows that the vortices move nearer to the diagonal joining edge of the cavity as the Reynolds numbers increase. A comparison of the location of the centers of the vortices showed similar results.
ACKNOWLEDGMENTS
The authors would like to thank the Universiti Teknologi Malaysia and Ministry of Higher Education, Malaysia for sponsoring this research. This research is supported by research grant Vot. 4F114 and 4L074.
REFERENCES
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C. S. N. Azwadi*, A. Rajab and A. Sofianuddin
Faculty of Mechanical Engineering, Universiti Teknologi Malaysia
81310 Skudai, Johor, Malaysia
*Email: [email protected]
Phone: +607-5534718; Fax: +607-5566159
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Copyright Universiti Malaysia Pahang Jan-Jun 2014
Abstract
In this paper, a second order Adams-Bashforth method is proposed to simulate four-sided square lid-driven cavity flow. The convective term and diffusive term in Navier-Stokes equations are solved using a finite central difference scheme and the unsteady term is solved using the Adams-Bashforth method. All of the flow is simulated at below critical Reynolds numbers in a square cavity with an isothermal condition and the same speed for all walls. In this study, the flow structure for a four-sided lid-driven cavity with its four vortices and a graph of the velocity profile along the center of the cavity are presented. In addition, we also study the effect of the Reynolds number on the development of vortices in the cavity. We find that the Reynolds number has a dominant effect on the flow structure in the cavity. The computed results also show good agreement with the published data.
You have requested "on-the-fly" machine translation of selected content from our databases. This functionality is provided solely for your convenience and is in no way intended to replace human translation. Show full disclaimer
Neither ProQuest nor its licensors make any representations or warranties with respect to the translations. The translations are automatically generated "AS IS" and "AS AVAILABLE" and are not retained in our systems. PROQUEST AND ITS LICENSORS SPECIFICALLY DISCLAIM ANY AND ALL EXPRESS OR IMPLIED WARRANTIES, INCLUDING WITHOUT LIMITATION, ANY WARRANTIES FOR AVAILABILITY, ACCURACY, TIMELINESS, COMPLETENESS, NON-INFRINGMENT, MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Your use of the translations is subject to all use restrictions contained in your Electronic Products License Agreement and by using the translation functionality you agree to forgo any and all claims against ProQuest or its licensors for your use of the translation functionality and any output derived there from. Hide full disclaimer