Abstract

Numerical investigation of correlation between the fluid particle acceleration and the intensity of turbulence in swirling flows at a large Reynolds number is carried out via direct numerical simulation. A weak power-law form correlation between the Lagrangian acceleration and the Eulerian turbulence intensity is derived. It is found that the increase of the swirl level leads to the increase of the exponent φ and the trajectory-conditioned correlation coefficient and results in a weak power-law augmentation of the acceleration intermittency. The trajectory-conditioned convection of turbulence fluctuation in the Eulerian viewpoint is generally linearly proportional to the fluctuation of Lagrangian accelerations, indicating a weak but clear relation between the Lagrangian intermittency and Eulerian intermittency effects. Moreover, except the case with vortex breakdown, the weak linear dependency is maintained when the swirl levels change, only with the coefficient of slope varied.

1. Introduction

As well known, the swirling flow, especially for the strongly swirling jets at large Reynolds numbers to which few studies were devoted, is one type of anisotropic turbulence, which is less understood than the homogenous and isotropic turbulence [1, 2]. In the past decades, the swirling flows have been studied extensively under the Eulerian framework, including a variety of scientific research topics and industrial applications, for example, swirling recirculating flow field [3, 4], open Von Kármán swirling flow [5], gas-liquid cylindrical cyclone [6], gas-liquid two-phase jet flow [7], gas turbine combustor [8], and so on. However, the swirling flows based on the Lagrangian framework have not been well investigated. Referring to the recent investigations of Lagrangian acceleration in highly turbulent flows [9, 10], the turbulent anisotropic flows with either a swirling or a rotating flow pattern are of specific interest. Unfortunately, the characteristics of Lagrangian acceleration for highly swirling flows are still not well known.

Moreover, due to the fundamental importance of the Lagrangian characteristics of fluid particle motion to transporting and mixing in turbulence and reacting systems [11], the Lagrangian measurement/modeling method has been well used recently as it is a powerful approach for improving the understanding of turbulent flows [12, 13]. Therefore, a large number of excellent studies have been carried out contributing to the Lagrangian characteristics of fluid particle motion, especially on the acceleration structure or Lagrangian velocity spectrum [14–18].

On the other hand, as the investigations of turbulence under the Eulerian frame are better developed than those under the Lagrangian frame, establishing the relationship between the Lagrangian statistics and Eulerian statistics should be helpful in determining the common intrinsic statistical features of turbulence. However, the joint Lagrangian and Eulerian statistics of fluid particles are not well understood yet. For example, the relationship between acceleration intermittency (from the Lagrangian viewpoint) and turbulence intensity (from the Eulerian viewpoint) is unknown.

Additionally, to carry out direct numerical simulation of strongly swirling jets at a larger Reynolds number is a state-of-the-art challenging work. Thus, direct numerical simulation of the strongly swirling jet is very essential and important to the scientific research of anisotropic turbulence.

In conclusion, a numerical study of direct numerical simulation of the Lagrangian motion of fluid particles at large Reynolds numbers is performed in present study, where the Lagrangian statistics and Eulerian statistics are combined together. The main aim of this study is to show the dependence of correlation between fluid particle acceleration and the intensity of turbulence on various levels of swirls and show the correlation between the Lagrangian acceleration and Eulerian convection of turbulence fluctuation in strongly swirling jets at a large Reynolds number.

2. Numerical Description

2.1. Governing Equations

The Navier-Stokes equations for incompressible fluids, based on the conservation laws of mass and momentum, are formulated in dimensionless forms as follows:(1)continuum equation: ,(2)momentum equation: .To solve the governing equations, the finite difference method is applied. The upwind compact schemes [19] are used to discretize the convection term. The fourth-order compact difference schemes [20] are applied for space derivatives and the pressure-gradient terms. The third-order explicit schemes are used to deal with the boundary points, keeping the global fourth-order spatial accuracy. The fourth-order Runge-Kutta schemes [21] are used for time integration. The pressure-Poisson equation is solved to obtain the pressure via using the fourth-order finite difference method [22]. The methods have already been successfully applied in my recently published literature [23].

2.2. Simulation Setup

The parameters used in the present simulation are listed in Table 1. In the momentum equation, the Reynolds number is defined as , where is the axial inlet velocity; is the Taylor microscale; and the kinematic viscosity  () (water at 20.3°C).

The configurations of swirling flow are illustrated in Figure 1(a), which are similar to those from an earlier study [24]. A round jet of diameter is imparted with a rotational azimuthal velocity at the inlet and issued into a rectangular flow domain of . The swirl level is the ratio of the maximum azimuthal velocity to the streamwise velocity ; that is, [25]. The axial and azimuthal inlet velocity profiles are the same as those mentioned in earlier studies [24, 26, 27] (Figures 1(b) and 1(c)). No inflow disturbance is introduced to keep the intrinsic feature of the strongly swirling flow. Three swirl numbers, that is, , 1.08, and 1.42, are simulated in the present study by varying the azimuthal velocity. The nonreflecting boundary condition is utilized for the outlet condition [28], and the side walls are set to be nonslipping wall boundaries.

The flow domain is discretized by Cartesian mesh grids. With this spatial discretization ( μm), the jet inlet area () is covered by 1791 mesh grids. It is estimated that the Kolmogorov length scale is about , which is in the same order of the finest mesh scale. According to [29], it is fine enough to capture the smallest scale of turbulence. For time integration, the time step is  μs and the total simulated time is  ms, about three convective periods.

The particles issued from the 1791 grid points inside the jet inlet area are traced, and, for each grid point, one particle is issued into the flow domain every 200 time steps. In this way, a total number of 179,100 fluid particles are traced in this study. The fluid particles originated from these 1791 points are designated as , , where is the particle number and designates the group number. Then, all the particles can be divided into 1791 groups. Each group has the same initial location and velocity. However, the trajectories of fluid particles within each group are not the same because the system of fluid flow dynamics is strongly nonlinear. An ensemble average over each group of particles is utilized to carry out the Lagrangian statistics. For each group, the instantaneous acceleration for 100 particles is traced and recorded at any time for analysis. Thus, each data group includes ~O (106) points. The ensemble average process should be statistically reliable over such a large number of data points.

3. Results and Discussions

3.1. Fluid Vortex Structures and Particle Trajectory

The typical vortex structure of is visualized in Figure 1(a). It is clearly seen that a bubble region is enclosed by the nearly axisymmetric vortices, forming an open angle toward downstream. It is so called the central recirculation zone (CRZ) or vortex breakdown (VB). Moreover, strong small vortices are observed due to the highly turbulent and swirling fluid flow.

Corresponding to this type of vortex structure, the fluid particles are transported from the initial locations to the downstream. The trajectories of one typical group of fluid particles originated from the same initial location at the inlet of the flow are shown in Figure 2. It is found that the fluid trajectories enclose a bubble region statistically too, which are initiated from the location where the axial motion of fluid particle is decreased to zero, that is, the stagnation point. After that, an immediate expansion in the lateral and spanwise directions is established. This feature of fluid trajectory reflects the structural characteristics of swirling flow under the Lagrangian viewpoint.

3.2. Joint Distribution of Acceleration and Turbulence Intensity

In general, the velocity field depends on the location and time, that is, , where “” denotes the “Eulerian” viewpoint. To average in time, the velocity field can be divided into a time averaged part and a fluctuation part , corresponding to the mean flow field and the turbulent fluctuation field, respectively. Hence, the root mean square (RMS) values of velocity can be used to evaluate the local intensity of turbulence at location . On the other hand, the motion of fluid particles can be traced under the Lagrangian framework. The velocity and acceleration of the traced particles are defined as and , respectively, where denotes the fluid particle and “” denotes the “Lagrangian” viewpoint. In this way, the statistical characteristics of Lagrangian motion of fluid particles with regard to the acceleration , velocity , and trajectories are obtained for analysis.

Assuming a “steady” turbulence field is reached, the turbulence intensity field can be quantified using the time-averaging method. The fluid particle moves through the “steady” turbulence field with temporally and spatially varied Lagrangian acceleration of . Focusing on and on the particle trajectories, a joint distribution of can be obtained for analysis via the Eulerian-Lagrangian joint statistics of turbulence. It is termed as the trajectory conditioned joint distribution here.

As shown in Figure 3, the trajectory conditioned distribution of for different levels of swirl is indicated. Every point in Figure 3 illustrates the pair of on the trajectories which the th group particles go through. Zonal distributions are observed for , 1.08, and 1.42, with the widths being increased under larger swirling levels. Thus, it is indicated that the and are correlated in some manner. Generally, this correlation may follow the form of power-law . Note that the linear relationship is also included in the power-law, provided . Based on this assumption, the data are fitted by the near power-law expression.

The log-log distribution of and for is illustrated in Figure 4. The trend of the log-log plot is approximately linear, although the data points are scattered widely. As the data points are corresponding to all fluid particles within the flow, the distribution should be scattered due to the stochastic and turbulent fluctuations of particles. Moreover, it could indicate the intrinsic Lagrangian characteristics of turbulent swirling flows, especially for the general trends of distribution and the statistical relationships between and .

In addition, it is seen from Figure 4 that the slope of the fitting line increases when the swirl level increases. The fitting equations are listed in Table 2. By these fitted expressions, the relationship between the Lagrangian acceleration and the local Eulerian turbulence intensity is indicated to follow a weak power-law form Statistically, the turbulence intensity should be large where the fluid particles always pass through with large acceleration and vice versa. If the averaged turbulence intensity level is in the same order as that with the same Reynolds number and no extra disturbance, the effect of the swirl upon the Lagrangian characteristics could be achieved through a change in the exponent and coefficient . Hence, the characteristics of intermittency are closely related to swirl level and exponent . With the increase of swirl levels, the exponent becomes larger. Consequently, the Lagrangian acceleration is nearly power-exponentially increased, leading to the augmented characteristics of intermittency.

In addition, Figure 4 shows that the scope of distribution of can be generally sketched by an inferior line () and a superior line () (Table 3). The majority of the data points are restricted inside the sketched scopes. The superior and inferior limiting lines show the proper limiting cases of the near power-law joint distribution; that is,where the limiting exponent is about .

3.3. Turbulent Convective Effect versus Lagrangian Acceleration

On the other hand, the Lagrangian acceleration is formulated as . With , the Lagrangian acceleration is equivalent to the Eulerian acceleration. Thus, the nonlinear convective term plays a dominant role in correlation as well as the difference between the Eulerian statistics and the Lagrangian statistics of turbulence. Moreover, from the Eulerian viewpoint, , where is the time-averaged velocity and is the fluctuation velocity. Based on the order analysis, it is assumed that the term plays a leading role in turbulence convection. Under this assumption, it is appropriate to consider that the term represents the effect of convection of turbulence fluctuations. Remember that it is based on the Eulerian viewpoint. Then, moving with a Lagrangian fluid particle, it is natural to calculate the along the particle trajectory. We call it the trajectory-conditioned , namely, . In this way, the joint Eulerian and Lagrangian statistics on correlation between the convection of turbulence fluctuation and the Lagrangian fluctuation of particle acceleration can be performed.

Figure 5 shows the RMS values of and acceleration for in the , , and directions, respectively. One point within Figure 5(a) represents the results for one group of particles. It is seen that, for low swirl levels (), the RMS values are distributed nearly linearly. After linear regression, the fitted expression is . Moreover, it is observed from Figure 5(b) and Figure 5(c) that this nearly linear correlation also exists in the other directions; that is, and . It indicates the correlation between the convection of turbulence fluctuations and the Lagrangian acceleration fluctuations along the particle trajectory; namely, the large fluctuation of Lagrangian acceleration indicates the large fluctuation of Eulerian convection of turbulence and vice versa. As a result, although scattered widely, the trends of the scattering distributions show the statistical correlation between the Lagrangian intermittency effects, which corresponds to the extreme events of the largely fluctuated Lagrangian acceleration, and the Eulerian intermittency effects of turbulence fluctuations, that is, the extreme events of convection of turbulence fluctuations.

However, for large swirl levels (Figure 6, ), this linear correlation in the axial direction seems to be disturbed, since the data points are widely scattered within a local domain. In contrast, the nearly linear correlation also occurs in the other directions. Remembering the occurrence of recirculation phenomena in the axial direction within the bubble-breakdown region, it is appropriate to explain that the disturbance of linear correlation is due to the formation of bubble vortex breakdown—a dramatic change of the large scale flow structure. In this way, the correlation of Lagrangian intermittency effects as well as the Eulerian intermittency effects becomes complex. It is correlated in the lateral and spanwise directions and attenuated in the axial direction.

4. Conclusion

The present study focuses on the effect of swirl levels on the correlation between the Lagrangian and Eulerian evaluations of turbulence. The statistical correlations between the Lagrangian and Eulerian evaluations of turbulence are demonstrated. It is found that the Lagrangian acceleration follows a weak power-exponential form of augmentation by the increase of swirl levels, leading to the augmented characteristics of intermittency. Moreover, the fluctuations of and become increasingly correlated to each other with the increase of the swirl levels. Additionally, the Eulerian convection of turbulence fluctuations is weakly proportional to the Lagrangian acceleration fluctuations, indicating the proportionally close correlation between the Eulerian and Lagrangian intermittency effects.

Conflict of Interests

The authors declare that there is no conflict of interests regarding the publication of this paper.

Acknowledgment

The authors are grateful for the support of this research by the National Natural Science Foundation of China (Grant no. 51106180).