Numerical Investigation of Active Flow Control Around a Generic Truck A-Pillar

The numerical accuracy is ensured by performing the unactuated flow field simulation on three computational grids. The details of the meshes are summarised in Table 2. The number of computational cells of the coarse grid has been reduced by 40 % with respect the middle grid. The coarsening procedure affects only the streamwise and spanwise directions. Thus, the grid has not been coarsened in the wall normal direction. Table 2 shows the good agreement of the three simulations concerning the drag and side force coefficient. Figure 4a) show the chosen profiles’ locations along the body, while Fig. 4b shows the streamwise velocity profiles of both the fine, the middle and the coarse grids at the chosen locations. The chosen location correspond to the following x coordinates: x ₁/W = 0.48, x ₂/W = 1.12, x ₃/W = 1.76, x ₄/W = 2.4, x ₅/W = 3.04. Figure 5a and b shows the normalized \(\overline {u^{\prime }u^{\prime }}\) and \(\overline {v^{\prime }v^{\prime }}\) stresses respectively, at three different locations. The mean value of drag and side force, Table 2, and the good agreement between the streamwise velocity Fig. 4 and stresses Fig. 5 profiles, confirms that mesh independence is achieved. Thus the middle grid has been employed to carry out the study presented in the results section.

One single POD temporal coefficient can oscillate at different frequencies, while the Fast Fourier Transform (FFT) analysis represents the area of interest of the actual frequencies of the flow. It is interesting to compare the two approaches in order to gain a complete understanding of the flow structures in terms of both the energy content and characteristic frequencies.

The present POD is made of a equidistantly sampled pressure snapshots p ^m = p(x, t ^m ) at time t ^m = mΔt, m = 1,..., M with the time Δt, and a Cartesian coordinate system x = (x, y, z) with unit vectors e _x , e _y , e _z respectively.

As it was originally proposed by Lumley [29], this method is based on energy ranking of orthogonal structures computed from a correlation matrix of the snapshots. A Singular Value Decomposition (SVD) approach is used to conduct the POD analysis on the mentioned set of snapshots. In the present POD, the pressure is decomposed in the mean field, 〈p〉, and the fluctuating part, p ^′, as The fluctuating part is then approximated, by the SVD approach, with space dependent modes, p _i , and time dependent mode coefficient, b _i , as The definition can now be written in a more compact form if we consider that b ₀ = 1 and p ₀ = 〈p〉 following [30], The first and second moments of the POD modes coefficients are: The energy content of the single mode, K _i , is approximated from the mode coefficients as and the total energy, K _Σ(t), is evaluated as

In the present work, the POD study is performed over 1000 equispaced time steps and the non dimensional time step Δt ^⋆ between each snapshot is chosen as Δt ^⋆ = 1.28×10⁻². In the present POD, mode 1 represents the mean value of the flow field and it contains the largest amount of energy. Every travelling structure is represented by a couple of modes, containing the same amount of energy but shifted in time. For example the most energetic travelling structures is represented by the sum of mode 2 and 3, visualised as 1 ^{s t} pair in Fig. 8a. Figure 8b shows the temporal coefficients of mode 2 and 3, which are similar but shifted in time. The shifting is necessary to reconstruct the motion of the considered flow structures. The accuracy of the POD is ensured performing the calculation on three different sets of snapshots, Fig. 6. Both the energy content of the first 100 modes, Fig. 6a, and the time history of the first two temporal coefficients, Fig. 6b, does not differ excessively between the three sets of snapshots. This confirms that the chosen time window covered by the snapshots is large enough to capture the main features of the flow.

The magnitude of the velocity at the actuation region (red slot in Fig. 2), U _{a f c} , is defined by the time varying boundary condition as follows, where U _{i n f} is the magnitude of the free stream velocity, and f _a is the chosen actuation frequency. Two non dimensional parameters describe the performances of the actuation. The first parameter is the momentum coefficient C _μ . It is an indicator of the energy spent for the actuation with respect to the energy of the unactuated flow. Here W _{a f c} = 0.012m is the width of the actuation slot. C _μ has a low value but sufficient to excite the thin boundary layer that characterizes the attached flow before the separation. All the frequencies in the present work are described in terms of the second non dimensional parameter, the reduced frequency F ⁺ (also called actuation Strouhal number). Here f represents the frequency in Hertz and L _{r e c} = 6.5m is the measured length of the recirculation bubble measured in the unactuated flow, Fig. 7.

The unactuated flow field was first studied to get a better understanding of its main features.

The POD performed on the unactuated flow is able to reproduce the main features of the flow. Figure 8a shows the energy content of the first 50 pressure modes with respect to the considered time interval. Mode 1 corresponds to the averaged flow field and it is the mode that contains the most energy. Figure 8a shows also that neighbouring modes contain the same amount of energy in pairs. Each pair of modes, with the exclusion of mode 1, describes the characteristic travelling structures acting in the flow domain. Figure 9a and b depicts a reconstruction of the pressure field by characteristic modes in comparison with the instantaneous pressure flow field, Fig. 9c. Figure 9 clarifies the conduct of the flow mentioned in the introductory section and widely described in [21]. Both the small structures at the front and the larger structures at the side are captured by two different pairs of modes, Fig. 9a. In merging the modes, a reconstruction in both time and space of the flow structures is observed, Fig. 9b. The POD separates the eddies which describe the detached shear layer (pair 7) from the eddies of the side region (pair 1). The shear layer eddies contain a much smaller energy content but they are fundamental for the dynamic of the flow. As it will be described in the following section, the actuation acts directly on the separated shear which can drastically shape the separated flow region. An FFT analysis conducted on the same set of snapshots indicates the spatial distribution of the most important frequencies describing the flow field. FFT is applied to each cell of the observed domain (Fig. 2c). Figure 10 highlights the differences in energy and space distribution of two different flow structures. The POD results (Fig. 10a and b) are compared against the FFT results, Fig. 10c. Figure 10c clearly shows that structures moving at F ⁺ = 1.4 have a larger energy content and space distribution (side region structures), while F ⁺ = 13 is only visible in a limited area and its energy is considerably lower (separated shear layer eddies). Figure 10b shows the PSD and the orbit plot of the corresponding temporal modes. In particular the orbit plot describes the time history of the time coefficients and highlights their possible periodicity. The periodicity of the time coefficients is strong and remarks the regular recurrence of the described structures. The spatial distribution of POD structures (Fig. 10a) and the frequency of its temporal mode (Fig. 10b) match well with the spatial distribution of the corresponding frequency extracted from the FFT analysis (Fig. 10c).

Before studying the effect of the actuation frequency on the flow, different directions of the actuation are tested. The normal actuation with respect to the local direction of the flow, direction k shown in Fig. 11a, is the most effective in terms of drag reduction, Fig. 11b. When the direction of the actuation forms an angle of 20^∘ with respect to the tangent of the model’s surface, direction j the performance are worsen, in particular the mean value of the drag coefficient increases with respect to the previous direction k. Thus, the normal actuation was kept for all the actuated configurations. The results shown so far describe the main features of the unactuated flow. Two main dynamics depict the flow: the separated shear layer eddies which move at a high frequency and the side region which contains low frequency structures (highlighted by the 7 ^{t h} p a i r and 1 ^{s t} p a i r of modes respectively, Fig. 9a). Even if the energy content of the first group of eddies is very low compared to the energy of the second one, their dynamic affects strongly the side region as will be explained in the following section. The drag coefficient history, Fig. 12a and its FFT plot, Fig. 12b, highlight significant frequencies in a range from F ⁺ = 0.6 to F ⁺ = 30. Thus, four different configurations are selected for the actuation: case 1 actuated at F ⁺ = 2.5, case 2 at F ⁺ = 5, case 3 at F ⁺ = 10 and case 4 actuated at F ⁺ = 20.

An optimal actuation is found in terms of induced fluctuations and drag reduction. The actuation introduces artificial oscillations in the flow, visible from the Root Mean Square (RMS) values of the drag, Table 3. The maximum drag reduction and minimum induced oscillations are observed for case 3, Table 3. Nevertheless, a deeper study of the instantaneous flow field is needed to gain a better understanding of the mechanisms that lead to the optimal configuration. Figure 13 shows how the actuation frequency affects the flow around the body. Figure 13a shows the spatial distribution of the actuation frequency for each case, respectively. The area characterized by the actuation frequency decreases, increasing the actuation frequency. Figure 13b shows the averaged value of the flow energy over the observed domain. Cases 1 and 2 show a clear peak defined by the actuation frequency. The energy of the actuation decreases for case 3 with respect to lower frequencies of the flow; the broader spectrum of case 3 defines that the actuation frequency is not clearly dominant. Noteworthy is also the drastic decrease of the overall flow energy in case 3 (see also Fig. 18 and Table 4). The POD results in Fig. 14 show the same results as shown in Fig. 13. Increasing the actuation frequency, the first most energetic mode decreases its area of interest, Fig. 14b, and its energy content in comparison to the other modes, Fig. 14a. Figure 14c shows the orbit plot of the corresponding temporal coefficients for cases 1, 2 and 3. All cases but the fourth, present a strong periodicity of the first pair of modes defined by the actuation frequency. In case 4, Fig. 15, the first pair of modes does not represent the actuation frequency as for the previous cases. The most energetic structures are large and defined by a low frequency (F ⁺ = 2). Only in the 4 ^{t h} pair is visible a trace of the separated shear layer structures defined by F ⁺ = 20 (the actuation frequency). The signal of the coefficient of drag, C _d , depicts the trend of the drag, increasing the actuation frequency (Fig. 16). Figure 16 shows C _d and its FFT for four different actuated cases. As was mentioned before, an optimal actuation frequency is found and shown in Fig. 16. The increase in the actuation frequency does not always benefit the aerodynamic performance of the model. In particular, case 4 shows an increase in both the induced fluctuation and mean value of the drag. Figure 16b shows how the induced fluctuation has less energy compared to the lower fluctuations of the flow. As was observed in Fig. 13b, a broader spectrum of characteristic frequencies is visible in Fig. 16b case 3, while all the other cases present a distinct peak at the actuation frequency. Figure 17 shows a zoom of the coefficient of drag in comparison with the sinusoidal actuation signal. The actuation signal represents the ZNMF actuation. In Fig. 17 the mean value of the actuation signal (dashed line) is shifted from the real zero mean value in order to compare it to the drag coefficient. Figure 17 clearly shows the difference in the dependency of the drag from the actuation. C _d of cases 1 and 4 shows a strong dependency from the actuation. C _d of case 2, and especially case 3, shows a weaker dependence from the actuation. In the latter case, the actuation is not able to force the drag signal following its oscillations, benefitting the overall performance. Furthermore, the integral energy level of the pressure flow field increases from case 3 to case 4, Fig 18 and Table 4. Figure 18 and Table 4 show how the 4 ^{t h} actuation brings more energy to lower frequencies of the flow, increasing the integral level of energy, thus the mean drag value. This seems to be in contrast with the results in Figs. 14 and 15. Previously was shown that an increase of F ⁺ is followed by a decrease of the influence of the actuation on the overall flow. In particular the energy of the mode representing the actuation decreases by increasing F ⁺. On the other hand the energy is not the only parameter that defines a flow. The dynamic of the interaction between the shear layer and the side region structures clarifies the elusive result of case 4 found in the C _d analysis. Figure 19 shows the instantaneous pressure field for the four different configurations. The low pressure areas at the front part indicate the cores of the Kelvin-Helmotz vortices that arise after the separation at the A-pillar. All V _{a f c i} are forced by the actuation which defines their frequency, position and dimension. Cases 1 and 2 present larger vortex cores. In these configurations, the vortex has time to develop into larger structures (between an actuation period and its subsequent), V _{a f c1} and V _{a f c2}. The first three cases present a definite trend; increasing the frequency, the dimension of V _{a f c i} decreases, and the vortex remains more attached to the surface of the body. As it was discussed in the preliminary study section, the flow topology is depicted by the motion of the separated shear layer which interacts with the side region larger eddies. The actuation intervenes directly on the shear layer and defines the frequencies and dimensions of its eddies. In the first three cases the interaction is strong, the actuation is dominant and the shear layer forces the side region to lock in with its own frequency. In other words the eddies forming the shear layer and the side region move at the same frequency (forced by the AFC), while affecting a smaller portion of fluid region moving from case 1 to case 3. Case 4 eludes from the described path. Two different eddies are visible: V _{a f c4}, which defines the shear with the actuation frequency and a larger eddy V _k4, responsible for the increase of the drag’s mean value visualized in Fig. 16. In the latter case the shear layer eddies are (as for the unactuated flow) separated by dimension and frequency from the side region structures. Indeed, the shear does not lock in the side region eddies. In this case, large oscillations, comparable with case 1, are visible in the C _d signal. The oscillations in case 1 are introduced by the large actuation period that allows V _{a f c1} to separate and develop periodically. The core of V _{a f c1} remains close to the surface of the model, yet being large. In case 4 instead, the high momentum that is introduced forces the flow to separate and reattach at the actuation slot, characterizing the drag oscillations. V _{a f c4} is smaller than V _{a f c1} but at the same time more distant from the surface. This fact allows the formation of a new and larger vortex, V _k4, that characterizes the mean value of the drag, widening the recirculation bubble, Figs. 20 and 21. An interpretation of the flow topology is given in Fig. 20. In the unactuated case the shear layer eddies (red) are visible after the separation, and the side region contains large structures (black) responsible of the large separation bubble (green). In case 3 the shear layer is able to lock in the motion of the side region avoiding the formation of larger structures. The last case, case 4, presents smaller eddies at the shear layer which are not able to sustain the lock in and allow the rise of larger structures which widen the recirculation bubble. Both instantaneous and averaged streamwise velocity flow fields are presented in Fig. 21. The reduction of the recirculation bubble is clearly in favour of case 3. Case 4 shows that further increase of actuation frequency, beyond that in case 3, is not beneficial. Indeed, Fig. 22 describes the trend of the flow behaviour increasing the actuation frequency. The actuation frequency is increased from case 1 to 4, (blue line in Fig. 22), and both C _d and C _{d, R M S} trends show a minimum for case 3. In particular, a drag reduction of 34 % with respect to the unactuated case is observed in case 3. The C _{d, R M S} value evaluated in case 3 decreases by 62 % with respect to the drag fluctuations of case 1.

Noteworthy is the connection found between the actuation frequencies and the frequency of the unactuated shear layer. When the actuation has a frequency lower than the unactuated shear layer, the latter is able to lock in the structures of the side region with its own frequency, obtaining a better result the closer is the actuation to the unactuated shear frequency (F ⁺ = 13). On the other hand, actuating with a higher frequency (F ⁺ = 20) the shear layer cannot sustain the lock in and the overall performances worsen.