Lagrangian and Eulerian pressure field evaluation of rod-airfoil flow from time-resolved tomographic PIV

Curle’s aeroacoustic analogy (1955), an extension of Lighthill’s theory (1952), accounts for the noise production from solid objects interacting with an unsteady flow. In the analytical formulation for low Mach number, the acoustic pressure fluctuation in the far-field region is a function of the time rate of change of the pressure fluctuation integral on the surface of the body caused by the interaction with the flow. This means that the surface pressure distribution has to be measured in time to evaluate the pressure fluctuation in the acoustic domain.

The instantaneous pressure field p can be inferred from the measurement of the time-resolved velocity field according to the incompressible (\(\rho\,=\,\hbox{const}\)) Navier Stokes equationswhereis the material acceleration. This can be computed either by means of Eq. (2) with an Eulerian approach, as proposed by Baur and Kongeter (1999), or with the Lagrangian approach (Liu and Katz 2006). The suitability of both schemes for the accurate evaluation of the pressure gradient distribution is currently under discussion (de Kat and van Oudheusden 2010), of which an experimental study is provided in the present paper.

Also, the pressure gradient spatial integration in a planar domain has been approached in different ways. Liu and Katz (2006) proposed an omni-directional virtual boundary integration algorithm, instead van Oudheusden et al. (2007) used a direct 2D integration technique based on the work of Baur and Kongeter (1999). Later, the same authors, referring to the work of Gurka et al. (1999), reverted to the use of Poisson equation,which has demonstrated superior accuracy and showed to be less prone to localized error propagation (de Kat et al. 2008). In the latter Neumann boundary conditionsare applied, whereas Dirichlet conditions are assigned where p is known either by a direct measurement or by invoking Bernoulli’s equation in region of steady and irrotational flow:

The evaluation of the sound source integral of the Curle’s analogy (1955) would require the measurement of the surface pressure distribution along the entire airfoil span. However, despite the fact that thin-volume TOMO PIV enables the velocity measurement over a limited airfoil span-wise, it is relevant to evaluate the effect of the 3D-flow features on the pressure field, which is obtained under the hypothesis of 2D flow if based on planar PIV measurements. Furthermore, the scheme used for the evaluation of the material velocity derivative is studied in relation to the measurement accuracy. Therefore, experiments need to be conducted at sufficiently high temporal resolution in order to be able to decouple the effects of the latter from the above ones.

The material derivative evaluation along a fluid particle trajectory can be performed only if the time evolution of three-component velocity vector is measured inside a volume, such as obtained by TR-TOMO PIV. In particular, between two time instants t ₁ and t ₂, the 3-D trajectory \(\Upgamma\) (see Fig. 1) can be reconstructed only between P ₂ and P ₃, that is inside the measurement domain \(x_{V}\times y_{V}\times z_{V}\). On the other hand, the reconstruction of \(\widehat{P_{1}P_{2}}\) and \(\widehat{P_{3}P_{4}}\) is done respectively using the measurement performed on adjacent fluid particle trajectories \(\Upgamma ''\) and \(\Upgamma '\) that are inside the measurement volume when \(\Upgamma\) is, respectively, still or already out (see trajectory projections \(\Upgamma^{\prime\prime}_{XZ}\) and \(\Upgamma^{\prime}_{XZ}\)). Thus, for a planar measurement, the reconstruction of 3D-flow trajectories is not possible (Liu and Katz 2006).

Substituting (2) in (1), it follows that the planar pressure gradient reads as In the above equations, the viscous term is not included as commonly assumed in other studies at Re > 10³ (Haigermoser 2009; de Kat et al. 2009; Koschatzky et al. 2010; Lorenzoni et al. 2009).

It is observed that planar measurements of 3D flow, providing two- or three-component velocity vector fields, result in an approximated evaluation of the planar pressure gradient distribution. On the contrary, tomographic ones return the complete velocity vector and the complete velocity gradient tensor, in turn enabling the determination of the pressure gradient under more general hypotheses.

The MART algorithm (Herrmann and Lent, 1976), which is implemented in LaVision Davis 7.4, is used to reconstruct the 3D-light intensity field. A total of 5 iterations of the algorithm are performed with a diffusion parameter of 0.5 for the first three.

Prior to the volume reconstruction, the 3D calibration function is corrected by the volume self-calibration to minimize the disparity fields, decreasing in the calibration error from a typical value of 0.5–0.1 pixel (Wieneke 2008). The accuracy of the reconstruction object is improved by means of image pre-processing with background intensity removal and non-linear subsliding minimum subtraction (11 × 11 kernel size).

Volumes of \(50 \times 50 \times 3\,\hbox{mm}^{3}\) discretized with 831 × 831 × 50 voxels are then obtained applying a pixel to voxel ratio of 1. The resulting voxel size is 59 \(10^{-3}\,\hbox{mm}/\hbox{vox}\).

The a-posteriori evaluation is made by means of the analysis of the reconstructed object intensity levels. The particle average peak intensity in a cross-section of the volume is displayed in Fig. 7 (left) from which it can be deduced that light is concentrated within 50 voxels (≈3 mm) at a slight angle with respect to the calibration plane. The reconstructed region is sketched along the boundaries of the illuminated region. The peak intensity profile is extracted and normalized (Fig. 7 right), yielding a signal-to-noise ratio (SNR) above 2 within a thickness of 30 voxels (1.8 mm) where, therefore, the measurement is considered reliable.

Three-dimensional particle field motion is computed by spatial cross-correlation of pairs of reconstructed volumes with VODIM software (Volume Deformation Iterative Multigrid, developed at TU Delft), an extension to volumetric intensity fields of the window deformation technique for planar cross-correlation (Scarano and Riethmuller 2000). Interrogation boxes of size decreasing from of 201 × 201 × 21 to 47 × 47 × 19 and 75% overlap between adjacent interrogation boxes produce a velocity field measured over a grid of 66 × 66 × 6 points. At the given particle concentration, an average of 50 particles are counted within the smallest interrogation box.

Data processing is performed by in parallel with a dual quad-core Intel Xeon processors at 2.66 GHz with 8 GB RAM memory requiring 2 and 2.5 min for the reconstruction of a pair of objects and 3D cross-correlation, respectively. Noisy fluctuations of the velocity vectors are reduced by applying a space–time regression, a second-order polynomial least-square fit over a kernel of 5 spatio-temporal samples (Scarano and Poelma 2009).

As the velocity domain is rather thin (just 6 measurement points along z-axis), the Lagrangian evaluation of the material derivative and, as consequence that of the pressure, is done on the mid z-plane of the domain where it is less likely that the fluid particles exit the domain at a given \(\Updelta t_{\hbox{{min}}}<\Updelta t<\Updelta t_{\hbox{{max}}}\) (see Sect. 2.2.1). In particular, the integration is performed on the third z-plane where regions affected by measurement noise are avoided. In Fig. 8, the integration domain is sketched and the Neumann and the Dirichlet boundary conditions are specified.

In the region in front of the airfoil (\(x/c \le 0;0.04 \le y/c \le -0.08\), Fig. 9), the mean flow is characterized by a decrease of u-velocity component leading to the stagnation point where the vertical velocity component rises in magnitude identifying a region of upward acceleration and one of downward. Flow symmetry is observed for the w-component which is affected by measurement errors not exceeding 1% of U _∞. From contours of turbulent kinetic energy,(see Fig. 9), intense turbulent motion is detected ahead of the airfoil in the region corresponding to the von Kármán wake shed from the rod.

The wake is constituted by counter-rotating vortices which interact with the airfoil leading edge, as shown in the sequence of snapshots of Fig. 13 (first row) by contours of the out-of-plane vorticity component. Time instant t is normalized with respect to the shedding period T yielding t* = t/T.

Measurements performed in the region corresponding to the laser shadow (in gray, see Fig. 9) are not reliable and therefore are avoided from the analysis. Additionally, velocity derivatives are not performed near by the boundaries of the measurement domain since velocity vectors are typically affected by noise (in gray, see Fig. 13).

From dimensional analysis discussed in Sect. 2.2.1, it results that, in order to limit the relative precision error to 10% maximum, ensuring that the z-displacement of the trajectory is shorter than z _v  = 30 voxels, the time separation to be used for the Lagrangian evaluation of the material acceleration must be chosen between 0.6 and 1.5 ms, according to Eqs. (18 and 19). In contrast, with respect to the estimation proposed in Sect. 2.2.2, when the Eulerian approach is used, the time separation must not be larger than 0.3 ms. This conflicts with the condition of velocity measurability, \(\Updelta t\ge 0.6\,\hbox{ms}\) (see Eq. (18)), and it leads to material acceleration affected by 20% in precision error.

Time separation constraints estimated for both the approaches are now verified by an a-posteriori analysis. Using the standard deviation \(\sigma_{\Updelta u}\) as an estimate of the typical velocity variation within \(\Updelta t,\left (\frac{DV}{Dt} \right )_{\hbox{{ref}}}\) of Eq. (14) can be rewritten asIn the above, velocity variations are evaluated along fluid particle trajectories when the approach is Lagrangian, or at fixed point when it is Eulerian.

The last step of the procedure consists in the spatial integration of Eq. (3) on the mid z-plane. In Fig. 14 (first row), the sequence of pressure fluctuation contours corresponding to those of vorticity is depicted to highlight the relation between cinematic and thermodynamic field. They are evaluated by means of the Lagrangian approach employing multi-step scheme with \(\Updelta t=1.2\,\hbox{ms}\).

Compared to those obtained by the Lagrangian method, the pressure fields evaluated by means of the Eulerian approach with \(\Updelta t= 0.4\,\hbox{ms}\), as illustrated in Fig. 14 (first and second row), show differences in the contour patterns, although less marked than those observed for the material derivative (Fig. 13). To have a more quantitative understanding of the influence of the two approaches on the pressure field, the pressure time histories at point B corresponding to those of material acceleration of Fig. 10 (bottom) are plotted in Fig. 12. Similarly to what observed for the material acceleration, when a time separation of 0.4 ms is employed, both the approaches lead to oscillating results with comparable values of standard deviation. In the Lagrangian approach, an increase in \(\Updelta t\) from 0.4 to 1.2 ms leads to a reduction in standard deviation of the pressure signal of 30%, similarly to what observed for the material acceleration. By contrast, in case of the Eulerian approach, the drop is of 25%, which is approximately the double of the reduction observed for the corresponding material acceleration. This smoothing effect might be due to the integration method, on which no further investigation has been conducted within this paper.

A synchronous planar and tomographic PIV measurement is simulated in order to evaluate 3-D flow effects on the pressure field. Volumes of 831 × 831 × 17 voxels, corresponding to \(50 \times 50 \times 1\,\hbox{mm}^{3}\) are extracted from the central z-position of the reconstructed tomographic objects. The imaged particle intensity levels are summed along z in a Gaussian way and are cross-correlated with interrogation windows of size identical to the x-y dimensions of the interrogation boxes (see Sect. 3.2). An average of 50 particles are counted in the smallest interrogation window.

A Lagrangian approach is used to evaluate the material acceleration. This, however, is evaluated along the projection of particle trajectories on the measurement plane, as only two velocity components can be measured by planar PIV.

Three- and two-dimensional-based material acceleration and pressure fluctuation show similar pattern, as illustrated in Fig. 15 where the flow quantities are plotted along y/c = −0.125 at t* = 0.72 (see Figs. 13 and 14). In general, the similarity is observed at each point of the integration plane and for all the time instants.

To further investigate the effect of flow 3-D on the Lagrangian approach, tomographic PIV data of a cylinder wake at Re = 540 are used. The attention is focused upon a subregion of 61 × 48 × 27 measurement points containing a vortex, which is located 5 cylinder diameters (d _R ) downstream. Details of the experiment are given in Scarano and Poelma (2009).

Compared to TOMO-PIV measurements obtained in thin-light volume configuration, the ones performed on the cylinder wake enable the evaluation of the pressure field also on planes which are not aligned with the dominant flow direction. As each shedding cycle is sampled approximately 9 times, the evaluation of the material acceleration is performed by single-step scheme (LO) without any substantial rise in truncation error (see Sect. 4.2.1). The pressure field is integrated on the planes y/d _R  = 5 and z/d _R  = 0 using the corresponding planar subsets of two-component velocity (respectively called as 2Dy and 2Dz) and the tomographic data (3D). 2Dy-, 2Dz- and 3D-based material acceleration and pressure field are compared along the intersection of the aforementioned planes (see Fig. 16). In case of 2Dy subset, errors are typically smaller than 20% similarly to what observed for the rod-airfoil flow. In contrast, if the planar subset is not parallel with the y-plane, which is the dominant direction of flow, the error increases, meaning of a larger influence of the out-of-plane velocity component on the trajectory reconstruction. On plane z/d _R  = 0, for example, the 2D-based evaluation lead to an error of 100%. Similar behavior is observed for the pressure field which is integrated assigning boundary condition of Dirichlet \(\Updelta p=\) 0 at point (x/d _R  = 4.71, y/d _R  = 5, z/d _R  = 0) and Neumann along the domain boundaries. Moreover, 3D-based pressure fluctuation evaluated on plane y/d _R  = 5 and on plane z/d _R  = 0 (respectively 3Dy and 3Dz, see Fig. 16 right) show small differences, as a result of the error introduced by the pressure integration method.