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Author(s):  
Zhixing Mei ◽  
Qiangwei Cai ◽  
Jing Ye ◽  
Yan Li ◽  
Bojing Zhu

Extreme ultraviolet (EUV) disturbances are ubiquitous during eruptive phenomena like solar flare and Coronal Mass Ejection (CME). In this work, we have performed a three-dimensional (3D) magnetohydrodynamic numerical simulation of CME with an analytic magnetic fluxrope (MFR) to study the complex velocity distribution associated with EUV disturbances. When the MFR erupts upward, a fast shock (FS) appears as a 3D dome, followed by outward moving plasma. In the center of the eruptive source region, an expanding CME bubble and a current sheet continuously grow, both of which are filled by inward moving plasma. At the flanks of the CME bubble, a complex velocity distribution forms because of the dynamical interaction between inward and outward plasma, leading to the formation of slow shock (SS) and velocity separatrix (VS). We note two types of vortices near the VS, not mentioned in the preceding EUV disturbance simulations. In first type of vortex, the plasma converges toward the vortex center, and in the second type, the plasma spreads out from the center. The forward modeling method has been used to create the synthetic SDO/AIA images, in which the eruptive MFR and the FS appear as bright structures. Furthermore, we also deduce the plasma velocity field by utilizing the Fourier local correlation tracking method on the synthetic images. However, we do not observe the VS, the SS, and the two types of vortices in this deduced velocity field.


2021 ◽  
Vol 9 (11) ◽  
pp. 1198
Author(s):  
Linlin Geng ◽  
Desheng Zhang ◽  
Jian Chen ◽  
Xavier Escaler

The tip leakage vortex (TLV) has aroused great concern for turbomachine performance, stability and noise generation as well as cavitation erosion. To better understand structures and dynamics of the TLV, large-eddy simulation (LES) is coupled with a homogeneous cavitation model to simulate the cavitation flow around a NACA0009 hydrofoil with a given clearance. The numerical results are validated by comparisons with experimental measurements. The results demonstrate that the present LES can well predict the mean behavior of the TLV. By visualizing the mean streamlines and mean streamwise vorticity, it shows that the TLV dominates the end-wall vortex structures, and that the generation and evolution of the other vortices are found to be closely related to the development of the TLV. In addition, as the TLV moves downstream, it undergoes an interesting progression, i.e., the vortex core radius keeps increasing and the axial velocity of vortex center experiences a conversion from jet-like profile to wake-like profile.


2021 ◽  
Author(s):  
Rodrigo Soto-Valle ◽  
Stefano Cioni ◽  
Sirko Bartholomay ◽  
Marinos Manolesos ◽  
Christian Navid Nayeri ◽  
...  

Abstract. This study describes the impact of postprocessing methods on the calculated parameters of tip vortices of a wind turbine model when tested using Particle Image Velocimetry (PIV). Several vortex identification methods and differentiation schemes are compared. The chosen methods are based on two components of the velocity field and its derivatives. They are applied to each instantaneous velocity field from the dataset and also to the calculated average velocity field. The methodologies are compared through the vortex center location, vortex core radius and jittering zone. Results show that the tip vortex center locations and radius have good comparability and can vary only a few grid spacings between methods. Conversely, the convection velocity and the jittering surface, defined as the area where the instantaneous vortex centers are located, vary between identification methods. Overall, the examined parameters depend significantly on the post-processing method and selected vortex identification criteria. Therefore, this study proves that the selection of the most suitable postprocessing methods of PIV data is pivotal to ensure robust results.


2021 ◽  
Vol 42 (Supplement_1) ◽  
Author(s):  
I Leo ◽  
J Sabatino ◽  
A Strangio ◽  
M Maglione ◽  
F Troilo ◽  
...  

Abstract Background Over the last decades growing evidence have demonstrated the promising role of intracardiac flow dynamic analysis in evaluating cardiac performance. Diastolic forces contribute to the formation of vortices, complex structures capable of kinetic energy storage and responsible of a smoother transition of blood from left ventricular (LV) inlet to outlet. Change in shape and location of these structures has been related with cardiovascular disease and prognosis. Purpose To investigate quantitative changes in vortices parameters in patients with different ventricular geometry. Methods We enrolled 72 consecutive patients (age 66±11 years, 49 male, 68%) with LV concentric hypertrophy (CH, n=15), eccentric hypertrophy (EH, n=13), concentric remodeling (CR, n=15) and normal LV geometry (CTRL, n=29). Each patient underwent a complete echocardiographic examination and a non-invasive intracardiac fluid dynamic analysis by Color Vector Flow Mapping. A 3-chamber apical view with a frame rate between 22 and 25 Hz has been acquired and subsequently analyzed offline by a semi-automatic software obtaining the following parameters: vortex area (VA) (the ratio between the total vortex area and the left ventricular (LV) area); vortex length (VL) (the longitudinal length of the vortex relative to the total LV length; vortex depth (VD) (the distance of the vortex center from the LV base relative to the total LV long axis). Bland Altman Plot has been used to assess intra and inter-observer variability. Results Mean VD was higher in CR, CH and EH compared to CTRL (p=0.013, p=0.001 and p=0.022, respectively). Moreover, CH showed higher VL (p=0.006) and larger VA (p=0.012) compared to CTRL. A similar trend was noticed in EH patients, despite did not reach statistical significance (p=0.21 and p=0.07 for VA and VL respectively). No significative differences in vortices parameters have been observed between CH and EH. Conclusion(s) This is the first study providing quantitative echocardiographic parameters of vortex location and morphology in different LV geometries. Higher values of VD were found in CR, CH and EG. Quantitative intra dynamic fluid assessment was feasible and reliable in the whole population and could provide additional information to the standard echocardiographic examination. FUNDunding Acknowledgement Type of funding sources: None.


2021 ◽  
Vol 42 (Supplement_1) ◽  
Author(s):  
A Strangio ◽  
J Sabatino ◽  
I Leo ◽  
M Maglione ◽  
F Troilo ◽  
...  

Abstract Background Assessment of intracardiac flows and turbulence has acquired rising significance in the past few years, due to the development and introduction of technologies for non-invasive cardiovascular imaging. Recent studies have shown that alterations in intracardiac fluid dynamics can be helpful to identify abnormalities in cardiac function. Purpose This study investigates the additional information provided by the quantitative assessment of intracardiac flow dynamics for the evaluation of patients with aortic stenosis (AS), by using an advanced echocardiography vortex-based approach. Methods Sixty-one patients with severe AS (33 females) and 38 healthy sex- and BSA-matched controls (CTRL) (15 females) were prospectively included and underwent echocardiographic assessment of intracardiac flow dynamics. Echocardiographic measurements were performed on apical three chamber views. The HyperDoppler software adapted to the echo-scanner without contrast injection was used to assess intracardiac vortex properties. The following parameters were obtained: vortex area (VA) (the ratio between the total vortex area and the left ventricular (LV) area); vortex length (VL) (the longitudinal length of the vortex relative to the total LV length; vortex depth (VD) (the distance of the vortex center from the LV base relative to the total LV long axis). Inter-rater variability was measured using intraclass correlation coefficients (ICCs) between two independent operators. Results Patients with severe AS (mean gradient: 47,5±13,9 mmHg; aortic valve area: 0.7±0.2 cm2; ejection fraction: 53±7%) had increased LV wall thickness (p<0.001) and mass index (p<0.001) compared with controls. Greater indexed left atrial volume (p<0.001), E/e' (p<0.001) and trans-tricuspid gradient (p<0.001) were also observed in the AS group. The assessment of VA, VL and VD was feasible in the whole population. Their calculation was reliable, as ICCs were very good for VA (0.878, p=0.033), VL (0.960, p=0.004) and VD (0,905, p=0.021). Mean VA was significantly larger in patients with severe aortic stenosis compared with CTRL (p=0.033). VL and VD (p=0.026 and p>0.001, respectively) were significantly higher in AS patients compared with CTRL. Among those who underwent TAVR, we observed a significant difference in the delta values of VA and VL pre-postTAVR in patients with and without significant paravalvular leak (p<0.05). Conclusions The newly defined VA, VL and VD, quantitative indices of vortical flow, were significantly increased in the LV cavity of patients with severe AS compared to normal subjects. These indices, whose measurement was feasible and reliable, might provide complementary information to standard echocardiography, useful for the further diagnostic and prognostic characterization of the heterogeneous population of patients with severe AS. FUNDunding Acknowledgement Type of funding sources: None.


2021 ◽  
Author(s):  
Reiner Onken ◽  
Burkard Baschek

Abstract. The evolution of a submesoscale cyclonic spiral of 1 km in diameter is simulated with ROMS (Regional Ocean Modeling System) using 33.3 m horizontal resolution in a triple-nested configuration. The generation of the spiral starts from a dense filament that is rolled into a vortex and detaches from the filament. During spin-up, extreme values are attained by various quantities, that are organized in single-arm and multi-arm spirals. The spin-down starts when the cyclone separates from the filament. At the same time, the horizontal speed develops a dipole-like pattern and isotachs form closed contours around the vortex center. The amplitudes of most quantities decrease significantly, but the instantaneous vertical velocity w exhibits high-frequency oscillations and more pronounced extremes than during spin-up. The oscillations are due to vortex Rossby waves (VRWs), that circle the eddy counterclockwise and generate multi-arm spirals with alternating signs by means of azimuthal vorticity advection. Experiments with virtual surface drifters and isopycnal floats indicate downwelling everywhere near the surface. The downwelling is most intense in the center of the spiral at all depth levels, leading to a radial outflow in the thermocline and weak upwelling at the periphery. This overturning circulation is driven by convergent near-surface flow and associated subduction of isopycnals. While the downwelling in the center may support the export of particulate organic carbon from the mixed layer into the main thermocline, the upwelling at the periphery effectuates an upward isopycnal transport of nutrients, enhancing the growth of phytoplankton in the euphotic zone.


Energies ◽  
2021 ◽  
Vol 14 (18) ◽  
pp. 5856
Author(s):  
Jianfei Tong ◽  
Lingbo Zhu ◽  
Yiping Lu ◽  
Tianjiao Liang ◽  
Youlian Lu ◽  
...  

Pipe height in cylindrical neutron moderator is an important factor to flow pattern, temperature distribution and even the neutron characters. In this paper, the steady-state thermal analysis of cold neutron moderator is carrying out with different heights, conjugated heat transfer method and one-way coupled with a neutron transfer software. The different pipe heights, which is the jet-to-surface distances (H/D = 0.5~6), were compared using a 2D moderator model. The results show that vortex size and velocity gradient from container wall to vortex center vary with H/D, the center of recirculation zone nearly remain constant, and heat transfer effect is weakened on the target bottom surface. With H/D increasing, the velocity at bottom target surface is progressively decreased, and cooling effect is poor, leading to the rise in temperature. The optimal range cooling performance is (H/D) = 0.5~1 at Re = 1.7 × 105, and the enhancement of beam power further strengthens the thermal deposition difference between container and liquid hydrogen. The results can be applied to moderator component design and optimization in the future spallation neutron source.


2021 ◽  
Author(s):  
Hao Fu ◽  
Shiwei Sun

Rotating Rayleigh-Bénard convection (RRBC) denotes the free convection between two parallel plates with a fixed temperature difference, placed in a rotating reference frame. It is a prototype model of geophysical and astrophysical convection. Rotation breaks the symmetry on its rotating axis, making the cyclones and anticyclones unequal in size and magnitude. Such an asymmetry has long been observed in experiments and simulations, but has not been explained with any theoretical model. A theory of such vorticity asymmetry is proposed specifically for the cellular regime, where background rotation is important and convection is weak. The property that columnar updraft and downdraft plumes are densely packed is shown to make the vertical vorticity profile at the vortex center approximately linear with height via thermal wind relation. This simplification of morphology enables a linkage between the vorticity strength of a plume which is quantified by vorticity Rossby number $\mathrm{Ro_V}$, and the vorticity magnitude difference between the cyclonic and anticyclonic ends of plumes which is quantified with a nondimensional asymmetry factor $\delta$. The lowest order relationship between $\delta$ and $\mathrm{Ro_V}$ is found to be constrained by vertical vorticity equation alone. An approximate analytical solution is found using asymptotic expansion, which shows that the asymmetry is generated mainly by the vertical advection and stretching of vertical vorticity in fluid interior, and is modified by the Ekman layer dynamics.


Author(s):  
Gunnar Jacobi ◽  
Alex Nila

Due to their good mechanical properties composite materials are increasingly applied for the construction of lifting surfaces in the maritime industry. However, besides improving the strength to weight ratio of a structure, the anisotropic material properties can also exhibit bend-twist coupling, when exposed to higher loads. In order to experimentally measure the fluid structure interaction, the object of investigation needs to exposed to the same fluid loadings, as it would experience during operation. To investigate the possibility to obtain simultaneous deformation and flow field measurements in a large hydrodynamic testing facility simultaneous PIV and DIC measurements are performed to obtain the deformation of a flexible NACA 0008 hydrofoil and to measure the flow field in the wing tip region. For the assessment of the performance of the methods two scenarios are presented including tests in stationary conditions with constant angles of attack and forced plunging oscillations. The calibration of both measurement systems is done independently and the wing tip, visible in the PIV images, is used for triangulation to find the position of the wing within the PIV coordinate system. The combination of both measurement techniques allows for an accurate determination of tip vortex center positions with respect to the deformed wing and their evolution downstream of the wing. During forced plunging motions, the phase lag of the wing tip and the influence on the wing tip vortex is observed.


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