On the optimum conditions for baffle installation in the backward facing step flow for maximization of the baffle performanceEslami, G.; Karbalaei, A.
2021 Thermophysics and Aeromechanics
doi: 10.1134/s0869864321060020
Various studies have shown that a baffle installation can enhance heat transfer in the backward facing step flows. This increases the pressure drop in the channel, as well. Therefore, naturally a question comes up here. In which location and orientation a given baffle should be installed to have the highest possible performance? In this study, the main focus is to find the best installation location Xb and Yb) and orientation (α) for a given baffle to maximize its thermal performance. To this end, a steady incompressible laminar flow was considered in a channel with an expansion ratio RE = 2. The bottom wall of the channel is partially heated with a constant heat flux. For numerical modeling, the Navier—Stokes equations were solved using the finite element method. Two new concepts entitled the maximum temperature constraint and the performance evaluation parameter (PEP) were defined to characterize the problem. Grid independence study was performed, and the numerical simulation was validated successfully with the published results. As the main result, a small zone close to the step was identified for the baffle installation which gives higher values of the PEP and constrained PEP (CPEP). It was shown that under the present circumstances, the case (Xb, Yb, α) = (0.3, 0.9, −15°) gives the highest heat transfer enhancement (75 %) and the case (Xb, Yb, α) = (0.3, 0.9, 30°) is the most optimum case from the thermal performance point of view with CPEP = 1.257.
Studying the hydrodynamics of a coolant behind the mixing intensifier grid of the PWR fuel assemblyDmitriev, S. M.; Dobrov, A. A.; Doronkov, D. V.; Doronkova, D. S.; Ivanova, K. E.; Obidina, K. A.; Pronin, A. N.; Ryazanov, A. V.; Solntsev, D. N.; Khrobostov, A. E.; Yalymova, O. D.
2021 Thermophysics and Aeromechanics
doi: 10.1134/s0869864321060032
The article presents the results of studies of a coolant flow behind the mixing intensifier grids of TVS Kvadrat fuel assemblies of the PWR. The purpose of the work is to evaluate the efficiency of mixing the coolant behind the intensifier grids of various designs and to choose their optimal design. To achieve this goal, a number of experiments are carried out on the aerodynamic research stand with scale models of fuel rod bundle fragments of fuel assemblies with mixing intensifier grids, equipped with turbulizing deflectors of various profile shapes. The cells located near the guide channel and regular cells are selected as the research area. The choice of the research area is due not only to the need to obtain a hydrodynamic picture of the coolant flow in characteristic cells and the choice of the optimal shape of the deflector, but also due to the necessary assessment of the influence of transverse coolant flows from the area of the guide channel on the flow motion in adjacent cells. The coolant flow pattern is represented by vector fields of transverse velocities, cartograms of the distribution of transverse and axial velocities, as well as graphical dependences of the distribution of the flow velocity components. Analysis of the spatial distribution of transverse and axial flow velocities allows studying and detailing the flow pattern of the coolant. Evaluation of the efficiency of the coolant mixing behind the grids and determination of the optimal shape of the deflector profile are carried out on the basis of a comprehensive analysis of the hydrodynamic pattern of the coolant flow and the parameters of intracellular vortex formation and intercellular mixing. The experimental results can be used in the engineering justification of structural solutions for the design of active zones of PWR reactors with TVS-Kvadrat. The accumulated database of experimental data is used for verification of CFD programs (both foreign and domestic development), as well as programs for thermal-hydraulic cell-by-cell calculation of active zones.
Probe influence on total pressure measurements in the zone of supersonic laminar separated flow reattachmentZapryagaev, V. I.; Kavun, I. N.; Trubitsyna, L. P.
2021 Thermophysics and Aeromechanics
doi: 10.1134/s0869864321060056
The influence of the Pitot probe on total pressure measurements in the near-wall flow in the zone of reattachment of a supersonic separated flow past a compression corner is considered. If the total pressure is measured near the model wall, a local maximum is observed in the region downstream of the reattachment line. This maximum can be either a physical structural element of the separated flow (high-pressure layer in which the total pressure reaches 0.8–0.95 of the free-stream total pressure) or a possible measurement error. The present study reveals the existence of a measured total pressure peak in the boundary layer on a horizontal flat plate and flat wedges. This peak is not associated with the high-pressure flow, but is rather a result of probe interaction with the model wall. The amplitude of this peak is found to depend on the ratio of the probe size and the boundary layer thickness. It is shown that the degree of the probe influence leading to distortion of the measurement results is smaller approximately by an order of magnitude than the maximum value of the measured total pressure in the high-pressure layer in the reattachment zone.
Optimization of geometric parameters of cylindrical film cooling hole with contoured craters to enhance film-cooling effectivenessBai, L. C.; Zhang, C.; Tong, Z. T.; Ju, P. F.
2021 Thermophysics and Aeromechanics
doi: 10.1134/s0869864321060081
The present study aims at obtaining the optimum contoured crater for a cylindrical-based film cooling hole with maximum area-averaged cooling effectiveness via computational fluid dynamics and optimization method. The influences of 5 geometrical parameters, which depict completely the dimensions of the contoured crater, were discussed through performing the orthogonal experiment design and range analysis. The optimum designs at blowing ratios of 0.5 and 1.5 were obtained by using the range analysis and the genetic algorithm combined with back propagation neural network respectively. From the analysis of the results, it can be found that the latter optimization method outperformed with higher area-averaged cooling effectiveness at both blowing ratios. The area-averaged cooling effectiveness of the optimized cratered holes were improved by 17.21 % at blowing ratio of 0.5 and 101.96 % at blowing ratio of 1.5, respectively, compared to those of the reference geometry. The improvements on the film-cooling performance were explained in terms of the flow filed and the vortex structures.