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37 results on '"Tong, Fulin"'

1. A self-induced mechanism of large-scale helical structures in compressible turbulent flows

Author

Yan, Zheng, Wang, Jianchun, Wang, Lifeng, Lei, Zhu, Wu, Junfeng, Duan, Junyi, Tong, Fulin, Li, Xinliang, and Yu, Changping

Subjects
Physics - Fluid Dynamics
Abstract

A novel self-sustaining mechanism is proposed for large-scale helical structures in compressible turbulent flows. The existence of two channels of subgrid-scale and viscosity terms for large-scale helicity evolution is confirmed for the first time, through selecting a physical definition of the large-scale helicity in compressible turbulence. Under the influence of the fluid element expansion, it is found that the helicity is generated at small scales via the second-channel viscosity, and the inverse cross-scale helicity transfers at inertial scales through the second-channel helicity flux. Together, they form a self-induced mechanism, which provides a physical insight into the long-period characteristic of large-scale helical structures in the evolution of compressible flow systems.

Published
2024

18. Wall heat flux in supersonic turbulent expansion flow with shock impingement.

Author

Tong, Fulin, Duan, Junyi, Yuan, Xianxu, and Li, Xinliang

Subjects
*HEAT flux, *JET impingement, *TURBULENT flow, *EDDY flux, *TURBULENCE, *HILBERT-Huang transform
Abstract

We perform direct numerical simulations to investigate the characteristics of wall heat flux (WHF) in the interaction of an oblique shock wave at an angle of 33.2° and free-stream Mach number M∞ = 2.25 impinging on supersonic turbulent expansion corners with deflection angles of 0o (flat plate), 6o and 12o. The effect of the expansion on the WHF characteristics is analysed by comparing it to the interaction with the flat plate under the same flow conditions and a fixed shock impingement point. In the post-expansion region, the decreased mean WHF is found to collapse onto the flat plate case when scaled with the mean wall pressure. The statistical properties of the WHF fluctuations, including probability density function, frequency spectra, and space–time correlations, are comparatively analysed. The expansion causes an increase in the occurrence probability of negative extreme events, an enhancement of high-frequency energy, and an inhibition of intermediate-frequency energy. The increased expansion angle also results in a faster recovery of characteristic spanwise length scales and an increase in convection velocity. We use the mean WHF decomposition method in conjunction with bidimensional empirical mode decomposition to quantitatively analyse the impact of expansion on scale contributions. It is demonstrated that the presence of the expansion corner has no significant impact on the decomposed results, but it significantly reduces the contribution associated with outer large-scale structures. [ABSTRACT FROM AUTHOR]

Published
2023
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27. Amplification of turbulent kinetic energy and temperature fluctuation in a hypersonic turbulent boundary layer over a compression ramp.

Author

Guo, Tongbiao, Zhang, Ji, Tong, Fulin, and Li, Xinliang

Subjects
TURBULENT boundary layer, KELVIN-Helmholtz instability, KINETIC energy, MOTION, SHOCK waves, TURBULENT mixing, HYPERSONIC aerodynamics, FREQUENCY spectra
Abstract

In this paper, direct numerical simulations in a Mach 6.0 hypersonic turbulent boundary layer over a 30 ° compression ramp are performed. The influence of shock wave/boundary layer interactions on the amplification of turbulent kinetic energy (TKE) and temperature fluctuation (TF) is explored, to provide an insight into the physical mechanism. In the initial part of the interaction region before the detachment of the shear layer, the amplification of the TKE and TF is found, via a frequency spectrum analysis, to be closely related to the low-frequency unsteadiness of the shock wave. Once the free shear layer is established, the shear component of the TKE production defined in the shear layer coordinate appears to act as the main contributor for the TKE amplification, owing to the mixing layer turbulence and the resultant Kelvin–Helmholtz instability. This is consistent with the result from the spectrum analysis that the TKE and TF amplification and their streamwise evolution are dominated by the spectral energy in the median-frequency range, arising from the mixing layer turbulence. As the flow moves downstream along the shock wave, the high-frequency spectral energy content of TF shows a decreasing trend, while the low-frequency spectral energy tends to increase gradually, implying that the shock wave low-frequency unsteadiness exists not only in the initial stage of the interaction region but also around the main shock wave. Under the combined influence of the shock wave intensity and interaction intensity, the median-frequency content appears to weaken first and then tends to increase before decreasing again. The variation amplitude appears to be small and generally dominates the distribution of the TF intensity. [ABSTRACT FROM AUTHOR]

Published
2023
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31. Performance improvement of optimization solutions by POD-based data mining

Author

Tong Fulin, Wenhua Wu, Jiaqi Luo, Peihong Zhang, Zhaolin Fan, Guiyu Zhou, and Yanhui Duan

Subjects
0209 industrial biotechnology, Source data, Rotor (electric), Mechanical Engineering, Aerospace Engineering, Particle swarm optimization, TL1-4050, 02 engineering and technology, Aerodynamics, computer.software_genre, 01 natural sciences, 010305 fluids & plasmas, law.invention, Shock (mechanics), Physics::Fluid Dynamics, 020901 industrial engineering & automation, Point of delivery, law, 0103 physical sciences, Data mining, Performance improvement, Adiabatic process, computer, Mathematics, Motor vehicles. Aeronautics. Astronautics
Abstract

The performance of an optimized aerodynamic shape is further improved by a second-step optimization using the design knowledge discovered by a data mining technique based on Proper Orthogonal Decomposition (POD) in the present study. Data generated in the first-step optimization by using evolution algorithms is saved as the source data, among which the superior data with improved objectives and maintained constraints is chosen. Only the geometry components of the superior data are picked out and used for constructing the snapshots of POD. Geometry characteristics of the superior data illustrated by POD bases are the design knowledge, by which the second-step optimization can be rapidly achieved. The optimization methods are demonstrated by redesigning a transonic compressor rotor blade, NASA Rotor 37, in the study to maximize the peak adiabatic efficiency, while maintaining the total pressure ratio and mass flow rate. Firstly, the blade is redesigned by using a particle swarm optimization method, and the adiabatic efficiency is increased by 1.29%. Then, the second-step optimization is performed by using the design knowledge, and a 0.25% gain on the adiabatic efficiency is obtained. The results are presented and addressed in detail, demonstrating that geometry variations significantly change the pattern and strength of the shock wave in the blade passage. The former reduces the separation loss, while the latter reduces the shock loss, and both favor an increase of the adiabatic efficiency. Keywords: Aerodynamic shape optimization, Computational fluid dynamics, Data mining, Particle swarm optimization, Proper Orthogonal Decomposition, Transonic flow, Turbomachinery

Published
2019

36. Characteristics of reattached boundary layer in shock wave and turbulent boundary layer interaction

Author

Tong, Fulin, Duan, Junyi, and Li, Xinliang

Abstract

The reattached boundary layer in the interaction of an oblique shock wave with a flat-plate turbulent boundary layer at Mach number 2.25 is studied by means of Direct Numerical Simulation (DNS). The numerical results are carefully compared with available experimental and DNS data in terms of turbulence statistics, wall pressure and skin friction. The coherent vortex structures are significantly enhanced due to the shock interaction, and the reattached boundary layer is characterized by large-scale structures in the outer region. The space-time correlation of fluctuating wall shear stress and streamwise velocity fluctuation reveals that the structural inclination angle exhibits a gradual decrease during the recovery process. The scale interactions are analyzed by using a two-point amplitude modulation correlation. A possible mechanism is proposed to account for the strong amplitude modulation in the downstream region. Moreover, the mean skin-friction is decomposed to understand the physically informed contributions. Unlike the upstream Turbulent Boundary Layer (TBL), the contribution associated with the Turbulence Kinetic Energy (TKE) production is greatly amplified, while the spatial growth contribution induced by the pressure gradient largely inhibits skin-friction generation. Based on bidimensional empirical mode decomposition, the turbulence kinetic energy production contribution is further split into different terms with specific spanwise length scales.

Published
2021
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37. A dual platform theory for carbon-based material oxidation with reaction-diffusion rate controlled kinetics.

Author

GUO Yijun, DAI Guangyue, GUI Yewei, TONG Fulin, QIU Bo, and LIU Bo

Subjects
*REACTION-diffusion equations, *ABLATION (Aerothermodynamics), *OXIDATION, *CARBON dioxide, *CARBON compounds
Abstract

The combustion of carbon-based materials in a high speed stream of dissociated air is analyzed, together with the oxidation mechanism from reaction rate controlled regime through the transition to diffusion controlled oxidation. The product of the heterogeneous reaction of carbon with oxygen is known to be CO and CO2, and CO2 is generally usually neglected when surface temperature is higher than 1000K in many literatures. However, we find that CO2 plays an important role in the whole oxidation processes, and can't be ignored through the three regimes. It is shown that two different platforms existed in the diffusion controlled regime. The first platform results from a reaction of the predominant CO2 product, and the other is due to the predominant CO product reaction. In fact, the concepts of "fast" reaction and "slow" reaction are not proper, since the two are the extreme cases of the general model we proposed. As surface temperature rises, the oxidation process will change automatically from nominated "fast" reaction to " slow" reaction. The dual platform theory has been confirmed by several experimental results. [ABSTRACT FROM AUTHOR]

Published
2014
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