Your search keyword '"Lian-Ping Wang"' showing total 7 results

1. Study of Local Turbulence Profiles Relative to the Particle Surface in Particle-Laden Turbulent Flows.

Author

Lian-Ping Wang, Ardila, Oscar G. C., Orlando Ayala, Hui Gao, and Cheng Peng

Subjects

TURBULENCE, TURBULENT flow, LATTICE Boltzmann methods, TRANSPORT theory, KINETIC energy, ENERGY transfer

Abstract

As particle-resolved simulations (PRSs) of turbulent flows laden with finite-size solid particles become feasible, methods are needed to analyze the simulated flows in order to convert the simulation data to a form useful for model development. In this paper, the focus is on turbulence statistics at the moving fluid-solid interfaces. An averaged governing equation is developed to quantify the radial transport of turbulent kinetic energy when viewed in a frame moving with a solid particle. Using an interface-resolved flow field solved by the lattice Boltzmann method (LBM), we computed each term in the transport equation for a forced, particle-laden, homogeneous isotropic turbulence. The results illustrate the distributions and relative importance of volumetric source and sink terms, as well as pressure work, viscous stress work, and turbulence transport. In a decaying particle-laden flow, the dissipation rate and kinetic energy profiles are found to be self-siimilar. [ABSTRACT FROM AUTHOR]

Published

2016

2. Flow Modulation by Finite-Size Neutrally Buoyant Particles in a Turbulent Channel Flow.

Author

Lian-Ping Wang, Cheng Peng, Zhaoii Guo, and Zhaosheng Yu

Subjects

TURBULENT flow, LATTICE Boltzmann methods, COMPUTER simulation, FINITE difference method, PARTICLES

Abstract

A fully mesoscopic, multiple-relaxation-time (MRT) lattice Boltzmann method (LBM) is developed to perform particle-resolved direct numerical simulation (DNS) of wallbounded turbulent particle-laden flows. The fluid-solid particle interfaces are treated as sharp interfaces with no-slip and no-penetration conditions. The force and torque acting on a solid particle are computed by a local Galilean-invariant momentum exchange method. The first objective of the paper is to demonstrate that the approach yields accurate results for both single-phase and particle-laden turbulent channel flows, by comparing the LBM results to the published benchmark results and a full-macroscopic finite-difference direct-forcing (FDDF) approach. The second objective is to study turbulence modulations by finite-size solid particles in a turbulent channel flow and to demonstrate the effects of particle size. Neutrally buoyant particles with diameters 10% and 5% the channel width and a volume fraction of about 7% are considered. We found that the mean flow speed was reduced due to the presence of the solid particles, but the local phase-averaged flow dissipation was increased. The effects of finite particle size are reflected in the level and location of flow modulation, as well as in the volume fraction distribution and particle slip velocity near the wall. [ABSTRACT FROM AUTHOR]

Published

2016

3. Retention and Transport of Silica Nanoparticles in Saturated Porous Media: Effect of Concentration and Particle Size.

Author

Chao Wang, Bobba, Aparna Devi, Attinti, Ramesh, Chongyang Shen, Lazouskaya, Volha, Lian-Ping Wang, and Yan Jin

Published

2012

4. Statistical mechanical description and modelling of turbulent collision of inertial particles

Author

*, LIAN-PING WANG, †, WEXLER, ANTHONY S., and ZHOU, YONG

Abstract

The collision rate of monodisperse solid particles in a turbulent gas is governed by a wide range of scales of motion in the flow. Recent studies have shown that large-scale energetic eddies are the dominant factor contributing to the relative velocity between two colliding particles (the turbulent transport effect), whereas small-scale dissipative eddies can enhance the collision rate significantly by inducing local non-uniform particle distribution (the accumulation effect). The turbulent transport effect is most noticeable when the particle inertial response time τp is of the order of the flow integral timescale and the accumulation effect is most pronounced when τp is comparable to the flow Kolmogorov time. We study these two contributions separately through direct numerical simulations. The two effects are quantified carefully with a numerical procedure that is independent of the computation of average collision rate. This facilitates the study of not only the statistical description of the collision kernel, but also the relative contributions and modelling of the two physical effects. Simulations at several flow Reynolds numbers were performed to suggest a model for the accumulation effect. The data show that the accumulation effect scales linearly with flow Taylor microscale Reynolds number Rλ, while the theory for fully developed turbulence indicates that the maximum level of the turbulent transport effect scales with R1/2λ. Finally, an integrated model has been developed to predict the collision rate at arbitrary flow Reynolds numbers and particle inertia.

Published

2000

5. Examination of hypotheses in the Kolmogorov refined turbulence theory through high-resolution simulations. Part 2. Passive scalar field

Author

*, LIAN-PING WANG, §, CHEN, SHIYI, and BRASSEUR, JAMES G.

Abstract

Using direct numerical simulations (DNS) and large-eddy simulations (LES) of velocity and passive scalar in isotropic turbulence (up to 5123 grid points), we examine directly and quantitatively the refined similarity hypotheses as applied to passive scalar fields (RSHP) with Prandtl number of order one. Unlike previous experimental investigations, exact energy and scalar dissipation rates were used and scaling exponents were quantified as a function of local Reynolds number. We first demonstrate that the forced DNS and LES scalar fields exhibit realistic inertial-range dynamics and that the statistical characteristics compare well with other numerical, theoretical and experimental studies. The Obukhov–Corrsin constant for the k−5/3 scalar variance spectrum obtained from the 5123 mesh is 0.87±0.10. Various statistics indicated that the scalar field is more intermittent than the velocity field. The joint probability distribution of locally-averaged energy dissipation εr and scalar dissipation χr is close to log-normal with a correlation coefficient of 0.25±0.01 between the logarithmic dissipations in the inertial subrange. The intermittency parameter for scalar dissipation is estimated to be in the range 0.43≈0.77, based on direct calculations of the variance of lnχr. The scaling exponents of the conditional scalar increment δrθ∣ χr,εr suggest a tendency to follow RSHP. Most significantly, the scaling exponent of δrθ∣ χr,εr over εr was shown to be approximately −⅙ in the inertial subrange, confirming a dynamical aspect of RSHP. In agreement with recent experimental results (Zhu et al. 1995; Stolovitzky et al. 1995), the probability distributions of the random variable βs = δrθ∣ χr,εr/ (χ1/2r ε−⅙r r1/3) were found to be nearly Gaussian. However, contrary to the experimental results, we find that the moments of βs are almost identical to those for the velocity field found in Part 1 of this study (Wang et al. 1996) and are insensitive to Reynolds number, large-scale forcing, and subgrid modelling.

Published

1999

6. In Memoriam: Dave Stock--Teacher and Pioneer Researcher in Multiphase Flow.

Author

Michaelides, Stathis, Reeks, Mike, Sommerfeld, Martin, and Lian-Ping Wang

Subjects

MULTIPHASE flow, TEACHER researchers

Published

2020

7. Clayton Crowe -- The Legacy of a Teacher and Pioneer Researcher in Multiphase Flow.

Author

Michaelides, Stathis, Reeks, Michael, Schwarzkopf, John D., Stock, David, and Lian-Ping Wang

Subjects

CROWE, Clayton

Abstract

The article presents an obituary for Doctor Clayton Crowe, a pioneer in fluid mechanics and multiphase flow research.

Published

2012