Your search keyword '"Zhao, Yunhua"' showing total 11 results

1. Numerical simulation of gas-particle flow with a second-order moment method in bubbling fluidized beds

Author

Lu Huilin, Chen Juhui, Sun Dan, Chen Ming, Zhao Yunhua, Wang Jianzhi, and Dimitri Gidaspow

Subjects

Physics::Fluid Dynamics, Barbotage, Jet (fluid), Fluidized bed, Chemistry, General Chemical Engineering, Vertical direction, Thermodynamics, Mechanics, Fluidization, Reynolds stress, Two-phase flow, Two-fluid model

Abstract

Flow behavior of gas and particles is performed by means of gas–solid two-fluid model with the second-order moment model of particles in the bubbling fluidized bed. The distributions of velocity and moments of particles are predicted in the bubbling fluidized beds. Predictions are compared with experimental data measured by Jung et al. (2005) in a bubbling fluidized bed and Patil et al. (2005) experiments in a bubbling fluidized bed with a jet. The simulated second-order moment in the vertical direction is on average 1.5–2.3 times larger than that in the lateral direction in the bubbling fluidized bed (Jung et al., 2005). For a bubbling fluidized bed with a jet, the ratio of normal second-order moment in the vertical direction to in the lateral direction is in the range of 0.5–2.5 (Patil et al., 2005). The bubblelike Reynolds normal stresses per unit bulk density used by Gidaspow et al. (2002) are computed from the simulated hydrodynamic velocities. The simulated bubblelike Reynolds normal stresses in the vertical direction is on average 4.5–6.0 times larger than that in the lateral direction in the bubbling fluidized bed (Jung et al., 2005). The predictions are in agreement with experimental second-order moments measured by Jung et al. (2005) and porosity measured by Patil et al. (2005).

Published

2010

2. A second-order moment method of dense gas–solid flow for bubbling fluidization

Author

Wang Shuai, Sun Dan, Li Xiang, Lu Huilin, Shen Zhiheng, Zhao Yunhua, Wei Li-xin, and Wang Shuyan

Subjects

Chemistry, Applied Mathematics, General Chemical Engineering, Thermodynamics, Fluid mechanics, General Chemistry, Reynolds stress, Two-fluid model, Industrial and Manufacturing Engineering, Physics::Fluid Dynamics, Fluidized bed, Velocity Moments, Particle, Fluidization, Two-phase flow

Abstract

A gas–solid two-fluid model with the second-order moment method is presented to close the set of equations applied to fluidization. With the kinetic theory of granular flow, transport equations for the velocity moments are derived for the particle phase. Closure equations for the third-order moments of velocity and for the fluid–particle velocity correlation are presented. The former is based on a modified model with the contribution of the increase of the binary collision probability, and the latter uses an algebraic model proposed by Koch and Sangani [1999. Particle pressure and marginal stability limits for a homogeneous monodisperse gas-fluidized bed: kinetic theory and numerical simulations. Journal of Fluid Mechanics 400, 229–263]. Boundary conditions for the set of equations describing flow of particles proposed by Strumendo and Canu [2002. Method of moments for the dilute granular flow of inelastic spheres. Physical Review E 66, 041304/1–041304/20] are modified with the consideration of the momentum exchange by collisions between the wall and particles. Flow behavior of gas and particles is performed by means of gas–solid two-fluid model with the second-order moment model of particles in the bubbling fluidized bed. The distributions of velocity and moments of particles are predicted in the bubbling fluidized bed. Predictions are compared with experimental data measured by Muller et al. [2008. Granular temperature: comparison of magnetic resonance measurements with discrete element model simulations. Powder Technology 184, 241–253] and Yuu et al. [2000. Numerical simulation of air and particle motions in bubbling fluidized bed of small particles. Powder Technology 110, 158–168]. in the bubbling fluidized beds. The simulated second-order moment in the vertical direction is 1.1–2.5 [Muller, C.R., Holland, D.J., Sedeman, A.J., Scott, S.A., Dennis, J.S., Gladden, L.F., 2008. Granular temperature: comparison of magnetic resonance measurements with discrete element model simulations. Powder Technology 184, 241–253] and 1.1–4.0 [Yuu, S., Umekage, T., Johno, Y., 2000. Numerical simulation of air and particle motions in bubbling fluidized bed of small particles. Powder Technology 110, 158–168] times larger than that in the lateral direction because of higher velocity fluctuations for particles in the bubble fluidized bed. The bubblelike Reynolds normal stresses per unit bulk density used by Gidaspow et al. [2004. Hydrodynamics of fluidization using kinetic theory: an emerging paradigm 2002 Flour–Daniel lecture. Powder Technology 148, 123–141.] are computed from the simulated hydrodynamic velocities. The predictions are in agreement with experimental second-order moments measured by Muller et al. [2008. Granular temperature: comparison of magnetic resonance measurements with discrete element model simulations. Powder Technology 184, 241–253] and fluctuating velocity of particles measured by Yuu et al. [2000. Numerical simulation of air and particle motions in bubbling fluidized bed of small particles. Powder Technology 110, 158–168].

Published

2009

3. Investigation of mixing/segregation of mixture particles in gas–solid fluidized beds

Author

Jianmin Ding, Lu Huilin, Zhao Yunhua, Li Wei, and Dimitri Gidaspow

Subjects

Chemistry, Applied Mathematics, General Chemical Engineering, Mixing (process engineering), Thermodynamics, General Chemistry, Industrial and Manufacturing Engineering, Physics::Fluid Dynamics, Barbotage, Fluidized bed, Volume fraction, Particle, Fluidization, Particle size, Magnetosphere particle motion

Abstract

A multi-fluid computational fluid dynamics (CFD) model based on kinetic theory of granular flow and Eulerian–Eulerian approach for binary mixture of particles was presented. The multi-fluid model with gas phase and two particle phases of either different particle sizes or densities is used to simulate flows in bubbling gas–solid fluidized beds. The flow behavior of particle mixing or separation in bubbling fluidized beds was numerically predicted. Details of particle collision information were obtained through tracing particle motions based on Eulerian–Lagrangian approach coupled with the discrete hard-sphere model. The distributions of volume fraction, velocity and granular temperature of particles of two different sizes or densities were obtained. The discrete hard-sphere modeling results quantified the granular temperatures, particle fluctuating velocities, particle phase stresses, as well as the particle shear viscosities. The simulations using both the multi-fluid model and the discrete hard-sphere model clearly indicate particle separation phenomenon in the fluidized beds, where relatively larger or heavier particles are observed near the bed bottom than at the bed top region while relatively smaller or lighter particles were found at bed top than at the bed bottom. Better particle mixing can be obtained by increasing the fluidizing velocity.

Published

2007

4. Numerical Modeling of Gas Tubular Distributors in Bubbling Fluidized-Bed Incinerators

Author

Liu Ya-ning, Zeng Linyan, Zhao Yunhua, Lu Huilin, and Jianmin Ding

Subjects

Range (particle radiation), Materials science, General Chemical Engineering, Bubble, Flow (psychology), Distributor, Numerical modeling, General Chemistry, Mechanics, Industrial and Manufacturing Engineering, Physics::Fluid Dynamics, Particle, Fluidization, Bubbling fluidized bed

Abstract

The use of a suitable gas distributor is essential for satisfactory performance of gas-solid fluidized-bed incinerators that are burning solid wastes. In the present study, the flow behavior of bubble and particles in bubbling fluidized beds with tubular distributor are performed using a two-fluid model. The computed instantaneous and time-averaged particle distributions, and the velocities of gas and particles, were analyzed. The effects of the jetting gas velocity and pipe spacing of tubular distributor on the quality of fluidization were investigated. The optimum pipe spacing is proposed to be in the range of 1.5-1.75, based on numerical results.

Published

2006

5. Hydrodynamics of gas–solid flow around immersed tubes in bubbling fluidized beds

Author

He Yurong, Jacques Bouillard, Yang Lidan, Dimitri Gidaspow, Sun Qiaoqun, Zhao Yunhua, Lu Huilin, School of Energy Science and Engineering / Department of Power Engineering, Harbin Institute of Technology (HIT), Department of Chemical and Biological Engineering [Chicago], Illinois Institute of Technology (IIT), and Institut National de l'Environnement Industriel et des Risques (INERIS)

Subjects

Coalescence (physics), Chemistry, General Chemical Engineering, Bubble, Thermodynamics, IMMERSED TUBES, Mechanics, Two-fluid model, WAVELET MULTI-RESOLUTION ANALYSIS, Physics::Fluid Dynamics, Barbotage, [SPI]Engineering Sciences [physics], Fluidized bed, Particle, FLUIDIZED BEDS, BODY-FITTED COORDINATE, Two-phase flow, Fluidization

Abstract

International audience; A numerical study was conducted based on the gas-solid two-fluid model using the body-fitted coordinate system to analyze the behavior of particles and bubbles flow in bubbling fluidized beds without and with immersed tubes. The kinetic theory of granular flow was implemented in the model. The images of simulated instantaneous particle concentration and velocity gave the process of the formation, coalescence and eruption of bubbles. The effects of the tube pitch and superficial gas velocity on the fluidization in a bubbling fluidized bed were investigated. Calculated bubble frequencies without and with immersed tubes were in agreement with previous experimental and simulation findings. The wavelet multi-resolution analysis was used to analyze the simulated data of instantaneous particle concentration. From the random-like particle concentration fluctuations, the fluctuating components due to particle flow and bubble motion can be extracted based on the wavelet multi-resolution analysis over a time-frequency plane.

Published

2004

6. Comparative study of the single and double specularity coefficients on two-fluid modeling of a pseudo-2D gas–solid fluidized bed.

Author

Zhuang, Jianchong, Zhao, Yunhua, Zhou, Minghan, Wang, Chengjing, and Lu, Bing

Subjects

*PRESSURE drop (Fluid dynamics), *GAUSSIAN distribution, *COMPARATIVE studies, *FLUIDIZATION

Abstract

[Display omitted] • Specularity coefficient has a monotonic but nonlinear impact on the fluidized bed. • The double specularity coefficients approach improves the predictive accuracy. • Freely bubbling transitions to slugging when the specularity coefficient is large. • Specularity coefficients for the front/back walls are crucial the pseudo-2D bed. The specularity coefficient is an unmeasurable parameter in the most popular wall boundary model during the two-fluid modeling of dense gas–solid flows. Using multiphaseEulerFoam solver, the influence of different specularity coefficient setting strategies on the gas–solid flow inside a pseudo-2D fluidized bed has been explored. It is found that the single specularity coefficient plays a regulatory role in the quantitative prediction. Increasing the specularity coefficient would cause a fluidization transition from freely bubbling to slugging, and the bed characteristics such as pressure drop and bed expansion present monotonic nonlinear changes. The double specularity coefficients approach is shown to significantly improve the predictive accuracy through verifying with the measured particle velocities, bubble diameter and rise velocity. In addition, the lognormal bubble size distribution and Gaussian bubble rise velocity distribution are observed. The specularity coefficient for walls in thickness direction is crucial and its different effects are unignorable. Overall, the present study provides a practical strategy of double specularity coefficients for the solid wall boundary conditions during two-fluid modeling. [ABSTRACT FROM AUTHOR]

Published

2022

7. Discrete particle modeling of gas fluidization with random collisional parameters.

Author

Zhao, Yunhua, Lu, Bing, Yang, Zhichao, and Zhong, Yingjie

Subjects

*DISCRETE systems, *GAS flow, *FLUIDIZATION, *COLLISIONS (Physics), *PARAMETER estimation, *HYDRODYNAMICS, *PHYSICS experiments, *COMPUTER simulation

Abstract

Gas-fluidized beds are widely used in industries. Discrete particle modeling (DPM) with the hard-sphere approach has been successfully developed to study the fundamental hydrodynamics of the gas-particle systems. However, most of the studies deal the collision with a deterministic method, in which all the collisional parameters are constant. In fact, particle shape is irregular, and its surface could be uneven. These factors will bring some uncertainty, much like the measured variance in the experiment, to the collision. In this study, the hard-sphere approach is extended to consider the collision uncertainty using randomly chosen collisional parameters near their constant values. Numerical simulations by DPM with the random and constant parameters are carried out for a bubbling fluidized bed. It is found that the particle velocities with random parameters are almost the same as those with constant parameters. However, the bed expansion, the kinetic energy level as well as the correlation of particle velocities show some differences. [ABSTRACT FROM AUTHOR]

Published

2013

8. Numerical studies of gas-solid flow behaviors and wall wear in a swirling fluidized bed.

Author

Wu, Qiang, Wang, Shuai, Zhang, Kai, Zhao, Yunhua, and He, Yurong

Subjects

*SWIRLING flow, *PRESSURE drop (Fluid dynamics), *AIR mattresses, *STATURE, *FLUIDIZATION, *GAS flow, *HEAT transfer

Abstract

A swirling gas-solid fluidized bed can effectively improve the fluidization quality and interphase heat transfer via the introduction of tangential gas flow. The Dense Discrete Phase Model (DDPM) is employed to investigate the gas-solid flow behaviors in a swirling gas-solid fluidized bed with the air plenum. In addition, the wall wear and particle mixing behaviors are also examined. The results demonstrate that various operation regimes appear with the increasing superficial velocity. The particles are prone to be centrifugally attached to the wall in the stable swirling regime and accompanied by strong elutriation. The decrease of central body height will reduce the bed pressure drop and swirling velocity. The increase of operation velocity is beneficial to particle mixing behaviors in a swirling bed with a lower central body. [Display omitted] • Flow characteristics in a SFB are investigated via the DDPM method. • Fluidization states for the SFB under different velocities are analyzed. • Wall erosion and particle mixing behaviors in a SFB are evaluated. [ABSTRACT FROM AUTHOR]

Published

2021

9. Numerical investigation on particle behavior in a bubbling fluidized bed with non-spherical particles using discrete hard sphere method.

Author

Wang, Tianyu, He, Yurong, Tang, Tianqi, and Zhao, Yunhua

Subjects

*FLUIDIZATION, *PARTICLE size distribution, *GRANULAR materials, *TURBULENCE, *GAS-solid interfaces, *BUBBLES

Abstract

In this work, a hard sphere particle method for non-spherical particles is applied to study particle behaviors in a bubbling fluidized bed. The influence of the non-spherical particle method and the restitution coefficient are examined. The particle behaviors, including the overall fluidization state (distributions of particle translational and rotational velocities, void fraction, etc.), bubble and particle fluctuations (particle and bubble granular temperatures), are studied. Specific variation rules which are difficult to measure experimentally are presented. As the bubble boundaries in the non-spherical particle system are not as clear as in the spherical case, there is a stronger fluctuation movement of bubbles, which also dominates the particle turbulent movement. The absolute values of particle translational and rotational velocities increase when the restitution coefficient decreases. And it affects the periodic fluctuation characteristics of gas-solid interactions. The variation rules for bubbles and particles as a function of the restitution coefficient are different. [ABSTRACT FROM AUTHOR]

Published

2016

10. DEM numerical simulation of wet cohesive particles in a spout fluid bed.

Author

He, Yurong, Peng, Wengen, Tang, Tianqi, Yan, Shengnan, and Zhao, Yunhua

Subjects

*SPOUTED bed processes, *COHESIVE strength (Mechanics), *DISCRETE element method, *COMPUTER simulation, *WETTING, *PARTICLES, *FLUIDIZATION

Abstract

The dynamic behavior of wet cohesive particles is greatly different from that of dry particles in a spout–fluid bed. A modified discrete element model (DEM) for wet particles is established by adding an additional module to consider the presence of the liquid bridge. DEM simulations are conducted for the dry and wet granular systems and the geometry of the bed is the same as the experimental one of Link et al. The influences of drag models and liquid contents are investigated. It is found that the Koch–Hill drag model predicts a dominant peak, the same as the measured results of Link et al., in the frequency domain of the dynamic pressure drop under Case A. However, the Gidaspow drag model fails to catch this phenomenon. With an increase of the liquid content, the fluctuation range of the pressure drop increases firstly and then decreases rapidly under Case A, but it monotonically increases under Case B. In the spout–fluid bed, dead zones, where the particles are de-fluidized, appear at the corners. The inclined angle and the area of the dead zone expand with the increase of the liquid content, which makes the value of the final Lacey mixing index decrease. [ABSTRACT FROM AUTHOR]

Published

2016

11. CFD simulations of bubbling beds of rough spheres

Author

Wang, Shuyan, Lu, Huilin, Li, Xiang, Yu, Long, Ding, Jianmin, and Zhao, Yunhua

Subjects

*FLUID dynamics, *FLUID mechanics, *DYNAMICS, *AERODYNAMICS

Abstract

Abstract: Hydrodynamics of three-dimensional gas–solid bubbling fluidized beds are numerically analyzed. The particle–particle interactions are simulated from the kinetic theory for flow of dense, slightly inelastic, slightly rough sphere proposed by Lun [1991. Kinetic theory for granular flow of dense, slightly inelastic, slightly rough sphere. Journal of Fluid Mechanics 233, 539–559] to account for rough sphere binary collisions and the frictional stress model proposed by Johnson et al. [1990. Frictional–collisional equations of motion for particulate flows and their application to chutes. Journal of Fluid Mechanics 210, 501–535] to consider the frictional contact forces between particles. The present model is evaluated by measured particle distributions and velocities of Yuu et al. [2001. Numerical simulation of air and particle motions in group-B particle turbulent fluidized bed. Powder Technology 118, 32–44] and experimental bed expansion of Taghipour et al. [2005. Experimental and computational study of gas–solid fluidized bed hydrodynamics. Chemical Engineering Science 60, 6857–6867]. Our computed results indicated that the present model gives better agreement with experimental data than the results from original kinetic theory for frictionless slightly inelastic sphere of Ding and Gidaspow [1990. A bubbling fluidization model using kinetic theory of granular flow. A.I.Ch.E. Journal 36, 523–538] with and without solid friction stress model. [Copyright &y& Elsevier]

Published

2008