Turbu lence mode lling for gas -particle flows · 2020. 8. 13. · Turbu lence mode lling for gas...
Transcript of Turbu lence mode lling for gas -particle flows · 2020. 8. 13. · Turbu lence mode lling for gas...
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Turbulence modelling for gas-particle flows
Mohit P. Tandon1, Meera Gupta2 and Aditya Karnik1
1 CD-adapco, India, 2 IIT-Delhi , India
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Outline
• An effort to understand the role of Particle Phase Turbulence
• Focus Applications: Downers and Risers
• Experimental Data: Lateral Segregation in Volume Fraction
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Background
• Fox (2014)# stressed on the need to separate between turbulent
kinetic energy and granular energy of particles
Individual Particle
Scale Cluster Scale
Fluctuations associated
with granular
temperature
Fluctuations associated
with turbulent kinetic energy
# Fox, R.O. On multiphase turbulence models for collisional fluid-particle flows, JFM (742), 2014
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• Volume Fraction
• Momentum
Turbulent Dispersion Force
Governing Equations: Particle Phase
s
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• Granular Temperature
• Turbulent Kinetic Energy
Governing Equations: Particle Phase
Interphase
Turbulence Exchange
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Governing Equations: Fluid Phase
• Turbulent Kinetic Energy
Turbulence induced due to the presence of particles
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Downer
• Experimental Details#
– Co-current down flow – Height of Column: 7 m – Diameter of Column: 0.14 m – Density of Particles: 1545 Kg/m3 – Diameter of Particles: 54 μm – Density of Gas: 1.18 Kg/m3 – Gas Viscosity: 1.8 e-5 Pas – Superficial Gas Velocity: 4.33 m/s – Inlet Solid Flow Rate: 70 Kg/m
2-s
g
Inlet for gas & particles
# Wang et al. Powder Technology (70), 1992, 271-275
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Downer
• Problem Set-up – Mesh: 70x70 – Radial Distribution Function: Ding-Gidaspow – Particle Viscosity: Gidaspow – Granular Conductivity: Gidaspow – Drag Model: Wen and Yu – Wall treatment: No-slip for gas and Slip for particles
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Downer: Results
Simulation without considering particle phase turbulence
0
0.005
0.01
0.015
0.02
0.025
0.03
0.035
0 0.2 0.4 0.6 0.8 1 1.2
Experimental
Simulation
r/R
Vo
lum
e F
ractio
n o
f P
art
icle
Lateral distribution of the particles
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Downer: Results
Simulation with particle phase turbulence – no exchange
r/R
Vo
lum
e F
ractio
n o
f P
art
icle
Lateral distribution of the particles
0
0.005
0.01
0.015
0.02
0.025
0.03
0.035
0.04
0 0.2 0.4 0.6 0.8 1 1.2
Experimental
Simulation A
Simulation B
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Downer: Results
Simulation with particle phase turbulence – exchange accounted
r/R
Vo
lum
e F
ractio
n o
f P
art
icle
Lateral distribution of the particles
0
0.005
0.01
0.015
0.02
0.025
0.03
0.035
0.04
0 0.2 0.4 0.6 0.8 1 1.2
Experimental
Simulation A
Simulation B
Simulation C
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Downer: Turbulent Kinetic Energy Exchange
Particle Phase:
Fluid Phase:
Net Dissipation of Turbulent Kinetic Energy
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Downer: Turbulent Kinetic Energy Exchange
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Downer: Turbulent Kinetic Energy Exchange
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Particle Thermal
Energy
Turbulent Kinetic
Energy Gas Mean Kinetic
Energy Gas
Turbulent Kinetic
Energy Particle
Mean
Shear
Inter Phase
Turbulent
Exchange
Mean Kinetic
Energy Particle Mean
Shear
Drag
Buoyancy
Granular
Temperature
ℇp e Collisions
Gas Thermal
Energy
ℇf Heat
Transfer
Energy Flow Diagram
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Downers: Parametric Study for beta
Lateral distribution of the particles
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Downers: Parametric Study for restitution coefficient
Lateral distribution of the particles
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Downers: Scale up investigation
Lateral distribution of the particles
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Riser
• Experimental Details
– Circulating Fluidized Bed – Density of Gas: 1.18 Kg/m3 – Gas Viscosity: 1.8 e-5 Pas – Superficial Gas Velocity: 1.29 m/s – Inlet Solid Flow Rate: 11.71 Kg/m
2-s
• Problem Set-up – Mesh: 80x430 – Radial Distribution Function: Ding-Gidaspow – Particle Viscosity: Syamlal – Granular Conductivity: Syamlal – Drag Model: EMMS – Wall treatment: No-slip for gas and Slip for particles
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Riser: Results
r/R
Vo
lum
e F
ractio
n o
f P
art
icle
Lateral distribution of the particles at z/D = 1.06
0
0.02
0.04
0.06
0.08
0.1
0.12
0.14
0.16
0 0.2 0.4 0.6 0.8 1
Experimental
Turbulence
Laminar
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Thank You!