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Journal Articles
Publisher: ASME
Article Type: Research-Article
J. Heat Mass Transfer. December 2024, 146(12): 121301.
Paper No: HT-23-1429
Published Online: September 19, 2024
Journal Articles
Accepted Manuscript
Publisher: ASME
Article Type: Research-Article
J. Heat Mass Transfer.
Paper No: HT-24-1181
Published Online: September 19, 2024
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 1 Schematic diagram of a bubbling FB More about this image found in Schematic diagram of a bubbling FB
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 2 Configuration of five bubbling FB risers ( a ) α = 0 deg, ( b ) α = 5 deg, ( c ) α = 10 deg, ( d ) α = 15 deg, and ( e ) α = 20 deg More about this image found in Configuration of five bubbling FB risers ( a ) α = 0 deg, ( b ) α = 5 de...
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 3 Configuration of mesh for the five risers More about this image found in Configuration of mesh for the five risers
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 4 Independence of time-step sizes on simulation results More about this image found in Independence of time-step sizes on simulation results
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 5 Independence of grid sizes on simulation results More about this image found in Independence of grid sizes on simulation results
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 6 Pressure drop comparison across experimental data with predictions from the Syamlal-O'Brien and Gidaspow drag models More about this image found in Pressure drop comparison across experimental data with predictions from the...
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 7 Contour of radial SVF ( a ) Syamlal-O'Brien model and ( b ) Gidaspow model More about this image found in Contour of radial SVF ( a ) Syamlal-O'Brien model and ( b ) Gidaspow model
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 8 Bed pressure drop variation at various cone angles (3D simulation and experiments) More about this image found in Bed pressure drop variation at various cone angles (3D simulation and exper...
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 9 Contour plot of static pressure at ( a ) α = 0 deg, ( b ) α = 5 deg, and ( c ) α = 10 deg More about this image found in Contour plot of static pressure at ( a ) α = 0 deg, ( b ) α = 5 deg, an...
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 10 Effect of cone angle on axial static pressure More about this image found in Effect of cone angle on axial static pressure
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 11 Comparison between experimental and simulation bed pressure drop More about this image found in Comparison between experimental and simulation bed pressure drop
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 12 Comparison of bed expansion ratio experimentally and numerically More about this image found in Comparison of bed expansion ratio experimentally and numerically
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 13 Effect of cone angle on the axial SVF More about this image found in Effect of cone angle on the axial SVF
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 14 Contour of time-averaged axial solid velocity field at ( a ) α = 0 deg, ( b ) α = 5 deg, and ( c ) α = 10 deg More about this image found in Contour of time-averaged axial solid velocity field at ( a ) α = 0 deg, (...
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 15 Contours of time-averaged axial SVF at ( a ) α = 0 deg, ( b ) α = 5 deg, and ( c ) α = 10 deg More about this image found in Contours of time-averaged axial SVF at ( a ) α = 0 deg, ( b ) α = 5 deg...
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 16 Contour plots of time-averaged SVF at an axial height of 10 cm at ( a ) α = 0 deg, ( b ) α = 5 deg, and ( c ) α = 10 deg More about this image found in Contour plots of time-averaged SVF at an axial height of 10 cm at ( a ) α ...
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 17 Effect of cone angle on radial SVF at an axial height of 10 cm More about this image found in Effect of cone angle on radial SVF at an axial height of 10 cm
Image
in Atmospheric Bubbling Fluidized Bed Risers: Effect of Cone Angle on Fluid Dynamics and Heat Transfer
> ASME Journal of Heat and Mass Transfer
Published Online: September 19, 2024
Fig. 18 Contour of time-averaged radial solid velocity field at an axial height of 10 cm at ( a ) α = 0 deg, ( b ) α = 5 deg, and ( c ) α = 10 deg More about this image found in Contour of time-averaged radial solid velocity field at an axial height of ...
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