Download JonSpangenberg280416

WG 3 meeting
Jon Spangenberg
28/04/2016
Outline
• FlowCyl simulations
• Suspension simulations
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DTU Mechanical Engineering, Technical University of Denmark
28/04/2016
10/06/2010
FlowCyl simulation
Geometry:
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DTU Mechanical Engineering, Technical University of Denmark
28/04/2016
10/06/2010
FlowCyl simulation
Simulation (water):
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DTU Mechanical Engineering, Technical University of Denmark
28/04/2016
10/06/2010
FlowCyl simulation
Simulation without bucket (Water):
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DTU Mechanical Engineering, Technical University of Denmark
28/04/2016
10/06/2010
FlowCyl simulation
Water results:
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DTU Mechanical Engineering, Technical University of Denmark
28/04/2016
10/06/2010
FlowCyl simulation
Rolands results:
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DTU Mechanical Engineering, Technical University of Denmark
28/04/2016
10/06/2010
FlowCyl simulation
Flow resistance vs. yield stress:
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DTU Mechanical Engineering, Technical University of Denmark
28/04/2016
10/06/2010
FlowCyl simulation
Next step:
• Correct the geometry
• Simulate all Rolands data
• Make similar comparison as Rolands have done
in his paper
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DTU Mechanical Engineering, Technical University of Denmark
28/04/2016
10/06/2010
Suspension simulation
Mono sized spheres: X:\cluster\STARCCM+\SuspensionInvestigation\v32\ParticleVelo
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DTU Mechanical Engineering, Technical University of Denmark
28/04/2016
10/06/2010
Suspension simulation
Mono-sized spheres:
Krieger-Dougherty
equation
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DTU Mechanical Engineering, Technical University of Denmark
28/04/2016
10/06/2010
Suspension simulation
Next step:
• Make additional simulations with mono-sized spheres
• Make rheological measurements on suspensions with bimodal sphere distributions
• Simulate suspensions with bi-modal sphere distribution
• Make rheological measurements on suspensions with
Rolands well-characterized filler (if that is ok with
Rolands)
• Simulate suspensions with Rolands well-characterized
filler
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DTU Mechanical Engineering, Technical University of Denmark
28/04/2016
10/06/2010