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A novel particle attrition model for conveying systems
Avi Uzi,
Haim Kalman
,
Avi Levy
Department of Mechanical Engineering
Research output
:
Contribution to journal
›
Article
›
peer-review
30
Scopus citations
Overview
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Keyphrases
Breakage
100%
Conveying System
100%
Particle Attrition
100%
Attrition Model
100%
Flow Field
50%
Interparticle Interactions
50%
Machine Functions
50%
Dilute Phase Pneumatic Conveying
50%
Breakage Model
50%
Model Prediction
25%
System Behavior
25%
Impact Velocity
25%
Particle Collision
25%
Pneumatic Conveying
25%
Particle Breakage
25%
Straight pipe
25%
Collision Frequency
25%
Attrition
25%
Particle Characteristics
25%
CFD-DEM Simulation
25%
Coarse Particles
25%
Trial-and-error
25%
Size Reduction
25%
Comminution
25%
Bending Elements
25%
Pipe Wall
25%
Pipe Section
25%
Two-phase Model
25%
Computational Resources
25%
Fine Particles
25%
Characteristic Function
25%
Low Computational
25%
Industrial pipelines
25%
Particle Size Reduction
25%
Discrete Entities
25%
High Impact Velocity
25%
Impact Collision
25%
Engineering
Breakage
100%
Conveying System
100%
Flow Field
28%
One Dimensional
28%
Size Reduction
28%
Dilute Phase
28%
Computational Fluid Dynamics
14%
Pneumatics
14%
Model Prediction
14%
System Behavior
14%
Good Agreement
14%
Pneumatic Conveying System
14%
Impact Velocity
14%
Conveying Pipeline
14%
Collision Frequency
14%
Digital Elevation Model
14%
Coarse Particle
14%
Particle Collision
14%
Pipe Section
14%
Pipe Wall
14%
Phase Model
14%
Computational Resource
14%
High Impact Velocity
14%
Chemical Engineering
Computational Fluid Dynamics-Discrete Element Method Model
100%