| 1 |
Simplified model for particle collision related to attrition in pneumatic conveying
Portnikov D, Santo N, Kalman H
Advanced Powder Technology, 31(1), 359, 2020 |
| 2 |
Rate of CO2 adsorbent attrition induced by gas jets on perforated plate distributors in bubbling fluidized beds
Kim D, Won Y, Park SY, Choi JH, Joo JB, Jo SH
Advanced Powder Technology, 31(10), 4411, 2020 |
| 3 |
Advanced imaging techniques to understand the impact of process variables on the particle morphology in a corn stover pellet
Tumuluru JS, Fillerup E, Kane JJ, Murray D
Chemical Engineering Research & Design, 161, 130, 2020 |
| 4 |
CFD-DEM modelling and simulation of pneumatic conveying: A review
Kuang SB, Zhou MM, Yu AB
Powder Technology, 365, 186, 2020 |
| 5 |
Preparation and characterization of high drug-loaded microgranules: Particle sizing and mechanical properties
Cho CH, Hwang KM, Hwang KM, Seok SH, Kim SH, Seo JW, Park ES
Powder Technology, 326, 344, 2018 |
| 6 |
Particle attrition mechanisms, their characterisation, and application to horizontal lean phase pneumatic conveying systems: A review
Kotzur BA, Berry R, Zigan S, Garcia-Trinanes P, Bradley MSA
Powder Technology, 334, 76, 2018 |
| 7 |
Particle size effect on the catalyst attrition in a lab-scale fluidized bed
Wu DF, Wu FH, Li YD
AIChE Journal, 63(3), 914, 2017 |
| 8 |
Particles' degradation and dynamics in conveying systems
Uzi A, Levy A
Powder Technology, 311, 247, 2017 |
| 9 |
Catalyst attrition in an ASTM fluidized bed
Wu DF, Wu FH, Gu ZD
Catalysis Today, 264, 70, 2016 |
| 10 |
Influence of Temperature on Fluidized-Bed Catalyst Attrition Behavior
Hao JG, Zhao YF, Ye M, Liu ZM
Chemical Engineering & Technology, 39(5), 927, 2016 |
