| 1 |
Analysis of dense phase pneumatic conveying of fly ash using CFD including particle size distribution
Alkassar Y, Agarwal VK, Pandey RK, Behera N
Particulate Science and Technology, 39(3), 322, 2021 |
| 2 |
Electrostatic devices related to pneumatic conveying of powders. A short literature review
Ndama AT, Ndong EO, Obame HE, Blampain EJJ
Particulate Science and Technology, 39(3), 285, 2021 |
| 3 |
Experimental study on particle velocity and acceleration length in pneumatic and hydraulic conveying systems
Santo N, Portnikov D, Kalman H
Powder Technology, 383, 1, 2021 |
| 4 |
Inertial measurement unit as a tool within dense phase pneumatic conveying. Investigation into velocity measurement accuracy, pressure and velocity relationships in slug flow
Lavrinec A, Orozovic O, Rajabnia H, Williams K, Jones MG, Klinzing G
Powder Technology, 382, 454, 2021 |
| 5 |
A continuum mechanics derivation of the empirical expression relating slug and particle velocities
Orozovic O, Lavrinec A, Georgiou F, Wensrich CM
Powder Technology, 380, 598, 2021 |
| 6 |
Experimental study on conveying characteristics of a novel top-discharge blow tank for fine cohesive powders
Zhu HP, Xu HB, Zhong WQ, Yu AB
Powder Technology, 379, 335, 2021 |
| 7 |
Measurement of velocity and concentration profiles of pneumatically conveyed particles in a square-shaped pipe using electrostatic sensor arrays
Qian XC, Yan Y, Wu ST, Zhang S
Powder Technology, 377, 693, 2021 |
| 8 |
Simplified model for particle collision related to attrition in pneumatic conveying
Portnikov D, Santo N, Kalman H
Advanced Powder Technology, 31(1), 359, 2020 |
| 9 |
Dilute phase pneumatic conveying of whey protein isolate powders: Particle breakage and its effects on bulk properties
Zhang FW, Olaleye AK, O'Mahony JA, Miao S, Cronin K
Advanced Powder Technology, 31(8), 3342, 2020 |
| 10 |
Efficiency and stability of lump coal particles swirling flow pneumatic conveying system
Zhou JW, Han XM, Jing SX, Liu Y
Chemical Engineering Research & Design, 157, 92, 2020 |
