| 1 |
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 |
| 2 |
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 |
| 3 |
Insights into horizontal slug flow pneumatic conveying from layer fraction and slug velocity measurements
Orozovic O, Lavrinec A, Alkassar Y, Chen J, Williams K, Jones MG, Klinzing GE
Powder Technology, 364, 218, 2020 |
| 4 |
Velocity and porosity relationships within dense phase pneumatic conveying as studied using coupled CFD-DEM
Lavrinec A, Orozovic O, Rajabnia H, Williams K, Jones MG, Klinzing G
Powder Technology, 375, 89, 2020 |
| 5 |
Observations of dense phase pneumatic conveying using an inertial measurement unit
Lavrinec A, Orozovic O, Williams K, Jones MG, Klinzing G, Clark W, Wang Z
Powder Technology, 343, 436, 2019 |
| 6 |
On the kinematics of horizontal slug flow pneumatic conveying and the relationship between slug length, porosity, velocities and stationary layers
Orozovic O, Lavrinec A, Alkassar Y, Williams K, Jones MG, Klinzing G
Powder Technology, 351, 84, 2019 |
| 7 |
Methods for in-situ porosity determination of moving porous columns and application to horizontal slug flow pneumatic conveying
Lecreps I, Orozovic O, Eisenmenger M, Jones MG, Sommer K
Powder Technology, 253, 710, 2014 |
| 8 |
Application of the principles of gas permeability and stochastic particle agitation to predict the pressure loss in slug flow pneumatic conveying systems
Lecreps I, Orozovic O, Jones MG, Sommer K
Powder Technology, 254, 508, 2014 |
| 9 |
Physical mechanisms involved in slug transport and pipe blockage during horizontal pneumatic conveying
Lecreps I, Orozovic O, Erden T, Jones MG, Sommer K
Powder Technology, 262, 82, 2014 |
