| 1 - 1 |
Particle breakage
Salman AD, Hounslow MJ |
| 2 - 18 |
Breakage of spheres and circular discs
Schonert K |
| 19 - 30 |
Descriptive classification of the impact failure modes of spherical particles
Salman AD, Reynolds GK, Fu JS, Cheong YS, Biggs CA, Adams MJ, Gorham DA, Lukenics J, Hounslow MJ |
| 31 - 40 |
Impact breakage of semi-brittle spheres
Chaudhri MM |
| 41 - 55 |
Crushing and fragmentation of brittle spheres under double impact test
Wu SZ, Chau KT, Yu TX |
| 56 - 64 |
Measurement and characterization of particle strength using a new robotic compression tester
Pitchumani R, Zhupanska O, Meesters GMH, Scarlett B |
| 65 - 83 |
Kinetics of fluidised bed melt granulation - IV. Selecting the breakage model
Tan HS, Salman AD, Hounslow M |
| 84 - 96 |
Effect of granule morphology on breakage behaviour during compression
Golchert D, Moreno R, Ghadiri M, Litster J |
| 97 - 109 |
Analysis of impact damage of agglomerates: effect of impact angle
Samimi A, Moreno R, Ghadiri M |
| 110 - 116 |
How do agglomerates break?
Thornton C, Liu LF |
| 117 - 129 |
Structure and cohesion of weakly agglomerated fractal systems
Tatek Y, Stoll S, Ouali L, Pefferkorn E |
| 130 - 143 |
Numerical approach to particle breakage under different loading conditions
Tang CA, Liu HY, Zhu WC, Yang TH, Li WH, Song L, Lin P |
| 144 - 150 |
Making a discrete grain breakage model practical for comminution equipment performance simulation
Herbst JA, Potapov AV |
| 151 - 159 |
The effect of damage on breakage kinetics
Austin LG |
| 160 - 169 |
Empirical breakage ratio of particles due to impact
Petukhov Y, Kalman H |
| 170 - 173 |
Synthesis of Perovskite-type lanthanum cobalt oxide nanoparticles by means of mechanochemical treatment
Ito T, Zhang Q, Saito F |
| 174 - 178 |
The breakage matrix approach to inadvertent particulate degradation: dealing with intra-mixture interactions
Baxter J, Abu-Nahar A, Tuzun U |
| 179 - 185 |
Mechanical characterisation of powders using nanoindentation
Taylor LJ, Papadopoulos DG, Dunn PJ, Bentham AC, Mitchell JC, Snowden MJ |
| 186 - 195 |
Influence of particle size and shape on the comminution of single particles in a rigidly mounted roll mill
Gutsche O, Fuerstenau DW |
| 196 - 203 |
Experimental investigation on a grinding rate constant of solid materials by a ball mill-effect of ball diameter and feed size
Kotake N, Daibo K, Yamamoto T, Kanda Y |
| 204 - 214 |
A study of the exit classification effect in wet ball milling
Cho HC, Austin LG |
| 215 - 229 |
On the use of scanning electron microscopy for the modelling of co-grinding kinetics in a tumbling ball mill
Zapata-Massot C, Frances C, Le Bolay N |
| 230 - 239 |
Ball mill simulation in wet grinding using a tumbling mill and its correlation to grinding rate
Mori H, Mio H, Kano J, Saito F |
| 240 - 252 |
A preliminary simulation model for fine grinding in high speed hammer mills
Austin LG |
| 253 - 263 |
On modelling of submicronic wet milling processes in bead mills
Frances C |
| 264 - 272 |
Impact attrition in crystallization processes. Analysis of repeated impacts events of individual crystals
Biscans B |
| 273 - 279 |
Determination of the attrition behaviour of ammonium sulphate and of pentaerythritol crystals using a Forced Circulation Crystalliser
Lieb A, Kind M |
| 280 - 290 |
Optimal low order methods of moments for solving the fragmentation equation
Kostoglou M, Karabelas AJ |
| 291 - 296 |
Preparation of microcrystals by in situ micronization
Rasenack N, Steckel H, Muller BW |
| 297 - 307 |
Reversible crystal growth-dissolution and aggregation-breakage: numerical and moment solutions for population balance equations
Madras G, McCoy BJ |
| 308 - 320 |
Progress in the understanding of bulk solids attrition in dilute phase pneumatic conveying
Frye L, Peukert W |
| 321 - 330 |
Numerical predictions of particle degradation in industrial-scale pneumatic conveyors
Chapelle P, Abou-Chakra H, Christakis N, Bridle I, Patel MK, Baxter J, Tuzun U, Cross M |
