| 1 |
Characterizing the intrinsic properties of powder-A combined discrete element analysis and Hall flowmeter testing study
Dai L, Chan YR, Vastola G, Khan N, Raghavan S, Zhang YW
Advanced Powder Technology, 32(1), 80, 2021 |
| 2 |
Flowability of steel and tool steel powders: A comparison between testing methods
Marchetti L, Hulme-Smith C
Powder Technology, 384, 402, 2021 |
| 3 |
Effect of strain rate on powder flow behaviour using ball indentation method
Zafar U, Hare C, Hassanpour A, Ghadiri M
Powder Technology, 380, 567, 2021 |
| 4 |
Reducing cohesion of metal powders for additive manufacturing by nanoparticle dry-coating
Gartner E, Jung HY, Peter NJ, Dehm G, Jagle EA, Uhlenwinkel V, Madler L
Powder Technology, 379, 585, 2021 |
| 5 |
Evaluation of mechanical properties of nanoparticles using a constant-volume shear tester
Shimada Y, Yamamura K, Matsusaka S
Advanced Powder Technology, 31(3), 1007, 2020 |
| 6 |
Effect of powder characteristics on production of oxide dispersion strengthened Fe-14Cr steel by laser powder bed fusion
Vasquez E, Giroux PF, Lomello F, Nussbaum M, Maskrot H, Schuster F, Castany P
Powder Technology, 360, 998, 2020 |
| 7 |
Dynamic ball indentation for powder flow characterization
Tirapelle M, Santomaso AC, Hare C
Powder Technology, 360, 1047, 2020 |
| 8 |
Improvement on flowability and fluidization of Group C particles after nanoparticle modification
Han MQ, Zhou YDZ, Zhu J
Powder Technology, 365, 208, 2020 |
| 9 |
Investigation of powder flowability at low stresses: Influence of particle size and size distribution
Stavrou AG, Hare C, Hassanpour A, Wu CY
Powder Technology, 364, 98, 2020 |
| 10 |
Using fractal dimension and shape factors to characterize the microcrystalline cellulose (MCC) particle morphology and powder flowability
Xiu HJ, Ma FY, Li JB, Zhao X, Liu LH, Feng P, Yang X, Zhang XF, Kozliak E, Ji Y
Powder Technology, 364, 241, 2020 |
