| 1 |
Numerical analysis of particle impacting and bonding processes during high velocity oxygen fuel spraying process
Pan JJ, Hu SS, Niu AN, Ding KY, Yang LJ
Applied Surface Science, 366, 187, 2016 |
| 2 |
Computational study of particle in-flight behavior in the HVOF thermal spray process
Li MH, Christofides PD
Chemical Engineering Science, 61(19), 6540, 2006 |
| 3 |
Multi-scale modeling and analysis of an industrial HVOF thermal spray process
Li MH, Christofides PD
Chemical Engineering Science, 60(13), 3649, 2005 |
| 4 |
Modeling and control of HVOF thermal spray processing of WC-Co coatings
Li MH, Shi D, Christofides PD
Powder Technology, 156(2-3), 177, 2005 |
| 5 |
Model-based estimation and control of particle velocity and melting in HVOF thermal spray
Li MH, Shi D, Christofides PD
Chemical Engineering Science, 59(22-23), 5647, 2004 |
| 6 |
Modeling and analysis of HVOF thermal spray process accounting for powder size distribution
Li MH, Christofides PD
Chemical Engineering Science, 58(3-6), 849, 2003 |
| 7 |
Influence of HVOF parameters on the corrosion resistance of NiWCrBSi coatings
Gil L, Staia MH
Thin Solid Films, 420-421, 446, 2002 |
| 8 |
Nylon 11/silica nanocomposite coatings applied by the HVOF process. I. Microstructure and morphology
Petrovicova E, Knight R, Schadler LS, Twardowski TE
Journal of Applied Polymer Science, 77(8), 1684, 2000 |
| 9 |
Nylon 11/silica nanocomposite coatings applied by the HVOF process. II. Mechanical and barrier properties
Petrovicova E, Knight R, Schadler LS, Twardowski TE
Journal of Applied Polymer Science, 78(13), 2272, 2000 |
