| 1 |
A COMPARATIVE STUDY OF DIRECT NUMERICAL SIMULATION AND EXPERIMENTAL RESULTS ON A PREFILMING AIRBLAST ATOMIZATION CONFIGURATION
Carmona J, Odier N, Desjardins O, Cuenot B, Misdariis A, Cayre A
Atomization and Sprays, 31(8), 9, 2021 |
| 2 |
MODAL ANALYSIS-BASED CLASSIFICATION OF LIQUID JETS IN CROSSFLOW
Mokhtarpour K, Jadidi M, Dolatabadi A
Atomization and Sprays, 31(7), 1, 2021 |
| 3 |
A COMPREHENSIVE STUDY ON THE INFLUENCE OF RESOLVING AN INJECTOR ORIFICE AND THE INFLUENCE OF CREATING STRIPPED OFF DROPLETS ON SPRAY FORMATION USING THE VSB2 SPRAY MODEL
Muthuramalingam VP, Nygren A, Karlsson A
Atomization and Sprays, 31(4), 15, 2021 |
| 4 |
Experimental Investigation on Single-Droplet Deformation and Breakup in a Concave-Wall Jet
Zhang J, Gao YB, Gong B, Li YX, Wu JH
Chemical Engineering & Technology, 44(2), 238, 2021 |
| 5 |
Viscoelastic liquid bridge breakup and liquid transfer between two surfaces
Chen H, Ponce-Torres A, Montanero JM, Amirfazli A
Journal of Colloid and Interface Science, 582, 1251, 2021 |
| 6 |
The influence of the negative wake on the deformation and breakup of viscoelastic droplets
Carril-Naranjo F, Mena B, Samayoa D, Guerrero A, Figueroa-Espinoza B
Korea-Australia Rheology Journal, 33(3), 283, 2021 |
| 7 |
Micro-explosion of a two-component droplet: How the initial temperature of the water core affects the breakup conditions and outcomes
Antonov DV, Kuznetsov GV, Fedorenko RM, Strizhak PA
Powder Technology, 382, 378, 2021 |
| 8 |
CONDITIONAL DAMPED RANDOM SURFACE VELOCITY MODEL OF TURBULENT JET BREAKUP
Trettel B
Atomization and Sprays, 30(8), 575, 2020 |
| 9 |
REEVALUATING THE JET BREAKUP REGIME DIAGRAM
Trettel B
Atomization and Sprays, 30(7), 517, 2020 |
| 10 |
A GENERALIZED OHNESORGE NOMOGRAM FOR LIQUID JET BREAKUP REGIMES
Brennt G, Stelter M
Atomization and Sprays, 30(3), 213, 2020 |
