easp 2.34; proghtml 2.34 (C)1999-2014 kawase
| Time | Paper ID | Title / Authors | Keywords | Topic code | Ack. number |
|---|---|---|---|---|---|
| Symposium <Bubbles, Drops, and Particles Dispersion Engineering 2014> | |||||
| (10:00–11:00) (Chair: Sakai M.) | |||||
| B204 | Viscoelastical changes of dense colloidal dispersions by kneading processes | kneading processes dense colloidal dispersions shear-thickening | S-23 | 424 | |
| B205 | Compound Droplet Formation Mechanism with Flow Focusing | Compound Droplet Flow Focusing Front-Tracking | S-23 | 377 | |
| B206 | CFD analysis for effect of neighboring pore in a membrane emulsification | CFD計算 エマルション 膜乳化 | S-23 | 744 | |
| (11:00–12:00) (Chair: Honma S.) | |||||
| B207 | Newly developed method for foam measurement via a Single-Tip Optical fiber Probe (S-TOP) based on 3D-ray tracing simulation | S-TOP foam measurement ray-tracing simulation | S-23 | 411 | |
| B208 | Measurement Technologies in Bubbles and Drops Dispersion Systems and Its Applications | Bubbles and Drops Dispersion Systems Measurement Technologies | S-23 | 193 | |
| Symposium <Extended Mixing Technology -Clarification of mixing phenomena and new applications> | |||||
| (13:00–13:40) (Chair: Horie T.) | |||||
| B213 | Two-phase flow in complex geometry and application to mixing device by lattice Boltzmann method | lattice Boltzmann method mixing two-phase flow | S-22 | 1015 | |
| (13:40–15:00) (Chair: Nishi K.) | |||||
| B215 | Effect of a particle size on unsteady CFD by MPS method about Newton fluid mixing | simulation MPS mixing | S-22 | 397 | |
| B216 | CFD on an emulsification phenomenon with a change of viscosity by agitation depending on shear rate as a key factor | mixing emulsion simulation | S-22 | 401 | |
| B217 | Evaluation of rotation-revolution mixing by using numerical simulation and particle count in solution (Hitachi, Ltd., Hitachi Res. Laboratory) Fukumura M., | rotation-revolution mixing numerical simulation particle count | S-22 | 313 | |
| B218 | Numerical study of non-Newtonian fluid mixing applied to estimate mixing time and Metzner-Otto constant | mixing time Metzner-Otto method non-Newtonian fluid | S-22 | 128 | |
| (15:00–16:00) (Chair: Shouno A.) | |||||
| B219 | Mixing Mechanism of Large Paddle Impeller Based on Streak Line Observation | Mixing Streak line Flow visualization | S-22 | 4 | |
| B220 | Quantification of structure of streak lobe in laminar mixing vessel equipped with single or double stage paddle impeller | laminar mixing streak lobe double stage paddle impeller | S-22 | 237 | |
| B221 | Evaluation of mixing performance with a periodic analysis of mixing pattern induced by a rotationally reciprocating impeller | mixing image analysis power curve | S-22 | 918 | |
| (16:00–16:40) (Chair: Mizumi R.) | |||||
| B222 | A study about the mixing effect in using a micromixing device utilizing the Marangoni convection on a gas-liquid free interface applied in a larger-scale channel | Gas-liquid free interface Marangoni effect PIV | S-22 | 315 | |
| B223 | Fundamental study on fluid heating with mixing blade heated by induction heating | Induction Heating Mixing Blade Fluid Heating | S-22 | 269 | |
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