Nauman, 1981 - Google Patents
Residence time distributions and micromixingNauman, 1981
View PDF- Document ID
- 4971281492860204644
- Author
- Nauman E
- Publication year
- Publication venue
- Chemical Engineering Communications
External Links
Snippet
This review is concerned primarily with the Lagrangian approach to mixing. First, the concepts of residence time and residence time distribution are introduced and defined. After a general treatment of this topic in the second chapter, the concept of micromixing is …
- 238000009826 distribution 0 abstract description 195
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Nauman | Residence time distributions and micromixing | |
| Dong et al. | Scale-up of micro-and milli-reactors: An overview of strategies, design principles and applications | |
| Mickaily-Huber et al. | Numerical simulations of mixing in an SMRX static mixer | |
| Jiang et al. | Helical flows and chaotic mixing in curved micro channels | |
| Aubin et al. | Effect of microchannel aspect ratio on residence time distributions and the axial dispersion coefficient | |
| Mandal et al. | Liquid–liquid mixing in coiled flow inverter | |
| Nauman | Residence time distributions | |
| US20080140376A1 (en) | Optimizing a chemical reaction in a plate-type open reactor | |
| Serra et al. | Numerical simulation of polymerization in interdigital multilamination micromixers | |
| Wells et al. | Methodology for modeling detailed imperfect mixing effects in complex reactors | |
| Kurnia et al. | Performance evaluation of liquid mixing in a T-junction passive micromixer with a twisted tape insert | |
| Moreau et al. | A new numerical method for axial dispersion characterization in microreactors | |
| Gidde | Concave wall-based mixing chambers and convex wall-based constriction channel micromixers | |
| Fazli-Abukheyli et al. | Combination of axial dispersion and velocity profile in parallel tanks-in-series compartment model for prediction of residence time distribution in a wide range of non-ideal laminar flow regimes | |
| Zhou et al. | Modeling LDPE tubular and autoclave reactors | |
| Hopley et al. | Residence time distribution in coil and plate micro-reactors | |
| Florit et al. | Kinetics-free process intensification: From semi-batch to series of continuous chemical reactors | |
| Xiong et al. | Topology optimization design of micromixer based on principle of Tesla valve: An experimental and numerical study | |
| Chen et al. | Continuous-flow synthesis of the liquid crystal intermediate 1-(4-ethoxy-2, 3-difluorobenzyl)-4-propylcyclohexan-1-ol in a microfluidic system: Experimental and numerical studies | |
| Zhao et al. | Intensification of mixing efficiency and reduction of pressure drop in a millimeter scale T-junction mixer optimized by an elliptical array hole structure | |
| Rojahn et al. | Mixing performance in a distributed-feed plate-type reactor with multinozzle injection for fine chemical production scale | |
| Chen et al. | Residence time distributions in microchannels with assistant flow inlets and assistant flow outlets | |
| Gao et al. | Monte Carlo modeling of free radical polymerization in microflow reactors | |
| Volpert et al. | Propagation of frontal polymerization—crystallization waves | |
| Gupta et al. | 3‐D flow analysis of non‐newtonian viscous fluids using “enriched” finite elements |