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Description of Disperse Multiphase Processes: Quo Vadis?
Author(s) -
Hohl Lena,
Panckow Robert P.,
Schulz Joschka M.,
Jurtz Nico,
Böhm Lutz,
Kraume Matthias
Publication year - 2018
Publication title -
chemie ingenieur technik
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.365
H-Index - 36
eISSN - 1522-2640
pISSN - 0009-286X
DOI - 10.1002/cite.201800079
Subject(s) - process (computing) , homogeneous , computer science , work (physics) , momentum (technical analysis) , interface (matter) , mass transfer , characterization (materials science) , process engineering , biochemical engineering , statistical physics , industrial engineering , mathematical optimization , biological system , mechanics , materials science , mechanical engineering , engineering , physics , nanotechnology , mathematics , finance , bubble , maximum bubble pressure method , economics , biology , operating system , parallel computing
The experimental accessibility of disperse systems often is a critical factor when it comes to the development of modeling approaches that intend to converge towards an exact solution. Often, integral or pseudo‐homogeneous values are used to reduce the complexity of the system, but a detailed single particle or interface analysis is crucial to understand relevant effects that also affect the swarm behavior. A high number of experimental techniques with respective limitations and advantages is available to quantify these effects. In this work, an overview on measurement techniques for momentum, heat and mass transfer in particle swarms as well as for the particle size distribution and interface characterization is provided. The industrial applicability is addressed by pointing out the vicinity to the process and the costs of different measurement techniques.