Berlin, Germany ; ; Boston, [Massachusetts] : , : De Gruyter, , 2016

©2016

3-11-040701-9

3-11-040718-3

1 online resource (328 p.)

Sammlung Wissenschaftlicher Commentare, , 1864-3426

FH 20080

883/.01

Epic poetry, Greek - Criticism, Textual

Epic poetry, Greek - History and criticism

Trojan War - Literature and the war

Electronic books.

Tedesco

Description based upon print version of record.

Frontmatter -- Inhalt -- Vorwort -- Hinweise zur Benutzung (mit Abkürzungsverzeichnis) -- 24 Regeln zur homerischen Sprache (R) -- Tabellarischer Überblick über die Handlung des 18. Gesangs -- Kommentar -- Bibliographische Abkürzungen

Basel, Switzerland : , : MDPI, , [2018]

©2018

3-03897-239-8

1 online resource (214 pages) : illustrations

660.28423

Mass transfer

Inglese

Includes bibliographical references.

About the Special Issue Editors . vii -- Dimitrios V. Papavassiliou and Quoc Nguyen Flow and Heat or Mass Transfer in the Chemical Process Industry Reprinted from: Fluids 2018, 3, 61, doi: 10.3390/fluids3030061  1 -- Athanasios G. Kanaris and Aikaterini A. Mouza Design of a Novel μ-Mixer Reprinted from: Fluids 2018, 3, 10, doi: 10.3390/fluids3010010  4 -- Cortes Williams III, Olufemi E. Kadri, Roman S. Voronov and Vassilios I. Sikavitsas Time-Dependent Shear Stress Distributions during Extended Flow Perfusion Culture of Bone Tissue Engineered Constructs Reprinted from: Fluids 2018, 3, 25, doi: 10.3390/fluids3020025  15 -- Agathoklis D. Passos, Dimitris Tziafas, Aikaterini A. Mouza and Spiros V. Paras Computational Modelling for Efficient Transdentinal Drug Delivery Reprinted from: Fluids 2018, 3, 4, doi: 10.3390/fluids3010004 . 29 -- Sarvenaz Sobhansarbandi, Lizon Maharjan, Babak Fahimi and Fatemeh Hassanipour Thermal Fluid Analysis of Cold Plasma Methane Reformer Reprinted from: Fluids 2018, 3, 31, doi: 10.3390/fluids3020031  46 -- Hai M. Duong, Ziyang Colin Xie, Koh Hong Wei, Ng Gek Nian, Kenneth Tan, Hong Jie Lim, An Hua Li, Ka-Shing Chung and Wen Zhen Lim Thermal Jacket Design Using Cellulose Aerogels for Heat Insulation Application of Water Bottles Reprinted from: Fluids 2017, 2, 64, doi: 10.3390/fluids2040064  64 -- Chrysafenia P. Koutsou, Anastasios J. Karabelas and Margaritis Kostoglou Fluid Dynamics and Mass Transfer in Spacer-Filled Membrane Channels: Effect of Uniform Channel-Gap Reduction

Due to Fouling Reprinted from: Fluids 2018, 3, 12, doi: 10.3390/fluids3010012  72 -- Anthony G. Dixon and Nicholas J. Medeiros Computational Fluid Dynamics Simulations of Gas-Phase Radial Dispersion in Fixed Beds with Wall Effects Reprinted from: Fluids 2017, 2, 56, doi: 10.3390/fluids2040056  92 -- Shahrouz Mohagheghian and Brian R. Elbing Characterization of Bubble Size Distributions within a Bubble Column Reprinted from: Fluids 2018, 3, 13, doi: 10.3390/fluids3010013  115 -- Sophie R ¨uttinger, Marko Hoffmann and Michael Schl ¨uter Experimental Analysis of a Bubble Wake Influenced by a Vortex Street Reprinted from: Fluids 2018, 3, 8, doi: 10.3390/fluids3010008 . 132 -- German E. Cortes Garcia, Kevin M. P. van Eeten, Michiel M. de Beer, Jaap C. Schouten and John van der Schaaf On the Bias in the Danckwerts' Plot Method for the Determination of the Gas-Liquid Mass-Transfer Coefficient and Interfacial Area Reprinted from: Fluids 2018, 3, 18, doi: 10.3390/fluids3010018  148 -- Yixiang Liao and Dirk Lucas Evaluation of Interfacial Heat Transfer Models for Flashing Flow with Two-Fluid CFD Reprinted from: Fluids 2018, 3, 38, doi: 10.3390/fluids3020038  158 -- Quoc Nguyen and Dimitrios V. Papavassiliou Quality Measures of Mixing in Turbulent Flow and Effects of Molecular Diffusivity Reprinted from: Fluids 2018, 3, 53, doi: 10.3390/fluids3030053  178 -- Suranga Dharmarathne, Venkatesh Pulletikurthi and Luciano Castillo Coherent Vortical Structures and Their Relation to Hot/Cold Spots in a Thermal Turbulent Channel Flow Reprinted from: Fluids 2018, 3, 14, doi: 10.3390/fluids3010014  194.

Flow through process equipment in a chemical or manufacturing plant (e.g., heat exchangers, reactors, catalyst regeneration units, separation units, pumps, pipes, smoke stacks, et cetera) is usually coupled with heat and/or mass transfer. Rigorous investigation of this coupling of momentum, heat, and mass transfer is not only important for the practice of designing process equipment, but is also important for improving our overall theoretical understanding of transfer phenomena. While generalizations and empiricisms, like the concept of the heat transfer coefficient or the widely used Reynolds analogy in turbulence, or the use of empirical transfer equations for flow in separation towers and reactors packed with porous media, have served practical needs in prior decades, such empiricisms can now be revised or altogether replaced by bringing modern experimental and computational tools to bear in understanding the interplay between flow and transfer. The patterns of flow play a critical role in enhancing the transfer of heat and mass. Typical examples are the coherent flow structures in turbulent boundary layers, which are responsible for turbulent transfer and mixing in a heat exchanger and for dispersion from a smoke stack, and the flow patterns that are a function of the configuration of a porous medium and are responsible for transfer in a fixed bed reactor or a fluid bed regenerator unit. The goal of this Special Issue is to be a forum for recent developments in theory, state-of-the-art experiments and computations on the interactions between flow and transfer in single and multi-phase flow, and from small scales to large scales, which can be important for the design of equipment in a chemical processing plant.