Includes bibliographical references and index.
|Statement||sponsored by the Heat Transfer Division, the Applied Mechanics Division, and the Materials Division, ASME ; edited by C. Beckermann ... [et al.].|
|Series||HTD ;, vol. 284, AMD ;, vol. 182, HTD (Series) ;, v. 284., AMD (Series) ;, v. 182.|
|Contributions||Beckermann, Christoph., American Society of Mechanical Engineers. Heat Transfer Division., American Society of Mechanical Engineers. Applied Mechanics Division., American Society of Mechanical Engineers. Materials Division., International Mechanical Engineering Congress and Exposition (1994 : Chicago, Ill.)|
|LC Classifications||TP156.S55 T73 1994|
|The Physical Object|
|Pagination||vi, 279 p. :|
|Number of Pages||279|
|LC Control Number||94078966|
The transport phenomena cover a vast range of length and time scales, from atomic dimensions up to macroscopic casting size and from nanoseconds for interface attachment kinetics to hours for casting solidification. The article describes how to determine which phenomena are most important at the particular length and time scale for the problem. Mathematical modeling of transport phenomena during alloy solidification C Beckermann Department of Mechanical Engineering, The University of Iowa, Iowa City I A R Viskanta School of Mechanical Engineering, Purdue University, West Lafayette IN Mathematical modeling of mass, momentum, heat, and species transport phenomena occurring. Find helpful customer reviews and review ratings for Transport Phenomena and Materials Processing at tonyasgaapartments.com Read honest and out of 5 stars rare book that links solidification to transport phenomena. August 23, I recommend including a solidification book or pairing this book with a solidification book over 2 semesters so 4/5(1). Solidification, Second Edition (Materials) [Jonathan Dantzig, Michel Rappaz] on tonyasgaapartments.com *FREE* shipping on qualifying offers. Solidification is one of the oldest processes for producing complex shapes for applications ranging from art to industryPrice: $
Transport phenomena have wide application. For example, in solid state physics, the motion and interaction of electrons, holes and phonons are studied under "transport phenomena". Another example is in biomedical engineering, where some transport phenomena of interest are thermoregulation, perfusion, and microfluidics. A gallium wt pct indium alloy is experimentally solidified in a square cavity, cooled from one vertical side wall. Solid, liquid, and mushy/slurry zones form during solidification. A thermosolutal convection pattern is inferred from the measured cooling curves, which also reveal undercooling and. Transport phenomena in solidification: presented at International Mechanical Engineering Congress and Exposition, Chicago, Illinois, November , [Christoph Beckermann; American Society of Mechanical Engineers. An ideal text for graduate level courses in transport phenomena for chemical engineers, Analysis of Transport Phenomena provides a unified treatment of momentum, heat, and mass transfer, emphasizing the concepts and analytical techniques that apply to all of these transport processes.4/5.
Transport Phenomena book. Read 10 reviews from the world's largest community for readers. Careful attention is paid to the presentation of the basic theo /5. Transport Phenomena in Porous Media II covers a wide range of the engineering and technological applications, including both stable and unstable flows, heat and mass transfer, porosity, and turbulence. Transport Phenomena in Porous Media II is the second volume in a series emphasising the fundamentals and applications of research in porous. This monograph covers a part of these demands, namely by presenting the available knowledge on transport phenomena in manufacturing and materials processing. It is divided into four parts. Part I deals with the fundamentals of transport phenomena, including the transfer of momentum, energy, mass, electric and magnetic properties. Presents basic principles of analyzing transport phenomena in multiphase systems with emphasis on melting, solidification, sublimation, vapor deposition, condensation, evaporation, boiling and two-phase flow heat transfer at the micro and macro levels.