Numerical Modelling and Experimental Testing of Heat Exchangers
Published on 22. December 2018
Book
Paperback/Softback
XVIII, 588 pages
978-3-030-08183-6 (ISBN)
Description
This book presents new methods of numerical modelling of tube heat exchangers, which can be used to perform design and operation calculations of exchangers characterized by a complex flow system. It also proposes new heat transfer correlations for laminar, transition and turbulent flows. A large part of the book is devoted to experimental testing of heat exchangers, and methods for assessing the indirect measurement uncertainty are presented. Further, it describes a new method for parallel determination of the Nusselt number correlations on both sides of the tube walls based on the nonlinear least squares method and presents the application of computational fluid dynamic (CFD) modeling to determine the air-side Nusselt number correlations. Lastly, it develops a control system based on the mathematical model of the car radiator and compares this with the digital proportional-integral-derivative (PID) controller. The book is intended for students, academics and researchers, as well as for designers and manufacturers of heat exchangers.
More details
Series
Edition
Softcover Reprint of the Original 1st 2019 ed.
Language
English
Place of publication
Cham
Switzerland
Publishing group
Springer International Publishing
Target group
Professional and scholarly
Illustrations
103 s/w Abbildungen, 89 farbige Abbildungen
XVIII, 588 p. 192 illus., 89 illus. in color.
Dimensions
Height: 235 mm
Width: 155 mm
Thickness: 33 mm
Weight
908 gr
ISBN-13
978-3-030-08183-6 (9783030081836)
DOI
10.1007/978-3-319-91128-1
Schweitzer Classification
Other editions
Additional editions
Book
05/2018
Springer
€160.49
Shipment within 10-15 days
Person
Professor Dawid Taler
, D.Sc., Ph.D. received his doctoral degree in 2002, and postdoctoral degree in 2009 from the Faculty of Mechanical Engineering and Robotics of the University of Science and Technology (AGH) in Cracow. Since 2011 he has been working as a professor at the Faculty of Environmental Engineering at the Cracow University of Technology. Currently, he manages the Department of Thermal Processes, Air Protection and Waste Utilization at the Cracow University of Technology. In 2016 he received the title of professor. He specializes in heat transfer and heating systems, including experimental methods in heat and fluid science. A particular research and development interest is the mathematical modelling and experimental investigation of heat exchangers and energy machines and devices. He is an author of 3 and co-author of 5 monographs and scientific books, 3 of which have been published in English. He has also published 30 chapters in international and national books. He is the author or co-author of over 290 articles in the field of heat transfer, numerical modelling of heat and flow processes, and energy and power technologies. Professor Taler also specializes in thermal and flow measurements, including heat flux measurements, determination of heat transfer coefficient and inverse heat transfer problems, especially the dynamics of heat exchangers and steam generators.
Content
Introduction.- Mass, momentum and energy conservation equations.- Laminar flow of fluids in ducts.- Turbulent fluid flow.- Analogies between the heat and the momentum transfer.- Developed turbulent fluid flow in ducts with a circular cross-section.- Basics of the heat exchanger modelling.- Engineering methods for thermal calculations of heat exchangers.- Mathematical models of heat exchangers.- Mathematical modelling of tube cross-flow heat exchangers operating in steady-state conditions.- Assessment of the indirect measurement uncertainty.- Experimental testing of heat exchangers.- Determination of the local and the mean heat transfer coefficient on the inner surface of a single tube and finding experimental correlations.- Determination of mean heat transfer coefficients using the Wilson method.- Determination of correlations for the heat transfer coefficient on the air side assuming a known heat transfer coefficient on the tube inner surface.- Parallel determination of correlations for heat transfer coefficients on the air and water sides.- Determination of correlations for the heat transfer coefficient on the air side by means of CFD simulations.- Automatic control of the liquid temperature at the car radiator outlet.- Final comments.