Current Hydraulic Laboratory Research in the United States
Author :
Publisher :
Page : 360 pages
File Size : 25,77 MB
Release : 1970
Category : Hydraulic engineering
ISBN :
Author :
Publisher :
Page : 360 pages
File Size : 25,77 MB
Release : 1970
Category : Hydraulic engineering
ISBN :
Author :
Publisher :
Page : 226 pages
File Size : 27,56 MB
Release : 1918
Category : Weights and measures
ISBN :
Author : Christopher E. Brennen
Publisher : Cambridge University Press
Page : 269 pages
File Size : 45,75 MB
Release : 2014
Category : Mathematics
ISBN : 1107644763
Cavitation and Bubble Dynamics deals with fundamental physical processes of bubble dynamics and cavitation for graduate students and researchers.
Author :
Publisher :
Page : 258 pages
File Size : 15,9 MB
Release : 1966
Category : Hydraulic engineering
ISBN :
Author : Joanna W. Schot
Publisher :
Page : 754 pages
File Size : 49,42 MB
Release : 1976
Category : Ships
ISBN :
Author : United States. National Bureau of Standards
Publisher :
Page : 696 pages
File Size : 38,42 MB
Release : 1968
Category : Hydraulic engineering
ISBN :
Author : S. G. Ahmed
Publisher : Bentham Science Publishers
Page : 647 pages
File Size : 29,9 MB
Release : 2022-06-30
Category : Mathematics
ISBN : 9815040898
The mathematical modelling of free and moving boundary problems are an important topic in engineering, industry, technology and theoretical sciences. These models allow us to make calculations involved in phase change transitions of materials due to heat transfer. Boundary layer applications are widespread in research and industry. Boundary Element Methods for Heat Transfer with Phase Change Problems: Theory and Application equips the reader with information about heat transfer problems occurring during phase changes. The book covers several boundary element methods, including methods for phase changes, fixed and moving domains and new approaches. The contents are rounded off with chapters on numerical results and industrial applications. Key features: - Simple, didactic presentation of boundary layer problems for heat transfer problems - Covers a wide range of boundary element methods - Includes methods for fixed and moving domains - Explains industrial applications of the methods - Includes solutions to numerical problems The book serves as a textbook for students of advanced mathematics and engineering. It is also a handbook for researchers working on numerical analysis, who require a focused volume on boundary element methods for heat transfer applications.
Author :
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Page : 214 pages
File Size : 36,82 MB
Release : 1951
Category : Weights and measures
ISBN :
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Page : 72 pages
File Size : 45,60 MB
Release : 1959
Category : Science
ISBN :
Author : C.A. Truesdell
Publisher : Springer Science & Business Media
Page : 822 pages
File Size : 18,82 MB
Release : 2012-12-06
Category : Science
ISBN : 3642459447
Sect 2. 317 tinuity surfaces 1. This suggests that a wake pressure Pw be associated with each flow past a bluff body, and that a wake parameter (2. 4) which plays the same role as the cavitation parameter (2. 1), be defined for the flow. This idea has been made the basis of a modified wake theory (ef. Sect. 11) which proves to be in good qu- titative agreement with pressure and drag measurements. It should be emphasized, however, that un h like the cavitation number, the wake parameter is a quantity which is not known a priori, and must be empirically determined in each case. (3) Jet flows. The problem of jet efflux from an orifice is one of the oldest in hydrodynamics and the first to be treated by Fig. 3a. the HELMHOLTZ free streamline theory. Of particular importance for engineering applications is the discharge coefficient Cd' which is defined in terms of the discharge Q per unit time, the pressure P, and the cross-sectional area A of the orifice, by the formula, (2. 5) where e is the fluid density. Two methods of measuring Cd have been most fre quently adopted. In the first the liquid issues from an orifice in a large vessel under the influence of gravity _,-____________ . , (Fig. 3 a), while in the second it 1 L is forced out of a nozzle or pipe under high pressure (Fig. 3 b).