Fluid MechanicsAcademic Press, 2010 M01 20 - 904 páginas Fluid mechanics, the study of how fluids behave and interact under various forces and in various applied situations—whether in the liquid or gaseous state or both—is introduced and comprehensively covered in this widely adopted text. Fluid Mechanics, Fourth Edition is the leading advanced general text on fluid mechanics.
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Página 9
... define the pressure in a moving medium, and this will be done in Chapter 4.) Sometimes the ordinary pressure is called the absolute pressure, in order to distinguish it from the gauge pressure, which is defined as the absolute pressure ...
... define the pressure in a moving medium, and this will be done in Chapter 4.) Sometimes the ordinary pressure is called the absolute pressure, in order to distinguish it from the gauge pressure, which is defined as the absolute pressure ...
Página 12
... defined. This definition, however, is not possible in fluid flows, and the question arises as to whether the relations derived in classical thermodynamics are applicable to fluids in constant motion. Experiments show that the results of ...
... defined. This definition, however, is not possible in fluid flows, and the question arises as to whether the relations derived in classical thermodynamics are applicable to fluids in constant motion. Experiments show that the results of ...
Página 14
... defined are thermodynamic properties, because they are defined in terms of other properties of the system. That is, we can determine Cp and Cv when two other properties of the system (say, p and T) are given. For certain processes ...
... defined are thermodynamic properties, because they are defined in terms of other properties of the system. That is, we can determine Cp and Cv when two other properties of the system (say, p and T) are given. For certain processes ...
Página 16
... define the thermal expansion coefficient α ≡ − 1 ρ ( ∂ρ∂T ) p , (1.20) where the subscript “p” signifies that ... defined as one that obeys the thermal equation of state p = ρRT, (1.21) where p is the pressure, ρ is the density, T ...
... define the thermal expansion coefficient α ≡ − 1 ρ ( ∂ρ∂T ) p , (1.20) where the subscript “p” signifies that ... defined as one that obeys the thermal equation of state p = ρRT, (1.21) where p is the pressure, ρ is the density, T ...
Página 21
... defined as kilograms of salt per kilogram of water. (The salinity of sea water is ≈3%.) Here, one defines the potential density as the density attained if a particle is taken to a reference pressure isentropically and at constant ...
... defined as kilograms of salt per kilogram of water. (The salinity of sea water is ≈3%.) Here, one defines the potential density as the density attained if a particle is taken to a reference pressure isentropically and at constant ...
Contenido
1 | |
25 | |
53 | |
81 | |
139 | |
Irrotational Flow | 165 |
Gravity Waves | 213 |
Dynamic Similarity | 279 |
Turbulence | 537 |
Geophysical Fluid Dynamics | 603 |
Aerodynamics | 679 |
Compressible Flow | 713 |
Introduction to Biofluid
Mechanics | 765 |
Some Properties of
Common Fluids | 841 |
Curvilinear Coordinates | 845 |
Founders of
Modern Fluid Dynamics | 851 |
Laminar Flow | 295 |
Boundary Layers and Related
Topics | 339 |
Computational Fluid
Dynamics | 411 |
Instability | 467 |
Visual Resources | 855 |
Index | 857 |
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Términos y frases comunes
approximation assumed atmosphere average becomes blood body boundary conditions boundary layer called Chapter circulation components Consider constant continuity coordinates cylinder decreases defined density depends derivative determined developed direction discussed distribution drag dynamics effects element energy equal equation example expressed field Figure finite flow fluid follows force function given gives gravity heat horizontal important increases initial instability integral irrotational length limit linear mass mean Mechanics method momentum motion moving normal Note obtain particle plane plate positive potential pressure problem propagation region relation represents requires result Reynolds number rotation scale shear shock shown shows side similarity solution speed steady streamlines stress surface surface tension temperature tensor theory tube turbulent unit variables vector velocity viscous volume vortex vorticity wall wave written zero