Fluid dynamics: Difference between revisions
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{{Short description|Aspects of fluid mechanics involving flow}} |
{{Short description|Aspects of fluid mechanics involving flow}} |
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[[File:Túnel de viento, vórtice de Von Karman.gif|thumb|upright=1.4|Computer generated animation of fluid in a tube flowing past a cylinder, showing the [[vortex shedding|shedding]] of a series of [[vortex|vortices]] in the flow behind it, called a [[von Kármán vortex street]]. The [[Streamlines, streaklines, and pathlines|streamlines]] show the direction of the fluid flow, and the color gradient shows the pressure at each point, from blue to green, yellow, and red indicating increasing pressure]] |
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{{Continuum mechanics|fluid}} |
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[[File:Teardrop shape.svg|thumb|300px|Typical [[aerodynamic]] teardrop shape, assuming a [[Viscosity|viscous]] medium passing from left to right, the diagram shows the pressure distribution as the thickness of the black line and shows the velocity in the [[boundary layer]] as the violet triangles. The green [[vortex generator]]s prompt the transition to [[turbulent flow]] and prevent back-flow also called [[flow separation]] from the high-pressure region in the back. The surface in front is as smooth as possible or even employs [[Dermal denticle|shark-like skin]], as any turbulence here increases the energy of the airflow. The truncation on the right, known as a [[Kammback]], also prevents backflow from the high-pressure region in the back across the [[Spoiler (aeronautics)|spoiler]]s to the convergent part.]] |
[[File:Teardrop shape.svg|thumb|300px|Typical [[aerodynamic]] teardrop shape, assuming a [[Viscosity|viscous]] medium passing from left to right, the diagram shows the pressure distribution as the thickness of the black line and shows the velocity in the [[boundary layer]] as the violet triangles. The green [[vortex generator]]s prompt the transition to [[turbulent flow]] and prevent back-flow also called [[flow separation]] from the high-pressure region in the back. The surface in front is as smooth as possible or even employs [[Dermal denticle|shark-like skin]], as any turbulence here increases the energy of the airflow. The truncation on the right, known as a [[Kammback]], also prevents backflow from the high-pressure region in the back across the [[Spoiler (aeronautics)|spoiler]]s to the convergent part.]] |
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{{Continuum mechanics|fluid}} |
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In [[physics]] and [[engineering]], '''fluid dynamics''' |
In [[physics]], [[physical chemistry]] and [[engineering]], '''fluid dynamics''' is a subdiscipline of [[fluid mechanics]] that describes the flow of [[fluid]]s – [[liquid]]s and [[gas]]es. It has several subdisciplines, including {{em|[[aerodynamics]]}} (the study of air and other gases in motion) and {{em|hydrodynamics}} (the study of water and other liquids in motion). Fluid dynamics has a wide range of applications, including calculating [[force]]s and [[moment (physics)|moment]]s on [[aircraft]], determining the [[mass flow rate]] of [[petroleum]] through [[pipeline transport|pipelines]], [[weather forecasting|predicting weather pattern]]s, understanding [[nebula]]e in [[interstellar space]] and [[Nuclear weapon design|modelling fission weapon detonation]]. |
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Fluid dynamics offers a systematic structure—which underlies these [[practical disciplines]]—that embraces empirical and semi-empirical laws derived from [[flow measurement]] and used to solve practical problems. The solution to a fluid dynamics problem typically involves the calculation of various properties of the fluid, such as [[flow velocity]], [[pressure]], [[density]], and [[temperature]], as functions of space and time. |
Fluid dynamics offers a systematic structure—which underlies these [[practical disciplines]]—that embraces empirical and semi-empirical laws derived from [[flow measurement]] and used to solve practical problems. The solution to a fluid dynamics problem typically involves the calculation of various properties of the fluid, such as [[flow velocity]], [[pressure]], [[density]], and [[temperature]], as functions of space and time. |
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Before the twentieth century, |
Before the twentieth century, "hydrodynamics" was synonymous with fluid dynamics. This is still reflected in names of some fluid dynamics topics, like [[magnetohydrodynamics]] and [[hydrodynamic stability]], both of which can also be applied to gases.<ref>{{Cite book | title=The Dawn of Fluid Dynamics: A Discipline Between Science and Technology | first=Michael | last=Eckert | publisher=Wiley | year=2006 | isbn=3-527-40513-5 | page=ix }}</ref> |
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==Equations== |
==Equations== |
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{{See also|Transport phenomena}} |
{{See also|Transport phenomena}} |
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The foundational axioms of fluid dynamics are the [[Conservation law (physics)|conservation law]]s, specifically, [[conservation of mass]], |
The foundational axioms of fluid dynamics are the [[Conservation law (physics)|conservation law]]s, specifically, [[conservation of mass]], [[conservation of momentum|conservation of linear momentum]], and [[conservation of energy]] (also known as the [[First Law of Thermodynamics]]). These are based on [[classical mechanics]] and are modified in [[quantum mechanics]] and [[general relativity]]. They are expressed using the [[Reynolds transport theorem]]. |
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In addition to the above, fluids are assumed to obey the [[continuum assumption]]. |
In addition to the above, fluids are assumed to obey the [[continuum assumption]]. At small scale, all fluids are composed of molecules that collide with one another and solid objects. However, the continuum assumption assumes that fluids are continuous, rather than discrete. Consequently, it is assumed that properties such as density, pressure, temperature, and flow velocity are well-defined at [[infinitesimal]]ly small points in space and vary continuously from one point to another. The fact that the fluid is made up of discrete molecules is ignored. |
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For fluids that are sufficiently dense to be a continuum, do not contain ionized species, and have flow velocities that are small in relation to the speed of light, the momentum equations for [[Newtonian fluid]]s are the [[Navier–Stokes equations]]—which is a [[non-linear]] set of [[differential equations]] that describes the flow of a fluid whose stress depends linearly on flow velocity gradients and pressure. The unsimplified equations do not have a general [[Solution in closed form|closed-form solution]], so they are primarily of use in [[computational fluid dynamics]]. |
For fluids that are sufficiently dense to be a continuum, do not contain ionized species, and have flow velocities that are small in relation to the speed of light, the momentum equations for [[Newtonian fluid]]s are the [[Navier–Stokes equations]]—which is a [[non-linear]] set of [[differential equations]] that describes the flow of a fluid whose stress depends linearly on flow velocity gradients and pressure. The unsimplified equations do not have a general [[Solution in closed form|closed-form solution]], so they are primarily of use in [[computational fluid dynamics]]. The equations can be simplified in several ways, all of which make them easier to solve. Some of the simplifications allow some simple fluid dynamics problems to be solved in closed form.{{citation needed|date= May 2014}} |
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In addition to the mass, momentum, and energy conservation equations, a [[thermodynamics|thermodynamic]] equation of state that gives the pressure as a function of other thermodynamic variables is required to completely describe the problem. An example of this would be the [[Ideal gas law|perfect gas equation of state]]: |
In addition to the mass, momentum, and energy conservation equations, a [[thermodynamics|thermodynamic]] equation of state that gives the pressure as a function of other thermodynamic variables is required to completely describe the problem. An example of this would be the [[Ideal gas law|perfect gas equation of state]]: |
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===Conservation laws=== |
===Conservation laws=== |
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Three conservation laws are used to solve fluid dynamics problems, and may be written in [[integral]] or [[Differential (infinitesimal)|differential]] form. The conservation laws may be applied to a region of the flow called a ''control volume''. |
Three conservation laws are used to solve fluid dynamics problems, and may be written in [[integral]] or [[Differential (infinitesimal)|differential]] form. The conservation laws may be applied to a region of the flow called a ''control volume''. A control volume is a discrete volume in space through which fluid is assumed to flow. The integral formulations of the conservation laws are used to describe the change of mass, momentum, or energy within the control volume. Differential formulations of the conservation laws apply [[Stokes' theorem]] to yield an expression that may be interpreted as the integral form of the law applied to an infinitesimally small volume (at a point) within the flow. |
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{{glossary}} |
{{glossary}} |
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where {{math|{{sfrac|D|D''t''}}}} is the [[material derivative]], which is the sum of [[time derivative|local]] and [[convective derivative]]s. This additional constraint simplifies the governing equations, especially in the case when the fluid has a uniform density. |
where {{math|{{sfrac|D|D''t''}}}} is the [[material derivative]], which is the sum of [[time derivative|local]] and [[convective derivative]]s. This additional constraint simplifies the governing equations, especially in the case when the fluid has a uniform density. |
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For flow of gases, to determine whether to use compressible or incompressible fluid dynamics, the [[Mach number]] of the flow is evaluated. As a rough guide, compressible effects can be ignored at Mach numbers below approximately 0.3. |
For flow of gases, to determine whether to use compressible or incompressible fluid dynamics, the [[Mach number]] of the flow is evaluated. As a rough guide, compressible effects can be ignored at Mach numbers below approximately 0.3. For liquids, whether the incompressible assumption is valid depends on the fluid properties (specifically the critical pressure and temperature of the fluid) and the flow conditions (how close to the critical pressure the actual flow pressure becomes). [[acoustics|Acoustic]] problems always require allowing compressibility, since [[sound waves]] are compression waves involving changes in pressure and density of the medium through which they propagate. |
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===Newtonian versus non-Newtonian fluids=== |
===Newtonian versus non-Newtonian fluids=== |
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===Laminar versus turbulent flow=== |
===Laminar versus turbulent flow=== |
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[[File:Laminar-turbulent transition.jpg|thumb|The transition from laminar to turbulent flow]] |
[[File:Laminar-turbulent transition.jpg|thumb|The transition from laminar to turbulent flow]] |
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Turbulence is flow characterized by recirculation, [[Eddy (fluid dynamics)|eddies]], and apparent [[random]]ness. |
Turbulence is flow characterized by recirculation, [[Eddy (fluid dynamics)|eddies]], and apparent [[random]]ness. Flow in which turbulence is not exhibited is called [[laminar flow|laminar]]. The presence of eddies or recirculation alone does not necessarily indicate turbulent flow—these phenomena may be present in laminar flow as well. Mathematically, turbulent flow is often represented via a [[Reynolds decomposition]], in which the flow is broken down into the sum of an [[average]] component and a perturbation component. |
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It is believed that turbulent flows can be described well through the use of the [[Navier–Stokes equations]]. [[Direct numerical simulation]] (DNS), based on the Navier–Stokes equations, makes it possible to simulate turbulent flows at moderate Reynolds numbers. Restrictions depend on the power of the computer used and the efficiency of the solution algorithm. The results of DNS have been found to agree well with experimental data for some flows.<ref>See, for example, Schlatter et al, Phys. Fluids 21, 051702 (2009); {{doi|10.1063/1.3139294}}</ref> |
It is believed that turbulent flows can be described well through the use of the [[Navier–Stokes equations]]. [[Direct numerical simulation]] (DNS), based on the Navier–Stokes equations, makes it possible to simulate turbulent flows at moderate Reynolds numbers. Restrictions depend on the power of the computer used and the efficiency of the solution algorithm. The results of DNS have been found to agree well with experimental data for some flows.<ref>See, for example, Schlatter et al, Phys. Fluids 21, 051702 (2009); {{doi|10.1063/1.3139294}}</ref> |
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Most flows of interest have Reynolds numbers much too high for DNS to be a viable option,<ref name=pope/>{{rp|344}} given the state of computational power for the next few decades. |
Most flows of interest have Reynolds numbers much too high for DNS to be a viable option,<ref name=pope/>{{rp|344}} given the state of computational power for the next few decades. Any flight vehicle large enough to carry a human ({{mvar|L}} > 3 m), moving faster than {{cvt|20|m/s|km/h mph}} is well beyond the limit of DNS simulation ({{mvar|Re}} = 4 million). Transport aircraft wings (such as on an [[Airbus A300]] or [[Boeing 747]]) have Reynolds numbers of 40 million (based on the wing chord dimension). Solving these real-life flow problems requires turbulence models for the foreseeable future. [[Reynolds-averaged Navier–Stokes equations]] (RANS) combined with [[turbulence modelling]] provides a model of the effects of the turbulent flow. Such a modelling mainly provides the additional momentum transfer by the [[Reynolds stresses]], although the turbulence also enhances the [[heat transfer|heat]] and [[mass transfer]]. Another promising methodology is [[large eddy simulation]] (LES), especially in the form of [[detached eddy simulation]] (DES) — a combination of LES and RANS turbulence modelling. |
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===Other approximations=== |
===Other approximations=== |
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===Relativistic fluid dynamics=== |
===Relativistic fluid dynamics=== |
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Relativistic fluid dynamics studies the macroscopic and microscopic fluid motion at large velocities comparable to the [[velocity of light]].<ref>{{cite book |last1=Landau |first1=Lev Davidovich |author1-link=Lev Landau|author2-link=Evgeny Lifshitz|first2=Evgenii Mikhailovich |last2=Lifshitz |title=Fluid Mechanics |location=London |publisher=Pergamon |year=1987 |isbn=0-08-033933-6 }}</ref> This branch of fluid dynamics accounts for the relativistic effects both from the [[special theory of relativity]] and the [[general theory of relativity]]. The governing equations are derived in [[Riemannian geometry]] for [[Minkowski spacetime]]. |
Relativistic fluid dynamics studies the macroscopic and microscopic fluid motion at large velocities comparable to the [[velocity of light]].<ref>{{cite book |last1=Landau |first1=Lev Davidovich |author1-link=Lev Landau|author2-link=Evgeny Lifshitz|first2=Evgenii Mikhailovich |last2=Lifshitz |title=Fluid Mechanics |location=London |publisher=Pergamon |year=1987 |isbn=0-08-033933-6 }}</ref> This branch of fluid dynamics accounts for the relativistic effects both from the [[special theory of relativity]] and the [[general theory of relativity]]. The governing equations are derived in [[Riemannian geometry]] for [[Minkowski spacetime]]. |
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=== Fluctuating hydrodynamics === |
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This branch of fluid dynamics augments the standard hydrodynamic equations with stochastic fluxes that model |
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thermal fluctuations.<ref>{{ cite book | last1= Ortiz de Zarate | first1= Jose M. | last2= Sengers | first2= Jan V. | title= Hydrodynamic Fluctuations in Fluids and Fluid Mixtures | publisher= Elsevier | location= Amsterdam | year= 2006}}</ref> |
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As formulated by [[Lev Landau|Landau]] and [[Evgeny Lifshitz|Lifshitz]],<ref>{{ cite book |last1=Landau |first1=Lev Davidovich |author1-link=Lev Landau|author2-link=Evgeny Lifshitz|first2=Evgenii Mikhailovich |last2=Lifshitz |title=Fluid Mechanics |location=London |publisher=Pergamon |year=1959 }}</ref> |
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a [[white noise]] contribution obtained from the [[fluctuation-dissipation theorem]] of [[statistical mechanics]] |
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is added to the [[viscous stress tensor]] and [[heat flux]]. |
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== Terminology == |
== Terminology == |
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The concept of pressure is central to the study of both fluid statics and fluid dynamics. |
The concept of pressure is central to the study of both fluid statics and fluid dynamics. A pressure can be identified for every point in a body of fluid, regardless of whether the fluid is in motion or not. Pressure can be [[Pressure measurement|measured]] using an aneroid, Bourdon tube, mercury column, or various other methods. |
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Some of the terminology that is necessary in the study of fluid dynamics is not found in other similar areas of study. |
Some of the terminology that is necessary in the study of fluid dynamics is not found in other similar areas of study. In particular, some of the terminology used in fluid dynamics is not used in [[fluid statics]]. |
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=== Characteristic numbers === |
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{{excerpt|Dimensionless numbers in fluid mechanics}} |
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=== Terminology in incompressible fluid dynamics === |
=== Terminology in incompressible fluid dynamics === |
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The concepts of total pressure and [[dynamic pressure]] arise from [[Bernoulli's equation]] and are significant in the study of all fluid flows. |
The concepts of total pressure and [[dynamic pressure]] arise from [[Bernoulli's equation]] and are significant in the study of all fluid flows. (These two pressures are not pressures in the usual sense—they cannot be measured using an aneroid, Bourdon tube or mercury column.) To avoid potential ambiguity when referring to pressure in fluid dynamics, many authors use the term [[static pressure]] to distinguish it from total pressure and dynamic pressure. [[Static pressure]] is identical to pressure and can be identified for every point in a fluid flow field. |
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A point in a fluid flow where the flow has come to rest (that is to say, speed is equal to zero adjacent to some solid body immersed in the fluid flow) is of special significance. |
A point in a fluid flow where the flow has come to rest (that is to say, speed is equal to zero adjacent to some solid body immersed in the fluid flow) is of special significance. It is of such importance that it is given a special name—a [[stagnation point]]. The static pressure at the stagnation point is of special significance and is given its own name—[[stagnation pressure]]. In incompressible flows, the stagnation pressure at a stagnation point is equal to the total pressure throughout the flow field. |
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=== Terminology in compressible fluid dynamics === |
=== Terminology in compressible fluid dynamics === |
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In a compressible fluid, it is convenient to define the total conditions (also called stagnation conditions) for all thermodynamic state properties (such as total temperature, total enthalpy, total speed of sound). |
In a compressible fluid, it is convenient to define the total conditions (also called stagnation conditions) for all thermodynamic state properties (such as total temperature, total enthalpy, total speed of sound). These total flow conditions are a function of the fluid velocity and have different values in frames of reference with different motion. |
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To avoid potential ambiguity when referring to the properties of the fluid associated with the state of the fluid rather than its motion, the prefix "static" is commonly used (such as static temperature and static enthalpy). |
To avoid potential ambiguity when referring to the properties of the fluid associated with the state of the fluid rather than its motion, the prefix "static" is commonly used (such as static temperature and static enthalpy). Where there is no prefix, the fluid property is the static condition (so "density" and "static density" mean the same thing). The static conditions are independent of the frame of reference. |
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Because the total flow conditions are defined by [[isentropic]]ally bringing the fluid to rest, there is no need to distinguish between total entropy and static entropy as they are always equal by definition. |
Because the total flow conditions are defined by [[isentropic]]ally bringing the fluid to rest, there is no need to distinguish between total entropy and static entropy as they are always equal by definition. As such, entropy is most commonly referred to as simply "entropy". |
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== |
==See also== |
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{{Main|Outline of fluid dynamics}} |
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* [[List of publications in physics#Fluid dynamics|List of publications in fluid dynamics]] |
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=== Fields of study === |
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* [[List of fluid dynamicists]] |
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*[[Acoustic theory]] |
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*[[Aerodynamics]] |
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*[[Aeroelasticity]] |
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*[[Aeronautics]] |
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*[[Computational fluid dynamics]] |
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*[[Flow measurement]] |
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*[[Geophysical fluid dynamics]] |
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*[[haemodynamics|Hemodynamics]] |
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*[[Hydraulics]] |
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*[[Hydrology]] |
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*[[Hydrostatics]] |
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*[[Electrohydrodynamics]] |
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*[[Magnetohydrodynamics]] |
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*[[Quantum hydrodynamics]] |
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===Mathematical equations and concepts=== |
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*[[Airy wave theory]] |
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*[[Benjamin–Bona–Mahony equation]] |
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*[[Boussinesq approximation (water waves)]] |
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*[[Different types of boundary conditions in fluid dynamics]] |
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*[[Elementary flow]] |
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*[[Helmholtz's theorems]] |
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*[[Kirchhoff equations]] |
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*[[Knudsen equation]] |
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*[[Manning equation]] |
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*[[Mild-slope equation]] |
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*[[Morison equation]] |
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*[[Navier–Stokes equations]] |
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*[[Oseen flow]] |
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*[[Poiseuille's law]] |
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*[[Pressure head]] |
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*[[Relativistic Euler equations]] |
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*[[Stokes stream function]] |
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*[[Stream function]] |
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*[[Streamlines, streaklines and pathlines]] |
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*[[Torricelli's Law]] |
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=== Types of fluid flow === |
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*[[Aerodynamic force]] |
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*[[Convection]] |
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*[[Cavitation]] |
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*[[Compressible flow]] |
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*[[Couette flow]] |
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*[[Effusive limit]] |
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*[[Free molecular flow]] |
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*[[Incompressible flow]] |
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*[[Inviscid flow]] |
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*[[Isothermal flow]] |
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*[[Open channel flow]] |
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*[[Pipe flow]] |
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*[[Pressure-driven flow]] |
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*[[Secondary flow]] |
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*[[Stream thrust averaging]] |
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*[[Superfluidity]] |
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*[[Transient flow]] |
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*[[Two-phase flow]] |
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=== Fluid properties === |
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*[[List of hydrodynamic instabilities]] |
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*[[Newtonian fluid]] |
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*[[Non-Newtonian fluid]] |
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*[[Surface tension]] |
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*[[Vapour pressure]] |
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===Fluid phenomena=== |
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*[[Balanced flow]] |
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*[[Boundary layer]] |
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*[[Coanda effect]] |
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*[[Convection cell]] |
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*[[squeeze mapping#Corner flow|Convergence/Bifurcation]] |
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*[[Darwin drift]] |
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*[[Drag (force)]] |
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*[[Droplet vaporization]] |
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*[[Hydrodynamic stability]] |
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*[[Kaye effect]] |
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*[[Lift (force)]] |
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*[[Magnus effect]] |
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*[[Ocean current]] |
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*[[Ocean surface waves]] |
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*[[Rossby wave]] |
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*[[Shock wave]] |
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*[[Soliton]] |
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*[[Stokes drift]] |
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*[[Teapot effect]] |
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*[[Fluid thread breakup|Thread breakup]] |
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*[[Turbulent jet breakup]] |
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*[[Upstream contamination]] |
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*[[Venturi effect]] |
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*[[Vortex]] |
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*[[Water hammer]] |
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*[[Wave drag]] |
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*[[Wind]] |
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===Applications=== |
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*[[Acoustics]] |
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*[[Aerodynamics]] |
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*[[Cryosphere science]] |
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*[[EFDC Explorer]] |
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*[[Fluidics]] |
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*[[Fluid power]] |
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*[[Geodynamics]] |
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*[[Hydraulic machinery]] |
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*[[Meteorology]] |
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*[[Naval architecture]] |
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*[[Oceanography]] |
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*[[Plasma physics]] |
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*[[Pneumatics]] |
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*[[3D computer graphics]] |
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=== Fluid dynamics journals === |
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* ''[[Annual Review of Fluid Mechanics]]'' |
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* ''[[Journal of Fluid Mechanics]]'' |
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* ''[[Physics of Fluids]]'' |
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* ''[[Physical Review Fluids]]'' |
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* ''[[Experiments in Fluids]]'' |
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* ''European Journal of Mechanics B: Fluids'' |
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* ''Theoretical and Computational Fluid Dynamics'' |
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* ''Computers and Fluids'' |
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* ''[[International Journal for Numerical Methods in Fluids]]'' |
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* ''[[Flow, Turbulence and Combustion]]'' |
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=== Miscellaneous === |
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{{Div col|colwidth=20em}} |
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*[[List of publications in physics#Fluid dynamics|Important publications in fluid dynamics]] |
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*[[Isosurface]] |
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*[[Keulegan–Carpenter number]] |
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*[[Rotating tank]] |
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*[[Sound barrier]] |
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*[[Beta plane]] |
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*[[Immersed boundary method]] |
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*[[Bridge scour]] |
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*[[Finite volume method for unsteady flow]] |
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* [[Flow visualization]] |
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==See also== |
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{{Div col}} |
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* {{Annotated link|Aileron}} |
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* {{Annotated link|Airplane}} |
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* {{Annotated link|Angle of attack}} |
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* {{Annotated link|Banked turn}} |
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* {{Annotated link|Bernoulli's principle}} |
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* {{Annotated link|Bilgeboard}} |
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* {{Annotated link|Boomerang}} |
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* {{Annotated link|Centerboard}} |
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* {{Annotated link|Chord (aircraft)}} |
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* {{Annotated link|Circulation control wing}} |
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* {{Annotated link|Currentology}} |
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* {{Annotated link|Diving plane}} |
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* {{Annotated link|Downforce}} |
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* {{Annotated link|Drag coefficient}} |
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* {{Annotated link|Fin}} |
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* {{Annotated link|Flipper (anatomy)}} |
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* {{Annotated link|Flow separation}} |
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* {{Annotated link|Foil (fluid mechanics)}} |
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* {{Annotated link|Fluid coupling}} |
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* {{Annotated link|Gas kinetics}} |
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* {{Annotated link|Hydrofoil}} |
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* {{Annotated link|Keel}} (hydrodynamic) |
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* {{Annotated link|Küssner effect}} |
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* {{Annotated link|Kutta condition}} |
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* {{Annotated link|Kutta–Joukowski theorem}} |
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* {{Annotated link|Lift coefficient}} |
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* {{Annotated link|Lift-induced drag}} |
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* {{Annotated link|Lift-to-drag ratio}} |
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* {{Annotated link|Lifting-line theory}} |
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* {{Annotated link|NACA airfoil}} |
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* {{Annotated link|Newton's third law}} |
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* {{Annotated link|Propeller}} |
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* {{Annotated link|Pump}} |
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* {{Annotated link|Rudder}} |
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* {{Annotated link|Sail}} (aerodynamics) |
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* {{Annotated link|Skeg}} |
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* {{Annotated link|Spoiler (automotive)}} |
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* {{Annotated link|Stall (flight)}} |
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* {{Annotated link|Surfboard fin}} |
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* {{Annotated link|Surface science}} |
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* {{Annotated link|Torque converter}} |
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* {{Annotated link|Trim tab}} |
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* {{Annotated link|Wing}} |
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* {{Annotated link|Wingtip vortices}} |
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== References == |
== References == |
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* {{cite book|last=Batchelor|first=G. K.|author-link=George Batchelor|title=An Introduction to Fluid Dynamics|publisher=Cambridge University Press|year=1967|isbn=0-521-66396-2}} |
* {{cite book|last=Batchelor|first=G. K.|author-link=George Batchelor|title=An Introduction to Fluid Dynamics|publisher=Cambridge University Press|year=1967|isbn=0-521-66396-2}} |
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* {{cite book|last=Chanson|first=H.|author-link=Hubert Chanson|title=Applied Hydrodynamics: An Introduction to Ideal and Real Fluid Flows|publisher=CRC Press, Taylor & Francis Group, Leiden, The Netherlands, 478 pages|year=2009|isbn=978-0-415-49271-3}} |
* {{cite book|last=Chanson|first=H.|author-link=Hubert Chanson|title=Applied Hydrodynamics: An Introduction to Ideal and Real Fluid Flows|publisher=CRC Press, Taylor & Francis Group, Leiden, The Netherlands, 478 pages|year=2009|isbn=978-0-415-49271-3}} |
||
* {{cite book|last=Clancy|first=L. J.|title=Aerodynamics|publisher=Pitman Publishing Limited|location=London|year=1975|isbn=0-273-01120-0}} |
* {{cite book|last=Clancy|first=L. J.|authorlink=Laurence Clancy|title=Aerodynamics|publisher=Pitman Publishing Limited|location=London|year=1975|isbn=0-273-01120-0}} |
||
* {{cite book|last=Lamb|first=Horace|author-link=Horace Lamb|title=Hydrodynamics|edition=6th|publisher=Cambridge University Press|year=1994|isbn=0-521-45868-4}} Originally published in 1879, the 6th extended edition appeared first in 1932. |
* {{cite book|last=Lamb|first=Horace|author-link=Horace Lamb|title=Hydrodynamics|edition=6th|publisher=Cambridge University Press|year=1994|isbn=0-521-45868-4}} Originally published in 1879, the 6th extended edition appeared first in 1932. |
||
* {{cite book|last=Milne-Thompson|first=L. M.|title=Theoretical Hydrodynamics|edition=5th|publisher=Macmillan|year=1968}} Originally published in 1938. |
* {{cite book|last=Milne-Thompson|first=L. M.|title=Theoretical Hydrodynamics|edition=5th|publisher=Macmillan|year=1968}} Originally published in 1938. |
||
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* [http://web.mit.edu/hml/ncfmf.html National Committee for Fluid Mechanics Films (NCFMF)], containing films on several subjects in fluid dynamics (in [[RealMedia]] format) |
* [http://web.mit.edu/hml/ncfmf.html National Committee for Fluid Mechanics Films (NCFMF)], containing films on several subjects in fluid dynamics (in [[RealMedia]] format) |
||
* [https://gfm.aps.org/ Gallery of fluid motion], "a visual record of the aesthetic and science of contemporary fluid mechanics," from the [[American Physical Society]] |
* [https://gfm.aps.org/ Gallery of fluid motion], "a visual record of the aesthetic and science of contemporary fluid mechanics," from the [[American Physical Society]] |
||
* [https:// |
* [https://www.iist.ac.in/sites/default/files/people/fm_books.html List of Fluid Dynamics books] |
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{{Fluid Mechanics}} |
{{Fluid Mechanics}} |
Latest revision as of 16:00, 11 November 2024
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In physics, physical chemistry and engineering, fluid dynamics is a subdiscipline of fluid mechanics that describes the flow of fluids – liquids and gases. It has several subdisciplines, including aerodynamics (the study of air and other gases in motion) and hydrodynamics (the study of water and other liquids in motion). Fluid dynamics has a wide range of applications, including calculating forces and moments on aircraft, determining the mass flow rate of petroleum through pipelines, predicting weather patterns, understanding nebulae in interstellar space and modelling fission weapon detonation.
Fluid dynamics offers a systematic structure—which underlies these practical disciplines—that embraces empirical and semi-empirical laws derived from flow measurement and used to solve practical problems. The solution to a fluid dynamics problem typically involves the calculation of various properties of the fluid, such as flow velocity, pressure, density, and temperature, as functions of space and time.
Before the twentieth century, "hydrodynamics" was synonymous with fluid dynamics. This is still reflected in names of some fluid dynamics topics, like magnetohydrodynamics and hydrodynamic stability, both of which can also be applied to gases.[1]
Equations
[edit]The foundational axioms of fluid dynamics are the conservation laws, specifically, conservation of mass, conservation of linear momentum, and conservation of energy (also known as the First Law of Thermodynamics). These are based on classical mechanics and are modified in quantum mechanics and general relativity. They are expressed using the Reynolds transport theorem.
In addition to the above, fluids are assumed to obey the continuum assumption. At small scale, all fluids are composed of molecules that collide with one another and solid objects. However, the continuum assumption assumes that fluids are continuous, rather than discrete. Consequently, it is assumed that properties such as density, pressure, temperature, and flow velocity are well-defined at infinitesimally small points in space and vary continuously from one point to another. The fact that the fluid is made up of discrete molecules is ignored.
For fluids that are sufficiently dense to be a continuum, do not contain ionized species, and have flow velocities that are small in relation to the speed of light, the momentum equations for Newtonian fluids are the Navier–Stokes equations—which is a non-linear set of differential equations that describes the flow of a fluid whose stress depends linearly on flow velocity gradients and pressure. The unsimplified equations do not have a general closed-form solution, so they are primarily of use in computational fluid dynamics. The equations can be simplified in several ways, all of which make them easier to solve. Some of the simplifications allow some simple fluid dynamics problems to be solved in closed form.[citation needed]
In addition to the mass, momentum, and energy conservation equations, a thermodynamic equation of state that gives the pressure as a function of other thermodynamic variables is required to completely describe the problem. An example of this would be the perfect gas equation of state:
where p is pressure, ρ is density, and T is the absolute temperature, while Ru is the gas constant and M is molar mass for a particular gas. A constitutive relation may also be useful.
Conservation laws
[edit]Three conservation laws are used to solve fluid dynamics problems, and may be written in integral or differential form. The conservation laws may be applied to a region of the flow called a control volume. A control volume is a discrete volume in space through which fluid is assumed to flow. The integral formulations of the conservation laws are used to describe the change of mass, momentum, or energy within the control volume. Differential formulations of the conservation laws apply Stokes' theorem to yield an expression that may be interpreted as the integral form of the law applied to an infinitesimally small volume (at a point) within the flow.
- Mass continuity (conservation of mass)
- The rate of change of fluid mass inside a control volume must be equal to the net rate of fluid flow into the volume. Physically, this statement requires that mass is neither created nor destroyed in the control volume,[2] and can be translated into the integral form of the continuity equation:
In the above integral formulation of this equation, the term on the left is the net change of momentum within the volume. The first term on the right is the net rate at which momentum is convected into the volume. The second term on the right is the force due to pressure on the volume's surfaces. The first two terms on the right are negated since momentum entering the system is accounted as positive, and the normal is opposite the direction of the velocity u and pressure forces. The third term on the right is the net acceleration of the mass within the volume due to any body forces (here represented by fbody). Surface forces, such as viscous forces, are represented by Fsurf, the net force due to shear forces acting on the volume surface. The momentum balance can also be written for a moving control volume.[3]
The following is the differential form of the momentum conservation equation. Here, the volume is reduced to an infinitesimally small point, and both surface and body forces are accounted for in one total force, F. For example, F may be expanded into an expression for the frictional and gravitational forces acting at a point in a flow.
Classifications
[edit]Compressible versus incompressible flow
[edit]All fluids are compressible to an extent; that is, changes in pressure or temperature cause changes in density. However, in many situations the changes in pressure and temperature are sufficiently small that the changes in density are negligible. In this case the flow can be modelled as an incompressible flow. Otherwise the more general compressible flow equations must be used.
Mathematically, incompressibility is expressed by saying that the density ρ of a fluid parcel does not change as it moves in the flow field, that is,
where D/Dt is the material derivative, which is the sum of local and convective derivatives. This additional constraint simplifies the governing equations, especially in the case when the fluid has a uniform density.
For flow of gases, to determine whether to use compressible or incompressible fluid dynamics, the Mach number of the flow is evaluated. As a rough guide, compressible effects can be ignored at Mach numbers below approximately 0.3. For liquids, whether the incompressible assumption is valid depends on the fluid properties (specifically the critical pressure and temperature of the fluid) and the flow conditions (how close to the critical pressure the actual flow pressure becomes). Acoustic problems always require allowing compressibility, since sound waves are compression waves involving changes in pressure and density of the medium through which they propagate.
Newtonian versus non-Newtonian fluids
[edit]All fluids, except superfluids, are viscous, meaning that they exert some resistance to deformation: neighbouring parcels of fluid moving at different velocities exert viscous forces on each other. The velocity gradient is referred to as a strain rate; it has dimensions T−1. Isaac Newton showed that for many familiar fluids such as water and air, the stress due to these viscous forces is linearly related to the strain rate. Such fluids are called Newtonian fluids. The coefficient of proportionality is called the fluid's viscosity; for Newtonian fluids, it is a fluid property that is independent of the strain rate.
Non-Newtonian fluids have a more complicated, non-linear stress-strain behaviour. The sub-discipline of rheology describes the stress-strain behaviours of such fluids, which include emulsions and slurries, some viscoelastic materials such as blood and some polymers, and sticky liquids such as latex, honey and lubricants.[5]
Inviscid versus viscous versus Stokes flow
[edit]The dynamic of fluid parcels is described with the help of Newton's second law. An accelerating parcel of fluid is subject to inertial effects.
The Reynolds number is a dimensionless quantity which characterises the magnitude of inertial effects compared to the magnitude of viscous effects. A low Reynolds number (Re ≪ 1) indicates that viscous forces are very strong compared to inertial forces. In such cases, inertial forces are sometimes neglected; this flow regime is called Stokes or creeping flow.
In contrast, high Reynolds numbers (Re ≫ 1) indicate that the inertial effects have more effect on the velocity field than the viscous (friction) effects. In high Reynolds number flows, the flow is often modeled as an inviscid flow, an approximation in which viscosity is completely neglected. Eliminating viscosity allows the Navier–Stokes equations to be simplified into the Euler equations. The integration of the Euler equations along a streamline in an inviscid flow yields Bernoulli's equation. When, in addition to being inviscid, the flow is irrotational everywhere, Bernoulli's equation can completely describe the flow everywhere. Such flows are called potential flows, because the velocity field may be expressed as the gradient of a potential energy expression.
This idea can work fairly well when the Reynolds number is high. However, problems such as those involving solid boundaries may require that the viscosity be included. Viscosity cannot be neglected near solid boundaries because the no-slip condition generates a thin region of large strain rate, the boundary layer, in which viscosity effects dominate and which thus generates vorticity. Therefore, to calculate net forces on bodies (such as wings), viscous flow equations must be used: inviscid flow theory fails to predict drag forces, a limitation known as the d'Alembert's paradox.
A commonly used[6] model, especially in computational fluid dynamics, is to use two flow models: the Euler equations away from the body, and boundary layer equations in a region close to the body. The two solutions can then be matched with each other, using the method of matched asymptotic expansions.
Steady versus unsteady flow
[edit]A flow that is not a function of time is called steady flow. Steady-state flow refers to the condition where the fluid properties at a point in the system do not change over time. Time dependent flow is known as unsteady (also called transient[8]). Whether a particular flow is steady or unsteady, can depend on the chosen frame of reference. For instance, laminar flow over a sphere is steady in the frame of reference that is stationary with respect to the sphere. In a frame of reference that is stationary with respect to a background flow, the flow is unsteady.
Turbulent flows are unsteady by definition. A turbulent flow can, however, be statistically stationary. The random velocity field U(x, t) is statistically stationary if all statistics are invariant under a shift in time.[9]: 75 This roughly means that all statistical properties are constant in time. Often, the mean field is the object of interest, and this is constant too in a statistically stationary flow.
Steady flows are often more tractable than otherwise similar unsteady flows. The governing equations of a steady problem have one dimension fewer (time) than the governing equations of the same problem without taking advantage of the steadiness of the flow field.
Laminar versus turbulent flow
[edit]Turbulence is flow characterized by recirculation, eddies, and apparent randomness. Flow in which turbulence is not exhibited is called laminar. The presence of eddies or recirculation alone does not necessarily indicate turbulent flow—these phenomena may be present in laminar flow as well. Mathematically, turbulent flow is often represented via a Reynolds decomposition, in which the flow is broken down into the sum of an average component and a perturbation component.
It is believed that turbulent flows can be described well through the use of the Navier–Stokes equations. Direct numerical simulation (DNS), based on the Navier–Stokes equations, makes it possible to simulate turbulent flows at moderate Reynolds numbers. Restrictions depend on the power of the computer used and the efficiency of the solution algorithm. The results of DNS have been found to agree well with experimental data for some flows.[10]
Most flows of interest have Reynolds numbers much too high for DNS to be a viable option,[9]: 344 given the state of computational power for the next few decades. Any flight vehicle large enough to carry a human (L > 3 m), moving faster than 20 m/s (72 km/h; 45 mph) is well beyond the limit of DNS simulation (Re = 4 million). Transport aircraft wings (such as on an Airbus A300 or Boeing 747) have Reynolds numbers of 40 million (based on the wing chord dimension). Solving these real-life flow problems requires turbulence models for the foreseeable future. Reynolds-averaged Navier–Stokes equations (RANS) combined with turbulence modelling provides a model of the effects of the turbulent flow. Such a modelling mainly provides the additional momentum transfer by the Reynolds stresses, although the turbulence also enhances the heat and mass transfer. Another promising methodology is large eddy simulation (LES), especially in the form of detached eddy simulation (DES) — a combination of LES and RANS turbulence modelling.
Other approximations
[edit]There are a large number of other possible approximations to fluid dynamic problems. Some of the more commonly used are listed below.
- The Boussinesq approximation neglects variations in density except to calculate buoyancy forces. It is often used in free convection problems where density changes are small.
- Lubrication theory and Hele–Shaw flow exploits the large aspect ratio of the domain to show that certain terms in the equations are small and so can be neglected.
- Slender-body theory is a methodology used in Stokes flow problems to estimate the force on, or flow field around, a long slender object in a viscous fluid.
- The shallow-water equations can be used to describe a layer of relatively inviscid fluid with a free surface, in which surface gradients are small.
- Darcy's law is used for flow in porous media, and works with variables averaged over several pore-widths.
- In rotating systems, the quasi-geostrophic equations assume an almost perfect balance between pressure gradients and the Coriolis force. It is useful in the study of atmospheric dynamics.
Multidisciplinary types
[edit]Flows according to Mach regimes
[edit]While many flows (such as flow of water through a pipe) occur at low Mach numbers (subsonic flows), many flows of practical interest in aerodynamics or in turbomachines occur at high fractions of M = 1 (transonic flows) or in excess of it (supersonic or even hypersonic flows). New phenomena occur at these regimes such as instabilities in transonic flow, shock waves for supersonic flow, or non-equilibrium chemical behaviour due to ionization in hypersonic flows. In practice, each of those flow regimes is treated separately.
Reactive versus non-reactive flows
[edit]Reactive flows are flows that are chemically reactive, which finds its applications in many areas, including combustion (IC engine), propulsion devices (rockets, jet engines, and so on), detonations, fire and safety hazards, and astrophysics. In addition to conservation of mass, momentum and energy, conservation of individual species (for example, mass fraction of methane in methane combustion) need to be derived, where the production/depletion rate of any species are obtained by simultaneously solving the equations of chemical kinetics.
Magnetohydrodynamics
[edit]Magnetohydrodynamics is the multidisciplinary study of the flow of electrically conducting fluids in electromagnetic fields. Examples of such fluids include plasmas, liquid metals, and salt water. The fluid flow equations are solved simultaneously with Maxwell's equations of electromagnetism.
Relativistic fluid dynamics
[edit]Relativistic fluid dynamics studies the macroscopic and microscopic fluid motion at large velocities comparable to the velocity of light.[11] This branch of fluid dynamics accounts for the relativistic effects both from the special theory of relativity and the general theory of relativity. The governing equations are derived in Riemannian geometry for Minkowski spacetime.
Fluctuating hydrodynamics
[edit]This branch of fluid dynamics augments the standard hydrodynamic equations with stochastic fluxes that model thermal fluctuations.[12] As formulated by Landau and Lifshitz,[13] a white noise contribution obtained from the fluctuation-dissipation theorem of statistical mechanics is added to the viscous stress tensor and heat flux.
Terminology
[edit]The concept of pressure is central to the study of both fluid statics and fluid dynamics. A pressure can be identified for every point in a body of fluid, regardless of whether the fluid is in motion or not. Pressure can be measured using an aneroid, Bourdon tube, mercury column, or various other methods.
Some of the terminology that is necessary in the study of fluid dynamics is not found in other similar areas of study. In particular, some of the terminology used in fluid dynamics is not used in fluid statics.
Characteristic numbers
[edit]Dimensionless numbers (or characteristic numbers) have an important role in analyzing the behavior of fluids and their flow as well as in other transport phenomena.[14] They include the Reynolds and the Mach numbers, which describe as ratios the relative magnitude of fluid and physical system characteristics, such as density, viscosity, speed of sound, and flow speed.
To compare a real situation (e.g. an aircraft) with a small-scale model it is necessary to keep the important characteristic numbers the same. Names and formulation of these numbers were standardized in ISO 31-12 and in ISO 80000-11.Terminology in incompressible fluid dynamics
[edit]The concepts of total pressure and dynamic pressure arise from Bernoulli's equation and are significant in the study of all fluid flows. (These two pressures are not pressures in the usual sense—they cannot be measured using an aneroid, Bourdon tube or mercury column.) To avoid potential ambiguity when referring to pressure in fluid dynamics, many authors use the term static pressure to distinguish it from total pressure and dynamic pressure. Static pressure is identical to pressure and can be identified for every point in a fluid flow field.
A point in a fluid flow where the flow has come to rest (that is to say, speed is equal to zero adjacent to some solid body immersed in the fluid flow) is of special significance. It is of such importance that it is given a special name—a stagnation point. The static pressure at the stagnation point is of special significance and is given its own name—stagnation pressure. In incompressible flows, the stagnation pressure at a stagnation point is equal to the total pressure throughout the flow field.
Terminology in compressible fluid dynamics
[edit]In a compressible fluid, it is convenient to define the total conditions (also called stagnation conditions) for all thermodynamic state properties (such as total temperature, total enthalpy, total speed of sound). These total flow conditions are a function of the fluid velocity and have different values in frames of reference with different motion.
To avoid potential ambiguity when referring to the properties of the fluid associated with the state of the fluid rather than its motion, the prefix "static" is commonly used (such as static temperature and static enthalpy). Where there is no prefix, the fluid property is the static condition (so "density" and "static density" mean the same thing). The static conditions are independent of the frame of reference.
Because the total flow conditions are defined by isentropically bringing the fluid to rest, there is no need to distinguish between total entropy and static entropy as they are always equal by definition. As such, entropy is most commonly referred to as simply "entropy".
See also
[edit]References
[edit]- ^ Eckert, Michael (2006). The Dawn of Fluid Dynamics: A Discipline Between Science and Technology. Wiley. p. ix. ISBN 3-527-40513-5.
- ^ a b Anderson, J. D. (2007). Fundamentals of Aerodynamics (4th ed.). London: McGraw–Hill. ISBN 978-0-07-125408-3.
- ^ Nangia, Nishant; Johansen, Hans; Patankar, Neelesh A.; Bhalla, Amneet Pal S. (2017). "A moving control volume approach to computing hydrodynamic forces and torques on immersed bodies". Journal of Computational Physics. 347: 437–462. arXiv:1704.00239. Bibcode:2017JCoPh.347..437N. doi:10.1016/j.jcp.2017.06.047. S2CID 37560541.
- ^ White, F. M. (1974). Viscous Fluid Flow. New York: McGraw–Hill. ISBN 0-07-069710-8.
- ^ Wilson, DI (February 2018). "What is Rheology?". Eye. 32 (2): 179–183. doi:10.1038/eye.2017.267. PMC 5811736. PMID 29271417.
- ^ Platzer, B. (2006-12-01). "Book Review: Cebeci, T. and Cousteix, J., Modeling and Computation of Boundary-Layer Flows". ZAMM. 86 (12): 981–982. Bibcode:2006ZaMM...86..981P. doi:10.1002/zamm.200690053. ISSN 0044-2267.
- ^ Shengtai Li, Hui Li "Parallel AMR Code for Compressible MHD or HD Equations" (Los Alamos National Laboratory) [1] Archived 2016-03-03 at the Wayback Machine
- ^ "Transient state or unsteady state? -- CFD Online Discussion Forums". www.cfd-online.com.
- ^ a b Pope, Stephen B. (2000). Turbulent Flows. Cambridge University Press. ISBN 0-521-59886-9.
- ^ See, for example, Schlatter et al, Phys. Fluids 21, 051702 (2009); doi:10.1063/1.3139294
- ^ Landau, Lev Davidovich; Lifshitz, Evgenii Mikhailovich (1987). Fluid Mechanics. London: Pergamon. ISBN 0-08-033933-6.
- ^ Ortiz de Zarate, Jose M.; Sengers, Jan V. (2006). Hydrodynamic Fluctuations in Fluids and Fluid Mixtures. Amsterdam: Elsevier.
- ^ Landau, Lev Davidovich; Lifshitz, Evgenii Mikhailovich (1959). Fluid Mechanics. London: Pergamon.
- ^ "ISO 80000-1:2009". International Organization for Standardization. Retrieved 2019-09-15.
Further reading
[edit]- Acheson, D. J. (1990). Elementary Fluid Dynamics. Clarendon Press. ISBN 0-19-859679-0.
- Batchelor, G. K. (1967). An Introduction to Fluid Dynamics. Cambridge University Press. ISBN 0-521-66396-2.
- Chanson, H. (2009). Applied Hydrodynamics: An Introduction to Ideal and Real Fluid Flows. CRC Press, Taylor & Francis Group, Leiden, The Netherlands, 478 pages. ISBN 978-0-415-49271-3.
- Clancy, L. J. (1975). Aerodynamics. London: Pitman Publishing Limited. ISBN 0-273-01120-0.
- Lamb, Horace (1994). Hydrodynamics (6th ed.). Cambridge University Press. ISBN 0-521-45868-4. Originally published in 1879, the 6th extended edition appeared first in 1932.
- Milne-Thompson, L. M. (1968). Theoretical Hydrodynamics (5th ed.). Macmillan. Originally published in 1938.
- Shinbrot, M. (1973). Lectures on Fluid Mechanics. Gordon and Breach. ISBN 0-677-01710-3.
- Nazarenko, Sergey (2014), Fluid Dynamics via Examples and Solutions, CRC Press (Taylor & Francis group), ISBN 978-1-43-988882-7
- Encyclopedia: Fluid dynamics Scholarpedia
External links
[edit]- National Committee for Fluid Mechanics Films (NCFMF), containing films on several subjects in fluid dynamics (in RealMedia format)
- Gallery of fluid motion, "a visual record of the aesthetic and science of contemporary fluid mechanics," from the American Physical Society
- List of Fluid Dynamics books