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Flow velocity

Flow velocity, also known as fluid velocity, is a vector quantity in fluid dynamics that describes the speed and direction of motion of fluid particles at a specific point in a flow field, typically denoted as \vec{v}( \mathbf{x}, t ) where \mathbf{x} is the position and t is time.^[1] It is measured in units of length per time, such as meters per second (m/s), and forms the basis of the velocity vector field, which maps instantaneous velocities across the entire fluid domain at any given moment.^[2] This concept is essential for characterizing fluid motion, whether in liquids or gases, and distinguishes flow velocity from scalar measures like speed by incorporating directional information critical for analyzing complex flows. The magnitude of flow velocity plays a pivotal role in quantifying fluid transport, particularly through the relation to volumetric flow rate Q = A v, where A is the cross-sectional area perpendicular to the flow and v is the average velocity.^[3] This relationship underpins the continuity equation, \nabla \cdot (\rho \vec{v}) = 0 for incompressible steady flows, ensuring conservation of mass by linking velocity variations to changes in density \rho or area.^[3] In practice, flow velocity influences phenomena like laminar versus turbulent regimes, determined by the Reynolds number Re = \frac{\rho v D}{\mu}, where D is a characteristic length and \mu is dynamic viscosity, with low Re indicating smooth, orderly flow and high Re signaling chaotic turbulence.^[4] Flow velocity is central to the governing equations of fluid motion, notably the Navier-Stokes equations, which predict the evolution of the velocity field under forces like pressure gradients, viscosity, and external body forces, expressed as \rho \left( \frac{\partial \vec{v}}{\partial t} + \vec{v} \cdot \nabla \vec{v} \right) = -\nabla p + \mu \nabla^2 \vec{v} + \rho \vec{g} for incompressible Newtonian fluids. Solutions to these equations yield the velocity field, enabling simulations of real-world behaviors from steady pipe flows to unsteady vortex shedding.^[5] In engineering applications, accurate measurement and control of flow velocity are vital for designing pipelines, optimizing aerodynamic shapes in aerospace, calibrating wind tunnels for testing, and monitoring processes in chemical and biomedical industries.^[6]^[7] Techniques such as particle image velocimetry (PIV) or ultrasonic Doppler methods allow non-invasive profiling of velocity fields, supporting advancements in turbulence modeling and flow control strategies.^[8]

Core Concepts

Definition

Flow velocity is a vector quantity \vec{v} that describes the instantaneous velocity of fluid particles at a given point in space and time, capturing both the speed and direction of the fluid's motion.^[9] In fluid mechanics, this velocity represents the rate at which fluid elements move through the continuum, essential for analyzing how fluids behave under various conditions.^[3] In Cartesian coordinates, the flow velocity is expressed as \vec{v} = u \hat{i} + v \hat{j} + w \hat{k}, where u, v, and w are the scalar components along the x, y, and z directions, respectively, each potentially varying with position and time.^[9] This vector notation allows for precise computation of fluid trajectories and interactions in three-dimensional space. Unlike scalar flow speed, which measures only the magnitude |\vec{v}| = \sqrt{u^2 + v^2 + w^2}, flow velocity emphasizes the directional nature critical to fluid dynamics, such as in determining shear stresses or convective transport.^[10] This distinguishes it from particle velocity in classical kinematics, where motion is typically described for discrete objects using Lagrangian tracking, whereas flow velocity employs an Eulerian framework fixed to spatial points to describe the collective behavior of the fluid continuum.^[11] The concept of flow velocity originated in 18th-century fluid mechanics through Leonhard Euler's foundational work on inviscid fluid motion in 1757, and was further developed in the 19th century with the inclusion of viscous effects in the Navier-Stokes equations by Claude-Louis Navier and George Gabriel Stokes.^[12]^[13]

Velocity Field

In fluid dynamics, the velocity field \vec{v}(\vec{r}, t) represents the velocity vector of the fluid at every point in a three-dimensional spatial domain, where \vec{r} denotes the position vector and t is time, thereby defining a continuous vector field that characterizes the motion throughout the fluid volume.^[14] This Eulerian description captures the flow's spatial and temporal variations by assigning a velocity to fixed points in space, rather than tracking individual fluid particles.^[15] For incompressible flows, where fluid density remains constant, the velocity field must satisfy the continuity equation \nabla \cdot \vec{v} = 0, which enforces the conservation of mass by ensuring that the net flux through any closed surface is zero.^[16] This condition implies that the field is divergence-free, preventing local expansion or contraction of the fluid elements.^[17] Velocity fields can be uniform, as in regions far from boundaries where \vec{v} remains constant in magnitude and direction across the domain, or non-uniform, such as in the vicinity of an obstacle where spatial gradients arise due to boundary effects and flow acceleration.^[18] For instance, uniform flow approximates conditions in a straight pipe with parallel walls, while non-uniform flow manifests around a cylinder in a cross-stream, exhibiting variations in speed and direction.^[19] To visualize the velocity field, streamlines are employed, which are instantaneous curves everywhere tangent to the local velocity vectors, providing a snapshot of the flow pattern at a fixed time.^[20] Pathlines, in contrast, trace the trajectories followed by individual fluid particles over time, revealing the historical paths within the evolving field.^[21] In steady flows, these two representations coincide, simplifying the analysis of persistent flow structures.^[15]

Flow Characteristics

Steady Flow

In fluid dynamics, steady flow refers to a condition where the velocity field remains constant over time at any fixed point in the flow domain. Mathematically, this is expressed as the partial derivative of the velocity vector with respect to time being zero, \partial \vec{v}/\partial t = 0, indicating that the flow properties observed from a stationary vantage point do not vary temporally. This definition aligns with the Eulerian perspective, which focuses on changes in fluid properties at specific spatial locations rather than following individual fluid particles.^[22]^[23] A key property of steady flow is that pathlines, which trace the trajectories of individual fluid particles, coincide exactly with streamlines, which are instantaneous lines tangent to the velocity vector at every point. This equivalence simplifies flow visualization and analysis, as the steady nature ensures that streaklines—injected tracer paths—also align with these lines, eliminating discrepancies that arise in time-varying flows. The dominance of the Eulerian description in steady flow allows engineers and researchers to predict velocity profiles without accounting for transient effects, facilitating the use of time-independent governing equations.^[15]^[24] Steady flow finds widespread application in scenarios such as fully developed pipe flow and uniform open-channel flow, where constant inlet conditions lead to time-invariant velocity distributions. In these cases, the assumption of steadiness simplifies the Navier-Stokes equations by eliminating the local time derivative term, reducing the momentum equation to a form that balances convective acceleration, pressure gradients, viscous forces, and body forces without temporal unsteadiness. For instance, in pipe flow, this leads to the Hagen-Poiseuille solution for laminar conditions, highlighting how steady assumptions enable analytical tractability in engineering design.^[25]^[26] Representative examples illustrate the range of steady flows. In a straight duct with constant cross-section and uniform pressure gradient, the flow achieves a constant axial velocity profile after an entrance length, exemplifying ideal steady conditions in internal flows. Conversely, the steady wake behind a circular cylinder at low Reynolds numbers (typically Re < 40) features symmetric recirculating vortices without shedding, demonstrating how steady flow can persist in external aerodynamics despite spatial variations in velocity. These cases underscore the practical utility of steady flow approximations in modeling persistent fluid behaviors.^[27]^[28]

Unsteady Flow

Unsteady flow in fluid mechanics refers to the condition where the velocity field \vec{v}(\vec{x}, t) varies with time at fixed points in space, mathematically expressed by the local acceleration term \partial \vec{v}/\partial t \neq 0.^[29] This temporal variation distinguishes unsteady flow from steady flow, which serves as a limiting case where \partial \vec{v}/\partial t = 0.^[15] In such flows, fluid properties like velocity evolve dynamically, often driven by external forcings or internal instabilities, leading to complex spatiotemporal behaviors in the velocity field.^[30] A fundamental characteristic of unsteady flow is the decomposition of the material acceleration, which follows individual fluid particles along their paths. The material derivative of the velocity, D\vec{v}/Dt, captures the total acceleration experienced by a fluid element and is given by

\frac{D\vec{v}}{Dt} = \frac{\partial \vec{v}}{\partial t} + (\vec{v} \cdot \nabla) \vec{v},

where the first term represents local acceleration due to explicit time dependence, and the second term denotes convective acceleration arising from spatial variations in the velocity field advected by the flow itself.^[31] Even in steady flows, convective acceleration can be significant, but unsteady flows introduce the additional local term, amplifying the challenges in predicting particle trajectories and overall flow evolution.^[32] This distinction is crucial for understanding phenomena where time-dependent changes dominate, such as in transient responses to sudden disturbances. Common examples of unsteady flow include oscillatory motions like surface waves on water, where velocity oscillates periodically due to wave propagation and energy transfer.^[29] Startup flows in pipes, initiated by sudden valve opening, exhibit initial transients as the velocity profile develops from rest to a quasi-steady state, involving both inertial and viscous effects.^[33] Another representative case is pulsatile blood flow in arteries, driven by the heart's cyclic pumping, resulting in time-varying velocity profiles that peak during systole and diminish during diastole.^[34] Simulating unsteady flows poses significant computational challenges, primarily due to the need for time-resolved numerical schemes that march forward in time, requiring finer temporal resolutions and greater resources compared to steady-state analyses.^[35] These simulations are essential for capturing transient phenomena like vortex shedding behind bluff bodies, where alternating vortices are periodically released, generating unsteady wakes that can lead to structural vibrations or noise.^[29] Vortex shedding exemplifies the role of unsteadiness in instability-driven flows, with the Strouhal number often characterizing the shedding frequency relative to flow speed and body size.^[36]

Flow Types

Incompressible Flow

In incompressible flow, the fluid density \rho is assumed to be constant throughout the flow field, which implies that the material derivative of density is zero: \frac{D\rho}{Dt} = 0. This assumption leads to the continuity equation simplifying to the divergence-free condition on the velocity field: \nabla \cdot \vec{v} = 0, ensuring that the volume of any fluid element remains constant as it moves through the flow. This solenoidal nature of the velocity field is a direct consequence of mass conservation under constant density, making it particularly suitable for modeling flows where compressibility effects are negligible.^[37] A key implication of this constant density is the principle of volume conservation, which dictates that the velocity magnitude adjusts to maintain constant volumetric flow rate in confined geometries such as ducts or pipes. For steady, one-dimensional flow, this manifests as the relation A_1 v_1 = A_2 v_2, where A is the cross-sectional area and v is the average velocity; thus, a reduction in area results in an increase in velocity to preserve the flow rate. This inverse relationship between velocity and cross-sectional area is fundamental to analyzing pipe networks and channel flows, simplifying predictions of velocity profiles without needing to account for density variations.^[17] Incompressible flow assumptions find wide application in low-speed liquid flows, such as water transport through pipelines, where the high bulk modulus of liquids minimizes density changes even under pressure variations. They are also employed in atmospheric boundary layers, where near-surface air motions occur at speeds much lower than the speed of sound, allowing simplified modeling of turbulence and wind profiles over terrain. Additionally, these approximations are standard in subsonic aerodynamics for velocities below Mach 0.3, such as airflow over low-speed aircraft wings or ship hulls in water.^[4]^[38] The validity of the incompressible approximation holds when compressibility effects are negligible, typically for flows where the Mach number M < 0.3, as this limits density variations to less than about 5% and suppresses acoustic wave propagation influences on the velocity field. For liquids, the assumption is robust except in scenarios involving rapid transients like sound waves, while for gases, it breaks down at higher speeds where thermal and pressure-induced density changes become significant. Exceeding these conditions requires transitioning to compressible flow models to accurately capture velocity behaviors.^[4]

Compressible Flow

In compressible flow, the fluid density \rho varies significantly due to changes in pressure, temperature, or velocity, distinguishing it from incompressible regimes where density is assumed constant. This variation is governed by the full continuity equation, \frac{\partial \rho}{\partial t} + \nabla \cdot (\rho \vec{v}) = 0, which ensures conservation of mass in unsteady or spatially varying density fields.^[39]^[40] The flow velocity \vec{v} plays a central role through the Mach number, defined as Ma = \frac{|\vec{v}|}{a}, where a is the local speed of sound, typically a = \sqrt{\gamma R T} for an ideal gas with \gamma as the specific heat ratio, R the gas constant, and T the temperature.^[41] Subsonic flow occurs when Ma < 1, allowing pressure disturbances to propagate upstream and influence the velocity field smoothly, while supersonic flow (Ma > 1) features velocities exceeding the speed of sound, leading to hyperbolic wave propagation and potential discontinuities.^[42] These regimes profoundly affect velocity profiles, with compressibility effects becoming negligible only for Ma \lesssim 0.3.^[43] Compressible flow principles are essential in high-speed aerodynamics, such as the design of transonic and supersonic aircraft where velocity gradients induce density changes impacting lift and drag.^[44] In propulsion systems like rocket nozzles, converging-diverging geometries accelerate flow to supersonic speeds, optimizing exhaust velocity for thrust.^[44] Shock waves, abrupt discontinuities in supersonic flows, cause sudden jumps in velocity—typically a decrease across a normal shock—along with increases in pressure and density, as seen in bow shocks ahead of high-speed vehicles.^[45] The momentum and continuity equations are coupled to the energy equation in compressible analyses, where the energy balance incorporates kinetic energy terms \frac{1}{2} \rho |\vec{v}|^2 and relates velocity to thermodynamic variables like temperature, enabling prediction of heating effects in high-speed flows.^[46]

Advanced Descriptions

Irrotational Flow

In fluid dynamics, irrotational flow describes a motion where the curl of the velocity field vanishes everywhere, expressed mathematically as \nabla \times \vec{v} = 0.^[47] This condition implies that fluid elements undergo translation and deformation without local rotation, distinguishing it from rotational flows where vorticity introduces spinning motion.^[48] The absence of vorticity simplifies the analysis by allowing the flow to be derived from a scalar field, making it particularly useful for theoretical modeling.^[49] A key property of irrotational flow is the existence of a velocity potential \phi, a scalar function such that the velocity vector is its gradient: \vec{v} = \nabla \phi.^[50] This representation stems directly from the vector calculus identity that the curl of a gradient is zero, ensuring consistency with the irrotational condition. For incompressible irrotational flows, substituting into the continuity equation yields Laplace's equation: \nabla^2 \phi = 0, which is an elliptic partial differential equation solvable via boundary value methods.^[47] Solutions to this equation provide the velocity field, enabling predictions of pressure and streamlines without solving the full Navier-Stokes equations.^[49] Irrotational flow finds applications in idealized scenarios, such as external aerodynamics around streamlined bodies like airfoils at low angles of attack, where viscous effects are minimal and flow remains attached.^[51] Basic configurations, including source and sink flows, model point-like mass addition or removal, serving as building blocks for more complex potential flows via superposition.^[50] These approximations are common in preliminary design of aircraft wings and propellers, providing insights into lift generation under inviscid assumptions.^[52] However, irrotational flow has significant limitations, as it assumes inviscid conditions and neglects boundary layer effects, rendering it invalid for viscous-dominated or separated flows.^[53] A classic illustration is d'Alembert's paradox, which demonstrates that steady, incompressible, irrotational flow around a closed body predicts zero net drag force, despite experimental evidence of drag in real fluids due to viscosity and wake formation.^[49] This discrepancy highlights the need for viscous corrections in practical engineering analyses.^[54]

Vorticity

Vorticity quantifies the local rotation of fluid elements within a flow and is defined as the curl of the velocity field: \vec{\omega} = \nabla \times \vec{v}.^[55] This vector measures the angular velocity of infinitesimal fluid parcels, distinguishing rotational motion from pure deformation or translation.^[56] In three-dimensional flows, \vec{\omega} has components given by \omega_x = \frac{\partial v_z}{\partial y} - \frac{\partial v_y}{\partial z}, \omega_y = \frac{\partial v_x}{\partial z} - \frac{\partial v_z}{\partial x}, and \omega_z = \frac{\partial v_y}{\partial x} - \frac{\partial v_x}{\partial y}, with its magnitude |\vec{\omega}| representing the rotation rate perpendicular to the plane of the shearing velocities.^[57] In two-dimensional flows, vorticity simplifies to a scalar, typically the out-of-plane component \omega_z, which captures the rotation in the flow plane.^[56] The generation and evolution of vorticity are governed by the vorticity transport equation, derived from the Navier-Stokes equations for incompressible, viscous flows:

\frac{D\vec{\omega}}{Dt} = (\vec{\omega} \cdot \nabla)\vec{v} + \nu \nabla^2 \vec{\omega}.

Here, \frac{D\vec{\omega}}{Dt} is the material derivative of vorticity, the term (\vec{\omega} \cdot \nabla)\vec{v} accounts for vortex stretching and tilting that amplifies vorticity in three dimensions, and \nu \nabla^2 \vec{\omega} represents diffusive spreading due to viscosity.^[57] In inviscid flows, the diffusion term vanishes, allowing vorticity to be conserved along fluid particle paths except through stretching effects.^[57] Baroclinic torque from density gradients can also generate vorticity in compressible or stratified flows, though this is absent in uniform-density cases.^[56] Vorticity plays a central role in vortex dynamics, such as in tornadoes, where horizontal vorticity from wind shear is tilted into the vertical by updrafts, intensifying the rotational core. Wingtip vortices on aircraft wings form due to concentrated spanwise vorticity rolling up from pressure differences across the wing, creating persistent trailing helical structures that pose hazards to following aircraft.^[58] In turbulence, vorticity concentrates into coherent tubular structures that drive enstrophy production and cascade energy to smaller scales, facilitating dissipation through viscous effects.^[59] These applications highlight vorticity's utility in modeling rotational flow phenomena beyond irrotational approximations, where \vec{\omega} = 0.^[56]

Velocity Potential

In irrotational flows, the velocity field can be expressed as the gradient of a scalar function known as the velocity potential, denoted by \phi. This representation simplifies the description of the flow since the curl of the velocity is zero by definition for irrotational conditions. The convention for the relationship varies in literature: commonly, \vec{v} = -\nabla \phi, such that the velocity components are u = -\frac{\partial \phi}{\partial x}, v = -\frac{\partial \phi}{\partial y}, and w = -\frac{\partial \phi}{\partial z} in Cartesian coordinates, though some texts use \vec{v} = \nabla \phi.^[50]^[60] For incompressible irrotational flows, the velocity potential satisfies Laplace's equation, \nabla^2 \phi = 0, which arises from the continuity equation \nabla \cdot \vec{v} = 0 combined with the irrotational condition. This elliptic partial differential equation allows solutions that are harmonic functions, enabling analytical or numerical methods to determine \phi throughout the flow domain.^[50]^[61] Boundary conditions for solving Laplace's equation typically involve specifying either the value of \phi (Dirichlet condition) or its normal derivative (Neumann condition) on the boundaries. In potential flow past solid surfaces, the Neumann condition \frac{\partial \phi}{\partial n} = 0 is standard, enforcing zero normal velocity to satisfy the impermeability requirement, where n is the outward normal direction. Dirichlet conditions may be applied in cases where \phi is prescribed, such as on far-field boundaries approximating uniform flow.^[60]^[62] Basic solutions to Laplace's equation can be superposed linearly to model complex flows due to the equation's linearity. For uniform flow in the x-direction with speed U, the potential is \phi = -U x (under the \vec{v} = -\nabla \phi convention), yielding constant velocity everywhere. A doublet, representing the limiting case of a source and sink of equal strength approaching each other, has the 2D potential \phi = -\frac{\mu \cos \theta}{2\pi r}, where \mu is the doublet strength, r is the radial distance, and \theta is the polar angle; superposing this with uniform flow models the irrotational flow around a circular cylinder.^[50]^[18]^[51]

Aggregate Measures

Bulk Velocity

Bulk velocity, often referred to as the mean or average velocity in fluid dynamics, represents the area-weighted average of the local fluid velocities across a given cross-sectional area perpendicular to the flow direction. This scalar value provides a single, representative measure of the flow speed for the entire section, assuming the velocity is primarily uniform in direction. It is particularly useful in scenarios where detailed velocity profiles are not required, but an overall flow characterization is needed.^[63]^[64] Mathematically, the bulk velocity U_b is defined as

U_b = \frac{1}{A} \int_A \vec{v} \cdot d\vec{A},

where A is the cross-sectional area, \vec{v} is the local velocity vector, and d\vec{A} is the differential area vector normal to the cross-section. This integral form ensures the calculation accounts for variations in velocity magnitude across the area while weighting each contribution by the local area element. The resulting U_b directly relates to the volumetric flow rate Q through the equation Q = U_b A, enabling straightforward determination of flow rates from measured or estimated bulk velocities.^[65]^[66] In engineering contexts, bulk velocity is commonly applied to assess flow rates in pipelines, where it simplifies the design and analysis of pressure drops and energy requirements. For instance, in pipe systems transporting liquids or gases, U_b is used to ensure velocities remain within acceptable limits to avoid excessive friction or erosion. Similarly, in ventilation systems, it helps quantify air movement through ducts, aiding in the optimization of airflow for building comfort and efficiency.^[64]^[67]^[68] For incompressible fluids, where density \rho is constant, the bulk velocity connects to the mass flow rate \dot{m} via \dot{m} = \rho U_b A. This relationship stems from the continuity equation and is essential for systems like water distribution networks or hydraulic machinery, where conserving mass flow is critical for performance predictions.^[66]

Average Velocity

In unsteady flows, the average velocity is obtained through time-averaging the instantaneous velocity over a period much longer than the characteristic turbulence timescales but shorter than any large-scale unsteadiness in the mean flow. This is mathematically expressed as

\langle \vec{v} \rangle = \frac{1}{T} \int_0^T \vec{v}(t) \, dt,

where T is the averaging interval and \vec{v}(t) is the instantaneous velocity vector.^[69] Such averaging smooths out temporal fluctuations to yield a representative mean flow field, essential for analyzing periodic or quasi-steady behaviors in engineering applications. For compressible flows, where density \rho varies significantly, the mass-averaged velocity provides a physically meaningful mean that weights contributions by local mass flux:

\vec{v}_m = \frac{\int_V \rho \vec{v} \, dV}{\int_V \rho \, dV},

with the integral taken over the control volume V.^[70] This approach, also known as Favre averaging when applied to turbulent fluctuations, ensures conservation properties in the averaged equations by using density-weighted means, such as \tilde{\vec{v}} = \overline{\rho \vec{v}} / \overline{\rho}, where the overbar denotes conventional time-averaging.^[70] In turbulent flows, Reynolds averaging decomposes the velocity into a time-averaged mean and a fluctuating component: \vec{v} = \langle \vec{v} \rangle + \vec{v}', where \langle \vec{v}' \rangle = 0.^[69] This decomposition, originally developed by Osborne Reynolds in his analysis of viscous fluid dynamics, leads to the Reynolds-averaged Navier-Stokes equations, which introduce Reynolds stresses to account for momentum transfer by turbulent eddies.^[71] For compressible turbulence, Favre averaging extends this by using density-weighted decomposition \vec{v} = \tilde{\vec{v}} + \vec{v}'', with \tilde{\vec{v}''} = 0, to handle variable density effects more robustly; this was formalized by Alexandre Favre building on earlier density-weighting ideas.^[70] These averaging methods find widespread application in modeling turbulent pipe flows, where Reynolds averaging captures the mean velocity profile and shear stresses to predict friction factors and pressure drops in engineering systems.^[72] In atmospheric modeling, they enable simulation of turbulent mixing and transport in the boundary layer, with Favre averaging particularly useful for compressible regimes in high-altitude or convective flows to accurately represent density variations and scalar dispersion.^[73] Unlike bulk velocity, which assumes a simple area-weighted average for steady, incompressible flows with uniform properties, these techniques incorporate temporal fluctuations, density weighting, or turbulent correlations to provide more accurate representations in complex, variable conditions.^[70]

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Equations of Compressible Fluid Flow - Richard Fitzpatrick
For the case of compressible flow, the continuity equation (1.40), and the Navier-Stokes equation (1.56), must be augmented by the energy conservation equation ...<|control11|><|separator|>
[40]
[PDF] AA210A Fundamentals of Compressible Flow
Jan 19, 2022 · Use the differential equation for continuity to replace the partial derivative inside the first integral on the right-hand-side and use the ...
[41]
Isentropic Flow Equations
Isentropic flow is a reversible process with constant entropy. Key equations include Mach number (M=v/a), speed of sound (a=sqrt(gam*p/r)), and p/r^gam= ...
[42]
[PDF] 2t. Compressible Flow of Gases - MIT
The size of the Mach number indicates whether the flow is subsonic, M < 1; transonic, M~1; or supersonic, M> 1. The term hyporsonic is often used to describe ...
[43]
https://www.aerodynamics4students.com/gas-dynamics-and-supersonic-flow/gasdynamics_w.php?page=1
[44]
[PDF] Equations, Tables and Charts for Compressible Flow
velocity behind the shock wave is supersonic, and for the cone the still higher Mach number above which the flow is supersonic even at the surface. (For ...
[45]
Normal Shock Wave Equations
The Mach number and speed of the flow also decrease across a shock wave. If the shock wave is perpendicular to the flow direction it is called a normal shock.
[46]
9.4.2 Physics of Compressible Flows - AFS ENEA
Compressible flows are characterized by total pressure and temperature. The energy equation couples velocity and temperature. The ideal gas law is modified for ...
[47]
Irrotational Flow - Richard Fitzpatrick
Flow is said to be irrotational when the vorticity has the magnitude zero everywhere. It immediately follows, from Equation (4.77), that the circulation around ...Missing: dynamics | Show results with:dynamics
[48]
Irrotational Flow - an overview | ScienceDirect Topics
Irrotational flow refers to fluid flow in which the fluid particles do not rotate about their own axis while moving along the streamline. AI generated ...
[49]
[PDF] 3 IRROTATIONAL FLOWS, aka POTENTIAL FLOWS - DAMTP
φ = κθ/2π, and recall that this satisfies Laplace's equation everywhere except at the origin. The corresponding velocity field is u = ∇φ =.
[50]
[PDF] Potential Flow Theory - MIT
We can substitute in the relationship between potential and velocity and arrive at the Laplace Equation, which we will revisit in our discussion on linear ...
[51]
Potential Flow Theory – Introduction to Aerospace Flight Vehicles
Uniform flow – A constant velocity field where the flow direction and magnitude remain the same everywhere. Source and sink flows – Radial flow where fluid ...
[52]
Airfoil Theory - an overview | ScienceDirect Topics
Airfoil theory analyzes pressure distribution and lift generation on airfoils, using potential-flow theory and considering factors like camber and angle of ...
[53]
Potential Flow and d'Alembert's Paradox - MathPages
If the vorticity of a flowing fluid is everywhere zero, then the flow is said to be irrotational. Kelvin showed that vorticity is conserved in an ideal non ...
[54]
d'Alembert's Paradox - an overview | ScienceDirect Topics
There is no drag on an arbitrary-cross-section object in steady two-dimensional, irrotational constant-density flow, a more general statement of d'Alembert's ...
[55]
[PDF] Vorticity - MIT
o. The vorticity is defined as the curl of the velocity vec- tor: @=VX V. Thus each point in the fluid has an as- sociated vector vorticity, and the whole fluid ...
[56]
[PDF] Chapter 14: Vorticity [version 1214.1.K] - Caltech PMA
When viscous stresses make the fluid imperfect, then the vortex lines diffuse through the moving fluid with a diffusion coefficient that is equal to the ...
[57]
[PDF] The Vorticity equation
The diffusion of vorticity only occurs in viscous flows. • For 3D ... • For 2D flows, the vorticity transport equation. Dω. Dt. = ν∇2ω together with ...
[58]
[PDF] Experimental Study of the Structure of a Wingtip Vortex
The main purpose of this project is to investigate the characteristics of a wingtip vortex generated from a NACA. 0015 rectangular wing section. Of primary.
[59]
[PDF] Vorticity and Vortex Dynamics - ResearchGate
The vorticity plays a key role in the former, and a vortex is nothing but a fluid body with high concentration of vorticity compared to its surrounding fluid.
[60]
[PDF] Incompressible, Inviscid, Irrotational Flow
Under these conditions the boundary condition for potential flow at a solid boundary is. u.n = 0 or. ∂φ. ∂n. = 0. (Bga10) where the vector, n, and coordinate ...
[61]
3. Chapter 3: Potential Flow Theory
Uniform flow: This occurs when the fluid is flowing at a constant velocity in a straight line. It's important to note that this type of flow is an idealization ...Missing: non- | Show results with:non-
[62]
[PDF] Chapter on Potential Flow Theory --Potter and Foss
A note on boundary conditions for potential flows is in order. Laplace's equation is second-order and require boundary conditions on the complete boundary ...
[63]
Bulk Velocity - an overview | ScienceDirect Topics
Bulk velocity is the average velocity of a fluid flowing through a system, typically obtained from flow rate measurements.
[64]
Fluid Velocity Distribution within Pipes - Engineers Edge
Average (Bulk) Velocity Ia single average velocity to represent the velocity of all fluid at that point in the pipe. Liquid in Horizontal and Vertical Motion ...
[65]
[PDF] FLUID FLOW
analysis, the average velocity is then V = (1/A)∫v dA, and the mass flow rate can be written as. = VA. (4) or. Q = = AV. (5) where Q is volumetric flow rate.
[66]
12.1: Flow Rate and Its Relation to Velocity - Physics LibreTexts
Feb 20, 2022 · Flow rate \(Q\) is defined to be the volume \(V\) flowing past a point in time \(t\), or \(Q = \frac{V}{t}\) where \(V\) is volume and \(t\) is ...
[67]
[PDF] MMV211 Fluid Mechanics LABORATION 2a Pipe Flow Systems
MOTIVATION. Viscous flow in pipes or ducts appears in many technical applications, e.g., district heating systems, pipelines, cooling systems, ventilation ...
[68]
Useful information on pipe velocity - Michael Smith Engineers Ltd
Pipe velocity is an area averaged property which is independent of the pipe's cross-sectional flow distribution and whether the flow is laminar or turbulent.
[69]
[PDF] 7. Basics of Turbulent Flow - MIT
Below an overbar is used to denote a time average over the time interval t to t+T, where T is much longer than any turbulence time scale, but much shorter than ...
[70]
Implementing Turbulence Models into the Compressible RANS ...
There are many technical papers and texts that derive and/or describe the compressible Reynolds-averaged Navier-Stokes equations (also termed the Favre-averaged ...
[71]
IV. On the dynamical theory of incompressible viscous fluids and the ...
On the dynamical theory of incompressible viscous fluids and the determination of the criterion. Osborne Reynolds.
[72]
[PDF] Turbulent Pipe Flows
One example of the application of the universal turbulent velocity profile is to fully-developed turbulent flow in a circular pipe.
[73]
A Diagnostic for Evaluating the Representation of Turbulence in ...
The representation of turbulence in atmospheric models is essential as eddies impact both the mean flow through mixing, and by dispersion of TKE into ...