User:Incredio/Flow Past A Cylinder

Fluid flow past a cylinder is classical mathematical solution for the flow of an inviscid, incompressible fluid around a cylinder that is transverse to the flow. Far from the cylinder, the flow is unidirectional and uniform.

"The flow of an incompressible fluid past a cylinder is one of the first mathematical models that a student of fluid dynamics encounters. This flow is an excellent vehicle for the study of concepts that will be encountered numerous times in mathematical physics, such as vector fields, coordinate transformations, and most important, the physical interpretation of mathematical results." [1]

Mathematical solution

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Colors: pressure field. Red is high and blue is low. Velocity vectors.
 
Close-up view of one quadrant of the flow. Colors: pressure field. Red is high and blue is low. Velocity vectors.
 
Pressure field (colors), streamfunction (black) with contour interval 0f   from bottom to top, velocity potential (white) with contour interval   from left to right.

A cylinder (or disk) of radius   is placed in two-dimensional, incompressible, inviscid flow. The goal is to find the steady velocity vector   and pressure   in a plane, subject to the condition that far from the cylinder the velocity vector is

 

where   is a constant, and at the boundary of the cylinder

 

where   is vector normal to the cylinder surface. The upstream flow is uniform and has no vorticity. The flow is inviscid, incompressible and has constant mass density  . The flow therefore remains without vorticity, or is said to be irrotational, with   everywhere. Being irrotational, there must exist a velocity potential  :

 

Being incompressible,  , so   must satisify Laplace's equation:

 

The solution for   is obtained most easily in polar coordinates   and  , related to conventional Cartesian coordinates by   and  . In polar coordinates, Laplace's equation is:

 

The solution that satisfies the boundary conditions is [2]

 

The velocity components in polar coordinates are obtained from the components of   in polar coordinates:

 

and

 

Being invisicid and irrotational, Bernoulli's equation allows the solution for pressure field to be obtained directly form the velocity field:

 

where the constants   and   appear so that   far from the cylinder, where  . Using

 ,
 

In the figures, the colorized field referred to as "pressure" is a plot of

 

On the surface of the cylinder, or  , pressure varies from a maximum of 1 (red color) at the stagnation points at   and   to a minimum of -3 (purple) on the sides of the cylinder, at   and  . Likewise,   varies from V=0 at the stagnation points to   on the sides, in the low pressure.

Stream function

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The flow being incompressible, a stream function can be found such that

 

It follows from this definition, using vector identities,

 

Therefore a contour of a constant value of   will also be a stream line, a line tangent to  . For the flow past a cylinder, we find:

 

Physical interpretation

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Laplace's equation is linear, and is one of the most elementary partial differential equations. This simple equation yields the entire solution for both   and   because of the constraint of irrotation and incompressibility. Having obtained the solution for   and  , the consistency of the pressure gradient with the accelerations can be noted.

The dynamic pressure at the upstream stagnation point has value of  , a value needed to decelerate the free stream flow of speed U. This same value appears at the downstream stagnation point, this high pressure is again need to decelerate the flow to zero speed. This symmetry arises only because the flow is completely frictionless.

The low pressure on sides on the cylinder is need to provide the centripetal acceleration of the flow.

 

where   is the radius of curvature of the flow. But  , and  . The integral of the equation for centripetal acceleration, which will over a distance   will thus yield

 

The exact solution has, for the lowest pressure,

 

The low pressure, which must be present to provide the centripetal acceleration, will also increase the flow speed as the fluid travels from higher to lower values of pressure. Thus we find the maximum speed in the flow,  , in the low pressure on the sides of the cylinder.

A value of   is consistent with conservation of the volume of fluid. With the cylinder blocking some of the flow, V must be greater than U somewhere in the plane through the center of the cylinder and transverse to the flow.

Comparison with flow of a real fluid past a cylinder

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The symmetry of this ideal solution has the peculiar property of having zero net drag on the cylinder, a property known as D'Alembert's paradox. Unlike an ideal inviscid fluid, a viscous flow past a cylinder, no matter how small the viscosity, will acquire vorticity in a thin boundary layer adjacent to the cylinder. Boundary layer separation can occur, and a trailing wake will occur behind the cylinder. The pressure will be lower on the wake side of the cylinder, than on the upstream side, resulting in a drag force in the downstream direction.

References

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  1. ^ http://library.wolfram.com/infocenter/Articles/2731/
  2. ^ William S. Janna, Introduction to Fluid Mechanics, PWS Publishing Company, Boston (1993)