Two-dimensional flow explained

In fluid mechanics, a two-dimensional flow is a form of fluid flow where the flow velocity at every point is parallel to a fixed plane. The velocity at any point on a given normal to that fixed plane should be constant.

Flow velocity in two dimensional flows

Flow velocity in Cartesian co-ordinates

Considering a two dimensional flow in the

X-Y

plane, the flow velocity at any point

(x,y,z)

at time

can be expressed as –

\bar{\boldsymbol{v}}(x,y,z,t)=v_{x(x,y,z,t)\hat{\boldsymbol{i}}}+v_{y(x,y,z,t)\hat{\boldsymbol{j}}.}

Velocity in cylindrical co-ordinates

Considering a two dimensional flow in the

r-\theta

plane, the flow velocity at a point

(r,\theta,z)

at a time

can be expressed as –

\bar{\boldsymbol{v}}(r,\theta,z,t)=v_{r(r,\theta,z,t)\hat{\boldsymbol{r}}}+v_{\theta(r,\theta,z,t)\hat{\boldsymbol{\theta}}.}

Vorticity in two dimensional flows

Vorticity in Cartesian co-ordinates

Vorticity in two dimensional flows in the

X-Y

plane can be expressed as –

\bar{\boldsymbol{\omega}}=\omega_{z\hat{\boldsymbol{k}},}

\omega

z=	\partialv_y
	\partialx

	\partialv_x
	\partialy

Vorticity in cylindrical co-ordinates

Vorticity in two dimensional flows in the

r-\theta

plane can be expressed as –

\bar{\boldsymbol{\omega}}=\omega_{z\hat{\boldsymbol{k}}}

\omega

z=	1
	r

	\partial	(r
	\partialr

	\partial\psi
	\partialr

	1
	r²

	\partial²\psi
	\partialr²

Two dimensional sources and sinks

Line/point source

that it generates.

Line/point sink

Similar to a line source, a line sink is a line which absorbs fluid flowing towards it, from planes perpendicular to it. When we consider 2-D flows on the perpendicular plane, it appears as a point sink.By symmetry, we assume the fluid flows radially inwards towards the sink.The strength of a sink is given by the volume flow rate

of the fluid it absorbs.

Types of two-dimensional flows

Uniform source flow

A radially symmetrical flow field directed outwards from a common point is called a source flow. The central common point is the line source described above. Fluid is supplied at a constant rate

from the source. As the fluid flows outward, the area of flow increases. As a result, to satisfy continuity equation, the velocity decreases and the streamlines spread out. The velocity at all points at a given distance from the source is the same.

The velocity of fluid flow can be given as -

\bar{\boldsymbol{v}}=v_{r(r)\hat{\boldsymbol{e}}}_r.

We can derive the relation between flow rate and velocity of the flow. Consider a cylinder of unit height, coaxial with the source. The rate at which the source emits fluid should be equal to the rate at which fluid flows out of the surface of the cylinder.

\int\limits_S\bar{\boldsymbol{v}} ⋅ {d\bar{\boldsymbol{S}}}=2\pirv_r(r)=Q,

\therefore

r(r)=	Q
	2\pir

The stream function associated with source flow is –

\psi(r,\theta)=

	Q
	2\pi

\theta.

The steady flow from a point source is irrotational, and can be derived from velocity potential. The velocity potential is given by –

\phi(r,\theta)=

	Q
	2\pi

lnr.

Uniform sink flow

Sink flow is the opposite of source flow. The streamlines are radial, directed inwards to the line source. As we get closer to the sink, area of flow decreases. In order to satisfy the continuity equation, the streamlines get bunched closer and the velocity increases as we get closer to the source. As with source flow, the velocity at all points equidistant from the sink is equal.

The velocity of the flow around the sink can be given by –

\bar{\boldsymbol{v}}=-v_r(r)\hat{\boldsymbol{e}}_r,

r(r)=	Q
	2\pir

The stream function associated with sink flow is –

\psi(r,\theta)=-

	Q
	2\pi

\theta.

The flow around a line sink is irrotational and can be derived from velocity potential. The velocity potential around a sink can be given by –

\phi(r,\theta)=-

	Q
	2\pi

lnr.

Irrotational vortex

A vortex is a region where the fluid flows around an imaginary axis.For an irrotational vortex, the flow at every point is such that a small particle placed there undergoes pure translation and does not rotate.Velocity varies inversely with radius in this case. Velocity will tend to

inf

r=0

that is the reason for center being a singular point. The velocity is mathematically expressed as –

\boldsymbol{v}=v_\theta\hat{\boldsymbol{e}}_\theta,

\theta=	K
	2\pir

Since the fluid flows around an axis,

v_r=0.

The stream function for irrotational vortices is given by –

\psi=-	K
	2\pi

lnr.

While the velocity potential is expressed as –

\phi=-	K
	2\pi

\theta.

For the closed curve enclosing origin, circulation (line integral of velocity field)

\Gamma=K

and for any other closed curves,

\Gamma=0

Doublet

A doublet can be thought of as a combination of a source and a sink of equal strengths kept at an infinitesimally small distance apart. Thus the streamlines can be seen to start and end at the same point.The strength of a doublet made by a source and sink of strength

kept a distance

is given by –

Λ=Q

	ds
	2\pi

The velocity of fluid flow can be expressed as –

\boldsymbol{v}=v_r\hat{\boldsymbol{e}}_r+v_\theta\hat{\boldsymbol{e}}_\theta,

v_r=-

	Λ
	r²

\cos\theta,

v_\theta=-

	Λ
	r²

\sin\theta.

The equations and the plot are for the limiting condition of

ds → 0

The concept of a doublet is very similar to that of electric dipoles and magnetic dipoles in electrodynamics.

External links

Two-dimensional sources and sinks