In fluid dynamics, a flow with periodic variations is known as pulsatile flow, or as Womersley flow. The flow profiles was first derived by John R. Womersley (1907–1958) in his work with blood flow in arteries.[1] The cardiovascular system of chordate animals is a very good example where pulsatile flow is found, but pulsatile flow is also observed in engines and hydraulic systems, as a result of rotating mechanisms pumping the fluid.
The pulsatile flow profile is given in a straight pipe by
u(r,t)=Re\left\{
| N | |
| \sum | |
| n=0 |
| iP'n | |
| \rhon\omega |
\left[1-
| ||||||||||
| J0(\alphan1/2i3/2) |
\right]ei\right\},
where:
| is the longitudinal flow velocity, | ||
| is the radial coordinate, | ||
| is time, | ||
| is the dimensionless Womersley number, | ||
| is the angular frequency of the first harmonic of a Fourier series of an oscillatory pressure gradient, | ||
| are the natural numbers, | ||
| is the pressure gradient magnitude for the frequency, | ||
| is the fluid density, | ||
| is the dynamic viscosity, | ||
| is the pipe radius, | ||
| is the Bessel function of first kind and order zero, | ||
| is the imaginary number, and | ||
| is the real part of a complex number. |
The pulsatile flow profile changes its shape depending on the Womersley number
\alpha=R\left(
| \omega\rho | |
| \mu |
\right)1/2.
For
\alpha\lesssim2
\alpha\gtrsim2
The Bessel function at its lower limit becomes[2]
\limz\toinftyJ0(z)=1-
| z2 | |
| 4 |
,
which converges to the Hagen-Poiseuille flow profile for steady flow for
\limnu(r,t)=-
| P'0 | |
| 4\mu |
\left(R2-r2\right),
or to a quasi-static pulse with parabolic profile when
\lim\alphau(r,t)=Re\left\{-
| N | |
| \sum | |
| n=0 |
| P'n | |
| 4\mu |
(R2-r2)ei\right\}=-
| N | |
| \sum | |
| n=0 |
| P'n | |
| 4\mu |
(R2-r2)\cos(n\omegat).
In this case, the function is real, because the pressure and velocity waves are in phase.
The Bessel function at its upper limit becomes[2]
\limz\toinftyJ0(zi)=
| ez | |
| \sqrt{2\piz |
which converges to
\limz\toinftyu(r,t)=Re\left\{
| N | |
| \sum | |
| n=0 |
| iP'n | |
| \rhon\omega |
\left[1-
| ||||||
| e |
\right]ei\right\}=-
| N | |
| \sum | |
| n=0 |
| P'n | |
| \rhon\omega |
\left[1-
| ||||||
| e |
\right]\sin(n\omegat).
This is highly reminiscent of the Stokes layer on an oscillating flat plate, or the skin-depth penetration of an alternating magnetic field into an electrical conductor.On the surface
u(r=R,t)=0
\alpha(1-r/R)
\rho
| \partialu | |
| \partialt |
=-
| N | |
| \sum | |
| n=0 |
P'n.
However, close to the walls, in a layer of thickness
l{O}(\alpha-1)
For deriving the analytical solution of this non-stationary flow velocity profile, the following assumptions are taken:[3] [4]
Thus, the Navier-Stokes equation and the continuity equation are simplified as
\rho
| \partialu | |
| \partialt |
=-
| \partialp | |
| \partialx |
+\mu\left(
| \partial2u | |
| \partialr2 |
+
| 1 | |
| r |
| \partialu | |
| \partialr |
\right)
and
| \partialu | |
| \partialx |
=0,
respectively. The pressure gradient driving the pulsatile flow is decomposed in Fourier series,
| \partialp | |
| \partialx |
(t)=
| N | |
| \sum | |
| n=0 |
P'nein\omega,
where
i
\omega
n=1
P'n
n
P'0
n=0
u(r,t)=
| N | |
| \sum | |
| n=0 |
Unein\omega,
where
Un
n=0
U0=-
| P'0 | |
| 4\mu |
\left(R2-r2\right).
Thus, the Navier-Stokes equation for each harmonic reads as
i\rhon\omegaUn=-P'n+\mu\left(
| \partial2Un | |
| \partialr2 |
+
| 1 | |
| r |
| \partialUn | |
| \partialr |
\right).
With the boundary conditions satisfied, the general solution of this ordinary differential equation for the oscillatory part (
n\geq1
Un(r)=AnJ0\left(\alpha
| r | |
| R |
n1/2i3/2\right)+BnY0\left(\alpha
| r | |
| R |
n1/2i3/2\right)+
| iP'n | |
| \rhon\omega |
,
where
J0( ⋅ )
Y0( ⋅ )
An
Bn
\alpha=R\surd(\omega\rho/\mu)
\partialUn/\partialr|r=0=0
Bn=0
J0'
Y0'
Un(R)=0
An=-
| iP'n | |
| \rhon\omega |
| 1 | |
| J0\left(\alphan1/2i3/2\right) |
n
Un(r)=
| iP'n | |
| \rhon\omega |
\left[1-
| ||||||||||
| J0(\alphan1/2i3/2) |
\right]=
| iP'n | |
| \rhon\omega |
\left[1-
| ||||||||||
| J0(Λn) |
\right],
where
Λn=\alphan1/2i3/2
u(r,t)=
| P'0 | |
| 4\mu |
\left(R2-r2\right)+Re\left\{
| N | |
| \sum | |
| n=1 |
| iP'n | |
| \rhon\omega |
\left[1-
| ||||||||||
| J0(Λn) |
\right]ei\right\}.
Flow rate is obtained by integrating the velocity field on the cross-section. Since,
| d | |
| dx |
\left[xpJp(ax)\right]=axpJp-1(ax) ⇒
| d | |
| dx |
\left[xJ1(ax)\right]=axJ0(ax),
then
Q(t)=\iintu(r,t)dA=Re\left\{\piR2
| N | |
| \sum | |
| n=1 |
| iP'n | |
| \rhon\omega |
\left[1-
| 2 | |
| Λn |
| J1(Λn) | |
| J0(Λn) |
\right]ei\right\}.
To compare the shape of the velocity profile, it can be assumed that
u(r,t)=f(r)
| Q(t) | |
| A |
,
where
f(r)=
| u(r,t) | |||
|
=Re\left\{
| N | |
| \sum | |
| n=1 |
\left[
| ||||||||||
| ΛnJ0(Λn)-2J1(Λn) |
\right]\right\}
is the shape function.[5] It is important to notice that this formulation ignores the inertial effects. The velocity profile approximates a parabolic profile or a plug profile, for low or high Womersley numbers, respectively.
For straight pipes, wall shear stress is
\tauw=\mu\left.
| \partialu | |
| \partialr |
\right|r=R.
The derivative of a Bessel function is
| \partial | |
| \partialx |
\left[x-pJ-p(ax)\right]=ax-pJp+1(ax) ⇒
| \partial | |
| \partialx |
\left[J0(ax)\right]=-aJ1(ax).
Hence,
\tauw=Re\left\{
| N | |
| \sum | |
| n=1 |
P'n
| R | |
| Λn |
| J1(Λn) | |
| J0(Λn) |
ei\right\}.
If the pressure gradient
P'n
\tilde{u}(t)=Re(u(0,t))\equiv
| N | |
| \sum | |
| n=1 |
\tilde{U}n\cos(n\omegat).
Noting that
J0(0)=1
u(0,t)=Re\left\{
| N | |
| \sum | |
| n=1 |
| iP'n | |
| \rhon\omega |
\left[
| J0(Λn)-1 | |
| J0(Λn) |
\right]ei\right\}
at the centre line. The measured velocity is compared with the full expression by applying some properties of complex number. For any product of complex numbers (
C=AB
|C|=|A||B|
\phiC=\phiA+\phiB
\tilde{U}n=\left|
| iP'n | |
| \rhon\omega |
\left[
| J0(Λn)-1 | |
| J0(Λn) |
\right]\right| ⇒ P'n=\tilde{U}n\left|i\rhon\omega\left[
| J0(Λn) | |
| 1-J0(Λn) |
\right]\right|
and
\tilde{\phi}=0=
| \phi | |
| P'n |
+
| \phi | |
| Un |
⇒
| \phi | |
| P'n |
=\operatorname{phase}\left(
| i | |
| \rhon\omega |
\left[
| 1-J0(Λn) | |
| J0(Λn) |
\right]\right),
which finally yield
| 1 | |
| \rho |
| \partialp | |
| \partialx |
=
| N | |
| \sum | |
| n=1 |
\tilde{U}n\left|i\rhon\omega\left[
| J0(Λn) | |
| 1-J0(Λn) |
\right]\right|\cos\left\{n\omegat+\operatorname{phase}\left(
| i | |
| \rhon\omega |
\left[
| 1-J0(Λn) | |
| J0(Λn) |
\right]\right)\right\}.