User:PMarmottant/Hydraulic resistance and capacity

We present here simple tools to compute the flow in complex network of channels, just knowing the applied pressure.

Hydrodynamic resistance[edit | edit source]

We have seen in the previous chapter that flow rate ${\displaystyle Q}$ in a channel is proportional to the applied pressure drop ${\displaystyle \Delta P}$. This can be summarized in

${\displaystyle \Delta P=R_{h}Q,}$

with ${\displaystyle R_{h}}$ the hydrodynamic resistance. This expression is formally the analog of the electrokinetic law between voltage difference and current, ${\displaystyle U=RI}$.

The expression for the hydraulic resistance is:

• channel of circular cross-section (total length ${\displaystyle L}$, radius ${\displaystyle R}$):

${\displaystyle R_{h}={\frac {8\mu L}{\pi R^{4}}}}$

• rectangular cross-section (width ${\displaystyle w}$ and height ${\displaystyle h}$)

${\displaystyle R_{h}\approx {\frac {12\mu L}{wh^{3}(1-0.630h/w)}}}$

In a network of channels, equivalent resistances can be computed (as in electrokinetics):

• two channels in series have a resistance ${\displaystyle R_{h}=R_{h1}+R_{h2}}$,
• two channels in parallel have a resistance ${\displaystyle 1/R_{h}=1/R_{h1}+1/R_{h2}.}$

These laws provide useful tools for the design of complex networks. Actually Kirchhoff's laws for electric circuits apply, being modified in:

• the sum of flow rates on a node of the circuit is zero
• the sum of pressure differences on a loop is zero

Hydrodynamic capacitance[edit | edit source]

The volume of fluid in a channel can change just because of a change in pressure: this is due either to fluid compressibility or either channel elasticity. This behavior can be summarized with

${\displaystyle Q=C_{h}{\frac {d\Delta P}{dt}}}$

with ${\displaystyle C_{h}}$ the hydrodynamic capacitance. It is the microfluidic analog of the electrokinetic law ${\displaystyle I=C\,dU/dt}$.

Compressible fluid in a container[edit | edit source]

A pressure increase can compress the fluid in a container. The compressibility is measured by

${\displaystyle K_{fluid}=-{\frac {1}{V}}{\frac {\partial V}{\partial P}}.}$

For water its value is ${\displaystyle K=4.6\times 10^{-5}/bar}$ which is usually negligible since pressure are usually less than a bar. For air it is ${\displaystyle K=1/P=1/bar}$ which considerable if pressure attain a bar.

The flow rate entering a tube of volume ${\displaystyle V}$, because of fluid compression ${\displaystyle d\Delta P/dt}$ is:

${\displaystyle Q=-{\frac {dV}{dt}}=V\left(-{\frac {1}{V}}{\frac {\partial V}{\partial P}}\right){\frac {d\Delta P}{dt}}=K_{fluid}V{\frac {d\Delta P}{dt}}}$

The hydrodynamic capacitance is therefore:

${\displaystyle C_{h}=K_{fluid}V}$

Elastic tubes[edit | edit source]

We define the tube dilatability as

${\displaystyle K_{tube}={\frac {1}{V_{tube}}}{\frac {\partial V_{tube}}{\partial P}}}$

It has a positive sign, since the tube volume increases with pressure.

The tube dilatability is approximately the inverse of the Young modulus ${\displaystyle K\simeq 1/E.}$ The following table gives order of magnitude of this dilatability for different materials

	${\displaystyle K_{tube}}$
steel	${\displaystyle \scriptstyle 0.5\times 10^{-6}}$/bar
plastic	${\displaystyle 0.01}$/bar
rubber	${\displaystyle 0.1}$/bar

This value can be interpreted in the following way: if the pressure is increased by 1 bar the relative volume increase is ${\displaystyle K_{tube}}$

Assuming a uniform pressure in the tube (which is not true in long tube where pressure decreases subtantially) , we find a flow rate entering the tube to inflate to be

${\displaystyle Q={\frac {dV_{tube}}{dt}}=K_{tube}V{\frac {\Delta P}{dt}}}$

The hydrodynamic capacitance is therefore

${\displaystyle C_{h}=K_{tube}V.}$

Modelisation of an elastic long tube with a substantial pressure drop[edit | edit source]

We consider a tube of length ${\displaystyle L}$ on which a pressure difference ${\displaystyle \Delta P}$ is applied. In the tube, the pressure decreases along the tube coordinate ${\displaystyle x}$ as ${\displaystyle P(x)=P_{0}+(1-x/L)\Delta P}$. The dilatation is therefore not homogeneous: larger near the entrance. The volume increase of the tube (compared to the rest situation at pressure ${\displaystyle P_{0}}$) is

${\displaystyle \Delta V=\int _{0}^{L}\left(1-{\frac {x}{L}}\right)\Delta P\;K_{tube}{\frac {dx}{L}}V_{tube}={\frac {\Delta P}{2}}K_{tube}V.}$

We have integrated the inflation of small volumes ${\displaystyle dx/L\times V_{tube}}$.

We obtain that the flow due to dilatation is

${\displaystyle Q={\frac {d\Delta V}{dt}}=C_{tube}{\frac {d\Delta P/2}{dt}}}$

meaning that only half the pressure difference loads the volume capacitor. The capacitor is placed in the middle of the channel, where the overpressure is half, see figure.

Application: syringe injection in a microchannel[edit | edit source]

The syringe is has a tube diameter ${\displaystyle R}$ and a volume ${\displaystyle V}$, while the (cylindrical) microchannel has a diameter ${\displaystyle r\ll R}$ and a volume ${\displaystyle v\ll V}$, and a length ${\displaystyle l}$. The resistance of the microchannel is much larger than that of the syringe ${\displaystyle R_{v}=8\mu l/\pi r^{4}\gg R_{V}}$. However the capacitance of the syringe is much larger ${\displaystyle C_{V}\gg C_{v}}$, because of the larger volume.

The equivalent circuit is therefore

The total flow is distributed in the microchannel branch and the capacitor branch:

${\displaystyle Q_{piston}={\frac {1}{R_{v}}}\Delta P+C_{V}{\frac {d\Delta P}{dt}}}$

If the piston is suddenly started, initially water or tube elasticity will absorb the flow, and the flow is stationary only for time larger tha a characteristic transient time

${\displaystyle \tau =R_{v}\,C_{V}={\frac {8\mu l}{\pi r^{4}}}VK,}$

with ${\displaystyle K}$ the compressibility of either water or the syringe tube.

As an example, we take a microchannel of radius 10 micrometers, length 1 cm and a syringe of volume 1cc: the characteristic time is 10 seconds, if the syringe is rigid (glass) and ${\displaystyle K=K_{water}}$, while it takes up to 1000 seconds if the syringe is in plastic ${\displaystyle K=K_{plastic}}$!

As a conclusion, for practical realization of microfluidic networks:

• avoid flexible tubes and prefer metallic tubes for a faster equilibration
• avoid flexible glues in contact with the liquid: they will compress
• avoid bubbles in the system, their compressibility is extremely high compared to plastic!
• impose pressure with a valve, instead of piston velocity: the pressure equilibrates at the speed of sound in the liquid and changes in pressure are very rapidly applied to the whole system.