12.4 Viscosity and laminar flow; poiseuille’s law (Page 4/12)

College physics for ap® courses Page 4 / 12

The circulatory system provides many examples of Poiseuille's law in action—with blood flow regulated by changes in vessel size and blood pressure. Blood vessels are not rigid but elastic. Adjustments to blood flow are primarily made by varying the size of the vessels, since the resistance is so sensitive to the radius. During vigorous exercise, blood vessels are selectively dilated to important muscles and organs and blood pressure increases. This creates both greater overall blood flow and increased flow to specific areas. Conversely, decreases in vessel radii, perhaps from plaques in the arteries, can greatly reduce blood flow. If a vessel's radius is reduced by only 5% (to 0.95 of its original value), the flow rate is reduced to about $(0.95)^{4} = 0 . 81$ of its original value. A 19% decrease in flow is caused by a 5% decrease in radius. The body may compensate by increasing blood pressure by 19%, but this presents hazards to the heart and any vessel that has weakened walls. Another example comes from automobile engine oil. If you have a car with an oil pressure gauge, you may notice that oil pressure is high when the engine is cold. Motor oil has greater viscosity when cold than when warm, and so pressure must be greater to pump the same amount of cold oil.

The figure shows a section of a cylindrical tube of length l. The two end cross section are shown to have pressure P two and P one respectively. The radius of the cylindrical tube is given by r. The direction of flow is shown by horizontal arrows toward right end of the tube. The flow rate is marked as Q. — Poiseuille's law applies to laminar flow of an incompressible fluid of viscosity $η$ through a tube of length $l$ and radius $r$ . The direction of flow is from greater to lower pressure. Flow rate $Q$ is directly proportional to the pressure difference $P_{2} - P_{1}$ , and inversely proportional to the length $l$ of the tube and viscosity $η$ of the fluid. Flow rate increases with $r^{4}$ , the fourth power of the radius.

What pressure produces this flow rate?

An intravenous (IV) system is supplying saline solution to a patient at the rate of $0.120 {cm}^{3} /s$ through a needle of radius 0.150 mm and length 2.50 cm. What pressure is needed at the entrance of the needle to cause this flow, assuming the viscosity of the saline solution to be the same as that of water? The gauge pressure of the blood in the patient's vein is 8.00 mm Hg. (Assume that the temperature is $20ºC$ .)

Strategy

Assuming laminar flow, Poiseuille's law applies. This is given by

Q = \frac{(P_{2} - P_{1}) π r^{4}}{8 η l},

where $P_{2}$ is the pressure at the entrance of the needle and $P_{1}$ is the pressure in the vein. The only unknown is $P_{2}$ .

Solution

Solving for $P_{2}$ yields

P_{2} = \frac{8 η l}{{πr}^{4}} Q + P_{1 .}

$P_{1}$ is given as 8.00 mm Hg, which converts to $1 . 066 \times 10^{3} {N/m}^{2}$ . Substituting this and the other known values yields

\begin{array}{l} P_{2} & = & [\frac{8 (1 . 00 \times 10^{- 3} N \cdot {s/m}^{2}) (2 . 50 \times 10^{- 2} m)}{π (0 . 150 \times 10^{- 3} m)^{4}}] (1 . 20 \times 10^{- 7} m^{3} /s) + 1 . 066 \times 10^{3} {N/m}^{2} \\ = & 1 . 62 \times 10^{4} {N/m}^{2} . \end{array}

Discussion

This pressure could be supplied by an IV bottle with the surface of the saline solution 1.61 m above the entrance to the needle (this is left for you to solve in this chapter's Problems and Exercises), assuming that there is negligible pressure drop in the tubing leading to the needle.

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Flow and resistance as causes of pressure drops

You may have noticed that water pressure in your home might be lower than normal on hot summer days when there is more use. This pressure drop occurs in the water main before it reaches your home. Let us consider flow through the water main as illustrated in [link] . We can understand why the pressure $P_{1}$ to the home drops during times of heavy use by rearranging

Questions & Answers

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Insulators (nonmetals) have a higher BE than metals, and it is more difficult for photons to eject electrons from insulators. Discuss how this relates to the free charges in metals that make them good conductors.

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P(pressure)=density ×depth×acceleration due to gravity Force =P×Area(28.0x8.5)

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That's just how the AP grades. Otherwise, you could be talking about m/s when the answer requires m/s^2. They need to know what you are referring to.

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Source: OpenStax, College physics for ap® courses. OpenStax CNX. Nov 04, 2016 Download for free at https://legacy.cnx.org/content/col11844/1.14

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