Deck 12: Fluid Flow

Flow rate is calculated as the area of the cross-section of a pipe times the velocity of a fluid, and the change of volume of the fluid in time.

The equation of continuity applies only to fluids flowing in tubes, not to free falling fluid.

The outer diameter of an aorta is d = 2.6 cm. The fraction of the total diameter attributed to the wall is 15%. If the speed of blood in the aorta is 0.22 m/s, what is the rate at which the heart is pumping blood into the aorta, in litres per minute?

A higher number of blood cells affects the flow resistance of blood through blood vessels. Resistance varies as a function of pressure difference.

How is it possible for birds to fly without flapping their wings (glide)? Which principle is responsible for this ability? How does the shape of the wing allow for gliding?

A pipe of 50 mm diameter is used to supply water from the first to the second floor. The pressure in the pipe is 5.0 atm, and the speed of the water is 2.5 m/s. On the second floor, 4.5 m above, the pipe has a diameter of 30 mm. What is the speed and pressure in the narrower pipe?

Narrowing the tube through which a viscous fluid flows to a third of its original radius will reduce the flow rate by a factor of 81.

The main purpose of the high pressure blood system in the human body is to supply organs with oxygen.

The continuity equation is valid for an ideal fluid but not for a Newtonian, real fluid.

The capillaries in our circulatory system are blood vessels connected in a series.

In a viscous fluid, the force needed to move two surfaces past each other increases as separation between the surfaces is reduced.

An artery that is constricted due to accumulated plaque on the inner walls tends to stretch outward a little in a constricted part, due to blood flow.

Laminar flow occurs only in an ideal dynamic fluid.

Figure 12.1 The figure shows a Venturi meter: connected tubes filled with an ideal fluid. The upper figure shows the fluid at rest, with the fluid shown by shading at the same height in a W-pipe. The lower figure shows moving fluid and uneven heights in a W-pipe.
Explain why the fluid, as shown by shading in Fig. 12.1, rises in the middle branch of the W-pipe when the fluid above it flows in the direction shown by the arrow. Which law explains this phenomenon?

If you hold two papers at the top and let them hang vertically, parallel to each other, and blow fast air between them, will the papers spread apart or stick together?

Arteriosclerosis is a constriction of the aorta due to plaque accumulated on the inner walls. An aneurysm is a widening of the aorta due to a weakening of the wall. In which of these two deformations will pressure on the walls increase, and in which will pressure decrease so much that it could close the aorta?

When a tube does not change radius, the pressure of a fluid must remain constant throughout the tube.

Bernoulli's equation states that an increase in the speed of an ideal fluid is accompanied by a drop in its pressure.

Figure 12.5 The figure shows volume flow rate of two different fluids.
Analyze curve (2) in Fig. 12.5, which describes a volume flow rate of blood as a function of the pressure difference along the blood vessel. How could an allergy that would cause widening of blood vessels lower the speed of blood, leading to anaphylactic shock?

What is the thickness of a honey (viscosity ç = 8 Pa s) between two 10-cm-diameter parallel plates so that a force of 5 N is needed to pull the plates past each other at a speed of 0.1 m/s?

Figure 12.4 The figure shows flow of fluid through pipe A, branching into two identical pipes B and C with radii equal to half the radius of A, which reunite into a single pipe D.
What fraction of the fluid from pipe A flows through pipe B in Fig. 12.4?

Figure 12.2 The figure shows pressures in vertical tubes due to flow of (a) an ideal fluid and (b) a real fluid.
How does the real fluid differ from the ideal fluid? Which law(s) show(s) that Fig. 12.2(a) applies to the ideal fluid? Which law explains the gradual drop of pressures in the vertical tubes in Fig. 12.2(b)?

Figure 12.4 The figure shows flow of fluid through pipe A, branching into two identical pipes B and C with radii equal to half the radius of A, which reunite into a single pipe D.
In Fig. 12.4, pipe A has a radius of 2 cm, and pipes B and C are each 6.0 m long. Glycerine, with a coefficient of viscosity 1.5 N s/m², flows through the pipes at 30.0 cm/s. What is the drop in pressure that results from branching into two pipes?

Figure 12.3 The figure shows pressures in vertical tubes due to flow of (a) real fluid through a tube of uniform cross-section, and (b) real fluid through a tube of uneven cross-section.
Which law or physical principle explains the gradual drop of pressures in vertical tubes in Fig. 12.3(a), and why is the height in the middle vertical tube lower than in the others?

Figure 12.5 The figure shows volume flow rate of two different fluids.
Describe the difference in characteristics of the two fluids (1 and 2) for which the flow rate versus pressure differences curves are given in Fig. 12.5. Which of the two can represent the flow rate of blood?