AP Physics 2 : Fluids

Study concepts, example questions & explanations for AP Physics 2

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Example Questions

Example Question #1 : Archimedes' Principle

A ball of mass  is lightly dropped into a tub with a base of . After it sinks to the bottom, the water rises by . Determine the density of the ball.

Possible Answers:

None of these

Correct answer:

Explanation:

The volume displaced will equal the volume of the ball.

Example Question #2 : Archimedes' Principle

How much of an iceberg is submerged below the water if the density of ice is  and the density of water is ?

Possible Answers:

Cannot be determined without knowing the mass of the iceberg.

Correct answer:

Explanation:

The volume of the submerged mass is the volume of the mass proportional to the density of the solid to the density of the fluid.

Determine the amount of ice that is submerged.

Example Question #1 : Fluid Dynamics

The mass flow rate through a cylindrical pipe of cross sectional area  is . What is the pressure drop over a distance ?

 

Assume 

Possible Answers:

Correct answer:

Explanation:

We will use Poiseuille's law to solve this problem:

  

We can determine the volumetric flow rate from the mass flow rate:

  

Now to determine an expression for radius:

  

Plugging this into the first expression, we get:

Now plugging in all of our values:

Example Question #1 : Poiseuille Flow

Water enters a circular tube at a velocity of . If the pressure drops by  after a distance of , what is the diameter of the tube?

 

Possible Answers:

Correct answer:

Explanation:

Let's begin with the generic form of Poiseulle's law:

Where:

Substituting this in:

And:

Substituting this in:

 

Rearranging for diameter:

Plugging in values:

 

Example Question #3 : Poiseuille Flow

Dynamic viscosity of water: 

Find the pressure change due to the Hagen-Poiseuille law in a  long pipe of radius , where the water is flowing at .

Possible Answers:

None of these

Correct answer:

Explanation:

Using

Where  is the dynamic viscosity

 is the length of the pipe

 is the velocity of the fluid

 is the diameter of the pipe

Plugging in values:

Example Question #4 : Poiseuille Flow

Dynamic viscosity of water: 

Find the pressure change due to the Hagen-Poiseuille law in a  long pipe of radius , where the water is flowing at .

Possible Answers:

None of these

Correct answer:

Explanation:

Using

Where  is the dynamic viscosity

 is the length of the pipe

 is the velocity of the fluid

 is the diameter of the pipe

Plugging in values:

Example Question #1 : Poiseuille Flow

Suppose two pipes made out of an identical material have the same length and the same liquid flowing through them. If pipe A has a cross-sectional diameter that is twice as great as pipe B, how does the flow rate in pipe A differ from the flow rate in pipe B?

Possible Answers:

The flow rate in pipe B is greater than pipe A by a factor of 

The flow rate is the same in both pipes

The flow rate in pipe A is greater than pipe B by a factor of 

The flow rate in pipe B is greater than pipe A by a factor of 

The flow rate in pipe A is greater than pipe B by a factor of 

Correct answer:

The flow rate in pipe A is greater than pipe B by a factor of 

Explanation:

For this question, we're asked to consider two pipes. Each pipe has the same length, is made out of the same material, and has the same fluid moving through it. The only difference is the cross-sectional diameter of these pipes. We're asked to find how the flow rate will differ between the two pipes.

In order to solve this question, we'll need to use Poiseuille's equation.

This equation tells us that the volume flow rate is directly proportional to two things: the pressure gradient between the ends of the pipe and the radius of the pipe raised to the fourth power. Moreover, the volume flow rate is inversely proportional to the viscosity of the fluid and also to the length of the pipe.

Now we need to ask the question - which of the variables in this equation is different in pipes A and B? Both pipes have the same length. Since each pipe has the same fluid moving through it, the viscosity will also be the same. Furthermore, we can assume that the pressure gradient at the end of each pipe is the same. The only thing that's left is the radius.

We're told that the diameter of pipe A is twice as great as pipe B. Since the radius is just half of the diameter, this also means that the radius of pipe A is twice as great as pipe B. Because the volume flow rate is dependent on the radius of the pipe raised to the fourth power, we can see that doubling the radius will result in a  fold difference in the volume flow rate. Thus, the flow rate in pipe A will be  times the flow rate in pipe B.

Example Question #1 : Turbulence

Turbulent flow is characterized by __________

Possible Answers:

regular streamlines

low flow rates 

All of these

irregular and chaotic flow 

Correct answer:

irregular and chaotic flow 

Explanation:

Turbulent flow is caused by sufficiently high flow rates, and is characterized by chaotic and irregular flow patterns. Streamlines represent the curves tangent to the point of the direction of flow; thus, if a flow is turbulent the streamlines will be chaotic as well. 

Example Question #1 : Turbulence

Which of the following is an example of turbulent flow? 

Possible Answers:

The flow of water through a hose

Pouring olive oil into a pan 

The flow of water in the center of a calm stream

The wisps of smoke from a blown-out candle 

Correct answer:

The wisps of smoke from a blown-out candle 

Explanation:

The wisps of smoke from a blown out candle start out a smooth, but eventually swirl and become chaotic and turbulent. The other examples can be intuitively thought of as smooth flow, and thus are laminar. 

Example Question #2 : Fluid Dynamics

Methanol is traveling through a cylindrical tube with a diameter of . What is the maximum velocity of methanol that maintains laminar flow?

 

Possible Answers:

Correct answer:

Explanation:

We will use the expression for Reynold's number for this problem:

Where  is the hydraulic diameter, and for a cylindrical tube, 

Rearranging for velocity:

For laminar flow: 

Plugging in our values into the expression, we get:

 

Methanol has a relatively low viscosity, so it only has a very small range for laminar flow and quickly becomes turbulent

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