Solving for Normal Force in Vertical Circular Motion Problem

AI Thread Summary
In a vertical circular motion problem involving a pilot performing a loop, the normal force acting on the pilot at the bottom of the loop is calculated using the equation FN = m(v²/r) + mg. The pilot's weight (Fg) acts downward while the normal force (FN) acts upward, and their sum equals the net force (FR) required for circular motion. After substituting the given values, the normal force was determined to be 4112.18 N. The discussion emphasizes the importance of correctly applying the forces involved and clarifying the relationship between them. Understanding these dynamics is crucial for solving similar physics problems effectively.
Iser
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Homework Statement



A 76-kg pilot at an air show performs a loop de loop with his plane. At the bottom of the 52-m radius loop, the plane is moving at 48 m/s. Determine the normal force acting upon the pilot.


Homework Equations



(ƩF)R = maR = m(v2/r)

The Attempt at a Solution



I drew a diagram and I know I have to figure it out considering the position of the plane at the bottom of the plane. At the bottom of the plane FR and FN are pointing towards the center of the circle while Fg is pointing the opposite direction. Since the pilot has no movement in the y-direction we know:

FR + FN = Fg

After that I tried putting in the values I have but I got Fg's value was smaller than the total of FR + FN which does not make sense meaning I've made a mistake. I'm confused on how to tackle the problem after this part.
 
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Iser said:
FR + FN = Fg

After that I tried putting in the values I have but I got Fg's value was smaller than the total of FR + FN which does not make sense meaning I've made a mistake. I'm confused on how to tackle the problem after this part.
Only two forces act on the pilot: The upward normal force and the downward gravitational force. Their sum equals the net force, which in this case equals what you call FR.

Show what you got for FR, FN, and Fg.
 
FR is the resultant force, right? And I'm guessing you're taking FR, FN and Fg to be the absolute values. So the equation FR + FN = Fg is not quite right. Remember that the resultant force is not an extra force on its own. The resultant force is the force due to the sum of all other forces.

edit: whoops, Doc Al got there first.
 
Doc Al said:
Only two forces act on the pilot: The upward normal force and the downward gravitational force. Their sum equals the net force, which in this case equals what you call FR.

Show what you got for FR, FN, and Fg.

Oh, ok I sort of see what you're getting at.

So by doing Fnet = FN - Fg

Then we use algebra to make it:

Fnet + Fg = FN

Which is then:

m(v2/r) + mg = FN

I then sub in the values I got from the question arriving to the answer of:

FN = 4112.18 N

Am I on the right track?
 
Iser said:
Oh, ok I sort of see what you're getting at.

So by doing Fnet = FN - Fg

Then we use algebra to make it:

Fnet + Fg = FN

Which is then:

m(v2/r) + mg = FN

I then sub in the values I got from the question arriving to the answer of:

FN = 4112.18 N

Am I on the right track?
Exactly right. :thumbs:

(Now compare that to what the normal force would be at the top of the loop. What's the key difference?)
 

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