Calculating normal force in a loop-the-loop situation

AI Thread Summary
To calculate the normal forces exerted on a pilot during a vertical loop, the key is to analyze the forces at both the bottom and top of the loop. At the bottom, the normal force is the sum of the centripetal force and the pilot's weight, resulting in a normal force of approximately 2.93 times the pilot's weight (mg). Conversely, at the top of the loop, the normal force is the centripetal force minus the weight, yielding a normal force of about 0.929 times mg. The centripetal force can be calculated using the formula mv²/r, where v is the speed and r is the radius of the loop. Understanding the free-body diagrams and the direction of forces is crucial for solving these types of problems.
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Homework Statement



Here's the situation:

A jet pilot puts an aircraft with a constant speed into a vertical circular loop. If the speed of the aircraft is 700 km/h and the radius of the circle is 2.0 km, calculate the normal forces exerted on the seat by the pilot at the bottom and top of the loop. Express your answer in terms of the pilot's weight mg.

a) at the bottom
b) at the top

I actually have the answers to the problem, but of course it doesn't help me understand the problem nor the process in getting there. Not sure which angular motion/centripetal force equations to use. But if it helps you verify results, here are the answers:

At bottom: 2.93*mg
At the top: .929*mg

I would really appreciate any help, even if it's just pointing me in the right direction as far as which equation to use, I'm not necessarily asking anyone to work it out. Thanks in advance!

Homework Equations



Not necessarily sure which to use, here's some conversions just for quick reference:
700 km/h = 194.444 m/s
2.0 km = 2000 m

Possible eqns:

Angular Velocity = \omega = \Delta\theta/\Deltat
Angular Acceleration = \alpha = \Delta\omega/\Deltat
\textbf{F}_{centripetal} = mass x accel(centrip) = mv^{2}/r
\textbf{F}_{gravity} = mg

The Attempt at a Solution



Can't quite figure out where to start...
 
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Start with 2 free-body diagrams, 1 for the forces on the pilot at the top of the loop and one for the bottom. Keep in mind what force(s) provide the centripetal acceleration for the pilot at those points.
 
At all times the centrifugal acceleration pushes the pilot onto the seat. The difference is the direction of the weight of the pilot, which is always the directed towards the centre of the earth. So at the bottom force = centrifugal + weight, at top its centrifugal - weight.
 
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