Presentation is loading. Please wait.

Presentation is loading. Please wait.

Vertical Circular Motion A demo T8 T8.

Published byShon Richards Modified over 8 years ago

Similar presentations

Presentation on theme: "Vertical Circular Motion A demo T8 T8."— Presentation transcript:

1

2 Vertical Circular Motion

3 A demo http://www.youtube.com/watch?v=mrKLJjx9V T8 http://www.youtube.com/watch?v=mrKLJjx9V T8

4 Motion in a Vertical Circle Consider the forces on a ball attached to a string as it moves in a vertical loop. As with any object moving in a circle there is a net force acting towards the center of the circle. + T mgBottom Maximum tension T, W opposes F c + T mg Top Right Weight has no effect on T + T mg Top Right Weight causes small decrease in tension T T mg + Left Side Weight has no effect on T + T mg Bottom T Top of Path Tension is minimum as weight helps F c force + The tension must adjust so that the central force remains constant throughout the circle.

5 Motion in a Vertical Circle r v v Resultant force toward center F c = mv 2 r Consider TOP of circle: AT TOP: T mg T + mg + T = mv 2 r T = - mg mv 2 r

6 Vertical Circle; Mass at bottom r v v Resultant force toward center F c = mv 2 r Consider bottom of circle: AT Bottom: T mg +T - mg = mv 2 r T = + mg mv 2 r T mg

7 Example: A 1.7 kg object is swung from the end of a 0.60 m string in a vertical circle. If the time of one revolution is 1.1 s, what is the tension in the string: a)at the top? b) at the bottom? Example: A 1.7 kg object is swung from the end of a 0.60 m string in a vertical circle. If the time of one revolution is 1.1 s, what is the tension in the string: a)at the top? b) at the bottom?

8 Now suppose the mass is spun with just enough speed to keep it moving in a circular path. What is the tension in the string at the top? We say that the mass at the peak of the arc is weightless, because the net force working on it is only gravity. This is the same as an object in total free fall.

9 Example: An object is swung in a vertical circle with a radius of 0.75 m. What is the minimum speed of the object at the top of the motion for the object to remain in circular motion? Example: An object is swung in a vertical circle with a radius of 0.75 m. What is the minimum speed of the object at the top of the motion for the object to remain in circular motion?

10 The Loop-the-Loop and Ferris Wheel Same as string, N replaces T AT TOP: N mg + AT BOTTOM: N mg + N = - mg mv 2 r N = + mg mv 2 r r v v

11 Example What is the apparent weight of a 60-kg person as she moves through the highest point when r = 45 m and the speed at that point is 6 m/s? n mg + r v v mg - N = mv 2 r n = mg - mv 2 r Apparent weight will be the normal force at the top: N = 540 N

12 Loop the loop What is minimum height to release the ball so that it stays in the loop?

13 Vertical Circular Motion – Ferris Wheel m = 50 kg, R = 15 m, At what v would the rider lose contact with the seat at the top? N mg +y At Top: Answer: v =12.2 m/s Hint: N=0

14 Spinning Bucket m = 80 g, r = 1.2 m, What is the minimum speed v so Rhino stays in the bucket? Nmg +y Rhino is most likely to lose contact at the top: When Rhino loses contact, N = 0 r v What is N on Rhino at top if v = 7 m/s ? Answer: 24.8 (N) What is the force of the bucket (Normal force) on Rhino at the bottom? N mg +y

15 Banked Curves: When cars travel at high speeds on highways, they do not rely solely on friction to keep the cars from sliding off the road. A greater centripetal force can exist if the turn is banked. Consider a car traveling at a constant speed around a frictionless banked corner. Banked Curves: When cars travel at high speeds on highways, they do not rely solely on friction to keep the cars from sliding off the road. A greater centripetal force can exist if the turn is banked. Consider a car traveling at a constant speed around a frictionless banked corner.

16 On a frictionless corner only F g and F N act on the car. Note that in this case F N is larger F g because it both: (1) Balances F g (2) Provides F c towards the center of the circle The sum of F N and F g must equal F c. FNFN FgFg FcFc

17 Example Calculate the angle at which a frictionless curve must be banked if a car is to round it safely at a speed of 22 m/s if its radius is 475 m. Example Calculate the angle at which a frictionless curve must be banked if a car is to round it safely at a speed of 22 m/s if its radius is 475 m.

18 Banked Turns θ N mg +y +x Banked turn with no frictionm = 1000 kg, r = 20 m, θ = 20 o What v should car have? r v N ≠ mgcosθ because there is a component of acceleration in the normal direction

19 Banked Turns with friction What if car goes faster than 8.4 m/s? Need friction to keep it from sliding up banked turn Static friction acts parallel to and down the banked turn θ r v N mg +y +x fsfs What if car goes slower than 8.4 m/s? Need friction to keep it from sliding down banked turn +y N mg +x fsfs Static friction acts parallel to and up the banked turn Not easy to solve for v max or v min on banked turns with friction

20 Example A 0.25 kg toy plane is attached to a string so that it flies in a horizontal circle with a radius of 0.80 m. The string makes a 28 o angle to the vertical. What is its period of rotation? Example A 0.25 kg toy plane is attached to a string so that it flies in a horizontal circle with a radius of 0.80 m. The string makes a 28 o angle to the vertical. What is its period of rotation? 28 o

Download ppt "Vertical Circular Motion A demo T8 T8."

Similar presentations

Horizontal Circular Motion

Horizontal Circular Motion
Newton’s Laws + Circular Motion. Sect. 5-2: Uniform Circular Motion; Dynamics A particle moving in uniform circular motion at radius r, speed v = constant:

Newton’s Laws + Circular Motion. Sect. 5-2: Uniform Circular Motion; Dynamics A particle moving in uniform circular motion at radius r, speed v = constant:
Chapter 10. Uniform Circular Motion

Chapter 10. Uniform Circular Motion
Chapter 6: Circular Motion & Other Applications of Newton’s Laws

Chapter 6: Circular Motion & Other Applications of Newton’s Laws
Uniform Circular Motion

Uniform Circular Motion
Motion in a Plane Chapter 8. Centripetal Acceleration Centripetal Acceleration – acceleration that points towards the center of a circle. – Also called.

Motion in a Plane Chapter 8. Centripetal Acceleration Centripetal Acceleration – acceleration that points towards the center of a circle. – Also called.
Using the “Clicker” If you have a clicker now, and did not do this last time, please enter your ID in your clicker. First, turn on your clicker by sliding.

Using the “Clicker” If you have a clicker now, and did not do this last time, please enter your ID in your clicker. First, turn on your clicker by sliding.
Using the “Clicker” If you have a clicker now, and did not do this last time, please enter your ID in your clicker. First, turn on your clicker by sliding.

Using the “Clicker” If you have a clicker now, and did not do this last time, please enter your ID in your clicker. First, turn on your clicker by sliding.
Centripetal Force. Law of Action in Circles  Motion in a circle has a centripetal acceleration.  For every acceleration there is a net force.  There.

Centripetal Force. Law of Action in Circles  Motion in a circle has a centripetal acceleration.  For every acceleration there is a net force.  There.
CIRCULAR MOTION We will be looking at a special case of kinematics and dynamics of objects in uniform circular motion (constant speed) Cars on a circular.

CIRCULAR MOTION We will be looking at a special case of kinematics and dynamics of objects in uniform circular motion (constant speed) Cars on a circular.
Centripetal Acceleration 13 Examples with full solutions.

Centripetal Acceleration 13 Examples with full solutions.
Circular Motion.

Circular Motion.
Rotational Motion and the Law of Gravity

Rotational Motion and the Law of Gravity
Torque It is easier to open a door when a force is applied at the knob as opposed to a position closer to the hinges. The farther away the force, the more.

Torque It is easier to open a door when a force is applied at the knob as opposed to a position closer to the hinges. The farther away the force, the more.
Demo spin stopper Is it accelerating? Does it have F net ? Direction of F net ? What causes F net ? Direction of F net ? Is tension doing work?

Demo spin stopper Is it accelerating? Does it have F net ? Direction of F net ? What causes F net ? Direction of F net ? Is tension doing work?
Chapter Opener. Caption: Newton’s laws are fundamental in physics

Chapter Opener. Caption: Newton’s laws are fundamental in physics
Chapter 5 Uniform Circular Motion. Chapter 5 Objectives (*vocab) 1. Centripetal Acceleration centripetal* uniform circular motion* period* formula for.

Chapter 5 Uniform Circular Motion. Chapter 5 Objectives (*vocab) 1. Centripetal Acceleration centripetal* uniform circular motion* period* formula for.
Example 1: A 3-kg rock swings in a circle of radius 5 m

Example 1: A 3-kg rock swings in a circle of radius 5 m
Centripetal Force and Acceleration

Centripetal Force and Acceleration
Circular Motion Pearson 2007-2008.

Circular Motion Pearson

Similar presentations

Ads by Google