Presentation is loading. Please wait.

Presentation is loading. Please wait.

Horizontal Circular Motion. Car rounding a flat-curve.

Published bySheryl Johnston Modified over 9 years ago

Similar presentations

Presentation on theme: "Horizontal Circular Motion. Car rounding a flat-curve."— Presentation transcript:

1 Horizontal Circular Motion

2 Car rounding a flat-curve

3 Car on a Flat-Curve Question: What is the centripetal force for a car moving along a curved road? Answer: Static frictional force between the road and the tires.

4 Centripetal acceleration

5 Smaller radius: larger force required to keep it in uniform circular motion. Radius of Circular Path

6 Car travels at a constant speed around two curves. Where is the car most likely to skid? Why? Skidding

7 Skidding Example

8 The Normal Force Can Yield a Centripetal Acceleration How many forces are acting on the car (assuming no friction)? Engineers have learned to “bank” curves so that cars can safely travel around the curve without relying on friction at all to supply the centripetal acceleration. Banked Curves

9 Q: Why the curved roads in highways are banked? A: The normal reaction supplement the frictional force for turning.

10 Banked Curves - Equations Vertical Equilibrium : F N cos  = mg Horizontal Acceleration :

11 Banking the curve can help keep cars from skidding. In fact, for every banked curve, there is one speed where the entire centripetal force is supplied by the horizontal component of the normal force, and no friction is required. This occurs when: Ideal Banking

12 Turning – Aeroplane Airplanes don’t have “rubber on the road”, so no friction to keep them from going sideways around turns Wings produce lift force, so proper bank angle supplies necessary horizontal component of force to produce turn

13 Turning - Aeroplane Answer: To generate the centripetal force required for the circular motion. Question: Why do airplanes make banked turn?

14 Airplanes in high-g turn gravity enhanced lift during turn: vertical component cancels gravity to produce level flight, horizontal component affects turn Pilot accelerated by orange (lift) vector, feels heavier than normal. In this case, pilot feels about 3 g’s (orange arrow about 3 times longer than gravity arrow)

15 Conical Pendulum A: The horizontal component of the tension in the string. What force produces the centripetal acceleration?

16 Old-Fashioned Swings The angle of the ropes tells us where the forces are: Ropes and gravity pull on swingers If no vertical motions (level swing), vertical forces cancel Only thing left is horizontal component pointing toward center: centripetal force Centripetal force is just mv 2 /r (F = ma; a = v 2 /r) gravity (mg) swing ropes: what you feel from your seat resultant: centripetal

Download ppt "Horizontal Circular Motion. Car rounding a flat-curve."

Similar presentations

Centripetal Acceleration

Centripetal Acceleration
Circular Motion & Highway Curves

Circular Motion & Highway Curves
CHAPTER-6 Force and Motion-II.

CHAPTER-6 Force and Motion-II.
1) component of the gravity force parallel to the plane increased 2) coeff. of static friction decreased 3) normal force exerted by the board decreased.

1) component of the gravity force parallel to the plane increased 2) coeff. of static friction decreased 3) normal force exerted by the board decreased.
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
Centripetal Acceleration and Centripetal Force

Centripetal Acceleration and Centripetal Force
Circular Motion; Gravitation

Circular Motion; Gravitation
Dynamics of Circular Motion

Dynamics of Circular Motion
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.
Vertical Circular Motion A demo T8 T8.

Vertical Circular Motion A demo T8 T8.
Circular Motion Lecturer: Professor Stephen T. Thornton

Circular Motion Lecturer: Professor Stephen T. Thornton
5.4 highway curves 5.5 Non-uniform circular motion 5.6 Drag Velocity

5.4 highway curves 5.5 Non-uniform circular motion 5.6 Drag Velocity
C H A P T E R 5 Dynamics of Uniform Circular Motion

C H A P T E R 5 Dynamics of Uniform Circular Motion
Centripetal Acceleration 13 Examples with full solutions.

Centripetal Acceleration 13 Examples with full solutions.
Circular Motion.

Circular Motion.
1 Ch5 Circular Motion and Force. 2 Centripetal Force - Swinging Ball Any body rotating about a fixed point will experience a centripetal (center seeking)

1 Ch5 Circular Motion and Force. 2 Centripetal Force - Swinging Ball Any body rotating about a fixed point will experience a centripetal (center seeking)
1© Manhattan Press (H.K.) Ltd. Cyclists rounding bends on a level road Vehicles rounding bends on a level road Vehicles rounding bends on a level road.

1© Manhattan Press (H.K.) Ltd. Cyclists rounding bends on a level road Vehicles rounding bends on a level road Vehicles rounding bends on a level road.
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

Similar presentations

Ads by Google