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Circular Motion

Circular Motion. Centripetal Force and Acceleration. Uniform Circular Motion. Suppose you were driving a car in a path of perfect circle with the radius constant. Your speedometer maintained a constant reading of 10mi/hr.

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Circular Motion

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  1. Circular Motion Centripetal Force and Acceleration

  2. Uniform Circular Motion • Suppose you were driving a car in a path of perfect circle with the radius constant. • Your speedometer maintained a constant reading of 10mi/hr. • In such a situation, the motion of your car can be described as experiencing uniform circular motion. (Circular Motion at a constant speed)

  3. The Direction of the Velocity Vector? • Objects moving in uniform circular motion have a constant speed, but does that mean they have a constant velocity? • Since an object is moving in a circle, its direction is continuously changing. • Although the magnitude of the velocity is constant, its direction is changing.

  4. The Direction of the Velocity Vector? • The best word used to describe the direction of the velocity vector is tangential. • The direction of the velocity vector at any instant is in the direction of a tangent line drawn to the circle. • A tangent line is a line that touches a circle at one point but does not intersect it.

  5. SUMMARY • An object moving in uniform circular motion is moving around the perimeter of the circle with a constant speed. While the speed of the object is constant, its velocity is changing. • Velocity, being a vector, has a constant magnitude but a changing direction. The direction is always directed tangent to the circle and as the object turns the circle, the tangent line is always pointing in a new direction.

  6. CHECKPOINT • A tube has been placed upon the table and shaped into a three-quarters circle. A golf ball is pushed into the tube at one end at high speed. The ball rolls through the tube and exits at the opposite end. Describe the path of the golf ball as it exits the tube.

  7. ANSWER • The ball will move along a path which is tangent to the spiral at the point where it exits the tube. At that point, the ball will no longer curve or spiral, but rather travel in a straight line in the tangential direction

  8. ACCELERATION • If you were driving a car in a circle at a constant speed of 20 mi/hr, would the car be accelerating?

  9. YES • Remember, acceleration is defined as the change in an object’s velocity ( not speed). • A change in the magnitude or direction of an object’s velocity constitutes a change in its acceleration.

  10. Direction of Acceleration • In order to determine the direction the object’s acceleration, we have to use the equation. We need to subtract vi from vf, but since they are vectors, we have to ad them graphically. The direction of the acceleration is inward, towards the center of the circle.

  11. SUMMARY • Objects moving in a circle at constant speed experience an acceleration that is directed towards the center of the circle.

  12. CHECKPOINT • The initial and final speed of a ball at two different points in time is shown below. The direction of the ball is indicated by the arrow. For each case, indicate if there is an acceleration. • Explain why or why not. Indicate the direction of the acceleration.

  13. ANSWER • There is no acceleration , because there is not change in velocity • The velocity vectors cancel each other out.

  14. EXAMPLE #2

  15. ANSWER #2 • Yes, there is an acceleration because the object experienced a change in its velocity. • The direction of the acceleration is by 5m/s, east(right)

  16. EXAMPLE #3

  17. ANSWER #3 • There is a change in the velocity due to the different directions of the velocity vectors. • The acceleration will be to the west (left)

  18. Classwork • Complete 7.1 Worksheet

  19. Centripetal Force An object experiencing an acceleration must also experience a net force. The direction of the net force must be in the same direction as the acceleration. An object moving in a circle must have an inward force acting upon it in order to cause its inward acceleration. Centripetal – Means “center-seeking”

  20. Centripetal Force explained by Newton’s 1st Law • According to Newton’s 1st Law – all moving objects continue to move in the same direction unless acted upon by an unbalanced force. • Moving objects will tend to travel in straight lines unless an unbalanced force causes it to turn. • Therefore; an unbalanced force is required for an object to move in circles.

  21. Centripetal Force • If an object moves in a circle, there is some net force acting on it, causing it to deviate from its straight-line path. As a bucket of water is tied to a string and spun in a circle, the tension force acting upon the bucket provides the centripetal force required for circular motion. As the moon orbits the Earth, the force of gravity acting upon the moon provides the centripetal force required for circular motion. As a car makes a turn, the force of friction acting upon the turned wheels of the car provides centripetal force required for circular motion.

  22. CHECKPOINT • Which vector below represents the direction of the force vector when the object is located at point A on the circle?

  23. ANSWER • D

  24. CHECKPOINT #2 • Which vector below represents the direction of the velocity vector when the object is located at point C on the circle?

  25. ANSWER • A – The vector that is tangent to the Point C on the circle.

  26. CHECKPOINT #3 • Which vector below represents the direction of the acceleration vector when the object is located at point A on the circle?

  27. ANSWER • D- Acceleration vector always points inward towards the unbalanced force.

  28. EQUATIONS • Tangential Speed Vt = 2πr / T

  29. CLASSWORK / HOMEWORK • PAGE 236 #’S 1-4 • PAGE 238 #’S 1-4

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