Chapter 5 Uniform Circular Motion Uniform Circular Motion

Chapter 5: Uniform Circular Motion

» Uniform Circular Motion: The motion of an object traveling at a constant (uniform) speed on a circular path 5 -1 Uniform Circular Motion

» Since we are dealing with object moving in a circle, it is convenient to talk about the period of the motion » Period (T) = the time required to travel once around the circle (one complete revolution. 5 -1 Uniform Circular Motion

» 5 -1 Uniform Circular Motion

» The blades on the turbines at the Wild Horse Wind Farm in eastern WA turn at a rate of 16 revolutions/minute. Each blade is approx. 39 m long. Compare the speed of the tip of the blade to the speed of the part of the blade that is 1 m from the center. 5 -1 Uniform Circular Motion

» First, find the time it Takes for one revolution. f= 16 rev/minute = 16 rev/60 sec = 0. 267 rev/sec T = 1/f = 3. 75 seconds 5 -1 Uniform Circular Motion

» Next, find the distance For one revolution a) r=39 m Distance = 2πr = 245 m v = distance/time = 245 m/3. 75 s = 65. 35 m/s speed of the tip 5 -1 Uniform Circular Motion

» Next, find the distance For one revolution b) r=1 m Distance = 2πr = 6. 3 m v = distance/time = 6. 3 m/3. 75 s = 1. 68 m/s speed of the inner part of the blade. 5 -1 Uniform Circular Motion

» For uniform circular motion, the speed is constant, but the velocity is not because the direction is changing continually! » At any instant, the velocity vector is always tangent to the circle. 5 -1 Uniform Circular Motion

» 1. A tube is 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. Check Your Understanding

» While the ball is in the tube, the tube exerts a force on the ball which causes the ball to accelerate in a circle. Once the ball leaves the tube, there are no forces acting on it. The ball will continue to move in a straight line. Check Your Understanding

» Draw the velocity vector at each point (A, B, C) in the object’s motion. Check Your Understanding

» Draw the velocity vector at each point (A, B, C) in the object’s motion. v If the object is accelerating (velocity is changing), then by Newton’s 2 nd Law, it must have a net force acting on it. Centripetal Acceleration

» Recall from the bowling ball lab that a net inward force was required to move the ball in a circle. v a a v The force and acceleration point in the same direction. Therefore, the object’s acceleration is towards that center of the circle at any given instant.

» The centripetal acceleration vector always points toward the center of the circle, and changes direction as the object moves. Centripetal Acceleration

» Example 1

» How do you find the length of an arc, s, ? r θ s s=rθ But θ must be in radians! Geometry Review

» P. 156 #1, 3, 5, 7, 8, 9, 10 Assignment