Presentation is loading. Please wait.

Presentation is loading. Please wait.

Module 4, Recitation 4 Concept Problems, Circular Motion.

Published byAdrian Greer Modified over 9 years ago

Similar presentations

Presentation on theme: "Module 4, Recitation 4 Concept Problems, Circular Motion."— Presentation transcript:

1 Module 4, Recitation 4 Concept Problems, Circular Motion

2 ConcepTest Tetherball Toward the top of the pole 1) Toward the top of the pole Toward the ground 2) Toward the ground Along the horizontal component of the tension force 3) Along the horizontal component of the tension force Along the vertical component of the tension force 4) Along the vertical component of the tension force Tangential to the circle 5) Tangential to the circle In the game of tetherball, the struck ball whirls around a pole. In what direction does the net force on the ball point? W T

3 vertical component of the tensionweight horizontal component of tensioncentripetal force The vertical component of the tension balances the weight. The horizontal component of tension provides the centripetal force that points toward the center of the circle. Toward the top of the pole 1) Toward the top of the pole Toward the ground 2) Toward the ground Along the horizontal component of the tension force 3) Along the horizontal component of the tension force Along the vertical component of the tension force 4) Along the vertical component of the tension force Tangential to the circle 5) Tangential to the circle In the game of tetherball, the struck ball whirls around a pole. In what direction does the net force on the ball point? W T W T ConcepTest Tetherball

4 You are a passenger in a car, not wearing a seat belt. The car makes a sharp left turn. From your perspective in the car, what do you feel is happening to you? (1) You are thrown to the right (2) You feel no particular change (3) You are thrown to the left (4) You are thrown to the ceiling (5) You are thrown to the floor ConcepTest Around the Curve I

5 You are a passenger in a car, not wearing a seat belt. The car makes a sharp left turn. From your perspective in the car, what do you feel is happening to you? (1) You are thrown to the right (2) You feel no particular change (3) You are thrown to the left (4) You are thrown to the ceiling (5) You are thrown to the floor ConcepTest Around the Curve I The passenger has the tendency to continue moving in a straight line. From your perspective in the car, it feels like you are being thrown to the right, hitting the passenger door.

6 (1) centrifugal force is pushing you into the door (2) the door is exerting a leftward force on you (3) both of the above (4) neither of the above During that sharp left turn, you found yourself hitting the passenger door. What is the correct description of what is actually happening? ConcepTest Around the Curve II

7 (1) centrifugal force is pushing you into the door (2) the door is exerting a leftward force on you (3) both of the above (4) neither of the above During that sharp left turn, you found yourself hitting the passenger door. What is the correct description of what is actually happening? The passenger has the tendency to continue moving in a straight line. There is a centripetal force, provided by the door, that forces the passenger into a circular path. ConcepTest Around the Curve II

8 ConcepTest Barrel of Fun A rider in a “barrel of fun” finds herself stuck with her back to the wall. Which diagram correctly shows the forces acting on her? 1 2 3 4 5

9 normal force centripetal force downward force of gravity is balanced by the upward frictional force The normal force of the wall on the rider provides the centripetal force needed to keep her going around in a circle. The downward force of gravity is balanced by the upward frictional force on her, so she does not slip vertically. ConcepTest Barrel of Fun A rider in a “barrel of fun” finds herself stuck with her back to the wall. Which diagram correctly shows the forces acting on her? 1 2 3 4 5 Follow-up: What happens if the rotation of the ride slows down?

10 ConcepTest Going in Circles I 1) N remains equal to mg 2) N is smaller than mg 3) N is larger than mg 4) None of the above You’re on a Ferris wheel moving in a vertical circle. When the Ferris wheel is at rest, the normal force N exerted by your seat is equal to your weight mg. How does N change at the top of the Ferris wheel when you are in motion?

11 ConcepTest Going in Circles I 1) N remains equal to mg 2) N is smaller than mg 3) N is larger than mg 4) None of the above You’re on a Ferris wheel moving in a vertical circle. When the Ferris wheel is at rest, the normal force N exerted by your seat is equal to your weight mg. How does N change at the top of the Ferris wheel when you are in motion? inward mg (down)N (up) N must be smaller than mg You are in circular motion, so there has to be a centripetal force pointing inward. At the top, the only two forces are mg (down) and N (up), so N must be smaller than mg. Follow-up: Where is N larger than mg?

Download ppt "Module 4, Recitation 4 Concept Problems, Circular Motion."

Similar presentations

18 Questions and then correct your quiz!

18 Questions and then correct your quiz!
1. ConcepTest 5.1 Tetherball

1. ConcepTest 5.1 Tetherball
ConcepTest 7.1 Tetherball

ConcepTest 7.1 Tetherball
Physics for Scientists and Engineers, 6e

Physics for Scientists and Engineers, 6e
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:
Circular Motion and Gravitation

Circular Motion and Gravitation
February 7, 2012 Honors Physics Mr. Payne Central Net Force Particle Model Energy Large X-class Flare Erupts on the Sun On Jan. 27, 2012, a large X-class.

February 7, 2012 Honors Physics Mr. Payne Central Net Force Particle Model Energy Large X-class Flare Erupts on the Sun On Jan. 27, 2012, a large X-class.
ConcepTest 6.1aTension I ConcepTest 6.1a Tension I 1) 0 N 2) 50 N 3) 100 N 4) 150 N 5) 200 N You tie a rope to a tree and you pull on the rope with a force.

ConcepTest 6.1aTension I ConcepTest 6.1a Tension I 1) 0 N 2) 50 N 3) 100 N 4) 150 N 5) 200 N You tie a rope to a tree and you pull on the rope with a force.
ConcepTest Clicker Questions

ConcepTest Clicker Questions
ConcepTest Clicker Questions College Physics, 7th Edition

ConcepTest Clicker Questions College Physics, 7th Edition
Uniform Circular Motion

Uniform Circular Motion
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.
ConcepTest 6.4Friction ConcepTest 6.4 Friction A) the force from the rushing air pushed it off B) the force of friction pushed it off C) no net force acted.

ConcepTest 6.4Friction ConcepTest 6.4 Friction A) the force from the rushing air pushed it off B) the force of friction pushed it off C) no net force acted.
Forces, Uniform Circular Motion, and Gravity Review October 7.

Forces, Uniform Circular Motion, and Gravity Review October 7.
Circular Motion and Other Applications of Newton’s Laws

Circular Motion and Other Applications of Newton’s Laws
Drag Forces Lecturer: Professor Stephen T. Thornton

Drag Forces Lecturer: Professor Stephen T. Thornton
ConcepTest 7.1Tetherball ConcepTest 7.1 Tetherball Toward the top of the pole. 1) Toward the top of the pole. Toward the ground. 2) Toward the ground.

ConcepTest 7.1Tetherball ConcepTest 7.1 Tetherball Toward the top of the pole. 1) Toward the top of the pole. Toward the ground. 2) Toward the ground.
Circular Motion and Other Applications of Newton’s Laws

Circular Motion and Other Applications of Newton’s Laws
Lecture 8 Applications of Newton’s Laws (Chapter 6)

Lecture 8 Applications of Newton’s Laws (Chapter 6)
III. Defining Force Force Newton’s First Law Friction

III. Defining Force Force Newton’s First Law Friction

Similar presentations

Ads by Google