Chapter 3.8 & 6 Solutions

Similar documents
Chapter 5 Using Newton s Laws: Friction, Circular Motion, Drag Forces. Copyright 2009 Pearson Education, Inc.

3600 s 1 h. 24 h 1 day. 1 day

VELOCITY, ACCELERATION, FORCE

Unit 4 Practice Test: Rotational Motion

circular motion & gravitation physics 111N

F N A) 330 N 0.31 B) 310 N 0.33 C) 250 N 0.27 D) 290 N 0.30 E) 370 N 0.26

PHY121 #8 Midterm I

Lecture Presentation Chapter 7 Rotational Motion

Lecture 07: Work and Kinetic Energy. Physics 2210 Fall Semester 2014

AP Physics Circular Motion Practice Test B,B,B,A,D,D,C,B,D,B,E,E,E, m/s, 0.4 N, 1.5 m, 6.3m/s, m/s, 22.9 m/s

Physics 2A, Sec B00: Mechanics -- Winter 2011 Instructor: B. Grinstein Final Exam

Centripetal Force. This result is independent of the size of r. A full circle has 2π rad, and 360 deg = 2π rad.

CHAPTER 6 WORK AND ENERGY

v v ax v a x a v a v = = = Since F = ma, it follows that a = F/m. The mass of the arrow is unchanged, and ( )

B Answer: neither of these. Mass A is accelerating, so the net force on A must be non-zero Likewise for mass B.

AP Physics - Chapter 8 Practice Test

4 Gravity: A Force of Attraction

Chapter 5: Circular Motion, the Planets, and Gravity

Solution Derivations for Capa #11

Newton s Law of Motion

Physics 1120: Simple Harmonic Motion Solutions

Linear Motion vs. Rotational Motion

Supplemental Questions

Chapter 10 Rotational Motion. Copyright 2009 Pearson Education, Inc.

Physics: Principles and Applications, 6e Giancoli Chapter 4 Dynamics: Newton's Laws of Motion

PHY231 Section 2, Form A March 22, Which one of the following statements concerning kinetic energy is true?

PHYS 211 FINAL FALL 2004 Form A

PHY231 Section 1, Form B March 22, 2012

Conceptual Questions: Forces and Newton s Laws

Physics 125 Practice Exam #3 Chapters 6-7 Professor Siegel

B) 286 m C) 325 m D) 367 m Answer: B

Name: Partners: Period: Coaster Option: 1. In the space below, make a sketch of your roller coaster.

Two-Body System: Two Hanging Masses

11. Describing Angular or Circular Motion

Review Chapters 2, 3, 4, 5

Problem Set 1. Ans: a = 1.74 m/s 2, t = 4.80 s

C B A T 3 T 2 T What is the magnitude of the force T 1? A) 37.5 N B) 75.0 N C) 113 N D) 157 N E) 192 N

Curso Física Básica Experimental I Cuestiones Tema IV. Trabajo y energía.

III. Applications of Force and Motion Concepts. Concept Review. Conflicting Contentions. 1. Airplane Drop 2. Moving Ball Toss 3. Galileo s Argument

226 Chapter 15: OSCILLATIONS

Forces. Definition Friction Falling Objects Projectiles Newton s Laws of Motion Momentum Universal Forces Fluid Pressure Hydraulics Buoyancy

Halliday, Resnick & Walker Chapter 13. Gravitation. Physics 1A PHYS1121 Professor Michael Burton

Displacement (x) Velocity (v) Acceleration (a) x = f(t) differentiate v = dx Acceleration Velocity (v) Displacement x

HW Set VI page 1 of 9 PHYSICS 1401 (1) homework solutions

Physics Midterm Review Packet January 2010

SOLID MECHANICS TUTORIAL MECHANISMS KINEMATICS - VELOCITY AND ACCELERATION DIAGRAMS

Chapter 9 Circular Motion Dynamics

Hand Held Centripetal Force Kit

Name Class Date. true

Fundamental Mechanics: Supplementary Exercises

5. Forces and Motion-I. Force is an interaction that causes the acceleration of a body. A vector quantity.

Uniform circular motion: Movement in a circle at a constant speed.

Forces. When an object is pushed or pulled, we say that a force is exerted on it.

Serway_ISM_V1 1 Chapter 4

PHYSICS 111 HOMEWORK SOLUTION #10. April 8, 2013

Lecture 16. Newton s Second Law for Rotation. Moment of Inertia. Angular momentum. Cutnell+Johnson: 9.4, 9.6

Chapter 4: Newton s Laws: Explaining Motion

Practice Test SHM with Answers

Educator Guide to S LAR SYSTEM El Prado, San Diego CA (619)

11. Rotation Translational Motion: Rotational Motion:

KE =? v o. Page 1 of 12

Section 1 Gravity: A Force of Attraction

Name Class Period. F = G m 1 m 2 d 2. G =6.67 x Nm 2 /kg 2

DIRECT ORBITAL DYNAMICS: USING INDEPENDENT ORBITAL TERMS TO TREAT BODIES AS ORBITING EACH OTHER DIRECTLY WHILE IN MOTION

2After completing this chapter you should be able to

Satellites and Space Stations

BHS Freshman Physics Review. Chapter 2 Linear Motion Physics is the oldest science (astronomy) and the foundation for every other science.

Candidate Number. General Certificate of Education Advanced Level Examination June 2014

Accelerometers: Theory and Operation

Rotational Inertia Demonstrator

Midterm Solutions. mvr = ω f (I wheel + I bullet ) = ω f 2 MR2 + mr 2 ) ω f = v R. 1 + M 2m

Chapter 4. Forces and Newton s Laws of Motion. continued

Physics 201 Homework 8

Physics Exam 2 Chapter 5N-New

9. The kinetic energy of the moving object is (1) 5 J (3) 15 J (2) 10 J (4) 50 J

State Newton's second law of motion for a particle, defining carefully each term used.

L-9 Conservation of Energy, Friction and Circular Motion. Kinetic energy. conservation of energy. Potential energy. Up and down the track

Physics 11 Assignment KEY Dynamics Chapters 4 & 5

Sample Questions for the AP Physics 1 Exam

Orbital Mechanics. Angular Momentum

Tennessee State University

State Newton's second law of motion for a particle, defining carefully each term used.

Physics 121 Homework Problems, Spring 2014

PHYS 101-4M, Fall 2005 Exam #3. MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question.

Acceleration due to Gravity

Chapter 11 Equilibrium


Chapter 6 Circular Motion

G U I D E T O A P P L I E D O R B I T A L M E C H A N I C S F O R K E R B A L S P A C E P R O G R A M

Lab 8: Ballistic Pendulum

HW Set II page 1 of 9 PHYSICS 1401 (1) homework solutions

Practice Exam Three Solutions

Lab 7: Rotational Motion

Halliday, Resnick & Walker Chapter 13. Gravitation. Physics 1A PHYS1121 Professor Michael Burton

The Effects of Wheelbase and Track on Vehicle Dynamics. Automotive vehicles move by delivering rotational forces from the engine to

Newton s Law of Universal Gravitation

3 Work, Power and Energy

Torque and Rotary Motion

Magnetism. d. gives the direction of the force on a charge moving in a magnetic field. b. results in negative charges moving. clockwise.

Transcription:

Chapter 3.8 & 6 Solutions P3.37. Prepare: We are asked to find period, speed and acceleration. Period and frequency are inverses according to Equation 3.26. To find speed we need to know the distance traveled by the speck in one period. Then the acceleration is given by Equation 3.30. Solve: (a) The disk s frequency can be converted as follows: The period is the inverse of the frequency: (b) The speed of the speck equals the circumference of its orbit divided by the period: which rounds to (c) From Equation 3.30, the acceleration of the speck is given by : Which rounds to. In units of g, this is as follows: Assess: The speed and acceleration of the edge of a CD are remarkable. The speed, is about As you will learn in chapter 4, very large forces are necessary to create large accelerations like P3.77. Prepare: We will use Equation 3.30 to relate the acceleration to the speed. But first we need to convert the speed of the car to Solve: (a) Your acceleration is given from the equation which converts as follows: The acceleration is or (b) The formula for centripetal acceleration, can be solved for v as follows: In this form we see that if the acceleration is doubled, then the velocity is multiplied by So we multiply the speed limit by At the acceleration would be twice the acceleration at

Assess: As noted in the solution to Problem 40, a small change in velocity can produce a large change in centripetal acceleration. Here, with an increase in speed of less than the acceleration doubles and the friction needed for the turn also doubles. Q6.22. Reason: There must be a centripetal force acting on the car directly toward the center of the circle. There are no other forces on the car beside the normal force and the weight, which act in the vertical direction. The correct choice is E. Assess: Since the car is going around the curve with constant speed, it is not accelerating in the direction tangent to the curve. This eliminates choices A, C, and D. Choice B would represent a centrifugal force, which seems to push the car out of the circular path. As discussed in Section 6.4, such a force actually does not exist. Q6.31. Reason: The skater turns one-and-a-half revolutions in 0.5 s. One-and-a-half revolutions is Her angular velocity is radians. The correct choice is D. Assess: This result is reasonable. She makes three revolutions in one second, which is radians per second. Q6.32. Reason: We first find (in rad/s) and then the centripetal acceleration. Let s make an estimate (one significant figure) for how far the hand is from the center of the body (the axis of rotation). Either think of a meter stick, or get one. From the center of your body to your hand is about 0.8 m for an average person. Now use Equation 6.8: The correct choice is C. Assess: We kept an extra guard digit in the intermediate calculations, but rounded the final result to one significant figure since that is all the data justifies. The result of 300 m/s 2 is large about 30 g. If your whole body experienced 30 g for more than a few seconds you would black out. However, this is only the skater s hand and only for a short time. Q6.33. Reason: In Question 6.31 we found that the angular velocity of the skater is 20 rad/s. Estimating the length of her arm to be about 0.75 m from the center of rotation, we can calculate the speed of her hand with Equation 6.7. The correct choice is D. Assess: This is actually a high velocity, over 30 mph. P6.3. Prepare: To compute the angular speed takes an hour to complete one revolution. Solve: we use Equation 6.3 and convert to rad/s. The minute hand Assess: This answer applies not just to the tip, but the whole minute hand. The answer is small, but the minute hand moves quite slowly. The second hand moves 60 times faster, or 0.10 rad/s. This too seems reasonable.

P6.13. Prepare: The horse and rider are in uniform circular motion. We are given A preliminary calculation will determine in rad/s for part (b): Solve: (a) Solve Equation 6.4 for (b) Use Equation 6.7: Assess: A time for two revolutions of 20 s seems reasonable; a speed of 2.5 m/s also seems reasonable. Note that for part (a) the answer is independent of the radius; it takes 20 s for everything to go around twice, not just the bucking horse. P6.15. Prepare: The pebble is a particle rotating around the axle in a circular orbit. We will use Equations 6.7 and 6.8. To convert units from rev/s to rad/s, we note that 1 rev = 2π rad. Solve: The pebble s angular velocity The speed of the pebble as it moves around a circle of radius r = 30 cm = 0.30 m is The centripetal acceleration is P6.17. Prepare: Equation 6.10 tells us the tension: Because all four are moving at the same speed, we need only consider the effect of m and r on T. A small r and a large m would make for a large T, as in case 3. Solve: Assess: Case 4 is the same as case 1 because both the mass and radius are doubled. P6.20. Prepare: We are given and A preliminary calculation using Table 1.3 will give v in m/s. Solve: (a) to two significant figures. (b) With the two forces on the ball being its weight and the force exerted by the hand, apply Newton s second law at the lowest point and solve for

Since the hand is providing the centripetal force, the direction is up when the ball is at the bottom of the circle. Assess: We check to see that we answered all parts of the problem: We gave the centripetal acceleration and the magnitude and direction of the force exerted by the hand. The centripetal acceleration seems large (200 g), but the force exerted by the hand seems reasonable, so everything is probably correct. The units check out. P6.23. Prepare: Model the passenger in a roller coaster car as a particle in uniform circular motion. A pictorial representation of the car, its free-body diagram, and a list of values are shown below. Note that the normal force of the seat pushing on the passenger is the passenger s apparent weight. Solve: Since the passengers feel 50% heavier than their true weight, the net force at the bottom of the dip is: Thus, from Newton s second law, Assess: A speed of 12 m/s or 27 mph for the roller coaster is reasonable. P6.26. Prepare: We will use the particle model for the test tube, which is in uniform circular motion. The radius to the end of the tube from the axis of rotation is 10 cm or 0.1 m. We will use Equation 6.8 and kinematic equations and work with SI units. Solve: (a) The acceleration is (b) An object falling 1 meter has a speed calculated as follows: When this object is stopped in upon hitting the floor, This result is one-fourth of the above radial acceleration in part (a). Assess: The radial acceleration of the centrifuge is large, but it is also true that falling objects are subjected to large accelerations when they are stopped by hard surfaces. P6.31. Prepare: Model the sun (s) and the earth (e) as spherical masses. Due to the large difference between your size and mass and that of either the sun or the earth, a human body can be treated as a particle. Use Equation 6.19. Solve: and Dividing these two equations gives

Assess: The result shows the smallness of the sun s gravitational force on you compared to that of the earth. P6.42. Prepare: We will use Equation 6.9 and Newton s second law. The electric force between the electron and the proton causes the centripetal acceleration needed for the electron s circular motion. Solve: Newton s second law is Substituting into this equation yields: Assess: This is a very high number of revolutions per second. P6.48. Prepare: Treat the coin as a particle which is undergoing circular motion. A visual overview of the coin s circular motion is shown below in the following pictorial representation, free-body diagram, and list of values. The force of static friction between the coin and the turntable, as long as the coin does not slide, causes the centripetal acceleration needed for circular motion. The force of static friction is This force is equivalent to the maximum centripetal force that can be applied without sliding. Work with SI units. Solve: That is, So, the coin will stay still on the turntable. Assess: A rotational speed of approximately 1 rev per second for the coin to stay stationary seems reasonable. P6.51. Prepare: Since the hanging block is at rest, the total force on it is zero. The two forces are the tension in the string, and the weight of the puck, Since the revolving puck is moving at constant speed in a circle, the total force on the puck is the centripetal force. We must write the equations and solve them. Solve: The total force on the block is From Newton s second law, the total force is zero so we write: The centripetal acceleration of the puck is caused by the tension in the string, so We solve this to obtain:

The puck must rotate at a speed of Assess: It is remarkable that a block can be supported by a puck moving horizontally. But both the puck and the block are able to pull on the string the block pulls downward on one end and the puck pulls outward on the other end. The relatively small mass of the puck is compensated by its high speed of P6.53. Prepare: Treat the car as a particle which is undergoing circular motion. The car is in circular motion with the center of the circle below the car. A visual overview of the car s circular motion is shown below in the following pictorial representation, free-body diagram, and list of values. Solve: Newton s second law at the top of the hill is This result shows that maximum speed is reached when n = 0 and the car is beginning to lose contact with the road. Then, Assess: A speed of 22 m/s is equivalent to 50 mph, which seems like a reasonable value. P6.57. Prepare: We expect the centripetal acceleration to be very large because is large. This will produce a significant force even though the mass difference of 10 mg is so small. A preliminary calculation will convert the mass difference to kg: 10 mg = 1.0 10 5 kg. If the two samples are equally balanced then the shaft doesn t feel a net force in the horizontal plane. However, the mass difference of 10 mg is what causes the force. We ll do another preliminary calculation to convert Solve: The centripetal acceleration is given by Equation 6.9 and the net force by Newton s second law. Assess: As we expected, the centripetal acceleration is large. The force is not huge (because of the small mass difference) but still enough to worry about. The net force scales with this mass difference, so if the mistake were bigger it could be enough to shear off the shaft.

2026 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information