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Chapter 7 Work and Kinetic Energy 7-1 Work done by a Constant Force A. Force along Displacement W = Fd Units: Nm = Joule P7.5 (p.200)

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Presentation on theme: "Chapter 7 Work and Kinetic Energy 7-1 Work done by a Constant Force A. Force along Displacement W = Fd Units: Nm = Joule P7.5 (p.200)"— Presentation transcript:

1 Chapter 7 Work and Kinetic Energy 7-1 Work done by a Constant Force A. Force along Displacement W = Fd Units: Nm = Joule P7.5 (p.200)

2 Chapter 7 Work and Kinetic Energy 7-1 Work done by a Constant Force B. Force at Angle to Displacement W = Fdcos P7.11 (p.200) Similar to assigned 7.14 d  F

3 A. B. C. CT1

4 The force acting on an object is proportional to the final speed. Incorrect Explanation: A decrease in the rate of speeding up is due to the force being 'used up.' 

5 A. B. C. CT2

6 For objects falling vertically, regardless of mass, the same force applied for the same amount of time produces the same motion. 

7 For objects on frictionless surfaces, regardless of mass, the same force applied for the same amount of time produces the same motion. The student explains linear acceleration with a reversed or otherwise incorrect relationship between force, mass, and acceleration. 

8

9 A. B. C. D. CT3

10 The student explains curved motion by having an outward force balancing an inward force. The student thinks that an outward force exists with all curved motion. 

11 A. B. C. D. CT4

12 A. B. C. D. The student thinks that only forces exactly in the direction of motion (or opposite) can speed up or slow down an object. All other forces just change the direction of motion. The student thinks that all unbalanced forces on an object will either cause the object to speed up or slow down. 

13 Chapter 7 Work and Kinetic Energy 7-1 Work done by a Constant Force C. Zero, Negative and Total Work W is zero if  = 90 or 270 W is negative if 90 <  < 270 W TOT = (F TOT cos)d or W TOT = W P7.9 (p.200) d  F TOT

14 Concept Question 5 P7.9: The coefficient of kinetic friction  k is A. equal to f k /mg. B. greater than f k /mg. C. less than f k /mg.

15 Chapter 7 Work and Kinetic Energy 7-2 Kinetic Energy (K) and the Work-Kinetic Energy Theorem K = mv 2 /2 W TOT = K P7.18 (p.200)

16 Concept Question 6 P7.18b: The work of the air resistance is A. positive B. negative C. zero P7.19 (p.200)

17 7-3 Work Done by a Variable Force Graphical Representation of the Work Done by a Constant Force F x

18 Work Done by a Non-Constant Force W = W 1 + W 2 = Total Area Under the Force-Displacement Curve

19 Work Done by a Continuously Varying Force

20 W = Total Area Under the Force-Displacement Curve

21 P7.29 (p.201) You do 7.28 7.32 Hint W = K W1 W2 W3 0.4 0.9

22 7.31 (p.201) W = ½ base x height W = ½kx 2

23 Concept Question 7 P7.31b: The additional work to compress the spring another 0.14 meters is A. 160J. B. more than 160J. C. less than 160J.

24 Chapter 7 Work and Kinetic Energy 7-4 Power P AV = W/t Units: J/s = Watt P AV = Fv (for constant v along displacement) P7.50 (p.202)

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