Chapter 5 QuickCheck Questions Applying Newton’s Laws © 2015 Pearson Education, Inc.

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Chapter 5 QuickCheck Questions Applying Newton’s Laws © 2015 Pearson Education, Inc.

Slide 5-2 QuickCheck 5.1 A ring, seen from above, is pulled on by three forces. The ring is not moving. How big is the force F? A.20 N B.10 cos  N C.10 sin  N D.20 cos  N E.20 sin  N © 2015 Pearson Education, Inc.

Slide 5-3 QuickCheck 5.1 A ring, seen from above, is pulled on by three forces. The ring is not moving. How big is the force F? A.20 N B.10 cos  N C.10 sin  N D.20 cos  N E.20 sin  N © 2015 Pearson Education, Inc.

Slide 5-4 QuickCheck 5.2 The box is sitting on the floor of an elevator. The elevator is accelerating upward. The magnitude of the normal force on the box is A. n > mg B. n = mg C. n < mg D. n = 0 E. Not enough information to tell © 2015 Pearson Education, Inc.

Slide 5-5 QuickCheck 5.2 The box is sitting on the floor of an elevator. The elevator is accelerating upward. The magnitude of the normal force on the box is A. n > mg B. n = mg C. n < mg D. n = 0 E. Not enough information to tell Upward acceleration requires a net upward force. © 2015 Pearson Education, Inc.

Slide 5-6 QuickCheck 5.3 A box is being pulled to the right at steady speed by a rope that angles upward. In this situation: A. n > mg B. n = mg C. n < mg D. n = 0 E.Not enough information to judge the size of the normal force © 2015 Pearson Education, Inc.

Slide 5-7 QuickCheck 5.3 A box is being pulled to the right at steady speed by a rope that angles upward. In this situation: A. n > mg B. n = mg C. n < mg D. n = 0 E.Not enough information to judge the size of the normal force © 2015 Pearson Education, Inc.

Slide 5-8 QuickCheck 5.4 What are the components of in the coordinate system shown? © 2015 Pearson Education, Inc.

Slide 5-9 QuickCheck 5.4 What are the components of in the coordinate system shown? © 2015 Pearson Education, Inc. D

Slide 5-10 QuickCheck 5.5 A 50-kg student (mg = 490 N) gets in a 1000-kg elevator at rest and stands on a metric bathroom scale. As the elevator accelerates upward, the scale reads A.> 490 N B.490 N C.< 490 N but not 0 N D.0 N © 2015 Pearson Education, Inc.

Slide 5-11 QuickCheck 5.5 A 50-kg student (mg = 490 N) gets in a 1000-kg elevator at rest and stands on a metric bathroom scale. As the elevator accelerates upward, the scale reads A.> 490 N B.490 N C.< 490 N but not 0 N D.0 N © 2015 Pearson Education, Inc.

Slide 5-12 QuickCheck 5.6 A 50-kg student (mg = 490 N) gets in a 1000-kg elevator at rest and stands on a metric bathroom scale. Sadly, the elevator cable breaks. What is the reading on the scale during the few seconds it takes the student to plunge to his doom? A.> 490 N B.490 N C.< 490 N but not 0 N D.0 N © 2015 Pearson Education, Inc.

Slide 5-13 QuickCheck 5.6 A 50-kg student (mg = 490 N) gets in a 1000-kg elevator at rest and stands on a metric bathroom scale. Sadly, the elevator cable breaks. What is the reading on the scale during the few seconds it takes the student to plunge to his doom? A.> 490 N B.490 N C.< 490 N but not 0 N D.0 N The bathroom scale would read 0 N. Weight is reading of a scale on which the object is stationary relative to the scale. © 2015 Pearson Education, Inc.

Slide 5-14 QuickCheck 5.7 A box on a rough surface is pulled by a horizontal rope with tension T. The box is not moving. In this situation: A. f s > T B. f s = T C. f s < T D. f s =  smg E. f s = 0 © 2015 Pearson Education, Inc.

Slide 5-15 QuickCheck 5.7 A box on a rough surface is pulled by a horizontal rope with tension T. The box is not moving. In this situation: A. f s > T B. f s = T C. f s < T D. f s =  smg E. f s = 0 Newton’s first law © 2015 Pearson Education, Inc.

Slide 5-16 QuickCheck 5.8 A box with a weight of 100 N is at rest. It is then pulled by a 30 N horizontal force. Does the box move? A.Yes B.No C.Not enough information to say © 2015 Pearson Education, Inc.

Slide 5-17 QuickCheck 5.8 A box with a weight of 100 N is at rest. It is then pulled by a 30 N horizontal force. Does the box move? A.Yes B.No C.Not enough information to say 30 N < f s max = 40 N © 2015 Pearson Education, Inc.

Slide 5-18 QuickCheck 5.9 A box is being pulled to the right over a rough surface. T > f k, so the box is speeding up. Suddenly the rope breaks. What happens? The box A.Stops immediately. B.Continues with the speed it had when the rope broke. C.Continues speeding up for a short while, then slows and stops. D.Keeps its speed for a short while, then slows and stops. E.Slows steadily until it stops. © 2015 Pearson Education, Inc.

Slide 5-19 QuickCheck 5.9 A box is being pulled to the right over a rough surface. T > f k, so the box is speeding up. Suddenly the rope breaks. What happens? The box A.Stops immediately. B.Continues with the speed it had when the rope broke. C.Continues speeding up for a short while, then slows and stops. D.Keeps its speed for a short while, then slows and stops. E.Slows steadily until it stops. © 2015 Pearson Education, Inc.

Slide 5-20 QuickCheck 5.10 All three 50-kg blocks are at rest. The tension in rope 2 is A.Greater than the tension in rope 1. B.Equal to the tension in rope 1. C.Less than the tension in rope 1. © 2015 Pearson Education, Inc.

Slide 5-21 QuickCheck 5.10 All three 50-kg blocks are at rest. The tension in rope 2 is A.Greater than the tension in rope 1. B.Equal to the tension in rope 1. C.Less than the tension in rope 1. Each block is in static equilibrium, with. © 2015 Pearson Education, Inc.

Slide 5-22 QuickCheck 5.11 Consider the situation in the figure. Which pair of forces is an action/reaction pair? A.The tension of the string and the friction force acting on A B.The normal force on A due to B and the weight of A C.The normal force on A due to B and the weight of B D.The friction force acting on A and the friction force acting on B © 2015 Pearson Education, Inc.

Slide 5-23 QuickCheck 5.11 Consider the situation in the figure. Which pair of forces is an action/reaction pair? A.The tension of the string and the friction force acting on A B.The normal force on A due to B and the weight of A C.The normal force on A due to B and the weight of B D.The friction force acting on A and the friction force acting on B © 2015 Pearson Education, Inc.

Slide 5-24 QuickCheck 5.12 Boxes A and B are being pulled to the right on a frictionless surface; the boxes are speeding up. Box A has a larger mass than Box B. How do the two tension forces compare? A. T 1 > T 2 B. T 1 = T 2 C. T 1 < T 2 D. Not enough information to tell © 2015 Pearson Education, Inc.

Slide 5-25 QuickCheck 5.12 Boxes A and B are being pulled to the right on a frictionless surface; the boxes are speeding up. Box A has a larger mass than Box B. How do the two tension forces compare? A. T 1 > T 2 B. T 1 = T 2 C. T 1 < T 2 D. Not enough information to tell © 2015 Pearson Education, Inc.

Slide 5-26 QuickCheck 5.13 Boxes A and B are sliding to the right on a frictionless surface. Hand H is slowing them. Box A has a larger mass than Box B. Considering only the horizontal forces: A. F B on H = F H on B = F A on B = F B on A B. F B on H = F H on B > F A on B = F B on A C. F B on H = F H on B < F A on B = F B on A D. F H on B = F H on A > F A on B © 2015 Pearson Education, Inc.

Slide 5-27 QuickCheck 5.13 Boxes A and B are sliding to the right on a frictionless surface. Hand H is slowing them. Box A has a larger mass than Box B. Considering only the horizontal forces: A. F B on H = F H on B = F A on B = F B on A B. F B on H = F H on B > F A on B = F B on A C. F B on H = F H on B < F A on B = F B on A D. F H on B = F H on A > F A on B © 2015 Pearson Education, Inc.

Slide 5-28 QuickCheck 5.14 The two masses are at rest. The pulleys are frictionless. The scale is in kg. The scale reads A.0 kg B.5 kg C.10 kg © 2015 Pearson Education, Inc.

Slide 5-29 QuickCheck 5.14 The two masses are at rest. The pulleys are frictionless. The scale is in kg. The scale reads A.0 kg B.5 kg C.10 kg © 2015 Pearson Education, Inc.

Slide 5-30 QuickCheck 5.15 The top block is accelerated across a frictionless table by the falling mass m. The string is massless, and the pulley is both massless and frictionless. The tension in the string is A. T < mg B. T = mg C. T > mg © 2015 Pearson Education, Inc.

Slide 5-31 Tension has to be less than mg for the block to have a downward acceleration. QuickCheck 5.15 The top block is accelerated across a frictionless table by the falling mass m. The string is massless, and the pulley is both massless and frictionless. The tension in the string is A. T < mg B. T = mg C. T > mg © 2015 Pearson Education, Inc.