PHYSICS 218 EXAM 2 Thursday, October 22, 2009 NAME: SECTION: 525 526 527 528 Note: 525 Recitation Wed 9:10-10:00 526 Recitation Wed 11:30-12:20 527 Recitation Wed 1:50-2:40 528 Recitation Mon 11:30-12:20 There are a total of 7 problems on this test: Problems 1, 2, and 3 are worth 6 or 7 points each, as indicated. For these three problems, points will be deducted for the wrong units or wrong number of significant digits. Other than that, no partial credit will be awarded for incorrect answers. Problems 4, 5, 6, and 7 are worth 20 points each. For these four problems, partial credit will be awarded where appropriate. For all 7 problems: You must show your work and/or explain your reasoning to receive any credit for a problem; merely stating the answer is NOT sufficient. Write your final answer(s) in the blanks provided. You may use the backs of the pages for scratch calculations if you wish, but only the work in the spaces provided on the front of the pages will be graded. For numerical values, assume that all specified digits are significant, including trailing zeros. Also remember, an answer CAN NOT be completely correct if it has the wrong units or the wrong number of significant digits. G O O D L U C K!!!!!
For problems 1, 2, and 3, do your work in the space provided, and write your final answer in the blank. Points will be deducted for the wrong units or wrong number of significant digits. Other than that, no partial credit will be awarded for incorrect answers. 1. (6 points) In the figure below, specify the point where the object will have the smallest kinetic energy. Point 2. (7 points) The spring of a spring gun has force constant k = 375 N/m and negligible mass. The spring is compressed 7.00 cm, and a ball with mass 0.0300 kg is placed at rest in the horizontal barrel against the compressed spring. The spring is then released, and the ball is propelled out the barrel of the gun. The barrel is 7.00 cm long. A constant resisting force of 5.50 N acts on the ball as it moves along the barrel. How far has the ball moved from its initial position when it reaches its maximum speed? Distance 3. At a construction site, a 60.0 kg bucket of concrete hangs from a light (but strong) cable that passes over a light friction-free pulley and is connected to an 85.0 kg box on a horizontal roof. A 45.0 kg bag of gravel rests on top of the box. The coefficients of friction between the box and its surrounding surfaces are given. The system is at rest. Draw a free-body diagram for the box that an Engineering professor would accept. (Diagram wrong, 0 pts; diagram with forces, 4 pts; diagram with forces and magnitudes, 7 pts.) Free-body Diagram
For problems 4, 5, 6, and 7, do your work in the space provided, and write your final answer in the blank. For these problems, partial credit will be awarded where appropriate, based on the work that you show. 4. (20 points) A balky cow is leaving the barn as you try harder and harder to push her back in. In coordinates with the origin at the barn door, the cow walks from x = 0 to x = 6.90 m as you apply a force with x-component F x = [20.0 N + (2.50 N/m)x]. How much work does the force that you apply do on the cow during this displacement? Work
5. (20 points) Kate, a bungee jumper, wants to jump off the edge of a bridge that spans a river below. Kate has a mass m, and the surface of the bridge is a height h above the water. The bungee cord, which has length L when unstretched, will first straighten and then stretch as Kate falls. Assume the bungee cord behaves as an ideal spring once it begins to stretch, with spring constant k. Also assume that Kate doesn't actually jump but simply steps off the edge of the bridge and falls straight downward, and that Kate s height is negligible compared to the distances in the problem. (a) How far below the bridge will Kate eventually be hanging, once she stops oscillating and comes finally to rest? Assume that she doesn't touch the water. (b) If Kate just barely touches the surface of the river on her first downward trip (i.e., before the first bounce), what is the spring constant k? Ignore all dissipative forces. Distance Spring constant
6. (20 points) A spacecraft descends vertically near the surface of Planet X. An upward thrust of 24.0 kn from its engines slows it down at a rate of 1.20 m/s 2, but it speeds up at a rate of 0.800 m/s 2 with an upward thrust of 9.50 kn. What is the spacecraft s weight near the surface of Planet X? Weight
7. (20 points) You are driving in a horizontal circular path of radius R on a highway that is banked at an angle θ from the horizontal, as shown in the figure below. At the instant shown in the figure, you are driving directly out of the page. The coefficient of static friction between your tires and the road is μ s, and the coefficient of kinetic friction is μ k. (a) In the space below, draw a free-body diagram for the car that an Engineering professor would accept. (b) Find the maximum speed, v max, that you can be moving in your circular path to avoid slipping on the bank. (Express your answer in terms of g and the constants specified above.) v max Free-body diagram