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Unformatted text preview: homework 25 YOO, HEE Due: Mar 29 2008, 4:00 am 1 Question 1, chap 13, sect 1. part 1 of 1 10 points A rod can pivot at one end and is free to rotate without friction about a vertical axis, as shown. A force vector F is applied at the other end, at an angle to the rod. L m F If vector F were to be applied perpendicular to the rod, at what distance d from the axis of rotation should it be applied in order to produce the same torque vector ? 1. d = L 2. d = 2 L 3. d = L cos 4. d = L tan 5. d = L sin correct Explanation: The torque the force generates is = F L sin . Thus the distance in question should be L sin . Question 2, chap 13, sect 1. part 1 of 1 10 points A system of two wheels fixed to each other is free to rotate about a frictionless axis through the common center of the wheels and per pendicular to the page. Four forces are ex erted tangentially to the rims of the wheels, as shown below. F 2 F F F 2 R 3 R What is the magnitude of the net torque on the system about the axis? 1. = 2 F R correct 2. = F R 3. = 0 4. = 5 F R 5. = 14 F R Explanation: The three forces F give counterclockwise torques while the other force 2 F gives a clock wise torque. So the total torque is = summationdisplay F i R i = 2 F 3 R + F 3 R + F 3 R + F 2 R = 2 F R . Question 3, chap 13, sect 1. part 1 of 1 10 points A disk of mass M and radius R rotates about its axis. A string is wrapped around the disk and exerts a constant force F = 2 M g at an angle , as shown in the diagram. homework 25 YOO, HEE Due: Mar 29 2008, 4:00 am 2 F R M Find the magnitude of the tangential ac celeration of a point on the rim of the disk, given that the moment of inertia of the disk is I = 1 2 M R 2 . 1. bardbl vectora t bardbl = 2 g sin 2. bardbl vectora t bardbl = 2 g cos 3. bardbl vectora t bardbl = 4 g sin 4. bardbl vectora t bardbl = 4 g tan 5. bardbl vectora t bardbl = 4 g correct 6. bardbl vectora t bardbl = 4 g cos 7. bardbl vectora t bardbl = 2 g 8. bardbl vectora t bardbl = 2 g tan 9. bardbl vectora t bardbl = 4 g tan 10. bardbl vectora t bardbl = 2 g tan...
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This note was uploaded on 05/04/2008 for the course PHY 303K taught by Professor Turner during the Spring '08 term at University of Texas at Austin.
 Spring '08
 Turner
 Physics, Force, Friction, Work

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