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Physics 218: Mechanics Instructor: Dr. Tatiana Erukhimova Lectures 34, 35, 36 Hw: Chapter 14 problems and exercises Torque and Angular Momentum Conservation of Angular Momentum r F Lrp dLtot ext dt dr 2 L r p r m[ ir ri ] mr (rhr ) dt “Walk the Plank” x1 Mg x2 N = mg Mgx1 = mgx 2 M x2 = x1 m Map of Texas t = r^× F = 0 Because r = 0 ^ F = mg t = r^× F ¹ 0 F = mg t = r^× F = 0 Because r = 0 ^ F = mg Brady, TX Skyhooks The skyhook alone won ’ t balance on your finger, but when you put a belt on it, it does! This is all because adding the belt which curves under as it hangs actually moves the center of mass right under your finger! Motion along the straight line: momentum P mV Vector directed along velocity The larger the momentum, the larger force you need to apply in order to change its magnitude or direction Rotational motion: angular momentum Moment of inertia L I Vector along Angular axis of rotation velocity P mV I mr L I 2 Conservation of angular momentum: when radius decreases, rotation velocity goes up L(before) = L(after) I bb I aa I mr 2 Torque and Angular Momentum Conservation of Angular Momentum r F Lrp dLtot ext dt dr 2 L r p r m[ ir ri ] mr (rhr ) dt Pr. 1 A bullet of mass m is fired in the negative x direction with velocity of magnitude V0, starting at x = x0, y=b. (y remains constant) What is its angular momentum, with respect to the origin, as a function of x? Neglect gravity. Pr. 2 A ball of mass m is dropped from rest from the point x = B, y=H. Find the torque produced by gravity about the origin as a function of time. Problem 6 p.267 Consider a massless teeter-totter of length R, pivoted about its center. One kid of mass m2 sits on the right end and another of mass m1 sits on the left end. What is dL as a function of θ, the angle the board makesdtwith horizontal? Two men of equal mass are skating in a circle on a perfectly frictionless pond. They are each holding onto a rope of length R. What happens to the magnitude of momentum p of each man if they both pull on the rope, “hand over hand”, and shorten the distance between them to R/2. (Assume the men again move in a circle and the magnitude of their momenta are equal). An ant of mass m is standing at the center of a massless rod of length l. The rod is pivoted at one end so that it can rotate in a horizontal plane. The ant and the rod are given an initial angular velocity 0. If the ant crawls out towards the end of the rod so that his distance from the pivot is given by l bt 2 , find the 2 angular velocity of the rod as a function of time, angular momentum, force exerted on the bug by the rod, torque about the origin. Moment of Inertia For symmetrical objects rotating about their axis of symmetry: 2 L I (rhr ); I mi ri i A man stands on a platform which is free to rotate on frictionless bearings. He has his arms extended with a huge mass m in each hand. If he is set into rotation with angular velocity 0 and then drops his hands to his sides, what happens to his angular velocity? (Assume that the man’s mass is negligible and that his arms have length R when extended and are R/4 from the center of his body when at his sides.) Newton’s law of gravitation Orbital motion Conservation of Angular Momentum A block of mass M is cemented to a circular platform at a distance b from its center. The platform can rotate, without friction, about a vertical axle through its center with a moment of inertia, Ip. If a bullet of mass m, moving horizontally with velocity of magnitude vB as shown, strikes and imbeds itself in the block, find the angular velocity of the platform after the collision. b vB axle top view Have a great day! Hw: Chapter 14 problems and exercises