y, a small piece of putty of mass m₁ is In fired with velocity v₁¡ at a stationary wooden block of mass m₂ resting on a horizontal table. After a head-on collision, the putty sticks to the wooden block and the two slide along the surface of the table together as a single mass. (A) What equations from conservation are useful for determining V₁f and v2f. Simplify equations and solve for vf in terms of v₁; and the two masses m₁ and m2. (B) After the collision the two masses slide along the table a distance x before being slowed by friction and coming to a stop. The coefficient of kinetic friction uk. Solve for the stopping distance x in terms of the masses m₁ and m2, the initial fired velocity of the putty v₁i, gravity g, and the coefficient of kinetic friction μk. (C) Before the experiment the mass of the putty is determined to be 105 grams, the mass of the block is 10.5 kg and the putty is fired with an initial speed of 25 m/s. The coefficient of friction between the block and the table is determined to be 0.15. Determine the expected stopping distance x.
y, a small piece of putty of mass m₁ is In fired with velocity v₁¡ at a stationary wooden block of mass m₂ resting on a horizontal table. After a head-on collision, the putty sticks to the wooden block and the two slide along the surface of the table together as a single mass. (A) What equations from conservation are useful for determining V₁f and v2f. Simplify equations and solve for vf in terms of v₁; and the two masses m₁ and m2. (B) After the collision the two masses slide along the table a distance x before being slowed by friction and coming to a stop. The coefficient of kinetic friction uk. Solve for the stopping distance x in terms of the masses m₁ and m2, the initial fired velocity of the putty v₁i, gravity g, and the coefficient of kinetic friction μk. (C) Before the experiment the mass of the putty is determined to be 105 grams, the mass of the block is 10.5 kg and the putty is fired with an initial speed of 25 m/s. The coefficient of friction between the block and the table is determined to be 0.15. Determine the expected stopping distance x.
Glencoe Physics: Principles and Problems, Student Edition
1st Edition
ISBN:9780078807213
Author:Paul W. Zitzewitz
Publisher:Paul W. Zitzewitz
Chapter9: Momentum And Its Conservation
Section: Chapter Questions
Problem 96A
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