Block m, of mass 15 kg moving with velocity v = 33 m/s on a frictioniess plane collides block my which is connected to block mg by a long. massiess spring with spring constant k = 7000 N/m : see the figure. Each of blocks mg and ma has a mass of 5 kg Before the collision. blocks mg and mg are stationary and the spring is relaxed. m2 Frictionless- • For parts A. B and C assume that the collision of blocks m, and mg is completely inelastic. (Because the spring is relaxed before the collision. block my does not move at the instant of impact. therefore (m, +m2) must move through a finite displacement before any force acts on mg and cause it to move) • For parts D and E assume that the collision of blocks m, and m, is elastic. (Because the spring is relaxed before the collision. block my does not move at the instant of impact therefore m, must move through a finite displacement before any force acts on mg and cause it to move) B) After the collision. what is the minimum kinetic energy of block my in units of joules? Answer:

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Chapter1: Units, Trigonometry. And Vectors
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) THE FOLLOWING QUESTIONS ARE BASED ON THE INFORMATION GIVEN BELOW.
Block m, of mass 15 kg moving with velocity v = 33 m/s on a frictionless plane collides block mg which is connected to block
m3 by a long. massless spring with spring constant k = 7000 N/m: see the figure. Each of blocks mą and ma has a mass of 5 kg.
Before the collision, blocks mą and mg are stationary and the spring is relaxed.
m2
Frictionless-
• For parts A. B and C assume that the collision of blocks m, and mą is completely inelastic. (Because the spring is relaxed
before the collision, block mg does not move at the instant of impact. therefore (m, +m2) must move through a finite
displacement before any force acts on mg and cause it to move)
• For parts D and E assume that the collision of blocks m, and m, is elastic. (Because the spring is relaxed before the
collision. block mg does not move at the instant of impact. therefore mẹ must move through a finite displacement before any
force acts on mg and cause it to move.)
B) After the collision, what is the minimum kinetic energy of block m, in units of joules?
Answer:
Transcribed Image Text:) THE FOLLOWING QUESTIONS ARE BASED ON THE INFORMATION GIVEN BELOW. Block m, of mass 15 kg moving with velocity v = 33 m/s on a frictionless plane collides block mg which is connected to block m3 by a long. massless spring with spring constant k = 7000 N/m: see the figure. Each of blocks mą and ma has a mass of 5 kg. Before the collision, blocks mą and mg are stationary and the spring is relaxed. m2 Frictionless- • For parts A. B and C assume that the collision of blocks m, and mą is completely inelastic. (Because the spring is relaxed before the collision, block mg does not move at the instant of impact. therefore (m, +m2) must move through a finite displacement before any force acts on mg and cause it to move) • For parts D and E assume that the collision of blocks m, and m, is elastic. (Because the spring is relaxed before the collision. block mg does not move at the instant of impact. therefore mẹ must move through a finite displacement before any force acts on mg and cause it to move.) B) After the collision, what is the minimum kinetic energy of block m, in units of joules? Answer:
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