Question

The figure below show three masses m=1.6 kg, m2=3.0 kg, and m3=4.6 kg which undergo two successive collisions. The first collision between mi, which has an initial velocity v=6.9 m/s, and m2 (which is initially at rest) is completely inelastic. The second collision between the combined mass mi+m2 and m3 (which is initially at rest) is elastic. What is the velocity of mg after the second collision? V 2 3 Select one 04.08 m/s O 2.40 m/s 2.64 m/s O 3.12 m/s 1.68 m/s

Answer 1

3 2 im, = 1.6 kg M2=3.0kg M3=4.6kg Collision between me and me Before collision. After collision v2 imal Imil mal Imi Viz is combined velocity of (m, +M2) from conservation of momentum mir + Maxo (mitm) 42 riv=6.gmis ... 4-6x6:9) = (1-6+3) 2. » V2 = (1-6 x 6.9 m/s = 2.4 m/s for collesoon between (Mitme) and Me Before callesion After collision IN2 (mitm) vie (m, 4M2) IM3 mg />v' HAY V₂=0m2 velocity of My before collesion.

From conservation of momentum. (M, AM2) Viz + Mg = (M. +Me) Via +M3 Va (1.6+3)x 2.4 +0=11.6+3) Vie +4.6 u > 11.04 -4.6 V' = 4.6 Via a vé= 111.04 14.6. 4.6. 4.6 Niat = 1,20 = 2.4 - Va Sence, callesoon is perfectly elastic so, velocity of seperation is equal to velocity of approach. vis vi → V--12:4-6) = 2.4 =2.4 +2.4. No=2.4m/s So, and option from the top is correct » Vastu 2 V3 = 2x2.4