Shown in the figure below is a set of two masses on a track. The regions with the solid black line have no friction and the region with the tan pattern has a coefficient of k= 0.401. The small mass, m 1.42 kg, is initially stationary at a height of Y1 = 0.78 meters. The large mass, M = 4.60 kg, is stationary on the flat surface. V₁ (1) V₂=? (2 Blocks stick together M V₂=? The following sequence of events occur: . 12: The small mass slides down the ramp. . 2-3: The small and large mass collide inelastically and stick together. • 3-4: The small and large mass slide together into the frictional region and come to a stop. Determine all the following: The velocity of the small mass at moment 2: v₂ = The velocity of the stuck masses moment 3: V3 = The distance required to come to a stop: d = m m/s d=? m/s stopped biddaman friction
Shown in the figure below is a set of two masses on a track. The regions with the solid black line have no friction and the region with the tan pattern has a coefficient of k= 0.401. The small mass, m 1.42 kg, is initially stationary at a height of Y1 = 0.78 meters. The large mass, M = 4.60 kg, is stationary on the flat surface. V₁ (1) V₂=? (2 Blocks stick together M V₂=? The following sequence of events occur: . 12: The small mass slides down the ramp. . 2-3: The small and large mass collide inelastically and stick together. • 3-4: The small and large mass slide together into the frictional region and come to a stop. Determine all the following: The velocity of the small mass at moment 2: v₂ = The velocity of the stuck masses moment 3: V3 = The distance required to come to a stop: d = m m/s d=? m/s stopped biddaman friction
Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
ChapterMA: Math Assessment
Section: Chapter Questions
Problem 1.1MA
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![Shown in the figure below is a set of two masses on a track. The regions with the solid black line have no friction and the region with the tan pattern has a coefficient of μk
Y1 = 0.78 meters. The large mass, M = 4.60 kg, is stationary on the flat surface.
Y₁
3 1
V₂ = ?
.
Blocks stick together
M
The following sequence of events occur:
V3=?
3
1→ 2: The small mass slides down the ramp.
• 2→ 3: The small and large mass collide inelastically and stick together.
• 34: The small and large mass slide together into the frictional region and come to a stop.
Determine all the following:
The velocity of the small mass at moment 2: v₂ =
The velocity of the stuck masses at moment 3: V3
The distance required to come to a stop: d =
m
m/s
d=?
m/s
stopped
4
M
friction
0.401. The small mass, m = 1.42 kg, is initially stationary at a height of](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2F7c4f071b-e761-4ac7-8258-1708f543e3fb%2Fded5d6c6-be93-4f36-b41a-8c506617948c%2Fvmq6ol_processed.jpeg&w=3840&q=75)
Transcribed Image Text:Shown in the figure below is a set of two masses on a track. The regions with the solid black line have no friction and the region with the tan pattern has a coefficient of μk
Y1 = 0.78 meters. The large mass, M = 4.60 kg, is stationary on the flat surface.
Y₁
3 1
V₂ = ?
.
Blocks stick together
M
The following sequence of events occur:
V3=?
3
1→ 2: The small mass slides down the ramp.
• 2→ 3: The small and large mass collide inelastically and stick together.
• 34: The small and large mass slide together into the frictional region and come to a stop.
Determine all the following:
The velocity of the small mass at moment 2: v₂ =
The velocity of the stuck masses at moment 3: V3
The distance required to come to a stop: d =
m
m/s
d=?
m/s
stopped
4
M
friction
0.401. The small mass, m = 1.42 kg, is initially stationary at a height of
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