A 4.5 kg box slides down a 5.2-m -high frictionless hill, starting from rest, ac
ID: 1441364 • Letter: A
Question
A 4.5 kg box slides down a 5.2-m -high frictionless hill, starting from rest, across a 2.2-m -wide horizontal surface, then hits a horizontal spring with spring constant 480 N/m . The other end of the spring is anchored against a wall. The ground under the spring is frictionless, but the 2.2-m-long horizontal surface is rough. The coefficient of kinetic friction of the box on this surface is 0.24
What is the speed of the box just before reaching the rough surface?
What is the speed of the box just before hitting the spring?
How far is the spring compressed?
Including the first crossing, how many complete trips will the box make across the rough surface before coming to rest?
Explanation / Answer
Energy balance with loss due to friction
at top of frictionless hill the box has its TOTAL starting energy as P.E.
P.E. top = mgh {where m = 4.5, g = 9.8, h = 5.2)
P.E. top = (4.5)(9.8)(5.2) = 229.32 J {total energy at start}
at bottom of frictionless hill the box has its TOTAL energy as K.E.
P.E. top = K.E. bottom = 1/2 mv²
229.32 = 0.5(4.5)v²
v = 10.1 m/s
b)over rough surface friction force extracts work from box energy total
Wf = FF x 2.2{where Wf = work done by friction force of FF)
FF = (0.24) x normal force
normal force = box weight = mg = (4.5)(9.8) = 44.1 N
FF = (0.24)(44.1) = 10.9N
Wf = (10.9)(2.4) = 26.16 J
box speed just before hitting spring is given by K.E. of box
K.E. before spring = K.E.bottom - Wf = 229.32 - 26.16 = 203.16 J
K.E. before spring = 1/2 mv²
203.16 = (0.5)(4.5)v²
v = 9.50 m/s
C)K.E. box = 203.16 J is stored at max spring compression as P.E. spring
203.16 = P.E. spring = 1/2 kx²
203.16 = (0.5)(500)x²
x = 0.901 m
d)Each time box crosses rough surface it loses Wf = 26.16J
Box starts with a total energy = 229.32 J
Box can cross rough surface = 229.32/26.16=8.76 times
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