A block of mass m = 2.00 kg is released from rest at h = 0.600...

A block of mass m = 2.00 kg is released from rest at h = 0.600 m above the surface of a table, at the top of a ? = 40.0

Expert Solution

a) the acceleration down a frictionless incline is g sin(theta) = 9.8m/s/s x sin40 = 6.29m/s

b) we can find final velocity from

vf^2=v0^2 + 2ad

vf = final vel
v0=initial vel =0
a = accel = 6.29m/s/s
d= distance traveled = distance down the plane = 0.6m/sin40 =0.933m
vf^2=0+2*6.29*0.933 => vf = 3.426m/s

now we write the x and y equations of motion for the block; down will be negative, so

x(t) = v0 cos(theta) t = 3.426 cos 40 t
y(t) = 2 - v0 sin(theta) t - 1/2 gt^2 = 2- 3.426 sin 40 t - 4.9 t^2

to find the time it takes the block to hit the ground once it leave the incline, set y(t)=0

and solve the quadratic 0=2 -2.20 t - 4.9t^2
t=0.452s

the horizontal distance traveled in that time is

x = 3.426 cos40* 0.452s = 1.18m

the time for the block to reach the bottom of the incline can be found from

d = 1/2 at^2 or t= sqrt[2d/a] = sqrt[2* 1.18 m/s / 6.29m/s/s] = 0.612s

so the total time = 0.612s+0.452s = 1.06s

genius_generous answered 1 month ago

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