Answer:
we see that the sphere is the body that arrives with the highest speed, therefore it must be the body that takes the least time,
Step-by-step explanation:
Let's analyze this exercise they ask us which body reaches the bottom of the ramp first, for which we must calculate the speed of the body in the final part, use the concepts of energy conservation
starting point. Highest part of the ramp
= U = m g h
at this point there is no kinematic energy because the body starts from rest
Final point. Lower part of the ramp
E_{m2} = K = ½ m v² + ½ I w²
we fix the reference system at this point, as the body is rolling, it has energy of connection and rotation
energy is conserved
E_{m1} = E_{m2}²
mgh = ½ m v² + ½ I w²
the angular and linear variables are related
v = wr
w = v / r
mg h = ½ m v² + ½ I v² / r²
mg h = ½ m v² (1 + I / m r²)
v² = 2gh / (1 + I / mr²)
Since all bodies start from rest, the body that has more speed at the end of the ramp, is the body that takes less time.
To find the speed we look in the tables for the moment of inertia of the bodies
circular loop I = mr²
disk I = ½ m r²
sphere I = 2/5 mr²
let's calculate the speed for each body
tie
v² = 2g h (1+ mr² / mr²)
v = √ (2gh) / √2
v = 0.707 ra (2gh
disk
v² = 2gh / (1 + ½ mr² / mr²)
v = ra 2gh / ra 3/2
v = 0.816 ra 2gh
sphere
v² = 2gh / (1 + 2/5 mr₂ / mr)
v = ra 2gh / ra 7/5
v = 0.845 ra 2gh
we see that the sphere is the body that arrives with the highest speed, therefore it must be the body that takes the least time, since
t = d / v