Answer:
A) d = 3.94m
B) d' = 3.14m
Step-by-step explanation:
We are given;
Mass of block; m = 242g = 0.242 kg
Spring constant; k = 1.62 kN/m = 1.62 x 10³ N/m
Extension of spring; x = 10 cm =0.1m
Coefficient of friction;µ = 0.44
Angle of inclination; θ = 60°
A) Equating the energy at the bottom of the ramp to the energy at a distance d up the ramp (at a height h in the vertical direction) we find;
W = (1/2)kx² = (1/2)•1.62 x 10³•0.1² = 8.1 J
W = mgh = 8.1
Where, h = d•sinθ
Thus, 8.1 = 0.242 x 9.8 x d sin 60
8.1 = 2.05387d
d = 8.1/2.05387
d = 3.94m
B) Here we equate the initial energy, still 8.1J, at the bottom of the ramp to the total energy at a distance d' up the ramp (at a height h') which is the sum of the gravitational potential energy (at h') and the energy losses due to
friction. The energy losses due to friction are calculated from the work
done by friction which is the force of friction times the displacement of
the object. The force of friction is simply the product of the normal force and the coefficient of kinetic friction. The normal force is found through a free body diagram and has magnitude F_n = mg cos θ . Putting this all together, we have;
8.1 = mgh' + ΔE
Thus,
8.1 = mgd'•sin θ + µmgd'•cos θ
So, d' = 8.1/[mgd'•sin θ + µmgd'•cos θ]
Plugging in relevant values;
8.1/[0.242x9.8(d'sin60 + (0.44 x d' x cos60))
8.1 = 2.3716d'(0.866 + 0.22)
8.1 = d'(2.3716 x 1.086)
d' = 8.1/2.576 = 3.14m