Answer:
Explanation:
1) Net force: According to Newtons second law, when a net force is acting on an object, the object must be accelerating i.e its speed changes from second to second. Also, Net force is the sum of all forces acting on an object. If the object is not accelerating the sum of net forces is zero
mathematically, Fnet = 0
∑Fₓ = 0, let the constants be represented as k
x = mass of the block
∴ F - K1x - K2x = 0
F = K1x + K2x
F = x(K1 + K2)
= 0.27(31 + 53)
= 22.63N
2) Effective spring constant
K_eff = K1 + K2
= 31 + 53
= 84N/m
3) Period of Oscillation of the block (T in second)
ω = angular speed/frequency
ω = √k_eff/mass of block
= √84/7.4
ω = √11.351 = 3.369rad/s
Also ω = 2π/T
∴T = 2π/ω
= 2π/3.369
T =1.86s
4) How long does it take the block to return to equilibrium for the first time?
period is 1.86s, from 0.27m to 0 is a quarter of one cycle,
so t = period/4
t = 1.86/4
= 0.465s
5) What is the speed of the block as it passes through the equilibrium position?
To determine the speed of the block, speed is maximum at equilibrium point (V = velocity or speed)
∴Vmax = mass of the block/angular speed
= 0.27/3.369
Vmax = 0.08m/s
6) What is the magnitude of the acceleration of the block as it passes through equilibrium?
The object is not accelerating, the object is at a particular position
Fnet = 0
In other words, at equilibrium acceleration is zero. magnitude of acceleration is zero.
7)Where is the block located, relative to equilibrium, at a time 1.06 s after it is released?
x(t) = Acos(ωt + φ)
x(t) = 0.27cos(3.369t + φ)
-0.27 = 0.27cos(3.369(0) + φ)
-1 = cosφ
φ = π
To calculate where the block is located
x(t) = Acos(ωt + φ)
x(t) = 0.27cos(3.369t + π)
x(1.06) = 0.27cos(3.369*1.06 +π)
x(0.08) = 0.245m (right)
