Answer:
v=0.94 m/s
Explanation:
Given that
M= 5.67 kg
k= 150 N/m
m=1 kg
μ = 0.45
The maximum acceleration of upper block can be μ g.
a= μ g ( g = 10 m/s²)
The maximum acceleration of system will ω²X.
ω = natural frequency
X=maximum displacement
For top stop slipping
μ g =ω²X
We know for spring mass system natural frequency given as
[tex]\omega=\sqrt{\dfrac{k}{M+m}}[/tex]
By putting the values
[tex]\omega=\sqrt{\dfrac{150}{5.67+1}}[/tex]
ω = 4.47 rad/s
μ g =ω²X
By putting the values
0.45 x 10 = 4.47² X
X = 0.2 m
From energy conservation
[tex]\dfrac{1}{2}kX^2=\dfrac{1}{2}(m+M)v^2[/tex]
[tex]kX^2=(m+M)v^2[/tex]
150 x 0.2²=6.67 v²
v=0.94 m/s
This is the maximum speed of system.
Answer:
V = 0.9294 ms-1
Explanation:
The following data is provided in the question:
Mass of first block = m1 = 5.67 kg
Mass of 2nd block = m2 = 1 Kg
Spring constant = K = 150 N/m
Coefficient of static friction = µ = 0.450
The acceleration for 2nd block will be
a = µg = (0.450)(9.8)
a = 4.41 m/s^2 .…………. (1)
In simple harmonic motion the acceleration is given as:
a = (ω^2)X …………… (2)
where, ω is natural frequency and X is the displacement.
We know that:
ω =√(K/(m1+m2)) = (150/6.67)^0.5
ω = 4.74 rad/s …………… (3)
Put equation (1) and (3) in (2) and solving for X,
X = 0.196 m
As the equation for energy conversion is:
½ KX2 = ½ (m1 + m2)V^2 …………. (4)
By putting the values and solving for V,
V = 0.9294 ms-1
