Chapter 26 : Helical Springs and Pendulums 545
∴Total deflection of cantilever at A,
22
1212
Wl W 11 l
W
kb k kb k
⎛⎞ ⎡⎤⎛⎞
δ= ⎜⎟+ = ⎢⎥⎜⎟+
⎝⎠ ⎢⎥⎣⎦⎝⎠
2
21
12
l
kk
b
W
kk
⎡⎤⎛⎞
⎢⎥⎜⎟+
= ⎢⎥⎝⎠
⎢⎥⎣⎦
and natural frequency of vibration of the system,
12
2
12
11
Hz
22
g gk k
n
l
Wk k
b
==
πδ π ⎡⎤⎛⎞
⎢⎥+⎜⎟
⎢⎥⎣⎦⎝⎠
Ans.
Example 26.15. A uniform thin rod as shown in Fig. 26.10 has a mass of 1 kg and carries
a concentrated mass of 2·5 kg at B. The rod is hinged at A, and is maintained in the horizontal
position by a spring of stiffness 1·8 kN/m at C.
Fig. 26.10.
Find the frequency of oscillation. Neglect the effect of the mass of the spring.
Solution. Given : Mass of rod = 1 kg ; Mass at B = 2·5 kg ; Length of rod AB = 300 + 300
= 600 mm = 0·6 m ; Stiffness of spring (s) = 1·8 kN/ m = 1800 N /m.
Let n = Frequency of oscillation.
θ = Small angular displacement of the rod, and
α = Angular acceleration of the rod AB.
We know that mass moment of inertia of the system about A,
IA = M.I. of 1 kg about A + M.I. of 2·5 kg about A
2
1(0·6) 2·5 (0·6) (^22) 1·02 kg-m
3
=+ =
Fig. 26.11.
If the rod AB is given a small angular displacement as shown in Fig. 26.11 and then released,
it will start oscillating about A with simple harmonic motion.