194 MECHANICAL ENGINEERING PRINCIPLES3.4 m. Determine the earliest time of day
that the yacht is refloated.
[11h,11min,52s]- A mass of 2 kg is attached to a vertical
spring. The initial state displacement of
this mass is 74 mm. The mass is displaced
downwards and then released. Determine
(a) the stiffness of the spring, and (b) the
frequency of oscillation of the mass.
[(a) 265.1 N/m (b) 1.83 Hz]- A particle of mass 4 kg rests on a smooth
horizontal surface and is attached to a hor-
izontal spring. The mass is then displaced
horizontally outwards from the spring a
distance of 26 mm and then released to
vibrate. If the periodic time is 0.75 s,
determine (a) the frequency f,(b)the
force required to give the mass the dis-
placement of 26 mm, (c) the time taken
to move horizontally inwards for the first
12 mm.
[(a) 1.33 Hz (b) 7.30 N (c) 0.12 s] - A mass of 3 kg rests on a smooth hori-
zontal surface, as shown in Figure 17.5.
If the stiffness of each spring is 1 kN/m,
determine the frequency of vibration of
the mass. It may be assumed that initially,
the springs are un-stretched. [4.11 Hz]
Figure 17.5- A helical spring, which has a mass of
10 kg attached to its top. If the mass
vibrates vertically with a frequency of
1.5 Hz, determine the stiffness of the
spring. [94.25 N/m]
17.4 The simple pendulum
A simple pendulum consists of a particle of mass m
attached to a mass-less string of length L, as shown
in Figure 17.6.
xLmgPqPFigure 17.6From Section 13.4, page 148,T=Ioα=−restoring couple=−mg(Lsinθ)But, Io=mL^2hence,mL^2 α+mgLsinθ= 0For small deflections, sinθ=θHence, L^2 α+gLθ= 0or α+gθ
L= 0But α+ω^2 θ=0 (see Section 17.6)Therefore, ω^2 =g
Land ω=√
g
L( 17. 12 )Now T=2 π
ω= 2 π√
L
g( 17. 13 )and f=1
T=√
g
L
2 π( 17. 14 )Problem 2. If the simple pendulum of
Figure 17.6 were of length 2 m, determine its
frequency of vibration. Takeg= 9 .81 m/s^2.