1) The period of a simple pendulum depends on B) III. only (the length of the pendulum)
2) The angular acceleration is C) [tex]15.7 rad/s^2[/tex]
3) The frequency of the oscillation is C) 1.6 Hz
4) The period of vibration is B) 0.6 s
5) The diameter of the nozzle is A) 5.0 mm
6) The force that must be applied is B) 266.7 N
Explanation:
1)
The period of a simple pendulum is given by
[tex]T=2\pi \sqrt{\frac{L}{g}}[/tex]
where
T is the period
L is the length of the pendulum
g is the acceleration of gravity
From the equation, we see that the period of the pendulum depends only on its length and on the acceleration of gravity, while there is no dependence on the mass of the pendulum or on the amplitude of oscillation. Therefore, the correct option is
B) III. only (the length of the pendulum)
2)
The angular acceleration of the rotating disc is given by the equation
[tex]\alpha = \frac{\omega_f - \omega_i}{t}[/tex]
where
[tex]\omega_f[/tex] is the final angular velocity
[tex]\omega_i[/tex] is the initial angular velocity
t is the time elapsed
For the compact disc in this problem we have:
[tex]\omega_i = 0[/tex] (since it starts from rest)
[tex]\omega_f = 300 rpm \cdot \frac{2\pi rad/rev}{60 s/min}=31.4 rad/s[/tex] is the final angular velocity
t = 2 s
Substituting, we find
[tex]\alpha = \frac{31.4-0}{2}=15.7 rad/s^2[/tex]
3)
For a simple harmonic oscillator, the acceleration and the displacement of the system are related by the equation
[tex]a=-\omega^2 x[/tex]
where
a is the acceleration
x is the displacement
[tex]\omega[/tex] is the angular frequency of the system
For the oscillator in this problem, we have the following relationship
[tex]a=-100 x[/tex]
which implies that
[tex]\omega^2 = 100[/tex]
And so
[tex]\omega = \sqrt{100}=10 rad/s[/tex]
Also, the angular frequency is related to the frequency [tex]f[/tex] by
[tex]f=\frac{\omega}{2\pi}[/tex]
Therefore, the frequency of this simple harmonic oscillator is
[tex]f=\frac{10}{2\pi}=1.6 Hz[/tex]
4)
When the mass is hanging on the sping, the weight of the mass is equal to the restoring force on the spring, so we can write
[tex]mg=kx[/tex]
where
m is the mass
[tex]g=9.8 m/s^2[/tex] is the acceleration of gravity
k is the spring constant
x = 8.0 cm = 0.08 m is the stretching of the spring
We can re-arrange the equation as
[tex]\frac{k}{m}=\frac{g}{x}=\frac{9.8}{0.08}=122.5[/tex]
The angular frequency of the spring is given by
[tex]\omega=\sqrt{\frac{k}{m}}=\sqrt{122.5}=11.1 Hz[/tex]
And therefore, its period is
[tex]T=\frac{2\pi}{\omega}=\frac{2\pi}{11.1}=0.6 s[/tex]
5)
According to the equation of continuity, the volume flow rate must remain constant, so we can write
[tex]A_1 v_1 = A_2 v_2[/tex]
where
[tex]A_1 = \pi r_1^2[/tex] is the cross-sectional area of the hose, with [tex]r_1 = 5 mm[/tex] being the radius of the hose
[tex]v_1 = 4 m/s[/tex] is the speed of the petrol in the hose
[tex]A_2 = \pi r_2^2[/tex] is the cross-sectional area of the nozzle, with [tex]r_2[/tex] being the radius of the nozzle
[tex]v_2 = 16 m/s[/tex] is the speed in the nozzle
Solving for [tex]r_2[/tex], we find the radius of the nozzle:
[tex]\pi r_1^2 v_1 = \pi r_2^2 v_2\\r_2 = r_1 \sqrt{\frac{v_1}{v_2}}=(5)\sqrt{\frac{4}{16}}=2.5 mm[/tex]
So, the diameter of the nozzle will be
[tex]d_2 = 2r_2 = 2(2.5)=5.0 mm[/tex]
6)
According to the Pascal principle, the pressure on the two pistons is the same, so we can write
[tex]\frac{F_1}{A_1}=\frac{F_2}{A_2}[/tex]
where
[tex]F_1[/tex] is the force that must be applied to the small piston
[tex]A_1 = \pi r_1^2[/tex] is the area of the first piston, with [tex]r_1= 2 cm[/tex] being its radius
[tex]F_2 = mg = (1500 kg)(9.8 m/s^2)=14700 N[/tex] is the force applied on the bigger piston (the weight of the car)
[tex]A_2 = \pi r_2^2[/tex] is the area of the bigger piston, with [tex]r_2= 15 cm[/tex] being its radius
Solving for [tex]F_1[/tex], we find
[tex]F_1 = \frac{F_2A_1}{A_2}=\frac{F_2 \pi r_1^2}{\pi r_2^2}=\frac{(14700)(2)^2}{(15)^2}=261 N[/tex]
So, the closest answer is B) 266.7 N.
Learn more about pressure:
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