What is the effect of increasing the distance to the moveable mass, 2, on the naturalfrequency of the system?) Increase in the natural frequencyDecrease the natural frequencyONo change in the natural frequencyThe natural frequency becomes a damped natural frequency 0.5m1mThe figure shows a slender rod with a mass of 6 kg. Attached to the rod is a spring ofstiffness k = 250 N /m .A moveable point mass m1= 1 kg is position at adistance x from the pivot point. You can assume small angle oscillations from theequilibrium position shown in the figure.

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\\\\ m, 0.5m 1m The figure shows a slender rod with a mass of 6 kg. Attached to the rod is a spring of stiffness k = 250 N /m .Amoveable point mass m1= 1 kg is position at a distance I from the pivot point. You can assume small angle oscillations from the equilibrium position shown in the figure.

\\\\ m, 0.5m 1m The figure shows a slender rod with a mass of 6 kg. Attached to the rod is a spring of stiffness k = 250 N /m .Amoveable point mass m1= 1 kg is position at a distance I from the pivot point. You can assume small angle oscillations from the equilibrium position shown in the figure.

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

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Concept explainers

Forced undamped vibrations

In mechanical engineering, vibration is expressed as the term that occurs due to an object's backward and forward movement about a point of equilibrium. Generally, there are three types of vibrations which are,

Question

What is the effect of increasing the distance to the moveable mass, 2, on the natural
frequency of the system?
) Increase in the natural frequency
Decrease the natural frequency
ONo change in the natural frequency
The natural frequency becomes a damped natural frequency

0.5m
1m
The figure shows a slender rod with a mass of 6 kg. Attached to the rod is a spring of
stiffness k = 250 N /m .A moveable point mass m1= 1 kg is position at a
distance x from the pivot point. You can assume small angle oscillations from the
equilibrium position shown in the figure.

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