A mass \(m\) attached to free end of a spring executes SHM with a period of \(1 \,s\) If the mass is increased by \(3\, kg\) the period of oscillation increases by one second, the value of mass \(m\) is ______\(kg.\)
Show Hint
The time period of SHM depends on mass and spring constant: \(T=2\pi\sqrt{\frac{m}{k}}\). For mass changes, compare squared ratios of T.
Correct Answer: 1
Approach Solution - 1
The time period of SHM is given by:
\[T=2\pi\sqrt{\frac{m}{k}}\]
Initially, \(T=1\) s:
\[1=2\pi\sqrt{\frac{m}{k}}\]
Squaring both sides:
\[\frac{m}{k}=\frac{1}{4\pi^{2}}\] ……………(1)
After increasing the mass by 3 kg, the period becomes 2 s:
\[2=2\pi\sqrt{\frac{m+3}{k}}\]
Squaring both sides:
\[\frac{m+3}{k}=\frac{4}{4\pi^{2}}=\frac{1}{\pi^{2}}\] ………………(2)
Dividing equation (2) by equation (1):
\[\frac{m+3}{m}=4\]
Simplify:
\[m+3=4m\]
\[3m=3 \Rightarrow m=1 \text{ kg}\]
Thus, the value of m is 1 kg.
Approach Solution -2
The correct answer is 1.
T=2πkm=1
T′=2πkm+3=2
T′T=m+3m=21
⇒m+3m=41
m=1
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Concepts Used:
Mechanical Properties of Solids
Mechanical properties of solids intricate the characteristics such as the resistance to deformation and their strength. Strength is the ability of an object to resist the applied stress, to what extent can it bear the stress.
Therefore, some of the mechanical properties of solids involve:
- Elasticity: When an object is stretched, it changes its shape and when we leave, it retrieves its shape. Or we can say it is the property of retrieving the original shape once the external force is removed. For example Spring
- Plasticity: When an object changes its shape and never attains its original shape even when an external force is removed. It is the permanent deformation property. For example Plastic materials.
- Ductility: When an object is been pulled in thin sheets, wires or plates, it will be assumed that it has ductile properties. It is the property of drawing into thin wires/sheets/plates. For example Gold or Silver
- Strength: The ability to hold out applied stress without failure. Many types of objects have higher strength than others.