Answer:
1)[tex]k=11.319kN/m[/tex]
2)displacement[tex]=13.02cm[/tex]
3)[tex]k_{eq}=5.65kN/m[/tex]
Explanation:
At equilibrium position the weight of the man should be balanced by force in the spring
thus we have at equilibrium
[tex]kx=mg\\\\k=\frac{mg}{x}[/tex]
Applying values we get
[tex]k=\frac{75\times 9.81}{0.065}\\\\k=11.319kN/m[/tex]
2)
When we add another identical spring we get an equivalent spring with spring constant as
[tex]\frac{1}{k_{eq}}=\frac{1}{k_1}+\frac{1}{k_2}[/tex]
Applying values we get
[tex]\frac{1}{k_{eq}}=\frac{1}{11.319}+\frac{1}{11.319}\\\\k_{eq}=5.65kN/m[/tex]
Thus at equilibrium we have
[tex]x_{2}k_{eq}=mg\\\\x_{2}=\frac{mg}{k_{eq}}\\\\x_{2}=\frac{75\times 9.81}{5.65}\times 10^{-3}=13.02cm[/tex]
3) Equivalent spring constant will be as calculated earlier [tex]k_{eq}=5.65kN/m[/tex]
