Answer:
the damping coefficient when the system is critically damped is 13.42 lb s/ft.
Explanation:
The directions are missing the last part, which is:
"A mass weighing 30 lb stretches a spring 7.5 in. The mass is also attached to a damper with coefficient γ. Determine the value of γ for which the system is critically damped. Assume that [tex]g = 32 \cfrac {ft}{s^2}[/tex]
Round your answer to three decimal places."
The spring system is determined by the following differential equation
[tex]my''+\gamma y'+ky=0[/tex]
where [tex]\gamma[/tex] is the damping coefficient, thus it is critically damped when the system transitions from real to complex solutions that happens at
[tex]\gamma_^2 -4km=0[/tex]
Solving for the damping coefficient.
[tex]\gamma^2 = 4km\\ \gamma = \sqrt{4km}[/tex]
where the spring constant k is given by
[tex]k = \cfrac{mg}{L}\\k = \cfrac wL\\[/tex]
And the mass is given by
[tex]mg = w\\ m = \cfrac wg[/tex]
So the damping coefficient will be
[tex]\gamma = \sqrt{4\cfrac wL \cfrac wg}\\\gamma = \sqrt{4\cfrac {w^2}{gL}}[/tex]
Replacing the given information we have:
[tex]\gamma = \sqrt{4\cfrac {(30\, lbs)^2}{32\cfrac{ft}{s^2}0.625 ft}[/tex]
Thus we get
[tex]\gamma = 13.42 \cfrac{lb \cdot s}{ft}[/tex]
The value of the damping coefficient when the system is critically damped is 13.42 lb s/ft.
