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reckk
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Homework Statement
http://img515.imageshack.us/img515/2668/ohyxf6.jpg
The mass-spring-damper-system is consist of a rotating body (Jo), a flat spring (E, I), a damper (b) and a connecting rod. Only the mass of the rotating body is to be considered. It is assumed that there's only a small angular travels due to the oscillation/vibration.
Find the differential equation φ(t) for the oscillation/vibration of the rotating body.
Values given: Jo = 0.3 kg/m² ; b = 200 kg/s ; a = 25cm ; L = 20 cm
Homework Equations
[tex]F_{D} = [/tex] [tex]b . a . \dot{\varphi}[/tex]
[tex]F_{F} = [/tex] [tex]c .a . \varphi[/tex]
The Attempt at a Solution
i have came up with two approaches.. but i don't know which one is correct
Solution 1:
[tex]J_{o}\ddot{\varphi} = -F_{F} . a - F_{D} . a[/tex]
[tex]J_{o}\ddot{\varphi} + b . a^{2} . \dot{\varphi} + c . a^{2} . \varphi = 0[/tex]
[tex]\ddot{\varphi} + \frac{b . a^{2}}{J_{o}} . \dot{\varphi} + \frac{c . a^{2}}{J_{o}} . \varphi = 0[/tex]
[tex]with[/tex]
[tex] 2\delta = \frac{b . a^{2}}{J_{o}} ; \omega{o}^{2} = \frac{c . a^{2}}{J_{o}}[/tex]
Solution 2:
[tex]m . a . \ddot{\varphi} = -F_{F} - F_{D} [/tex]
[tex]m . a . \ddot{\varphi} + b . a \dot{\varphi} + c . a . \varphi = 0 [/tex]
[tex]\ddot {\varphi} + \frac{ba}{ma} \dot{\varphi} + \frac {ca}{ma}\varphi = 0[/tex]
[tex]with[/tex]
[tex] 2\delta = \frac{b}{m} ; \omega_{o}^{2} = \frac {c}{m} [/tex]
both would give different answers for calculating other unknowns.. so i wonder which one is correct ?
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