Pulley system on a double inclined plane: Difference between revisions

Revision as of 18:13, 18 September 2010

This article discusses a scenario/arrangement whose statics/dynamics/kinematics can be understood using the ideas of classical mechanics.
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This article is about the following scenario. A fixed triangular wedge has two inclines $I_{1}$ and $I_{2}$ making angles $\alpha _{1}$ and $\alpha _{2}$ with the horizontal. A pulley is affixed to the top vertex of the triangle. A string through the pulley has attached at its two ends blocks of masses $m_{1}$ and $m_{2}$ , resting on the two inclines $I_{1}$ and $I_{2}$ respectively. The string is inextensible. The coefficients of static and kinetic friction between $m_{1}$ and $I_{1}$ are $\mu _{s1}$ and $\mu _{k1}$ respectively. The coefficients of static and kinetic friction between $m_{2}$ and $I_{2}$ are $\mu _{s2}$ and $\mu _{k2}$ respectively. Assume that $\mu _{k1}\leq \mu _{s1}$ and $\mu _{k2}\leq \mu _{s2}$ .

Summary of cases starting from rest

Case	What happens qualitatively	Magnitude of accelerations
$\!m_{1}\sin \alpha _{1}-m_{2}\sin \alpha _{2}>\mu _{s1}m_{1}\cos \alpha _{1}+\mu _{s2}m_{2}\cos \alpha _{2}$	$m_{1}$ slides downward and $m_{2}$ slides upward, with the same magnitude of acceleration	$\!a=g(m_{1}\sin \alpha _{1}-m_{2}\sin \alpha _{2}-\mu _{k1}m_{1}\sin \alpha _{1}-\mu _{k2}m_{2}\sin \alpha _{2})/(m_{1}+m_{2})$ .
$\!m_{2}\sin \alpha _{2}-m_{1}\sin \alpha _{1}>\mu _{s1}m_{1}\cos \alpha _{1}+\mu _{s2}m_{2}\cos \alpha _{2}$	$m_{2}$ slides downward and $m_{1}$ slides upward, with the same magnitude of acceleration	$\!a=g(m_{2}\sin \alpha _{2}-m_{1}\sin \alpha _{1}-\mu _{k1}m_{1}\sin \alpha _{1}-\mu _{k2}m_{2}\sin \alpha _{2})/(m_{1}+m_{2})$ .
$\!\|m_{1}\sin \alpha _{1}-m_{2}\sin \alpha _{2}\|\leq \|\mu _{s1}m_{1}\cos \alpha _{1}+\mu _{s2}m_{2}\cos \alpha _{2}\|$	The system remains at rest	$0$

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 ! Case !! What happens qualitatively !! Magnitude of accelerations
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-| <math>\! m_1\sin \alpha_1 - m_2\sin \alpha_2 > \mu_{s1}m_1\cos \alpha_1 + \mu_{s2}m_2\cos \alpha_2</math> || <math>m_1</math> slides downward and <math>m_2</math> slides upward, with the same magnitude of acceleration || <math>\! a = g[m_1 \sin \alpha_1 - m_2 \sin \alpha_2 - \mu_{k1}m_1\sin \alpha_1 - \mu_{k2}m_2 \sin\alpha_2]</math>.
+| <math>\! m_1\sin \alpha_1 - m_2\sin \alpha_2 > \mu_{s1}m_1\cos \alpha_1 + \mu_{s2}m_2\cos \alpha_2</math> || <math>m_1</math> slides downward and <math>m_2</math> slides upward, with the same magnitude of acceleration || <math>\! a = g(m_1 \sin \alpha_1 - m_2 \sin \alpha_2 - \mu_{k1}m_1\sin \alpha_1 - \mu_{k2}m_2 \sin\alpha_2)/(m_1 + m_2)</math>.
 |-
-| <math>\! m_2\sin \alpha_2 - m_1\sin \alpha_1 > \mu_{s1}m_1\cos \alpha_1 + \mu_{s2}m_2\cos \alpha_2</math> || <math>m_2</math> slides downward and <math>m_1</math> slides upward, with the same magnitude of acceleration || <math>\! a = g[m_2 \sin \alpha_2 - m_1 \sin \alpha_1 - \mu_{k1}m_1\sin \alpha_1 - \mu_{k2}m_2 \sin\alpha_2]</math>.
+| <math>\! m_2\sin \alpha_2 - m_1\sin \alpha_1 > \mu_{s1}m_1\cos \alpha_1 + \mu_{s2}m_2\cos \alpha_2</math> || <math>m_2</math> slides downward and <math>m_1</math> slides upward, with the same magnitude of acceleration || <math>\! a = g(m_2 \sin \alpha_2 - m_1 \sin \alpha_1 - \mu_{k1}m_1\sin \alpha_1 - \mu_{k2}m_2 \sin\alpha_2)/(m_1 + m_2)</math>.
 |-
 | <math>\! |m_1 \sin \alpha_1 - m_2 \sin \alpha_2| \le |\mu_{s1}m_1 \cos \alpha_1 + \mu_{s2}m_2 \cos \alpha_2|</math> || The system remains at rest || <math>0</math>
 |}