The slider of mass m₁ = 0.4 kg moves along the smooth support surface with velocity v₁ = 5 m/s when in the position shown. After negotiating the curved portion, it moves onto the inclined face of an initially stationary block of mass m₂ = 2 kg. The coefficient of kinetic friction between the slider and the block is μk = 0.30. Determine the velocity v' (m/s) of the system after the slider has come to rest relative to the block. Neglect friction at the small wheels, and neglect any effects associated with the transition. -μk = 0.30 m2 20° U1 0.5 m smooth m1
The slider of mass m₁ = 0.4 kg moves along the smooth support surface with velocity v₁ = 5 m/s when in the position shown. After negotiating the curved portion, it moves onto the inclined face of an initially stationary block of mass m₂ = 2 kg. The coefficient of kinetic friction between the slider and the block is μk = 0.30. Determine the velocity v' (m/s) of the system after the slider has come to rest relative to the block. Neglect friction at the small wheels, and neglect any effects associated with the transition. -μk = 0.30 m2 20° U1 0.5 m smooth m1
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Transcribed Image Text:The slider of mass m₁ = 0.4 kg moves along the smooth support
surface with velocity v₁ = 5 m/s when in the position shown. After
negotiating the curved portion, it moves onto the inclined face of
an initially stationary block of mass m₂ = 2 kg. The coefficient of
kinetic friction between the slider and the block is μk = 0.30.
Determine the velocity v' (m/s) of the system after the slider has
come to rest relative to the block. Neglect friction at the small
wheels, and neglect any effects associated with the transition.
-μk = 0.30
m2
20°
U1
0.5 m
smooth
m1
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