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In the figure shown co-efficient of fric...

In the figure shown co-efficient of friction between the block B and C is 0.4. There is no friction between the block C and hte surface on which it is placed. The system of blocks is released from rest in the shown situation. Find the distance moved by the block C when block A descends through a distance 2m. Given masses of the blocks are `m_(A)=3 kg, m_(B)=5 kg and m_(C)=10 kg`.

Text Solution

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Let there is no relative motion between the blocks B and C
Hence
`T=(m_(B)+m_(C))a" " ...(1)`
And `m_(A)g-T=m_(A)a " "...(2)`
From (1) and (2), we get
`a=(m_(A)g)/(m_(A)+m_(B)+m_(C))=(30)/(18)=(5)/(3)m//s^(2)`
`rArr` Net force on the block C is, `F=m_(c)a=10xx(5//3)N=16.6N`
If maximum value of frictional force acting on block C is`f_("max")`, then
`f_(("max"))=mu m_(B)g=0.4xx5xx10=20N " " because F le f_("max")`
Hence there is no relative between the block B and C. Therefore distance moved by C is 2m only.
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