A rod of length `l`, mass `M`, cross section area `A` is placed on a rough horizonatal surface. A horizonatal force `F` is applied to rod as shwon in figure. The coefficient of fricition between rod and surface is `mu`, the Young, modulus of material of rod is `Y`. [Assume that fricition force is distributed uniformly on rod] The elongation in the rod if `F lt mu Mg` isA. ZeroB. `[(F- (mu Mg)/(2))/(2AY)]l`C. `(Fl)/(2AY)`D. None

A rod of length `l`, mass `M`, cross section area `A` is placed on a r

1.	A rod of length `l`, mass `M`, cross section area `A` is placed on a rough horizonatal surface. A horizonatal force `F` is applied to rod as shwon in figure. The coefficient of fricition between rod and surface is `mu`, the Young, modulus of material of rod is `Y`. [Assume that fricition force is distributed uniformly on rod] The elongation in the rod if `F lt mu Mg` isA. ZeroB. `[(F- (mu Mg)/(2))/(2AY)]l`C. `(Fl)/(2AY)`D. None
Answer» Correct Answer - C Then, `F-T - f_(1) = 0 & T = f_(2)` where `f_(1) + f_(2) = f = F` As friction force is distributed uniformly, `f_(1) = (fx)/(l)` `rArr T = F - f_(1) = F (f xx x )/(l) = F [1 - (x)/(l)]` Let `Delta (dx)` be the elongation in `dx` lenghth of rod `Delta (dx)` be the elongation in `dx` lenghth of rod `Delta (dx) = (Tdx)/(Ay) = (F(1 - (x)/(l))dx)/(AY)` Total elongation, `Delta L = int Delta (dx) = int_(0)^(1) (F)/(AY) (1 - (x)/(l))dx = (Fl)/(2YA)`

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