A rod of length l and cross-sectional ar...

A rod of length l and cross-sectional area A has a variable conductivity given by `K=alphaT`,where `alpha` is a positive constant and T is temperatures in Kelvin. Two ends of the rod are maintained at temperatures `T_(1)andT_(2)(T_(1)gtT_(2))`. Heat current flowing through the rod will be :

`T_(1)((T_(2))/(T_(1)))^(x/L)`

`(x)/(L)ln(T_(2))/(T_(1))`

`T_(1)e^(T_(2)x)/(T_(1)L)`

`T_(1) + (T_(2)-T_(1))/(L)x`

Text Solution

Verified by Experts

The correct Answer is:

`KA(-(dT)/(dx)) = overset(**)(Q) implies ((alpha)/(T)) A (-(dT)/(dx)) = overset(**)(Q)`
`implies - underset(T_(1))overset(T_(2))int (dT)/(T)= (overset(**)(Q))/(alphaA) underset(0)overset(2)int "dx" … (i)` &`underset(T_(1))overset(T)int (dT)/(T) = (overset(**)(Q))/(alphaA) underset(0)overset("x")int"dx" …(ii)`
`implies "ln"((T_(1))/(T_(2))) = ((overset(**)(Q))/(alphaA))L` and ln`((T_(1))/(T))= ((overset(**)(Q))/(alphaA))x`
`implies T = T_(1)((T_(2))/(T_(1)))^(x//L)`

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