Rate of heat flow from P to Q,

$${{dQ} \over {dt}} = {{2KA(T - 10)} \over 1}$$

Rate of heat flow from Q to S,

$${{dQ} \over {dt}} = {{KA(4000 - T)} \over 1}$$

At steady state, state rate of heat flow is same

$$ \therefore $$ $${{2KA(T - 10)} \over 1} = KA(400 - T)$$

or $$2T - 20 = 400 - T$$ or $$3T = 420$$

$$ \therefore $$ $$T = 140^\circ $$



Temperature of junction is $$140^\circ $$C.

Temperature at a distance x from end P is $${T_x} = (130x + 10^\circ )$$

Change in length dx is suppose dy.

Then, $$dy = \alpha dx({T_x} - 10)$$

$$\int_0^{\Delta y} {dy} = \int_0^1 {\alpha dx(130x + 10 - 10)} $$

$$\Delta y = \left[ {{{\alpha {x^2}} \over 2} \times 130} \right]_0^1$$

$$\Delta y = 1.2 \times {10^{ - 5}} \times 65$$

$$\Delta y = 78.0 \times {10^{ - 5}}$$ m = 0.78 mm