''Conduction stops once rod achieves thermal steady state.''

What is thermal steady state ?

Two rods, one of iron and another of aluminium of equal length and equal cross-sections are connected with each other. The free end of the iron rod is kept at 100" "^(@)C and the free end of aluminium rod is kept at 0" "^(@)C . If thermal conductivity of aluminium is four times that of iron, find the temperature of their contact surface in the thermal steady state.

Three large discs have same area. They are kept at equidistant in parallel. They can be considered as perfect black bodies and their thermal conductivity is very large. If temperature of first and third discs are 2T C and 3T C respectively then temperature of second disc in thermal steady state is . . . . .

The figure shows the cross-section of the outer wall of a house buit in a hill-resort to keep the house insulated from the freezing temperature of outside. The wall consists of teak wood of thickness L_(1) and brick of thickness (L_(2) = 5L_(1)) , sandwitching two layers of an unknown material with identical thermal conductivites and thickness. The thermal conductivity of teak wood is K_(1) and that of brick is (K_(2) = 5K) . Heat conducion through the wall has reached a steady state with the temperature of three surfaces being known. (T_(1) = 25^(@)C, T_(2) = 20^(@)C and T_(5) = - 20^(@)C) . Find the interface temperature T_(4) and T_(3) .

Constant temperature of ends are T_(1) and T_(2) (where T_(1)gtT_(2) ) for a conducting rod of 'L' length and cross-sectional area A. What would be the rate of heat transfer in thermal steady state ?

What is the temperature of the steel-copper junction is the steady state of the system shown in figure. Length of the steel rod = 15.0 cm, length of the copper rod = 10.0 cm, temperature of the furnace =300^(@)C , temperature of the other end =0^(@)C . The area of cross section of the steel rod is twice that of the copper rod. (Thermal conductivity of steel =50.2" Js"^(-1)m^(-1)K^(-1) , and copper =385" Js"^(-1)m^(-1)KJ^(-1) ).

What is the temperature of the steel - copper junction in the steady state of the system shown in Fig. Length of the steel rod = 15.0 cm, length of the copper rod = 10.0 cm, temperature of the furnace =400" "^(@)C , temperature of the other end =0" "^(@)C . The area of cross section of the steel rod is twice that of the copper rod. (Thermal conductivity of steel =50.2" J s"^(-1)m^(-1)K^(-1), and of copper =385" J s"^(-1)m-1" "K^(-1) ).