Consider the slabe shown in Figure. Suppose that L = 15.0 cm , A `= 105 cm^(2)`, and the material is copper. If `T_(H) = 125^(@)C, T_(C ) = 10.0^(@)C`, and a steady state is reached, find the conduction rate through the slabe.

Consider the situation shown in figure.The switch is closed at t=0 when the capacitor C_(1) as a function of time t .

Consider the circuit shown in the figure. Find the charge on capacitor C between A and D in steady state.

Figure shows ( in cross section ) a wall consisting of four layers, with thermal conductivities k_(1) = 0.060W//m.K, k_(3)= 0.040W//m.K , and k_(4) = 0.12W//m.K(k_(2) is not known). The layer thickness are L_(1) = 1.2 cm, L_(3) = 5.6 cm , and L_(4) = 4.0 cm ( L_(2) is not known ) . The known temperatures are T_(1) = 30^(@)C, T_(12) = 25^(@)C , and T_(4) = - 10^(@) C . Energy transfer through the wall is steady. What is interface temperature T_(34) ?

Three rods of equal length, area of cross section and thermal conductivity are connected as shown in the figure. There is no heat loss through lateral surface of the rods and temperature of ends are T_(A)=100^(@)C, T_(B)=70^(@)C and T_(C)=50^(@)C . Find the temperature of junction.

What is the temperature of the steel-copper junction in the steady state system show in Fig. 7(e).17 ? Length of steel rod = 15.0 cm, length of the copper rod = 10.0 cm, temperature of the furnace =300^(@)C , temperature of other end 0^(@)C . The are 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 of copper =3895 js^(-1) m^(-1) K^(-1) ).

In the circuit shown in figure. The charge on capacitor C_(2) in steady state is 10^(x) mu C . Find the value of x . .

What is the temperature of steel-copper jumction in the steady state of the system shown in fig. Length of the steel rod = 30.0 cm, length of the copper rod = 20.0 cm, temperature of the furnace = 300^(@)C , temperature of cold 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) .^(@)C^(-1) and of copper = 358 Js^(-1) m^(-1) .^(@)C^(-1) .

Six identical uniform conducting rods are fixed to make a regular hexagon as shown. The ends A and C are maintained at constant temperature 2T_(0) and 6 T_(0) . After the steady state is reached. Pick up the correct relation between temperatures T_(B),T_(B),T_(E) and T_(F) of ends B,D,E and F respectively.

Figure shows the cross section of a wall made of white pine of thickness L_(a) and brick of thickness L_(d) = = 2.0 L_(a) , sandwiching two layers of unknonw material with identical thicknesses and thermal conductivities. The thermal conductivity of the pine is k_(a) and that of the brick is k_(d) ( = 5.0k_(a)) . The face area A of the wall is unknown. Thermal conduction through the wall has reached the steady state, the only known interface temperatures are T_(1) = 25^(@)C, T_(2) = 20^(@)C , and T_(5 ) = - 10^(@)C . What is interface temperature T_(4) ?

Heat is flowing through a rod of length 25.0 cm having cross-sectional area 8.80 cm^(2) . The coefficient of thermal conductivity for the material of the rod is K = 9.2 xx 10^(-2) kcal s^(-1) m^(-1) .^(@)C^(-1) . The Temperatures of the ends of the rod are 125^(@)C and 0^(@)C in the steady state. Calculate (i) temeprature gradient in the rod (ii) temperature of a point at a distance of 10.0 cm from the hot end and (iii) rate of flow of heat.