Two metal cubes with 3 cm- edges of copper and aluminium are arranged as shown in figure. Find
(a)the total thermal current from one reservoir to the other
(b) the ratio of the thermal current carried by the copper cube to that carried by the aluminium cube. Thermal conductivity of copper is 401 `W//m.K` and that of aluminium id 237 `W//m.K` .

One face of an aluminium cube of edge 2 metre is maintained at 100^(@)C and the other end is maintained at 0^(@)C . All other surfaces are covered by adiabatic walls. Find the amount of heat flowing of heat thorugh the cube in 5 seconds. (thermal conductivity of aliminium is 209 W//m-.^(@)C)

What is the temperature of the aluminium junction in the steady state of the system shown in Fig. Length of the load =15.0 cm, length of the aluminium rod =10.0 cm temperature of the furnace = 400" "^(@)C , temperature of the other end =0" "^(@)C . The area of cross section of the lead rod is twice that of the aluminium rod. (Thermal conductivity of steel =34.9" J s"^(-1)m^(-1)K^(-1), and copper =205" J s"^(-1)m-1" "K^(-1) )

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) ).

A metallic rod of cross-sectional area 20 cm^(2) , with the lateral surface insulated to prevent heat loss, has one end immersed in boiling water and the other in ice water mixture. The heat conducted through the rod melts the ice at the rate of 1 gm for every 84 sec. The thermal conductivity of the rod is 160 Wm^(-1)K^(-1) . Latent heat of ice=80 cal/gm, 1 ca=4.2 joule. What is the length (in m) of the rod?

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) ).

An iron bar (L_(1)=0.1" m",A_(1)=0.02" m"^(2),K_(1)=97" Wm"^(-1)K^(-1)) and a brass bar (L_(2)=0.1" m",A_(2)=0.02" m"^(2),K_(2)=109" W m"^(-1)K^(-1)) are soldered end to end as shown in figure. The free ends of the iron bar and brass bar are maintained at 373 K and 273 K respectively. Obtain expressions for and hence compute (i) the temperature of the junction of the two bars, (ii) the equivalent thermal conductivity of the compound bar, and (iii) the heat current through the compound bar.

Two rectangular blocks, having identical dimensions, an be arranged either in configuration-I or in configuration-II as shown in the figure. One of the blocks has thermal conductivity k and the other 2k. The temperature difference between the ends along the x-axis is the same in both the configurations. It takes 9s to transport a certain amount of heat from the hot end to the cold end in the configuration-I. The time to transport the same amount of heat in the configuration-II is

An iron bar (L_(1) = 0.1 m , A_(1) = 0.02 m^(2), K_(1) = 79 W m^(-1) K^(-1)) and a brass bar (L_(2) = 0.1 m, A_(2) = 0.02 m^(2) , K_(2) = 109 W m^(-1) K^(-1)) are soldered end to end as shown in Fig. 11.16. The free ends of the iron bar and brass bar are maintained at 373 K and 273 K respectively. Obtain expressions for and hence compute (1) the temperature of the function of the two bars, (11) the equivalent thermal conductivity of the compound bar, and (111) the heat current through the compound bar.