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` .

Two metal cubes with 3 cm-edges of copper and aluminium are arranged as shown in figure. (K_(CU) = 385 W//m-K, K_(AL) = 209 W//m-K) The total thermal current from one reservoir to the other is :

Two metal cubes with 3 cm edges of copper and aluminium are arranged as shown. Thermal conductivities of copper and aluminium are 401 W/m-K and 237 W/m-K.

The ends of a copper rod of length 1m and area of cross-section 1cm^2 are maintained at 0^@C and 100^@C . At the centre of the rod there is a source of heat of power 25 W. Calculate the temperature gradient in the two halves of the rod in steady state. Thermal conductivity of copper is 400 Wm^-1 K^-1 .

Three metal rods made of copper, aluminium and brass, each 20 cm long 4cm in diameter, are placed end to end with aluminium between the other two. The free ends of copper and brass are maintained at 100 and 0^(@)C respectively. Assume that the thermal conductivity of copper is twice that of aluminium and four times that of brass. The approximately equilibrium temperatures of the copper-aluminiu and aluminium-brass junctions are respectively.

The ends of copper rod of length 1m and area of cross section 1cm^(2) are maintained at 0^(@)C and 100^(@)C . At the centre of rod, there is a source of heat of 32W . The thermal conductivity of copper is 400W//mK

A uniform copper rod 50 cm long is insulated on the sides, and has its ends exposed to ice and steam, respectively. If there is a layer of water 1 mm thick at each end, calculate the temperature gradient in the bar. The thermal conductivity of copper is 436 W m^(-1) K^(-1) and that of water is 0.436 Wm^(-1) K^(-1) .

A copper rod 2 m long has a circular cross-section of radius 1 cm. One end is kept at 100^@C and the other at 0^@C . The surface is insulated so that negligible heat is lost through the surface. In steady state, find (a) the thermal resistance of the bar (b) the thermal current H (c) the temperature gradient (dT)/(dx) and (d) the temperature at a distance 25 cm from the hot end. Thermal conductivity of copper is 401 W//m-K.

Two identical solid bodies one of aluminium and other of copper are heated to the same temperature and are put in same surrounding. If the emissivity of the aluminium body is 4 times that of copper body, find the ratio of the thermal power radiated by the two bodies. If specific heat of aluminum is 900//kg^(@)C and that of copper is 390 J//kg^(@)C and density of copper is 3.4 times that of aluminum, find the ratio of rate of cooling of the two spheres.

Find the thermal resistance of an aluminium rod of length 20cm and area of cross section 1cm^(2) . The heat current is along the length of the rod. Thermal conductivity of aluminium =200Wm^(-1)K^(-1) .

Two metal cubes A and B of same size are arranged as shown in Figure. The extreme ends of the combination are maintened at the indicated temperatures. The arrangement is thermally insulted. The coefficients of thermal conductivity of A and B are 300W//m ^@C and 200 W//m^@C, respectively. After steady state is reached the temperature t of the interface will be ......