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)`

One face of a copper cube of edge 10 cm is maintained at 100^(@)C and the opposite face is maintained at 0^(@)C . All other surfaces are covered with an insulating material. Find the amount of heat flowing per second through the cube. Thermal conductivety of copper is 385Wm^(-1) ^(@)C^(-1) .

One end of conducting rod is maintained at temperature 50^(@)C and at the other end ice is melting at 0^(@)C . The rate of melting of ice is doubled if:

One end of a metal rod of length 1.0 m and area of cross section 100 cm^(2) is maintained at . 100^(@)C . If the other end of the rod is maintained at 0^(@)C , the quantity of heat transmitted through the rod per minute is (Coefficient of thermal conductivity of material of rod = 100 W//m-K )

The ends of a metre stick are maintained at 100^(@)C and 0^(@)C . One end of a rod is maintained at 25^(@)C . Where should its other end be touched on the metre stick so that there is no heat current in the rod in steady state?

One end of a brass rod of length 2.0 m and cross section 1cm^2 is kept in stream at 100^@C and the other end in ice at 0^@C . The lateral suface of the rod is covered by heat insulator. Determine the amount of ice melting per minute. Thermal conductivity of brass is 110 W//m-K and specific latent heat of fusion of ice is 80 cal//g .

The ends of a metre stick are maintain at 100^(@)C and 0^(@)C . One end of a rod is mainntained 25^(@)C . Where should its other end be touched on the metre stick so that there is no heat current in the rod in steady state?

Two parallel plates A and B are joined together to form a compound plate . The thicknesses of the plate are 4.0cm and 2.5cm respectively and the area of cross section is 100cm^(2) for each plate. The thermal conductivities are K_(A)=200Wm^(-1) ^(@)C^(-1) for the palte B. The outer surface of the plate A is maintainned at 100^(@)C and the outer surface of the plate A is maintained at 100^(@)C . and the outer surface of the plate B is maintained at 0^(@)C. Find (a) the rate of heat flow through any cross section, (b) the temperature at the interface and (c) the equivalent thermal conductivity of the compound plate.

The lleft end of a copper rod (length=20cm. Area of cross section=0.02cm^(2) is maintained at 20^(@)C and the right end is maintained at 80^(@)C . Neglecting any lkkoss of heat through radiation, find (a) the temperature at a point 11cm from the left end and (b) the heat current through the rod. thermal conductivity of copper =385Wm=^(-1) ^(@)C^(-1) .

A compound rod is formed of a steel core of diameter 1cm and outer casing is of copper, whose outer diameter is 2cm . The length of this compound rod is 2m and one end is maintained as 100^(@)C and the end is at 0^(@)C . If the outer surface of the rod is thermally insulated, then heat current in the rod will be (Given thermal conductivity of steel j=12cal//m//k//s , thermal conductivity of copper =92cal//m//k//s

A rod AB is 1m long. The temperature of its one end A is maintained at 100^(@) C and other end B at 10^(@) C, the temperature at a distance of 60 cm from point B is