A rod of length `L` with sides fully insulated is made of a material whose thermal conductivity `K` varies with temperature as `K=(alpha)/(T)` where `alpha` is constant. The ends of rod are at temperature `T_(1)` and `T_(2)(T_(2)gtT_(1))` Find the rate of heat flow per unit area of rod .

The coefficient of linear expansion 'alpha ' of the material of a rod of length l_(0) varies with absolute temperature as alpha = aT -bT^(2) where a & b are constant. The linear expansion of the rod when heated from T_(1) to T_(2) = 2T_(1) is :-

Radius of a conductor increases uniformly from left end to right end as shown in fig. Material of the conductor is isotropic and its curved surface is thermally isolated from surrounding. Its ends are maintained at temperatures T_(1) and T_(2) ( T_(1) gt T_(2)) : If, in steady state, heat flow rate is equal to H , then which of the following graphs is correct

The temperature of the two outer surfaces of a composite slab, consisting of two materials having coefficients of thermal conductivity K and 2K and thickness x and 4x respectively. Temperatures on the opposite faces of composite slab are T_(1) and T_(2) where T_(2)gtT_(1) , as shown in fig. what is the rate of flow of heat through the slab in a steady state?

The two ends of a metal rod are maintained at temperatures 100^(@)C and 110^(@)C . The rate of heat flow in the rod is found to be 4.0" Js"^(-1) . If the ends are maintained at temperatures 200^(@)C and 210^(@)C , the rate of heat flow will be :

n moles of an ideal triatomic linear gas undergoes a process in which the temperature changes with volume as T=K_(1)V^(2) where K_(1) is a constant. Choose incorrect alternative.

n moles of an ideal triatomic linear gas undergoes a process in which the temperature changes with volume as T=K_(1)V^(2) where K_(1) is a constant. Choose incorrect alternative.

The temperature of the two outer surfaces of a composite slab, consisting of two materials having coefficients of thermal conductivity K and 2K and thicknesses x and 4x, respectively are T_(2) and T_(1)(T_(2)gtT_(1)) . The rate of heat of heat transfer through the slab, in ? steady state is [(A(T_(2)-T_(1))/(x)]f , with f equal to :-

n moles of an ideal triatomic linear gas undergoes a process in which the temperature changes with volume as 'T'= K_(1) V^(2) where k_(1) is a constant. Choose incorrect alternative.

In above diagram, a combined rod is formed by connecting two rods of length l_(1) and l_(2) respectively and thermal conductivity k_(1) and k_(2) respectively. Temperature of ends of rods are T_(1) and T_(2) constant, then find the temperature of their contact surface ?

One end of rod of length L and cross-sectional area A is kept in a furance of temperature T_(1) . The other end of the rod is kept at at temperature T_(2) . The thermal conductivity of the material of the rod is K and emissivity of the rod is e . It is given that T_(2)=T_(S)+DeltaT where DeltaT lt lt T_(S) , T_(S) being the temperature of the surroundings. If DeltaT prop (T_(1)-T_(S)) , find the proportionality constant. Consider that heat is lost only by radiation at the end where the temperature of the rod is T_(2) .