Two rods A and B of same cross-sectional area A and length l are connected in series between a source `(T_(1)=100^(@)C)` and a sink `(T_(2)-0^(@)C)` as shown in figure. The rod is laterally insulated.

The ratio of the thermal resistance of the rods is

Two rods A and B of same cross sectional are A and length l connected in series between a source (T_(1) =100^(@)C) and a sink (T_(2) =0^(@)C) as shown in The rod is laterally insulated The ratio of thermal resistance of the rod is .

Two rods A and B of same cross-sectional area A and length l are connected in series between a source (T_(1)=100^(@)C) and a sink (T_(2)-0^(@)C) as shown in figure. The rod is laterally insulated. If T_(A) and T_(B) are the temperature drops across the rod A and B, then

Two rods A and B of same cross-sectional area A and length l are connected in series between a source (T_(1)=100^(@)C) and a sink (T_(2)-0^(@)C) as shown in figure. The rod is laterally insulated. If G_(A) and G_(B) are the temperature gradients across the rod A and B, then

Two rods A and B of same cross sectional are A and length l connected in series between a source (T_(1) =100^(@)C) and a sink (T_(2) =0^(@)C) as shown in The rod is laterally insulated If A_(A) and T_(B) are the temperature drops across temperature gradients the rod A and B then .

Two rods A and B of same length and cross-sectional area are connected in series and a temperature difference of 100^@C is maintained across the combination as shoen in Fig. If the thermal conductivity of the rod A is 3 k and that of rod B is k, Then i.Determine the thermal resistance of each rod. ii. determine the heat current flowing through each rod. iii. determine the heat current flowing through each rod. iv. plot the variation of temperature along the length of the rod.

Two cylindrical rods of same cross-section area and same length are connected in series to an ideal cell as shown.The resistivity of left rod is rho and that if right rod is 2 rho Then the variation of potential and electric field at any point P distant x from left end of combined rod system are given by

Three rods of the same length and the same area of the cross-section are joined. The temperature of two ends one T_(1) and T_(2) as shown in the figure. As we move along the rod the variation of temperature are as shown in the following [Rods are insulated from the surrounding except at the faces]

A metal rod of area of cross section A has length L and coefficient of thermal conductivity K the thermal resistance of the rod is .

Two ends of a rod of non uniform area of cross section are maintained at temperature T_(1) and T_(2) (T_(1)>T_(2)) as shown in the figure If l is heat current through the cross-section of conductor at distance x from its left face, then the variation of l with x is best represented by