Two rods of different materials are placed between massive walls as shown in figure. The cross section of the rods is A, their moduil of elastricity are `E_(1)` and `E_(2)` respectively. If rods are heated by t degrees, then (coefficients of liner expansion of material of rods are `alpha_(1)` and `alpha_(2)` respectively)

Two rods A and B of different materials are welded together as shown in figure. Their thermal conductivities are K_(1) and K_(2) . The thermal conductivity of the composite rod will be

If two rods of length L and 2L having coefficients of linear expansion alpha and 2alpha respectively are connected so that total length becomes 3L, the average coefficient of linear expansion of the composite rod equals

If two rods of length L and 2L having coefficients of linear expansion alpha and 2alpha respectively are connected so that total length becomes 3L, the average coefficient of linear expansion of the composite rod equals

Two steel rods and an aluminum rod of equal length l_0 and equal cross section are joined rigidly at their ends as shown in the figure below. All the rods are in a state of zero tension at 0^@C . Find the length of the system when the temperature is raised to theta . Coefficient of linear expansion of aluminum and steel are alpha_a and alpha_s respectively. Young's modulus of aluminum is Y_a and of steel is Y_s .

Two steel rods and an aluminium rod of equal length l_0 and equal cross- section are joined rigidly at their ends as shown in the figure below. All the rods are in a state of zero tension at 0^@ C . Find the length of the system when the temperature is raised to theta . Coefficient of linear expansion of aluminium and steel are alpha_(a) and alpha_(s) respectively. Young's modulus of aluminium is Y_(a) and of steel is Y_(s) .

Two rods of different metals having the same area of cross section A are placed between the two massive walls as shown is Fig. The first rod has a length l_1 , coefficient of linear expansion alpha_1 and Young's modulus Y_1 . The correcsponding quantities for second rod are l_2,alpha_2 and Y_2 . The temperature of both the rods is now raised by t^@C . i. Find the force with which the rods act on each other (at higher temperature) in terms of given quantities. ii. Also find the length of the rods at higher temperature.

Two rods of different metals having the same area of cross section A are placed between the two massive walls as shown is Fig. The first rod has a length l_1 , coefficient of linear expansion alpha_1 and Young's modulus Y_1 . The correcsponding quantities for second rod are l_2,alpha_2 and Y_2 . The temperature of both the rods is now raised by t^@C . i. Find the force with which the rods act on each other (at higher temperature) in terms of given quantities. ii. Also find the length of the rods at higher temperature.

Three rods of equal length of same material are joined to form an equilateral triangle ABC as shown in figure. Area of cross-section of rod AB is S, of rod BC is 2S and that of AC is S. Then match the following.

Two rods having length l_(1) and l_(2) , made of materials with the linear coefficient of expansion alpha_(1) and alpha_(2) were welded together. The equivalent coefficients of linear expansion for the obtained rod:-

The coefficient of linear expansion of an in homogeneous rod change linearly from alpha_(1) to alpha_(2) from one end to the other end of the rod. The effective coefficient of linear expansion of rod is