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 Aluminium rods and a steel rod of equal cross-sectional area and equal length l_(0) are joined rigidly side by side as shown in figure. Initially the rods are at 0^(@)C . Find the length of the rod at the temperature theta if young's modulus of elasticity of the aluminium and steel are Y_(a) and Y_(s) respectively and coefficient of linear expansion of aluminum and steel are alpha_(a) and alpha_(s) respectively. |{:("Aluminium"),("Steel"),("Aluminium"):}|

Two same length rods of brass and steel of equal cross-sectional area are joined end to end as shown in figure and supported between two rigid vertical walls. Initially the rods are unstrained. If the temperature of system is raised by Deltat . Find the displacement of the junction of two rods. Given that the coefficient of linear expansion and young's modulus of brass and steel are apha_(b).alpha_(s)(alpha_(b)gtalpha_(s)),Y_(b) and Y_(s) respectively.

A thin rod, length L_(0) at 0^(@)C and coefficient of linear expansion alpha has its two ends mintained at temperatures theta_(1) and theta_(2) respectively Find its new length .

What should be the sum of lengths of an aluminium and steel rod at 0^(@)C is, so that all the temperature their difference in length is 0.25m . (Take coefficient of linear expansion for aluminium and steel at 0^(@)C as 22 xx 10^(-6)//.^(@)C and 11 xx 10^(-5)//.^(@)C respectively.)

Two rods are connected as shown. The rods are of same length and same cross sectional area. In steady state, the temperature (theta) of the interface will be -

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)

A steel rod of length L_0 . has a cross sectional area A. The force required to stretch this rod by the same amount as the expansion produced by heating it through DeltaT is (coefficient of linear expansion of steel is alpha and young's modulus for steel is Y ).

The length of two metallic rods at temperatures theta are L_(A) and L_(B) and their linear coefficient of expansion are alpha_(A) and alpha_(B) respectively. If the difference in their lengths is to remian constant at any temperature then

Two rods of equal cross sections area are joined end the end as shown in figure. These are supported between two rigid vertical walls. Initially the rods are unstrained . If temperature of system is increased by DeltaT then shifting in junction if junction if Y_(1)alpha_(1) gt Y_(2)alpha_(2) is given by -

A steel wire AB of length 85cm at 10^(@)C is fixed rigidly at points A and B in an aluminium frame as shown. If the temperature of the system is raised to 110^(@)C , what extra stress will be produced in the wire relative to aluminium frame. Assume that coefficient of linear expansion for aluminium and steel are 23xx10^(-6)//^(@)C and 11xx10^(-6)//^(@)C respectively and Young's moduls for steel is 2xx10^(11) pa.