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 thermal stress developed in first rod-

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 junction will not shift if -

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 rod of length / and radius r is held between two rigid walls so that it is not allowed to expand. If its temperature is increased, then the force developed in it is proportional to

Two rods of similar area of cross section and length are joined as shown in the figure. The ratio of their thermal conductivity is 2:3. The free ends are maintained at 100^(@)C and 0^(@)C respectivley. THE temperature at junction in steady state is

A uniform cylindrical rod of length L and cross-sectional area by forces as shown in figure. The elongation produced in the rod is

A metal rod has length L, radius of its cross-section r. Youngs modulus Y and thermal coefficient of linear expansion is α.It is clamped between two rigid supports with negligible tension. If its temperature is increased by T^@C , then force exerted by the rod on any of the supports is

Two rods of different materials having coefficient of thermal expansion alpha_1 and alpha_2 and Young's modulus Y_1 and Y_2 respectively are fixed between two rigid supports separately. The rods are heated such that they undergo same temperature increment. If thermal stress developed in two rods are equal, then Y_1 : Y_2 is

Two similar rods are joined as shown in figure. Then temperature of junction is (assume no heat loss through lateral surface of rod and temperatures at the ends are shown in steady state )

Two ends of a rod of uniform cross sectional area are kept at temperature 3T_(0) and T_(0) as shown. Thermal conductivity of rod varies as k=alphaT , (where alpha is a constant and T is absolute temperature). In steady state, the temperature of the middle section of the rod is

A metal rod if fixed rigidly at two ends so as to prevent its thermal expension. If L, alpha , Y respectively denote the length of the rod , coefficient of linear thermal expension and Young's modulus of its material, then for an increase in temperature of the rod by Delta T, the longitudinal stress developed in the rod is