If heat is absorbed at `T_(1)(k)` and rejected at `T_(2)(k)`. Then it can be shown that `eta` =`1 - (T_(2))/(T_(1))`. What is the most common value of `T_(2)`?

A heat engine absorbs heat Q_(1) at temperature T_(1) and Q_(2) at temperature T_(2) . Work done by the engine is (Q_(1)+Q_(1)) . This data:

Two Carnot engines are operated in succession. The first engine receives heat from a source at T=800K and rejects to sink at T_(2)K . The second engine receives heat rejected by the first engine and rejects to another sink at T_(3)= 300K . If work outputs of the two engines are equal, then find the value of T_(2) .

Two Carnot engines A and B are operated is succession. The first one A receives heat from a source at T_(1)=800K and rejects to a sink at T_(2)K . The second engine B receives hence rejected by the first engine and rejects the another sink at T_(3) =300K. If the efficiencies of two engines are equal, then the value of T_(2) is

The V - i graph for a conductor at temperature T_(1) and T_(2) are as shown in the figure. ( T_(2) - T_(1)) is proportional to

A large tank is filled with water to a height H . A small hole is made at the base of the tank. It takes T_(1) time to decrease the height of water to (H)/(eta) (eta gt 1) , and it takes T_(2) times to take out the rest of water. If T_(1) = T_(2) , then the value of eta is

The V-l graph for a conductor at temperatures T_(1) " and " T_(2) are as shown in the figure. The term T_(2) -T_(1) is proportional to