An ideal heat engine operates on Carnot cycle between `227^@C and 127^@C`. It absorbs `6 xx 10^4` cal at the higher temperature. The amount of heat converted into work equals to

An ideal gas heat engine operates in Carnot cycle between 227^@C and 127^@C . It absorbs 6.0 xx 10^4 cal of heat at high temperature. Amount of heat converted to work is :

An ideal gas heat engine operates in a Carnot's cycle between 227^(@)C and 127^(@)C . It absorbs 6 xx 10^(4) J at high temperature. The amount of heat converted into work is

An ideal gas heat engine operates in a Carnot's cycle between 227^(@)C and 127^(@)C . It absorbs 6 xx 10^(4) J at high temperature. The amount of heat converted into work is

An ideal gas heat engine operates in a Carnot cycle between 27^(@)C and 127^(@)C . It absorbs 6 kcal at the higher temperature. The amount of heat (in kcal) converted into work is equal to

An ideal gas heat engine operates in a Carnot cycle between 227^(@)C and 127^(@)C . It absorbs 6K cal. of heat at higher temperature. The amount of heat in k cal ejected to sink is

A Carnot's engine works as refrigerator between 250 K and 300K. It receives 500 cal heat from the reservoir at the lower temperature. The amount of work done in each cycle to operate the refrigerator is :

A heat engine operating between 227^(@)C and 77^(@)C absorbs 10 kcal of heat from the 227^(@)C reservoir reversibly per cycle. Calculate total work done (in kcal) in two cycles.

If a carnot engine works between 127^(@)C and 527^(@)C then its efficiency is

If a Carnot engine works between 127^@C and 727^@C , then its efficiency is

An ideal Carnot's engine works between 227^(@)C and 57^(@)C . The efficiency of the engine will be