An ideal gas heat engine operators in a carnot's cycle between `227^(@)C` and `127^(@)C`. It absorbs `6xx10^(4)J` at high temperature. The amount of heat converted into work is …………… .

An ideal gas heat engine is operating between 227°C and 127°C. It absorbs 10^4 J of heat at the higher temperature. The amount of heat converted into work is ______ J .

A carnot engine operates between 227^@C and 127^@C . If it absorbs 60 xx 10^4 calorie at higher temperature, how much work per cycle can the engine perform?

The efficiency of a heat engine working between 27^(@)C and 127^(@)C is:

A carnot engine operates with source at 127^(@)C and sink at 27^(@)C . If the source supplies 40 KJ of heat energy, the work done by the engine is

An engine operating between 127^@C and 47^@C takes some specified amount of heat from a high temperature reservoir. Assuming that there are no frictional losses, calculate the percentage efficiency of an engine.

A sample of an ideal gas is taken through the cyclic process abca . It absorbs 50 J of heat during the part ab, no heat during bc and rejects 70 J of heat during ca. 40 J of work is done on the gas during the part bc.(a) find the internal energy of the gas at b and c if it is 1500 J at a. (b) calculate the work done by the gas during the part ca.

A heat engine operates between a cold reservoir at tempreture T_(2)=300 K and a hot reservior at tempreture T_(1) . It takes 200 J of heat from the hot reservior and delivers 120 J of heat to the cold reservior in a cycle. What could be the minimum tempreture of the hot reservior ?