A carnot engine operates between two reservoirs of temperature "900K" and "300K" .The engine performs "1200J" of work per cycle.The heat energy (in joules) delivered by the engine to the low temperature reservoir,in a cycle is

A carnot engine operates between two reservoirs of temperature 900K and 300K. The engine performs 1200 J of work per cycle. The heat energy delivered by the engine to the low temperature reservoir in a cycle is:

A cannot engine operates between two reservoirs of temperature T_(1) and T_(2) .The efficiency of engine is 25 %. The engine performs 100 J of work percycle. The heat energy (in J) delivered by the engine to the low temperature reservoir in a cycle is _______

Imagine a Carnot engine that operates between the temperatures T_H = 850 K and T_L = 300 K . The engine performs 1200 J of work cach cycle, which takes 0.25 s. (d) How much energy । Q_L। is delivered as heat to the low-temperature reservoir every cycle?

A Carnot engine operates between hot and cold reservoirs with temperatures 527^@ C and -73.0^@ C , respectively. If the engine performs 1000.0 J of work per cycle, how much heat is extracted per cycle from the hot reservoir?

An engine operates between temperatures 100K and 1000K. If the engine does 5000J of work per minute. How much heat is expelled by the engine?

A heat engine works between temperatures 300K and 600K .The efficiency of the engine can be ?

Imagine a Carnot engine that operates between the temperatures T_H = 850 K and T_L = 300 K . The engine performs 1200 J of work cach cycle, which takes 0.25 s. (c) How much energy । Q_H। is extracted as heat from the high-temperature reservoir every cycle?

A carnot engine operates between temperature 600 K and 300 K . It absorbs 100 J from the source. Calculate the heat transferred to the sink.

Imagine a Carnot engine that operates between the temperatures T_H = 850 K and T_L = 300 K . The engine performs 1200 J of work cach cycle, which takes 0.25 s. (a) What is the efficiency of this engine?

A heat engine operates between a cold reservoir at temperature T_(2)=400 K and a hot reservoir at temperature T . It takes 300 J of heat from the hot reservoir and delivers 240 J of heat to the cold reservoir in a cycle. The minimum temperature of the hot reservoir has to be _____________ K.