Thanks, so in this case, the pumping would require more power than the amount of power the condenser and boiler would save?SteamKing said:When the working fluid (water, or steam more precisely) exits the turbine, it is still in a gaseous state. The function of the condenser is to perform the phase change of the steam back into liquid water. Liquid water takes less power to pump back into the boiler than steam does.
Thanks for the reply!njardus said:What SteamKing said seems like a good answer, I'd just like to add one thing: Pumps like to work in either a fully liquid or fully gaseous regime. This is why the condenser completely condenses the working fluid. If the working fluid were to have some gaseous component to it, you run the risk of cavitation occurring in your pump, which will kill the pump rather quickly.
The Rankine cycle efficiency is a measure of the efficiency of a steam power plant, which is used to generate electricity. It is the ratio of the net work output to the heat input to the system, and is usually expressed as a percentage.
The Rankine cycle efficiency can be calculated using the formula: Efficiency = (Work output / Heat input) * 100%. Work output is the difference between the enthalpy of the steam at the turbine inlet and the enthalpy of the steam at the turbine outlet, while heat input is the energy added to the system through the boiler.
The Rankine cycle efficiency is affected by several factors, including the steam quality, turbine efficiency, condenser pressure, and boiler temperature. Higher steam quality and turbine efficiency, as well as lower condenser pressure and higher boiler temperature, can result in a higher Rankine cycle efficiency.
The ideal Rankine cycle efficiency is 100%, which means that all of the heat energy input to the system is converted into work output. However, in real-world systems, the Rankine cycle efficiency is usually lower due to various factors such as heat losses and mechanical inefficiencies.
The Rankine cycle efficiency can be improved by implementing various measures such as using higher quality steam, optimizing turbine design and operation, reducing condenser pressure, and increasing boiler temperature. Additionally, incorporating technologies such as superheating, reheating, and regenerative feedwater heating can also improve the Rankine cycle efficiency.