Solve for i, ii, iii A simple Rankine cycle is implemented in a steam power plant. The working fluid used iswater. Water enters the pump at 25 kPa whereas the superheated steam enters the turbine at8MPa. The highest temperature in the Rankine cycle is recorded at 600 °C. Taking theisentropic efficiency of the pump to be at 80% and the isentropic efficiency of the turbine to be88%, determine the following information if the pump is constantly delivering water at a rateof 5 kg/s.1)The quality of vapor exiting the turbine11)111)iv)v)vi)Actual power required to operate the pumpActual power generated by the turbineThe rate of which heat is added in the boilerThe thermal efficiencyConstruct the diagram of Rankine cycle with reheating function on a T-s diagramwith respect to saturation lines. Refer to Figure 2 for additional information.WpumpisPumpBoilerTurbineCondenserWuboutTestFigure 2 A schematic representation of an Simple Rankine Cycle

Given:Pressure at pump inlet, P3=25KPaPressure at turbine inlet, P1=8MPaTemperature at turbine…

A simple Rankine cycle is implemented in a steam power plant. The working fluid used is water. Water enters the pump at 25 kPa whereas the superheated steam enters the turbine at SMPa. The highest temperature in the Rankine cycle is recorded at 600 °C. Taking the isentropic efficiency of the pump to be at 80% and the isentropic efficiency of the turbine to be 88%, determine the following information if the pump is constantly delivering water at a rate of 5 kg/s. 1) ii) 111) The quality of vapor exiting the turbine Actual power required to operate the pump Actual power generated by the turbine

A simple Rankine cycle is implemented in a steam power plant. The working fluid used is water. Water enters the pump at 25 kPa whereas the superheated steam enters the turbine at SMPa. The highest temperature in the Rankine cycle is recorded at 600 °C. Taking the isentropic efficiency of the pump to be at 80% and the isentropic efficiency of the turbine to be 88%, determine the following information if the pump is constantly delivering water at a rate of 5 kg/s. 1) ii) 111) The quality of vapor exiting the turbine Actual power required to operate the pump Actual power generated by the turbine

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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