1. Consider the following schematic of a power plant (operating in what is called a'Rankine Cycle')TurbineSteamgeneratorCondenserColing waterEconomiaerThe power plant control room reports that the plant is operating continuously at the followingpeak load conditions:a. Power to pump = 300KWb. Rate of steam flow = 25 kg/sc. Cooling water temperature at condenser inlet = 13 Cd. Cooling water temperature at condenser outlet = 34 CAdditionally, the following measurements were made at various points in the piping connectingthe power plant componentsData Pressure Temp. Quality enthalpy Specific Velocity(kJ/kg)point (kPa)volume (m/s)(m3/kg)(C)(x)1620026100435900177----4.5700493-----55500482-----61030.9418379643----- Calculate the diameter of the pipe connecting the turbine to the condenser. Designdata for the plant shows the following pipe diametersCalculate cooling water flow rate in gpm ('gallons per minute') through the condenser ifthe temperature of the cooling water increases from 13 C to 24 C in the condenser.

Answered: Image /qna-images/answer/31db188d-bd4c-40f3-8966-239fb63497be.jpg

Calculate the diameter of the pipe connecting the turbine to the condenser. Design data for the plant shows the following pipe diameters Calculate cooling water flow rate in gpm (ʻgallons per minute') through the condenser if the temperature of the cooling water increases from 13 C to 24 C in the condenser.

Calculate the diameter of the pipe connecting the turbine to the condenser. Design data for the plant shows the following pipe diameters Calculate cooling water flow rate in gpm (ʻgallons per minute') through the condenser if the temperature of the cooling water increases from 13 C to 24 C in the condenser.

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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