Engineering, 28.07.2020 17:01 krystalScott17
A steam power plant design consists of an ideal Rankine cycle with regeneration. Steam enters Turbine 1 at P1 and T1 at the rate of m1 and exits at P2. A fraction (y') of the steam exiting Turbine 1 is diverted to a closed feedwater heater while the remainder enters Turbine 2. A portion (y'') of the steam exiting Turbine 2 at P3 is diverted to an open feedwater heater while the remainder enters Turbine 3. The exit of Turbine 3 is fed into a condenser that operates at P4. Saturared liquid exits the condenser and is fed to Pump 1. The outlet of Pump 1 is fed into the open feedwater heater. Saturated liquid exits the open feedwater heater and is fed to Pump 2. The outlet of pump 2 is fed to the closed feedwater heater. Saturated liquid exits the low pressure output of the closed feedwater heater and is fed through a steam trap to the open feedwater heater. Both exits of the closed feedwater heater are at the same temperature. All turbines and pumps are isentropic.
--Given Values--
m1 (kg/s) = 50
P1 (Bar) = 160
T1 (oC) = 640
P2 (Bar) = 10
T3 (C) = 600
P4 (Bar) = 1
P5 (Bar) = 0.06
a) Determine the specific enthalpy (kJ/kg) at the inlet of turbine 1.
Your Answer = Correct! Exact Answer= 3573.50 +/- 1.16E+00
b) Determine the specific enthalpy (kJ/kg) at the exit of turbine 1.
Your Answer =
c) Determine the specific enthalpy (kJ/kg) at the inlet of turbine 2 .
Your Answer =
d) Determine the specific enthalpy (kJ/kg) at the exit of turbine 2.
Your Answer =
e) Determine the specific enthalpy (kJ/kg) at the condenser exit.
Your Answer =
f) Determine the specific enthalpy (kJ/kg) at the exit of the low pressure pump.
Your Answer =
g) Determine the specific enthalpy (kJ/kg) at the exit of the feedwater heater.
Your Answer =
h) Determine the specific enthalpy (kJ/kg) at the exit of the high pressure pump.
Your Answer =
i) Determine the fraction (y') of flow diverted to the open feedwater heater.
Your Answer =
j) Determine the power (MW) produced by turbine 1.
Your Answer =
k) Determine the power (MW) produced by turbine 2.
Your Answer =
l) Determine the power (kW) required (a positive number) by the low pressure pump.
Your Answer =
m) Determine the power (kW) required (a positive number) by the high pressure pump.
Your Answer =
n) Determine the total rate of heat transfer (MW) supplied to the boiler.
Your Answer =
o) Determine the thermal efficiency (%) of the power plant.
Your Answer =
Answers: 1
Another question on Engineering
Engineering, 04.07.2019 18:10
Afull journal bearing has a journal diameter of 27 mm, with a unilateral tolerance of -0.028 mm. the bushing bore has a diameter of 27.028 mm and a unilateral tolerance of 0.04 mm. the l/d ratio is 0.5. the load is 1.3 kn and the journal runs at 1200 rev/min. if the average viscosity is 50 mpa-s, find the minimum film thickness, the power loss, and the side flow for the minimum clearance assembly.
Answers: 1
Engineering, 04.07.2019 18:10
Draw the engineering stress-strain curve for (a) bcc; (b) fcc metals and mark important points.
Answers: 1
Engineering, 04.07.2019 18:10
Which of the following refers to refers to how well the control system responds to sudden changes in the system. a)-transient regulation b)- distributed regulation c)-constant regulation d)-steady-state regulation
Answers: 1
Engineering, 04.07.2019 18:10
Calculate the bore of a cylinder that has a stroke of 18 inches and an extension time of 6 seconds at a flow rate of 4 gal/min.
Answers: 3
You know the right answer?
A steam power plant design consists of an ideal Rankine cycle with regeneration. Steam enters Turbin...
Questions
Mathematics, 23.03.2020 22:07
Mathematics, 23.03.2020 22:07
History, 23.03.2020 22:07
Mathematics, 23.03.2020 22:07
Mathematics, 23.03.2020 22:09
Geography, 23.03.2020 22:09
History, 23.03.2020 22:09
