A system consists of a turbine and heat exchanger are connected in series. The working fluid is entering the turbine at P= 0.6 Mpa, T= 200 °C and leaving it with P2- 0.2Mpa. Then the turbine exit becomes the heat exchanger inlet to increase the fluid temperature to become 800 °C. Considering that the adiabatic power y =1.4 and the specific heat c, - 1.005 KJ/Kg.K. Determine the turbine production work WT and heat exchanger energy needed to be added qHE. T = 200 °C P=0.6 Mpa- T T,? P;= 0.2 Mpa h pigh HE T= 800 °C P=? 9 in
A system consists of a turbine and heat exchanger are connected in series. The working fluid is entering the turbine at P= 0.6 Mpa, T= 200 °C and leaving it with P2- 0.2Mpa. Then the turbine exit becomes the heat exchanger inlet to increase the fluid temperature to become 800 °C. Considering that the adiabatic power y =1.4 and the specific heat c, - 1.005 KJ/Kg.K. Determine the turbine production work WT and heat exchanger energy needed to be added qHE. T = 200 °C P=0.6 Mpa- T T,? P;= 0.2 Mpa h pigh HE T= 800 °C P=? 9 in
Introduction to Chemical Engineering Thermodynamics
8th Edition
ISBN:9781259696527
Author:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Publisher:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Chapter1: Introduction
Section: Chapter Questions
Problem 1.1P
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A system consists of a turbine and heat exchanger are connected in
series. The working fluid is entering the turbine at P= 0.6 Mpa, T=
200 °C and leaving it with P2= 0.2Mpa. Then the turbine exit becomes
the heat exchanger inlet to increase the fluid temperature to become 800
°C. Considering that the adiabatic power y =1.4 and the specific heat c,
= 1.005 KJ/Kg.K. Determine the turbine production work WT and heat
exchanger energy needed to be added qHE
T = 200 °C
P, = 0.6 Mpa-
T
T ?
P2= 0.2 Mpa
h high
HE
T;= 800 °C
P, =?
9 in
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