Regenerative rankine cycle - Complete Overview
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May 03, 2021
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About This Presentation
Lecture 3: Regenerative Rankine cycle
Slide Content
An Introduction to Rankine cycle with
Regeneration
A technique to raise the average
temperature of the heat addition process.
Regeneration
A technique to raise the average
temperature of the heat addition process.
T
1
a
3
s
Internal heat transfer to feed water heater.
4
2
Principle of the Regenerative Cycle
Extract a portion of the steam from the turbine and send to (regenerative)
feedwater heater(s) to preheat the condensate before entering the boiler.
1
a
3
s
Internal heat transfer to feed water heater.
4
2
Principle of the Regenerative Cycle
Extract a portion of the steam from the turbine and send to (regenerative)
feedwater heater(s) to preheat the condensate before entering the boiler.
Open Feedwater Heater
Introduction
Introduction
Closed Feedwater heater (Figures)
The ideal Regenerative
Rankine cycle with an
open feedwater heater.
Using Open Feedwater Heaters
Note: Heat loss from the feedwater heater is considered negligible.
(1)
(1)
(y)
(1-y)
(1)
(y)
(1-y)
What is Pump IIcalled?
Rankine cycle with an
open feedwater heater.
Using Open Feedwater Heaters
Note: Heat loss from the feedwater heater is considered negligible.
(1)
(1)
(y)
(1-y)
(1)
(y)
(1-y)
What is Pump IIcalled?
OFwH ( mass fractions [y] )ymm/
6 5 )1(
1//
52
5256
5326
ymm
mmmm
mmmm
mm
outin
Let be the fraction of mass extracted from the turbine for the feedwater
heater. Conservation of mass gives:
()
EE
mhmhmh
ymh ymhmh
y
hh
hh
in out
66 22 33
56 52 53
3 2
6 2
1
Conservation of energy for the open feedwater heater:
y
From the outlet
of the condenser
and first feedwater
pump. (1-y kg.)
From the
turbine.
(y kg.)
To the second
feedwater pump.
(1 kg.)
1-y
6
2
3 Open
FWH
6 5 )1(
1//
52
5256
5326
ymm
mmmm
mmmm
mm
outin
Let be the fraction of mass extracted from the turbine for the feedwater
heater. Conservation of mass gives:
()
EE
mhmhmh
ymh ymhmh
y
hh
hh
in out
66 22 33
56 52 53
3 2
6 2
1
Conservation of energy for the open feedwater heater:
y
From the outlet
of the condenser
and first feedwater
pump. (1-y kg.)
From the
turbine.
(y kg.)
To the second
feedwater pump.
(1 kg.)
1-y
6
2
3 Open
FWH
45
121,342,
762,651,
1
)1(
hhQ
hhyWandhhW
hhyWandhhW
H
ININ
OUTOUT
h
s
1
3
4
2
W
OUT,1
Q
H
Q
C
W
IN,1
5
6
7
W
OUT,2
W
IN,2
(1 kg)
(y kg)
(1-y kg)
The h-s diagram of Regenerative Cycle with OFwH
45
12347665 )1()1(
hh
hhyhhhhyhh
45
121,342,
762,651,
1
)1(
hhQ
hhyWandhhW
hhyWandhhW
H
ININ
OUTOUT
h
s
1
3
4
2
W
OUT,1
Q
H
Q
C
W
IN,1
5
6
7
W
OUT,2
W
IN,2
(1 kg)
(y kg)
(1-y kg)
The h-s diagram of Regenerative Cycle with OFwH
45
12347665 )1()1(
hh
hhyhhhhyhh
OFwH (Deaerating heater or DA)
§Purpose is also to vent dissolved gases from the cycle.
Procedure is called deaeration. Note that solubility of
these gases decreases with increasing temperature.
§Helps to minimize corrosion.
§In general, only one is used.
§Purpose is also to vent dissolved gases from the cycle.
Procedure is called deaeration. Note that solubility of
these gases decreases with increasing temperature.
§Helps to minimize corrosion.
§In general, only one is used.
Closed Feedwater Heater
Introduction
Introduction
Closed Feedwater heater (Figure)
))(1(;
))(1(
)())(1(
1856
8776
3412
hhyQhhQ
hhyhhW
hhyhhyW
CH
T
P
(1)
(1)
(y)
(1-y)
(y)
(1-y)
TTD or TD = Terminal temp. difference = Bled steam exit temp. –Feedwater exit temp.
The ideal regenerative Rankine
cycle with a closed feedwater
heater pumped forwards
))(1(
)())(1(
1856
8776
3412
hhyQhhQ
hhyhhW
hhyhhyW
CH
T
P
(1)
(1)
(y)
(1-y)
(y)
(1-y)
TTD or TD = Terminal temp. difference = Bled steam exit temp. –Feedwater exit temp.
The ideal regenerative Rankine
cycle with a closed feedwater
heater pumped forwards
The ideal regenerative Rankine
cycle with a closed feedwater
heater cascaded backwards)())(1(;
))(1(
)(
151836
8776
12
hhyhhyQhhQ
hhyhhW
hhW
CH
T
P
(1)
(1)
(y)
(1-y)
(y)
(1-y)54: hhNote
cycle with a closed feedwater
heater cascaded backwards)())(1(;
))(1(
)(
151836
8776
12
hhyhhyQhhQ
hhyhhW
hhW
CH
T
P
(1)
(1)
(y)
(1-y)
(y)
(1-y)54: hhNote
OFwH
§The extracted steam and condensate are physically mixed (direct-contact).
§Always requires additional pump per heater.
CFwH
§The extracted steam and the condensate are notmixed (shell-and-tube HX).
§May or may not require pump (depends on type).
Some differences between OFwH and CFwH
§The extracted steam and condensate are physically mixed (direct-contact).
§Always requires additional pump per heater.
CFwH
§The extracted steam and the condensate are notmixed (shell-and-tube HX).
§May or may not require pump (depends on type).
Some differences between OFwH and CFwH
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