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CONTROLS OF SUPER CRITICAL BOILERS

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Title: CONTROLS OF SUPER CRITICAL BOILERS


1
CONTROLS OF SUPER CRITICAL BOILERS
Presentation By AJAY SHUKLA Sr.Faculty PMI,
2
Boiler Turbine Control
3
Boiler Following Mode
4
Turbine Following Mode
5
Coordinate Mode Control
6
Coordinate Mode Control
7
Drum and OT Control Comparison
8
Drum and OT Control Comparison
9
OT Control Overview
10
Cycle of Supercritical Power Plant
11
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12
Supercritical Power Plant
13
OT Control Overview
14
OT Start up Control mode
15
Super Critical Units Controls Mode
16
Flushing Mode
17
Flushing Mode
18
Start-Up System with Recirculation
Start-Up System Recirculation Pump in Main
Bypass Line
SH
Separator
Flash Tank
WW
C
ECO
HWL
To Condenser
C
Deaerator
HPH
C
BFP
19
Start UP System
20
START-UP
  • If the water system of the boiler is empty
    (economizer, furnace walls, separators), then the
    system is filled with approximately 10 TMCR feed
    water flow.
  • When the level in the separator reaches
    set-point, the WR valve will begin to open.
  • When the WR valve reaches gt30 open for
    approximately one minute, then increase feed
    water flow set-point to 30 TMCR. As the flow
    increases, WR valve will reach full open and ZR
    valve will begin to open.
  • The water system is considered full when
  • The separator water level remains stable for
    two(2) minutes
  • and
  • The WR valve is fully opened and ZR valve is gt15
    open for two(2) minutes.

21
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22
SEPARATOR STORAGE TANK LEVEL CONTROL
  • Separator level is maintained by the combined
    action of a separator storage tank level feed
    water demand and the positioning of WR and ZR
    drain valves.
  • Feed water demand is developed in response to
    separator storage tank level error and total fuel
    flow so as to prevent tank level from dropping
    too low.
  • The WR and ZR valves are controlled in a split
    range manner to maintain the liquid level once
    the level reaches a high limit.
  • The WR valve will respond first and then the ZR
    when the WR exceeds its linear operating range.
  • Tank geometry is such that fluctuations in tank
    level are very dynamic, for this reason, only
    proportional control action established through
    the WR/ZR function curves is used to position
    these valves in response to level error.

23
UG VALVE CONTROL
  • Control objective
  • Maintain minimum economizer inlet flow.
  • Control action
  • The boiler circulating pump is started following
    the start of a turbine-driven feed water pump and
    the final clean-up cycle. This pump circulates
    feed water from the evaporator outlet back to the
    economizer inlet.
  • Located at the outlet of this pump is the UG
    valve which controls economizer inlet flow during
    the start-up phase of operation. Demand for this
    recirculation control valve is established based
    on measured economizer inlet flow compared to a
    minimum boiler flow set point.

24
Separator water circuit of Super Critical
25
FEEDWATER CONTROL LOOP
  • Control objective
  • Develop total unit feed water demand as required
    to support unit load.
  • Adjust feed water demand to maintain desired
    separator outlet temperature.
  • Adjust separator outlet temperature set point as
    required to maintain acceptable platen superheat
    spray control range.
  • Incorporate separator storage tank level (wet
    mode) feed water demand.
  • Maintain minimum required economizer inlet flow.
  • .

26
Feedwater Control
27
Feed water firing rate ratio control
28
Feed water firing rate ratio control
29
Feed Forward with model
Process
Setpoint
Feed Forward
f(x)
S
P /-
C -/
D
K
?
C /-
P /-
30
Feed Forward
process
FF
setpoint
PROCESS
FF
f(x)
P /-
C -/
P /-
C -/
D
D
K
K
C /-
P /-
C /-
P /-
X
S
31
Model predictive control

MW
_
Fuel with model
Without model
Turbine setpoint
Water wall Temperature
C
tsec
0
60
180
240
300
120
32
Firing Rate Master
33
Fuel Rate Master
34
Feed Forward Firing Rate Control
35
Feed Forward Firing Rate Control
36
ANY QUESTIONS PLEASE
37
Yuhuan 4x1000MW Preparation of light off
38
Multi-combusting Nozzles with Separated Overfire
Air Damper
39
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40
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41
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42
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43
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44
START-UP contd..
  • Water flows through the economizer and
    evaporator, and discharges the boiler through
    the WR valve to the flash tank and via connecting
    pipe to the condenser.
  • Start BCP and open the UG valve to establish
    minimum water wall flow
  • at 30 TMCR.
  • As the pressure is raised, first the WR and
    then the ZR valves will open when
  • separator water level increases due to boiler
    water swell. As pressure further
  • increases, the WR and ZR valves will start to
    close as the water level decreases.
  • The steam temperature at the separator inlet will
    reach a stable superheated
  • condition at app. 30 TMCR, causing the level in
    the separator to decrease and
  • eventually disappear. The boiler is now in
    once-through mode (dry mode). The
  • BCP (Boiler Circulating Pump) will be stopped
    automatically.
  • It is extremely important that minimum water wall
    flow be maintained at all times when firing the
    boiler to prevent tube damage due to overheating.

45
FEEDWATER CONTROL LOOP contd..
  • Demand for feed water is established
    predominately by the Boiler Master demand.
  • This signal, processed though a boiler transfer
    function provides the feed forward component of
    the total feed water demand.
  • The boiler transfer function is a tunable
    dynamic element providing a means to dynamically
    match the feed water feed forward demand to
    actual evaporator heat transfer.
  • Optimization of the feed forward in this manner
    minimizes temperature fluctuations that may
    otherwise result from varying dynamic response
    between the firing and feed water control systems
    (as they relate to evaporator heat transfer)
    thereby lessening the dependence on feedback
    correction.

46
FEEDWATER CONTROL LOOP contd..
  • The first controller acts on a load dependent
    average platen spray differential temperature.
  • Its output represents the required adjustment to
    evaporator heat transfer/steam generation to
    maintain both the steam conditions and flue gas
    temperatures entering the platen superheat
    section so as to ensure adequate platen spray
    control range.
  • A second controller acts on a load dependent
    separator outlet temperature set point corrected
    by the platen spray differential temperature
    controllers output.
  • This controller acts to adjust feed water in
    response to firing system disturbances and the
    relatively fast effect they have on separator
    outlet steam temperatures.
  • The overall combined feed water feedback control
    action is such that feed water demand is
    responsive to changes in the overall unit heat
    transfer profile.

47
FEEDWATER CONTROL LOOP contd..
  • The combined feed forward/feedback demand signal
    is subject to a minimum economizer inlet flow set
    point (wet mode) activated if the boiler
    circulation pump is not in service and the unit
    is being fired.
  • This ensures the minimum economizer inlet cooling
    flow is maintained by the feed water supply
    system in the event the start-up system is not
    available.
  • The feed forward/feedback demand signal is
    subject to a second wet mode feed water demand
    developed to support separator storage tank level
    control.
  • The resulting demand provides the set point to a
    feed water master controller.
  • The fuel/feed water ratio protection logic
    provides overriding control of individual feeder
    speed demands in the event of an excessively
    high fuel to feed water ratio.

48
THANK YOU
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