U.S. patent application number 09/748522 was filed with the patent office on 2001-05-10 for method for operating a boiler using oxygen-enriched oxidants.
This patent application is currently assigned to L'AIR LIQIDE, SOCIETE ANONYME POUR L'ETUDE ET L'EXPLOITATION DES PROCEDES GEORGES CLAUDE. Invention is credited to Charon, Oliver, Marin, Ovidiu.
Application Number | 20010000863 09/748522 |
Document ID | / |
Family ID | 23736800 |
Filed Date | 2001-05-10 |
United States Patent
Application |
20010000863 |
Kind Code |
A1 |
Marin, Ovidiu ; et
al. |
May 10, 2001 |
Method for operating a boiler using oxygen-enriched oxidants
Abstract
A method for operating a boiler using oxygen-enriched oxidants
includes introducing oxygen-enriched air, or oxygen and air, in
which the oxygen concentration ranges from about 21% to about 100%
by volume. Fuel and oxygen-enriched air are introduced into the
combustion space within the steam-generating boiler. The fuel and
oxygen-enriched air is combusted to generate thermal energy. At
least a portion of the flue gases are collected and at least a
portion are recirculated through the boiler. In the
steam-generating boiler, the oxygen-enriched oxidant is introduced
at one or more locations within the radiation zone and the
convection zone of the boiler. Additionally, flue gas is collected
and recirculated into one or more locations within the radiation
zone and/or the convection zone of the boiler. The amount of oxygen
enrichment and the total gas flow through the boiler is controlled
so as to maintain the heat transfer patterns within the boiler at
the originally-design specification for operation by air
combustion.
Inventors: |
Marin, Ovidiu; (Lisle,
IL) ; Charon, Oliver; (Chicago, IL) |
Correspondence
Address: |
Jasper W. Dockrey
BRINKS HOFER GILSON & LIONE
P.O. BOX 10395
CHICAGO
IL
60610
US
|
Assignee: |
L'AIR LIQIDE, SOCIETE ANONYME POUR
L'ETUDE ET L'EXPLOITATION DES PROCEDES GEORGES CLAUDE
|
Family ID: |
23736800 |
Appl. No.: |
09/748522 |
Filed: |
December 22, 2000 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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09748522 |
Dec 22, 2000 |
|
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09437526 |
Nov 10, 1999 |
|
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09437526 |
Nov 10, 1999 |
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09329555 |
Jun 10, 1999 |
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Current U.S.
Class: |
110/345 ;
110/204 |
Current CPC
Class: |
Y02E 20/348 20130101;
F23C 2900/07021 20130101; Y02E 20/322 20130101; F23L 15/00
20130101; F23C 9/00 20130101; F23L 2900/07007 20130101; Y02E 20/32
20130101; Y02E 20/34 20130101; F23D 2900/00006 20130101; Y02E
20/344 20130101; F23L 2900/07001 20130101; F23L 7/007 20130101 |
Class at
Publication: |
110/345 ;
110/204 |
International
Class: |
F23J 011/00; F23B
005/02 |
Claims
What is claimed is:
1. A method of operating a steam-generating boiler including a
radiation zone and a convection zone comprising: introducing fuel
into a combustion space within the boiler; introducing
oxygen-enriched air into the combustion space, wherein the
oxygen-enriched air contains about 21% to about 100% by volume
oxygen; combusting the fuel and oxygen-enriched air to generate
thermal energy in the combustion space; and collecting at least a
portion of flue gases and recirculating at least a portion of the
flue gases through the boiler.
2. The method of claim 1, wherein the oxygen concentration in the
oxygen-enriched air comprises about 21 to about 40% by volume.
3. The method of claim 2, wherein the oxygen concentration in the
oxygen-enriched air comprises about 21 to about 28% by volume.
4. The method of claim 1, wherein the recirculation of flue gases
comprises recirculating about 0-95% by volume of total flue
gas.
5. The method of claim 4, wherein the recirculation of the gases
comprises recirculating about 10% to about 30% by volume of total
flue gas.
6. The method of claim 1, wherein introducing oxygen-enriched air
comprises injecting oxygen-enriched air into the radiation zone and
into the convection zone and wherein recirculating the flue gas
comprises introducing the recirculated flue gas into the radiation
zone and into the convection zone.
7. The method of claim 1, wherein introducing oxygen-enriched air
comprises injecting oxygen-enriched air into one of the radiation
zone and the convection zone and wherein recirculating the flue gas
comprises introducing the recirculated flue gas into one of the
radiation zone and the convection zone.
8. The method of claim 1, wherein introducing oxygen-enriched air
comprises premixing oxygen with combustion air and injecting
through air burners located at the lowest point in the radiation
zone.
9. The method of claim 1, wherein introducing oxygen-enriched air
comprises lancing oxygen directly into a combustion chamber in
proximity to air burners located in a lower region of the radiation
zone.
10. The method of claim 1, wherein introducing oxygen-enriched air
comprises lancing oxygen directly into a combustion chamber at a
location intermediate to the lowest point of the radiation zone and
the interface of the radiation zone and the convection zone.
11. The method of claim 1, wherein introducing oxygen-enriched air
comprises injecting oxygen through an oxygen-enriched burner
located in an upper region of the convection zone.
12. The method of claim 1, wherein introducing oxygen-enriched air
comprises injecting oxygen through a low-calorific fuel oxygen
burner located in a lower region of the radiation zone.
13. A method of operating a steam-generating boiler including a
radiation zone and a convection zone comprising: introducing fuel
into a combustion space within the boiler; introducing oxygen and
air into the combustion space, to form an air/oxygen mixture,
wherein the oxygen concentration in the air/oxygen mixture is about
21 to about 100% by volume oxygen and wherein oxygen is injected at
one or more locations within the boiler; combusting the fuel and
oxygen-enriched air to generate thermal energy in the combustion
space; and collecting flue gases and recirculating the flue gases
through the boiler.
14. The method of claim 13, wherein oxygen injection at one or more
locations comprises one or more of: premixing oxygen with
combustion air and injecting through air burners located at the
lowest point in the radiation zone; injecting oxygen directly into
a combustion chamber in proximity to air burners located in a lower
region of the radiation zone; injecting oxygen directly into a
combustion chamber at a location intermediate to the lowest point
of the radiation zone and the interface of the radiation zone and
the convection zone; injecting oxygen through an oxygen burner
located in an upper region of the convection zone; and injecting
oxygen through a low-calorific fuel oxygen burner.
15. The method of claim 14 comprising one or more of the following
steps: introducing about 0 to about 80% by volume of the total
oxygen by premixing oxygen with combustion air and injecting
through air burners located at the lowest point in the radiation
zone; introducing about 0 to about 100% by volume of the total
oxygen by lancing oxygen directly into a combustion chamber in
proximity to air burners located in a lower region of the radiation
zone; introducing about 0 to about 50% by volume of the total
oxygen by lancing oxygen directly into a combustion chamber at a
location intermediate to the lowest point of the radiation zone and
the interface of the radiation zone and the convection zone; and
introducing about 0 to about 50% by volume of the total oxygen by
injecting oxygen through an oxygen burner located in an upper
region of the convection zone, wherein the total of the volumetric
percentages of added oxygen equals about 100.
16. The method of claim 14 comprising one or more of the following
steps: introducing about 0 to about 100% by volume of the total
oxygen by premixing oxygen with combustion air and injecting
through air burners located at the lowest point in the radiation
zone; introducing about 0 to about 80% by volume of the total
oxygen by lancing oxygen directly into a combustion chamber in
proximity to air burners located in a lower region of the radiation
zone; introducing about 0 to about 40% by volume of the total
oxygen by lancing oxygen directly into a combustion chamber at a
location intermediate to the lowest point of the radiation zone and
the interface of the radiation zone and the convection zone; and
introducing about 0 to about 60% by volume of the total oxygen by
injecting oxygen through an oxygen burner located in an upper
region of the convection zone, wherein the total of the volumetric
percentages added oxygen from the foregoing equals about 100.
17. The method of claim 14 comprising one or more of the following
steps: introducing about 50 to about 100% by volume of the total
oxygen by lancing oxygen directly into a combustion chamber at a
location intermediate to the lowest point of the radiation zone and
the interface of the radiation zone and the convection zone; and
introducing about 0 to about 50% by volume of the total oxygen by
injecting oxygen through an oxygen burner located in an upper
region of the convection zone, wherein the total of the volumetric
percentage of added oxygen equals about 100.
18. The method of claim 14 comprising: introducing about 0 to about
30% by volume of the total oxygen by lancing oxygen directly into a
combustion chamber at a location intermediate to the lowest point
of the radiation zone and the interface of the radiation zone and
the convection zone; introducing about 0 to about 20% by volume of
the total oxygen by injecting oxygen through an oxygen burner
located in an upper region of the convection zone; and introducing
about 0 to about 100% by volume of the total oxygen by injecting
oxygen through a low-calorific fuel oxygen burner located in a
lower region of the radiation zone, wherein the total of the
volumetric percentages equals about 100.
19. The method of claim 14, wherein the oxygen concentration in the
oxygen-enriched air comprises about 21% to about 40% by volume.
20. The method of claim 19, wherein the oxygen concentration in the
oxygen-enriched air comprises about 21% to about 28% by volume.
21. The method of claim 14, wherein the recirculation of flue gases
comprises recirculating about 0% to about 95% by volume of total
flue gas.
22. The method of claim 4, wherein the recirculation of the gases
comprises recirculating about 10% to about 30% by volume of total
flue gas.
23. A method of operating a steam-generating boiler including a
radiation zone and a convection zone comprising: introducing fuel
into a combustion space within the boiler; introducing oxygen
premixed with preheated air into the combustion space, wherein the
oxygen concentration in air is about 21 to about 100% by volume
oxygen and wherein oxygen is injected at one or more locations
within the boiler; combusting the fuel and oxygen-enriched air to
generate thermal energy in the combustion space; and collecting
flue gases and recirculating the flue gases through the boiler.
24. The method of claim 23, wherein the recirculation of flue gases
comprises recirculating about 0% to about 95% by volume of total
flue gas.
Description
CROSS REFERENCE TO RELATED APPLICATION
1. This application is a continuation-in-part of application Ser.
No. 09/329,555 filed Jun. 10, 1999, the disclosure of which is
incorporated by reference herein.
FIELD OF THE INVENTION
2. This invention relates, in general, to methods of operating
steam-generating boilers and, more particularly, to methods for
improving combustion conditions and operating efficiency in
steam-generating boilers.
BACKGROUND OF THE INVENTION
3. Boilers are widely used to generate steam for numerous
applications. In a water-tube boiler, combustion of stoker or
pulverized coal and coke, or gas or oil fuels provide radiation to
the boiler tubes. Further, heat transfer is accomplished by
arranging the flow of hot gases over the tubes to provide
convection-heat transfer. In a typical low-pressure boiler designed
to generate 200,000 lb/hr of steam at 235 psig and 500.degree.F.,
about 99.degree. F. of superheat is required since the saturation
temperature at this pressure is only 401.degree. F. In some systems
designed to generate the required amount of superheating, radiant
boiler tubes cover an entire wall and roof surface within the
boiler forming a "waterwall." With such systems, the temperature of
the refractory walls is kept down, thus decreasing maintenance
requirements. Often the water tubes are partially embedded in the
walls. Typically, in this type of boiler, water is fed by gravity
from the upper drums to headers at the bottom end of the waterwall
tubes on all four radiant walls. Water circulation is upward
through these tubes and the steam is disengaged from water in the
upper drums of the boiler. The steam then passes through a steam
separator before being superheated.
4. In a low-pressure boiler, the convection tubes reduce the flue
gas temperature sufficiently such that the convection tubes can be
routed directly to the air preheater, eliminating the need for a
feed-water preheater sometimes referred to as an "economizer." The
convection tubes are typically bent tubes running from the upper
drums to the lower drums of the boiler. Water circulation in these
tubes is, in general, downward in the cooler bank of tubes and
upward through the hotter bank of tubes.
5. A typical power-generating steam boiler has a capacity of about
450,000 lb/hr of 900 psig steam delivered at about 875.degree.F.
Since the saturation temperature at 900 psig is 532.degree.F.,
considerable superheating is required to obtain the steam delivery
temperature. Because of the need for considerable superheat duty,
little boiler convection surface can be placed between the radiant
boiler and the superheater. This is because high-temperature
combustion gases must be used to obtain the required superheat
temperature while maintaining a reasonable superheater tube surface
area. Since the feed water must be brought to the saturation
temperature before it is admitted to the boiler drum, considerable
heat is absorbed in the economizer section.
6. The thermal efficiency of the boiler can be further increased by
preheating the combustion air with the flue gases before they are
sent to the stack. In steam generating boilers, large amounts of
fuel are needed for the combustion process. This is because of the
need for superheating in order to achieve the required outlet steam
temperatures of both low-pressure and power-generating steam
boilers.
7. As the requirements for electrical energy continue to increase,
improved operating methods are necessary in order to maintain fuel
consumption and exhaust emissions within acceptable levels.
Improvements in fuel combustion within steam generating boilers is
one means to increase the operational efficiency of the boiler.
However, any change in the combustion process within an existing
steam-generating boiler must not take place without consideration
of the thermodynamic processes within the boiler. For example,
different heat transfer patterns within the various areas of the
boiler such as the radiation zone and the convection zone, can lead
to different localized vaporization/superheatin- g rates of the
steam. Nonuniform vaporization can lead to damage to the water
tubes within the boiler. Additionally, non-uniform localized vapor
superheating can lead to lower heat transfer coefficients, which
can cause pipe overheating. Accordingly, when making alterations to
the combustion process within the boiler, it is desirable to
maintain relatively unchanged the originally designed heat transfer
patterns within the boiler.
8. One method for increasing the efficiency of the combustion
process is to use oxygen-enriched air as an oxidant.
Oxygen-enriched combustion has been employed in numerous industrial
applications such as glass, steel, aluminum and cement
manufacturing. The use of oxygen-enriched air has led to
significant process improvements such as fuel savings, production
increases and expanded use of waste materials as fuel.
Additionally, oxygen enrichment has been used for combustion in the
lower central zone of recovery boilers in the pulp and paper
industries.
9. The use of oxygen-enriched air is also employed in operation of
boilers using coal-water-mixture (CWM). The results of
experimentation conducted with a 700 HP water-tube boiler using
bituminous CWM suggest that the use of oxygen-enriched air
increased carbon burnout, reduced uncontrolled fly ash emissions
and reduced combustion air preheating requirements. Additionally,
the boiler efficiency increased because of reduced flue gas heat
losses.
10. Although the use of oxygen-enriched air and oxygen-containing
gases has been shown to improve boiler operation, further
improvements are necessary to fully realize the increased
operational efficiency potentially obtainable in large
steam-generating boilers. The need to maintain thermodynamic
balance within the radiation zone and convection zone of a large
steam-generating boiler is necessary if existing boilers are to be
retrofitted for oxygen enhanced combustion. Accordingly, a need
exists for a method of operating a steam-generating boiler that
fully utilizes oxygen enhanced combustion while maintaining
parameters such as the flue gas mass flow rate and steam properties
such as temperature, pressure, flow rate and the like within boiler
design limits.
SUMMARY OF THE INVENTION
11. The present invention is for a method of operating a
steam-generating boiler using premixed oxygen-enriched air
exclusively or in combination with oxygen and air for fuel
combustion within the boiler. The method of the present invention
can be carried out with a wide variety of fuels including
hydrocarbon gases, oil, CWM, low-calorie fuels and the like. The
method of the present invention also results in minimizing the
carbon content in ash produced by the combustion process.
Additionally, the method of the present invention can lead to
increased steam throughput, a reduction in fuel usage, reduced
NO.sub.x emissions and improve the ability of the boiler to be
operated with low-quality fuels such as carbonaceous waste
materials and the like. The method of the present invention also
allows adjustment in the turn down ratio over a wide range.
Importantly, the method of the present invention enables the use of
oxygen-enhanced combustion within a boiler originally designed for
air combustion. Accordingly, the gas flow patterns and heat
transfer characteristics within the boiler are not substantially
altered from the originally-designed heat transfer patterns
developed from unenriched air combustion.
12. In one aspect of the invention, oxygen-enriched air containing
about 21 to about 100 percent by volume oxygen is introduced into
one or more locations within a steam-generating boiler. In the
process of the invention, oxygen-enriched air can be introduced
into the radiation zone and/or intro the convection zone using one
of several techniques such as oxygen premixing, oxygen lancing and
oxygen burners. Additionally, the method of the invention also
includes the introduction of recirculated flue gasses. The flue gas
recirculation rate is adjusted to maintain temperature profile and
the flow of flue gases within the originally-designed parameters
for the subject boiler.
13. In another aspect of the invention, the amount of oxygen
introduced at the various injection points in the boiler is
predetermined depending upon the particular operational aspect of
the boiler that is to be optimized. The specific amount of oxygen
introduced at each predetermined location within the boiler is
adjusted such that oxygen-enriched combustion is carried out within
the boiler at a total volume metric oxygen concentration of between
about 21% to about 100%.
14. In yet another aspect, a method of operating a steam-generating
boiler is disclosed that includes a radiation zone and a convection
zone includes introducing a fuel into the combustion space within
the boiler. Either oxygen-enriched air or oxygen in combination
with air is also introduced into the combustion space. The total
oxygen concentration ranges from about 21% to about 100% by volume.
The oxygen-enriched air is combusted with the fuel to generate
thermal energy within the combustion space of the boiler. Flue
gases are collected and recirculated through the boiler with the
oxygen-enriched air.
BRIEF DESCRIPTION OF SEVERAL VIEWS OF THE DRAWINGS
15. FIG. 1 is a schematic diagram of a high-capacity
steam-generating boiler having a plurality of oxygen introduction
sites arranged in accordance with the invention;
16. FIG. 2 is a cross-sectional schematic diagram of an oxygen
sparger for premixing oxygen in accordance with the invention;
17. FIG. 3 is a cross-sectional schematic diagram of an oxygen
lance useful for injecting oxygen in accordance with the
invention;
18. FIG. 4 is a cross-sectional schematic diagram of an oxygen
burner useful for introducing oxygen into the convection zone of a
steam-generating boiler in accordance with the invention;
19. FIG. 5 is a plot of fuel savings versus oxygen concentration
obtained by operating a steam-generating boiler in accordance with
the invention; [and]
20. FIG. 6 is a plot of recirculation ratio versus oxygen
concentration for the operation of a steam-generating boiler in
accordance with the inventions; and
21. FIG. 7 is a plot of recirculation ratio versus oxygen
concentration for the operation of a steam-generating boiler at
oxygen concentrations up to 100% in accordance with the
invention.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
22. Shown in FIG. 1 is a cross-sectional schematic diagram of a
high-capacity steam-generating boiler 10. Boiler 10 includes a
radiation zone 12 and a convection zone 14. Those skilled in the
art will appreciate that steam-generating boilers include a
multitude of components such as water-tubes, steam-tubes,
superheaters, boiler drums and the like. In general, the flow of
water is upward through radiation zone 12 converting to steam in
the upper regions of radiation zone 12. The superheated steam and
hot water are transferred to convection zone 14 and exit through an
outlet (not shown) at the upper portion of radiation zone 12. The
flow of flue gases within boiler 10 is generally represented by
arrow 16. In accordance with the invention, combustion of fuel
introduced into boiler 10 can take place throughout radiation zone
12 and the upper region 18 of convection zone 14.
23. In accordance with the invention, oxygen-enriched air, or air
and oxygen, or both, can be introduced at one or more locations in
boiler 10. In one embodiment, one or more air burners 21 are
attached and inserted into a lower portion 20 of radiation zone 12.
Fuel is injected into air burner 21 through a fuel line 22.
Preheated, oxygen-enriched air is introduced through oxidant line
24. Oxygen can be premixed with air either before or after the air
preheater (not shown). Additionally, recirculated flue gas is
introduced into lower portion 20 through flue gas recirculation
line 26. Those skilled in the art will recognize that a variety of
techniques are possible for introducing recirculated flue gas into
boiler 10. For example, flue gas recirculation line 26 can be
connected to fuel line 22 or to oxidant line 24. Alternatively,
recirculated flue gas can be directly injected at one of several
locations in radiation zone 12.
24. In addition to introducing oxygen-enriched air through air
burner 21, oxygen can be injected by lancing into various stages of
radiation zone 12. Oxygen-enriched air or oxygen can be lanced into
lower portion 20 of radiation zone 12 through oxidant line 28.
Additionally, the present invention contemplates the use of oxygen
staging at one or more locations in radiation zone 12 beginning at
lower portion 20 and extending to an upper portion 30 of radiation
zone 12. For example, oxygen can be lanced into radiation zone 12
at upper portion 30 through an oxidant line 31. Although FIG. 1
depicts two oxygen introduction sites at stage levels above lower
portion 20, it is to be understood that a plurality of such oxygen
introduction stages can be employed at various locations between
lower portion 20 and upper portion 30 of radiation zone 12.
25. The method of the present invention also contemplates the
introduction of oxygen-enriched air or a combination of air and
oxygen, or both, into boiler 10 within convection zone 14. For
example, oxygen and fuel can be introduced in upper region 18 of
convection zone 14 through a fuel line 32 and an oxidant line 34,
respectively. The oxygen and fuel initiate combustion in upper
region 18. Additionally, recirculated flue gas can be introduced in
upper region 18 through flue gas recirculation line 36. The flue
gases are collected at a lower region 38 of convection zone 14 and
exit through a flue gas collection line 40.
26. In addition to providing an operating method in which
oxygen-enriched air or oxygen and air can be introduced at various
locations within boiler 10, the present invention also contemplates
operation of boiler 10 using low-calorie fuel. Accordingly, boiler
10 can include an oxygen-enriched fuel burner 42 inserted into
lower portion 20 of radiation zone 12 or into upper region 18 of
convection zone 14. Low-calorie fuel such as carbonaceous waste,
pulverized waste and the like can be entrained in air and
introduced along with oxygen and combustion air through fuel burner
42.
27. In accordance with the invention, various apparatus are used to
introduce oxygen-enriched air or oxygen into boiler 10. For the
introduction of preheated, oxygen-enriched air, preferably a
convectional air burner such as an oxygen sparger is used to
introduce premixed oxygen and air into the combustion space within
radiation zone 12. In a preferred embodiment, the oxygen sparger is
an oxygen delivery unit available from Air Liquide Corp. under the
tradename "OXYNATOR." A cross-sectional schematic diagram of the
air inlet 21 is illustrated in FIG. 2. Air inlet 21 includes an
oxygen nozzle 44 mounted within a housing 46. Air is introduced
through a port 48 at the rear of housing 46. The oxygen and air are
mixed within air inlet 21 and ejected through an outlet port 50.
Air inlet 21 effectively mixes oxygen and air and introduces an
oxidant stream directly into the combustion space within radiation
zone 12. Those skilled in the art will appreciate that other types
of air inlet can also be employed to introduce premixed oxygen and
air into a steam boiler before or after the preheater. Accordingly,
variations and modifications can be made to the air inlet
illustrated in FIG. 2 and all such variations and modifications are
within the scope of the present invention.
28. FIG. 3 illustrates a cross-sectional schematic view of an
oxygen lance 52. Oxygen lance 52 can be used for lancing oxygen
directly into radiation zone 12. Oxygen lance 52 includes an oxygen
inlet 54 encased by a first water cooling jacket 56. First water
cooling jacket 56 is, in turn, encased by a second water cooling
jacket 58. Water is introduced through inlet tube 60 and exits
through outlet tube 62. Oxygen is lanced into radiation zone 12
through a nozzle 64. Those skilled in the art will recognize that
the particular design of oxygen lance 52 is only one such design of
an oxygen lance and that many other component arrangements of an
oxygen lance are possible. Accordingly, all such other designs are
contemplated by the present invention. Oxygen lance 52 can be
coupled to oxidant lines 28 and 31 for lancing oxygen into
radiation zone 12.
29. FIG. 4 illustrates a partial cut-away, cross-sectional view of
an oxygen burner 66. Oxygen burner 66 includes an air inlet 68, an
oxygen inlet 70 and a fuel inlet 72. A housing 74 encloses a first
tube 76 which encloses a second tube 78. Air that is introduced
through air inlet 68 traverses an annular space 80 between housing
74 and first tube 76. Oxygen that is introduced through oxygen
inlet 70 traverses an annular space 82 located between first and
second tubes 76 and 78. Fuel that is introduced through fuel inlet
72 traverses the inner portion of second tube 78. Oxygen burner 66
accommodates the introduction of oxidizers and fuel for a
combustion in upper region 18 of convection zone 14. In addition to
air, air inlet 68 can also be used to introduce recirculated flue
gas. In addition, inlet 68 can be closed altogether and a full
oxy-burner can be employed. In the embodiment of the invention
illustrated in FIG. 1, oxygen burner 66 can be coupled to fuel line
32, oxidant line 34 and flue gas recirculation line 36.
Alternatively, combustion air can be introduced into oxygen burner
66 through air inlet 68 and a separate nozzle can be employed for
the injection of recirculated flue gas through flue gas
recirculation line 36.
30. In an alternative embodiment, a low calorie fuel can be
introduced using the oxygen burner illustrated in FIG. 4. Those
skilled in the art will appreciate that other arrangements for a
low-calorie fuel and oxygen burner are possible. Accordingly, all
such other arrangements of a low-calorie fuel burner for
introducing fuels such as carbonaceous wastes and the like into a
steam boiler are within the scope of the present invention.
Additionally, a variety of methods can be used to introduce
recirculated flue gas in boiler 10, including premixing with air,
lancing and through burners.
31. The use of oxygen-enriched combustion in boiler 10 can both
reduce the mass fraction of nitrogen and the combustion exhaust,
and increase the adiabatic temperature of the combustion flame.
Changes in exhaust composition and adiabatic flame temperature can
increase localized heat transfer rates at various locations in the
radiation zone of the boiler. In keeping with the original design
parameter preservation of the invention, oxygen-enriched combustion
is carried out while recirculating a predetermined mass flow rate
of flue gas. The flow rate of recirculated flue gas is specified
such that the flame temperature and the total mass flow rate
through the boiler is kept approximately the same as for air
combustion operation.
32. The controlled introduction of recirculated flue gas can be
carried out through flue gas recirculation lines 26 and 36 shown in
FIG. 1. In the method of the invention, both the extraction and the
recirculation of flue gas in boiler 10 are optimized to maintain
maximal operational efficiency. To achieve maximum operational
efficiency, the temperature of the recirculated flue gas must be
controlled to predetermined levels.
33. The flue gas recirculation flow rate, together with the
oxygen-enriched air and fuel requirements are determined by the
acceptable range of flame temperature and overall mass flow rate
through the boiler. Using mass and energy conservation equations, a
system of two equations can be written in terms of the fuel flow
rate m and recirculated flue gas flow rate m.sub.R as unknown. The
mass and energy conservation equations are given below as Equations
(1) and (2), respectively.
{dot over (m)}.sub.total,bch.sub.bc,T.sub..sub.ad,bc={dot over
(m)}.sub.total,oh.sub.o,T.sub..sub.ad,o+{dot over
(m)}.sub.Rh.sub.R,T.sub- ..sub.R (1)
{dot over (m)}.sub.total,bc={dot over (m)}.sub.total,o+{dot over
(m)}.sub.R, (2)
34. Where the subscript bc refers to the base case (air
combustion), o refers to the oxygen-enriched combustion operation
and R refers to the flue gas recirculation stream and h is the
specific enthalpy of the different streams at a given temperature.
By solving Equations (1) and (2), the ratio between the
oxygen-enriched case and the base case in terms of fuel consumption
can be approximated as shown by Equation (3). 1 FS = m . f , o m .
f , bc = bc o c _ p , T ad , bc T ad , bc - c _ p , R T R c _ p , T
ad , o T ad , o - c _ p , R T R ( 3 )
35. Where {overscore (c)}.sub.p, T.sub.ad,bc is the specific heat
capacity of the fuel for the base case and {overscore (c)}.sub.p,
T.sub.ad,o is the specific heat capacity for oxygen-enriched
combustion, {overscore (c)}.sub.p, R is the specific heat capacity
of recirculated flue gas, T.sub.ad,bc is the temperature of air
combustion, T.sub.ad,o is the temperature for oxygen-enriched
combustion and T.sub.R. is the temperature of the recirculated flue
gas. Nondimensional parameter .THETA. is defined as shown in
Equation (4). 2 = m . total m . f , ( 4 )
36. A value for .THETA. can be calculated from the excess oxygen
ratio .lambda., where
.lambda.=m.sub.o.sub..sub.2.sub.,in/m.sub.o.sub..sub.2,st-
oichiometric and the amount of oxygen in an oxidant introduced into
the boiler given by a nondimensional variable o, where
o=(79-o.sub.a)/(21+o.sub.a), where o.sub.a is the volumetric oxygen
percentage over that contained in air (assumed to be 21%). A
relationship for .THETA. is given in terms of .lambda. and o by
Equation (5).
.THETA.=1+2.667.lambda.+2.334.lambda.o. (5)
37. Where the coefficients 2.667 and 2.334 are estimated for pure
carbon combustion. The recirculated flue gas RC can be expressed as
a fraction of the total gas mass flow rate flowing through the
boiler m.sub.total as shown by Equation (6). 3 RC = m . R m . total
= 1 - FS o bc . ( 6 )
38. Where FS is the fuel savings in percent as compared with air
combustion. For carbon combustion, the fuel savings FS as
determined by Equation (3) can be calculated for different oxygen
enrichment levels. FIG. 5 illustrates a plot of fuel savings versus
oxygen concentration obtained by means of the foregoing analysis.
The plot indicates that, as the oxygen concentration increases, the
amount of fuel saved versus that necessary for air combustion
increases steadily from 0% to almost 8% as the oxygen concentration
varies from 21% to 27% by volume.
39. FIG. 6 is a plot of RC versus oxygen concentration in percent
by volume. The values for RC are determined from Equation (6) and
represent the amount of flue gas recirculation normalized by the
total mass flow rate through the boiler. As indicated in the plot
of FIG. 6, recirculation levels can be increased steadily from 0%
to slightly more than 25% as the oxygen concentration varies from
21% to 27% by volume. This is well within acceptable limits for
standard air combustion boiler design. Further, it is important to
note that the temperature profile in the boiler is maintained at
design levels such that heat transfer patterns within the boiler
are not adversely effected.
40. It is important to note that the data shown in FIGS. 5 and 6
are theoretical estimates for pure carbon combustion. For other
fuels used in actual boiler operation, the specific results will
vary from that shown in FIGS. 5 and 6, however, the general trends
will be the same.
41. The foregoing analysis indicates that oxygen-enriched air can
be used in a convectional steam-generating boiler, while preserving
the heat transfer patterns, flame temperature and total mass flow
rate at air combustion designed levels. In a preferred embodiment,
the oxygen concentration in the oxygen-enriched air varies from
greater than 21% to about 100% by volume. In a more preferred
embodiment, the oxygen concentration in the oxygen-enriched air
varies from about 22% to about 100% by volume. In a still more
preferred embodiment of the invention, the oxygen concentration in
oxygen-enriched air varies from about 21% to about 28% by volume.
In a still more preferred embodiment of the invention, the oxygen
concentration in the oxygen-enriched air varies from about 21% to
about 40% by volume. In a most preferred embodiment, the oxygen
concentration in the oxygen-enriched air varies from about 23% to
about 28% by volume. Further, where the oxygen concentration varies
from about 21% to about 28% by volume, a preferred recirculation
rate is about 0% to 50% by volume of total flue gas and a more
preferred flue gas recirculation rate is about 10% to 30% by volume
of total flue gas.
42. FIG. 7 is a plot of RC versus oxygen concentration in percent
by volume for values of oxygen concentration up to 100%. The values
for RC are again determined from Equation (6). The values for RC
are again determined from Equation (6). The plot shows that, as the
oxygen enrichment level exceeds about 50%, the optimal
recirculation ratio levels off. At 100% oxygen, the RC is about
95%. The data indicates that, as the oxygen concentration exceeds
about 50%, an RC of about 70% or more is needed to maintain normal
steam-generating boiler operation. Accordingly, it is within the
scope of the invention to operate a steam-generating boiler at a
recirculation ratio that varies from about 0% to about 95%
depending upon the oxygen concentration in the oxygen-enriched
air.
43. The advantages of operating a steam-generating boiler in
accordance with the invention can be shown through computer
modeling by means of a CFD model named "ATHENA.RTM." software
developed by Air Liquide. The CFD model assumes an 18t/h saturated
steam boiler using methane gas and having a T.sub.V=500 K, where
T.sub.v is the steam vaporization temperature. Assuming equal heat
transfer rates to the walls of the boiler, the model can calculate
the fuel savings for air combustion and oxygen-enriched combustion
with 23% by volume oxygen. The calculated fuel consumption and the
contribution to the total heat transfer within the boiler from
radiation and convection is shown in Table I below.
1TABLE I Oxygen- Full Oxygen-Enriched Air-Fuel Enriched Combustion
with Parameter Combustion Combustion Recirculation Fuel consumption
100% 94% 96.6% Radiative transfer 63% 67% 64% contribution to total
heat transfer Convective transfer 37% 33% 36% contribution to total
heat transfer
44. The calculated results in Table I show that as the
concentration of oxygen and the oxidant increases, the contribution
of radiation to the overall heat transfer to the walls increases by
about 4% compared to the air combustion case. Additionally,
operation of the boiler by oxygen-enriched combustion reduces the
fuel consumption by about 6% compared to the air combustion
case.
45. Table I also indicates the calculated fuel consumption and
radiative and convective heat transfer contributions for
oxygen-enriched operation with flue gas recirculation. Flue gas
recirculation can modify the heat transfer patterns within the
boiler because of increased flame temperatures. In accordance with
the invention, the use of flue gas recirculation with
oxygen-enrichment reduces the disruption to the heat transfer
patterns. As in the non-recirculation case, the oxygen
concentration in the oxygen-enriched combustion is about 23% by
volume. The results shown in Table I for oxygen-enriched combustion
with recirculation assume a 12% flue gas recirculation rate at a
temperature of about 500 K. As indicated in Table I, flue gas
recirculation leads to a fuel savings of about 3.4% as compared
with air combustion. It is important to note that, although the
recirculation results in more moderate fuel savings when compared
with nonrecirculation, oxygen-enriched combustion, the
recirculation preserves the original heat transfer patterns, which
can be an important factor for boiler operation. The recirculated
flue gas flow rate can be decreased for higher recirculated gas
temperatures.
46. In many circumstances, it is important that the boiler operate
under basic design parameters such as a constant total gas flow
rate. In Table II, modeling results are shown for operation of a
boiler in accordance with the present invention using
oxygen-enriched air containing an oxygen concentration of about 23%
by volume without flue gas recirculation.
2TABLE II Oxygen-Enriched Parameter Air-Fuel Combustion Combustion
Flue gas mass flow rate 100% 100% Heat transfer to the load 100%
113% Fuel consumption 100% 109%
47. The modeling calculations shown in Table II indicate a 13%
increase in heat transfer to the load when using oxygen-enriched
combustion as compared to air combustion, while only increasing
fuel consumption by about 9%.
48. In accordance with the heat transfer improvement, flow pattern
and temperature profile preservation aspect of the invention, the
total of oxygen introduced into boiler 10 can be distributed
through the various introduction sites in radiation zone 12 and
convection zone 14. For example, where it is sought to maximize the
fuel savings in the operation of boiler 10, oxygen or
oxygen-enriched air can be introduced through oxidant lines 24, 28,
31 and 34. In a preferred embodiment, about 0% to about 80% of the
total oxygen is introduced through oxidant line 24, about 0% to
about 100% of the total oxygen is introduced through oxidant line
28, about 0% to about 50% of the total oxygen is introduced through
oxidant line 31 and about 0% to about 50% of the total oxygen is
introduced through oxidant line 34. Additionally, where increased
production of steam is sought, the total oxygen introduced into
boiler 10 can be distributed through oxidant lines 24, 28, 31 and
34. In a preferred embodiment, about 0% to about 100% is introduced
through oxidant line 24, about 0% to about 80% through oxidant line
28, about 0% to about 40% through oxidant line 31 and about 0% to
about 60% through oxidant line 34.
49. Where reduced NO.sub.x emissions are desired, the total oxygen
introduced into boiler 10 can be distributed by oxidant line 31 and
34. Preferably, about 50% to about 100% of the total oxygen can be
introduced through oxidant line 31 and about 0% to about 50% can be
introduced through oxidant line 34.
50. Where it is desired to operate boiler 10 with a low-calorie
fuel, the total oxygen in boiler 10 can be introduced by
distributing the oxygen through oxidant line 31, oxidant line 34
and oxygen-fuel burner 42. Preferably, about 0% to about 30% of the
total oxygen is introduced through oxidant line 31, about 0% to
about 20% through oxidant line 34 and about 0% to about 100%
through oxygen-fuel burner 42. In all the foregoing cases, the
total oxygen distributed through the various oxidant lines and in
the case of the use of low-calorie fuel, through the oxygen-fuel
burner equals 100% of the total oxygen introduced into boiler
10.
51. It is important to note that, although the foregoing oxygen
distribution methods address specific boiler operating goals, one
particular distribution method does not exclude the other operating
improvements. All the foregoing oxygen distribution methods can be
combined with flue gas recirculation such that flue gas flow rate
and heat transfer patterns remain relatively unchanged.
Additionally, as previously described, the flue gas recirculation
can be employed in both the radiation zone and the convection zone
for enhancing the heat transfer within boiler 10.
52. Thus, it is apparent that there has been disclosed, in
accordance with the invention, a method for operating a boiler
using oxygen-enriched oxidants that fully provides the advantages
set forth above. Although the invention has been described and
illustrated with reference to specific illustrative embodiments
thereof, it is not intended that the invention be limited to those
illustrative embodiments. Those skilled in the art will recognize
that variations and modifications can be made without departing
from the spirit of the invention. It is therefore intended to
include within the invention all such variations and modifications
as fall within the scope of the appended claims and equivalents
thereof.
* * * * *