EP0554254B1 - AN ADVANCED OVERFIRE AIR SYSTEM FOR NOx CONTROL - Google Patents
AN ADVANCED OVERFIRE AIR SYSTEM FOR NOx CONTROL Download PDFInfo
- Publication number
- EP0554254B1 EP0554254B1 EP91912984A EP91912984A EP0554254B1 EP 0554254 B1 EP0554254 B1 EP 0554254B1 EP 91912984 A EP91912984 A EP 91912984A EP 91912984 A EP91912984 A EP 91912984A EP 0554254 B1 EP0554254 B1 EP 0554254B1
- Authority
- EP
- European Patent Office
- Prior art keywords
- overfire air
- air
- fossil fuel
- furnace
- fuel
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Lifetime
Links
- 239000002803 fossil fuel Substances 0.000 claims description 50
- 238000002485 combustion reaction Methods 0.000 claims description 16
- 238000010304 firing Methods 0.000 abstract description 95
- 238000009826 distribution Methods 0.000 abstract description 28
- 239000007921 spray Substances 0.000 abstract description 14
- 230000002349 favourable effect Effects 0.000 abstract description 12
- 238000000034 method Methods 0.000 abstract description 9
- 239000000446 fuel Substances 0.000 description 123
- IJGRMHOSHXDMSA-UHFFFAOYSA-N Atomic nitrogen Chemical compound N#N IJGRMHOSHXDMSA-UHFFFAOYSA-N 0.000 description 22
- 238000002347 injection Methods 0.000 description 20
- 239000007924 injection Substances 0.000 description 20
- 230000009467 reduction Effects 0.000 description 17
- 238000006722 reduction reaction Methods 0.000 description 17
- 239000012530 fluid Substances 0.000 description 16
- 239000007789 gas Substances 0.000 description 16
- 239000003245 coal Substances 0.000 description 14
- QVGXLLKOCUKJST-UHFFFAOYSA-N atomic oxygen Chemical compound [O] QVGXLLKOCUKJST-UHFFFAOYSA-N 0.000 description 10
- 230000015572 biosynthetic process Effects 0.000 description 10
- 238000002156 mixing Methods 0.000 description 10
- 229910052757 nitrogen Inorganic materials 0.000 description 10
- 239000001301 oxygen Substances 0.000 description 10
- 229910052760 oxygen Inorganic materials 0.000 description 10
- 230000000694 effects Effects 0.000 description 7
- 230000008859 change Effects 0.000 description 6
- 238000010276 construction Methods 0.000 description 6
- 230000002829 reductive effect Effects 0.000 description 6
- 235000017899 Spathodea campanulata Nutrition 0.000 description 4
- 238000004519 manufacturing process Methods 0.000 description 4
- 239000000203 mixture Substances 0.000 description 4
- 238000010298 pulverizing process Methods 0.000 description 4
- 238000012360 testing method Methods 0.000 description 4
- OKTJSMMVPCPJKN-UHFFFAOYSA-N Carbon Chemical compound [C] OKTJSMMVPCPJKN-UHFFFAOYSA-N 0.000 description 3
- UGFAIRIUMAVXCW-UHFFFAOYSA-N Carbon monoxide Chemical compound [O+]#[C-] UGFAIRIUMAVXCW-UHFFFAOYSA-N 0.000 description 3
- MWUXSHHQAYIFBG-UHFFFAOYSA-N Nitric oxide Chemical compound O=[N] MWUXSHHQAYIFBG-UHFFFAOYSA-N 0.000 description 3
- 229910052799 carbon Inorganic materials 0.000 description 3
- 238000006243 chemical reaction Methods 0.000 description 3
- 239000000567 combustion gas Substances 0.000 description 3
- 239000003546 flue gas Substances 0.000 description 3
- 239000008246 gaseous mixture Substances 0.000 description 3
- 230000003647 oxidation Effects 0.000 description 3
- 238000007254 oxidation reaction Methods 0.000 description 3
- 235000019738 Limestone Nutrition 0.000 description 2
- 238000007792 addition Methods 0.000 description 2
- 239000002802 bituminous coal Substances 0.000 description 2
- 239000003054 catalyst Substances 0.000 description 2
- 238000010531 catalytic reduction reaction Methods 0.000 description 2
- 230000005611 electricity Effects 0.000 description 2
- 238000010438 heat treatment Methods 0.000 description 2
- 230000002452 interceptive effect Effects 0.000 description 2
- 239000006028 limestone Substances 0.000 description 2
- 230000007246 mechanism Effects 0.000 description 2
- 230000002441 reversible effect Effects 0.000 description 2
- 239000000725 suspension Substances 0.000 description 2
- 235000008733 Citrus aurantifolia Nutrition 0.000 description 1
- 235000011941 Tilia x europaea Nutrition 0.000 description 1
- 239000000809 air pollutant Substances 0.000 description 1
- 231100001243 air pollutant Toxicity 0.000 description 1
- 238000003915 air pollution Methods 0.000 description 1
- 238000007664 blowing Methods 0.000 description 1
- 150000001722 carbon compounds Chemical class 0.000 description 1
- 230000003111 delayed effect Effects 0.000 description 1
- 230000001419 dependent effect Effects 0.000 description 1
- 239000000295 fuel oil Substances 0.000 description 1
- 230000002401 inhibitory effect Effects 0.000 description 1
- 239000004571 lime Substances 0.000 description 1
- 239000010742 number 1 fuel oil Substances 0.000 description 1
- 239000002245 particle Substances 0.000 description 1
- 230000008569 process Effects 0.000 description 1
- 238000010791 quenching Methods 0.000 description 1
- 230000000171 quenching effect Effects 0.000 description 1
- 230000006798 recombination Effects 0.000 description 1
- 238000005215 recombination Methods 0.000 description 1
- 238000009420 retrofitting Methods 0.000 description 1
- 239000002893 slag Substances 0.000 description 1
- 239000004071 soot Substances 0.000 description 1
Images
Classifications
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F23—COMBUSTION APPARATUS; COMBUSTION PROCESSES
- F23C—METHODS OR APPARATUS FOR COMBUSTION USING FLUID FUEL OR SOLID FUEL SUSPENDED IN A CARRIER GAS OR AIR
- F23C7/00—Combustion apparatus characterised by arrangements for air supply
- F23C7/02—Disposition of air supply not passing through burner
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F23—COMBUSTION APPARATUS; COMBUSTION PROCESSES
- F23C—METHODS OR APPARATUS FOR COMBUSTION USING FLUID FUEL OR SOLID FUEL SUSPENDED IN A CARRIER GAS OR AIR
- F23C5/00—Disposition of burners with respect to the combustion chamber or to one another; Mounting of burners in combustion apparatus
- F23C5/08—Disposition of burners
- F23C5/32—Disposition of burners to obtain rotating flames, i.e. flames moving helically or spirally
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F23—COMBUSTION APPARATUS; COMBUSTION PROCESSES
- F23L—SUPPLYING AIR OR NON-COMBUSTIBLE LIQUIDS OR GASES TO COMBUSTION APPARATUS IN GENERAL ; VALVES OR DAMPERS SPECIALLY ADAPTED FOR CONTROLLING AIR SUPPLY OR DRAUGHT IN COMBUSTION APPARATUS; INDUCING DRAUGHT IN COMBUSTION APPARATUS; TOPS FOR CHIMNEYS OR VENTILATING SHAFTS; TERMINALS FOR FLUES
- F23L9/00—Passages or apertures for delivering secondary air for completing combustion of fuel
- F23L9/02—Passages or apertures for delivering secondary air for completing combustion of fuel by discharging the air above the fire
Definitions
- This invention relates to tangentially fired, fossil fuel furnaces, and more specifically, to overfire air systems for reducing the NO x emissions from tangentially fired, pulverized coal furnaces.
- Pulverized coal has been successfully burned in suspension in furnaces by tangential firing methods for a long time.
- the tangential firing technique involves introducing the fuel and air into a furnace from the four corners thereof so that the fuel and air are directed tangent to an imaginary circle in the center of the furnace.
- This type of firing has many advantages, among them being good mixing of the fuel and the air, stable flame conditions, and long residence time of the combustion gases in the furnaces.
- thermal NO x results from the thermal fixation of molecular nitrogen and oxygen in the combustion air.
- the rate of formation of thermal NO x is extremely sensitive to local flame temperature and somewhat less so to local concentration of oxygen.
- Virtually all thermal NO x is formed at the region of the flame which is at the highest temperature.
- the thermal NO x concentration is subsequently "frozen” at the level prevailing in the high temperature region by the thermal quenching of the combustion gases.
- the flue gas thermal NO x concentrations are, therefore, between the equilibrium level characteristic of the peak flame temperature and the equilibrium level at the flue gas temperature.
- fuel NO x derives from the oxidation of organically bound nitrogen in certain fossil fuels such as coal and heavy oil.
- the formation rate of fuel NO x is strongly affected by the rate of mixing of the fuel and air stream in general, and by the local oxygen concentration in particular.
- the flue gas NO x concentration due to fuel nitrogen is typically only a fraction, e.g., 20 to 60 percent, of the level which would result from complete oxidation of all nitrogen in the fuel. From the preceding it should thus now be readily apparent that overall NO x formation is a function both of local oxygen levels and of peak flame temperatures.
- auxiliary air is directed at a circle of larger diameter than that of the fuel, thus forming a layer of air adjacent the walls.
- overfire air consisting essentially of all of the excess air supplied to the furnace, is introduced into the furnace at a level considerably above all of the primary and auxiliary air introduction levels, with the overfire air being directed tangentially to an imaginary circle, and in a direction opposite to that of the auxiliary air.
- Patent Number 4,669,3908 an apparatus is provided which is characterized by a first pulverized fuel injection compartment in which the combined amount of primary air and secondary air to be consumed is less than the theoretical amount of air required for the combustion of the pulverized fuel to be fed as mixed with the primary air to a furnace, by a second pulverized fuel injection compartment in which the combined primary and secondary air amount is substantially equal to, or, preferably, somewhat less than, the theoretical air for the fuel to be fed as mixed with the primary air, and by a supplementary air compartment for injecting supplementary air into the furnace, the three compartments being arranged close to one another.
- the gaseous mixtures of primary air and pulverized fuel injected by the first and second pulverized fuel injection compartments of the apparatus are mixed in such proportions as to reduce the NO x production.
- the primary air-pulverized fuel mixture from the second pulverized fuel injection compartment which alone can hardly be ignited stably, is allowed to coexist with the flame of the readily ignitible mixture from the first pulverized fuel injection compartment to ensure adequate ignition and combustion.
- An apparatus is thus allegedly provided for firing pulverized fuel with stable ignition and low NO x production.
- the apparatus in accordance with the teachings of U. S. Patent Number 4,669,398 is characterized in that additional compartments for issuing an inert fluid are disposed, one for each, in spaces provided between the three compartments.
- the gaseous mixtures of primary air and pulverized fuel are thus kept from interfering with each other by a curtain of the inert fluid from one of the inert fluid injection compartments, and the production of NO x from the gaseous mixtures that are discharged from the first and second pulverized fuel injection compartments allegedly can be minimized.
- the primary air-pulverized fuel mixture from the first pulverized fuel injection compartment and the supplementary air from the supplementary air compartment are prevented from interfering with each other by another curtain of the inert fluid from another compartment. This allegedly permits the primary air-pulverized fuel mixture to burn without any change in the mixing ratio, thus avoiding any increase in the NO x production.
- the stream is separated into two portions, with one portion being a fuel rich portion and the other portion being a fuel lean portion.
- the fuel rich portion is introduced into the furnace in a first zone. Air is also introduced into the first zone in a quantity insufficient to support complete combustion of all of the fuel in the fuel rich portion.
- the fuel lean portion is introduced into the furnace in a second zone. Also, air is introduced into the second zone in a quantity such that there is excess air over that required for combustion of all of the fuel within the furnace.
- lime is introduced into the furnace simultaneously with the fuel so as to minimize the peak temperature within the furnace and so as to also minimize the formation of NO x and SO x in the combustion gases.
- overfire air The theory of NO x emissions reduction by overfire air is as follows. Operation with overfire air inhibits the rate of NO x formation by both atmospheric nitrogen fixation (thermal NO x ) and fuel nitrogen oxidation (fuel NO x ).
- the use of overfire air reduces the total oxygen available in the primary flame zone.
- fuel nitrogen undergoes a recombination reaction to form molecular nitrogen, N 2 , rather than nitrogen oxide, simply due to insufficient oxygen in this zone and the intense competition with carbon species for the available oxygen. Consequently, the formation of NO x through fuel nitrogen conversion is greatly reduced.
- overfire air operation results in reduction of thermal NO x formation through the temperature dependent Zeldovich mechanism.
- Heat release during the initial stages of combustion in the primary flame zone is somewhat reduced and delayed due to the reduced oxygen environment, with combustion ideally completed in the vicinity of the overfire air injection ports.
- the stretching of the heat release over a greater furnace volume results in lower peak combustion temperatures, thereby reducing thermal NO x formation.
- overfire air is through one or two closely grouped ports at a single fixed elevation at the top of the windbox, referred to as close-coupled overfire air, or at a higher elevation, referred to as separated overfire air.
- Experimental testing has shown a significant reduction in NO x with fossil fuel firing when, for a fixed total quantity of overfire air, the overfire air is introduced partly through close-couple overfire air ports and partly through separated overfire air ports.
- experimental testing has shown that there exists a most favorable distribution of overfire air between the close coupled overfire air ports and the separated overfire air ports. In the case of bituminous coal, for example, this most favorable distribution has 1/3 of the overfire air flowing through the close coupled overfire air ports and 2/3 of the overfire air flowing through the separated overfire air ports.
- overfire air is introduced into a furnace such that the air mixes with furnace gases in a controlled and thorough manner is also critical to maximizing overfire air effectiveness.
- Test data has shown that improvements in NO x emissions are attainable when the overfire air is injected from each furnace corner through two, three or more compartments with each compartment introducing a portion of the total overfire air flow at different firing angles such as to achieve a horizontal "spray” or “fan” distribution of air over the furnace plan area as compared to when other injection patterns are utilized for purposes of injecting the overfire air into the furnace.
- furnace outlet conditions are also improved inasmuch as a more uniform flame pattern is created at the vertical outlet plane of the furnace.
- All tangentially fired, fossil fuel furnaces have a nonuniform flow pattern in the convective pass due to the tangential lower furnace flow pattern. This nonuniform flow pattern results in more flow on one side than the other and creates a side-to-side imbalance in steam temperature.
- overfire air mixing with the furnace gases can be had by introducing the overfire air at high momentum.
- the overfire air is introduced at velocities significantly above those typically employed in prior art firing systems, e.g., 60 to 90 m./sec. (200 to 300 ft./sec.) versus 30 to 45 m./sec. (100 to 150 ft./sec.).
- a boost fan may be needed to attain these higher overfire air velocities.
- a firing system employing high momentum overfire air is found in US-A 4501 204.
- a firing system that introduces fuel and air into a tangentially fired pulverized coal furnace at a burner level and tangentially to an imaginary circle such that a resultant fireball moves upward within the furnace with a rotational spin.
- High pressure and low pressure overfire air is introduced into the furnace through horizontally and vertically tiltable nozzles above the fuel and air, tangential to an imaginary circle but in the reverse rotational direction to that of the fireball and with sufficient velocity so as to nullify the spin of the fireball.
- exhaust gases leaving the furnace flow in a straight line with little or no spin removing potential temperature imbalance problems.
- an advanced overfire air system for NO x control which is designed for use in a firing system of the type that is particularly suited for employment in fossil fuel-fired furnaces embodying a burner region.
- the subject advanced overfire air system includes multi-elevations of overfire air compartments. These multi-elevations of overfire air compartments consist of a plurality of close coupled overfire air compartments and a plurality of separated overfire air compartments.
- the plurality of close coupled overfire air compartments are suitably supported at a first elevation within the burner region of the furnace.
- a close coupled overfire air nozzle is supported in mounted relation within each of the plurality of close coupled overfire air compartments.
- the plurality of separated overfire air compartments are suitably supported at a second elevation within the burner region of the furnace so as to be spaced from but aligned with the plurality of close coupled overfire air compartments.
- a plurality of separated overfire air nozzles are supported in mounted relation within the plurality of separated overfire air compartments such that the plurality of separated overfire air nozzles extend at different angles relative to each other whereby the overfire air exiting therefrom establishes a horizontal "spray” or "fan” distribution of overfire air over the plan area of the burner region of the furnace.
- An overfire air supply means is operatively connected to both the close coupled overfire air nozzles and to the separated overfire air nozzles for supplying overfire air thereto in accordance with a predetermined most favorable distribution of overfire air therebetween and for supplying overfire air through the separated overfire air nozzles into the burner region of the furnace at velocities significantly higher than the velocities employed heretodate in prior art firing systems to inject overfire air into a furnace.
- a firing system generally designated by the reference numeral 12 in Figure 1 of the drawing, embodying an advanced overfire air system, generally designated by the reference numeral 14 in Figure 1 of the drawing, constructed in accordance with the present invention such that in accordance with the present invention the advanced overfire air system 14 is capable of being installed in the furnace 10 as part of the firing system 12 and when so installed therein is operative for reducing the NO x emissions from the fossil fuel-fired furnace 10, it is deemed to be sufficient that there be presented herein merely a description of the nature of the components of the fossil fuel-fired furnace 10 with which the aforesaid firing system 12 and the aforesaid advanced overfire air system 14 cooperate.
- the fossil fuel-fired furnace 10 as illustrated therein includes a burner region, generally designated by the reference numeral 16. As will be described more fully hereinafter in connection with the description of the nature of the construction and the mode of operation of the firing system 12 and of the advanced overfire air system 14, it is within the burner region 16 of the fossil fuel-fired furnace 10 that in a manner well-known to those skilled in this art combustion of the fossil fuel and air is initiated.
- the hot gases that are produced from combustion of the fossil fuel and air rise upwardly in the fossil fuel-fired furnace 10.
- the hot gases in a manner well-known to those skilled in this art give up heat to the fluid flowing through the tubes (not shown in the interest of maintaining clarity of illustration in the drawing) that in conventional fashion line all four of the walls of the fossil fuel-fired furnace 10. Then, the hot gases exit the fossil fuel-fired furnace 10 through the horizontal pass, generally designated by the reference numeral 18, of the fossil fuel-fired furnace 10, which in turn leads to the rear gas pass, generally designated by the reference numeral 20, of the fossil fuel-fired furnace 10. Both the horizontal pass 18 and the rear gas pass 20 commonly contain other heat exchanger surface (not shown) for generating and super heating steam, in a manner well-known to those skilled in this art.
- the steam commonly is made to flow to a turbine (not shown), which forms one component of a turbine/generator set (not shown), such that the steam provides the motive power to drive the turbine (not shown) and thereby also the generator (not shown), which in known fashion is cooperatively associated with the turbine (not shown), such that electricity is thus produced from the generator (not shown).
- the advanced overfire air system 14 is designed to be utilized in a firing system, such as the firing system 12, so that when the firing system 12 in turn is utilized in a furnace, such as the fossil fuel-fired furnace 10 of Figure 2 of the drawing, the advanced overfire air system 14 is operative to reduce the NO x emissions from the fossil fuel-fired furnace 10.
- the firing system 12 includes a housing preferably in the form of a windbox denoted by the reference numeral 22 in Figures 1 and 2 of the drawing.
- the windbox 22 in a manner well-known to those skilled in this art is supported by conventional support means (not shown) in the burner region 16 of the fossil fuel-fired furnace 10 such that the longitudinal axis of the windbox 22 extends substantially in parallel relation to the longitudinal axis of the fossil fuel-fired furnace 10.
- a first air compartment denoted generally by the reference numeral 24 in Figure 2 of the drawing, is provided at the lower end of the windbox 22.
- An air nozzle denoted by the reference numeral 26, is supported in mounted relation, through the use of any conventional form of mounting means (not shown) suitable for use for such a purpose, within the air compartment 24.
- An air supply means which is illustrated schematically in Figure 1 of the drawing wherein the air supply means is denoted generally by the reference numeral 28, is operatively connected in a manner to be more fully described hereinafter to the air nozzle 26 whereby the air supply means 28 supplies air to the air nozzle 26 and therethrough into the burner region 16 of the fossil fuel-fired furnace 10.
- the air supply means 28 includes a fan seen at 30 in Figure 1 of the drawing, and the air ducts denoted by the reference numeral 32 which are connected in fluid flow relation to the fan 30 on the one hand and on the other hand, as seen schematically at 34 in Figure 1 of the drawing, to the air nozzle 26 through separate valves and controls (not shown).
- a first fuel compartment denoted generally by the reference numeral 36 in Figure 2 of the drawing, is provided in the windbox 22 within the lower portion thereof such as to be located substantially in juxtaposed relation to the air compartment 24.
- a first fuel nozzle denoted by the reference numeral 38 in Figure 2 of the drawing, is supported in mounted relation, through the use of any conventional form of mounting means (not shown) suitable for use for such a purpose, within the fuel compartment 36.
- a fuel supply means which is illustrated schematically in Figure 1 of the drawing wherein the fuel supply means is denoted generally by the reference numeral 40, is operatively connected in a manner to be more fully described hereinafter to the fuel nozzle 38 whereby the fuel supply means 40 supplies fuel to the fuel nozzle 38 and therethrough into the burner region 16 of the fossil fuel-fired furnace 10.
- the fuel supply means 40 includes a pulverizer, seen at 42 in Figure 1 of the drawing, wherein the fossil fuel that is to be burned in the fossil fuel-fired furnace 10 undergoes pulverization in a manner well-known to those skilled in this art, and the fuel ducts, denoted by the reference numeral 44, which are connected in fluid flow relation to the pulverizer 42 on the one hand and on the other hand, as seen schematically at 46 in Figure 1 of the drawing, to the fuel nozzle 38 through separate valves and controls (not shown).
- the pulverizer 42 is operatively connected to the fan 30 such that air is also supplied from the fan 30 to the pulverizer 42 whereby the fuel supplied from the pulverizer 42 to the fuel nozzle 38 is transported through the fuel ducts 44 in an air stream in a manner which is well-known to those skilled in this art.
- the windbox 22 is also provided with a second air compartment, denoted generally by the reference numeral 48 in Figure 2 of the drawing.
- the air compartment 48 as best understood with reference to Figure 2 of the drawing, is provided in the windbox 22 such as to be located substantially in juxtaposed relation to the fuel compartment 36.
- the air nozzle 50 is operatively connected to the air supply means 28, the latter having been described herein previously, through the air ducts 32, which as best understood with reference to Figure 1 of the drawing are connected in fluid flow relation to the fan 30 on the one hand and on the other hand, as seen schematically at 52 in Figure 1 of the drawing, to the air nozzle 50 through separate valves and controls (not shpwn) whereby the air supply means 28 supplies air to the air nozzle 50 and therethrough into the burner region 16 of the fossil fuel-fired furnace 10 in the same manner as that which has been described herein previously in connection with the discussion hereinbefore of the air nozzle 26.
- a second fuel compartment denoted generally by the reference numeral 54 in Figure 2 of the drawing, is provided in the windbox 22 such as to be located substantially in juxtaposed relation to the air compartment 48.
- a second fuel nozzle denoted generally by the reference numeral 56 in Figure 2 of the drawing, is supported in mounted relation, through the use of any conventional form of mounting means (not shown) suitable for use for such a purpose, within the fuel compartment 54.
- the fuel nozzle 56 is operatively connected to the fuel supply means 40, the latter having been described previously herein, through the fuel ducts 44, which as best understood with reference to Figure 1 of the drawing, are connected in fluid flow relation on the one hand to the pulverizer 42 wherein the fossil fuel that is to be burned in the fossil fuel-fired furnace 10 undergoes pulverization in a manner well-known to those skilled in the art, and on the other hand, as seen schematically at 58 in Figure 1 of the drawing, to the fuel nozzle 56 through separate valves and controls (not shown) whereby the fuel supply means 40 supplies fuel to the fuel nozzle 56 and therethrough into the burner region 16 of the fossil fuel-fired furnace 10 in the same manner as that which has been described herein previously in connection with the discussion hereinbefore of the fuel nozzle 38.
- the pulverizer 42 is operatively connected to the fan 30 such that air is also supplied from the fan 30 to the pulverizer 42 whereby the fuel supplied from the pulverizer 42 to the fuel compartment 54 is transported through the fuel ducts 44 in an air stream in a manner which is well-known to those skilled in the art.
- a third air compartment denoted generally by the reference numeral 60 in Figure 2 of the drawing.
- the air compartment 60 as best understood with reference to Figure 2 of the drawing, is provided in the windbox 22 such as to be located substantially in juxtaposed relation to the fuel compartment 54.
- An air nozzle denoted by the reference numeral 62 in Figure 2 of the drawing, is supported in mounted relation, through the use of any conventional form of mounting means (not shown) suitable for use for such a purpose, within the air compartment 60.
- the air nozzle 62 is operatively connected to the air supply means 28, the latter having been described herein previously, through the air ducts 32, which as best understood with reference to Figure 1 of the drawing are connected in fluid flow relation to the fan 30 on the one hand and on the other hand, as seen schematically at 64 in Figure 1 of the drawing, to the air nozzle 62 through separate valves and controls (not shown) whereby the air supply means 28 supplies air to the air nozzle 62 and therethrough into the burner region 16 of the fossil fuel-fired furnace 10 in the same manner as that which has been described herein previously in connection with the discussion hereinbefore of the air nozzles 26 and 50.
- the firing system 12 in accordance with the embodiment thereof illustrated in Figures 1 and 2 of the drawing, further includes a third fuel compartment, denoted generally by the reference numeral 66 in Figure 2 of the drawing.
- the fuel compartment 66 is provided in the windbox 22 such as to be located substantially in juxtaposed relation to the air compartment 60.
- a third fuel nozzle, denoted by the reference numeral 68 in Figure 2 of the drawing, is supported in mounted relation, through the use of any conventional form of mounting means (not shown) suitable for use for such a purpose, within the fuel compartment 66.
- the fuel nozzle 68 is operatively connected to the fuel supply means 40, the latter having been described previously herein, through the fuel ducts 44, which as best understood with reference to Figure 1 of the drawing are connected in fluid flow relation on the one hand to the pulverizer 42 wherein the fossil fuel that is to be burned in the fossil fuel-fired furnace 10 undergoes pulverization in a manner well-known to those skilled in the art, and on the other hand as seen schematically at 70 in Figure 1 of the drawing to the fuel nozzle 68 through separate valves and controls (not shown) whereby the fuel supply means 40 supplies fuel to the fuel nozzle 68 and therethrough into the burner region 16 of the fossil fuel-fired furnace 10 in the same manner as that which has been described herein previously in connection with the discussion hereinbefore of the fuel nozzles 38 and 56.
- the pulverizer 42 as can be seen with reference to Figure 1 of the drawing is operatively connected to the fan 30 such that air is also supplied from the fan 30 to the pulverizer 42 whereby the fuel supplied from the pulverizer 42 to the fuel compartment 66 is transported through the fuel ducts 44 in an air stream in a manner well-known to those skilled in the art.
- a fourth air compartment denoted generally by the reference numeral 72 in Figure 2 of the drawing.
- the fourth air compartment 72 is provided in the windbox 22 such as to be located substantially in juxtaposed relation to the fuel compartment 66.
- a fourth air nozzle denoted by the reference numeral 74 in Figure 2 of the drawing, is supported in mounted relation, through the use of any conventional form of mounting means (not shown) suitable for use for such a purpose, within the air compartment 72.
- the air nozzle 74 is operatively connected to the air supply means 28, the latter having been described herein previously, through the air ducts 32, which as best understood with reference to Figure 1 of the drawing are connected in fluid flow relation to the fan 30 on the one hand and on the other hand, as seen schematically at 76 in Figure 1 of the drawing, to the air nozzle 74 through separate valves and controls (not shown) whereby the air supply means 28 supplies air to the air nozzle 74 and therethrough into the burner region 16 of the fossil fuel-fired furnace 10 in the same manner as that which has been described herein previously in connection with the discussion hereinbefore of the air nozzles 26,50 and 62.
- a fourth fuel compartment denoted generally by the reference numeral 78 in Figure 2 of the drawing, is provided in the windbox 22 such as to be located substantially in juxtaposed relation to the air compartment 72.
- a fourth fuel nozzle denoted by the reference numeral 80 in Figure 2 of the drawing, is supported in mounted relation, through the use of any conventional form of mounting means (not shown) suitable for use for such a purpose, within the fuel compartment 78.
- the fuel nozzle 80 is operatively connected to the fuel supply means 40, the latter having been described previously herein, through the fuel ducts 44, which as best understood with reference to Figure 1 of the drawing are connected in fluid flow relation on the one hand to the pulverizer 42 wherein the fossil fuel that is to be burned in the fossil fuel-fired furnace 10 undergoes pulverization in a manner well-known to those skilled in the art, and on the other hand as seen schematically at 82 in Figure 1 of the drawing to the fuel nozzle 80 through separate valves and controls (not shown) whereby the fuel supply means 40 supplies fuel to the fuel nozzle 80 and therethrough into the burner region 16 of the fossil fuel-fired furnace 10 in the same manner as that which has been described herein previously in connection with the discussion hereinbefore of the fuel nozzles 38,56 and 68.
- the pulverizer 42 is operatively connected to the fan 30 such that air is also supplied from the fan 30 to the pulverizer 42 whereby the fuel supplied from the pulverizer 42 to the fuel compartment 78 is transported through the fuel ducts 44 in an air stream in a manner well-known to those skilled in the art.
- the advanced overfire air system 14 in accordance with the present invention includes a pair of close coupled overfire air compartments, denoted generally by the reference numerals 84 and 86, respectively, in Figure 2 of the drawing.
- the close coupled overfire air compartments 84 and 86 are provided in the windbox 22 of the firing system 12 within the upper portion of the windbox 22 such as to be located substantially in juxtaposed relation to the air compartment 78, the latter having been the subject of discussion hereinbefore.
- a pair of close coupled overfire air nozzles denoted by the reference numerals 88 and 90, respectively, in Figure 2 of the drawing, are supported in mounted relation, through the use of any conventional form of mounting means (not shown) suitable for use for such a purpose, within the pair of close coupled overfire air compartments such that the close coupled overfire air nozzle 88 is mounted in the close coupled overfire air compartment 84 and the close coupled overfire air nozzle 90 is mounted in the close coupled overfire air compartment 86.
- the close coupled overfire air nozzles 88 and 90 are each operatively connected to the air supply means 28, the latter having been described herein previously, through the air ducts 32, which as best understood with reference to Figure 1 of the drawing are connected in fluid flow relation to the fan 30 on the one hand and on the other hand as seen schematically at 92 in Figure 1 of the drawing to each of the close coupled overfire air nozzles 88 and 90 through separate valves and controls (not shown) whereby the air supply means 28 supplies air to each of the close coupled overfire air nozzles 88 and 90 and therethrough into the burner region 16 of the fossil fuel-fired furnace 10.
- the advanced overfire air system 14 further includes a plurality of separated overfire air compartments, which are suitably supported, through the use of any conventional form of support means (not shown) suitable for use for such a purpose, within the burner region 16 of the furnace 10 so as to be spaced from the close coupled overfire air compartments 84 and 86, and so as to be substantially aligned with the longitudinal axis of the windbox 22.
- the aforementioned plurality of separated overfire air compartments in accordance with the preferred embodiment of the invention, comprises in number three such compartments, which are denoted generally in Figure 2 of the drawing by the reference numerals 94,96 and 98, respectively.
- a plurality of separated overfire air nozzles are supported in mounted relation, through the use of any conventional form of mounting means (not shown) suitable for use for such a purpose, within the plurality of separated overfire air compartments 94,96 and 98 such that the separated overfire air nozzle 100 is mounted for both the vertical (tilting) and horizontal (yaw) movement in the separated overfire air compartment 94, the separated overfire air nozzle 102 is mounted for both vertical (tilting) and horizontal (yaw) movement in the separated overfire air compartment 96, and the separated overfire air nozzle 104 is mounted for both vertical (tilting) and horizontal (yaw) movement in the separated overfire air compartment 98.
- the plurality of separated overfire air nozzles 100,102 and 104 are each operatively connected to the air supply means 28, the latter having been described herein previously, through the air ducts 32, which as best understood with reference to Figure 1 of the drawing are connected in fluid flow relation to the fan 30 on the one hand and on the other hand as seen schematically at 106 in Figure 1 of the drawing to each of the separated overfire air nozzles 100,102 and 104 through separate valves and controls (not shown) whereby the air supply means 28 supplies air to each of the separated overfire air nozzles 100,102 and 104 and therethrough into the burner region 16 of the fossil fuel-fired furnace 10.
- air is introduced into the burner region 16 of the fossil fuel-fired furnace 10 through the air compartments 24,48,60 and 72
- fossil fuel is introduced into the burner region 16 of the fossil fuel-fired furnace 10 through the fossil fuel compartments 36,54,66 and 78.
- combustion of the fossil fuel that is introduced thereinto through the fossil fuel compartments 36,54,66 and 78 and of the air that is introduced thereinto through the air compartments 24,48,60 and 72 is initiated in the burner region 16 of the fossil fuel-fired furnace 10 combustion of the fossil fuel that is introduced thereinto through the fossil fuel compartments 36,54,66 and 78 and of the air that is introduced thereinto through the air compartments 24,48,60 and 72.
- the hot gases give up heat in a manner well-known to those skilled in this art to the fluid flowing through the tubes (not shown) that in conventional fashion line all four of the walls of the fossil fuel-fired furnace 10.
- these hot gases exit the fossil fuel-fired furnace 10 through the horizontal pass 18 of the fossil fuel-fired furnace 10, which in turn leads to the rear gas pass 20 of the fossil fuel-fired furnace 10.
- the horizontal pass 18 and the rear gas pass 20 commonly each contain other heat exchanger surface (not shown) for generating and super heating steam, in a manner well-known to those skilled in this art. Thereafter, this steam commonly is made to flow to a turbine (not shown), which forms one component of a turbine/generator set (not shown), such that the steam provides the motive power to drive the turbine (not shown) and thereby also the generator (not shown), which in known fashion is cooperatively associated with the turbine (not shown), such that electricity is thus produced from the generator (not shown).
- the objective sought to be achieved through the use thereof is that of inhibiting the rate of NO x formation by both atmospheric nitrogen fixation (thermal NO x ) and fuel nitrogen (fuel NO x ). This is accomplished by reducing the total oxygen that is available in the primary flame zone.
- overfire air is introduced through one or two closely grouped compartments at a single fixed elevation of the burner region 16 of the fossil fuel-fired furnace 10 at the top of the windbox 22, and through one or more additional compartments located at a higher elevation.
- the overfire air is introduced into the burner region 16 of the fossil fuel-fired furnace 10 partly through the close coupled overfire air compartments 84 and 86 and partly through the separated overfire air compartments 94,96 and 98 such that there exists a predetermined most favorable distribution of the overfire air between close coupled overfire air and separated overfire air.
- Figure 3 is a graphical depiction of the effect on NO x when using an advanced overfire air system constructed in accordance with the present invention wherein there is a predetermined apportionment of the overfire air between close coupled overfire air and separated overfire air.
- the line denoted by the reference numeral 108 in Figure 3 represents a baseline plot of the NO x ppm levels from a furnace, such as the fossil fuel-fired furnace 10, when operating with a firing system, such as the firing system 12.
- the line denoted by the reference numeral 110 in Figure 3 represents a plot of the NO x ppm levels from a furnace, such as the fossil fuel-fired furnace 10, when operating with a firing system, such as the firing system 12, and with 0% overfire air.
- the line denoted therein by the reference numeral 112 represents a plot of the NO x ppm levels from a furnace, such as the fossil fuel-fired furnace 10, when operating with 20% overfire air and wherein all 20% of the overfire air is introduced into the furnace as close coupled overfire.
- the line denoted in Figure 3 by the reference numeral 114 represents a plot of the NO x ppm levels from a furnace, such as the fossil fuel-fired furnace 10, when operating with 20% overfire air and wherein all 20% of the overfire air is introduced into the furnace as separated overfire air.
- the point denoted therein by the reference numeral 116 is a plot of the NO x ppm level from a furnace, such as the fossil fuel-fired furnace 10, when operating with a firing system 12 with which an advanced overfire air system 14 constructed in accordance with the present invention is cooperatively associated and with 20% overfire air, and wherein of the 20% overfire air in accordance with a most favorable distribution thereof 9% of this overfire air is introduced as close coupled overfire air and 11% of the overfire air is introduced as separated overfire air.
- a second characteristic which the advanced overfire air system 14 embodies in accordance with the present invention is that the separated overfire air is injected into the burner region 16 of the fossil fuel-fired furnace 10 from each of the four corners thereof through a plurality, e.g., two, three or more compartments with each compartment introducing a portion of the total separated overfire air flow at different firing angles, which angles are established by moving the separated overfire air nozzles 94,96 and 98 vertically (tilting) and/or horizontally (yawing), such as to achieve a horizontal "spray” or "fan” distribution of separated overfire air over the furnace plan area.
- the four corners 10a,10b,10c and 10d of the fossil fuel-fired furnace 10 are each provided with separated overfire air compartments 94,96 and 98.
- the separated overfire air that is injected into the burner region 16 of the fossil fuel-fired furnace 10 from each of the four corners 10a,10b,10c and 10d thereof through the separated overfire air compartments 94,96 and 98 located thereat is injected at a different firing angle, the latter being denoted in Figure 4 by means of the reference numerals 118,120 and 122, respectively, and wherein for ease of reference the same numerals are utilized in connection with each of the four corners 10a,10b,10c and 10d of the fossil fuel-fired furnace 10.
- the injection into the burner region 16 of the fossil fuel-fired furnace 10 at the different firing angles denoted by the reference numerals 118,120 and 122 in Figure 4 has the effect of producing a horizontal "spray” or "fan” distribution of the separated overfire air over the furnace plan area.
- the separated overfire air that is injected into the burner region 16 of the fossil fuel-fired furnace 10 at each of the different firing angles 118,120 and 122 follows the path denoted by the reference numerals 124,126 and 128, respectively.
- Figure 5 is a graphical depiction of the effect on NO x of using an advanced overfire air system constructed in accordance with the present invention wherein the overfire air is distributed in accordance with the horizontal "spray" or "fan” distribution pattern illustrated in Figure 4.
- the point denoted therein by the reference numeral 130 is a plot of the NO x ppm level from a furnace, such as the fossil fuel-fired furnace 10, when operating with a firing system, such as the firing system 12, and wherein all of the separated overfire air that is injected through the separated overfire air compartments is injected into the burner region 16 of the fossil fuel-fired furnace 10 at the same firing angle, i.e., at an angle of +15° such that the separated overfire air is injected so as to be co-rotational with the fuel and air that is being injected into the burner region 16 of the fossil fuel-fired furnace 10 through the fuel compartments 38,54,66 and 78 and the air compartments 24,48,60 and 72, respectively.
- the point denoted in Figure 5 by the reference numeral 132 is a plot of the NO x ppm level from a furnace, such as the fossil fuel-fired furnace 10, when operating with a firing system, such as the firing system 12, and wherein all of the separated overfire air that is injected through the separated overfire air compartment is injected into the burner region 16 of the fossil fuel-fired furnace 10 at the same firing angle, i.e, at an angle of -15° such that the separated overfire air is injected so as to be counter rotational with the fuel and air that is being injected into the burner region 16 of the fossil fuel-fired furnace 10 through the fuel compartments 38,54,66 and 78 and the air compartments 24,48,60 and 72, respectively.
- the point denoted therein by the reference numeral 134 is a plot of the NO x ppm level from a furnace, such as the fossil fuel-fired furnace 10, when operating with a firing system 12 with which an advanced overfire air system 14 constructed in accordance with the present invention is cooperatively associated and wherein all of the separated overfire air is injected through each of the separated overfire air compartments 94,96 and 98 at a different firing angle such that the horizontal "spray” or "fan” distribution of separated overfire air that is depicted in Figure 4 of the drawing is achieved over the furnace plan area.
- the firing angles that are employed for this purpose for the separated overfire air compartments 94,96 and 98 are +15°, 0° and -15°.
- a third characteristic which the advanced overfire air system 14 embodies in accordance with the present invention is that the separated overfire air is injected into the burner region 16 of the fossil fuel-fired furnace 10 at velocities significantly higher than those utilized heretofore in prior art firing systems, e.g., 200 to 300 ft./sec. versus 100 to 150 ft./sec.
- the advantages that accrue from the injection of the separated overfire air at such increased velocities are best understood with reference to Figure 6 of the drawing.
- Figure 6 is a graphical depiction of the effect on NO x of using an advanced overfire air system constructed in accordance with the present invention wherein the overfire air is injected into the furnace at high velocities.
- the line denoted by the reference numeral 136 in Figure 6 represents a plot of the NO x ppm levels from a furnace, such as the fossil fuel-fired furnace 10, when operating with a firing system, such as the firing system 12 and wherein the overfire air is injected at low velocities, i.e., at the velocities commonly utilized heretofore in prior art firing systems.
- the line denoted by the reference numeral 138 in Figure 6 represents a plot of the NO x ppm levels from a furnace, such as the fossil fuel-fired furnace 10, when operating with a firing system 12 with which an advanced overfire air system 14 constructed in accordance with the present invention is cooperatively associated and wherein the separated overfire air injected into the burner region 16 of the fossil fuel-fired furnace 10 through the separated overfire air compartments 94,96 and 98 is injected at velocities significantly higher than those utilized heretofore in prior art firing systems, e.g., 200 to 300 ft./sec. versus 100 to 150 ft./sec.
- a new and improved advanced overfire air system for NO x control which is designed for use in a firing system of the type that is employed in fossil fuel-fired furnaces.
- an advanced overfire air system for NO x control that is designed for use in a firing system of the type that is employed in tangentially fired, fossil fuel furnaces.
- an advanced overfire air system for NO x control for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces such that through the use thereof NO x emissions are capable of being reduced to levels that are at least equivalent to, if not better than, that which is currently being contemplated as the standard for the United States in the legislation being proposed.
- an advanced overfire air system for NO x control that is designed for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces characterized in that the advanced overfire air system involves the use of multi-elevations of overfire air compartments consisting of close coupled overfire air compartments and separated overfire air compartments.
- an advanced overfire air system for NO x control that is designed for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces and which is characterized in that there is a predetermined most favorable distribution of overfire air between the close coupled overfire air compartments and the separated overfire air compartments.
- an advanced overfire air system for NO x control that is designed for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces and which is characterized in that the advanced overfire air system involves the use of a multi-angle injection pattern.
- an advanced overfire air system for NO x control that is designed for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces and which is characterized in that in accordance with the multi-angle injection pattern thereof a portion of the total overfire air flow is introduced at different angles such as to achieve a horizontal "spray” or "fan” distribution of overfire air over the plan area of the furnace.
- an advanced overfire air system for NO x control that is designed for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces and which is characterized in that the advanced overfire air system involves the injection of overfire air into the furnace at velocities significantly higher than those utilized heretofore in prior art firing systems.
- an advanced overfire air system for NO x control that is designed for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces such that through the use thereof no additions, catalysts or added premium fuel costs are needed for the operation thereof.
- an advanced overfire air system for NO x control that is designed for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces and which is characterized in that the advanced overfire air system is totally compatible with other emission reduction-type systems such as limestone injection systems, reburn systems and selective catalytic reduction (SCR) systems that one might seek to employ in order to accomplish additional emission reduction.
- an advanced overfire air system for NO x control that is designed for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces and which is characterized in that the advanced overfire air system is equally well suited for use either in new applications or in retrofit applications.
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Abstract
Description
- This invention relates to tangentially fired, fossil fuel furnaces, and more specifically, to overfire air systems for reducing the NOx emissions from tangentially fired, pulverized coal furnaces.
- Pulverized coal has been successfully burned in suspension in furnaces by tangential firing methods for a long time. The tangential firing technique involves introducing the fuel and air into a furnace from the four corners thereof so that the fuel and air are directed tangent to an imaginary circle in the center of the furnace. This type of firing has many advantages, among them being good mixing of the fuel and the air, stable flame conditions, and long residence time of the combustion gases in the furnaces.
- Recently though, more and more emphasis has been placed on the minimization as much as possible of air pollution. To this end, most observers in the United States expect the U. S. Congress to enact comprehensive air emission reduction legislation by no later than the end of 1990. The major significance that such legislation will have is that it will be the first to mandate the retrofitting of NOx and SOx controls on existing fossil fuel fired units. Heretofore, prior laws have only dealt with the new construction of units.
- With further reference in particular to the matter of NOx control, it is known that oxides of nitrogen are created during fossil fuel combustion by two separate mechanisms which have been identified to be thermal NOx and fuel NOx. Thermal NOx results from the thermal fixation of molecular nitrogen and oxygen in the combustion air. The rate of formation of thermal NOx is extremely sensitive to local flame temperature and somewhat less so to local concentration of oxygen. Virtually all thermal NOx is formed at the region of the flame which is at the highest temperature. The thermal NOx concentration is subsequently "frozen" at the level prevailing in the high temperature region by the thermal quenching of the combustion gases. The flue gas thermal NOx concentrations are, therefore, between the equilibrium level characteristic of the peak flame temperature and the equilibrium level at the flue gas temperature.
- On the other hand, fuel NOx derives from the oxidation of organically bound nitrogen in certain fossil fuels such as coal and heavy oil. The formation rate of fuel NOx is strongly affected by the rate of mixing of the fuel and air stream in general, and by the local oxygen concentration in particular. However, the flue gas NOx concentration due to fuel nitrogen is typically only a fraction, e.g., 20 to 60 percent, of the level which would result from complete oxidation of all nitrogen in the fuel. From the preceding it should thus now be readily apparent that overall NOx formation is a function both of local oxygen levels and of peak flame temperatures.
- Continuing, some changes have been proposed to be made in the standard tangential firing technique. These changes have been proposed primarily in the interest of achieving an even better reduction of emissions through the use thereof. One such change resulted in the arrangement that was the subject matter of U. S. patent application, serial number 786,437, now abandoned, entitled "A Control System And Method For Operating A Tangentially Fired Pulverized Coal Furnace", which was filed on October 11, 1985 and which was assigned to the same assignee as the present patent application. In accordance with the teachings of the aforesaid U. S. patent application, it was proposed to introduce pulverized coal and air tangentially into the furnace from a number of lower burner levels in one direction, and to introduce coal and air tangentially into the furnace from a number of upper burner levels in the opposite direction. As a consequence of utilizing this type of arrangement, it was alleged that better mixing of the fuel and air was accomplished, thus permitting the use of less excess air than with a normal tangentially fired furnace, which, as is well-known to those skilled in the art, is generally fired with 20-30% excess air. The reduction in excess air helps minimize the formation of NOx which, as noted previously herein, is a major air pollutant of coal-fired furnaces. It also results in increased efficiency of the unit. Although the firing technique to which the aforesaid U. S. patent application was directed reduces NOx, there were some disadvantages associated therewith. Namely, since the reverse rotation of the gases in the furnace cancel each other out, the gases flow in a more or less straight line through the upper portion of the furnace, thereby increasing the possibility of unburned carbon particles leaving the furnace due to reduced upper furnace turbulence and mixing. In addition, slag and unburned carbon deposits on the furnace walls can occur. These wall deposits reduce the efficiency of heat transfer to the water-cooled tubes lining the walls, increases the need for soot blowing, and reduces the life span of the tubes.
- Another such change resulted in the arrangement that forms the subject matter of U. S. Patent Number 4,715,301 entitled "Low Excess Air Tangential Firing System", which issued on December 29, 1987 and which is assigned to the same assignee as the present patent application. In accordance with the teachings of U. S. Patent Number 4,715,301, a furnace is provided in which pulverized coal is burned in suspension with good mixing of the coal and air, as in the case of the now abandoned U. S. patent application, which has been the subject of discussion hereinabove. Furthermore, all of the advantages previously associated with tangentially fired furnaces are obtained, by having a swirling, rotating fireball in the furnace. The walls are protected by a blanket of air, reducing slagging thereof. This is accomplished by introducing coal and primary air into the furnace tangentially at a first level, introducing auxiliary air in an amount at least twice that of the primary air into the furnace tangentially at a second level directly above the first level, but in a direction opposite to that of the primary air, with there being a plurality of such first and second levels, one above the other. As a result of the greater mass and velocity of the auxiliary air, the ultimate swirl within the furnace will be in the direction of the auxiliary air introduction. Because of this, the fuel, which is introduced in a direction counter to the swirl of the furnace, is forced after entering the unit, to change direction to that of the overall furnace gases. Tremendous turbulent mixing between the fuel and air is thus created in this process. This increased mixing reduces the need for high levels of excess air within the furnace. This increase mixing also results in enhanced carbon conversion which improves the unit's overall heat release rate while at the same time reducing upper furnace slagging and fouling. The auxiliary air is directed at a circle of larger diameter than that of the fuel, thus forming a layer of air adjacent the walls. In addition, overfire air, consisting essentially of all of the excess air supplied to the furnace, is introduced into the furnace at a level considerably above all of the primary and auxiliary air introduction levels, with the overfire air being directed tangentially to an imaginary circle, and in a direction opposite to that of the auxiliary air.
- Yet another such change resulted in the arrangement for firing pulverized coal as a fuel with low NOx emissions that forms the subject matter of U. S. Patent Number 4,669,398, entitled "Pulverized Fuel Firing Apparatus", and which issued on June 2, 1987. In accordance with the teachings of U. S. Patent Number 4,669,398, an apparatus is provided which is characterized by a first pulverized fuel injection compartment in which the combined amount of primary air and secondary air to be consumed is less than the theoretical amount of air required for the combustion of the pulverized fuel to be fed as mixed with the primary air to a furnace, by a second pulverized fuel injection compartment in which the combined primary and secondary air amount is substantially equal to, or, preferably, somewhat less than, the theoretical air for the fuel to be fed as mixed with the primary air, and by a supplementary air compartment for injecting supplementary air into the furnace, the three compartments being arranged close to one another. The gaseous mixtures of primary air and pulverized fuel injected by the first and second pulverized fuel injection compartments of the apparatus are mixed in such proportions as to reduce the NOx production. Moreover, the primary air-pulverized fuel mixture from the second pulverized fuel injection compartment, which alone can hardly be ignited stably, is allowed to coexist with the flame of the readily ignitible mixture from the first pulverized fuel injection compartment to ensure adequate ignition and combustion. An apparatus is thus allegedly provided for firing pulverized fuel with stable ignition and low NOx production.
- Secondly, the apparatus in accordance with the teachings of U. S. Patent Number 4,669,398 is characterized in that additional compartments for issuing an inert fluid are disposed, one for each, in spaces provided between the three compartments. The gaseous mixtures of primary air and pulverized fuel are thus kept from interfering with each other by a curtain of the inert fluid from one of the inert fluid injection compartments, and the production of NOx from the gaseous mixtures that are discharged from the first and second pulverized fuel injection compartments allegedly can be minimized. Also, the primary air-pulverized fuel mixture from the first pulverized fuel injection compartment and the supplementary air from the supplementary air compartment are prevented from interfering with each other by another curtain of the inert fluid from another compartment. This allegedly permits the primary air-pulverized fuel mixture to burn without any change in the mixing ratio, thus avoiding any increase in the NOx production.
- Yet still another change resulted in the arrangement for firing pulverized coal as a fuel while at the same time effecting a reduction in NOx and SOx emission that forms the subject matter of U. S. Patent Number 4,426,939, entitled "Method Of Reducing NOx and SOx Emission", which issued on January 24, 1984 and which is assigned to the same assignee as the present patent application. In accordance with the teachings of U. S. Patent Number 4,426,939, a furnace is fired with pulverized coal in a manner that reduces the peak temperature in the furnace while still maintaining good flame stability and complete combustion of the fuel. The manner in which this is accomplished is as follows. Pulverized coal is conveyed in an air stream towards the furnace. In the course of being so conveyed, the stream is separated into two portions, with one portion being a fuel rich portion and the other portion being a fuel lean portion. The fuel rich portion is introduced into the furnace in a first zone. Air is also introduced into the first zone in a quantity insufficient to support complete combustion of all of the fuel in the fuel rich portion. The fuel lean portion, on the other hand, is introduced into the furnace in a second zone. Also, air is introduced into the second zone in a quantity such that there is excess air over that required for combustion of all of the fuel within the furnace. Lastly, lime is introduced into the furnace simultaneously with the fuel so as to minimize the peak temperature within the furnace and so as to also minimize the formation of NOx and SOx in the combustion gases.
- Although firing systems constructed in accordance with the teachings of the now abandoned U. S. patent application and the three issued U. S. patents to which reference has been made hereinbefore have been demonstrated to be operative for the purpose for which they have been designed, there has nevertheless been evidenced in the prior art a need for such firing systems to be improved. More specifically, a need has been evidenced in the prior art for a new and improved firing system that would be advantageously characterized by the fact that an advanced overfire air system is incorporated therein. To this end, the basic concept of overfire air has been provide to be the most cost effective method for controlling NOx in tangentially fired, fossil fuel furnaces. Overfire air is introduced into the furnace tangentially through additional air compartments, termed overfire air ports, that are designed as vertical extensions of the corner windboxes with which the tangentially fired, fossil fuel furnace is equipped.
- The theory of NOx emissions reduction by overfire air is as follows. Operation with overfire air inhibits the rate of NOx formation by both atmospheric nitrogen fixation (thermal NOx) and fuel nitrogen oxidation (fuel NOx). The use of overfire air reduces the total oxygen available in the primary flame zone. As a result of this reduced oxygen zone, fuel nitrogen undergoes a recombination reaction to form molecular nitrogen, N2, rather than nitrogen oxide, simply due to insufficient oxygen in this zone and the intense competition with carbon species for the available oxygen. Consequently, the formation of NOx through fuel nitrogen conversion is greatly reduced. Similarly, overfire air operation results in reduction of thermal NOx formation through the temperature dependent Zeldovich mechanism. Heat release during the initial stages of combustion in the primary flame zone is somewhat reduced and delayed due to the reduced oxygen environment, with combustion ideally completed in the vicinity of the overfire air injection ports. The stretching of the heat release over a greater furnace volume results in lower peak combustion temperatures, thereby reducing thermal NOx formation.
- Typical application of overfire air is through one or two closely grouped ports at a single fixed elevation at the top of the windbox, referred to as close-coupled overfire air, or at a higher elevation, referred to as separated overfire air. Experimental testing has shown a significant reduction in NOx with fossil fuel firing when, for a fixed total quantity of overfire air, the overfire air is introduced partly through close-couple overfire air ports and partly through separated overfire air ports. Moreover, experimental testing has shown that there exists a most favorable distribution of overfire air between the close coupled overfire air ports and the separated overfire air ports. In the case of bituminous coal, for example, this most favorable distribution has 1/3 of the overfire air flowing through the close coupled overfire air ports and 2/3 of the overfire air flowing through the separated overfire air ports.
- In addition to the above, the manner in which overfire air is introduced into a furnace such that the air mixes with furnace gases in a controlled and thorough manner is also critical to maximizing overfire air effectiveness. Test data has shown that improvements in NOx emissions are attainable when the overfire air is injected from each furnace corner through two, three or more compartments with each compartment introducing a portion of the total overfire air flow at different firing angles such as to achieve a horizontal "spray" or "fan" distribution of air over the furnace plan area as compared to when other injection patterns are utilized for purposes of injecting the overfire air into the furnace. In addition, it has been found that through the use of such an injection pattern for the overfire air, furnace outlet conditions are also improved inasmuch as a more uniform flame pattern is created at the vertical outlet plane of the furnace. All tangentially fired, fossil fuel furnaces have a nonuniform flow pattern in the convective pass due to the tangential lower furnace flow pattern. This nonuniform flow pattern results in more flow on one side than the other and creates a side-to-side imbalance in steam temperature. The introduction of overfire air into the furnace by means of the injection pattern that has been described above wherein through the use thereof a horizontal "spray" or "fan" distribution of overfire air over the furnace plan area is had reduces this imbalance.
- Finally, improved overfire air mixing with the furnace gases can be had by introducing the overfire air at high momentum. To achieve high overfire air momentum, the overfire air is introduced at velocities significantly above those typically employed in prior art firing systems, e.g., 60 to 90 m./sec. (200 to 300 ft./sec.) versus 30 to 45 m./sec. (100 to 150 ft./sec.). A boost fan may be needed to attain these higher overfire air velocities.
- A firing system employing high momentum overfire air is found in US-A 4501 204. Therein described is a firing system that introduces fuel and air into a tangentially fired pulverized coal furnace at a burner level and tangentially to an imaginary circle such that a resultant fireball moves upward within the furnace with a rotational spin. High pressure and low pressure overfire air is introduced into the furnace through horizontally and vertically tiltable nozzles above the fuel and air, tangential to an imaginary circle but in the reverse rotational direction to that of the fireball and with sufficient velocity so as to nullify the spin of the fireball. Thus, exhaust gases leaving the furnace flow in a straight line with little or no spin removing potential temperature imbalance problems.
- To thus summarize, a need has been evidenced in the prior art for such a new and improved firing system incorporating an advanced overfire air system that would be particularly suited for use in connection with tangentially fired, fossil fuel furnaces and that when so employed therein would render it possible to accomplish through the use thereof reductions in the level of NOx emissions to levels that are at least equivalent to, if not better than, that which is currently being contemplated as the standard for the United States in legislation which is being proposed. Moreover, such results would be achievable with such a new and improved firing system according to claim 1 incorporating an advanced overfire air system without the necessity of requiring for the operation thereof any additions, catalysts or added premium fuel costs. Furthermore, such results would be obtainable with such a new and improved firing system incorporating an advanced overfire air system which is totally compatible with other emission reduction-type systems such as limestone injection systems, reburn systems and selective catalytic reduction (SCR) systems that one might seek to employ in order to accomplish additional emission reduction. Last but not least, such results would be attainable with such a new and improved firing system incorporating an advanced overfire air system which is equally suitable for use either in new applications or in retrofit applications.
- In accordance with the present invention there is provided an advanced overfire air system for NOx control which is designed for use in a firing system of the type that is particularly suited for employment in fossil fuel-fired furnaces embodying a burner region. The subject advanced overfire air system includes multi-elevations of overfire air compartments. These multi-elevations of overfire air compartments consist of a plurality of close coupled overfire air compartments and a plurality of separated overfire air compartments. The plurality of close coupled overfire air compartments are suitably supported at a first elevation within the burner region of the furnace. A close coupled overfire air nozzle is supported in mounted relation within each of the plurality of close coupled overfire air compartments. The plurality of separated overfire air compartments are suitably supported at a second elevation within the burner region of the furnace so as to be spaced from but aligned with the plurality of close coupled overfire air compartments. A plurality of separated overfire air nozzles are supported in mounted relation within the plurality of separated overfire air compartments such that the plurality of separated overfire air nozzles extend at different angles relative to each other whereby the overfire air exiting therefrom establishes a horizontal "spray" or "fan" distribution of overfire air over the plan area of the burner region of the furnace. An overfire air supply means is operatively connected to both the close coupled overfire air nozzles and to the separated overfire air nozzles for supplying overfire air thereto in accordance with a predetermined most favorable distribution of overfire air therebetween and for supplying overfire air through the separated overfire air nozzles into the burner region of the furnace at velocities significantly higher than the velocities employed heretodate in prior art firing systems to inject overfire air into a furnace.
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- Figure 1 is a diagrammatic representation in the nature of a vertical sectional view of a fossil fuel-fired furnace embodying an advanced overfire air system for NOx control constructed in accordance with the present invention;
- Figure 2 is a diagrammatic representation in the nature of a vertical sectional view of a firing system of the type employed in tangentially fired, fossil-fuel furnaces illustrating the embodiment therein of an advanced overfire air system for NOx control constructed in accordance with the present invention;
- Figure 3 is a graphical depiction of the effect on NOx when using an advanced overfire air system constructed in accordance with the present invention wherein there is a predetermined apportionment of the overfire air between close coupled overfire air and separated overfire air;
- Figure 4 is a plan view of the horizontal "spray" or "fan" distribution pattern for the overfire air which is employed in an advanced overfire air system constructed in accordance with the present invention;
- Figure 5 is a graphical depiction of the effect on NOx of using an advanced overfire air system constructed in accordance with the present invention wherein the overfire air is distributed in accordance with the horizontal "spray" or "fan" distribution pattern illustrated in Figure 4; and
- Figure 6 is a graphical depiction of the effect on NOx of using an advanced overfire air system constructed in accordance with the present invention wherein the overfire air is injected into the furnace at high velocities.
- Referring now to the drawing, and more particularly to Figure 1 thereof, there is depicted therein a fossil fuel-fired furnace, generally designated by the
reference numeral 10. Inasmuch as the nature of the construction and the mode of operation of fossil fuel-fired furnaces per se are well-known to those skilled in the art, it is not deemed necessary, therefore, to set forth herein a detailed description of the fossil fuel-firedfurnace 10 illustrated in Figure 1. Rather, for purposes of obtaining an understanding of a fossil fuel-firedfurnace 10, which is capable of having cooperatively associated therewith a firing system, generally designated by thereference numeral 12 in Figure 1 of the drawing, embodying an advanced overfire air system, generally designated by thereference numeral 14 in Figure 1 of the drawing, constructed in accordance with the present invention such that in accordance with the present invention the advancedoverfire air system 14 is capable of being installed in thefurnace 10 as part of thefiring system 12 and when so installed therein is operative for reducing the NOx emissions from the fossil fuel-firedfurnace 10, it is deemed to be sufficient that there be presented herein merely a description of the nature of the components of the fossil fuel-firedfurnace 10 with which theaforesaid firing system 12 and the aforesaid advancedoverfire air system 14 cooperate. For a more detailed description of the nature of the construction and the mode of operation of the components of the fossil fuel-firedfurnace 10, which are not described herein, one may have reference to the prior art, e.g., U. S. Patent No. 4,719,587, which issued on January 12, 1988 to F. J. Berte and which is assigned to the same assignee as the present application. - Referring further to Figure 1 of the drawing, the fossil fuel-fired
furnace 10 as illustrated therein includes a burner region, generally designated by thereference numeral 16. As will be described more fully hereinafter in connection with the description of the nature of the construction and the mode of operation of thefiring system 12 and of the advancedoverfire air system 14, it is within theburner region 16 of the fossil fuel-firedfurnace 10 that in a manner well-known to those skilled in this art combustion of the fossil fuel and air is initiated. The hot gases that are produced from combustion of the fossil fuel and air rise upwardly in the fossil fuel-firedfurnace 10. During the upwardly movement thereof in the fossil fuel-firedfurnace 10, the hot gases in a manner well-known to those skilled in this art give up heat to the fluid flowing through the tubes (not shown in the interest of maintaining clarity of illustration in the drawing) that in conventional fashion line all four of the walls of the fossil fuel-firedfurnace 10. Then, the hot gases exit the fossil fuel-firedfurnace 10 through the horizontal pass, generally designated by thereference numeral 18, of the fossil fuel-firedfurnace 10, which in turn leads to the rear gas pass, generally designated by thereference numeral 20, of the fossil fuel-firedfurnace 10. Both thehorizontal pass 18 and therear gas pass 20 commonly contain other heat exchanger surface (not shown) for generating and super heating steam, in a manner well-known to those skilled in this art. Thereafter, the steam commonly is made to flow to a turbine (not shown), which forms one component of a turbine/generator set (not shown), such that the steam provides the motive power to drive the turbine (not shown) and thereby also the generator (not shown), which in known fashion is cooperatively associated with the turbine (not shown), such that electricity is thus produced from the generator (not shown). - With the preceding by way of background, reference will now be had particularly to Figures 1 and 2 of the drawing for purposes of describing the
firing system 12 and the advancedoverfire air system 14 which in accordance with the present invention is designed for use as part of a firing system, such as thefiring system 12, and with the firing system, such as thefiring system 12, in turn being designed to be cooperatively associated with a furnace constructed in the manner of the fossil fuel-firedfurnace 10 that is depicted in Figure 1 of the drawing. More specifically, the advancedoverfire air system 14 is designed to be utilized in a firing system, such as thefiring system 12, so that when thefiring system 12 in turn is utilized in a furnace, such as the fossil fuel-firedfurnace 10 of Figure 2 of the drawing, the advancedoverfire air system 14 is operative to reduce the NOx emissions from the fossil fuel-firedfurnace 10. - Considering first the
firing system 12, as best understood with reference to Figures 1 and 2 of the drawing thefiring system 12 includes a housing preferably in the form of a windbox denoted by thereference numeral 22 in Figures 1 and 2 of the drawing. Thewindbox 22 in a manner well-known to those skilled in this art is supported by conventional support means (not shown) in theburner region 16 of the fossil fuel-firedfurnace 10 such that the longitudinal axis of thewindbox 22 extends substantially in parallel relation to the longitudinal axis of the fossil fuel-firedfurnace 10. - Continuing with the description of the
firing system 12, in accordance with the illustration thereof in Figures 1 and 2 of the drawing a first air compartment, denoted generally by thereference numeral 24 in Figure 2 of the drawing, is provided at the lower end of thewindbox 22. An air nozzle, denoted by thereference numeral 26, is supported in mounted relation, through the use of any conventional form of mounting means (not shown) suitable for use for such a purpose, within theair compartment 24. An air supply means, which is illustrated schematically in Figure 1 of the drawing wherein the air supply means is denoted generally by thereference numeral 28, is operatively connected in a manner to be more fully described hereinafter to theair nozzle 26 whereby the air supply means 28 supplies air to theair nozzle 26 and therethrough into theburner region 16 of the fossil fuel-firedfurnace 10. To this end, the air supply means 28 includes a fan seen at 30 in Figure 1 of the drawing, and the air ducts denoted by thereference numeral 32 which are connected in fluid flow relation to thefan 30 on the one hand and on the other hand, as seen schematically at 34 in Figure 1 of the drawing, to theair nozzle 26 through separate valves and controls (not shown). - With further reference to the
windbox 22, in accordance with the nature of the construction of the illustrated embodiment of the firing system 12 a first fuel compartment, denoted generally by thereference numeral 36 in Figure 2 of the drawing, is provided in thewindbox 22 within the lower portion thereof such as to be located substantially in juxtaposed relation to theair compartment 24. A first fuel nozzle, denoted by thereference numeral 38 in Figure 2 of the drawing, is supported in mounted relation, through the use of any conventional form of mounting means (not shown) suitable for use for such a purpose, within thefuel compartment 36. A fuel supply means, which is illustrated schematically in Figure 1 of the drawing wherein the fuel supply means is denoted generally by thereference numeral 40, is operatively connected in a manner to be more fully described hereinafter to thefuel nozzle 38 whereby the fuel supply means 40 supplies fuel to thefuel nozzle 38 and therethrough into theburner region 16 of the fossil fuel-firedfurnace 10. Namely, the fuel supply means 40 includes a pulverizer, seen at 42 in Figure 1 of the drawing, wherein the fossil fuel that is to be burned in the fossil fuel-firedfurnace 10 undergoes pulverization in a manner well-known to those skilled in this art, and the fuel ducts, denoted by thereference numeral 44, which are connected in fluid flow relation to the pulverizer 42 on the one hand and on the other hand, as seen schematically at 46 in Figure 1 of the drawing, to thefuel nozzle 38 through separate valves and controls (not shown). As can be seen with reference to Figure 1 of the drawing, the pulverizer 42 is operatively connected to thefan 30 such that air is also supplied from thefan 30 to the pulverizer 42 whereby the fuel supplied from the pulverizer 42 to thefuel nozzle 38 is transported through thefuel ducts 44 in an air stream in a manner which is well-known to those skilled in this art. - In addition to the
air compartment 24 and thefuel compartment 36, which have been described hereinabove, thewindbox 22 is also provided with a second air compartment, denoted generally by thereference numeral 48 in Figure 2 of the drawing. Theair compartment 48, as best understood with reference to Figure 2 of the drawing, is provided in thewindbox 22 such as to be located substantially in juxtaposed relation to thefuel compartment 36. An air nozzle, denoted by thereference numeral 50 in Figure 2 of the drawing, is supported in mounted relation, through the use of any conventional form of mounting means (not shown) suitable for use for such a purpose, within theair compartment 48. Theair nozzle 50 is operatively connected to the air supply means 28, the latter having been described herein previously, through theair ducts 32, which as best understood with reference to Figure 1 of the drawing are connected in fluid flow relation to thefan 30 on the one hand and on the other hand, as seen schematically at 52 in Figure 1 of the drawing, to theair nozzle 50 through separate valves and controls (not shpwn) whereby the air supply means 28 supplies air to theair nozzle 50 and therethrough into theburner region 16 of the fossil fuel-firedfurnace 10 in the same manner as that which has been described herein previously in connection with the discussion hereinbefore of theair nozzle 26. - Continuing with the description of the
firing system 12, in accord with the illustrated embodiment thereof a second fuel compartment, denoted generally by thereference numeral 54 in Figure 2 of the drawing, is provided in thewindbox 22 such as to be located substantially in juxtaposed relation to theair compartment 48. A second fuel nozzle, denoted generally by thereference numeral 56 in Figure 2 of the drawing, is supported in mounted relation, through the use of any conventional form of mounting means (not shown) suitable for use for such a purpose, within thefuel compartment 54. Thefuel nozzle 56 is operatively connected to the fuel supply means 40, the latter having been described previously herein, through thefuel ducts 44, which as best understood with reference to Figure 1 of the drawing, are connected in fluid flow relation on the one hand to the pulverizer 42 wherein the fossil fuel that is to be burned in the fossil fuel-firedfurnace 10 undergoes pulverization in a manner well-known to those skilled in the art, and on the other hand, as seen schematically at 58 in Figure 1 of the drawing, to thefuel nozzle 56 through separate valves and controls (not shown) whereby the fuel supply means 40 supplies fuel to thefuel nozzle 56 and therethrough into theburner region 16 of the fossil fuel-firedfurnace 10 in the same manner as that which has been described herein previously in connection with the discussion hereinbefore of thefuel nozzle 38. Mention is once again made here of the fact that as can be seen with reference to Figure 1 of the drawing, the pulverizer 42 is operatively connected to thefan 30 such that air is also supplied from thefan 30 to the pulverizer 42 whereby the fuel supplied from the pulverizer 42 to thefuel compartment 54 is transported through thefuel ducts 44 in an air stream in a manner which is well-known to those skilled in the art. - With further reference to the
windbox 22, in accord with the illustrated embodiment thereof, there is provided therein a third air compartment, denoted generally by thereference numeral 60 in Figure 2 of the drawing. Theair compartment 60, as best understood with reference to Figure 2 of the drawing, is provided in thewindbox 22 such as to be located substantially in juxtaposed relation to thefuel compartment 54. An air nozzle, denoted by thereference numeral 62 in Figure 2 of the drawing, is supported in mounted relation, through the use of any conventional form of mounting means (not shown) suitable for use for such a purpose, within theair compartment 60. Theair nozzle 62 is operatively connected to the air supply means 28, the latter having been described herein previously, through theair ducts 32, which as best understood with reference to Figure 1 of the drawing are connected in fluid flow relation to thefan 30 on the one hand and on the other hand, as seen schematically at 64 in Figure 1 of the drawing, to theair nozzle 62 through separate valves and controls (not shown) whereby the air supply means 28 supplies air to theair nozzle 62 and therethrough into theburner region 16 of the fossil fuel-firedfurnace 10 in the same manner as that which has been described herein previously in connection with the discussion hereinbefore of theair nozzles - In addition to the foregoing, the
firing system 12, in accordance with the embodiment thereof illustrated in Figures 1 and 2 of the drawing, further includes a third fuel compartment, denoted generally by thereference numeral 66 in Figure 2 of the drawing. Thefuel compartment 66 is provided in thewindbox 22 such as to be located substantially in juxtaposed relation to theair compartment 60. A third fuel nozzle, denoted by thereference numeral 68 in Figure 2 of the drawing, is supported in mounted relation, through the use of any conventional form of mounting means (not shown) suitable for use for such a purpose, within thefuel compartment 66. Thefuel nozzle 68 is operatively connected to the fuel supply means 40, the latter having been described previously herein, through thefuel ducts 44, which as best understood with reference to Figure 1 of the drawing are connected in fluid flow relation on the one hand to the pulverizer 42 wherein the fossil fuel that is to be burned in the fossil fuel-firedfurnace 10 undergoes pulverization in a manner well-known to those skilled in the art, and on the other hand as seen schematically at 70 in Figure 1 of the drawing to thefuel nozzle 68 through separate valves and controls (not shown) whereby the fuel supply means 40 supplies fuel to thefuel nozzle 68 and therethrough into theburner region 16 of the fossil fuel-firedfurnace 10 in the same manner as that which has been described herein previously in connection with the discussion hereinbefore of thefuel nozzles fan 30 such that air is also supplied from thefan 30 to the pulverizer 42 whereby the fuel supplied from the pulverizer 42 to thefuel compartment 66 is transported through thefuel ducts 44 in an air stream in a manner well-known to those skilled in the art. - Continuing with the description of the
firing system 12, in accord with the embodiment thereof illustrated in Figures 1 and 2 of the drawing there is provided in the windbox 22 a fourth air compartment, denoted generally by thereference numeral 72 in Figure 2 of the drawing. Thefourth air compartment 72 is provided in thewindbox 22 such as to be located substantially in juxtaposed relation to thefuel compartment 66. A fourth air nozzle, denoted by thereference numeral 74 in Figure 2 of the drawing, is supported in mounted relation, through the use of any conventional form of mounting means (not shown) suitable for use for such a purpose, within theair compartment 72. Theair nozzle 74 is operatively connected to the air supply means 28, the latter having been described herein previously, through theair ducts 32, which as best understood with reference to Figure 1 of the drawing are connected in fluid flow relation to thefan 30 on the one hand and on the other hand, as seen schematically at 76 in Figure 1 of the drawing, to theair nozzle 74 through separate valves and controls (not shown) whereby the air supply means 28 supplies air to theair nozzle 74 and therethrough into theburner region 16 of the fossil fuel-firedfurnace 10 in the same manner as that which has been described herein previously in connection with the discussion hereinbefore of theair nozzles - Also, in accord with the illustrated embodiment of the
firing system 12, a fourth fuel compartment, denoted generally by thereference numeral 78 in Figure 2 of the drawing, is provided in thewindbox 22 such as to be located substantially in juxtaposed relation to theair compartment 72. A fourth fuel nozzle, denoted by thereference numeral 80 in Figure 2 of the drawing, is supported in mounted relation, through the use of any conventional form of mounting means (not shown) suitable for use for such a purpose, within thefuel compartment 78. Thefuel nozzle 80 is operatively connected to the fuel supply means 40, the latter having been described previously herein, through thefuel ducts 44, which as best understood with reference to Figure 1 of the drawing are connected in fluid flow relation on the one hand to the pulverizer 42 wherein the fossil fuel that is to be burned in the fossil fuel-firedfurnace 10 undergoes pulverization in a manner well-known to those skilled in the art, and on the other hand as seen schematically at 82 in Figure 1 of the drawing to thefuel nozzle 80 through separate valves and controls (not shown) whereby the fuel supply means 40 supplies fuel to thefuel nozzle 80 and therethrough into theburner region 16 of the fossil fuel-firedfurnace 10 in the same manner as that which has been described herein previously in connection with the discussion hereinbefore of thefuel nozzles fan 30 such that air is also supplied from thefan 30 to the pulverizer 42 whereby the fuel supplied from the pulverizer 42 to thefuel compartment 78 is transported through thefuel ducts 44 in an air stream in a manner well-known to those skilled in the art. - A description will now be had herein of the nature of the construction of the advanced
overfire air system 14 of the present invention, and of the manner in which the advancedoverfire air system 14 in accordance with the present invention forms part of a firing system, such as thefiring system 12. For purposes of this description, reference will be had in particular to Figures 1 and 2 of the drawing. Thus, as best understood with reference to Figures 1 and 2, the advancedoverfire air system 14 in accord with the best mode embodiment of the invention includes a pair of close coupled overfire air compartments, denoted generally by thereference numerals windbox 22 of thefiring system 12 within the upper portion of thewindbox 22 such as to be located substantially in juxtaposed relation to theair compartment 78, the latter having been the subject of discussion hereinbefore. A pair of close coupled overfire air nozzles, denoted by thereference numerals overfire air nozzle 88 is mounted in the close coupledoverfire air compartment 84 and the close coupledoverfire air nozzle 90 is mounted in the close coupledoverfire air compartment 86. The close coupledoverfire air nozzles air ducts 32, which as best understood with reference to Figure 1 of the drawing are connected in fluid flow relation to thefan 30 on the one hand and on the other hand as seen schematically at 92 in Figure 1 of the drawing to each of the close coupledoverfire air nozzles overfire air nozzles burner region 16 of the fossil fuel-firedfurnace 10. - Continuing with the description of the advanced
overfire air system 14, in accordance with the best mode embodiment of the invention the advancedoverfire air system 14 further includes a plurality of separated overfire air compartments, which are suitably supported, through the use of any conventional form of support means (not shown) suitable for use for such a purpose, within theburner region 16 of thefurnace 10 so as to be spaced from the close coupled overfire air compartments 84 and 86, and so as to be substantially aligned with the longitudinal axis of thewindbox 22. The aforementioned plurality of separated overfire air compartments, in accordance with the preferred embodiment of the invention, comprises in number three such compartments, which are denoted generally in Figure 2 of the drawing by thereference numerals overfire air nozzle 100 is mounted for both the vertical (tilting) and horizontal (yaw) movement in the separatedoverfire air compartment 94, the separatedoverfire air nozzle 102 is mounted for both vertical (tilting) and horizontal (yaw) movement in the separatedoverfire air compartment 96, and the separatedoverfire air nozzle 104 is mounted for both vertical (tilting) and horizontal (yaw) movement in the separatedoverfire air compartment 98. The plurality of separated overfire air nozzles 100,102 and 104 are each operatively connected to the air supply means 28, the latter having been described herein previously, through theair ducts 32, which as best understood with reference to Figure 1 of the drawing are connected in fluid flow relation to thefan 30 on the one hand and on the other hand as seen schematically at 106 in Figure 1 of the drawing to each of the separated overfire air nozzles 100,102 and 104 through separate valves and controls (not shown) whereby the air supply means 28 supplies air to each of the separated overfire air nozzles 100,102 and 104 and therethrough into theburner region 16 of the fossil fuel-firedfurnace 10. - A brief description will now be set forth herein of the mode of operation of the advanced
overfire air system 14 constructed in accordance with the present invention and of thefiring system 12 with which the advancedoverfire air system 14 is designed to be employed for the purpose of effectuating a reduction in the NOx emissions from a furnace, such as the fossil fuel-firedfurnace 10, in which there is installed both thefiring system 12 and the advancedoverfire air system 14 that is cooperatively associated therewith. Insofar as concerns the mode of operation of thefiring system 12, constructed in accordance with the illustration thereof in Figures 1 and 2 of the drawing, air and fossil fuel is introduced into theburner region 16 of the fossil fuel-firedfurnace 10 through alternate elevations of air compartments and fuel compartments which are suitably provided in thewindbox 22 for this purpose. Namely, in accord with the illustrated embodiment of thefiring system 12 air is introduced into theburner region 16 of the fossil fuel-firedfurnace 10 through the air compartments 24,48,60 and 72, and fossil fuel is introduced into theburner region 16 of the fossil fuel-firedfurnace 10 through the fossil fuel compartments 36,54,66 and 78. In a manner well-known to those skilled in this art there is initiated in theburner region 16 of the fossil fuel-firedfurnace 10 combustion of the fossil fuel that is introduced thereinto through the fossil fuel compartments 36,54,66 and 78 and of the air that is introduced thereinto through the air compartments 24,48,60 and 72. The hot gases that are produced from this combustion of the fossil fuel and air in theburner region 16 of the fossil fuel-firedfurnace 10 in known fashion rise upwardly in the fossil fuel-firedfurnace 10. During this upwardly movement thereof in the fossil fuel-firedfurnace 10, the hot gases give up heat in a manner well-known to those skilled in this art to the fluid flowing through the tubes (not shown) that in conventional fashion line all four of the walls of the fossil fuel-firedfurnace 10. Then, these hot gases exit the fossil fuel-firedfurnace 10 through thehorizontal pass 18 of the fossil fuel-firedfurnace 10, which in turn leads to therear gas pass 20 of the fossil fuel-firedfurnace 10. Thehorizontal pass 18 and therear gas pass 20 commonly each contain other heat exchanger surface (not shown) for generating and super heating steam, in a manner well-known to those skilled in this art. Thereafter, this steam commonly is made to flow to a turbine (not shown), which forms one component of a turbine/generator set (not shown), such that the steam provides the motive power to drive the turbine (not shown) and thereby also the generator (not shown), which in known fashion is cooperatively associated with the turbine (not shown), such that electricity is thus produced from the generator (not shown). - Insofar as concerns the mode of operation of the advanced
overfire air system 14, the objective sought to be achieved through the use thereof is that of inhibiting the rate of NOx formation by both atmospheric nitrogen fixation (thermal NOx) and fuel nitrogen (fuel NOx). This is accomplished by reducing the total oxygen that is available in the primary flame zone. To this end, in accord with the mode of operation of the advancedoverfire air system 14, overfire air is introduced through one or two closely grouped compartments at a single fixed elevation of theburner region 16 of the fossil fuel-firedfurnace 10 at the top of thewindbox 22, and through one or more additional compartments located at a higher elevation. The closely grouped compartments, commonly referred to in the industry as close coupled overfire air compartments, are seen at 84 and 86 in Figure 2 of the drawing, and the compartments located at the higher elevation, commonly referred to in the industry as separated overfire air compartments, are seen at 94,96 and 98 in Figure 2 of the drawing. - One of the characteristics which the advanced
overfire air system 14 embodies in accordance with the present invention is that the overfire air is introduced into theburner region 16 of the fossil fuel-firedfurnace 10 partly through the close coupled overfire air compartments 84 and 86 and partly through the separated overfire air compartments 94,96 and 98 such that there exists a predetermined most favorable distribution of the overfire air between close coupled overfire air and separated overfire air. The advantages that accrue from the utilization of this most favorable distribution of overfire air are best understood with reference to Figure 3 of the drawing. As noted previously herein, Figure 3 is a graphical depiction of the effect on NOx when using an advanced overfire air system constructed in accordance with the present invention wherein there is a predetermined apportionment of the overfire air between close coupled overfire air and separated overfire air. The line denoted by the reference numeral 108 in Figure 3 represents a baseline plot of the NOx ppm levels from a furnace, such as the fossil fuel-firedfurnace 10, when operating with a firing system, such as thefiring system 12. On the other hand, the line denoted by the reference numeral 110 in Figure 3 represents a plot of the NOx ppm levels from a furnace, such as the fossil fuel-firedfurnace 10, when operating with a firing system, such as thefiring system 12, and with 0% overfire air. Continuing, the line denoted therein by the reference numeral 112 represents a plot of the NOx ppm levels from a furnace, such as the fossil fuel-firedfurnace 10, when operating with 20% overfire air and wherein all 20% of the overfire air is introduced into the furnace as close coupled overfire. Whereas, the line denoted in Figure 3 by thereference numeral 114 represents a plot of the NOx ppm levels from a furnace, such as the fossil fuel-firedfurnace 10, when operating with 20% overfire air and wherein all 20% of the overfire air is introduced into the furnace as separated overfire air. - With further reference to Figure 3, the point denoted therein by the reference numeral 116 is a plot of the NOx ppm level from a furnace, such as the fossil fuel-fired
furnace 10, when operating with afiring system 12 with which an advancedoverfire air system 14 constructed in accordance with the present invention is cooperatively associated and with 20% overfire air, and wherein of the 20% overfire air in accordance with a most favorable distribution thereof 9% of this overfire air is introduced as close coupled overfire air and 11% of the overfire air is introduced as separated overfire air. Thus, from the preceding and from a reference to Figure 3 the following should now be readily apparent: 1) that the use of overfire air results in a reduction in the NOx ppm levels as compared to when 0% overfire air is employed, 2) that the use of overfire air wherein all of the overfire air is introduced as separated overfire air results in a greater reduction in the NOx ppm levels as compared to when the same amount of overfire air is employed but all of this overfire air is introduced as close coupled overfire air, and 3) that an even greater reduction in NOx ppm level is realized when the same amount of overfire air is employed but this overfire air is introduced into the furnace in accordance with a most favorable distribution thereof as between close coupled overfire air and separated overfire air, e.g., as illustrated in Figure 3 wherein with 20% overfire air being introduced, the most favorable distribution thereof is 9% close coupled overfire air and 11% separated overfire air. This most favorable distribution of overfire air between close coupled overfire air and separated overfire air has been found to vary as a function of coal type. For example, in the case of bituminous coal the tests that were run therewith show that the most favorable distribution of the overfire air was 1/3 close coupled overfire air and 2/3 separated overfire air. - A second characteristic which the advanced
overfire air system 14 embodies in accordance with the present invention is that the separated overfire air is injected into theburner region 16 of the fossil fuel-firedfurnace 10 from each of the four corners thereof through a plurality, e.g., two, three or more compartments with each compartment introducing a portion of the total separated overfire air flow at different firing angles, which angles are established by moving the separatedoverfire air nozzles burner region 16 of the fossil fuel-firedfurnace 10 is depicted in Figure 4 of the drawing. To this end, as best seen with reference to Figure 4 the separated overfire air in accord with the present invention is injected into theburner region 16 of the fossil fuel-firedfurnace 10 from each corner thereof, the latter being denoted in Figure 4 by the reference numerals 10a,10b,10c and 10d, respectively. In accord with the best mode embodiment of the invention, this injection of the separated overfire air is accomplished through the three separated overfire air compartments 94,96 and 98, which have been described hereinbefore and which are illustrated in Figure 2 of the drawing. - Although not shown in Figure 2, it is to be understood that the four corners 10a,10b,10c and 10d of the fossil fuel-fired
furnace 10 are each provided with separated overfire air compartments 94,96 and 98. Moreover, the separated overfire air that is injected into theburner region 16 of the fossil fuel-firedfurnace 10 from each of the four corners 10a,10b,10c and 10d thereof through the separated overfire air compartments 94,96 and 98 located thereat is injected at a different firing angle, the latter being denoted in Figure 4 by means of the reference numerals 118,120 and 122, respectively, and wherein for ease of reference the same numerals are utilized in connection with each of the four corners 10a,10b,10c and 10d of the fossil fuel-firedfurnace 10. Further, as best understood with reference to Figure 4 of the drawing, the injection into theburner region 16 of the fossil fuel-firedfurnace 10 at the different firing angles denoted by the reference numerals 118,120 and 122 in Figure 4 has the effect of producing a horizontal "spray" or "fan" distribution of the separated overfire air over the furnace plan area. Namely, as depicted in Figure 4, the separated overfire air that is injected into theburner region 16 of the fossil fuel-firedfurnace 10 at each of the different firing angles 118,120 and 122 follows the path denoted by the reference numerals 124,126 and 128, respectively. Collectively the paths 124,126 and 128 create a distribution pattern which as best seen with reference to Figure 4 is in the form of a horizontal "spray" or "fan" distribution pattern. Also, to be noted from Figure 4 is the fact that the distribution pattern for the separated overfire air injected from each of the corners 10a,10b,10c and 10d of the fossil fuel-firedfurnace 10 substantially overlap one another at the center of theburner region 16 of the fossil fuel-firedfurnace 10. - The advantages that accrue from the utilization of different firing angles for purposes of injecting into the
burner region 16 of the fossil fuel-firedfurnace 10 the separated overfire air from the separated overfire air compartments 94,96 and 98 are best understood with reference to Figure 5 of the drawing. As noted previously herein, Figure 5 is a graphical depiction of the effect on NOx of using an advanced overfire air system constructed in accordance with the present invention wherein the overfire air is distributed in accordance with the horizontal "spray" or "fan" distribution pattern illustrated in Figure 4. Referring to Figure 5, the point denoted therein by the reference numeral 130 is a plot of the NOx ppm level from a furnace, such as the fossil fuel-firedfurnace 10, when operating with a firing system, such as thefiring system 12, and wherein all of the separated overfire air that is injected through the separated overfire air compartments is injected into theburner region 16 of the fossil fuel-firedfurnace 10 at the same firing angle, i.e., at an angle of +15° such that the separated overfire air is injected so as to be co-rotational with the fuel and air that is being injected into theburner region 16 of the fossil fuel-firedfurnace 10 through the fuel compartments 38,54,66 and 78 and the air compartments 24,48,60 and 72, respectively. The point denoted in Figure 5 by the reference numeral 132 is a plot of the NOx ppm level from a furnace, such as the fossil fuel-firedfurnace 10, when operating with a firing system, such as thefiring system 12, and wherein all of the separated overfire air that is injected through the separated overfire air compartment is injected into theburner region 16 of the fossil fuel-firedfurnace 10 at the same firing angle, i.e, at an angle of -15° such that the separated overfire air is injected so as to be counter rotational with the fuel and air that is being injected into theburner region 16 of the fossil fuel-firedfurnace 10 through the fuel compartments 38,54,66 and 78 and the air compartments 24,48,60 and 72, respectively. With further reference to Figure 5, the point denoted therein by the reference numeral 134 is a plot of the NOx ppm level from a furnace, such as the fossil fuel-firedfurnace 10, when operating with afiring system 12 with which an advancedoverfire air system 14 constructed in accordance with the present invention is cooperatively associated and wherein all of the separated overfire air is injected through each of the separated overfire air compartments 94,96 and 98 at a different firing angle such that the horizontal "spray" or "fan" distribution of separated overfire air that is depicted in Figure 4 of the drawing is achieved over the furnace plan area. In accord with the best mode embodiment of the invention, the firing angles that are employed for this purpose for the separated overfire air compartments 94,96 and 98 are +15°, 0° and -15°. Thus, from the preceding and from a reference to Figure 5 the following should now be readily apparent: 1) that injecting all of the separated overfire air through the separated overfire air compartments at the same firing angle of -15° such that the separated overfire air is injected so as to be counter rotational with the fuel and air that is being injected into the burner region 16 of the fossil fuel-fired furnace 10 through the fuel compartments 38,54,66 and 78 and the air compartments 24,48,60 and 72, respectively, results in a greater reduction in the NOx ppm level as compared to when all of the separated overfire air is injected through the separated overfire air compartments at the same angle of +15° such that all of the separated overfire air is injected so as to be co-rotational with the fuel and air that is being injected into the burner region 16 of the fossil fuel-fired furnace 10 through the fuel compartments 38,54,66 and 78 and the air compartments 24,48,60 and 72, respectively, and 2) that injecting all of the separated overfire air through the separated overfire air compartments 94,96 and 98 at different firing angles of +15°, 0° and -15° such that the horizontal "spray" or "fan" distribution of separated overfire air that is depicted in Figure 4 of the drawing is achieved over the furnace plan area results in a greater reduction in the NOx ppm level as compared to when all of the separated overfire air is injected through the separated overfire air compartments at the same firing angle of -15° such that the separated overfire air is injected so as to be counter rotational with the fuel and air that is being injected into the burner region 16 of the fossil fuel-fired furnace 10 through the fuel compartments 38,44,66 and 78 and the air compartments 24,48,60 and 72, respectively. - A third characteristic which the advanced
overfire air system 14 embodies in accordance with the present invention is that the separated overfire air is injected into theburner region 16 of the fossil fuel-firedfurnace 10 at velocities significantly higher than those utilized heretofore in prior art firing systems, e.g., 200 to 300 ft./sec. versus 100 to 150 ft./sec. The advantages that accrue from the injection of the separated overfire air at such increased velocities are best understood with reference to Figure 6 of the drawing. As noted previously herein, Figure 6 is a graphical depiction of the effect on NOx of using an advanced overfire air system constructed in accordance with the present invention wherein the overfire air is injected into the furnace at high velocities. The line denoted by the reference numeral 136 in Figure 6 represents a plot of the NOx ppm levels from a furnace, such as the fossil fuel-firedfurnace 10, when operating with a firing system, such as thefiring system 12 and wherein the overfire air is injected at low velocities, i.e., at the velocities commonly utilized heretofore in prior art firing systems. On the other hand, the line denoted by the reference numeral 138 in Figure 6 represents a plot of the NOx ppm levels from a furnace, such as the fossil fuel-firedfurnace 10, when operating with afiring system 12 with which an advancedoverfire air system 14 constructed in accordance with the present invention is cooperatively associated and wherein the separated overfire air injected into theburner region 16 of the fossil fuel-firedfurnace 10 through the separated overfire air compartments 94,96 and 98 is injected at velocities significantly higher than those utilized heretofore in prior art firing systems, e.g., 200 to 300 ft./sec. versus 100 to 150 ft./sec. Thus, from the preceding and from a reference to Figure 6 it should now be readily apparent that injecting all of the separated overfire air through the separated overfire air compartments 94,96 and 98 into theburner region 16 of the fossil fuel-firedfurnace 10 at velocities significantly higher than those utilized heretofore in prior art firing systems results in a greater reduction in the NOx ppm levels as compared to when all of the overfire air is injected into theburner region 16 of the fossil fuel-firedfurnace 10 at low velocities, i.e., at the velocities commonly utilized heretofore in prior art firing systems. - Thus, in accordance with the present invention there is provided a new and improved advanced overfire air system for NOx control which is designed for use in a firing system of the type that is employed in fossil fuel-fired furnaces. As well, there is provided in accord with the present invention an advanced overfire air system for NOx control that is designed for use in a firing system of the type that is employed in tangentially fired, fossil fuel furnaces. Moreover, in accord with the present invention there is provided an advanced overfire air system for NOx control for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces such that through the use thereof NOx emissions are capable of being reduced to levels that are at least equivalent to, if not better than, that which is currently being contemplated as the standard for the United States in the legislation being proposed. Also, there is provided in accord with the present invention an advanced overfire air system for NOx control that is designed for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces characterized in that the advanced overfire air system involves the use of multi-elevations of overfire air compartments consisting of close coupled overfire air compartments and separated overfire air compartments. Further, in accordance with the present invention there is provided an advanced overfire air system for NOx control that is designed for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces and which is characterized in that there is a predetermined most favorable distribution of overfire air between the close coupled overfire air compartments and the separated overfire air compartments. Besides, there is provided in accord with the present invention an advanced overfire air system for NOx control that is designed for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces and which is characterized in that the advanced overfire air system involves the use of a multi-angle injection pattern. In addition, in accordance with the present invention there is provided an advanced overfire air system for NOx control that is designed for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces and which is characterized in that in accordance with the multi-angle injection pattern thereof a portion of the total overfire air flow is introduced at different angles such as to achieve a horizontal "spray" or "fan" distribution of overfire air over the plan area of the furnace. Furthermore, there is provided in accord with the present invention an advanced overfire air system for NOx control that is designed for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces and which is characterized in that the advanced overfire air system involves the injection of overfire air into the furnace at velocities significantly higher than those utilized heretofore in prior art firing systems. Additionally, in accordance with the present invention there is provided an advanced overfire air system for NOx control that is designed for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces such that through the use thereof no additions, catalysts or added premium fuel costs are needed for the operation thereof. Penultimately, there is provided in accord with the present invention an advanced overfire air system for NOx control that is designed for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces and which is characterized in that the advanced overfire air system is totally compatible with other emission reduction-type systems such as limestone injection systems, reburn systems and selective catalytic reduction (SCR) systems that one might seek to employ in order to accomplish additional emission reduction. Finally, in accordance with the present invention there is provided an advanced overfire air system for NOx control that is designed for use in a firing system of the type employed in tangentially fired, fossil fuel furnaces and which is characterized in that the advanced overfire air system is equally well suited for use either in new applications or in retrofit applications.
Claims (3)
- A tangentially fired fossil fuel furnace 10 having a plurality of walls embodying therewithin a burner region 16, a windbox 22 embodying a plurality of elevations and mounted in supported relation within the burner region 16 of the tangentially fired fossil fuel furnace 10, a first fossil fuel nozzle 68 supported in the windbox 22 at a first elevation thereof and operative for introducing fossil fuel in a first direction into the burner region 16 of the tangentially fired fossil fuel furnace 10 through the windbox 22 at the first elevation thereof, a combustion supporting secondary air nozzle 74 supported in the windbox 22 at a second elevation thereof and operative for introducing combustion supporting secondary air in the first direction into the burner region 16 of the tangentially fired fossil fuel furnace 10 through the windbox 22 at the second elevation thereof, a second fossil fuel nozzle 80 supported in the windbox 22 at a third elevation thereof and operative for introducing fossil fuel in the first direction into the burner region 16 of the tangentially fired fossil fuel furnace 10 through the windbox 22 at the third elevation thereof, and an advanced overfire air system 14 for accomplishing NOx control in the tangentially fired fossil fuel furnace 10, said advanced overfire air system 14 being characterized in that:a. a first overfire air nozzle 88,90 is supported in the windbox 22 at a fourth elevation thereof and is operative for introducing overfire air in the first direction into the burner region 16 of the tangentially fired fossil fuel furnace 10 through the windbox 22 at the fourth elevation thereof;b. a plurality of overfire air compartments 94,96 are mounted in supported relation in the burner region 16 of the tangentially fired fossil fuel furnace 10 above and in spaced relation to the windbox 22;c. a second overfire air nozzle 100 is supported in one 94 of the plurality of overfire air compartments 94,96 and is operative for introducing overfire air in a second direction counter rotational to the first direction into the burner region 16 of the tangentially fired fossil fuel furnace 10 through the one 94 of the plurality of overfire air compartments 94,96;d. a third overfire air nozzle 102 is supported in another one 96 of the plurality of overfire air compartments 94,96 and is operative for introducing overfire air in a direction other than the second direction into the burner region 16 of the tangentially fired fossil fuel furnace 10 through the another one 96 of the plurality of overfire air compartments 94,96; ande. air supply means 28 is connected to the first overfire air nozzle 88,90, the second overfire air nozzle 100 and the third overfire air nozzle 102, the air supply means 28 is operative to supply to the first overfire air nozzles 88,90 for introduction through the windbox 22 at the fourth elevation thereof approximately one-third of the total amount of overfire air that is introduced into the burner region 16 of the tangentially fired fossil fuel furnace 10 and is operative to supply to the second overfire air nozzle 100 and the third overfire air nozzle 102 for introduction through the plurality of overfire air compartments 94,96 the remaining approximately two-thirds of the total amount of overfire air that is introduced into the burner region 16 of the tangentially fired fossil fuel furnace 10.
- A tangentially fired fossil fuel furnace 10 having an advanced overfire air system 14 as set forth in Claim 1 wherein the second overfire air nozzle 100 is operative to introduce the overfire air into the burner region 16 at velocities in the range of 60 m./sec. to 90 m./sec. (200 ft./sec. to 300 ft./sec.).
- A tangentially fired fossil fuel furnace 10 having an advanced overfire air system 14 as set forth in Claim 1 wherein the third overfire air nozzle 102 is operative to introduce the overfire air into the burner region 16 at velocities in the range of 60 m./sec. to 90 m./sec. (200 ft./sec. to 300 ft./sec.).
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US60717790A | 1990-10-31 | 1990-10-31 | |
US607177 | 1990-10-31 | ||
PCT/US1991/004440 WO1992008078A1 (en) | 1990-10-31 | 1991-06-24 | AN ADVANCED OVERFIRE AIR SYSTEM FOR NOx CONTROL |
Publications (2)
Publication Number | Publication Date |
---|---|
EP0554254A1 EP0554254A1 (en) | 1993-08-11 |
EP0554254B1 true EP0554254B1 (en) | 1996-08-21 |
Family
ID=24431152
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP91912984A Expired - Lifetime EP0554254B1 (en) | 1990-10-31 | 1991-06-24 | AN ADVANCED OVERFIRE AIR SYSTEM FOR NOx CONTROL |
Country Status (15)
Country | Link |
---|---|
EP (1) | EP0554254B1 (en) |
JP (1) | JP2731794B2 (en) |
KR (1) | KR970009483B1 (en) |
AU (1) | AU646677B2 (en) |
BR (1) | BR9107060A (en) |
CA (1) | CA2091341C (en) |
CS (1) | CS327791A3 (en) |
DE (1) | DE69121579D1 (en) |
ES (1) | ES2092573T3 (en) |
FI (1) | FI931941A0 (en) |
HU (1) | HUT65491A (en) |
MX (1) | MX9100537A (en) |
WO (1) | WO1992008078A1 (en) |
YU (1) | YU141991A (en) |
ZA (1) | ZA915500B (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
TWI494527B (en) * | 2011-11-16 | 2015-08-01 | Mitsubishi Heavy Ind Ltd | Fuel burners, combustible solid fuel burner units and combustible solid fuel boilers |
Families Citing this family (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
FR2752042B1 (en) * | 1996-07-31 | 1998-09-11 | Gec Alsthom Stein Ind | SECONDARY AIR SUPPLY NOZZLE IN A COMBUSTION FIREPLACE |
CN102913898B (en) * | 2012-10-16 | 2015-06-24 | 东方电气集团东方锅炉股份有限公司 | Over-fire air distribution manner in front and back wall opposed firing boiler |
JP6284345B2 (en) * | 2013-11-15 | 2018-02-28 | 三菱日立パワーシステムズ株式会社 | boiler |
JP6203033B2 (en) * | 2013-12-17 | 2017-09-27 | 三菱日立パワーシステムズ株式会社 | boiler |
Family Cites Families (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4425855A (en) * | 1983-03-04 | 1984-01-17 | Combustion Engineering, Inc. | Secondary air control damper arrangement |
US4501204A (en) * | 1984-05-21 | 1985-02-26 | Combustion Engineering, Inc. | Overfire air admission with varying momentum air streams |
JPS6370005A (en) * | 1986-09-10 | 1988-03-30 | Mitsubishi Heavy Ind Ltd | Boiler |
US4940004A (en) * | 1989-07-07 | 1990-07-10 | J. H. Jansen Company, Inc. | High energy combustion air nozzle and method for improving combustion in chemical recovery boilers |
US5020454A (en) * | 1990-10-31 | 1991-06-04 | Combustion Engineering, Inc. | Clustered concentric tangential firing system |
-
1991
- 1991-06-24 JP JP3512292A patent/JP2731794B2/en not_active Expired - Fee Related
- 1991-06-24 EP EP91912984A patent/EP0554254B1/en not_active Expired - Lifetime
- 1991-06-24 BR BR919107060A patent/BR9107060A/en active Search and Examination
- 1991-06-24 AU AU81086/91A patent/AU646677B2/en not_active Ceased
- 1991-06-24 HU HU9300808A patent/HUT65491A/en unknown
- 1991-06-24 CA CA002091341A patent/CA2091341C/en not_active Expired - Lifetime
- 1991-06-24 ES ES91912984T patent/ES2092573T3/en not_active Expired - Lifetime
- 1991-06-24 WO PCT/US1991/004440 patent/WO1992008078A1/en active IP Right Grant
- 1991-06-24 DE DE69121579T patent/DE69121579D1/en not_active Expired - Lifetime
- 1991-07-15 ZA ZA915500A patent/ZA915500B/en unknown
- 1991-08-06 MX MX9100537A patent/MX9100537A/en not_active IP Right Cessation
- 1991-08-16 YU YU141991A patent/YU141991A/en unknown
- 1991-10-29 CS CS913277A patent/CS327791A3/en unknown
-
1993
- 1993-04-28 KR KR93701252A patent/KR970009483B1/en not_active IP Right Cessation
- 1993-04-29 FI FI931941A patent/FI931941A0/en not_active Application Discontinuation
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
TWI494527B (en) * | 2011-11-16 | 2015-08-01 | Mitsubishi Heavy Ind Ltd | Fuel burners, combustible solid fuel burner units and combustible solid fuel boilers |
US9702545B2 (en) | 2011-11-16 | 2017-07-11 | Mitsubishi Heavy Industries, Ltd. | Oil-fired burner, solid fuel-fired burner unit, and solid fuel-fired boiler |
Also Published As
Publication number | Publication date |
---|---|
WO1992008078A1 (en) | 1992-05-14 |
KR930702645A (en) | 1993-09-09 |
HUT65491A (en) | 1994-06-28 |
KR970009483B1 (en) | 1997-06-13 |
JP2731794B2 (en) | 1998-03-25 |
CA2091341C (en) | 1995-12-05 |
YU141991A (en) | 1995-10-03 |
CS327791A3 (en) | 1992-05-13 |
FI931941A (en) | 1993-04-29 |
CA2091341A1 (en) | 1992-05-01 |
JPH05507345A (en) | 1993-10-21 |
DE69121579D1 (en) | 1996-09-26 |
BR9107060A (en) | 1993-09-14 |
ES2092573T3 (en) | 1996-12-01 |
HU9300808D0 (en) | 1993-06-28 |
MX9100537A (en) | 1992-06-05 |
FI931941A0 (en) | 1993-04-29 |
AU646677B2 (en) | 1994-03-03 |
AU8108691A (en) | 1992-05-26 |
EP0554254A1 (en) | 1993-08-11 |
ZA915500B (en) | 1992-04-29 |
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