US20070298357A1 - Oxygen to expand burner combustion capability - Google Patents

Oxygen to expand burner combustion capability Download PDF

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Publication number
US20070298357A1
US20070298357A1 US11/475,026 US47502606A US2007298357A1 US 20070298357 A1 US20070298357 A1 US 20070298357A1 US 47502606 A US47502606 A US 47502606A US 2007298357 A1 US2007298357 A1 US 2007298357A1
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United States
Prior art keywords
burner
fuel
air
fed
oxygen
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.)
Abandoned
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US11/475,026
Inventor
Stefan E.F. Laux
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Praxair Technology Inc
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Praxair Technology Inc
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Publication date
Application filed by Praxair Technology Inc filed Critical Praxair Technology Inc
Priority to US11/475,026 priority Critical patent/US20070298357A1/en
Assigned to PRAXAIR TECHNOLOGY, INC. reassignment PRAXAIR TECHNOLOGY, INC. ASSIGNMENT OF ASSIGNORS INTEREST (SEE DOCUMENT FOR DETAILS). Assignors: LAUX, STEFAN E.F.
Priority to EP07796311.4A priority patent/EP2038581B1/en
Priority to CN200780024488XA priority patent/CN101479532B/en
Priority to PCT/US2007/014447 priority patent/WO2008002447A2/en
Priority to MX2008015165A priority patent/MX2008015165A/en
Priority to CA2654922A priority patent/CA2654922C/en
Priority to ES07796311.4T priority patent/ES2587697T3/en
Priority to BRPI0712772A priority patent/BRPI0712772B1/en
Publication of US20070298357A1 publication Critical patent/US20070298357A1/en
Priority to NO20090374A priority patent/NO342259B1/en
Priority to US13/017,483 priority patent/US8459986B2/en
Priority to US13/894,167 priority patent/US9091441B2/en
Priority to US13/894,110 priority patent/US9091440B2/en
Priority to US13/894,494 priority patent/US9091442B2/en
Abandoned legal-status Critical Current

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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23LSUPPLYING 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
    • F23L7/00Supplying non-combustible liquids or gases, other than air, to the fire, e.g. oxygen, steam
    • F23L7/007Supplying oxygen or oxygen-enriched air
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23DBURNERS
    • F23D1/00Burners for combustion of pulverulent fuel
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23DBURNERS
    • F23D1/00Burners for combustion of pulverulent fuel
    • F23D1/005Burners for combustion of pulverulent fuel burning a mixture of pulverulent fuel delivered as a slurry, i.e. comprising a carrying liquid
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E20/00Combustion technologies with mitigation potential
    • Y02E20/34Indirect CO2mitigation, i.e. by acting on non CO2directly related matters of the process, e.g. pre-heating or heat recovery

Definitions

  • the present invention relates to combustion of carbonaceous fuel in a combustion device such as a coal-fired utility boiler.
  • Combustion systems are usually designed to burn fuel that is characterized in that one or more properties of the fuel relevant to combustion of the fuel lies within a range of values.
  • the combustion system generally performs at its highest efficiency when the fuel characteristics fall within the ranges for which the system is designed. Attempts to combust fuel having one or more characteristics outside the range for that characteristic might encounter equipment limitations that prevent the system from reaching design capacity or might lead to negative side effects resulting in operational problems, higher emissions and increased maintenance.
  • Features that may be affected by attempts to combust fuels having one or more characteristics outside of the ranges for which the system is designed include stability of the combustion process, flame heat release pattern, combustion efficiency, NOx emissions, and air and flue gas fan capacity.
  • One example of a characteristic for which a combustion system is often designed is the mass flow rate of fuel into the combustion chamber of the system.
  • Most solid fuel fired combustion systems (for example, systems that combust coal in a boiler) use air-swept pulverizers to dry and pulverize the fuel, which is then carried into the combustion chamber and ignited.
  • the transport medium for the pulverized fuel is air
  • the pulverizers and the fuel piping are designed to achieve at least a minimum air velocity to avoid settling of fuel particles in the flowing stream of transport air. This design condition then requires operating the pulverizer with at least a minimum air flow rate, even under conditions of low fuel mass flow rates.
  • a combustion method that permits combustion to be maintained with a stable flame, even at fuel mass flow rates below those for which the system is designed, would thus be useful.
  • characteristics for which a combustion system is often designed are the content of inert (i.e. not combustible) matter (whether solid, such as ash and minerals, or liquid, typically water), and the specific energy value of the fuel, i.e. the amount of energy obtainable upon combustion of the combustible matter present per unit mass of combustible matter.
  • Fuels that may lead to such operational problems may nonetheless have an economical advantage over fuels that conform to the design specifications of the system.
  • a combustion method that permits combustion to be maintained with a stable flame, even with fuel that contains too high a proportion of inert matter or too low a specific energy value for the system, would thus be useful.
  • One aspect of the present invention is a method of modifying operation of a burner, comprising
  • step (E) combusting said fuel and air fed in step (C) with said oxidant fed in step (D) in a stable flame at said burner, wherein said oxidant is fed into the base of said flame at a mass flow rate that maintains said stable flame.
  • Another aspect of the present invention is a method of operating a burner, comprising
  • step (C) combusting said fuel and air fed in step (B) in a stable flame at said burner while also feeding a stream of gaseous oxidant comprising more than 21 vol. % oxygen into the base of said flame at said burner, wherein said oxidant combusts with said fuel and air, wherein said oxidant is fed into the base of said flame at a mass flow rate that maintains said stable flame.
  • the stream of gaseous oxidant comprising more than 21 vol. % oxygen is in addition to the fuel-air stream and the one or more streams of air other than the air mixed with the fuel in the fuel-air stream.
  • the combustion that is made possible by feeding the gaseous oxidant is advantageously carried out without feeding supplemental fuel in gaseous, liquid or solid form such as natural gas or methane, fuel oil or liquid hydrocarbons, or solids which contain a higher content of volatilizable matter than is contained in the particulate solid fuel that is fed and combusted in the practice of this invention.
  • supplemental fuel in gaseous, liquid or solid form such as natural gas or methane, fuel oil or liquid hydrocarbons, or solids which contain a higher content of volatilizable matter than is contained in the particulate solid fuel that is fed and combusted in the practice of this invention.
  • a flame is “stable” means that, once it is established under a given set of combustion conditions, it continues to burn indefinitely under those combustion conditions.
  • FIG. 1 is a cross-sectional view of one embodiment of apparatus with which the present invention can be practiced.
  • FIG. 2 is a cross-sectional view a burner useful in the embodiment of FIG. 1 .
  • FIG. 3 is a cross-sectional view of the burner of FIG. 2 , showing modification of that embodiment in accordance with the present invention.
  • FIG. 1 depicts a representative combustion system with which the present invention can be practiced.
  • the system includes combustion device 1 , such as a coal-fired boiler.
  • the fuel in this illustration is coal, but fuels with which the present invention is useful include any matter that has heating value, i.e. that liberates heat upon combustion.
  • the terms “fuel” and “fuel solids” used herein refer to the matter that is fed to be combusted, including the combustible constituents thereof as well as any noncombustible constituents that are present.
  • Combustion device 1 houses combustion chamber 3 , which is typically a space that can withstand the high temperatures that are attained by the combustion that is carried out in combustion chamber 3 .
  • the combustion chamber can be made of, or be lined with, refractory material, or it can be contained by walls of tubes that carry material such as water that absorbs heat from the combustion chamber. Products of the combustion pass out of combustion chamber through flue 5 .
  • the heat that is generated by the combustion can be used in any of various ways (not shown in FIG. 1 ) such as forming steam in pipes that surround combustion chamber 3 or that are arrayed across flue 5 .
  • Burner 11 is provided through a surface of combustion device 1 .
  • the burners can be wall-mounted, roof-mounted, or corner-mounted.
  • Fuel-air stream 12 comprising a mixture of fuel and air, and air stream 13 , are fed through burner 11 and combusted in combustion chamber 3 .
  • the combustion forms flame 15 whose base is at the burner.
  • Optional overfire air stream 14 of air is fed into combustion chamber 3 downstream from flame 15 , between flame 15 and flue 5 .
  • the air streams 13 (and overfire air streams 14 when used) can be fed from a common windbox or plenum (not shown) which is conventional in current industrial practice.
  • the fuel-air stream 12 can be formed in unit 17 , which in many embodiments is a pulverizer in which the fuel 18 is pulverized into particulate form that can be carried in a stream of transport air, and in which the fuel is mixed with air 19 which serves as transport air and which also provides some oxygen for combustion.
  • the pulverizer typically has a maximum mass flow rate of fuel (termed the “full load”) at which it can produce fuel-air stream 12 .
  • Unit 17 can instead be apparatus which forms the fuel-air stream by combining a stream of already pulverized particulate fuel with a stream of transport air.
  • FIGS. 2 and 3 depict in cross-section one embodiment of a burner 11 , which is representative of burners with which the present invention can be practiced.
  • Passage 22 conveys the fuel-air stream 12 toward and into combustion chamber 3 , where it combusts in flame 15 as shown in FIGS. 1 and 3 .
  • Passage or passages 23 convey air stream 13 toward and into combustion chamber 3 , where the air provides oxygen for combustion in flame 15 .
  • Optional passage or passages 24 convey secondary air toward and into combustion chamber 3 , where the secondary air can participate in the combustion.
  • the burners depicted in FIGS. 2 and 3 are preferably circular, with passage 22 disposed along the central axis of the burner.
  • the optional secondary air can be provided through one passage 24 that is concentrically located completely around passage 22 , or through two or more separate passages each of which has its own opening into combustion chamber 3 .
  • FIG. 3 depicts the burner of FIG. 2 which has been modified in accordance with the present invention.
  • Reference numerals that appear in both FIGS. 2 and 3 have the same meanings for the embodiment of FIG. 3 as for the embodiment of FIG. 2 .
  • the embodiment of FIG. 3 includes lance 31 which is situated within passage 22 .
  • Lance 31 ends at opening 33 which is situated to feed gas out of opening 33 into the base 35 of flame 15 .
  • the other end of lance 31 is connected to a supply of oxidant which is equipped with suitable valves and controls so that it provides a stream of oxidant into lance 31 when desired and at the flow rate desired.
  • the oxidant should contain more than 21 vol. % oxygen, and preferably contains more than 30 vol. % oxygen and more preferably at least 90 vol. % oxygen.
  • the oxidant can be supplied from a suitable storage tank, or can be provided by combining a stream of air with a stream of commercially pure oxygen (e.g. 99 vol. % or higher purity oxygen) in amounts relative to each other that establish the desired oxygen content.
  • the present invention can be practiced in the following manner to modify a burner so that particulate solid carbonaceous fuel can be combusted at the burner even though the fuel is fed at a fuel solids mass flow rate so low that combustion of the fuel at the burner with air as the only source of oxygen for combustion cannot be maintained in a stable flame at the burner.
  • the minimum fuel solids mass flow rate is determined, for that burner, at which combustion of the fuel with air as the sole source of oxygen for combustion could be maintained in a stable flame at the burner.
  • One way to determine this rate is to determine, at the minimum airflow rate that is necessary for operation of the burner, the minimum content of fuel solids in that airflow at which combustion of the fuel fed in that airflow can be maintained in a stable flame at the burner, with air as the only source of oxygen for combustion.
  • the combination of the minimum airflow rate and the minimum fuel solids content establishes a minimum fuel solids mass flow rate at which combustion in air could be maintained at the burner in a stable flame.
  • Lance 31 or equivalent conduit is placed through burner 22 as shown in FIG. 3 , with its outlet end positioned at the opening of the burner at its other end connected (through conventional valves and controls enabling control of the flow rate and enabling one to turn the flow on and off) to a source of oxidant containing more than 21 vol. % oxygen, conveniently at least 30 vol. % oxygen, and preferably at least 90 vol. % oxygen.
  • a fuel-air stream is fed through the burner at a solids mass flow rate which is lower than that minimum established as described above, combustion air is fed through the burner (for instance, through passage or passages 23 of the burner in FIG. 3 ), and oxidant containing more than 21 vol. % oxygen, conveniently at least 30 vol. % oxygen, and preferably at least 90 vol. % oxygen, is fed through lance 31 .
  • the oxidant emerging at outlet 33 is fed into the base 35 of the flame at the burner.
  • the mixture of the fuel-air stream, the combustion air stream, and the oxidant is ignited, and the oxidant emerging at outlet 33 is fed into the base 35 of the flame at the burner.
  • the mass flow rate at which oxygen is fed into the base of the flame is adjusted to determine a value at which combustion of the fuel is maintained in a stable flame at the burner. Then, the flow rate of oxygen is held at that level, or is increased to ensure stable combustion even in the event of fluctuations of the mass flow rate of the fuel.
  • the amount of oxygen that is present in the oxidant emerging from outlet 33 into the base 35 of the flame is 1% to 25% of the total stoichiometric amount required to completely combust the combustible portion of the fuel that is fed. If desired, the oxygen content of the oxidant can be adjusted to accommodate the needs of the situation; as the feed rate decreases, increasing the oxygen content of the oxidant will generally be needed to maintain stable combustion of the fuel.
  • This embodiment of the invention is expected to permit combustion in a stable flame at the burner to be maintained even when the fuel solids mass flow rate corresponds to 30% or less of the minimum fuel solids mass flow rate needed for stable combustion to be maintained when air is used as the only source of oxygen for combustion.
  • the minimum fuel solids mass flow rate at which this invention becomes applicable whether expressed as an absolute figure or as a percentage of the maximum flow rate, varies from one unit to another but can readily be determined experimentally for any unit.
  • the present invention can be practiced in the following manner to modify a burner so that particulate solid carbonaceous fuel can be combusted in the burner even though the stream of air mixed with fuel which is fed through the burner (such as from a pulverizer) has an air-to-fuel mass ratio so high, such as 2.5 or higher or even 3.0 or higher (i.e. that might be encountered upon “turndown” of the combustion rate), that combustion of the fuel in the burner with air as the only source of oxygen for combustion cannot be maintained in a stable flame at the burner.
  • the maximum air-to-fuel mass ratio in the stream of air mixed with fuel that is fed through the burner is determined, for that burner, at which combustion of the fuel can be maintained in a stable flame at the burner, with air as the only source of oxygen for combustion.
  • Lance 31 or equivalent conduit is placed through burner 22 as shown in FIG. 3 , with its outlet end positioned at the opening of the burner at its other end connected (through conventional valves and controls enabling control of the flow rate and enabling one to turn the flow on and off) to a source of oxidant containing more than 21 vol. % oxygen, conveniently at least 30 vol. % oxygen, and preferably at least 90 vol. % oxygen.
  • a fuel-air stream is fed through the burner wherein the air-to-fuel ratio of that stream is higher than that maximum established as described above, combustion air is fed through the burner (for instance, through passage or passages 23 of the burner in FIG. 3 ), and oxidant containing more than 21 vol. % oxygen, conveniently at least 30 vol.
  • % oxygen and preferably at least 90 vol. % oxygen, is fed through lance 31 . If combustion at the burner has already been established, the oxidant emerging at outlet 33 is fed into the base 35 of the flame at the burner. If combustion at the burner has not already been established, the mixture of the fuel-air stream, the combustion air stream, and the oxidant is ignited, and the oxidant emerging at outlet 33 is fed into the base 35 of the flame at the burner.
  • the mass flow rate at which oxygen is fed into the base of the flame is adjusted to determine a value at which stable combustion of the fuel is maintained in a flame at the burner. Then, the flow rate of oxygen is held at that level, or increased to ensure stable combustion even in the event of fluctuations of the content of noncombustible matter in the fuel.
  • the amount of oxygen that is present in the oxidant emerging from outlet 33 into the base 35 of the flame is 1% to 25% of the total stoichiometric amount required to completely combust the combustible portion of the fuel fed.
  • the oxygen content of the oxidant can be adjusted to accommodate the needs of the situation; as the air-to-fuel ratio of the fuel feed stream increases, increasing the oxygen content of the oxidant will generally be needed to maintain stable combustion of the fuel.
  • the maximum air-to-fuel ratio in the fuel feed stream varies from one unit to another but can readily be determined experimentally for any given unit.
  • combustion of fuel fed in streams of air mixed with the fuel wherein the air-to-fuel ratio is below about 2.0 is less likely to need the assistance provided by the present invention, whereas the ability of the present invention to achieve combustion of fuel fed in feed streams having higher air-to-fuel ratios is likely to be realized with fuel feed streams fed at air-to-fuel ratios of 2.5 or higher, and even more likely when fed at air-to-fuel ratios of 3.0 or higher.
  • the present invention can be practiced in the following manner to modify a burner so that particulate solid carbonaceous fuel can be combusted in the burner even though the fuel contains an amount of noncombustible (inert) material so high, up to 70 or 75 wt. %, or even 80 to 90 wt. %, that combustion of the fuel in the burner with air as the only source of oxygen for combustion cannot be maintained in a stable flame at the burner.
  • Fuel containing that much inert material can be found or formed naturally, or can be formed by blending fuel with lesser (or no) inert material with inert material or with fuel containing even higher amounts of inert material.
  • the maximum content of noncombustible matter in the fuel is determined, for that burner, at which combustion of the fuel can be maintained in a stable flame at the burner, with air as the only source of oxygen for combustion.
  • Lance 31 or equivalent conduit is placed through burner 22 as shown in FIG. 3 , with its outlet end positioned at the opening of the burner at its other end connected (through conventional valves and controls enabling control of the flow rate and enabling one to turn the flow on and off) to a source of oxidant containing more than 21 vol. % oxygen, conveniently at least 30 vol. % oxygen, and preferably at least 90 vol. % oxygen.
  • a fuel-air stream is fed through the burner wherein the content of noncombustible matter in the fuel is higher than that maximum established as described above, combustion air is fed through the burner (for instance, through passage or passages 23 of the burner in FIG. 3 ), and oxidant containing more than 21 vol. % oxygen, conveniently at least 30 vol.
  • % oxygen and preferably at least 90 vol. % oxygen, is fed through lance 31 . If combustion at the burner has already been established, the oxidant emerging at outlet 33 is fed into the base 35 of the flame at the burner. If combustion at the burner has not already been established, the mixture of the fuel-air stream, the combustion air stream, and the oxidant is ignited, and the oxidant emerging at outlet 33 is fed into the base 35 of the flame at the burner.
  • the mass flow rate at which oxygen is fed into the base of the flame is adjusted to determine a value at which stable combustion of the fuel is maintained in a flame at the burner. Then, the flow rate of oxygen is held at that level, or increased to ensure stable combustion even in the event of fluctuations of the content of noncombustible matter in the fuel.
  • the amount of oxygen that is present in the oxidant emerging from outlet 33 into the base 35 of the flame is 1% to 25% of the total stoichiometric amount required to completely combust the combustible portion of the fuel fed.
  • the oxygen content of the oxidant can be adjusted to accommodate the needs of the situation; as the percentage of combustible matter in the fuel decreases, increasing the oxygen content of the oxidant will generally be needed to maintain stable combustion of the fuel.
  • the maximum noncombustible matter content above which the present invention becomes applicable varies from one unit to another but can readily be determined experimentally for any given unit.
  • combustion of fuels having noncombustible matter content below about 30 wt. % is less likely to need the assistance provided by the present invention, whereas the ability of the present invention to achieve combustion of fuel having high noncombustible matter content is likely to be realized with fuel containing 35 wt. % or higher noncombustible matter, and even more likely with fuel containing 40 wt. % or higher noncombustible matter.
  • the present invention can be practiced in the following manner to modify a burner so that particulate solid carbonaceous fuel can be combusted in the burner even though the specific energy content of the fuel (e.g. BTU per pound of fuel) is so low that combustion of the fuel in the burner with air as the only source of oxygen for combustion cannot be maintained in a stable flame at the burner.
  • specific energy content of the fuel e.g. BTU per pound of fuel
  • the minimum specific energy content of the fuel is determined at which combustion of the fuel can be maintained in a stable flame at the burner, with air as the only source of oxygen for combustion.
  • Lance 31 or equivalent conduit is placed through burner 22 as shown in FIG. 3 , with its outlet end positioned at the opening of the burner at its other end connected (through conventional valves and controls enabling control of the flow rate and enabling one to turn the flow on and off) to a source of oxidant containing more than 21 vol. % oxygen, conveniently at least 30 vol. % oxygen, and preferably at least 90 vol. % oxygen.
  • a fuel-air stream is fed through the burner wherein the specific energy content of the fuel is lower than that minimum established as described above, combustion air is fed through the burner (for instance, through passage or passages 23 of the burner in FIG. 3 ), and oxidant containing more than 21 vol. % oxygen, conveniently at least 30 vol. % oxygen, and preferably at least 90 vol. % oxygen, is fed through lance 31 .
  • combustion air is fed through the burner (for instance, through passage or passages 23 of the burner in FIG. 3 ), and oxidant containing more than 21 vol. % oxygen, conveniently at least 30 vol. % oxygen, and preferably at least 90 vol. % oxygen, is fed through lance 31 .
  • the oxidant emerging at outlet 33 is fed into the base 35 of the flame at the burner.
  • the mixture of the fuel-air stream, the combustion air stream, and the oxidant is ignited, and the oxidant emerging at outlet 33 is fed into the base 35 of the flame at the burner.
  • the mass flow rate at which oxygen is fed into the base of the flame is adjusted to determine a value at which stable combustion of the fuel is maintained in a flame at the burner. Then, the flow rate of oxygen is held at that level, or increased to ensure stable combustion even in the event of fluctuations of the specific energy content of the fuel.
  • the amount of oxygen that is present in the oxidant emerging from outlet 33 into the base 35 of the flame is 1% to 25% of the total stoichiometric amount required to completely combust the combustible portion of the fuel fed.
  • the oxygen content of the oxidant can be adjusted to accommodate the needs of the situation; as the specific energy content of the fuel decreases, increasing the oxygen content of the oxidant will generally be needed to maintain stable combustion of the fuel.
  • the minimum specific energy content below which the present invention becomes applicable varies from one unit to another but can readily be determined experimentally for any given unit.
  • combustion of fuels having specific energy content above about 10,000 BTU/pound is less likely to need the assistance provided by the present invention, whereas the ability of the present invention to achieve combustion of fuel having low specific energy content is likely to be realized with fuel having a specific energy content of 8,000 BTU/pound or lower, as determined from a dried fuel sample, and even more likely with fuel having a specific energy content of 6,000 BTU/pound or lower as determined from a dried fuel sample.

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Pre-Mixing And Non-Premixing Gas Burner (AREA)

Abstract

A burner at which fuel cannot be combusted with air as the only source of oxygen for combustion in a stable flame at the burner when the feed rate of the fuel is too low, when the fuel is fed at too high an air-to-fuel mass ratio, when the fuel contains too high an amount of inert matter, or when the specific energy content of the fuel is too low, is modified by supplying oxidant containing more than 21 vol. % oxygen into the base of a flame at the burner, whereupon such fuels can be combusted at the burner.

Description

    FIELD OF THE INVENTION
  • The present invention relates to combustion of carbonaceous fuel in a combustion device such as a coal-fired utility boiler.
  • BACKGROUND OF THE INVENTION
  • Combustion systems are usually designed to burn fuel that is characterized in that one or more properties of the fuel relevant to combustion of the fuel lies within a range of values. The combustion system generally performs at its highest efficiency when the fuel characteristics fall within the ranges for which the system is designed. Attempts to combust fuel having one or more characteristics outside the range for that characteristic might encounter equipment limitations that prevent the system from reaching design capacity or might lead to negative side effects resulting in operational problems, higher emissions and increased maintenance. Features that may be affected by attempts to combust fuels having one or more characteristics outside of the ranges for which the system is designed include stability of the combustion process, flame heat release pattern, combustion efficiency, NOx emissions, and air and flue gas fan capacity.
  • One example of a characteristic for which a combustion system is often designed is the mass flow rate of fuel into the combustion chamber of the system. Most solid fuel fired combustion systems (for example, systems that combust coal in a boiler) use air-swept pulverizers to dry and pulverize the fuel, which is then carried into the combustion chamber and ignited. Since the transport medium for the pulverized fuel is air, the pulverizers and the fuel piping are designed to achieve at least a minimum air velocity to avoid settling of fuel particles in the flowing stream of transport air. This design condition then requires operating the pulverizer with at least a minimum air flow rate, even under conditions of low fuel mass flow rates. Maintaining this minimum air flow rate thus dilutes the air/fuel mixture, under conditions of low fuel mass flow rates, to a degree that stable combustion can not be attained and the burner flame gradually extinguishes. This is typically the case at loads below 30% of the full load capacity of the pulverizer. Practitioners have found it necessary to use auxiliary fuel (such as natural gas or oil) to maintain flame and combustion stability when the fuel is being fed at such low rates.
  • A combustion method that permits combustion to be maintained with a stable flame, even at fuel mass flow rates below those for which the system is designed, would thus be useful.
  • Other examples of characteristics for which a combustion system is often designed are the content of inert (i.e. not combustible) matter (whether solid, such as ash and minerals, or liquid, typically water), and the specific energy value of the fuel, i.e. the amount of energy obtainable upon combustion of the combustible matter present per unit mass of combustible matter. Fuels that contain more inert matter than the range of inert matter for which the combustion system is designed, and fuels that have a specific energy value below the range of specific energy values for which the system is designed, when fed into the combustion system, cause many of the problems such as inability to maintain combustion with a stable flame.
  • Fuels that may lead to such operational problems may nonetheless have an economical advantage over fuels that conform to the design specifications of the system. Thus, a combustion method that permits combustion to be maintained with a stable flame, even with fuel that contains too high a proportion of inert matter or too low a specific energy value for the system, would thus be useful.
  • BRIEF SUMMARY OF THE INVENTION
  • One aspect of the present invention is a method of modifying operation of a burner, comprising
  • (A) providing a burner through which a stream of air mixed with particulate solid carbonaceous fuel, and one or more streams of air other than the air mixed with said fuel, can be fed and combusted in a stable flame at said burner, but wherein maintaining said stable flame at said burner when air provided in said streams is the only source of oxygen for said combustion requires that the fuel satisfy one or more conditions in that one or more of (1) the mass flow rate of the fuel through said burner, (2) the fuel-to-air ratio of the stream of air mixed with fuel that is fed through the burner, (3) the content of combustible (i.e. non-inert) matter in the fuel, and (4) the specific energy value of the fuel, must be at least sufficient for said stable flame to be maintained at said burner,
  • (B) inserting through said burner a lance the outlet end of which is positioned to eject gas into the base of a flame at said burner,
  • (C) feeding through said burner a stream of air mixed with particulate solid fuel which does not satisfy at least one of said conditions and therefore cannot be combusted in a stable flame at said burner in air as the only source of oxygen for combustion, and feeding through said burner said one or more streams of air other than the air mixed with said fuel,
  • (D) feeding gaseous oxidant comprising more than 21 vol. % oxygen through the outlet end of said lance, and
  • (E) combusting said fuel and air fed in step (C) with said oxidant fed in step (D) in a stable flame at said burner, wherein said oxidant is fed into the base of said flame at a mass flow rate that maintains said stable flame.
  • Another aspect of the present invention is a method of operating a burner, comprising
  • (A) providing a burner through which a stream of air mixed with particulate solid carbonaceous fuel, and one or more streams of air other than the air mixed with said fuel, can be fed and combusted in a stable flame at said burner, but wherein maintaining said stable flame at said burner when air provided in said streams is the only source of oxygen for said combustion requires that the fuel satisfy one or more conditions in that one or more of (1) the mass flow rate of the fuel through said burner, (2) the fuel-to-air ratio of the stream of air mixed with fuel that is fed through the burner, (3) the content of combustible matter in the fuel, and (4) the specific energy value of the fuel, must be at least sufficient for said stable flame to be maintained at said burner,
  • (B) feeding through said burner a stream of air mixed with particulate solid fuel which does not satisfy at least one of said conditions and therefore cannot be combusted in a stable flame at said burner in air as the only source of oxygen for combustion, and feeding through said burner said one or more streams of air other than the air mixed with said fuel, and
  • (C) combusting said fuel and air fed in step (B) in a stable flame at said burner while also feeding a stream of gaseous oxidant comprising more than 21 vol. % oxygen into the base of said flame at said burner, wherein said oxidant combusts with said fuel and air, wherein said oxidant is fed into the base of said flame at a mass flow rate that maintains said stable flame.
  • In both of the aforementioned aspects of the present invention, the stream of gaseous oxidant comprising more than 21 vol. % oxygen is in addition to the fuel-air stream and the one or more streams of air other than the air mixed with the fuel in the fuel-air stream.
  • In both of the aforementioned aspects of the present invention, the combustion that is made possible by feeding the gaseous oxidant is advantageously carried out without feeding supplemental fuel in gaseous, liquid or solid form such as natural gas or methane, fuel oil or liquid hydrocarbons, or solids which contain a higher content of volatilizable matter than is contained in the particulate solid fuel that is fed and combusted in the practice of this invention.
  • As used herein, that a flame is “stable” means that, once it is established under a given set of combustion conditions, it continues to burn indefinitely under those combustion conditions.
  • BRIEF DESCRIPTION OF THE DRAWING
  • FIG. 1 is a cross-sectional view of one embodiment of apparatus with which the present invention can be practiced.
  • FIG. 2 is a cross-sectional view a burner useful in the embodiment of FIG. 1.
  • FIG. 3 is a cross-sectional view of the burner of FIG. 2, showing modification of that embodiment in accordance with the present invention.
  • DETAILED DESCRIPTION OF THE INVENTION
  • FIG. 1 depicts a representative combustion system with which the present invention can be practiced. The system includes combustion device 1, such as a coal-fired boiler. The fuel in this illustration is coal, but fuels with which the present invention is useful include any matter that has heating value, i.e. that liberates heat upon combustion. The terms “fuel” and “fuel solids” used herein refer to the matter that is fed to be combusted, including the combustible constituents thereof as well as any noncombustible constituents that are present.
  • Combustion device 1 houses combustion chamber 3, which is typically a space that can withstand the high temperatures that are attained by the combustion that is carried out in combustion chamber 3. The combustion chamber can be made of, or be lined with, refractory material, or it can be contained by walls of tubes that carry material such as water that absorbs heat from the combustion chamber. Products of the combustion pass out of combustion chamber through flue 5. The heat that is generated by the combustion can be used in any of various ways (not shown in FIG. 1) such as forming steam in pipes that surround combustion chamber 3 or that are arrayed across flue 5.
  • Burner 11 is provided through a surface of combustion device 1. In actual practice, anywhere from 1 to 20 or more burners may be provided, depending on the size of the installation. Furthermore, the burners can be wall-mounted, roof-mounted, or corner-mounted. Fuel-air stream 12 comprising a mixture of fuel and air, and air stream 13, are fed through burner 11 and combusted in combustion chamber 3. The combustion forms flame 15 whose base is at the burner. Optional overfire air stream 14 of air is fed into combustion chamber 3 downstream from flame 15, between flame 15 and flue 5. When more than one burner is employed, the air streams 13 (and overfire air streams 14, when used) can be fed from a common windbox or plenum (not shown) which is conventional in current industrial practice.
  • The fuel-air stream 12 can be formed in unit 17, which in many embodiments is a pulverizer in which the fuel 18 is pulverized into particulate form that can be carried in a stream of transport air, and in which the fuel is mixed with air 19 which serves as transport air and which also provides some oxygen for combustion. The pulverizer typically has a maximum mass flow rate of fuel (termed the “full load”) at which it can produce fuel-air stream 12. Unit 17 can instead be apparatus which forms the fuel-air stream by combining a stream of already pulverized particulate fuel with a stream of transport air.
  • FIGS. 2 and 3 depict in cross-section one embodiment of a burner 11, which is representative of burners with which the present invention can be practiced. Passage 22 conveys the fuel-air stream 12 toward and into combustion chamber 3, where it combusts in flame 15 as shown in FIGS. 1 and 3. Passage or passages 23 convey air stream 13 toward and into combustion chamber 3, where the air provides oxygen for combustion in flame 15. Optional passage or passages 24 convey secondary air toward and into combustion chamber 3, where the secondary air can participate in the combustion.
  • The burners depicted in FIGS. 2 and 3 are preferably circular, with passage 22 disposed along the central axis of the burner. In one embodiment there is one passage 23 which is annular and concentrically located completely around passage 22. In other embodiments, there can be two or more passages 23, each terminating in its own opening into combustion chamber 3. Likewise, the optional secondary air can be provided through one passage 24 that is concentrically located completely around passage 22, or through two or more separate passages each of which has its own opening into combustion chamber 3.
  • FIG. 3 depicts the burner of FIG. 2 which has been modified in accordance with the present invention. Reference numerals that appear in both FIGS. 2 and 3 have the same meanings for the embodiment of FIG. 3 as for the embodiment of FIG. 2.
  • The embodiment of FIG. 3 includes lance 31 which is situated within passage 22. Lance 31 ends at opening 33 which is situated to feed gas out of opening 33 into the base 35 of flame 15. The other end of lance 31 is connected to a supply of oxidant which is equipped with suitable valves and controls so that it provides a stream of oxidant into lance 31 when desired and at the flow rate desired. The oxidant should contain more than 21 vol. % oxygen, and preferably contains more than 30 vol. % oxygen and more preferably at least 90 vol. % oxygen. The oxidant can be supplied from a suitable storage tank, or can be provided by combining a stream of air with a stream of commercially pure oxygen (e.g. 99 vol. % or higher purity oxygen) in amounts relative to each other that establish the desired oxygen content.
  • The present invention can be practiced in the following manner to modify a burner so that particulate solid carbonaceous fuel can be combusted at the burner even though the fuel is fed at a fuel solids mass flow rate so low that combustion of the fuel at the burner with air as the only source of oxygen for combustion cannot be maintained in a stable flame at the burner.
  • The minimum fuel solids mass flow rate is determined, for that burner, at which combustion of the fuel with air as the sole source of oxygen for combustion could be maintained in a stable flame at the burner. One way to determine this rate is to determine, at the minimum airflow rate that is necessary for operation of the burner, the minimum content of fuel solids in that airflow at which combustion of the fuel fed in that airflow can be maintained in a stable flame at the burner, with air as the only source of oxygen for combustion. The combination of the minimum airflow rate and the minimum fuel solids content establishes a minimum fuel solids mass flow rate at which combustion in air could be maintained at the burner in a stable flame.
  • Lance 31 or equivalent conduit is placed through burner 22 as shown in FIG. 3, with its outlet end positioned at the opening of the burner at its other end connected (through conventional valves and controls enabling control of the flow rate and enabling one to turn the flow on and off) to a source of oxidant containing more than 21 vol. % oxygen, conveniently at least 30 vol. % oxygen, and preferably at least 90 vol. % oxygen.
  • Then, a fuel-air stream is fed through the burner at a solids mass flow rate which is lower than that minimum established as described above, combustion air is fed through the burner (for instance, through passage or passages 23 of the burner in FIG. 3), and oxidant containing more than 21 vol. % oxygen, conveniently at least 30 vol. % oxygen, and preferably at least 90 vol. % oxygen, is fed through lance 31. If combustion at the burner has already been established, the oxidant emerging at outlet 33 is fed into the base 35 of the flame at the burner. If combustion at the burner has not already been established, the mixture of the fuel-air stream, the combustion air stream, and the oxidant is ignited, and the oxidant emerging at outlet 33 is fed into the base 35 of the flame at the burner.
  • The mass flow rate at which oxygen is fed into the base of the flame is adjusted to determine a value at which combustion of the fuel is maintained in a stable flame at the burner. Then, the flow rate of oxygen is held at that level, or is increased to ensure stable combustion even in the event of fluctuations of the mass flow rate of the fuel. Typically, the amount of oxygen that is present in the oxidant emerging from outlet 33 into the base 35 of the flame is 1% to 25% of the total stoichiometric amount required to completely combust the combustible portion of the fuel that is fed. If desired, the oxygen content of the oxidant can be adjusted to accommodate the needs of the situation; as the feed rate decreases, increasing the oxygen content of the oxidant will generally be needed to maintain stable combustion of the fuel.
  • This embodiment of the invention is expected to permit combustion in a stable flame at the burner to be maintained even when the fuel solids mass flow rate corresponds to 30% or less of the minimum fuel solids mass flow rate needed for stable combustion to be maintained when air is used as the only source of oxygen for combustion. The minimum fuel solids mass flow rate at which this invention becomes applicable, whether expressed as an absolute figure or as a percentage of the maximum flow rate, varies from one unit to another but can readily be determined experimentally for any unit.
  • The present invention can be practiced in the following manner to modify a burner so that particulate solid carbonaceous fuel can be combusted in the burner even though the stream of air mixed with fuel which is fed through the burner (such as from a pulverizer) has an air-to-fuel mass ratio so high, such as 2.5 or higher or even 3.0 or higher (i.e. that might be encountered upon “turndown” of the combustion rate), that combustion of the fuel in the burner with air as the only source of oxygen for combustion cannot be maintained in a stable flame at the burner. (It will of course be recognized that references herein to an air-to-fuel ratio too high to enable a stable flame, and to a fuel-to-air ratio needing to be above a value to enable a stable flame, are simply different ways of expressing the same point.)
  • The maximum air-to-fuel mass ratio in the stream of air mixed with fuel that is fed through the burner is determined, for that burner, at which combustion of the fuel can be maintained in a stable flame at the burner, with air as the only source of oxygen for combustion.
  • Lance 31 or equivalent conduit is placed through burner 22 as shown in FIG. 3, with its outlet end positioned at the opening of the burner at its other end connected (through conventional valves and controls enabling control of the flow rate and enabling one to turn the flow on and off) to a source of oxidant containing more than 21 vol. % oxygen, conveniently at least 30 vol. % oxygen, and preferably at least 90 vol. % oxygen. Then, a fuel-air stream is fed through the burner wherein the air-to-fuel ratio of that stream is higher than that maximum established as described above, combustion air is fed through the burner (for instance, through passage or passages 23 of the burner in FIG. 3), and oxidant containing more than 21 vol. % oxygen, conveniently at least 30 vol. % oxygen, and preferably at least 90 vol. % oxygen, is fed through lance 31. If combustion at the burner has already been established, the oxidant emerging at outlet 33 is fed into the base 35 of the flame at the burner. If combustion at the burner has not already been established, the mixture of the fuel-air stream, the combustion air stream, and the oxidant is ignited, and the oxidant emerging at outlet 33 is fed into the base 35 of the flame at the burner.
  • The mass flow rate at which oxygen is fed into the base of the flame is adjusted to determine a value at which stable combustion of the fuel is maintained in a flame at the burner. Then, the flow rate of oxygen is held at that level, or increased to ensure stable combustion even in the event of fluctuations of the content of noncombustible matter in the fuel. Typically, the amount of oxygen that is present in the oxidant emerging from outlet 33 into the base 35 of the flame is 1% to 25% of the total stoichiometric amount required to completely combust the combustible portion of the fuel fed. If desired, the oxygen content of the oxidant can be adjusted to accommodate the needs of the situation; as the air-to-fuel ratio of the fuel feed stream increases, increasing the oxygen content of the oxidant will generally be needed to maintain stable combustion of the fuel.
  • The maximum air-to-fuel ratio in the fuel feed stream, above which the present invention becomes applicable, varies from one unit to another but can readily be determined experimentally for any given unit. In general, combustion of fuel fed in streams of air mixed with the fuel wherein the air-to-fuel ratio is below about 2.0 is less likely to need the assistance provided by the present invention, whereas the ability of the present invention to achieve combustion of fuel fed in feed streams having higher air-to-fuel ratios is likely to be realized with fuel feed streams fed at air-to-fuel ratios of 2.5 or higher, and even more likely when fed at air-to-fuel ratios of 3.0 or higher.
  • The present invention can be practiced in the following manner to modify a burner so that particulate solid carbonaceous fuel can be combusted in the burner even though the fuel contains an amount of noncombustible (inert) material so high, up to 70 or 75 wt. %, or even 80 to 90 wt. %, that combustion of the fuel in the burner with air as the only source of oxygen for combustion cannot be maintained in a stable flame at the burner. Fuel containing that much inert material can be found or formed naturally, or can be formed by blending fuel with lesser (or no) inert material with inert material or with fuel containing even higher amounts of inert material.
  • The maximum content of noncombustible matter in the fuel is determined, for that burner, at which combustion of the fuel can be maintained in a stable flame at the burner, with air as the only source of oxygen for combustion.
  • Lance 31 or equivalent conduit is placed through burner 22 as shown in FIG. 3, with its outlet end positioned at the opening of the burner at its other end connected (through conventional valves and controls enabling control of the flow rate and enabling one to turn the flow on and off) to a source of oxidant containing more than 21 vol. % oxygen, conveniently at least 30 vol. % oxygen, and preferably at least 90 vol. % oxygen. Then, a fuel-air stream is fed through the burner wherein the content of noncombustible matter in the fuel is higher than that maximum established as described above, combustion air is fed through the burner (for instance, through passage or passages 23 of the burner in FIG. 3), and oxidant containing more than 21 vol. % oxygen, conveniently at least 30 vol. % oxygen, and preferably at least 90 vol. % oxygen, is fed through lance 31. If combustion at the burner has already been established, the oxidant emerging at outlet 33 is fed into the base 35 of the flame at the burner. If combustion at the burner has not already been established, the mixture of the fuel-air stream, the combustion air stream, and the oxidant is ignited, and the oxidant emerging at outlet 33 is fed into the base 35 of the flame at the burner.
  • The mass flow rate at which oxygen is fed into the base of the flame is adjusted to determine a value at which stable combustion of the fuel is maintained in a flame at the burner. Then, the flow rate of oxygen is held at that level, or increased to ensure stable combustion even in the event of fluctuations of the content of noncombustible matter in the fuel. Typically, the amount of oxygen that is present in the oxidant emerging from outlet 33 into the base 35 of the flame is 1% to 25% of the total stoichiometric amount required to completely combust the combustible portion of the fuel fed. If desired, the oxygen content of the oxidant can be adjusted to accommodate the needs of the situation; as the percentage of combustible matter in the fuel decreases, increasing the oxygen content of the oxidant will generally be needed to maintain stable combustion of the fuel.
  • The maximum noncombustible matter content above which the present invention becomes applicable varies from one unit to another but can readily be determined experimentally for any given unit. In general, combustion of fuels having noncombustible matter content below about 30 wt. % is less likely to need the assistance provided by the present invention, whereas the ability of the present invention to achieve combustion of fuel having high noncombustible matter content is likely to be realized with fuel containing 35 wt. % or higher noncombustible matter, and even more likely with fuel containing 40 wt. % or higher noncombustible matter.
  • The present invention can be practiced in the following manner to modify a burner so that particulate solid carbonaceous fuel can be combusted in the burner even though the specific energy content of the fuel (e.g. BTU per pound of fuel) is so low that combustion of the fuel in the burner with air as the only source of oxygen for combustion cannot be maintained in a stable flame at the burner.
  • The minimum specific energy content of the fuel is determined at which combustion of the fuel can be maintained in a stable flame at the burner, with air as the only source of oxygen for combustion.
  • Lance 31 or equivalent conduit is placed through burner 22 as shown in FIG. 3, with its outlet end positioned at the opening of the burner at its other end connected (through conventional valves and controls enabling control of the flow rate and enabling one to turn the flow on and off) to a source of oxidant containing more than 21 vol. % oxygen, conveniently at least 30 vol. % oxygen, and preferably at least 90 vol. % oxygen.
  • Then, a fuel-air stream is fed through the burner wherein the specific energy content of the fuel is lower than that minimum established as described above, combustion air is fed through the burner (for instance, through passage or passages 23 of the burner in FIG. 3), and oxidant containing more than 21 vol. % oxygen, conveniently at least 30 vol. % oxygen, and preferably at least 90 vol. % oxygen, is fed through lance 31. If combustion at the burner has already been established, the oxidant emerging at outlet 33 is fed into the base 35 of the flame at the burner. If combustion at the burner has not already been established, the mixture of the fuel-air stream, the combustion air stream, and the oxidant is ignited, and the oxidant emerging at outlet 33 is fed into the base 35 of the flame at the burner.
  • The mass flow rate at which oxygen is fed into the base of the flame is adjusted to determine a value at which stable combustion of the fuel is maintained in a flame at the burner. Then, the flow rate of oxygen is held at that level, or increased to ensure stable combustion even in the event of fluctuations of the specific energy content of the fuel. Typically, the amount of oxygen that is present in the oxidant emerging from outlet 33 into the base 35 of the flame is 1% to 25% of the total stoichiometric amount required to completely combust the combustible portion of the fuel fed. If desired, the oxygen content of the oxidant can be adjusted to accommodate the needs of the situation; as the specific energy content of the fuel decreases, increasing the oxygen content of the oxidant will generally be needed to maintain stable combustion of the fuel.
  • The minimum specific energy content below which the present invention becomes applicable varies from one unit to another but can readily be determined experimentally for any given unit. In general, combustion of fuels having specific energy content above about 10,000 BTU/pound is less likely to need the assistance provided by the present invention, whereas the ability of the present invention to achieve combustion of fuel having low specific energy content is likely to be realized with fuel having a specific energy content of 8,000 BTU/pound or lower, as determined from a dried fuel sample, and even more likely with fuel having a specific energy content of 6,000 BTU/pound or lower as determined from a dried fuel sample.

Claims (26)

1. A method of modifying operation of a burner, comprising
(A) providing a burner through which a stream of air mixed with particulate solid carbonaceous fuel, and one or more streams of air other than the air mixed with said fuel, can be fed and combusted in a stable flame at said burner, but wherein maintaining said stable flame at said burner when air provided in said streams is the only source of oxygen for said combustion requires that the fuel satisfy one or more conditions in that one or more of (1) the mass flow rate of the fuel through said burner, (2) the fuel-to-air ratio of the stream of air mixed with fuel that is fed through the burner, (3) the content of combustible matter in the fuel, and (4) the specific energy value of the fuel, must be at least sufficient for said stable flame to be maintained at said burner,
(B) inserting through said burner a lance the outlet end of which is positioned to eject gas into the base of a flame at said burner,
(C) feeding through said burner a stream of air mixed with particulate solid fuel which does not satisfy at least one of said conditions and therefore cannot be combusted in a stable flame at said burner in air as the only source of oxygen for combustion, and feeding through said burner said one or more streams of air other than the air mixed with said fuel,
(D) feeding gaseous oxidant comprising more than 21 vol. % oxygen through the outlet end of said lance, and
(E) combusting said fuel and air fed in step (C) with said oxidant fed in step (D) in a stable flame at said burner, wherein said oxidant is fed into the base of said flame at a mass flow rate that maintains said stable flame.
2. A method according to claim 1 wherein the gaseous oxidant fed in step (D) comprises at least 90 vol. % oxygen.
3. A method according to claim 1 wherein the mass flow rate of the fuel fed through said burner in step (C) is not sufficient for said fuel to be combusted in a stable flame at said burner in air as the only source of oxygen for said combustion of said fuel.
4. A method according to claim 3 wherein the gaseous oxidant fed in step (D) comprises at least 90 vol. % oxygen.
5. A method according to claim 1 where the air-to-fuel mass ratio of the stream of air mixed with fuel that is fed through said burner is too high for said fuel to be combusted in a stable flame at said burner in air as the only source of oxygen for said combustion of said fuel.
6. A method according to claim 5 wherein the gaseous oxidant fed in step (D) comprises at least 90 vol. % oxygen.
7. A method according to claim 1 wherein the specific energy value of the fuel fed in step (C) is not sufficient for said fuel to be combusted in a stable flame at said burner in air as the only source of oxygen for said combustion of said fuel.
8. A method according to claim 7 wherein the gaseous oxidant fed in step (D) comprises at least 90 vol. % oxygen.
9. A method of modifying operation of a burner, comprising
(A) providing a burner through which a stream of air mixed with particulate solid carbonaceous fuel, and one or more streams of air other than the air mixed with said fuel, can be fed and combusted in a stable flame at said burner,
(B) determining the minimum mass flow rate of particulate solid carbonaceous fuel through said burner below which combustion of said fuel with air as the only source of oxygen for said combustion cannot be maintained in a stable flame at said burner,
(C) inserting through said burner a lance the outlet end of which is positioned to eject gas into the base of a flame at said burner and the inlet end of which is connected to a source of gaseous oxidant comprising more than 21 vol. % oxygen,
(D) feeding through said burner a stream of air mixed with said particulate solid fuel at a mass flow rate of said fuel below said minimum, and feeding through said burner said one or more streams of air other than the air mixed with said fuel,
(E) feeding gaseous oxidant comprising more than 21 vol. % oxygen through the outlet end of said lance, and
(F) combusting said fuel and air fed in step (D) with said oxidant fed in step (E) in a stable flame at said burner, wherein said oxidant is fed into the base of said flame at a mass flow rate that maintains said stable flame.
10. A method according to claim 9 wherein the gaseous oxidant fed in step (D) comprises at least 90 vol. % oxygen.
11. A method of modifying operation of a burner, comprising
(A) providing a burner through which a stream of air mixed with particulate solid carbonaceous fuel, and one or more streams of air other than the air mixed with said fuel, can be fed and combusted in a stable flame at said burner,
(B) determining the maximum air-to-fuel mass ratio of the stream of air mixed with fuel that is fed through said burner above which combustion of said fuel with air as the only source of oxygen for said combustion cannot be maintained in a stable flame at said burner,
(C) inserting through said burner a lance the outlet end of which is positioned to eject gas into the base of a flame at said burner and the inlet end of which is connected to a source of gaseous oxidant comprising more than 21 vol. % oxygen,
(D) feeding through said burner a stream of air mixed with said particulate solid fuel at an air-to-fuel ratio above said maximum, and feeding through said burner said one or more streams of air other than the air mixed with said fuel,
(E) feeding gaseous oxidant comprising more than 21 vol. % oxygen through the outlet end of said lance, and
(F) combusting said fuel and air fed in step (D) with said oxidant fed in step (E) in a stable flame at said burner, wherein said oxidant is fed into the base of said flame at a mass flow rate that maintains said stable flame.
12. A method according to claim 11 wherein the gaseous oxidant fed in step (D) comprises at least 90 vol. % oxygen.
13. A method of modifying operation of a burner, comprising
(A) providing a burner through which a stream of air mixed with particulate solid carbonaceous fuel, and one or more streams of air other than the air mixed with said fuel, can be fed and combusted in a stable flame at said burner,
(B) determining the maximum content of noncombustible matter of particulate solid carbonaceous fuel above which combustion of said fuel with air as the only source of oxygen for said combustion cannot be maintained in a stable flame at said burner,
(C) inserting through said burner a lance the outlet end of which is positioned to eject gas into the base of a flame at said burner and the inlet end of which is connected to a source of gaseous oxidant comprising more than 21 vol. % oxygen,
(D) feeding through said burner a stream of air mixed with said particulate solid fuel having a content of noncombustible matter above said maximum, and feeding through said burner said one or more streams of air other than the air mixed with said fuel,
(E) feeding gaseous oxidant comprising more than 21 vol. % oxygen through the outlet end of said lance, and
(F) combusting said fuel and air fed in step (D) with said oxidant fed in step (E) in a stable flame at said burner, wherein said oxidant is fed into the base of said flame at a mass flow rate that maintains said stable flame.
14. A method according to claim 13 wherein the gaseous oxidant fed in step (D) comprises at least 90 vol. % oxygen.
15. A method of modifying operation of a burner, comprising
(A) providing a burner through which a stream of air mixed with particulate solid carbonaceous fuel, and one or more streams of air other than the air mixed with said fuel, can be fed and combusted in a stable flame at said burner,
(B) determining the minimum specific energy content of particulate solid carbonaceous fuel below which combustion of said fuel with air as the only source of oxygen for said combustion cannot be maintained in a stable flame at said burner,
(C) inserting through said burner a lance the outlet end of which is positioned to eject gas into the base of a flame at said burner and the inlet end of which is connected to a source of gaseous oxidant comprising more than 21 vol. % oxygen,
(D) feeding through said burner a stream of air mixed with said particulate solid fuel having a specific energy content below said minimum, and feeding through said burner said one or more streams of air other than the air mixed with said fuel,
(E) feeding gaseous oxidant comprising more than 21 vol. % oxygen through the outlet end of said lance, and
(F) combusting said fuel and air fed in step (D) with said oxidant fed in step (E) in a stable flame at said burner, wherein said oxidant is fed into the base of said flame at a mass flow rate that maintains said stable flame.
16. A method according to claim 15 wherein the gaseous oxidant fed in step (D) comprises at least 90 vol. % oxygen.
17. A method of operating a burner, comprising
(A) providing a burner through which a stream of air mixed with particulate solid carbonaceous fuel, and one or more streams of air other than the air mixed with said fuel, can be fed and combusted in a stable flame at said burner, but wherein maintaining said stable flame at said burner when air provided in said streams is the only source of oxygen for said combustion requires that the fuel satisfy one or more conditions in that one or more of (1) the mass flow rate of the fuel through said burner, (2) the fuel-to-air ratio of the stream of air mixed with fuel that is fed through the burner, (3) the content of combustible matter in the fuel, and (4) the specific energy value of the fuel, must be at least sufficient for said stable flame to be maintained at said burner,
(B) feeding through said burner a stream of air mixed with particulate solid fuel which does not satisfy at least one of said conditions and therefore cannot be combusted in a stable flame at said burner in air as the only source of oxygen for combustion, and feeding through said burner said one or more streams of air other than the air mixed with said fuel, and
(C) combusting said fuel and air fed in step (B) in a stable flame at said burner while also feeding gaseous oxidant comprising more than 21 vol. % oxygen into the base of said flame at said burner, wherein said oxidant combusts with said fuel and air, wherein said oxidant is fed into the base of said flame at a mass flow rate that maintains said stable flame.
18. A method according to claim 17 wherein the gaseous oxidant fed in step (C) comprises at least 90 vol. % oxygen.
19. A method of operating a burner, comprising
(A) providing a burner through which a stream of air mixed with particulate solid carbonaceous fuel, and one or more streams of air other than the air mixed with said fuel, can be fed and combusted in a stable flame at said burner,
(B) feeding through said burner a stream of air mixed with said particulate solid fuel at a mass flow rate of said fuel below the minimum mass flow rate of particulate solid carbonaceous fuel through said burner below which combustion of said fuel with air as the only source of oxygen for said combustion cannot be maintained in a stable flame at said burner, and feeding through said burner said one or more streams of air other than the air mixed with said fuel,
(C) combusting said fuel and air fed in step (B) in a stable flame at said burner while feeding gaseous oxidant comprising more than 21 vol. % oxygen into the base of said flame at said burner, wherein said oxidant combusts with said fuel and air, wherein said oxidant is fed into the base of said flame at a mass flow rate that maintains said stable flame.
20. A method according to claim 19 wherein the gaseous oxidant fed in step (C) comprises at least 90 vol. % oxygen.
21. A method of operating a burner, comprising
(A) providing a burner through which a stream of air mixed with particulate solid carbonaceous fuel, and one or more streams of air other than the air mixed with said fuel, can be fed and combusted in a stable flame at said burner,
(B) feeding through said burner a stream of air mixed with said particulate solid fuel at an air-to-fuel ratio above the maximum air-to-fuel mass ratio of the stream of air mixed with fuel that is fed through said burner above which combustion of said fuel with air as the only source of oxygen for said combustion cannot be maintained in a stable flame at said burner, and feeding through said burner said one or more streams of air other than the air mixed with said fuel, and
(C) combusting said fuel and air fed in step (B) in a stable flame at said burner while feeding gaseous oxidant comprising more than 21 vol. % oxygen into the base of said flame at said burner, wherein said oxidant combusts with said fuel and air, wherein said oxidant is fed into the base of said flame at a mass flow rate that maintains said stable flame.
22. A method according to claim 21 wherein the gaseous oxidant fed in step (C) comprises at least 90 vol. % oxygen.
23. A method of operating a burner, comprising
(A) providing a burner through which a stream of air mixed with particulate solid carbonaceous fuel, and one or more streams of air other than the air mixed with said fuel, can be fed and combusted in a stable flame at said burner,
(B) feeding through said burner a stream of air mixed with said particulate solid fuel having a content of noncombustible matter above the maximum content of noncombustible matter of particulate solid carbonaceous fuel above which combustion of said fuel with air as the only source of oxygen for said combustion cannot be maintained in a stable flame at said burner, and feeding through said burner said one or more streams of air other than the air mixed with said fuel,
(C) combusting said fuel and air fed in step (B) in a stable flame at said burner while feeding gaseous oxidant comprising more than 21 vol. % oxygen into the base of said flame at said burner, wherein said oxidant combusts with said fuel and air, wherein said oxidant is fed into the base of said flame at a mass flow rate that maintains said stable flame.
24. A method according to claim 23 wherein the gaseous oxidant fed in step (C) comprises at least 90 vol. % oxygen.
25. A method of operating a burner, comprising
(A) providing a burner through which a stream of air mixed with particulate solid carbonaceous fuel, and one or more streams of air other than the air mixed with said fuel, can be fed and combusted in a stable flame at said burner,
(B) feeding through said burner a stream of air mixed with said particulate solid fuel having a specific energy content below the minimum specific energy content of particulate solid carbonaceous fuel below which combustion of said fuel with air as the only source of oxygen for said combustion cannot be maintained in a stable flame at said burner, and feeding through said burner said one or more streams of air other than the air mixed with said fuel,
(C) combusting said fuel and air fed in step (B) in a stable flame at said burner while feeding gaseous oxidant comprising more than 21 vol. % oxygen into the base of said flame at said burner, wherein said oxidant combusts with said fuel and air, wherein said oxidant is fed into the base of said flame at a mass flow rate that maintains said stable flame.
26. A method according to claim 25 wherein the gaseous oxidant fed in step (C) comprises at least 90 vol. % oxygen.
US11/475,026 2006-06-27 2006-06-27 Oxygen to expand burner combustion capability Abandoned US20070298357A1 (en)

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Application Number Priority Date Filing Date Title
US11/475,026 US20070298357A1 (en) 2006-06-27 2006-06-27 Oxygen to expand burner combustion capability
BRPI0712772A BRPI0712772B1 (en) 2006-06-27 2007-06-21 methods of modifying the operation of a burner, and of operating a burner
CA2654922A CA2654922C (en) 2006-06-27 2007-06-21 Oxygen to expand burner combustion capability
ES07796311.4T ES2587697T3 (en) 2006-06-27 2007-06-21 Oxygen to increase the combustion capacity of burners
CN200780024488XA CN101479532B (en) 2006-06-27 2007-06-21 Oxygen to expand burner combustion capability
PCT/US2007/014447 WO2008002447A2 (en) 2006-06-27 2007-06-21 Oxygen to expand burner combustion capability
MX2008015165A MX2008015165A (en) 2006-06-27 2007-06-21 Oxygen to expand burner combustion capability.
EP07796311.4A EP2038581B1 (en) 2006-06-27 2007-06-21 Oxygen to expand burner combustion capability
NO20090374A NO342259B1 (en) 2006-06-27 2009-01-26 Oxygen to expand burner combustion
US13/017,483 US8459986B2 (en) 2006-06-27 2011-01-31 Oxygen to expand burner combustion capability
US13/894,110 US9091440B2 (en) 2006-06-27 2013-05-14 Oxygen to expand burner combustion capability
US13/894,167 US9091441B2 (en) 2006-06-27 2013-05-14 Oxygen to expand burner combustion capability
US13/894,494 US9091442B2 (en) 2006-06-27 2013-05-15 Oxygen to expand burner combustion capability

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US11/475,026 US20070298357A1 (en) 2006-06-27 2006-06-27 Oxygen to expand burner combustion capability

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US13/017,483 Expired - Fee Related US8459986B2 (en) 2006-06-27 2011-01-31 Oxygen to expand burner combustion capability
US13/894,167 Expired - Fee Related US9091441B2 (en) 2006-06-27 2013-05-14 Oxygen to expand burner combustion capability
US13/894,110 Expired - Fee Related US9091440B2 (en) 2006-06-27 2013-05-14 Oxygen to expand burner combustion capability
US13/894,494 Expired - Fee Related US9091442B2 (en) 2006-06-27 2013-05-15 Oxygen to expand burner combustion capability

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US13/894,167 Expired - Fee Related US9091441B2 (en) 2006-06-27 2013-05-14 Oxygen to expand burner combustion capability
US13/894,110 Expired - Fee Related US9091440B2 (en) 2006-06-27 2013-05-14 Oxygen to expand burner combustion capability
US13/894,494 Expired - Fee Related US9091442B2 (en) 2006-06-27 2013-05-15 Oxygen to expand burner combustion capability

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US (5) US20070298357A1 (en)
EP (1) EP2038581B1 (en)
CN (1) CN101479532B (en)
BR (1) BRPI0712772B1 (en)
CA (1) CA2654922C (en)
ES (1) ES2587697T3 (en)
MX (1) MX2008015165A (en)
NO (1) NO342259B1 (en)
WO (1) WO2008002447A2 (en)

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US9518734B2 (en) 2013-01-28 2016-12-13 General Electric Technology Gmbh Fluid distribution and mixing grid for mixing gases
CN104807004B (en) * 2015-04-15 2017-04-05 华南理工大学 A kind of device of pulverized coal channel thickness coal dust segregated combustion

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US8459986B2 (en) 2013-06-11
US9091440B2 (en) 2015-07-28
US20110123938A1 (en) 2011-05-26
MX2008015165A (en) 2008-12-12
US9091441B2 (en) 2015-07-28
ES2587697T3 (en) 2016-10-26
CN101479532B (en) 2012-05-30
BRPI0712772A2 (en) 2012-09-25
WO2008002447A3 (en) 2008-03-20
BRPI0712772B1 (en) 2020-02-04
CA2654922A1 (en) 2008-01-03
US20130252182A1 (en) 2013-09-26
WO2008002447A2 (en) 2008-01-03
US9091442B2 (en) 2015-07-28
US20130244189A1 (en) 2013-09-19
EP2038581B1 (en) 2016-06-08
US20130244188A1 (en) 2013-09-19
EP2038581A2 (en) 2009-03-25
CN101479532A (en) 2009-07-08
CA2654922C (en) 2012-01-24
NO342259B1 (en) 2018-04-30
NO20090374L (en) 2009-01-26

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