CN100540118C

CN100540118C - The method that is used for furnace reduction and control sulfur trioxide

Info

Publication number: CN100540118C
Application number: CNB2005800113244A
Authority: CN
Inventors: 布赖恩·S·希金斯
Original assignee: Brian S Higgins
Current assignee: HUAXI ENERGY INDUSTRY GROUP Co Ltd
Priority date: 2004-02-14
Filing date: 2005-02-14
Publication date: 2009-09-16
Anticipated expiration: 2025-02-14
Also published as: CN100560187C; CN100540116C; CN1942706A; CN1942707A; CN1942233A

Abstract

A kind ofly in the sulfurous fuels combustion process, control SO ₃Method, described method step comprises: the described fuel of partial combustion is to produce reducing environment; Keep a sufficient period so that with SO described reducing environment ₃Be reduced to SO ₂To obtain the SO of an expectation level ₃And the residue of the described fuel that in oxidation environment, burns; Reduce SO in the flue gas thus ₃Level of conversion.

Description

The method that is used for furnace reduction and control sulfur trioxide

Technical field

The present invention relates to a kind of method that is used to reduce from the byproduct emission of combustion reaction in general, and more specifically relates to sulfur trioxide (SO in a kind of reduction combustion furnace ₃) method.

Background technology

SO ₃ Reduce

People think that always the flue gas in power plant is a kind of source of atmospheric pollution for a long time.In the burning of fossil fuel, the oxidized formation of some naturally occurring element (for example) SO ₃, NOx, HCl, HF and like that.(the SO especially if these acid ₃) concentration surpassed some critical value then it may have problems.For example, work as SO ₃When concentration raise, the acid dew-point temperature of flue gas can raise.If the temperature of flue gas is lower than the acid dew-point temperature of flue gas, the then SO in the gas ₃Form H with condensing and reacting with water ₂SO ₄, cause stove internal corrosion problem.And, from the flue gas that burner hearth leaves can cool off rapidly and described gas in SO ₃And other sour condensing, (it is SO to form local acid rain ₃And other sour coagulation and landing thing) fall on every side on the ground, have subsequent corrosion.Too much SO ₃Can condense into droplet, and form visible plume when leaving burner hearth, this can cause aesthetic problem and local political issue.If have the NH of being similar in the described flue gas ₃Compound, then these compounds may with SO ₃React and form ammonium hydrogen sulfate (NH ₃HSO ₄), it subsequently can the contaminated air heater.

Therefore, there are following needs: reduce the flue gas acid dew point temperature so that acid dew-point temperature is lower than the flue-gas temperature in the coldest part of burner hearth (for example carrier pipe and chimney).Also there are another needs: reduce the acid content of flue gas so that minimize local acid rain and the other problem relevant with the peracidity flue gas.

SO ₃ Increase

The particulate matter that is loaded with in the flue gas can be removed by electrostatic precipitator, electrostatic precipitator can make described individual particle accept an electric charge and utilize this electric charge that they are attracted to collecting board subsequently and implement the cleaning.The efficient of these electrostatic precipitator depends on that described individual particle obtains the ability of electric charge, that is, and and the resistivity of described particle.Have been found that and have SO in the flue gas ₃Can effectively reduce the resistivity of described particle, it is charged that it is easier to electrostatic means.

In coal combustion, some naturally occurring sulphur is converted into SO ₃On the other hand, SO ₃The validity that reduces described particulate matter resistivity depends on SO ₃Concentration, wherein about 15 to 2,000 ten thousand umbers (ppm) can obtain optimum.Therefore, dust collector efficiency is regulated SO in the flue gas ₃The quantity sulfur content of institute's coal combustion (no matter how) is Zong so that SO ₃Concentration is in the influence of the ability in the optimum range.

SO ₃Also be in SCR (catalyst) device, to pass through SO ₂Oxidation produce, and surpass best 15 to 20ppm optium concentration through regular meeting.In SCR, be generally used for NOx is reduced to N ₂The catalyst admixture of (in the presence of ammonia) also can be with SO ₂Be oxidized to SO ₃The speed of this reaction has strong temperature dependency, and under higher temperature, can be with 1% SO ₂Change into SO ₃High sulfur-bearing U.S. coal any position in boiler all can produce from 2,000 to 3 the SO of 000ppm ₂, and therefore can produce 20 to 30ppm SO in the SCR outside ₃The SO that problem is, similar 50% (or 10 to 15ppm) comes out from described SCR ₃Can discharge chimney by cleaner.About 8 to 10ppm the time (depending on granule density), SO ₃Become a visible blue plume.

And, SO ₃Can also catalytic way in other boiler surfaces via interacting with element/chemicals (for example vanadium) and producing.

Therefore, because all SO that before SCR, form ₃Can be added into the SO of discharge ₃In, so reduce the SO that before SCR, forms ₃For reducing the SO that discharges ₃Be important and allow and use SCR to reduce the NOx of gas and can not produce excessive SO ₃

SO ₃ Control

If SO ₃Concentration is too low, and then deduster will be to be lower than best efficient work.On the other hand, if SO ₃Concentration is too high, and then flue gas can become peracidity, produces " blue smoke " and promotes to form acid rain.In addition, acidic flue gas can promote the corrosion to the transmission flue, and works as and NH ₃The type chemicals in conjunction with the time can block air heater.

And SCR common every year, only desire was used six months (in summer ozone control season), then had been left in the basket in winter.This situation in deduster, in pipeline, and can cause SO in exhaust chimney outside ₃The seasonal variations of concentration.

Therefore people expect whether dependence uses SCR to control SO in the flue gas ₃Concentration.SO near 40ppm ₃Concentration can cause the sour problem in serious disadvantageous part, though not necessarily adjusted, can cause the local political issue of facility.U.S.EPA points out that expectation is in the future to SO ₃Discharging manage.

Therefore, people expectation has and a kind ofly can regulate SO in the flue gas under the situation of using or do not use SCR ₃The SO of concentration ₃Flue gas system is with SO ₃Thereby concentration maintains optimum level reaches high ESP usefulness, and does not increase local SO ₃Discharging.

Classification

The burning classification is with two or the process of more a plurality of stage calcinating fuel (being coal).The rich fuel stage (or briefly, enrichment stage) is available air inadequate stage for the described fuel of completing combustion wherein.The poor fuel stage is one wherein to have for the described fuel of completing combustion fully or stage of excess air.Classification is used to pass through a) to reduce peak temperature (heating power type NOx) in the prior art and b) provides a reducing environment to come reducing NOx (NOx reduction).Macroscopical classification is that each section of burner hearth is divided into the enrichment stage with the poor stage and by using these for example after-flame wind technology such as (OFA) realizations.The microcosmic classification promptly produces and has the different functionalities feature the nearly micro of (for example reduction potential, temperature, and like that).For example, the microcosmic classification in the burner hearth can be in the phase I of described burner hearth by using low-NOx combustor and regulating the rotary blade setting value and air register is reached.The classification that increases can be increased in the time of staying in the reducing atmosphere and can strengthen the effect of described reducing atmosphere.

Prior art has adopted the microcosmic classification to reduce the discharging of NOx in the combustion furnace.Low-NOx combustor (LNB) is delivered in the burner hearth by a wind with high fuel content and mixes to come classification with the secondary wind facies that flows through one or more secondary air register.LNB mainly uses the microcosmic classification.Flow by a LNB is designed to make the volatile components of coal to mix with available near zone air with the stoichiometric proportion near (1.0).Near the clean burning in the central core of burner be generally enriched fuel and can not produce a large amount of hot NOx because temperature is very low.When increasing air was mixed in described central core lentamente, coal finally exhausted through furnace depth.Most of NOx of this region generating is NO from fuel-bound nitrogen and via intermediate HCN reaction.The speed that outside secondary wind is mixed in the core air-flow is set by the rotary blade in damper and rotary blade and the coal pipeline.Have a combustion product that enriches and the continuous mixing of secondary wind owing to spread all over the combustion zone, the LNB system reduces NOx by classification.Blending ratio increases between abundant core air-flow and the outside secondary general mood stream by reducing in classification.

Prior art has adopted macroscopical classification to reduce discharging in the combustion furnace.The macroscopic view classification is made up of the fuel and the air that highly mix in the low burner hearth, is mixed to one and is lower than one stoichiometric proportion for most of air-flow.Final still need excessive oxygen to guarantee that all fuel have burnt and reduce the danger of exploding.In the burner hearth of macroscopical classification, excess air is introduced the downstream of burner.The classification that increases is reached by the quality that increases the time of staying, temperature or reduce combustion product under the situation that lacks oxygen.

The NOx that prior art uses microcosmic classification (LNB) and macroscopical classification (OFA) dual mode to reduce in the combustion furnace discharges.Under microcosmic classification and both situations of macroscopical classification, use each above-mentioned combination and adjusted to reach the reduction of NOx emission.

Never teaching is crossed the SO that classification is used for the reduction of flue gas acidity, acid dew-point temperature control or burning gases in the prior art ₃Concentration control.

Summary of the invention

The present invention relates to a kind of being used for reduces SO in combustion system and method ₃Method.

The invention further relates to a kind of being used for controls SO in combustion system and method ₃Method.

The invention still further relates to a kind of use and in combustion system and method, reduce SO ₃The combustion furnace of method.

Therefore, the present invention's one target provides a kind of being used at combustion system and method utilization burning classification reduction SO ₃Method.

Another target of the present invention provides a kind of being used at combustion system and method utilization burning grading control SO ₃Method.

Another target of the present invention provides a kind of combustion furnace, and described combustion furnace can use can control SO ₃Method, and described method can adapt to the variation of the sulfur content of institute's combustion fuel.

Another target of the present invention provides a kind of SCR control NO that utilizes in the sulfurous fuels combustion process _xSO is controlled in discharging ₃Method, described method step comprises:

A) in the phase I the described fuel of partial combustion to produce reducing environment;

B) regulate the described reducing environment time period, so as before SCR with SO ₃Be reduced to SO ₂And reach the SO of expectation ₃Level;

C) in second stage, use oxidation environment combustion fuel residue and burning intermediate;

Control SO in the flue gas thus ₃Level.

A target more of the present invention provides a kind of use can control SO in the sulfurous fuels combustion process ₃The combustion furnace operated of method, described method step comprises:

A) the described fuel of partial combustion is to produce reducing environment;

B) regulate the described reducing environment time period, so that with SO ₃Be reduced to SO ₂And reach the SO of expectation ₃Level;

C) combustion fuel residue in oxidation environment;

Reduce SO in the flue gas thus ₃Level of conversion.

Another target of the present invention provides a kind ofly controls SO in the sulfurous fuels combustion process ₃The method of concentration, described method step comprises:

B) the described reducing environment time period is regulated, so that preferentially with SO ₃Be reduced to SO ₂And the SO of acquisition expectation ₃Level;

Control SO in the flue gas thus ₃Level.

Those skilled in the art are aspect hereinafter will understand that the present invention these and other after the description about preferred embodiment in conjunction with graphic reading in the industry.

The specific embodiment

In the explanation, identical conventional letter is all represented identical or corresponding part in some views hereinafter.Equally, in the explanation, should be appreciated that term " forward ", " backward ", " preceding ", " back ", " right side ", " left side ", " making progress ", " downwards " and like that hereinafter all for ease of describing used vocabulary and it should not being interpreted as restricted term.In the present invention, " reducible acid " refer to wherein and can reduce or eliminate acid acid by described acid being carried out electrochemical reduction.

The present invention relates to one uses the burning classification to reduce and control the method for acid dew-point temperature in stove.The invention further relates to one uses the burning classification at furnace reduction and control SO ₃Method.The classification that increases is advantageously used in reducing simultaneously acidity, reduces acid dew-point temperature and reduces SO in the flue gas ₃Level.

Reduce acidity, acid dew-point temperature and SO via the microcosmic classification ₃

With in rich " reduction " environment, NOx is reverted back N ₂Method similar, in reducing environment with SO ₃Revert back SO ₂For macroscopical classification, the burner hearth center below the OFA mouth is enriched with a large amount of fuel.The environment of this classification can be adjusted into even still less mix to produce the classification of reproducibility microcosmic in the phase I at described burner hearth.Thereby rotary blade speed setting value that can be by reducing wind and coal stream or reduce secondary wind rotary blade and air register in addition or otherwise and set value to reduce to mix and produce the reproducibility microcosmic stage; Can be in addition or otherwise change wind and coal stream and secondary be distinguished and admirable between relative muzzle velocity.

During the fuel-bound combustion of sulfur, though most of fuel-bound sulphur forms SO ₂, but have some directly to form SO ₃SO ₂Can form more SO via following oxidation reaction ₃

SO ₂+O(+M)→SO ₃(+M)

Yet this trisome reaction speed is very slow.In oxidation environment, produce SO ₃Another source be by the reaction:

SO ₂+O ₂→SO ₃+O。

This reaction does not need three main bodys to collide simultaneously; Yet it is very responsive to temperature, need high temperature, and it is easy to take place back reaction:

SO ₃+O→SO ₂+O ₂。

In reducing environment, owing to lack O and O ₂Material, above-mentioned three kinds of reactions are neither to be taken place with any remarkable quantity.In reducing environment, SO ₃To SO ₂Directly transform by following general " reduction " reaction and take place:

SO ₃+R→SO ₂+RO，

Wherein R is any reduction group class.In fossil-fuel-fired, main group is the H group.

SO ₃+H→SO ₂+OH

In reducing environment, many groups and molecule can be functional; For example H, OH, C, CO, CH, CH ₂C ₂H, CH ₃, C _nH _m, N, NHi, and many other groups and molecule.

When the reduction group of valid density (" R "), above-mentioned SO ₃Reduction reaction speed is exceedingly fast.In stage, sufficient concentration mainly appears in the reducing environment at first (rich fuel) of described burner hearth.

In a rich fuel staging reducing environment, (for example OH, O, O because the oxidisability combustible substance ₂, HO ₂, H ₂O ₂, and other this type of material) concentration reduce greatly, so the oxidation chemistry process stops.In this environment, for all can utilize oxygen species, each material was that very tool is emulative.With the molecule that relatively exists than small concentration with oxygen atom by the aerobic material consumption that exists with high concentration; For example, the oxygen among the NO is by such as C, CO, H, and other material consumption of CH.Molecule with a plurality of oxygen atoms is especially dangerous; That is SO, ₃To change into SO rapidly via any group around almost (the most remarkable be H atom) removal oxygen ₂

Therefore, in a reducing environment, when keeping described reducing environment, SO ₃Reduction reaction is very fast and in fact irreversible.

Astoundingly and importantly, for the inventive method and system, the SO of net effect in the phase I, during burning, forming ₃Be reduced to SO rapidly ₂, and by being oxidized to SO ₂And can not regenerate SO ₃, because in burner hearth, do not have the sufficient time of staying in the stage under the sufficiently high temperature at poor fuel afterwards.Therefore, the present invention can utilize reaction rate difference to reduce easily and keep SO in the flue gas ₃Level.

The reduction potential that the classification that increases can be increased in the time of staying in the reducing atmosphere or increase described atmosphere is to reduce SO ₃Concentration also reduces dew-point temperature thus.Therefore, for promoting SO ₃Reduction, can increase the time of staying maybe can increase reduction potential in the flue gas.

For increasing the time of staying, can utilize several different methods:

1) can prolong distance between between the stage;

2) can increase mixing for macroscopical hierarchical application;

3) can reduce mixing for the microcosmic hierarchical application;

4) can reduce mass flow (deep layer classification);

5) can increase volume utilization (for example vortex) between the stage;

6) can increase pressure;

7) can increase density.

For increasing the reduction potential in the flue gas, can utilize several different methods:

1) can increase temperature;

2) can reduce stoichiometric proportion (that is the ratio of air and fuel);

3) can increase local burnup's stream (for fixing air stream);

4) can reduce local air stream (for fixing fuel stream).

Mixing in the stage also can influence reduction process.One has complete mix stages the best of stoichiometric proportion mixture, and this is because these reaction conditions can reach maximum temperature, still keeps described reducing environment simultaneously; That is, minimize such as oxide groups such as O groups.But, be unpractical owing to mix fully, therefore, in fact use one less than 1 stoichiometric proportion, it can make the appearance that has greater than the position of 1 stoichiometric proportion minimize.Yet, when mixing minimizing, need the longer time of staying and/or higher temperature reach total acidity, acid dew-point temperature and/or SO ₃The similar attenuating of concentration.Yet the temperature of burning gases depends on the level of mixing on a certain degree, reduces its reduction if mix.Therefore, if the mixing of a given degree needs a temperature that raises, then must be by the alternate manner temperature that raises, for example air is carried out preheating, changes the heat transfer characteristic, and like that of burner hearth.Perhaps or in addition, can introduce (for example OFA sprays) and increase the time of staying in the described reducing environment by postponing poor stage air.

Note SO ₃By in a catalyst to SO ₂A catalyst carries out oxidation and forms, because can make SO ₂By following reaction oxidation:

SO ₂+1/2O ₂→SO ₃

Only depend on SO owing to described through catalytic reaction ₂And O ₂Concentration, SO in the catalyst ₃Generation be not subjected to SO in the gas ₃The restriction of concentration.Therefore, the whole SO that reduce by the present invention ₃Can reduce outlet SO independently ₃And be not subjected to SO in the catalyst ₃The influence of generation and can not influence SO in the catalyst ₃Generation.

Therefore, the invention provides just like following method: control also reduces flue gas acidity, flue gas SO especially ₃Concentration influences the efficient of electrostatic precipitator to help (1), reaches more preferably, and (2) reduce SO in the flue gas ₃And the concentration of other reducible acid to be to reduce flue gas acidity and acid dew point, reduces thus that air heater stops up, air channel burn into and be disposed to SO in the environment ₃Emission (it may be the source of visible plume and local acid rain).

In a preferred embodiment of the present invention, adjust acidity and SO in the burner hearth ₃Macroscopical classification of level is reached by using OFA.In another preferred embodiment, regulate acidity and SO in the burner hearth ₃The microcosmic classification of level is reached by using low-NOx combustor.In another preferred embodiment, will be used to regulate acidity and SO in the burner hearth by being used in combination macroscopical classification and the microcosmic classification that OFA and low-NOx combustor reach ₃Level.Use the burner hearth of SCR for being in operation, preferable acidity is regulated to reduce total flue gas acidity.For the burner hearth that does not use SCR or use bypass SCR, preferable to SO ₃Regulate so that to the SO of ESP ₃Level increases or helps sinking.For current ESP, the SO in waste gas between about 10 to about 15ppm (by volume) ₃Level is suitable for best ESP efficient.

Dew-point temperature is to be used to estimate and/or to regulate the reducing environment variable with the acidity that obtains fully to lower and/or the SO of expectation ₃The suitable parameter of level.In order to reach the SO of an expectation ₃Level and work relative humidity can be measured dew point and corresponding adjusting reducing environment variable to reach the expectation dew point.Measure acidity and/or SO ₃Other method of level can be used for identical purpose and does not deviate from scope of the present invention.

In a preferred embodiment of the present invention, a power plant is controlled so that a microcosmic stage or a macroscopic view stage reducing environment along degree of depth classification to be provided in low burner hearth.OFA in higher burner hearth can provide essential oxygen to reach acceptable level with the after-flame of guaranteeing remaining uncombusted fuel, burning intermediate and/or CO.In addition, available SCR comes reducing NOx.Therefore, one embodiment of the invention comprises that one has the combustion furnace of OFA and low-NOx combustor, and it is applied to sulfurous fuels to reduce dew-point temperature and to lower SO ₃Concentration.In addition, can provide SCR to come reducing NOx.Described low-NOx combustor is preferably just like following grade: it can provide abundant mixing to reduce and SO so that sufficient acid dew-point temperature to be provided in the starting stage ₃Concentration lowers, and therefore, (if needs) allows use SCR.Therefore, one embodiment of the invention comprises that one has the combustion furnace of high-grade low-NOx combustor, and it is used to lower flue gas acidity, reduces acid dew-point temperature and lowers flue gas SO ₃The purpose of concentration.This embodiment can further comprise SCR.

Abundant reducing environment of the present invention be can less than about 2 seconds, better less than about 0.5 second in SO ₃Be reduced to SO ₂Reducing environment.In the present invention, this reducing environment can be in the phase I flue-gas temperature more than or equal to 900Kelvin (1160), better greater than about 1255K (1800) even goodly realize during greater than about 1650K (2500).One reducing environment for wherein reduce the concentration ratio of group and oxide group greater than concentration ratio about 1, more specifically H group and O group greater than about 1 environment.Better reducing environment for wherein reduce the concentration ratio of group and oxide group greater than concentration ratio about 10, more specifically H group and O group greater than about 10 environment.

Therefore, the combustion furnace of operation relates to following steps according to the present invention:

B) make described reducing environment keep a grace time section, so that with SO ₃Be reduced to SO ₂And reach the SO of expectation ₃Level;

Control SO in the flue gas thus ₃Level.

A kind of being used at reduction of sulfurous fuels combustion process or control SO ₃The inventive method, may further comprise the steps:

Reduce thus or the control flue gas in SO ₃Level.

These methods can comprise the step of microcosmic classification and/or macroscopical classification phase I fuel combustion and/or macroscopical classification.Described microcosmic classification can be by using low-NOx combustor to provide and described macroscopical classification can provide by using after-flame wind.Described fuel can be any fuel, especially carbon-containing fuel, for example coal.

Example

The result that following Examples set can use the inventive method to reach.In 3 different power plants, use the inventive method reduction SO ₃Emission.Experimental data shown in the table 1 and 2 is by using high speed after-flame wind and being measured by third company.

Table 1. hierarchy depth in 2 different power plant to SO ₃The influence of level.

*-98.5% sulphur is converted into SO in the hypothesis coal ₂And 1.5% sulphur is converted into SO in the coal ₃The basis on estimate to obtain.

For the situation of " shallow " classification, the after-flame air port is nearly closed, but still comprises cool stream (about 10% total air).For the situation of " medium " classification, total air stream of similar 20% is formed in the after-flame air port.For the situation of " deeply " classification, total air stream of similar 30% is formed in the after-flame air port.Three groups of equipment is all corner firing equipment and the OFA system is positioned at the burner region top just.

The influence (power plant 3, with table 1 different) of the classification of three kinds of levels of table 2. in a single power plant.

Therefore, described experimental data is showed use the inventive method adjusting SO ₃The ability of level.

After reading above-mentioned explanation, those in the industry those skilled in the art also can carry out some modification or improvement.For simple and clear and be easy to read, this paper has left out all modifications and improvement, but these contents all suitably are covered by in the aforesaid right claimed range.

Claims

1, a kind of SCR control NO that in the sulfurous fuels combustion process, utilizes _xSO is controlled in discharging ₃Method, described method step comprises:

Control SO in the flue gas thus ₃Level.

2, the method for claim 1, it further comprises the step of the described phase I fuel combustion of microcosmic classification.

3, method as claimed in claim 2, wherein said microcosmic classification provides by using low-NOx combustor.

4, the method for claim 1, it further comprises macroscopical classification step of described fuel combustion phase I.

5, method as claimed in claim 4, wherein said macroscopical classification provides by using after-flame wind.

6, the method for claim 1, it further comprises combining of microcosmic classification and macroscopical classification.

7, method as claimed in claim 6, wherein said microcosmic classification provides by low-NOx combustor and macroscopical classification provides by after-flame wind.

8, the method for claim 1, wherein said fuel are coal.

9, a kind of use can be controlled SO in the sulfurous fuels combustion process ₃The combustion furnace operated of method, described method step comprises:

A) the described fuel of partial combustion is to produce reducing environment;

C) combustion fuel residue in oxidation environment;

Reduce SO in the flue gas thus ₃Level of conversion.

10, combustion furnace as claimed in claim 9, wherein said method further comprises the step of the described phase I fuel combustion of microcosmic classification.

11, combustion furnace as claimed in claim 10, wherein said microcosmic classification provides by using low-NOx combustor.

12, combustion furnace as claimed in claim 9, wherein said method further comprise macroscopical classification step of described fuel combustion phase I.

13, combustion furnace as claimed in claim 12, wherein said macroscopical classification provides by using after-flame wind.

14, combustion furnace as claimed in claim 9, wherein said method further comprise combining of microcosmic classification and macroscopical classification.

15, combustion furnace as claimed in claim 14, wherein said microcosmic classification provides by low-NOx combustor and macroscopical classification provides by after-flame wind.

16, combustion furnace as claimed in claim 9, wherein said fuel are coal.

17, a kind ofly in the sulfurous fuels combustion process, control SO ₃The method of concentration, described method step comprises:

Control SO in the flue gas thus ₃Level.

18, method as claimed in claim 17, it further comprises the step of the described phase I fuel combustion of microcosmic classification.

19, method as claimed in claim 18, wherein said microcosmic classification provides by using low-NOx combustor.

20, method as claimed in claim 17, it further comprises macroscopical classification step of described fuel combustion phase I.

21, method as claimed in claim 20, wherein said macroscopical classification provides by using after-flame wind.

22, method as claimed in claim 17, it further comprises combining of microcosmic classification and macroscopical classification.

23, method as claimed in claim 22, wherein said microcosmic classification provides by low-NOx combustor and macroscopical classification provides by after-flame wind.

24, method as claimed in claim 17, wherein said fuel are coal.