CN103822225B - Integrated low nitrogen burning system and control method - Google Patents

Abstract

The present invention proposes a kind of integrated low nitrogen burning system, comprise controller module, secondary air flow sensor, fuel flow sensor and Secondary Air air damper controller; Described controller module is used for: from each work burner secondary air flow sensor reading signal and sue for peace; From each work, the fuel flow sensor of burner reads signal and sues for peace; The signal of single given fuel flow sensor and described fuel total flow are carried out division arithmetic; Described fuel flow rate ratio and secondary air flow summation are carried out multiplying; By described required secondary air flow Signal transmissions to the Secondary Air air damper controller of single given corresponding burner.The present invention effectively, in time can carry out fuel flow rate, air classification, again burning and bias combustion energy technology is organically combined, maintains idealized chemical equivalent, reach the optimization of burning, nitrogen discharged amount is down to minimum.

Description

Integrated low nitrogen burning system and control method

Technical field

The present invention relates to for solid-fuelled method for controlling combustion and combustion system.

Background technology

Solid fossil fuel such as coal is the important energy, and coal combustion is one of main source of world power for generating electricity.But, be also one of air-polluting main source by the pollutant of Discharged form Coal Combustion.Such as, the nitrogen oxide (NOx) of Discharged form Coal Combustion reaches more than 2,000 ten thousand tons every year, is important pollution sources.

The NOx produced in coal combustion process has two main sources: fuel NO_x and heating power NOx.Fuel NO_x is the NOx that the nitrogen (fuel bound nitrogen) existed in the mode of chemical bond in coal is formed through burning conversion.Fuel bound nitrogen (or coke-N) discharges in series of complex combustion process, and its primary initial product is HCN and/or NHi, and then initial the or intermediate product such as HCN is oxidized to NOx or is reduced to N2.If atmosphere residing for the initial product of nitrogen is oxidisability (lack of fuel), then NO _xthe primary product of fuel bound nitrogen will be become.If anoxic (fuel-rich material) atmosphere, then HCN and NHi at coking coal on the surface by becoming N2 with CO or C (charcoal) or other nitrogen containing component reaction conversions.

Heating power NOx refers to the NOx formed by the high-temperature oxydation of atmospheric nitrogen.The formation of heating power NOx is the exponential function of temperature and the square root function of oxygen concentration.NOx that is lower or the lower generation of oxygen concentration is fewer for ignition temperature.Therefore, the generation of hot NOx can be controlled by control reaction temperature or oxygen concentration.But lower ignition temperature or lower oxygen concentration make burning of coal speed slack-off, efficiency of combustion reduces.Burn rate can cause the imperfect combustion of coal and the prolonging combustion of coal slowly.

In the pulverized coal boiler of common power station, because ignition temperature is generally lower than 1550 DEG C, the NOx that heating power NOx accounts for total generation is less.Therefore, the formation that NOx generation in combustion mainly reduces fuel NO_x is reduced.Developed various combustion technology for this reason.The main points of these technology are mainly by controlling the combustion atmosphere in stove, and make when fuel bound nitrogen is separated out, atmosphere is reproducibility, and thus the intermediate product such as HCN and NHi is reduced into nitrogen, and does not generate NOx.In stove, low NOx combusting technology mainly comprises low-NOx combustor, Researched of Air Staging Combustion Burning Pulverized Coal, fuel and fires and flue gas recirculation etc. again.

Wherein single flow coal powder light-dark is separated the first-selected measure that low-NOx combustor is tangentially firing boiler control NOx.It takes particular organization Pulverized Coal Concentration to be separated, and forms the powered coal density deviation burning of local at the burning initial stage, is also the generation of the reducing atmosphere control NOx of local.Common once-through type shade burner mainly contains: the PM type pulverized coal concentrator of the horizontal bias inspissator utilizing horizontal elbow centrifugal force or forced steering mechanism, the WR type vertical strong/weak inspissator utilizing vertical elbow centrifugal force and dependence inertial separation.Denitration (or NOx) efficiency of these low-NOx combustors is about 20-40%.

Before coal dust after-flame, maintaining reducing atmosphere to a certain degree in the flame downstream of low-NOx combustor, is control the conventional measure that in stove, NOx generates further.The conventional means adopted be change traditional consentrated air supply mode and by partial oxidation agent (air) from main burner region disconnecting out, send in stove by the spout above burner, form air classification (OFA) burning in furnace height direction.Classification wind mainly contains compact, single-stage divergence type and multi-stage separation mixed type etc. three kinds, and mostly adopts multi-stage separation hybrid mode.Air classification matches with low-NOx combustor, can reduce NOx emission and be about 40-60%.

The distance in air classification degree and classification wind snout and main burner region, determines reducing atmosphere degree and the time of staying of coal dust under oxygen debt condition of burner region, thus determines the growing amount of NOx.But main burner region is in oxygen debt condition: the burning that can postpone coal dust on the one hand, reduce the after-flame degree of coal dust; Water-cooling wall surface can be caused to be in reducing atmosphere on the other hand, cause water-cooling wall coking and/or high-temperature flue gas corrosion.For improving the after-flame degree of coal dust, can only the mixability of flue gas of initiation combustion near intensified burner spout and the classification wind in later stage.Under burner region entirety is in reducing atmosphere condition, for controlling the oxygen amount of water-cooling wall near surface more than 2.0%, reduce slagging scorification and cigarette corroded, incident angle in stove of the First air of tangentially firing boiler, Secondary Air and allocation of the amount of air most important.

In addition, when secondary wind pressure deficiency, also can utilize booster fan extracting high-temperature Secondary Air, the position higher at distance top layer burner sprays into burner hearth as high speed burnout degree.Supercharged, secondary wind can play the effect of classifired combustion on the one hand, extends the time of staying of pulverized coal particle in oxygen debt environment, improves NOx control ability; Fully mixing of burnout degree and upstream flue gas can be strengthened on the other hand, the after-flame of raising coal dust and CO.

Researched of Air Staging Combustion Burning Pulverized Coal makes the coal dust firing initial stage be in oxygen debt environment, and meeting delayed combustion, reduces efficiency of combustion.For while control NOx emission, the after-flame of coal dust can not also be reduced, developed another kind of low-NO_x combustion technology---reburning technology.High efficency low NOx burner and fuel fire into combine with technique such as Researched of Air Staging Combustion Burning Pulverized Coals together by again, become three regions: primary zone, reburning zone and burning-out zone at freeze profile.Here, the primary fuel of about 80-85% sprays into primary zone, vigorous combustion under oxidizing atmosphere (α=~ 1.1); The secondary fuel (microfine coal of natural gas, oil or high volatile) of about 15-20% sprays into burner hearth above primary zone, under strongly reducing atmosphere (α=0.7-0.9) condition, secondary fuel burning produces a large amount of hydrocarbon radical (HCN), with the NOx coming primary burner region, reduction reaction occurs and generates N2; Remaining Secondary Air sends into burning-out zone by OFA spout, oxygen enrichment (α=~ 1.15) burning uncompleted burned carbon and CO.

Reburning technology, while control NOx emission, takes into account the boiler performances such as after-flame, slagging scorification and corrosion, and be low NOx combusting technology more advanced at present, NOx reduced rate is about 50-70%.The NOx control ability of reburning technology and burner hearth closely related along the oxygen content control on elevation, this requires higher to the operation mode of boiler and control accuracy.But, up to now also not for the control method of reburning technology.In addition, the fuel that general reburning technology uses is mostly gaseous fuel, costly.Other method adopts microfine coal, because the granularity of required coal dust is comparatively thin, also constrains the extensive effectively application at engineering field.

Summary of the invention

Not enough for above-mentioned prior art, the technical problem to be solved in the present invention is to provide a kind of enable NOx that must discharge and drops to minimum, has again method for controlling combustion and the system of economy and security concurrently simultaneously.

For solving the problems of the technologies described above, the technical solution used in the present invention is, integrated low nitrogen burning control method, comprises Secondary Air and distributes rate-determining steps, and described Secondary Air distributes rate-determining steps and comprises the steps:

(11) from each work burner secondary air flow sensor reading signal and sue for peace, draw secondary air flow summation;

(12) from each work, the fuel flow sensor of burner reads signal and sues for peace, and draws fuel total flow;

(13) signal of single given fuel flow sensor and described fuel total flow are carried out division arithmetic, draw the fuel flow rate ratio of this single given corresponding burner;

(14) described fuel flow rate ratio and secondary air flow summation are carried out multiplying, draw secondary air flow signal needed for single given corresponding burner;

(15) by described required secondary air flow Signal transmissions to the Secondary Air air damper controller of single given corresponding burner.

Further technical scheme is, also comprises fiery windward rate-determining steps, and described fiery windward rate-determining steps comprises the steps:

(21) read signal from oxygen level sensor and be converted to the total chemical equivalent signal of unit;

(22) read signal from unit load cell and be converted into combustion zone chemical equivalent signal;

(23) combustion zone chemical equivalent signal and the total chemical equivalent signal of unit are carried out division arithmetic, draw combustion zone chemical equivalent ratio signal;

(24) generating reference signal, and sue for peace with described combustion zone chemical equivalent ratio signal, the windward that must fire regional chemistry equivalents ratio signal;

(25) read signal from bellows flow sensor and First air flow sensor and sue for peace respectively, drawing air total flow signal;

(26) described fiery windward regional chemistry equivalents ratio signal and air total flow signal are carried out multiplying, must fire flow signal needed for windward;

(27) flow signal needed for described fiery windward is sent to fiery windward air damper controller.

Further technical scheme is, in described fiery windward rate-determining steps, also comprises the steps:

(28) read signal from air flow sensor secondary air flow sensor, reburning fuel auxiliary air flow sensor and fire respectively, and summation show not containing the air total flow signal of First air;

(29) signal read from air flow sensor on fire and the described air total flow signal not containing First air are carried out division arithmetic, the windward that must fire flow proportional signal;

Described step (24) is specially, generating reference signal, and sues for peace with described combustion zone chemical equivalent ratio signal, the windward that must fire regional chemistry equivalents ratio signal; Described fiery windward regional chemistry equivalents ratio signal and fiery windward flow proportional signal carry out calculus of differences, and difference result and fiery windward regional chemistry equivalents ratio signal are sued for peace;

Described step (26) is specially, and carry out multiplying with air total flow signal after described fiery windward regional chemistry equivalents ratio signal is added difference result, must fire flow signal needed for windward.

Further technical scheme can also be, also comprise reburning fuel rate-determining steps, and described reburning fuel rate-determining steps comprises the steps:

(31) default reburning fuel scaling signal is generated;

(32) from reburning fuel flow sensor and each work, the fuel flow sensor of burner reads signal and sues for peace respectively, draws actual consumption fuel total flow signal;

(33) signal read from reburning fuel flow sensor and described actual consumption fuel total flow signal are carried out division arithmetic, draw actual reburning fuel scaling signal;

(34) described default reburning fuel scaling signal and described actual reburning fuel scaling signal are carried out calculus of differences, and difference result and described default reburning fuel scaling signal are sued for peace, draw reburning fuel setting scaling signal after compensating;

(35) from fuel total flow sensor reading signal, and reburning fuel after this signal and described compensation is set scaling signal carry out multiplying, draw required reburning fuel flow signal;

(36) described required reburning fuel flow signal is sent to reburning fuel flow controller.

The invention allows for a kind of corresponding control system, comprising controller module, some for being arranged on secondary air flow sensor in different burner, some for being arranged on fuel flow sensor in different burner tubes respectively and for adjusting the Secondary Air air damper controller controlling Secondary Air damper positions respectively;

Described controller module is used for: from each work burner secondary air flow sensor reading signal and sue for peace, draw secondary air flow summation; From each work, the fuel flow sensor of burner reads signal and sues for peace, and draws fuel total flow; The signal of single given fuel flow sensor and described fuel total flow are carried out division arithmetic, draws the fuel flow rate ratio of this single given corresponding burner; Described fuel flow rate ratio and secondary air flow summation are carried out multiplying, draws secondary air flow signal needed for single given corresponding burner; By described required secondary air flow Signal transmissions to the Secondary Air air damper controller of single given corresponding burner.

Further technical scheme is, also comprises oxygen level sensor, unit load cell, bellows flow sensor, First air flow sensor and the fiery windward air damper controller for regulable control fire windward damper positions;

Described controller module also for: read signal be converted to the total chemical equivalent signal of unit from oxygen level sensor; Read signal from unit load cell and be converted into combustion zone chemical equivalent signal; Combustion zone chemical equivalent signal and the total chemical equivalent signal of unit are carried out division arithmetic, draws combustion zone chemical equivalent ratio signal; Generating reference signal, and sue for peace with described combustion zone chemical equivalent ratio signal, the windward that must fire regional chemistry equivalents ratio signal; Read signal from bellows flow sensor and First air flow sensor and sue for peace respectively, drawing air total flow signal; Described fiery windward regional chemistry equivalents ratio signal and air total flow signal are carried out multiplying, and must fire flow signal needed for windward; Flow signal needed for described fiery windward is sent to fiery windward air damper controller.

Further technical scheme is, also comprises air flow sensor on reburning fuel auxiliary air flow sensor and fire;

Described controller module also for: read signal from air flow sensor secondary air flow sensor, reburning fuel auxiliary air flow sensor and fire respectively, and summation show not containing the air total flow signal of First air; The signal read from air flow sensor on fire and the described air total flow signal not containing First air are carried out division arithmetic, the windward that must fire flow proportional signal; Described fiery windward regional chemistry equivalents ratio signal and fiery windward flow proportional signal carry out calculus of differences, and difference result and fiery windward regional chemistry equivalents ratio signal are sued for peace; Carry out multiplying with air total flow signal after described fiery windward regional chemistry equivalents ratio signal is added difference result, must fire flow signal needed for windward.

Further technical scheme can also be, also comprise the reburning fuel flow sensor for being arranged on territory, reburning zone pipeline, for be arranged on main pipeline fuel total flow sensor and for regulating the reburning fuel flow controller of reburning fuel flow;

Described controller module also for: generate preset reburning fuel scaling signal; From reburning fuel flow sensor and each work, the fuel flow sensor of burner reads signal and sues for peace respectively, draws actual consumption fuel total flow signal; The signal read from reburning fuel flow sensor and described actual consumption fuel total flow signal are carried out division arithmetic, draws actual reburning fuel scaling signal; Described default reburning fuel scaling signal and described actual reburning fuel scaling signal are carried out calculus of differences, and difference result and described default reburning fuel scaling signal are sued for peace, draw reburning fuel setting scaling signal after compensating; From fuel total flow sensor reading signal, and reburning fuel after this signal and described compensation is set scaling signal carry out multiplying, draw required reburning fuel flow signal; Described required reburning fuel flow signal is sent to reburning fuel flow controller.

Preferably, described reburning fuel flow controller is the baffle plate for being arranged on air-coal separating elbow, and needed for this baffle plate can send according to controller module, reburning fuel flow signal rotates.

Preferably, also comprise a kind of fine grained fuel and obtain mechanism, described fine grained fuel obtains mechanism and comprises separation bend pipe, segmentation separator and mill; One end of described separation bend pipe is entrance, and the other end is provided with coarse granule fuel outlet and fine grained fuel outlet; The fine grained fuel outlet being separated bend pipe is communicated with the entrance of segmentation separator; The segmentation outlet of separator is communicated with the entrance of mill, and the outlet of mill is communicated with the entrance of segmentation separator.

The present invention is based on the understanding of inventor to prior art.One of problem is: although the prior art (mainly referring to grading combustion technology) of minimizing NOx is based on certified knowwhy, and the process approach of the required or use of these technology and equipment do not reach optimal N Ox usually to be reduced.In the Typical Disposition of combustion system applying reburning fuel and fiery windward, oxidant (combustion air) is first injected in a vertical collection chamber (bellows) by air-introduced machine; Be assigned in burner hearth by series of parallel air channel afterwards.The air door of independent distribution can adjust the flow velocity of combustion air.According to the difference controlling object, air door can be divided into four kinds: fuel/air mixture air door, is positioned near fuel nozzle ports height; Auxiliary air air door, between fuel nozzle ports; Fire windward air door, is arranged on fuel nozzle ports; Reburning fuel air door.Secondary Air (the air stream beyond the removing flow in fuel) total amount injecting burner hearth is controlled by air-introduced machine.Auxiliary air air door is then used for controlling the pressure reduction between bellows and burner hearth, and this pressure reduction is the function of the total air mass flow of unit.The position of fuel/air mixture air door is the function of feeder rotating speed, and the position of fiery windward air door is then the function of unit load or unit air mass flow.

Existing control fire windward and the control system of Secondary Air are made up of the assay method of air total amount and the method for default program control fiery windward flowing into burner hearth.The fire throttle opening random groups unit load of windward and air mass flow and change.Existing combustion control technology is not monitored or is controlled the chemical equivalent in main burner region.Therefore, the chemical equivalent in main burner region and the total chemical equivalent of unit do not have to be individually adjusted.The chemical equivalent of fuel region controls the chemical equivalent then depending on main burner region again.The interdependence of these four kinds of air doors makes between the discharge of NOx (reduction) and efficiency of combustion conflicting, i.e. NO _xthe reduction of discharge capacity, in CO and flying dust, the content of carbon can increase, because the two variation tendency is identical.

Two of problem be existing reburning fuel method not only (gaseous fuel and microfine coal) expensive but also do not have or can not change with the change of main fuel: reburning fuel, once setting (kind, flow, flow velocity), is just difficult to regulate again.But the change of main fuel and the change of air quantity all set (better) working value by making the amount of reburning fuel and chemical equivalent value district depart from.

Reasonable solution first problem, need obtain space and in the time two required for (desirable is possible) combustion chemistry equivalent, the each combustion zone of accurate control (that is: main combustion zone, reburning fuel district, fiery windward district), preferably controls each burner (air/fuel ratio).Thermal power plant's operation of passing through is a coal pulverizer by the coal supply of multiple supply pipe coal chute to multiple burner, is thus difficult to the accurate mass flow of the reality obtaining the coal being transported to a given burner, also just cannot learns accurate air/fuel ratio.The method of mass flow being always used for measuring coal measures the coal supply amount entering single coal pulverizer, then divided by connecting the number of coal chute of coal pulverizer.Or measure the mass flow of the coal flowing out coal pulverizer with sensor, by the number of measurement result except coal chute, thus learn the Theoretical Mass flow flowing through each pipeline.But, because the difference of size between pipe and pipe, and obstruction in some pipeline and accumulation, with the factor that other cause the flow of the coal flowing through certain pipeline different, the supposition flowing through the coal amount of each burner identical is incorrect, causes the amount to given burner off-target air/fuel ratio greatly.

The invention provides method---the discrete control system that one accurately can control each combustion zone (that is: main combustion zone, reburning fuel district, fiery windward district).Whole control system comprises fire upper wind system, secondary air system and reburning fuel combustion system.These three systems are separate, can individually control.The fiery windward that fiery windward subsystem is used for controlling to be conveyed into burner hearth accounts for the ratio of required total air.Secondary Air subsystem is used for controlling the distribution of Secondary Air between different burner, i.e. the stoichiometric ratio of main combustion zone.Reburning fuel subsystem is used for the reburning fuel of control inputs burner hearth and accounts for the ratio of required total amount of fuel.The advantage of discrete control system can regulate separately and optimize each combustion zone, simplifies the operation of boiler operator, thus realize optimization (NOx reduces and high efficiency of combustion) in practice.

Secondary Air subsystem is used to calculate the mass velocity maintained required for the desirable chemical equivalent proportion of main burner region.The input signal of Secondary Air subsystem is the sensor of the total air mass flow of boiler controller system, and single burner air flow sensor.Distribution in Secondary Air subsystem of the present invention between different burner mainly considers that fuel (herein for the coal dust) amount of each burner actual consumption distributes Secondary Air, and this is that flow by directly measuring the coal dust be transported in this burner through this coal chute obtains.Now existing can certain material of Accurate Measurement, be such as the sensor of the mass flow of pulverized coal flow piping.Such as some sensors are the amount of charge measuring the coal dust flowing through coal chute with electrode, also have some to be detect microwave absorption, directly can measure the flow of the air carrying coal dust or do not carry coal dust.The sensor of another kind of type is in feed pipe, arrange an alternating electric field, measures the mass flow of coal dust by measuring electric field.Verified, these sensors be applicable to of the present invention, such as, in U.S. Patent No. 6,109, in 097 announce a typical equipment.This sensor is arranged in each coal chute, measures pulverized coal mass flow.The mass flow flowing through the coal dust of each burner coal chute can be determined and gather, then the total mass flow rate being transported to the coal dust in burner hearth just can be determined.The ratio flowing through the average discharge of the coal chute of the burner in the flow of the coal of a specific burner coal chute and all working also can be determined.The steam flow that boiler produces also can be determined, and with the total theoretical combustion air deciding each burner needs, can comprise First air, Secondary Air and marginal wind.Based on the coal dust actual flow flowing through each burner, combustion air demand just can be corrected, and therefore just better can maintain the stoichiometric ratio of combustion air and fuel.

Fire windward subsystem is according to boiler plant running status, coal, and the optimum value of fuel combustion state and NOx emission setting is run.On fire wind system using two class signals as input signal, the first from the signal of Secondary Air and reburning subsystem, the fiery windward mass velocity required for expression; It two is some sensors from boiler plant, wind flow on these sensors main acoustic wind case to burner hearth pressure reduction, the pressure of bellows, box temperature and fire.Fire windward subsystem processes these signals in conjunction with airdoor control subsystem, and the fiery windward damper positions required for exporting, and makes under this position, air can in fiery windward reasonable distribution, and the stoichiometric ratio in main burner region can be maintained.

Reburning fuel subsystem is used for the reburning fuel of control inputs burner hearth and accounts for the ratio of required total amount of fuel.The input signal of this subsystem is fuel total flow signal, pulverized coal flow signal and burning coal powder flow signal again in single burner.The coal of these signals and boiler plant running status, unit, fuel combustion state and NOx emission etc. combine and can be used for regulating the flow of reburning fuel and the air quantity of reburning fuel.

The design of reburning fuel subsystem can with solving Second Problem (that is: high cost and the rigidity of existing reburning fuel combustion method are run), and its realization then must in conjunction with concrete device and equipment.In a preferred embodiment of the present invention, combustion system can comprise separator, and it is designed to the air/fuel stream from pulverized coal preparation system to be divided into dense air/fuel stream and diluted air/fuel stream.Described separator connects burner, for burner provides dense air/fuel stream.Described diluted air/fuel stream then comprises thinner coal dust directly as reburning fuel.Our experiment experience shows, the average diameter of this strand of diluted air/fuel stream pulverized coal particle is 1/4 to 1/2 of the average diameter of pulverized coal particle in First air, thus can meet coal dust as the requirement of reburning fuel to granular size.Here, it is 0.3 to 1.0 that the air that diluted air/fuel stream coal dust contains and the ratio of the concentration of coal dust convert stoichiometric ratio to, and concrete numerical value depends on that First air flows through the speed of bend pipe, the flexibility from dense rare stream baffle opening in the kind, bend pipe of coal pulverizer fineness of pulverized coal out, coal dust and bend pipe.One of them most preferred scheme is the average diameter of this strand of diluted air/fuel stream pulverized coal particle is 1/4 to 1/3 of the average diameter of pulverized coal particle in First air, and its coal dust content accounts for 10 ~ 20% of total coal dust amount.This scheme makes economic generation reburning fuel become possibility.

For boiler can be made under any operating mode to remain on NOx as far as possible little and situation that efficiency of combustion is as far as possible high, another preferred version of reburning fuel is that its concentration (accounting for the ratio of total First air) is adjustable with chemical equivalent.This can by outside aforementioned fine powder (dense/dilute phase) separator, increase set of device again: introduce together with coal dust that one pulverized coal flow and elbow separator come from coal mill system and send into a fine coal size classes device, through this grader, large particle is sent into one little (micro-) type coal pulverizer and is continued to shatter, and thin coal dust is then sent into recombustion burner and entered burner hearth.For making chemical equivalent adjustable, introduce the auxiliary wind of combustion again and again at reburning fuel spout.Like this, according to the method for aforementioned reburning RACS, can facilitate and regulate neatly and fire flow and chemical equivalent again.

At this, term " NOx " refers to nitrogen oxide, comprises NO, NO2, NO3, N2O, N2O3, N2O4, N3O4 and their mixture.

At this, term " NHi " refers to NH, NH2 and NH3 and their mixture.

At this, term " fuel bound nitrogen " refers to as the nitrogen element existed in coal with molecular forms, and this molecule is made up of carbon and nitrogen and possible oxygen.

At this, the ratio of air capacity used and theoretical air requirement required when completing burning when term " chemical equivalent α " refers to that fuel (be herein representative with coal) burns, theoretical air requirement required when α=1 has represented burning.

Integrated low nitrogen burning system of the present invention and control method, effectively, in time can carry out fuel flow rate, air classification, again burning and bias combustion energy technology be organically combined, maintains idealized chemical equivalent, reach the optimization of burning, nitrogen discharged amount is down to minimum.

Accompanying drawing explanation

Fig. 1 is the structural representation of the integrated low nitrogen burning system of the present invention.

Fig. 2 is the present invention's integrated low nitrogen burning systematic difference schematic diagram.

Fig. 3 is the principle schematic of the Secondary Air distribution RACS of the integrated low nitrogen burning system of the present invention.

Fig. 4 is the principle schematic of the fiery windward RACS of the present invention's integrated low nitrogen burning system.

Fig. 5 is the principle schematic of the reburning fuel RACS of the integrated low nitrogen burning system of the present invention.

Fig. 6 is the light-dark separation device schematic diagram for reburning RACS of the integrated low nitrogen burning system of the present invention.

Detailed description of the invention

Below in conjunction with the drawings and specific embodiments, the present invention is described in further detail.

The present invention also discloses a kind of integrated low nitrogen burning control method, comprises Secondary Air and distributes rate-determining steps, fiery windward rate-determining steps and reburning fuel rate-determining steps.

Described Secondary Air distributes rate-determining steps and comprises the steps:

(11) from each work burner secondary air flow sensor reading signal and sue for peace, draw secondary air flow summation;

(12) from each work, the fuel flow sensor of burner reads signal and sues for peace, and draws fuel total flow;

(13) signal of single given fuel flow sensor and described fuel total flow are carried out division arithmetic, draw the fuel flow rate ratio of this single given corresponding burner;

(14) described fuel flow rate ratio and secondary air flow summation are carried out multiplying, draw secondary air flow signal needed for single given corresponding burner;

(15) by described required secondary air flow Signal transmissions to the Secondary Air air damper controller of single given corresponding burner.

Described fiery windward rate-determining steps comprises the steps:

(21) read signal from oxygen level sensor and be converted to the total chemical equivalent signal of unit;

(22) read signal from unit load cell and be converted into combustion zone chemical equivalent signal;

(23) combustion zone chemical equivalent signal and the total chemical equivalent signal of unit are carried out division arithmetic, draw combustion zone chemical equivalent ratio signal;

(24) generating reference signal, and sue for peace with described combustion zone chemical equivalent ratio signal, the windward that must fire regional chemistry equivalents ratio signal; Described fiery windward regional chemistry equivalents ratio signal and fiery windward flow proportional signal carry out calculus of differences, and difference result and fiery windward regional chemistry equivalents ratio signal are sued for peace;

(25) read signal from bellows flow sensor and First air flow sensor and sue for peace respectively, drawing air total flow signal;

(26) by described fiery windward regional chemistry equivalents ratio signal and add that the air total flow signal after difference result carries out multiplying, must fire flow signal needed for windward;

(27) flow signal needed for described fiery windward is sent to fiery windward air damper controller.

(28) read signal from air flow sensor secondary air flow sensor, reburning fuel auxiliary air flow sensor and fire respectively, and summation show not containing the air total flow signal of First air;

(29) signal read from air flow sensor on fire and the described air total flow signal not containing First air are carried out division arithmetic, the windward that must fire flow proportional signal;

Described reburning fuel rate-determining steps comprises the steps:

(31) default reburning fuel scaling signal is generated;

(32) from reburning fuel flow sensor and each work, the fuel flow sensor of burner reads signal and sues for peace respectively, draws actual consumption fuel total flow signal;

(33) signal read from reburning fuel flow sensor and described actual consumption fuel total flow signal are carried out division arithmetic, draw actual reburning fuel scaling signal;

(34) described default reburning fuel scaling signal and described actual reburning fuel scaling signal are carried out calculus of differences, and difference result and described default reburning fuel scaling signal are sued for peace, draw reburning fuel setting scaling signal after compensating;

(35) from fuel total flow sensor reading signal, and reburning fuel after this signal and described compensation is set scaling signal carry out multiplying, draw required reburning fuel flow signal;

(36) described required reburning fuel flow signal is sent to reburning fuel flow controller.

The invention allows for a kind of integrated low nitrogen burning system of correspondence, below in conjunction with accompanying drawing, the method and system that the present invention proposes are described in further detail.

As shown in Figure 1, integrated low nitrogen burning system of the present invention, comprise controller module 100, described controller module 100 distributes control module 300 by Secondary Air, fire windward control module 200 and reburning fuel control module 400 form, it should be noted that, Secondary Air distributes control module 300, fire windward control module 200 and reburning fuel control module 400 can be realized also can being realized by software module by hardware device, such as, each arithmetic logic in each module can be realized by the hardware logic arithmetic unit of reality, also can be that controller module 100 is directly realized by a control chip group, the program of each logic of load operating in control chip group.Hereafter the form with logical device is described.

Be illustrated in figure 2 the example that integrated low nitrogen burning system of the present invention is applied to middle warehouse formula coal-powder boiler, the fuel described in the present embodiment is Pulverized Coal.Fuel is through burner and fire device again and enter burner hearth combustion.The mode of movement of fuel is as follows: ground coal dust falls into blender 12 from Pulverized Coal Bin 11, mix with the hot blast after air preheater 24 preheating in a mixer, enter into deep or light (thickness) separator 13 subsequently, after being separated in dense-and-weak separator, be divided into denseer (slightly) pulverized coal flow 33 and lighter (carefully) pulverized coal flow 34, denseer (slightly) pulverized coal flow 33 to be divided in each combustor nozzle that (in figure, numeral 18 represents First air air doors subsequently as First air, for succinctly only drawing two), spray in burner hearth 22 and burn, lighter (carefully) pulverized coal flow 34, circulating flue gas 35, pulverized coal flow 36 after micro-mill is subsequently all through the conveying of pipeline 37, enter segmentation separator 14, the slightly fine breeze be isolated to.Auxiliary hot blast flows out from air door 19; The isolated slightly thick pulverized coal flow 38 of segmentation separator enters in micro grinder 16 and grinds, segmentation after grinding also enters pulverized-coal collector through pipeline 36, like this, form a partial circulating between pulverized-coal collector and micro grinder, ensure that finally entering the pulverized coal flow 39 firing spout 20 again has appropriate and enough fineness of pulverized coal.In addition, segmentation separator inlet has also passed into circulating flue gas 35, and the whole power firing the flowing of process pulverized coal flow is again driven by blower fan 25.

In Fig. 2, the follow-up supply of coal-powder boiler air is all provided by main air case 27, mainly contains Secondary Air 17 (have in each burner, only draw two in figure) and fiery windward 21, also has a small amount of auxiliary air 19 needed for reburning fuel in addition.Under the effect of pressure fan 23, the air preheater 24 of cold air through being positioned at back-end ductwork heats, form hot blast, a hot blast part is used for effect that is dry and pulverized coal conveying, enter in blender 12 through pipeline 31, another part then enters in bellows 27, and each air door in bellows is assigned in burner hearth, thus providing air for the catching fire of coal dust, smooth combustion and after-flame, in Fig. 1,40 represent that the hot blast in bellows is assigned to fiery windward air door.In Fig. 2,15 is flapper, and object is when preventing pulverized coal flow from entering another pressure limit by a certain pressure limit, and air channelling phenomenon occurs, thus maintenance powder circulates smoothly, and 26 represent non-return valve, prevent pulverized coal flow from flowing back to blender through pipeline 34.

The present invention also comprises some for being arranged on secondary air flow sensor 55 in different burner, some for being arranged on fuel flow sensor 53 in different burner tubes respectively and for adjusting the Secondary Air air damper controller 308 ' controlling Secondary Air damper positions, above-mentioned device and Secondary Air distribute control module 300 and coordinate respectively; Oxygen level sensor 59, unit load cell 60, bellows flow sensor 54, First air flow sensor 52 and the fiery windward air damper controller 218 ' for regulable control fire windward damper positions, also comprise air flow sensor 58 on reburning fuel auxiliary air flow sensor 56 and fire, above device coordinates with fiery windward control module 200; For be arranged on territory, reburning zone pipeline reburning fuel flow sensor 57, for be arranged on main pipeline fuel total flow sensor 51 and for regulating the reburning fuel flow controller 408 ' of reburning fuel flow, above device be used for coordinate with reburning fuel control module 400.

As shown in Figure 3, Secondary Air in controller module 100 distributes control module 300, from each work, the secondary air flow sensor 55 of burner reads signal 76, multiple signals 76 enter adder 305 to carry out summation and draws secondary air flow summation (signal 306), i.e. 306 summations representing the secondary air flow of burner in all working.From each work, the fuel flow sensor 53 of burner reads signal 81, multiple signals 81 enter adder 301 to carry out summation and draws fuel total flow (signal 302), and signal 302 represents the total flow of the coal dust of the burner dissipated in this coal-powder boiler work.Wherein a road signal 81 (given single fuel flow sensor 53) and signal 302 enter divider 303 and carry out division arithmetic, draw the fuel flow rate ratio (signal 304) of this single given corresponding burner, the pulverized coal flow that namely signal 304 represents single given burner accounts for the ratio of the coal dust total flow of the burner dissipated in coal-powder boiler all working.Signal 306 and signal 304 enter multiplier 307 and carry out multiplying, and draw secondary air flow signal (signal 308) needed for single given corresponding burner, namely signal 308 represents the given secondary air flow needed for single burner; Signal 308 is sent to Secondary Air air damper controller 308 '.When it should be noted that optimum enforcement, can all arrange a Secondary Air air damper controller 308 ' to each burner, the fuel flow sensor 53 for each correspondence calculates a signal 308, controls corresponding Secondary Air air damper controller 308 '.And in actual enforcement, if be difficult to each burner all establish Secondary Air air damper controller 308 ', can control with single, this control strategy is still effective than merely presetting mean value in prior art.Such control ensures that the Secondary Air being entered burner hearth by given single burner is to the Secondary Air needed for the burning of burner, to optimize the proportioning of fuel and air quantity, reduces the discharge of NOx.

As shown in Figure 4, the fiery windward control module 200 in controller module 100, reads signal 71 from oxygen level sensor 59, after signal generator 201, obtains signal 202, and signal 202 represents the total chemical equivalent of unit.Read signal 72 from unit load cell 60, obtain signal 204 after signal generator 203, signal 204 represents the chemical equivalent of coal-powder boiler combustion zone.Signal 204 and signal 202 enter divider 207 and carry out division arithmetic, and draw combustion zone chemical equivalent ratio signal (signal 208), namely signal 208 represents that the chemical equivalent of coal-powder boiler combustion zone accounts for the total stoichiometric ratio of unit.Signal generator 205 produces reference signal 206, and this reference signal 206 can be based on fuel kind, line size reference factor and fixed reference value, also can be the reference value drawn by other sensor feedback.Signal 208 and signal 206 enter adder 209 and sue for peace, the windward that must fire regional chemistry equivalents ratio signal (signal 210).The signal 76 read from secondary air flow sensor 55, the signal 75 read from reburning fuel auxiliary air flow sensor 56 and all enter adder 217 carry out summation operation from the signal 74 that air flow sensor fire 58 reads, draw not containing the air total flow signal (signal 221) of First air.Signal 74 and signal 221 enter divider 219 and carry out division arithmetic, the windward that must fire flow proportional signal (signal 220).Signal 210 and signal 220 enter difference engine 213 and carry out calculus of differences, draw difference result signal 214, signal 210 and signal 214 are sued for peace in adder 211, draw signal 212, signal 212 is that the required fiery windward regional chemistry equivalent that compensate in air door characteristic after uncertain factor accounts for the total stoichiometric ratio of unit.Cancel the step such as adder 217, difference engine 213, then eliminate compensation mechanism, the accuracy of signal can decrease, but still can effectively reduce nitrogen discharged than prior art.The signal 73 of bellows flow sensor 54, the signal 77 of First air flow sensor 52 enter adder 215 and draw air total flow signal (signal 216), signal 216 and signal 212 enter multiplier 217 to carry out multiplying and draws signal 218, then signal 218 represents the flow of required fiery windward, signal 218 is imported into fiery windward air damper controller 218 ', thus the adjustment that the position and needing to this position controlling fiery windward air door is made, on the fire ensureing to enter burner hearth, wind flow is wind flow on required fire.

As shown in Figure 5, reburning fuel control module 400 in controller module 100, signal 91 is read and the fuel flow sensor 53 of burner reads signal 81 from each work from reburning fuel flow sensor 57, enter adder 409 to sue for peace, draw actual consumption fuel total flow signal (signal 410), signal 91 and signal 410 enter divider 411 and carry out division arithmetic, draw actual reburning fuel scaling signal (signal 412).Also comprise signal generator 401 in reburning fuel control module 400, this signal generator 401 is for generating default reburning fuel scaling signal (signal 402).Signal 402 and signal 312 are entered in difference engine 403 and carries out calculus of differences, draw difference result signal 404.Signal 404 and signal 402 enter adder 405 and show that compensating rear reburning fuel sets scaling signal (signal 406).Signal 92 is read from fuel total flow sensor 51, signal 92 and signal 406 enter multiplier 407 and carry out multiplying, draw required reburning fuel flow signal (signal 408), signal 408 is input in reburning fuel flow controller 408 ', realizes the flow-control to pulverized coal flow 39.

As shown in Figure 6, the reburning fuel flow controller 408 ' in the present embodiment is a baffle plate.Pulverized coal flow 32 after blender 12, through dense-and-weak separator 13, under the influence of centrifugal force, is divided into denseer (slightly) pulverized coal flow 33 and lighter (carefully) pulverized coal flow 34.Denseer flow in fuel 33 enters in burner as First air immediately, and the jet of high concentration pulverized coal can reduce air-flow ignition temperature, improves reaction speed, ensure that the fast and stable burning at initial stage, and reduces the discharge of NOx; Lighter flow in fuel 34 is more thin coal dusts, isolates thinner coal dust 39, enter and fire in device again above burner, enter hearth combustion by jet via segmentation separator 14.The afterburning effect of reburning fuel can reduce the content of oxygen in flue gas, thus reduce the discharge of NOx, the aperture of reburning fuel auxiliary air air door to be regulated according to the concrete ratio of reburning fuel, to ensure at this (α < 1) burning under anaerobic condition of (reburning) region reburning fuel in combustion process.Air capacity and the concrete adjustment process of chemical equivalent value can be passed through reburning fuel auxiliary air flow sensor 56 and throttle opening controller realizes.Described deep or light (thickness) separator arranges baffle plate in elbow, and this baffle plate controls by damper regulator (i.e. reburning fuel flow controller 408 '), and control strategy illustrates in Figure 5.In figure 6, when during baffle plate is by figure, position rotates clockwise, comparatively thick coal culm stream aperture reduces, and comparatively thin powdered coal stream aperture increases, thus regulates the ratio of deep or light fuel; Otherwise when during baffle plate is by figure, position rotates counterclockwise, comparatively thick coal culm stream aperture increases, and comparatively thin powdered coal stream aperture reduces.In theory, when ature of coal is deteriorated, by controlling by baffle plate slightly toward upper rotation, thus the coal powder density being entered burner hearth by burner jet can be improved, being conducive to the ignition of breeze airflow.Thus, air-coal separating considerably increases the adaptability of burner for coal type change.It should be noted that, control flow in fuel 39 and be only a kind of by baffle plate fuel metering stream 33 and flow in fuel 34 and not only easily implemented but also one of means that cost is low, during actual enforcement, can also by controlling blower fan 25 or having the direct skirt road of the pipeline of flow in fuel 32 to realize to other technologies means such as flow in fuel 37.The invention also discloses a kind of fine grained fuel and obtain mechanism, described fine grained fuel obtains mechanism and comprises separation bend pipe, segmentation separator 14 and mill 16; One end of described separation bend pipe is entrance (entering for flow in fuel 32), and the other end is provided with coarse granule fuel outlet (flowing out for flow in fuel 33) and fine grained fuel outlet (flowing out for flow in fuel 34); The fine grained fuel outlet being separated bend pipe is communicated with the entrance of segmentation separator 14; The outlet of segmentation separator 14 is communicated with the entrance of mill 16 (i.e. pipeline 38), and the outlet of mill 16 is communicated with (i.e. pipeline 36) with the entrance of segmentation separator 14.It should be noted that, when optimum, be separated by means of only pipeline and can realize required fine breeze, without the need to additionally increasing segmentation separator 14 and the such device of mill 16, reducing costs; But in reality, be difficult to settle realization at one go optimum, by the combination with segmentation separator 14, mill 16, can effectively realize obtaining fine breeze, with the demand that satisfied reduction is nitrogen discharged.To obtain for the purpose of fine breeze in the present embodiment, thinner pulverized coal particle is also construed as fine grained mentioned above; In addition for the solid fuel of other types, also fine grained fuel can be obtained, such as colliery powder.

Only using middle warehouse formula coal-powder boiler as the example of an application, technology contents of the present invention is described in the present embodiment, can using dissimilar boiler as application of the present invention in reality, in addition, for the boiler without multiple combustion zone (such as do not have fiery windward region or do not have reburning fuel region), the corresponding control module and rate-determining steps mentioned in the present invention suitably can be reduced.On the other hand, only using coal dust as fuel example in the present embodiment, can be applied to the Combustion System of other solid fuels (such as gangue, biomass fuel, rubbish etc.) in reality, the sensor only need selected is applicable to.

Claims (10)

1. an integrated low nitrogen burning control method, is characterized in that, comprises Secondary Air and distributes rate-determining steps, and described Secondary Air distributes rate-determining steps and comprises the steps:

(11) from each work burner secondary air flow sensor reading signal and sue for peace, draw secondary air flow summation;

(12) from each work, the fuel flow sensor of burner reads signal and sues for peace, and draws fuel total flow;

(13) signal of single given fuel flow sensor and described fuel total flow are carried out division arithmetic, draw the fuel flow rate ratio of this single given corresponding burner;

(14) described fuel flow rate ratio and secondary air flow summation are carried out multiplying, draw secondary air flow signal needed for single given corresponding burner;

(15) by described required secondary air flow Signal transmissions to the Secondary Air air damper controller of single given corresponding burner.

2. integrated low nitrogen burning control method according to claim 1, is characterized in that: also comprise fiery windward rate-determining steps, described fiery windward rate-determining steps comprises the steps:

(21) read signal from oxygen level sensor and be converted to the total chemical equivalent signal of unit;

(22) read signal from unit load cell and be converted into combustion zone chemical equivalent signal;

(23) combustion zone chemical equivalent signal and the total chemical equivalent signal of unit are carried out division arithmetic, draw combustion zone chemical equivalent ratio signal;

(24) generating reference signal, and sue for peace with described combustion zone chemical equivalent ratio signal, the windward that must fire regional chemistry equivalents ratio signal;

(25) read signal from bellows flow sensor and First air flow sensor and sue for peace respectively, drawing air total flow signal;

(26) described fiery windward regional chemistry equivalents ratio signal and air total flow signal are carried out multiplying, must fire flow signal needed for windward;

(27) flow signal needed for described fiery windward is sent to fiery windward air damper controller.

3. integrated low nitrogen burning control method according to claim 2, is characterized in that: in described fiery windward rate-determining steps, also comprise the steps:

(28) read signal from air flow sensor secondary air flow sensor, reburning fuel auxiliary air flow sensor and fire respectively, and summation show not containing the air total flow signal of First air;

(29) signal read from air flow sensor on fire and the described air total flow signal not containing First air are carried out division arithmetic, the windward that must fire flow proportional signal;

Described step (24) is specially, generating reference signal, and sues for peace with described combustion zone chemical equivalent ratio signal, the windward that must fire regional chemistry equivalents ratio signal; Described fiery windward regional chemistry equivalents ratio signal and fiery windward flow proportional signal carry out calculus of differences, and difference result and fiery windward regional chemistry equivalents ratio signal are sued for peace;

Described step (26) is specially, and carry out multiplying with air total flow signal after described fiery windward regional chemistry equivalents ratio signal is added difference result, must fire flow signal needed for windward.

4. the integrated low nitrogen burning control method according to claim 1-3 any one, is characterized in that: also comprise reburning fuel rate-determining steps, described reburning fuel rate-determining steps comprises the steps:

(31) default reburning fuel scaling signal is generated;

(32) from reburning fuel flow sensor and each work, the fuel flow sensor of burner reads signal and sues for peace respectively, draws actual consumption fuel total flow signal;

(33) signal read from reburning fuel flow sensor and described actual consumption fuel total flow signal are carried out division arithmetic, draw actual reburning fuel scaling signal;

(34) described default reburning fuel scaling signal and described actual reburning fuel scaling signal are carried out calculus of differences, and difference result and described default reburning fuel scaling signal are sued for peace, draw reburning fuel setting scaling signal after compensating;

(35) from fuel total flow sensor reading signal, and reburning fuel after this signal and described compensation is set scaling signal carry out multiplying, draw required reburning fuel flow signal;

(36) described required reburning fuel flow signal is sent to reburning fuel flow controller.

5. an integrated low nitrogen burning system, is characterized in that: comprise controller module, some for being arranged on secondary air flow sensor in different burner, some for being arranged on fuel flow sensor in different burner tubes respectively and for adjusting the Secondary Air air damper controller controlling Secondary Air damper positions respectively;

Described controller module is used for: from each work burner secondary air flow sensor reading signal and sue for peace, draw secondary air flow summation; From each work, the fuel flow sensor of burner reads signal and sues for peace, and draws fuel total flow; The signal of single given fuel flow sensor and described fuel total flow are carried out division arithmetic, draws the fuel flow rate ratio of this single given corresponding burner; Described fuel flow rate ratio and secondary air flow summation are carried out multiplying, draws secondary air flow signal needed for single given corresponding burner; By described required secondary air flow Signal transmissions to the Secondary Air air damper controller of single given corresponding burner.

6. integrated low nitrogen burning system according to claim 5, is characterized in that: also comprise oxygen level sensor, unit load cell, bellows flow sensor, First air flow sensor and the fiery windward air damper controller for regulable control fire windward damper positions;

Described controller module also for: read signal be converted to the total chemical equivalent signal of unit from oxygen level sensor; Read signal from unit load cell and be converted into combustion zone chemical equivalent signal; Combustion zone chemical equivalent signal and the total chemical equivalent signal of unit are carried out division arithmetic, draws combustion zone chemical equivalent ratio signal; Generating reference signal, and sue for peace with described combustion zone chemical equivalent ratio signal, the windward that must fire regional chemistry equivalents ratio signal; Read signal from bellows flow sensor and First air flow sensor and sue for peace respectively, drawing air total flow signal; Described fiery windward regional chemistry equivalents ratio signal and air total flow signal are carried out multiplying, and must fire flow signal needed for windward; Flow signal needed for described fiery windward is sent to fiery windward air damper controller.

7. integrated low nitrogen burning system according to claim 6, is characterized in that: also comprise air flow sensor on reburning fuel auxiliary air flow sensor and fire;

Described controller module also for: read signal from air flow sensor secondary air flow sensor, reburning fuel auxiliary air flow sensor and fire respectively, and summation show not containing the air total flow signal of First air; The signal read from air flow sensor on fire and the described air total flow signal not containing First air are carried out division arithmetic, the windward that must fire flow proportional signal; Described fiery windward regional chemistry equivalents ratio signal and fiery windward flow proportional signal carry out calculus of differences, and difference result and fiery windward regional chemistry equivalents ratio signal are sued for peace; Carry out multiplying with air total flow signal after described fiery windward regional chemistry equivalents ratio signal is added difference result, must fire flow signal needed for windward.

8. the integrated low nitrogen burning system according to claim 5-7 any one, is characterized in that: also comprise the reburning fuel flow sensor for being arranged on territory, reburning zone pipeline, for be arranged on main pipeline fuel total flow sensor and for regulating the reburning fuel flow controller of reburning fuel flow;

Described controller module also for: generate preset reburning fuel scaling signal; From reburning fuel flow sensor and each work, the fuel flow sensor of burner reads signal and sues for peace respectively, draws actual consumption fuel total flow signal; The signal read from reburning fuel flow sensor and described actual consumption fuel total flow signal are carried out division arithmetic, draws actual reburning fuel scaling signal; Described default reburning fuel scaling signal and described actual reburning fuel scaling signal are carried out calculus of differences, and difference result and described default reburning fuel scaling signal are sued for peace, draw reburning fuel setting scaling signal after compensating; From fuel total flow sensor reading signal, and reburning fuel after this signal and described compensation is set scaling signal carry out multiplying, draw required reburning fuel flow signal; Described required reburning fuel flow signal is sent to reburning fuel flow controller.

9. integrated low nitrogen burning system according to claim 8, it is characterized in that: described reburning fuel flow controller is the baffle plate for being arranged on air-coal separating elbow, needed for this baffle plate can send according to controller module, reburning fuel flow signal rotates.

10. integrated low nitrogen burning system according to claim 8, is characterized in that: also comprise a kind of fine grained fuel and obtain mechanism, and described fine grained fuel obtains mechanism and comprises separation bend pipe, segmentation separator and mill; One end of described separation bend pipe is entrance, and the other end is provided with coarse granule fuel outlet and fine grained fuel outlet; The fine grained fuel outlet being separated bend pipe is communicated with the entrance of segmentation separator; The segmentation outlet of separator is communicated with the entrance of mill, and the outlet of mill is communicated with the entrance of segmentation separator.