CN103017529A

CN103017529A - Method and system for controlling air quantity of main draft fan of sintering machine

Info

Publication number: CN103017529A
Application number: CN2012105782909A
Authority: CN
Inventors: 孙超; 袁立新; 申伟杰; 卢杨权; 高鹏双
Original assignee: Zhongye Changtian International Engineering Co Ltd
Current assignee: Zhongye Changtian International Engineering Co Ltd
Priority date: 2012-12-27
Filing date: 2012-12-27
Publication date: 2013-04-03
Anticipated expiration: 2032-12-27
Also published as: CN103017529B

Abstract

The invention discloses a method and a system for controlling the air quantity of a main draft fan of a sintering machine. The method comprises the steps of: measuring the trolley speed of a sintering trolley, calculating the vertical sintering speed of materials, and determining the effective air quantity of each air bellow; detecting smoke components of a big flue; calculating the effective air rate of each air bellow according to the detected smoke components; calculating the target air quantity of the big flue; and sending the target air quantity of the big flue to a main draft fan controller to serve as a regulating parameter, and regulating the frequency of the main draft fan to change towards a target frequency by the main draft fan controller. When the speed of the sintering trolley changes, the method can be used to regulate the air quantity of the main draft fan to be matched with the current trolley speed automatically and accurately, and thus reduce the energy consumption of the main draft fan in a sintering process on the premise of guaranteeing the sintering quality.

Description

Sintering machine main air exhauster air quantity control method and system

Technical field

The application relates to the SINTERING TECHNOLOGY field, particularly relates to a kind of sintering machine main air exhauster air quantity control method and system.

Background technology

Along with developing rapidly of modern industry, the iron and steel production scale is increasing, and energy resource consumption is also more and more, and the energy-conserving and environment-protective index more and more becomes the important investigation factor of steel manufacture process.In iron and steel is produced, the iron-bearing material ore needs to process through sintering system before entering blast furnace process, namely, with various powdery iron-containing raw materials, allocate an amount of fuel and flux into, add an amount of water, after mixing and pelletizing, cloth is placed on roasting on the pallet, makes it that series of physical chemical change occur, form the sintering deposit of easily smelting, this process is referred to as sintering.

Sintering system mainly comprises a plurality of equipment such as pallet, mixer, main exhauster, central cooler, its total technological process is referring to shown in Figure 1: various raw materials are in proportioning room 1 proportioning, form mixed material, then enter mixer 2 mixings and pelletizing, pass through round roller batcher 3 and nine roller material distributing machine 4 with its uniformly dispersing formation bed of material on pallet 5, igniting blower fan 12 and the blower fan 11 of igniting are material igniting beginning sintering process again.The sintering deposit that obtains after sintering is finished enters central cooler 9 coolings after single roll crusher 8 fragmentations, finally by delivering to blast furnace or finished product ore storage bin behind the whole grain of screening.Wherein, the oxygen that sintering process needs is provided by main exhauster 10, pallet 5 belows are provided with a plurality of vertical bellows 6 side by side, the bellows below is the large flue of horizontal setting (or claiming flue) 7, large flue 7 links to each other with main exhauster 10, the negative pressure wind process chassis that main exhauster 10 produces by large flue 7 and bellows 6 is for sintering process provides combustion air.

In order to guarantee sintering quality, usually initial stage of sintering to the speed of pallet and pallet on material bed thickness regulate, so that sintering end point can (be generally second-to-last bellows on the pallet) in the fixed position that sets in advance, and in case after determining sintering end point, speed and the thickness of feed layer of pallet just are determined.Yet in actual production process, because the impact of the memory space factor of the market factor, raw material memory space factor and sintering deposit etc. needs to regulate Sintering Yield and then regulates the sintered material amount, and then needs to regulate thickness of feed layer or machine speed.But because the adjustable extent of thickness of feed layer is less, the time delay of simultaneously thickness of feed layer adjusting is longer, has serious hysteresis quality, so usually adopt the regulating platform vehicle speed that inventory is regulated.Yet after machine speed changed, sintering end point will depart from the fixed position, can't guarantee preferably sintering quality.

For adapting to the machine speed variation to the impact of sintering quality, in existing sintering process, the main exhauster of sintering machine system turns round according to maximum design power, and this must cause too high power consumption and loss.

Summary of the invention

In view of this, the embodiment of the present application provides a kind of sintering machine main air exhauster air quantity control method and system, to reduce the energy consumption of main exhauster in the sintering process.

To achieve these goals, the technical scheme that provides of the embodiment of the present application is as follows:

A kind of sintering machine main air exhauster air quantity control method comprises:

Measure the machine speed of pallet, utilize known thickness of feed layer, known sintering end point and described machine speed to calculate the vertical sintering speed of material, and, utilize relation between effective wind rate and the vertical sintering speed to determine the effective wind rate of each bellows;

Detect the smoke components of large flue;

The smoke components that obtains according to detection calculates effective wind rate of each bellows;

Calculate large flue target air quantity, described large flue target air quantity equals the air quantity sum of each bellows, and the air quantity of each bellows equals the effective wind rate of described bellows divided by effective wind rate;

Described large flue target air quantity is sent to the main exhauster controller as regulating parameter, and the frequency that described main exhauster controller is regulated main exhauster changes to target frequency, and described target frequency equals the corresponding frequency of large flue target air quantity.

In another embodiment based on said method, also comprise the steps:

Detect the current air quantity of large flue;

Calculate the difference of the current air quantity of large flue and large flue target air quantity;

If described difference is more than or equal to the threshold value of setting, then described large flue target air quantity is sent to the main exhauster controller as regulating parameter, otherwise, described large flue target air quantity is sent to the bellows valve positioner as regulating parameter, described bellows valve positioner is regulated the aperture of bellows valve, makes the large flue effective wind rate equal the effective wind rate of described large flue target air quantity before valve regulated.

The present invention also provides a kind of sintering machine main air exhauster air quantity control system, comprising:

The tachometric survey unit is for the machine speed of measuring pallet;

The vertical sintering speed computing unit is used for utilizing known thickness of feed layer, known sintering end point and described machine speed to calculate the vertical sintering speed of material;

The effective wind rate determining unit is used for utilizing relation between effective wind rate and the vertical sintering speed to determine the effective wind rate of each bellows;

The detection of exhaust gas compositions unit is for detection of the smoke components in the large flue;

Effective wind rate computing unit is for effective wind rate of calculating each bellows according to described smoke components;

The Wind Coverage Calculation unit is used for calculating large flue target air quantity, and described large flue target air quantity equals the air quantity sum of each bellows, and the air quantity of each bellows equals effective wind rate divided by effective wind rate;

Control module is used for large flue target air quantity is sent to the main exhauster controller as regulating parameter, and the frequency that described main exhauster controller is regulated main exhauster changes to target frequency, and described target frequency equals the corresponding frequency of large flue target air quantity.

By above technical scheme as seen, this main exhauster air quantity control method that the embodiment of the present application provides, the sintering pallet that has set for thickness of feed layer, sintering end point, by detecting the machine speed on the chassis, determine the effective wind rate required with corresponding each bellows of machine speed, when sintering, by detecting the smoke components of current sintering machine large flue, can calculate effective wind rate of current each bellows, effective wind rate refers to participate in the sintering process the shared ratio of effective wind rate of sintering reaction here.Calculate large flue target air quantity according to effective wind rate and effective wind rate, and this large flue target air quantity is sent to the main exhauster controller, the frequency that the main exhauster controller just can be regulated main exhausting blower fan changes to target frequency, and target frequency equals the corresponding frequency of large flue target air quantity here.

Compared with prior art, the method that the embodiment of the present application provides, after the speed of sintering pallet changes, can be automatically, the air quantity of main exhauster is adjusted to current machine speed is complementary exactly, realization reduces the energy consumption of main exhauster in the sintering process under the prerequisite that guarantees sintering quality.The method that the embodiment of the invention provides, one ton of sintering deposit product of every production, can realize electric energy saving 15%, if the embodiment of the invention is applied to the control of 180 square metres of sintering machines, with do not adopt the solution of the present invention and compare, the Spring Festival holidays are economized approximately 1,080 ten thousand degree of electric energy, if the embodiment of the invention is applied to the control of 360 square metres of sintering machines, with do not adopt the solution of the present invention and compare, the Spring Festival holidays are economized approximately 2,160 ten thousand degree of electric energy, can bring many economic and social benefits such as monetary savings, reducing polluted emission.

It may be noted that especially has the equipment that much is mutually related in the sintering system, comparatively speaking, with the associated equipment of more miscellaneous equipment, can be called system equipment, such as pallet, main exhauster etc.; And with the associated equipment of less equipment, then can be called local devices, such as air door of bellows, bellows etc.Obviously, regulating system equipment is taken out frequency, the main exhausting door of adjusting etc. such as regulating platform vehicle speed, adjusting master larger to systematic influence; And the adjusting local devices is then less on the impact of system.Therefore, in sintering system, by local devices, but not by the adjusting of system equipment system is exerted one's influence, be conducive to system stability and extension device life-span.Therefore, in the embodiment of the invention, only have when the difference of the current air quantity of large flue and large flue target air quantity during more than or equal to the threshold value set, described large flue target air quantity is sent to the main exhauster controller as regulating parameter, the frequency of being regulated main exhauster by described main exhauster controller changes to target frequency, otherwise, when the difference of the current air quantity of large flue and large flue target air quantity is less than or equal to the threshold value of setting, described large flue target air quantity is sent to the bellows valve positioner as regulating parameter, described bellows valve positioner is regulated the aperture of bellows valve, makes the large flue effective wind rate equal the effective wind rate of described large flue target air quantity before valve regulated.The embodiment of the invention stabilizes to prerequisite to keep machine speed and main exhauster frequency and main exhauster air door, when air quantity changes greatly, realize regulating target by regulating the main exhauster frequency, and change hour at air quantity, realize regulating target by the aperture of regulating sintering bellows valve, and then the vertical speed that realizes regulating the material sintering, thereby more accurate control sintering process and sintering end point.As seen, the embodiment of the invention provides a kind of regulative mode that is conducive to system stability.

Description of drawings

In order to be illustrated more clearly in the embodiment of the present application or technical scheme of the prior art, the below will do to introduce simply to the accompanying drawing of required use in embodiment or the description of the Prior Art, apparently, the accompanying drawing that the following describes only is some embodiment that put down in writing among the application, for those of ordinary skills, under the prerequisite of not paying creative work, can also obtain according to these accompanying drawings other accompanying drawing.

Fig. 1 is the structural representation of existing sintering machine;

The flow chart of the sintering machine main air exhauster air quantity control method that Fig. 2 provides for the embodiment of the present application one;

The flow chart of the sintering machine main air exhauster air quantity control method that Fig. 3 provides for the embodiment of the present application two;

The flow chart of the sintering machine main air exhauster air quantity control method that Fig. 4 provides for the embodiment of the present application three;

The structural representation of the sintering machine main air exhauster air quantity control system that Fig. 5 provides for the embodiment of the present application four;

The structural representation of the sintering machine main air exhauster air quantity control system that Fig. 6 provides for the embodiment of the present application five;

The structural representation of the sintering machine main air exhauster air quantity control system that Fig. 7 provides for the embodiment of the present application six.

The specific embodiment

In order to make those skilled in the art person understand better technical scheme among the application, below in conjunction with the accompanying drawing in the embodiment of the present application, technical scheme in the embodiment of the present application is clearly and completely described, obviously, described embodiment only is the application's part embodiment, rather than whole embodiment.Based on the embodiment among the application, those of ordinary skills are not making the every other embodiment that obtains under the creative work prerequisite, all should belong to the scope of the application's protection.

In the sintering system, load is usually expressed as various ways, as, inventory, thickness of feed layer, even because the relevance of equipment, an equipment may be the load of another associate device, for example machine speed just may be the load of main exhauster.In the reality, have a lot of reasons, change such as equipment fault, design, cause load variations or fluctuation, thereby change or affect the balance of sintering system and stablize, at this moment, just need to change the duty of System Dependent equipment, that is, carry out system and regulate, can not guarantee otherwise Sintering Yield will occur, or environmental pollution, invalid energy consume the problems such as excessive.

Embodiment one:

The flow chart of the main exhauster air quantity control method that Fig. 2 provides for the embodiment of the present application one.

As shown in Figure 2, the method comprises:

S201: the machine speed of measuring pallet.

When measuring the machine speed of pallet, can obtain the chassis speed of service of setting in the chassis control appliance, as machine speed.But in actual motion, owing to reasons such as wearing and tearing or mechanical breakdowns, may cause the actual motion speed of chassis inconsistent with the setting speed of service, and then can affect the air quantity of regulating main exhauster, so in the present embodiment, installation rate sampling instrument on chassis, the actual motion speed of direct-detection chassis, as machine speed, to avoid owing to chassis actual motion speed and the inconsistent adjusting that affects main exhausting amount of the setting speed of service.

In addition, can also obtain the inventory of sintering machine, in the situation that determine thickness of feed layer H, utilize formula (1) to calculate the machine speed V corresponding with detecting inventory _Chassis

E=S _Chassis* h _{The bed of material}* V _Chassis* ρ/1000 (1)

Wherein: E is the sintered material amount of unit interval, and unit is t/min; S _ChassisBe the pallet width, unit is m; h _{The bed of material}Be thickness of feed layer, unit is mm; V _ChassisPallet speed, m/min; ρ is sintering deposit density t/m ³For the sintering machine of specific material, the chassis width, and material density be certain.

After so just can accomplishing when actual production to regulate inventory, can be in time obtain and the machine speed of regulating rear inventory and being complementary according to inventory.

S202: the vertical sintering speed that calculates material.

After detecting machine speed, thickness of feed layer, chassis length parameter that coupling system is pre-stored utilize formula (2) can calculate material bed vertical sintering speed.

V _{Hang down}=H _{The bed of material}/ (L/ V _Chassis)=(H _{The bed of material}* V _Chassis)/L (2)

Wherein, V _{Hang down}Be vertical sintering speed (mm/min), H _{The bed of material}Be thickness of feed layer (mm), L is known sintering end point (m), V _ChassisBe machine speed (m/min).

S203: the effective wind rate that calculates each bellows.

In sintering process, effective wind rate refers to participate in the shared air quantity of oxygen of sintering reaction, and the required effective wind rate of material thorough roasting under known standard state utilizes formula (3) just can access the effective wind rate of each bellows under the standard state.

Q _{Mark is arranged}=V _{Hang down}* Q _{The t mark}(3)

Wherein, Q _{Mark is arranged}Be the effective wind rate of each bellows under the standard state, Q _{The t mark}Be the abundant required effective wind rate of material roasting under the standard state.

S204: the smoke components that detects large flue.

In material bed sintering process, the oxygen full consumption in the air quantity that main exhauster can be produced not fallen, but only some oxygen participates in sintering reaction, so, can understand the oxygen situation of supplies consumption in the sintering process by smoke components.In the present embodiment, detect the using smoke from big gas duct composition, mainly detect O in the unit volume flue gas ₂, CO, CO ₂, N ₂, NO, NO ₂Content.

S205: the smoke components that obtains according to detection calculates effective wind rate of each bellows.

Because air enters in the sintering reaction process, oxygen need participate in the reactions such as iron ore solid phase reaction and coke burning, so the oxygen in the air inlet is after sintering process, and the amount of its oxygen in flue gas can change; Because nitrogen does not participate in the solid phase reaction of iron ore, thus nitrogen through after the sintering process with NO, NO ₂, N ₂Form exist, but in flue gas Measurement accuracy.

According to the constant law of material, the stable content of nitrogen and oxygen in the air, like this according to nitrogen in flue gas amount and oxidized nitrogen amount, just can calculate the interior nitrogen of large flue and the amount of oxygen of entering into, according to remaining oxygen amount in the flue gas that records, utilize formula (4) accurately to calculate and participate in the reaction amount of oxygen simultaneously.

Wherein:

In the air in amount of oxygen/air nitrogen amount be a constant; Oxidized nitrogen amount can by detect in the flue gas analyzer NO, NO ₂Amount calculates; The nitrogen in flue gas amount also can be by detecting the N that obtains in the flue gas analyzer ₂Amount calculates.

Therefore, can calculate participation reaction amount of oxygen.

After calculating participation reaction amount of oxygen, utilize formula (5), can calculate the effective wind rate of large flue K.

Wherein: K is the effective wind rate of large flue, and the remaining oxygen amount can be by detecting the O that obtains in the flue gas in the flue gas analyzer ₂Amount calculates.

By the fume component analysis to large flue, can calculate effective wind rate of current each bellows.

In the present embodiment, with the smoke components of the large flue smoke components as each bellows, in fact be the average that obtains each bellows smoke components, thereby reduce the uncertainty impact that the physical characteristic difference of each bellows is brought, as leak out, bellows resistance etc.Therefore, in a further embodiment, also can detect the smoke components of each bellows, calculate according to this effective wind rate of each bellows, because this mode requires the flue gas inspection instrument quantity used more, make system have more complexity, cost is also higher.

In addition, step S204 can not limit and be positioned at as shown in Figure 1 after the step S203, and can also carry out simultaneously with step S201, and can be after step S203 and step S205, execution in step S206.

S206: calculate large flue target air quantity.

For each bellows, air quantity equals effective wind rate divided by effective wind rate, so according to formula (6), can calculate the air quantity Q of each bellows _i

Q _i=Q _{I has mark}/ K (6)

Wherein, Q _iBe the air quantity of bellows, Q _{I has mark}Effective wind rate for bellows.

Because large flue target air quantity Q _{Large flue}Equal the air quantity Q of all bellows _iSum so behind the air quantity that calculates each bellows, utilize formula (7), can be calculated large flue target air quantity Q _{Large flue}

Wherein, the 20th, the number of bellows on the sintering machine in this example, Q _iIt is the air quantity of i bellows.

Can calculate large flue target air quantity Q by above-mentioned formula _{Large flue}

S207: large flue target air quantity is sent to the main exhauster controller as regulating parameter.

By above-mentioned steps, can obtain an adjusting parameter Q who is used for regulating main exhauster _{Large flue}And should regulate parameter and send to the main exhauster controller, the frequency of regulating main exhauster according to " frequency relation of target air quantity parameter and main exhauster " by described main exhauster controller changes to target frequency, described target frequency equals the corresponding frequency values of large flue target air quantity, to realize the air force of control main exhauster.

In addition, when large flue exists when leaking out, the air quantity of main exhauster equals large flue target air quantity and the pipeline air quantity sum of leaking out, and at this moment, the air quantity sum of large flue target air quantity and pipeline need to being leaked out sends to the main exhauster controller as the adjusting parameter.Pipeline leaks out and also changes not quite when negative pressure variation is little, and in actual applications, the pipeline air quantity that leaks out can obtain in advance by experiment.

According to embodiment one, as long as change as the machine speed of load, all need to regulate the frequency of main exhauster, the power consumption of main exhauster and the variation of load are adapted, thereby realize energy-conservation.Yet main exhauster is as system equipment, and its adjusting meeting is had a negative impact to the stability of whole sintering system.Therefore, other embodiment based on described embodiment one provides an improved plan, this scheme when namely machine speed changes greatly, is regulated main exhauster in load, and in load variations hour, regulate the valve opening of bellows, like this adjusting of main exhauster and the adjusting of valve opening are combined, in load variations hour, reach the effect of main exhauster frequency adjustment with the adjusting of valve opening, thereby realize the less energy-conservation regulation scheme of whole sintering system impact.

Specifically, (not shown in figure 1) between the step S206 of embodiment one and step S207 also comprises the steps:

S1, the current air quantity of detection large flue;

The difference of S2, the calculating current air quantity of large flue and large flue target air quantity;

S3, judge described difference whether more than or equal to the threshold value of setting, if described difference is then carried out S207 more than or equal to the threshold value of setting, otherwise, execution in step S4;

S4, described large flue target air quantity is sent to the bellows valve positioner as regulating parameter, described bellows valve positioner is regulated the aperture of bellows valve, makes the large flue effective wind rate equal the effective wind rate of described large flue target air quantity before valve regulated.

In the sintering system, the validity of air quantity reduces along with the increase of air quantity, otherwise increases along with the minimizing of air quantity.For example, bed of material resistance is along with the sintering process duration is longer and more and more less, the reducing of bed of material resistance makes the air quantity by the bed of material increasing, the effective wind (being the oxygen that contains in the wind) that participates in sintering is then fewer and feweri, corresponding air quantity validity is also just more and more less, at this moment, and by regulating bellows valve openings (closing), suitably increase the bellows negative pressure, just be conducive to the air quantity of remaining valid.

The effect of step S3 is, judge the variation size of load, to determine to regulate main exhauster or controlling opening of valve, determine in other words the selection of regulating measure, so that when load variations is little, by the adjusting of valve being replaced the adjusting to main exhauster, thus make regulate as far as possible little on the impact of sintering system.

The effect of step S4 is, determines that the aperture change of valve greatly still diminishes.When obtaining large flue target air quantity, the variation that load is described needs system effective wind rate corresponding to described large flue target air quantity to provide, this effective wind rate is before valve regulated, be to calculate under the current valve state, that is, current effective wind rate multiply by described large flue target air quantity, therefore, the target that valve opening is regulated makes the large flue effective wind rate equal the effective wind rate of described large flue target air quantity before valve regulated exactly.Wherein, the large flue effective wind rate can calculate by large flue target air quantity and the effective wind rate that detection obtains.In view of those skilled in the art can realize according to the indication of the present embodiment this scheme, do not repeat them here.

Embodiment two:

The flow chart of the main exhauster air quantity control method that Fig. 3 provides for embodiment two.

According to shown in Figure 3, step S301 ~ S303 is equivalent to step S201 ~ S203 among the embodiment one, about the detailed description of step S301 ~ S303 can referring in above-described embodiment one to the description of step S201 ~ S203, do not repeat them here.

S304: according to the smoke components in the unit volume flue gas in the time interval detection large flue that sets in advance.

Here, in the present embodiment, the smoke components in the large flue in the unit volume flue gas is O in the unit volume flue gas ₂, CO, CO ₂, N ₂, NO, NO ₂Content.When detecting the using smoke from big gas duct composition, the time interval detection using smoke from big gas duct composition according to setting in advance can make and detect the more variation of adaptive system load.For example, work as system load, when unstable such as machine speed, select the shorter time interval, such as 1 second or 0.5 second, and when system load is stablized, select the long time interval, such as 10 seconds or 20 seconds, so both can make the adjusting of main exhauster be unlikely to too frequent and affect Systems balanth, the smoke components that can in time understand again in the sintering machine large flue changes, and in time regulates main exhauster.

In the present embodiment, the described time interval according to setting in advance is detected the smoke components in the unit volume flue gas in the large flue, refer to collect described smoke components after, start subsequent step S305 according to time interval of setting in advance, rather than whenever collect a smoke components and just start immediately subsequent step S305.

Therefore, dynamic adjustments interval detection time can be realized like this: gather described smoke components with the less time interval, if the difference of adjacent twice collection value is less than the value of setting, for example 5%(should set value when system, determined by parameters such as the degree of regulation of main exhauster and the stabilities of a system, this does not give unnecessary details), then select the long time interval, such as 10 seconds or 20 seconds, start subsequent step S305, otherwise, the shorter time interval selected, such as 1 second or 0.5 second, start subsequent step S305.In other example, start the time interval of subsequent step S305, depend on the amplitude of the difference of adjacent twice collection value, described amplitude is larger, and the time interval that starts subsequent step S305 is shorter, otherwise the time interval that starts subsequent step S305 is longer.In view of determining like this time-interval system and easily realizing, do not repeat them here.

S305: utilize described smoke components determine to participate in the reaction amount of oxygen, and calculate the adjacent difference of determining to obtain participating in reacting amount of oxygen behind the smoke components that detects for twice.

S306: judge that whether the difference that participates in the reaction amount of oxygen is greater than the value of setting in advance.

When judged result be greater than the time, execution in step S307; Otherwise execution in step S308.

S307: utilize the current detection result to calculate effective wind rate of each bellows.

When the difference of adjacent twice testing result during greater than the value of setting in advance, then represent the current system unstable working condition, need to utilize the up-to-date smoke components that detects as regulating according to the air quantity that removes to regulate main exhauster, so, in this step, utilize current detection result (being the up-to-date smoke components data of large flue) to go to calculate effective wind rate of each bellows.Execution in step S309 after this step.

S308: according to detecting effective wind rate of determining to obtain to participate in to react each bellows of mean value computation of amount of oxygen behind the smoke components for adjacent twice.

When the difference of adjacent twice testing result is less than or equal to the value of setting in advance, mean that the current system duty is relatively stable.In addition, once detect error to the impact of sintering process for fear of certain, adopt the average of adjacent twice testing result, as the foundation of subsequent calculations large flue target air quantity.Execution in step S309 after this step.

S309: calculate large flue target air quantity.

S310: large flue target air quantity is sent to the main exhauster controller as regulating parameter.

In the embodiment of the present application, step S206 ~ S207 is corresponding one by one among step S309 ~ S310 and the embodiment one, detailed description can with reference in above-described embodiment about the description of step S206 ~ S207, do not repeat them here.

In the other embodiment based on described embodiment two, specifically, between the step S309 and step S310 of embodiment two, also comprise the steps:

S1, the current air quantity of detection large flue;

S3, judge described difference whether more than or equal to the threshold value of setting, if described difference is then carried out S310 more than or equal to the threshold value of setting, otherwise, execution in step S4;

Embodiment three:

The present embodiment is with reference to flow process shown in Figure 4.According to shown in Figure 4, step S401 ~ S406 is equivalent to step S201 ~ S206 among the embodiment one, about the detailed description of step S401 ~ S406 can referring in above-described embodiment one to the description of step S201 ~ S206, do not repeat them here.

S407: the difference of the large flue target air quantity that the calculating twice adjacent calculation obtains.

S408: judge that whether described difference is greater than the value that sets in advance.

When judged result be greater than the time, execution in step S409; Otherwise execution in step S410.

S409: with the current large flue target air quantity that calculates as regulating parameter.

S410: the average of the large flue target air quantity that twice adjacent calculation is obtained is as regulating parameter.

S411: will regulate parameter and send to the main exhauster controller.

The large flue target air quantity that obtains when twice adjacent calculation is during greater than the value of setting in advance, expression current system unstable working condition, at this moment will utilize latest computed to large flue target air quantity remove to regulate the air quantity of main exhauster.

When the large flue target air quantity that obtains when twice adjacent calculation is less than or equal to the value of setting in advance, mean that the current system duty is relatively stable, for avoiding certain once to detect error to the impact of sintering process, the average that adopts twice adjacent calculation to obtain large flue target air quantity is controlled the frequency of main exhauster, and is comparatively constant with the air quantity that keeps main exhauster.

In the other embodiment based on described embodiment three, specifically, after the judgement of the step S408 of embodiment three is finished, before the step S411, also comprise the steps:

S1, the current air quantity of detection large flue;

S3, judge described difference whether more than or equal to the threshold value of setting, if described difference is then carried out S411 more than or equal to the threshold value of setting, otherwise, execution in step S4;

Embodiment four:

The present embodiment provides a kind of sintering machine main air exhauster air quantity control system.

As shown in Figure 5, this system comprises: tachometric survey unit 51, vertical sintering speed computing unit 52, effective wind rate determining unit 53, detection of exhaust gas compositions unit 54, effective wind rate computing unit 55, Wind Coverage Calculation unit 56 and control module 57, wherein,

Tachometric survey unit 51 is used for measuring the machine speed on the pallet.

Tachometric survey unit 51 can obtain the chassis speed of service of setting in the chassis control appliance, as machine speed.But in actual motion, owing to reasons such as wearing and tearing or mechanical breakdowns, may cause the actual motion speed of chassis inconsistent with the setting speed of service, and then can affect the air quantity of regulating main exhauster.So in the present embodiment, installation rate sampling instrument on chassis, the actual motion speed of tachometric survey unit 51 direct-detection chassis is as machine speed, to avoid owing to chassis actual motion speed and the inconsistent adjusting that affects main exhausting amount of the setting speed of service.

Vertical sintering speed computing unit 52 is used for utilizing known thickness of feed layer, known sintering end point and described machine speed to calculate material bed vertical sintering speed.

Effective wind rate determining unit 53 is used for utilizing relation between effective wind rate and the vertical sintering speed to determine the effective wind rate of each bellows.

Utilize the detection of exhaust gas compositions probe that arranges in the large flue of sintering machine, can pop one's head in by detection of exhaust gas compositions in detection of exhaust gas compositions unit 54 like this, detects the smoke components in the large flue.In the embodiment of the present application, the smoke components that detects of detection of exhaust gas compositions unit 54 refers to the O in the unit volume gas ₂, CO, CO ₂, N ₂, NO, NO ₂Content.

Effective wind rate computing unit 55 is used for utilizing the testing result of described detection of exhaust gas compositions unit 54 to calculate effective wind rate of current each bellows of sintering machine.

Effective wind rate computing unit 55 calculates effective wind rate of all bellows according to formula (4) and (5) among the embodiment one.

Wind Coverage Calculation unit 56 is used for calculating large flue target air quantity.In the present embodiment, large flue target air quantity equals the air quantity sum of each bellows, and the air quantity of each bellows equals effective wind rate divided by effective wind rate.

Control module 57, the large flue target air quantity that is used for calculating sends to the main exhauster controller as regulating parameter, the frequency that described main exhauster controller is regulated main exhauster changes to target frequency, and described target frequency equals the corresponding frequency of large flue target air quantity.

In addition, when large flue exists when leaking out, the air quantity of main exhauster equals large flue target air quantity and the pipeline air quantity sum of leaking out, and therefore, the air quantity sum of large flue target air quantity and pipeline need to being leaked out sends to the main exhauster controller as the adjusting parameter.Described pipeline leaks out and also changes not quite when negative pressure variation is little, and in actual applications, the pipeline air quantity that leaks out can obtain in advance by experiment, and is then pre-stored in system.

Compared with prior art, this system that the embodiment of the present application provides, when external factor forces inventory to change so that after the change of sintering pallet speed, can be automatically, the air quantity of main exhauster be adjusted to current machine speed be complementary exactly, realization reduces the energy consumption of main exhauster in the sintering process under the prerequisite that guarantees sintering quality.

Embodiment five:

In the present embodiment, detection of exhaust gas compositions unit 54 is when detecting, according to the smoke components in the time interval detection large flue of setting.

As shown in Figure 6, this sintering machine main air exhauster air quantity control system that the present embodiment provides is compared with embodiment illustrated in fig. 5, also comprises:

Amount of oxygen determining unit 61 is connected with detection of exhaust gas compositions unit 54, is used for utilizing described smoke components to determine to participate in the reaction amount of oxygen;

Amount of oxygen difference computational unit 62 is used for calculating the adjacent difference of determining to obtain participating in reacting amount of oxygen behind the smoke components that detects for twice;

Amount of oxygen difference judging unit 63 is connected with described effective wind rate computing unit 55, is used for judging that described amount of oxygen determining unit 61 determines to obtain whether participating in reacting the difference of amount of oxygen greater than the value of setting in advance.

When judged result be greater than the time, effectively wind rate computing unit 55 utilizes the current detection result to calculate effective wind rate of each bellows; When being less than or equal to, effectively wind rate computing unit 55 is according to effective wind rate of each bellows of mean value computation of adjacent twice testing result.

In other embodiment based on embodiment four and embodiment five, between Wind Coverage Calculation unit 56 and the control module 57, also comprise following unit (not drawing among Fig. 5, Fig. 6):

The air measuring unit is for detection of the current air quantity of large flue;

The difference of judging unit, the calculating current air quantity of large flue and large flue target air quantity, and, judge that whether described difference is more than or equal to the threshold value of setting, if described difference is more than or equal to the threshold value of setting, then indicate control module 57, the large flue target air quantity that calculates is sent to the main exhauster controller as regulating parameter; Otherwise, indication control module 57, described large flue target air quantity is sent to the bellows valve positioner as regulating parameter, and described bellows valve positioner is regulated the aperture of bellows valve, makes the large flue effective wind rate equal the effective wind rate of described large flue target air quantity before valve regulated.

Control module 57 in the present embodiment is compared with the control module 57 among the embodiment five with embodiment four, changes.

Embodiment six:

As shown in Figure 7, the present embodiment is compared with embodiment illustrated in fig. 6, also comprises:

Air quantity difference computational unit 71 be used for to be calculated the difference of the large flue target air quantity that twice adjacent calculation obtains;

Air quantity difference judging unit 72 is connected with described control module 57, is used for judging that whether the difference of the large flue target air quantity that air quantity difference computational unit 71 calculates is greater than the value of setting in advance.

Regulate parameter determining unit 73, be used for when judged result be greater than the time, with the current large flue target air quantity that calculates as regulating parameter, and when judged result when being less than or equal to, the average of the large flue target air quantity that twice adjacent calculation is obtained is as the adjusting parameter.

Last control module 57 sends to the main exhauster controller with determined adjusting parameter.

In other embodiment based on embodiment six, between air quantity difference judging unit 72 and the control module 57, also comprise following unit (not drawing among Fig. 7):

Control module 57 in the present embodiment is compared with the control module 57 among the embodiment six, changes.

The above only is the application's preferred embodiment, makes those skilled in the art can understand or realize the application.Multiple modification to these embodiment will be apparent to one skilled in the art, and General Principle as defined herein can in the situation of the spirit or scope that do not break away from the application, realize in other embodiments.Therefore, the application will can not be restricted to these embodiment shown in this article, but will meet the widest scope consistent with principle disclosed herein and features of novelty.

Claims

1. a sintering machine main air exhauster air quantity control method is characterized in that, comprising:

Detect the smoke components of large flue;

2. method according to claim 1 is characterized in that:

Obtain the machine speed of setting in the sintering pallet control appliance according to the time interval that sets in advance; Perhaps, detect the inventory of sintering machine according to the time interval that sets in advance, calculate the machine speed corresponding with described inventory according to known thickness of feed layer.

3. method according to claim 2 is characterized in that:

Periodically detect the smoke components in the unit volume flue gas in the large flue.

4. method according to claim 3 is characterized in that, also comprises:

Utilize described smoke components to determine to participate in the flue gas reaction amount of oxygen;

Calculate the adjacent difference of determining to obtain participating in reacting amount of oxygen behind the smoke components that detects for twice;

Judge that whether the difference of described participation reaction amount of oxygen is greater than the value of setting in advance;

If greater than, determine that the participation reaction amount of oxygen that obtains calculates effective wind rate of each bellows after utilizing the current detection smoke components, otherwise, according to detecting effective wind rate of determining to obtain to participate in to react each bellows of mean value computation of amount of oxygen behind the smoke components for adjacent twice.

5. method according to claim 4 is characterized in that, also comprises:

The difference of the large flue target air quantity that the calculating twice adjacent calculation obtains;

Judge that whether the difference of described large flue target air quantity is greater than the value of setting in advance;

If greater than, the current large flue target air quantity that calculates is defined as regulating parameter, otherwise the average of the large flue target air quantity that twice adjacent calculation is obtained is defined as regulating parameter;

Described adjusting parameter is sent to described main exhauster controller.

6. according to claim 1,2,3,4 or 5 described methods, characterized by further comprising:

Detect the current air quantity of large flue;

7. a sintering machine main air exhauster air quantity control system is characterized in that, comprising:

The tachometric survey unit is for the machine speed of measuring pallet;

8. system according to claim 7 is characterized in that, described detection of exhaust gas compositions unit detects the smoke components in the unit volume flue gas in the large flue according to the time interval that sets in advance;

This system further comprises:

The amount of oxygen determining unit is used for utilizing described smoke components to determine to participate in the reaction amount of oxygen;

Difference computational unit is used for calculating the adjacent difference of determining to obtain participating in reacting amount of oxygen behind the smoke components that detects for twice;

The difference judging unit is used for judging that whether the difference of described participation reaction amount of oxygen is greater than the value of setting in advance;

When judged result be greater than the time, described effective wind rate computing unit utilizes determines that the participation reaction amount of oxygen that obtains calculates effective wind rate of each bellows behind the current detection smoke components; Otherwise, according to detecting effective wind rate of determining to obtain to participate in to react each bellows of mean value computation of amount of oxygen behind the smoke components for adjacent twice.

9. system according to claim 8 is characterized in that, described detection of exhaust gas compositions unit detects the smoke components in the unit volume flue gas in the large flue according to the time interval that sets in advance;

This system further comprises:

The air quantity difference computational unit be used for to be calculated the difference of the large flue target air quantity that twice adjacent calculation obtains;

Air quantity difference judging unit is used for judging that whether the difference of the large flue target air quantity that the air quantity difference computational unit calculates is greater than the value of setting in advance;

Regulate the parameter determining unit, be used for when judged result be greater than the time, as the adjusting parameter, otherwise the average of the large flue target air quantity that twice adjacent calculation is obtained is as the adjusting parameter with the current large flue target air quantity that calculates;

The described adjusting parameter that described control module will be determined sends to described main exhauster controller.

10. system according to claim 9 is characterized in that, this system further comprises:

The air measuring unit is for detection of the current air quantity of large flue

Judging unit is for the difference of calculating the current air quantity of large flue and large flue target air quantity;

If described difference is more than or equal to the threshold value of setting, then described control module sends to the main exhauster controller with described large flue target air quantity as regulating parameter, otherwise, described control module sends to the bellows valve positioner with described large flue target air quantity as regulating parameter, described bellows valve positioner is regulated the aperture of bellows valve, makes the large flue effective wind rate equal the effective wind rate of described large flue target air quantity before valve regulated.