CN113621793B - Sintered solid fuel size fraction control method - Google Patents

Abstract

The invention discloses a method and a system for controlling the particle size fraction of a sintered solid fuel, which utilize an on-site laser process gas analysis system to carry out on-line detection on CO and CO2 in the components of waste gas in the sintering process, thereby obtaining a combustion ratio (CO/CO + CO 2) to measure the utilization degree of the chemical energy of the solid fuel carbon in the sintering process. And meanwhile, the particle size fraction of the sintered solid fuel is detected on line, a multiple regression relationship is carried out on the combustion ratio of the solid fuel, the average particle size fraction of the sintered solid fuel, the sintering negative pressure and the historical data of the proportion of the sintered solid fuel by using a partial least square method, and the particle size fraction of the sintered solid fuel is reasonably controlled and adjusted by using the process parameters and the combustion ratio [ CO/CO + CO2 ] of the better sintered solid fuel. The utilization degree of the chemical energy of the carbon of the solid fuel is always in a better control interval, so that the smooth operation of the sintering process is supported, and the consumption level of the solid fuel is effectively reduced under the condition of meeting the requirement of the sintering process.

Description

Sintered solid fuel size control method

Technical Field

The invention relates to the technical field of sintering, in particular to a sintered solid fuel size fraction control system and a sintered solid fuel size fraction control method.

Background

The sintered ore is the main iron-containing raw material in blast furnace production, and is prepared through mixing return ore of blast furnace, sintered return ore, mixed ore, fuel and flux in certain proportion, adding proper amount of water, mixing and pelletizing, and sintering in sintering machine to form lump material. Factors influencing the quality of the sintered ore are many, and the proper proportion of different iron ore powder and the addition amount of fuel and flux need to be determined before sintering so as to meet the requirement of the blast furnace burden structure.

The particle size of the fuel has a great influence on the sintering process, and from the kinetic and thermodynamic analysis of carbon combustion in the sintering process, it can be known that:

1) When the particle size of the solid fuel is too large: the combustion speed becomes slow, the combustion zone widens, the air permeability of the sinter bed becomes poor, and the vertical sintering speed and the utilization coefficient of the sintering machine decrease. In the sintering and distributing process, large-particle coke powder or coal powder is concentrated at the lower part of a sintering material layer due to segregation, and the heat of the lower layer is obviously higher than that of the upper layer due to the automatic heat storage function, so that the over-melting phenomenon occurs, and the air permeability of the sintering material layer is reduced;

2) When the solid fuel particle size is too small: the carbon combustion speed is too fast, the liquid phase reaction is incomplete, the strength of sintering ore and the sintering yield are reduced, and the utilization coefficient of the sintering machine is reduced. Thus, in the actual sintering process, a suitable particle size range for the solid fuel should be determined.

Due to market resources and purchasing, the types of raw materials for sintering inevitably change frequently, and the particle size of the raw materials fluctuates; the traditional sintering fuel is controlled to a certain extent stably and non-fluctuated, namely the particle size of the fuel is generally not adjusted along with the fluctuation of the particle size of the raw material, or the particle size of the fuel is passively adjusted only according to the change of the sintered mineral mass, so that the problem that the particle size of the sintering fuel is not matched with the particle size of the sintering raw material exists.

Through patent search, some related technical schemes are disclosed, for example:

for example, the Chinese invention patent CN106939373B discloses a method for controlling the particle size of sintering fuel, belonging to the technical field of sintering. The control method comprises the following steps: controlling the average grain diameter D of the sintering raw material to be 2.5-6.5mm; and adjusting the average grain size of the sintering fuel according to the average grain size of the sintering raw material, controlling the average grain size D of the sintering fuel to be 1.5-3mm, and simultaneously controlling the ratio range of the average grain size of the sintering fuel to the average grain size of the sintering raw material to be not less than 0.3 and not more than 0.6. The invention adjusts the particle size of the sintering fuel according to the particle size of the sintering raw material, so that the particle size of the sintering fuel is reasonably matched with the particle size of the sintering raw material, the combustion speed of the fuel is moderate, the air permeability of a sinter bed is good, the liquid phase reaction is complete, and the technical effects of improving the quality of the sinter and reducing the fuel consumption are achieved.

Chinese patent application, publication No.: CN110142095A, which discloses an intelligent control method and device for crushing a sintering fuel, wherein the proportion of each grain size component in the sintering fuel is determined according to the grain size component of the sintering fuel corresponding to the current moment; the average value of the grain size composition proportion of the sintering fuel of the two times is calculated, and the average grain size composition proportion of the sintering fuel is used as a judgment basis, so that the accuracy of data can be improved, and errors are avoided. And judging whether the average particle size composition proportion meets a particle size constraint condition, and if not, adjusting the gap between the upper two rollers and the gap between the lower two rollers of the fuel crusher according to an intelligent control rule. The intelligent control method and the intelligent control device can accurately adjust the gap between the upper roller and the gap between the lower roller of the fuel crusher, so that the particle size composition proportion of the crushed sintering fuel meets the particle size constraint condition. When the sintering fuel is applied to the sintering process, the phenomena of insufficient fuel at the upper part and excessive fuel at the lower part of a sintering material layer can be avoided, and the sintering quality of products can be improved.

The Chinese invention patent CN106521145A discloses a method and a device for improving the combustion efficiency of sintering fuel, wherein the method comprises the following steps: preparing materials for sintering in a material mixing chamber; mixing the materials for the first time; carrying out secondary mixing on the materials, wherein the water distribution amount of the materials after secondary mixing is 6.0-8.0% by mass; distributing the secondarily mixed materials on a sintering machine to form a sintering material surface; controlling the ignition temperature of the sintering machine to be 1000-1200 ℃; wherein, the slaked lime in the material is powdery; when preparing the materials, 40-80% of the total mass of the fuel is added into the materials in the batching chamber, and 20-60% of the total mass of the fuel is added into the materials within the last 1min of the secondary mixing. Therefore, lime is processed into powdery slaked lime by using the slaker, and the slaked lime cannot expand when meeting water in the granulation process of secondary mixing, so that the adhesion effect of fuel added in the secondary mixing is prevented from being damaged, and further, the fuel is prevented from being separated from other particles and moved down and taken away by air draft; finally, the use effect of the fuel is ensured, and the combustion rate is improved.

The above publications have certain disadvantages, and only satisfy the basic requirements of the sintering process, and fail to fully consider the efficient control of the chemical energy of the sintered solid fuel, so the practical production effect of supporting the stable and smooth operation of the sintering process and reducing the consumption of the sintered solid fuel is limited.

Disclosure of Invention

The invention aims to solve the technical problem of realizing a sintering solid fuel particle size control system and a control method, so that the utilization degree of the chemical energy of the carbon of the solid fuel is always in a better control interval, thereby supporting the smooth operation of the sintering process and being beneficial to effectively reducing the consumption level of the solid fuel under the condition of meeting the requirements of the sintering process.

In order to achieve the purpose, the invention adopts the technical scheme that: a sintered solid fuel fraction control method comprising the steps of:

step 1, obtaining waste gas in a sintering machine air box branch pipe, and obtaining CO and CO in the waste gas ₂ The concentration value of (a);

step 2 according to CO and CO ₂ The solid fuel combustion ratio is calculated according to the concentration value;

step 3, obtaining the composition of each grade of the solid fuel burdening and feeding position of the sintering machine, and obtaining the average grade of the sintered solid fuel;

step 4, analyzing historical data of the combustion ratio of the solid fuel, the average particle size fraction of the sintered solid fuel, the sintering negative pressure and the proportion of the sintered solid fuel by using a partial least square method to obtain a multiple regression formula;

and 5, forming a historical basic sample data set by taking the average numerical value of each parameter per 30-minute period as 1 sample data. Considering the time sequence corresponding relation of each datum, and then judging the target value of the average particle size control adjustment of the sintered solid fuel according to the sintering process parameters and the combustion ratio of the better sintered solid fuel;

step 6, adjusting the combustion ratio of the solid fuel to enable the average particle size fraction of the sintered solid fuel to approach a target value, namely acquiring the target value of the average particle size fraction of the sintered solid fuel by taking the combustion ratio of the sintered solid fuel as a target according to the condition of the numerical distribution range of the combustion ratio of the sintered solid fuel and carrying out control adjustment of different grades;

and 7, adjusting the average particle size of the sintered solid fuel to enable the average particle size of the sintered solid fuel to approach a target value, namely adjusting the crushing technological parameters of the sintered solid fuel according to the target value of the average particle size of the better sintered solid fuel, so that the linear particle size detection value of the sintered solid fuel approaches a control target value, and realizing the control adjustment of the particle size of the sintered solid fuel.

In the step 1, an in-place laser process gas analysis system is adopted to analyze the waste gas of a specified bellows branch pipe to which the sintering machine belongs, and in the step 3, an online size fraction detection device is arranged at a sintering solid fuel batching and feeding position to analyze the average size fraction of the sintering solid fuel.

In the step 1, a plurality of points are arranged on the sampling points of the waste gas, and CO at each sampling point ₂ The concentration value of (A) is processed into an average value, and then the average value is processed into a value of [ CO/(CO + CO ] ₂ ) Calculating the burning ratio R of the sintered solid fuel _b 。

When any one of the following conditions is met, the currently calculated burning ratio value of the sintered solid fuel is removed; 1) When the sintering is stopped or the end point position of the sintering process is abnormally advanced; 2) The rising point position of the sintering end point is advanced to the position before the exhaust gas sampling point.

The time difference between the start of the sintering batch feed and the first exhaust gas sampling point is calculated as the interval between the execution of the cycles of step 1 to step 7.

In the step 4, the combustion ratio R of the solid fuel in the interval time is obtained _b Average size fraction M of sintered solid fuel _R Sintering negative pressure P and sintering solid fuel ratio P _R And calculating a group of average values, and forming a historical basic sample data set by using each group of average values as one sample data.

In the step 4, a multiple regression analysis formula:

R _b ＝α*P _R +β*P+γ*M _R +C

wherein R is _b Is the combustion ratio of solid fuel, P _R For the proportion of the sintered solid fuel, P is the negative pressure in the sintering process, M _R The average particle size fraction of the sintered solid fuel is alpha, beta and gamma which are regression coefficients, and C is a constant term;

r in historical base sample data set _b And M _R Calculating the mean value

And corresponding data interval range value | R _b I and I M _R |。

In the step 6, the sintering solid fuel proportion PR is adjusted in real time according to the actual composition of the sintering ore FeO and the corresponding sintering ore FeO control reference value, so that the average particle size of the sintering solid fuel approaches the target value.

The steps areIn step 7, the current Rb is compared with

And (3) comparison:

if it is

If yes, the average grade of the sintered solid fuel maintains the current grade value, and the crushing technological parameters of the solid fuel are not adjusted;

if it is

If yes, obtaining the current sintering negative pressure P and the sintering solid fuel ratio P _R Data, and the current combustion ratio R _b 70% of the values correspond to the values that are carried over:

M _R ′＝(70％*R _b -α*P _R -C- β P)/γ, obtaining M _R ' value;

the parameters of the sintering solid fuel crushing process are correspondingly adjusted, so that the indication value of an on-line particle size detection device at the proportioning and feeding position of the sintering solid fuel approaches to M _R ' value.

The invention utilizes an in-situ laser process gas analysis system to analyze CO and CO in the waste gas components in the sintering process ₂ Performing on-line detection to obtain combustion ratio [ CO/CO + CO ] ₂ The degree of utilization of the chemical energy of the solid fuel carbon during sintering is measured. Meanwhile, the particle size fraction of the sintered solid fuel is detected on line, the combustion ratio of the solid fuel, the average particle size fraction of the sintered solid fuel, the sintering negative pressure and the historical data of the proportion of the sintered solid fuel are obtained by a partial least square method to carry out multiple regression, and the process parameters and the combustion ratio of the sintered solid fuel [ CO/CO + CO ] which is better are used ₂ The particle size of the sintered solid fuel is reasonably controlled and adjusted. The utilization degree of the chemical energy of the carbon of the solid fuel is always in a better control interval, so that the smooth operation of the sintering process is supported, and the consumption level of the solid fuel is effectively reduced under the condition of meeting the requirements of the sintering process.

Drawings

The following is a brief description of the contents of each figure in the description of the present invention:

FIG. 1 shows CO and CO in the exhaust gas from the sintering process ₂ The trend of change of (c);

FIG. 2 is a graph of sintering waste gas combustion ratio versus solid fuel fraction;

FIG. 3 is a graph showing the relationship between the burning ratio of sintering exhaust gas and the fraction of solid fuel;

FIG. 4 is a graph showing the relationship between the combustion ratio of the sintering waste gas and the sintering negative pressure.

Detailed Description

The following description of the embodiments with reference to the drawings is intended to illustrate the present invention in further detail, such as the shapes and structures of the related components, the mutual positions and connections between the components, the functions and working principles of the components, the manufacturing process and the operation method, etc., so as to help those skilled in the art understand the present invention more completely, accurately and deeply.

As shown in FIG. 1, the present invention adopts an in-situ laser process gas analysis system to analyze CO and CO in the exhaust gas of a designated air box branch pipe to which a sintering machine belongs ₂ And carrying out online data detection. The measurement probe of the in-situ laser process gas analysis system consists of a transmitting unit and a receiving unit and has multiple functions of spectral analysis, man-machine interaction, positive pressure control, data communication and the like. The transmitting unit is composed of devices such as a human-computer interface, a laser driving module, a central processing module, a semiconductor laser, a precise optical element and the like, mainly realizes functions such as semiconductor laser transmission, spectrum data processing, human-computer interaction and the like, and the receiving unit is composed of a photoelectric sensor, a signal processing module, a power supply module, the precise optical element and the like. The main function of the receiving unit is to receive the sensing signal and transmit the spectral absorption signal to the transmitting unit for processing. The positive pressure control module has special explosion-proof design for a laser process gas analysis system, the transmitting and receiving unit of the positive pressure control module adopts positive pressure explosion-proof design, and protective gas (nitrogen) is introduced into the box body to achieve the positive pressure explosion-proof effect. The transmitting unit and the receiving unit pass through instrument flanges and welding flangesAnd the locking hoop is connected with the detected process gas pipeline. The power supply is turned on, the root valve is opened, the laser with specific frequency emitted by the semiconductor laser passes through the gas channel through the emitting unit, the sensor in the receiving unit receives the attenuated laser beam and transmits the measuring signal to the central analysis module, the central analysis module analyzes and processes the measuring signal to obtain the measured gas concentration, and the gas concentration information is displayed through the liquid crystal display screen and is output through the standard interface. In order to prevent dust and other pollutants in the tested environment from accumulating on the window, gas such as industrial nitrogen is used for continuously blowing through a blowing gas inlet so as to form a section of gas curtain protection between the optical window and the industrial gas.

The on-line laser process gas analysis system can be directly installed on a process gas pipeline or utilizes a sampling tube to lead the detected gas to a built-in process gas detection pipeline of the on-line laser process gas analysis system for on-line detection of gas components by an air pump. CO and CO in sintering waste gas in normal sintering production process ₂ The concentration change law of (A) is shown in figure 1, namely sintering head and tail bellows waste gases CO and CO ₂ Low concentration, sintering middle bellows waste gas CO and CO ₂ The concentration is high. While the burning ratio [ CO/(CO + CO) ] is usually used in the sintering process ₂ ) The utilization degree of chemical energy of the solid fuel carbon in the sintering process is measured, if the combustion ratio is large, the carbon utilization is poor, and the atmosphere reducibility is stronger, otherwise, the carbon utilization is good, and the oxidizing atmosphere is strong.

Sampling the analyzed CO and CO from multiple sampling points ₂ The concentration value of (B) is averaged in terms of [ CO/(CO + CO ] ₂ ) Calculating a combustion ratio R of the sintered solid fuel _b ：

R _b ＝CO/(CO+CO ₂ ) Formula 1

When the sintering machine stops or the end point position of the sintering process is abnormally advanced, and the rising point position of the sintering end point is advanced to the position of the No. 15 sintering air box, the calculated sintering solid fuel combustion ratio value is rejected through the setting of a judging program;

an online particle size detection device is arranged at a proportioning and feeding position of the sintered solid fuel, so that the composition of each particle size of the sintered solid fuel can be obtained in real time, and the average particle size MR of the sintered solid fuel is obtained;

according to the principle of the sintering process, under the condition that the thickness of a sintering layer and the proportion of sintering return ores are stable, the influence factors of the combustion ratio of sintering waste gas comprise the fraction of sintered solid fuel particles (shown in figure 2), the proportion of solid fuel (shown in figure 3) and the negative pressure in the sintering process (shown in figure 4). Combustion ratio R of the solid fuel _b Average size fraction M of sintered solid fuel _R Sintering negative pressure P and sintering solid fuel ratio P _R The data of (a) take an average value of 30 minutes.

The average value of each parameter in each 30-minute period is 1 sample data, and a historical basic sample data set is formed.

Because the time difference from the start of feeding the sintering ingredients to the position of a sintering 5# sintering bellows branch pipe is about 30min, the real-time detection of the grain size fraction of the sintering solid fuel, the real-time proportioning value and the combustion ratio R of the sintering solid fuel are considered _b And the time sequence corresponding relation of the sintering negative pressure P.

And the proportion PR of the sintered solid fuel is adjusted in real time according to the actual composition of the FeO of the sintered ore and the corresponding control reference value of the FeO of the sintered ore.

The combustion ratio R of the solid fuel is determined by partial least squares _b Average size fraction M of sintered solid fuel _R Sintering negative pressure P and sintering solid fuel ratio P _R The following formula can be obtained by performing multiple regression analysis on the historical data.

R _b ＝α*P _R +β*P+γ*M _R + C formula 2

In the formula: r _b Combustion ratio (%) of solid fuel; p is the negative pressure (KPa) of the sintering process; p is _R The proportion of the sintered solid fuel is (%); m _R Is the average size fraction (mm) of the sintered solid fuel; α, β, γ: are all regression coefficients; c is a constant term.

Average size fraction M for the above-mentioned sintered solid fuel _R And the combustion ratio R of the sintered solid fuel _b The historical data is processed to obtain the corresponding mean value

And corresponding data interval range value | R _b |、|M _R |。

Under the normal crushing process condition, the average size fraction range of the sintered solid fuel corresponding to the sintered solid fuel is about 1.55mm-2.75mm, wherein the size fraction of the solid fuel which is less than or equal to 0.5mm is 18-33%, the size fraction of 0.5mm-1mm is 12-25%, the size fraction of 1mm-2mm is 9-20%, the size fraction of 2mm-3mm is 9-22%, the size fraction of 3mm-5mm is 10-37%, the size fraction of 5mm-8mm is 0-21%, and the size fraction of more than or equal to 8mm is 0-7%.

Derived from the above equation 2

M _R ＝(R _b -α*P _R -C-beta P)/gamma formula 3

The combustion ratio R of the solid fuel of the current 30min period is compared _b And

make a comparison if

When the process is established, the average grade of the sintered solid fuel maintains the current grade value, and the crushing process parameters of the solid fuel are not adjusted.

If the current combustion ratio R of the solid fuel for the 30min period _b And

make a comparison, and

when the sintering process is established, the sintering negative pressure P and the sintering solid fuel ratio P in the current 30min period are matched _R Data, and the current combustion ratio R of solid fuel for the 30min period _b 70% of the value corresponds to the numerical bandBy entering the above formula 3, M can be obtained _R A value of

M _R ′＝(70％*R _b -α*P _R -C-beta P)/gamma formula 6

At this time, the average particle size of the sintered solid fuel is adjusted to M _R The value of the device is that the crushing process parameters of the sintered solid fuel need to be adjusted correspondingly, so that the indication value of an online size fraction detection device at the proportioning and feeding position of the sintered solid fuel approaches to M _R ' value.

The average particle size fraction of the sintered solid fuel is controlled and adjusted by repeating the steps through program calculation, so that the utilization degree of the chemical energy of the carbon of the solid fuel is always in a better control interval, the smooth operation of the sintering process is supported, and the consumption level of the solid fuel is effectively reduced under the condition of meeting the requirements of the sintering process.

The present invention has been described in detail with reference to the accompanying drawings, and it is to be understood that the invention is not limited to the specific embodiments described above, and that various insubstantial modifications of the inventive concepts and solutions, or their direct application to other applications without modification, are intended to be covered by the scope of the invention.

Claims (4)

1. A method for controlling the fraction of sintered solid fuel, comprising the steps of:

step 1, obtaining waste gas in a sintering machine air box branch pipe, and obtaining CO and CO in the waste gas ₂ The concentration value of (a);

analyzing the waste gas of a specified bellows branch pipe of the sintering machine by using an on-position laser process gas analysis system, wherein in the step 3, an online size fraction detection device is arranged at a sintering solid fuel batching and feeding position to analyze the average size fraction of the sintering solid fuel;

step 2, according to CO and CO ₂ The solid fuel combustion ratio is calculated according to the concentration value;

step 3, obtaining the composition of each grade of the solid fuel burdening and feeding position of the sintering machine, and obtaining the average grade of the sintered solid fuel;

step 4, analyzing historical data of the combustion ratio of the solid fuel, the average particle size fraction of the sintered solid fuel, the sintering negative pressure and the proportion of the sintered solid fuel by using a partial least square method to obtain a multiple regression formula;

obtaining the combustion ratio R of the solid fuel in the interval time _b Average size fraction M of sintered solid fuel _R Sintering negative pressure P and sintering solid fuel ratio P _R Calculating a group of average values, and forming a historical basic sample data set by taking each group of average values as sample data;

multiple regression analysis formula:

wherein R is _b Is the combustion ratio of solid fuel, P _R For the proportion of the sintered solid fuel, P is the negative pressure in the sintering process, M _R Alpha, beta and gamma are regression coefficients for the average size fraction of the sintered solid fuel, and C is a constant term;

r in historical base sample data set _b And M _R Calculating the mean value

、

And corresponding data interval range values

And

；

step 5, adjusting the sintering solid fuel proportion PR in real time according to the actual composition of the sintering ore FeO and the corresponding sintering ore FeO control reference value;

step 6, the current Rb is compared with

Comparing;

if it is

If so, maintaining the average particle size of the sintered solid fuel at the current particle size value, and not adjusting the crushing technological parameters of the solid fuel;

if it is

If yes, obtaining the current sintering negative pressure P and the sintering solid fuel ratio P _R Data, and the current combustion ratio R _b 70% of the values correspond to the values that are carried over:

obtaining

A value;

the parameters of the sintering solid fuel crushing process are correspondingly adjusted, so that the indication value of an on-line particle size detection device at the proportioning and feeding position of the sintering solid fuel approaches to

The value is obtained.

2. The sintered solid fuel fraction control method according to claim 1, characterized in that: in the step 1, a plurality of points are arranged on the sampling points of the waste gas, and CO at each sampling point ₂ The concentration value of (A) is processed into an average value, and then the average value is processed into a value of [ CO/(CO + CO ] ₂ ) Calculating the burning ratio R of the sintered solid fuel _b 。

3. The sintered solid fuel fraction control method according to claim 2, characterized in that: when any one of the following conditions is met, the currently calculated burning ratio value of the sintered solid fuel is removed; 1) When the sintering is stopped or the end point position of the sintering process is abnormally advanced; 2) The rising point position of the sintering end point is advanced to the position before the exhaust gas sampling point.

4. The sintered solid fuel fraction control method as claimed in any one of claims 1 to 3, wherein: the time difference between the start of the sintering batch feed and the first exhaust gas sampling point is calculated as the interval between the execution of the cycles of step 1 to step 6.

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