阅读说明：本技术 基于并罐高炉的偏斜检测及校正方法、装置及存储介质 (Deflection detection and correction method and device based on parallel-tank blast furnace and storage medium ) 是由 赵华涛 卢瑜 杜屏 翟明 朱华 朱德贵 于 2021-07-13 设计创作，主要内容包括：本发明公开了一种基于并罐高炉的偏斜检测及校正方法、装置及存储介质,包括获取高炉的工艺参数；根据工艺参数计算两个料罐方向上的矿焦比、风口总面积以及铁口炉温；根据两个料罐方向上矿焦比的关系、风口总面积的关系以及铁口炉温的关系；判断高炉是否存在偏斜。通过实施本发明,获取高炉工作过程中的工艺参数,计算了两个料罐方向上的矿焦比、风口总面积以及铁口炉温,并基于计算的两个料罐方向上矿焦比、风口总面积以及铁口炉温的关系,进行高炉偏斜的判断。相比现有技术中采用探尺探测的料面高度进行判断的方式,该方法不仅考虑了炉顶O/C偏差,同时还考虑了下部送风偏差以及炉温偏差,从而使得高炉偏斜的检测更具有实际指导意义。(The invention discloses a deflection detection and correction method, a deflection detection and correction device and a storage medium based on a parallel-tank blast furnace, which comprises the steps of obtaining process parameters of the blast furnace; calculating ore-coke ratio, total area of a tuyere and furnace temperature of an iron notch in the directions of the two charging buckets according to the technological parameters; according to the relation of ore-coke ratio in the direction of the two charging buckets, the relation of total area of the tuyere and the relation of furnace temperature of the iron notch; and judging whether the blast furnace has deflection. By implementing the method, the process parameters in the working process of the blast furnace are obtained, the ore-coke ratio, the total area of the tuyere and the furnace temperature of the iron notch in the two charging bucket directions are calculated, and the blast furnace deflection is judged based on the calculated relationship among the ore-coke ratio, the total area of the tuyere and the furnace temperature of the iron notch in the two charging bucket directions. Compared with the mode of judging the material level height detected by the stock rod in the prior art, the method not only considers the O/C deviation of the furnace top, but also considers the lower air supply deviation and the furnace temperature deviation, so that the detection of the blast furnace deflection has practical guiding significance.)

1. A deflection detection and correction method based on a parallel-tank blast furnace is characterized by comprising the following steps:

acquiring technological parameters of the blast furnace, wherein the technological parameters comprise material distribution parameters, tuyere parameters and taphole parameters;

calculating ore-coke ratio, total area of the tuyere and furnace temperature of the iron notch in the directions of the two charging buckets according to the process parameters;

according to the relation of ore-coke ratio in the direction of the two charging buckets, the relation of total area of the tuyere and the relation of furnace temperature of the iron notch; and judging whether the blast furnace has deflection or not.

2. The method of claim 1, wherein calculating ore-to-coke ratios in two bucket directions according to the process parameters comprises:

determining the blanking speed of the previous batch of materials, the height change of the stock rod when the current batch of coke and ore are distributed and the distribution time according to the distribution parameters;

determining the thickness change of the current batch of coke according to the blanking speed of the previous batch of materials, the height change of a stock rod when the current batch of coke is distributed and the distribution time;

determining the blanking speed of the current batch of coke according to the height change of the stock rod and the material distribution time when the current batch of coke is distributed;

determining the thickness change of the current batch of ore according to the current batch of coke blanking speed, the height change of a stock rod during the current batch of ore distribution and the distribution time;

and determining the ore-coke ratio in the directions of the two charging buckets according to the thickness change of the current batch of coke and the thickness change of the current batch of coke.

3. The method of claim 1, wherein calculating the total area of the tuyere in the two charging bucket directions according to the process parameters comprises:

and determining the total area of the air inlet in the preset time in the directions of the two charging tanks according to the air inlet parameters.

4. The method for detecting and correcting the deflection of the parallel-connected blast furnace according to claim 1, wherein calculating the furnace temperature of the taphole in two charging bucket directions according to the process parameters comprises:

determining furnace temperature components in each direction according to the azimuth layout of the charging bucket and the iron notch;

and calculating the furnace temperature of the iron notch in the directions of the two charging pots according to the furnace temperature component in each direction.

5. The method for detecting and correcting the deflection based on the parallel-charging blast furnace according to the claim 1, characterized in that the method is based on the relationship of ore-coke ratio in the two charging bucket directions, the relationship of total area of the tuyere and the relationship of furnace temperature of the iron notch; judging whether the blast furnace has deflection or not, comprising the following steps:

judging whether the ore-coke ratio and the furnace temperature of an iron notch in the directions of two charging tanks per day have equidirectional deviation or not exceeding a first preset value;

and when the number of times of equidirectional deviation exceeds a first preset value, determining that the blast furnace has deflection.

6. The method for detecting and correcting the deflection based on the parallel-tank blast furnace according to claim 5, further comprising:

when the blast furnace has deflection, judging whether the deviation between the total areas of the tuyeres is greater than a second preset value,

when the total area of the air inlet is larger than the second preset value, the total area of the air inlet is adjusted to reduce the deviation of the air inlet, and the number of coal guns injected in the direction of the two charging buckets is kept the same.

7. The method for detecting and correcting the deflection based on the parallel-tank blast furnace according to claim 5, further comprising:

when the blast furnace is inclined, judging whether the deviation of the total area of the tuyere is smaller than a third preset value;

and when the charging mode is smaller than the third preset value, changing the combined charging mode of the two charging buckets and the charging materials.

8. A skew detection and correction device based on a parallel tank blast furnace is characterized by comprising:

the parameter acquisition module is used for acquiring technological parameters of the blast furnace, wherein the technological parameters comprise material distribution parameters, tuyere parameters and taphole parameters;

the calculation module is used for calculating ore-coke ratio, total area of the tuyere and furnace temperature of the iron notch in the two charging bucket directions according to the process parameters;

the judging module is used for judging the relationship between the ore-coke ratio in the two charging bucket directions, the relationship between the total area of the tuyere and the relationship between the furnace temperature of the iron notch; and judging whether the blast furnace has deflection or not.

9. A computer-readable storage medium storing computer instructions for causing a computer to perform the method for parallel-stoke furnace-based skew detection and correction according to any one of claims 1 to 7.

10. An electronic device, comprising: a memory and a processor, the memory and the processor are connected with each other in communication, the memory stores computer instructions, the processor executes the computer instructions to execute the method for detecting and correcting the deflection based on the parallel-tank blast furnace according to any one of claims 1 to 7.

Technical Field

The invention relates to the technical field of blast furnace smelting, in particular to a deflection detection and correction method and device based on a parallel tank blast furnace and a storage medium.

Background

The blast furnace top charging system is one of the important components of the whole blast furnace system, and the current mainstream bell-less blast furnace top is mainly divided into a serial tank type furnace top and a parallel tank type furnace top according to the arrangement form of charging tanks, and the bell-less blast furnace top charging system is widely applied to iron and steel enterprises.

Compared with a serial tank type bell-less furnace top system, the tank type bell-less furnace top adopts two parallel weighing material tanks to work alternately, the charging capacity and the material driving line capacity are strong, the furnace top system is low in height, small in weight and convenient to maintain, and the large-scale blast furnace is mainly applied in many cases. However, the parallel-tank bell-less furnace top also has inherent defects, and as the discharge outlets of the two charging tanks deviate from the center line of the blast furnace, the furnace burden distribution in the blast furnace can generate segregation phenomenon, so that the furnace burden distribution in the circumferential direction of the blast furnace is uneven, and the distribution and the production of gas flow are obviously adversely affected. In daily production, how to reduce the influence of segregation of the material in the tank by adjusting the operating system is very important.

For a bell-less twin-tank blast furnace, in operation, it is common to determine whether there is a material bias based on two symmetrically arranged stock rod readings, but the stock rod only detects the level of the material. The height of the charge level cannot reflect the working state of the blast furnace, and whether the blast furnace is inclined or not cannot be accurately detected.

Disclosure of Invention

In view of this, embodiments of the present invention provide a method, an apparatus, and a storage medium for detecting and correcting a deflection of a parallel-tank blast furnace, so as to solve a technical problem in the prior art that it is not possible to accurately detect whether a blast furnace has a deflection by detecting a level height.

The technical scheme provided by the invention is as follows:

the first aspect of the embodiment of the invention provides a deflection detection and correction method based on a parallel-tank blast furnace, which comprises the following steps: acquiring technological parameters of the blast furnace, wherein the technological parameters comprise material distribution parameters, tuyere parameters and taphole parameters; calculating ore-coke ratio, total area of the tuyere and furnace temperature of the iron notch in the directions of the two charging buckets according to the process parameters; according to the relation of ore-coke ratio in the direction of the two charging buckets, the relation of total area of the tuyere and the relation of furnace temperature of the iron notch; and judging whether the blast furnace has deflection or not.

Optionally, calculating ore-coke ratio in two bucket directions according to the process parameters includes: determining the blanking speed of the previous batch of materials, the height change of the stock rod when the current batch of coke and ore are distributed and the distribution time according to the distribution parameters; determining the thickness change of the current batch of coke according to the blanking speed of the previous batch of materials, the height change of a stock rod when the current batch of coke is distributed and the distribution time; determining the blanking speed of the current batch of coke according to the height change of the stock rod and the material distribution time when the current batch of coke is distributed; determining the thickness change of the current batch of ore according to the current batch of coke blanking speed, the height change of a stock rod during the current batch of ore distribution and the distribution time; and determining the ore-coke ratio in the directions of the two charging buckets according to the thickness change of the current batch of coke and the thickness change of the current batch of coke.

Optionally, calculating the total area of the tuyere in the two charging bucket directions according to the process parameters includes: and determining the total area of the air inlet in the preset time in the directions of the two charging tanks according to the air inlet parameters.

Optionally, calculating the furnace temperature of the iron notch in the two charging bucket directions according to the process parameters includes: determining furnace temperature components in each direction according to the azimuth layout of the charging bucket and the iron notch; and calculating the furnace temperature of the iron notch in the directions of the two charging pots according to the furnace temperature component in each direction.

Optionally, according to the relation of ore-coke ratio in the direction of the two charging buckets, the relation of total area of the tuyere and the relation of furnace temperature of the iron notch; judging whether the blast furnace has deflection or not, comprising the following steps: judging whether the ore-coke ratio and the furnace temperature of an iron notch in the directions of two charging tanks per day have equidirectional deviation or not exceeding a first preset value; and when the number of times of equidirectional deviation exceeds a first preset value, determining that the blast furnace has deflection.

Optionally, the method for detecting and correcting the deflection based on the parallel-tank blast furnace further comprises: and when the blast furnace has deflection, judging whether the deviation between the total areas of the air ports is greater than a second preset value, and when the deviation is greater than the second preset value, adjusting the total areas of the air ports to reduce the deviation and keeping the same number of coal guns injected in the direction of the two charging buckets.

Optionally, the method for detecting and correcting the deflection based on the parallel-tank blast furnace further comprises: when the blast furnace is inclined, judging whether the deviation of the total area of the tuyere is smaller than a third preset value; and when the charging mode is smaller than the third preset value, changing the combined charging mode of the two charging buckets and the charging materials.

The second aspect of the embodiments of the present invention provides a skew detection and correction device based on a parallel-tank blast furnace, including: the parameter acquisition module is used for acquiring technological parameters of the blast furnace, wherein the technological parameters comprise material distribution parameters, tuyere parameters and taphole parameters; the calculation module is used for calculating ore-coke ratio, total area of the tuyere and furnace temperature of the iron notch in the two charging bucket directions according to the process parameters; the judging module is used for judging the relationship between the ore-coke ratio in the two charging bucket directions, the relationship between the total area of the tuyere and the relationship between the furnace temperature of the iron notch; and judging whether the blast furnace has deflection or not.

A third aspect of the embodiments of the present invention provides a computer-readable storage medium, which stores computer instructions for causing a computer to execute the method for detecting and correcting a deflection based on a parallel-connected blast furnace according to any one of the first aspect and the first aspect of the embodiments of the present invention.

A fourth aspect of an embodiment of the present invention provides an electronic device, including: the system comprises a memory and a processor, wherein the memory and the processor are connected with each other in a communication mode, the memory stores computer instructions, and the processor executes the computer instructions so as to execute the deflection detection and correction method based on the parallel-connected blast furnace according to the first aspect and any one of the first aspect of the embodiments of the invention.

The technical scheme provided by the invention has the following effects:

according to the deflection detection and correction method, device and storage medium based on the parallel-tank blast furnace, provided by the embodiment of the invention, the ore-coke ratio, the total area of the tuyere and the furnace temperature of the iron notch in the two charging tank directions are calculated by obtaining the process parameters in the working process of the blast furnace, and the deflection of the blast furnace is judged based on the calculated relationship among the ore-coke ratio, the total area of the tuyere and the furnace temperature of the iron notch in the two charging tank directions. Compared with the mode of judging the material level height detected by the stock rod in the prior art, the method not only considers the deviation of the ore-coke ratio at the furnace top, but also considers the deviation of the air supply at the lower part and the deviation of the furnace temperature, so that the detection of the blast furnace deflection has practical guiding significance.

The deflection detection and correction method, the deflection detection and correction device and the storage medium based on the parallel-tank blast furnace provided by the embodiment of the invention not only realize the detection of the deflection of the blast furnace by comparing the ore-coke ratio and the furnace temperature in the two charging bucket directions. Meanwhile, when the deflection is determined, the deflection of the blast furnace is corrected by judging the total area of the tuyere. Therefore, the method can provide a certain guiding direction for the blast furnace operator to correct the skew.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a flow chart of a method for combined vessel blast furnace based skew detection and correction according to an embodiment of the present invention;

FIG. 2 is a block diagram of a parallel tank blast furnace according to an embodiment of the present invention;

FIG. 3 is a timing diagram illustrating a material distribution and blanking process according to an embodiment of the present invention;

FIG. 4 is a schematic illustration of a layer thickness distribution according to an embodiment of the invention;

FIG. 5 is a schematic illustration of the distribution and feed of coke and ore in accordance with an embodiment of the present invention;

FIG. 6 is a top view of a tuyere and a bucket arrangement according to an embodiment of the present invention;

FIG. 7 is a top view of a taphole area and bucket arrangement according to an embodiment of the invention;

FIG. 8 is a block diagram of a tilt detection and correction apparatus for a parallel tank blast furnace according to an embodiment of the present invention;

FIG. 9 is a schematic structural diagram of a computer-readable storage medium provided in accordance with an embodiment of the present invention;

fig. 10 is a schematic structural diagram of an electronic device provided in an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The embodiment of the invention provides a deflection detection and correction method based on a parallel-tank blast furnace, as shown in figure 1, the method comprises the following steps:

step S101: acquiring technological parameters of the blast furnace, wherein the technological parameters comprise material distribution parameters, tuyere parameters and taphole parameters; specifically, in order to detect the blast furnace inclination, the operation state of the entire blast furnace is first clarified. As shown in fig. 2, a schematic view of the structure of the blast furnace and the corresponding process parameter acquisition is given. The blast furnace comprises a furnace top feeding belt 1, a first charging bucket 2, a third charging bucket 3, a first material flow valve 4, a second material flow valve 5, a mechanical stock rod 6, a furnace top PLC7, a server 8 and a client 9. The furnace top PLC7 is respectively connected with the furnace top feeding belt 1, the first charging bucket 2, the third charging bucket 3, the first material flow valve 4, the second material flow valve 5 and the mechanical stock rod 6 to control the corresponding structures. For example, the batch number of the top charging belt 1 is controlled; controlling the material name 1 of a first material tank 2; controlling the material name 2 of a third material tank 3; controlling the opening and closing states of the first material flow valve 4, such as opening to be 1 and closing to be 0; controlling the opening and closing states of the second material flow valve 5, wherein the opening state is 1, and the closing state is 0; and controlling the lifting and lowering of the mechanical stock rod 6. The server 8 collects control data of the furnace top PLC7 and performs logic processing. The client 9 connects to the server 8 and presents the corresponding processing result to the client.

Specifically, during the operation of the blast furnace, the material distribution and the blanking are realized by controlling the opening and the closing of the material flow valve. Therefore, the control signals in the working process of the blast furnace can be related according to the time sequence of material distribution and material discharge shown in figure 3.

Firstly, associating a material batch number and a material name with the opening action of a material flow valve: when the material flow valve 1 is changed from 0 to 1, the material batch number is 1, and the material name 1 is 1, the material flow valve 1 is opened, and the material is distributed by the material name 1 of the material batch number; the material flow valve 2 is changed from 0 to 1, the material batch number is 1, and the material name 2 is 1, then the material flow valve 2 is opened, and the material distribution of the material batch number with the material name 2 is started.

Then, establishing a Cartesian product by utilizing an online database, and associating the batch number and the name of the material with the mechanical stock rod lifting action of the blast furnace: changing the scale from 0 to 1, setting the material name 1 to 0, setting the material name 2 to be not empty and not equal to 0, finishing material distribution with the material name 2, setting the scale and preparing for blanking; the tape is changed from 0 to 1, the material name 1 is 0 and the material name 2 is 0, or the tape is changed from 0 to 1, the material name 1 is not empty and not equal to 0, the material name 2 is not empty and not equal to 0, and the time interval is not more than 10 minutes according to the tape lifting and the tape placing, namely T_{Lifting ruler-putting ruler}If the time is less than 10min, finishing the blanking with the material name 2, lifting the ruler, and preparing for distributing. And judging the scale putting and lifting of the material name 1 in the same way. Therefore, the batch number, the material name and the stock rod lifting signal point are combined.

And finally, establishing a Cartesian product by utilizing an online database, and associating the rule lifting action with the opening of the material flow valve: the time difference between the opening of the material flow valve and the lifting ruler is within 30s, and the material flow valve and the lifting ruler all have the same material name. The material flow valve 1 is opened from 0 to 1, andthe lifting rule is changed from 0 to 1, and T_{Material flow valve 1 opening-lifting ruler}And (3) establishing Cartesian product through a database, associating the stock rod lifting rule with the opening action of the material flow valve to obtain a complete event and a complete variable, indicating that the material is completely discharged under the material name 1 of the material batch number, lifting the rule, preparing for material distribution, similarly obtaining the material is completely discharged under the material name 2 of the material batch number, lifting the rule, and preparing for material distribution.

Specifically, in the process of combining the material flow valve and the stock rod signals, certain process or equipment faults can cause signal establishment errors, and need to be eliminated. For example, a special process for removing clean coke: when coke is completely filled, only one material name (C) plus a material batch number is required, and the corresponding material name (O) plus the material batch number is not required, so that the coke is removed through database knowledge; the situation of pouring can is eliminated: the charging bucket which has the ore loading when the charging bucket is inverted continuously loads coke, but the two charging buckets alternately load coke and ore, the matching is disordered, and the coke is removed through the database knowledge; removing multiple opening signals of the material flow valve: due to equipment failure, a plurality of material flow valve opening signals occur, and the last opening signal is selected by using database knowledge; and (3) eliminating the condition of probe signal loss: when a scale lifting or scale placing signal point is lost occasionally due to equipment failure, a material flow valve opening signal replaces a scale placing signal, and a material flow valve closing signal replaces a scale lifting signal; because the influence of the time point of the stock rod lifting on the material speed is great in the current hour or the last hour, the data acquisition server and the master control room computer are subjected to time synchronization.

Specifically, according to the signal establishing process, a list can be built in the database, the first column is sequentially increased by natural numbers from 1 to N, then the information extracted from each batch of coke is sequentially filled from the second column according to time, batch number and batch name, and the information of the coke in the previous batch and the coke in the next batch is filled into the corresponding columns to form a database table. And calculating the difference delta T between the coke time of the current batch and the coke time of the previous batch, comparing the current batch Ni with Ni-1, if the delta T is less than 10min (usually a complete batch time), and Ni is Ni-1, deleting i-1 pieces of information, deleting the custom column and other information to obtain a new table 2 for subsequent calculation. For example, the typical cloth timing sequence is: COCOCO. when the cloth is burnt, the cloth is distributedThe sequence is as follows: COCCOCO (C underlined is net coke), which can then be treated in the manner mentioned above.

TABLE 1

TABLE 2

Specifically, through the data acquisition and signal processing processes, the material distribution parameters of the blast furnace in a certain long period can be more conveniently determined, and in addition, in order to detect the deflection of the blast furnace, research shows that the parameters such as the furnace temperature of a tuyere and an iron notch can possibly influence the deflection. Therefore, besides the burden distribution parameters, the tuyere parameters and the taphole parameters of the blast furnace need to be acquired.

Step S102: calculating ore-coke ratio, total area of a tuyere and furnace temperature of an iron notch in the directions of the two charging buckets according to the technological parameters; specifically, based on the material distribution parameters, an ore-coke ratio calculation model in the material distribution process can be constructed, so that the ore-coke ratios in the two charging bucket directions are calculated; calculating to obtain the total area of the tuyere based on the tuyere parameters; and constructing a silicon content model of the taphole area based on the taphole parameters, and calculating the furnace temperature of the taphole.

Step S103: and judging whether the blast furnace has deflection or not according to the relation of ore-coke ratio in the two charging bucket directions, the relation of total area of the tuyere and the relation of furnace temperature of the iron notch.

Specifically, after the ore-coke ratio, the total area of the tuyere and the furnace temperature of the taphole are calculated, the blast furnace skew is detected and corrected according to the relationship among the ore-coke ratio, the total area of the tuyere and the furnace temperature of the taphole. For example, the average ore-coke ratio per shift of the No. 1 stock rod and the No. 2 stock rod, the average silicon content per shift of the No. 1 iron notch and the No. 2 iron notch and the tuyere area in one month can be counted to judge the blast furnace deflection.

According to the deflection detection and correction method based on the parallel-tank blast furnace, provided by the embodiment of the invention, the ore-coke ratio, the total area of the tuyere and the furnace temperature of the iron notch in the two charging tank directions are calculated by obtaining the process parameters in the working process of the blast furnace, and the deflection of the blast furnace is judged based on the calculated relationship among the ore-coke ratio, the total area of the tuyere and the furnace temperature of the iron notch in the two charging tank directions. Compared with the mode of judging the material level height detected by the stock rod in the prior art, the method not only considers the deviation of the ore-coke ratio at the furnace top, but also considers the deviation of the air supply at the lower part and the deviation of the furnace temperature, so that the detection of the blast furnace deflection has practical guiding significance.

As an optional implementation manner of the embodiment of the present invention, calculating the ore-coke ratio in the two bucket directions according to the process parameters includes: determining the blanking speed of the previous batch of materials, the height change of the stock rod when the current batch of coke and ore are distributed and the distribution time according to the distribution parameters; determining the thickness change of the current batch of coke according to the blanking speed of the previous batch of materials, the height change of a stock rod when the current batch of coke is distributed and the distribution time; determining the blanking speed of the current batch of coke according to the height change of the stock rod and the material distribution time when the current batch of coke is distributed; determining the thickness change of the current batch of ore according to the current batch of coke blanking speed, the height change of a stock rod during the current batch of ore distribution and the distribution time; and determining the ore-coke ratio in the directions of the two charging buckets according to the thickness change of the current batch of coke and the thickness change of the current batch of coke.

Specifically, two mechanical probes and two charging buckets are arranged symmetrically on two sides of the center line of the blast furnace, and the directions of the two mechanical probes and the two charging buckets are the same. In the material distribution process, the height of the measuring rod can change along with the material distribution and the production process. As shown in fig. 4, the height of the probe before distributing is LO, the height of the probe after distributing is L1, the height difference between the probe before distributing and after distributing is a, and in the distributing process, the LO of the original charge level will fall to L2 along with the normal progress of smelting, so the height difference measured by the probe is b, and assuming that the descending speeds of the charge level are the same in the radial direction, the thickness of the charge layer measured by the actual probe is a + b, and after the thicknesses of the charge layers of coke and ore are respectively calculated, the ore-coke ratio at the measured point can be obtained.

Specifically, as shown in fig. 5, which is a schematic diagram of distribution and feeding of coke and ore, the process can be determined from the data acquisition and signal processing process for the distribution process in step S101. In order to determine the current coke and ore bed thicknesses, the distribution process of the previous batch needs to be determined. As shown, the previous batch of material is assumed to be laid with coke first and then with ore. The feeding speed of the last batch, i.e. the (i-1) th batch of ores is VO_i－1＝(H₂－H₁)/(T₂－T₁) (ii) a The coke layer thickness of the current batch, i.e., batch i, is represented as a + b, where a ═ H₂－H₃，b＝VO_i－1＊(T₃－T₂) Whereby the coke layer thickness TC_i＝a+b＝H₂－H₃+VO_i－1＊(T₃－T₂) (ii) a Same principle for charging VC of ith coke batch_i＝(H₄－H₃)/(T₄－T₃) (ii) a Thickness of the ith batch of mineral layers: TO_i＝H₄－H₅+VC_i＊(T₅－T₄) (ii) a Thus, the ore-to-coke ratio for the ith batch was: r_i＝TO_i/TC_i. In the above formula, H₁、H₂、H₃、H₄、H₅、H₆Respectively representing the change in level, T, detected by the stock rod₁、T₂、T₃、T₄、T₅、T₆Respectively showing the corresponding time when the cloth is distributed.

In particular, to make the determined blast furnace skew more accurate, the ore-coke ratio that needs to be calculated is more representative. After the ore-coke ratio of a batch of materials is calculated, the ore-coke ratio in one period can be calculated according to actual working conditions. For example, the average ore-to-coke ratio R _ for each shift of the two probes may be calculated_A，R＿_B. The average ore-to-coke ratio can be determinedAnd carrying out average calculation according to the calculated ore-coke ratio of each batch of materials. Wherein each shift can be eight hours, and can be longer or shorter, and can be determined according to actual work.

As an optional implementation manner of the embodiment of the present invention, calculating the total area of the tuyere in the two charging bucket directions according to the process parameter includes: and determining the total area of the air inlet in the preset time in the directions of the two charging buckets according to the air inlet parameters. Specifically, two charging pots of a parallel-pot blast furnace are generally arranged symmetrically. As shown in FIG. 6, the cross section of the hearth part of the blast furnace is taken as a top view, O is the center of the blast furnace, the center points of the two charging buckets and the cross section of the hearth are connected to AB, and AB is rotated up and down by 45 degrees along the center point O of the blast furnace to obtain diameters EF and CD. Thus obtaining the position of the tuyere in each charging bucket, and acquiring the total area of the tuyere in the corresponding position after probing, such as acquiring the total area S _ of the average tuyere per class in the EACO sector in the charging bucket 1_AThe total area S _ of the average tuyere in each class in the collection sector DBFO in the charging bucket 2_B。

Particularly, in the production process of the blast furnace, the area of the tuyere thereof can be adjusted according to actual needs. Therefore, the total area of the tuyere in the direction of each charging bucket in a period of time, such as 8 hours, can be calculated. When the total area of the air ports is calculated, the number of the air ports can be determined firstly, and then data such as the height, the diameter, the angle, the length and the like of each working air port in the direction of each charging bucket are determined, so that the total area of the air ports in each charging bucket is calculated.

As an optional implementation manner of the embodiment of the present invention, calculating the furnace temperatures of the iron notch in the two charging bucket directions according to the process parameters includes: determining furnace temperature components in each direction according to the azimuth layout of the charging bucket and the iron notch; and calculating the furnace temperature of the iron notch in the directions of the two charging pots according to the furnace temperature component in each direction.

Specifically, as shown in fig. 7, considering the working uniformity of the taphole, the tapholes are usually arranged symmetrically along the vertical line CD of the 1# tank and the 2# tank during the design, and if the tapholes are AA, BB, CC, DD, respectively, and the included angles between the line connecting the taphole and the center of the blast furnace and the line AB are α, β, respectively, the component of the silicon content of the molten iron in each furnace corresponding to each taphole in the direction A, B is taken and combinedSummation, i.e. furnace temperature Si _ per furnace of No. 1 tap hole_A＝Si＿_AA＊cosα+Si＿_BBPer furnace temp. Si of Cos beta, 2# iron notch_B＝Si＿_CC＊cosα+Si＿_DDCalculating the furnace temperature of 1# and 2# iron notch of each shift as Si-cos beta respectively_AAnd Si_B。

As an optional implementation manner of the embodiment of the invention, according to the relationship between the ore-coke ratio in the two charging buckets, the relationship between the total area of the tuyere and the relationship between the furnace temperature of the iron notch; judging whether the blast furnace has deflection or not comprises the following steps: judging whether the ore-coke ratio and the furnace temperature of an iron notch in the directions of two charging tanks per day have equidirectional deviation or not exceeding a first preset value; and when the number of times of equidirectional deviation exceeds a first preset value, determining that the blast furnace has deflection.

Specifically, after the relationship between the ore-coke ratio in the two charging bucket directions, the relationship between the total area of the tuyere and the furnace temperature of the iron notch are obtained through calculation, whether the blast furnace is inclined or not can be judged according to the relationship. In the judgment, the average ore-coke ratio of the No. 1 stock rod and the No. 2 stock rod per shift, the average silicon content of the No. 1 iron notch and the No. 2 iron notch per shift and the total area of the tuyere can be counted in one month. When the specific judgment is carried out, firstly, whether the ore-coke ratio and the iron notch furnace temperature have equidirectional deviation times in the directions of two charging buckets every day exceed a first preset value or not is judged, namely, whether the ore-coke ratio and the iron notch furnace temperature have equidirectional deviation probability is larger than the first preset value or not is judged. The first preset value can be set according to actual needs. Such as daily R_A≦R＿_BHas a frequency of > 60% and Si_A≦Si＿_BThe frequency of (A) is > 60% or when R _ R_A≧R＿_BHas a frequency of > 60% and Si_A≧Si＿_BThe frequency of (2) is > 60%. At this time, the operation of the blast furnace in the circumferential direction is not uniform, i.e. the blast furnace has deflection.

In one embodiment, upon detecting a blast furnace skew, the skew needs to be corrected. In order to determine a specific correction mode, whether the deviation between the total areas of the air ports is greater than a second preset value or not can be judged, and when the deviation is greater than the second preset value, the total areas of the air ports are adjusted to reduce the deviation, so that the coal powder injection quantity in the two charging bucket directions is kept the same. Specifically, when the blast furnace is detected to have deflection, whether the blast furnace has lower air supply deviation or not can be judged firstly, and when the lower air supply deviation exists, the lower air supply deviation is corrected firstly, namely the total area of the air ports and the pulverized coal injection quantity are adjusted.

In one embodiment, under the condition of deflection, if the total area deviation of the tuyere is smaller than a third preset value, the combined charging mode of the two charging buckets and the charging materials is changed. Specifically, if a small bottom deviation is detected when there is a deviation, then the correction needs to be performed by a canister inversion method.

Specifically, the second preset value and the third preset value may be determined according to actual needs. If the second preset value is set to 1.67%, the third preset value is set to 1%. I.e., in the presence of skew, if (S _ S)_A－S＿_B)/S＿_A| ≧ 1.67%, the area of the tuyere is properly adjusted to reduce the difference between the two sides, such as less than 1%, and the coal powder injection quantity of the two sides is kept the same; if (S _ L)_A－S＿_B)/S＿_AIf the coal powder injection quantity is the same, the combined charging mode of the charging bucket and the furnace burden is changed, if the charging bucket 1 is used for charging coke and the charging bucket 2 is used for charging ore, the charging bucket 2 is used for charging coke and the charging bucket 1 is used for charging ore.

The deflection detection and correction method based on the parallel-tank blast furnace provided by the embodiment of the invention realizes the detection of the deflection of the blast furnace by comparing the ore-coke ratio and the furnace temperature in the two charging bucket directions. Meanwhile, when the deflection is determined, the deflection of the blast furnace is corrected by judging the total area of the tuyere. Therefore, the method can provide a certain guiding direction for the blast furnace operator to correct the skew.

The embodiment of the invention also provides a deflection detection and correction device based on the parallel-tank blast furnace, as shown in fig. 8, the device comprises:

the parameter acquisition module is used for acquiring technological parameters of the blast furnace, wherein the technological parameters comprise material distribution parameters, tuyere parameters and taphole parameters; for details, refer to the related description of step S101 in the above method embodiment.

The calculation module is used for calculating ore-coke ratio, total area of the tuyere and furnace temperature of the iron notch in the two charging bucket directions according to the technological parameters; for details, refer to the related description of step S102 in the above method embodiment.

The judging module is used for judging the relationship between the ore-coke ratio in the two charging bucket directions, the relationship between the total area of the tuyere and the relationship between the furnace temperature of the iron notch; and judging whether the blast furnace has deflection or not. For details, refer to the related description of step S103 in the above method embodiment.

According to the deflection detection and correction device based on the parallel-tank blast furnace, provided by the embodiment of the invention, the ore-coke ratio, the total area of the air port and the furnace temperature of the iron port in the two charging tank directions are calculated by obtaining the process parameters in the working process of the blast furnace, and the deflection of the blast furnace is judged based on the calculated relationship among the ore-coke ratio, the total area of the air port and the furnace temperature of the iron port in the two charging tank directions. Compared with the mode of judging the material level height detected by the stock rod in the prior art, the device not only considers the deviation of the ore-coke ratio at the top of the blast furnace, but also considers the deviation of the air supply at the lower part and the deviation of the furnace temperature, so that the detection of the blast furnace deflection has practical guiding significance.

The functional description of the skew detection and correction device based on the parallel-tank blast furnace provided by the embodiment of the invention refers to the skew detection and correction method based on the parallel-tank blast furnace in the embodiment in detail.

An embodiment of the present invention further provides a storage medium, as shown in fig. 9, on which a computer program 601 is stored, and the instructions, when executed by a processor, implement the steps of the skew detection and correction method based on the parallel-tank blast furnace in the foregoing embodiments. The storage medium is also stored with audio and video stream data, characteristic frame data, an interactive request signaling, encrypted data, preset data size and the like. The storage medium may be a magnetic Disk, an optical Disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a Flash Memory (Flash Memory), a Hard Disk (Hard Disk Drive, abbreviated as HDD) or a Solid State Drive (SSD), etc.; the storage medium may also comprise a combination of memories of the kind described above.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by a computer program, which can be stored in a computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. The storage medium may be a magnetic Disk, an optical Disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a Flash Memory (Flash Memory), a Hard Disk (Hard Disk Drive, abbreviated as HDD) or a Solid State Drive (SSD), etc.; the storage medium may also comprise a combination of memories of the kind described above.

An embodiment of the present invention further provides an electronic device, as shown in fig. 10, the electronic device may include a processor 51 and a memory 52, where the processor 51 and the memory 52 may be connected by a bus or in another manner, and fig. 10 takes the example of connection by a bus as an example.

The processor 51 may be a Central Processing Unit (CPU). The Processor 51 may also be other general purpose processors, Digital Signal Processors (DSPs), Application Specific Integrated Circuits (ASICs), Field Programmable Gate Arrays (FPGAs) or other Programmable logic devices, discrete Gate or transistor logic devices, discrete hardware components, or combinations thereof.

The memory 52, which is a non-transitory computer readable storage medium, may be used to store non-transitory software programs, non-transitory computer executable programs, and modules, such as the corresponding program instructions/modules in the embodiments of the present invention. The processor 51 executes various functional applications and data processing of the processor by running non-transitory software programs, instructions and modules stored in the memory 52, namely, implementing the method for detecting and correcting the deflection based on the parallel-shaft blast furnace in the above method embodiment.

The memory 52 may include a storage program area and a storage data area, wherein the storage program area may store an operating system, an application program required for at least one function; the storage data area may store data created by the processor 51, and the like. Further, the memory 52 may include high speed random access memory, and may also include non-transitory memory, such as at least one magnetic disk storage device, flash memory device, or other non-transitory solid state storage device. In some embodiments, the memory 52 may optionally include memory located remotely from the processor 51, and these remote memories may be connected to the processor 51 via a network. Examples of such networks include, but are not limited to, the internet, intranets, local area networks, mobile communication networks, and combinations thereof.

The one or more modules are stored in the memory 52 and, when executed by the processor 51, perform a parallel shaft furnace based skew detection and correction method as in the embodiment of fig. 1-7.

The details of the electronic device may be understood by referring to the corresponding descriptions and effects in the embodiments shown in fig. 1 to fig. 7, which are not described herein again.

Although the embodiments of the present invention have been described in conjunction with the accompanying drawings, those skilled in the art may make various modifications and variations without departing from the spirit and scope of the invention, and such modifications and variations fall within the scope defined by the appended claims.