KR20190078319A - System and method of evaluating furnace operation state - Google Patents

Abstract

Disclosed are a system and a method for evaluating a furnace operation situation. The system for evaluating a furnace operation situation includes: an image obtaining unit obtaining multiple pieces of image data by each winnowing machine installed in a furnace; a winnowing machine combustion state determining unit classifying a combustion state by each winnowing machine based on artificial intelligence using the image data by each winnowing machine; a winnowing machine combustion state index generating unit generating a combustion state index by each winnowing machine using a classification result of the combustion state by each winnowing machine, classified by the winnowing machine combustion state determining unit; and an integrated evaluation unit generating an integrated combustion state index based on the combustion state index by each winnowing machine.

Description

TECHNICAL FIELD [0001] The present invention relates to a system and a method for evaluating a situation of a blast furnace operation,

The present application relates to a blast furnace operation situation evaluation system and method.

In order to evaluate the operation status of the blast furnace, attempts have been made to analyze the image data taken through the blast furnace and determine the situation in the furnace or to monitor the operating data to determine the situation in the furnace.

Conventionally, however, the operator has simply judged the blast furnaceability or the luminescence of the blast furnace through the image data or judged the furnace condition by the luminance analysis of the image data.

In this connection, Patent Document 1 described in the following prior art document discloses a control method based on determination of the operational status of a furnace.

Japanese Laid-Open Patent Application No. 2015-52148 (Publication Date: Mar. 19, 2015)

In the related art, there is a need for a method for quantitatively evaluating the tuff combustion state based on the tug-guided image data and for integrally evaluating the blast furnace operation status based on the evaluation.

In order to solve the above problems, an embodiment of the present invention provides a blast furnace operation situation evaluation system.

According to an embodiment of the present invention, a blast furnace operation status evaluation system includes an image acquisition unit that acquires a plurality of wind turbine image data provided in a blast furnace; An image collecting unit for collecting the image data of the wind type acquired by the image acquiring unit; A tidal burning state determination unit for classifying the air-fueled combustion states based on artificial intelligence using the air-conditioned image data; A tidal burning state index generating unit for generating an air-fueled combustion state index by using the air-fueled combustion state classification result classified by the tidal burning state determining unit; And an integrated evaluation unit for generating an integrated combustion state index based on the air-fuel ratio combustion state index.

Meanwhile, another embodiment of the present invention provides a method for evaluating blast furnace operation status.

According to another aspect of the present invention, there is provided a method for evaluating blast furnace operation status, comprising: collecting a plurality of blast furnace image data provided in a blast furnace; Classifying the combustion state of each airway based on artificial intelligence using the airway image data; Generating an air-fueled combustion state index by using the air-fuel ratio classified state classification result; And generating an integrated combustion state index based on the air-fueled combustion state index.

In addition, the means for solving the above-mentioned problems are not all enumerating the features of the present invention. The various features of the present invention and the advantages and effects thereof will be more fully understood by reference to the following specific embodiments.

According to one embodiment of the present invention, it is possible to classify the tuyere combustion state based on the deep running based on the tuyere image data. In addition to the tuyere combustion state classification result, the analysis result of the tuyere image data and the analysis result of the blast furnace data are additionally , And it is possible to collectively evaluate and control the blast furnace operation status.

As a result, it is possible to quantitatively evaluate blast furnaceability and sulfur content to enable stable blast furnace operation and improve productivity.

1 is a configuration diagram of a blast furnace operation situation evaluation system according to an embodiment of the present invention.
FIG. 2 is a view for explaining a concept of classifying a tuyere combustion state primarily on a deep learning basis according to an embodiment of the present invention.
FIGS. 3 and 4 are views for explaining a concept of determining a tidal combustion state classification on the basis of a result obtained by accumulating results obtained by primary classification on a deep learning basis according to an embodiment of the present invention.
5 is a flowchart of a method for evaluating blast furnace operation status according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, in order that those skilled in the art can easily carry out the present invention. In the following detailed description of the preferred embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In the drawings, like reference numerals are used throughout the drawings.

In addition, in the entire specification, when a part is referred to as being 'connected' to another part, it may be referred to as 'indirectly connected' not only with 'directly connected' . Also, to "include" an element means that it may include other elements, rather than excluding other elements, unless specifically stated otherwise.

1 is a configuration diagram of a blast furnace operation situation evaluation system according to an embodiment of the present invention.

1, a blast furnace operation status evaluation system 100 according to an exemplary embodiment of the present invention includes an image acquisition unit 110, an image collection unit 120, a tile combustion state determination unit 130, A production information collection unit 150, an integrated evaluation unit 160, and an aging control unit 170. The production unit 140, the operation information collection unit 150,

The image acquiring unit 110 acquires image data for each tuyere 11 provided in the blast furnace 10.

For example, the image acquiring unit 110 may include a plurality of cameras installed in the respective tuyeres 11, and acquire the respective blind image data in real time (for example, in units of ms) can do.

The image capturing unit 120 is for capturing the image data of each of the pieces of the image data acquired by the image acquiring unit 110.

For example, the image capturing unit 120 may collect image data obtained in real time for each tuyere from a plurality of cameras included in the image capturing unit 110.

The image collection unit 120 may map the collected image data to collection environment information including a tug number and a data acquisition time.

The image data that has been mapped by the image collection unit 120 may be stored in a data storage (not shown) provided in the blast operation status evaluation system 100 or may be transmitted to the tile combustion status determination unit 130 in real time .

The toughening combustion state determination unit 130 is for classifying the combustion state of each airway using the airway distinction image data received from the image collection unit 120. The airway state determination unit 130 includes an AI based determination unit 131, (132).

The AI-based determination unit 131 can classify the combustion state of each air-fuel mixture based on artificial intelligence using the image data of the air-conditioned air. For example, the AI-based determination unit 131 can classify the combustion state of each air-fuel mixture based on the deep-run basis.

According to an exemplary embodiment, the AI-based determination unit 131 may classify each air-fueled combustion state based on the CNN (Convolutional Neural Network) using the air-differentiated image data.

If necessary, the AI-based determination unit 131 determines the classification of the tidal combustion state based on the result of accumulating the primary classification results of the classified combustion state classification in time series to further improve the consistency of the combustion state classification .

The concept of classifying and establishing the tuyere combustion state by the AI-based determination unit 131 will be described in more detail with reference to FIG. 2 to FIG.

FIG. 2 is a view for explaining a concept of classifying a tuyere combustion state primarily on a deep learning basis according to an embodiment of the present invention.

Referring to FIG. 2, the AI-based determination unit 131 performs image deep-processing (for example, based on CNN) on each of the first tugging image to the Nth tugging image data 21 to 2N obtained for each tug To obtain the first to tenth flue gas combustion state classification to Nth tuyere combustion state classification results 21 'to 2N'. Here, N means the number of tongues.

FIGS. 3 and 4 are views for explaining a concept of determining a tidal combustion state classification on the basis of a result obtained by accumulating results obtained by primary classification on a deep learning basis according to an embodiment of the present invention.

Referring to FIG. 3, the AI-based determination unit 131 accumulates the combustion state classification results primarily classified for each taurine in time series, that is, the first tidal combustion state classification 31-1, 31- 2, 31-3, the second tidal combustion state classifications 32-1, 32-2, 32-3 and the Nth tidal combustion state classifications 3N-1, 3N-2, 3N-3, It is possible to determine the tidal combustion state classification by tungsten, and obtain the determined tuyball combustion state classification result (31 'to 33').

In this embodiment, for determining the classification of the tidal burning state, any combustion state classification is performed based on a plurality of combustion state classification results primarily classified during any time period (t-1 to t + 1) Or more, it can be decided to classify the combustion state. This makes it possible to improve the accuracy of classification of the tuyere combustion state.

Next, referring to FIG. 4, the AI-based determination unit 131 calculates the first tidal combustion state classification 41-1, 41-2, and 41-3 as a result of accumulating the combustion state classification results primarily classified for each taurine, 2, 41 - 3), the second tidal combustion state classifications 42 - 1, 42 - 2, 42 - 3 and the N th tug combustion state classifications 4 N - 1, 4 N - 2, 4 N - Based on the time-series deep running, the tuyere combustion state classification can be determined for each tuyere, and the confirmed tuyere combustion state classification results (41 'to 43') can be obtained.

For example, the AI-based determination unit 131 may determine whether or not an RNN (Recurrent Neural Network) or an RNN (Recurrent Neural Network) based on a plurality of combustion state classification results that are primarily classified for each time period t- Based on the Recurrent Convolutional Neural Network (RCNN), it is possible to determine the classification of each type of tidal burning condition.

Since the combustion state of the tuyere changes with continuity with time, it may be less accurate to judge the state of combustion of the tuyere by only a state at an arbitrary point in time.

Therefore, according to the present embodiment, in order to determine the classification of the combustion state of the tuyere by comprehensively considering the change of the combustion state of the tuyere according to the temporal flow, the accuracy of the classification of the tuyere combustion state is further improved by applying the image time- .

On the other hand, as shown in FIG. 3 and FIG. 4, in establishing the classification of the tidal combustion state based on the results accumulated in time series, a time period (for example, t- t + 1) and the start time (t-1) of the corresponding time period.

According to an embodiment, at the time of initial execution, the tuyball combustion state classification can be established by accumulating the result of primary classification for the time period set by the user, starting from the point in time when the tuyball combustion state classification is first detected .

If the determination result of the tidal combustion state classification accumulates, the time period described above is adjusted according to the elapsed time information from when the tidal combustion state classification is first detected to when the tidal combustion state classification is transferred to another state, Can be improved.

The combustion state of the tuyeres classified by the AI-based determination unit 131 may include, for example, a normal combustion state, a poor combustion state, a non-pulverized coal injection, a unreduced melt drop (dropping light drop), a cock turning, and the like. Here, the pulverized coal is judged whether or not the pulverized coal is blown, and the unreduced melted material drop (live fall drop) means whether or not the raw material to be reduced at the furnace portion is not reduced, And the turning of the coke means judging whether or not the coke turns in the middle of the furnace.

The image processing base determination unit 132 can diagnose the tuyere apparatus through the image processing of the image data of the tandem image, and can determine the tuyere combustion state.

According to one embodiment, the image processing-based determination unit 132 may perform an image processing on the image data of the background image to determine whether or not the toughening equipment abnormality including the presence or absence of the tornado, presence of the tornado, clogging of the tornado, lance banding, It can be judged.

In addition, the image processing base determination unit 132 may extract the combustion area and the combustion brightness (i.e., luminance) through image processing on the image data of the air-conditioned image.

In addition, when the combustion state is normal, the image processing base determination unit 132 can determine the pulverized coal flow rate through image processing on the image data of the wind type.

Various image processing techniques known to those skilled in the art may be applied to the image processing based on the image data by the image processing base determination unit 132, and a detailed description thereof will be omitted.

The determination by the AI-based determination unit 131 and the image processing-based determination unit 132 may be performed in parallel.

The results of the classification of the air condition classified by the air conditioner combustion state determiner 130 and the results of the air conditioner diagnosis may be mapped and stored and managed together with the image data and the collected environment information.

The tidal burning state index generator 140 generates the tidal burning state index using the result of the air-fuel ratio combustion state classification classified by the tuyere combustion state determiner 130. FIG.

According to one embodiment, the air-fuel ratio combustion state index generated by the air-flow combustion state index generating unit 140 may include a combustion state failure index, a pulverized coal non-spent index, a unreduced melt falling index, A combustion state level index, a pulverized coal flow rate index, a ruggedness index (Raceway) index, and the like.

For example, the tidal burning state index generator 140 counts the number of times that an arbitrary classification result is generated based on the classification result of each air-fuel mixture combustion state by the tidal combustion state determiner 130 every predetermined period, The related index can be generated by scoring according to the number of times counted for each cycle.

The tidal combustion state index generator 140 scales the combustion state level index according to the combustion area and the combustion brightness (i.e., brightness) extracted by the tidal flame combustion state determiner 130, Can be combined to generate a combustion status level index. Here, the reference information used for generating the combustion state level index can be updated according to the input signal by the manager. Accordingly, the updated reference information is reflected in real time, and the index information reflecting the blast condition can be generated.

The tidal burning state index generator 140 may generate the tidal system abnormality index by scoring the tidal system diagnosis result determined by the tidal burning state determiner 130. Here, the irregularity abnormality index may include a tug curvature index, a tug attachment index, a tug blockage index, a lance damage index, and the like.

The operation information collecting unit 150 is for collecting, in real time, operational information generated during blast furnace operation. Here, the operating information may include, for example, the temperature of the corona body, the pressure, the flow rate of the cooling water, and the like.

The operation information collected in real time by the operation information collecting unit 150 can be mapped and stored and managed with the tidal combustion state index information generated by the tidal combustion state index generating unit 140 described above.

The integrated evaluation unit 160 calculates the integrated value of the tug combustion state index information generated by the tug burning state index generating unit 140 based on the tug burning state index information generated for each tug and the operation information collected by the operation information collection number 150 This is to evaluate it integrally.

According to an embodiment, the integrated evaluation unit 160 may generate an integrated combustion state index by comprehensively considering the taurine combustion state index information generated for each taurine by the taurine combustion state index generating unit 140. [ For example, the integrated combustion state index is 1: 1 matched to the tidal combustion state index generated for each tuyere such as integrated combustion state failure index, integrated pulverized coal unloading index, integrated unreduced melt drop And may include an integrated combustion state index.

Also, the integrated evaluation unit 160 may generate the columnar balance index based on the tuyere combustion race index generated for each tuyere.

Also, the integrated evaluation unit 160 can generate an integrated tuff facility abnormality index based on the tuff equipment abnormality index generated for each tornado.

Based on the tug burning state index information generated for each tuyere by the tug burning state index generating unit 140 or the integrated combustion state index generated by the integrated evaluation unit 160, the sulfur content control unit 170 performs pulverized coal injection control, N2 Purge control, and blast furnace charge control to control blast furnace sulfur content.

According to one embodiment, the aging control unit 170 may perform the pulverized coal injection control when the pulverized coal unloading index for any tuyere exceeds a preset reference value.

In addition, the sulfur content control unit 170 may perform the blast furnace charge control when the drop of the live light occurs in an arbitrary tidal area and the unreduced melt drop index exceeds a preset reference value.

According to another embodiment, the aging control unit 170 may integrally control the plurality of tuyere based on the integrated combustion state index or the circumferential balance index information.

For example, when the live fall falls only in a certain direction, the sulfur content control unit 170 can control the content of the blast furnace, such as changing the charge direction by changing the charge content distribution.

The blast operation status evaluation system 100 described above with reference to FIG. 1 includes a processing device capable of performing application of an artificial intelligence algorithm to input data and image processing and capable of calculating various indices, a control device Or a combination of devices.

5 is a flowchart of a method for evaluating blast furnace operation status according to another embodiment of the present invention.

Referring to FIG. 5, according to another embodiment of the present invention, the image obtaining unit 110 and the image collecting unit 120 calculate image data for each tile provided in the blast furnace in real time (S510).

Thereafter, the tuyere combustion state determination unit 130 can classify the combustion states of the respective tuyere using the image data for each airway classification (S520). Specifically, the AI-based determination unit 131 first classifies the tidal combustion state on the basis of artificial intelligence using the image data of each airway type (S521), and then classifies the tidal combustion state based on the classification result (S522). In parallel with this, the image processing based determination unit 132 may classify the combustion state of each tuyere through image processing of each tandem image data, and diagnose the tuyere apparatus (S525).

Thereafter, the tidal flue combustion state index generator 140 generates a flue state combustion state index based on the result of the air-fuel ratio combustion state classification (S530), and the integrated evaluation unit 160 calculates the air- The operating status of the blast furnace can be evaluated integrally in the circumferential direction based on the state index (S540).

Thereafter, the longevity control unit 170 can control the longevity based on the collectively evaluated operating conditions (S550).

5 is the same as that described above with reference to FIG. 1 to FIG. 4, so that a detailed description thereof will be omitted.

The present invention is not limited to the above-described embodiments and the accompanying drawings. It will be apparent to those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

10: blast furnace
11: Tungus
110:
120:
130: tuyere combustion state judging unit
131: AI-based judgment unit
132: image processing base judgment unit
140: tuyere combustion state index generator
150: Operation information collecting section
160: Integrated Evaluation Unit
170:

Claims (12)

An image acquiring unit for acquiring a plurality of pieces of image data of the blind furnace;
An image collecting unit for collecting the image data of the wind type acquired by the image acquiring unit;
A tidal burning state determination unit for classifying the air-fueled combustion states based on artificial intelligence using the air-conditioned image data;
A tidal burning state index generating unit for generating an air-fueled combustion state index by using the air-fueled combustion state classification result classified by the tidal burning state determining unit; And
And an integrated evaluation unit for generating an integrated combustion state index based on the air-fuel ratio combustion state index.
The method according to claim 1,
And an AI-based determination unit for classifying the combustion state of each air-fuel mixture based on the deep-run based on the air-terminated image data.
3. The method of claim 2,
Wherein the AI-based determination unit determines the classification of the blast state according to the result of accumulating the blast combustion state classification result classified by the deep running based on time series for a predetermined time period.
The method of claim 3,
Wherein the AI-based determination unit determines the combustion state classification when an arbitrary combustion state classification occurs more than a predetermined number of times during the time period.
The method of claim 3,
Wherein the AI-based determination unit determines the combustion state classification based on the time-series deep-learning based on the air-classified combustion state accumulation result accumulated during the time period.
The method of claim 3,
Wherein the time period is adjusted according to the elapsed time information from the time when the tidal combustion state classification is first detected to the time when the tidal combustion state classification is changed to another state.
3. The apparatus according to claim 2, wherein the tidal burning-
Further comprising an image processing-based determination unit for diagnosing the tuyere apparatus through image processing of the image data for the tandem image and determining the tuyere combustion state.
The method according to claim 1,
Wherein the combustion state classification includes a normal combustion state, a poor combustion state, no pulverized coal injection, a non-reduced melt drop, and a cock turning.
The method according to claim 1,
Further comprising an aging control section for performing at least one of pulverized coal intake control, N2 purge control, and blast furnace charge control based on the air-fuel ratio combustion state index or the integrated combustion state index.
The method according to claim 1,
The blast state index according to the present invention includes at least one of a blast condition index, a blast furnace unfilled index, a unreduced melt drop index, a coke turning index, a combustion state level index, a pulverized coal flow index, system.
Collecting a plurality of pieces of image data for each of the blast furnaces;
Classifying the combustion state of each airway based on artificial intelligence using the airway image data;
Generating an air-fueled combustion state index by using the air-fuel ratio classified state classification result; And
And generating an integrated combustion state index based on the air-fuel ratio combustion state index.
12. The method of claim 11, wherein classifying the air-
Classifying each air-fueled combustion state on the basis of a deep learning using the air-terminated image data; And
And determining the classification of the blast state according to the result of accumulating the blast combustion state classification result classified by the deep running basis in time series for a predetermined time period.

Images