阅读说明：本技术 转炉及其转炉煤气柜煤气储量的预测方法、预测系统 (Converter and prediction method and prediction system for gas reserves of converter gas holder of converter ) 是由 李宁 吴泽 姜文豪 彭珍 李志永 崔化师 马金龙 林夏 于 2021-07-29 设计创作，主要内容包括：本发明公开了一种转炉煤气柜煤气储量的预测方法,包括：获取转炉生产作业计划、每炉次煤气回收量、每炉次煤气回收时间、煤气柜的当前煤气储量和用气设备的实时煤气用量；根据转炉生产作业计划、每炉次煤气回收时间和每炉次煤气回收量,确定在转炉生产作业计划的执行时间段里的实时煤气产量；根据煤气柜的当前煤气储量、实时煤气产量和实时煤气用量,预测转炉煤气柜在转炉生产作业计划的执行时间段里的煤气储量。在获得生产计划作业时间里的煤气储量数据后,可根据煤气储量的变化对煤气用户进行调度,使在生产计划作业时间里的煤气柜的煤气储量保持在合理区间运行,提高了转炉煤气回收系统的运行效率。(The invention discloses a method for predicting gas reserves of a converter gas holder, which comprises the following steps: acquiring a converter production operation plan, the recovery amount of gas per time, the recovery time of gas per time, the current gas storage amount of a gas cabinet and the real-time gas consumption of gas utilization equipment; determining the real-time gas yield in the execution time period of the converter production operation plan according to the converter production operation plan, the recovery time of the gas in each time and the recovery amount of the gas in each time; and predicting the gas reserves of the converter gas holder in the execution time period of the converter production operation plan according to the current gas reserves, the real-time gas yield and the real-time gas consumption of the gas holder. After the gas reserve data in the production planning operation time is obtained, the gas users can be scheduled according to the change of the gas reserve, so that the gas reserve of the gas cabinet in the production planning operation time is kept in reasonable interval operation, and the operation efficiency of the converter gas recovery system is improved.)

1. The method for predicting the gas reserves of the converter gas holder is characterized by comprising the following steps of:

acquiring a converter production operation plan, the recovery amount of gas per time, the recovery time of gas per time, the current gas storage amount of a gas cabinet and the real-time gas consumption of gas utilization equipment;

determining the real-time coal gas yield in the execution time period of the converter production operation plan according to the converter production operation plan, the recovery time of the coal gas in each time and the recovery amount of the coal gas in each time;

and predicting the gas reserves of the converter gas holder in the execution time period of the converter production operation plan according to the current gas reserves of the gas holder, the real-time gas yield and the real-time gas consumption.

2. The prediction method of claim 1, wherein after the predicting the gas reserves of the converter gas holder over the execution time period of the converter production campaign, the prediction method further comprises:

and adjusting the gas consumption of the gas utilization equipment according to the gas reserve of the converter gas holder in the execution time period of the converter production operation plan.

3. The prediction method of claim 1, wherein after the predicting the gas reserves of the converter gas holder over the execution time period of the converter production campaign, the prediction method further comprises:

and performing visualization processing on the gas reserves of the converter gas holder in the execution time period of the converter production operation plan to obtain a gas reserve prediction curve in the execution time period.

4. The prediction method according to claim 1, wherein the determining the real-time gas yield in the execution time period of the converter production operation plan according to the converter production operation plan, the time for recovering the gas per furnace, and the amount of gas recovered per furnace specifically comprises:

determining the converter smelting start time of molten iron in each furnace according to the converter production operation plan;

determining the coal gas recovery time period of each heat according to the converter smelting start time of the molten iron in each furnace and the coal gas recovery time of each heat;

and determining the real-time gas yield in the execution time period of the production operation plan of the converter according to the gas recovery quantity of each heat and the gas recovery time period of each heat.

5. The prediction method according to claim 4, wherein the determining the converter smelting start time of molten iron per furnace according to the converter production work plan includes:

generating a converter smelting Gantt chart according to the converter production operation plan;

and determining the converter smelting start time of the molten iron in each furnace according to the converter smelting Gantt chart.

6. The prediction method of claim 1, wherein the converter production schedule is obtained from a steel production manufacturing execution MES system.

7. The prediction method of claim 1, wherein the current gas reserves of the gas cabinet and the real-time gas usage of the gas-using equipment are obtained from a production database system.

8. A system for predicting gas reserves of a converter gas holder, the system comprising:

the acquisition module is used for acquiring a converter production operation plan, the recovery amount of the gas per time, the recovery time of the gas per time, the current gas storage amount of a gas cabinet and the real-time gas consumption of gas equipment;

the determining module is used for determining the real-time coal gas yield in the execution time period of the converter production operation plan according to the converter production operation plan, the recovery time of the coal gas in each time and the recovery amount of the coal gas in each time;

and the prediction module is used for predicting the gas reserves of the converter gas holder in the execution time period of the converter production operation plan according to the current gas reserves of the gas holder, the real-time gas yield and the real-time gas consumption.

9. The prediction system of claim 8, further comprising:

and the adjusting module is used for adjusting the gas consumption of the gas utilization equipment according to the gas reserve of the converter gas holder in the execution time period of the converter production operation plan.

10. A converter installation, characterized in that it comprises a prediction system according to claim 8 or 9.

Technical Field

The application relates to the technical field of steel smelting, in particular to a converter and a method and a system for predicting gas reserves of a converter gas chamber of the converter.

Background

Molten iron produced by blast furnace ironmaking contains a large amount of carbon, and when oxygen is blown in converter steelmaking, the large amount of carbon is oxidized to generate carbon monoxide and carbon dioxide, so that converter gas is obtained by collecting, storing and recovering converter gas; the converter recovered gas enters a gas chamber for temporary storage after being purified. At present, in the production of ferrous metallurgy, the recovery of converter gas produced by converter smelting is discontinuous, while the transportation of converter gas is continuous. Wherein, other units for steel making, hot rolling and other main processes of steel and iron are rigid users of converter gas, and each generator set is a converter gas adjusting user. Therefore, in actual production, due to the non-continuity or the non-uniformity of the converter rhythm in steel making production, the tank capacity of the gas tank, that is, the significant change of the gas storage capacity, is easily caused, the limited collection is required when the tank level is high, and the mixed gas of blast furnace gas and coke gas is required to be co-fired when the tank level is low, so that the energy waste caused by insufficient recovery of converter gas or the unreasonable energy configuration caused by co-firing of other gas is caused, and the operating efficiency of the converter gas recovery system is influenced.

Disclosure of Invention

The invention provides a converter and a method and a system for predicting gas reserves of a converter gas holder of the converter, and aims to solve or partially solve the technical problem of low operation efficiency of a converter gas recovery system caused by discontinuity or unbalanced rhythm of converter gas recovery.

In order to solve the above technical problem, according to an alternative embodiment of the present invention, there is provided a method for predicting a gas reserve of a converter gas holder, including:

acquiring a converter production operation plan, the recovery amount of gas per time, the recovery time of gas per time, the current gas storage amount of a gas cabinet and the real-time gas consumption of gas utilization equipment;

determining the real-time coal gas yield in the execution time period of the converter production operation plan according to the converter production operation plan, the recovery time of the coal gas in each time and the recovery amount of the coal gas in each time;

and predicting the gas reserves of the converter gas holder in the execution time period of the converter production operation plan according to the current gas reserves of the gas holder, the real-time gas yield and the real-time gas consumption.

Optionally, after predicting the gas reserves of the converter gas holder in the execution time period of the converter production operation plan, the predicting method further includes:

and adjusting the gas consumption of the gas utilization equipment according to the gas reserve of the converter gas holder in the execution time period of the converter production operation plan.

Optionally, after predicting the gas reserves of the converter gas holder in the execution time period of the converter production operation plan, the predicting method further includes:

and performing visualization processing on the gas reserves of the converter gas holder in the execution time period of the converter production operation plan to obtain a gas reserve prediction curve in the execution time period.

Optionally, the determining, according to the converter production operation plan, the coal gas recovery time of each time and the coal gas recovery amount of each time, a real-time coal gas yield in an execution time period of the converter production operation plan specifically includes:

determining the converter smelting start time of molten iron in each furnace according to the converter production operation plan;

determining the coal gas recovery time period of each heat according to the converter smelting start time of the molten iron in each furnace and the coal gas recovery time of each heat;

and determining the real-time gas yield in the execution time period of the production operation plan of the converter according to the gas recovery quantity of each heat and the gas recovery time period of each heat.

Further, the determining the converter smelting start time of molten iron in each furnace according to the converter production operation plan includes:

generating a converter smelting Gantt chart according to the converter production operation plan;

and determining the converter smelting start time of the molten iron in each furnace according to the converter smelting Gantt chart.

Optionally, the converter production operation plan is obtained from a steel-making production execution MES system.

Optionally, the current gas reserves of the gas cabinet and the real-time gas usage of the gas-using equipment are obtained from a production database system.

According to another alternative embodiment of the present invention, there is provided a system for predicting gas reserves of a converter gas holder, comprising:

the acquisition module is used for acquiring a converter production operation plan, the recovery amount of the gas per time, the recovery time of the gas per time, the current gas storage amount of a gas cabinet and the real-time gas consumption of gas equipment;

the determining module is used for determining the real-time coal gas yield in the execution time period of the converter production operation plan according to the converter production operation plan, the recovery time of the coal gas in each time and the recovery amount of the coal gas in each time;

and the prediction module is used for predicting the gas reserves of the converter gas holder in the execution time period of the converter production operation plan according to the current gas reserves of the gas holder, the real-time gas yield and the real-time gas consumption.

Optionally, the prediction system further comprises:

and the adjusting module is used for adjusting the gas consumption of the gas utilization equipment according to the gas reserve of the converter gas holder in the execution time period of the converter production operation plan.

According to yet another alternative embodiment of the present invention, there is provided a converter plant comprising the prediction system described above.

Through one or more technical schemes of the invention, the invention has the following beneficial effects or advantages:

the invention provides a method for predicting the gas reserves of a converter gas holder, which obtains an accurate converter smelting time plan by obtaining a strictly programmed converter production plan, thereby accurately mastering the converter smelting production rhythm; then obtaining the real-time coal gas yield when the converter smelting production plan is executed according to the recovery amount of the coal gas of each time, the recovery time of the coal gas of each time and the converter production operation plan, namely decomposing the total recovery amount of the converter coal gas according to the steelmaking time of the converter to obtain the real-time recovery amount of the converter coal gas in the whole converter smelting process; the real-time gas storage amount information of the gas cabinet in a preset time period when a converter production operation plan is executed in the future can be predicted by combining the gas storage amount data of the gas cabinet at the current moment and the real-time gas consumption of gas-using equipment; after the future real-time gas reserve information of the gas holder is obtained, the gas consumption of gas equipment for converter gas can be timely adjusted according to the variation trend of the real-time gas reserve, when the capacity of the gas holder or the gas reserve is higher, the gas supply is increased, and the condition of energy waste caused by limited collection of the converter gas when the capacity of the gas holder is higher is reduced; when the capacity of the gas cabinet is low, the gas supply is reduced, and the situation that the energy source configuration is unreasonable due to the co-combustion of blast furnace gas and coke gas mixed gas when the capacity of the gas cabinet is low is reduced. In general, by means of the scheme, the gas reserves of the gas holder in the future operation plan execution time period are kept to operate in a reasonable interval, and the operation efficiency of the converter gas recovery system is improved.

The foregoing description is only an overview of the technical solutions of the present invention, and the embodiments of the present invention are described below in order to make the technical means of the present invention more clearly understood and to make the above and other objects, features, and advantages of the present invention more clearly understandable.

Drawings

Various other advantages and benefits will become apparent to those of ordinary skill in the art upon reading the following detailed description of the preferred embodiments. The drawings are only for purposes of illustrating the preferred embodiments and are not to be construed as limiting the invention. Also, like reference numerals are used to refer to like parts throughout the drawings. In the drawings:

FIG. 1 is a schematic flow chart of a method for predicting gas reserves in a converter gas holder according to an embodiment of the invention;

FIG. 2 shows a schematic diagram of a system for predicting gas reserves in a converter gas holder according to yet another embodiment of the invention;

fig. 3 shows a control principle diagram of a prediction system according to a further embodiment of the invention.

Detailed Description

In order to make the present application more clearly understood by those skilled in the art to which the present application pertains, the following detailed description of the present application is made with reference to the accompanying drawings by way of specific embodiments. Throughout the specification, unless otherwise specifically noted, terms used herein should be understood as having meanings as commonly used in the art. Accordingly, unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. If there is a conflict, the present specification will control. Unless otherwise specifically stated, various apparatuses and the like used in the present invention are either commercially available or can be prepared by existing methods.

In order to solve the technical problem that the operating efficiency of a converter gas recovery system is reduced due to discontinuous converter gas recovery and unbalanced rhythm, the invention provides a method for predicting the gas storage capacity of a converter gas holder, which has the following overall thought:

acquiring a converter production operation plan, the recovery amount of gas per time, the recovery time of gas per time, the current gas storage amount of a gas cabinet and the real-time gas consumption of gas utilization equipment; determining the real-time coal gas yield in the execution time period of the converter production operation plan according to the converter production operation plan, the recovery time of the coal gas in each time and the recovery amount of the coal gas in each time; and predicting the gas reserves of the converter gas holder in the execution time period of the converter production operation plan according to the current gas reserves of the gas holder, the real-time gas yield and the real-time gas consumption.

The principle that the prediction method can improve the operation efficiency of the converter gas recovery system is as follows: because the recovery quantity of the converter gas of each heat in the steelmaking process is balanced and stable, an accurate converter smelting time plan is obtained by obtaining a converter production plan which is strictly compiled, and thus the smelting production rhythm of the converter is accurately mastered; then obtaining the real-time coal gas yield when the converter smelting production plan is executed according to the recovery amount of the coal gas of each time, the recovery time of the coal gas of each time and the converter production operation plan, namely decomposing the total recovery amount of the converter coal gas according to the steelmaking time of the converter to obtain the real-time recovery amount of the converter coal gas in the whole converter smelting process; the real-time gas storage amount information of the gas cabinet in a preset time period when a converter production operation plan is executed in the future can be predicted by combining the gas storage amount data of the gas cabinet at the current moment and the real-time gas consumption of gas-using equipment; after the future real-time gas reserve information of the gas holder is obtained, the gas consumption of gas equipment for converter gas can be timely adjusted according to the variation trend of the real-time gas reserve, when the capacity of the gas holder or the gas reserve is higher, the gas supply is increased, and the condition of energy waste caused by limited collection of the converter gas when the capacity of the gas holder is higher is reduced; when the capacity of the gas cabinet is low, the gas supply is reduced, and the situation that the energy source configuration is unreasonable due to the co-combustion of blast furnace gas and coke gas mixed gas when the capacity of the gas cabinet is low is reduced. In general, by means of the scheme, the gas reserves of the gas holder in the future operation plan execution time period are kept to operate in a reasonable interval, and the operation efficiency of the converter gas recovery system is improved.

In the following, the above-described embodiments will be described in detail with reference to the following embodiments:

in an alternative embodiment, as shown in fig. 1, the method for predicting the gas reserves of the converter gas holder comprises:

s1: acquiring a converter production operation plan, the recovery amount of gas per time, the recovery time of gas per time, the current gas storage amount of a gas cabinet and the real-time gas consumption of gas utilization equipment;

specifically, the converter production operation plan is a production operation plan data table compiled and uploaded in the steel-making production execution system, and includes plan information such as how much molten iron needs to be smelted by the converter in the next period of time, and smelting start time and smelting end time of each molten iron during converter smelting.

The recovery amount of the coal gas in each furnace is the total amount of the coal gas which can be recovered in the converter smelting process of the molten iron in one furnace; the coal gas recovery time of each furnace is the coal gas recovery time of the molten iron in the converter smelting process. Generally, the total gas recovery amount and the gas recovery time of a heat are relatively stable, for example, when a furnace of molten iron is smelted in a converter, the gas recovery time is usually 10-14 minutes, and the recovery amount is 2000 cubic meters per minute. Therefore, the total quantity and the recovery time of the coal gas recovered in each furnace can be predetermined and stored for the calling of the subsequent steps.

The current gas reserve of the gas holder is the gas capacity at the current moment. The nominal capacity of a converter gas holder is usually over several ten thousand cubic meters, for example, the nominal capacity of a commonly used dry gas holder is 8 ten thousand cubic meters, wherein the upper limit of the gas is 7 ten thousand cubic meters, and the lower limit is 0.7 ten thousand cubic meters. The real-time gas reserves of the gas cabinet can be obtained by measuring with a measuring element of the gas cabinet, and then the data is uploaded to an INSQL production database system through a DCS control system.

The real-time gas consumption of the gas utilization equipment is the real-time gas consumption of all converter gas users. The gas-using equipment comprises, but is not limited to, gas-using equipment such as a steel-making sleeve kiln, a hot rolling heating furnace, a generator set and the like. Collecting the real-time gas consumption of each gas-using device through a gas flow detection element, such as a flow transmitter, and summarizing to obtain the real-time gas consumption of all the gas-using devices; and the real-time air supply quantity of a gas blower positioned between the gas cabinet and gas equipment can be directly acquired. In this embodiment, the real-time gas usage is expressed by the gas usage in unit time, which may be seconds or minutes, and may also be measured by defining other types of time; and after the real-time gas consumption is obtained, the real-time gas consumption of the gas utilization equipment is uploaded to the INSQL production database system through the PLC control system.

In order to obtain the data, an application program can be programmed to be connected with an INSQL production database and an MES system database, the production operation plan of the converter is obtained from the MES system database, and the current gas storage amount of the gas cabinet and the real-time gas consumption of the gas-using equipment are obtained from the production database system.

S2: determining the real-time coal gas yield in the execution time period of the converter production operation plan according to the converter production operation plan, the recovery time of the coal gas in each time and the recovery amount of the coal gas in each time;

the real-time gas yield is determined according to the total gas recovery amount of each furnace and the gas recovery time of each furnace when a converter production operation plan is executed, and is the real-time gas recovery amount decomposed according to the steelmaking time of the converter. Similarly, the real-time gas production can also be measured by the gas recovery per unit time.

Thus, one method of determining real-time gas production may be:

determining the converter smelting start time of molten iron in each furnace according to the converter production operation plan;

determining the coal gas recovery time period of each heat according to the converter smelting start time of the molten iron in each furnace and the coal gas recovery time of each heat;

and determining the real-time gas yield in the execution time period of the production operation plan of the converter according to the gas recovery quantity of each heat and the gas recovery time period of each heat.

Generally, the coal gas recovery is performed after the start of converter smelting for 10 to 14 minutes. Therefore, the gas recovery time period of each heat in the whole converter production operation plan can be determined according to the gas recovery time and the converter smelting start time of each molten iron in the operation plan.

By the method, the coal gas recovery is decomposed according to the coal gas recovery stage and other stages in the converter smelting process, so that the coal gas recovery amount per unit time at any moment, namely the real-time coal gas yield, is obtained when the converter smelting production plan is executed. In the gas recovery stage, the real-time gas yield is equal to the gas recovery amount of the current heat divided by the gas recovery time of the current heat; in the non-gas recovery stage, the real-time gas yield is zero.

In order to improve the calculation efficiency, the converter production operation plan can be processed into a converter smelting Gantt chart, so that:

generating a converter smelting Gantt chart according to the converter production operation plan;

and determining the converter smelting start time of the molten iron in each furnace according to the converter smelting Gantt chart.

S3: and predicting the gas reserves of the converter gas holder in the execution time period of the converter production operation plan according to the current gas reserves of the gas holder, the real-time gas yield and the real-time gas consumption.

Specifically, after the real-time gas yield and the real-time gas consumption are obtained, the real-time gas yield is subtracted from the real-time gas consumption to obtain a real-time gas variable, the real-time gas variable is overlapped with the current gas reserves of the gas cabinet, and then the real-time gas reserves data in the time period of executing the production operation plan of the converter in the future can be calculated to obtain the change trend of the gas reserves. In order to improve the accuracy of gas reserve calculation, the volume data of a buffer system of the converter gas chamber can be acquired to participate in calculation. Because the current gas reserve data of the gas holder is collected and stored in real time, the scheme supports predicting and updating the gas reserve change trend in the execution time of the production operation plan of the converter at any time.

Optionally, the prediction method further includes:

and adjusting the gas consumption of the gas utilization equipment according to the gas reserve of the converter gas holder in the execution time period of the converter production operation plan.

Specifically, an upper limit value and a lower limit value of the gas holder capacity can be preset, when the fact that the gas reserve in a certain period of time in the future is lower than the lower limit value is detected, a gas use scheduling instruction is sent to converter gas user equipment to inform a user that the gas use amount needs to be reduced in advance, the air supply amount of a converter gas blower between the converter gas holder and the gas using equipment is reduced after scheduling is completed, the gas supply is reduced, and the situation that blast furnace gas or coke mixed gas needs to be co-fired due to insufficient converter gas in the later period is avoided; when the coal gas storage amount in a certain period of time in the future is detected to be higher than the upper limit value, a coal gas use scheduling instruction is sent to converter coal gas user equipment to inform a user that the coal gas use amount can be increased or gas using equipment can be added in the next period of time, if the user does not need to increase the coal gas use amount, the coal gas use amount as a coal gas use amount adjusting user, such as a generator set, can be increased, the air supply amount of a converter coal gas blower is increased after scheduling is completed, coal gas supply is increased, and the situation that the recovery amount of the converter coal gas needs to be reduced due to excessive converter coal gas in the later period is avoided; thereby improving the operation benefit of the converter gas recovery system.

Optionally, the prediction method further includes:

and performing visualization processing on the gas reserves of the converter gas holder in the execution time period of the converter production operation plan to obtain a gas reserve prediction curve in the execution time period.

After the coal gas reserve prediction curve is obtained, the coal gas reserve prediction curve can be sent to a man-machine interaction picture of a steel-making MES system in an operation area, so that an operator can master the volume change trend of a next gas cabinet, and a basis can be provided for the operator to schedule the coal gas consumption of gas-using equipment.

Generally speaking, a production operation plan of a steel-making converter covers a converter scheduling plan of about 6 hours, so the scheme can predict the cabinet volume change condition of the converter gas cabinet within six hours in advance, and can realize the timely adjustment of the converter gas consumption and the gas conversion blower according to the prediction result, thereby improving the operation benefit of the converter gas recovery system.

Based on the same inventive concept of the previous embodiment, in yet another alternative embodiment, as shown in fig. 2, there is provided a system for predicting gas reserves of a converter gas holder, comprising:

the acquisition module 10 is used for acquiring a converter production operation plan, the recovery amount of gas per time, the recovery time of gas per time, the current gas storage amount of a gas cabinet and the real-time gas consumption of gas utilization equipment;

the determining module 20 is configured to determine a real-time gas yield in an execution time period of the converter production operation plan according to the converter production operation plan, the recovery time of the gas in each time and the recovery amount of the gas in each time;

and the prediction module 30 is configured to predict the gas reserves of the converter gas holder in the execution time period of the converter production operation plan according to the current gas reserves of the gas holder, the real-time gas yield and the real-time gas consumption.

In actual implementation, the prediction system can be secondarily developed based on a steel-making manufacturing execution MES information system. FIG. 3 is a schematic diagram of the overall control principle including a prediction system, a steelmaking MES information system and a gas-using equipment. Through programming development, the PLC control system acquires cabinet volume data (namely gas storage volume) of the converter gas cabinet through a cabinet volume detection element, acquires air output data of a converter gas blower and converter gas consumption data generated by gas-using equipment through a flow transmitter, and uploads the data to the INSQL production database system. And uploading the converter smelting operation schedule of the steelmaking to a steelmaking MES information system. And (3) connecting an INSQL production database and an MES information system database by compiling an application program of a prediction system to obtain the real-time tank capacity (namely real-time gas storage capacity) of the converter gas tank, the real-time consumption of each converter gas user and a converter production operation schedule. The real-time coal gas yield of the converter in the planned operation time is obtained by processing the operation schedule of the steel-making converter and combining the coal gas recovery amount and the coal gas recovery time of each time; the real-time gas consumption in the planned operation time is obtained by summarizing the gas consumption of each converter gas user; calculating the gas chamber capacity change data in the planned operation time by combining the gas chamber capacity of the gas chamber at the current moment; after the cabinet volume change data is obtained, a scheduling instruction can be sent to a converter gas user to control a converter gas blower to adjust the gas supply amount. The gas cabinet volume change trend can be visually output on an HMI (human machine interface) picture of an MES (manufacturing execution system) information system, and a basis is provided for scheduling the converter gas consumption of a user.

Optionally, the prediction system further includes an adjusting module, configured to adjust a gas usage amount of the gas utilization equipment according to a gas reserve of the converter gas holder in an execution time period of the converter production operation plan.

Optionally, the prediction system further includes a visualization module, configured to perform visualization processing on the gas reserves of the converter gas holder in the execution time period of the converter production operation plan, so as to obtain a gas reserve prediction curve in the execution time period.

Optionally, the determining module 20 is specifically configured to:

determining the converter smelting start time of molten iron in each furnace according to the converter production operation plan;

determining the coal gas recovery time period of each heat according to the converter smelting start time of the molten iron in each furnace and the coal gas recovery time of each heat;

and determining the real-time gas yield in the execution time period of the production operation plan of the converter according to the gas recovery quantity of each heat and the gas recovery time period of each heat.

Further, the determining module 20 is configured to:

generating a converter smelting Gantt chart according to the converter production operation plan;

and determining the converter smelting start time of the molten iron in each furnace according to the converter smelting Gantt chart.

Optionally, the obtaining module 10 obtains the converter production operation plan from a steel-making manufacturing execution MES system.

Optionally, the obtaining module 10 obtains the current gas reserves of the gas chamber and the real-time gas usage of the gas-using equipment from a production database system.

Based on the same inventive concept as the previous embodiment, in a further alternative embodiment, a converter plant is provided, which comprises the prediction system as in the previous embodiment.

Through one or more embodiments of the present invention, the present invention has the following advantageous effects or advantages:

the invention provides a method for predicting the gas reserves of a converter gas holder, which obtains an accurate converter smelting time plan by obtaining a strictly programmed converter production plan, thereby accurately mastering the converter smelting production rhythm; then obtaining the real-time coal gas yield when the converter smelting production plan is executed according to the recovery amount of the coal gas of each time, the recovery time of the coal gas of each time and the converter production operation plan, namely decomposing the total recovery amount of the converter coal gas according to the steelmaking time of the converter to obtain the real-time recovery amount of the converter coal gas in the whole converter smelting process; the real-time gas storage amount information of the gas cabinet in a preset time period when a converter production operation plan is executed in the future can be predicted by combining the gas storage amount data of the gas cabinet at the current moment and the real-time gas consumption of gas-using equipment; after the future real-time gas reserve information of the gas holder is obtained, the gas consumption of gas equipment for converter gas can be timely adjusted according to the variation trend of the real-time gas reserve, when the capacity of the gas holder or the gas reserve is higher, the gas supply is increased, and the condition of energy waste caused by limited collection of the converter gas when the capacity of the gas holder is higher is reduced; when the capacity of the gas cabinet is low, the gas supply is reduced, and the situation that the energy source configuration is unreasonable due to the co-combustion of blast furnace gas and coke gas mixed gas when the capacity of the gas cabinet is low is reduced. In general, by means of the scheme, the gas reserves of the gas holder in the future operation plan execution time period are kept to operate in a reasonable interval, and the operation efficiency of the converter gas recovery system is improved.

While the preferred embodiments of the present application have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. Therefore, it is intended that the appended claims be interpreted as including preferred embodiments and all alterations and modifications as fall within the scope of the application.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present application without departing from the spirit and scope of the application. Thus, if such modifications and variations of the present application fall within the scope of the claims of the present application and their equivalents, the present application is intended to include such modifications and variations as well.