CN117492604A

CN117492604A - Flue gas treatment method and purification system for garbage incineration

Info

Publication number: CN117492604A
Application number: CN202311467519.6A
Authority: CN
Inventors: 吴浩仑; 谢高峰; 江维
Original assignee: Anhui Zhongyi Environmental Protection New Material Co ltd
Current assignee: Anhui Zhongyi Environmental Protection New Material Co ltd
Priority date: 2023-11-02
Filing date: 2023-11-02
Publication date: 2024-02-02
Anticipated expiration: 2043-11-02
Also published as: CN117492604B

Abstract

The invention provides a flue gas treatment method and a purification system for garbage incineration, which are characterized in that a treatment total model is established, the treatment total model is decomposed based on the functional attribute of treatment equipment to obtain a sub-treatment model, and a model association configuration table is generated by counting the sub-treatment model; the first management end performs data configuration feedback on the model association configuration table to the server, the sub-processing models in the model association configuration table are provided with corresponding second management ends, and each second management end is provided with management configuration authority; generating an interactive display interface based on the corresponding processing total model and sub-processing model, and generating a customized display interface based on the configuration of monitoring equipment corresponding to the sub-processing model by the second management end; and carrying out interface adjustment on the customized display interface according to the monitoring information of the monitoring equipment, and sending a corresponding instruction about flue gas treatment to the second management end or the third management end which is pre-configured after reaching the threshold condition corresponding to the customized display interface.

Description

Flue gas treatment method and purification system for garbage incineration

Technical Field

The invention relates to a data processing technology, in particular to a flue gas treatment method and a purification system for garbage incineration.

Background

Waste incineration is a common waste treatment method, and waste is converted into heat energy and exhaust gas by high-temperature incineration. However, the exhaust gases may contain harmful substances and therefore need to be cleaned by flue gas treatment equipment to ensure that the emissions meet environmental standards.

In the prior art, the management of the flue gas treatment equipment generally depends on the alarm sent by the monitoring equipment to monitor the performance and the exhaust emission of the flue gas treatment equipment, but a manager cannot check the real-time condition of each flow in the flue gas treatment equipment, and the flexibility and the timeliness are lacked, so that the manager cannot intervene and adjust in time according to the real-time condition, the management efficiency is low, and the user experience is low.

Therefore, how to customize and generate a display interface according to a plurality of processing functions of the flue gas processing equipment so that a user can intuitively check the implementation condition of the flue gas processing equipment, thereby realizing timely intervention, reducing the response time of responding to the solution problem, and improving the user experience, and becoming the problem to be solved urgently.

Disclosure of Invention

The embodiment of the invention provides a flue gas treatment method and a purification system for garbage incineration, which can customize and generate a display interface according to a plurality of treatment functions of flue gas treatment equipment so that a user can intuitively check the implementation condition of the flue gas treatment equipment, thereby realizing timely intervention, reducing response time for responding to a solution problem and improving user experience.

In a first aspect of the embodiment of the present invention, there is provided a flue gas treatment method for refuse incineration, including:

the method comprises the steps that a server establishes a processing total model corresponding to the waste incineration flue gas processing equipment, decomposes the corresponding processing total model based on the functional attributes of all the processing equipment to obtain corresponding sub-processing models, counts all the sub-processing models to generate corresponding model association configuration tables, and sends the corresponding model association configuration tables to a first management end;

the first management end performs data configuration on the model association configuration table and feeds the data back to the server so that sub-processing models in the model association configuration table have corresponding second management ends, and each second management end has management configuration authority of the corresponding sub-processing model;

after judging that any second management end has access requirements, the server generates an interactive display interface based on the corresponding processing total model and sub-processing model, and generates a customized display interface based on the configuration of monitoring equipment corresponding to the sub-processing model by the second management end;

and carrying out interface adjustment on the customized display interface according to the monitoring information of the monitoring equipment, and sending a corresponding instruction about flue gas treatment to the second management end or the third management end which is pre-configured after the threshold condition corresponding to the customized display interface is reached.

Optionally, in one possible implementation manner of the first aspect, the server establishes a total processing model corresponding to the flue gas processing device for garbage incineration, decomposes the corresponding total processing model based on the functional attributes of all processing devices to obtain corresponding sub-processing models, counts all sub-processing models to generate a corresponding model association configuration table, and sends the corresponding model association configuration table to the first management end, where the method includes:

the method comprises the steps that a server establishes a total treatment model corresponding to waste incineration flue gas treatment equipment, wherein the total treatment model comprises treatment equipment with different functional attributes;

counting processing equipment with the same functional attribute to construct sub-processing models and generate corresponding sub-labels so as to decompose the total processing model to obtain corresponding sub-processing models;

and counting all sub-labels of the sub-processing models, filling the sub-labels into a model association configuration table, and sending the model association configuration table to a first management end, wherein each sub-label in the model association configuration table is provided with a corresponding unit column.

Optionally, in one possible implementation manner of the first aspect, the data configuration of the model association configuration table is fed back to the server by the first management end, so that the sub-processing models in the model association configuration table have corresponding second management ends, each second management end has management configuration authority of the corresponding sub-processing model, and the method includes:

The first management end performs data configuration on the model association configuration table so that the unit columns of each sub-label are provided with corresponding management labels, and the management labels correspond to the second management end;

after receiving the model association configuration table, the server establishes a new blank unit in the unit column of each sub-label, traverses the monitoring label of the monitoring equipment corresponding to each sub-processing model, fills the monitoring label into the new blank unit and stores the new blank unit.

Optionally, in one possible implementation manner of the first aspect, after determining that an arbitrary second management end has an access requirement, the server generates an interactive display interface based on the corresponding processing total model and the sub-processing model, and generates a custom display interface based on the configuration of the monitoring device corresponding to the sub-processing model by the second management end, where the custom display interface includes:

after judging that any second management end has an access requirement, the server determines corresponding first unit columns based on a model association configuration table and management labels of the second management end, and determines the first number of the first unit columns;

establishing a first display interface corresponding to the total processing models and a second display interface corresponding to the first number, displaying the total processing models in the first display interface, and displaying each sub-processing model in the corresponding second display interface;

Counting processing equipment associated with monitoring equipment corresponding to the monitoring tag in the first unit column, determining a model image corresponding to the sub-processing model by the corresponding processing equipment, establishing corresponding display slots, and setting different first pixel values for each display slot in the second display interface;

and assembling the first display interface and the second display interface into an interactive display interface, counting monitoring information of monitoring equipment corresponding to the monitoring tag in the first unit column, generating a preset interactive table, sending the preset interactive table to the second management end, and obtaining a customized display interface based on configuration of the preset interactive table by the second management end.

Optionally, in one possible implementation manner of the first aspect, the assembling the first display interface and the second display interface into the interactive display interface, counting monitoring information of the monitoring device corresponding to the monitoring tag in the first cell line, generating a preset interactive table, and sending the preset interactive table to the second management end, and obtaining the customized display interface based on configuration of the preset interactive table by the second management end includes:

dividing the second display interfaces into areas to obtain a display area corresponding to the sub-processing model and a display area of the customized display interface, wherein each second display interface corresponds to a display area of one customized display interface;

Counting monitoring information of monitoring equipment corresponding to the monitoring tag in the first unit column to generate a preset interaction table and sending the preset interaction table to the second management end, wherein the preset interaction table comprises an amplitude maximum value statistical grid, an amplitude minimum value statistical grid, a threshold maximum value statistical grid, a threshold minimum value statistical grid and a monitoring statistical grid;

and generating a quantitative display diagram corresponding to each monitoring device based on the configuration of the second management end on the statistical grid in the preset interactive table, and assembling display areas classified to different second display interfaces by different quantitative display diagrams into a customized display interface.

Optionally, in one possible implementation manner of the first aspect, the generating, based on the configuration of the second management end on the statistics grid in the preset interaction table, a quantized display diagram corresponding to each monitoring device, and assembling display areas categorized by different quantized display diagrams into different second display interfaces into a custom display interface includes:

the quantization display diagram is provided with a preset number of scales, the maximum scale and the minimum scale of the quantization display diagram are added based on the maximum amplitude value and the minimum amplitude value, and the scale difference value between the adjacent scales is obtained based on the maximum amplitude value, the minimum amplitude value and the preset number;

Adding scale values to other scales of the quantitative display diagram based on the scale difference value, the maximum scale or the minimum scale;

determining scale marks corresponding to the maximum value and the minimum value of the threshold value in the quantization display diagram to obtain a maximum scale mark and a minimum scale mark of the threshold value, and determining the scale marks corresponding to the monitoring information in the quantization display diagram to obtain a monitoring scale mark;

and determining a target area of the quantization display diagram according to the position of the monitoring scale line, and filling the pixel points of the first pixel value to obtain the quantization display diagram.

Optionally, in one possible implementation manner of the first aspect, the determining, according to the position of the monitoring tick mark, the target area of the quantization display map, and filling the pixel points of the first pixel value to obtain the quantization display map includes:

if the threshold minimum value is the same as the amplitude minimum value and the threshold maximum value is different from the amplitude maximum value, counting all areas between the monitoring scale mark and the minimum scale as target areas;

if the threshold minimum value is different from the amplitude minimum value, and the threshold maximum value is the same as the amplitude maximum value, counting all areas from the monitoring scale mark to the maximum scale mark as target areas;

If the threshold minimum value is different from the amplitude minimum value, the threshold maximum value is different from the amplitude maximum value, and a target area is determined according to the relative positions between the monitoring scale line and the threshold maximum value and between the monitoring scale line and the threshold minimum value;

and determining a first pixel value of the display slot position corresponding to the monitoring label, and adjusting the pixel value of the pixel point of the target area to the first pixel value to obtain a quantized display diagram.

Optionally, in a possible implementation manner of the first aspect, the determining the target area according to the relative position between the monitoring tick mark and the threshold maximum value and the threshold minimum value includes:

acquiring a first position value and a second position value between the monitoring scale mark and a threshold maximum value and a threshold minimum value respectively;

if the first position value is smaller than or equal to the second position value, taking the area between the monitoring scale line and the threshold maximum scale line corresponding to the threshold maximum value as a target area;

and if the first position value is larger than the second position value, taking the area between the monitoring scale line and the minimum threshold scale line corresponding to the minimum threshold value as a target area.

Optionally, in one possible implementation manner of the first aspect, the adjusting the interface of the customized display interface according to the monitoring information of the monitoring device, and sending a corresponding instruction about flue gas treatment to the second management end or the third management end configured in advance after reaching a threshold condition corresponding to the customized display interface, includes:

Dynamically adjusting the monitoring scale marks of the customized display interface according to the monitoring information of the monitoring equipment, and dynamically determining the corresponding target areas;

after judging that the monitoring scale mark is larger than the threshold maximum scale mark or smaller than the threshold minimum scale mark, determining an area between the monitoring scale mark and the threshold maximum scale mark or an area between the monitoring scale mark and the threshold minimum scale mark to obtain a reminding area;

and (3) filling the second pixel value into the pixel point of the reminding area, and sending a corresponding second display interface and an instruction corresponding to the monitoring equipment to a second management end or a preconfigured third management end.

In a second aspect of the embodiments of the present invention, there is provided a flue gas treatment and purification system for refuse incineration, comprising:

the establishing module is used for enabling the server to establish a total treatment model corresponding to the waste incineration flue gas treatment equipment, decomposing the corresponding processing total model based on the functional attributes of all the processing equipment to obtain corresponding sub-processing models, counting all the sub-processing models to generate a corresponding model association configuration table, and sending the corresponding model association configuration table to the first management end;

the configuration module is used for enabling the first management end to carry out data configuration on the model association configuration table and then feed back to the server so that sub-processing models in the model association configuration table have corresponding second management ends, and each second management end has management configuration authority of the corresponding sub-processing model;

The generation module is used for enabling the server to generate an interactive display interface based on the corresponding processing total model and the sub-processing model after judging that any second management end has access requirements, and generating a customized display interface based on the configuration of monitoring equipment corresponding to the sub-processing model by the second management end;

the adjusting module is used for carrying out interface adjustment on the customized display interface according to the monitoring information of the monitoring equipment, and sending a corresponding instruction about flue gas treatment to the second management end or the third management end which is pre-configured after the threshold condition corresponding to the customized display interface is reached.

The beneficial effects of the invention are as follows:

1. according to the invention, the total processing model of the flue gas processing equipment is decomposed into a plurality of sub-processing models according to the functional attributes, and configuration data and monitoring are carried out according to different attributes, so that fine management is realized, corresponding interactive display interfaces and customized display interfaces are generated according to the sub-processing models managed by each second management end, the comprehensive monitoring and management of users are facilitated, the experience of the users is improved, and related monitoring data are checked in time, so that timely intervention is realized. According to the invention, the total processing model is decomposed according to the functional attribute of the processing equipment to obtain sub-processing models, so that follow-up fine management is facilitated, a corresponding second management end is configured for each sub-processing model to carry out follow-up management, when the second management end accesses, an interactive display interface is generated according to the total processing model and the sub-processing models to display a system corresponding to the smoke processing equipment and the sub-processing models, meanwhile, a customized display interface corresponding to each sub-processing model is generated, and interface adjustment is carried out on the customized display interface according to monitoring information, so that a user can conveniently observe monitoring data at each sub-processing model in time to intervene in time, and after a threshold condition corresponding to the customized display interface is reached, a corresponding processing instruction is generated, and automatic intervention is realized.

2. According to the invention, the total treatment model of the flue gas treatment equipment is decomposed according to the functional attribute of the treatment equipment to obtain sub-treatment models, and a corresponding second management end is configured for each sub-treatment model, so that the monitoring data of the sub-treatment models can be conveniently observed and interfered in time by the subsequent second management end. According to the invention, the processing equipment with the same functional attribute in the processing total model is built into the sub-processing model, and the sub-labels of the sub-processing model are filled into the model association configuration table, so that corresponding management labels are conveniently added for the sub-processing model, the second management end corresponds to the corresponding sub-processing model and the corresponding monitoring equipment, when the second management end is conveniently accessed, the display interface and the corresponding monitoring data corresponding to the second management end are automatically called for display, and each management end is conveniently and rapidly positioned to monitor the data, so that the reaction time is reduced, and the user experience is improved.

3. According to the sub-processing models managed by the different second management ends, the interactive display interfaces and the customized display interfaces corresponding to the sub-processing models are customized and generated, so that a user can realize comprehensive monitoring and management, timely locate the relevant monitoring data, timely display the dynamic changes of the data by utilizing the customized display interfaces, and the user can observe and timely intervene conveniently, and experience of the user is improved. The invention constructs the first display interface corresponding to the processing total model and the second display interface corresponding to the sub-processing model, and generates the display slot position in the second display interface to display the processing equipment, thereby facilitating the user to position the corresponding processing equipment, displaying the data in each sub-processing model according to the monitoring data of the monitoring equipment in a quantitative display mode, enabling the user to visually see the real-time state, and generating the reminding area and the corresponding instruction when exceeding the threshold condition, thereby assisting the user to perform quick positioning and automatic processing, improving the user experience, more accurate positioning and improving the management efficiency.

Drawings

FIG. 1 is a flow chart of a flue gas treatment method for refuse incineration provided by the invention;

fig. 2 is a schematic structural diagram of a flue gas treatment and purification system for garbage incineration.

Detailed Description

The technical scheme of the invention is described in detail below by specific examples. The following embodiments may be combined with each other, and some embodiments may not be repeated for the same or similar concepts or processes.

The invention provides a flue gas treatment method for garbage incineration, which is shown in fig. 1 and comprises the following steps of S1-S4:

s1, a server establishes a total treatment model corresponding to the flue gas treatment equipment for garbage incineration, decomposes the corresponding total treatment model based on the functional attributes of all the treatment equipment to obtain corresponding sub-treatment models, counts all the sub-treatment models to generate a corresponding model association configuration table, and sends the corresponding model association configuration table to a first management end.

It should be noted that, the flue gas from the garbage incineration needs to be subjected to multiple stages of treatment, and is subjected to complicated steps, such as high-temperature combustion, dust removal, desulfurization, and pin removal, and different steps have different functions, such as dust removal needs to pass through a bag-type dust removal system, pin removal needs to pass through a pin removal system, and the like, and different monitoring devices and different requirements are provided in different steps, so that the management end alone manages all devices in the flue gas treatment device simultaneously, and the management efficiency is low. Therefore, the method can decompose the total treatment model corresponding to the flue gas treatment equipment according to the functional attribute, and is convenient for the subsequent distribution of different second management ends by taking the functional attribute as a unit for management.

It will be appreciated that the server will build a total treatment model corresponding to the flue gas treatment device for garbage incineration, where the total treatment model includes treatment devices with different functional properties, for example, a dust removal device, a heat exchange device, etc., and the total treatment model may be a model corresponding to the flue gas treatment device.

Further, the corresponding total treatment model is decomposed according to the functional attributes of all the treatment equipment to obtain corresponding sub-treatment models, wherein the sub-treatment models at least comprise one or more of a lime slurry preparation system, an absorption tower system, a bag-type dust removal system, a heat recovery system, a denitration system and a desulfurization system, and the functional attributes can be functions of dust removal, heat recovery and the like.

Through the embodiment, the processing equipment is decomposed according to the functional attribute of the processing equipment, so that different sub-processing models corresponding to different functional attributes are obtained, multi-terminal simultaneous management is realized, and management efficiency is improved.

Further, all sub-processing models are counted to generate corresponding model association configuration tables, and the corresponding model association configuration tables are sent to the first management end.

In some embodiments, in step S1 (the server establishes a total treatment model corresponding to the flue gas treatment device for garbage incineration, decomposes the corresponding total treatment model based on the functional attributes of all the treatment devices to obtain corresponding sub-treatment models, counts all the sub-treatment models to generate a corresponding model association configuration table and sends the corresponding model association configuration table to the first management end), and includes S11-S12:

S11, the server establishes a total treatment model corresponding to the waste incineration flue gas treatment equipment, wherein the total treatment model comprises treatment equipment with different functional attributes.

It will be appreciated that the server will build a total model of the treatment corresponding to the flue gas treatment devices for waste incineration, i.e. a model corresponding to all flue gas treatment devices. Wherein the total processing model comprises processing equipment with different functional attributes, such as a bag-type dust collector, a heat exchanger and the like.

S12, counting processing equipment with the same functional attribute to construct a sub-processing model and generating a corresponding sub-label so as to decompose the total processing model to obtain a corresponding sub-processing model.

It can be understood that the server may count that the processing devices with the same functional attribute construct a sub-processing model and generate corresponding sub-tags, for example, the functions of both the bag-type dust collector and the dust collector are for flue gas dust removal, so that the processing devices with the dust removal function construct corresponding sub-processing models and generate corresponding sub-tags. So as to realize the decomposition of the total processing model to obtain a corresponding sub-processing model. Each sub-processing model has a corresponding sub-label, for example, the bag-type dust removing system is A1, and the label is manually preset and is not limited herein.

Through the embodiment, the total treatment model of the flue gas treatment equipment is decomposed by utilizing functions corresponding to different procedures to obtain a plurality of sub-treatment models, so that each sub-treatment model corresponds to one functional attribute, such as dust removal, heat recovery and the like.

S13, counting all sub-labels of the sub-processing models, filling the sub-labels into a model association configuration table, and sending the model association configuration table to a first management end, wherein each sub-label in the model association configuration table has a corresponding unit column.

It can be understood that the server counts that the sub-labels of all the sub-processing models are filled into a model association configuration table and sent to the first management end, where the model association configuration table is a table for performing association configuration on all the sub-processing models and the corresponding second management end. And, each sub-tag in the model association configuration table has a corresponding cell column.

S2, the first management end performs data configuration on the model association configuration table and feeds the data back to the server so that sub-processing models in the model association configuration table have corresponding second management ends, and each second management end has management configuration authority of the corresponding sub-processing model.

It can be understood that the first management end performs data configuration on the model association configuration table and feeds back the data configuration to the server, so that the sub-processing models in the model association configuration table have corresponding second management ends, that is, the corresponding second management ends are configured for each sub-processing model, and each second management end has management configuration authority of the corresponding sub-processing model, for example, a threshold is configured for the monitoring device in each sub-processing model.

In some embodiments, the step S2 (the first management end performs data configuration on the model association configuration table and feeds back to the server, so that the sub-processing models in the model association configuration table have corresponding second management ends, each second management end has a management configuration authority of the corresponding sub-processing model) includes S21-S22:

s21, the first management end performs data configuration on the model association configuration table so that the unit columns of each sub-label are provided with corresponding management labels, and the management labels correspond to the second management end.

It can be understood that the first management end performs data configuration on the model association configuration table, that is, configures a corresponding management tag for each sub-tag in the model association configuration table, so that the unit column of each sub-tag has a corresponding management tag, and the management tag corresponds to the second management end, so that each sub-processing model has a corresponding second management end.

S22, after receiving the model association configuration table, the server establishes a new blank unit in the unit column of each sub-label, traverses the monitoring label of the monitoring device corresponding to each sub-processing model, fills the monitoring label into the new blank unit and stores the new blank unit.

It can be understood that after the server receives the model association configuration table, i.e. after completing configuration of the corresponding second management end for the sub-processing model, a new blank unit is built in a unit column of each sub-label, for example, a blank unit is built in a unit column corresponding to an A1 sub-label of the bag-type dust removal system, where the unit column is a column region filled with information of each sub-processing model, it is easy to understand that the sub-label A1 has a row column region corresponding to the sub-label, each sub-label has a corresponding region, for example, each row in the table corresponds to a unit column, so that the monitoring label corresponding to the sub-label is conveniently filled in a unit column, the sub-processing model corresponds to a monitoring device corresponding to the sub-label, and the monitoring data of the monitoring device of the sub-processing model is convenient to be counted in a subsequent manner.

Further, the server traverses the monitoring label of the monitoring device corresponding to each sub-processing model, fills the monitoring label into a new blank unit for storage, so that the monitoring device corresponding to the sub-processing model is counted, and the subsequent counting and displaying of the monitoring data of each sub-processing model are facilitated. The monitoring device can be a temperature sensor, a humidity sensor, a smoke concentration sensor and the like.

S3, after judging that any second management end has access requirements, the server generates an interactive display interface based on the corresponding processing total model and sub-processing model, and generates a customized display interface based on the configuration of monitoring equipment corresponding to the sub-processing model by the second management end.

It can be understood that after the server determines that any second management end has an access requirement, the server generates an interactive display interface based on the processing total model and the corresponding sub-processing model, and generates a customized display interface based on the configuration of the monitoring device corresponding to the sub-processing model by the second management end.

In some embodiments, step S3 (after the server determines that any second management end has an access requirement, generating an interactive display interface based on the corresponding overall processing model and the sub-processing model, and generating a customized display interface based on the configuration of the monitoring device corresponding to the sub-processing model by the second management end) includes S31-S34:

s31, after judging that any second management end has access requirements, the server determines corresponding first unit columns based on the model association configuration table and management labels of the second management end, and determines first number of the first unit columns.

It can be understood that after the server determines that any second management end has an access requirement, the server associates the unit columns having the same management label with the configuration table based on the management label positioning model of the second management end as the first unit columns, so as to obtain a plurality of first unit columns corresponding to the second management end. And a first number of first cell bars may be determined.

S32, a first display interface corresponding to the total processing models and a second display interface corresponding to the first number are established, the total processing models are displayed in the first display interface, and each sub-processing model is displayed in the corresponding second display interface.

It can be understood that the server constructs a first display interface corresponding to the total processing model, constructs a first number of second display interfaces, and displays the total processing model in the first display interface, and displays each sub-processing model in the corresponding second display interface.

S33, processing equipment associated with the monitoring equipment corresponding to the monitoring tag in the first unit column is counted, corresponding model images of the corresponding processing equipment in the sub-processing model are determined, corresponding display slots are established, and different first pixel values are set for each display slot in the second display interface.

It can be understood that the server counts the processing devices associated with the monitoring devices corresponding to the monitoring tags in the first unit columns, for example, the monitoring devices corresponding to the monitoring tags in the first unit columns are smoke concentration sensors, and the associated processing devices are bag-type dust collectors.

Further, the server determines the model image corresponding to the sub-processing model of the processing device and establishes a corresponding display slot, for example, determines the corresponding model image of the bag-type dust collector in the bag-type dust collection system and establishes a display slot at the position of the model image, for example, the display slot may be a rectangular frame, which is not limited herein, and the display slot is constructed on the picture of the bag-type dust collector, so as to facilitate subsequent display of monitoring information of the monitoring device inside the bag-type dust collector, for example, concentration information monitored by the smoke concentration sensor. The display slot is a slot for displaying monitoring information.

And a different first pixel value is set for each display slot in the second display interface, which may be a different first pixel value for a background color of each display slot, for example, blue, green, and other backgrounds.

S34, assembling the first display interface and the second display interface into an interactive display interface, counting monitoring information of monitoring equipment corresponding to the monitoring tag in the first unit column, generating a preset interactive table, sending the preset interactive table to the second management end, and obtaining a customized display interface based on configuration of the second management end on the preset interactive table.

It is easy to understand that, because the processing equipment and the flow of the flue gas processing device are numerous, the sub-processing models are numerous, and the number of the corresponding second display interfaces of each second management end is numerous, so that the display cannot be performed in the same display screen at the same time, and therefore, the invention can perform folding combined display.

It can be understood that the server folds and assembles the first display interface and the second display interface into an interactive display interface, for example, one first display interface and two second display interfaces, folds and combines 3 display interfaces, and displays the 3 display interfaces in the form of page numbers, wherein the first page is the first display interface, the second page is one of the second display interfaces, the third page is the other second display interface, and the subsequent management end can select one of the second display interfaces for displaying.

Further, monitoring information of monitoring equipment corresponding to the monitoring tag in the first unit column is counted, a preset interaction table is generated and sent to the second management end, and a customized display interface is obtained based on configuration of the second management end on the preset interaction table. The preset interaction table is a table for counting monitoring information of all monitoring tags corresponding to the monitoring equipment in the first unit column.

In some embodiments, in step S34 (assembling the first display interface and the second display interface into an interactive display interface, counting monitoring information of the monitoring device corresponding to the monitoring tag in the first cell line, generating a preset interactive table, and sending the preset interactive table to the second management end, and obtaining a customized display interface based on configuration of the preset interactive table by the second management end), the method includes S341-S343:

s341, carrying out region division on the second display interfaces to obtain a display region corresponding to the sub-processing model and a display region of the customized display interface, wherein each second display interface corresponds to a display region of one customized display interface.

It can be understood that the server may perform region division on the second display interfaces to obtain a display region of the corresponding sub-processing model and a display region of the custom display interface, where each second display interface has a display region corresponding to one custom display interface.

It is easy to understand that the second display interface displays sub-processing models, each sub-processing model corresponds to different functional attributes and can be understood as different processing flows, and each flow is provided with different monitoring devices for monitoring the current condition, so that the invention configures a corresponding custom display interface for monitoring information detected by the monitoring devices in each sub-processing model, for example, a bag dust removal system is displayed in the upper half area, a display slot is established at a bag dust remover in the bag dust removal system, data monitored by sensors in the bag dust removal system, for example, concentration information is displayed in the lower half area, and the custom display interface corresponding to the concentration information is displayed in the lower half area. The method and the system enable the subsequent user to observe the sub-processing model and simultaneously view the dynamic change of the monitoring information in the sub-processing model, and are convenient for the manager to visually check and manage.

S342, counting monitoring information of monitoring equipment corresponding to the monitoring tag in the first unit column, generating a preset interaction table, and sending the preset interaction table to the second management end, wherein the preset interaction table comprises an amplitude maximum value statistical grid, an amplitude minimum value statistical grid, a threshold maximum value statistical grid, a threshold minimum value statistical grid and a monitoring statistical grid.

It can be understood that the server may count the monitoring information of the monitoring device corresponding to the monitoring tag in the first cell line, generate a preset interaction table, and send the preset interaction table to the second management end, where the preset interaction table includes an amplitude maximum value statistics cell, an amplitude minimum value statistics cell, a threshold maximum value statistics cell, a threshold minimum value statistics cell, and a monitoring statistics cell, and the monitoring statistics cell is a cell for counting the monitoring information.

S343, generating a quantitative display diagram corresponding to each monitoring device based on the configuration of the statistical grid in the preset interactive table by the second management end, classifying different quantitative display diagrams into display areas of different second display interfaces, and assembling the display areas into a customized display interface.

It can be understood that, based on the configuration of the statistical grid in the preset interactive table by the second management end, a quantized display diagram corresponding to each monitoring device is generated, and display areas of different quantized display diagrams classified to different second display interfaces are assembled into a customized display interface, that is, different quantized display diagrams are classified to display areas of the second display interfaces corresponding to the different quantized display diagrams and assembled into the customized display interface. For example, classifying a quantitative display diagram generated by a smoke concentration sensor in the bag-type dust collector into a lower half area of a second display interface corresponding to the bag-type dust collection system for display, so as to obtain a customized display interface.

It is to be understood that the second management end may configure corresponding data for the maximum amplitude statistics, the minimum amplitude statistics, the maximum threshold statistics, and the minimum threshold statistics in the preset interaction table, which may be manually preset.

In some embodiments, in step S343 (generating a quantized display diagram corresponding to each monitoring device based on the configuration of the second management end to the statistics in the preset interaction table, and assembling the display areas categorized to different second display interfaces into a customized display interface by different quantized display diagrams) includes S3431-S3434:

and S3431, the quantization display diagram is provided with a preset number of scales, the maximum scale and the minimum scale of the quantization display diagram are added based on the maximum value and the minimum value of the amplitude, and the scale difference value between the adjacent scales is obtained based on the maximum value, the minimum value and the preset number of the amplitude.

It should be noted that the quantization display chart can be understood as a rectangular chart similar to the thermometer for displaying the temperature, and the quantization display chart has a preset number of scales, so that the corresponding scale values can be conveniently added later.

It can be understood that the quantization display diagram has a preset number of scales, the maximum scale and the minimum scale of the quantization display diagram are added based on the maximum value and the minimum value of the amplitude, and the scale difference between the adjacent scales is obtained based on the maximum value and the minimum value of the amplitude and the preset number.

It is to be understood that, according to the ratio of the difference value between the maximum amplitude value and the minimum amplitude value to the preset number, the scale difference value between the adjacent scales is obtained, that is, the maximum amplitude value is added to the uppermost scale in the quantization display diagram, the minimum amplitude value is added to the lowermost scale in the quantization display diagram, and then the scale values are sequentially added in a superimposed manner from bottom to top according to the scale difference value.

And S3432, adding scale values to other scales of the quantitative display diagram based on the scale difference value, the maximum scale or the minimum scale.

S3433, determining the graduation marks corresponding to the maximum value and the minimum value of the threshold value in the quantization display diagram to obtain the maximum graduation mark and the minimum graduation mark of the threshold value, and determining the graduation marks corresponding to the monitoring information in the quantization display diagram to obtain the monitoring graduation marks.

It should be noted that, the server may determine the graduation line corresponding to the maximum value and the minimum value of the threshold in the quantization display chart, where the maximum value and/or the minimum value of the threshold may or may not exist, for example, the temperature may have the maximum value of the threshold, but the minimum value of the threshold does not exist, which is specifically set according to the actual situation corresponding to the sub-processing module.

It can be understood that the server determines the graduation marks corresponding to the fixed threshold maximum value and the threshold minimum value in the quantization display diagram, obtains the threshold maximum graduation mark and the threshold minimum graduation mark, and determines the graduation mark corresponding to the monitoring information in the quantization display diagram, so as to obtain the monitoring graduation mark. The maximum value and the minimum value of the threshold are the maximum value and the minimum value in a reasonable interval preset by a user, and the monitoring scale mark is obtained according to the scale mark corresponding to the monitoring information in the quantitative display diagram, namely, the corresponding scale mark is determined in the quantitative display diagram to be used as the monitoring scale mark according to the currently monitored monitoring data.

Through the mode, the follow-up user can intuitively check the condition of the current monitoring data, and when the follow-up user is not located in a reasonable interval, the problem is indicated, and the follow-up user can directly process the problem.

And S3434, determining a target area of the quantization display diagram according to the position of the monitoring scale mark, and filling the pixel points of the first pixel value to obtain the quantization display diagram.

It is easy to understand that the method and the device can determine the target area of the quantitative display chart according to the position of the monitoring scale mark, namely, determine the target area of the quantitative display chart according to the current monitoring condition and the monitoring scale mark, deepen and display the target area, and display the real-time temperature through the mercury part in a thermometer similar to the mercury part. And the target area is filled with the corresponding first pixel value, so that the target area corresponds to the corresponding display slot phase, and the observation is convenient.

In some embodiments, in step S3434 (determining the target area of the quantization display map according to the position of the monitoring tick mark and filling the pixel points of the first pixel value to obtain the quantization display map) includes S34341-S34344:

and S34341, if the threshold minimum value is the same as the amplitude minimum value and the threshold maximum value is different from the amplitude maximum value, counting all areas from the monitoring scale line to the minimum scale as target areas.

It will be appreciated that if the server determines that the threshold minimum value is the same as the amplitude minimum value, that is, it may be understood that the threshold minimum value is not set at this time, and the threshold maximum value is different from the amplitude maximum value, that is, the threshold maximum value is set, for example, the amplitude maximum value is 100, and the threshold maximum value is 90, which are different at this time. For example, the temperature sensor is used for monitoring the temperature of the environment, and the minimum value is not required to be set, but the temperature is required to be ensured not to be too high so as not to influence the normal work of personnel. The maximum value of the threshold is a maximum critical value preset by people, and the minimum value of the threshold is a minimum critical value preset by people.

Furthermore, since only the threshold maximum value is set, the scale value of the subsequent monitoring scale line is only required to be ensured not to be larger than the threshold maximum value, and if the scale value exceeds the threshold maximum value, a corresponding instruction is sent to perform automatic early warning, so that all areas between the monitoring scale line and the minimum scale are counted as target areas. The area between the monitoring graduation mark and the minimum graduation mark is displayed directly, namely, the normal area is displayed.

And S34342, if the threshold minimum value is different from the amplitude minimum value and the threshold maximum value is the same as the amplitude maximum value, counting all areas from the monitoring scale mark to the maximum scale mark as target areas.

It will be appreciated that if it is determined that the threshold minimum value is different from the amplitude minimum value, i.e. the threshold minimum value is set at this time, the threshold minimum value is different from the amplitude minimum value, e.g. the amplitude minimum value is 0, the threshold minimum value is 10, and the threshold maximum value is the same as the amplitude maximum value, i.e. the threshold maximum value is not set at this time.

Furthermore, since only the threshold minimum value is set, the scale value of the subsequent monitoring scale line is only required to be ensured to be not smaller than the threshold minimum value, namely, all areas above the threshold minimum value are normal areas, and once the scale value is lower than the threshold minimum value, an instruction is sent to perform automatic early warning. Therefore, at this time, all areas between the monitoring graduation line and the maximum graduation line are counted as target areas, namely, normal areas are displayed, and the graduation line corresponding to the minimum threshold value corresponds to the warning line.

And S34343, if the threshold minimum value is different from the amplitude minimum value and the threshold maximum value is different from the amplitude maximum value, determining a target area according to the relative positions of the monitoring scale line, the threshold maximum value and the threshold minimum value.

It will be appreciated that if it is determined that the threshold minimum value is different from the amplitude minimum value, i.e. the threshold minimum value is set at this time, the threshold minimum value is thus different from the amplitude minimum value, and the threshold maximum value is different from the amplitude maximum value, i.e. the threshold maximum value is set at this time, it will be appreciated that the threshold maximum value and the threshold minimum value are set at the same time. At this time, the area between the scale marks with 2 warning scale marks is used as a target area, and the area between the scale marks with the closest scale marks corresponding to the minimum threshold value or the maximum threshold value is used as a target area, so that the user can watch the scale marks conveniently and remind the user in time.

Further, the target area is determined according to the relative positions of the monitoring scale line, the threshold maximum value and the threshold minimum value.

In some embodiments, in step S34343 (determining the target area according to the relative position between the monitoring tick mark and the threshold maximum value, the threshold minimum value) includes:

And acquiring a first position value and a second position value between the monitoring scale line and the threshold maximum value and the threshold minimum value respectively.

It will be appreciated that the server will obtain a first position value and a second position value between the monitoring tick mark and the threshold maximum value and the threshold minimum value, respectively.

The first position value is the absolute value of the difference value between the monitoring information corresponding to the monitoring scale line and the maximum value of the threshold value, and the second position value is the absolute value of the difference value between the monitoring information corresponding to the monitoring scale line and the minimum value of the threshold value. I.e. the value of the difference between the monitoring information and the threshold maximum and minimum values.

And if the first position value is smaller than or equal to the second position value, taking the area between the monitoring scale line and the threshold maximum scale line corresponding to the threshold maximum value as a target area.

It can be understood that if the first position value is smaller than or equal to the second position value, the monitored scale line is close to the threshold maximum scale line, and the area between the monitored scale line and the threshold maximum scale line corresponding to the threshold maximum value is taken as the target area. It is to be understood that, since the monitoring scale line is closer to the threshold maximum scale line, it is understood that the monitoring scale line is closer to the upper warning scale line, and therefore, the area between the monitoring scale line and the threshold maximum scale line is taken as the target area, that is, when the target area is displayed, no abnormality occurs, and when the target area is not present, it is indicated that the abnormality occurs at this time, and then a corresponding instruction is sent to the management end for management.

It can be understood that if the first position value is greater than the second position value, it indicates that the monitored scale line is close to the threshold minimum scale line at this time, and the area between the monitored scale line and the threshold minimum scale line corresponding to the threshold minimum value is taken as the target area. It is to be understood that, since the monitoring scale line is closer to the minimum threshold scale line, it is understood that the monitoring scale line is closer to the lower warning scale line, so that the area between the monitoring scale line and the minimum threshold scale line is taken as the target area, that is, when the target area is displayed, no abnormality occurs, and when the target area is not displayed, the abnormality is indicated, and then a corresponding instruction is sent to the management end for management.

S34344, determining a first pixel value of the display slot corresponding to the monitoring label, and adjusting the pixel value of the pixel point of the target area to the first pixel value to obtain a quantized display diagram.

It can be understood that the server determines a first pixel value of the display slot corresponding to the monitoring tag, and then adjusts the pixel value of the pixel point of the target area to the first pixel value to obtain the quantized display map. The color of the display slot position of the same monitoring equipment at the sub-processing model and the color of the target area are unified into one color, so that the user can check conveniently.

And S4, carrying out interface adjustment on the customized display interface according to the monitoring information of the monitoring equipment, and sending a corresponding instruction about flue gas treatment to the second management end or the third management end which is pre-configured after the threshold condition corresponding to the customized display interface is reached.

It can be understood that the server can carry out interface adjustment on the customized display interface according to the monitoring information of the monitoring equipment, so that the invention can dynamically display the monitoring information through the customized display interface, and is convenient for a user to monitor and manage in time.

Further, after reaching the threshold condition corresponding to the customized display interface, a corresponding instruction about flue gas treatment is sent to the second management end or the third management end configured in advance, for example, after reaching the threshold condition, a corresponding treatment instruction, for example, an instruction that the temperature is too high and needs to be reduced is generated, so that automatic treatment is realized.

In some embodiments, in step S4 (interface adjustment is performed on the customized display interface according to the monitoring information of the monitoring device, and a corresponding instruction about flue gas treatment is sent to the second management end or the third management end configured in advance after reaching the threshold condition corresponding to the customized display interface), including S41-S4:

S41, dynamically adjusting the monitoring scale marks of the customized display interface according to the monitoring information of the monitoring equipment, and dynamically determining the corresponding target areas.

It can be understood that the server dynamically adjusts the monitoring scale line of the customized display interface according to the monitoring information of the monitoring device, and dynamically determines the corresponding target area. It is understood that the monitoring information such as temperature, concentration and the like is dynamically changed and can be displayed in real time according to the monitoring data.

S42, after judging that the monitoring scale mark is larger than the threshold maximum scale mark or smaller than the threshold minimum scale mark, determining the area between the monitoring scale mark and the threshold maximum scale mark or the area between the monitoring scale mark and the threshold minimum scale mark to obtain a reminding area.

It can be understood that after the server judges that the monitoring scale line is greater than the threshold maximum scale line or less than the threshold minimum scale line, that is, when an abnormality occurs at this time, the area between the monitoring scale line and the threshold maximum scale line or the area between the monitoring scale line and the threshold minimum scale line is determined to obtain the reminding area. That is, the area where the monitor tick mark exceeds the threshold maximum tick mark portion and the area where the monitor tick mark is lower than the threshold minimum tick mark are used as the alert area.

S43, filling second pixel values into the pixel points of the reminding area, and sending corresponding second display interfaces and instructions corresponding to the monitoring equipment to a second management end or a preconfigured third management end.

It can be understood that the server fills the pixel points of the reminding area with the second pixel values, for example, red, and sends the corresponding second display interface and the instruction corresponding to the monitoring device to the second management end or the preconfigured third management end. That is, the second display interface where the abnormality occurs and the instruction corresponding to the abnormality are sent to the second management end or the third management end configured in advance to manage, and the third management end may be a management end configured in advance to handle the abnormal situation.

Referring to fig. 2, a schematic structural diagram of a flue gas treatment and purification system for garbage incineration according to an embodiment of the present invention includes:

The present invention also provides a storage medium having stored therein a computer program for implementing the methods provided by the various embodiments described above when executed by a processor.

The storage medium may be a computer storage medium or a communication medium. Communication media includes any medium that facilitates transfer of a computer program from one place to another. Computer storage media can be any available media that can be accessed by a general purpose or special purpose computer. For example, a storage medium is coupled to the processor such the processor can read information from, and write information to, the storage medium. In the alternative, the storage medium may be integral to the processor. The processor and the storage medium may reside in an application specific integrated circuit (Application Specific Integrated Circuits, ASIC for short). In addition, the ASIC may reside in a user device. The processor and the storage medium may reside as discrete components in a communication device. The storage medium may be read-only memory (ROM), random-access memory (RAM), CD-ROMs, magnetic tape, floppy disk, optical data storage device, etc.

The present invention also provides a program product comprising execution instructions stored in a storage medium. The at least one processor of the device may read the execution instructions from the storage medium, the execution instructions being executed by the at least one processor to cause the device to implement the methods provided by the various embodiments described above.

In the above embodiments of the terminal or the server, it should be understood that the processor may be a central processing unit (english: central Processing Unit, abbreviated as CPU), or may be other general purpose processors, digital signal processors (english: digital Signal Processor, abbreviated as DSP), application specific integrated circuits (english: application Specific Integrated Circuit, abbreviated as ASIC), or the like. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like. The steps of a method disclosed in connection with the present invention may be embodied directly in a hardware processor for execution, or in a combination of hardware and software modules in a processor for execution.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the invention.

Claims

1. A flue gas treatment method for refuse incineration, characterized by comprising:

2. A flue gas treatment method for refuse incineration according to claim 1, characterised in that,

the server establishes a processing total model corresponding to the waste incineration flue gas processing equipment, decomposes the corresponding processing total model based on the functional attributes of all the processing equipment to obtain corresponding sub-processing models, counts all the sub-processing models to generate a corresponding model association configuration table, and sends the corresponding model association configuration table to a first management end, and the method comprises the following steps:

3. A flue gas treatment method for refuse incineration according to claim 2, characterised in that,

the first management end performs data configuration on the model association configuration table and feeds back to a server so that sub-processing models in the model association configuration table have corresponding second management ends, each second management end has management configuration authority of the corresponding sub-processing model, and the method comprises the following steps:

4. A flue gas treatment method for refuse incineration according to claim 3, characterised in that,

after judging that any second management end has access requirements, the server generates an interactive display interface based on the corresponding processing total model and sub-processing model, and generates a customized display interface based on the configuration of monitoring equipment corresponding to the sub-processing model by the second management end, and the method comprises the following steps:

5. A flue gas treatment method for refuse incineration according to claim 4, characterised in that,

the step of assembling the first display interface and the second display interface into an interactive display interface, counting the monitoring information of the monitoring equipment corresponding to the monitoring tag in the first unit column, generating a preset interactive table, sending the preset interactive table to the second management end, and obtaining a customized display interface based on the configuration of the second management end to the preset interactive table, wherein the step of obtaining the customized display interface comprises the following steps:

6. A flue gas treatment method for refuse incineration according to claim 5, characterised in that,

generating a quantized display diagram corresponding to each monitoring device based on the configuration of the second management end on the statistics grid in the preset interaction table, and assembling display areas classified to different second display interfaces by different quantized display diagrams into custom display interfaces, wherein the method comprises the following steps:

7. A flue gas treatment method for refuse incineration according to claim 6, characterised in that,

the method for determining the target area of the quantization display diagram according to the position of the monitoring scale mark and filling the pixel points of the first pixel value to obtain the quantization display diagram comprises the following steps:

8. A flue gas treatment method for refuse incineration according to claim 7, characterised in that,

the determining the target area according to the relative positions of the monitoring scale line, the threshold maximum value and the threshold minimum value comprises the following steps:

9. A flue gas treatment method for refuse incineration according to claim 6, characterised in that,

the interface adjustment is performed on the customized display interface according to the monitoring information of the monitoring device, and after the threshold condition corresponding to the customized display interface is reached, a corresponding instruction about flue gas treatment is sent to the second management end or the third management end which is pre-configured, including:

10. A flue gas treatment clean system for msw incineration, its characterized in that includes: