CN117139317A - Cement solid waste processing system dust treatment device - Google Patents

Abstract

The application discloses a dust treatment device of a cement solid waste treatment system, which relates to the technical field of cement solid waste treatment and comprises the following components: analyzing the cement solid waste treatment process, reading basic information of each process treatment device, and generating a preset dust amount identification result; establishing equipment space coordinates; collecting plant data and extracting plant characteristics; and establishing the spatial distribution of equipment by using equipment spatial coordinates, analyzing the dust treatment influence through plant characteristics, generating a dust treatment influence mark, configuring the equipment position and the equipment power of the negative pressure dust removal equipment by combining the preset dust quantity mark result, and executing dust treatment control. The application solves the technical problem that dust generated in the cement solid waste treatment process in the prior art is harmful to the environment and human body, and achieves the technical effect of effectively treating the dust generated in the cement solid waste treatment by intelligently controlling the negative pressure dust removal equipment.

Description

Cement solid waste processing system dust treatment device

Technical Field

The application relates to the technical field of cement solid waste treatment, in particular to a dust treatment device of a cement solid waste treatment system.

Background

The solid waste generated in the cement production process is called cement solid waste, and can be divided into clinker production solid waste, cement grinding solid waste, household garbage and the like, and the solid waste is decomposed, crushed and reused through a solid waste treatment system, so that the pollution to the environment can be avoided, the resource recovery can be realized, the purposes of energy conservation and emission reduction are achieved, but dust is generated due to the operation of solid waste decomposition and the like in the solid waste treatment process, the pollution is caused to the surrounding environment, and the physical health of surrounding people is endangered.

Disclosure of Invention

The application provides a dust treatment device of a cement solid waste treatment system, which is used for solving the technical problem that dust generated in the cement solid waste treatment process in the prior art causes harm to the environment.

In a first aspect of the application, there is provided a dust treatment method for a cement solid waste treatment system, the method comprising: analyzing a cement solid waste treatment process, reading basic information of each process treatment device, and generating a preset dust quantity identification result according to an analysis result and the basic information; establishing equipment space coordinates, wherein the equipment space coordinates are obtained by establishing a unique coordinate axis in a processing factory, and the equipment space coordinates comprise dust release coordinates; collecting factory building data of the processing factory and extracting factory building features, wherein the factory building features comprise wall surface blocking features, corner features and environment features; establishing the spatial distribution of equipment by using the equipment spatial coordinates, using the dust release coordinates as released equipment reference coordinates, and performing impact analysis of dust treatment by using the plant characteristics to generate a dust treatment impact mark; configuring equipment positions and equipment powers of the negative pressure dust removing equipment according to the preset dust amount identification result and the dust treatment influence identification, and distributing the negative pressure dust removing equipment according to the configuration result; and executing dust treatment control by the negative pressure dust removing equipment.

In a second aspect of the present application, there is provided a dust treatment apparatus for a cement solid waste treatment system, the system comprising: the device comprises a preset dust quantity identification result generation module, a cement solid waste treatment process analysis module and a cement solid waste treatment module, wherein the preset dust quantity identification result generation module is used for analyzing cement solid waste treatment processes, reading basic information of each process treatment device and generating a preset dust quantity identification result according to analysis results and the basic information; the equipment space coordinate establishing module is used for establishing equipment space coordinates, the equipment space coordinates are obtained by establishing unique coordinate axes in a processing factory, and the equipment space coordinates comprise dust release coordinates; the factory building feature extraction module is used for collecting factory building data of the processing factory and extracting factory building features, wherein the factory building features comprise wall surface blocking features, corner features and environment features; the dust treatment influence identification generation module is used for establishing the space distribution of equipment by using the equipment space coordinates, taking the dust release coordinates as released equipment reference coordinates, and analyzing the influence of dust treatment by the plant characteristics to generate a dust treatment influence identification; the negative pressure dust removing equipment distribution module is used for configuring equipment positions and equipment powers of the negative pressure dust removing equipment according to the preset dust amount identification result and the dust treatment influence identification, and distributing the negative pressure dust removing equipment according to the configuration result; and the first dust treatment control module is used for executing dust treatment control by the negative pressure dust removing equipment.

One or more technical schemes provided by the application have at least the following technical effects or advantages:

the application provides a dust treatment method of a cement solid waste treatment system, which relates to the technical field of cement solid waste treatment, and generates a preset dust amount identification result by analyzing a cement solid waste treatment process and reading basic information of each process treatment device; establishing equipment space coordinates including dust release coordinates; collecting plant data and extracting plant characteristics; the space distribution of the equipment is established by the equipment space coordinates, the dust treatment influence analysis is carried out through plant features, the dust treatment influence mark is generated, the equipment position and the equipment power of the negative pressure dust removal equipment are configured by combining the preset dust quantity mark result, the dust treatment control is carried out, the technical problem that dust generated in the cement solid waste treatment process in the prior art is harmful to the environment and human body is solved, and the technical effect that the dust generated in the cement solid waste treatment is effectively treated by the intelligent control negative pressure dust removal equipment is realized.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings required for the description of the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments of the present application, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic flow chart of a dust treatment method of a cement solid waste treatment system according to an embodiment of the application;

fig. 2 is a schematic flow chart of a dust treatment influence mark obtained in a dust treatment method of a cement solid waste treatment system according to an embodiment of the present application;

fig. 3 is a schematic flow chart of dust treatment control optimization of a negative pressure dust removal device performed by feedback control information in a dust treatment method of a cement solid waste treatment system according to an embodiment of the present application;

fig. 4 is a schematic structural diagram of a dust treatment device of a cement solid waste treatment system according to an embodiment of the present application.

Reference numerals illustrate: the device comprises a predetermined dust amount identification result generation module 11, an equipment space coordinate establishment module 12, a factory building feature extraction module 13, a dust treatment influence identification generation module 14, a negative pressure dust removal equipment distribution module 15 and a first dust treatment control module 16.

Detailed Description

The application provides a dust treatment method of a cement solid waste treatment system, which is used for solving the technical problem that dust generated in the cement solid waste treatment process in the prior art has harm to the environment and human body.

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present application. It will be apparent that the described embodiments are only some, but not all, embodiments of the application. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

It should be noted that the terms "first," "second," and the like in the description and the claims of the present application and the above-described drawings are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate such that the embodiments of the application described herein may be implemented in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or server that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed but may include other steps or modules not expressly listed or inherent to such process, method, article, or apparatus.

In a first embodiment, as shown in fig. 1, the present application provides a dust treatment method of a cement solid waste treatment system, the method comprising:

t10: analyzing a cement solid waste treatment process, reading basic information of each process treatment device, and generating a preset dust quantity identification result according to an analysis result and the basic information;

optionally, analyzing the cement solid waste treatment process of the currently used cement solid waste treatment system, extracting basic information of treatment equipment used by each process, and if the currently used cement solid waste treatment process comprises three processes of compaction, crushing and sorting, extracting equipment basic information of solid waste compaction equipment, crushing equipment and screening equipment, including equipment use, power, pollution discharge and the like, calculating the maximum value of dust amount generated by each equipment used by each production process in unit time according to the analysis result of the cement solid waste treatment process and the basic information, multiplying the maximum value by a safety coefficient, such as 1.3, and carrying out dust generation amount identification by the product to obtain a preset dust amount identification result, namely the theoretical maximum value of the dust amount generated by each equipment.

T20: establishing equipment space coordinates, wherein the equipment space coordinates are obtained by establishing a unique coordinate axis in a processing factory, and the equipment space coordinates comprise dust release coordinates;

by way of example, by means of the field arrangement conditions of the currently used cement solid waste treatment plants, including plant arrangement conditions, equipment arrangement conditions and pipeline arrangement conditions, a coordinate origin is selected in the treatment plants, a unique three-dimensional coordinate axis is established, and further, the space coordinates of each equipment in the treatment plants are determined, so that the space coordinates are used as equipment space coordinates, and the equipment space coordinates comprise dust release coordinates, wherein the dust release coordinates are coordinates of parts with larger dust amount, namely, the coordinates of equipment with main dust sources, are determined according to the sizes of dust amounts generated by different equipment, and can be used for determining key parts for dust treatment.

T30: collecting factory building data of the processing factory and extracting factory building features, wherein the factory building features comprise wall surface blocking features, corner features and environment features;

it should be understood that, through the place layout diagram, factory building design diagram, environment monitoring device etc. of the treatment factory, the factory building data collection is carried out to the treatment factory, and according to the factory building data that gathers, draw wall separation characteristic, corner characteristic, the environmental characteristic of treatment factory, wall separation characteristic refers to the wall body overall arrangement, the wall of factory building, corner characteristic refers to the quantity of air non-circulation position such as the corner of factory building wall body, probably causes dust to pile up the problem, environmental characteristic refers to the ventilation condition of factory building, including natural ventilation and ventilation device's wind speed and amount of wind etc. easily influence dust treatment effect.

T40: establishing the spatial distribution of equipment by using the equipment spatial coordinates, using the dust release coordinates as released equipment reference coordinates, and performing impact analysis of dust treatment by using the plant characteristics to generate a dust treatment impact mark;

specifically, through digital simulation technology, the space coordinates of the equipment are used, the space distribution of solid waste treatment equipment is established in a virtual space, namely equipment models are arranged, meanwhile, a virtual factory building three-dimensional model is established by referring to factory building layout drawings, the dust release coordinates are used as released equipment reference coordinates, solid waste treatment simulation and dust treatment simulation are carried out, the influence analysis of dust treatment is carried out through factory building features, namely the dust concentration of each part of a factory building, the flowing and stacking condition of dust are analyzed, and therefore dust treatment influence identification is carried out on each part, and the dust pollution condition of each part of the factory building can be reflected.

Further, as shown in fig. 2, step T40 of the embodiment of the present application further includes:

t41: establishing an influence analysis network, wherein the influence analysis network is a simulation network, and synchronizing the dust release coordinate serving as a released equipment reference coordinate with the plant characteristics to the influence analysis network;

t42: simulating the flow direction of dust by using a flow sub-network to generate a flow simulation result of the dust;

t43: synchronizing the flow simulation result to a stacking sub-network, and performing dust stacking simulation through the stacking sub-network to generate a dust stacking simulation result;

t44: and feeding back the flow simulation result and the accumulation simulation result to the influence analysis network to obtain a dust treatment influence mark.

The method includes the steps of establishing an influence analysis network, namely a virtual space for carrying out factory building solid waste treatment simulation and dust influence analysis, taking dust release coordinates as released equipment reference coordinates, combining factory building characteristics as simulation parameters, synchronizing the factory building characteristics to the influence analysis network, constructing a virtual solid waste treatment system, inputting simulation equipment operation parameters, carrying out dust flow direction simulation through a flow sub-network, and generating a dust flow simulation result including a flow direction, a flow range and the like.

Further, the flow simulation result is synchronized to a stacking sub-network, dust stacking simulation is performed through the stacking sub-network, a dust stacking simulation result is generated, the dust stacking simulation result comprises stacking positions, stacking volumes and the like, finally the flow simulation result and the stacking simulation result are fed back to the impact analysis network, dust impact identifiers of all parts of a factory are performed through the impact analysis network, the dust impact identifiers comprise flow impact identifiers and stacking impact identifiers, and the dust impact identifiers are used as dust treatment impact identifiers, so that dust flow conditions and stacking conditions of all parts of the processing factory can be reflected.

T50: configuring equipment positions and equipment powers of the negative pressure dust removing equipment according to the preset dust amount identification result and the dust treatment influence identification, and distributing the negative pressure dust removing equipment according to the configuration result;

the dust removing requirement calculation of each part of the processing factory building is carried out by utilizing the theoretical maximum value of the dust quantity generated by each device, namely the preset dust quantity identification result, and combining dust influence data of each part of the processing factory building calculated through a digital simulation technology, namely the dust treatment influence identification, and the dust removing equipment configuration is carried out according to the dust removing requirement of each part, so that the device position of the dust removing equipment and the equipment power required by each position are determined, and negative pressure dust removing equipment is distributed in the processing factory building according to the device configuration result.

T60: and executing dust treatment control by the negative pressure dust removing equipment.

Specifically, the dust removal treatment in the factory building is performed by controlling all negative pressure dust removal equipment distributed in the cement solid waste treatment factory building, so that the purposes of controlling the air quality in the cement solid waste treatment factory building and reducing the harm of dust to human bodies and the pollution to the environment are achieved.

Further, step T60 of the embodiment of the present application further includes:

t61: reading the real-time running power of the processing equipment and setting delay response;

t62: inputting the real-time running power into a decision unit, wherein the decision unit is a decision processor which is initialized according to the configuration result of the negative pressure dust removing equipment;

t63: and obtaining a decision result of the decision unit, and executing dust treatment control of the negative pressure dust removing equipment according to the delay response and the decision result.

Optionally, the real-time operation power of the processing equipment is read, the processing equipment, namely the cement solid waste processing equipment, comprises a crusher, a dryer, a pulverizer and the like, and according to the difference of the real-time operation power of the processing equipment, the time from the start of dust discharge to the start of the processing equipment is different, so that corresponding delay response time is set according to different powers of different equipment, and according to the configuration result of the negative pressure dust removal equipment, the start response time for different solid waste processing equipment is set, and a decision processor is obtained by combining neural network training.

Further, the real-time running power is input into a decision unit to obtain a decision result, namely the starting time of the dust removing equipment, and the dust treatment control of the negative pressure dust removing equipment is executed according to the delay response and the decision result, so that the dust removing equipment is ensured to be started in time and the electric power waste is avoided.

Further, the embodiment of the present application further includes a step T70, where the step T70 further includes:

t71: classifying the environmental characteristics to obtain control environmental characteristics and natural environmental characteristics;

t72: generating a first simulation influence constraint by using the control characteristic extremum of the control environment characteristic;

t73: generating a second simulation influence constraint by using the variation extremum of the natural environment characteristic;

t74: performing analysis optimization of an influence analysis network according to the first simulation influence constraint and the second simulation influence constraint, generating an optimized dust treatment influence mark, and establishing response mapping with control environment characteristics and natural environment characteristics;

t75: and executing dust treatment control according to the response mapping and the optimized dust treatment influence mark.

It should be understood that the environmental features are classified to obtain control environmental features and natural environmental features, where the control environmental features refer to artificial control setting environmental features, such as an environmental wind speed, an air humidity, and the like controlled by an air conditioner negative pressure machine. Further, the control characteristic extremum of the control environmental characteristic is taken as a first simulation influence constraint, the control characteristic extremum refers to the maximum value of the environmental characteristic controlled by people, such as the maximum wind speed, as the first simulation influence constraint, and similarly, the change extremum of the natural environmental characteristic is taken as a second simulation influence constraint, namely, the natural environmental parameter adjustment range when dust treatment simulation is carried out.

Further, environmental parameter limitation is carried out on the analysis process of the influence analysis network by using the first simulation influence constraint and the second simulation influence constraint, so that the simulation process is optimized, an optimized dust treatment influence mark is generated, a response mapping of the influence analysis network to control environmental characteristics and natural environmental characteristics is established, real-time environmental control information and environmental detection data are collected to carry out response mapping in the simulation process, dust treatment control is carried out by combining the optimized dust treatment influence mark, and the accuracy of the simulation process is improved.

Further, as shown in fig. 3, the embodiment of the present application further includes a step T80, where the step T80 further includes:

t81: a conventional space region and an auxiliary space region are obtained, and the conventional space region and the auxiliary space region are obtained by space region division according to the dust treatment influence mark;

t82: dust detection sensors are respectively arranged in the conventional space area and the auxiliary space area;

t83: reading real-time monitoring data of the dust detection sensor, taking conventional real-time detection data as real-time feedback data, and taking auxiliary real-time detection data as verification feedback data to generate feedback control information;

t84: and executing dust treatment control optimization of the negative pressure dust removing equipment by the feedback control information.

Optionally, the space region is divided by using the dust treatment influence identifier to obtain a conventional space region and an auxiliary space region, the conventional space region refers to a region with higher dust release amount, the auxiliary space region refers to a region with lower dust release amount, dust detection sensors are respectively arranged in the conventional space region and the auxiliary space region, further, real-time monitoring data of each dust detection sensor are read, the conventional real-time detection data is used as real-time feedback data, the auxiliary real-time detection data is used as verification feedback data to verify the real-time feedback data, feedback control information is generated, the dust concentration and the diffusion range of each part are included, and according to the feedback control information, dust treatment parameters of the negative pressure dust removal equipment are optimized to achieve better dust removal control effect.

Further, step T83 of the embodiment of the present application further includes:

t83-1: performing delay comparison according to the real-time feedback data and the real-time running power to obtain a delay comparison result;

t83-2: if the delay comparison result meets the preset threshold range, directly generating feedback control information by using the real-time feedback data;

t83-3: if the delay comparison result cannot meet the preset threshold range, detecting and verifying by using the auxiliary real-time detection data;

t83-4: and if the detection verification result meets the verification standard, generating a retention feedback.

In one possible embodiment of the application, according to the dust concentration change time of each part displayed by the real-time feedback data, comparing the dust concentration change time with the dust concentration change time corresponding to the real-time operation power of the solid waste treatment equipment to obtain a delay comparison result, namely a concentration change time error, and if the delay comparison result meets a preset threshold range, namely the time error is overlarge, directly taking the real-time feedback data as feedback control information to adjust parameters of the negative pressure dust removal equipment.

Further, if the delay comparison result cannot meet the preset threshold range, it is indicated that the parameters of the negative pressure dust removing equipment in the conventional space region meet the requirements, then the auxiliary real-time detection data is used for detecting and verifying the auxiliary space region, and if the detection and verification result meets the verification standard, it is indicated that the parameters of the negative pressure dust removing equipment in the conventional space region also meet the requirements, then a maintaining feedback is generated, and the current parameters of the negative pressure dust removing equipment are maintained for dust removing treatment.

Further, step T83 of the embodiment of the present application further includes:

t83-5: if the detection verification result cannot meet the verification standard, carrying out feedback parameter configuration according to the detection verification result and the delay comparison difference value;

t83-6: and generating feedback control information according to the feedback parameter configuration result.

Optionally, the detection and verification result of the auxiliary real-time detection data cannot meet the verification standard, which indicates that the parameters of the negative pressure dust removing equipment in the conventional space region cannot meet the requirements, and calculating the feedback parameter according to the detection and verification result and the delay comparison difference value, and adjusting the parameters of the negative pressure dust removing equipment according to the feedback parameter.

In summary, the embodiment of the application has at least the following technical effects:

according to the application, a cement solid waste treatment process is analyzed, basic information of each process treatment device is read, and a preset dust amount identification result is generated; establishing equipment space coordinates; collecting plant data and extracting plant characteristics; and establishing the spatial distribution of equipment by using equipment spatial coordinates, analyzing the dust treatment influence through plant characteristics, generating a dust treatment influence mark, configuring the equipment position and the equipment power of the negative pressure dust removal equipment by combining the preset dust quantity mark result, and executing dust treatment control.

The technical effect of effectively treating dust generated by cement solid waste treatment through intelligent control of negative pressure dust removal equipment is achieved.

In a second embodiment, based on the same inventive concept as the dust treatment method of a cement solid waste treatment system in the foregoing embodiment, as shown in fig. 4, the present application provides a dust treatment device of a cement solid waste treatment system, where the device and the method in the embodiment of the present application are based on the same inventive concept, and the device includes:

the device comprises a preset dust quantity identification result generation module 11, a cement solid waste treatment process analysis module 11 and a dust quantity identification module, wherein the preset dust quantity identification result generation module 11 is used for analyzing cement solid waste treatment processes, reading basic information of each process treatment device and generating a preset dust quantity identification result according to analysis results and the basic information;

an equipment space coordinate establishing module 12, wherein the equipment space coordinate establishing module 12 is used for establishing equipment space coordinates, the equipment space coordinates are obtained by establishing unique coordinate axes in a processing factory, and the equipment space coordinates comprise dust release coordinates;

the factory building feature extraction module 13 is used for collecting factory building data of the processing factory and extracting factory building features, wherein the factory building features comprise wall surface blocking features, corner features and environment features;

the dust treatment influence identification generation module 14 is configured to establish spatial distribution of equipment according to the equipment spatial coordinates, and perform dust treatment influence analysis according to the plant characteristics by using the dust release coordinates as released equipment reference coordinates to generate a dust treatment influence identification;

the negative pressure dust removing equipment distribution module 15 is used for configuring equipment positions and equipment powers of the negative pressure dust removing equipment according to the preset dust amount identification result and the dust treatment influence identification, and distributing the negative pressure dust removing equipment according to the configuration result;

the first dust-handling control module 16, the first dust-handling control module 16 is configured to execute dust-handling control with the negative pressure dust removing apparatus.

Further, the device further comprises:

the influence analysis network establishment module is used for establishing an influence analysis network, the influence analysis network is a simulation network, the dust release coordinates are used as released equipment reference coordinates, and the dust release coordinates and the plant characteristics are synchronized to the influence analysis network;

the flow simulation result generation module is used for simulating the flow direction of dust by using a flow sub-network to generate a flow simulation result of the dust;

the stacking simulation result generation module is used for synchronizing the flow simulation result to a stacking sub-network, and performing dust stacking simulation through the stacking sub-network to generate a dust stacking simulation result;

the dust treatment influence identification obtaining module is used for feeding back the flow simulation result and the accumulation simulation result to the influence analysis network to obtain a dust treatment influence identification.

Further, the device further comprises:

the environment characteristic obtaining module is used for carrying out characteristic classification on the environment characteristics to obtain control environment characteristics and natural environment characteristics;

the first simulation influence constraint generation module is used for generating a first simulation influence constraint by using the control characteristic extremum of the control environment characteristic;

the second simulation influence constraint generation module is used for generating a second simulation influence constraint by using the variation extremum of the natural environment characteristic;

the response map building module is used for executing analysis optimization of an influence analysis network according to the first simulation influence constraint and the second simulation influence constraint, generating an optimized dust treatment influence identifier and building a response map with control environment characteristics and natural environment characteristics;

and the second dust treatment control module is used for executing dust treatment control according to the response mapping and the optimized dust treatment influence mark.

Further, the device further comprises:

the delay response setting module is used for reading the real-time running power of the processing equipment and setting delay response;

the decision processing module is used for inputting the real-time running power into a decision unit, and the decision unit is a decision processor which is initialized according to the configuration result of the negative pressure dust removal equipment;

the dust treatment execution module is used for obtaining a decision result of the decision unit and executing dust treatment control of the negative pressure dust removal equipment according to the delay response and the decision result.

Further, the device further comprises:

the space region acquisition module is used for acquiring a conventional space region and an auxiliary space region, and the conventional space region and the auxiliary space region are obtained by space region division according to the dust treatment influence mark;

a dust detection sensor setting module for setting dust detection sensors in the normal space region and the auxiliary space region, respectively;

the feedback control information generation module is used for reading real-time monitoring data of the dust detection sensor, taking conventional real-time detection data as real-time feedback data, taking auxiliary real-time detection data as verification feedback data and generating feedback control information;

and the dust treatment control optimization module is used for executing dust treatment control optimization of the negative pressure dust removal equipment by the feedback control information.

Further, the device further comprises:

the delay comparison result acquisition module is used for carrying out delay comparison according to the real-time feedback data and the real-time running power to obtain a delay comparison result;

the feedback control information extraction module is used for directly generating feedback control information by the real-time feedback data if the delay comparison result meets a preset threshold range;

the detection and verification module is used for carrying out detection and verification by using the auxiliary real-time detection data if the delay comparison result cannot meet the preset threshold range;

and the holding feedback generation module is used for generating holding feedback if the detection verification result meets the verification standard.

Further, the device further comprises:

the feedback parameter configuration module is used for carrying out feedback parameter configuration according to the detection verification result and the delay comparison difference value if the detection verification result cannot meet the verification standard;

and the feedback control information acquisition module is used for generating feedback control information according to the feedback parameter configuration result.

It should be noted that the sequence of the embodiments of the present application is only for description, and does not represent the advantages and disadvantages of the embodiments. And the foregoing description has been directed to specific embodiments of this specification. Other embodiments are within the scope of the following claims. In some cases, the actions or steps recited in the claims can be performed in a different order than in the embodiments and still achieve desirable results. In addition, the processes depicted in the accompanying figures do not necessarily require the particular order shown, or sequential order, to achieve desirable results. In some embodiments, multitasking and parallel processing are also possible or may be advantageous.

The foregoing description of the preferred embodiments of the application is not intended to limit the application to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and scope of the application are intended to be included within the scope of the application.

The specification and figures are merely exemplary illustrations of the present application and are considered to cover any and all modifications, variations, combinations, or equivalents that fall within the scope of the application. It will be apparent to those skilled in the art that various modifications and variations can be made to the present application without departing from the scope of the application. Thus, the present application is intended to include such modifications and alterations insofar as they come within the scope of the application or the equivalents thereof.

Claims (8)

1. A dust treatment device for a cement solid waste treatment system, the device comprising:

the device comprises a preset dust quantity identification result generation module, a cement solid waste treatment process analysis module and a cement solid waste treatment module, wherein the preset dust quantity identification result generation module is used for analyzing cement solid waste treatment processes, reading basic information of each process treatment device and generating a preset dust quantity identification result according to analysis results and the basic information;

the equipment space coordinate establishing module is used for establishing equipment space coordinates, the equipment space coordinates are obtained by establishing unique coordinate axes in a processing factory, and the equipment space coordinates comprise dust release coordinates;

the factory building feature extraction module is used for collecting factory building data of the processing factory and extracting factory building features, wherein the factory building features comprise wall surface blocking features, corner features and environment features;

the dust treatment influence identification generation module is used for establishing the space distribution of equipment by using the equipment space coordinates, taking the dust release coordinates as released equipment reference coordinates, and analyzing the influence of dust treatment by the plant characteristics to generate a dust treatment influence identification;

the negative pressure dust removing equipment distribution module is used for configuring equipment positions and equipment powers of the negative pressure dust removing equipment according to the preset dust amount identification result and the dust treatment influence identification, and distributing the negative pressure dust removing equipment according to the configuration result;

and the first dust treatment control module is used for executing dust treatment control by the negative pressure dust removing equipment.

2. The apparatus of claim 1, wherein the apparatus further comprises:

the influence analysis network establishment module is used for establishing an influence analysis network, the influence analysis network is a simulation network, the dust release coordinates are used as released equipment reference coordinates, and the dust release coordinates and the plant characteristics are synchronized to the influence analysis network;

the flow simulation result generation module is used for simulating the flow direction of dust by using a flow sub-network to generate a flow simulation result of the dust;

the stacking simulation result generation module is used for synchronizing the flow simulation result to a stacking sub-network, and performing dust stacking simulation through the stacking sub-network to generate a dust stacking simulation result;

the dust treatment influence identification obtaining module is used for feeding back the flow simulation result and the accumulation simulation result to the influence analysis network to obtain a dust treatment influence identification.

3. The apparatus of claim 2, wherein the apparatus further comprises:

the environment characteristic obtaining module is used for carrying out characteristic classification on the environment characteristics to obtain control environment characteristics and natural environment characteristics;

the first simulation influence constraint generation module is used for generating a first simulation influence constraint by using the control characteristic extremum of the control environment characteristic;

the second simulation influence constraint generation module is used for generating a second simulation influence constraint by using the variation extremum of the natural environment characteristic;

the response map building module is used for executing analysis optimization of an influence analysis network according to the first simulation influence constraint and the second simulation influence constraint, generating an optimized dust treatment influence identifier and building a response map with control environment characteristics and natural environment characteristics;

and the second dust treatment control module is used for executing dust treatment control according to the response mapping and the optimized dust treatment influence mark.

4. The apparatus of claim 1, wherein the apparatus further comprises:

the delay response setting module is used for reading the real-time running power of the processing equipment and setting delay response;

the decision processing module is used for inputting the real-time running power into a decision unit, and the decision unit is a decision processor which is initialized according to the configuration result of the negative pressure dust removal equipment;

the dust treatment execution module is used for obtaining a decision result of the decision unit and executing dust treatment control of the negative pressure dust removal equipment according to the delay response and the decision result.

5. The apparatus of claim 4, wherein the apparatus further comprises:

the space region acquisition module is used for acquiring a conventional space region and an auxiliary space region, and the conventional space region and the auxiliary space region are obtained by space region division according to the dust treatment influence mark;

a dust detection sensor setting module for setting dust detection sensors in the normal space region and the auxiliary space region, respectively;

the feedback control information generation module is used for reading real-time monitoring data of the dust detection sensor, taking conventional real-time detection data as real-time feedback data, taking auxiliary real-time detection data as verification feedback data and generating feedback control information;

and the dust treatment control optimization module is used for executing dust treatment control optimization of the negative pressure dust removal equipment by the feedback control information.

6. The apparatus of claim 5, wherein the apparatus further comprises:

the delay comparison result acquisition module is used for carrying out delay comparison according to the real-time feedback data and the real-time running power to obtain a delay comparison result;

the feedback control information extraction module is used for directly generating feedback control information by the real-time feedback data if the delay comparison result meets a preset threshold range;

the detection and verification module is used for carrying out detection and verification by using the auxiliary real-time detection data if the delay comparison result cannot meet the preset threshold range;

and the holding feedback generation module is used for generating holding feedback if the detection verification result meets the verification standard.

7. The apparatus of claim 6, wherein the apparatus further comprises:

the feedback parameter configuration module is used for carrying out feedback parameter configuration according to the detection verification result and the delay comparison difference value if the detection verification result cannot meet the verification standard;

and the feedback control information acquisition module is used for generating feedback control information according to the feedback parameter configuration result.

8. A method for dust treatment of a cement solid waste treatment system, the method comprising:

analyzing a cement solid waste treatment process, reading basic information of each process treatment device, and generating a preset dust quantity identification result according to an analysis result and the basic information;

establishing equipment space coordinates, wherein the equipment space coordinates are obtained by establishing a unique coordinate axis in a processing factory, and the equipment space coordinates comprise dust release coordinates;

collecting factory building data of the processing factory and extracting factory building features, wherein the factory building features comprise wall surface blocking features, corner features and environment features;

establishing the spatial distribution of equipment by using the equipment spatial coordinates, using the dust release coordinates as released equipment reference coordinates, and performing impact analysis of dust treatment by using the plant characteristics to generate a dust treatment impact mark;

configuring equipment positions and equipment powers of the negative pressure dust removing equipment according to the preset dust amount identification result and the dust treatment influence identification, and distributing the negative pressure dust removing equipment according to the configuration result;

and executing dust treatment control by the negative pressure dust removing equipment.