CN117061903B - Information acquisition system of garbage throwing equipment and intelligent garbage room - Google Patents

Abstract

The invention relates to the field of artificial intelligence, and discloses an information acquisition system of garbage throwing equipment and an intelligent garbage room, which are used for realizing intelligent monitoring and control of the garbage throwing equipment. The system comprises: the intelligent garbage collection system comprises an intelligent environment-friendly garbage room, an environment parameter monitoring module, an equipment operation monitoring module, an intelligent garbage platform and an interactive display module; the intelligent environment-friendly garbage room comprises intelligent garbage throwing equipment and a garbage station room; the environment parameter detection module is used for monitoring the garbage station house and is connected with the intelligent garbage platform, the equipment operation monitoring module is respectively connected with the intelligent garbage throwing equipment and the intelligent garbage platform, and the intelligent garbage platform is connected with the interactive display module.

Description

Information acquisition system of garbage throwing equipment and intelligent garbage room

Technical Field

The invention relates to the field of artificial intelligence, in particular to an information acquisition system of garbage throwing equipment and an intelligent garbage room.

Background

For a long time, garbage station houses are all areas which are easy to pollute the environment of a building area, and are also easy to contact and cross-infect viruses. The garbage houses on the market at present have the following pain points: 1. the traditional garbage site is generally arranged in an active dense area or a landscape leisure space, has a certain influence on the image of a community, and if the odor emitted by garbage cannot be well controlled, residents are not willing to stay in rest, and more talks about quality and liking living. 2. The traditional garbage house delivery area and the clearing area are together, and the garbage house delivery area and the clearing area generally pass through a living area during clearing, so that noise and smell are very high, and physical and mental health of residents is affected. 3. The traditional garbage bin is flip formula or side-opening push door formula generally, and it takes place when throwing in the contact bung, and when the resident carried more rubbish, the operation of throwing in was inconvenient, and the experience of throwing in was not good. 4. Conventionally, garbage cans are generally exposed to the outside, so that peculiar smell and bacteria in the garbage can grow, and secondary pollution is easily caused if no reasonable deodorizing measures are taken. 5. The traditional garbage house generally cannot monitor various index data in real time, and is easy to cause untimely garbage clearing, killing and the like.

Disclosure of Invention

The invention provides an information acquisition system of garbage throwing equipment and an intelligent garbage room, which are used for realizing intelligent monitoring and control of the garbage throwing equipment.

The first aspect of the invention provides an information acquisition system of a garbage throwing device, which comprises: the intelligent garbage collection system comprises an intelligent environment-friendly garbage room, an environment parameter monitoring module, an equipment operation monitoring module, an intelligent garbage platform and an interactive display module; the intelligent environment-friendly garbage room comprises intelligent garbage throwing equipment and a garbage station room; the environment parameter detection module is used for monitoring the garbage station room and is connected with the intelligent garbage platform, the equipment operation monitoring module is respectively connected with the intelligent garbage throwing equipment and the intelligent garbage platform, and the intelligent garbage platform is connected with the interactive display module;

the environment parameter monitoring module is used for: collecting an environmental parameter index set of the garbage station room, and transmitting the environmental parameter index set to the intelligent garbage platform; receiving and responding to an environment decision instruction set issued by the intelligent garbage platform;

the equipment operation monitoring module is used for: collecting a device running state parameter set of the intelligent garbage throwing device, and transmitting the device running state parameter set to the intelligent garbage platform; receiving and responding to a device decision instruction set issued by the intelligent garbage platform;

The intelligent garbage platform is used for: inputting the environmental parameter index set into a preset environmental parameter decision analysis model set for environmental parameter analysis to obtain an environmental decision strategy set, and generating the environmental decision instruction set according to the environmental decision strategy set; inputting the equipment operation state parameter set into a preset equipment operation state parameter decision analysis model set to analyze the equipment operation state parameter, obtaining an equipment decision strategy set, and generating the equipment decision instruction set according to the equipment decision strategy set; and sending the environment decision strategy set and the equipment decision strategy set to the interactive display module for visual interactive display.

With reference to the first aspect, in a first implementation manner of the first aspect of the present invention, the smart garbage platform includes: the environment parameter decision unit is specifically used for:

inputting the environment parameter index set into a preset environment parameter clustering model, and calculating a plurality of first data labels corresponding to the environment parameter index set through the environment parameter clustering model;

performing label distance calculation on the environment parameter index set and the plurality of first data labels to obtain a plurality of label distance data of each first data label, and performing average analysis on the plurality of label distance data of each first data label to obtain a target label distance of each first data label;

Performing model parameter replacement on the environment parameter clustering model through the target tag distance to obtain a target parameter clustering model;

performing data tag optimization operation on the plurality of first data tags through the target parameter clustering model to obtain a plurality of second data tags, and performing data tag clustering analysis on the environment parameter index set through the plurality of second data tags to obtain a plurality of target environment parameter data, wherein the plurality of target environment parameter data comprise: temperature and humidity data and air quality data;

inputting the plurality of target environmental parameter data into a preset environmental parameter decision analysis model set, wherein the environmental parameter decision analysis model set comprises: a temperature and humidity detection model, a garbage room odor detection model and a volatile organic compound concentration detection model;

and respectively carrying out environmental parameter analysis on the plurality of target environmental parameter data through the environmental parameter decision analysis model set to obtain an environmental decision strategy set, and generating the environmental decision instruction set according to the environmental decision strategy set.

With reference to the first aspect, in a second implementation manner of the first aspect of the present invention, the smart garbage platform further includes: the device parameter decision unit is specifically configured to:

Inputting the equipment operation state parameter set into a preset equipment operation state parameter decision analysis model set, wherein the equipment operation state parameter decision analysis model set comprises: the garbage can overflow analysis model, the medicament spraying control model and the equipment operation abnormality detection model;

extracting the parameters of the garbage bin from the running state parameter set of the equipment to obtain garbage bin capacity data, and inputting the garbage bin capacity data into the garbage bin overflow analysis model to carry out garbage bin overflow analysis to obtain a garbage bin overflow decision strategy;

extracting the equipment networking state data from the equipment operation state parameter set to obtain target equipment networking state data, inputting the target equipment networking state data into the medicament spraying control model to perform medicament spraying control, and obtaining a medicament spraying control decision strategy;

extracting running state data of the equipment running state parameter set to obtain equipment running time data and equipment fault state data, and inputting the equipment running time data and the equipment fault state data into the equipment running abnormality detection model to detect equipment running abnormality to obtain an equipment running abnormality decision strategy;

Generating a device decision strategy set according to the garbage bin overflow decision strategy, the medicament spraying control decision strategy and the device operation abnormality decision strategy, and generating the device decision instruction set according to the device decision strategy set.

With reference to the first aspect, in a third implementation manner of the first aspect of the present invention, the smart garbage platform further includes: the passive pollutant optimizing unit is specifically used for:

acquiring a target equipment model of the intelligent garbage throwing equipment and garbage room area information of the garbage station room, and analyzing the garbage room area information to obtain delivery area parameter information and clearance area parameter information;

determining a first boundary condition of a delivery zone according to the delivery zone parameter information, and determining a second boundary condition of a clearing zone according to the clearing zone parameter information;

establishing a computing grid of the intelligent environment-friendly garbage room according to the target equipment model, and determining CFD simulation parameters according to the computing grid, wherein the CFD simulation parameters comprise: time step, solver selection and iterative convergence criteria;

according to the first boundary condition and the second boundary condition, performing air flow and pollutant simulation on the delivery area and the clearing area to obtain a target simulation result;

Generating a target evaluation index of the diffusion condition of pollutants in the delivery area and positive and negative pressure design according to the target simulation result;

and determining ventilation design optimization schemes of the delivery area and the clearing area according to the target evaluation indexes.

With reference to the first aspect, in a fourth implementation manner of the first aspect of the present invention, the interactive display module is specifically configured to:

acquiring an equipment layout diagram of the intelligent environment-friendly garbage room, and performing interactive display interface mapping according to the equipment layout diagram, the delivery area parameter information and the clearance area parameter information to obtain an initial interactive display interface;

acquiring the environment decision strategy set and the equipment decision strategy set of the intelligent garbage platform, and carrying out text analysis on the environment decision strategy set and the equipment decision strategy to obtain target text data;

and visually displaying the target text data through a preset interface container component to generate a target interactive display interface.

With reference to the first aspect, in a fifth implementation manner of the first aspect of the present invention, the intelligent garbage throwing device is specifically configured to:

acquiring weight sensing data and object sensing data based on a weight sensing area and an object sensing area which are preset in the intelligent garbage throwing equipment;

Extracting weight characteristics of the weight sensing data to obtain weight characteristic information, and calculating the distance between the object sensing data and the intelligent garbage throwing device to obtain throwing distance data;

generating a throwing port opening or closing instruction of the intelligent garbage throwing device according to the weight characteristic information and the throwing distance data;

and opening or closing the opening of the intelligent garbage throwing device is controlled by the opening or closing instruction of the throwing opening.

A second aspect of the present invention provides an intelligent garbage room, the intelligent garbage room executing the information acquisition system of the garbage throwing apparatus according to the first aspect of the present invention, the information acquisition system of the garbage throwing apparatus comprising: the intelligent garbage collection system comprises an intelligent environment-friendly garbage room, an environment parameter monitoring module, an equipment operation monitoring module, an intelligent garbage platform and an interactive display module; the intelligent environment-friendly garbage room comprises intelligent garbage throwing equipment and a garbage station room; the environment parameter detection module is used for monitoring the garbage station room and is connected with the intelligent garbage platform, the equipment operation monitoring module is respectively connected with the intelligent garbage throwing equipment and the intelligent garbage platform, and the intelligent garbage platform is connected with the interactive display module;

The environment parameter monitoring module is used for: collecting an environmental parameter index set of the garbage station room, and transmitting the environmental parameter index set to the intelligent garbage platform; receiving and responding to an environment decision instruction set issued by the intelligent garbage platform;

the equipment operation monitoring module is used for: collecting a device running state parameter set of the intelligent garbage throwing device, and transmitting the device running state parameter set to the intelligent garbage platform; receiving and responding to a device decision instruction set issued by the intelligent garbage platform;

the intelligent garbage platform is used for: inputting the environmental parameter index set into a preset environmental parameter decision analysis model set for environmental parameter analysis to obtain an environmental decision strategy set, and generating the environmental decision instruction set according to the environmental decision strategy set; inputting the equipment operation state parameter set into a preset equipment operation state parameter decision analysis model set to analyze the equipment operation state parameter, obtaining an equipment decision strategy set, and generating the equipment decision instruction set according to the equipment decision strategy set; and sending the environment decision strategy set and the equipment decision strategy set to the interactive display module for visual interactive display.

With reference to the second aspect, in a first implementation manner of the second aspect of the present invention, the intelligent garbage room executes the information collection system of the garbage throwing device according to the first aspect of the present invention, and the intelligent garbage platform includes: the environment parameter decision unit is specifically used for:

inputting the environment parameter index set into a preset environment parameter clustering model, and calculating a plurality of first data labels corresponding to the environment parameter index set through the environment parameter clustering model;

performing label distance calculation on the environment parameter index set and the plurality of first data labels to obtain a plurality of label distance data of each first data label, and performing average analysis on the plurality of label distance data of each first data label to obtain a target label distance of each first data label;

performing model parameter replacement on the environment parameter clustering model through the target tag distance to obtain a target parameter clustering model;

performing data tag optimization operation on the plurality of first data tags through the target parameter clustering model to obtain a plurality of second data tags, and performing data tag clustering analysis on the environment parameter index set through the plurality of second data tags to obtain a plurality of target environment parameter data, wherein the plurality of target environment parameter data comprise: temperature and humidity data and air quality data;

Inputting the plurality of target environmental parameter data into a preset environmental parameter decision analysis model set, wherein the environmental parameter decision analysis model set comprises: a temperature and humidity detection model, a garbage room odor detection model and a volatile organic compound concentration detection model;

and respectively carrying out environmental parameter analysis on the plurality of target environmental parameter data through the environmental parameter decision analysis model set to obtain an environmental decision strategy set, and generating the environmental decision instruction set according to the environmental decision strategy set.

With reference to the second aspect, in a second implementation manner of the second aspect of the present invention, the intelligent garbage room executes the information collecting system of the garbage throwing device according to the first aspect of the present invention, and the intelligent garbage platform further includes: the device parameter decision unit is specifically configured to:

inputting the equipment operation state parameter set into a preset equipment operation state parameter decision analysis model set, wherein the equipment operation state parameter decision analysis model set comprises: the garbage can overflow analysis model, the medicament spraying control model and the equipment operation abnormality detection model;

Extracting the parameters of the garbage bin from the running state parameter set of the equipment to obtain garbage bin capacity data, and inputting the garbage bin capacity data into the garbage bin overflow analysis model to carry out garbage bin overflow analysis to obtain a garbage bin overflow decision strategy;

extracting the equipment networking state data from the equipment operation state parameter set to obtain target equipment networking state data, inputting the target equipment networking state data into the medicament spraying control model to perform medicament spraying control, and obtaining a medicament spraying control decision strategy;

extracting running state data of the equipment running state parameter set to obtain equipment running time data and equipment fault state data, and inputting the equipment running time data and the equipment fault state data into the equipment running abnormality detection model to detect equipment running abnormality to obtain an equipment running abnormality decision strategy;

generating a device decision strategy set according to the garbage bin overflow decision strategy, the medicament spraying control decision strategy and the device operation abnormality decision strategy, and generating the device decision instruction set according to the device decision strategy set.

With reference to the second aspect, in a third implementation manner of the second aspect of the present invention, the intelligent garbage room executes the information collecting system of the garbage throwing device according to the first aspect of the present invention, and the intelligent garbage platform further includes: the passive pollutant optimizing unit is specifically used for:

acquiring a target equipment model of the intelligent garbage throwing equipment and garbage room area information of the garbage station room, and analyzing the garbage room area information to obtain delivery area parameter information and clearance area parameter information;

determining a first boundary condition of a delivery zone according to the delivery zone parameter information, and determining a second boundary condition of a clearing zone according to the clearing zone parameter information;

establishing a computing grid of the intelligent environment-friendly garbage room according to the target equipment model, and determining CFD simulation parameters according to the computing grid, wherein the CFD simulation parameters comprise: time step, solver selection and iterative convergence criteria;

according to the first boundary condition and the second boundary condition, performing air flow and pollutant simulation on the delivery area and the clearing area to obtain a target simulation result;

Generating a target evaluation index of the diffusion condition of pollutants in the delivery area and positive and negative pressure design according to the target simulation result;

and determining ventilation design optimization schemes of the delivery area and the clearing area according to the target evaluation indexes.

With reference to the second aspect, in a fourth implementation manner of the second aspect of the present invention, the intelligent garbage room executes the information collection system of the garbage throwing device according to the first aspect of the present invention, and the interactive display module is specifically configured to:

acquiring an equipment layout diagram of the intelligent environment-friendly garbage room, and performing interactive display interface mapping according to the equipment layout diagram, the delivery area parameter information and the clearance area parameter information to obtain an initial interactive display interface;

acquiring the environment decision strategy set and the equipment decision strategy set of the intelligent garbage platform, and carrying out text analysis on the environment decision strategy set and the equipment decision strategy to obtain target text data;

and visually displaying the target text data through a preset interface container component to generate a target interactive display interface.

With reference to the second aspect, in a fifth implementation manner of the second aspect of the present invention, the intelligent garbage room executes an information collecting system of the garbage throwing device according to the first aspect of the present invention, where the intelligent garbage throwing device is specifically configured to:

Acquiring weight sensing data and object sensing data based on a weight sensing area and an object sensing area which are preset in the intelligent garbage throwing equipment;

extracting weight characteristics of the weight sensing data to obtain weight characteristic information, and calculating the distance between the object sensing data and the intelligent garbage throwing device to obtain throwing distance data;

generating a throwing port opening or closing instruction of the intelligent garbage throwing device according to the weight characteristic information and the throwing distance data;

and opening or closing the opening of the intelligent garbage throwing device is controlled by the opening or closing instruction of the throwing opening.

In the technical scheme provided by the invention, the system comprises: the intelligent garbage collection system comprises an intelligent environment-friendly garbage room, an environment parameter monitoring module, an equipment operation monitoring module, an intelligent garbage platform and an interactive display module; the intelligent environment-friendly garbage room comprises intelligent garbage throwing equipment and a garbage station room; the environment parameter detection module is used for monitoring the garbage station room and is connected with the intelligent garbage platform, the equipment operation monitoring module is respectively connected with the intelligent garbage throwing equipment and the intelligent garbage platform, and the intelligent garbage platform is connected with the interactive display module; the invention is suitable for building basements, overhead floors and floors of various communities; all original garbage throwing points such as office buildings, schools, hospitals, parks, industrial parks and the like are used for constructing a non-contact throwing, odorless, degerming, tidy and healthy throwing environment, classifying garbage, non-contact throwing boxes, deodorizing, decontaminating, degerming, convenient transportation, cleaning garbage houses, intelligent control, intelligent index monitoring and intelligent data display technology integration, guaranteeing high-quality throwing environments of households at equipment levels, further realizing intelligent monitoring and control of garbage throwing equipment, and guaranteeing health, comfort and convenient experience of the households in all directions by carrying out pain point analysis, standard formulation and optimal design on spaces in front areas, back areas and station rooms.

Drawings

Fig. 1 is a schematic diagram of an embodiment of an information collection system of a garbage throwing device according to an embodiment of the present invention.

Detailed Description

The embodiment of the invention provides an information acquisition system of garbage throwing equipment and an intelligent garbage room, which are used for realizing intelligent monitoring and control of the garbage throwing equipment. The terms "first," "second," "third," "fourth" and the like in the description and in the claims and in the above drawings, if any, 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 described herein may be implemented in other sequences than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed or inherent to such process, method, article, or apparatus.

For ease of understanding, a specific flow of an embodiment of the present invention will be described below with reference to fig. 1, where an embodiment of an information collecting system of a garbage throwing apparatus according to an embodiment of the present invention includes:

the information acquisition system of the garbage throwing device comprises: the intelligent environment-friendly garbage room 101, an environment parameter monitoring module 102, a device operation monitoring module 103, an intelligent garbage platform 104 and an interactive display module 105; the intelligent environment-friendly garbage room 101 comprises an intelligent garbage throwing device 1011 and a garbage station room 1012; the environment parameter monitoring module 102 is respectively connected with the garbage station room 1012 and the intelligent garbage platform 104, the equipment operation monitoring module 103 is respectively connected with the intelligent garbage throwing equipment 1011 and the intelligent garbage platform 104, and the intelligent garbage platform 104 is connected with the interactive display module 105;

the environmental parameter monitoring module 102 is configured to: collecting an environmental parameter index set of the garbage station room 1012 and transmitting the environmental parameter index set to the intelligent garbage platform 104; and receiving and responding to the environment decision instruction set issued by the intelligent garbage platform 104;

the device operation monitoring module 103 is configured to: collecting a device operation state parameter set of the intelligent garbage throwing device 1011, and transmitting the device operation state parameter set to the intelligent garbage platform 104; and receiving and responding to the device decision instruction set issued by the intelligent garbage platform 104;

The smart trash platform 104 is configured to: inputting the environmental parameter index set into a preset environmental parameter decision analysis model set for environmental parameter analysis to obtain an environmental decision strategy set, and generating an environmental decision instruction set according to the environmental decision strategy set; inputting the equipment operation state parameter set into a preset equipment operation state parameter decision analysis model set to analyze the equipment operation state parameter, obtaining an equipment decision strategy set, and generating an equipment decision instruction set according to the equipment decision strategy set; and sending the environment decision strategy set and the device decision strategy set to the interactive display module 105 for visual interactive display.

Specifically, the information acquisition system of the garbage throwing device is an intelligent system and comprises an intelligent environment-friendly garbage room, an environment parameter monitoring module, a device operation monitoring module, an intelligent garbage platform and an interactive display module. The goal of this system is to provide an integrated solution to achieve intelligence and optimization of garbage management. First, the intelligent environmental protection garbage room is the core part of the system. The garbage station comprises intelligent garbage throwing equipment and a garbage station room. The intelligent garbage can may be various types of intelligent garbage cans, such as a garbage can having automatic door opening and closing and sorting functions. When the user puts in rubbish, intelligent device can open automatically to classify according to the kind of rubbish. A refuse station house is a container and storage area of equipment for collecting and storing refuse. Secondly, an environmental parameter monitoring module and an equipment operation monitoring module are key components for data acquisition and monitoring. The environmental parameter monitoring module is connected with the garbage station room and the intelligent garbage platform and is used for collecting environmental parameter index sets of the garbage station room, such as temperature, humidity, air quality and the like. These data are transmitted to the intelligent garbage platform for analysis and decision making. For example, the monitoring module may periodically measure the temperature and humidity within the waste station room so that the intelligent waste platform may monitor the environmental conditions and take corresponding action, such as adjusting the ventilation system or alerting maintenance personnel. The equipment operation monitoring module is connected with the intelligent garbage throwing equipment and the intelligent garbage platform and is used for collecting operation state parameter sets of the intelligent garbage throwing equipment, such as electric quantity, fault information and the like. These data are transmitted to the intelligent garbage platform for analysis and decision making. For example, the monitoring module can monitor the electric quantity of the garbage throwing device in real time and send an alarm to the intelligent garbage platform when the electric quantity is too low so as to replace a battery or charge in time. The intelligent garbage platform is a central processing unit of the system and is responsible for data analysis and decision generation. The method comprises the steps of receiving data from an environment parameter monitoring module and a device operation monitoring module, inputting an environment parameter index set into a preset environment parameter decision analysis model set to perform environment parameter analysis, and obtaining an environment decision strategy set. Meanwhile, the device running state parameter set is input into a preset device running state parameter decision analysis model set to carry out device running state parameter analysis, and a device decision strategy set is obtained. Based on these policy sets, the intelligent garbage platform generates an environment decision instruction set and a device decision instruction set. For example, the intelligent garbage platform can make a garbage disposal plan, such as reasonably scheduling the time and frequency of cleaning garbage station rooms, according to the analysis result of the environmental parameters. Meanwhile, the device can also generate guiding suggestions for equipment maintenance and service according to the analysis result of the equipment operation state parameters, such as timely replacement of damaged sensors or cleaning of garbage throwing equipment. And finally, the interactive display module is connected with the intelligent garbage platform and is used for sending the generated environment decision strategy set and the generated equipment decision strategy set to a display screen for visual interactive display. In this way, the manager and maintainer can check the decision result and suggestion generated by the system through the interactive display module, and perform corresponding operation and adjustment according to the requirement. For example, the display screen can display the current environmental condition of the garbage station house, the running state of equipment, the next operation proposal and other information, so that the manager can conveniently make decisions. Wherein, intelligent environmental protection garbage room 101 still includes: the disinfection module and the remote control module are key components in the intelligent environment-friendly garbage room 101. Advanced technologies such as ultraviolet rays, ozone and the like are adopted to realize efficient sterilization and deodorization effects. Specifically, the sterilization module can utilize ultraviolet radiation to kill bacteria, viruses and other microorganisms, and effectively eliminate potential pathogen transmission risks in the garbage room. In addition, ozone is also a gas with strong oxidizing ability, which can rapidly oxidize and decompose odor molecules, and effectively eliminate unpleasant odor in garbage houses. The intelligent environment-friendly garbage room 101 also has a remote control function, and allows property managers to remotely monitor and manage the running state of the garbage room in real time through a cloud platform or a mobile phone application. Through the remote control function, property management personnel can conveniently adjust the working time and the intensity of the disinfection module so as to adapt to different requirements and time schedules. Meanwhile, the garbage capacity, the running state of equipment, environmental parameters and other information can be monitored remotely, the situation of a garbage room can be mastered in time, and the management efficiency is improved. The intelligent environment-friendly garbage room 101 can effectively reduce bacteria and peculiar smell in the garbage room by using the sterilizing module, improves the environmental sanitation level, and provides a clean and comfortable throwing environment for households. The remote control function enhances the management convenience and efficiency of the garbage room, and the manager can monitor and regulate and control at any time and any place, respond to the problems in time and ensure the normal operation of the garbage room. The design and functional integration of the intelligent environmental protection garbage room 101 tightly combines the disinfection module and the remote control function with the garbage disposal equipment, and provides a comprehensive and intelligent garbage management solution. By applying advanced disinfection technology and remote monitoring means, the intelligent environment-friendly garbage room 101 realizes efficient, safe and sanitary operation of the garbage room, and provides a more comfortable and convenient throwing environment for users. In addition, the design of the intelligent environmental protection garbage room 101 also provides an expanded and customized space to adapt to different scenes and requirements, and brings new innovation and development to the garbage management industry.

The smart trash platform 104 includes: the environment parameter decision unit is specifically used for:

inputting the environmental parameter index set into a preset environmental parameter clustering model, and calculating a plurality of first data labels corresponding to the environmental parameter index set through the environmental parameter clustering model;

performing label distance calculation on the environment parameter index set and the plurality of first data labels to obtain a plurality of label distance data of each first data label, and performing average analysis on the plurality of label distance data of each first data label to obtain a target label distance of each first data label;

performing model parameter replacement on the environment parameter clustering model through the target tag distance to obtain a target parameter clustering model;

performing data tag optimization operation on the plurality of first data tags through the target parameter clustering model to obtain a plurality of second data tags, and performing data tag clustering analysis on the environment parameter index set through the plurality of second data tags to obtain a plurality of target environment parameter data, wherein the plurality of target environment parameter data comprise: temperature and humidity data and air quality data;

inputting a plurality of target environmental parameter data into a preset environmental parameter decision analysis model set, wherein the environmental parameter decision analysis model set comprises: a temperature and humidity detection model, a garbage room odor detection model and a volatile organic compound concentration detection model;

And respectively carrying out environmental parameter analysis on the plurality of target environmental parameter data through the environmental parameter decision analysis model set to obtain an environmental decision strategy set, and generating an environmental decision instruction set according to the environmental decision strategy set.

Specifically, first, the collected environmental parameter index set is input into a preset environmental parameter clustering model. The clustering model is capable of clustering the set of environmental parameter indicators and calculating a plurality of first data labels for each cluster. These first data tags may reflect different characteristics or patterns of the set of environmental parameter indicators. And secondly, calculating the tag distance between the environmental parameter index set and the plurality of first data tags to obtain a plurality of tag distance data of each first data tag. The tag distance reflects the degree of similarity or difference between the set of environmental parameter indicators and each of the first data tags. And then, carrying out average analysis on a plurality of tag distance data of each first data tag to obtain the target tag distance of each first data tag. And replacing the model parameters of the environmental parameter clustering model by using the target tag distance to obtain a target parameter clustering model. The target parameter clustering model can more accurately reflect the characteristics and modes of the environment parameter index set. And then, carrying out data tag optimization operation on the plurality of first data tags through the target parameter clustering model to obtain a plurality of second data tags. These second data tags more accurately describe the characteristics and patterns of the set of environmental parameter indicators. And then, carrying out data tag clustering analysis on the environment parameter index set by using a plurality of second data tags, thereby obtaining a plurality of target environment parameter data. These target environmental parameter data may include temperature and humidity data, air quality data, and the like. Further, a plurality of target environmental parameter data are input into a preset environmental parameter decision analysis model set. The model set comprises a plurality of specific environmental parameter decision analysis models, such as a temperature and humidity detection model, a garbage room odor detection model and a volatile organic compound concentration detection model. And analyzing the plurality of target environmental parameter data through the environmental parameter decision analysis model set to obtain a corresponding environmental decision strategy set. The policy sets provide a targeted environmental decision scheme according to specific environmental parameter data and the characteristics of the model. And generating an environment decision instruction set according to the environment decision strategy set to guide actual operation and adjustment. For example, assume that an environmental parameter decision unit of the intelligent garbage platform collects an environmental parameter index set of a garbage station room, including data such as temperature, humidity, air quality, and the like. And calculating a plurality of first data labels such as a normal state, high temperature and high humidity, poor air quality and the like through a preset environmental parameter clustering model. And then, carrying out label distance calculation on the environment parameter index set and the first data labels to obtain label distance data of each first data label. And obtaining the target label distance of each first data label through mean value analysis. And replacing model parameters of the environmental parameter clustering model according to the target tag distance to obtain a target parameter clustering model. And carrying out data tag optimization operation through the target parameter clustering model to obtain a plurality of second data tags, such as 'suitable environment', 'high temperature and humidity environment', 'excellent air quality' and the like. And carrying out data tag cluster analysis on the environment parameter index set by using the second data tags to obtain a plurality of target environment parameter data. And inputting the target environmental parameter data into a preset environmental parameter decision analysis model set, such as a temperature and humidity detection model, a garbage room odor detection model, a volatile organic compound concentration detection model and the like, so as to perform environmental parameter analysis. And generating a corresponding environment decision strategy set according to the analysis result, such as adjusting a temperature and humidity control device, starting an air purification system, increasing garbage collection frequency and the like. And finally, generating a corresponding environment decision instruction set according to the environment decision strategy set, wherein the environment decision instruction set is used for guiding the operation and adjustment of the garbage management system.

The smart trash platform 104 further includes: the device parameter decision unit is specifically configured to:

inputting the equipment operation state parameter set into a preset equipment operation state parameter decision analysis model set, wherein the equipment operation state parameter decision analysis model set comprises: the garbage can overflow analysis model, the medicament spraying control model and the equipment operation abnormality detection model;

extracting the parameters of the garbage bin from the running state parameter set of the equipment to obtain garbage bin capacity data, and inputting the garbage bin capacity data into a garbage bin overflow analysis model to carry out garbage bin overflow analysis to obtain a garbage bin overflow decision strategy;

extracting the equipment networking state data from the equipment operation state parameter set to obtain target equipment networking state data, inputting the target equipment networking state data into a medicament spraying control model to perform medicament spraying control, and obtaining a medicament spraying control decision strategy;

extracting operation state data from the equipment operation state parameter set to obtain equipment operation time data and equipment fault state data, and inputting the equipment operation time data and the equipment fault state data into an equipment operation abnormality detection model to detect equipment operation abnormality to obtain an equipment operation abnormality decision strategy;

Generating a device decision strategy set according to the garbage bin overflow decision strategy, the medicament spraying control decision strategy and the device operation abnormality decision strategy, and generating a device decision instruction set according to the device decision strategy set.

Specifically, firstly, the collected equipment operation state parameter set is input into a preset equipment operation state parameter decision analysis model set. The model set comprises a garbage can overflow analysis model, a medicament spraying control model, an equipment operation abnormality detection model and the like. And extracting the parameters of the garbage bin from the equipment running state parameter set to obtain capacity data of the garbage bin. Inputting the garbage can capacity data into a garbage can overflow analysis model for analysis, and obtaining a corresponding garbage can overflow decision strategy. For example, if the trash can capacity exceeds a certain threshold, a decision strategy to trigger trash can cleaning is required. And likewise, extracting the device networking state data from the device running state parameter set to obtain the networking state data of the target device. And inputting the networking state data into a medicament spraying control model for analysis to obtain a medicament spraying control decision strategy. For example, when the networking state of the device is abnormal, corresponding measures need to be taken to repair the networking problem or ensure the stability of data transmission. Furthermore, the set of device operational state parameters is subjected to operational state data extraction, including device runtime data and device fault state data. And analyzing the data input device operation abnormality detection model to obtain a decision strategy of device operation abnormality. For example, if the running time of the device exceeds a preset threshold or a fault state occurs, corresponding decision strategies such as maintenance or alarm and the like need to be timely adopted. And generating a device decision strategy set according to the garbage can overflow decision strategy, the medicament spraying control decision strategy and the device operation abnormality decision strategy. These decision strategy sets provide corresponding decision schemes based on the analysis results of the equipment operation state parameters. And finally, generating a device decision instruction set according to the device decision strategy set, wherein the device decision instruction set is used for guiding the operation and adjustment of the device. For example, assume that the device parameter decision unit of the intelligent garbage platform collects parameters such as capacity data of the garbage can, device networking state data, and device running time and fault state. And analyzing the capacity data of the garbage can through a preset garbage can overflow analysis model to obtain a decision strategy for judging whether the garbage can overflows or not. And if the capacity of the garbage can exceeds a set threshold value, generating a corresponding garbage can cleaning instruction. Meanwhile, the networking state data of the equipment is analyzed through the medicament spraying control model, and a control decision strategy of medicament spraying is generated. For example, if the networking state of the device is abnormal, a corresponding control strategy needs to be triggered, such as reconnecting the network or sending an alarm message. In addition, the equipment operation time and fault state data are analyzed through the equipment operation abnormality detection model, and a decision strategy of equipment operation abnormality is generated. For example, when the device run time exceeds a set threshold or a fault condition occurs, a decision strategy is required to trigger maintenance or alarms. From these analysis results, a set of device decision strategies, such as "trash can clean", "networking repair", and "device repair", are formed. And finally, generating a corresponding device decision instruction set according to the device decision strategy set, wherein the device decision instruction set is used for guiding the operation and adjustment of the devices in the garbage management system.

The smart trash platform 104 further includes: the passive pollutant optimizing unit is specifically used for:

acquiring a target equipment model of the intelligent garbage throwing equipment 1011 and garbage room area information of a garbage station room 1012, and analyzing the garbage room area information to obtain delivery area parameter information and clearance area parameter information;

determining a first boundary condition of the delivery area according to the delivery area parameter information, and determining a second boundary condition of the clearing area according to the clearing area parameter information;

establishing a computing grid of the intelligent environmental protection garbage room 101 according to the target equipment model, and determining CFD simulation parameters according to the computing grid, wherein the CFD simulation parameters comprise: time step, solver selection and iterative convergence criteria;

according to the first boundary condition and the second boundary condition, air flow and pollutant simulation are carried out on the delivery area and the clearing area, and a target simulation result is obtained;

generating a target evaluation index of the diffusion condition of pollutants in the delivery area and the positive and negative pressure design according to the target simulation result;

and determining ventilation design optimization schemes of the delivery area and the clearing area according to the target evaluation indexes.

Specifically, the passive contaminant optimization unit in the intelligent waste platform 104 is a key component for optimizing the airflow and contaminant diffusion conditions in the waste room area. The ventilation design optimization of the delivery area and the clearing area is realized by acquiring the target equipment model and garbage room area information of the garbage station room and combining with a computational fluid dynamics (Computational Fluid Dynamics, CFD) simulation technology. First, the passive contaminant optimization unit may obtain a target device model of the intelligent garbage placement device 1011 and garbage room area information of the garbage station room 1012. Such information includes the structure, size, ventilation equipment configuration, etc. of the garbage room. Through analysis of the garbage room area information, delivery area parameter information and clearance area parameter information can be obtained. The delivery zone parameter information provides relevant parameters of the garbage disposal area, such as the position, frequency, speed, etc. of garbage disposal. The clearing area parameter information provides relevant parameters of the clearing area, such as the number of clearing vehicles, clearing frequency, path, etc. Based on the delivery zone parameter information, the passive contaminant optimization unit determines a first boundary condition of the delivery zone. These boundary conditions include vent location of the delivery zone, vent size, and ventilation volume. By proper configuration and adjustment of these boundary conditions, the air flow conditions in the delivery zone can be controlled, thereby affecting the spread of contaminants. Similarly, the passive contaminant optimization unit determines a second boundary condition of the clearing area based on the clearing area parameter information. These boundary conditions relate to the location of the ventilation equipment in the clearance area, the size of the ventilation openings, the amount of ventilation, etc. By optimizing the boundary conditions of the clearing area, the air flow condition of the clearing area can be improved, and the residence time of pollutants can be reduced. Next, the passive contaminant optimization unit builds a computational grid of the intelligent environmental protection garbage room 101 using the target device model. The computational grid is a virtual spatial grid for performing numerical simulations of air flow and contaminant propagation. Based on the computational grid, the passive contaminant optimization unit determines CFD simulation parameters such as time step, solver selection, and iterative convergence criteria. Based on the computational grid and CFD simulation parameters, the passive contaminant optimization unit may perform air flow and contaminant simulation on the delivery area and the clearance area. Through CFD simulation, the relevant information such as the air flow speed, the pressure distribution and the pollutant concentration distribution in the delivery area and the clearing area can be calculated. These simulation results can help the server understand the direction, speed, and spread of the air flow. Based on the simulation result, the passive pollutant optimizing unit generates a target evaluation index of the diffusion condition of pollutants in the delivery area and the positive and negative pressure design. These indicators can measure the distribution of contaminants in the delivery area and whether there is a risk of contamination overflow. According to the evaluation index, the ventilation design of the delivery area can be optimized to reduce the influence of pollutant diffusion to the greatest extent. And finally, determining ventilation design optimization schemes of the delivery area and the clearing area by the passive pollutant optimization unit according to target evaluation indexes and optimization requirements. This includes adjusting the position, number, and ventilation of the ventilation devices, etc., to achieve optimal air flow and contaminant diffusion control. By implementing the optimization scheme, the air quality of the garbage room area can be improved, and the influence of pollutants on the surrounding environment and the human health is reduced. For example, assume that a passive contaminant optimization unit in the smart trash platform 104 performs a contaminant optimization design. And determining the position and ventilation quantity of the ventilation opening in the delivery area of the garbage room area according to the parameter information of the delivery area. Through CFD simulation, current ventilation designs were found to be at risk of contaminant spills, with undesirable diffusion of contaminants within the delivery zone. Based on the target evaluation index, the passive contaminant optimization unit adjusts the position and ventilation amount of the ventilation opening and performs CFD simulation again. After optimization, the simulation result shows that the diffusion condition of pollutants in a delivery area is improved, the air flow is smoother, and the residence time of the pollutants is reduced.

The interactive display module 105 is specifically configured to:

acquiring an equipment layout diagram of the intelligent environment-friendly garbage room 101, and performing interactive display interface mapping according to the equipment layout diagram, delivery area parameter information and clearance area parameter information to obtain an initial interactive display interface;

acquiring an environment decision strategy set and a device decision strategy set of the intelligent garbage platform 104, and carrying out text analysis on the environment decision strategy set and the device decision strategy to obtain target text data;

and visually displaying the target text data through a preset interface container component to generate a target interactive display interface.

Specifically, first, the interactive display module may obtain a device layout diagram of the intelligent environmental protection garbage room 101. The equipment layout provides location and layout information of various equipment in the garbage area, such as garbage cans, sensors, clearance vehicles, and the like. And the interactive display module identifies and positions the equipment in the equipment layout diagram according to the equipment layout diagram so as to display and operate in the interactive display interface. The interactive display module then obtains delivery zone parameter information and clearance zone parameter information. The delivery area parameter information comprises relevant information such as garbage throwing positions, delivery time and the like, and the clearance area parameter information comprises relevant information such as clearance vehicle paths, clearance time and the like. And the interactive display module maps the delivery area and the clearance area on the interactive display interface according to the parameter information and the equipment layout diagram, and forms an initial interactive display interface. Meanwhile, the interactive display module also acquires an environment decision strategy set and a device decision strategy set of the intelligent garbage platform 104. The environment decision strategy set comprises related strategies such as garbage disposal, clearance scheduling and the like, and the equipment decision strategy set comprises related strategies such as equipment operation control, fault handling and the like. The interactive display module performs text parsing on the strategy sets and converts the strategy sets into processable target text data. And finally, the interactive display module performs visual display on the target text data through a preset interface container assembly to generate a target interactive display interface. The interface container component may include interactive elements such as charts, indicators, buttons, text boxes, etc. for presenting and manipulating the target text data. And the interactive display module displays the target text data in a visual mode in an interactive display interface according to the content and the format of the target text data, and provides visual information and an operation interface for a user. For example, assume that interactive display module 105 is presenting an interactive display interface of smart trash platform 104. According to the device layout diagram of the intelligent environment-friendly garbage room 101, the positions and types of all devices, such as garbage cans, sensors and the like, are identified on the interactive display interface. Meanwhile, according to the delivery area parameter information and the clearance area parameter information, the boundary, the path and other information of the delivery area and the clearance area are displayed on the interactive display interface, so that a user can know the garbage throwing and clearance conditions. The interactive display interface also displays information of the environment decision strategy set and the equipment decision strategy set. For example, the interface may display current garbage disposal policies, decision policies on how to deal with garbage can overflow or abnormal conditions, policies for equipment operation control and fault handling, and the like. The information is visually displayed through the interface container component, so that a user can intuitively know the running state and decision strategy of the intelligent garbage platform.

The intelligent garbage throwing device 1011 is specifically configured to:

acquiring weight sensing data and object sensing data based on a weight sensing area and an object sensing area preset in the intelligent garbage throwing device 1011;

extracting weight characteristics of the weight sensing data to obtain weight characteristic information, and calculating the distance between the object sensing data and the intelligent garbage throwing device 1011 to obtain throwing distance data;

according to the weight characteristic information and the throwing distance data, a throwing port opening or closing instruction of the intelligent garbage throwing device 1011 is generated;

and opening or closing the opening of the intelligent garbage throwing device 1011 is controlled by an opening or closing instruction of the throwing opening.

Specifically, first, a weight sensing area and an object sensing area are preset in the smart trash placement device 1011. The weight sensing area is used for detecting the weight change of the garbage, and the object sensing area is used for detecting the approaching or separating condition of an object. The device collects weight sensing data and object sensing data through the two regions. Next, the intelligent garbage placement device 1011 performs weight feature extraction with respect to the weight sensing data. The purpose of weight feature extraction is to extract feature information related to the delivery operation from the acquired weight sensing data. For example, the characteristics of weight difference, weight change rate and the like before and after garbage throwing can be extracted, so that subsequent judgment and decision can be made. Meanwhile, the intelligent garbage throwing device 1011 also calculates the distance between the object sensing data and the device, and obtains throwing distance data. The distance data can be used to determine the distance between an object (e.g., a hand or a garbage bag) and the dispensing opening, and thus determine whether the dispensing opening needs to be opened or closed. Next, based on the weight characteristic information and the delivery distance data, the smart trash delivery apparatus 1011 generates an opening or closing instruction of the delivery port. According to preset throwing rules and strategies, the equipment can determine the opening and closing states of the throwing ports according to the conditions of weight change and object distance. For example, when the weight sensing data indicates that the weight of the garbage is above a certain threshold and the object sensing data indicates that the distance between the object and the dispensing opening is within a suitable range, the device may generate an instruction to open the dispensing opening. Finally, through the opening or closing instruction of the throwing port, the intelligent garbage throwing device 1011 controls the throwing port correspondingly. The device can execute the action of opening or closing the throwing port according to the generated instruction so as to finish garbage throwing operation. For example, the intelligent garbage throwing device 1011 senses the garbage throwing process, the weight sensing area can acquire weight data, and the object sensing area can detect the approaching condition of the object. According to the acquired weight data, the equipment performs weight characteristic extraction and compares the weight difference between the current weight and the previous moment. Meanwhile, according to the object sensing data, the device calculates the distance between the object and the throwing port. And according to the weight characteristic information and the throwing distance data, the equipment generates a corresponding throwing port opening or closing instruction. If the weight change is greater than a preset threshold value and the distance between the object and the throwing port is proper, the device can generate an instruction for opening the throwing port, so that the garbage can be smoothly thrown into the garbage can.

In an embodiment of the present invention, a system includes: the intelligent garbage collection system comprises an intelligent environment-friendly garbage room, an environment parameter monitoring module, an equipment operation monitoring module, an intelligent garbage platform and an interactive display module; the intelligent environment-friendly garbage room comprises intelligent garbage throwing equipment and a garbage station room; the environment parameter monitoring module is respectively connected with the garbage station room and the intelligent garbage platform, the equipment operation monitoring module is respectively connected with the intelligent garbage throwing equipment and the intelligent garbage platform, and the intelligent garbage platform is connected with the interactive display module; the invention is suitable for building basements, overhead floors and floors of various communities; all original garbage throwing points such as office buildings, schools, hospitals, parks, industrial parks and the like are used for constructing a non-contact throwing, odorless, degerming, tidy and healthy throwing environment, classifying garbage, non-contact throwing boxes, deodorizing, decontaminating, degerming, convenient transportation, cleaning garbage houses, intelligent control, intelligent index monitoring and intelligent data display technology integration, guaranteeing high-quality throwing environments of households at equipment levels, further realizing intelligent monitoring and control of garbage throwing equipment, and guaranteeing health, comfort and convenient experience of the households in all directions by carrying out pain point analysis, standard formulation and optimal design on spaces in front areas, back areas and station rooms.

The information acquisition system of the garbage throwing device in the embodiment of the invention is described above, and the intelligent garbage room in the embodiment of the invention is described below, wherein one embodiment of the intelligent garbage room in the embodiment of the invention comprises:

the intelligent garbage room executes the information acquisition system of the garbage throwing device according to the first aspect of the invention, and the information acquisition system of the garbage throwing device comprises: the intelligent garbage collection system comprises an intelligent environment-friendly garbage room, an environment parameter monitoring module, an equipment operation monitoring module, an intelligent garbage platform and an interactive display module; the intelligent environment-friendly garbage room comprises intelligent garbage throwing equipment and a garbage station room; the environment parameter detection module is used for monitoring the garbage station room and is connected with the intelligent garbage platform, the equipment operation monitoring module is respectively connected with the intelligent garbage throwing equipment and the intelligent garbage platform, and the intelligent garbage platform is connected with the interactive display module;

the environment parameter monitoring module is used for: collecting an environmental parameter index set of the garbage station room, and transmitting the environmental parameter index set to the intelligent garbage platform; receiving and responding to an environment decision instruction set issued by the intelligent garbage platform;

The equipment operation monitoring module is used for: collecting a device running state parameter set of the intelligent garbage throwing device, and transmitting the device running state parameter set to the intelligent garbage platform; receiving and responding to a device decision instruction set issued by the intelligent garbage platform;

the intelligent garbage platform is used for: inputting the environmental parameter index set into a preset environmental parameter decision analysis model set for environmental parameter analysis to obtain an environmental decision strategy set, and generating the environmental decision instruction set according to the environmental decision strategy set; inputting the equipment operation state parameter set into a preset equipment operation state parameter decision analysis model set to analyze the equipment operation state parameter, obtaining an equipment decision strategy set, and generating the equipment decision instruction set according to the equipment decision strategy set; and sending the environment decision strategy set and the equipment decision strategy set to the interactive display module for visual interactive display.

Optionally, the intelligent garbage room executes the information acquisition system of the garbage throwing device according to the first aspect of the present invention, and the intelligent garbage platform includes: the environment parameter decision unit is specifically used for:

Inputting the environment parameter index set into a preset environment parameter clustering model, and calculating a plurality of first data labels corresponding to the environment parameter index set through the environment parameter clustering model;

performing label distance calculation on the environment parameter index set and the plurality of first data labels to obtain a plurality of label distance data of each first data label, and performing average analysis on the plurality of label distance data of each first data label to obtain a target label distance of each first data label;

performing model parameter replacement on the environment parameter clustering model through the target tag distance to obtain a target parameter clustering model;

performing data tag optimization operation on the plurality of first data tags through the target parameter clustering model to obtain a plurality of second data tags, and performing data tag clustering analysis on the environment parameter index set through the plurality of second data tags to obtain a plurality of target environment parameter data, wherein the plurality of target environment parameter data comprise: temperature and humidity data and air quality data;

inputting the plurality of target environmental parameter data into a preset environmental parameter decision analysis model set, wherein the environmental parameter decision analysis model set comprises: a temperature and humidity detection model, a garbage room odor detection model and a volatile organic compound concentration detection model;

And respectively carrying out environmental parameter analysis on the plurality of target environmental parameter data through the environmental parameter decision analysis model set to obtain an environmental decision strategy set, and generating the environmental decision instruction set according to the environmental decision strategy set.

Optionally, the intelligent garbage room executes the information acquisition system of the garbage throwing device according to the first aspect of the present invention, and the intelligent garbage platform further includes: the device parameter decision unit is specifically configured to:

inputting the equipment operation state parameter set into a preset equipment operation state parameter decision analysis model set, wherein the equipment operation state parameter decision analysis model set comprises: the garbage can overflow analysis model, the medicament spraying control model and the equipment operation abnormality detection model;

extracting the parameters of the garbage bin from the running state parameter set of the equipment to obtain garbage bin capacity data, and inputting the garbage bin capacity data into the garbage bin overflow analysis model to carry out garbage bin overflow analysis to obtain a garbage bin overflow decision strategy;

extracting the equipment networking state data from the equipment operation state parameter set to obtain target equipment networking state data, inputting the target equipment networking state data into the medicament spraying control model to perform medicament spraying control, and obtaining a medicament spraying control decision strategy;

Extracting running state data of the equipment running state parameter set to obtain equipment running time data and equipment fault state data, and inputting the equipment running time data and the equipment fault state data into the equipment running abnormality detection model to detect equipment running abnormality to obtain an equipment running abnormality decision strategy;

generating a device decision strategy set according to the garbage bin overflow decision strategy, the medicament spraying control decision strategy and the device operation abnormality decision strategy, and generating the device decision instruction set according to the device decision strategy set.

Optionally, the intelligent garbage room executes the information acquisition system of the garbage throwing device according to the first aspect of the present invention, and the intelligent garbage platform further includes: the passive pollutant optimizing unit is specifically used for:

acquiring a target equipment model of the intelligent garbage throwing equipment and garbage room area information of the garbage station room, and analyzing the garbage room area information to obtain delivery area parameter information and clearance area parameter information;

determining a first boundary condition of a delivery zone according to the delivery zone parameter information, and determining a second boundary condition of a clearing zone according to the clearing zone parameter information;

Establishing a computing grid of the intelligent environment-friendly garbage room according to the target equipment model, and determining CFD simulation parameters according to the computing grid, wherein the CFD simulation parameters comprise: time step, solver selection and iterative convergence criteria;

according to the first boundary condition and the second boundary condition, performing air flow and pollutant simulation on the delivery area and the clearing area to obtain a target simulation result;

generating a target evaluation index of the diffusion condition of pollutants in the delivery area and positive and negative pressure design according to the target simulation result;

and determining ventilation design optimization schemes of the delivery area and the clearing area according to the target evaluation indexes.

Optionally, the intelligent garbage room executes the information acquisition system of the garbage throwing device according to the first aspect of the present invention, and the interactive display module is specifically configured to:

acquiring an equipment layout diagram of the intelligent environment-friendly garbage room, and performing interactive display interface mapping according to the equipment layout diagram, the delivery area parameter information and the clearance area parameter information to obtain an initial interactive display interface;

acquiring the environment decision strategy set and the equipment decision strategy set of the intelligent garbage platform, and carrying out text analysis on the environment decision strategy set and the equipment decision strategy to obtain target text data;

And visually displaying the target text data through a preset interface container component to generate a target interactive display interface.

Optionally, the intelligent garbage room executes the information acquisition system of the garbage throwing device according to the first aspect of the present invention, where the intelligent garbage throwing device is specifically configured to:

acquiring weight sensing data and object sensing data based on a weight sensing area and an object sensing area which are preset in the intelligent garbage throwing equipment;

extracting weight characteristics of the weight sensing data to obtain weight characteristic information, and calculating the distance between the object sensing data and the intelligent garbage throwing device to obtain throwing distance data;

generating a throwing port opening or closing instruction of the intelligent garbage throwing device according to the weight characteristic information and the throwing distance data;

and opening or closing the opening of the intelligent garbage throwing device is controlled by the opening or closing instruction of the throwing opening.

By the cooperative cooperation of the above components, the system comprises: the intelligent garbage collection system comprises an intelligent environment-friendly garbage room, an environment parameter monitoring module, an equipment operation monitoring module, an intelligent garbage platform and an interactive display module; the intelligent environment-friendly garbage room comprises intelligent garbage throwing equipment and a garbage station room; the environment parameter detection module is used for monitoring the garbage station room and is connected with the intelligent garbage platform, the equipment operation monitoring module is respectively connected with the intelligent garbage throwing equipment and the intelligent garbage platform, and the intelligent garbage platform is connected with the interactive display module; the invention is suitable for building basements, overhead floors and floors of various communities; all original garbage throwing points such as office buildings, schools, hospitals, parks, industrial parks and the like are used for constructing a non-contact throwing, odorless, degerming, tidy and healthy throwing environment, classifying garbage, non-contact throwing boxes, deodorizing, decontaminating, degerming, convenient transportation, cleaning garbage houses, intelligent control, intelligent index monitoring and intelligent data display technology integration, guaranteeing high-quality throwing environments of households at equipment levels, further realizing intelligent monitoring and control of garbage throwing equipment, and guaranteeing health, comfort and convenient experience of the households in all directions by carrying out pain point analysis, standard formulation and optimal design on spaces in front areas, back areas and station rooms.

It will be clear to those skilled in the art that, for convenience and brevity of description, specific working procedures of the above-described systems, apparatuses and units may refer to corresponding procedures in the foregoing method embodiments, which are not repeated herein.

The integrated units, if implemented in the form of software functional units and sold or used as stand-alone products, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present invention may be embodied essentially or in part or all of the technical solution or in part in the form of a software product stored in a storage medium, including instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to perform all or part of the steps of the method according to the embodiments of the present invention. And the aforementioned storage medium includes: a U-disk, a removable hard disk, a read-only memory (ROM), a random access memory (random acceS memory, RAM), a magnetic disk, or an optical disk, or other various media capable of storing program codes.

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 technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (5)

1. An information acquisition system of a garbage throwing device, which is characterized by comprising: the intelligent garbage collection system comprises an intelligent environment-friendly garbage room, an environment parameter monitoring module, an equipment operation monitoring module, an intelligent garbage platform and an interactive display module; the intelligent environment-friendly garbage room comprises intelligent garbage throwing equipment and a garbage station room; the environment parameter detection module is used for monitoring the garbage station room and is connected with the intelligent garbage platform, the equipment operation monitoring module is respectively connected with the intelligent garbage throwing equipment and the intelligent garbage platform, and the intelligent garbage platform is connected with the interactive display module;

The environment parameter monitoring module is used for: collecting an environmental parameter index set of the garbage station room, and transmitting the environmental parameter index set to the intelligent garbage platform; receiving and responding to an environment decision instruction set issued by the intelligent garbage platform;

the equipment operation monitoring module is used for: collecting a device running state parameter set of the intelligent garbage throwing device, and transmitting the device running state parameter set to the intelligent garbage platform; receiving and responding to a device decision instruction set issued by the intelligent garbage platform;

the intelligent garbage platform is used for: inputting the environmental parameter index set into a preset environmental parameter decision analysis model set for environmental parameter analysis to obtain an environmental decision strategy set, and generating the environmental decision instruction set according to the environmental decision strategy set; inputting the equipment operation state parameter set into a preset equipment operation state parameter decision analysis model set to analyze the equipment operation state parameter, obtaining an equipment decision strategy set, and generating the equipment decision instruction set according to the equipment decision strategy set; the environment decision strategy set and the equipment decision strategy set are sent to the interactive display module for visual interactive display; wherein, intelligent rubbish platform includes: the environment parameter decision unit is specifically used for: inputting the environment parameter index set into a preset environment parameter clustering model, and calculating a plurality of first data labels corresponding to the environment parameter index set through the environment parameter clustering model; performing label distance calculation on the environment parameter index set and the plurality of first data labels to obtain a plurality of label distance data of each first data label, and performing average analysis on the plurality of label distance data of each first data label to obtain a target label distance of each first data label; performing model parameter replacement on the environment parameter clustering model through the target tag distance to obtain a target parameter clustering model; performing data tag optimization operation on the plurality of first data tags through the target parameter clustering model to obtain a plurality of second data tags, and performing data tag clustering analysis on the environment parameter index set through the plurality of second data tags to obtain a plurality of target environment parameter data, wherein the plurality of target environment parameter data comprise: temperature and humidity data and air quality data; inputting the plurality of target environmental parameter data into a preset environmental parameter decision analysis model set, wherein the environmental parameter decision analysis model set comprises: a temperature and humidity detection model, a garbage room odor detection model and a volatile organic compound concentration detection model; and respectively carrying out environmental parameter analysis on the plurality of target environmental parameter data through the environmental parameter decision analysis model set to obtain an environmental decision strategy set, and generating the environmental decision instruction set according to the environmental decision strategy set.

2. The information collection system of a garbage disposal apparatus of claim 1, wherein the intelligent garbage platform further comprises: the device parameter decision unit is specifically configured to:

inputting the equipment operation state parameter set into a preset equipment operation state parameter decision analysis model set, wherein the equipment operation state parameter decision analysis model set comprises: the garbage can overflow analysis model, the medicament spraying control model and the equipment operation abnormality detection model;

extracting the parameters of the garbage bin from the running state parameter set of the equipment to obtain garbage bin capacity data, and inputting the garbage bin capacity data into the garbage bin overflow analysis model to carry out garbage bin overflow analysis to obtain a garbage bin overflow decision strategy;

extracting the equipment networking state data from the equipment operation state parameter set to obtain target equipment networking state data, inputting the target equipment networking state data into the medicament spraying control model to perform medicament spraying control, and obtaining a medicament spraying control decision strategy;

extracting running state data of the equipment running state parameter set to obtain equipment running time data and equipment fault state data, and inputting the equipment running time data and the equipment fault state data into the equipment running abnormality detection model to detect equipment running abnormality to obtain an equipment running abnormality decision strategy;

Generating a device decision strategy set according to the garbage bin overflow decision strategy, the medicament spraying control decision strategy and the device operation abnormality decision strategy, and generating the device decision instruction set according to the device decision strategy set.

3. The information collection system of a garbage disposal apparatus of claim 1, wherein the intelligent garbage platform further comprises: the passive pollutant optimizing unit is specifically used for:

acquiring a target equipment model of the intelligent garbage throwing equipment and garbage room area information of the garbage station room, and analyzing the garbage room area information to obtain delivery area parameter information and clearance area parameter information;

determining a first boundary condition of a delivery zone according to the delivery zone parameter information, and determining a second boundary condition of a clearing zone according to the clearing zone parameter information;

establishing a computing grid of the intelligent environment-friendly garbage room according to the target equipment model, and determining CFD simulation parameters according to the computing grid, wherein the CFD simulation parameters comprise: time step, solver selection and iterative convergence criteria;

According to the first boundary condition and the second boundary condition, performing air flow and pollutant simulation on the delivery area and the clearing area to obtain a target simulation result;

generating a target evaluation index of the diffusion condition of pollutants in the delivery area and positive and negative pressure design according to the target simulation result;

and determining ventilation design optimization schemes of the delivery area and the clearing area according to the target evaluation indexes.

4. The information collection system of a garbage disposal apparatus according to claim 3, wherein the interactive display module is specifically configured to:

acquiring an equipment layout diagram of the intelligent environment-friendly garbage room, and performing interactive display interface mapping according to the equipment layout diagram, the delivery area parameter information and the clearance area parameter information to obtain an initial interactive display interface;

acquiring the environment decision strategy set and the equipment decision strategy set of the intelligent garbage platform, and carrying out text analysis on the environment decision strategy set and the equipment decision strategy to obtain target text data;

and visually displaying the target text data through a preset interface container component to generate a target interactive display interface.

5. The information collection system of a garbage disposal apparatus according to claim 1, wherein the intelligent garbage disposal apparatus is specifically configured to:

acquiring weight sensing data and object sensing data based on a weight sensing area and an object sensing area which are preset in the intelligent garbage throwing equipment;

extracting weight characteristics of the weight sensing data to obtain weight characteristic information, and calculating the distance between the object sensing data and the intelligent garbage throwing device to obtain throwing distance data;

generating a throwing port opening or closing instruction of the intelligent garbage throwing device according to the weight characteristic information and the throwing distance data;

and opening or closing the opening of the intelligent garbage throwing device is controlled by the opening or closing instruction of the throwing opening.