CN114881831A - Garden carbon emission monitoring method based on industrial internet - Google Patents

Abstract

The invention discloses a method for monitoring carbon emission of a park based on an industrial internet, belonging to the technical field of carbon emission monitoring and comprising the following specific steps: the method comprises the following steps: acquiring a park drawing and park information, and dividing a monitoring area according to the acquired park drawing and park information; step two: setting a monitoring area label, and matching a corresponding monitoring scheme according to the monitoring area label; step three: arranging monitoring devices according to the obtained monitoring scheme, and performing real-time data acquisition to obtain monitoring data; step four: acquiring a park drawing, establishing a park display model according to the acquired park drawing, and inputting acquired monitoring data into the park display model for real-time display; through monitoring regional division, the monitoring area in the rational planning garden guarantees the accuracy of monitoring data from many aspects, solves because of remaining the organic matter of not thorough oxidation in the waste gas, increases the error problem between monitoring emission and the actual emission, improves the accuracy of monitoring data.

Description

Garden carbon emission monitoring method based on industrial internet

Technical Field

The invention belongs to the technical field of carbon emission monitoring, and particularly relates to a park carbon emission monitoring method based on an industrial internet.

Background

In the industrial production, waste gas is generally discharged, if the concentration of carbon dioxide is too high, environmental pollution is easily caused, the problems of greenhouse effect and the like are caused in the discharging process, and in order to avoid the problems of environmental pollution and the like, the discharge needs to be monitored at any time; the currently common monitoring mode is to set a corresponding gas collector in the waste discharge pipe, collect a certain volume of discharge gas through the gas collector, monitor the carbon dioxide content in the discharge gas, and finally determine the actual carbon dioxide discharge amount according to the conversion of a certain proportion.

The current commonly used monitoring mode has the following technical problems: the single monitoring point carries out quantitative monitoring and is difficult to accurately reflect the actual emission, leads to the monitoring result error great, is difficult to the real-time carbon emission of accurate judgement, and in the exhaust-gas treatment process, still remain the organic matter of not thorough oxidation in the waste gas moreover, and the organic matter can carry out secondary oxidation and produce a certain amount of carbon dioxide in the air of emission process, has further increased the error between monitoring emission and the actual emission.

Accordingly, the present invention has been made to solve the above-mentioned problems, or portions thereof, and to provide a method for monitoring carbon emissions in a campus based on the industrial internet.

Disclosure of Invention

In order to solve the problems existing in the scheme, the invention provides a method for monitoring the carbon emission of a park based on an industrial internet.

The purpose of the invention can be realized by the following technical scheme:

a garden carbon emission monitoring method based on an industrial internet specifically comprises the following steps:

the method comprises the following steps: acquiring a park drawing and park information, and dividing a monitoring area according to the acquired park drawing and park information;

step two: setting a monitoring area label, and matching a corresponding monitoring scheme according to the monitoring area label;

step three: arranging monitoring devices according to the obtained monitoring scheme, and performing real-time data acquisition to obtain monitoring data;

step four: acquiring a park drawing, establishing a park display model according to the acquired park drawing, and inputting acquired monitoring data into the park display model for real-time display;

the method for matching the corresponding monitoring scheme according to the monitoring area label comprises the following steps:

establishing a single scheme library and a region monitoring scheme matching library, identifying a monitoring region label needing to be matched, respectively inputting the monitoring region label into the single scheme library and the region monitoring scheme matching library for matching, obtaining a corresponding region monitoring scheme and a single monitoring scheme, and integrating the obtained region monitoring scheme and the single monitoring scheme into a monitoring scheme for outputting.

Further, the method for dividing the monitoring area according to the acquired park drawing and the park information comprises the following steps:

identifying a target factory in a garden drawing according to garden information, marking a target factory area, setting a maximum representative radius of a monitoring area, and marking the maximum representative radius of the monitoring area as Rmax; calculating the representative radius of each target factory, and establishing a corresponding range circle in a garden drawing according to the calculated representative radius of the target factory; numbering the range circles according to the target factory representative radius and the target factory position;

selecting a range circle with a first serial number sequence as a merging center for merging to obtain a new center circle, identifying the radius of the new center circle, merging again when the radius of the new center circle is not larger than the maximum representative radius until the radius of the new center circle is larger than the maximum representative radius, performing regression processing to obtain a merging circle, and integrally marking a target factory area included in the merging circle as a monitoring area; and so on until all monitoring area divisions are completed.

Further, the method of calculating the representative radius of each target plant includes:

the method comprises the steps of obtaining the carbon emission of a target factory and the distance between the target factories, marking the carbon emission outlets of the target factories in a garden drawing, and marking the obtained carbon emission and the distance between the target factories on corresponding positions in the garden drawing; acquiring production information of a target factory, setting a scaling coefficient of the target factory according to the acquired production information, marking carbon emission as TP, marking a distance between the target factories as XBL, and marking the scaling coefficient of the target factory as SF; and calculating the representative radius of each target factory according to a representative radius formula Rd which is lambda multiplied by alpha multiplied by TP multiplied by SF, wherein lambda is a correction factor, the value range is 0< lambda is less than or equal to 1, and alpha is a conversion coefficient.

Further, the method for selecting the range circle with the first serial number sequence as the merging center for merging comprises the following steps:

marking the range circle with the first serial number sequence as a center circle, identifying the center of the range circle contained in the center circle and the range circle intersected with the center circle, merging the range circles according to the contact relation priority, identifying the representative radius and the center point coordinate of the corresponding merged range circle, calculating the merged radius, setting the center of a new center circle after merging according to the center point coordinate of the range circle and the center point coordinate of the center circle, and setting the new center circle to replace the original center circle and range circle according to the center point coordinate and the merged radius of the new center circle.

Further, the method for calculating the merge radius includes:

according to the formula of the combined radius Rd ═ r ₀ +Rd ₁ ) X η calculating the radius of merger, where Rd ₀ Is the center circle radius, Rd1 is the range circle radius, and η is the radius adjustment factor.

Further, the method for setting the monitoring area label comprises the following steps:

the method comprises the steps of obtaining the carbon emission gas types of all target factories in a monitoring area, setting corresponding target factory label assignments according to the obtained carbon emission gas types, obtaining the corresponding combined circle radius of the monitoring area, integrating the obtained combined circle radius and the target factory label assignments into a monitoring area label, and marking the monitoring area label.

Further, the method for establishing the single item scheme library comprises the following steps:

and obtaining the assigned value of the target factory label, setting a corresponding single monitoring scheme according to the assigned value of the target factory label, printing the corresponding assigned value label of the target factory on the single monitoring scheme, and establishing a single scheme library according to the single monitoring scheme.

Further, the method for establishing the matching library of the regional monitoring scheme comprises the following steps:

non-repeated combination is carried out according to the single monitoring scheme in the single scheme library, the regional monitoring scheme is compiled according to the single monitoring scheme combination, and a corresponding combination assignment label is marked on the regional monitoring scheme; and establishing a region monitoring scheme matching library according to the region monitoring scheme.

Compared with the prior art, the invention has the beneficial effects that: by dividing the monitoring area, reasonably planning the monitoring area in the park, ensuring the accuracy of monitoring data from multiple aspects, solving the problem that the organic matters which are not completely oxidized are remained in the waste gas, and can be secondarily oxidized in the air in the discharging process to generate a certain amount of carbon dioxide, further increasing the error between the monitored discharge amount and the actual discharge amount, and improving the accuracy of the monitoring data; by establishing the garden display model, the garden management personnel can visually know the carbon emission condition in the garden conveniently.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a flow chart of the method of the present invention.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

As shown in fig. 1, the industrial internet-based campus carbon emission monitoring method specifically comprises the following steps:

the method comprises the following steps: acquiring a park drawing and park information, and dividing monitoring areas according to the acquired park drawing and the park information;

the campus information includes information on the use, location, gas emission, etc. of each plant in the campus.

The method for dividing the monitoring area according to the acquired park drawing and the park information comprises the following steps:

identifying a target factory in a garden drawing according to the garden information, namely a factory which emits greenhouse gases such as carbon dioxide; marking target factory areas, acquiring the carbon emission of target factories and the distance between the target factories, marking the carbon emission outlets of the target factories in a garden drawing, and marking the acquired carbon emission and the distance between the target factories on corresponding positions in the garden drawing; acquiring production information of a target factory, setting a scaling factor of the target factory according to the acquired production information, marking the carbon emission as TP, marking the distance between the target factories as XBL and marking the scaling factor of the target factory as SF; setting the maximum representative radius of the monitoring area, setting by an expert group according to the actual situation, and marking the maximum representative radius of the monitoring area as Rmax; calculating the representative radius of each target factory according to a representative radius formula Rd which is lambda multiplied by alpha multiplied by TP multiplied by SF, wherein lambda is a correction factor, the value range is 0< lambda is less than or equal to 1, alpha is a conversion coefficient, and a corresponding carbon emission conversion coefficient matching table is set by an expert group according to historical data; establishing a corresponding range circle in the garden drawing according to the calculated representative radius of the target factory; numbering the range circles according to the target factory representative radius and the target factory position;

selecting a range circle with a first serial number sequence as a merging center for merging to obtain a new center circle, identifying the radius of the new center circle, merging again when the radius of the new center circle is not larger than the maximum representative radius until the radius of the new center circle is larger than the maximum representative radius, performing regression processing to obtain a merging circle, and integrally marking a target factory area included in the merging circle as a monitoring area; and so on until all monitoring area divisions are completed.

The process of demoting is to cancel the previous merged area.

The distance between the respective target plants refers to the distance between the discharge ports of the target plants.

And setting a scaling coefficient of a target plant according to the obtained production information, namely setting by an expert group according to information such as the type of carbon emission gas in the production information, the type of plant production and the like, and establishing a corresponding matching table, wherein the specific unpublished part is common knowledge in the field.

Numbering is carried out according to the target factory representative radius and the target factory representative position as a range circle, the numbering sequence is the sequence which is preferentially taken as a merging center, the numbering can be carried out in a manual mode or in a mode of training a neural network model, and the specific unpublished part is common knowledge in the field.

The method for selecting the range circle with the first serial number sequence as the merging center for merging comprises the following steps:

marking the range circle with the first serial number sequence as a center circle, identifying the range circle center contained in the center circle and the range circle intersected with the center circle, merging the range circles according to the contact relation priority, identifying the representative radius and the center point coordinate of the corresponding merged range circle, and obtaining the merged radius formula Rd' ═ Rd (Rd) ₀ +Rd ₁ ) X η calculating the radius of merger, where Rd ₀ Is a central circle radius, Rd ₁ The radius is the radius of the range circle, eta is the radius adjustment coefficient, matching is carried out according to the difference value between the radius of the center circle and the radius of the range circle, and a corresponding matching table is set by an expert group, which is the common knowledge in the field specifically; setting a new center circle center after combination according to the center point coordinates of the range circle and the center point coordinates of the center circle, and setting a new center circle center according to the new center circle neutralization combination radiusThe center circle replaces the original center circle and range circle.

A range circle intersecting a center circle means that the corresponding range circle center is outside the center circle.

Contact relationship priority is the priority of the containment relationship over the intersection relationship, with the closest priority being given to the peer, and so on.

Step two: setting a monitoring area label, and matching a corresponding monitoring scheme according to the monitoring area label;

the method for setting the monitoring area label comprises the following steps:

the method comprises the steps of obtaining the carbon emission gas types of all target factories in a monitoring area, setting corresponding target factory label assignments according to the obtained carbon emission gas types, obtaining the corresponding combined circle radius of the monitoring area, integrating the obtained combined circle radius and the target factory label assignments into a monitoring area label, and marking the monitoring area label.

The method comprises the steps of setting corresponding target factory label assignment according to the obtained carbon emission gas type, namely judging whether the gas type emitted by the plant is changed when the gas type is emitted into the air or not to generate new greenhouse gases such as carbon dioxide, wherein in the waste gas treatment process, organic matters which are not completely oxidized still remain in the waste gas possibly, and the organic matters can be secondarily oxidized in the air to generate a certain amount of carbon dioxide in the emission process, so that a corresponding label assignment matching table is set by an expert group according to the property of the gas type emitted, matching is carried out to obtain the corresponding target factory label assignment, and the specific undisclosed part is common knowledge in the field.

And integrating the obtained combination circle radius and the target factory label assignment into a monitoring area label, namely integrating corresponding numerical values to form a corresponding matching assignment label, and marking the matching assignment label as the monitoring area label.

The method for matching the corresponding monitoring scheme according to the monitoring area label comprises the following steps:

obtaining the assigned value of the target factory label, setting a corresponding single monitoring scheme according to the assigned value of the target factory label, marking the corresponding assigned value label of the target factory on the single monitoring scheme, and establishing a single scheme library according to the single monitoring scheme;

non-repeated combination is carried out according to a single monitoring scheme in a single scheme library, and a regional monitoring scheme is compiled according to the combination of the single monitoring scheme, wherein the regional monitoring scheme is used for monitoring control in a monitoring region and is discussed and set by an expert group; marking a corresponding combined assignment tag for the area monitoring scheme; establishing a region monitoring scheme matching library according to the region monitoring scheme;

and identifying a monitoring area label needing to be matched, respectively inputting the monitoring area label into the single scheme library and the area monitoring scheme matching library for matching, obtaining a corresponding area monitoring scheme and a single monitoring scheme, and integrating the obtained area monitoring scheme and the single monitoring scheme into a monitoring scheme for outputting.

The corresponding single monitoring scheme is set according to the tag assignment of the target plant, namely the monitoring scheme is specifically compiled, a manual mode is adopted for compiling, the tag assignment method is suitable for the interior of the target plant, and a corresponding detection device is generally set in a corresponding discharge device for monitoring.

Step three: arranging monitoring devices according to the obtained monitoring scheme, and performing real-time data acquisition to obtain monitoring data;

step four: acquiring a park drawing, establishing a park display model according to the acquired park drawing, and inputting acquired monitoring data into the park display model for real-time display;

the park drawings refer to the park drawings after the marks are processed in the previous step.

The park display model is a park three-dimensional data model capable of displaying monitoring data, and the specific establishing process is common knowledge in the field, so detailed description is not given.

The park display model displays the overproof data in the monitoring data in a distinguishing manner, corresponding alarm information can be set according to needs, corresponding data intervals can be set at corresponding display data, the data exceeding the data intervals are regarded as the overproof data, corresponding data conversion algorithms can be set for certain data to convert the data, the converted data are displayed, and the specific unpublished part is common knowledge in the field, so that detailed description is omitted.

The above formulas are all calculated by removing dimensions and taking numerical values thereof, the formula is a formula which is obtained by acquiring a large amount of data and performing software simulation to obtain the closest real situation, and the preset parameters and the preset threshold value in the formula are set by the technical personnel in the field according to the actual situation or obtained by simulating a large amount of data.

The working principle of the invention is as follows: acquiring a park drawing and park information, and dividing a monitoring area according to the acquired park drawing and park information; identifying target plants in the garden drawing according to the garden information, marking target plant areas, setting the maximum representative radius of a monitoring area, calculating the representative radius of each target plant, and establishing a corresponding range circle in the garden drawing according to the calculated representative radius of the target plant; numbering the range circles according to the target factory representative radius and the target factory position; selecting a range circle with a first serial number sequence as a merging center for merging to obtain a new center circle, identifying the radius of the new center circle, merging again when the radius of the new center circle is not larger than the maximum representative radius until the radius of the new center circle is larger than the maximum representative radius, performing regression processing to obtain a merging circle, and integrally marking a target factory area included in the merging circle as a monitoring area; and so on until all monitoring area divisions are completed;

setting a monitoring area label, establishing a single scheme library and a regional monitoring scheme matching library, identifying the monitoring area label needing to be matched, respectively inputting the monitoring area label into the single scheme library and the regional monitoring scheme matching library for matching, obtaining a corresponding regional monitoring scheme and a single monitoring scheme, and integrating the obtained regional monitoring scheme and the single monitoring scheme into a monitoring scheme for outputting; arranging monitoring devices according to the obtained monitoring scheme, and performing real-time data acquisition to obtain monitoring data; acquiring a park drawing, establishing a park display model according to the acquired park drawing, and inputting the acquired monitoring data into the park display model for real-time display.

Although the present invention has been described in detail with reference to the preferred embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the spirit and scope of the present invention.

Claims (8)

1. A campus carbon emission monitoring method based on an industrial internet is characterized by comprising the following specific steps:

the method comprises the following steps: acquiring a park drawing and park information, and dividing a monitoring area according to the acquired park drawing and park information;

step two: setting a monitoring area label, and matching a corresponding monitoring scheme according to the monitoring area label;

step three: arranging monitoring devices according to the obtained monitoring scheme, and performing real-time data acquisition to obtain monitoring data;

step four: acquiring a park drawing, establishing a park display model according to the acquired park drawing, and inputting acquired monitoring data into the park display model for real-time display;

the method for matching the corresponding monitoring scheme according to the monitoring area label comprises the following steps:

establishing a single scheme library and a region monitoring scheme matching library, identifying a monitoring region label needing to be matched, respectively inputting the monitoring region label into the single scheme library and the region monitoring scheme matching library for matching, obtaining a corresponding region monitoring scheme and a single monitoring scheme, and integrating the obtained region monitoring scheme and the single monitoring scheme into a monitoring scheme for outputting.

2. The industrial internet-based campus carbon emission monitoring method according to claim 1, wherein the method for dividing the monitoring area according to the obtained campus drawing and the campus information comprises:

identifying a target factory in a garden drawing according to garden information, marking a target factory area, setting a maximum representative radius of a monitoring area, and marking the maximum representative radius of the monitoring area as Rmax; calculating the representative radius of each target factory, and establishing a corresponding range circle in a garden drawing according to the calculated representative radius of the target factory; numbering the range circles according to the target factory representative radius and the target factory position;

selecting a range circle with a first serial number sequence as a merging center for merging to obtain a new center circle, identifying the radius of the new center circle, merging again when the radius of the new center circle is not larger than the maximum representative radius until the radius of the new center circle is larger than the maximum representative radius, performing regression processing to obtain a merging circle, and integrally marking a target factory area included in the merging circle as a monitoring area; and so on until all the monitoring area division is completed.

3. The industrial internet-based campus carbon emission monitoring method of claim 2, wherein the method of calculating the representative radius of each target plant comprises:

the method comprises the steps of obtaining the carbon emission of a target factory and the distance between the target factories, marking the carbon emission outlets of the target factories in a garden drawing, and marking the obtained carbon emission and the distance between the target factories on corresponding positions in the garden drawing; acquiring production information of a target factory, setting a scaling coefficient of the target factory according to the acquired production information, marking carbon emission as TP, marking a distance between the target factories as XBL, and marking the scaling coefficient of the target factory as SF; and calculating the representative radius of each target factory according to a representative radius formula Rd which is lambda multiplied by alpha multiplied by TP multiplied by SF, wherein lambda is a correction factor, the value range is 0< lambda is less than or equal to 1, and alpha is a conversion coefficient.

4. The industrial internet-based campus carbon emission monitoring method according to claim 2, wherein the method of selecting the range circle with the first existing serial number sequence as the merging center for merging comprises:

marking the range circle with the first serial number sequence as a center circle, identifying the center of the range circle contained in the center circle and the range circle intersected with the center circle, merging the range circles according to the contact relation priority, identifying the representative radius and the center point coordinate of the corresponding merged range circle, calculating the merged radius, setting the center of a new center circle after merging according to the center point coordinate of the range circle and the center point coordinate of the center circle, and setting the new center circle to replace the original center circle and range circle according to the center point coordinate and the merged radius of the new center circle.

5. The industrial internet-based campus carbon emission monitoring method of claim 4, wherein the method of calculating the radius of merger comprises:

according to the formula of the combined radius Rd ═ r ₀ +Rd ₁ ) X η calculating the radius of merger, where Rd ₀ Is the center circle radius, Rd1 is the range circle radius, and η is the radius adjustment factor.

6. The industrial internet-based campus carbon emission monitoring method of claim 1, wherein the method of setting the monitoring area tag comprises:

the method comprises the steps of obtaining the type of carbon emission gas of each target factory in a monitoring area, setting corresponding target factory label assignment according to the type of the obtained carbon emission gas, obtaining a merging circle radius corresponding to the monitoring area, integrating the obtained merging circle radius and the target factory label assignment into a monitoring area label, and marking the monitoring area label.

7. The industrial internet-based campus carbon emission monitoring method of claim 1, wherein the method of creating a single project library comprises:

and obtaining the assigned value of the target factory label, setting a corresponding single monitoring scheme according to the assigned value of the target factory label, printing the corresponding assigned value label of the target factory on the single monitoring scheme, and establishing a single scheme library according to the single monitoring scheme.

8. The industrial internet-based campus carbon emission monitoring method of claim 7, wherein the method of establishing the regional monitoring scheme matching library comprises:

non-repeated combination is carried out according to the single monitoring scheme in the single scheme library, the regional monitoring scheme is compiled according to the single monitoring scheme combination, and a corresponding combination assignment label is marked on the regional monitoring scheme; and establishing a region monitoring scheme matching library according to the region monitoring scheme.

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