CN114022034A - Carbon neutralization supply system in operation building - Google Patents

Abstract

The invention discloses a carbon neutralization replenishment system in an operation building, which belongs to the technical field of carbon neutralization replenishment and comprises a carbon neutralization replenishment platform for performing carbon replenishment on each operation building, wherein the carbon neutralization replenishment platform comprises: the carbon neutralization analysis unit is used for performing carbon neutralization analysis on each operation building; the carbon supply transaction unit is used for performing carbon supply transaction for each operation building; the server is in communication connection with the carbon neutralization analysis unit, the carbon replenishment transaction unit and the replenishment analysis unit, the carbon neutralization analysis unit sends information obtained through analysis to the server, the server generates a carbon replenishment transaction signal and sends the carbon replenishment transaction signal to the carbon replenishment transaction unit, and the carbon replenishment transaction unit conducts carbon replenishment transaction on a middle neutralization operation building and a negative neutralization operation building. The invention can relieve the operation building with the carbon emission exceeding the standard by supplying, and can increase the carbon neutralization time, thereby controlling the carbon emission with the lowest cost and improving the carbon neutralization efficiency.

Description

Carbon neutralization supply system in operation building

Technical Field

The invention relates to the technical field of carbon neutralization and supply, in particular to a carbon neutralization and supply system in an operating building.

Background

The term of carbon neutralization, energy conservation and emission reduction refers to that enterprises, groups or individuals measure and calculate the total amount of greenhouse gas emission generated directly or indirectly within a certain time, and the emission of carbon dioxide generated by the enterprises, groups or individuals is counteracted through the forms of tree planting, energy conservation and emission reduction and the like, so that 'zero emission' of the carbon dioxide is realized; carbon replenishment, one of the efforts of modern people to alleviate global warming, refers to the individual or organization providing corresponding funds to the carbon dioxide reduction business to offset their carbon dioxide emissions. With this environmental approach, people calculate the amount of carbon dioxide emissions produced directly or indirectly by their daily activities and calculate the economic cost required to offset these carbon dioxide emissions. Individuals and businesses can reduce their "carbon footprint" through carbon replenishment transactions.

However, in the prior art, the carbon neutralization of each operating building cannot be accurately analyzed, so that the general trend of each operating building cannot be accurately collected, and carbon supply transaction is not facilitated; in addition, the inability to accurately match the operating building for carbon replenishment transactions adds complexity to the carbon emissions traceability.

In view of the above technical drawbacks, a solution is proposed.

Disclosure of Invention

In view of the above-mentioned problems, the present invention provides a system for carbon neutralization and replenishment in a building, comprising:

a carbon neutralization replenishment platform for use in the replenishment of carbon to respective operating structures, the carbon neutralization replenishment platform comprising:

the carbon neutralization analysis unit is used for performing carbon neutralization analysis on each operation building, calculating a carbon neutralization efficiency analysis coefficient of each operation building, comparing the calculated carbon neutralization efficiency analysis coefficient with a preset carbon neutralization analysis coefficient threshold value, marking the operation building which is greater than or equal to the carbon neutralization analysis coefficient threshold value as a positive neutralization operation building, and marking the operation building which is smaller than the carbon neutralization analysis coefficient threshold value as a negative neutralization operation building;

the carbon supply transaction unit is used for performing carbon supply transaction for each operating building;

a server;

wherein, the server communication is connected carbon neutralization analysis unit carbon replenishment transaction unit with replenishment analysis unit, carbon neutralization analysis unit with the information that the analysis obtained send to behind the server, the server generates carbon replenishment transaction signal and sends to carbon replenishment transaction unit, carbon replenishment transaction unit will the centre with the operation building with the carbon replenishment transaction is carried out to the negative neutralization operation building.

Preferably, the carbon neutralization and replenishment platform further comprises a replenishment analysis unit for analyzing carbon replenishment transactions, the replenishment analysis unit is in communication connection with the server, the carbon replenishment transaction unit sends the information of the carbon replenishment transactions to the server, the server further generates a replenishment analysis signal and sends the replenishment analysis signal to the carbon neutralization analysis unit, and the carbon neutralization analysis unit analyzes and judges the current situation of the transactions through the carbon replenishment transactions.

Preferably, the carbon neutralization analysis unit determining the current status of the transaction through carbon replenishment transaction analysis includes:

respectively obtaining the number of the positive neutralization operation buildings and the negative neutralization operation buildings according to the information obtained by the analysis of the carbon neutralization analysis unit;

according to the information obtained by the analysis of the carbon neutralization analysis unit, the actual carbon emission of each operating building is also obtained;

calculating and obtaining a difference value between the total carbon emission amount limit and the actual carbon emission amount of each operating building according to the total carbon emission amount limit and the actual carbon emission amount of each operating building;

calculating to obtain a carbon replenishment analysis coefficient according to the difference value;

comparing the carbon supply analysis coefficient with a preset carbon supply analysis coefficient threshold value;

if the carbon replenishment analysis coefficient is larger than or equal to the carbon replenishment analysis coefficient threshold value, judging that the corresponding carbon replenishment analysis is qualified, and sending a carbon replenishment analysis qualified signal to the server; and if the carbon replenishment analysis coefficient is less than the carbon replenishment analysis coefficient threshold value, judging that the corresponding carbon replenishment analysis is unqualified, and sending a carbon replenishment unqualified signal to the server.

Preferably, calculating the carbon supply analysis coefficient according to the difference comprises:

calculating to obtain a carbon replenishment analysis coefficient FX according to a formula;

in the formula: ZH is the number of said median and operational buildings; FH is the number of negative neutralization operating buildings; ZCZ is the difference value between the total carbon emission limit and the actual carbon emission limit of each operating building; c1, c2 and c3 are all preset proportionality coefficients, c1 is more than c2 is more than c3 is more than 0, alpha is an error correction factor and is 2.31, and e is a natural constant.

Preferably, the carbon neutralization analysis unit performs carbon neutralization analysis on each operating building, including:

marking the operation buildings as i, wherein i is a positive integer, and collecting the carbon emission amount, the carbon emission speed, the carbon absorption amount and the carbon absorption speed of each operation building;

calculating and obtaining a carbon neutralization efficiency analysis coefficient of each operation building according to the collected carbon emission amount, carbon emission speed, carbon absorption amount and carbon absorption speed of each operation building;

comparing the carbon neutralization efficiency analysis coefficient for each of the operational buildings to the carbon neutralization analysis coefficient threshold: if the carbon neutralization efficiency analysis coefficient of the operation building is larger than or equal to the carbon neutralization analysis coefficient threshold value, judging that the carbon neutralization efficiency of the corresponding operation building is normal and marking the operation building as a middle neutralization operation building;

and if the carbon neutralization efficiency analysis coefficient of the operation building is less than the carbon neutralization analysis coefficient threshold value, judging that the carbon neutralization efficiency of the corresponding operation building is abnormal and marking as a negative neutralization operation building.

Preferably, the calculating and obtaining the carbon neutralization efficiency analysis coefficient of each operating building according to the collected carbon emission amount, carbon emission speed, carbon absorption amount and carbon absorption speed of each operating building comprises:

according to a formula, calculating and obtaining a carbon neutralization efficiency analysis coefficient Zhi of each operating building;

in the formula: tpi is the carbon emission of each said operating building; tvi is the carbon emission rate of each of the operating buildings; TXi is the carbon uptake of each of the operating buildings; XVi is the carbon absorption rate of each of the operating buildings; z1, z2, z3 and z4 are all preset proportionality coefficients, z1 is more than z2 and more than z3 is more than z4 and more than 0, and beta is an error correction factor and is 1.25.

Preferably, the carbon supply transaction unit performing the carbon supply transaction for each of the operation buildings includes:

obtaining the residual carbon emission amount credit of the positive and negative neutralization operation buildings and the required carbon emission amount credit of the negative and positive neutralization operation buildings according to the total carbon emission amount credit of each operation building and the actual carbon emission amount of each operation building;

comparing the corresponding required carbon emission amount limit of the negative neutralization operation building with the corresponding residual carbon emission amount limit of the positive neutralization operation building, and if the difference between the corresponding required carbon emission amount limit of the negative neutralization operation building and the corresponding residual carbon emission amount limit of the positive neutralization operation building is less than a corresponding difference threshold value, judging that the negative neutralization operation building is properly matched with the positive neutralization operation building; and if the difference value between the required carbon emission amount limit corresponding to the negative neutralization operation building and the remaining carbon emission amount limit corresponding to the positive neutralization operation building is larger than or equal to the corresponding difference threshold value, judging that the negative neutralization operation building is not properly matched with the positive neutralization operation building.

Preferably, the carbon neutralization replenishment platform further comprises a database for storing data, and the database is in communication connection with the server.

Compared with the prior art, the invention has the beneficial effects that:

according to the invention, carbon neutralization analysis is carried out on each operating building, the carbon neutralization efficiency of the operating building is judged, the carbon emission trend of the operating building is accurately collected, and convenience is provided for carbon supply transaction; carbon supply transaction is carried out on each operating building, the carbon neutralization efficiency of each operating building is accurately judged, the carbon emission can be accurately traced, and meanwhile, the carbon neutralization cost can be reduced to the maximum extent on the premise that the carbon emission does not exceed the standard through carbon supply; analyzing the carbon supply transaction, judging the current transaction situation through the carbon supply transaction analysis, and judging the influence of the transaction on carbon neutralization; the carbon emission amount exceeding operation building can be relieved through replenishment, the carbon neutralization time can be prolonged, the carbon emission amount is controlled at the lowest cost, and the carbon neutralization efficiency is improved.

Drawings

FIG. 1 is a schematic block diagram of a carbon neutralization and replenishment system for use in a building in accordance with the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The invention is described in further detail below with reference to the accompanying drawing 1:

as shown in fig. 1, the present invention provides a carbon neutralization and replenishment system for use in a building, comprising:

the carbon neutralization and supply platform is used for supplying carbon to each operation building, each operation building is provided with a fixed carbon emission limit in the application, the carbon supply means that carbon emission limit transaction is carried out among the operation buildings, the carbon emission of the whole operation building is clearly known, and the carbon emission trend is accurately collected;

the carbon neutralization replenishment platform comprises:

the carbon neutralization analysis unit is used for performing carbon neutralization analysis on each operation building, calculating a carbon neutralization efficiency analysis coefficient of each operation building, comparing the calculated carbon neutralization efficiency analysis coefficient with a preset carbon neutralization analysis coefficient threshold value, marking the operation building which is greater than or equal to the carbon neutralization analysis coefficient threshold value as a positive neutralization operation building, and marking the operation building which is smaller than the carbon neutralization analysis coefficient threshold value as a negative neutralization operation building;

the carbon supply transaction unit is used for performing carbon supply transaction for each operation building;

a server;

the server is in communication connection with the carbon neutralization analysis unit, the carbon replenishment transaction unit and the replenishment analysis unit, the carbon neutralization analysis unit sends information obtained through analysis to the server, the server generates a carbon replenishment transaction signal and sends the carbon replenishment transaction signal to the carbon replenishment transaction unit, and the carbon replenishment transaction unit conducts carbon replenishment transaction on a middle neutralization operation building and a negative neutralization operation building.

Specifically, the server generates carbon neutralization analysis signal and sends carbon neutralization analysis signal to carbon neutralization analysis unit, and carbon neutralization analysis unit is used for carrying out carbon neutralization analysis to each operation building, judges the carbon neutralization efficiency of operation building, and the accurate carbon emission trend of gathering the operation building provides convenience for the carbon supply transaction, and concrete analysis process is as follows:

marking the operation buildings as i, wherein i is a positive integer, and acquiring the carbon emission amount, the carbon emission speed, the carbon absorption amount and the carbon absorption speed of each operation building;

calculating and obtaining a carbon neutralization efficiency analysis coefficient Zhi of each operating building according to a formula;

in the formula: tpi is the carbon emission of each operating building; tvi is the carbon emission rate of each operating building; TXi is the carbon uptake of each operating building; XVi is the carbon absorption rate of each operating building; z1, z2, z3 and z4 are all preset proportionality coefficients, z1 is more than z2 and more than z3 is more than z4 and more than 0, and beta is an error correction factor and is 1.25;

the carbon neutralization efficiency analysis coefficient is a numerical value for evaluating the carbon neutralization efficiency of the operation building by normalizing the parameters of each operation building; the carbon absorption amount is larger than the carbon emission amount, the carbon absorption speed is larger than the carbon emission speed, the smaller the analysis coefficient of the carbon neutralization efficiency of the operation building is, and the better the carbon neutralization efficiency of the operation building is.

The carbon neutralization efficiency analysis coefficient ZHi for each operating building is compared to a carbon neutralization analysis coefficient threshold: if the carbon neutralization efficiency analysis coefficient ZHi of the operation building is larger than or equal to the carbon neutralization analysis coefficient threshold, judging that the carbon neutralization efficiency of the corresponding operation building is normal and marking the operation building as a middle neutralization operation building;

and if the carbon neutralization efficiency analysis coefficient ZHi of the operation building is less than the carbon neutralization analysis coefficient threshold value, judging that the carbon neutralization efficiency of the corresponding operation building is abnormal and marking the operation building as the negative neutralization operation building.

The in-carbon neutralization analysis unit transmits the center neutralization operation building and the neutralization operation building obtained by the analysis to the server.

Further, after receiving the positive neutralization operation building and the negative neutralization operation building, the server generates a carbon supply transaction signal and sends the carbon supply transaction signal to a carbon supply transaction unit; the carbon supply transaction unit is used for carrying out carbon supply transaction for each operation building, accurately judges the carbon neutralization efficiency of each operation building, can accurately trace to the source to carbon emission, simultaneously, can reduce the carbon neutralization cost to the utmost extent on the premise that the carbon emission does not exceed the standard through the carbon supply, and the specific carbon supply transaction process is as follows:

obtaining the residual carbon emission amount limit of the middle and operation buildings and the required carbon emission amount limit of the negative and operation buildings according to the total carbon emission amount limit of each operation building and the actual carbon emission amount of each operation building;

comparing the corresponding required carbon emission amount limit of the negative neutralization operation building with the corresponding residual carbon emission amount limit of the positive neutralization operation building, and if the difference value between the corresponding required carbon emission amount limit of the negative neutralization operation building and the corresponding residual carbon emission amount limit of the positive neutralization operation building is less than the corresponding difference value threshold value, judging that the negative neutralization operation building is properly matched with the positive neutralization operation building; and if the difference value between the required carbon emission amount limit corresponding to the negative neutralization operation building and the remaining carbon emission amount limit corresponding to the positive neutralization operation building is larger than or equal to the corresponding difference threshold value, judging that the negative neutralization operation building is not properly matched with the positive neutralization operation building.

In this embodiment, the carbon neutralization and replenishment platform further includes a replenishment analysis unit for analyzing the carbon replenishment transaction, the replenishment analysis unit is in communication connection with the server, and after the carbon replenishment transaction unit sends the information of the carbon replenishment transaction to the server, the server further generates a replenishment analysis signal and sends the replenishment analysis signal to the carbon neutralization analysis unit, the carbon neutralization analysis unit analyzes and judges the current situation of the transaction through the carbon replenishment transaction, and the specific analysis process is as follows:

respectively obtaining the number of the positive and negative neutralization operation buildings according to the information obtained by the analysis of the carbon neutralization analysis unit;

according to the information obtained by the analysis of the carbon neutralization analysis unit, the actual carbon emission of each operating building is also obtained;

calculating to obtain a difference value between the total carbon emission limit and the actual carbon emission of each operating building according to the total carbon emission limit and the actual carbon emission of each operating building;

calculating to obtain a carbon replenishment analysis coefficient FX according to a formula;

in the formula: ZH is the number of median and operational buildings; FH is the number of negative neutralization operating buildings; ZCZ is the difference value between the total carbon emission limit of each operating building and the actual carbon emission limit; c1, c2 and c3 are all preset proportionality coefficients, c1 is more than c2 is more than c3 is more than 0, alpha is an error correction factor, the value is 2.31, and e is a natural constant;

comparing the carbon replenishment analysis coefficient FX with a preset carbon replenishment analysis coefficient threshold value;

if the carbon replenishment analysis coefficient FX is larger than or equal to the carbon replenishment analysis coefficient threshold value, judging that the corresponding carbon replenishment analysis is qualified, and sending a carbon replenishment analysis qualified signal to the server; and if the carbon replenishment analysis coefficient FX is smaller than the carbon replenishment analysis coefficient threshold, judging that the corresponding carbon replenishment analysis is unqualified, and sending a carbon replenishment unqualified signal to the server. In the application, the qualified carbon supply analysis means that the carbon supply can meet the carbon neutralization, and conversely, the unqualified carbon supply analysis means that the carbon supply can not meet the carbon neutralization.

In this embodiment, the carbon neutralization replenishment platform further comprises a database for storing data, and the database is in communication connection with the server.

The working principle of the invention is as follows: when the system works, each operation building is replenished with carbon through a carbon neutralization replenishing platform, a server generates a carbon neutralization analysis signal and sends the carbon neutralization analysis signal to a carbon neutralization analysis unit, and the carbon neutralization analysis unit performs carbon neutralization analysis on each operation building to judge the carbon neutralization efficiency of the operation building; dividing the operation building into a positive neutralization operation building and a negative neutralization operation building, and sending the positive neutralization operation building and the negative neutralization operation building to a server; after receiving the positive and negative neutralization operation buildings, the server generates a carbon supply transaction signal and sends the carbon supply transaction signal to a carbon supply transaction unit; carbon supply transaction is carried out for each operation building through a carbon supply transaction unit; the server generates a replenishment analysis signal and sends the replenishment analysis signal to the replenishment analysis unit, and the replenishment analysis unit analyzes the carbon replenishment transaction.

The above formulas are all calculated by taking the numerical value of the dimension, the formula is a formula which obtains the latest real situation by acquiring a large amount of data and performing software simulation, and the preset parameters in the formula are set by the technical personnel in the field according to the actual situation.

The above is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and various modifications and changes will occur to those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. A carbon neutralization recharge system for use in a building, the system comprising a carbon neutralization recharge platform for recharging each building, the carbon neutralization recharge platform comprising:

the carbon neutralization analysis unit is used for performing carbon neutralization analysis on each operation building, calculating a carbon neutralization efficiency analysis coefficient of each operation building, comparing the calculated carbon neutralization efficiency analysis coefficient with a preset carbon neutralization analysis coefficient threshold value, marking the operation building which is greater than or equal to the carbon neutralization analysis coefficient threshold value as a positive neutralization operation building, and marking the operation building which is smaller than the carbon neutralization analysis coefficient threshold value as a negative neutralization operation building;

the carbon supply transaction unit is used for performing carbon supply transaction for each operating building;

a server;

wherein, the server communication is connected carbon neutralization analysis unit carbon replenishment transaction unit with replenishment analysis unit, carbon neutralization analysis unit with the information that the analysis obtained send to behind the server, the server generates carbon replenishment transaction signal and sends to carbon replenishment transaction unit, carbon replenishment transaction unit will the centre with the operation building with the carbon replenishment transaction is carried out to the negative neutralization operation building.

2. The system of claim 1, wherein the carbon neutralization and replenishment platform further comprises a replenishment analysis unit for analyzing the carbon replenishment transaction, the replenishment analysis unit is in communication connection with the server, and after the carbon replenishment transaction unit sends the information of the carbon replenishment transaction to the server, the server further generates a replenishment analysis signal and sends the replenishment analysis signal to the carbon neutralization analysis unit, and the carbon neutralization analysis unit analyzes and judges the current transaction status through the carbon replenishment transaction.

3. The system of claim 2, wherein the carbon neutralization analysis unit determines the status of the transaction by analyzing the carbon replenishment transaction comprises:

respectively obtaining the number of the positive neutralization operation buildings and the negative neutralization operation buildings according to the information obtained by the analysis of the carbon neutralization analysis unit;

according to the information obtained by the analysis of the carbon neutralization analysis unit, the actual carbon emission of each operating building is also obtained;

calculating and obtaining a difference value between the total carbon emission amount limit and the actual carbon emission amount of each operating building according to the total carbon emission amount limit and the actual carbon emission amount of each operating building;

calculating to obtain a carbon replenishment analysis coefficient according to the difference value;

comparing the carbon supply analysis coefficient with a preset carbon supply analysis coefficient threshold value;

if the carbon replenishment analysis coefficient is larger than or equal to the carbon replenishment analysis coefficient threshold value, judging that the corresponding carbon replenishment analysis is qualified, and sending a carbon replenishment analysis qualified signal to the server; and if the carbon replenishment analysis coefficient is less than the carbon replenishment analysis coefficient threshold value, judging that the corresponding carbon replenishment analysis is unqualified, and sending a carbon replenishment unqualified signal to the server.

4. The system of claim 3, wherein calculating the carbon supply analysis coefficients based on the difference comprises:

calculating to obtain a carbon replenishment analysis coefficient FX according to a formula;

in the formula: ZH is the number of said median and operational buildings; FH is the number of negative neutralization operating buildings; ZCZ is the difference value between the total carbon emission limit and the actual carbon emission limit of each operating building; c1, c2 and c3 are all preset proportionality coefficients, c1 is more than c2 is more than c3 is more than 0, alpha is an error correction factor and is 2.31, and e is a natural constant.

5. The system of claim 4, wherein the carbon neutralization analysis unit performs carbon neutralization analysis on each operating building, and comprises:

marking the operation buildings as i, wherein i is a positive integer, and collecting the carbon emission amount, the carbon emission speed, the carbon absorption amount and the carbon absorption speed of each operation building;

calculating and obtaining a carbon neutralization efficiency analysis coefficient of each operation building according to the collected carbon emission amount, carbon emission speed, carbon absorption amount and carbon absorption speed of each operation building;

comparing the carbon neutralization efficiency analysis coefficient for each of the operational buildings to the carbon neutralization analysis coefficient threshold: if the carbon neutralization efficiency analysis coefficient of the operation building is larger than or equal to the carbon neutralization analysis coefficient threshold value, judging that the carbon neutralization efficiency of the corresponding operation building is normal and marking the operation building as a middle neutralization operation building;

and if the carbon neutralization efficiency analysis coefficient of the operation building is less than the carbon neutralization analysis coefficient threshold value, judging that the carbon neutralization efficiency of the corresponding operation building is abnormal and marking as a negative neutralization operation building.

6. The system of claim 5, wherein the step of calculating and obtaining the carbon neutralization efficiency analysis coefficient of each operation building according to the collected carbon emission amount, carbon emission speed, carbon absorption amount and carbon absorption speed of each operation building comprises:

according to a formula, calculating and obtaining a carbon neutralization efficiency analysis coefficient Zhi of each operating building;

in the formula: tpi is the carbon emission of each said operating building; tvi is the carbon emission rate of each of the operating buildings; TXi is the carbon uptake of each of the operating buildings; XVi is the carbon absorption rate of each of the operating buildings; z1, z2, z3 and z4 are all preset proportionality coefficients, z1 is more than z2 and more than z3 is more than z4 and more than 0, and beta is an error correction factor and is 1.25.

7. The system of claim 6, wherein the carbon supply transaction unit performs carbon supply transaction for each of the operation buildings, and comprises:

obtaining the residual carbon emission amount credit of the positive and negative neutralization operation buildings and the required carbon emission amount credit of the negative and positive neutralization operation buildings according to the total carbon emission amount credit of each operation building and the actual carbon emission amount of each operation building;

comparing the corresponding required carbon emission amount limit of the negative neutralization operation building with the corresponding residual carbon emission amount limit of the positive neutralization operation building, and if the difference between the corresponding required carbon emission amount limit of the negative neutralization operation building and the corresponding residual carbon emission amount limit of the positive neutralization operation building is less than a corresponding difference threshold value, judging that the negative neutralization operation building is properly matched with the positive neutralization operation building; and if the difference value between the required carbon emission amount limit corresponding to the negative neutralization operation building and the remaining carbon emission amount limit corresponding to the positive neutralization operation building is larger than or equal to the corresponding difference threshold value, judging that the negative neutralization operation building is not properly matched with the positive neutralization operation building.

8. The system of claim 1, wherein the carbon neutralization and replenishment platform further comprises a database for storing data, the database being communicatively coupled to the server.

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