KR102662083B1 - Carbon Emission Information Inquiry Program Building Method of the Target System and a Storage Medium for Recording the Program Constructed by the Same - Google Patents

Abstract

The method for calculating carbon emissions of a target system and constructing an information inquiry program according to the present invention includes step (a) in which the information management unit of the operation server sets classification boundaries of the target system subject to carbon emissions calculation and classifies lower organizations, the information Step (b), where the management unit specifies the carbon emission source for each sub-organization classified in step (a) above, and the data processing unit of the operation server determines the amount of carbon emissions for each carbon emission source specified in step (b) above. Through step (c) of calculating and the carbon emissions by carbon emission source calculated by the program construction unit of the operation server in step (c), information related to carbon emissions for the target system can be searched online and on the computer. It includes step (d) of building a carbon emissions calculation and information inquiry program implemented with an executable graphical user interface.

Description

Carbon Emission Information Inquiry Program Building Method of the Target System and a Storage Medium for Recording the Program Constructed by the Same}

The present invention relates to a method of constructing a program for calculating carbon emissions and information inquiry of a target system and to a storage medium recording the program constructed thereby. More specifically, it relates to classifying sub-organizations of a target system and specifying carbon emission sources to determine carbon emissions. This relates to a method of building a carbon emissions calculation and information inquiry program for a target system that can provide high-quality carbon emissions-related information through calculation, and a storage medium that records the program constructed thereby.

Recently, as environmental pollution has accelerated due to industrial development, awareness of environmental pollution is gradually increasing in various fields, and various methods to reduce environmental pollution are being researched and discussed.

In addition, the concept of carbon neutrality has recently been spreading around the world.

Carbon neutrality is the concept of reducing carbon dioxide emissions generated by companies or individuals as much as possible, increasing absorption to minimize net emissions, and then offsetting the remainder, thereby reducing actual carbon dioxide emissions to ‘zero’. In other words, this means bringing the total amount of carbon dioxide to a neutral state by establishing measures to reabsorb carbon dioxide to the extent of offsetting the amount of carbon dioxide emitted into the atmosphere.

In order to achieve carbon neutrality, it is most important to accurately calculate the carbon emissions of companies and individuals and manage the emissions of affiliated organizations (supply chains). However, conventionally, only carbon dioxide directly emitted by companies is calculated, so it cannot be said that accurate carbon emissions are measured.

Therefore, a method to solve these problems is required.

Korean Patent No. 10-1081486

The present invention is an invention made to solve the problems of the prior art described above. It classifies the sub-organization of a specific target system in detail, specifies the carbon emission source in detail, and allows the calculation of carbon emissions, thereby providing accurate information on carbon emissions. The purpose is to provide information.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

The method of constructing a carbon emission calculation and information inquiry program of the target system of the present invention to achieve the above purpose is to set the classification boundary of the target system subject to carbon emissions calculation by the information management department of the operation server to classify sub-organizations ( Step a), step (b), where the information management unit specifies the carbon emission source for each sub-organization classified in step (a), and the data processing unit of the operation server specifies each carbon emission source specified in step (b). Step (c) of calculating carbon emissions by carbon emission source, and the program construction unit of the operation server searches carbon emission-related information for the target system online through the carbon emissions by carbon emission source calculated in step (c). It can be done and includes step (d) of building a carbon emissions calculation and information inquiry program implemented with a graphical user interface executable by a computer.

At this time, in step (a), the information management department classifies sub-organizations by setting classification boundaries into unit groups divided by preset purposes for the geography-based unit facility that builds the target system or the target system (a) It may include step -1) and step (a-2) in which the information management department adds transportation and auxiliary facilities owned by the target system as a sub-organization.

And step (b) is step (b-1) in which the information management department defines a plurality of carbon emission types for each sub-organization classified in step (a), and step (b-1) in which the information management department defines a plurality of carbon emission types for each sub-organization classified in step (a). It may include step (b-2) of specifying detailed carbon emission sources for each carbon emission type defined by .

Here, the carbon emission types defined in step (b-1) may include direct emission types, indirect emission types, and other emission types.

In addition, in step (b-2), the information management department specifies each item of fixed combustion source, mobile combustion source, fugitive emission source, waste treatment facility, forest sink, fertilizer use, and owned animals as detailed carbon emission sources as the direct emission type. Step (b-2-1), step (b-2-2) in which the information management department specifies each item of electricity use, heat use, water use, and waste as the indirect emission types as detailed carbon emission sources, and the information management department As the above other emission types, it may include step (b-2-3) of specifying each item of commuting/school transportation and business trip as a detailed carbon emission source.

In addition, step (c) is a step (c-1) in which the data processing unit calculates a base emission figure for each carbon emission source specified in step (b), and the data processing unit calculates an emission coefficient through the base emission figure. Step (c-2) of calculating, step (c-3) where the data processing unit calculates carbon emissions by multiplying the base emission figure and the emission coefficient, and carbon emissions calculated by step (c-3) It may include step (c-4) of converting into carbon dioxide equivalent (CO ₂ eq).

And the step (d) is a step (d-1) in which the program building unit collects the carbon emissions by carbon emission source calculated in step (c) as base data, and the program building unit processes the base data. It may include a step (d-2) of generating data and a step (d-3) of the program construction unit constructing the carbon emissions calculation and information inquiry program using the base data and the processed data.

At this time, the processed data in step (d-2) may include at least one of the total carbon emissions information of the target system, the total carbon emissions information for each sub-organization, and the carbon emissions information for each carbon emission type of the sub-organization. You can.

Additionally, the total carbon emissions of the target system can be calculated by calculating the share of sub-organizations of the target system and multiplying the calculated share.

In addition, the present invention can be provided in the form of a computer-readable storage medium that records the carbon emission calculation and information inquiry program of the target system implemented by the method of constructing the carbon emission calculation and information inquiry program of the target system as described above.

The method of constructing a carbon emission calculation and information inquiry program of a target system of the present invention to solve the above-mentioned problems and the storage medium recording the program constructed thereby are used to set the classification boundary of the target system subject to carbon emissions calculation to create sub-organizations. It has the advantage of providing more accurate and reasonable carbon emissions-related information compared to the existing method by classifying and specifying in detail the carbon emission sources from which carbon is emitted for each classified sub-organization and calculating each carbon emission amount. .

In addition, the present invention can contribute to environmental protection by continuously monitoring the contribution to environmental pollution and responding to domestic and international laws and obligations by providing information related to carbon emissions and raising awareness at the same time.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a diagram showing each process of a method for calculating carbon emissions of a target system and building an information inquiry program according to an embodiment of the present invention;
Figure 2 is a diagram conceptually showing a system for implementing a method for calculating carbon emissions of a target system and building an information inquiry program according to an embodiment of the present invention;
Figure 3 is a diagram showing the detailed process of step (a) in the method of calculating carbon emissions of a target system and building an information inquiry program according to an embodiment of the present invention;
Figure 4 is a diagram showing the detailed process of step (b) in the method for calculating carbon emissions of a target system and building an information inquiry program according to an embodiment of the present invention;
Figure 5 is a diagram showing the detailed process of step (c) in the method of calculating carbon emissions of a target system and building an information inquiry program according to an embodiment of the present invention;
Figure 6 is a diagram showing the detailed process of step (d) in the method of calculating carbon emissions of a target system and building an information inquiry program according to an embodiment of the present invention;
Figure 7 is a diagram illustrating the initial screen of the carbon emission calculation and information inquiry program of the target system built according to the present invention;
Figure 8 is a diagram illustrating a screen provided in the detailed carbon emission details tab of the carbon emission calculation and information inquiry program of the target system built according to the present invention;
Figure 9 is a diagram showing an exemplary display screen for the carbon measurement tab menu of the carbon emission calculation and information inquiry program of the target system built according to the present invention;
Figure 10 is a diagram showing an exemplary display screen for the Insight tab menu of the carbon emission calculation and information inquiry program of the target system built according to the present invention;
Figure 11 is a diagram showing an exemplary display screen for the survey request tab menu of the carbon emission calculation and information inquiry program of the target system built according to the present invention; and
Figure 12 is a diagram showing an exemplary display screen for the settings tab menu of the carbon emission calculation and information inquiry program of the target system built according to the present invention.

In this specification, when a component (or region, layer, portion, etc.) is referred to as being “on,” “connected to,” or “coupled to” another component, it is directly placed/on the other component. This means that they can be connected/combined or a third component can be placed between them.

Like reference numerals refer to like elements. Additionally, in the drawings, the thickness, proportions, and dimensions of components are exaggerated for effective explanation of technical content.

“And/or” includes all combinations of one or more that the associated configurations may define.

Terms such as first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, a first component may be named a second component without departing from the scope of the present invention, and similarly, the second component may also be named a first component. Singular expressions include plural expressions unless the context clearly dictates otherwise.

Additionally, terms such as “below,” “on the lower side,” “above,” and “on the upper side” are used to describe the relationship between the components shown in the drawings. The above terms are relative concepts and are explained based on the direction indicated in the drawings.

Unless otherwise defined, all terms (including technical terms and scientific terms) used in this specification have the same meaning as commonly understood by a person skilled in the art to which the present invention pertains. Additionally, terms such as those defined in commonly used dictionaries should be interpreted as having meanings consistent with their meanings in the context of the relevant technology, and unless interpreted in an idealized or overly formal sense, are explicitly defined herein. do.

Terms such as “include” or “have” are intended to designate the presence of features, numbers, steps, operations, components, parts, or combinations thereof described in the specification, but do not include one or more other features, numbers, or steps. , it should be understood that it does not exclude in advance the possibility of the existence or addition of operations, components, parts, or combinations thereof.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

The method of calculating carbon emissions of a target system and building an information inquiry program according to the present invention is performed through an operation server and can be driven by a processor of the operation server.

In addition, the program built by the carbon emissions calculation and information inquiry program of the target system can be output through an image output device such as a display module, and can provide visible information through a graphical user interface visualized on the operation server, certain terminals, etc. You can.

In particular, the storage medium storing the program built by the target system's carbon emissions calculation and information inquiry program can be installed on an operation server or certain terminal using a removable disk or communication network, and the target system's carbon emissions calculation and information inquiry program The construction method allows an operation server and a certain terminal to be operated by various functional means.

In other words, in the present invention, information processing by software is concretely realized through hardware.

Hereinafter, with reference to the attached drawings, a method for calculating carbon emissions of a target system and building an information inquiry program according to an embodiment of the present invention will be described.

Figure 1 is a diagram showing the entire process of calculating carbon emissions of a target system and building an information inquiry program according to an embodiment of the present invention.

And FIG. 2 is a diagram conceptually showing a system for calculating carbon emissions of a target system and building an information inquiry program according to an embodiment of the present invention. In the following description, the symbols assigned to each component refer to the drawing. It is based on .

As shown in Figure 1, the method for calculating carbon emissions of a target system and building an information inquiry program according to an embodiment of the present invention includes steps (a) to (d).

Step (a) is a process in which the information management unit 110 of the operation server 100 sets the classification boundary of the target system subject to carbon emissions calculation and classifies subordinate organizations.

Here, the target system refers to a certain institution/organization such as a company, university, etc., and the purpose of the present invention is to build a program that can query the carbon emission information of such a target system.

And the classification boundary refers to a virtual standard that allows us to distinguish the various sub-organizations that make up the target system.

In other words, in step (a), classification boundaries are set according to the characteristics of the target system subject to carbon emissions calculation, and sub-organizations are classified.

Figure 3 is a diagram showing the detailed process of step (a) in the method of calculating carbon emissions of a target system and building an information inquiry program according to an embodiment of the present invention.

As shown in FIG. 3, step (a) includes steps (a-1) and (a-2) in detail.

Step (a-1) is a process in which the information management department 110 classifies sub-organizations by setting classification boundaries into unit groups divided by preset purposes for the geography-based unit facility or target system for constructing the target system. .

For example, if the target system is a company, the sub-organization may be a geographically based unit facility such as headquarters/production facility/storage facility, or may be a unit group such as each department divided by task.

Alternatively, if the target system is a university, the lower-level organization may be a geographically-based unit facility such as a building within each university site, or a unit group such as a department/division.

And step (a-2) is a process in which the information management department 110 adds the means of transportation and auxiliary facilities owned by the target system as subordinate organizations.

In other words, the sub-organization of the target system may further include geographically-based unit facilities or unit groups, transportation such as vehicles, and other auxiliary facilities excluding the unit facilities or unit groups.

Next, step (b) is a process in which the information management department 110 specifies the carbon emission source for each sub-organization classified in step (a).

In this process, each sub-organization identifies carbon emission sources to calculate the subsequent carbon emissions.

Figure 4 is a diagram showing the detailed process of step (b) in the method of calculating carbon emissions of a target system and building an information inquiry program according to an embodiment of the present invention.

Step (b) includes steps (b-1) and (b-2) in detail, and step (b-2) includes steps (b-2-1) and (b-2-2). May include steps.

Step (b-1) is a process in which the information management department 110 defines a plurality of carbon emission types for each sub-organization classified in step (a).

At this time, carbon emission types defined in step (b-1) may include direct emission types, indirect emission types, and other emission types.

Direct emission types refer to sources that directly emit/absorb greenhouse gases, indirect emission types refer to sources that indirectly generate greenhouse gases, and other emission types refer to emission sources other than direct and indirect emission types. .

And in step (b-2), the information management unit 110 specifies detailed carbon emission sources for each carbon emission type defined in step (b-1), that is, direct emission type, indirect emission type, and other emission type. It is a process.

In detail, in step (b-2-1), the information management department 110 details each item of fixed combustion source, mobile combustion source, fugitive emission source, waste treatment facility, forest sink, fertilizer use, and owned animals as direct emission types. It is a process of specifying.

Stationary combustion sources are carbon emissions sources that generate carbon emissions through the combustion process of fuel or waste, such as steam (heat) and power production, heating, and waste incineration.

Additionally, a mobile combustion source is a carbon emission source that generates carbon emissions through transportation means owned and managed by the target system, and a fugitive emission source is a carbon emission source that generates carbon emissions from products such as fire extinguishers, insulators, and refrigerants.

Additionally, waste treatment facilities are a source of carbon emissions that generate carbon emissions from treatment facilities that process waste generated from the target system.

At this time, in the forest sink, greenhouse gases are absorbed due to an increase in carbon accumulation in the forest's biomass, and therefore, unlike other carbon emission sources, the figure may be displayed as a negative in the carbon emission calculation process, which will be described later.

And step (b-2-2) is a process in which the information management unit 110 specifies each item of electricity use, heat use, water use, and waste as indirect emission types as detailed carbon emission sources.

In this way, indirect emission types can be various carbon emission sources that indirectly generate greenhouse gases.

In addition, step (b-2-3) is a process in which the information management unit 110 specifies each item of commuting/school means and business trips as detailed carbon emission sources as other emission types.

Other emission types specified by this process are the remaining emission sources excluding direct emission types and indirect emission types.

Next, step (c) is a process in which the data processing unit 120 of the operation server 100 calculates the amount of carbon emissions for each carbon emission source specified in step (b).

In step (c), the process of calculating carbon emissions individually is performed for each carbon emission source of direct emission type, indirect emission type, and other emission type specified in step (b).

Figure 5 is a diagram showing the detailed process of step (c) in the method of calculating carbon emissions of a target system and building an information inquiry program according to an embodiment of the present invention.

As shown in Figure 5, step (c) may include steps (c-1) to (c-4) in detail, and in particular, step (c-1) is different for each carbon emission source. It is applied in this way, and steps (c-2) to (c-4) can be commonly applied to each carbon emission source.

Step (c-1) is a process in which the data processing department calculates the basic emission figure for each carbon emission source specified in step (b).

Specifically, if the carbon emission source is a direct emission type and is a stationary combustion source/mobile combustion source, the base emission figure can be calculated by calculating fuel consumption and calorific value for each fuel and multiplying them.

In addition, when the carbon emission source is a direct emission type and a waste treatment facility, when solid waste is buried, when solid waste is biologically treated, when sewage/wastewater is treated, when waste is incinerated, basic emission figures are calculated. Different methods can be applied.

In the case of landfilling solid waste, the basic emission figure is calculated by collecting activity data at the waste treatment facility, that is, the landfill amount for each year, and calculating the DDOCmτ and DDOCmaτ values for the first year of landfilling and the DDOCmτ and DDOCmaτ values up to the year of calculation. It can be calculated using multiplication.

In addition, when solid waste is treated biologically, the basic emission figure can be calculated by determining the biological treatment volume at the waste treatment facility, and when sewage/wastewater is treated, the basic emission figure is determined by determining BOD ₅ , TN, and inflow sewage volume. It can be calculated in this way.

In addition, when incinerating waste, the basic emission figure can be calculated by determining the amount of waste incineration.

And if the carbon emission source is a direct emission type and a fugitive emission source, the base emission figure can be calculated by determining the number of registered fire extinguishers, refrigerators, and air conditioners, and determining the type/refrigerant charge of each refrigerant.

Additionally, if the carbon emission source is a direct emission type and a forest sink, the base emission figure can be calculated by determining the forest area. However, as mentioned above, forest sinks absorb greenhouse gases due to an increase in carbon accumulation in forest biomass, and unlike other carbon emission sources, in the carbon emission calculation process, the figure may be displayed as a negative figure.

In addition, if the carbon emission source is a direct emission type and fertilizer use, the base emission figure can be obtained by identifying the location of fertilizer use and the amount of fertilizer used. If the carbon emission source is a direct emission type and it is an owned animal, the basic emission figure can be calculated by determining the location of fertilizer use and the amount of fertilizer used. It can be calculated by identifying the animal's breeding location, breeding method, and animal type.

And if the carbon emission source is an indirect emission type and uses steam (heat), the base emission figure can be obtained by determining the amount of heat usage from the district heating corporation, etc., and if the carbon emission source is an indirect emission type and electricity use, the basic emission figure can be calculated. can be calculated by determining power usage from Korea Electric Power Corporation, etc.

In addition, if the carbon emission source is an indirect emission type and water use, the base emission figure can be obtained by determining the amount of water usage from waterworks, etc., and if the carbon emission source is an indirect emission type and waste, the basic emission figure can be calculated as landfill/incineration/ It can be calculated by determining the type of waste treatment, type of waste, and amount of waste such as wastewater.

In addition, if the carbon emission source is other emission types and is a means of commuting/school or business trip, the base emission figure can be calculated through the results of a survey of personnel within the relevant subordinate organization.

Afterwards, in step (c-2), the data processing unit 120 calculates the emission coefficient through the base emission figure, and in step (c-3), the data processing unit 120 multiplies the base emission figure and the emission coefficient. The process of calculating carbon emissions is carried out.

Once the carbon emissions are calculated in this way, in step (c-4), a process is performed to convert the carbon emissions calculated in step (c-3) into carbon dioxide equivalent (CO2eq).

The process of calculating carbon emissions for each carbon emission source can be performed in the same manner as above.

Next, in step (d), the program construction unit 130 of the operation server 100 searches carbon emissions-related information for the target system online through the carbon emissions by carbon emission source calculated in step (c). The process of building a carbon emissions calculation and information inquiry program implemented with a computer-executable graphical user interface is carried out.

Figure 6 is a diagram showing the detailed process of step (d) in the method of calculating carbon emissions of a target system and building an information inquiry program according to an embodiment of the present invention.

As shown in FIG. 6, step (d) may include steps (d-1) to (d-3) in detail.

Step (d-1) is a process in which the program construction unit 130 collects the carbon emissions by carbon emission source calculated in step (c) as base data.

That is, the program construction unit 130 collects the carbon emissions for each carbon emission source calculated in step (c) as base data, which is basic data for building a carbon emissions calculation and information inquiry program.

And step (d-2) is a process in which the program construction unit 130 processes base data to generate processed data, and creates new data by processing carbon emissions by carbon emission source in various ways.

For example, the processed data in step (d-2) may include at least one of the total carbon emissions information of the target system, the total carbon emissions information by subordinate organization, and the carbon emission information by carbon emission type of subordinate organizations.

At this time, the total carbon emissions of the target system can be calculated by calculating the share of the sub-organization of the target system and multiplying the calculated share. In other words, if the target system does not have a 100% stake in the subordinate organization, the total carbon emissions can be calculated at the same rate according to the stake.

In addition, the processed data in step (d-2) adds carbon emission excess ratio information that derives carbon emission sources with carbon emissions exceeding the preset standard emission figure for each sub-organization of the target system and calculates the exceedance ratio. It can be included.

Through this carbon emission excess ratio information, it is possible to easily determine which carbon emission source is currently emitting excessive carbon within the relevant subordinate organization.

In addition, the program construction unit 130 derives a carbon emission source having a carbon emission amount exceeding a preset standard emission figure from any lower organization, and then determines the carbon emission source of the same carbon emission source of another lower organization in the same target system for the corresponding carbon emission source. Emissions can be aggregated and processed together into emission-relative information that allows comparisons to be made.

The carbon emission excess ratio information and emission comparison information processed in this way can also be used in the process of establishing the carbon emission calculation and information inquiry program in step (d-3) below, and is separately owned by the manager of carbon emission-related activities for each subordinate organization. It can be transmitted to one administrator terminal.

Accordingly, managers can receive and prepare for carbon emissions excess ratio information and emissions comparison information for subordinate organizations they manage, as well as carbon emissions excess ratio information and emissions comparison information for other subordinate organizations, and take action on the relevant items. can be taken.

In this process, the manager may request information about activities that can improve carbon emissions in relation to carbon emission sources with excessive carbon emissions from the information management unit 110 of the operation server 100, and the information management unit 110 Can transmit a request for cooperation in providing related information to another manager terminal that manages another sub-organization that maintains the best carbon emissions for the corresponding carbon emission source.

Accordingly, in order to improve carbon emissions, managers who manage other lower-level organizations collect related data on activities taking place in their lower-level organizations and use the information management unit 110 of the operation server 100 through the manager terminal they own. The information management unit 110 can transmit this to the manager terminal of the manager who requested information on activities that can improve carbon emissions.

Thereafter, the information management unit 110 can monitor the carbon emissions of the carbon emission source of the lower organization according to a preset cycle, calculate the carbon emission change for each cycle, and transmit it to the administrator terminal owned by the manager of the lower organization. Feedback can be provided accordingly.

In addition, the program construction unit 130 of the operation server 100 processes the above history information into data, and discloses the history information so that all program users can refer to it in the process of building a carbon emissions calculation and information inquiry program. You can.

In addition, in step (d-3), the program construction unit 130 uses the base data collected in step (d-1) and the processed data generated in step (d-2) to calculate carbon emissions and conduct an information inquiry program. will be built.

Below, we will look at each drawing illustrating the graphic user interface of the carbon emissions calculation and information inquiry program built in the above manner.

Figure 7 is a diagram illustrating the initial screen of the carbon emission calculation and information inquiry program of the target system built according to the present invention.

As shown in Figure 7, on the initial screen of the target system's carbon emissions calculation and information inquiry program, menu tabs such as organizational design/carbon measurement/insight/survey request/setting, etc. may be displayed on the left, and the corresponding tabs may be displayed in the remaining area. Details about the menu may be displayed.

At this time, in the initial screen shown in Figure 7, the university is applied as the target system, and the undergraduate unit such as Gyeongsang National University/College of Engineering/College of Business Administration is applied as the sub-organization.

And when the organizational design tab is selected on the initial screen, the organization chart of each sub-organization is displayed in the center, and carbon emissions information by sub-organization is displayed on the right screen. This can be converted into carbon emissions information for that sub-organization when the user selects a random sub-organization.

Here, a button such as 'View report' can be added to the right screen, and if the user selects it, it moves to the 'Insight' page and detailed carbon emissions information can be displayed.

Figure 8 is a diagram illustrating a screen provided in the carbon emission details tab of the carbon emission calculation and information inquiry program of the target system built according to the present invention.

As shown in Figure 8, when the user selects the carbon emissions details tab, detailed carbon emissions for the corresponding sub-organization, that is, information on carbon emissions by carbon emission type/detailed carbon emission source, may be displayed.

Figure 9 is a diagram showing an exemplary display screen for the carbon measurement tab menu of the carbon emission calculation and information inquiry program of the target system built according to the present invention.

As shown in Figure 9, when the user selects the carbon measurement tab menu, a tree may be provided to perform settings for carbon emission measurement for each sub-organization.

Figure 10 is a diagram showing an exemplary display screen for the Insight tab menu of the carbon emission calculation and information inquiry program of the target system built according to the present invention.

As shown in Figure 10, when the user selects the Insight tab menu, various analyzed statistics can be provided based on the carbon emissions of the target system.

Figure 11 is a diagram showing an exemplary display screen for the survey request tab menu of the carbon emission calculation and information inquiry program of the target system built according to the present invention.

As shown in FIG. 11, when a user selects the survey request tab menu, input items that the user can enter directly to request a specific survey from the operation server may be provided.

The main purpose of this survey function is to collect carbon emissions data generated from commuting and business trips for executives and employees belonging to the target system. Through this, it is possible to collect survey type, cycle, response period, and recipient information, and additionally, the means of transportation, fuel used for transportation, and travel distance can also be collected. Based on this collected information, the amount of carbon emissions generated during commuting or business trips can be calculated.

Figure 12 is a diagram showing an exemplary display screen for the settings tab menu of the carbon emission calculation and information inquiry program of the target system built according to the present invention.

As shown in FIG. 12, when a user selects the settings tab menu, various setting buttons and input screens may be provided through which the user can set detailed settings for the target system/sub-organization/members, etc.

As described above, preferred embodiments according to the present invention have been examined, and the fact that the present invention can be embodied in other specific forms in addition to the embodiments described above without departing from the spirit or scope thereof is recognized by those skilled in the art. It is self-evident to them. Therefore, the above-described embodiments are to be regarded as illustrative and not restrictive, and thus the present invention is not limited to the above description but may be modified within the scope of the appended claims and their equivalents.

100: Operation server
110: Information Management Department
120: Data processing unit
130: Program Construction Department

Claims (10)

Step (a) where the information management department of the operation server sets classification boundaries for the target system subject to carbon emissions calculation and classifies lower-level organizations;
Step (b) where the information management department specifies carbon emission sources for each sub-organization classified in step (a);
Step (c) where the data processing unit of the operation server calculates the amount of carbon emissions for each carbon emission source specified in step (b); and
The program construction unit of the operation server can search carbon emission-related information for the target system online through the carbon emissions by carbon emission source calculated in step (c) above, and through a graphical user interface executable by a computer. Step (d) of establishing an implemented carbon emissions calculation and information inquiry program;
Including,
In step (c),
Step (c-1) where the data processing unit calculates a base emission figure for each carbon emission source specified in step (b);
Step (c-2) where the data processing unit calculates an emission coefficient through the base emission figure;
Step (c-3) in which the data processing unit calculates carbon emissions by multiplying the base emission figure and the emission coefficient; and
Step (c-4) of converting the carbon emissions calculated in step (c-3) into carbon dioxide equivalent (CO2eq);
Includes,
In step (c-1),
If the carbon emission source is a direct emission type and is a fixed or mobile combustion source, the basic emission figure is calculated by calculating the fuel consumption and calorific value of each fuel and multiplying them,
If the carbon emission source is a direct emission type and a forest sink, the above basic emission figure is calculated by determining the forest area, but the figure is displayed as a minus,
How to calculate the carbon emissions of the target system and build an information inquiry program. According to paragraph 1,
In step (a),
Step (a-1) of the information management department classifying sub-organizations by setting classification boundaries into geographically-based unit facilities for constructing the target system or unit groups divided by preset purposes for the target system; and
Step (a-2) in which the information management department adds transportation and auxiliary facilities owned by the target system as a subordinate organization;
Including,
How to calculate the carbon emissions of the target system and build an information inquiry program. According to paragraph 1,
In step (b),
Step (b-1) where the information management department defines a plurality of carbon emission types for each sub-organization classified in step (a); and
Step (b-2) where the information management unit specifies detailed carbon emission sources for each carbon emission type defined in step (b-1);
Including,
How to calculate the carbon emissions of the target system and build an information inquiry program. According to paragraph 3,
Carbon emission types defined in step (b-1) include direct emission types, indirect emission types, and other emission types.
How to calculate the carbon emissions of the target system and build an information inquiry program. According to paragraph 4,
In step (b-2),
Step (b-2-1) in which the information management department specifies each of the direct emission types, such as fixed combustion sources, mobile combustion sources, fugitive emission sources, waste treatment facilities, forest sinks, fertilizer use, and owned animals, as detailed carbon emission sources;
Step (b-2-2) where the information management unit specifies each item of electricity use, heat use, water use, and waste as the indirect emission type as a detailed carbon emission source; and
Step (b-2-3) in which the information management department specifies each item of commuting/school means and business trips as the other emission types as detailed carbon emission sources;
Including,
How to calculate the carbon emissions of the target system and build an information inquiry program. delete According to paragraph 1,
In step (d),
Step (d-1) in which the program construction unit collects the carbon emissions by carbon emission source calculated in step (c) as base data;
Step (d-2) in which the program construction unit processes the base data to generate processed data; and
Step (d-3) of the program construction unit constructing the carbon emissions calculation and information inquiry program using the base data and the processed data;
Including,
How to calculate the carbon emissions of the target system and build an information inquiry program. In clause 7,
The processed data in step (d-2) is,
Containing at least one of the total carbon emissions information of the target system, the total carbon emissions information for each sub-organization, and the carbon emissions information for each carbon emission type of the sub-organization,
How to calculate the carbon emissions of the target system and build an information inquiry program. According to clause 8,
The total carbon emissions of the target system are:
Calculating the share of the sub-organization of the target system and calculating the calculated share by multiplying it.
How to calculate the carbon emissions of the target system and build an information inquiry program. The carbon emission calculation and information inquiry program of the target system implemented by the method of constructing the carbon emission calculation and information inquiry program of the target system according to any one of paragraphs 1 to 5 and 7 to 9 can be read by a computer that records it. storage media that can be used.