CN116451984B

CN116451984B - Multi-venue green electricity traceability data processing method and system

Info

Publication number: CN116451984B
Application number: CN202310727892.4A
Authority: CN
Inventors: 徐奇锋; 乔松博; 庄晓丹; 陈昊; 俞静; 骆希; 陈梦瑶; 王伟
Original assignee: Zhejiang Electric Power Trade Center Co ltd; Zhejiang Huayun Information Technology Co Ltd
Current assignee: Zhejiang Electric Power Trade Center Co ltd; Zhejiang Huayun Information Technology Co Ltd
Priority date: 2023-06-20
Filing date: 2023-06-20
Publication date: 2023-09-05
Anticipated expiration: 2043-06-20
Also published as: CN116451984A

Abstract

The invention provides a method and a system for processing green traceability data of a multi-venue, comprising the following steps: determining a power transmission control node corresponding to each sub power supply line; determining the power supply attribute of a power supply main line corresponding to each power transmission control node, wherein the output of each power transmission control node corresponds to one sub power supply line of a plurality of venues, and the input of each power transmission control node is connected with one power supply main line; the server obtains the first gate control data of each power transmission control node and the second gate control data analysis record of the venue to obtain power supply data; carrying out statistical analysis on power supply data in a preset time period to obtain power consumption analysis data of each venue, wherein the power consumption analysis data comprises power consumption analysis sub-information corresponding to a load group in the corresponding venue; and the traceability analysis model acquires the power utilization analysis sub-information of the load group corresponding to the corresponding venue according to the received analysis requirement, processes the power utilization analysis sub-information to obtain an analysis result output and display, and the analysis result at least comprises at least one of text information or image information.

Description

Multi-venue green electricity traceability data processing method and system

Technical Field

The invention relates to a data processing technology, in particular to a method and a system for processing green traceability data of a multi-venue.

Background

It is well known that in large events such as sub-establishments, more venues are required to provide a playing field, wherein one of the conditions necessary for each venue is the power supply basis. Generally, a venue may require multiple power lines to supply power, and the power load of the venue is also high, which results in complex power consumption relationship of the venue.

In the prior art, in order to know the source and the destination of electricity consumption data of a venue, the electricity consumption data needs to be traced and analyzed, the required data is often recorded manually, and due to the manual reasons, the problem that the data recording is inaccurate can be caused by the above mode, and meanwhile, tracing and analyzing data cannot be intuitively displayed.

Therefore, how to intuitively display the traceable analysis data of the venue by combining the analysis demands of the users becomes a problem to be solved urgently.

Disclosure of Invention

The embodiment of the invention provides a method and a system for processing green traceability data of a multi-venue, which can intuitively display traceability analysis data of the venue by combining analysis requirements of users.

In a first aspect of the embodiment of the present invention, a method for processing green traceability data of a multi-venue is provided, including:

Acquiring power supply lines supplied by each venue in a plurality of venues, counting the power supply lines supplied by each venue to obtain a power supply line set of the corresponding venue, and determining a power transmission control node corresponding to each power supply line;

determining power supply attributes of a power supply main line corresponding to each power transmission control node, wherein the power supply attributes at least comprise green power attributes and non-green power attributes, the output of each power transmission control node corresponds to one sub power supply line of a plurality of venues, and the input of each power transmission control node is connected with one power supply main line;

the method comprises the steps that a server obtains first brake control data of each power transmission control node and second brake control data of a venue to obtain power supply data, wherein the first brake control data comprise first brake closing information or first brake opening information of corresponding power transmission control nodes and corresponding power supply lines, and the second brake control data comprise second brake closing information or second brake opening information of corresponding sub power supply lines to load groups in the venue;

carrying out statistical analysis on power supply data in a preset time period to obtain power consumption analysis data of each venue, wherein the power consumption analysis data comprises power consumption analysis sub-information corresponding to a load group in the corresponding venue;

And the traceability analysis model acquires the power consumption analysis sub-information of the load group corresponding to the corresponding venue according to the received analysis requirement, processes the power consumption analysis sub-information to obtain an analysis result output and display, and the analysis result at least comprises at least one of text information or image information.

Optionally, in one possible implementation manner of the first aspect, the acquiring power supply lines supplied by each venue of the plurality of venues, counting the power supply lines supplied by each venue to obtain a power supply line set of the corresponding venue, and determining a power transmission control node corresponding to each power supply line, including:

acquiring power supply line topological graphs corresponding to all venues, determining venue nodes corresponding to each venue in the power supply line topological graphs, and taking sub-lines connected with the venue nodes as sub-power supply lines of the corresponding venues;

generating a topology statistical table corresponding to the power supply line topology map, generating a first topology node corresponding to each venue node in the topology statistical table, and generating a second topology node connected with the first topology node according to the connection relation between each venue node and the sub power supply line;

and generating a third topological node connected with the second topological node according to the power transmission control node connected with each sub power supply line, and generating a power supply tree structure corresponding to each venue in a topology statistics table according to the first topological node, the second topological node and the third topological node.

Optionally, in one possible implementation manner of the first aspect, the determining a power supply attribute of a power supply main line corresponding to each power transmission control node, where the power supply attribute includes at least a green power attribute and a non-green power attribute, and each power transmission control node corresponds to one sub power supply line of a plurality of venues includes:

and determining the power supply attribute of the power supply main line corresponding to each power transmission control node, and performing identification configuration on the third topological node of the power supply tree structure according to the power supply attribute of the power transmission control node, wherein the identifications comprise green power identifications and non-green power identifications.

Optionally, in a possible implementation manner of the first aspect, the server obtains the first gate control data of each power transmission control node and the second gate control data analysis record of the venue to obtain the power supply data, including:

generating a power distribution control node corresponding to each venue in a topology statistics table, and connecting the power distribution control node with a first topology node of the corresponding venue;

the server generates corresponding load sub-nodes according to the load group configuration information of the user on each venue, connects the load sub-nodes of each venue with the power distribution control nodes of the corresponding venue to obtain a power utilization tree structure, and obtains a total tree structure corresponding to each venue according to the power supply tree structure and the power utilization tree structure;

The server determines the information of the corresponding load sub-node according to the first switching-on information or the first switching-off information, the second switching-on information or the second switching-off information, and power supply data of the corresponding load sub-node is obtained.

Optionally, in a possible implementation manner of the first aspect, the determining, by the server, information of the corresponding load sub-node according to the first closing information or the first opening information, the second closing information or the second opening information includes:

if the first gate control data of the power transmission control node acquired by the server has corresponding first closing information, taking a third topological node corresponding to the corresponding power transmission control node as a third topological node to be selected;

determining a second topological node to be selected corresponding to a third topological node to be selected according to the first closing information, and determining a first topological node and a power distribution control node which are directly connected with the second topological node as the first topological node and the power distribution control node to be selected;

determining load sub-nodes connected with the power distribution control nodes to be selected according to second gate control data of the venue so as to generate power supply paths corresponding to each load sub-node;

And acquiring the power consumption of the load sub-node, and recording the power consumption and the power supply time of the power supply path to obtain the power supply data of the corresponding load sub-node.

Optionally, in one possible implementation manner of the first aspect, the statistical analysis of the power supply data in the preset period of time obtains power consumption analysis data of each venue, where the power consumption analysis data includes power consumption analysis sub-information corresponding to a load group in the corresponding venue, and the method includes:

if the power supply data of the load sub-nodes in the preset time period are judged to be the same power supply path, calculating according to the power supply path to obtain corresponding power supply analysis information, wherein the power supply analysis information at least comprises the power supply quantity of one power supply main line to one load sub-node;

if the power supply data of the load sub-nodes in the preset time period are judged to be a plurality of power supply paths, calculating according to the plurality of power supply paths to obtain corresponding power supply analysis information, wherein the power supply analysis information at least comprises the power supply quantity of a plurality of power supply main lines to the plurality of load sub-nodes respectively;

and counting the power supply analysis information of the load sub-nodes included in each load group, and summing the power supply analysis information with the same power supply path to obtain power utilization analysis sub-information corresponding to the load group of the corresponding venue, wherein the power utilization analysis sub-information at least comprises the sum of the power supply quantity of each power supply main line to the corresponding venue.

Optionally, in one possible implementation manner of the first aspect, the traceability analysis model obtains, according to the received analysis requirement, power consumption analysis sub-information of a load group corresponding to a corresponding venue, and processes the power consumption analysis sub-information to obtain an analysis result output and display, where the analysis result at least includes at least one of text information or image information, and includes:

the traceability analysis model determines a corresponding data acquisition target, a data calculation formula and a preset display mode according to comparison of the received analysis demand and a preset analysis table, wherein the preset analysis table has a corresponding relation between the analysis demand and the data acquisition target and the data calculation formula;

acquiring the power utilization analysis sub-information of the corresponding load group based on the data acquisition target, and inputting the corresponding power utilization analysis sub-information into a data calculation formula to obtain a text analysis result;

and matching a preset display mode according to the analysis result of the characters to obtain an analysis result of an image corresponding to the analysis result of the characters.

Optionally, in one possible implementation manner of the first aspect, the method further includes:

when judging that a real-time analysis display request of a user is received, acquiring a power supply path corresponding to each load sub-node in a total tree structure, determining a power supply attribute of a third topological node corresponding to the corresponding power supply path, and determining a display mode of the corresponding power supply path according to the power supply attribute, wherein the display modes comprise a green power display mode and a non-green power display mode;

And displaying the power supply paths corresponding to all the load sub-nodes in the total tree structure according to the display modes of the corresponding power supply attributes, and if the plurality of overlapped power supply paths are judged to have different display modes, analyzing the plurality of overlapped power supply paths according to an overlapped display strategy, and determining the display modes of the overlapped paths.

Optionally, in one possible implementation manner of the first aspect, if the determining that the plurality of overlapping power supply paths have different display manners, analyzing the plurality of overlapping power supply paths according to an overlapping display policy, and determining the display manner of the overlapping paths includes:

the overlapping display strategy comprises a green electricity highlighting mode, and if the power supply attribute of the third topological node of at least one power supply path in the plurality of overlapping power supply paths is judged to comprise a green electricity attribute, the overlapping paths are displayed according to a green electricity display mode;

if the power supply attribute of the third topological node in the plurality of overlapped power supply paths is judged to be the non-green power attribute, displaying the overlapped paths according to a non-green power display mode;

the overlapping display strategy comprises a non-green electricity highlighting mode, and if the power supply attribute of the third topological node of at least one power supply path in the plurality of overlapping power supply paths is judged to comprise the non-green electricity attribute, the overlapping paths are displayed according to a non-green electricity display mode;

And if the power supply attribute of the third topological node in the plurality of overlapped power supply paths is judged to be the green power attribute, displaying the overlapped paths according to a green power display mode.

the overlapping display strategy comprises a mixed display mode, and if the third topological nodes of the plurality of overlapping power supply paths respectively comprise green power attributes and non-green power attributes, the first path number of the power supply paths with the green power attributes and the second path number of the power supply paths with the non-green power attributes are obtained;

obtaining a green electrical attribute duty ratio and a non-green electrical attribute duty ratio according to the first path number and the second path number;

obtaining the total number of pixels by obtaining the number of all pixel points in an overlapped path, and equally dividing the total number of pixels according to the preset segmentation number to obtain a plurality of sub-path sections, wherein each sub-path section has the sub-number of pixels;

displaying two sub-path segments of the edge according to a preset separation color, and respectively determining corresponding green display pixel points and non-green display pixel points of the sub-path segments according to the green electric attribute duty ratio and the non-green electric attribute duty ratio for the sub-path segments of the non-edge;

After all the sub-path sections are judged to be determined, the green display pixel points and the non-green display pixel points are obtained according to the sub-path sections of the edges and the sub-path sections of the non-edges, and the overlapping paths with mixed colors are obtained, wherein the green display pixel points and the non-green display pixel points have different colors.

Optionally, in one possible implementation manner of the first aspect, the obtaining the number of all pixel points in the overlapping path obtains a total number of pixels, and equally dividing the total number of pixels according to a preset number of segments to obtain a plurality of sub-path segments, where each sub-path segment has a sub-number of pixels, and includes:

obtaining the total number of pixels by obtaining the number of all pixel points in the overlapped path, and equally dividing the total number of pixels according to the preset segmentation number to obtain the sub-number of pixels of each sub-path segment if the total number of pixels is judged to be divisible by the segmentation number;

if the total number of the pixels cannot be divided by the segmentation number, equally dividing the total number of the pixels according to the preset segmentation number to obtain the number of the pixels of each sub-path segment, and obtaining a corresponding remainder of the pixel points;

the pixel point remainder is divided equally and then the pixel point sub-numbers distributed to the sub-path segments of the edge are respectively added, if the pixel point remainder cannot be divided equally, the pixel point remainder is added to the sub-path segments of the edge in different numbers, and the difference value between the different numbers is 1;

And sequentially determining corresponding sub-path segments in the overlapped paths according to the number of pixel points allocated to each sub-path segment.

In a second aspect of the embodiment of the present invention, a system for processing green traceability data of a multi-venue is provided, including:

the acquisition module is used for acquiring the electronic power supply lines supplied by each venue in the plurality of venues, counting the electronic power supply lines supplied by each venue to obtain a power supply line set of the corresponding venue, and determining a power transmission control node corresponding to each sub power supply line;

the power supply system comprises a determining module, a power supply control module and a power supply control module, wherein the determining module is used for determining the power supply attribute of a power supply main line corresponding to each power transmission control node, the power supply attribute at least comprises a green power attribute and a non-green power attribute, the output of each power transmission control node corresponds to one sub power supply line of a plurality of venues, and the input of each power transmission control node is linked with one power supply main line;

the recording module is used for enabling the server to acquire first brake control data of each power transmission control node and second brake control data of the venue to analyze and record to obtain power supply data, wherein the first brake control data comprises first brake closing information or first brake opening information of corresponding power transmission control nodes and corresponding power supply lines, and the second brake control data comprises second brake closing information or second brake opening information of corresponding sub-power supply lines to a load group in the venue;

The analysis module is used for carrying out statistical analysis on the power supply data in a preset time period to obtain power consumption analysis data of each venue, wherein the power consumption analysis data comprises power consumption analysis sub-information corresponding to a load group in the corresponding venue;

the display module is used for enabling the traceability analysis model to acquire the power utilization analysis sub-information of the load group corresponding to the corresponding venue according to the received analysis requirement, processing the power utilization analysis sub-information to obtain an analysis result output display, and the analysis result at least comprises at least one of text information or image information.

The beneficial effects are that: 1. according to the scheme, the power supply line sets of the venues and the power transmission control nodes corresponding to the sub power supply lines are obtained by combing the corresponding power relations of different venues, so that the first closing information or the first opening information of the corresponding power supply sub power supply lines are obtained, meanwhile, the second closing information or the second opening information of the load groups in the venues can be obtained, and the power relation diagram can be formed by combining the information, so that the traceable analysis data of the load groups in the venues can be intuitively displayed. In addition, the scheme can also acquire the power consumption analysis sub-information of the load group corresponding to the corresponding venue through the traceability analysis model in combination with the analysis requirement of the user, process the power consumption analysis sub-information to obtain analysis result output display, and intuitively display traceability analysis data of the venue in combination with the analysis requirement of the user.

2. When the scheme is used for forming the power relation graph, a power supply tree structure corresponding to each venue is generated in the topology statistics table by combining the first topology node, the second topology node and the third topology node, meanwhile, a corresponding load sub-node is generated according to the load group configuration information of a user on each venue, the load sub-node of each venue is connected with the power distribution control node of the corresponding venue to obtain a power utilization tree structure, and finally, the power supply tree structure and the power utilization tree structure are combined to obtain a total tree structure corresponding to each venue, so that the carding of the power relation of each venue is realized. In addition, the scheme can combine the first switching-on information or the first switching-off information, the second switching-on information or the second switching-off information to generate a power supply path corresponding to each load sub-node, and meanwhile, combine the power supply path to obtain power utilization analysis sub-information corresponding to the load group of the corresponding venue. And finally, grabbing the corresponding data target by combining the traceability analysis model with the analysis requirement of the user, and then obtaining the corresponding traceability analysis data by combining the preset calculation model, so that the traceability analysis data of the stadium is obtained and visually displayed.

3. When receiving a real-time analysis display request of a user, the scheme acquires power supply paths corresponding to all load sub-nodes in the total tree structure, and then determines a display mode of the corresponding power supply paths according to the power supply attributes by combining the power supply attributes of the third topological nodes corresponding to the corresponding power supply paths. And when the display is performed, displaying the corresponding attribute of the non-overlapped power supply paths, and displaying the power supply paths with the overlapped power supply paths by using an overlapped display strategy. When the overlapped display strategy is in the green highlighting mode, the green highlighting is prioritized; when the overlay display strategy is in a non-green highlighting mode, prioritizing the non-green highlighting; when the overlapped display strategy is in the mixed display mode, the green electric attribute duty ratio and the non-green electric attribute duty ratio are calculated by combining the first path number of the power supply paths of the green electric attribute and the second path number of the power supply paths of the non-green electric attribute, and then the pixel point pixel values of the plurality of sub-path segments are changed by using the duty ratio, so that the overlapped path with mixed colors is obtained. When determining the sub-path segments, a related scheme is also arranged to determine the number of pixels of each sub-path segment.

Drawings

Fig. 1 is a schematic flow chart of a multi-venue green electricity tracing data processing method according to an embodiment of the present invention;

fig. 2 is a topology diagram of power supply lines corresponding to all venues according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a multi-venue green electricity traceability data processing system according to an embodiment of the present invention.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The terms "first," "second," "third," "fourth" and the like in the description and in the claims and in the above drawings, if any, are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate such that the embodiments of the invention described herein may be implemented in sequences other than those illustrated or otherwise described herein.

It should be understood that, in various embodiments of the present invention, the sequence number of each process does not mean that the execution sequence of each process should be determined by its functions and internal logic, and should not constitute any limitation on the implementation process of the embodiments of the present invention.

It should be understood that in the present invention, "comprising" and "having" and any variations thereof are intended to cover non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements that are expressly listed or inherent to such process, method, article, or apparatus.

It should be understood that in the present invention, "plurality" means two or more. "and/or" is merely an association relationship describing an association object, meaning that there may be three relationships, e.g., a and/or B, may represent: a exists alone, A and B exist together, and B exists alone. The character "/" generally indicates that the context-dependent object is an "or" relationship. "comprising A, B and C", "comprising A, B, C" means that all three of A, B, C comprise, "comprising A, B or C" means that one of the three comprises A, B, C, and "comprising A, B and/or C" means that any 1 or any 2 or 3 of the three comprises A, B, C.

It should be understood that in the present invention, "B corresponding to a", "a corresponding to B", or "B corresponding to a" means that B is associated with a, from which B can be determined. Determining B from a does not mean determining B from a alone, but may also determine B from a and/or other information. The matching of A and B is that the similarity of A and B is larger than or equal to a preset threshold value.

As used herein, "if" may be interpreted as "at … …" or "at … …" or "in response to a determination" or "in response to detection" depending on the context.

The technical scheme of the invention is described in detail below by specific examples. The following embodiments may be combined with each other, and some embodiments may not be repeated for the same or similar concepts or processes.

Referring to fig. 1, a flow chart of a multi-venue green electricity tracing data processing method provided by an embodiment of the present invention includes S1-S5:

s1, acquiring electronic power supply lines supplied by each venue in a plurality of venues, counting the electronic power supply lines supplied by each venue to obtain a power supply line set of the corresponding venue, and determining a power transmission control node corresponding to each sub power supply line.

In practical applications, when hosting large-scale activities such as subcongregation, more venues are required to provide the competition area, wherein one of the necessary venues is to supply power. Generally, a venue may need multiple power lines to supply power, so the scheme obtains the power lines supplied by each venue in the multiple venues, and then calculates the power lines supplied by each venue to obtain the power line set of the corresponding venue.

Meanwhile, after the sub power supply lines are obtained, the scheme also determines the power transmission control node corresponding to each sub power supply line. The power transmission control node is a node for controlling whether the corresponding sub power supply line is powered.

In some embodiments, S1 (obtaining power supply lines supplied by each venue of the plurality of venues, counting power supply lines supplied by each venue to obtain a power supply line set of the corresponding venue, and determining a power transmission control node corresponding to each power supply line) includes S11-S13:

s11, obtaining power supply circuit topological graphs corresponding to all venues, determining venue nodes corresponding to each venue in the power supply circuit topological graphs, and taking sub-circuits connected with the venue nodes as sub-power supply circuits of the corresponding venues.

Referring to fig. 2, the scheme obtains power supply line topology diagrams corresponding to all venues, that is, obtains power supply diagrams of all venues, determines venue nodes corresponding to each venue in the power supply line topology diagrams, and uses sub-lines connected with the venue nodes as sub-power supply lines of the corresponding venues.

And S12, generating a topology statistical table corresponding to the power supply line topological graph, generating a first topology node corresponding to each venue node in the topology statistical table, and generating a second topology node connected with the first topology node according to the connection relation between each venue node and the sub power supply line.

Referring to fig. 2, the scheme generates a topology statistics table corresponding to the power supply line topology map, generates a first topology node corresponding to each venue node in the topology statistics table, and then generates a second topology node connected with the first topology node according to the connection relationship between each venue node and the sub power supply line.

It can be understood that the first topology node is a node corresponding to a venue, and the second topology node is a node corresponding to a sub power supply line. For example, when a venue corresponds to a plurality of sub-power lines, then a plurality of second topology nodes are connected.

And S13, generating a third topological node connected with the second topological node according to the power transmission control node connected with each sub power supply line, and generating a power supply tree structure corresponding to each venue in a topology statistical table according to the first topological node, the second topological node and the third topological node.

The third topology node is a power transmission control node, and is connected with the second topology node, for example, a node for controlling whether an actual power supply party supplies power, for example, a control node corresponding to a power supply party such as Xinjiang, yunnan and the like.

It is worth mentioning that through the above-mentioned mode, can obtain the power supply tree structure that every venue corresponds, clearly demonstrate the power supply relation.

S2, determining the power supply attribute of a power supply main line corresponding to each power transmission control node, wherein the power supply attribute at least comprises a green power attribute and a non-green power attribute, the output of each power transmission control node corresponds to one sub power supply line of a plurality of venues, and the input of each power transmission control node is connected with one power supply main line.

It can be understood that, because the power supply is divided into multiple types, including a non-green power type and a green power type, for example, in order to perform classified display, the power supply attribute of the power supply main line corresponding to each power transmission control node is obtained.

The power supply main line is a power supply main line corresponding to a power transmission control node, for example, a power supply main line corresponding to a Xinjiang node, the output of each power transmission control node (the third topological node in fig. 2) corresponds to one sub power supply line (the second topological node in fig. 2) of a plurality of venues, and the input of each power transmission control node is connected with one power supply main line (for example, a power supply main line corresponding to Xinjiang and Yunnan).

In some embodiments, S2 (determining a power attribute of a power supply line corresponding to each power transmission control node, where the power attribute includes at least a green power attribute and a non-green power attribute, and each power transmission control node corresponds to one sub-power supply line of a plurality of venues) includes:

The power supply attribute of the power supply main line corresponding to each power transmission control node is obtained, and then the power supply attribute of the power transmission control node is combined to perform identification configuration on the third topological node of the power supply tree structure, wherein the identification comprises a green power identification and a non-green power identification.

It is worth mentioning that, through the above-mentioned sign, can learn the power supply type to when carrying out the demonstration in the follow-up, combine actual conditions to carry out the customization show.

And S3, the server acquires first brake control data of each power transmission control node and second brake control data of the venue, analysis records are carried out on the first brake control data to obtain power supply data, the first brake control data comprise first brake closing information or first brake opening information of corresponding power transmission control nodes and corresponding power supply lines, and the second brake control data comprise second brake closing information or second brake opening information of corresponding sub-power supply lines to a load group in the venue.

The first brake control data refers to control data corresponding to the power transmission control node, and comprises first switching-on information or first switching-off information of the corresponding power transmission control node and a corresponding power supply line. It can be understood that when the first switching-on information is the first switching-on information, the corresponding sub power supply line is indicated to be powered by the corresponding power transmission control node; when the first switching-on information is the first switching-off information, the corresponding sub power supply line is not supplied by the corresponding power transmission control node.

Generally, there are various power loads in a venue, such as a lighting lamp, a camera, a display screen, etc., so that a venue may have a plurality of sub-power lines for supplying power to the corresponding power loads. The second brake control data comprise second switch-on information or second switch-off information of the corresponding sub-power supply lines to the load groups in the venue, namely, the brake control data for controlling whether the corresponding load groups are electrified.

In some embodiments, the step of S3 (the server obtaining the first gate control data of each power transmission control node and the second gate control data analysis record of the venue to obtain the power supply data) includes steps of S31-S33:

and S31, generating power distribution control nodes corresponding to each venue in the topology statistics table, and connecting the power distribution control nodes with first topology nodes of the corresponding venue.

Referring to fig. 2, the distribution control node is disposed corresponding to a venue, and the distribution control node is connected to a first topology node of the corresponding venue.

S32, the server generates corresponding load sub-nodes according to the load group configuration information of the user for each venue, connects the load sub-nodes of each venue with the power distribution control nodes of the corresponding venue to obtain a power utilization tree structure, and obtains a total tree structure corresponding to each venue according to the power supply tree structure and the power utilization tree structure.

Because each venue has a plurality of load groups, the scheme can combine the load group configuration information of the user on each venue to generate corresponding load sub-nodes, and then the load sub-nodes of each venue are connected with the power distribution control nodes of the corresponding venue to obtain the electricity utilization tree structure. It is understood that the electricity tree structure refers to an electricity relation diagram of a corresponding venue.

Finally, the scheme can obtain a total tree structure corresponding to each stadium according to the power supply tree structure and the power utilization tree structure. It should be noted that the overall tree structure includes both a power supply relationship and a power consumption relationship.

S33, the server determines the information of the corresponding load sub-node according to the first switching-on information or the first switching-off information, the second switching-on information or the second switching-off information, and power supply data of the corresponding load sub-node is obtained.

The server can determine the information of the corresponding load sub-node by combining the first switching-on information or the first switching-off information, the second switching-on information or the second switching-off information, and power supply data of the corresponding load sub-node is obtained.

Wherein S33 (the server determines the information of the corresponding load sub-node according to the first closing information or the first opening information, the second closing information or the second opening information) includes S331-S334:

s331, if the first gate control data of the power transmission control node acquired by the server has corresponding first closing information, taking a third topological node corresponding to the corresponding power transmission control node as a third topological node to be selected.

It can be understood that if the first gate control data of the power transmission control node acquired by the server has corresponding first closing information, which indicates that the power transmission control node supplies power, at this time, a third topology node corresponding to the corresponding power transmission control node is used as the third topology node to be selected.

And S332, determining a second topological node to be selected corresponding to the third topological node to be selected according to the first closing information, and determining a first topological node and a power distribution control node which are directly connected with the second topological node as the first topological node and the power distribution control node to be selected.

According to the scheme, according to the first closing information, a second topological node to be selected corresponding to the third topological node to be selected, namely the second topological node connected with the third topological node in fig. 2, is determined.

Then, a first topological node and a power distribution control node which are directly connected with the second topological node are determined as the first topological node and the power distribution control node to be selected.

S333, determining load sub-nodes connected with the power distribution control node to be selected according to second gate control data of the venue so as to generate a power supply path corresponding to each load sub-node.

The scheme combines second gate control data of the venue to determine load sub-nodes connected with the power distribution control node to be selected so as to generate a power supply path corresponding to each load sub-node. By the method, the load groups in the venue can be split, and the power supply paths corresponding to the load sub-nodes are obtained

And S334, acquiring the power consumption of the load sub-node, and recording the power consumption and the power supply time of the power supply path to obtain the power supply data of the corresponding load sub-node.

Meanwhile, the power consumption of the load sub-node can be obtained, the power consumption of the power supply path and the power supply time are recorded to obtain the power supply data of the corresponding load sub-node, and the power supply data of the corresponding load sub-node can be obtained through calculation of the power consumption and the power supply time.

And S4, carrying out statistical analysis on the power supply data in a preset time period to obtain power consumption analysis data of each venue, wherein the power consumption analysis data comprises power consumption analysis sub-information corresponding to a load group in the corresponding venue.

The power supply data statistical analysis in a preset time period, for example, the power supply data in 24 hours is counted, and the power consumption analysis data of each stadium is obtained.

The electricity analysis data comprise electricity analysis sub-information corresponding to the load group in the corresponding venue.

In some embodiments, S4 (statistical analysis of power supply data in a preset period of time to obtain power consumption analysis data of each venue, where the power consumption analysis data includes power consumption analysis sub-information corresponding to a load group in the respective venue) includes S41-S43:

And S41, if the power supply data of the load sub-nodes in the preset time period are judged to be the same power supply path, calculating according to the power supply path to obtain corresponding power supply analysis information, wherein the power supply analysis information at least comprises the power supply quantity of one power supply main line to one load sub-node.

With respect to the power supply dimension, it is understood that in some cases, there may be only one power supply path to power the load child nodes.

When the statistics is carried out, if the power supply data of the load sub-nodes in the preset time period are judged to be the same power supply path, at the moment, the corresponding power supply analysis information is obtained by calculating one power supply path.

The power supply analysis information at least comprises the power supply quantity of one power supply main line to one load sub-node.

And S42, if the power supply data of the load sub-nodes in the preset time period are judged to be a plurality of power supply paths, calculating according to the plurality of power supply paths to obtain corresponding power supply analysis information, wherein the power supply analysis information at least comprises the power supply amounts of a plurality of power supply main lines to the plurality of load sub-nodes.

It will be appreciated that in some cases, there may be multiple power paths powering the load sub-nodes.

If the power supply data of the load sub-nodes in the preset time period are judged to be a plurality of power supply paths, at the moment, comprehensive calculation is needed to be carried out on the plurality of power supply paths, and corresponding power supply analysis information is obtained.

The power supply analysis information at least comprises power supply amounts of a plurality of power supply main lines to a plurality of load sub-nodes respectively.

And S43, counting the power supply analysis information of the load sub-nodes included in each load group, and summing the power supply analysis information with the same power supply path to obtain power consumption analysis sub-information corresponding to the load group of the corresponding venue, wherein the power consumption analysis sub-information at least comprises the sum of the power supply quantity of each power supply main line to the corresponding venue.

The power supply analysis information of the load sub-nodes included in each load group in the venue is counted, and then the power supply analysis information with the same power supply path is summed to obtain power supply analysis sub-information corresponding to the load group of the venue.

The power consumption analysis sub-information at least comprises the sum of power supply quantity of each power supply main line to a corresponding stadium.

For example, for the load sub-node 1 and the load sub-node 2, the same power supply path 1 is used for supplying power, and then the scheme calculates the sum of power supply analysis information of the power supply path 1 to the load sub-node 1 and the load sub-node 2 to obtain power supply information of the power supply path 1 to the corresponding venue.

In another example, the load sub-node 3 and the load sub-node 4 use the same power supply path 2 to supply power, and then the scheme calculates the sum of power supply analysis information of the power supply path 2 to the load sub-node 3 and the load sub-node 4 to obtain power supply information of the power supply path 2 to a corresponding venue. By the mode, the power supply data of each power supply main line to the corresponding stadium can be obtained.

S5, the traceability analysis model obtains the power consumption analysis sub-information of the load group corresponding to the corresponding venue according to the received analysis requirement, processes the power consumption analysis sub-information to obtain an analysis result output and display, and the analysis result at least comprises at least one of text information or image information.

When a user has analysis requirements, the traceable analysis model can be utilized to receive the input analysis requirements, then the power utilization analysis sub-information of the load group corresponding to the corresponding venue is obtained, and the analysis result is obtained through processing and output and display.

The analysis result at least comprises at least one of text information or image information, namely, the analysis result can be displayed through the text information or the image information.

It should be noted that the analysis requirement may be an analysis requirement for a corresponding dimension in a venue, for example, the venue a is selected for analysis, and the analysis requirement may be: the ratio of green electricity to total electricity, the ratio of green electricity to non-green electricity, the ratio of Xinjiang electricity to all electricity, etc., may be preset for the user to select.

S5 (the traceability analysis model obtains the power consumption analysis sub-information of the load group corresponding to the corresponding venue according to the received analysis requirement, processes the power consumption analysis sub-information to obtain an analysis result output and displays, and the analysis result at least comprises at least one of text information or image information) comprises S51-S53:

s51, the traceability analysis model compares the received analysis requirements with a preset analysis table, and determines a corresponding data acquisition target, a data calculation formula and a preset display mode, wherein the preset analysis table is internally provided with a corresponding relation between the analysis requirements and the data acquisition target and the data calculation formula.

It can be understood that the analysis requirements are different, and the corresponding data acquisition targets, data calculation formulas and preset display modes can also be different. For example, aiming at the analysis requirement of the proportion of the green electricity in the stadium A to the total electricity, the data acquisition targets are green electricity data and total electricity data, and the data calculation formula is a proportion formula of the green electricity data and the total electricity data.

S52, acquiring the power utilization analysis sub-information of the corresponding load group based on the data acquisition target, and inputting the corresponding power utilization analysis sub-information into a data calculation formula to obtain a text analysis result.

According to the scheme, the data acquisition targets are combined to acquire the power utilization analysis sub-information of the corresponding load group, and then the corresponding power utilization analysis sub-information is input into a data calculation formula to be processed to obtain the analysis result of the characters.

And S53, matching a preset display mode according to the analysis result of the characters to obtain an analysis result of an image corresponding to the analysis result of the characters.

And finally, matching the preset display mode by combining the analysis result of the characters to obtain an analysis result of the image corresponding to the analysis result of the characters.

On the basis of the embodiment, the method further comprises the steps of A1-A2:

a1, when judging that a real-time analysis display request of a user is received, acquiring a power supply path corresponding to each load sub-node in a total tree structure, determining a power supply attribute of a third topological node corresponding to the corresponding power supply path, and determining a display mode of the corresponding power supply path according to the power supply attribute, wherein the display modes comprise a green power display mode and a non-green power display mode.

The scheme is provided with a real-time analysis display request, when judging that the real-time analysis display request of a user is received, a power supply path corresponding to each load sub-node in the total tree structure is obtained, and then the power supply attribute of a third topological node corresponding to the corresponding power supply path is determined.

And then, determining display modes of the corresponding power supply paths according to the power supply attributes, wherein the display modes comprise a green power display mode and a non-green power display mode. For example, the green display mode may display the power supply path with green pixels, and the non-green display mode may display the power supply path with red pixels.

A2, displaying the power supply paths corresponding to all the load sub-nodes in the total tree structure according to the display modes of the corresponding power supply attributes, and if the plurality of overlapped power supply paths are judged to have different display modes, analyzing the plurality of overlapped power supply paths according to an overlapped display strategy, and determining the display modes of the overlapped paths.

The scheme can display power supply paths corresponding to all load sub-nodes in the total tree structure according to a display mode of corresponding power supply attributes.

It should be noted that in some cases, overlapping paths may occur between multiple power supply paths, if it is determined that multiple overlapping power supply paths have different display modes, display errors may be caused, and in this case, the display modes of the overlapping paths may be determined by analyzing the multiple overlapping power supply paths according to an overlapping display policy.

In some embodiments, A2 (if it is determined that the plurality of overlapping power supply paths have different display modes, analyzing the plurality of overlapping power supply paths according to an overlapping display policy, and determining the display mode of the overlapping paths) includes a21-a24:

and A21, the overlapping display strategy comprises a green electricity highlighting mode, and if the power supply attribute of the third topological node of at least one power supply path in the plurality of overlapping power supply paths is judged to comprise the green electricity attribute, the overlapping paths are displayed according to a green electricity display mode.

The overlapping display strategy of the scheme comprises a green electricity highlighting mode, and in the green electricity highlighting mode, the overlapping paths are displayed in a priority mode, so that if the power supply attribute of the third topological node of at least one power supply path in the plurality of overlapping power supply paths is judged to comprise the green electricity attribute, the overlapping paths are displayed uniformly according to a green electricity display mode.

And A22, if the power supply attribute of the third topological node in the plurality of overlapped power supply paths is judged to be the non-green power attribute, displaying the overlapped paths according to a non-green power display mode.

It should be noted that, in the green power highlighting mode, if the power supply attribute of the third topology node in the plurality of overlapped power supply paths is a non-green power attribute, the overlapped paths are displayed according to a non-green power display mode.

And A23, the overlapping display strategy comprises a non-green electricity highlighting mode, and if the power supply attribute of the third topological node of at least one power supply path in the plurality of overlapping power supply paths is judged to comprise the non-green electricity attribute, the overlapping paths are displayed according to a non-green electricity display mode.

The overlapping display strategy of the scheme comprises a non-green electricity highlighting mode, and in the non-green electricity highlighting mode, the overlapping display mode is preferentially displayed in the non-green electricity mode, so that if the power supply attribute of the third topological node of at least one power supply path in the plurality of overlapping power supply paths is judged to comprise the non-green electricity attribute, the overlapping paths are uniformly displayed according to a non-green electricity display mode.

And A24, if the power supply attribute of the third topological node in the plurality of overlapped power supply paths is judged to be the green power attribute, displaying the overlapped paths according to a green power display mode.

It should be noted that, in the non-green highlighting mode, if the power supply attribute of the third topology node in the plurality of overlapped power supply paths is the green power attribute, the overlapped paths are displayed according to the green power display mode.

In some embodiments, A2 (if it is determined that the plurality of overlapping power supply paths have different display modes, analyzing the plurality of overlapping power supply paths according to an overlapping display policy, and determining the display mode of the overlapping paths) includes a25-a29:

And A25, the overlapped display strategy comprises a mixed display mode, and if the third topological nodes of the overlapped power supply paths respectively comprise green power attributes and non-green power attributes, the first path number of the power supply paths with the green power attributes and the second path number of the power supply paths with the non-green power attributes are obtained.

The overlapping display strategy of the scheme comprises a mixed display mode, and different data are required to be combined and displayed in the mixed display mode.

If it is determined that the third topological nodes of the plurality of overlapped power supply paths respectively include green power attributes and non-green power attributes, the scheme can acquire the first path number of the power supply paths with the green power attributes and the second path number of the power supply paths with the non-green power attributes.

And A26, obtaining the green electric property duty ratio and the non-green electric property duty ratio according to the first path number and the second path number.

The green electric property duty ratio and the non-green electric property duty ratio can be obtained according to the ratio of the first path number to the second path number.

A27, obtaining the total number of pixels by obtaining the number of all pixel points in the overlapped path, and equally dividing the total number of pixels according to the preset segmentation number to obtain a plurality of sub-path sections, wherein each sub-path section has the sub-number of pixels.

When the mixed display is performed, the method can obtain the total number of pixels by firstly obtaining the number of all pixel points in the overlapped path, wherein the total number of the pixels is 300, then the total number of the pixels is uniformly divided into a plurality of sub-path sections according to the preset segmentation number, each sub-path section is provided with the pixel sub-number, the preset segmentation number is 10, and each sub-path section is provided with the pixel sub-number of 30.

Wherein a27 (obtaining the total number of pixels obtained by obtaining the number of all pixel points in the overlapped path, and equally dividing the total number of pixels according to a preset segmentation number to obtain a plurality of sub-path segments, each sub-path segment having the number of pixel sub-numbers) includes a 271-a 274:

and A271, obtaining the total number of pixels by obtaining the number of all pixel points in the overlapped path, and equally dividing the total number of pixels according to the preset segmentation number to obtain the sub-number of pixels of each sub-path segment if the total number of pixels can be divided into the segmentation number.

In an exemplary embodiment, the total number of pixels is 300, and the preset number of segments is 10, for example, and then each sub-path segment has 30 sub-pixels.

It should be noted that in the above case, the total number of pixels can be divided into the divided numbers.

And A272, if the total number of the pixels is not divided into the segment numbers, equally dividing the total number of the pixels according to the preset segment numbers to obtain the pixel sub-number of each sub-path segment, and obtaining the remainder of the corresponding pixel points.

Another example is that the total number of pixels is 302, for example, and the preset number of segments is 10, for example, in which case the total number of pixels is not divisible by the number of segments.

At this time, the method includes dividing the total number of pixels into the sub-number of pixels 30 according to the preset number of segments, and obtaining the remainder 2 of the corresponding pixel point.

And A273, adding the pixel point remainder to the sub-path segments of the edge in different numbers if the pixel point remainder cannot be equally divided after equally dividing the pixel point remainder, wherein the difference between the different numbers is 1.

According to the scheme, after the remainder of the pixel points is equally divided, the number of the pixel points allocated to the sub-path sections of the edge is added respectively, for example, when the remainder is 2, the remainder can be equally divided, then 1 pixel point is added to the 1 st section and the 10 th section respectively, that is, 31 pixel points are arranged on the 1 st section and the 10 th section, and 30 pixel points are arranged on the other sections.

If the remainder of the pixel cannot be equally divided, for example, the remainder is 3, the present solution adds the remainder of the pixel to the sub-path segment of the edge in different amounts, and the difference between the different amounts is 1. For example, 2 are added for segment 1 and 1 is added for segment 10.

A274, sequentially determining corresponding sub-path segments in the overlapped path according to the sub-numbers of the pixel points allocated to each sub-path segment.

The scheme sequentially determines corresponding sub-path segments in the overlapped paths according to the sub-number of the pixel points allocated to each sub-path segment. For example, the first pixel of the overlapping path is traversed until the number of pixels corresponding to the 1 st segment corresponds, and then the first pixel is regarded as the 1 st segment, and the other pixels are similar.

And A28, displaying the two sub-path segments of the edge according to a preset separation color, and respectively determining corresponding green display pixel points and non-green display pixel points of the sub-path segments according to the green attribute duty ratio and the non-green attribute duty ratio for the sub-path segments of the non-edge.

After obtaining the sub-path segments, the scheme displays the two sub-path segments of the edge according to a preset separation color, for example, yellow to distinguish the overlapped paths. And then, respectively determining corresponding green display pixel points and non-green display pixel points of the sub-path segments according to the green attribute duty ratio and the non-green attribute duty ratio of the non-edge sub-path segments.

For example, the green electric property ratio and the non-green electric property ratio are 1:2, and the number of pixels of one non-edge sub-path segment is 30, so that the number of corresponding green electric display pixels is 10, and the number of non-green electric display pixels is 20. It should be noted that in some cases, when the calculated number of green display pixels or the calculated number of non-green display pixels is not an integer, one of the calculated numbers is rounded up, and the other is reduced by 1.

After the number of the corresponding green display pixels and the number of the non-green display pixels are obtained in the non-edge sub-path segment, the first pixel of the non-edge sub-path segment may be traversed, for example, the first 10 pixels are searched to be used as the green display pixels, and the last 20 pixels are searched to be used as the non-green display pixels.

And A29, after all the sub-path sections are judged to determine the green electric display pixel points and the non-green electric display pixel points, overlapping paths with mixed colors are obtained according to the sub-path sections of the edges and the sub-path sections of the non-edges, and the green electric display pixel points and the non-green electric display pixel points have different colors.

After all the sub-path sections are judged to be determined, the green display pixel points and the non-green display pixel points are obtained according to the sub-path sections of the edges and the sub-path sections of the non-edges, and overlapping paths with mixed colors are obtained, wherein the green display pixel points and the non-green display pixel points have different colors.

Referring to fig. 3, a schematic structural diagram of a multi-venue green electricity tracing data processing system according to an embodiment of the present invention includes:

The present invention also provides a storage medium having stored therein a computer program for implementing the methods provided by the various embodiments described above when executed by a processor.

The storage medium may be a computer storage medium or a communication medium. Communication media includes any medium that facilitates transfer of a computer program from one place to another. Computer storage media can be any available media that can be accessed by a general purpose or special purpose computer. For example, a storage medium is coupled to the processor such the processor can read information from, and write information to, the storage medium. In the alternative, the storage medium may be integral to the processor. The processor and the storage medium may reside in an application specific integrated circuit (Application Specific Integrated Circuits, ASIC for short). In addition, the ASIC may reside in a user device. The processor and the storage medium may reside as discrete components in a communication device. The storage medium may be read-only memory (ROM), random-access memory (RAM), CD-ROMs, magnetic tape, floppy disk, optical data storage device, etc.

The present invention also provides a program product comprising execution instructions stored in a storage medium. The at least one processor of the device may read the execution instructions from the storage medium, the execution instructions being executed by the at least one processor to cause the device to implement the methods provided by the various embodiments described above.

In the above embodiments of the terminal or the server, it should be understood that the processor may be a central processing unit (english: central Processing Unit, abbreviated as CPU), or may be other general purpose processors, digital signal processors (english: digital Signal Processor, abbreviated as DSP), application specific integrated circuits (english: application Specific Integrated Circuit, abbreviated as ASIC), or the like. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like. The steps of a method disclosed in connection with the present invention may be embodied directly in a hardware processor for execution, or in a combination of hardware and software modules in a processor for execution.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the invention.

Claims

1. The method for processing the green traceability data of the multi-venue is characterized by comprising the following steps of:

2. The method for processing multi-venue green electricity traceability data according to claim 1, wherein,

the method for obtaining the electronic power supply lines of each venue in the plurality of venues, counting the electronic power supply lines of each venue to obtain the electronic power supply line set of the corresponding venue, and determining the power transmission control node corresponding to each sub power supply line comprises the following steps:

generating a topology statistical table corresponding to a power supply line topology graph, generating a first topology node corresponding to each venue node in the topology statistical table, and generating a second topology node connected with the first topology node according to the connection relation between each venue node and a sub power supply line, wherein the first topology node is a node corresponding to a venue;

Generating a third topological node connected with the second topological node according to the power transmission control node connected with each sub power supply line, and generating a power supply tree structure corresponding to each venue in a topology statistics table according to the first topological node, the second topological node and the third topological node, wherein the third topological node is the power transmission control node.

3. The method for processing multi-venue green electricity traceability data according to claim 2, wherein,

the determining a power supply attribute of a power supply main line corresponding to each power transmission control node, where the power supply attribute at least includes a green power attribute and a non-green power attribute, and each power transmission control node corresponds to one sub power supply line of a plurality of venues, includes:

4. The method for processing multi-venue green electricity traceability data according to claim 2, wherein,

the server obtains the first gate control data of each power transmission control node and the second gate control data analysis record of the venue to obtain power supply data, and the power supply data comprises:

5. The method for processing multi-venue green electricity traceability data according to claim 4, wherein,

the server determines the information of the corresponding load sub-node according to the first switching-on information or the first switching-off information, the second switching-on information or the second switching-off information, and the method comprises the following steps:

6. The method for processing multi-venue green electricity traceability data according to claim 5, wherein,

the statistical analysis of the power supply data in the preset time period is performed to obtain power consumption analysis data of each venue, wherein the power consumption analysis data comprises power consumption analysis sub-information corresponding to a load group in the corresponding venue, and the statistical analysis comprises the following steps:

7. The method for processing multi-venue green electricity traceability data according to claim 1, wherein,

the traceability analysis model obtains the power consumption analysis sub-information of the load group corresponding to the corresponding venue according to the received analysis requirement, processes the power consumption analysis sub-information to obtain an analysis result output and display, and the analysis result at least comprises at least one of text information or image information and comprises the following components:

8. The multi-venue green electricity traceability data processing method according to claim 5, further comprising:

9. The method for processing multi-venue green electricity traceability data according to claim 8, wherein,

if the multiple overlapped power supply paths are judged to have different display modes, analyzing the multiple overlapped power supply paths according to an overlapped display strategy to determine the display mode of the overlapped paths, wherein the method comprises the following steps:

10. The method for processing multi-venue green electricity traceability data according to claim 9, wherein,

11. The method for processing multi-venue green electricity traceability data according to claim 10, wherein,

the method comprises the steps of obtaining the total number of pixels by obtaining the number of all pixel points in an overlapped path, equally dividing the total number of pixels according to the preset segmentation number to obtain a plurality of sub-path sections, wherein each sub-path section has the sub-number of pixels, and the method comprises the following steps:

12. Multi-venue green electricity traceability data processing system, which is characterized by comprising: