CN109377412B - Intensive distribution and debugging graph model maintenance system and maintenance method thereof - Google Patents
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Abstract
The invention discloses a distribution and dispatching intensive graph model maintenance system and a maintenance method thereof, wherein the distribution and dispatching intensive graph model maintenance system comprises a GIS system and a distribution and dispatching intensive system, the GIS system transmits a graph model of a distribution network single line graph to the distribution and dispatching intensive system, the distribution and dispatching intensive system is provided with a concurrency processing module, a full-automatic import module and a manual intervention module before final import, the concurrency processing module is used for processing a plurality of graph model maintenance requests in the same time period, the full-automatic import module is used for automatically importing the graph model by a program, and the manual intervention module is used for manually auditing when an actual model is finally imported. The invention greatly saves the labor cost by concurrent processing and full-automatic introduction, and can liberate the labor to do more complex monitoring work; compared with other introduction processes, the method is simple and concise, has clear conditioning and is easy to implement, and meanwhile, the complex problems are decomposed and integrated.
Description
Technical Field
The invention belongs to the technical field of a distribution and dispatching intensive graph model maintenance system, and particularly relates to a distribution and dispatching intensive graph model maintenance system and a maintenance method thereof.
Background
In a typical intensive distribution system, there are more than 160 plant stations, more than 1000 feeders, 1100 feeder pictures and more than 200 distribution network ring network diagrams. The graphs are generated in an artificial drawing mode, and then a distribution network model is generated by a PCS-9000 system library filling program and is used as a basis for subsequent acquisition, analysis and display of the system.
At present, 78 GIS single line diagrams are introduced into a typical intensive dispatching system, 78 GIS single line diagrams are audited, all single line diagrams are introduced on line at the end of 8 months, and the final scale reaches 1500 feeder lines. Taking months 4-5 as an example, the first zone: 211 transaction, zone two: 322 transaction, new picture: 138 feeder lines. Such a large number of transactions are difficult to process in a conventional manner, and thus, full-automatic and parallelized processing is required, and manual intervention without time is required to complete such huge work.
Disclosure of Invention
The technical problem solved by the invention is as follows: the utility model provides a distribution intensification graph model maintenance system and a maintenance method thereof, which are used for solving the problems in the prior art.
The technical scheme adopted by the invention is as follows: the utility model provides a join in marriage and transfer intensive drawing die maintenance system, including GIS system and join in marriage and transfer intensive system, GIS system will join in marriage the drawing die transmission of net single line drawing to join in marriage and transfer intensive system, join in marriage and transfer intensive system and be provided with concurrent processing module, full-automatic leading-in module and the manual intervention module before finally leading-in, concurrent processing module is used for handling a plurality of drawing die maintenance requests of same period, full-automatic leading-in module is used for the automatic drawing die of carrying on of procedure to import, manual intervention module is used for by manual verification when finally leading-in actual model.
And the dispatching intensification system adopts PCS-9000.
A maintenance method for a distribution intensive graph model maintenance system comprises the following steps: the GIS system transmits a graphic model (SVG file and CIM) of a distribution network single line diagram to a distribution and dispatching intensification system, the distribution and dispatching intensification system performs concurrent processing through a concurrent processing module, performs full-automatic trial leading-in work through a full-automatic leading-in module, and is subjected to manual intervention of a manual intervention module before final leading-in, and a manual approving party can be formally led in, and if the user is not approved, the user is not led in.
A maintenance method of a distribution intensive graph model maintenance system comprises the following specific steps:
1) the method comprises the steps that graphics and models imported by the GIS are accurate and reach designated folders in a region in batches, original folders of the graphics and models are stored in the region, all subfolders are copied to a folder A, and an original directory structure is maintained;
2) the method comprises the following steps that a red library is imported into a folder A in an automatic flow mode, pictures are imported, a record list is formed, an alarm is given if various import problems occur in the import process, the red library is automatically imported if no problems exist, and all imported pictures form the record list;
3) after the importing operation, various checking operations are carried out, including OID consistency checking, null point breakpoint checking, null hanging equipment checking, GIS system ID and other system ID consistency checking and duplicate name checking;
4) the dispatcher can log in the tool to check all the abnormal red and black images, if manual intervention is needed, the images are configured in the configuration file, and when the dispatcher logs in the tool to check all the images which are imported before, the newly imported images are compared with the images in the original system;
5) when a certain transaction is processed on site and a red graph is required to be converted into a black graph in scheduling, picking out a feeder line set with a consistent graph from a record list; the manual intervention is about to end, and the subsequent operation continues to enter an automatic flow;
6) copying the feeders from the original folder to folder B; reassigning one copy from the original folder for folder B;
7) deleting all the folders screened by the dispatcher and the programs in the original folders in the step (4);
8) automatically importing dat2 in the folder B according to the original flow;
9) dat2 drags the library to red.
When the graph model files of the plurality of feeder graphs enter the intensive dispatching system, the intensive dispatching system conducts parallel import operation on the graphs and the models without the association relation.
The operation steps of the full-automatic import module are as follows: before starting the import process, firstly, drag the dat3 to the dat2, import the new model into dat2, and mark the red map on dat2, put the image OID and the model checking tool on the red-black map after the dat2 import, and show the result on the red-black map.
If the artificial intervention prognosis and the artificial recognition difference exist, continuously introducing the scadad logical library and verifying, if the scadad verification fails, dragging the library through dat3 to recover dat2 and recover the scadad logical library, and if the scadad verification succeeds, backing up dat2 to dat 3; if the difference displayed by the red-black image is not recognized artificially, the database is dragged by the dat3 to recover the dat2, and the flow is skipped, and the subsequent links are stopped.
The invention has the beneficial effects that: compared with the prior art, the invention has the following effects:
(1) the invention greatly saves the labor cost by concurrent processing and full-automatic introduction, and can liberate the labor to do more complex monitoring work;
(2) compared with other introduction processes, the method is simple and concise, has clear conditioning and is easy to implement, and meanwhile, the complex problems are decomposed and integrated;
(3) based on the maintenance process of the distribution intensive graph model, which is an important link of paperless office, the distribution intensive system seamlessly guides a distribution network single line graph and a model generated by a GIS (geographic information system) into the distribution intensive system, and the usability and authority of the graph and the model are ensured through manual auditing operation;
(4) the distribution intensification graph-model maintenance process can select two control modes of 'semi-closed loop' and 'full-closed loop': the 'semi-closed loop' means that each step of operation is manually confirmed to be carried out for the next step, and the 'full-closed loop' means that all links except the final auditing link which needs to be reserved do not need manual intervention;
(5) after the import is finished, the distribution and intensification graph-model maintenance flow can show all the routes with import success and import failure and show the failure reasons.
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Fig. 1 is a schematic structural view of the present invention.
Detailed Description
The invention is further described below with reference to specific examples.
Example 1: the utility model provides a join in marriage and transfer intensive drawing die maintenance system, including GIS system and join in marriage and transfer intensive system, GIS system will join in marriage the drawing die transmission of net single line drawing to join in marriage and transfer intensive system, join in marriage and transfer intensive system and be provided with concurrent processing module, full-automatic leading-in module and the manual intervention module before finally leading-in, concurrent processing module is used for handling a plurality of drawing die maintenance requests of same period, full-automatic leading-in module is used for the automatic drawing die of carrying on of procedure to import, manual intervention module is used for by manual verification when finally leading-in actual model.
And the dispatching intensification system adopts PCS-9000.
Preferably, when the graph model files of a plurality of feeder graphs enter the distribution intensification system, the distribution intensification system carries out parallel import operation on the graphs and the models without the association relationship for processing as soon as possible.
Preferably, all of the following operations are performed fully automatically. Before starting the import process, in order to ensure that dat2 is consistent with the dat3 application library, firstly dragging dat3 to dat2, importing a new model into dat2, marking a red graph on dat2, placing the image OID and the model verification tool on the dat2 import, and displaying the result on the red-black graph.
Preferably, if the prognosis is manually performed and the difference is manually accepted, continuously introducing the scadad logical library and verifying, if the scadad verification fails, dragging the library through dat3 to recover dat2 and recover the scadad logical library, and if the scadad verification succeeds, backing up dat2 to dat 3; if the difference displayed by the red-black image is not recognized artificially, the database is dragged by the dat3 to recover the dat2, and the flow is skipped, and the subsequent links are stopped.
A maintenance method of a distribution intensive graph model maintenance system comprises the following specific implementation steps:
1) all subfolders are copied from the original folder, which stores the map model in a region, to folder a. The prerequisite for this operation is that the graphics, models imported by the GIS have been correct, and that they reach a designated folder in one area in bulk, the original folder referred to above. At this time, in order that the subsequent adding, deleting and modifying operations for each graph model sub-folder do not affect the original content, an original folder needs to be copied into the folder A, and the original directory structure is kept for the subsequent operations;
2) and importing a red library (with the same mode as dat) in the folder A in an automatic process mode, importing a picture and forming a record list. The operation is automatic, if various import problems occur, an alarm is given, and if no problem exists, the red library is imported in a full-automatic mode. Simultaneously forming all the imported pictures into a recording list so as to be well documented during subsequent manual intervention;
3) and checking the consistency of the image OID and the like. After the importing operation, various checking operations are carried out, including but not limited to OID consistency checking, null point breakpoint checking, null hanging equipment checking, GIS system ID and other system ID consistency checking and duplicate name checking;
4) the dispatcher can log into the tool to view the red and black plots of all transactions. At this time, if manual intervention is needed, the configuration can be performed in a configuration file, and when a dispatcher login tool can check all the graphs which are imported before, and the newly imported graphs and the graphs in the original system are compared;
5) and when the scheduling needs to change the red graph into the black graph after a certain transaction is processed on site, picking out the feeder line set with the consistent graph from the record list. At the moment, the manual intervention is about to be finished, and the subsequent operation continues to enter an automatic flow;
6) the program copies these feeds from the original folder to folder B. Because the lines picked out by manual intervention are not necessarily all the graphs and models in the previous folder A, a copy needs to be redistributed from the original folder for the folder B to use;
7) according to a fourth step all folders (containing both confirmed and rejected) screened by the dispatcher and the program in the original folder are deleted. The purpose of this step is to only introduce the circuit approved by manual intervention;
8) in folder B, automatically importing files according to the original flow (dat 2/3- > dscada). The step is still automatic import, and if errors exist in each imported sub-process, the error content can be displayed in the form of logs and alarms;
9) dat2 drags the library to red for the next round of dispatcher operation. This operation is introduced for the next round of flow.
Practical test example of practical process: suppose 10 feeder graphs come from the GIS system into the original folder between 0 and 12 points on a certain day:
1) copying the 10 sub-folders into a folder A from an original folder for storing the graph model in one area, and keeping the original directory structure;
2) and sequentially importing red libraries (with the same pattern as dat) into the folder A in an automatic flow mode, importing pictures and forming a record list. At that time, there are 10 new feeder graphs in the red library, and the 10 new feeders are also shown in the record list;
3) at this time, the 11 th feeder line enters the original folder;
4) automatically checking the 11 th feeder line into a folder A and automatically importing the feeder line;
5) and calling various checks such as picture OID consistency check and the like after each lead-in. If the verification does not pass the direct rejection, if the verification passes the reservation of the feeder line;
6) the dispatcher at3 pm checks the red and black plots of all the exceptions with the log-in tool. At this time, the dispatcher can check the transaction condition of the 11 feeders;
7) the dispatcher checks, and if some feeders (for example, feeders 4 and 5) are obviously abnormal and have errors, the feeders are marked in the list, and at the moment, two feeders (4 and 5) of 11 feeders are already selected and are considered to have errors;
8) after the field construction at night is completed, a dispatcher receives an instruction, the feeder lines 7 and 8 can transmit power, and the graphics and the models which are subjected to transaction are required to be led into an actual system and converted into the actual models for dispatching;
9) the program automatically copies these feeders 7, 8 from the original folder to folder B. While the feeder lines 4, 5 are deleted in the original folder. Only 1, 2, 3, 6, 9, 10 and 11 feeder lines exist in the original folder;
10) in folder B, automatically importing files according to the original flow (dat 2/3- > dscada). The step is still automatic import, and if errors exist in each imported sub-process, the error content can be displayed in the form of logs and alarms;
11) dat2 drags the library to the red library for the next import.
The above description is only an example of the specific embodiments of the present invention, and the scope of the present invention is not limited thereto. Those skilled in the art can easily find out the modifications or alterations within the technical scope of the present disclosure, which should be covered by the protection scope of the present disclosure. For this reason, the protection scope of the present invention shall be subject to the protection scope of the appended claims.
Claims (5)
1. A maintenance method of a distribution intensive graph model maintenance system is characterized in that: the distribution network single line diagram management system comprises a GIS system and a distribution and dispatching intensive system, wherein the GIS system transmits a diagram model of a distribution network single line diagram to the distribution and dispatching intensive system, the distribution and dispatching intensive system is provided with a concurrency processing module, a full-automatic import module and a manual intervention module before final import, the concurrency processing module is used for processing a plurality of diagram model maintenance requests in the same time interval, the full-automatic import module is used for automatically importing the diagram model by a program, and the manual intervention module is used for manually auditing when an actual model is finally imported; the GIS system transmits a graph model of a distribution network single line diagram to a distribution and dispatching intensification system, the distribution and dispatching intensification system performs concurrent processing through a concurrent processing module, performs full-automatic trial import work through a full-automatic import module, and is subjected to manual intervention of a manual intervention module before final import, and a manual approving party can formally import the graph model, and does not import the graph model if the graph model is not approved; the method comprises the following specific steps:
1) the method comprises the steps that graphics and models imported by the GIS are accurate and reach designated folders in a region in batches, original folders of the graphics and models are stored in the region, all subfolders are copied to a folder A, and an original directory structure is maintained;
2) the method comprises the following steps that a red library is imported into a folder A in an automatic flow mode, pictures are imported, a record list is formed, an alarm is given if various import problems occur in the import process, the red library is automatically imported if no problems exist, and all imported pictures form the record list;
3) after the importing operation, various checking operations are carried out, including OID consistency checking, null point breakpoint checking, null hanging equipment checking, GIS system ID and other system ID consistency checking and duplicate name checking;
4) the dispatcher can log in the tool to check all the abnormal red and black images, if manual intervention is needed, the images are configured in the configuration file, and when the dispatcher logs in the tool to check all the images imported before and the newly imported images are compared with the images in the original system;
5) when a certain transaction is processed on site and a red graph is required to be converted into a black graph in scheduling, picking out a feeder line set with a consistent graph from a record list; the manual intervention is about to end, and the subsequent operation continues to enter an automatic flow;
6) copying the feeders from the original folder to folder B; redistributing a graph model from the original folder for the folder B to use;
7) deleting all folders screened by the dispatcher and the program according to the original folders in the step (4);
8) in the folder B, automatically importing dat2 in sequence according to the original flow chart model;
9) dat2 drags the library to red.
2. The maintenance method of a coordinate intensive graphic model maintenance system according to claim 1, characterized in that: and the dispatching intensification system adopts PCS-9000.
3. The maintenance method of a coordinate intensive graphic model maintenance system according to claim 1, characterized in that: when the graph model files of the plurality of feeder graphs enter the intensive dispatching system, the intensive dispatching system conducts parallel import operation on the graphs and the models without the association relation.
4. The maintenance method of a coordinate intensive graphic model maintenance system according to claim 1, characterized in that: the operation steps of the full-automatic import module are as follows: before starting the import process, firstly, drag the dat3 to the dat2, import the new model into dat2, and mark red graph on dat2, and after importing the graph model into dat2, display the verification result of the graph model on the red-black graph tool interface.
5. The maintenance method of a coordinate intensive graphic model maintenance system according to claim 1, characterized in that: if the artificial intervention prognosis and the artificial recognition difference exist, continuously introducing the scadad logical library and verifying, if the scadad verification fails, dragging the library through dat3 to recover dat2 and recover the scadad logical library, and if the scadad verification succeeds, backing up dat2 to dat 3; if the difference displayed by the red-black image is not recognized artificially, the database is dragged by the dat3 to recover the dat2, and the flow is skipped, and the subsequent links are stopped.
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