CN114691668B

CN114691668B - Inspection data automatic processing method suitable for multidimensional measurement asset management

Info

Publication number: CN114691668B
Application number: CN202210601853.5A
Authority: CN
Inventors: 严华江; 韩鑫泽; 裘华东; 李熊; 安东; 黄沁沁; 柳圆成; 周晨晖; 陆艳; 庄琛
Original assignee: State Grid Zhejiang Electric Power Co Ltd; Marketing Service Center of State Grid Zhejiang Electric Power Co Ltd
Current assignee: State Grid Zhejiang Electric Power Co Ltd; Marketing Service Center of State Grid Zhejiang Electric Power Co Ltd
Priority date: 2022-05-30
Filing date: 2022-05-30
Publication date: 2022-08-26
Anticipated expiration: 2042-05-30
Also published as: CN114691668A

Abstract

The invention provides an inspection data automatic processing method suitable for multi-dimensional measurement asset management, which comprises the following steps: acquiring a path to be inspected corresponding to the attribute dimension of the target equipment in a database to be inspected, and determining first equipment information and second equipment information in the path to be inspected; acquiring a verification main body and at least one verification time in a verification path; extracting inspection information corresponding to the finished inspection nodes in the path to be inspected, and extracting inspection time of the inspection nodes if the inspection information corresponds to the verification requirements of the verification subject; if the inspection time is within the corresponding verification time, acquiring the number of the finished inspection nodes to obtain the finished number, and if the finished number is the same as the number of the verification nodes in the verification path, outputting first inspection reminding information; and if the inspection information does not correspond to the verification subject, outputting second inspection reminding information, and if the inspection time does not belong to the corresponding verification time, outputting third inspection reminding information.

Description

Inspection data automatic processing method suitable for multidimensional measurement asset management

Technical Field

The invention relates to the technical field of data processing, in particular to an automatic audit data processing method suitable for multi-dimensional measurement asset management.

Background

The metering assets such as the intelligent electric meter and the low-voltage current transformer have the characteristics of large usage amount and large loss amount in a power grid system, and during the management process of the metering assets, the conditions that the metering assets are lost due to illegal operation and are not easy to manage easily occur.

After the loss of the related equipment for measuring the assets occurs, the staff can recover the lost measuring equipment and install the new measuring equipment to the target user, but in the process, due to the operation problems of the staff, the situations that the installation time is dragged, the recovered measuring equipment and the installed measuring equipment cannot be effectively controlled occur, and the reason for the problems is that the measuring equipment is not subjected to standardized management.

In order to guarantee the standardized management of the metering assets, the metering assets need to be audited, and corresponding rectification is performed when the audit has problems, so that an automatic audit data processing scheme is urgently needed.

Disclosure of Invention

The embodiment of the invention provides an automatic inspection data processing method suitable for multi-dimensional measurement asset management, which can be used for carrying out standardized management on measurement assets, adopting different inspection strategies on the measurement assets with multiple dimensions, carrying out dynamic and routing automatic monitoring on corresponding installation time and installation main bodies of the measurement assets, and timely reminding correction when problems occur.

In a first aspect of the embodiments of the present invention, an automatic audit data processing method applicable to multidimensional measurement asset management is provided, including:

acquiring a path to be inspected corresponding to the attribute dimension of the target equipment in a database to be inspected, and determining first equipment information of the replaced first metering equipment and second equipment information of newly added second metering equipment in the path to be inspected;

generating a verification path according to the target equipment attribute, the first metering equipment and the second metering equipment, wherein the verification path corresponds to a node of the path to be checked, and acquiring a verification main body and at least one verification time in the verification path;

extracting inspection information corresponding to the finished inspection nodes in the path to be inspected, and extracting inspection time of the inspection nodes if the inspection information corresponds to the verification body;

if the inspection time is within the corresponding verification time, acquiring the number of the finished inspection nodes to obtain the finished number, and if the finished number is the same as the number of the verification nodes in the verification path, outputting first inspection reminding information and deleting the path to be inspected from the database to be inspected;

and if the inspection information does not correspond to the verification main body, outputting second inspection reminding information, and if the inspection time does not belong to the corresponding verification time, outputting third inspection reminding information.

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

if the number of the finished nodes is different from the number of the verification nodes in the verification path, acquiring an additional label of the path to be checked, and modifying the checking frequency information of the additional label;

and performing ascending sorting according to the checking frequency information of each path to be checked in the database to be checked to obtain a path sorting result.

Optionally, in a possible implementation manner of the first aspect, the generating the path to be audited includes:

the target equipment attribute comprises equipment dimension types and replacement user information, an inspection initial path corresponding to the equipment dimension types is obtained, and the replacement user information is added to the inspection initial path;

acquiring a first inspection node of the inspection initial path, wherein the first inspection node stores initial first time information;

and creating a second inspection node, a third inspection node and a fourth inspection node which are sequentially connected in the inspection initial path, receiving information filled in the second inspection node, the third inspection node and the fourth inspection node by ex-warehouse acquisition equipment, installation acquisition equipment and in-warehouse acquisition equipment in real time, and generating a path to be inspected.

Optionally, in a possible implementation manner of the first aspect, the receiving, in real time, information that the outbound collection device, the installed collection device, and the inbound collection device fill the second inspection node, the third inspection node, and the fourth inspection node, and generating a path to be inspected includes:

if the second equipment information of the second metering equipment is acquired based on the ex-warehouse acquisition equipment, acquiring a second inspection node of the initial path, and storing the ex-warehouse team label, the second equipment information and the second acquisition time to the second inspection node;

if the installation acquisition equipment is judged to acquire the second equipment information of the second metering equipment and the first equipment information of the first metering equipment, acquiring a third inspection node of the initial path, and storing the installation user tag, the second equipment information, the first equipment information and third acquisition time to the third inspection node;

and if the judgment is made that the first equipment information of the first metering equipment is acquired based on the warehousing acquisition equipment, acquiring a fourth inspection node of the initial path, and storing the warehousing team label, the first equipment information and the fourth acquisition time to the fourth inspection node.

Optionally, in a possible implementation manner of the first aspect, the generating a verification path according to the target device attribute, the first metering device, and the second metering device includes:

acquiring a verification initial path corresponding to the equipment dimension type, and adding replacement user information to the verification initial path;

acquiring a first verification node of the verification initial path, and storing initial first time information in the first verification node;

a second verification node, a third verification node and a fourth verification node which are connected in sequence are established in the verification initial path;

and determining corresponding work group information according to the replacement user information, determining verification time periods of adjacent verification nodes according to the user position of the replacement user information and the group position of the work group information, and generating verification time of each verification node according to the first time information and the verification time periods.

Optionally, in a possible implementation manner of the first aspect, the determining, according to the replacement user information, corresponding work shift group information, determining, according to a user position of the replacement user information and a shift group position of the work shift group information, a verification time period of an adjacent verification node, and generating, according to the first time information and the verification time period, verification time of each verification node includes:

determining a first verification time period of a first inspection node and a second inspection node according to the equipment dimension type, and obtaining second verification time corresponding to the second inspection node based on the first time information and the first verification time period;

acquiring an administrative region where the replacement user information is located, and determining work group information corresponding to the administrative region;

obtaining a team verification main body and a user verification main body according to the working team information, respectively storing the team verification main body into a second inspection node and a fourth inspection node, and storing the user verification main body into a third inspection node;

calculating to obtain alternative route information according to the user position and the team position;

and calculating according to the replacement route information and the second verification time to obtain third verification time and fourth verification time corresponding to the third inspection node and the fourth inspection node respectively.

Optionally, in a possible implementation manner of the first aspect, the calculating according to the replacement distance information and the second verification time to obtain a third verification time and a fourth verification time respectively corresponding to the third inspection node and the fourth inspection node includes:

if the replacement route information is smaller than the reference route information, taking a preset first time value as a second verification time period and a third verification time period;

and obtaining third verification time of a third inspection node according to the second verification time and the second verification time period, and obtaining fourth verification time of a fourth inspection node according to the third verification time and the third verification time period.

if the replacement route information is larger than the reference route information, comparing the replacement route information with the reference route information to obtain a numerical offset value, and carrying out forward offset processing on the first time numerical value based on the numerical offset value to obtain a second time numerical value;

and taking the second time value as a second verification time period and a third verification time period.

receiving a third time value and/or a fourth time value actively configured by the staff for the second verification time period and/or the third verification time period;

updating the second verification time period and/or the third verification time period based on the third time value and/or the fourth time value, respectively;

performing difference comparison on the third time value and/or the fourth time value and the second time value to obtain a first comparison result and/or a second comparison result;

and updating and training the first offset weight value according to the first comparison result to obtain a second offset weight value of a second verification time period, and updating and training the second offset weight value according to the second comparison result to obtain a third offset weight value of a third verification time period.

Optionally, in a possible implementation manner of the first aspect, the updating, according to the first comparison result, the offset weight value to obtain a second offset weight value for calculating a second verification time period, and the updating, training, according to the second comparison result, the second offset weight value to obtain a third offset weight value for calculating a third verification time period includes:

if the first comparison result or the second comparison result is greater than 0, increasing and updating the first offset weight value to obtain a second offset weight value or a third offset weight value;

and if the first comparison result or the second comparison result is smaller than 0, reducing and updating the first offset weight value to obtain a second offset weight value or a third offset weight value.

Optionally, in a possible implementation manner of the first aspect, the extracting audit information corresponding to completed audit nodes in the path to be audited, and if the audit information corresponds to the verification subject, extracting audit time of the audit nodes includes:

determining nodes filled with information at the previous time in an inspection initial path as finished inspection nodes, and extracting all information in the finished inspection nodes to obtain inspection information;

the inspection information comprises any one or more of warehouse-out collection equipment, warehouse-in collection equipment, warehouse-out team labels, installation user labels and warehouse-in team labels;

and if the ex-warehouse team group label, the installation user label and the in-warehouse team group label correspond to the team verification main body and the user verification main body, extracting the inspection time of the finished inspection node.

Optionally, in a possible implementation manner of the first aspect, if the audit time falls within the corresponding verification time, obtaining a number of completed audit nodes to obtain a completed number, and if the completed number is the same as the number of verification nodes in the verification path, outputting first audit prompting information to delete the path to be audited from the database to be audited, where the method includes:

extracting second acquisition time, third acquisition time and fourth acquisition time corresponding to at least one of a second inspection node, a third inspection node and a fourth inspection node in the finished inspection nodes;

taking the second acquisition time as second inspection time, taking the third acquisition time as third inspection time and taking the fourth acquisition time as fourth inspection time;

and if the second checking time, the third checking time and the fourth checking time are respectively less than the second verification time, the third verification time and the fourth verification time, the checking time belongs to the corresponding verification time.

A second aspect of the embodiments of the present invention provides a storage medium, in which a computer program is stored, and the computer program is used for implementing the method of the first aspect and various possible designs of the first aspect of the present invention when executed by a processor.

The invention provides an automatic inspection data processing method suitable for multi-dimensional measurement asset management, which generates corresponding verification paths according to different dimensions of measurement assets, and updates nodes in the paths to be inspected in real time according to real-time operations of workers and users. Moreover, the invention can automatically update the database to be inspected, and automatically delete the database after judging that all nodes in a path to be inspected completely inspect and meet the requirements of time and subject, so that the invention can not repeatedly inspect the same path to be inspected. The invention can actively check before all the nodes of the path to be checked are finished, realizes all-round check in and after the affairs, improves the checking efficiency, and realizes the purpose of checking the illegal behavior in time at the initial stage of illegal operation. Moreover, the ex-warehouse replacement equipment and the in-warehouse replaced equipment can be automatically associated, so that the corresponding relation between each damaged equipment and the replacement equipment can be determined during the later equipment installation tracing, and the management is easy.

According to the technical scheme provided by the invention, the second equipment information or the first equipment information sent by the ex-warehouse acquisition equipment, the installation acquisition equipment and the in-warehouse acquisition equipment server can be acquired in real time, and different labels, time and equipment information are added to different nodes according to different sent main bodies, so that the invention can acquire corresponding information in real time and add the information to the path to be inspected in real time.

According to the technical scheme provided by the invention, different first verification time periods can be set according to metering equipment with different types and dimensions, and a second verification time period and a third verification time period are determined by combining the user position for replacing user information and the team position for working team information, so that when a verification path is obtained, the proper second verification time period and third verification time period can be determined according to the different user positions and the team positions of the metering equipment, the corresponding time can be reasonably determined when a team worker installs and replaces the metering equipment on the user, in order to ensure that the determined second verification time period and third verification time period are more accurate, the first offset weight value can be continuously trained according to the feedback of the worker, and a second offset weight value and a third offset weight value which are different in the second verification time period and the third verification time period are calculated, different calculation models and schemes are provided for the subsequent second verification time period and the subsequent third verification time period, so that the calculated second verification time period and the calculated third verification time period are more consistent with the current calculation scene, and proper and reasonable verification time is determined for each installation and replacement of the metering equipment.

Drawings

Fig. 1 is a schematic view of an application scenario of the technical solution provided by the present invention;

FIG. 2 is a flow diagram of a first embodiment of an automated audit data processing method suitable for multi-dimensional metered asset management;

FIG. 3 is a flow diagram of a second embodiment of an automated audit data processing method suitable for multi-dimensional metered asset management.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The terms "first," "second," "third," "fourth," and the like in the description and in the claims, as well as in the drawings, if any, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the invention described herein are capable of operation in sequences other than those illustrated or described herein.

It should be understood that, in various embodiments of the present invention, the sequence numbers of the processes do not mean the execution sequence, and the execution sequence of the processes should be determined by the functions and the internal logic of the processes, 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 application, "comprising" and "having" and any variations thereof, are intended to cover a 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 expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

It should be understood that, in the present invention, "a plurality" means two or more. "and/or" is merely an association describing an associated object, meaning that three relationships may exist, e.g., a and/or B, may mean: a exists alone, A and B exist simultaneously, and B exists alone. The character "/" generally indicates that the former and latter associated objects are in an "or" relationship. "comprises A, B and C" and "comprises A, B, C" means that all three of A, B, C comprise, "comprises A, B or C" means that one of A, B, C comprises, "comprises A, B and/or C" means that any 1 or any 2 or 3 of A, B, C comprises.

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

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

The technical solution of the present invention will be described in detail below with specific examples. The following several specific embodiments may be combined with each other, and details of the same or similar concepts or processes may not be repeated in some embodiments.

As shown in fig. 1, an application scenario schematic diagram of the technical scheme provided by the present invention includes a server, and an ex-warehouse collection device, an installation collection device, and a warehousing collection device connected to the server, where the ex-warehouse collection device and the warehousing collection device may be configured at a crew department of a power grid, where the ex-warehouse collection device and the warehousing collection device may be the same device terminal disposed at the crew department of the crew, and the installation collection device may be a device terminal at a user department. The APP that staff used can be installed to the equipment terminal of team personnel department, and the APP that the user used can be installed to the equipment terminal of user department. The server can be respectively connected with the ex-warehouse acquisition equipment, the installation acquisition equipment and the in-warehouse acquisition equipment and receives transmitted information and data, the server performs data interaction with the database to be checked, and the corresponding path to be checked in the database to be checked is called for processing and comparison.

The invention provides an automatic processing method of inspection data suitable for multi-dimensional measurement asset management, as shown in fig. 2, comprising the following steps:

step S110, obtaining a path to be audited corresponding to the attribute dimension of the target device in the database to be audited, and determining first device information of the replaced first metering device and second device information of the newly added second metering device in the path to be audited. The server can actively acquire the path to be checked, and the target equipment attribute can be an intelligent electric meter, a voltage transformer and the like. The first device information of the replaced first metering device may be understood as device information in which a damaged replacement has occurred or which is replaced at regular intervals, for example, the smart meter a. The second device information of the newly added second metering device may be understood as device information for replacing the smart meter a, such as the smart meter B.

In a possible implementation manner, the technical solution provided by the present invention generates the path to be checked by the following steps, including:

the target equipment attribute comprises equipment dimension types and replacement user information, an inspection initial path corresponding to the equipment dimension types is obtained, and the replacement user information is added to the inspection initial path. In an actual scenario, before a path to be checked is obtained, the input target device attributes are obtained, where the target device attributes at this time at least include a device dimension type, replacement user information, and a target device number, and different target devices have different numbers. For example, if the smart meter a in the home of the user R fails or is damaged, the replacement user information at this time is the user R, the number of the smart meter a may be 102354, and the device dimension category includes the type to which the device belongs, for example, the smart meter dimension, and the like. Different device dimensional categories will have corresponding, different audit initial paths. It can be understood that, for example, the device dimension type is an intelligent electric meter, the intelligent electric meter needs to be installed at a user home, and the initial path for inspection at this time is set with corresponding nodes according to the user home. For example, the device dimension type is a voltage transformer, the voltage transformer needs to be installed at a substation, and the inspection initial path at this time is set with corresponding nodes according to the substation. There may be different initial paths for auditing for different device dimensional categories. The invention adds corresponding replacement user information to each inspection initial path, and at the moment, the inspection initial path adds corresponding replacement user information.

And acquiring a first inspection node of the inspection initial path, and storing initial first time information in the first inspection node. In a practical scenario, the first audit node of each audit initial path is the audit node when the equipment is damaged and needs to be updated, for example, the smart meter a in the home of the user R is damaged at 12/13/23: 41:29 in 2021, at this time, the first audit node is created first, and the first time information is stored in the first audit node at 12/13/23: 41:29 in 2021. The first time information may be input by a worker. The first time information may be in units of days.

And creating a second inspection node, a third inspection node and a fourth inspection node which are sequentially connected in the inspection initial path, receiving information filled in the second inspection node, the third inspection node and the fourth inspection node by ex-warehouse acquisition equipment, installation acquisition equipment and in-warehouse acquisition equipment in real time, and generating a path to be inspected. When the dimension corresponding to the inspection initial path is the intelligent electric meter, a second inspection node, a third inspection node and a fourth inspection node are established on the basis of the first inspection node, and the first inspection node, the second inspection node, the third inspection node and the fourth inspection node are connected in sequence. The invention fills the inspection node according to the information acquired by the ex-warehouse acquisition equipment, the installation acquisition equipment and the in-warehouse acquisition equipment to obtain the corresponding path to be inspected, and the path to be inspected can be regarded as being updated in real time. Different audit nodes will be populated with the collected information by different collection devices.

In a possible implementation manner, the receiving information of the outbound collection device, the installed collection device, and the inbound collection device, which is filled in the second inspection node, the third inspection node, and the fourth inspection node, in real time, and generating the path to be inspected includes:

and if the second equipment information of the second metering equipment is acquired based on the ex-warehouse acquisition equipment, acquiring a second inspection node of the initial path, and storing the ex-warehouse team label, the second equipment information and the second acquisition time to the second inspection node. At this moment, the corresponding smart meter B in the warehouse needs to be taken out of the warehouse, so that second equipment information of the second metering equipment can be collected according to the warehouse-out collection equipment, the collection mode can be actively input, the identification code of the second metering equipment can also be identified to realize automatic input, and the second equipment information can be the serial number of the smart meter B. Wherein, the number of each smart electric meter is unique. And the second collection time can be the time for identifying the second metering equipment by the warehouse-out collection equipment, and the warehouse-out operation of the intelligent electric meter B is completed by the staff of the team by default at the moment.

And if the installation acquisition equipment is judged to acquire the second equipment information of the second metering equipment and the first equipment information of the first metering equipment, acquiring a third inspection node of the initial path, and storing the installation user tag, the second equipment information, the first equipment information and third acquisition time to the third inspection node. At this time, it may be understood that a team member performs work such as removal of the first metering device, installation of the second metering device, and the like at a user, and when the team member performs installation, the team member may perform assistance operation by the user, that is, the user acquires the second device information of the second metering device and the first device information of the first metering device by the installation acquisition device, and the installation user tag may be a user R. The acquisition mode can be active entry or automatic identification of the identification code. The second device information may be a number of the smart meter B, and the first device information may be a number of the smart meter a. The third acquisition time may be a time at which the acquisition device is installed to identify the second metering device.

And if the judgment is made that the first equipment information of the first metering equipment is acquired based on the warehousing acquisition equipment, acquiring a fourth inspection node of the initial path, and storing the warehousing team label, the first equipment information and the fourth acquisition time to the fourth inspection node. At this time, the operation that the user puts the removed first metering device in storage may be understood, and the storage team label may be a team S. The third acquisition time may be a time at which the warehousing acquisition device identifies the first metering device.

Through the operation steps of the devices, the ex-warehouse and installation records of the second metering device are realized, the removal and storage records of the first metering device are realized, the corresponding time is counted, the first metering device, the second metering device, the team and the user are effectively corresponding, and the device has the advantages of being easy to view and understand.

Step S120, generating a verification path according to the target device attribute, the first metering device and the second metering device, wherein the verification path corresponds to the node of the path to be audited, and acquiring a verification subject and at least one verification time in the verification path. The verification path corresponding to the target equipment attribute is determined according to the target equipment attribute, in an actual working scene, after one first metering equipment is damaged, a corresponding second metering equipment is determined according to the storage relation of the first metering equipment in the storehouse, and the corresponding relation between the first metering equipment and the second metering equipment can be set manually, so that the verification path is generated according to the target equipment attribute, the first metering equipment and the second metering equipment which are originally possessed. The verification path at this time also has 4 verification nodes, each of which has a corresponding verification subject and verification time.

In one possible implementation manner, the technical solution provided by the present invention, in step S120 includes:

and acquiring a verification initial path corresponding to the equipment dimension type, and adding replacement user information to the verification initial path. Different device dimension types can also have different verification initial paths, and the device dimension types and the verification initial paths can be correspondingly set in advance. The invention can firstly obtain the verification initial path, and the replacement user information is the original information, so the replacement user information can be directly added to the verification initial path.

And acquiring a first verification node of the verification initial path, and storing initial first time information in the first verification node. The first time information is the time when the first metering equipment is damaged, so the invention can directly fill the first time information into the first verification node.

And creating a second verification node, a third verification node and a fourth verification node which are sequentially connected in the verification initial path. The invention sets a second verification node, a third verification node and a fourth verification node which correspond to each other, and verifies that the nodes in the initial path and the path to be checked are corresponding to each other. And each node in the path to be inspected can be correspondingly inspected and verified through the corresponding verification node after being filled with information.

And determining corresponding work group information according to the replacement user information, determining verification time periods of adjacent verification nodes according to the user position of the replacement user information and the group position of the work group information, and generating verification time of each verification node according to the first time information and the verification time periods. The invention firstly determines the corresponding work group information according to the replacement user information, and different replacement user information may correspond to different work group information. For example, replacement user R corresponds to team S. The verification time periods of the adjacent verification nodes are determined by combining the user position and the team position, so that the longer the distance between the user position and the team position is, the longer the corresponding verification time period is possibly, and the later the corresponding verification time is, and the corresponding verification time period can be reasonably determined according to the distance information.

In a possible implementation manner, the determining, according to the replacement user information, corresponding work team group information, determining verification time periods of adjacent verification nodes according to the user position of the replacement user information and the team group position of the work team group information, and generating verification time of each verification node according to the first time information and the verification time periods includes:

and determining a first verification time period of the first inspection node and the second inspection node according to the equipment dimension type, and obtaining second verification time corresponding to the second inspection node based on the first time information and the first verification time period. In an actual scenario, the first verification period is determined according to the device dimension type, and the first metering devices of different dimensions and types may have different verification periods and times and are not affected by the user location before the outbound operation and the outbound operation are performed, so that the first verification period between the first audit node and the second audit node is relatively fixed, and the first verification period may be actively set. For example, the first time information is 13 days at 12 months in 2021, and the first verification time period is 1 day, then the second verification time corresponding to the second audit node at this time is 14 days at 12 months in 2021.

And acquiring an administrative area where the replacement user information is located, and determining work group information corresponding to the administrative area. The administrative region where the user information is replaced is obtained, generally, different work groups are set in different administrative regions, and therefore the corresponding work group information is determined according to the administrative region where the user information is replaced.

And obtaining a team verification main body and a user verification main body according to the work team information, respectively storing the team verification main body into a second inspection node and a fourth inspection node, and storing the user verification main body into a third inspection node. The invention can obtain a team verification main body and a user verification main body by combining the work team information, and can understand that the team verification main body is a team which can carry out warehouse-in and warehouse-out operation on corresponding first metering equipment and second metering equipment, and the user verification main body is a user needing to dismantle the first metering equipment and install the second metering equipment, so that the second inspection node, the third inspection node and the fourth inspection node of the invention can respectively set corresponding team verification main bodies and user verification main bodies, so that only the main bodies with corresponding authorities can execute corresponding operation and receive corresponding operation.

And calculating to obtain the replacement distance information according to the user position and the team position. The invention can calculate according to the user position and the team position to obtain the corresponding replacement distance information, and can calculate according to the longitude information and the latitude information of the user position and the team position to obtain the replacement distance information.

And calculating according to the replacement route information and the second verification time to obtain third verification time and fourth verification time corresponding to the third inspection node and the fourth inspection node respectively. The invention can carry out comprehensive calculation by combining the replacement route information to obtain corresponding third verification time and fourth verification time, the route between the second inspection node and the third inspection node can be regarded as the forward route, the route between the third inspection node and the fourth inspection node can be regarded as the return route, and the forward route and the return route are generally the same and corresponding.

In a possible implementation manner, the calculating according to the replacement route information and the second verification time to obtain a third verification time and a fourth verification time respectively corresponding to the third audit node and the fourth audit node includes:

and if the replacement route information is smaller than the reference route information, taking a preset first time value as a second verification time period and a third verification time period. At this time, it is proved that the user location is closer to the group location, and at this time, the first time value may be used as the second verification time period and the third verification time period, and the first time value may be 1 day, 2 days, and so on.

And obtaining third verification time of a third inspection node according to the second verification time and the second verification time period, and obtaining fourth verification time of a fourth inspection node according to the third verification time and the third verification time period. At this time, the second verification time period, and the third verification time period may be combined to perform sequential calculation, so as to obtain a third verification time and a fourth verification time. For example, if the second verification period and the third verification period are 2 days, and the second verification period is 12, month and 14 days in 2021, the third verification period is 12, month and 16 days in 2021, and the fourth verification period is 12, month and 18 days in 2021. Through the mode, the verification time corresponding to each inspection node can be determined, and the verification paths have the corresponding verification time.

In a possible embodiment, the technical solution provided by the present invention further includes:

if the replacement route information is larger than the reference route information, comparing the replacement route information with the reference route information to obtain a numerical offset value, and carrying out forward offset processing on the first time numerical value based on the numerical offset value to obtain a second time numerical value. At this time, it is proved that the distance between the user position and the team position may be relatively long, so that the replacement route information needs to be compared with the reference route information at this time to determine a numerical offset value, and if the difference between the replacement route information and the reference route information is larger, the numerical offset value at this time may be larger, and the second time value after the forward offset processing is larger.

The second time value is calculated as a second verification period and a third verification period in a first calculation manner by the following formula,

wherein the content of the first and second substances,

the second time value calculated for the first calculation,

is the value of the first time, and is,

in order to replace the course information,

is a baseThe information of the quasi-path is obtained,

is a first offset weight value. By passing

A numerical offset value may be obtained and the first offset weight value may be set by the staff according to the actual scene, if

The larger the distance between the user position and the team position, the larger the second time value, and the second time value is obtained by the invention

A large rounding process is performed, e.g.

Is 3.1, then rounded

Namely 4.

After the second time value is obtained, the present invention directly uses the second time value as the second verification time period and the third verification time period, where the second time value may be 3 days, which is increased compared to 2 days of the first time value.

acquiring all installation task quantities of a team at the current moment to the second metering equipment, and obtaining a first installation coefficient value according to the installation task quantities;

acquiring the replacement path information corresponding to each installation task, acquiring the average replacement path information of all the installation tasks, and acquiring a second installation coefficient value according to the average replacement path information;

acquiring the number information of the groups, and obtaining a third installation coefficient value according to the number information;

performing fusion calculation according to the first mounting coefficient value, the second mounting coefficient value and the third mounting coefficient value to obtain a second time value, calculating the second time value in a second calculation mode,

wherein the content of the first and second substances,

a second time value calculated for the second calculation,

in order to install the amount of tasks,

in order to be the weight value of the task amount,

is as follows

The replacement distance information corresponding to each installation task,

in order to be an upper limit value for the installation task,

in order to be a quantitative value for the installation task,

in order to install the weight for the route,

the number of the people in the group is,

is a power constant. By passing

The coefficient value corresponding to the installation task amount can be obtained if the installation task amount

The larger the second time value, the larger the second time value. By passing

Average alternate path information for all installed tasks can be obtained if

The larger the value of the second time is, the larger the corresponding value of the second time is. If the number of people in the group is more, then

The smaller the second time value is, the smaller the second time value is. Through the technical scheme, the method and the device can comprehensively consider the relationship between the user position and the team position, and also comprehensively consider the conditions of the task amount, the number of people and the like of the team, so that the method and the device can determine the appropriate second time value according to different positions and working conditions of the team, dynamically adjust the second time value, accord with corresponding calculation scenes, and maximally guarantee the replacement efficiency of the team on the second metering equipment on the premise of meeting the load requirement of the corresponding team. The second time value calculated by the method has more dimensions, is more suitable for the current team scene, and is in different calculation modes when calculating the second time value for different teams, so that the method is more suitable for the corresponding teams.

and receiving a third time value and/or a fourth time value actively configured by the staff for the second verification time period and/or the third verification time period. In an actual working scene, due to reasons such as a team or a user, the automatically calculated second verification time period and/or third verification time period may not meet the current scene requirement, so that at this time, a worker may actively configure a corresponding third time value and/or fourth time value.

Updating the second and/or third verification time periods based on the third and/or fourth time values, respectively. And at the moment, updating the second verification time period and/or the third verification time period according to the actively configured third time value and/or fourth time value, so that the updated second verification time period and/or third verification time period meet the actual requirements of ex-warehouse installation and in-warehouse recovery.

And performing difference comparison on the third time value and/or the fourth time value and the second time value to obtain a first comparison result and/or a second comparison result. The third time value and/or the fourth time value and the second time value are subjected to difference comparison, and a corresponding first comparison result and/or a second comparison result are determined, the first comparison result and/or the second comparison result can embody a difference value between a second verification time period and/or a third verification time period which are automatically calculated and a second verification time period and/or a third verification time period which are actually required, and the larger the first comparison result and/or the second comparison result is, the larger the absolute value of the difference between the third time value and/or the fourth time value and the second time value is proved to be.

And updating and training the first offset weight value according to the first comparison result to obtain a second offset weight value for calculating a second verification time period, and updating and training the second offset weight value according to the second comparison result to obtain a third offset weight value for calculating a third verification time period. The first offset weight value is updated and trained, so that the trained second offset weight value and the trained third offset weight value are more consistent with the current calculation scene.

In a possible implementation manner, the updating the offset weight value according to the first comparison result to obtain a second offset weight value for calculating a second verification time period, and the updating and training the second offset weight value according to the second comparison result to obtain a third offset weight value for calculating a third verification time period includes:

and if the first comparison result or the second comparison result is greater than 0, increasing and updating the first offset weight value to obtain a second offset weight value or a third offset weight value. When the first comparison result or the second comparison result is greater than 0, it is proved that the first offset weight value is smaller, so that the first offset weight value needs to be increased at this time.

And if the first comparison result or the second comparison result is smaller than 0, reducing and updating the first offset weight value to obtain a second offset weight value or a third offset weight value. When the first comparison result or the second comparison result is smaller than 0, it is proved that the first offset weight value is larger at this time, so that the first offset weight value needs to be reduced at this time.

The updated trained second and third offset weight values are obtained by the following equations,

wherein, the first and the second end of the pipe are connected with each other,

is the value of the third time period,

is the value of the fourth time period,

is a second offset weight value that is a function of,

is the third offset weight value of the first offset weight value,

for the first offset-normalized value, the value,

is a secondThe normalized value is shifted. First offset normalization value

And a second offset normalization value

The method can be calculated and set by staff in advance according to actual scenes. The invention is provided with

And

the magnitude of the second offset weight value and the magnitude of the third offset weight value increased compared to the first offset weight value may be obtained, so that if the first comparison result or the second comparison result is greater than 0, the second offset weight value and the third offset weight value may be proportionally calculated according to a difference between the third time value and the second time value and a difference between the fourth time value and the second time value.

The invention is provided with

And

the magnitude of the second offset weight value and the magnitude of the third offset weight value, which are decreased compared to the first offset weight value, may be obtained, so that if the first comparison result or the second comparison result is less than 0, the second offset weight value and the third offset weight value may be proportionally calculated according to a difference between the third time value and the second time value and a difference between the fourth time value and the second time value.

Step S130, extracting the inspection information corresponding to the finished inspection nodes in the path to be inspected, and if the inspection information corresponds to the verification body, extracting the inspection time of the inspection nodes. When the path to be inspected is inspected, the inspection information corresponding to the finished inspection node is extracted, the inspection information comprises time and main bodies, such as second acquisition time information, third acquisition time information, an installation user tag, a team user tag and the like, and corresponding operation questions can be embodied by the installation user tag and the team user tag. The invention firstly judges the inspection information and the verification main body, for example, if the intelligent electric meter B needs to be installed to the user R, the installed user label is the user R, the verification main body is the user R, if the installed user label corresponds to the verification main body, the main body is proved to be correct, so the inspection time of the inspection node needs to be extracted at this time, and the time verification is carried out.

In a possible implementation manner of the technical solution provided by the present invention, step S130 includes:

and determining nodes filled with information at the previous time in the inspection initial path as finished inspection nodes, and extracting all information in the finished inspection nodes to obtain inspection information. The invention takes the node filled with information as the completed inspection node, namely the node has realized the operation. For example, a first audit node, a second audit node, a third audit node and a fourth audit node exist in the audit initial path, at this time, the third audit node is already completed, but the fourth audit node is not completed, so that the extracted nodes filled with information at this time are the first audit node, the second audit node and the third audit node.

The inspection information comprises any one or more of warehouse-out collection equipment, warehouse-in collection equipment, warehouse-out team labels, installation user labels and warehouse-in team labels. The invention takes the labels of the outbound team group, the labels of the installation users and the labels of the inbound team group as part of the inspection information.

And if the ex-warehouse team group label, the installation user label and the in-warehouse team group label correspond to the team verification main body and the user verification main body, extracting the inspection time of the finished inspection node. If the first metering device and the second metering device are corresponding to each other, the installation of the team and the installed user at the moment is proved to be corresponding to the installation of the first metering device and the second metering device, the inspection time of the inspection node needs to be checked again at the moment, and whether the corresponding inspection time meets the corresponding requirements or not is judged.

Step S140, if the inspection time is within the corresponding verification time, acquiring the number of the completed inspection nodes to obtain the completed number, and if the completed number is the same as the number of the verification nodes in the verification path, outputting first inspection reminding information and deleting the path to be inspected from the database to be inspected. The inspection time is within the corresponding verification time, the corresponding acquisition time information is less than the corresponding verification time information, for example, the inspection time is the second acquisition time information, the second acquisition time information is 13 days 12 and 12 months 2021, and the second verification time is 14 days 12 and 12 months 2021, so that the inspection time is within the corresponding verification time, and the inspection time does not exceed the corresponding verification time. Therefore, the number of the completed inspection nodes is required to be obtained, such as 4 inspection nodes (the first inspection node, the second inspection node, the third inspection node, and the fourth inspection node) in total, and the number of the verification nodes in the verification path is also 4. If the number of the finished paths is equal to the number of the verification nodes in the verification path and is 4, the verification information of all the nodes in the verification path is verified to be checked, so that the first verification prompting information can be output at the moment, namely, a worker is reminded that the corresponding path to be checked is checked to be finished, the conditions of operation violation and operation overtime are avoided, and the path to be checked is deleted from the database to be checked at the moment, so that the same path to be checked cannot be checked repeatedly.

In one possible implementation manner, the technical solution provided by the present invention, in step S140, includes:

and extracting second acquisition time, third acquisition time and fourth acquisition time corresponding to at least one of the second inspection node, the third inspection node and the fourth inspection node in the finished inspection nodes. The invention can determine the acquisition time corresponding to each inspection node, and the acquisition time can be understood as the ex-warehouse time, the installation time, the in-warehouse time and the like of corresponding equipment.

And taking at least one of the second acquisition time, the third acquisition time and the fourth acquisition time as a second inspection time, a third inspection time and a fourth inspection time. The invention will correspond each acquisition time to the audit time. It can be understood that the same time in the acquisition process is the acquisition time, and the same time in the inspection process is the inspection time.

And if the second checking time, the third checking time and the fourth checking time are respectively less than the second verification time, the third verification time and the fourth verification time, the checking time belongs to the corresponding verification time. At the moment, the installation behaviors of the team are all proved to be within the corresponding time, and the time requirement of installation is met.

Step S150, if the inspection information does not correspond to the verification subject, outputting second inspection reminding information, and if the inspection time does not belong to the corresponding verification time, outputting third inspection reminding information. When the checking information does not correspond to the verification main body, the fact that the main body of the installed team is incorrect or the main body of the installed user is incorrect is proved, so that second checking reminding information needs to be output at the moment, a higher-level manager is reminded of informing that problems possibly occur in the installation at the moment, and the metering equipment and the main body do not correspond to each other and need to be checked and checked in detail. When the inspection time does not belong to the corresponding verification time, the installation time and the disassembly time are proved to exceed the time set by the standard, so that third inspection reminding information is output at the moment. The invention can respectively verify the main body and the time in the path to be checked through the verification path, so that the invention can verify the corresponding main body and the time in a flow and standardization manner after the metering equipment at a certain position and main body is damaged, and the working personnel can accord with the corresponding flow and standard when the metering equipment is replaced and installed.

In a possible embodiment, as shown in fig. 3, the technical solution provided by the present invention further includes:

step S160, if the number of completed nodes is different from the number of verification nodes in the verification path, acquiring an additional tag of the path to be inspected, and modifying the inspection frequency information of the additional tag. At this time, part of the team members of the nodes in the path to be inspected are not performed, so that the number of the completed nodes is different from the number of the verification nodes in the verification path, and at this time, the inspection frequency information of the additional labels of the path to be inspected is modified, namely, the path to be inspected is not completely completed, but the completed inspection nodes are verified.

Step S170, sorting in ascending order according to the inspection frequency information of each path to be inspected in the database to be inspected to obtain a path sorting result. The invention can carry out ascending sequencing aiming at the checking frequency information of the paths to be checked, so that the paths to be checked with less checking frequency are positioned at the front part of the path sequencing result, and further, when a large amount of paths to be checked appear, the invention can preferentially check and verify the paths to be checked which are not checked or have less checking frequency. The efficiency of inspecting the paths to be inspected with problems is improved.

The present invention also provides a storage medium having a computer program stored therein, the computer program being executable by a processor to implement the methods provided by the various embodiments described above.

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 may 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 that the processor can read information from, and write information to, the storage medium. Of course, the storage medium may also be integral to the processor. The processor and the storage medium may reside in an Application Specific Integrated Circuits (ASIC). Additionally, the ASIC may reside in user equipment. Of course, 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 tapes, floppy disks, optical data storage devices, and the like.

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, and the execution of the execution instructions by the at least one processor causes 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 (CPU), other general-purpose processors, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), etc. 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, or in a combination of the hardware and software modules within the processor.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims

1. The automatic inspection data processing method suitable for multi-dimensional measurement asset management is characterized by comprising the following steps of:

if the inspection information does not correspond to the verification main body, outputting second inspection reminding information, and if the inspection time does not belong to the corresponding verification time, outputting third inspection reminding information;

generating a path to be checked by the following steps of:

establishing a second inspection node, a third inspection node and a fourth inspection node which are sequentially connected in the inspection initial path, receiving information filled in the second inspection node, the third inspection node and the fourth inspection node by ex-warehouse acquisition equipment, installation acquisition equipment and in-warehouse acquisition equipment in real time, and generating a path to be inspected;

the real-time receiving of the information of the outbound collection equipment, the installation collection equipment and the inbound collection equipment filling the second inspection node, the third inspection node and the fourth inspection node, and the generation of the path to be inspected include:

if the fact that the first equipment information of the first metering equipment is collected based on the warehousing collection equipment is judged, a fourth inspection node of the initial path is obtained, and warehousing team labels, the first equipment information and fourth collection time are stored in the fourth inspection node;

the generating a verification path according to the target device attribute, the first metering device and the second metering device includes:

2. The method of claim 1, further comprising:

3. The method of claim 1, wherein the audit data is automatically processed for multi-dimensional asset management,

the determining corresponding work group information according to the replacement user information, determining verification time periods of adjacent verification nodes according to the user position of the replacement user information and the group position of the work group information, and generating verification time of each verification node according to the first time information and the verification time periods comprises:

calculating to obtain alternative journey information according to the user position and the team position;

4. The method of claim 3, wherein the audit data is automatically processed for multi-dimensional asset management,

the step of calculating according to the replacement route information and the second verification time to obtain third verification time and fourth verification time respectively corresponding to the third inspection node and the fourth inspection node comprises the following steps:

5. The method of claim 4, further comprising:

6. The method of claim 5, further comprising:

7. The method of claim 6, wherein the audit data is automatically processed for multi-dimensional metrology asset management,

the updating the offset weight value according to the first comparison result to obtain a second offset weight value for calculating a second verification time period, and the updating training the second offset weight value according to the second comparison result to obtain a third offset weight value for calculating a third verification time period includes:

if the first comparison result or the second comparison result is smaller than 0, the first offset weight value is reduced and updated to obtain a second offset weight value or a third offset weight value.

8. The method of claim 3, wherein the audit data is automatically processed for multi-dimensional asset management,

the extracting of the inspection information corresponding to the completed inspection nodes in the path to be inspected, and if the inspection information corresponds to the verification body, extracting the inspection time of the inspection nodes includes:

9. The method of claim 8, wherein the audit data is automatically processed for multi-dimensional metrology asset management,

if the inspection time is within the corresponding verification time, acquiring the number of the finished inspection nodes to obtain the finished number, and if the finished number is the same as the number of the verification nodes in the verification path, outputting first inspection reminding information and deleting the path to be inspected from the database to be inspected, wherein the method comprises the following steps: