CN115099597A - Embedded flow control method of power grid incremental equipment based on physical ID - Google Patents

Abstract

The invention relates to a power grid incremental equipment embedded flow control method based on physical ID, which belongs to the technical field of physical asset incremental equipment flow control, and is characterized in that collected equipment information, business processing information of each link and the like are transmitted to an embedded flow control system through an information collection terminal through a special power grid; the authority management adopts the integration of a unified authority system, identity authentication is carried out through an interface program isc _ sm of the unified authority system and an interface program isc _ sso of the unified authentication program isc _ sso, single sign-on of the system is realized, management of service application authority is realized through controlled resource management, when a user with access authority logs in the system, all applications and functions under own functions can be browsed and used, and division of personnel responsibility and software use authority is realized.

Description

Embedded flow control method of power grid incremental equipment based on physical ID

Technical Field

The invention belongs to the technical field of process control of physical asset incremental equipment, and particularly relates to an embedded process control method of power grid incremental equipment based on physical ID.

Background

At present, the service communication of the full life cycle of incremental equipment is realized in an asset full life management system through a physical ID technology, but the full coverage of the physical ID is not realized in the actual data transfer of part of service links, so that the condition of 'gear breaking' of the physical ID in the communication of the process cannot meet the asset full life management requirement.

The prior art needs a new technical solution to solve the above problems.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: the embedded flow management and control method of the power grid incremental equipment based on the physical ID is provided, and by means of a physical ID application management and control platform, the communication and monitoring of data of each link of the incremental equipment in an asset life-cycle system are realized, the data circulation condition of each link and the operation and processing condition of each service are mastered in real time, the core service of the equipment management is monitored in an all-round and whole process, the transverse cooperation and longitudinal communication of the equipment management are enhanced, and the life-cycle management of the equipment asset is comprehensively promoted.

A power grid incremental device embedded flow management and control method based on entity ID is characterized in that: comprises the following steps which are sequentially carried out,

establishing an incremental equipment embedded flow control system based on a physical ID, inputting a project planning list into the system, and editing a standard flow for detachable materials in project materials;

step two, purchasing project materials according to the list in the step one, establishing a label in the system, generating a material object ID, and monitoring material information data;

inputting engineering construction data and acceptance data in the system, establishing an equipment transferring inventory, synchronizing the equipment inventory with PMS equipment asset lean management system data and ERP enterprise resource planning data, determining material taking-out of the incremental equipment, inputting the engineering construction data, checking and checking on site, and generating equipment transferring inventory link monitoring data;

step four, creating a production operation stage equipment ledger, creating an asset card label, and determining real object ID-based equipment link monitoring data of the incremental equipment;

and fifthly, standardizing the processes of equipment asset scrapping, waste material warehousing and waste material ex-warehouse by tracking the real object ID, and determining the monitoring data of the links of waste material warehousing and waste material ex-warehouse of the incremental equipment.

The incremental device embedded flow management and control system based on the entity ID in the first step comprises a presentation layer, a service interaction layer, a service logic layer and a persistence layer, wherein the presentation layer is used for displaying system functions and adopts an SG-UAP platform presentation frame as an operation interface; the service interaction layer adopts an RESTFUL client service architecture to provide service for the presentation layer; the business logic layer comprises a comparison experiment management logic component and an SG-UAP platform standard logic component; the persistence layer comprises an SG-UAP platform persistence component; and the data interaction of each level of the presentation layer, the service interaction layer, the service logic layer and the persistence layer adopts JDBC connection.

And in the third step, the asset lean management system data of the PMS equipment and the resource planning data of the ERP enterprise are accessed to the unified storage service of the full-service unified data center, and structured data, unstructured data and collected measurement data are uniformly stored and managed.

Through the design scheme, the invention can bring the following beneficial effects: the embedded flow management and control method of the power grid incremental device based on the physical ID is based on a physical ID application management and control platform, so that the communication and monitoring of data of each link of the incremental device in an asset life-cycle system are realized, the data circulation condition of each link and the operation and processing condition of each service are mastered in real time, the core service of the device management is monitored in an all-round and all-process manner, the transverse cooperation and longitudinal communication of the device management are enhanced, and the management of the equipment asset life-cycle is comprehensively promoted.

The invention has the further beneficial effects that:

the invention adopts SG-UAP platform, has flexible configuration and recombination capability of service processing, provides a standard open interface, is convenient for sharing and interaction of system information, and has good horizontal expansion capability so as to adapt to the expansion requirement of development of service scale on system performance;

the system has high safety and reliability, ensures the safe and stable operation of the system by adopting various safety mechanisms and technical means, meets the safe operation requirement of a network information system, and specifically comprises the following contents:

and (3) data security: the encryption of information packets supporting data exchange and the encryption of data transmission channels.

And (4) network security: the system safety is improved; the method adopts a reliable and effective safety means to ensure the safety of system information and information transmission, for example, the information transmitted on the network is not intercepted illegally, and the information which is modified illegally and input illegally is not admitted.

And (4) authentication security: the method has perfect security and secrecy means, and realizes the authentication, authorization and access control of the application user.

Drawings

The invention is further described with reference to the following figures and detailed description:

fig. 1 is a schematic block diagram of a process of the embedded process control method of the power grid incremental device based on the entity ID.

Fig. 2 is a schematic block diagram of the functional implementation of the embedded flow control method of the power grid incremental device based on the physical ID.

Fig. 3 is a schematic diagram of an incremental device embedded flow management and control system based on a physical ID according to the present invention.

Detailed Description

The method for managing and controlling the embedded flow of the incremental equipment of the power grid based on the physical ID comprises the steps of transmitting the managed and controlled key business information to an embedded flow management and control system through a private power grid by using an information acquisition terminal to acquire equipment information, business processing information of each link and the like; the authority management adopts the integration of a unified authority system, identity authentication is carried out through an interface program isc _ sm of the unified authority system and an interface program isc _ sso of the unified authentication program isc _ sso, single sign-on of the system is realized, management of service application authority is realized through controlled resource management, when a user with access authority logs in the system, all applications and functions under own functions can be browsed and used, and division of personnel responsibility and software use authority is realized.

As shown in fig. 2, the method comprises the following steps, and the following steps are performed in sequence:

the method comprises the following steps: and (4) planning a planning stage. And defining the service flow and the working requirements of the work such as equipment material inventory compilation and the like in the preliminary design stage of the project. When the material requirement is submitted, the specification and the business process are definitely filled aiming at the detachable materials.

Step two: and (5) material purchasing. And confirming the business processes and the working requirements of contract signing, entity ID generation, material technical parameter maintenance, warehousing and material receiving work in the material purchasing stage. The maintenance of the technical parameters of the materials needs to confirm whether the maintenance work of the supplier is finished or not when the goods are received. And (4) specific filling specifications and business processes are made for material warehousing and material receiving. Determining bidding purchase of the incremental equipment, signing a contract (generating a physical ID), inputting technical parameters of materials, acquiring receiving information, handing over materials, checking, accepting and warehousing links and monitoring data.

Step three: and (5) engineering construction. And (4) determining project construction data entry and project site acceptance and checking in the project construction stage, and generating service flows and working requirements of work such as equipment transfer and inventory, equipment inventory and synchronous PMS (permanent magnet synchronous machine). Engineering construction data entry and maintenance need to be explicitly entered into a working responsible person. Aiming at the on-site acceptance and checking of the project, an equipment transfer fund clearing book, an equipment clearing synchronous PMS (permanent magnet synchronous machine) explicit filling specification and a service flow are generated. And determining the monitoring data of the links of material receiving and delivery, engineering construction data input, on-site acceptance and checking and generating equipment transferring and inventory of the incremental equipment.

Step four: and (5) a production operation stage. And (4) defining the business flow and the working requirements of the work such as equipment ledger creation, asset card creation and the like in the production operation stage. And (4) specifically filling specifications and business processes aiming at equipment ledger creation and asset card creation. And determining the link monitoring data of the incremental equipment based on the real object ID.

Step five: and (5) retirement disposal stage. And the business flow and the working requirements of the work of equipment asset scrapping, waste material warehousing, waste material ex-warehouse and the like in the retirement treatment stage are determined. And specific filling specifications and business processes are performed according to equipment asset scrapping, waste material warehousing, waste material ex-warehouse and the like. And determining monitoring data of links of warehousing waste materials and delivering the waste materials out of the incremental equipment.

During the course of the above-mentioned steps,

by carrying out the physical ID label on the incremental equipment, the service link through monitoring is ensured, the data of each service link of the full flow of the physical ID of the incremental equipment is accessed, a data verification mechanism of each link is solidified, the real-time monitoring of the data through condition is realized, the problem data rectification prompt is provided, the data maintainability is improved, and the integrity and the accuracy of the data of each link are ensured.

By carrying out entity ID labeling on the incremental equipment, the flow control of the single equipment is ensured, the entity ID is used as a core, and 12 links of planning plan, demand submission, contract signing, material fulfillment, material warehousing, material ex-warehouse, engineering construction, engineering acceptance, account book increase, engineering transfer, equipment operation and maintenance and retirement treatment are run through, so that the single full-life cycle management of the incremental equipment is realized.

Through carrying out the ID label in kind to increment equipment, guarantee whole project overall process control to the project is the dimension, realizes whole project overall process on-line monitoring, establishes project establishment, material purchase, arrives each link data such as goods acceptance, engineering construction, acceptance check, engineering commentaries on classics material to the project of project and carries out the analysis, promotes the real-time ability of controlling of project execution conditions.

The functions which can be realized by adopting the embedded flow management and control method of the power grid incremental equipment based on the entity ID are shown in figure 2,

1. and (3) comprehensive display: according to the asset life-cycle management theory, the overall run-through condition display of the incremental equipment in the asset life-cycle is realized.

(1) And (3) comprehensively displaying equipment assets: the method realizes the cumulative penetration condition of incremental equipment, the penetration condition of items, the penetration condition of real object ID, the penetration condition of each basic unit and the like in the last three years.

(2) And (3) equipment monomer through display: the method takes the physical ID as a core, and realizes the run-through condition of the physical ID single equipment in the whole life cycle of the asset through 12 links of planning plan, demand reporting, contract signing, material fulfillment, material warehousing, material ex-warehouse, test report, project acceptance, machine account newly-increased, project material transfer, equipment operation and maintenance and decommissioning treatment.

(3) Incremental device pass-through case: the method realizes the integral through condition display of the incremental equipment in each link of planning, requirement submission, contract signing, material fulfillment, material warehousing, material ex-warehousing, test report, project acceptance check, account newly-increased, project transfer, equipment operation and maintenance, retirement treatment and the like.

(4) And (3) unit equipment through display: and realizing the business data processing condition display of each unit or basic unit and running through each link in the incremental equipment.

2. Incremental cut-through: according to each link of the asset life, the continuity condition detail of the incremental equipment in each link is realized.

(1) Incremental shoot-through case: and the through condition statistics of the incremental equipment in all links of the asset life is realized.

(2) Incremental through detail: and the business data processing information detail of the incremental equipment in each link of the asset life is realized.

(3) Reporting an increment problem: and a problem reporting function is provided for the problems of the incremental equipment in the link-through service.

(4) And (4) auditing the increment problem: and performing online auditing treatment on the increment through problem reported by each unit.

3. Incremental cut-through monitoring: and accessing data of each link of the full process of the physical ID, monitoring the data maintenance condition according to different services of each stage, checking the integrity and the accuracy of the data, and reminding problems in each link.

(1) Contract management object ID generation: and (4) generating a real object ID condition according to the material list details when each unit creates the purchase order.

(2) Maintenance of technical parameters of materials: and maintaining the technical parameter information of each unit material corresponding to the real object ID by the supplier.

(3) Acquiring receiving information: and the material information condition of each unit project is acquired according to the real object ID.

(4) Material handover and acceptance inspection: and carrying out material transfer and material acceptance on site of each unit project.

(5) Material taking and delivery: and (4) on-site material taking and ex-warehouse conditions of each unit project.

(6) Entering engineering construction data: and (4) reporting data entry conditions of field experiments of all units in the engineering construction stage.

(7) Checking and checking on site: and checking the condition of each unit on the project site in the project acceptance stage.

(8) Generating an equipment transferring inventory: and (4) checking and accepting the equipment fund transfer and inventory condition generated by each unit after checking and counting on site.

(9) Creating equipment based on the entity ID: and each unit details the equipment ledger condition created in the PMS according to the project fund transfer list.

(10) Warehousing waste materials: and (4) warehousing condition of each unit after the equipment is scrapped.

(11) Discharging waste materials from a warehouse: and (4) recycling the waste equipment of each unit for ex-warehouse.

4. And (4) project whole-course management and control: the project is used as a dimension, the whole process monitoring of project establishment, material purchasing, goods arrival acceptance inspection, engineering construction, acceptance check and engineering transfer of the whole project is realized, and the detailed data of each link of the project is recorded while the progress monitoring of the whole project is realized.

(1) Item basic information: the basic information of all items is detailed.

(2) Equipment material inventory detail: and (4) detailed information of all material materials in a specific project is recorded.

(3) And (3) purchasing an order: all purchase order detail information under a specific project.

(4) Maintaining technical parameters of materials: and maintaining all material technical parameters under specific projects.

(5) Handing over, accepting and warehousing: and (4) on-site material handover detail and acceptance detail information under the specific project.

(6) Material taking and delivery: and all on-site material receiving ex-warehouse detail information under specific projects.

(7) And (4) inputting an experimental report: and (4) recording detailed information of all experimental reports under specific items.

(8) Generating details of the ID of the object: and specific detailed list information generated by the object IDs under all the items.

(9) Checking and accepting on site: and checking and counting detailed information of all the projects under the specific project.

(10) Equipment transfer and inventory clearing: and transferring detailed information of all equipment under the specific items.

The specific list of functions is shown in the following table:

the incremental equipment embedded flow management and control system based on the entity ID is adopted, is completed by means of a uniform analysis service component of a full-service uniform data center analysis domain, and follows the integral technical planning of one platform, one system, multiple scenes and micro applications of the national network company. As shown in fig. 3, the system integrally adopts a B/S structure with a front end and a back end separated, the front end and the back end are both developed based on an SG-UAP development platform, the front end uses a micro application presentation framework CUBE, the back end uses a micro service architecture, and the overall structure of the system is divided into different logical hierarchies such as a presentation layer, a service interaction layer, a business logic layer, a persistence layer and the like according to functional classification, and each layer provides different services; the technical implementation conforms to industry mainstream standards and protocols such as J2EE, WebService, XML, SNMP, HTTP, TCP/IP, JSON and the like.

The presentation layer is responsible for realizing the presentation of the functions of the comparison experiment management system, and provides a uniform, standard and friendly operation interface for a user on the basis of a SG-UAP platform micro application presentation framework (CUBE).

And the service interaction layer is based on the SG-UAP platform, adopts a micro-service architecture and provides RESTful-style service for the presentation layer.

The service logic layer meets the requirement of the national network information technology architecture, and the short message platform related service logic is realized by taking JAVA as a main development language in an SG-UAP platform micro-service framework.

The data interaction adopts JDBC connection, JDBC (Java DataBase Connectivity) is a Java API for executing SQL statements, can provide uniform access for various relational databases, and consists of a group of classes and interfaces written by Java language. JDBC provides a benchmark by which more advanced tools and interfaces can be built to enable database developers to write database applications.

The standard method of establishing a connection to a database is to call the drivermanager getconnection method. The method accepts a string containing a URL. The DriverManager class (the so-called JDBC management layer) will try to find drivers that can connect to the database represented by that URL.

The data source of the incremental device embedded process management and control system based on the entity ID is PMS, ERP and other business system data, the PMS, ERP and other business system data are accessed to the unified storage service of the full-business unified data center, and structured data, unstructured data and collected and measured data are stored and managed in a unified mode.

And then, data conversion, data calculation and analysis and data mining are carried out on the service data through a data analysis component of the full-service unified data center.

The method takes the entity ID as an information index, and by means of technologies of Internet of things such as intelligent sensing, graph recognition, RFID and the like, entity ID information is embedded into each business link of the whole life of the asset, so that embedded flow management and control of incremental equipment are realized, the business and operation flows of each link of the whole life of the asset are further standardized from the aspects of standardizing the business flow, promoting department cooperation, guaranteeing data sharing, monitoring management and control in real time and the like, problems are timely found and timely rectified by monitoring the data communication condition, the working efficiency is effectively improved, and the enterprise operation cost is reduced.

Claims (3)

1. A power grid incremental device embedded flow management and control method based on entity ID is characterized in that: comprises the following steps which are sequentially carried out,

establishing an incremental equipment embedded flow control system based on a physical ID, inputting a project planning list into the system, and editing a standard flow for detachable materials in project materials;

step two, purchasing project materials according to the list in the step one, establishing a label in the system, generating a material object ID, and monitoring material information data;

inputting engineering construction data and acceptance data in the system, establishing an equipment transferring inventory, synchronizing the equipment inventory with PMS equipment asset lean management system data and ERP enterprise resource planning data, determining the link monitoring data of material receiving and delivery, engineering construction data input, on-site acceptance checking and inventory and generating equipment transferring inventory of incremental equipment;

step four, creating a production operation stage equipment ledger, creating an asset card label, and determining real object ID-based equipment link monitoring data of the incremental equipment;

and fifthly, standardizing the processes of equipment asset scrapping, waste material warehousing and waste material ex-warehouse by tracking the real object ID, and determining the monitoring data of the links of waste material warehousing and waste material ex-warehouse of the incremental equipment.

2. The physical ID-based embedded flow control method for the power grid incremental device according to claim 1, wherein the method comprises the following steps: the incremental device embedded flow management and control system based on the entity ID in the first step comprises a presentation layer, a service interaction layer, a service logic layer and a persistence layer, wherein the presentation layer is used for displaying system functions and adopts an SG-UAP platform presentation frame as an operation interface; the service interaction layer adopts an RESTFUL client service architecture to provide service for the presentation layer; the business logic layer comprises a comparison experiment management logic component and an SG-UAP platform standard logic component; the persistence layer comprises an SG-UAP platform persistence component; and the data interaction of each level of the presentation layer, the service interaction layer, the service logic layer and the persistence layer adopts JDBC connection.

3. The physical ID-based embedded flow control method for the power grid incremental device according to claim 1, wherein the method comprises the following steps: and in the third step, the asset lean management system data of the PMS equipment and the resource planning data of the ERP enterprise are accessed to the unified storage service of the full-service unified data center, and structured data, unstructured data and collected measurement data are uniformly stored and managed.

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