CN111680962A - Comparison experiment management method for live-line detector - Google Patents

Abstract

The invention discloses a comparison experiment management method for a live-line detector, which belongs to the technical field of live-line detection and realizes the functions of incoming goods acceptance check, periodic inspection, instrument check registration, receiving and issuing of the check instrument, experiment information recording and the like of the live-line detector by utilizing a real object ID (identity) code and a mobile interconnection technology. And comparison experiment management of instrument and meter equipment based on the real object ID is realized. And the entity ID is used as a link, so that information communication in the whole process of experimental management of instrument and meter equipment is realized, the equipment management efficiency is improved, and the equipment management lean level is improved.

Description

Comparison experiment management method for live-line detector

Technical Field

The invention relates to the technical field of live detection, in particular to a comparison experiment management method for a live detection instrument.

Background

With the comprehensive development of the charged detection work, the types and the number of charged detection instruments also increase year by year, the current traditional inspection mode mainly relying on manpower cannot meet the requirements of network access detection and periodic comparison of the charged detection instruments, the current situation restricts the working efficiency of operators, and the management work of the charged detection instruments is also limited.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provide a comparison experiment management method for a charged detector.

In order to achieve the purpose, the invention adopts the following scheme: a comparison experiment management method for a charged detector is characterized by comprising the following steps:

generating a real object ID code of a charged detection instrument, and installing a label containing the real object ID code on the corresponding charged detection instrument;

step two, inspection of the arrived goods

Scanning a real object ID code of a detection-sending electrified detection instrument, receiving the electrified detection instrument and inputting the corresponding real object ID code into a power grid material real object ID application control platform system;

automatically distributing laboratories by applying a control platform system according to the received electrified detection instrument type power grid material entity ID;

thirdly, carrying out a comparison experiment;

fourthly, carrying out experiment record registration in the power grid material entity ID application control platform system;

checking the experiment records, entering the step (c) after the examination, and returning to the step (c) after the examination is not passed;

sixthly, generating an experimental report by using the ID of the power grid material object by using a control platform system;

seventhly, judging whether the experimental report is qualified or not, informing a sending unit to take a charged detection instrument, and carrying out the step (b); if the quality is not qualified, informing a checking unit to maintain or replace the charged detection instrument, and re-checking the charged detection instrument;

applying a power grid material object ID to a control platform to carry out the release and registration of a to-be-inspected electrified detection instrument;

step three, regular inspection

Scanning a real object ID code of a charged detection instrument, and performing censorship registration of the charged detection instrument in a power grid material real object ID application control platform;

scanning a real object ID code of the electrified detection instrument, and receiving the scanned real object ID code by the electrified detection instrument in a power grid material real object ID application control platform;

automatically distributing laboratories by applying a control platform according to the ID of the physical objects of the materials of the power grid receiving the type of the electrified detection instrument;

fourthly, carrying out comparison experiments;

carrying out experiment record registration in a power grid material entity ID application control platform;

checking the test record, entering the step (c) after the test is passed, and returning to the step (c) after the test is not passed;

seventhly, generating an experimental report by using the ID application control platform of the power grid material object;

judging whether the experimental report is qualified or not, informing a sending unit to take the charged detection instrument, and carrying out the step ninthly; if not, informing the unit to contact maintenance and going to the step (R);

ninthly, the physical ID of the materials of the power grid applies the management and control platform to carry out the issuing and registration of the inspection live-line detection instrument;

and (c) judging whether the maintained electrified detection instrument is qualified or not at the capacitor (r), returning to the step (i) if the instrument is qualified, and stopping the instrument and registering the instrument in the power grid material object ID application control platform if the instrument is not qualified.

And the real object ID code is a unique lifelong ID code of the power grid asset corresponding to the electrified detection instrument.

Through the design scheme, the invention can bring the following beneficial effects: the method utilizes the real object ID coding and the mobile interconnection technology to realize the functions of the charged detection instrument such as arrival acceptance, periodic inspection, instrument check registration, instrument receiving, instrument issuing, experiment information recording and the like. And comparison experiment management of instrument and meter equipment based on the real object ID is realized. And the ID code of the real object is used as a link, so that the information communication of the whole experimental management process of the instrument and meter equipment is realized, the equipment management efficiency is improved, and the lean level of the equipment management is improved.

Drawings

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

fig. 1 is a flowchart of a comparison experiment management method of a charged detection instrument according to the present invention.

Fig. 2 is a flow chart of the inspection of the incoming product in the comparison experiment management method of the charged detection instrument provided by the invention.

Fig. 3 is a flowchart of a periodic inspection in a comparison experiment management method of a charged detection instrument according to the present invention.

Detailed Description

In order to more clearly illustrate the invention, the invention is further illustrated below with reference to specific examples, which will be understood by those skilled in the art; the following detailed description is illustrative and not restrictive, and is not to be construed as limiting the scope of the invention, which is defined by the appended claims.

As shown in fig. 1, fig. 2 and fig. 3, the present invention provides a comparison experiment management method for a live line detector, which is characterized in that the method includes the following steps:

generating a real object ID code of a charged detection instrument, and installing a label containing the real object ID code on the corresponding charged detection instrument;

the physical ID code is a unique lifelong ID code of the power grid asset physical corresponding to the electrified detection instrument;

step two, inspection of the arrived goods

Scanning a real object ID code of a detection-sending electrified detection instrument, receiving the electrified detection instrument and inputting the corresponding real object ID code into a power grid material real object ID application control platform system;

automatically distributing laboratories by applying a control platform system according to the received electrified detection instrument type power grid material entity ID;

thirdly, carrying out a comparison experiment;

fourthly, carrying out experiment record registration in the power grid material entity ID application control platform system;

checking the experiment records, entering the step (c) after the examination, and returning to the step (c) after the examination is not passed;

sixthly, generating an experimental report by using the ID of the power grid material object by using a control platform system;

seventhly, judging whether the experimental report is qualified or not, informing a sending unit to take a charged detection instrument, and carrying out the step (b); if the quality is not qualified, informing a checking unit to maintain or replace the charged detection instrument, and re-checking the charged detection instrument;

applying a power grid material object ID to a control platform to carry out the release and registration of a to-be-inspected electrified detection instrument;

step three, regular inspection

Scanning a real object ID code of a charged detection instrument, and performing censorship registration of the charged detection instrument in a power grid material real object ID application control platform;

scanning a real object ID code of the electrified detection instrument, and receiving the scanned real object ID code by the electrified detection instrument in a power grid material real object ID application control platform;

automatically distributing laboratories by applying a control platform according to the ID of the physical objects of the materials of the power grid receiving the type of the electrified detection instrument;

fourthly, carrying out comparison experiments;

carrying out experiment record registration in a power grid material entity ID application control platform;

checking the test record, entering the step (c) after the test is passed, and returning to the step (c) after the test is not passed;

seventhly, generating an experimental report by using the ID application control platform of the power grid material object;

judging whether the experimental report is qualified or not, informing a sending unit to take the charged detection instrument, and carrying out the step ninthly; if not, informing the unit to contact maintenance and going to the step (R);

ninthly, the physical ID of the materials of the power grid applies the management and control platform to carry out the issuing and registration of the inspection live-line detection instrument;

and (c) judging whether the maintained electrified detection instrument is qualified or not at the capacitor (r), returning to the step (i) if the instrument is qualified, and stopping the instrument and registering the instrument in the power grid material object ID application control platform if the instrument is not qualified.

The standards and specifications quoted in the comparison experiment management method of the present invention are as follows:

in the process of comparison experiment management construction, the following principles are followed:

1. scalability principle

The method is designed and constructed by the idea of service platform, so that the method has flexible configuration and recombination capability of service processing; and a standard open interface is provided, so that the sharing and interaction of the system information of the power grid material physical ID application control platform are facilitated. The design of a hardware platform needs to have good horizontal expansion capability so as to meet the expansion requirement of the development of business scale on the system performance of the power grid material entity ID application control platform.

2. Principle of safety

Compared with the prior art, the system has high safety and reliability, ensures the safe and stable operation of the power grid material physical ID application control platform system by adopting various safety mechanisms and technical means, and meets the requirement of the national power grid company on the safe operation of the network and information power grid material physical ID application control platform system.

3. Principle of economy

Compared with the practical and economic performance of experimental management and construction, the method has the advantages that the existing resources are utilized as much as possible, reasonable investment is maintained on the premise of high performance, and the maximum economic benefit and social benefit are expected to be obtained on the premise of optimal cost.

4. Principle of advancement

Based on the industry universal open standard, the advanced and mature technology is adopted, so that the power grid material entity ID application control platform system can meet the existing service management requirements of the national power grid company, and simultaneously, the requirements of service requirements and development changes in a period of time in the future are met.

General technical route

The technical route adopts a method of driving layer by layer from a business architecture to an application architecture and a data architecture to a technical architecture in the overall architecture design process according to the principle of 'business driving'. The power grid material physical ID application control platform system adopts a multilayer system structure in consideration of the aspects of performance, maintainability, expansibility, portability and the like of the power grid material physical ID application control platform system, and in the multilayer system structure, application program logic can be divided into the following layers: a data layer, a logic layer, and a presentation layer.

The unified development platform is adopted for realizing the technical architecture, the componentized and dynamic software technology is adopted, a multi-layer technical system design is realized by utilizing a consistent sharable data model according to an interface control layer, a service logic layer and a data layer, through application integration, each interface component for realizing the construction service of the power grid material physical ID application control platform system can be integrated on each layer in a cooperative work manner in an enterprise, reuse is realized, different service requirements of the power grid material physical ID application control platform system are met, efficient and convenient service support is provided for each unit, an advanced working platform and flexible service construction capability are provided for internal services and managers, and the technical system design is realized according to the layers such as a display layer, the service logic layer and the data layer.

Starting from the overall business architecture and application functions, designing and dividing the data architecture of experiment management based on SG-CIM data subject domain comparison, and analyzing a primary data subject domain and a secondary data subject domain of the power grid material real object ID application control platform system.

The comparison experiment management business data relates to 7 subject domains in SG-CIM12 primary subject domains, including: the system comprises an equipment data subject field, an asset data subject field, a security data subject field, a material data subject field, a project data subject field, a financial subject field and a personnel subject field.

The design of the power grid material physical ID application control platform system adopts a design idea of a service-oriented and layered architecture componentization framework, the whole architecture of the power grid material physical ID application control platform system is divided into different logical layers such as a presentation layer, an application service layer, a logical support layer, a data storage layer, a data interface layer and a data source layer according to functional classification, and each layer provides different services; the technical implementation follows the mainstream standards and protocols in the industries such as J2EE, WebService, XML, SNMP, HTTP, TCP/IP, JSON and the like, a Web technical route (B/S) is selected, a mature development platform is adopted for implementation, and the technical architecture is shown as a table:

performance and reliability

Alignment experimental management needs to provide high performance and high stability, including:

(1) the power grid material entity ID application control platform system response time: average user response time <3 s; maximum user response time <15 s;

(2) performance and fault recovery: the power grid material object ID application control platform system requires 7 x 24 hours of stable operation; the fault recovery time (automatic) is less than or equal to 1 hour, and the fault recovery time (manual) is less than or equal to 2 hours;

(3) the ID of the power grid material object is applied to the control platform system and is concurrent: the concurrency stability requirement is 200, and the power grid material entity ID application control platform system continuously runs for 96 hours;

(4) the system stability of the power grid material entity ID application control platform is as follows: stability in supporting long-term operation; the stability of the power grid material entity ID application control platform system can be tested by high pressure for 8-12 hours;

(5) user use guarantee: when the system is used by a large-scale user, the existing user experience is not reduced, and the operation of high occupation of user host resources is not influenced in a development environment.

Information security

(1) The safety index needs to meet the information safety standard requirement of the national power grid company;

(2) and if the safety standard of the information construction of the China network company is changed in the design process of the power grid material entity ID application control platform system, executing by taking the change result as a standard reference.

Extensibility

(1) The power grid material physical ID application control platform system adopts a component design concept, a power grid material physical ID application control platform system framework is separated from service logic, the function expansion of the power grid material physical ID application control platform system can be realized on the premise of not changing the architecture, and the normal operation of the original function is not influenced;

(2) when the load of the power grid material physical ID application control platform system is increased, the dynamic expansion of hardware is supported, the software architecture of the whole power grid material physical ID application control platform system is not required to be changed, and the required service quality is ensured.

Multi-platform support

The system supports a plurality of operation platforms, the server side comprises a Windows Server2003 operation power grid material object ID application control platform system, SUSElinux, RedHatLinux5.0 and other linux operation systems, and the client side provides multi-browser support.

Ease of use

The comparison experiment management has the following characteristics:

(1) the ease of entering a power grid material entity ID application control platform system and completing basic tasks by a user;

(2) after a user proficiently uses the power grid material object ID to apply the control platform system, the time required for completing the task is short;

(3) namely, after leaving for a period of time, the user can skillfully use the hands when using the electric heating cooker again;

(4) satisfaction degree: namely, the overall satisfaction degree of the user to the power grid material entity ID application control platform system.

Detailed design of power grid material entity ID application control platform system

Description of functions

The power grid material entity ID application control platform system comprises: the home page display is divided into four parts: and comprehensively displaying and comparing the experimental conditions in a chart form, analyzing the qualified conditions of the instruments according to the quantity of each unit instrument and the type angle of the instruments, counting the instruments to be detected and carrying out early warning analysis on the instruments to be detected.

Underlying data management

Basic data

Description of functions

And basic data management realizes maintenance and management of instrument types, test projects, laboratories and other basic data.

Instrument type meter

Test type table

Instrument type and experiment type association table

Experimental project table

Management of experimental cycles

Description of functions

Setting comparison test periods aiming at different instrument types and test types, automatically forming a test detection plan of the instrument, early warning days and the like.

And associating the corresponding instrument type with the experiment type to generate an experiment plan based on the material object ID code or the instrument code.

Logic description:

a database:

experiment schedule:

instrument management

Instrument ledger management

Description of functions

Through the ID coding of the real object, the whole process monitoring of the instrument states such as the submission, the receiving and the issuing of the instrument and the information recording of the instrument handover process are realized.

Logic description:

sequence of	Logical description presentation name	Description of the logic
			1	Object ID coding	swidbm
2	Instrument coding	yqbm
			3	Name of instrument	yqmc
4	Type of instrument	yqlx
			5	City of local place	ssds
6	Operation and maintenance unit	ywdw
			7	Instrument master	yqzr
8	Asset unit	zcdw
			9	Instrument status	yqzt
10	Specification and model	ggxh
			11	Manufacturer of the product	sccj
12	Property of property	zcxz
			13	Asset coding	zcbh

Instrument submission registration

Description of functions

And (3) checking the service of the supplier instrument or regularly checking each unit instrument, checking and registering through an adding button of the power grid material object ID application control platform system, and clicking a checking button to submit to a detection unit for receiving and checking after the adding is finished. Detailed business process referring to fig. 2, a comparative experiment management arrival check business process diagram is shown.

Logic description:

sequence of	Logical description presentation name	Description of the logic
			1	Object ID coding	SWIDBM
2	Instrument coding	YQBM
			3	Name of instrument	YQMC
4	Type of instrument	YQLX
			5	Name of experiment	SYMC
6	Asset unit	ZCDW
			7	Specification and model	GGXH
8	Manufacturer of the product	SCCJ
			9	Factory number	CCBH
10	Date of submission	SJRQ
			11	Person for censorship	SJR
12	Instrument status	YQZT

A database:

submission to inspection equipment

Description of functions

After the supplier instrument is checked or the unit instruments are submitted for regular delivery, the detection unit receives the instruments and changes the instrument state into 'waiting for inspection'.

Logic description:

a database:

instrument release management

Description of functions

And after the experimental report is qualified, each unit goes to the detection unit to pick up the instrument, and the detection unit issues and registers the instrument.

Logic description:

a database:

laboratory management

List to be checked

Description of functions

And inquiring a corresponding test list to be tested based on the material object ID code or the laboratory code and the laboratory name, and clicking and inputting after the list to be tested is selected to carry out the inputting to be tested.

Description of the logic

A database:

detection record entry

Description of functions

And (3) recording detection records, realizing the fixed line of 11 template systems, and recording results through detection results, thereby realizing online generation of inspection reports, recording result audits and the like.

Detecting record queries

Description of functions

After the detection records are recorded and stored, the detection records are circulated to inquire, and the examination and verification experiment results, the examination and verification state and the like can be inquired.

Logic description:

a database:

Claims (2)

1. a comparison experiment management method for a charged detector is characterized by comprising the following steps:

generating a real object ID code of a charged detection instrument, and installing a label containing the real object ID code on the corresponding charged detection instrument;

step two, inspection of the arrived goods

Scanning a real object ID code of a detection-sending electrified detection instrument, receiving the electrified detection instrument and inputting the corresponding real object ID code into a power grid material real object ID application control platform system;

automatically distributing laboratories by applying a control platform system according to the received electrified detection instrument type power grid material entity ID;

thirdly, carrying out a comparison experiment;

fourthly, carrying out experiment record registration in the power grid material entity ID application control platform system;

checking the experiment records, entering the step (c) after the examination, and returning to the step (c) after the examination is not passed;

sixthly, generating an experimental report by using the ID of the power grid material object by using a control platform system;

seventhly, judging whether the experimental report is qualified or not, informing a sending unit to take a charged detection instrument, and carrying out the step (b); if the quality is not qualified, informing a checking unit to maintain or replace the charged detection instrument, and re-checking the charged detection instrument;

applying a power grid material object ID to a control platform to carry out the release and registration of a to-be-inspected electrified detection instrument;

step three, regular inspection

Scanning a real object ID code of a charged detection instrument, and performing censorship registration of the charged detection instrument in a power grid material real object ID application control platform;

scanning a real object ID code of the electrified detection instrument, and receiving the scanned real object ID code by the electrified detection instrument in a power grid material real object ID application control platform;

automatically distributing laboratories by applying a control platform according to the ID of the physical objects of the materials of the power grid receiving the type of the electrified detection instrument;

fourthly, carrying out comparison experiments;

carrying out experiment record registration in a power grid material entity ID application control platform;

checking the test record, entering the step (c) after the test is passed, and returning to the step (c) after the test is not passed;

seventhly, generating an experimental report by using the ID application control platform of the power grid material object;

judging whether the experimental report is qualified or not, informing a sending unit to take the charged detection instrument, and carrying out the step ninthly; if not, informing the unit to contact maintenance and going to the step (R);

ninthly, the physical ID of the materials of the power grid applies the management and control platform to carry out the issuing and registration of the inspection live-line detection instrument;

and (c) judging whether the maintained electrified detection instrument is qualified or not at the capacitor (r), returning to the step (i) if the instrument is qualified, and stopping the instrument and registering the instrument in the power grid material object ID application control platform if the instrument is not qualified.

2. The comparison experiment management method for the charged detection instrument according to claim 1, which is characterized in that: and the physical ID code is a unique lifelong ID code of the power grid asset corresponding to the electrified detection instrument.

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