CN112055069A - Electric power automation equipment testing method and system - Google Patents

Abstract

The invention provides a power automation equipment testing method which comprises the following steps that a demand issuing module is used for acquiring to-be-tested equipment information input by power personnel, generating an equipment testing request according to the to-be-tested equipment information and sending the equipment testing request to a server; the positioning module is used for acquiring the position information of the corresponding to-be-tested equipment according to the to-be-tested equipment information and sending the position information to the server; the server is used for generating a recommendation instruction according to the equipment test request, acquiring candidate tester information in an idle state, and sending the candidate tester information and the recommendation instruction to the test recommendation module; and the test recommendation module is used for screening the testers according to the candidate tester information and a preset screening rule, determining target tester information and sending the target tester information to the server. The invention can test according to the actual requirement of the equipment to be tested, avoids the waste of human resources, and adopts corresponding measures to adjust and improve the environment of the area where the equipment to be tested is located.

Description

Electric power automation equipment testing method and system

Technical Field

The invention relates to the technical field of power system automation, in particular to a method and a system for testing power automation equipment.

Background

Electric power is an energy source using electric energy as power. In the 70 s of the 19 th century, the invention and application of electric power opened up the second industrialized climax. The technology becomes one of three technological revolution which occur in the world since 18 th century of human history, and the technology changes the lives of people. The large-scale power system appearing in the 20 th century is one of the most important achievements in the history of human engineering science, and is a power generation and consumption system consisting of links of power generation, power transmission, power transformation, power distribution, power utilization and the like. It converts the primary energy of nature into electric power through mechanical energy devices, and then supplies the electric power to each user through power transmission, transformation and distribution.

In daily work, the electric power automation equipment needs to be tested at intervals, so that the normal operation of the electric power work is guaranteed, but the current detection mode of the electric power automation equipment is limited to periodic test and cannot be tested according to the actual requirement of the electric power automation equipment; meanwhile, after the electric power automation equipment breaks down, a certain tester needs to be contacted by a telephone to test the fault, when the tester cannot be driven in time, the electric power work is influenced due to long-time stagnation, other testers are searched and contacted again, a large amount of time is wasted, the test resources of the electric power automation equipment cannot be reasonably distributed, and the test efficiency is low.

Disclosure of Invention

The invention aims to provide a method and a system for testing electric power automation equipment, and solve the technical problems that in the prior art, when a tester cannot timely drive away, the electric power work is influenced due to long-time stagnation, a large amount of time is wasted, the test resources of the electric power automation equipment cannot be reasonably distributed, and the test efficiency is low.

In one aspect of the present invention, a power automation device testing system is provided, including:

the demand issuing module is used for acquiring information of the equipment to be tested input by power personnel, generating an equipment testing request according to the information of the equipment to be tested and sending the equipment testing request to the server;

the positioning module is used for acquiring the position information of the corresponding to-be-tested equipment according to the to-be-tested equipment information and sending the position information to the server;

the server is used for generating a recommendation instruction according to the equipment test request, acquiring candidate tester information in an idle state, and sending the candidate tester information and the recommendation instruction to the test recommendation module;

the test recommendation module is used for screening the testers according to the candidate tester information and a preset screening rule, determining target tester information and sending the target tester information to the server;

the server is further used for sending the equipment test request and the position information to an intelligent terminal of the target testing personnel according to the target testing personnel information so as to inform the target testing personnel to carry out equipment test on the equipment to be tested in an equipment site;

the test analysis module is used for receiving a device test request input by a target tester, carrying out test analysis on the device to be tested, generating a test result and sending the test result to the intelligent terminal of the target tester; wherein the test result comprises normal or abnormal.

Preferably, the system further comprises:

the system comprises a registration login module, a server and a test system, wherein the registration login module is used for submitting personal information to register and sending the personal information to the server by a power person through an intelligent terminal, and the power person logs in the test system through the intelligent terminal to update the working state of the power person, wherein the working state comprises working or idle;

the data acquisition module is used for acquiring tool information of the equipment to be tested, and acquiring personal information and the current working state of power personnel;

the display module is used for displaying the test result generated by the test analysis module;

the background debugging module is used for modifying the parameters of the equipment to be tested by a target tester;

the fault feedback module is used for acquiring the test result, and sending a fault signal to the intelligent terminal of the target tester when the test result is used for judging that the equipment to be tested is in fault;

the evaluation module is used for evaluating the test work of the target tester in the test process by the power personnel and feeding back the evaluation result to the server;

the experience sharing module is used for the target tester to share the effective scheme in the test process of the device to be tested to the server;

and the generating and printing module is used for generating a report form for the test result by the target tester and printing the report form.

Preferably, the first and second liquid crystal materials are,

the test recommending module acquires personal information and working states of the power personnel through the data acquisition module, and marks the power personnel in an idle state as candidate test personnel;

acquiring total test quantity Czi and success test quantity Cci of the candidate testers, and calculating success test rate Cgi of the candidate testers according to the total test quantity and the success test quantity;

calculating a test recommended value TJ of the candidate tester according to the test success rate of the candidate tester;

sorting the candidate testers according to the test recommendation values, screening the top four candidate testers, and calculating corresponding test capability values CN;

and marking the candidate with the maximum testing capability value CN as the target tester.

Preferably, after receiving the device test request input by the target tester, the test analysis module performs test analysis on the device to be tested and the external environment thereof to generate an internal test result and an external test result; wherein the internal test result and the external test result both include normal or abnormal.

Preferably, the fault feedback module generates a fault signal according to the abnormal internal test result or external test result, and feeds back the fault signal to the server.

Preferably, the registration login module further updates test information of the electric power staff in the server when the electric power staff register and log in the test system, where the test information at least includes a total test amount, a test success amount, a test task amount, test efficiency, a total test duration, a test price, an experience amount, and a goodness of appreciation.

In another aspect of the present invention, a method for testing an electric power automation device is provided, which is implemented based on the electric power automation device testing system, and includes the following steps:

step S1, a demand release module acquires information of equipment to be tested input by power personnel, generates an equipment test request according to the information of the equipment to be tested and sends the equipment test request to a server;

step S2, the server generates a recommendation instruction according to the equipment test request, acquires candidate tester information in an idle state, and sends the candidate tester information and the recommendation instruction to a test recommendation module;

step S3, the test recommending module screens the testers according to the candidate tester information and a preset screening rule, determines target tester information and sends the target tester information to the server;

step S4, the server sends the device test request and the position information to the intelligent terminal of the target tester according to the target tester information to inform the target tester to carry out device test on the device to be tested on the device site;

step S5, a test analysis module receives a device test request input by a target tester, tests and analyzes the device to be tested, generates a test result, and sends the test result to the intelligent terminal of the target tester and the server; wherein the test result comprises normal or abnormal.

Preferably, the step S3 includes:

the test recommendation module acquires personal information and working states of the power personnel through the data acquisition module, and marks the power personnel in an idle state as candidate test personnel;

acquiring total test quantity Czi and success test quantity Cci of the candidate testers, and calculating success test rate Cgi of the candidate testers according to the total test quantity and the success test quantity;

calculating the test recommended value TJ of the candidate testers according to the following formula:

wherein a1, a2 and a3 are all preset fixed proportionality coefficient values; cavti is the average total test duration of the candidate testers; cri is the current testing task amount of the candidate testing personnel;

and sorting the candidate testers according to the test recommendation values, screening the top four candidate testers, and calculating the corresponding test capability value CN according to the following formula:

wherein HPh is the favorable rating of the candidate; ZXh is the linear distance of the candidate from the power automation device to be tested; RTh is the working time of the candidate personnel;

and marking the candidate with the maximum testing capability value CN as the target tester.

Preferably, the step S5 includes:

after receiving the equipment test request input by the target tester, the test analysis module performs test analysis on the equipment to be tested:

calculating a stable value Wt of the device to be tested according to the following formula:

wdmax is an upper limit value of the temperature allowed by the equipment to be tested during working; wdmin is the lower limit value of the temperature allowed by the equipment to be tested during working; sdmax is the upper limit value of the allowable humidity of the equipment to be tested during working; sdmin is a lower limit value of allowable humidity of the equipment to be tested during working, and alpha and beta are fixed values of preset proportionality coefficients; wd is the temperature value of the equipment to be tested; sd is the humidity value of the device to be tested;

randomly acquiring voltage values Dlo and current values Dyo of the equipment to be tested at five time points, and calculating to obtain an average current value DPlo and an average voltage value DPyl;

calculating a normal value ZC of the device to be tested according to the following formula:

wherein mu is a correction factor and takes the value of 0.024464684; d1, d2 and d3 are all preset fixed proportional coefficient values; xs is the line loss rate when the electric power passes through the equipment to be tested;

comparing a normal value ZC of the device to be tested with a first set threshold range to generate an internal test result, wherein the internal test result comprises normal or abnormal;

testing and analyzing the external environment of the device to be tested:

acquiring a rainfall value Jyu, an outdoor temperature value SWwu and an indoor temperature value SNwu of an area where the equipment to be tested is located in the future one week according to the position information, and calculating an average rainfall value JPy, an average air temperature value SWPw and an indoor average air temperature value SNPw;

the moisture impact value CSu for the area where the device under test is located is calculated according to the following formula:

wherein, both alpha and beta are fixed values of preset proportionality coefficients;

comparing the wetness impact value CSu to a second set threshold range generates an external test result, wherein the external test result includes normal or abnormal.

Preferably, the step S5 includes:

when the internal test result is abnormal, the test analysis module generates an internal test abnormal signal and feeds the internal test abnormal signal back to the server;

and when the external test result is abnormal, the test analysis module generates an external test abnormal signal and feeds the external test abnormal signal back to the server.

In summary, the embodiment of the invention has the following beneficial effects:

according to the system and the method for testing the electric power automation equipment, the electric power workers issue the testing requirements and then screen out corresponding testers, so that the testing can be performed according to the actual requirements of the equipment to be tested, and the waste of human resources is avoided; a large amount of time is saved, the testing resources of the equipment are reasonably distributed, and the testing efficiency is effectively improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is within the scope of the present invention for those skilled in the art to obtain other drawings based on the drawings without inventive exercise.

Fig. 1 is a schematic diagram of a test system of a power automation device in an embodiment of the invention.

Fig. 2 is a schematic main flow chart of a test method for an electric automation device in an embodiment of the invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings.

Fig. 1 is a schematic diagram of an embodiment of a power automation device testing system according to the present invention. In this embodiment, the system includes:

the demand release module is used for acquiring information of equipment to be tested (electric power automation equipment) input by an electric power worker, generating an equipment test request according to the information of the equipment to be tested (electric power automation equipment), and sending the equipment test request to the server.

And the positioning module is used for acquiring the position information of the corresponding equipment to be tested (electric power automation equipment) according to the information of the equipment to be tested (electric power automation equipment) and sending the position information to the server.

And the server is used for generating a recommendation instruction according to the equipment test request, acquiring candidate tester information in an idle state, and sending the candidate tester information and the recommendation instruction to the test recommendation module.

The test recommendation module is used for screening the testers according to the candidate tester information and a preset screening rule, determining target tester information and sending the target tester information to the server;

in a specific embodiment, the test recommendation module acquires personal information and working states of power personnel through the data acquisition module, and marks the power personnel in an idle state as candidate test personnel;

acquiring total test quantity Czi and success test quantity Cci of the candidate testers, and calculating success test rate Cgi of the candidate testers according to the total test quantity and the success test quantity;

calculating a test recommended value TJ of the candidate tester according to the test success rate of the candidate tester;

sorting the candidate testers according to the test recommendation values, screening the top four candidate testers, and calculating corresponding test capability values CN;

and marking the candidate with the maximum testing capability value CN as the target tester.

The server is further used for sending the equipment test request and the position information to an intelligent terminal of the target testing personnel according to the target testing personnel information so as to inform the target testing personnel to carry out equipment test on the equipment to be tested (electric power automation equipment) on the equipment site.

The test analysis module is used for receiving a device test request input by a target tester, performing test analysis on the device to be tested (electric power automation device), generating a test result and sending the test result to the intelligent terminal of the target tester; wherein the test result comprises normal or abnormal;

in a specific embodiment, after receiving an equipment test request input by a target tester, the test analysis module performs test analysis on equipment to be tested (electric power automation equipment) and an external environment thereof to generate an internal test result and an external test result; wherein the internal test result and the external test result both include normal or abnormal.

Specifically, the system further comprises:

the system comprises a registration login module, a server and a test system, wherein the registration login module is used for submitting personal information to register and sending the personal information to the server by a power person through an intelligent terminal, and the power person logs in the test system through the intelligent terminal to update the working state of the power person, wherein the working state comprises working or idle;

in a specific embodiment, the registration login module further updates test information of the electric power personnel in the server when the electric power personnel register and log in the test system, where the test information at least includes a total test amount, a test success amount, a test task amount, test efficiency, a total test duration, a test price, an experience amount, and a goodness.

The data acquisition module is used for acquiring tool information of a device to be tested (electric power automation device), and acquiring personal information and the current working state of an electric power person.

And the display module is used for displaying the test result generated by the test analysis module.

And the background debugging module is used for modifying the parameters of the equipment to be tested (the power automation equipment) by a target tester.

The fault feedback module is used for acquiring the test result, and sending a fault signal to the intelligent terminal of a target tester when the test result is used for judging that the equipment to be tested (electric power automation equipment) is in fault;

in a specific embodiment, the fault feedback module generates a fault signal according to the abnormal internal test result or external test result, and feeds back the fault signal to the server.

And the evaluation module is used for evaluating the test work of the target tester in the test process by the power personnel and feeding back the evaluation result to the server.

And the experience sharing module is used for the target tester to share the effective scheme in the test process of the equipment to be tested (the power automation equipment) to the server.

And the generating and printing module is used for generating a report form for the test result by the target tester and printing the report form.

Fig. 2 is a schematic diagram of an embodiment of a method for testing a power automation device according to the present invention. In this embodiment, the method comprises the steps of:

step S1, a demand release module acquires information of equipment to be tested (electric power automation equipment) input by an electric power worker, generates an equipment test request according to the information of the equipment to be tested (electric power automation equipment), and sends the equipment test request to a server;

step S2, the server generates a recommendation instruction according to the equipment test request, acquires candidate tester information in an idle state, and sends the candidate tester information and the recommendation instruction to a test recommendation module;

step S3, the test recommending module screens the testers according to the candidate tester information and a preset screening rule, determines target tester information and sends the target tester information to the server;

in a specific embodiment, the test recommendation module acquires personal information and working states of power personnel through the data acquisition module;

marking the power personnel in an idle state as candidate testers, and marking as i, i is 1, … … and n;

acquiring total test quantity Czi and success test quantity Cci of the candidate testers, and calculating success test rate Cgi of the candidate testers according to the total test quantity and the success test quantity; understandably, the current testing task amount Cri of the candidate testers is also obtained; obtaining the total test duration Cti of the candidate testers, and calculating the average total test duration Cavti of the candidate testers by utilizing a summation and averaging formula; acquiring the number of experience posts of candidate testers, and marking the number of the experience posts as Fi;

calculating the test recommended value TJ of the candidate testers according to the following formula:

wherein a1, a2 and a3 are all preset fixed proportionality coefficient values; cavti is the average total test duration of the candidate testers; cri is the current testing task amount of the candidate testing personnel;

and sorting the candidate testers according to the test recommendation values, screening the top four candidate testers, and calculating the corresponding test capability value CN according to the following formula:

wherein HPh is the favorable rating of the candidate tester; ZXh is the linear distance between the candidate tester and the device to be tested (power automation device); RTh is the working time of the candidate testing personnel; as can be understood, the time of first registration and login is subtracted from the current time of the mobile phone terminal of the candidate tester to obtain the working duration of the candidate tester, and the working duration is marked as RTh; s7: establishing a two-dimensional coordinate system by taking a device to be tested (electric power automation device) to be tested as an original point, and calculating by using a formula to obtain a linear distance ZXh between the four candidate testers and the device to be tested (electric power automation device) to be tested; meanwhile, obtaining good scores HPh of candidate testers;

marking the candidate tester with the maximum testing capability value CN as a target tester; and sending a test instruction to the intelligent terminal of the target tester, and simultaneously increasing the total test amount of the target tester once.

Step S4, the server sends the device test request and the position information to the intelligent terminal of the target tester according to the target tester information to inform the target tester to carry out device test on the device to be tested (electric power automation device) on the device site;

step S5, a test analysis module receives a device test request input by a target tester, tests and analyzes the device to be tested (electric power automation device), generates a test result, and sends the test result to the intelligent terminal of the target tester and the server; wherein the test result comprises normal or abnormal;

in a specific embodiment, after receiving a device test request input by a target tester, the test analysis module performs test analysis on a device to be tested (power automation device):

calculating a stable value Wt of a device to be tested (power automation device) according to the following formula:

wherein Wdmax is an upper limit value of temperature allowed when a device to be tested (electric power automation device) works; wdmin is the lower limit value of the temperature allowed by the equipment to be tested (electric power automation equipment) during working; sdmax is the upper limit value of the allowable humidity of the equipment to be tested (electric automation equipment) during operation; sdmin is a lower limit value of allowable humidity of a device to be tested (electric power automation device) during working, and alpha and beta are fixed values of preset proportionality coefficients; wd is a temperature value of the device to be tested (power automation device); sd is the humidity value of the device under test (power automation device);

randomly acquiring voltage values Dlo and current values Dyo of devices to be tested (electric power automation devices) at five time points, and calculating to obtain an average current value DPlo and an average voltage value DPyl;

the normal value ZC of the device to be tested (power automation device) is calculated according to the following formula:

wherein mu is a correction factor and takes the value of 0.024464684; d1, d2 and d3 are all preset fixed proportional coefficient values; xs is the line loss rate of the electric power passing through the equipment to be tested (electric power automation equipment); it can be understood that the line loss rate Xs when the electric power passes through the electric power automation equipment is calculated by using a line loss formula;

comparing a normal value ZC of a device to be tested (electric power automation device) with a first set threshold range to generate an internal test result, generating a test abnormal signal and feeding the test abnormal signal back to a server, and sending the test result to a display module; wherein the internal test result comprises normal or abnormal;

the external environment of a device to be tested (power automation device) is subjected to test analysis:

acquiring a rainfall value Jyu, an outdoor temperature value SWwu and an indoor temperature value SNwu of an area where a device to be tested (electric power automation equipment) is located in the future one week according to the position information, and calculating an average rainfall value JPy, an average air temperature value SWPw and an indoor average air temperature value SNPw; u is 1, … …, 7, u stands for days; as can be understood, the total rainfall value Jyz of the area in the future one week is obtained by using a summation formula, so that the average rainfall value JPy of the area in the future one week is calculated, and by analogy, the outdoor average air temperature value SWPw of the area in the future one week is obtained; acquiring an indoor temperature value SNwu of equipment to be tested (electric power automation equipment), and calculating an indoor average temperature value SNPw of a future week in an area where the equipment to be tested is located;

the moisture impact value CSu for the area where the device under test (power automation device) is located is calculated according to the following formula:

wherein, both alpha and beta are fixed values of preset proportionality coefficients;

comparing the wetness impact value CSu to a second set threshold range generates an external test result, wherein the external test result includes normal or abnormal.

More specifically, when the internal test result is abnormal, the test analysis module generates an internal test abnormal signal and feeds the internal test abnormal signal back to the server;

and when the external test result is abnormal, the test analysis module generates an external test abnormal signal and feeds the external test abnormal signal back to the server.

In summary, the embodiment of the invention has the following beneficial effects:

according to the system and the method for testing the electric power automation equipment, the electric power automation equipment is tested and analyzed through the test analysis module, a normal value of the electric power automation equipment is calculated by using a formula according to a temperature value and a humidity value of the electric power automation equipment, and is compared with a set threshold range to generate a test result, so that the conventional mode of regularly testing the electric power automation equipment is changed, test requirements are issued by electric power workers, then the corresponding test workers are screened out, the test can be carried out according to the actual requirements of the electric power automation equipment, and the waste of human resources is avoided; a large amount of time is saved, the testing resources of the equipment are reasonably distributed, and the testing efficiency is effectively improved.

While the invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not to be limited to the disclosed embodiment, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

Claims (10)

1. A power automation device test system, comprising:

the demand issuing module is used for acquiring information of the equipment to be tested input by power personnel, generating an equipment testing request according to the information of the equipment to be tested and sending the equipment testing request to the server;

the positioning module is used for acquiring the position information of the corresponding to-be-tested equipment according to the to-be-tested equipment information and sending the position information to the server;

the server is used for generating a recommendation instruction according to the equipment test request, acquiring candidate tester information in an idle state, and sending the candidate tester information and the recommendation instruction to the test recommendation module;

the test recommendation module is used for screening the testers according to the candidate tester information and a preset screening rule, determining target tester information and sending the target tester information to the server;

the server is further used for sending the equipment test request and the position information to an intelligent terminal of the target testing personnel according to the target testing personnel information so as to inform the target testing personnel to carry out equipment test on the equipment to be tested in an equipment site;

the test analysis module is used for receiving a device test request input by a target tester, carrying out test analysis on the device to be tested, generating a test result and sending the test result to the intelligent terminal of the target tester; wherein the test result comprises normal or abnormal.

2. The system of claim 1, further comprising:

the system comprises a registration login module, a server and a test system, wherein the registration login module is used for submitting personal information to register and sending the personal information to the server by a power person through an intelligent terminal, and the power person logs in the test system through the intelligent terminal to update the working state of the power person, wherein the working state comprises working or idle;

the data acquisition module is used for acquiring tool information of the equipment to be tested, and acquiring personal information and the current working state of power personnel;

the display module is used for displaying the test result generated by the test analysis module;

the background debugging module is used for modifying the parameters of the equipment to be tested by a target tester;

the fault feedback module is used for acquiring the test result, and sending a fault signal to the intelligent terminal of the target tester when the test result is used for judging that the equipment to be tested is in fault;

the evaluation module is used for evaluating the test work of the target tester in the test process by the power personnel and feeding back the evaluation result to the server;

the experience sharing module is used for the target tester to share the effective scheme in the test process of the device to be tested to the server;

and the generating and printing module is used for generating a report form for the test result by the target tester and printing the report form.

3. The system of claim 2, wherein the test recommending module acquires personal information and working states of the electric power personnel through the data collecting module, and marks the electric power personnel in an idle state as candidate testers;

acquiring total test quantity Czi and success test quantity Cci of the candidate testers, and calculating success test rate Cgi of the candidate testers according to the total test quantity and the success test quantity;

calculating a test recommended value TJ of the candidate tester according to the test success rate of the candidate tester;

sorting the candidate testers according to the test recommendation values, screening the top four candidate testers, and calculating corresponding test capability values CN;

and marking the candidate with the maximum testing capability value CN as the target tester.

4. The system of claim 3, wherein the test analysis module performs test analysis on the device under test and its external environment after receiving a device test request input by a target tester, and generates an internal test result and an external test result; wherein the internal test result and the external test result both include normal or abnormal.

5. The system of claim 4, wherein the fault feedback module generates a fault signal according to the internal test result or the external test result which is abnormal, and feeds back the fault signal to the server.

6. The system of claim 5, wherein the registration and login module further updates test information of the electric power personnel in the server when the electric power personnel register and log in a test system, wherein the test information at least comprises a total test amount, a test success amount, a test task amount, a test efficiency, a total test duration, a test price, an experience amount and a goodness of appreciation.

7. A power automation device testing method realized based on the power automation device testing system of any one of claims 1 to 6, characterized by comprising the following steps:

step S1, a demand release module acquires information of equipment to be tested input by power personnel, generates an equipment test request according to the information of the equipment to be tested and sends the equipment test request to a server;

step S2, the server generates a recommendation instruction according to the equipment test request, acquires candidate tester information in an idle state, and sends the candidate tester information and the recommendation instruction to a test recommendation module;

step S3, the test recommending module screens the testers according to the candidate tester information and a preset screening rule, determines target tester information and sends the target tester information to the server;

step S4, the server sends the device test request and the position information to the intelligent terminal of the target tester according to the target tester information to inform the target tester to carry out device test on the device to be tested on the device site;

step S5, a test analysis module receives a device test request input by a target tester, tests and analyzes the device to be tested, generates a test result, and sends the test result to the intelligent terminal of the target tester and the server; wherein the test result comprises normal or abnormal.

8. The method of claim 7, wherein the step S3 includes:

the test recommendation module acquires personal information and working states of the power personnel through the data acquisition module, and marks the power personnel in an idle state as candidate test personnel;

acquiring total test quantity Czi and success test quantity Cci of the candidate testers, and calculating success test rate Cgi of the candidate testers according to the total test quantity and the success test quantity;

calculating the test recommended value TJ of the candidate testers according to the following formula:

wherein a1, a2 and a3 are all preset fixed proportionality coefficient values; cavti is the average total test duration of the candidate testers; cri is the current testing task amount of the candidate testing personnel;

and sorting the candidate testers according to the test recommendation values, screening the top four candidate testers, and calculating the corresponding test capability value CN according to the following formula:

wherein HPh is the favorable rating of the candidate; ZXh is the linear distance of the candidate from the power automation device to be tested; RTh is the working time of the candidate personnel;

and marking the candidate with the maximum testing capability value CN as the target tester.

9. The method of claim 8, wherein the step S5 includes:

after receiving the equipment test request input by the target tester, the test analysis module performs test analysis on the equipment to be tested:

calculating a stable value Wt of the device to be tested according to the following formula:

wdmax is an upper limit value of the temperature allowed by the equipment to be tested during working; wdmin is the lower limit value of the temperature allowed by the equipment to be tested during working; sdmax is the upper limit value of the allowable humidity of the equipment to be tested during working; sdmin is a lower limit value of allowable humidity of the equipment to be tested during working, and alpha and beta are fixed values of preset proportionality coefficients; wd is the temperature value of the equipment to be tested; sd is the humidity value of the device to be tested;

randomly acquiring voltage values Dlo and current values Dyo of the equipment to be tested at five time points, and calculating to obtain an average current value DPlo and an average voltage value DPyl;

calculating a normal value ZC of the device to be tested according to the following formula:

wherein mu is a correction factor and takes the value of 0.024464684; d1, d2 and d3 are all preset fixed proportional coefficient values; xs is the line loss rate when the electric power passes through the equipment to be tested;

comparing a normal value ZC of the device to be tested with a first set threshold range to generate an internal test result, wherein the internal test result comprises normal or abnormal;

testing and analyzing the external environment of the device to be tested:

acquiring a rainfall value Jyu, an outdoor temperature value SWwu and an indoor temperature value SNwu of an area where the equipment to be tested is located in the future one week according to the position information, and calculating an average rainfall value JPy, an average air temperature value SWPw and an indoor average air temperature value SNPw;

the moisture impact value CSu for the area where the device under test is located is calculated according to the following formula:

wherein, both alpha and beta are fixed values of preset proportionality coefficients;

comparing the wetness impact value CSu to a second set threshold range generates an external test result, wherein the external test result includes normal or abnormal.

10. The method of claim 9, wherein the step S5 includes:

when the internal test result is abnormal, the test analysis module generates an internal test abnormal signal and feeds the internal test abnormal signal back to the server;

and when the external test result is abnormal, the test analysis module generates an external test abnormal signal and feeds the external test abnormal signal back to the server.

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