CN114879075A - Power supply monitoring method, system, terminal and storage medium - Google Patents

Abstract

The invention relates to a power supply monitoring method, a system, a terminal and a storage medium, belonging to the technical field of test monitoring, wherein the method comprises the following steps: setting test parameters based on the received parameter setting instruction; receiving a channel selection instruction aiming at a target test channel; after a test starting instruction is received, controlling the working state of a target test power supply corresponding to a target test channel based on test parameters; acquiring real-time operation data corresponding to a target test power supply, generating or updating an operation database corresponding to the target test power supply based on the acquired real-time operation data, and storing the operation database in association with a channel number of a target test channel; and judging whether the target test power supply is abnormal or not based on the real-time operation data, the current safety interval and the voltage safety interval, and turning off the target test power supply when the judgment result is yes. The power supply testing and monitoring system can improve testing and monitoring efficiency of the power supply.

Description

Power supply monitoring method, system, terminal and storage medium

Technical Field

The invention relates to the technical field of test monitoring, in particular to a power supply monitoring method, a power supply monitoring system, a power supply monitoring terminal and a storage medium.

Background

With the development of society, the pursuit of science and technology is continuously improved, and the technical requirements on various electric products are more urgent. In the research and development process of various electric products, a power supply is needed to supply power, and the reliability of the power supply can directly determine the service life of the product. The reliability of the power supply is therefore a fundamental concern.

In order to monitor the reliability of the power supply, a user uses devices such as a current meter and a voltage meter to test each reliability item of the power supply and record data through a series of operations such as wiring, timing, power-on and power-off.

The inventors have found that the above prior art has at least the following problems: in the process of executing the method, the operation state of the power supply to be tested needs to be manually controlled and data needs to be recorded, so that the efficiency is not high.

Disclosure of Invention

In order to improve the efficiency of testing and monitoring a power supply, the application provides a power supply monitoring method, a power supply monitoring system, a terminal and a storage medium.

In a first aspect, the present application provides a power supply monitoring method, which adopts the following technical scheme:

a power monitoring method, the method being based on a smart device in a power monitoring system, the method comprising:

setting test parameters based on the received parameter setting instruction, wherein the test parameters comprise on-off times, on-off time, test current, test voltage, a current safety interval and a voltage safety interval;

receiving a channel selection instruction aiming at a target test channel;

after a test starting instruction is received, controlling the working state of a target test power supply corresponding to the target test channel based on the test parameters;

acquiring real-time operation data corresponding to the target test power supply, generating or updating an operation database corresponding to the target test power supply based on the acquired real-time operation data, and storing the operation database in association with a channel number of the target test channel;

and judging whether the target test power supply is abnormal or not based on the real-time operation data, the current safety interval and the voltage safety interval, and turning off the target test power supply when the judgment result is yes.

By adopting the technical scheme, the intelligent equipment can automatically control the working state of the target test power supply corresponding to the target test channel based on the received parameter setting instruction and the channel selection instruction, and receive and judge real-time running data generated in the test process in real time. Compared with a manual operation test, the automatic monitoring of the power supply is realized, and the test efficiency is improved.

Optionally, the test parameters further include a current early warning interval and a voltage early warning interval; after the obtaining real-time operating data corresponding to the target test power supply and storing the real-time operating data in association with the channel number of the target test channel, the method further includes:

judging whether a real-time current value in the real-time operation data exceeds the current early warning interval or not;

judging whether a real-time voltage value in the real-time operation data exceeds the voltage early warning interval or not;

and when the judgment result of at least one item is yes, generating an alarm instruction aiming at the target test power supply.

Through adopting above-mentioned technical scheme, in the experimentation, smart machine can be in real time with received real-time current value and real-time voltage value respectively with electric current early warning interval and voltage early warning interval contrast, thereby in time discover to have the power of transfinite risk, smart machine is after discerning at least one numerical value in real-time current value and the real-time voltage value and surpass corresponding early warning interval, will generate the instruction of reporting an emergency and asking for help reminding user target test power to have the transfinite risk, so that the user can observe and handle the target test power that has the transfinite risk in time.

Optionally, the method further includes:

and after receiving a first query instruction aiming at the first test channel, calling and feeding back an operation database corresponding to the first test channel.

By adopting the technical scheme, when a user wants to inquire the operation data of a certain power supply in the test process, a first inquiry instruction aiming at the test channel connected with the power supply can be input into the intelligent equipment, so that the intelligent equipment can call and feed back the corresponding operation database, and the operation is convenient.

Optionally, the target test power supply may further feed back its own power supply number, and the operation database may further be associated with the power supply number; the method further comprises the following steps:

and after receiving a second query instruction carrying a target power supply number, calling and feeding back an operation database corresponding to the target power supply number.

By adopting the technical scheme, when a user wants to inquire the running data of any power supply, the second inquiry request carrying the power supply number of the power supply can be input into the intelligent equipment without being limited by a test channel, and the running database is associated with the power supply number, so that the inquiry of the user on the historical data is facilitated.

Optionally, the method further includes:

after a reliability query request aiming at the target power supply number is received, evaluating the reliability grade of a target test power supply based on a prestored reliability evaluation rule and an operation database corresponding to the target power supply number;

and feeding back the reliability grade.

By adopting the technical scheme, the user can input the reliability query request, so that the intelligent equipment can evaluate and feed back the reliability grade of the target test power supply, and the user can know the reliability of the target test power supply more intuitively.

Optionally, after determining whether the target test power supply is abnormal based on the real-time operation data, the current safety interval and the voltage safety interval, the method further includes:

when the judgment result is yes, adding a target power supply number corresponding to the target test power supply into a fault number library;

the method further comprises the following steps: and when the target test power supply corresponding to the target power supply number is identified to be not abnormal all the time in a complete test, deleting the target power supply number from the fault number library.

By adopting the technical scheme, the arrangement of the fault number library is beneficial to a user to know all power supplies with faults in time.

Optionally, before receiving the test start instruction, the method further includes:

receiving a reservation request carrying reservation time information;

after receiving a test starting instruction, controlling the working state of the target test power supply corresponding to the target test channel based on the test parameters, specifically including:

and after the system time reaches the reserved time, controlling the working state of the target test power supply corresponding to the target test channel based on the test parameters.

By adopting the technical scheme, the user can reserve the test starting time in advance by inputting the reservation request, and after the intelligent equipment receives the reservation request, when the system time reaches the reserved time, the test is automatically controlled to start, so that the flexibility of setting the test time is improved.

In a second aspect, the present application provides a power monitoring system, which adopts the following technical solution:

the utility model provides a power monitoring system, includes smart machine, switching equipment, and through a plurality of needs that switching equipment and smart machine are connected carry out the power monitored, smart machine includes:

the parameter setting module is used for setting test parameters based on the received parameter setting instruction, wherein the test parameters comprise on-off times, on-off time, test current, test voltage, a current safety interval and a voltage safety interval;

the instruction receiving module is used for receiving a channel selection instruction aiming at a target test channel;

the test power supply control module is used for controlling the working state of a target test power supply corresponding to the target test channel based on the test parameters after receiving a test starting instruction;

the operation data acquisition module is used for acquiring real-time operation data corresponding to the target test power supply;

the data storage module is used for generating or updating an operation database corresponding to the target test power supply based on the acquired real-time operation data and storing the operation database in association with the channel number of the target test channel;

the abnormity judgment module is used for judging whether the target test power supply is abnormal or not based on the real-time operation data, the current safety interval and the voltage safety interval;

and the test power supply control module is also used for switching off the target test power supply when the judgment result is yes.

In a third aspect, the present application provides an intelligent terminal, which adopts the following technical scheme:

an intelligent terminal comprising a memory and a processor, said memory having stored thereon a computer program that can be loaded by the processor and that executes the method according to the first aspect.

In a fourth aspect, the present application provides a computer-readable storage medium, which adopts the following technical solutions:

a computer readable storage medium comprising a computer program stored thereon which is loadable by a processor and adapted to carry out the method of the first aspect.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the intelligent device can automatically control the working state of the target test power supply corresponding to the target test channel based on the received parameter setting instruction and the channel selection instruction, and receive and judge real-time operation data generated in the test process in real time. Compared with a manual operation test, the automatic monitoring of the power supply is realized, and the test efficiency is improved.

2. The user can input the reliability query request, so that the intelligent device can evaluate and feed back the reliability grade of the target test power supply, and the reliability of the target test power supply can be better and more intuitively known by the user.

Drawings

FIG. 1 is a block diagram of a power monitoring system embodied in an embodiment of the present application;

FIG. 2 is a schematic flow chart diagram of a method for monitoring a power supply according to an embodiment of the present application;

fig. 3 is a block diagram of an architecture for embodying an intelligent device in an embodiment of the present application.

Description of reference numerals: 31. a parameter setting module; 32. an instruction receiving module; 33. a test power supply control module; 34. operating a data acquisition module; 35. a data storage module; 36. and an abnormality judgment module.

Detailed Description

The present application is described in further detail below with reference to figures 1-3.

The embodiment of the application discloses a power supply monitoring method which can be applied to a power supply monitoring system. Referring to fig. 1, the power monitoring system may be applied to a test for monitoring reliability of a power supply, and the execution subject may be an intelligent device in the power monitoring system, the intelligent device may be a computer configured with an interaction component, the interaction component includes a display screen and an input device, and the input device may be a keyboard, a mouse, and the like. The power monitoring system also comprises a switching device and a plurality of power supplies which are connected with the intelligent device through the switching device and need to be monitored, wherein the switching device can be a GPIB-USB-HS card, the GPIB-USB-HS card is provided with a USB interface used for being connected with the intelligent device and a plurality of GPIB channels, and each GPIB channel can be used for being connected with one power supply to be detected.

The process flow shown in fig. 2 will be described in detail below with reference to the specific embodiments, and the contents may be as follows:

s101: and setting test parameters based on the received parameter setting instruction.

The test parameters comprise on-off times, on-off time, test current, test voltage, a current safety interval and a voltage safety interval.

In implementation, before an experiment starts, a user can send a parameter setting request to the intelligent device through the input device, so that the intelligent device displays a parameter setting interface through the display screen, and then the user can input experiment parameters required by the experiment on the parameter setting interface and click the virtual button representing confirmation, so as to send a parameter setting instruction to the intelligent device. In addition, device templates can be stored in the intelligent equipment, and test parameters are recorded in each device template. The user can also check and select any device template in the parameter setting interface, so that a parameter setting instruction is sent to the intelligent equipment. The intelligent device can complete the setting of the test parameters in the test based on the received parameter setting instruction.

S102: a channel selection instruction for a target test channel is received.

Wherein the target test channel may be any one of all test channels.

In implementation, after the user connects the target test power supply to the target test channel, the channel number of the target test channel can be selected from the intelligent device through the input device, so that a channel selection instruction for the target test channel is input into the intelligent device.

S103: after a test starting instruction is received, controlling the working state of a target test power supply corresponding to a target test channel based on test parameters;

the target test power supply is a test power supply connected to the intelligent equipment through a target test channel.

In implementation, after the settings are completed, a user can send a test start instruction to the intelligent device through the input device, and after the intelligent device receives the test start instruction, the intelligent device can send the test parameters which are set and completed in the step S101 to the target test power supply corresponding to the target test channel, so that the target test power supply periodically runs according to the on-time and the off-time, and in the on-state, the target test power supply respectively uses the test current and the test voltage as the theoretical current and the theoretical voltage to work. Under normal conditions, the target test power supply stops testing after the switching times reach the on-off times in the test parameters.

S104: the method comprises the steps of obtaining real-time operation data corresponding to a target test power supply, generating or updating an operation database corresponding to the target test power supply based on the obtained real-time operation data, and storing the operation database in association with a channel number of a target test channel.

The real-time operation data comprises operation time, power-on residual time, power-off residual time, a real-time current value and a real-time voltage value.

In implementation, in the test process, the intelligent device receives real-time operation data fed back by the target test power supply, and when the real-time operation data fed back by the target test power supply is received for the first time in the test, the intelligent device generates an operation database corresponding to the target test power supply and is associated with the channel number of the target test channel. And then, when the real-time operation data fed back by the target test power supply is acquired, the intelligent equipment updates the corresponding operation database.

S105: and judging whether the target test power supply is abnormal or not based on the real-time operation data, the current safety interval and the voltage safety interval, and turning off the target test power supply when the judgment result is yes.

The current safety interval can be [ a1, a2], a1 is a current safety lower limit value, and a2 is a current safety upper limit value; the voltage safety interval can be [ b1, b2], and b1 is the lower voltage safety limit, and b2 is the upper voltage safety limit.

In implementation, after the intelligent device acquires real-time operation data fed back by the target test power supply, the real-time current value of the intelligent device can be compared with the current safety interval, and the real-time voltage value of the intelligent device can be compared with the voltage safety interval. And when the real-time current value exceeds the current safety interval, judging that the target test power supply has a current overrun fault, and when the real-time voltage value exceeds the voltage safety interval, judging that the target test power supply has a voltage overrun fault. When recognizing that at least one of the current overrun fault or the voltage overrun fault occurs, the intelligent equipment can judge that the target test power supply is abnormal and turn off the target test power supply.

Optionally, in another embodiment, in order to reduce the possibility of the occurrence of the overrun, the test parameters may further include a current warning interval and a voltage warning interval.

The current warning interval may be [ a3, a4], a3 is a current warning lower limit value, a4 is a current warning upper limit value, and the current warning interval is within the range of the current safety interval, for example, a3= a1+ (a2-a1) × 10%, a4= a2- (a2-a1) × 10%; the voltage warning interval may be [ b3, b4], b3 is a voltage warning lower limit value, b4 is a voltage warning upper limit value, and the voltage warning interval is within the above voltage safety interval, for example, b3= b1+ (b2-b1) 10%, b4= b2- (b2-b1) 10%.

In this case, after the above S104, the following may be further included:

and judging whether the real-time current value in the real-time operation data exceeds the current early warning interval.

In implementation, after receiving the real-time operation data, the intelligent device can compare the real-time current value with the current early warning interval, so as to judge whether the real-time current value exceeds the current early warning interval.

And judging whether the real-time voltage value in the real-time operation data exceeds a voltage early warning interval.

In implementation, after receiving the real-time operation data, the intelligent device can judge whether the real-time voltage value exceeds the voltage early warning interval.

And when the judgment result of at least one item is yes, generating an alarm instruction aiming at the target test power supply.

In implementation, when any one of the real-time current value exceeding the current early warning interval or the real-time voltage value exceeding the voltage early warning interval occurs, the risk that the target test power supply has a fault is represented. At this time, the intelligent device generates an alarm instruction for the target test power supply. Then, the intelligent device may control the display screen to display a situation description text for the above situation based on the alarm instruction, for example, "there is an overrun risk in the real-time current value of channel No. 1" and "there is an overrun risk in the real-time voltage value of channel No. 6". The intelligent device can also send the alarm instruction to preset alarm equipment, so that a prompt is sent to the user through the alarm equipment. Wherein, the alarm device can be a sound-light alarm device, a voice broadcast device and the like which are externally connected on the intelligent device.

Optionally, in another embodiment, in order to facilitate the user to query and retrieve the historical operating data, the method may further include the following steps:

and after receiving a first query instruction aiming at the first test channel, calling and feeding back an operation database corresponding to the first test channel.

Wherein the first test channel may be any one of all test channels.

In implementation, a user may select a channel number of a first test channel through an input device, and input a first query instruction carrying the channel number to an intelligent device. And after receiving the first query instruction, the intelligent device calls an operation database corresponding to the first test channel, and generates an operation data table or an operation data curve corresponding to the first channel number based on the operation database. Taking the operation data curve as an example, the operation data curve may respectively include a real-time voltage value change curve and a real-time current value change curve, and the real-time voltage value change curve and the real-time current value change curve are respectively used for reflecting the change situation of the real-time voltage value and the real-time current value of the test power supply in the first test channel along with time. And then, the intelligent device can display the operation data table or the operation data curve through the display screen, so that the intelligent device is convenient for a user to view.

Optionally, in another embodiment, in order to facilitate query of the historical test data, the target test power supply may further feed back its own power supply number, and the operation database may further be stored in association with the power supply number, where the method may further include the following steps:

and after receiving a second query instruction carrying the target power supply number, calling and feeding back an operation database corresponding to the target power supply number.

In implementation, a user may select a target power source number through an input device, and further select a target time range to be queried, so as to input a second query instruction carrying the target power source number and the target time range to the intelligent device. After receiving the second query instruction, the intelligent device may call an operation database corresponding to the target power source number, and generate an operation data table or an operation data curve based on historical operation data located in the target time range. The smart device may then display the generated operational data table or operational data curve on a display screen for easy viewing by the user.

Optionally, in another embodiment, in order to help the user to more intuitively understand the target test power reliability, the method may further include the following steps:

and after receiving a reliability query request aiming at the target power supply number, evaluating the reliability grade of the target test power supply based on a pre-stored reliability evaluation rule and an operation database corresponding to the target power supply number.

In an implementation, a user may send a reliability query request for a target power supply number to a smart device through an input device. After receiving the reliability query request, the intelligent device may evaluate the reliability level of the target test power supply based on a pre-stored reliability evaluation rule and an operation database corresponding to the target power supply number. The specific evaluation procedure may be as follows: the smart device calculates the variance of all real-time current values and the variance of all real-time voltage values, respectively, based on the operating database corresponding to the target power source number, and then the smart device may evaluate the reliability level of the target test power source based on the magnitudes of the two variances.

And feeding back the reliability level.

In implementation, the smart device may display the obtained reliability level through a display screen.

Optionally, in another embodiment, in order to facilitate the user to identify the failed test power supply and to facilitate the user to perform non-failure confirmation on the repaired test power supply, after S105, the following may be further included:

and when the judgment result is yes, adding a target power supply number corresponding to the target test power supply into the fault number library.

The power supply numbers of all the test power supplies with faults, the fault types corresponding to the power supply numbers and the total number of the test power supplies with faults are recorded in the fault number library.

In implementation, after the intelligent device judges that the target test power supply is abnormal, the intelligent device can add the target power supply number corresponding to the target test power supply into the fault number library. The user can send a fault query request to the intelligent device through the input device, and after the intelligent device receives the fault query request, the intelligent device calls the fault number library and feeds the fault number library back to the display screen.

And when the target test power supply corresponding to the target power supply number is identified not to be abnormal all the time in a complete test, deleting the target power supply number and the fault type corresponding to the target power supply number from the fault number library, and updating the total number of the test power supplies with faults.

In implementation, a user can take down and maintain an abnormal target test power supply, the target test power supply is connected to the system again after the maintenance is completed, the user controls the target test power supply to perform a test again through the intelligent device, if the target test power supply is not abnormal in the test process, a target power supply number corresponding to the target test power supply and a corresponding fault type are deleted from the fault number library, and the total number of the test power supplies with faults is updated.

Optionally, in another embodiment, in order to facilitate the user to control the test time, before receiving the test start instruction, the following may be further included:

and receiving a reservation request carrying reservation time information.

In implementation, a user may set the reservation time through the input device, so as to send a reservation request to the smart device, where the request carries reservation time information.

After receiving a test starting instruction, controlling the working state of a target test power supply corresponding to a target test channel based on test parameters, specifically comprising:

and after the system time reaches the appointment starting time, controlling the working state of the target test power supply corresponding to the target test channel based on the test parameters.

In implementation, after receiving the reservation request, the smart device may set a reservation starting time based on the reservation time information, and control the target test power supply corresponding to the target test channel to execute the test starting instruction after the system time reaches the reservation starting time.

The implementation principle of the embodiment of the application is as follows: the user selects the instruction to intelligent equipment input parameter setting instruction and passageway through input device, later, the user clicks experimental start instruction through the virtual button on the display screen, intelligent equipment is after receiving experimental start instruction, select the instruction based on parameter setting instruction and passageway that have received, the operating condition of automatic control target test power, for manual operation, this application is more accurate to the control of test time, and need not the manual work and carry out the repetitive operation of circular telegram and outage to the target test power, user's work burden has been alleviateed, be favorable to improving work efficiency.

Based on the method, the embodiment of the application further discloses a power supply monitoring system, and the power supply monitoring system comprises intelligent equipment, switching equipment and a plurality of power supplies which are connected with the intelligent equipment through the switching equipment and need to be monitored. Referring to fig. 3, the smart device includes:

and the parameter setting module 31 is configured to set test parameters based on the received parameter setting instruction, where the test parameters include on-off times, on-time, off-time, test current, test voltage, a current safety interval, and a voltage safety interval.

And the instruction receiving module 32 is configured to receive a channel selection instruction for the target test channel.

And the test power supply control module 33 is configured to control the working state of the target test power supply corresponding to the target test channel based on the test parameters after receiving the test start instruction.

And the operation data acquisition module 34 is used for acquiring real-time operation data corresponding to the target test power supply.

And the data storage module 35 is configured to generate or update an operation database corresponding to the target test power supply based on the acquired real-time operation data, and store the operation database in association with the channel number of the target test channel.

And the abnormity judgment module 36 is used for judging whether the target test power supply is abnormal or not based on the real-time operation data, the current safety interval and the voltage safety interval.

The test power control module 33 is further configured to turn off the target test power if the determination result is yes.

Optionally, the smart device may further include:

and the early warning judgment module is used for judging whether the real-time current value in the real-time operation data exceeds the current early warning interval or not and also used for judging whether the real-time voltage value in the real-time operation data exceeds the voltage early warning interval or not.

And the alarm instruction generating module is used for generating an alarm instruction aiming at the target test power supply when the judgment result of at least one item is yes.

Optionally, the smart device may further include:

and the query result feedback module is used for calling and feeding back the operation database corresponding to the first test channel after receiving the first query instruction aiming at the first test channel.

Optionally, the target test power supply may also feed back its own power supply number, and the operation database may also be associated with the power supply number.

And the query result feedback module is also used for calling and feeding back the operation database corresponding to the target power supply number after receiving a second query instruction carrying the target power supply number.

Optionally, the smart device further includes:

and the reliability grade evaluation module is used for evaluating the reliability grade of the target test power supply based on a prestored reliability evaluation rule and an operation database corresponding to the target power supply number after receiving the reliability query request aiming at the target power supply number.

And the reliability grade feedback module is used for feeding back the reliability grade.

Optionally, the smart device may further include:

and the fault recording module is configured to, after the abnormality determining module 36 determines whether the target test power supply is abnormal based on the real-time operation data, the current safety interval and the voltage safety interval, execute the following processing: and when the judgment result is yes, adding a target power supply number corresponding to the target test power supply into the fault number library.

And the fault recording module is also used for deleting the target power supply number from the fault number library after identifying that the target test power supply corresponding to the target power supply number is not abnormal all the time in one complete test.

Optionally, the instruction receiving module 32 may be further configured to receive a reservation request carrying reservation time information.

The test power control module 33 is specifically configured to control the working state of the target test power corresponding to the target test channel based on the test parameter after the system time reaches the reserved time.

The embodiment of the application also discloses an intelligent terminal, which comprises a memory and a processor, wherein the memory is stored with a computer program which can be loaded by the processor and can execute the power supply monitoring method.

An embodiment of the present application further discloses a computer-readable storage medium, which stores a computer program that can be loaded by a processor and execute the power monitoring method as described above, and the computer-readable storage medium includes, for example: various media capable of storing program codes, such as a usb disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk.

The above examples are only used to illustrate the technical solutions of the present application, and do not limit the scope of protection of the application. It is to be understood that the embodiments described are only some of the embodiments of the present application and not all of them. All other embodiments, which can be derived by a person skilled in the art from these embodiments without making any inventive step, are within the scope of the present application.

Claims (10)

1. A power monitoring method, wherein the method is based on a smart device in a power monitoring system, and wherein the method comprises:

setting test parameters based on the received parameter setting instruction, wherein the test parameters comprise on-off times, on-off time, test current, test voltage, a current safety interval and a voltage safety interval;

receiving a channel selection instruction aiming at a target test channel;

after a test starting instruction is received, controlling the working state of a target test power supply corresponding to the target test channel based on the test parameters;

acquiring real-time operation data corresponding to the target test power supply, generating or updating an operation database corresponding to the target test power supply based on the acquired real-time operation data, and storing the operation database in association with a channel number of the target test channel;

and judging whether the target test power supply is abnormal or not based on the real-time operation data, the current safety interval and the voltage safety interval, and turning off the target test power supply when the judgment result is yes.

2. The power supply monitoring method according to claim 1, wherein the test parameters further comprise a current warning interval and a voltage warning interval;

after the obtaining real-time operating data corresponding to the target test power supply and storing the channel number associated with the target test channel, the method further includes:

judging whether a real-time current value in the real-time operation data exceeds the current early warning interval or not;

judging whether a real-time voltage value in the real-time operation data exceeds the voltage early warning interval or not;

and when the judgment result of at least one item is yes, generating an alarm instruction aiming at the target test power supply.

3. A method as claimed in claim 1, wherein the method further comprises:

and after receiving a first query instruction aiming at the first test channel, calling and feeding back an operation database corresponding to the first test channel.

4. The power supply monitoring method according to claim 1, wherein the target test power supply further feeds back its own power supply number, and the operation database is further associated with the power supply number;

the method further comprises the following steps: and after receiving a second query instruction carrying a target power supply number, calling and feeding back an operation database corresponding to the target power supply number.

5. The method of claim 4, further comprising:

after a reliability query request aiming at the target power supply number is received, evaluating the reliability grade of a target test power supply based on a prestored reliability evaluation rule and an operation database corresponding to the target power supply number;

and feeding back the reliability grade.

6. The power supply monitoring method according to claim 4, after determining whether the target test power supply is abnormal based on the real-time operation data, the current safety interval and the voltage safety interval, further comprising:

when the judgment result is yes, adding a target power supply number corresponding to the target test power supply into a fault number library;

the method further comprises the following steps: and when the target test power supply corresponding to the target power supply number is identified to be not abnormal all the time in a complete test, deleting the target power supply number from the fault number library.

7. The power supply monitoring method according to claim 1, further comprising, before receiving the test start command:

receiving a reservation request carrying reservation time information;

after receiving a test starting instruction, controlling the working state of the target test power supply corresponding to the target test channel based on the test parameters, specifically including:

and after the system time reaches the reserved time, controlling the working state of the target test power supply corresponding to the target test channel based on the test parameters.

8. The utility model provides a power monitoring system, its characterized in that, includes smart machine, switching equipment, and through a plurality of power that need monitor that switching equipment and smart machine are connected, smart machine includes:

the parameter setting module (31) is used for setting test parameters based on the received parameter setting instruction, wherein the test parameters comprise on-off times, on-time, off-time, test current, test voltage, a current safety interval and a voltage safety interval;

the instruction receiving module (32) is used for receiving a channel selection instruction aiming at the target test channel;

the test power supply control module (33) is used for controlling the working state of a target test power supply corresponding to the target test channel based on the test parameters after receiving a test starting instruction;

an operational data acquisition module (34) for acquiring real-time operational data corresponding to the target test power supply;

the data storage module (35) is used for generating or updating an operation database corresponding to the target test power supply based on the acquired real-time operation data, and storing the operation database in association with the channel number of the target test channel;

the abnormity judgment module (36) is used for judging whether the target test power supply is abnormal or not based on the real-time operation data, the current safety interval and the voltage safety interval;

and the test power supply control module (33) is also used for turning off the target test power supply when the judgment result is yes.

9. An intelligent terminal, comprising a memory and a processor, the memory having stored thereon a computer program that can be loaded by the processor and that executes the method according to any one of claims 1 to 7.

10. A computer-readable storage medium, in which a computer program is stored which can be loaded by a processor and which executes the method of any one of claims 1 to 7.

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