CN117193145A - Electrical control method and system for automatic production line of electrician examination and culture equipment - Google Patents

Abstract

The application discloses an electrical control method and system for an automatic production line of an electrician examination and culture device, which relate to the field of electrical control and comprise the following steps: the operation input module is used for extracting a first standard operation sequence set and a second actual operation sequence, and judging whether to give a warning to an examinee or not by comparing the first standard operation sequence set with the second actual operation sequence; the operation danger monitoring module is used for judging whether to give an alarm to an examinee or not and judging that the equipment takes measures; the circuit safety monitoring module is used for judging that the equipment takes measures; and the equipment safety monitoring module is used for monitoring the equipment safety coefficient in real time and judging whether to start the circuit breaker to cut off the power supply of the equipment. The application realizes the effect of monitoring the equipment risk caused by the operation influence of personnel and the internal environment influence of equipment in real time, and simultaneously can give an alarm to the examinee when the examinee operates incorrectly, thereby being convenient for the examinee to correct in time.

Description

Electrical control method and system for automatic production line of electrician examination and culture equipment

Technical Field

The application relates to the field of electrical control, in particular to an electrical control method and system for an automatic production line of electrician examination and culture equipment.

Background

With the continued development of the power industry and electrician field, the need for qualified electricians is also increasing, including electricians' training and certification to ensure that they possess the necessary skills and knowledge to safely operate and maintain electrical equipment, where electrical safety is critical, as electrical faults can lead to fires, electrical shock accidents, and equipment damage, training electricians and improving their electrical safety awareness is critical to reducing the risk of accidents.

Modern electrical systems are becoming more and more complex, including automated control systems and smart devices. Electricians need to know how to operate and maintain these systems to ensure their reliability and efficiency, to develop the actual operating skills of electricians, need electricians 'test equipment to provide experimental and simulation environments, to allow students to perform actual operations under safe conditions, electricians' training is often required to be combined with skill assessment and certification systems to ensure that the students have the necessary skill level and to pass corresponding certification tests, and different types of electrical equipment and control systems need different operation and maintenance methods, so different types of electrical control methods and systems need to be studied to meet the needs of different fields.

For example, the patent application publication number CN115201543a discloses a control method of an electrical device comprising three phases respectively connected to the three phases of the electrical network, and which makes it possible to determine an alarm based on a comparison between specific parameters associated with each phase and obtained from the temperature and current measurements of each phase.

However, the above method has a certain limitation, including limited coverage, and no consideration of the influence of personnel operation on the safety of the equipment, and at this time, an electrical control method capable of simultaneously considering the influence of personnel operation and the influence of the internal environment of the equipment is needed, so the application provides an electrical control method and an electrical control system for an automatic production line of an electrician examination and culture equipment.

Disclosure of Invention

The application aims to provide an electrical control method and system for an automatic production line of an electrician examination and culture device, so as to solve the problems in the background technology.

In order to achieve the above purpose, the present application provides the following technical solutions: an electrical control method for an automatic production line of an electrician examination and culture device, comprising the following steps:

s1, extracting all skill standard operation sequences, writing the skill standard operation sequences into a first standard operation sequence set, and writing the actual operation sequences of the examinees into a second actual operation sequence;

s2, judging whether to give a warning to the examinee by comparing the first standard operation sequence set with the second actual operation sequence;

s3, monitoring valve danger coefficient in real time in the operation process of the examineeSetting the valve initial safety value +.>And valve hazard safety value->When the valve danger coefficient is more than or equal to the valve initial safety value +.>And less than or equal to the valve dangerous safety value +.>When the valve danger coefficient is larger than the valve danger safety value +.>If the valve risk factor is smaller than the valve initial safety value +.>S5, performing;

s4, setting a circuit safety strategy and a circuit safety threshold valueAnd->Calculating a circuit hazard value for the average value of the current, the voltage and the temperature in the device in the combined circuit>Setting a judging function->、/>And->If the judging function->If yes, S5 is performed, if yes, the judgment function +.>If not, according to the judgment function +.>And->Judging that the equipment takes measures;

s5, monitoring the safety coefficient of the equipment in real time, and setting the safety coefficient indexAnd calculating the safety coefficient of the equipment by combining the current, the voltage, the temperature in the equipment and the vibration frequency in the circuit, and judging whether to start the circuit breaker to cut off the power supply of the equipment.

The application is further improved in that the first set of standard operation sequences is obtained by sequentially writing the standard electrician operation sequences of all skills into the operation sequences，/>Indicate->First step of middle skills>Seed operationSequence of->Indicate->Step of writing the operation sequence of each skill into skill standard operation set ++>Skill standard operation set>Writing a first set of standard operation sequences +.>Obtained by (a) a->，/>Representing common->An operation skill.

The application is further improved in that the specific step S2 comprises the following steps:

s21, positioning the first standard operation sequence setSkill standard operation set corresponding to actual operation skill in (2)>Wherein->Indicate->Middle skills are all->Seed operation sequenceA column;

s22, recording the first operation as 'examinee operation 1' when the examinee performs the first operation, and recording the 'examinee operation 1' into a second actual operation sequence；

S23, setting a condition functionIf->If so, the test taker continues to operate and updates the second actual operating sequence +.>If->If not, giving an alarm to the examinee;

s24, repeating the steps S22 and S23 until the operation of the examinee is finished.

The application is further improved in that the valve risk factorThe valve switch of the electrician examination and culture equipment is provided with a pressure sensor by combining the valve pressure value and the valve opening time to obtain the +.>The pressure value of the individual valves->Measure->Valve opening time->The calculation formula of the valve danger coefficient is +.>。

The application further improves that the specific content of the S4 comprises the following steps:

s41, measuring voltage conditions and current conditions in equipment, uniformly installing temperature sensors in the equipment, obtaining equipment temperature data and deriving the equipment temperature data;

s42, substituting the data obtained in the step S41 into a circuit hazard calculation strategy to calculate a circuit hazard value。

The application further improves that the specific content of the S41 comprises the following steps:

s411, measuring all voltage data sets of equipmentCurrent data setWherein->Representing the number of voltages measured, +.>Representing the measured current quantity;

s412, uniformly installing in the equipmentExtracting measured values of all temperature sensors to be listed in a temperature data set +.>Wherein->Indicate->The measured values of the individual temperature sensors.

The application further improves that the specific steps of the circuit danger calculation strategy are as follows:

s421, extracting the minimum value of the voltage data setMaximum value of current data set->Mean value of the temperature in the device->；

S422, importing the data extracted in S421 into a dangerous value of a dangerous calculation strategy calculation circuitWherein->Weight of current data, +.>Is the weight of the voltage data, +.>Is a weight of the temperature data.

The application is further improved in that the judging functionThe calculation formula of (2) is as follows:if judge->If yes, S5 is performed, if yes>If not, running the judgment function +.>And->If judge->If yes, starting the circuit breaker to cut off the power supply of the equipment, and if yes, judging +.>If so, starting the circuit breaker to cut off the power supply of the equipment and immediately starting the cooling measure.

The application is further improved in that the safety factorThe calculation steps of (a) are as follows:

s51, acquiring the time of the equipmentA set of speeds of vibration within seconds, said time +.>The speed acquisition frequency in seconds is every +.>Collecting once per second to obtain time ∈ ->Speed set of vibrations in seconds +.>；

S52, computing device is in timeMean acceleration of vibration in seconds +.>And average speed；

S53, measuring equipment in timeDistance of displacement of vibration in seconds +.>Safety factor->The calculation formula of (2) isWherein->Weight of current data, +.>Is the weight of the voltage data, +.>Weight of temperature data, +.>Weight of displacement distance of vibration, +.>Weight of average speed +.>Is the weight of the average acceleration.

The application is further improved in that the step S5 is performed by a safety factor indexAnd safety factor->The relation between them is judged when +.>And when the circuit breaker is started, the power supply of the equipment is cut off.

In another aspect, the present application provides an electrical control system for an automated production line of an electrician examination and culture apparatus, comprising:

the operation input module is used for extracting all skill standard operation sequences and writing the skill standard operation sequences into a first standard operation sequence set, writing the actual operation sequences of the examinees into a second actual operation sequence, and judging whether to give a warning to the examinees by comparing the first standard operation sequence set with the second actual operation sequence;

the operation danger monitoring module is used for monitoring valve danger coefficient in real time in the operation process of the examineeSetting the valve initial safety value +.>And valve hazard safety value->By comparing the valve risk factor with the valve initial safety value +.>And valve hazard safety value->Judging whether to give an alarm to the examinee or not and judging that the equipment takes measures;

the circuit safety monitoring module is used for setting a circuit safety strategy and a circuit safety threshold valueAnd->Calculating a circuit hazard value for the average value of the current, the voltage and the temperature in the device in the combined circuit>Setting a judging function->、/>And->Judging that the equipment takes measures;

and the equipment safety monitoring module monitors the equipment safety coefficient in real time, calculates the equipment safety coefficient by combining the current, the voltage, the temperature in the equipment and the vibration frequency in the circuit, and judges whether to start the circuit breaker to cut off the power supply of the equipment.

The application is further improved in that the operation input module comprises a first standard operation sequence set acquisition unit, a second actual operation sequence acquisition unit and an operation set comparison unit; the first standard operation sequence set acquisition unit is used for extracting all skill standard operation sequences and writing the skill standard operation sequences into a first standard operation sequence set; the second actual operation sequence acquisition unit is used for writing the actual operation sequence of the examinee into a second actual operation sequence; the operation set comparison unit is used for comparing the first standard operation sequence set and the second actual operation sequence, and judging whether to give a warning to the examinee.

An electronic device, comprising: a processor and a memory, wherein the memory stores a computer program for the processor to call;

the processor executes the automatic production line electrical control method of the electrical examination and culture equipment by calling the computer program stored in the memory.

A computer readable storage medium storing instructions that, when executed on a computer, cause the computer to perform any one of the above-described automated production line electrical control methods of an electrical test culture device.

Compared with the prior art, the application has the beneficial effects that:

1. according to the application, firstly, all skill standard operation sequences are extracted and written into a first standard operation sequence set, the actual operation sequence of the examinee is written into a second actual operation sequence, and then the first standard operation sequence set and the second actual operation sequence are compared, so that the real-time monitoring of the operation of the examinee is realized, an alarm can be given to the examinee when the operation of the examinee is wrong, and the examinee can correct the operation in time conveniently;

2. secondly, the valve danger coefficient is monitored in real time through the valve pressure and the opening time in the operation process of the examinee, so that the equipment damage caused by improper operation of the examinee can be reduced; the equipment is timely subjected to power-off processing through calculating the dangerous value of the internal circuit of the equipment and the safety coefficient of the equipment, so that the effect of monitoring the equipment risk caused by the operation influence of personnel and the internal environment influence of the equipment in real time is realized.

Drawings

FIG. 1 is a flow chart of an electrical control method of an automatic production line of an electrician examination and culture device;

FIG. 2 is a block diagram of an electrical control system of an automatic production line of an electrician examination and culture device according to the present application;

FIG. 3 shows a schematic diagram of the apparatus of the present application;

fig. 4 shows a schematic diagram of a storage medium according to the present application.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments.

Example 1

Fig. 1 shows a flowchart of an electrical control method of an automatic production line of an electrician examination and culture device, which comprises the following specific steps:

s1, extracting all skill standard operation sequences, writing the skill standard operation sequences into a first standard operation sequence set, and writing the actual operation sequences of the examinees into a second actual operation sequence;

the first standard operation sequence set is formed by sequentially writing the standard electrician operation sequences of all skills into the operation sequence，/>Indicate->First step of middle skills>Seed sequence of operations->Indicate->Step of writing the operation sequence of each skill into skill standard operation set ++>Skill standard operation set>Writing a first set of standard operation sequences +.>Obtained by (a) a->，/>Representing common->Seed operation skills;

s2, judging whether to give a warning to the examinee by comparing the first standard operation sequence set with the second actual operation sequence;

s21, positioning the first standard operation sequence setSkill standard operation set corresponding to actual operation skill in (2)>Wherein->Indicate->Middle skills are all->A seed operation sequence;

s22, recording the first operation as 'examinee operation 1' when the examinee performs the first operation, and recording the 'examinee operation 1' into a second actual operation sequence；

S23, setting a condition functionIf->If so, the test taker continues to operate and updates the second actual operating sequence +.>If->If not, giving an alarm to the examinee;

s24, repeating the steps S22 and S23 until the operation of the examinee is finished.

In this embodiment, the valve risk factorThe valve switch of the electrician examination and culture equipment is provided with a pressure sensor by combining the valve pressure value and the valve opening time to obtain the +.>The pressure value of the individual valves->Measure->Valve opening time->The calculation formula of the valve danger coefficient is +.>。

S3, monitoring valve danger coefficient in real time in the operation process of the examineeSetting the valve initial safety value +.>And valve hazard safety value->When the valve danger coefficient is more than or equal to the valve initial safety value +.>And less than or equal to the valve dangerous safety value +.>When the valve danger coefficient is larger than the valve danger safety value +.>If the valve risk factor is smaller than the valve initial safety value +.>S5, performing;

s4, setting a circuit safety strategy and a circuit safety threshold valueAnd->Calculating circuit hazard values from average values of current, voltage and temperature in equipment in combined circuit/>Setting a judging function->、/>And->If the judging function->If yes, S5 is performed, if yes, the judgment function +.>If not, according to the judgment function +.>And->Judging that the equipment takes measures;

s41, measuring voltage conditions and current conditions in equipment, uniformly installing temperature sensors in the equipment, obtaining equipment temperature data and deriving the equipment temperature data;

s42, substituting the data obtained in the step S41 into a circuit hazard calculation strategy to calculate a circuit hazard value。

In this embodiment, the specific content of S41 includes the following steps:

s411, measuring all voltage data sets of equipmentCurrent data setWherein->Representing the number of voltages measured, +.>Representing the measured current quantity;

s412, uniformly installing in the equipmentExtracting measured values of all temperature sensors to be listed in a temperature data set +.>Wherein->Indicate->The measured values of the individual temperature sensors.

In this embodiment, the specific steps of the circuit hazard calculation strategy are as follows:

s421, detecting performance problems, overload conditions or other current related anomalies of the electrical components by monitoring the current, wherein the current in the circuit is not too large, and the too low voltage value in the electrical components represents a sign of reduced equipment performance, thereby extracting the minimum value of the voltage data setMaximum value of current data set->Mean value of the temperature in the device->；

S422, importing the data extracted in S421 into a dangerous value of a dangerous calculation strategy calculation circuitWherein->Weight of current data, +.>Is the weight of the voltage data, +.>Is a weight of the temperature data.

In this embodiment, the judgment functionThe calculation formula of (2) is as follows:if judge->If yes, S5 is performed, if yes>If not, running the judgment function +.>And->If judge->If yes, starting the circuit breaker to cut off the power supply of the equipment, and if yes, judging +.>If so, starting the circuit breaker to cut off the power supply of the equipment and immediately starting the cooling measure.

S5, monitoring the safety coefficient of the equipment in real time, and setting the safety coefficient indexCalculating the safety coefficient of the equipment by combining the current, the voltage, the temperature in the equipment and the vibration frequency in the circuit, and judging whether to start the circuit breaker to cutThe equipment is powered off, abnormal vibration may indicate a malfunction or imbalance of the mechanical components, and therefore the vibration frequency of the computing equipment should be considered in the calculation of the safety factor;

s51, acquiring the time of the equipmentA set of speeds of vibration within seconds, said time +.>The speed acquisition frequency in seconds is every +.>Collecting once per second to obtain time ∈ ->Speed set of vibrations in seconds +.>；

S52, computing device is in timeMean acceleration of vibration in seconds +.>And average speed；

S53, measuring equipment in timeDistance of displacement of vibration in seconds +.>Safety factor->The calculation formula of (2) isWherein->Weight of current data, +.>Is the weight of the voltage data, +.>Weight of temperature data, +.>Weight of displacement distance of vibration, +.>Weight of average speed +.>Weight for average acceleration;

in this embodiment, the step S5 is performed by a safety factor indexAnd safety factor->The relation between them is judged when +.>And when the circuit breaker is started, the power supply of the equipment is cut off.

Example 2

An electrical control system of an automatic production line of an electrician examination and culture device, which is realized based on the electrical control method of the automatic production line of the electrician examination and culture device: FIG. 2 shows a frame diagram of an electrical control system of an automatic production line of an electrician examination and culture device, comprising:

the operation input module is used for extracting all skill standard operation sequences and writing the skill standard operation sequences into a first standard operation sequence set, writing the actual operation sequences of the examinees into a second actual operation sequence, and judging whether to give a warning to the examinees by comparing the first standard operation sequence set with the second actual operation sequence;

the operation danger monitoring module is used for monitoring valve danger coefficient in real time in the operation process of the examineeSetting the valve initial safety value +.>And valve hazard safety value->By comparing the valve risk factor with the valve initial safety value +.>And valve hazard safety value->Judging whether to give an alarm to the examinee or not and judging that the equipment takes measures;

the circuit safety monitoring module is used for setting a circuit safety strategy and a circuit safety threshold valueAnd->Calculating a circuit hazard value for the average value of the current, the voltage and the temperature in the device in the combined circuit>Setting a judging function->、/>And->Judging that the equipment takes measures;

and the equipment safety monitoring module monitors the equipment safety coefficient in real time, calculates the equipment safety coefficient by combining the current, the voltage, the temperature in the equipment and the vibration frequency in the circuit, and judges whether to start the circuit breaker to cut off the power supply of the equipment.

In this embodiment, the operation input module includes a first standard operation sequence set acquisition unit, a second actual operation sequence acquisition unit, and an operation set comparison unit; the first standard operation sequence set acquisition unit is used for extracting all skill standard operation sequences and writing the skill standard operation sequences into a first standard operation sequence set; the second actual operation sequence acquisition unit is used for writing the actual operation sequence of the examinee into a second actual operation sequence; the operation set comparison unit is used for comparing the first standard operation sequence set and the second actual operation sequence, and judging whether to give a warning to the examinee.

Example 3

Fig. 3 shows a schematic device diagram of the present application, and this embodiment provides an electronic device, including: a processor and a memory, wherein the memory stores a computer program for the processor to call;

the processor executes the automatic production line electrical control method of the electrician examination and culture equipment by calling the computer program stored in the memory.

The electronic device can generate larger difference due to different configurations or performances, and can comprise one or more processors (Central Processing Units, CPU) and one or more memories, wherein at least one computer program is stored in the memories, and the computer program is loaded and executed by the processors to realize the automatic production line electrical control method of the electrical test equipment provided by the embodiment of the method. The electronic device can also include other components for implementing the functions of the device, for example, the electronic device can also have wired or wireless network interfaces, input-output interfaces, and the like, for inputting and outputting data. The present embodiment is not described herein.

Example 4

FIG. 4 shows a schematic diagram of a storage medium according to the present application, and this embodiment proposes a computer readable storage medium 200, on which a computer program is stored that is erasable;

when the computer program runs on the computer equipment, the computer equipment is caused to execute the automatic production line electrical control method of the electrician examination and culture equipment.

For example, the computer readable storage medium 200 can be Read-Only Memory (ROM), random access Memory (Random Access Memory, RAM), compact disk Read-Only Memory (Compact Disc Read-Only Memory, CD-ROM), magnetic tape, floppy disk, optical data storage device, etc.

It should be understood that, in various embodiments of the present application, the sequence numbers of the foregoing processes do not mean the order of execution, and the order of execution of the processes should be determined by the functions and internal logic thereof, and should not constitute any limitation on the implementation process of the embodiments of the present application.

It should be understood that determining B from a does not mean determining B from a alone, but can also determine B from a and/or other information.

The above embodiments may be implemented in whole or in part by software, hardware, firmware, or any other combination. When implemented in software, the above-described embodiments may be implemented in whole or in part in the form of a computer program product. The computer program product comprises one or more computer instructions or computer programs. When the computer instructions or computer program are loaded or executed on a computer, the processes or functions in accordance with embodiments of the present application are produced in whole or in part. The computer may be a general purpose computer, a special purpose computer, a computer network, or other programmable apparatus. The computer instructions may be stored in or transmitted from one computer-readable storage medium to another, for example, by way of wired or/and wireless networks from one website site, computer, server, or data center to another. Computer readable storage media can be any available media that can be accessed by a computer or data storage devices, such as servers, data centers, etc. that contain one or more collections of available media. The usable medium may be a magnetic medium (e.g., floppy disk, hard disk, magnetic tape), an optical medium (e.g., DVD), or a semiconductor medium. The semiconductor medium may be a solid state disk.

It will be appreciated by those skilled in the art that embodiments of the present application may be provided as a method, system, or computer program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.

The present application is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems) and computer program products according to embodiments of the application. It will be understood that each flow and/or block of the flowchart illustrations and/or block diagrams, and combinations of flows and/or blocks in the flowchart illustrations and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

The embodiments of the present application have been described above with reference to the accompanying drawings, but the present application is not limited to the above-described embodiments, which are merely illustrative and not restrictive, and many forms may be made by those having ordinary skill in the art without departing from the spirit of the present application and the scope of the claims, which are all within the protection of the present application.

Claims (14)

1. An electrical control method for an automatic production line of an electrician examination and culture device is characterized by comprising the following steps of: the method comprises the following specific steps:

s1, extracting all skill standard operation sequences, writing the skill standard operation sequences into a first standard operation sequence set, and writing the actual operation sequences of the examinees into a second actual operation sequence;

s2, judging whether to give a warning to the examinee by comparing the first standard operation sequence set with the second actual operation sequence;

s3, monitoring valve danger coefficient in real time in the operation process of the examineeSetting the valve initial safety value +.>And valve hazard safety value->When the valve danger coefficient is more than or equal to the valve initial safety value +.>And less than or equal to the valve dangerous safety value +.>When the valve danger coefficient is larger than the valve danger safety value +.>If the valve risk factor is smaller than the valve initial safety value +.>S5, performing;

s4, setting a circuit safety strategy and a circuit safety threshold valueAnd->Calculating a circuit hazard value for the average value of the current, the voltage and the temperature in the device in the combined circuit>Setting a judging function->、/>And->If the judging function->If yes, S5 is performed, if yes, the judgment function +.>If not, according to the judgment function +.>Andjudging that the equipment takes measures;

s5, monitoring the safety coefficient of the equipment in real time, and setting the safety coefficient indexAnd calculating the safety coefficient of the equipment by combining the current, the voltage, the temperature in the equipment and the vibration frequency in the circuit, and judging whether to start the circuit breaker to cut off the power supply of the equipment.

2. The electrical control method for an automatic production line of an electrotechnical examination and culture device according to claim 1, wherein the method comprises the following steps: the first standard operation sequence set is formed by sequentially writing the standard electrician operation sequences of all skills into the operation sequence，/>Indicate->First step of middle skills>Seed sequence of operations->Indicate->Step of writing the operation sequence of each skill into skill standard operation set ++>Skill standard operation set>Writing a first set of standard operation sequences +.>Obtained by (a) a->，/>Representing common->An operation skill.

3. The electrical control method for an automatic production line of an electrotechnical examination and culture device according to claim 2, wherein the method comprises the following steps: the specific step of S2 comprises the following steps:

s21, positioning the first standard operation sequence setSkill standard operation set corresponding to actual operation skill in the processWherein->Indicate->Middle skills are all->A seed operation sequence;

s22, recording the first operation as 'examinee operation 1' when the examinee performs the first operation, and recording the 'examinee operation 1' into a second actual operation sequence；

S23, setting a condition functionIf->If yes, the examinee continues to operate and updates the second actual operation sequenceIf->If not, giving an alarm to the examinee;

s24, repeating the steps S22 and S23 until the operation of the examinee is finished.

4. An electrical control method for an automated production line of an electrotechnical test culture device according to claim 3, wherein: the valve risk coefficientThe valve switch of the electrician examination and culture equipment is provided with a pressure sensor by combining the valve pressure value and the valve opening time to obtain the +.>The pressure value of the individual valves->Measure->Valve opening time->The calculation formula of the valve danger coefficient is +.>。

5. The electrical control method for an automatic production line of an electrotechnical examination and culture device according to claim 4, wherein the method comprises the following steps: the specific content of the S4 comprises the following steps:

s41, measuring voltage conditions and current conditions in equipment, uniformly installing temperature sensors in the equipment, obtaining equipment temperature data and deriving the equipment temperature data;

s42, substituting the data obtained in the step S41 into a circuit hazard calculation strategy to calculate a circuit hazard value。

6. The electrical control method for an automatic production line of an electrotechnical examination and culture device according to claim 5, wherein the method comprises the following steps: the specific content of S41 includes the following steps:

s411, measuring all voltage data sets of equipmentCurrent data set->Wherein->Representing the number of voltages measured, +.>Representing the measured current quantity;

s412, uniformly installing in the equipmentExtracting measured values of all temperature sensors to be listed in a temperature data set +.>Wherein->Indicate->The measured values of the individual temperature sensors.

7. The electrical control method for an automatic production line of an electrotechnical examination and culture device according to claim 6, wherein the method comprises the following steps: the circuit hazard calculation strategy comprises the following specific steps:

s421, extracting the minimum value of the voltage data setMaximum value of current data set->Mean value of the temperature in the device->；

S422, importing the data extracted in S421 into a dangerous value of a dangerous calculation strategy calculation circuitWherein->Weight of current data, +.>Is the weight of the voltage data, +.>Is a weight of the temperature data.

8. The electrical control method for an automatic production line of an electrotechnical examination and culture apparatus according to claim 7, wherein: the judging functionThe calculation formula of (2) is as follows: />If judgeIf yes, S5 is performed, if yes>If not, running the judgment functionAnd->If judge->If yes, starting the circuit breaker to cut off the power supply of the equipment, and if yes, judging +.>If so, starting the circuit breaker to cut off the power supply of the equipment and immediately starting the cooling measure.

9. The electrical control method for an automatic production line of an electrotechnical examination and culture device according to claim 8, wherein the method comprises the following steps: the safety coefficientThe calculation steps of (a) are as follows:

s51, acquiring the time of the equipmentA set of speeds of vibration within seconds, said time +.>Speed acquisition frequency in secondsFor every->Collecting once per second to obtain time ∈ ->Speed set of vibrations in seconds +.>；

S52, computing device is in timeMean acceleration of vibration in seconds +.>And average speed；

S53, measuring equipment in timeDistance of displacement of vibration in seconds +.>Safety factor->The calculation formula of (2) isWherein->Weight of current data, +.>Is the weight of the voltage data, +.>Weight of temperature data, +.>Weight of displacement distance of vibration, +.>Weight of average speed +.>Is the weight of the average acceleration.

10. The electrical control method for an automatic production line of an electrotechnical examination and culture device according to claim 9, wherein the method comprises the following steps: said step S5 is performed by a safety factor indexAnd safety factor->The relation between them is judged when +.>And when the circuit breaker is started, the power supply of the equipment is cut off.

11. An electrical control system for an automatic production line of an electrical examination and culture device, which is realized based on an electrical control method for an automatic production line of an electrical examination and culture device according to any one of claims 1-10, and is characterized in that: comprising the following steps:

the operation input module is used for extracting all skill standard operation sequences and writing the skill standard operation sequences into a first standard operation sequence set, writing the actual operation sequences of the examinees into a second actual operation sequence, and judging whether to give a warning to the examinees by comparing the first standard operation sequence set with the second actual operation sequence;

the operation danger monitoring module is used for monitoring valve danger coefficient in real time in the operation process of the examineeSetting the valve initial safety value +.>And valve hazard safety value->By comparing the valve risk factor with the valve initial safety value +.>And valve hazard safety value->Judging whether to give an alarm to the examinee or not and judging that the equipment takes measures;

the circuit safety monitoring module is used for setting a circuit safety strategy and a circuit safety threshold valueAnd->Calculating a circuit hazard value for the average value of the current, the voltage and the temperature in the device in the combined circuit>Setting a judging function->、And->Judging that the equipment takes measures;

and the equipment safety monitoring module monitors the equipment safety coefficient in real time, calculates the equipment safety coefficient by combining the current, the voltage, the temperature in the equipment and the vibration frequency in the circuit, and judges whether to start the circuit breaker to cut off the power supply of the equipment.

12. An automated production line electrical control system for an electrotechnical exam culture apparatus according to claim 11, wherein: the operation input module comprises a first standard operation sequence set acquisition unit, a second actual operation sequence acquisition unit and an operation set comparison unit; the first standard operation sequence set acquisition unit is used for extracting all skill standard operation sequences and writing the skill standard operation sequences into a first standard operation sequence set; the second actual operation sequence acquisition unit is used for writing the actual operation sequence of the examinee into a second actual operation sequence; the operation set comparison unit is used for comparing the first standard operation sequence set and the second actual operation sequence, and judging whether to give a warning to the examinee.

13. An electronic device, comprising: a processor and a memory, wherein the memory stores a computer program for the processor to call;

the processor executes an automatic production line electrical control method of the electrical examination apparatus according to any one of claims 1 to 10 by calling a computer program stored in the memory.

14. A computer-readable storage medium, characterized by: instructions stored thereon which, when executed on a computer, cause the computer to perform a method for controlling the electrical production line of an electrical examination apparatus according to any one of claims 1-10.