CN116667203B - Electric power basic operation safety protection method and system based on gas detector - Google Patents

Abstract

The application relates to a safety protection method and a safety protection system for electric power basic operation based on a gas detector, which sequentially obtain the selected requirement data of the detector set by a main body of the current electric power basic operation, obtain the data of the used gas detector and generate the current comprehensive requirement data; generating a current required safety evaluation value, selecting a target gas detector, generating a detector recommendation instruction according to the target gas detector, starting a camera module and a dialogue module of the target gas detector, and acquiring a working environment image and real-time voice transmission data around a current power basic operation main body; and acquiring the muscle state data of the current power basic operation main body, and carrying out safety protection according to the muscle state data, the working environment image and the real-time voice transmission data. The application realizes the active and passive aspects to carry out the safety protection of the current power basic operation main body, and improves the safety protection coefficient and the safety protection level.

Description

Electric power basic operation safety protection method and system based on gas detector

Technical Field

The application relates to the technical field of electric power operation, in particular to an electric power basic operation safety protection method and system based on a gas detector.

Background

In some electric power engineering, cables, pile foundations, equipment foundations and the like need to be constructed or adjusted, wherein the related underground facilities need to adopt a foundation pit operation mode. For example: and (3) cabling: in the power transmission and distribution process, cabling is needed, so that a foundation pit with a certain depth is dug, a supporting system is installed in the pit, and then relevant setting and laying are needed. Or the construction of the equipment foundation is adjusted, so that in order to ensure the stable operation of the equipment and the load bearing capacity of the equipment, constructors need to frequently check and repair the equipment according to the needs. At this time, the foundation pit needs to be opened to expose the equipment and perform maintenance and adjustment.

In addition, the power transmission and transformation station or the electric tower foundation is adjusted: in some cases, the foundation of the electric wire tower or the transformer substation needs to be rebuilt or dismantled for the reasons of land subsidence, wind disaster, water disaster and the like. This requires a pit operation to shift and reset the equipment in order. When the foundation pit is used for working, attention is paid to the fact that when the depth is increased, higher working difficulty and risk are brought to field personnel, and when dangerous situations including but not limited to toxic gas and the like exist in the foundation pit, the working personnel are required to use a gas detector to assist in working.

However, the current gas detector is used for electric power operation, and the safety protection level is not high.

Disclosure of Invention

In view of the above, it is necessary to provide a method and a system for protecting safety of electric power foundation work based on a gas detector, which can provide a safety protection level.

The technical scheme of the invention is as follows:

a gas detector-based power base operation safety protection method, the method comprising:

acquiring detector selection requirement data set by a current power basic operation main body, acquiring used gas detector data used by the current power basic operation main body in a preset time period, and generating current comprehensive requirement data according to the detector selection requirement data and the used gas detector data; performing data analysis on the current comprehensive requirement data based on a gas detector recommendation engine, generating a current requirement safety evaluation value after the analysis is completed, selecting a target gas detector from a pre-stored instrument database according to the current requirement safety evaluation value, and generating a detector recommendation instruction according to the target gas detector, wherein the detector recommendation instruction is used for instructing the current power basic operation main body to take the target gas detector; responding to the current power basic operation main body to trigger the target gas detector, starting a camera module and a dialogue module of the target gas detector, and acquiring working environment images and real-time voice transmission data around the current power basic operation main body; and acquiring muscle state data of the current electric power basic operation main body based on the target gas detector, and performing safety protection according to the muscle state data, the working environment image and the real-time voice transmission data.

Specifically, acquiring detector selection requirement data set by a current power basic operation main body, acquiring used gas detector data used by the current power basic operation main body in a preset time period, and generating current comprehensive requirement data according to the detector selection requirement data and the used gas detector data; the method specifically comprises the following steps:

acquiring a selected trigger instruction selected by a detector by a current power foundation operation main body, and generating a foundation pit work guiding interface according to the selected trigger instruction, wherein the foundation pit work guiding interface is used for displaying a foundation pit condition input field; acquiring actual foundation pit environment data of a current foundation pit, which are input by the current power foundation operation main body in the foundation pit condition input field; analyzing the danger level of the foundation pit according to the actual foundation pit environment data, and generating a current estimated danger level of the foundation pit; generating a standard recommendation detector according to the pre-estimated risk level of the current foundation pit, wherein the standard recommendation detector comprises a plurality of actual detector parameters; displaying each actual detector parameter to the current power basic operation main body, and acquiring the current revised parameters of the current power basic operation main body on the actual detector parameters; correcting the parameters of the actual detector according to the current revised parameters, and generating the selected requirement data of the detector; acquiring used gas detector data used by the current power basic operation main body in a preset time period in response to generation of the detector selection request data; comparing the used gas detector data with the detector selected requirement data, and obtaining difference parameter data, wherein the difference parameter data is a parameter which is possessed by the used gas detector data and is not possessed by the detector selected requirement data; and modifying the selected requirement data of the detector according to the difference parameter data, and generating current comprehensive requirement data.

Specifically, based on a gas detector recommendation engine, carrying out data analysis on the current comprehensive requirement data, generating a current requirement safety evaluation value after the analysis is completed, selecting a target gas detector from a pre-stored instrument database according to the current requirement safety evaluation value, and generating a detector recommendation instruction according to the target gas detector; the method specifically comprises the following steps:

performing feature splitting on the current comprehensive requirement data, and generating a plurality of refinement basic requirement parameters after the feature splitting is completed; comparing each refinement basic requirement parameter with each standard gas detection parameter table, and obtaining an actual gap parameter, wherein one refinement basic requirement parameter corresponds to one standard gas detection parameter table, the standard gas detection parameter table comprises a plurality of standard detection parameters, and one refinement basic requirement parameter corresponds to one actual gap parameter after being compared with one standard detection parameter; sorting a plurality of actual gap parameters corresponding to the basic requirement parameters for refining, screening out the actual gap parameters with the smallest values, and setting the screened actual gap parameters as screening gap parameters; obtaining corresponding standard detection parameters according to the screening gap parameters, generating actual security levels according to the standard detection parameters, and generating actual gap levels according to the screening gap parameters, wherein one refinement basic requirement parameter corresponds to one actual gap level and one actual security level; generating a current required safety evaluation value according to the actual gap grade and the actual safety grade based on a gas detector recommendation engine by the following formula:

Wherein Q is the current required safety evaluation value, n is the number of the refined basic requirement parameters, P (x) is the actual gap grade corresponding to the n refined basic requirement parameters, and T (x) is the actual safety grade corresponding to the n refined basic requirement parameters; responding to the generation of the current required safety evaluation value, acquiring standard detection instruments in a stored instrument database, and acquiring standard detection safety values of the standard detection instruments; comparing each standard detection safety value with the current required safety evaluation value, and screening out a standard detection safety value matched with the current required safety evaluation value; and setting a standard detection instrument corresponding to the screened standard detection safety value as a target gas detector, and generating a detector recommended instruction according to the target gas detector.

Specifically, acquiring muscle state data of the current power basic operation main body based on the target gas detector, and performing safety protection according to the muscle state data, the working environment image and real-time voice transmission data; the method specifically comprises the following steps:

acquiring a pre-stored acquisition time interval in response to acquiring the working environment image and the real-time voice transmission data; acquiring initial muscle electrical signals of the current power basic operation main body in each acquisition time interval based on the target gas detector according to the acquisition time interval as a unit; acquiring pre-stored interference signal waveforms, screening the initial muscle electric signals according to the interference signal waveforms, and generating initial screening electric signals after screening; acquiring blank electric signals in the initial screening electric signals, acquiring blank signal lengths and blank signal quantity of the blank electric signals, and generating blank signal quality according to the blank signal lengths and the blank signal quantity, wherein one initial screening electric signal corresponds to one blank signal quality; removing the initial screening electric signals corresponding to the blank signal quality which is greater than or equal to the standard signal quality, and generating effective muscle electric signals; generating muscle state data from each of the effective muscle electrical signals; and carrying out safety protection according to the muscle state data, the working environment image and the real-time voice transmission data.

Specifically, an electric power basic operation safety protection system based on gas detector, the system includes:

the demand data acquisition module is used for acquiring detector selection demand data set by a current power basic operation main body, acquiring used gas detector data used by the current power basic operation main body in a preset time period, and generating current comprehensive demand data according to the detector selection demand data and the used gas detector data;

the detection instrument selection module is used for carrying out data analysis on the current comprehensive requirement data based on a gas detector recommendation engine, generating a current requirement safety evaluation value after the analysis is completed, selecting a target gas detector from a pre-stored instrument database according to the current requirement safety evaluation value, and generating a detector recommendation instruction according to the target gas detector, wherein the detector recommendation instruction is used for indicating the current power basic operation main body to take the target gas detector;

the environment data acquisition module is used for responding to the current power basic operation main body to trigger the target gas detector, starting a camera module and a dialogue module of the target gas detector and acquiring working environment images and real-time voice transmission data around the current power basic operation main body;

And the safety protection module is used for acquiring the muscle state data of the current power basic operation main body based on the target gas detector and carrying out safety protection according to the muscle state data, the working environment image and the real-time voice transmission data.

Specifically, the demand data acquisition module is further configured to:

acquiring a selected trigger instruction selected by a detector by a current power foundation operation main body, and generating a foundation pit work guiding interface according to the selected trigger instruction, wherein the foundation pit work guiding interface is used for displaying a foundation pit condition input field; acquiring actual foundation pit environment data of a current foundation pit, which are input by the current power foundation operation main body in the foundation pit condition input field; analyzing the danger level of the foundation pit according to the actual foundation pit environment data, and generating a current estimated danger level of the foundation pit; generating a standard recommendation detector according to the pre-estimated risk level of the current foundation pit, wherein the standard recommendation detector comprises a plurality of actual detector parameters; displaying each actual detector parameter to the current power basic operation main body, and acquiring the current revised parameters of the current power basic operation main body on the actual detector parameters; correcting the parameters of the actual detector according to the current revised parameters, and generating the selected requirement data of the detector; acquiring used gas detector data used by the current power basic operation main body in a preset time period in response to generation of the detector selection request data; comparing the used gas detector data with the detector selected requirement data, and obtaining difference parameter data, wherein the difference parameter data is a parameter which is possessed by the used gas detector data and is not possessed by the detector selected requirement data; and modifying the selected requirement data of the detector according to the difference parameter data, and generating current comprehensive requirement data.

Specifically, the detection instrument selection module is further configured to:

performing feature splitting on the current comprehensive requirement data, and generating a plurality of refinement basic requirement parameters after the feature splitting is completed; comparing each refinement basic requirement parameter with each standard gas detection parameter table, and obtaining an actual gap parameter, wherein one refinement basic requirement parameter corresponds to one standard gas detection parameter table, the standard gas detection parameter table comprises a plurality of standard detection parameters, and one refinement basic requirement parameter corresponds to one actual gap parameter after being compared with one standard detection parameter; sorting a plurality of actual gap parameters corresponding to the basic requirement parameters for refining, screening out the actual gap parameters with the smallest values, and setting the screened actual gap parameters as screening gap parameters; obtaining corresponding standard detection parameters according to the screening gap parameters, generating actual security levels according to the standard detection parameters, and generating actual gap levels according to the screening gap parameters, wherein one refinement basic requirement parameter corresponds to one actual gap level and one actual security level; generating a current required safety evaluation value according to the actual gap grade and the actual safety grade based on a gas detector recommendation engine by the following formula:

Wherein Q is the current required safety evaluation value, n is the number of the refined basic requirement parameters, P (x) is the actual gap grade corresponding to the n refined basic requirement parameters, and T (x) is the actual safety grade corresponding to the n refined basic requirement parameters; responding to the generation of the current required safety evaluation value, acquiring standard detection instruments in a stored instrument database, and acquiring standard detection safety values of the standard detection instruments; comparing each standard detection safety value with the current required safety evaluation value, and screening out a standard detection safety value matched with the current required safety evaluation value; and setting a standard detection instrument corresponding to the screened standard detection safety value as a target gas detector, and generating a detector recommended instruction according to the target gas detector.

Specifically, the safety protection module is further used for:

acquiring a pre-stored acquisition time interval in response to acquiring the working environment image and the real-time voice transmission data; acquiring initial muscle electrical signals of the current power basic operation main body in each acquisition time interval based on the target gas detector according to the acquisition time interval as a unit; acquiring pre-stored interference signal waveforms, screening the initial muscle electric signals according to the interference signal waveforms, and generating initial screening electric signals after screening; acquiring blank electric signals in the initial screening electric signals, acquiring blank signal lengths and blank signal quantity of the blank electric signals, and generating blank signal quality according to the blank signal lengths and the blank signal quantity, wherein one initial screening electric signal corresponds to one blank signal quality; removing the initial screening electric signals corresponding to the blank signal quality which is greater than or equal to the standard signal quality, and generating effective muscle electric signals; generating muscle state data from each of the effective muscle electrical signals; and carrying out safety protection according to the muscle state data, the working environment image and the real-time voice transmission data.

A computer device comprising a memory and a processor, said memory storing a computer program, said processor implementing the steps of the gas detector based power base job safety protection method described above when said computer program is executed.

A computer readable storage medium having stored thereon a computer program which when executed by a processor performs the steps of the gas detector based power base job safety protection method described above.

The invention has the following technical effects:

according to the electric power basic operation safety protection method and system based on the gas detector, the detector selection requirement data set by the current electric power basic operation main body are sequentially acquired, the used gas detector data used by the current electric power basic operation main body in a preset time period are acquired, and the current comprehensive requirement data are generated according to the detector selection requirement data and the used gas detector data; performing data analysis on the current comprehensive requirement data based on a gas detector recommendation engine, generating a current requirement safety evaluation value after the analysis is completed, selecting a target gas detector from a pre-stored instrument database according to the current requirement safety evaluation value, and generating a detector recommendation instruction according to the target gas detector, wherein the detector recommendation instruction is used for instructing the current power basic operation main body to take the target gas detector; responding to the current power basic operation main body to trigger the target gas detector, starting a camera module and a dialogue module of the target gas detector, and acquiring working environment images and real-time voice transmission data around the current power basic operation main body; the invention aims to ensure the safety problem of the current power basic operation main body in the process of foundation pit operation, on one hand, the safety protection is carried out from the selection of the gas detector used by the current power basic operation main body, on the other hand, the safety is ensured from the image acquisition and the voice transmission carried out by the gas detector used by the current power basic operation main body, and the actual working state of the current power basic operation main body is reflected through the muscle state data, so that the safety of the current power basic operation main body is ensured from multiple aspects, and the safety protection of the current power basic operation main body is carried out from two aspects of active and passive, thereby improving the safety protection coefficient and the grade.

Drawings

FIG. 1 is a flow chart of a method for protecting safety of power base operation based on a gas detector in one embodiment;

FIG. 2 is a block diagram of a power base operation safety protection system based on a gas detector in one embodiment;

FIG. 3 is an internal block diagram of a computer device in one embodiment.

Detailed Description

The present application will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present application more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the application.

In one embodiment, a terminal is provided for: acquiring detector selection requirement data set by a current power basic operation main body, acquiring used gas detector data used by the current power basic operation main body in a preset time period, and generating current comprehensive requirement data according to the detector selection requirement data and the used gas detector data; performing data analysis on the current comprehensive requirement data based on a gas detector recommendation engine, generating a current requirement safety evaluation value after the analysis is completed, selecting a target gas detector from a pre-stored instrument database according to the current requirement safety evaluation value, and generating a detector recommendation instruction according to the target gas detector, wherein the detector recommendation instruction is used for instructing the current power basic operation main body to take the target gas detector; responding to the current power basic operation main body to trigger the target gas detector, starting a camera module and a dialogue module of the target gas detector, and acquiring working environment images and real-time voice transmission data around the current power basic operation main body; and acquiring muscle state data of the current electric power basic operation main body based on the target gas detector, and performing safety protection according to the muscle state data, the working environment image and the real-time voice transmission data.

The terminal may be, but is not limited to, various personal computers, notebook computers, smart phones, tablet computers, and portable wearable devices.

In one embodiment, as shown in fig. 1, there is provided a gas detector-based power base operation safety protection method, the method comprising:

step S100: acquiring detector selection requirement data set by a current power basic operation main body, acquiring used gas detector data used by the current power basic operation main body in a preset time period, and generating current comprehensive requirement data according to the detector selection requirement data and the used gas detector data;

step S200: performing data analysis on the current comprehensive requirement data based on a gas detector recommendation engine, generating a current requirement safety evaluation value after the analysis is completed, selecting a target gas detector from a pre-stored instrument database according to the current requirement safety evaluation value, and generating a detector recommendation instruction according to the target gas detector, wherein the detector recommendation instruction is used for instructing the current power basic operation main body to take the target gas detector;

Step S300: responding to the current power basic operation main body to trigger the target gas detector, starting a camera module and a dialogue module of the target gas detector, and acquiring working environment images and real-time voice transmission data around the current power basic operation main body;

step S400: and acquiring muscle state data of the current electric power basic operation main body based on the target gas detector, and performing safety protection according to the muscle state data, the working environment image and the real-time voice transmission data.

In this embodiment, in order to ensure a safety problem of the current power foundation operation main body in the process of performing the foundation pit operation, on one hand, safety protection is performed by selecting a gas detector used by the current power foundation operation main body, specifically, selecting requirement data of the detector set by the current power foundation operation main body is obtained, used gas detector data used by the current power foundation operation main body in a preset time period is obtained, and current comprehensive requirement data is generated according to the selected requirement data of the detector and the used gas detector data; then, based on a gas detector recommendation engine, carrying out data analysis on the current comprehensive requirement data, generating a current requirement safety evaluation value after the analysis is completed, selecting a target gas detector from a pre-stored instrument database according to the current requirement safety evaluation value, and generating a detector recommendation instruction according to the target gas detector; on the other hand, the safety is ensured by image acquisition and voice transmission performed by the gas detector used by the current power basic operation main body, and the actual working state of the current power basic operation main body is reflected by muscle state data, specifically, the target gas detector is triggered by responding to the current power basic operation main body, a camera module and a dialogue module of the target gas detector are started, and the working environment image and real-time voice transmission data around the current power basic operation main body are obtained; then, based on the target gas detector, muscle state data of the current electric power basic operation main body are obtained, safety protection is carried out according to the muscle state data, the working environment image and the real-time voice transmission data, further, the safety in use is guaranteed from multiple aspects, and further, the safety protection of the current electric power basic operation main body is carried out in two aspects of active and passive, and the safety protection coefficient and the safety protection grade are improved.

In one embodiment, step S100: acquiring detector selection requirement data set by a current power basic operation main body, acquiring used gas detector data used by the current power basic operation main body in a preset time period, and generating current comprehensive requirement data according to the detector selection requirement data and the used gas detector data; the method specifically comprises the following steps:

step S110: acquiring a selected trigger instruction selected by a detector by a current power foundation operation main body, and generating a foundation pit work guiding interface according to the selected trigger instruction, wherein the foundation pit work guiding interface is used for displaying a foundation pit condition input field;

step S120: acquiring actual foundation pit environment data of a current foundation pit, which are input by the current power foundation operation main body in the foundation pit condition input field;

step S130: analyzing the danger level of the foundation pit according to the actual foundation pit environment data, and generating a current estimated danger level of the foundation pit;

in this step, the actual foundation pit environment data includes soil layer, stone layer, groundwater level, hydrological pressure, distance, type, height of surrounding buildings, etc., where the actual foundation pit environment data is obtained by surveying the current power foundation operation main body before performing foundation pit operation, and data input is performed, then corresponding risk coefficients are generated according to different data, and finally each risk coefficient is added to obtain the estimated risk level of the current foundation pit.

Step S140: generating a standard recommendation detector according to the pre-estimated risk level of the current foundation pit, wherein the standard recommendation detector comprises a plurality of actual detector parameters;

step S150: displaying each actual detector parameter to the current power basic operation main body, and acquiring the current revised parameters of the current power basic operation main body on the actual detector parameters;

step S160: correcting the parameters of the actual detector according to the current revised parameters, and generating the selected requirement data of the detector;

in this embodiment, in order to ensure that the obtained current comprehensive requirement data accords with the usage habit of the current power foundation operation main body, and in order to improve the convenience of the current power foundation operation main body in selecting a gas detector, a selected trigger instruction selected by the detector is obtained by the current power foundation operation main body, and a foundation pit work guiding interface is generated according to the selected trigger instruction, where the foundation pit work guiding interface is used for displaying a foundation pit condition input field; then, acquiring actual foundation pit environment data of the current foundation pit, which are input by the current power foundation operation main body in the foundation pit condition input field; analyzing the foundation pit danger level according to the actual foundation pit environment data, generating a current foundation pit estimated danger level, generating a standard recommended detector according to the current foundation pit estimated danger level, displaying each actual detector parameter to the current power foundation operation main body, and acquiring the current revised parameters of the current power foundation operation main body on the actual detector parameters; and finally, correcting the actual detector parameters according to the current revised parameters, and generating detector selection requirement data, so that the generated detector selection requirement data is comprehensive and accords with the operation habit of the current power basic operation main body.

Step S170: acquiring used gas detector data used by the current power basic operation main body in a preset time period in response to generation of the detector selection request data;

step S180: comparing the used gas detector data with the detector selected requirement data, and obtaining difference parameter data, wherein the difference parameter data is a parameter which is possessed by the used gas detector data and is not possessed by the detector selected requirement data;

step S190: and modifying the selected requirement data of the detector according to the difference parameter data, and generating current comprehensive requirement data.

In this embodiment, in order to ensure that the generated demand data meets the current use demand and the previous use habit of the user, on one hand, the used gas detector data is compared with the detector selection demand data, and difference parameter data is obtained, where the difference parameter data is a parameter possessed by the used gas detector data and a parameter not possessed by the detector selection demand data, so that the difference parameter data compensates the detector selection demand data set currently, thereby realizing reliable and refined generation of data.

In one embodiment, step S200: performing data analysis on the current comprehensive requirement data based on a gas detector recommendation engine, generating a current requirement safety evaluation value after the analysis is completed, selecting a target gas detector from a pre-stored instrument database according to the current requirement safety evaluation value, and generating a detector recommendation instruction according to the target gas detector; the method specifically comprises the following steps:

step S210: performing feature splitting on the current comprehensive requirement data, and generating a plurality of refinement basic requirement parameters after the feature splitting is completed;

step S220: comparing each refinement basic requirement parameter with each standard gas detection parameter table, and obtaining an actual gap parameter, wherein one refinement basic requirement parameter corresponds to one standard gas detection parameter table, the standard gas detection parameter table comprises a plurality of standard detection parameters, and one refinement basic requirement parameter corresponds to one actual gap parameter after being compared with one standard detection parameter;

in this embodiment, the refinement basic requirement parameters at least include a required measurement range, a required measurement precision, a required response time, a display parameter, and the like, and the more the number of the required refinement basic requirement parameters is, the more accurate the current required security evaluation value is finally obtained.

Each standard gas detection parameter corresponds to one refinement basic requirement parameter, and the standard gas detection parameter is data capable of reflecting the requirement of the refinement basic requirement parameter.

Step S230: sorting a plurality of actual gap parameters corresponding to the basic requirement parameters for refining, screening out the actual gap parameters with the smallest values, and setting the screened actual gap parameters as screening gap parameters;

step S240: obtaining corresponding standard detection parameters according to the screening gap parameters, generating actual security levels according to the standard detection parameters, and generating actual gap levels according to the screening gap parameters, wherein one refinement basic requirement parameter corresponds to one actual gap level and one actual security level;

in this embodiment, when an actual security level is generated according to the standard detection parameters, different detection parameters are preset to correspond to different levels, so that when the standard detection parameters are acquired, the actual security registration can be generated by comparison, and similarly, different screening gap parameters also correspond to different levels, so that the actual gap level is generated.

Step S250: generating a current required safety evaluation value according to the actual gap grade and the actual safety grade based on a gas detector recommendation engine by the following formula:

wherein Q is the current required safety evaluation value, n is the number of the refined basic requirement parameters, P (x) is the actual gap grade corresponding to the n refined basic requirement parameters, and T (x) is the actual safety grade corresponding to the n refined basic requirement parameters;

in this embodiment, the gas detector recommendation engine generally employs a sandwich feedforward neural network, and the model can cope with nonlinear input and has adaptive learning capability. Specifically, in the present embodiment, it realizes the production of the current required security evaluation value by the above formula.

Step S260: responding to the generation of the current required safety evaluation value, acquiring standard detection instruments in a stored instrument database, and acquiring standard detection safety values of the standard detection instruments;

step S270: comparing each standard detection safety value with the current required safety evaluation value, and screening out a standard detection safety value matched with the current required safety evaluation value;

step S280: and setting a standard detection instrument corresponding to the screened standard detection safety value as a target gas detector, and generating a detector recommended instruction according to the target gas detector.

In this embodiment, since the sandwiched feedforward neural network is the prior art, the gas detector recommendation engine in this embodiment is not specifically described, and the main innovation point is the above formula.

In one embodiment, step S400: acquiring muscle state data of the current power basic operation main body based on the target gas detector, and performing safety protection according to the muscle state data, the working environment image and real-time voice transmission data; the method specifically comprises the following steps:

step S410: acquiring a pre-stored acquisition time interval in response to acquiring the working environment image and the real-time voice transmission data;

step S420: acquiring initial muscle electrical signals of the current power basic operation main body in each acquisition time interval based on the target gas detector according to the acquisition time interval as a unit;

step S430: acquiring pre-stored interference signal waveforms, screening the initial muscle electric signals according to the interference signal waveforms, and generating initial screening electric signals after screening;

step S440: acquiring blank electric signals in the initial screening electric signals, acquiring blank signal lengths and blank signal quantity of the blank electric signals, and generating blank signal quality according to the blank signal lengths and the blank signal quantity, wherein one initial screening electric signal corresponds to one blank signal quality;

Step S450: removing the initial screening electric signals corresponding to the blank signal quality which is greater than or equal to the standard signal quality, and generating effective muscle electric signals;

step S460: generating muscle state data from each of the effective muscle electrical signals;

step S470: and carrying out safety protection according to the muscle state data, the working environment image and the real-time voice transmission data.

In this embodiment, in order to ensure accuracy of the acquired muscle state data, the initial muscle signals are acquired first, then the interference signal waveforms are filtered, that is, the common muscle signals may have interference of the interference signals, if the acquired initial muscle signals have the interference signal waveforms, the interference signal waveforms are directly filtered, then the blank signals in the initial screening electrical signals are filtered, that is, the blank signal length and the blank signal number of each blank signal are acquired, blank signal quality is generated according to the blank signal length and the blank signal number, then the initial screening electrical signals corresponding to the blank signal quality greater than or equal to the standard signal quality are removed, and effective muscle electrical signals are generated, and finally the muscle state data is generated according to each effective muscle electrical signal.

In one embodiment, when the safety protection is performed according to the muscle state data, the working environment image and the real-time voice transmission data, the safety protection is divided into active protection, specifically, protection judgment is performed according to the working environment image and the real-time voice transmission data, whether the image is dangerous or not is judged according to the working environment image and the real-time voice transmission data, and whether dangerous data are contained in voice transmission or not is judged, if the dangerous data are contained in voice transmission, the gas detector is directly used for carrying out dangerous warning, and rescue workers are prompted to be in place. On the other hand, through passive safety protection, namely through the muscle state data, in this embodiment, the gas detector is connected with the muscle electric signal detection module, namely the muscle electric signal detection module measures the muscle electric signal through placing the electrode near the muscle, and then realizes obtaining the muscle state data, judges whether the muscle tremble is unusual through the muscle state data, and then judges whether this muscle tremble leads to motion, posture or stability problem, if judging the influence, then carries out the early warning.

In one embodiment, as shown in fig. 2, a gas detector-based power base work safety protection system, the system comprising:

The demand data acquisition module is used for acquiring detector selection demand data set by a current power basic operation main body, acquiring used gas detector data used by the current power basic operation main body in a preset time period, and generating current comprehensive demand data according to the detector selection demand data and the used gas detector data;

the detection instrument selection module is used for carrying out data analysis on the current comprehensive requirement data based on a gas detector recommendation engine, generating a current requirement safety evaluation value after the analysis is completed, selecting a target gas detector from a pre-stored instrument database according to the current requirement safety evaluation value, and generating a detector recommendation instruction according to the target gas detector, wherein the detector recommendation instruction is used for indicating the current power basic operation main body to take the target gas detector;

the environment data acquisition module is used for responding to the current power basic operation main body to trigger the target gas detector, starting a camera module and a dialogue module of the target gas detector and acquiring working environment images and real-time voice transmission data around the current power basic operation main body;

And the safety protection module is used for acquiring the muscle state data of the current power basic operation main body based on the target gas detector and carrying out safety protection according to the muscle state data, the working environment image and the real-time voice transmission data.

In one embodiment, the demand data acquisition module is further configured to:

acquiring a selected trigger instruction selected by a detector by a current power foundation operation main body, and generating a foundation pit work guiding interface according to the selected trigger instruction, wherein the foundation pit work guiding interface is used for displaying a foundation pit condition input field; acquiring actual foundation pit environment data of a current foundation pit, which are input by the current power foundation operation main body in the foundation pit condition input field; analyzing the danger level of the foundation pit according to the actual foundation pit environment data, and generating a current estimated danger level of the foundation pit; generating a standard recommendation detector according to the pre-estimated risk level of the current foundation pit, wherein the standard recommendation detector comprises a plurality of actual detector parameters; displaying each actual detector parameter to the current power basic operation main body, and acquiring the current revised parameters of the current power basic operation main body on the actual detector parameters; correcting the parameters of the actual detector according to the current revised parameters, and generating the selected requirement data of the detector; acquiring used gas detector data used by the current power basic operation main body in a preset time period in response to generation of the detector selection request data; comparing the used gas detector data with the detector selected requirement data, and obtaining difference parameter data, wherein the difference parameter data is a parameter which is possessed by the used gas detector data and is not possessed by the detector selected requirement data; and modifying the selected requirement data of the detector according to the difference parameter data, and generating current comprehensive requirement data.

In one embodiment, the detection instrument selection module is further configured to:

performing feature splitting on the current comprehensive requirement data, and generating a plurality of refinement basic requirement parameters after the feature splitting is completed; comparing each refinement basic requirement parameter with each standard gas detection parameter table, and obtaining an actual gap parameter, wherein one refinement basic requirement parameter corresponds to one standard gas detection parameter table, the standard gas detection parameter table comprises a plurality of standard detection parameters, and one refinement basic requirement parameter corresponds to one actual gap parameter after being compared with one standard detection parameter; sorting a plurality of actual gap parameters corresponding to the basic requirement parameters for refining, screening out the actual gap parameters with the smallest values, and setting the screened actual gap parameters as screening gap parameters; obtaining corresponding standard detection parameters according to the screening gap parameters, generating actual security levels according to the standard detection parameters, and generating actual gap levels according to the screening gap parameters, wherein one refinement basic requirement parameter corresponds to one actual gap level and one actual security level; generating a current required safety evaluation value according to the actual gap grade and the actual safety grade based on a gas detector recommendation engine by the following formula:

Wherein Q is the current required safety evaluation value, n is the number of the refined basic requirement parameters, P (x) is the actual gap grade corresponding to the n refined basic requirement parameters, and T (x) is the actual safety grade corresponding to the n refined basic requirement parameters; responding to the generation of the current required safety evaluation value, acquiring standard detection instruments in a stored instrument database, and acquiring standard detection safety values of the standard detection instruments; comparing each standard detection safety value with the current required safety evaluation value, and screening out a standard detection safety value matched with the current required safety evaluation value; and setting a standard detection instrument corresponding to the screened standard detection safety value as a target gas detector, and generating a detector recommended instruction according to the target gas detector.

In one embodiment, the safety protection module is further configured to:

acquiring a pre-stored acquisition time interval in response to acquiring the working environment image and the real-time voice transmission data; acquiring initial muscle electrical signals of the current power basic operation main body in each acquisition time interval based on the target gas detector according to the acquisition time interval as a unit; acquiring pre-stored interference signal waveforms, screening the initial muscle electric signals according to the interference signal waveforms, and generating initial screening electric signals after screening; acquiring blank electric signals in the initial screening electric signals, acquiring blank signal lengths and blank signal quantity of the blank electric signals, and generating blank signal quality according to the blank signal lengths and the blank signal quantity, wherein one initial screening electric signal corresponds to one blank signal quality; removing the initial screening electric signals corresponding to the blank signal quality which is greater than or equal to the standard signal quality, and generating effective muscle electric signals; generating muscle state data from each of the effective muscle electrical signals; and carrying out safety protection according to the muscle state data, the working environment image and the real-time voice transmission data.

In one embodiment, as shown in fig. 3, a computer device includes a memory and a processor, where the memory stores a computer program, and the processor implements the steps described in the above-described gas detector-based power base operation safety protection method when the computer program is executed.

A computer readable storage medium having stored thereon a computer program which when executed by a processor performs the steps of the gas detector based power base job safety protection method described above.

Those skilled in the art will appreciate that implementing all or part of the above described methods may be accomplished by way of a computer program stored on a non-transitory computer readable storage medium, which when executed, may comprise the steps of the embodiments of the methods described above. Any reference to memory, storage, database, or other medium used in embodiments provided herein may include non-volatile and/or volatile memory. The nonvolatile memory can include Read Only Memory (ROM), programmable ROM (PROM), electrically Programmable ROM (EPROM), electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), dynamic RAM (DRAM), synchronous DRAM (SDRAM), double Data Rate SDRAM (DDRSDRAM), enhanced SDRAM (ESDRAM), synchronous Link DRAM (SLDRAM), memory bus direct RAM (RDRAM), direct memory bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM), among others.

The technical features of the above embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above examples illustrate only a few embodiments of the application, which are described in detail and are not to be construed as limiting the scope of the application. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the application, which are all within the scope of the application. Accordingly, the scope of protection of the present application is to be determined by the appended claims.

Claims (10)

1. A gas detector-based power foundation work safety protection method, the method comprising:

acquiring detector selection requirement data set by a current power basic operation main body, acquiring used gas detector data used by the current power basic operation main body in a preset time period, and generating current comprehensive requirement data according to the detector selection requirement data and the used gas detector data; performing data analysis on the current comprehensive requirement data based on a gas detector recommendation engine, generating a current requirement safety evaluation value after the analysis is completed, selecting a target gas detector from a pre-stored instrument database according to the current requirement safety evaluation value, and generating a detector recommendation instruction according to the target gas detector, wherein the detector recommendation instruction is used for instructing the current power basic operation main body to take the target gas detector; responding to the current power basic operation main body to trigger the target gas detector, starting a camera module and a dialogue module of the target gas detector, and acquiring working environment images and real-time voice transmission data around the current power basic operation main body; and acquiring muscle state data of the current electric power basic operation main body based on the target gas detector, and performing safety protection according to the muscle state data, the working environment image and the real-time voice transmission data.

2. The gas detector-based power base operation safety protection method according to claim 1, wherein detector selection requirement data set by a current power base operation main body are obtained, used gas detector data used by the current power base operation main body in a preset time period are obtained, and current comprehensive requirement data is generated according to the detector selection requirement data and the used gas detector data; the method specifically comprises the following steps:

acquiring a selected trigger instruction selected by a detector by a current power foundation operation main body, and generating a foundation pit work guiding interface according to the selected trigger instruction, wherein the foundation pit work guiding interface is used for displaying a foundation pit condition input field; acquiring actual foundation pit environment data of a current foundation pit, which are input by the current power foundation operation main body in the foundation pit condition input field; analyzing the danger level of the foundation pit according to the actual foundation pit environment data, and generating a current estimated danger level of the foundation pit; generating a standard recommendation detector according to the pre-estimated risk level of the current foundation pit, wherein the standard recommendation detector comprises a plurality of actual detector parameters; displaying each actual detector parameter to the current power basic operation main body, and acquiring the current revised parameters of the current power basic operation main body on the actual detector parameters; correcting the parameters of the actual detector according to the current revised parameters, and generating the selected requirement data of the detector; acquiring used gas detector data used by the current power basic operation main body in a preset time period in response to generation of the detector selection request data; comparing the used gas detector data with the detector selected requirement data, and obtaining difference parameter data, wherein the difference parameter data is a parameter which is possessed by the used gas detector data and is not possessed by the detector selected requirement data; and modifying the selected requirement data of the detector according to the difference parameter data, and generating current comprehensive requirement data.

3. The gas detector-based power base operation safety protection method according to claim 2, wherein a gas detector-based recommendation engine performs data analysis on the current comprehensive requirement data, generates a current requirement safety evaluation value after analysis is completed, selects a target gas detector from a pre-stored instrument database according to the current requirement safety evaluation value, and generates a detector recommendation indication according to the target gas detector; the method specifically comprises the following steps:

performing feature splitting on the current comprehensive requirement data, and generating a plurality of refinement basic requirement parameters after the feature splitting is completed; comparing each refinement basic requirement parameter with each standard gas detection parameter table, and obtaining an actual gap parameter, wherein one refinement basic requirement parameter corresponds to one standard gas detection parameter table, the standard gas detection parameter table comprises a plurality of standard detection parameters, and one refinement basic requirement parameter corresponds to one actual gap parameter after being compared with one standard detection parameter; sorting a plurality of actual gap parameters corresponding to the basic requirement parameters for refining, screening out the actual gap parameters with the smallest values, and setting the screened actual gap parameters as screening gap parameters; obtaining corresponding standard detection parameters according to the screening gap parameters, generating actual security levels according to the standard detection parameters, and generating actual gap levels according to the screening gap parameters, wherein one refinement basic requirement parameter corresponds to one actual gap level and one actual security level; generating a current required safety evaluation value according to the actual gap grade and the actual safety grade based on a gas detector recommendation engine by the following formula:

Wherein Q is the current required safety evaluation value, n is the number of the refined basic requirement parameters, P (x) is the actual gap grade corresponding to the n refined basic requirement parameters, and T (x) is the actual safety grade corresponding to the n refined basic requirement parameters; responding to the generation of the current required safety evaluation value, acquiring standard detection instruments in a stored instrument database, and acquiring standard detection safety values of the standard detection instruments; comparing each standard detection safety value with the current required safety evaluation value, and screening out a standard detection safety value matched with the current required safety evaluation value; and setting a standard detection instrument corresponding to the screened standard detection safety value as a target gas detector, and generating a detector recommended instruction according to the target gas detector.

4. The gas detector-based power base operation safety protection method according to claim 1, wherein the muscle state data of the current power base operation main body is acquired based on the target gas detector, and safety protection is performed according to the muscle state data, the working environment image and real-time voice transmission data; the method specifically comprises the following steps:

Acquiring a pre-stored acquisition time interval in response to acquiring the working environment image and the real-time voice transmission data; acquiring initial muscle electrical signals of the current power basic operation main body in each acquisition time interval based on the target gas detector according to the acquisition time interval as a unit; acquiring pre-stored interference signal waveforms, screening the initial muscle electric signals according to the interference signal waveforms, and generating initial screening electric signals after screening; acquiring blank electric signals in the initial screening electric signals, acquiring blank signal lengths and blank signal quantity of the blank electric signals, and generating blank signal quality according to the blank signal lengths and the blank signal quantity, wherein one initial screening electric signal corresponds to one blank signal quality; removing the initial screening electric signals corresponding to the blank signal quality which is greater than or equal to the standard signal quality, and generating effective muscle electric signals; generating muscle state data from each of the effective muscle electrical signals; and carrying out safety protection according to the muscle state data, the working environment image and the real-time voice transmission data.

5. An electrical power base operation safety protection system based on a gas detector, the system comprising:

the demand data acquisition module is used for acquiring detector selection demand data set by a current power basic operation main body, acquiring used gas detector data used by the current power basic operation main body in a preset time period, and generating current comprehensive demand data according to the detector selection demand data and the used gas detector data;

the detection instrument selection module is used for carrying out data analysis on the current comprehensive requirement data based on a gas detector recommendation engine, generating a current requirement safety evaluation value after the analysis is completed, selecting a target gas detector from a pre-stored instrument database according to the current requirement safety evaluation value, and generating a detector recommendation instruction according to the target gas detector, wherein the detector recommendation instruction is used for indicating the current power basic operation main body to take the target gas detector;

the environment data acquisition module is used for responding to the current power basic operation main body to trigger the target gas detector, starting a camera module and a dialogue module of the target gas detector and acquiring working environment images and real-time voice transmission data around the current power basic operation main body;

And the safety protection module is used for acquiring the muscle state data of the current power basic operation main body based on the target gas detector and carrying out safety protection according to the muscle state data, the working environment image and the real-time voice transmission data.

6. The gas detector-based power base operation safety protection system of claim 5, wherein the demand data acquisition module is further configured to:

acquiring a selected trigger instruction selected by a detector by a current power foundation operation main body, and generating a foundation pit work guiding interface according to the selected trigger instruction, wherein the foundation pit work guiding interface is used for displaying a foundation pit condition input field; acquiring actual foundation pit environment data of a current foundation pit, which are input by the current power foundation operation main body in the foundation pit condition input field; analyzing the danger level of the foundation pit according to the actual foundation pit environment data, and generating a current estimated danger level of the foundation pit; generating a standard recommendation detector according to the pre-estimated risk level of the current foundation pit, wherein the standard recommendation detector comprises a plurality of actual detector parameters; displaying each actual detector parameter to the current power basic operation main body, and acquiring the current revised parameters of the current power basic operation main body on the actual detector parameters; correcting the parameters of the actual detector according to the current revised parameters, and generating the selected requirement data of the detector; acquiring used gas detector data used by the current power basic operation main body in a preset time period in response to generation of the detector selection request data; comparing the used gas detector data with the detector selected requirement data, and obtaining difference parameter data, wherein the difference parameter data is a parameter which is possessed by the used gas detector data and is not possessed by the detector selected requirement data; and modifying the selected requirement data of the detector according to the difference parameter data, and generating current comprehensive requirement data.

7. The gas detector-based power base operation safety protection system of claim 6, wherein the detector selection module is further configured to:

performing feature splitting on the current comprehensive requirement data, and generating a plurality of refinement basic requirement parameters after the feature splitting is completed; comparing each refinement basic requirement parameter with each standard gas detection parameter table, and obtaining an actual gap parameter, wherein one refinement basic requirement parameter corresponds to one standard gas detection parameter table, the standard gas detection parameter table comprises a plurality of standard detection parameters, and one refinement basic requirement parameter corresponds to one actual gap parameter after being compared with one standard detection parameter; sorting a plurality of actual gap parameters corresponding to the basic requirement parameters for refining, screening out the actual gap parameters with the smallest values, and setting the screened actual gap parameters as screening gap parameters; obtaining corresponding standard detection parameters according to the screening gap parameters, generating actual security levels according to the standard detection parameters, and generating actual gap levels according to the screening gap parameters, wherein one refinement basic requirement parameter corresponds to one actual gap level and one actual security level; generating a current required safety evaluation value according to the actual gap grade and the actual safety grade based on a gas detector recommendation engine by the following formula:

Wherein Q is the current required safety evaluation value, n is the number of the refined basic requirement parameters, P (x) is the actual gap grade corresponding to the n refined basic requirement parameters, and T (x) is the actual safety grade corresponding to the n refined basic requirement parameters; responding to the generation of the current required safety evaluation value, acquiring standard detection instruments in a stored instrument database, and acquiring standard detection safety values of the standard detection instruments; comparing each standard detection safety value with the current required safety evaluation value, and screening out a standard detection safety value matched with the current required safety evaluation value; and setting a standard detection instrument corresponding to the screened standard detection safety value as a target gas detector, and generating a detector recommended instruction according to the target gas detector.

8. The gas detector-based power base operation safety protection system of claim 7, wherein the safety protection module is further configured to:

acquiring a pre-stored acquisition time interval in response to acquiring the working environment image and the real-time voice transmission data; acquiring initial muscle electrical signals of the current power basic operation main body in each acquisition time interval based on the target gas detector according to the acquisition time interval as a unit; acquiring pre-stored interference signal waveforms, screening the initial muscle electric signals according to the interference signal waveforms, and generating initial screening electric signals after screening; acquiring blank electric signals in the initial screening electric signals, acquiring blank signal lengths and blank signal quantity of the blank electric signals, and generating blank signal quality according to the blank signal lengths and the blank signal quantity, wherein one initial screening electric signal corresponds to one blank signal quality; removing the initial screening electric signals corresponding to the blank signal quality which is greater than or equal to the standard signal quality, and generating effective muscle electric signals; generating muscle state data from each of the effective muscle electrical signals; and carrying out safety protection according to the muscle state data, the working environment image and the real-time voice transmission data.

9. A computer device comprising a memory and a processor, the memory storing a computer program, characterized in that the processor implements the steps of the method of any of claims 1 to 4 when the computer program is executed.

10. A computer readable storage medium, on which a computer program is stored, characterized in that the computer program, when being executed by a processor, implements the steps of the method of any of claims 1 to 4.