CN115877115B - Safety detection system for installation of weak current equipment based on big data - Google Patents

Abstract

The invention discloses a safety detection system for weak current equipment installation based on big data, which belongs to the field of weak current equipment and is used for solving the problem that the safety detection is inaccurate due to the fact that no regional factors and equipment factors are combined in the weak current equipment installation.

Description

Safety detection system for installation of weak current equipment based on big data

Technical Field

The invention belongs to the field of weak current equipment, relates to a safety detection technology, and in particular relates to a safety detection system for installing weak current equipment based on big data.

Background

Weak current devices can be regarded as weak current systems, and power applications can be classified into strong current and weak current according to the intensity of power transmission. Building and building group power usage generally refers to strong electricity of 220V50Hz and above. Mainly provides electric energy for people, and converts electric energy into other energy sources, such as air conditioner electricity consumption, illumination electricity consumption, power electricity consumption and the like. The weak current in the intelligent building is mainly of two types, namely low-voltage electric energy such as a specified safety voltage class, a control voltage and the like, and the low-voltage electric energy comprises alternating current and direct current, the alternating current is less than 36V, the direct current is less than 24V, such as a 24V direct current control power supply, or an emergency lighting lamp standby power supply. Another type is information sources carrying information such as voice, image, data, etc., such as telephone, television, computer information.

When the existing weak current equipment is installed, the area factors of the installation place and the equipment factors of the weak current equipment are not combined, so that the safety detection during the installation of the weak current equipment is not accurate enough, and therefore, a safety detection system for the installation of the weak current equipment based on big data is provided.

Disclosure of Invention

Aiming at the defects of the prior art, the invention aims to provide a security detection system for weak current equipment installation based on big data.

The technical problems to be solved by the invention are as follows:

how to improve the accuracy of safety detection during weak current equipment installation based on multiple factors.

The aim of the invention can be achieved by the following technical scheme:

the security detection system for the installation of the weak current equipment based on the big data comprises a region division module, a big database, a region analysis module, a data acquisition module, an equipment analysis module, a security level judgment module, a server and a user terminal, wherein the region division module is used for dividing the installation place of the weak current equipment into a plurality of installation regions; the large database is used for storing the historical fault data of each installation area and the preset operation data of weak current equipment of different types, and sending the historical fault data and the preset operation data to the server, wherein the server sends the historical fault data to the area analysis module and sends the corresponding preset operation data to the equipment analysis module; the regional analysis module is used for analyzing the regional condition of the weak current equipment installation region according to the historical fault data, and analyzing to obtain the regional safety coefficient of the installation region and feeding the regional safety coefficient back to the server;

the data acquisition module is used for acquiring real-time operation data of the weak current equipment installed in different installation areas and feeding back the real-time operation data to the server, and the server sends the real-time operation data to the equipment analysis module; the equipment analysis module is used for analyzing real-time operation data of the weak current equipment installed in the installation area, analyzing to obtain equipment safety coefficients of the installation area, and feeding the equipment safety coefficients back to the server, wherein the server sends the area safety coefficients and the equipment safety coefficients of the installation area to the safety level judgment module;

the security level judging module is used for judging the security level of the installation area, the security level of the installation area is obtained through judgment and fed back to the server, and the server sends the security level to the emergency processing module and the user terminal;

the emergency processing module comprises a voice unit, a display unit and an emergency power-off unit and is used for carrying out emergency processing on weak current equipment in an installation area according to the safety level.

Further, the historical fault data are the number of power faults of the installation area, the power fault time of each power fault, the accident occurrence number and the accident occurrence time of each accident;

the preset operation data are preset voltage intervals, preset temperature value intervals and continuous operation duration upper limit values of weak current equipment of different models;

the real-time operation data comprise a real-time voltage value, a real-time temperature value and a real-time continuous operation duration of the weak current equipment installed in the installation area.

Further, the analysis process of the area analysis module is specifically as follows:

acquiring the number of power failures in the installation area and the power failure time of each power failure, calculating the time interval of adjacent power failure time to obtain a plurality of groups of power failure interval duration of the installation area, adding and summing the plurality of groups of power failure interval duration to obtain the average power failure interval duration of the installation area;

then obtaining the accident occurrence times in the installation area and the accident occurrence time in each accident, and similarly, calculating the accident occurrence interval average duration of the installation area;

calculating the safety duration of the installation area;

then calculating the area safety value of the installation area;

the regional safety value is compared with the regional safety threshold value, and the regional safety coefficient of the installation region is judged.

Further, the zone security value is proportional to the zone security coefficient, i.e., the greater the zone security value, the greater the zone security coefficient.

Further, the analysis process of the device analysis module is specifically as follows:

acquiring a real-time voltage value of the weak current equipment installed in the installation area;

if the real-time voltage value is in the preset voltage interval, not performing any operation, if the real-time voltage value is not in the preset voltage interval, calculating the difference value between the real-time voltage value and the preset voltage interval, obtaining the voltage deviation value of the weak current equipment installed in the installation area, and entering the next step;

similarly, acquiring a real-time temperature value of the weak current equipment installed in the installation area;

if the real-time temperature value is in the preset temperature interval, not performing any operation, if the real-time temperature value is not in the preset temperature interval, calculating the difference value between the real-time temperature value and the preset temperature interval, obtaining the temperature deviation value of the installed weak current equipment in the installation area, and entering the next step;

acquiring real-time continuous operation time length of weak current equipment in an installation area, and then acquiring an upper limit value of the continuous operation time length of the weak current equipment;

if the real-time continuous operation time length does not exceed the continuous operation time length upper limit value, not performing any operation, and if the real-time continuous operation time length exceeds the continuous operation time length upper limit value, subtracting the continuous operation time length upper limit value from the real-time continuous operation time length to obtain the operation excess time length of the weak current equipment installed in the installation area and entering the next step;

calculating the equipment safety value of the weak current equipment installed in the installation area;

the equipment safety values of all the installed weak current equipment in the installation area are added and divided by the number of the installed weak current equipment in the installation area to obtain the equipment safety values of the installation area;

the equipment safety value is compared with the equipment safety threshold value, and the equipment safety coefficient of the installation area is judged.

Further, the equipment safety value of the installation area is in direct proportion to the equipment safety coefficient, namely, the larger the equipment safety value of the installation area is, the larger the equipment safety coefficient is.

Further, the determination process of the security level determination module is specifically as follows:

acquiring an area safety coefficient and an equipment safety coefficient of an installation area;

calculating the security level value of weak current equipment in the installation area;

acquiring a security level threshold stored in a server;

comparing the security level value of the installation area with a security level threshold value;

the security level of the installation area is determined to be a first security level if the security level value is greater than or equal to the second security level threshold, the security level of the installation area is determined to be a second security level if the security level value is greater than or equal to the first security level threshold and less than the second security level threshold, and the security level of the installation area is determined to be a third security level if the security level value is less than the first security level threshold.

Further, the security level threshold comprises a first security level threshold and a second security level threshold, and the first security level threshold is less than the second security level threshold;

the first security level is higher than the second security level, which is higher than the third security level.

Further, the emergency treatment process of the emergency treatment module is specifically as follows:

when the safety level of the installation area is the first safety level, the voice unit prompts that the operation is normal, and the display unit is green;

when the safety level of the installation area is the second safety level or the third safety level, the corresponding installation area is marked as a fault area and enters the next step, if the installation area is the second safety level, the voice unit prompts abnormal work, the emergency power-off unit is started but not operated, a maintenance instruction is generated and sent to the corresponding user terminal, meanwhile, the display unit is yellow, if the installation area is the third safety level, the voice unit prompts abnormal work, the emergency power-off unit is started and operated, the emergency power-off unit starts to cut off power supply of the appointed fault area, the maintenance instruction is generated and sent to the corresponding user terminal, and the display unit is red.

Further, the user terminal is used for performing fault elimination on the designated fault area after receiving the maintenance instruction, and when the hidden trouble of the fault area is eliminated, the safety level of the fault area is adjusted to be the first safety level.

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

according to the invention, firstly, the area dividing module is used for dividing the installation place of the weak current equipment to obtain a plurality of installation areas, then, on the one hand, the area analyzing module is used for analyzing the area condition of the installation area of the weak current equipment to obtain the area safety factor of the installation area, on the other hand, the equipment analyzing module is used for analyzing the real-time operation data of the weak current equipment installed in the installation area to obtain the equipment safety factor of the installation area, the area safety factor and the equipment safety factor are both sent to the safety grade judging module, the safety grade of the installation area is judged by the safety grade judging module, the safety grade of the installation area is obtained and sent to the emergency processing module, and the emergency processing module carries out emergency processing on the weak current equipment in the installation area according to the safety grade.

Drawings

The present invention is further described below with reference to the accompanying drawings for the convenience of understanding by those skilled in the art.

FIG. 1 is an overall system block diagram of the present invention;

FIG. 2 is a schematic block diagram of an emergency treatment module according to the present invention;

fig. 3 is a block diagram of yet another system of the present invention.

Detailed Description

The technical solutions of the present invention will be clearly and completely described in connection with the embodiments, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-2, the security detection system for installing weak current equipment based on big data comprises a region dividing module, a big database, a region analyzing module, a data collecting module, an equipment analyzing module, a security level judging module, a server and a user terminal;

the region dividing module is used for dividing the installation place of the weak current equipment into a plurality of installation regions, and adding a mark number u which represents the number of the installation region, wherein u=1, 2, … …, z and z are positive integers;

the large database is used for storing historical fault data of each installation area and preset operation data of weak current equipment of different types, and sending the historical fault data and the preset operation data to the server, the server sends the historical fault data to the area analysis module, and the server sends the corresponding preset operation data to the equipment analysis module according to the model;

the historical fault data is the number of power faults in the installation area, the power fault time of each power fault, the accident occurrence number, the accident occurrence time of each accident and the like; the preset operation data are preset voltage intervals, preset temperature value intervals and continuous operation duration upper limit values of weak current equipment of different models;

the area analysis module is used for analyzing the area condition of the weak current equipment installation area according to the historical fault data, and the analysis process is specifically as follows:

step S1: acquiring the number CDu of power failures in the installation area and the power failure time of each power failure, calculating the time interval of adjacent power failure time to obtain a plurality of groups of power failure interval duration of the installation area, adding and summing the plurality of groups of power failure interval duration to obtain the power failure interval average duration JGSu of the installation area;

step S2: then acquiring accident occurrence times CGu in the installation area and accident occurrence time of each accident;

similarly, the accident occurrence interval average duration JGHu of the installation area can be calculated;

the specific explanation is that the power failure interval duration is the interval duration between the power failure time of the last power failure in the installation area and the power failure time of the current power failure, and the accident interval duration is the interval duration between the accident occurrence time of the last accident in the installation area and the accident occurrence time of the current accident;

step S3: substituting the electric power failure interval average duration JGSu and the accident occurrence interval average duration JGHu of the installation area into the calculated AQSu=JGSu×a1+JGHu×a2 to calculate the safety duration AQSu of the installation area; wherein a1 and a2 are weight coefficients with fixed values, and the values of a1 and a2 are larger than zero;

step S4: then through the formula

Calculating an area security value QAu of the installation area; wherein b1 and b2 are proportionality coefficients with fixed values, the values of b1 and b2 are both larger than zero, and e is a natural constant;

step S7: if QAu is less than X1, the area safety coefficient of the installation area is alpha 1;

if X1 is less than or equal to QAu and less than X2, the area safety coefficient of the installation area is alpha 2;

if X2 is less than or equal to QAu, the area safety coefficient of the installation area is alpha 3; wherein X1 and X2 are regional safety thresholds with fixed values, the values of X1 and X2 are larger than zero, and simultaneously, 0 < alpha 1 < alpha 2 < alpha 3;

it can be understood that the regional safety value is proportional to the regional safety coefficient, i.e. the greater the regional safety value, the greater the regional safety coefficient;

the regional analysis module feeds back the regional safety coefficient of the installation region to the server, and the server sends the regional safety coefficient of the installation region to the safety level judgment module;

in this embodiment, the data acquisition module is configured to acquire real-time operation data of weak current devices installed in different installation areas, and feed back the real-time operation data to the server, where the server sends the real-time operation data to the device analysis module;

the real-time operation data comprise a real-time voltage value, a real-time temperature value, a real-time continuous operation time length and the like of the weak current equipment installed in the installation area, wherein the real-time voltage value and the real-time temperature value are average values of the weak current equipment in unit time;

the equipment analysis module is used for analyzing real-time operation data of the weak current equipment installed in the installation area, and the analysis process is specifically as follows:

step S101: acquiring a real-time voltage value of the installed weak current equipment in the installation area, if the real-time voltage value is in a preset voltage interval, not performing any operation, if the real-time voltage value is not in the preset voltage interval, calculating a difference value between the real-time voltage value and the preset voltage interval to obtain a voltage deviation value PVun of the installed weak current equipment in the installation area and entering the next step, wherein n=1, 2, … …, x and x are positive integers, and n is the number representing the installed weak current equipment in the installation area;

step S102: similarly, acquiring a real-time temperature value of the installed weak current equipment in the installation area, if the real-time temperature value is in a preset temperature interval, not performing any operation, and if the real-time temperature value is not in the preset temperature interval, calculating a difference value between the real-time temperature value and the preset temperature interval, obtaining a temperature deviation value PTun of the installed weak current equipment in the installation area, and entering the next step;

the preset voltage interval comprises a voltage upper limit value and a voltage lower limit value, if the real-time voltage value is smaller than the voltage lower limit value of the preset voltage interval, the voltage lower limit value is used for subtracting the real-time voltage value to obtain a voltage deviation value, and if the real-time voltage value is larger than the voltage upper limit value of the preset voltage interval, the voltage upper limit value is subtracted from the real-time voltage value to obtain the voltage deviation value, and the calculation mode of the temperature deviation value is the same as that of the voltage deviation value;

step S103: acquiring a real-time continuous operation time length PSun of the weak current equipment in the installation area, then acquiring a continuous operation time length upper limit value of the weak current equipment, if the real-time continuous operation time length does not exceed the continuous operation time length upper limit value, not performing any operation, and if the real-time continuous operation time length exceeds the continuous operation time length upper limit value, subtracting the continuous operation time length upper limit value from the real-time continuous operation time length to obtain an operation excess time length PVun of the installed weak current equipment in the installation area and entering the next step;

step S104: calculating to obtain a device security value SAun of the weak current device installed in the installation area through a formula SAun=1/(PTun+PSun+PVun);

step S106: since the obtained device security value is the device security value of a certain installed weak current device in the installation area, the device security value SAu of the installation area is obtained by adding all the device security values of the installed weak current devices in the installation area and dividing the added value by the number of the installed weak current devices in the installation area;

step S107: if SAu is less than Y1, the equipment safety coefficient of the installation area is beta 1;

if Y1 is less than or equal to SAu and less than Y2, the equipment safety coefficient of the installation area is beta 2;

if Y2 is less than or equal to SAu, the equipment safety coefficient of the installation area is beta 3; wherein Y1 and Y2 are both equipment safety thresholds with fixed values, Y1 is smaller than Y2, and simultaneously, beta 1 is smaller than beta 2 and beta 3 are larger than 0;

it can be understood that the equipment safety value of the installation area is in direct proportion to the equipment safety coefficient, namely, the larger the equipment safety value of the installation area is, the larger the equipment safety coefficient is;

the equipment analysis module feeds back the equipment safety coefficient of the installation area to a server, and the server sends the equipment safety coefficient to the safety level judgment module;

the security level judging module is used for judging the security level of the installation area, and the judging process is specifically as follows:

step S201: acquiring the calculated area safety coefficient and equipment safety coefficient of the installation area, which are respectively marked as QXu and SXu;

step S202: the security level value DJu of the weak current equipment in the installation area is calculated by the formula DJu = QXu ×c1+ SXu ×c2; wherein, c1 and c2 are weight coefficients with fixed values, and the values of c1 and c2 are larger than zero;

step S203: the method comprises the steps of obtaining a security level threshold stored in a server, and comparing the security level value of an installation area with the security level threshold;

the safety level threshold comprises a first safety level threshold and a second safety level threshold, and the first safety level threshold is smaller than the second safety level threshold;

step S204: if the security level value is greater than or equal to the second security level threshold, determining the security level of the installation area as a first security level;

if the security level value is greater than or equal to the first security level threshold value and less than the second security level threshold value, the security level of the installation area is judged to be the second security level;

if the security level value is smaller than the first security level threshold value, the security level of the installation area is judged to be a third security level;

it is understood that the first security level is higher than the second security level, which is higher than the third security level;

the security level judging module feeds the security level of the installation area back to the server, and the server sends the security level to the emergency processing module and the user terminal;

the emergency treatment module comprises a voice unit, a display unit and an emergency power-off unit, and is used for carrying out emergency treatment on weak current equipment in an installation area according to the safety level, wherein the emergency treatment process is specifically as follows:

when the safety level of the installation area is the first safety level, the voice unit prompts that the operation is normal, and the display unit is green;

when the safety level of the installation area is the second safety level or the third safety level, the corresponding installation area is marked as a fault area and the next step is carried out;

if the second security level is the second security level, the voice unit prompts that the work is abnormal, the emergency power-off unit is started but not operated, a maintenance instruction is generated and sent to the corresponding user terminal, and meanwhile, the display unit displays yellow;

if the third safety level is the third safety level, the voice unit prompts abnormal work, the emergency power-off unit is started and operated, the emergency power-off unit starts to cut off the power supply of the appointed fault area, a maintenance instruction is generated and sent to the corresponding user terminal, and the display unit displays red;

the user terminal is used for carrying out fault elimination on the appointed fault area after receiving the maintenance instruction, and when the hidden trouble of the fault area is eliminated, the safety level of the fault area is adjusted to be a first safety level;

in another embodiment, referring to fig. 3, the safety detection system further includes a fault monitoring module, where the data acquisition module is configured to acquire real-time response data of weak current devices in different installation areas, and feed back the real-time response data to the server, the server sends the real-time response data to the fault monitoring module, and the large database stores preset response data of weak current devices of different types, and sends the preset response data of the corresponding weak current devices to the fault detection module according to the model;

the method specifically needs to be explained, the real-time response data comprise receiving time of any instruction received by the weak current equipment in the installation area and sending time of information corresponding to the instruction, the preset response data comprise normal response time duration intervals and abnormal response time duration intervals of the weak current equipment of different types, namely the response time duration intervals of the weak current equipment in normal operation and the response time duration intervals of the weak current equipment in abnormal operation, and the data acquisition module can be a timer in specific implementation;

the fault monitoring module is used for carrying out fault judgment on weak current equipment in the installation area, and the fault judgment process is as follows:

step S301: acquiring a normal response time interval and an abnormal response time interval of the weak current equipment according to the model;

step S302: the method comprises the steps that a user terminal sends an arbitrary instruction to weak current equipment in an installation area, the receiving time of the instruction received by the weak current equipment is recorded, the weak current equipment sends corresponding information to the user terminal according to the instruction, and meanwhile the sending time of the corresponding information sent by the weak current equipment is recorded;

the instruction can be a temperature inquiry instruction, the information sent by the weak current equipment is a temperature value, and similarly, if the instruction can be a voltage inquiry instruction, the information sent by the weak current equipment is a voltage value;

step S304: subtracting the receiving time from the transmitting time to obtain the real-time response time of the weak current equipment in the installation area;

if the response time is in the normal response time interval, judging that the weak current equipment works normally;

if the response time is in the abnormal response time interval, judging that the weak current equipment works abnormally, marking the corresponding weak current equipment as detection equipment, and sending the detection equipment to the user terminal;

the above formulas are all the dimensionality removal and numerical calculation, the size of the coefficient is a specific numerical value obtained by quantizing each parameter, and the size of the coefficient is only required to be not influenced by the proportional relation between the parameter and the quantized numerical value.

The preferred embodiments of the invention disclosed above are intended only to assist in the explanation of the invention. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best understand and utilize the invention. The invention is limited only by the claims and the full scope and equivalents thereof.

Claims (7)

1. The safety detection system for the installation of the weak current equipment based on the big data is characterized by comprising a region division module, a big database, a region analysis module, a data acquisition module, an equipment analysis module, a safety level judgment module, a server and a user terminal, wherein the region division module is used for dividing the installation place of the weak current equipment into a plurality of installation regions; the large database is used for storing historical fault data of each installation area and preset operation data of weak current equipment of different types, and sending the historical fault data and the preset operation data to the server, the server sends the historical fault data to the area analysis module and sends corresponding preset operation data to the equipment analysis module, the historical fault data is the power fault times of the installation area, the power fault time when each power fault occurs, the accident occurrence times and the accident occurrence time when each accident occur, and the preset operation data is the preset voltage interval, the preset temperature value interval and the upper limit value of continuous operation duration of the weak current equipment of different types; the area analysis module is used for analyzing the area condition of the weak current equipment installation area according to the historical fault data, and the analysis process is specifically as follows:

acquiring the number of power failures in the installation area and the power failure time of each power failure, calculating the time interval of adjacent power failure time to obtain a plurality of groups of power failure interval duration of the installation area, adding and summing the plurality of groups of power failure interval duration to obtain the average power failure interval duration of the installation area;

then obtaining the accident occurrence times in the installation area and the accident occurrence time in each accident, and similarly, calculating the accident occurrence interval average duration of the installation area;

calculating the safety duration of the installation area;

then calculating the area safety value of the installation area;

comparing the regional safety value with a regional safety threshold value, and judging the regional safety coefficient of the installation region;

the regional analysis module feeds back the regional safety coefficient of the installation region to the server;

the data acquisition module is used for acquiring real-time operation data of the weak current equipment installed in different installation areas and feeding the real-time operation data back to the server, and the server sends the real-time operation data to the equipment analysis module, wherein the real-time operation data comprises a real-time voltage value, a real-time temperature value and a real-time continuous operation duration of the weak current equipment installed in the installation areas; the equipment analysis module is used for analyzing real-time operation data of the weak current equipment installed in the installation area, and the analysis process is specifically as follows:

acquiring a real-time voltage value of the weak current equipment installed in the installation area;

if the real-time voltage value is in the preset voltage interval, not performing any operation, if the real-time voltage value is not in the preset voltage interval, calculating the difference value between the real-time voltage value and the preset voltage interval, obtaining the voltage deviation value of the weak current equipment installed in the installation area, and entering the next step;

similarly, acquiring a real-time temperature value of the weak current equipment installed in the installation area;

if the real-time temperature value is in the preset temperature interval, not performing any operation, if the real-time temperature value is not in the preset temperature interval, calculating the difference value between the real-time temperature value and the preset temperature interval, obtaining the temperature deviation value of the installed weak current equipment in the installation area, and entering the next step;

acquiring real-time continuous operation time length of weak current equipment in an installation area, and then acquiring an upper limit value of the continuous operation time length of the weak current equipment;

if the real-time continuous operation time length does not exceed the continuous operation time length upper limit value, not performing any operation, and if the real-time continuous operation time length exceeds the continuous operation time length upper limit value, subtracting the continuous operation time length upper limit value from the real-time continuous operation time length to obtain the operation excess time length of the weak current equipment installed in the installation area and entering the next step;

calculating the equipment safety value of the weak current equipment installed in the installation area;

the equipment safety values of all the installed weak current equipment in the installation area are added and divided by the number of the installed weak current equipment in the installation area to obtain the equipment safety values of the installation area;

the equipment safety value is compared with the equipment safety threshold value, and the equipment safety coefficient of the installation area is judged;

the equipment analysis module feeds back the equipment safety coefficient of the installation area to the server, and the server sends the area safety coefficient and the equipment safety coefficient of the installation area to the safety level judgment module;

the security level judging module is used for judging the security level of the installation area, the security level of the installation area is obtained through judgment and fed back to the server, and the server sends the security level to the emergency processing module and the user terminal;

the emergency processing module comprises a voice unit, a display unit and an emergency power-off unit and is used for carrying out emergency processing on weak current equipment in an installation area according to the safety level.

2. The safety detection system for installation of weak electric devices based on big data according to claim 1, wherein the area safety value is proportional to the area safety factor, i.e. the larger the area safety value is, the larger the area safety factor is.

3. The safety detection system for installation of weak electric equipment based on big data according to claim 1, wherein the equipment safety value of the installation area is proportional to the equipment safety coefficient, i.e. the larger the equipment safety value of the installation area is, the larger the equipment safety coefficient is.

4. The security detection system for installation of weak electric equipment based on big data according to claim 1, wherein the determination process of the security level determination module is specifically as follows:

acquiring an area safety coefficient and an equipment safety coefficient of an installation area;

calculating the security level value of weak current equipment in the installation area;

acquiring a security level threshold stored in a server;

comparing the security level value of the installation area with a security level threshold value;

the security level of the installation area is determined to be a first security level if the security level value is greater than or equal to the second security level threshold, the security level of the installation area is determined to be a second security level if the security level value is greater than or equal to the first security level threshold and less than the second security level threshold, and the security level of the installation area is determined to be a third security level if the security level value is less than the first security level threshold.

5. The big data based security detection system for weak current equipment installation of claim 4, wherein the security level threshold comprises a first security level threshold and a second security level threshold, and the first security level threshold is less than the second security level threshold;

the first security level is higher than the second security level, which is higher than the third security level.

6. The safety detection system for installing weak electric equipment based on big data according to claim 1, wherein the emergency treatment process of the emergency treatment module is specifically as follows:

when the safety level of the installation area is the first safety level, the voice unit prompts that the operation is normal, and the display unit is green;

when the safety level of the installation area is the second safety level or the third safety level, the corresponding installation area is marked as a fault area and enters the next step, if the installation area is the second safety level, the voice unit prompts abnormal work, the emergency power-off unit is started but not operated, a maintenance instruction is generated and sent to the corresponding user terminal, meanwhile, the display unit is yellow, if the installation area is the third safety level, the voice unit prompts abnormal work, the emergency power-off unit is started and operated, the emergency power-off unit starts to cut off power supply of the appointed fault area, the maintenance instruction is generated and sent to the corresponding user terminal, and the display unit is red.

7. The safety detection system for installation of weak current equipment based on big data according to claim 6, wherein the user terminal is configured to perform fault removal on the designated fault area after receiving the maintenance command, and when the hidden trouble of the fault area is removed, the safety level of the fault area is adjusted to the first safety level.

Images