CN114040556B - Intelligent illumination fault automatic alarm method, system and storage medium - Google Patents

Abstract

The invention relates to an intelligent illumination fault automatic alarm method, an intelligent illumination fault automatic alarm system and a storage medium, which belong to the field of intelligent illumination, wherein the intelligent illumination fault automatic alarm method comprises the following steps: acquiring the region detection data measured by each region monitoring device in real time in a preset illumination time period; if the detection data of the target area corresponding to the target monitoring area is identified to be abnormal, sending a start detection signal to all target monomer monitoring devices in the target monitoring area; identifying monomer detection data corresponding to the target lighting fixtures fed back by all target monomer monitoring devices in the target monitoring area; marking a target lighting lamp corresponding to the abnormal single body detection data as an abnormal lamp; generating and feeding back a fault report corresponding to the abnormal lamp, wherein the fault report carries the actual address of the abnormal lamp. The invention has the effect of saving the energy source required in the monitoring process.

Description

Intelligent illumination fault automatic alarm method, system and storage medium

Technical Field

The invention relates to the field of intelligent illumination, in particular to an intelligent illumination fault automatic alarm method, an intelligent illumination fault automatic alarm system and a storage medium.

Background

The intelligent lighting is a distributed wireless remote measuring, remote controlling and remote controlling system which is formed by the technologies of computer, wireless communication data transmission, spread spectrum power carrier communication technology, computer intelligent information processing, energy-saving electric control and the like, so as to realize intelligent control of the lighting lamp.

At present, in order to realize intelligent monitoring of the lighting fixtures, a monitoring device is generally configured for each lighting fixture, and the monitoring device detects the running lighting fixtures in real time, so that the lighting fixtures with faults can be found out in time.

In carrying out the present application, the inventors have found that the above-described technique has at least the following problems: in the process of operating the lighting fixture, each monitoring device can operate together, so that the consumption of energy sources is large.

Disclosure of Invention

In order to save energy required in the monitoring process, the application provides an intelligent illumination fault automatic alarm method, an intelligent illumination fault automatic alarm system and a storage medium.

In a first aspect, the present application provides an intelligent illumination fault automatic alarm method, which adopts the following technical scheme:

an intelligent lighting fault automatic alarm method, which is based on a control terminal in an intelligent lighting fault automatic alarm system, the intelligent lighting fault automatic alarm system further comprises area monitoring equipment and single monitoring equipment, each area monitoring equipment corresponds to a monitoring area, each monitoring area is respectively and correspondingly provided with a plurality of lighting fixtures, and the single monitoring equipment corresponds to the lighting fixtures one by one, and the method comprises the following steps:

acquiring area detection data corresponding to the monitored areas, which are measured by each area monitoring device, in real time in a preset illumination time period;

if the detection data of the target area corresponding to the target monitoring area is identified to be abnormal, sending a start detection signal to all target monomer monitoring devices in the target monitoring area;

identifying monomer detection data corresponding to the target lighting fixtures fed back by all target monomer monitoring devices in the target monitoring area;

marking a target lighting lamp corresponding to the abnormal single body detection data as an abnormal lamp;

generating and feeding back a fault report corresponding to the abnormal lamp, wherein the fault report carries the actual address of the abnormal lamp.

By adopting the technical scheme, in the running process of the lighting fixtures, the area monitoring equipment acquires the area detection data of the circuit formed by all the lighting fixtures in the corresponding monitoring area in real time and feeds the data back to the control terminal, and after recognizing that the target monitoring area with abnormal data exists, the control terminal starts all the target single monitoring equipment in the target monitoring area, so that the abnormal light fixtures are further determined, corresponding fault reports are generated, and the lighting fixtures are monitored. Through setting up the regional monitoring equipment that corresponds to different monitoring areas, realize the real-time supervision to a plurality of lighting fixtures through regional monitoring equipment to need not all monomer monitoring equipment and be in running state constantly at the running process of lighting fixtures, only after regional detection data appears unusual, control terminal can further start corresponding monomer check out test set, thereby has practiced thrift the energy.

Optionally, after the marking, as the abnormal lamp, the target lighting lamp corresponding to the single body detection data with the abnormality, the method further includes:

judging the fault type of the corresponding abnormal lamp based on the abnormal monomer detection data and a pre-stored fault type reference table;

the fault report also carries the fault type of the abnormal lamp.

By adopting the technical scheme, the control terminal feeds back the actual address of the abnormal lamp and the judged fault type of the abnormal lamp, so that the processing efficiency of maintenance personnel on the abnormal lamp is improved.

Optionally, the method further comprises:

in a non-illumination time period, sending a micro-lighting signal to each illumination lamp according to a preset temporary detection period, and simultaneously sending a temporary detection signal to each single monitoring device so that each single monitoring device can acquire temporary detection data of the corresponding illumination lamp;

after receiving the temporary detection data, judging whether the temporary detection data is abnormal or not;

and marking the illumination lamp corresponding to the temporary detection data with the abnormality as an abnormal lamp.

By adopting the technical scheme, when the lighting lamp is in an idle state, the control terminal controls each lighting lamp to be turned on slightly according to a preset temporary detection period and controls each single monitoring device to acquire temporary detection data, and then the control terminal judges whether the corresponding lighting lamp fails or not by verifying the received temporary detection data, so that the possibility of timely finding the failure is improved.

Optionally, the marking the lighting fixture corresponding to the temporary detection data with the abnormality as an abnormal fixture specifically includes:

marking the lighting lamp corresponding to the temporary detection data with the abnormality as a lamp to be rechecked;

transmitting a re-inspection request signal to the single monitoring equipment corresponding to each lamp to be re-inspected so that the single monitoring equipment can acquire re-inspection data of the lamp to be re-inspected;

after receiving the recheck data, judging whether the recheck data has abnormality or not;

marking the lamp to be rechecked corresponding to the rechecked data with the abnormality as an abnormal lamp.

By adopting the technical scheme, the control terminal can carry out secondary detection on the lighting lamp which is judged to be the lamp to be rechecked, so that the possibility of misjudgment is reduced.

Optionally, different ones of the monomer monitoring devices correspond to different temporary detection periods, and the method further includes:

based on a preset calculation method, counting the fault occurrence probability of each lighting lamp in a preset period;

and adjusting the temporary detection period corresponding to each single monitoring device corresponding to each lighting lamp based on the respective fault occurrence probability of each lighting lamp.

By adopting the technical scheme, as the working environments of different lighting fixtures are different, the possibility of faults is also different, and the control terminal adjusts the temporary detection period of the corresponding single monitoring equipment according to the fault occurrence probability of each lighting fixture, so that the targeted monitoring of each lighting fixture is facilitated, and the possibility of timely finding faults is further improved.

Optionally, the time interval of the temporary detection period of the single monitoring device corresponding to the lighting fixture with higher fault occurrence probability is shorter.

Optionally, after the identifying the monomer detection data corresponding to the target lighting fixture fed back by all target monomer monitoring devices in the target monitoring area, the method further includes:

calculating theoretical region detection data corresponding to the target monitoring region based on a preset calculation method and monomer detection data measured by all the target monomer monitoring devices;

comparing actual region detection data corresponding to the target monitoring region with theoretical region detection data;

when the difference value between the actual region detection data and the theoretical region detection data is larger than a preset difference value threshold value, a verification request signal is sent to the target region monitoring equipment and the target single monitoring equipment so that the target region monitoring equipment and the target single monitoring equipment feed back self-checking data;

and verifying whether the received self-checking data are abnormal, and marking target area monitoring equipment or target single monitoring equipment corresponding to the self-checking data with the abnormality as abnormal monitoring equipment.

By adopting the technical scheme, the control terminal can judge whether the single monitoring equipment and the area monitoring equipment have the possibility of faults by comparing the actually detected area detection data with the calculated theoretical area detection data, and after judging the target area monitoring equipment and the target single monitoring equipment which are likely to be faulty, the control terminal can further acquire the self-detection data of the target area monitoring equipment and the target single monitoring equipment so as to further identify the abnormal monitoring equipment with the faults. Through the verification to regional monitoring equipment and monomer monitoring equipment, help improving the accuracy of fault judgement.

In a second aspect, the present application provides an intelligent illumination fault automatic detection system, which adopts the following technical scheme:

the utility model provides an wisdom illumination trouble automatic alarm system, includes control terminal, regional monitoring equipment and monomer monitoring equipment, every regional monitoring equipment all corresponds there is the monitoring area, every correspond respectively in the monitoring area and be provided with a plurality of illumination lamps and lanterns, monomer monitoring equipment one-to-one illumination lamps and lanterns, control terminal includes:

the data acquisition module is used for acquiring the area detection data measured by each area monitoring device in real time in a preset illumination time period;

the data identification module is used for identifying whether the target area detection data corresponding to the target monitoring area is abnormal or not;

the signal sending module is used for sending a start detection signal to all target single monitoring devices in the target monitoring area after the abnormality of the target area detection data corresponding to the target monitoring area is identified;

the data identification module is also used for identifying monomer detection data corresponding to the target lighting lamp, which are fed back by all target monomer monitoring devices in the target monitoring area;

the lamp marking module is used for marking the target lighting lamp corresponding to the monomer detection data with the abnormality as an abnormal lamp;

the fault report generation module is used for generating fault reports corresponding to all the abnormal lamps;

and the fault report feedback module is used for feeding back fault reports corresponding to all the abnormal lamps.

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

a smart terminal comprising a memory and a processor, the memory having stored thereon a computer program capable of being loaded by the processor and executing the method according to the first aspect.

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

a computer readable storage medium comprising a computer program stored with instructions executable by a processor to load and execute the method according to the first aspect.

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

by setting the area monitoring equipment corresponding to different monitoring areas, the real-time monitoring of a plurality of lighting fixtures is realized through the area monitoring equipment, so that all the single monitoring equipment is not required to be in an operation state at any time in the operation process of the lighting fixtures, and the control terminal can further start the corresponding single detection equipment only after the abnormality occurs in the area detection data, thereby realizing the effect of saving energy required in the monitoring process;

when the lighting fixtures are in an idle state, the control terminal controls each lighting fixture to be turned on slightly according to a preset temporary detection period, controls each single monitoring device to acquire temporary detection data, and then judges whether the corresponding lighting fixture fails or not by verifying the temporary detection data, so that the possibility of timely finding the failure is improved;

through the verification to regional monitoring equipment and monomer monitoring equipment, help improving the accuracy of fault judgement.

Drawings

FIG. 1 is a flow chart illustrating an intelligent lighting fault automatic alarm method according to an embodiment of the present application;

FIG. 2 is a flow chart illustrating a verification process of a monitoring device according to an embodiment of the present application;

fig. 3 is a block diagram of a control terminal according to an embodiment of the present application.

Reference numerals illustrate: 31. a data acquisition module; 32. a data identification module; 33. a signal transmitting module; 34. a luminaire marking module; 35. a fault report generation module; 36. and a fault report feedback module.

Detailed Description

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

The embodiment of the application discloses an intelligent illumination fault automatic alarm method which can be applied to an intelligent illumination fault automatic alarm system, and an execution subject is a control terminal in the intelligent illumination fault automatic alarm system. The intelligent illumination fault automatic alarm system can be configured in application scenes such as urban illumination, factory illumination and the like, and further comprises area monitoring equipment and single monitoring equipment, wherein each area monitoring equipment corresponds to one monitoring area, a plurality of illumination lamps can be connected in parallel in each monitoring area, and each illumination lamp corresponds to one single monitoring equipment one by one. The area monitoring device can monitor the whole operation data of the circuit formed by all the lighting fixtures in the corresponding monitoring area, wherein the operation data can be electrical parameters such as current, voltage, power and the like. The single monitoring equipment, the regional monitoring equipment and the lighting lamp are all electrically connected to the control terminal.

The process flow shown in fig. 1 will be described in detail with reference to the specific embodiments, and the following may be included:

s101: and acquiring the region detection data corresponding to the monitored region, which is measured by each region monitoring device, in real time in a preset illumination time period.

The preset illumination time period is a time period preset by a worker and used for lighting the illumination lamp, and the illumination time period can be flexibly set due to different time of day and night alternation in different seasons.

In practice, the lighting fixtures are automatically illuminated within a preset lighting period, and the area monitoring devices also begin to operate synchronously. And in the illumination time period, the area monitoring equipment acquires the area detection data of the corresponding monitoring area in real time, and feeds the acquired area detection data back to the control terminal.

S102: and if the detection data of the target area corresponding to the target monitoring area is identified to be abnormal, sending a start detection signal to all target monomer monitoring devices in the target monitoring area.

Wherein the target monitoring area may be any one or any plurality of all monitoring areas.

In implementation, the control terminal compares the acquired region detection data with corresponding preset standard data, so as to judge whether each region detection data has abnormality. Wherein, standard data corresponding to different monitoring areas can be set to different values. When it is judged that the target area detection data fed back by the target area detection equipment are abnormal, the control terminal sends a start detection signal to all target single monitoring equipment in the target monitoring area corresponding to the target area detection equipment, and the target single monitoring equipment acquires the operation data of the corresponding target lighting lamp after receiving the start detection signal, namely the single detection data.

S103: and identifying monomer detection data corresponding to the target lighting fixtures fed back by all target monomer monitoring devices in the target monitoring area.

In implementation, the target monomer monitoring device feeds back the acquired monomer detection data of the corresponding target lighting lamp to the control terminal, and the control terminal compares the acquired monomer detection data with corresponding preset standard monomer detection data, so that whether each monomer detection data is abnormal or not is identified.

S104: and marking the target lighting lamp corresponding to the abnormal single body detection data as an abnormal lamp.

In implementation, when the control terminal identifies that the single detection data corresponding to a certain target lighting lamp is abnormal, the target lighting lamp is marked as an abnormal lamp.

S105: a fault report corresponding to the abnormal light fixture is generated and fed back.

In implementation, the control terminal may generate a fault report corresponding to the abnormal lamp after completing identification of all the monomer detection data, where the fault report carries an actual address of the abnormal lamp. The actual address of each lighting lamp is pre-stored in the control terminal, so that the lighting lamp is convenient to directly extract. And then, the control terminal sends the generated fault report to intelligent equipment carried by staff, or directly displays the fault report on a preset public display screen, so that the fault personnel can conveniently check the fault report, and the abnormal lamp can be timely processed.

Optionally, in another embodiment, to further facilitate the timely handling of the abnormal lamps by the staff, following the above S104, the following processes may also exist:

and judging the fault type of the corresponding abnormal lamp based on the abnormal monomer detection data and a pre-stored fault type reference table.

In the implementation, a fault type reference table is pre-stored in the control terminal, and the common correspondence between abnormal data and fault types is recorded in the fault type reference table. After the control terminal identifies the abnormal lamps, comparing the abnormal monomer detection data corresponding to the abnormal lamps with a preset fault type reference table, so as to preliminarily judge the fault type of each abnormal lamp.

In this case, the fault report generated in S105 also carries the fault type of the abnormal lamp.

Optionally, in order to perform full inspection on the lighting fixture periodically, so as to facilitate timely discovery of the abnormal lighting fixture, in another embodiment, the method may further include the following:

in the first step, in the non-illumination time period, micro-lighting signals are sent to each illumination lamp according to a preset temporary detection period, and meanwhile temporary detection signals are sent to each single monitoring device, so that each single monitoring device can acquire temporary detection data of the corresponding illumination lamp.

The non-illumination time period refers to a time period except for the illumination time period, and in the non-illumination time period, the illumination lamp is in an off state.

In an implementation, when in a non-lighting period, the control terminal may send a micro-lighting signal to each lighting fixture at a preset temporary detection period, e.g., once every 2 hours, once every 4 hours, etc., such that the lighting fixture operates at a preset micro-current. Meanwhile, the control terminal also sends temporary detection signals to each single monitoring device, so that the single monitoring devices acquire the operation data of the corresponding lighting lamp, namely the temporary detection data.

And step two, after the temporary detection data are received, judging whether the temporary detection data are abnormal or not.

In implementation, after receiving the temporary detection data fed back by the monomer monitoring device, the control terminal compares the temporary detection data with pre-stored standard temporary detection data, so as to judge whether each temporary detection data has an abnormality.

And thirdly, marking the lighting lamp corresponding to the temporary detection data with the abnormality as an abnormal lamp.

In implementation, the control terminal marks the illumination lamp corresponding to the temporary detection data with the abnormality as an abnormal lamp, so that the abnormal illumination lamp can be found in time, and the influence of the abnormal lamp on normal illumination is reduced.

Further, in another embodiment, in order to reduce the possibility of erroneous judgment, the specific processing procedure may be as follows:

and marking the lighting lamp corresponding to the temporary detection data with the abnormality as a lamp to be rechecked.

In implementation, after recognizing that a certain temporary detection data is abnormal, the control terminal may mark the lighting fixture corresponding to the single monitoring device that obtains the temporary detection data, that is, the lighting fixture corresponding to the temporary detection data as a to-be-rechecked lighting fixture.

And sending a re-inspection request signal to the single monitoring equipment corresponding to each lamp to be re-inspected so that the single monitoring equipment can acquire re-inspection data of the lamps to be re-inspected.

In implementation, after marking the lamps to be re-inspected, the control terminal can send a re-inspection request signal to the single monitoring device corresponding to each lamp to be re-inspected, and the single monitoring device can acquire the operation data of the corresponding lighting lamp again after receiving the re-inspection request signal, namely re-inspection data. And then, the single monitoring equipment feeds the acquired reinspection data back to the control terminal.

After receiving the recheck data, judging whether the recheck data has abnormality.

In implementation, after receiving the reinspection data, the control terminal compares the reinspection data with the pre-stored standard temporary detection data, so as to judge whether the reinspection data is abnormal.

Marking the lamp to be rechecked corresponding to the rechecked data with the abnormality as an abnormal lamp.

In implementation, after judging that the reinspection data corresponding to a certain lamp to be reinspected is abnormal, the control terminal represents that the obtained continuous two running data aiming at the lamp to be reinspected is abnormal, and at the moment, the possibility of misjudgment of two times of detection is extremely low, so that the control terminal can judge the lamp to be reinspected as an abnormal lamp.

Further, because the operational environment that different illumination lamps and lanterns are located is different, therefore the possibility that different illumination lamps and lanterns break down also is different, in order to adapt to this kind of difference, can set up different interim detection cycle to the monomer monitoring facilities that different illumination lamps and lanterns correspond, at this moment, this application can also include following processing procedure:

based on a preset calculation method, the fault occurrence probability of each lighting fixture in a preset period is counted.

The preset time period may be a time period of 1 month, 2 months, etc., and the specific length may be preset by a worker.

In implementation, when the switching time nodes of two adjacent preset time periods are reached each time, the control terminal counts the probability that each single monitoring device acquires abnormal single monitoring data, namely the fault occurrence probability of the corresponding lighting lamp, in the previous preset time period. Wherein the probability of failure occurrence of a certain lighting fixture= (number of abnormal single detection data of the lighting fixture/total number of acquired single detection data of the lighting fixture).

Based on the respective fault occurrence probability of each lighting lamp, the respective temporary detection period of the single monitoring equipment corresponding to each lighting lamp is adjusted.

In implementation, after the control terminal calculates the fault occurrence probability of each lighting fixture in the previous preset period, the temporary detection period of the single monitoring device corresponding to each lighting fixture in the subsequent preset period can be adjusted based on the calculation result and the preset corresponding relation between the fault occurrence probability and the temporary detection period, so that the time interval of the temporary detection period corresponding to the lighting fixture with higher fault occurrence probability is shorter, the temporary detection period can be adjusted regularly, and key monitoring of the lighting fixture which is easy to damage is realized.

Optionally, in another embodiment, in order to reduce the impact caused by such a situation, in combination with fig. 2, after S103, the following processing steps may be further included, since there is a possibility that the area monitoring device and the monomer monitoring device may also malfunction:

s201: theoretical region detection data corresponding to the target monitoring region are calculated based on a preset calculation method and monomer detection data measured by all target monomer monitoring devices.

In an implementation, after obtaining the monomer detection data fed back by all the target monomer monitoring devices in the target monitoring area, the control terminal may calculate, based on a preset calculation method and all the monomer detection data, theoretical area detection data corresponding to all the lighting fixtures in the target monitoring area. The preset calculation method can be preset by a worker according to a specific circuit in the target monitoring area.

S202: the actual region detection data corresponding to the target monitoring region is compared with the theoretical region detection data.

In implementation, after calculating theoretical region detection data of the target monitoring region, the control terminal may compare the theoretical region detection data with region detection data actually acquired by the corresponding target region monitoring device.

S203: and when the difference value between the actual area detection data and the theoretical area detection data is larger than a preset difference value threshold value, sending verification request signals to target area monitoring equipment and target single monitoring equipment so that the target area monitoring equipment and the target single monitoring equipment feed back self-checking data.

In the implementation, when the control terminal recognizes that the difference between the actual area detection data and the theoretical area detection data is greater than a preset difference threshold, it is determined that the target area monitoring device or at least one target monomer monitoring device has failed. At this time, in order to further confirm which monitoring device is faulty, the control terminal may send a verification request signal to both the target area monitoring device and the target monomer monitoring device, where the target area monitoring device and the target monomer monitoring device perform self-detection after receiving the verification request signal, so as to obtain self-detection data of the self-detection device, and feed back the obtained self-detection data to the control terminal. The self-checking data can carry the equipment number of the monitoring equipment, so that the control terminal can conveniently recognize the equipment number.

S204: and verifying whether the received self-checking data are abnormal, and marking target area monitoring equipment or target single monitoring equipment corresponding to the abnormal self-checking data as abnormal monitoring equipment.

In implementation, after receiving the self-checking data fed back by the target area monitoring device or the target single monitoring device, the control terminal compares each self-checking data with the pre-stored corresponding standard self-checking data, so as to judge whether each self-checking data has an abnormality. When judging that the self-checking data has an abnormality, the control terminal can mark the target area monitoring device or the single area monitoring device corresponding to the self-checking data with the abnormality as the abnormality monitoring device. And then, the control terminal can generate a monitoring equipment fault report corresponding to the abnormal monitoring equipment and feed the monitoring equipment fault report back to the staff, so that the staff can conveniently and timely process the fault report.

In this application, through setting up the regional monitoring equipment that corresponds to different monitoring areas, realize the real-time supervision to a plurality of lighting fixtures through regional monitoring equipment to need not all monomer monitoring equipment and be in running state constantly at the running process of lighting fixtures, only after regional detection data appears unusual, control terminal can further start corresponding monomer detection equipment, thereby realized the effect of saving the required energy of monitoring in-process.

Based on the above method, the embodiment of the application also discloses an intelligent illumination fault automatic alarm system, referring to fig. 3, the intelligent illumination fault automatic alarm system comprises a control terminal, area monitoring devices and single monitoring devices, each area monitoring device corresponds to a monitoring area, a plurality of illumination lamps are correspondingly arranged in each monitoring area, and the single monitoring devices correspond to the illumination lamps one by one. Wherein, control terminal includes:

the data acquisition module 31 is configured to acquire, in real time, area detection data corresponding to the monitored area, where the area detection data is measured by each area monitoring device in a preset illumination time period;

the data identifying module 32 is configured to identify whether the target area detection data corresponding to the target monitoring area is abnormal;

the signal sending module 33 is configured to send a start detection signal to all target monomer monitoring devices in the target monitoring area after identifying that the target area detection data corresponding to the target monitoring area is abnormal;

the data identification module 32 is further configured to identify monomer detection data corresponding to the target lighting fixtures fed back by all target monomer monitoring devices in the target monitoring area;

the lamp marking module 34 is configured to mark a target lighting lamp corresponding to the abnormal single body detection data as an abnormal lamp;

a fault report generation module 35 for generating a fault report corresponding to the abnormal light fixture;

a fault report feedback module 36 for feeding back a fault report corresponding to the abnormal light fixture.

Optionally, the control terminal further includes a fault type judging module, configured to judge, after the luminaire marking module 34 marks the target lighting luminaire corresponding to the abnormal monomer detection data as an abnormal luminaire, a fault type of the corresponding abnormal luminaire based on the abnormal monomer detection data and a pre-stored fault type reference table.

Optionally, the signal sending module 33 is further configured to send, in a non-illumination period, a micro-lighting signal to each lighting fixture according to a preset temporary detection period, and simultaneously send a temporary detection signal to the single monitoring device, so that each single monitoring device obtains temporary detection data of the corresponding lighting fixture;

the data identification module 32 is further configured to determine whether the temporary detection data is abnormal after receiving the temporary detection data;

the luminaire marking module 34 is further configured to mark a lighting luminaire corresponding to the temporary detection data with an abnormality as an abnormal luminaire.

Optionally, the luminaire marking module 34 is further configured to mark a lighting luminaire corresponding to the temporary detection data with the abnormality as a luminaire to be rechecked;

the signal sending module 33 is further configured to send a re-inspection request signal to the single monitoring device corresponding to each to-be-re-inspected lamp, so that the single monitoring device obtains re-inspection data of the to-be-re-inspected lamp;

the data identification module 32 is further configured to determine whether the review data is abnormal after receiving the review data;

the lamp marking module 34 is further configured to mark a lamp to be retested corresponding to the retested data with the abnormality as an abnormal lamp.

Optionally, the control terminal further includes:

the fault probability statistics module is used for counting the fault occurrence probability of each lighting lamp in a preset period based on a preset calculation method;

the period adjustment module is used for adjusting the temporary detection period corresponding to each single monitoring device corresponding to each lighting lamp based on the respective fault occurrence probability of each lighting lamp.

Optionally, the control terminal further includes:

the data calculation module is used for calculating theoretical area detection data corresponding to the target monitoring area based on a preset calculation method and monomer detection data measured by all target monomer monitoring equipment after identifying the monomer detection data corresponding to the target lighting lamp and fed back by all target monomer monitoring equipment in the target monitoring area;

the data recognition module 32 is further configured to compare actual region detection data corresponding to the target monitoring region with theoretical region detection data;

the signal sending module 33 is further configured to send a verification request signal to the target area monitoring device and the target monomer monitoring device when the difference between the actual area detection data and the theoretical area detection data is greater than a preset difference threshold, so that the target area monitoring device and the target monomer monitoring device feed back self-checking data;

the data identification module 32 is further configured to verify whether the received self-checking data has an anomaly;

the control terminal also comprises a monitoring equipment marking module which is used for marking the target area monitoring equipment or the target single monitoring equipment corresponding to the self-checking data with the abnormality as the abnormality monitoring equipment.

The embodiment of the application also discloses an intelligent terminal, which comprises a memory and a processor, wherein the memory stores a computer program which can be loaded by the processor and execute the intelligent illumination fault automatic alarm method.

The embodiment of the application also discloses a computer readable storage medium storing a computer program capable of being loaded by a processor and executing the intelligent illumination fault automatic alarm method, for example, the computer readable storage medium comprises: a U-disk, a removable hard disk, a Read-Only Memory (ROM), a random access Memory (Random Access Memory, RAM), a magnetic disk, or an optical disk, or other various media capable of storing program codes.

The above embodiments are only used to illustrate the technical solutions of the present application, and not to limit the scope of protection of the application. It will be apparent that the described embodiments are merely some, but not all, of the embodiments of the present application. Based on these embodiments, all other embodiments that may be obtained by one of ordinary skill in the art without inventive effort are within the scope of protection sought herein.

Claims (9)

1. The utility model provides a wisdom illumination trouble automatic alarm method which characterized in that, the method is based on the control terminal in the wisdom illumination trouble automatic alarm system, wisdom illumination trouble automatic alarm system still includes regional monitoring equipment and monomer monitoring equipment, every regional monitoring equipment all corresponds there is the monitoring area, every monitoring area corresponds respectively and is provided with a plurality of illumination lamps and lanterns, monomer monitoring equipment one-to-one corresponds illumination lamps and lanterns, the method includes:

acquiring area detection data corresponding to the monitored areas, which are measured by each area monitoring device, in real time in a preset illumination time period;

if the detection data of the target area corresponding to the target monitoring area is identified to be abnormal, sending a start detection signal to all target monomer monitoring devices in the target monitoring area;

identifying monomer detection data corresponding to the target lighting fixtures fed back by all target monomer monitoring devices in the target monitoring area;

marking a target lighting lamp corresponding to the abnormal single body detection data as an abnormal lamp;

generating and feeding back a fault report corresponding to the abnormal lamp, wherein the fault report carries the actual address of the abnormal lamp; after the identifying of the monomer detection data corresponding to the target lighting fixtures fed back by all target monomer monitoring devices in the target monitoring area, the method further comprises:

calculating theoretical region detection data corresponding to the target monitoring region based on a preset calculation method and monomer detection data measured by all the target monomer monitoring devices;

comparing actual region detection data corresponding to the target monitoring region with theoretical region detection data;

when the actual difference value between the region detection data and the theoretical region detection data is larger than a preset difference value threshold value, a verification request signal is sent to target region monitoring equipment and target single monitoring equipment so that the target region monitoring equipment and the target single monitoring equipment feed back self-checking data;

and verifying whether the received self-checking data are abnormal, and marking target area monitoring equipment or target single monitoring equipment corresponding to the self-checking data with the abnormality as abnormal monitoring equipment.

2. The intelligent illumination failure automatic alarm method according to claim 1, further comprising, after the marking of the target illumination lamp corresponding to the single body detection data having the abnormality as an abnormal lamp:

judging the fault type of the corresponding abnormal lamp based on the abnormal monomer detection data and a pre-stored fault type reference table;

the fault report also carries the fault type of the abnormal lamp.

3. The intelligent lighting fault automatic alarm method of claim 1, further comprising:

in a non-illumination time period, sending a micro-lighting signal to each illumination lamp according to a preset temporary detection period, and simultaneously sending a temporary detection signal to each single monitoring device so that each single monitoring device can acquire temporary detection data of the corresponding illumination lamp;

after receiving the temporary detection data, judging whether the temporary detection data is abnormal or not;

and marking the illumination lamp corresponding to the temporary detection data with the abnormality as an abnormal lamp.

4. The intelligent lighting fault automatic alarm method according to claim 3, wherein the marking the lighting fixture corresponding to the temporary detection data with the abnormality as an abnormal lighting fixture specifically comprises:

marking the lighting lamp corresponding to the temporary detection data with the abnormality as a lamp to be rechecked;

transmitting a re-inspection request signal to the single monitoring equipment corresponding to each lamp to be re-inspected so that the single monitoring equipment can acquire re-inspection data of the lamp to be re-inspected;

after receiving the recheck data, judging whether the recheck data has abnormality or not;

marking the lamp to be rechecked corresponding to the rechecked data with the abnormality as an abnormal lamp.

5. The intelligent lighting fault automatic alarm method of claim 3, wherein different ones of the individual monitoring devices correspond to different ones of the temporary detection periods, the method further comprising:

based on a preset calculation method, counting the fault occurrence probability of each lighting lamp in a preset period;

and adjusting the temporary detection period corresponding to each single monitoring device corresponding to each lighting lamp based on the respective fault occurrence probability of each lighting lamp.

6. The intelligent illumination failure automatic alarm method according to claim 5, wherein the time interval of the temporary detection period of the individual monitoring device corresponding to the illumination lamp with higher failure occurrence probability is shorter.

7. An wisdom illumination trouble automatic alarm system, its characterized in that includes control terminal, regional monitoring equipment and monomer monitoring equipment, every regional monitoring equipment all corresponds there is the monitoring area, every the monitoring area corresponds respectively to be provided with a plurality of illumination lamps and lanterns, monomer monitoring equipment one-to-one illumination lamps and lanterns, control terminal includes:

the data acquisition module (31) is used for acquiring the area detection data corresponding to the monitoring area, which is measured by each area monitoring device, in real time in a preset illumination time period;

the data identification module (32) is used for identifying whether the target area detection data corresponding to the target monitoring area is abnormal or not;

the signal sending module (33) is used for sending a start detection signal to all target single monitoring devices in the target monitoring area after the abnormality of the target area detection data corresponding to the target monitoring area is identified;

the data identification module (32) is further used for identifying monomer detection data corresponding to the target lighting fixtures, which are fed back by all target monomer monitoring devices in the target monitoring area;

after identifying the monomer detection data corresponding to the target lighting lamp fed back by all target monomer monitoring devices in the target monitoring area, the method further comprises the following steps:

calculating theoretical region detection data corresponding to the target monitoring region based on a preset calculation method and monomer detection data measured by all target monomer monitoring devices;

comparing actual region detection data corresponding to the target monitoring region with theoretical region detection data;

when the difference value between the actual region detection data and the theoretical region detection data is larger than a preset difference value threshold value, a verification request signal is sent to target region monitoring equipment and target single monitoring equipment, so that the target region monitoring equipment and the target single monitoring equipment feed back self-checking data;

verifying whether the received self-checking data are abnormal or not, and marking target area monitoring equipment or target single monitoring equipment corresponding to the self-checking data with the abnormality as abnormal monitoring equipment;

the lamp marking module (34) is used for marking the target illumination lamp corresponding to the single body detection data with the abnormality as an abnormal lamp;

a fault report generation module (35) for generating a fault report corresponding to the abnormal light fixture;

a fault report feedback module (36) for feeding back a fault report corresponding to the abnormal light fixture.

8. An intelligent terminal comprising a memory and a processor, the memory having stored thereon a computer program capable of being loaded by the processor and performing the method according to any of claims 1 to 6.

9. A computer readable storage medium, characterized in that a computer program is stored which can be loaded by a processor and which performs the method according to any of claims 1 to 6.