CN113840431B - Wisdom lighting control system - Google Patents

Abstract

The invention discloses an intelligent illumination control system, which comprises: the illumination module is used for illuminating a target environment where the intelligent illumination control system is located; the first detection module is used for detecting wind speed data and gas concentration data inside the target environment; the adjusting module is used for intelligently adjusting the lifting height of the lighting module according to the wind speed data and the gas concentration data; and the monitoring module is used for monitoring the real-time condition in the target environment so as to evaluate whether risks exist. The lighting effect can be intelligently guaranteed to the maximum according to the real-time condition of the interior of the target, the practicability and the experience feeling of workers are improved, further, the safety monitoring of the interior of the target environment can be realized, the complete operation of engineering or work in the interior of the target environment is guaranteed, the stability is improved, meanwhile, the safety is also improved, meanwhile, the function diversification is also realized, the practicability is further improved, the multiple functions are realized in the same occupied area, and the cost is reduced.

Description

Wisdom lighting control system

Technical Field

The invention relates to the technical field of intelligent lighting, in particular to an intelligent lighting control system.

Background

At present, with the continuous improvement of GDP in China, people's standard of living is higher and higher, the important factor that drives GDP to improve is the utilization and exploitation of the energy, wherein the emphasis is in the trades such as oil, petrochemical industry, army, railway, boats and ships, electric power, metallurgy, industrial and mining, mostly need a stable lighting system to guarantee the illumination work and the safety monitoring work of each engineering or region in these trades, current lighting system realizes the illumination for setting up an independent lighting apparatus that is used for the illumination in certain fixed region, because highly fixed when setting up, so can't be according to the actual conditions in the environment come the height of adjusting lighting apparatus rationally intelligently, it can only realize the illumination function simultaneously, can't realize the function diversification.

Disclosure of Invention

In view of the above-mentioned problems, the present invention provides an intelligent lighting control system to solve the problems mentioned in the background art that the height of the lighting device cannot be reasonably and intelligently adjusted according to the actual conditions in the environment because the height is fixed during the setting, and that the lighting device can only realize the lighting function and cannot realize the function diversification.

An intelligent lighting control system, the system comprising:

the illumination module is used for illuminating a target environment where the intelligent illumination control system is located;

the first detection module is used for detecting wind speed data and gas concentration data inside the target environment;

the adjusting module is used for intelligently adjusting the lifting height of the lighting module according to the wind speed data and the gas concentration data;

and the monitoring module is used for monitoring the real-time condition in the target environment so as to evaluate whether risks exist.

Preferably, the lighting module includes:

the acquisition submodule is used for acquiring environmental parameters inside the target environment;

the screening submodule is used for screening out a target environment parameter related to the brightness from the environment parameters;

the first determining submodule is used for determining the target illumination intensity of light required by the interior of the target environment according to the target environment parameters;

and the lighting sub-module is used for generating lamplight with target illumination intensity to light the target environment.

Preferably, the first detection module includes:

the setting submodule is used for setting a detection period;

the wind speed detection submodule is used for detecting wind speed data in a target environment according to the detection period;

the gas concentration detection submodule is used for detecting gas concentration data in the target environment according to the detection period;

and the storage submodule is used for storing the detected wind speed data and the detected gas concentration data.

Preferably, the adjusting module includes:

the evaluation submodule is used for evaluating the safety index of the lighting module at the current height according to the wind speed data;

a second determination submodule for determining a visibility within a target environment from said gas concentration data;

the calculation sub-module is used for judging whether the current height of the lighting module needs to be adjusted or not according to the safety index and the visibility, and if so, calculating the adjusted target height;

an adjusting submodule for adjusting the lighting module from a current height to the target height.

Preferably, the monitoring module includes:

the camera shooting sub-module is used for shooting real-time dynamic conditions in a target environment and acquiring a shot video;

the analysis submodule is used for analyzing the shot video to determine whether risk factors or danger factors exist in the target environment;

the evaluation submodule is used for evaluating the risk level in the target environment according to the risk factors and the risk factors when the risk factors or the risk factors exist in the target environment;

and the alarm submodule is used for sending out corresponding alarm prompts according to the risk level.

Preferably, the lighting module further includes: a battery module for providing electrical energy to the lighting module;

the system further comprises:

the charging module is used for charging the battery module;

a voltage detection module for detecting a charging voltage and a discharging voltage of the battery module;

the first judgment module is used for judging whether the charging voltage and the discharging voltage are low voltages or not, and if yes, a protection instruction is sent out;

and the voltage protection module is used for carrying out charging and discharging protection on the battery module according to the protection instruction.

Preferably, the system further comprises:

the second detection module is used for detecting the illumination intensity of the illumination module;

the analysis module is used for analyzing the current light decay rate of the lighting module according to the illumination intensity;

the second judgment module is used for judging the current lighting efficiency of the lighting module according to the current light attenuation rate;

and the reminding module is used for comparing the current lighting efficiency with the preset lighting efficiency to obtain a comparison result, judging whether the lighting module needs to be replaced according to the comparison result, and if so, sending a voice reminding for replacement.

Preferably, the system further comprises:

the third detection module is used for detecting the dust concentration on the surface of the lighting module;

the third judgment module is used for judging whether the normal lighting work of the lighting module is influenced or not according to the dust concentration, and if so, a cleaning instruction is generated;

the cleaning module is used for cleaning the surface of the lighting module according to the cleaning instruction;

and the setting module is used for setting the timing detection period of the third detection module.

Preferably, the lighting module further includes: the illumination intensity intelligent regulation submodule is used for intelligently regulating the illumination intensity of the illumination module according to the change of the environmental factors in the target environment, and the steps of the illumination intensity intelligent regulation submodule comprise:

acquiring a first environment factor of the lighting module in a target environment under different lighting brightness;

generating an illumination-environment factor experience learning table in the target environment according to the first environment factors under different illumination brightness;

acquiring a second environment factor of the illumination module under the current illumination brightness;

determining standard illumination brightness corresponding to a second environment factor based on the illumination-environment factor empirical learning table;

calculating the current illumination error and the current illumination error change rate of the target environment according to the current illumination brightness and the standard illumination brightness;

calculating the illumination correction quantity by utilizing a preset self-adaptive fuzzy algorithm based on the current illumination error and the current illumination error change rate;

generating a first illumination compensation quantity corresponding to the second environment factor according to the illumination correction quantity, the standard illumination brightness and the maintaining duration of the second environment factor;

repeating the operation to determine a second illumination compensation amount corresponding to a third environment factor of each time period except the second environment factor in the target environment;

generating an operation state change instruction in each time period according to the first illumination compensation amount, the second environmental factor, the third environmental factor and respective maintaining time lengths of the first illumination compensation amount and the second illumination compensation amount;

intelligently adjusting the operating instruction in each time period in the target environment according to the operating state changing instruction;

detecting activity factors in a target environment in each time period in real time, and intelligently setting the delayed execution duration of the operation state changing instruction in each time period according to the activity factors;

acquiring first light color characteristic data of the illumination module in each time period, and confirming whether the first light color data in the time period is matched with preset second light color data or not, if so, no subsequent operation is needed, otherwise, confirming whether the target illumination of the illumination module in the time period is attenuated or enhanced according to the comparison result of the first light color data and the preset second light color data;

and if the illumination intensity of the target in the time slot is increased until the illumination intensity is equal to the preset illumination intensity corresponding to the target illumination compensation amount in the time slot, and if the illumination intensity of the target in the time slot is increased, the illumination intensity of the target in the time slot is decreased until the illumination intensity is equal to the preset illumination intensity corresponding to the target illumination compensation amount in the time slot.

Preferably, when the evaluation sub-module determines that the risk factor or the risk factor exists in the target environment, the step of evaluating the risk level in the target environment according to the risk factor and the risk factor includes:

evaluating the current weight value of the safety metric index in the target environment according to the risk factor and the risk factor;

determining a security threat event level in the target environment according to the current weighted value of the security metric index;

acquiring a risk index corresponding to the security threat event level;

evaluating whether the risk index is a natural risk index or an artificial risk index or a combination of the natural risk index and the artificial risk index to obtain an evaluation result;

and evaluating the risk level in the target environment according to the evaluation result and the risk degree of the risk index.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and drawings.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

Fig. 1 is a schematic structural diagram of an intelligent lighting control system according to the present invention;

fig. 2 is a schematic structural diagram of a lighting module in an intelligent lighting control system according to the present invention;

fig. 3 is a schematic structural diagram of a first detection module in an intelligent lighting control system according to the present invention;

fig. 4 is a schematic structural diagram of a regulation module in an intelligent lighting control system according to the present invention.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The implementations described in the exemplary embodiments below are not intended to represent all implementations consistent with the present disclosure. Rather, they are merely examples of apparatus and methods consistent with certain aspects of the present disclosure, as detailed in the appended claims.

At present, with the continuous improvement of GDP in China, people's standard of living is higher and higher, the important factor that drives GDP to improve is the utilization and exploitation of the energy, wherein the emphasis is in the trades such as oil, petrochemical industry, army, railway, boats and ships, electric power, metallurgy, industrial and mining, mostly need a stable lighting system to guarantee the illumination work and the safety monitoring work of each engineering or region in these trades, current lighting system realizes the illumination for setting up an independent lighting apparatus that is used for the illumination in certain fixed region, because highly fixed when setting up, so can't be according to the actual conditions in the environment come the height of adjusting lighting apparatus rationally intelligently, it can only realize the illumination function simultaneously, can't realize the function diversification. In order to solve the above problem, the present embodiment discloses an intelligent lighting control system.

An intelligent lighting control system, as shown in fig. 1, the system comprising:

the lighting module 101 is used for lighting a target environment where the intelligent lighting control system is located;

a first detection module 102, configured to detect wind speed data and gas concentration data inside the target environment;

the adjusting module 103 is used for intelligently adjusting the lifting height of the lighting module according to the wind speed data and the gas concentration data;

a monitoring module 104 for monitoring real-time conditions within the target environment to assess whether a risk exists;

in this embodiment, the luminous flux of the lighting module is 5 times of that of a halogen bulb with the same power, the service life of the bulb reaches more than 100000 hours and is 5-10 times of that of a common halogen bulb, the heating value is small, the energy is saved, the safety is high, a CREE light source is adopted, the light decay rate is low, the light efficiency is high, the service life is long, the spotlight and floodlight are adjustable, meanwhile, a special waterproof, shockproof and dustproof reinforcing material is arranged on the surface of the CREE light source, the lighting module can normally work in rainy days, foggy days and other conditions, the height of the lighting module can be flexibly adjusted, the lighting module can horizontally rotate by 360 degrees and vertically rotate by 220 degrees, and no lighting blind area exists. The illumination module realizes remote control through a computer according to wireless communication data transmission and a spread spectrum power carrier communication technology, and can realize different illumination brightness according to different scenes.

The working principle of the technical scheme is as follows: the method comprises the steps of firstly utilizing an illumination module to illuminate illumination intensity of a target according to brightness inside a target environment, then utilizing a first detection module to detect wind speed data and gas concentration data inside the target environment in real time in an illumination process, determining wind speed and visibility inside the target environment according to the detected data so as to intelligently adjust the height of the illumination module, monitoring real-time conditions inside the target environment in real time through a monitoring module to achieve safety monitoring work, and achieving the safety monitoring work while achieving an illumination function.

The beneficial effects of the above technical scheme are: by intelligently adjusting the height of the illumination module according to the wind speed data and the gas concentration data in the target environment, the illumination effect can be intelligently ensured to the maximum according to the real-time condition in the target environment, the practicability and the experience feeling of workers are improved, further, the safety monitoring of the interior of the target environment can be realized by utilizing the monitoring module to monitor the real-time condition in the target environment in real time, the complete proceeding of the engineering or work in the target environment is ensured, the safety is improved while the stability is improved, the function diversification is realized, the practicability is further improved, the multifunction is realized in the same occupied area, the cost is reduced, the problem that in the prior art, the height is fixed when the illumination module is arranged, so the height of the illumination device can not be reasonably and intelligently adjusted according to the actual condition in the environment is solved, meanwhile, the lighting lamp can only realize the lighting function, and cannot realize the function diversification.

In one embodiment, as shown in fig. 2, the lighting module includes:

the acquisition submodule 1011 is used for acquiring environmental parameters inside the target environment;

a screening submodule 1012 for screening out a target environment parameter related to brightness from the environment parameters;

the first determining sub-module 1013 is configured to determine, according to the target environment parameter, a target illumination intensity of light required inside a target environment;

a lighting sub-module 1014 for generating light of a target illumination intensity to illuminate the target environment.

The beneficial effects of the above technical scheme are: the required target illumination intensity can be determined by collecting the internal environment parameters of the target, and the required illumination intensity in each environment can be reasonably determined according to different parameters of different environments, so that the illumination work can be stably ensured, and the illumination efficiency is improved.

In one embodiment, as shown in fig. 3, the first detection module includes:

a setting submodule 1021 for setting a detection period;

the wind speed detection submodule 1022 is configured to detect wind speed data in the target environment according to the detection period;

a gas concentration detection submodule 1023 for detecting gas concentration data in the target environment according to the detection period;

and the storage submodule 1024 is used for storing the detected wind speed data and the detected gas concentration data.

The beneficial effects of the above technical scheme are: the environment parameters in the target environment can be periodically detected by setting a detection period so as to cope with the diversified changes in the target environment, the practicability is further improved, meanwhile, the wind speed data and the gas concentration data detected at every time are stored, so that the follow-up data calling of workers can be facilitated, and the practicability and the experience of the workers are further improved.

In one embodiment, as shown in fig. 4, the adjusting module includes:

the evaluation sub-module 1031 is used for evaluating the safety index of the lighting module at the current height according to the wind speed data;

a second determination sub-module 1032 for determining a visibility within the target environment from the gas concentration data;

a calculating sub-module 1033, configured to determine whether the current height of the lighting module needs to be adjusted according to the safety index and the visibility, and if so, calculate an adjusted target height;

an adjustment sub-module 1034 for adjusting the lighting module from a current height to the target height.

The beneficial effects of the above technical scheme are: whether the lighting module needs to be adjusted or not is comprehensively evaluated from two aspects of visibility and safety, and the adjusted target height is calculated, so that the optimal adjustment height can be accurately obtained according to the actual situation, the lighting effect is guaranteed, and the lighting efficiency is further improved.

In one embodiment, the monitoring module includes:

the camera shooting sub-module is used for shooting real-time dynamic conditions in a target environment and acquiring a shot video;

the analysis submodule is used for analyzing the shot video to determine whether risk factors or danger factors exist in the target environment;

the evaluation submodule is used for evaluating the risk level in the target environment according to the risk factors and the risk factors when the risk factors or the risk factors exist in the target environment;

and the alarm submodule is used for sending out corresponding alarm prompts according to the risk level.

The beneficial effects of the above technical scheme are: the risk factors or risk factors in the surveillance video are evaluated, so that intelligent risk evaluation can be effectively carried out on the target environment, the accuracy and intelligence of evaluation are improved, manual evaluation is not needed, the fault tolerance rate of accident handling is improved, further, the risk level in the target environment can be effectively evaluated by determining the risk level in the target environment, so that a worker can reasonably and effectively take corresponding measures against the risk factors or risk factors, and the safety is further improved.

In one embodiment, the lighting module further comprises: a battery module for providing electrical energy to the lighting module;

the system further comprises:

the charging module is used for charging the battery module;

a voltage detection module for detecting a charging voltage and a discharging voltage of the battery module;

the first judgment module is used for judging whether the charging voltage and the discharging voltage are low voltages or not, and if yes, a protection instruction is sent out;

and the voltage protection module is used for carrying out charging and discharging protection on the battery module according to the protection instruction.

The beneficial effects of the above technical scheme are: the probability of safety accidents can be effectively reduced by carrying out charging and discharging protection on the battery module, the use frequency and the use reasonableness of the battery module can be ensured while the safety is further improved, and the service life of the battery module is indirectly prolonged.

In one embodiment, the system further comprises:

the second detection module is used for detecting the illumination intensity of the illumination module;

the analysis module is used for analyzing the current light decay rate of the lighting module according to the illumination intensity;

the second judgment module is used for judging the current lighting efficiency of the lighting module according to the current light attenuation rate;

the reminding module is used for comparing the current lighting efficiency with the preset lighting efficiency to obtain a comparison result, judging whether the lighting module needs to be replaced or not according to the comparison result, and if so, sending a replacement voice prompt;

in this embodiment, if the comparison result indicates that the current lighting efficiency is much greater than or greater than the preset lighting efficiency, it is determined that the lighting module does not need to be replaced, and if the current lighting efficiency is much less than the preset lighting efficiency, it is determined that the lighting module needs to be replaced.

The beneficial effects of the above technical scheme are: the current lighting efficiency of the lighting module is judged in real time to remind a worker to replace the lighting module, so that the lighting efficiency inside the target environment can be further guaranteed, the situation that safety accidents happen due to the fact that the equipment cannot be lighted due to the fact that the equipment is in a problem is avoided, and safety is further improved.

In one embodiment, the system further comprises:

the third detection module is used for detecting the dust concentration on the surface of the lighting module;

the third judgment module is used for judging whether the normal lighting work of the lighting module is influenced or not according to the dust concentration, and if so, a cleaning instruction is generated;

the cleaning module is used for cleaning the surface of the lighting module according to the cleaning instruction; and the setting module is used for setting the timing detection period of the third detection module.

The beneficial effects of the above technical scheme are: the surface of the lighting module is cleaned regularly, so that the cleanliness of the surface of the lighting module can be effectively guaranteed, and meanwhile, the lighting efficiency in the target environment is further guaranteed.

In one embodiment, the lighting module further comprises: the illumination intensity intelligent regulation submodule is used for intelligently regulating the illumination intensity of the illumination module according to the change of the environmental factors in the target environment, and the steps of the illumination intensity intelligent regulation submodule comprise:

acquiring a first environment factor of the lighting module in a target environment under different lighting brightness;

generating an illumination-environment factor experience learning table in the target environment according to the first environment factors under different illumination brightness;

acquiring a second environment factor of the illumination module under the current illumination brightness;

determining standard illumination brightness corresponding to a second environment factor based on the illumination-environment factor empirical learning table;

calculating the current illumination error and the current illumination error change rate of the target environment according to the current illumination brightness and the standard illumination brightness;

calculating the illumination correction quantity by utilizing a preset self-adaptive fuzzy algorithm based on the current illumination error and the current illumination error change rate;

generating a first illumination compensation quantity corresponding to the second environment factor according to the illumination correction quantity, the standard illumination brightness and the maintaining duration of the second environment factor;

repeating the operation to determine a second illumination compensation amount corresponding to a third environment factor of each time period except the second environment factor in the target environment;

generating an operation state change instruction in each time period according to the first illumination compensation amount, the second environmental factor, the third environmental factor and respective maintaining time lengths of the first illumination compensation amount and the second illumination compensation amount;

intelligently adjusting the operating instruction in each time period in the target environment according to the operating state changing instruction;

detecting activity factors in a target environment in each time period in real time, and intelligently setting the delayed execution duration of the operation state changing instruction in each time period according to the activity factors;

acquiring first light color characteristic data of the illumination module in each time period, and confirming whether the first light color data in the time period is matched with preset second light color data or not, if so, no subsequent operation is needed, otherwise, confirming whether the target illumination of the illumination module in the time period is attenuated or enhanced according to the comparison result of the first light color data and the preset second light color data;

and if the illumination intensity of the target in the time slot is increased until the illumination intensity is equal to the preset illumination intensity corresponding to the target illumination compensation amount in the time slot, and if the illumination intensity of the target in the time slot is increased, the illumination intensity of the target in the time slot is decreased until the illumination intensity is equal to the preset illumination intensity corresponding to the target illumination compensation amount in the time slot.

The beneficial effects of the above technical scheme are: the illumination efficiency can be guaranteed and the loss of electric energy can be avoided at the same time by intelligently adjusting the illumination intensity in each time period in the target environment, the cost is reduced, further, the illumination correction amount under different environmental factors can be accurately determined according to the actual illumination condition of the illumination module by calculating the illumination compensation amount in each time period, further, the illumination amount in each time period in the target environment can be guaranteed to accord with the preset level of workers, the experience of the workers is improved, further, the delay time for intelligently determining the illumination intensity in each time period according to the change of the activity factors in the target environment can be intelligently adjusted more humanized, and the practicability and the experience of the workers are further improved.

In one embodiment, when the evaluation sub-module confirms that the risk factor or the risk factor exists in the target environment, the step of evaluating the risk level in the target environment according to the risk factor and the risk factor includes:

evaluating the current weight value of the safety metric index in the target environment according to the risk factor and the risk factor;

determining a security threat event level in the target environment according to the current weighted value of the security metric index;

acquiring a risk index corresponding to the security threat event level;

evaluating whether the risk index is a natural risk index or an artificial risk index or a combination of the natural risk index and the artificial risk index to obtain an evaluation result;

and evaluating the risk level in the target environment according to the evaluation result and the risk degree of the risk index.

The beneficial effects of the above technical scheme are: the safety condition in the target environment can be visually determined by evaluating the safety measurement indexes of the risk factors and the risk factors in the target environment, and meanwhile, the safety level in the target environment can be effectively evaluated, further, the evaluation result can be more objective and accurate by evaluating the risk level according to the risk indexes, and the practicability is improved.

In one embodiment, the system further comprises a GPS positioning module, and the holder control module is used for realizing the functions of face recognition, sound alarm, on-site command, on-site calling and the like, so that the multifunctional requirements of the engineering can be met as much as possible.

It will be understood by those skilled in the art that the first and second terms of the present invention refer to different stages of application.

Other embodiments of the disclosure will be apparent to those skilled in the art from consideration of the specification and practice of the disclosure disclosed herein. This application is intended to cover any variations, uses, or adaptations of the disclosure following, in general, the principles of the disclosure and including such departures from the present disclosure as come within known or customary practice within the art to which the disclosure pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the disclosure being indicated by the following claims.

It will be understood that the present disclosure is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The scope of the present disclosure is limited only by the appended claims.

Claims (9)

1. An intelligent lighting control system, comprising:

the illumination module is used for illuminating a target environment where the intelligent illumination control system is located;

the first detection module is used for detecting wind speed data and gas concentration data inside the target environment;

the adjusting module is used for intelligently adjusting the lifting height of the lighting module according to the wind speed data and the gas concentration data;

the monitoring module is used for monitoring the real-time condition in the target environment to evaluate whether risks exist or not;

the lighting module further includes: the illumination intensity intelligent regulation submodule is used for intelligently regulating the illumination intensity of the illumination module according to the change of the environmental factors in the target environment, and the steps of the illumination intensity intelligent regulation submodule comprise:

acquiring a first environment factor of the lighting module in a target environment under different lighting brightness;

generating an illumination-environment factor experience learning table in the target environment according to the first environment factors under different illumination brightness;

acquiring a second environment factor of the illumination module under the current illumination brightness;

determining standard illumination brightness corresponding to a second environment factor based on the illumination-environment factor empirical learning table;

calculating the current illumination error and the current illumination error change rate of the target environment according to the current illumination brightness and the standard illumination brightness;

calculating the illumination correction quantity by utilizing a preset self-adaptive fuzzy algorithm based on the current illumination error and the current illumination error change rate;

generating a first illumination compensation quantity corresponding to the second environment factor according to the illumination correction quantity, the standard illumination brightness and the maintaining duration of the second environment factor;

repeating the operation to determine a second illumination compensation amount corresponding to a third environment factor of each time period except the second environment factor in the target environment;

generating an operation state change instruction in each time period according to the first illumination compensation amount, the second environmental factor, the third environmental factor and respective maintaining time lengths of the first illumination compensation amount and the second illumination compensation amount;

intelligently adjusting the operating instruction in each time period in the target environment according to the operating state changing instruction;

detecting activity factors in a target environment in each time period in real time, and intelligently setting the delayed execution duration of the operation state changing instruction in each time period according to the activity factors;

acquiring first light color characteristic data of the illumination module in each time period, and confirming whether the first light color data in the time period is matched with preset second light color data or not, if so, no subsequent operation is needed, otherwise, confirming whether the target illumination of the illumination module in the time period is attenuated or enhanced according to the comparison result of the first light color data and the preset second light color data;

and if the illumination intensity of the target in the time slot is increased until the illumination intensity is equal to the preset illumination intensity corresponding to the target illumination compensation amount in the time slot, and if the illumination intensity of the target in the time slot is increased, the illumination intensity of the target in the time slot is decreased until the illumination intensity is equal to the preset illumination intensity corresponding to the target illumination compensation amount in the time slot.

2. The intelligent lighting control system of claim 1, wherein the lighting module comprises:

the acquisition submodule is used for acquiring environmental parameters inside the target environment;

the screening submodule is used for screening out a target environment parameter related to the brightness from the environment parameters;

the first determining submodule is used for determining the target illumination intensity of light required by the interior of the target environment according to the target environment parameters;

and the lighting sub-module is used for generating lamplight with target illumination intensity to light the target environment.

3. The intelligent lighting control system of claim 1, wherein the first detection module comprises:

the setting submodule is used for setting a detection period;

the wind speed detection submodule is used for detecting wind speed data in a target environment according to the detection period;

the gas concentration detection submodule is used for detecting gas concentration data in the target environment according to the detection period;

and the storage submodule is used for storing the detected wind speed data and the detected gas concentration data.

4. The intelligent lighting control system of claim 1, wherein the adjustment module comprises:

the evaluation submodule is used for evaluating the safety index of the lighting module at the current height according to the wind speed data;

a second determination submodule for determining a visibility within a target environment from said gas concentration data;

the calculation sub-module is used for judging whether the current height of the lighting module needs to be adjusted or not according to the safety index and the visibility, and if so, calculating the adjusted target height;

an adjusting submodule for adjusting the lighting module from a current height to the target height.

5. The intelligent lighting control system of claim 1, wherein the monitoring module comprises:

the camera shooting sub-module is used for shooting real-time dynamic conditions in a target environment and acquiring a shot video;

the analysis submodule is used for analyzing the shot video to determine whether risk factors or danger factors exist in the target environment;

the evaluation submodule is used for evaluating the risk level in the target environment according to the risk factors and the risk factors when the risk factors or the risk factors exist in the target environment;

and the alarm submodule is used for sending out corresponding alarm prompts according to the risk level.

6. The intelligent lighting control system of claim 1, wherein the lighting module further comprises: a battery module for providing electrical energy to the lighting module;

the system further comprises:

the charging module is used for charging the battery module;

a voltage detection module for detecting a charging voltage and a discharging voltage of the battery module;

the first judgment module is used for judging whether the charging voltage and the discharging voltage are low voltages or not, and if yes, a protection instruction is sent out;

and the voltage protection module is used for carrying out charging and discharging protection on the battery module according to the protection instruction.

7. The intelligent lighting control system of claim 1, wherein the system further comprises:

the second detection module is used for detecting the illumination intensity of the illumination module;

the analysis module is used for analyzing the current light decay rate of the lighting module according to the illumination intensity;

the second judgment module is used for judging the current lighting efficiency of the lighting module according to the current light attenuation rate;

and the reminding module is used for comparing the current lighting efficiency with the preset lighting efficiency to obtain a comparison result, judging whether the lighting module needs to be replaced according to the comparison result, and if so, sending a voice reminding for replacement.

8. The intelligent lighting control system of claim 1, wherein the system further comprises:

the third detection module is used for detecting the dust concentration on the surface of the lighting module;

the third judgment module is used for judging whether the normal lighting work of the lighting module is influenced or not according to the dust concentration, and if so, a cleaning instruction is generated;

the cleaning module is used for cleaning the surface of the lighting module according to the cleaning instruction;

and the setting module is used for setting the timing detection period of the third detection module.

9. The intelligent lighting control system of claim 5 wherein the step of evaluating the risk level in the target environment based on the risk factor and the risk factor when the evaluation sub-module determines that the risk factor or the risk factor is present in the target environment comprises:

evaluating the current weight value of the safety metric index in the target environment according to the risk factor and the risk factor;

determining a security threat event level in the target environment according to the current weighted value of the security metric index;

acquiring a risk index corresponding to the security threat event level;

evaluating whether the risk index is a natural risk index or an artificial risk index or a combination of the natural risk index and the artificial risk index to obtain an evaluation result;

and evaluating the risk level in the target environment according to the evaluation result and the risk degree of the risk index.

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