WO2018054164A1

WO2018054164A1 - Portable illumination controller and intelligent monitoring system

Info

Publication number: WO2018054164A1
Application number: PCT/CN2017/094724
Authority: WO
Inventors: 尤建兴
Original assignee: 得能创科有限公司
Priority date: 2016-09-23
Filing date: 2017-07-27
Publication date: 2018-03-29
Also published as: CN107869705A

Abstract

A portable illumination controller and an intelligent monitoring system. The portable illumination controller comprises a cylinder (1), a central processing module (3) and a plurality of light meters (2). The plurality of light meters (2) are mounted at intervals on a side surface of the cylinder (1), and are individually provided with photosensors (20). The photosensors (20) are individually connected to the central processing module (3), and measure a plurality of luminance values in an area needing illumination (7). The central processing module (3) is mounted on an upper face of the cylinder (1), receives and processes the plurality of luminance values measured by the photosensors (20) to generate a current luminance value, and controls the current luminance value to be transmitted in real time to a lighting control module (6) provided in the area needing illumination (7) so as to perform real-time lighting control. The portable illumination controller of the present invention has a simple and portable structure, and achieves, with the lighting control module (6), real-time and accurate control and adjustment of power consumption of an electrical lighting system in an indoor environment.

Description

Lantern controller and intelligent monitoring system

Technical field

The invention relates to the field of lamp control special devices and automatic lamp control technology, in particular to a lantern controller and an intelligent monitoring system for lighting lamp control.

Background technique

At present, the use of lighting appliances, especially lighting appliances in indoor places, has become very popular, but unfortunately, the use of a large number of lighting appliances has led to a significant increase in energy consumption, and it is impossible to know which lighting appliance is a large increase in energy consumption. Mainly caused by the need for expensive professional manpower, costly labor and capital costs to replace the layout of energy-saving lighting appliances, but frequent replacement of energy-saving lighting appliances have not fundamentally solved the problem of increased energy consumption and waste of resources; especially For example, aircraft and other aircraft maintenance sites, in actual maintenance applications, almost all lighting appliances (such as ceiling lights on the ceiling) need to be turned on at maximum power / rated power, the power consumption is very large, and very flashing Eyes, especially when repairing aircraft or car brakes, wheels, etc., these components are usually under the bottom of the aircraft or car (ie, when there is obstruction), the existing lighting system cannot be targeted for this situation. Focus on lighting, so it can only enhance the brightness of all lighting appliances to full User demand, further increase the increase of energy consumption, waste of resources; In addition, the existing indoor lighting control system (referred to as the light control system) can only achieve control lights (ie, light or light), or control lighting scenes (ie Conventional lighting control, such as regular dimming); therefore, there is a need in particular for a device/device to be used in conjunction with the installation and use of an indoor scale control system for real-time lighting control of lighting appliances in indoor locations.

Summary of the invention

The invention provides a lighting controller for the lighting electrical system of the current indoor place, which has a large power consumption, high energy consumption, and cannot focus on the key areas, and adopts a combined or separate configuration photometer. The structure, combined with the central processing module and the like, enables real-time sensing and measurement of the brightness value in the illumination area that needs to be illuminated, and then performs real-time light control with the light control module provided in the illumination area requiring illumination, thereby realizing the focus on the key areas. Lighting, non-key areas for energy-saving lighting and other functions, in order to achieve real-time, precise control of the lighting energy consumption of indoor lighting equipment. The invention also relates to an intelligent monitoring system for lights in an indoor area lighting area.

The technical solution of the present invention is as follows:

A lantern controller is characterized in that it comprises a pillar, a central processing module and a plurality of photometers, wherein the plurality of photometers are fixed and spaced apart on a side surface of the pillar, each of the photometers Setting a photometric unit, each of the photometric units being respectively connected to the central processing module, and measuring, by each of the photometric units, a plurality of brightness values in an illumination area that needs to be illuminated; the central processing module is fixedly disposed in the The upper end surface of the pillar, the central processing module receives and Processing a plurality of brightness values measured by each light metering unit to obtain a current brightness value, and controlling the current brightness value to be transmitted in real time to the light control module disposed in the illumination area to be illuminated for real-time light control.

The struts are cylindrical struts, and the side surfaces of the cylindrical struts are sequentially arranged with a plurality of grooves in the circumferential direction and the axial direction, and the photometers are embedded in the grooves one by one and each of the measuring electrodes The light meter can be plugged and unplugged.

The grooves are circumferentially spaced apart in a circumferential direction on the side surface of the cylindrical pillar and are sequentially spaced apart in the axial direction to form two or more turns, and the number of the grooves in the one turn is 8-12, correspondingly The number of photometers in the circle described is the same as the number of grooves.

A plurality of photometry units are disposed on each of the photometers, and each of the photometric units is circumferentially disposed at a top of the photometer.

The central processing module receives and processes a plurality of brightness values measured by each light metering unit to obtain a current brightness value, where the central processing module receives the plurality of brightness values measured by each light metering unit, and selects the light metering unit to measure The maximum of the plurality of brightness values, or the data processing to obtain an average of the plurality of brightness values measured by the respective photometric units, thereby obtaining a current brightness value.

The central processing module includes a processor, a display screen, and an adjustment component. The adjustment component is a knob or a lever. The display screen and the adjustment component are respectively connected to the processor, and each of the photometric units is respectively connected to the processor. The processor receives and processes a plurality of brightness values measured by each light metering unit to obtain a current brightness value, and controls the current brightness value to be transmitted in real time to the light control module disposed in the illumination area to be illuminated for real-time light control; The display screen displays a plan view of the illumination area to be illuminated and the current brightness value in real time under the control of the processor, and the preset brightness value in the illumination area to be illuminated is set by the knob or the pull rod;

Or the central processing module includes a processor and a touch display screen, the touch display screen is connected to the processor, each of the photometry units is respectively connected to a processor, and the processor receives and processes each test. The plurality of brightness values measured by the light unit obtain a current brightness value, and control the current brightness value to be transmitted in real time to the light control module disposed in the illumination area to be illuminated for real-time light control; the touch display screen is under the control of the processor Displaying a plan view of the illumination area to be illuminated and the current brightness value in real time, and setting a preset brightness value in the illumination area to be illuminated through the touch display screen.

The central processing module further includes a first Wi-Fi communication module, the first Wi-Fi communication module is connected to the processor, and each of the photometers respectively includes a second Wi-Fi communication module, where the Two Wi-Fi communication modules are respectively connected to each of the photometric units, the second Wi-Fi communication module is further connected to a processor, and the processor is received and processed by the second Wi-Fi communication module. The plurality of brightness values measured by the light metering units obtain a current brightness value, and the current brightness value is transmitted to the light control module set in the illumination area to be illuminated by the first Wi-Fi communication module for real-time light control. .

The lantern controller further includes a base, and the cylindrical pillar is disposed on the base.

The base is a tumbler base.

An intelligent monitoring system for a lamp in an indoor area illumination area, comprising the above-mentioned lantern controller, further comprising a lamp control module, wherein the lantern controller and the lamp control module are both disposed in an illumination area to be illuminated and The light controller is connected to the light control module through a central processing module, and the light control module is connected to the light in the illumination area, and the light controller transmits the current brightness value obtained to the light control module in real time; the light control module The current brightness value is compared with a brightness threshold required by the user illumination to determine whether the current brightness value satisfies the user illumination requirement, and the lamp in the illumination area is controlled to meet the user illumination requirement when the brightness threshold is deviated.

The light control module compares the current brightness value with the brightness threshold required by the user illumination, and does not satisfy the user illumination requirement when the current brightness value deviates from the brightness threshold. When the current brightness value is less than the brightness threshold, the light control module controls the brightness adjustment. When the lamp or the current brightness value in the illumination area that needs illumination is greater than the brightness threshold, the light control module controls to dim the light in the illumination area that needs illumination, and the light controller repeatedly monitors and obtains the current brightness value and controls The current brightness value is transmitted to the light control module in real time for cyclic real-time light control until the current brightness value in the illumination area requiring illumination meets the user illumination requirements.

The lighting controller is configured to be a plurality of, and the illumination area to be illuminated includes a plurality of sub-areas, and each of the lantern controllers is disposed in the sub-area in a one-to-one correspondence, and each of the lantern controllers is connected to the lamp control module.

The technical effects of the present invention are as follows:

The invention relates to a lantern controller, comprising a pillar, a central processing module and a plurality of photometers, wherein a plurality of photometers are fixed and spaced apart on a side surface of the pillar (preferably a cylindrical pillar and a lateral direction thereof) A plurality of grooves are arranged at intervals, and each photometer is embedded in the groove one by one. Each of the photometers is provided with a photometry unit, and the central processing module is disposed on the upper end surface of the cylindrical pillar, and the structure is simple, compact and volume. Light weight, easy to carry, easy to install in any position in the actual lighting control application, can achieve 360 ° all-round illumination brightness sensing measurement and processing; each metering unit is connected to the central processing module, and through each test The light unit measures a plurality of brightness values in the illumination area that needs to be illuminated; the central processing module receives and processes a plurality of brightness values measured by each of the photometry units, thereby enabling data processing to obtain real-time accurate brightness values in the illumination area, and controlling the current brightness values in real time. The light control module disposed in the illumination area that needs to be illuminated to meet the lighting control module in the illumination area to realize the illumination area The lighting energy consumption of the lighting electrical system in the domain is adjusted in real time and precisely.

The light controller of the present invention preferably has a light meter embedded in the groove, which can be arranged to be pluggable. In actual light control applications, the area and/or illumination accuracy of the illumination area can be illuminated according to the needs. Requirements, arbitrarily selected fit (ie, insert/embedded), or split type (ie, pull-out); that is, the lantern controller of the present invention uses a side surface to set the photometer in the circumferential direction and the axial direction Further, the structure of the photometer is further configured to be combined or separately, so that it can be easily measured and processed at any position in the actual light control application place, and the split photometer is used. It will not be blocked by the user or other obstructions to achieve further accurate real-time measurement, which can further improve the real-time measurement accuracy of the brightness value in the illumination area, and then realize the lighting electrical system in the illumination area with the lamp control module in the illumination area. The lighting energy consumption is real-time and precise control adjustment, which avoids the problems that the prior art cannot adjust the illumination brightness according to the user's demand, resulting in poor brightness or high energy consumption, and can realize key lighting for key areas and energy-saving lighting for non-key areas. Features.

The invention also relates to an intelligent monitoring system for a lamp in an indoor area illumination area, which is characterized by using the above-mentioned lantern controller and a lamp control module proposed by the invention to adjust the brightness of the lamp in the illumination area to realize the lighting appliance in the illumination area. The lighting energy consumption of the system is adjusted in real time and precisely, and the key lighting and energy-saving lighting are set as needed to meet the lighting requirements of the user in the case of reducing energy waste.

DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a first preferred schematic view of a lantern controller of the present invention.

Figure 2 is a plan view of Figure 1.

Figure 3 is a schematic view showing a second preferred configuration of the lantern controller of the present invention.

Fig. 4 is a view showing a third preferred configuration of the lantern controller of the present invention.

Fig. 5 is a flow chart showing the operation of the intelligent monitoring system for the lamp in the indoor area illumination area of the present invention.

Fig. 6 is a schematic view showing the structure of an intelligent monitoring system for lamps in an indoor area lighting area of the present invention.

The labels in the figure are listed as follows:

1-cylindrical strut; 2-photometer; 20-metering unit; 3- central processing module; 30-display; 31-knob; 4-base; 5--light controller; 6-light control module; - illumination area requiring illumination; 8-sub-area; 9-light.

detailed description

The invention will now be described with reference to the accompanying drawings.

The invention relates to a lantern controller, comprising a pillar, a central processing module and a plurality of photometers. A plurality of photometers are fixed and spaced apart on a side surface of the pillar, and each of the photometers is provided with a photometry unit, respectively The photometric unit is respectively connected to the central processing module, and each brightness measuring unit measures a plurality of brightness values in the illumination area to be illuminated; the central processing module is fixedly disposed on the upper end surface of the pillar, and the central processing module receives and processes each photometric unit. The measured brightness values obtain the current brightness value, and the current brightness value is controlled to be transmitted in real time to the light control module set in the illumination area to be illuminated for real-time light control.

1 is a schematic view of a first preferred structure of the lantern controller of the present invention. The pillar of the lantern controller in this embodiment is a cylindrical pillar 1, a groove is provided on the cylinder pillar 1, and a plurality of photometers are embedded. To the groove and the cylinder The fixed arrangement of the body pillars 1. The lantern controller comprises a cylindrical pillar 1, a central processing module 3 and eight photometers 2 (only four photometers 2 of the front side surface of the cylinder pillar 1 are shown in Fig. 1, and four other photometers) 2 on the rear side surface of the cylindrical pillar 1), the circumferential side of the cylindrical pillar 1 is circumferentially arranged with a total of 8 grooves in a circle, and 8 photometers 2 are respectively embedded in 8 grooves, each metering Each of the meters 2 is provided with a photometry unit, each of which is connected to the central processing module 3, and the central processing module 3 is disposed on the upper end surface of the cylindrical pillar 1. As shown in FIG. 2, the central processing module 3 may include a processor (not shown in Figures 1 and 2), a display screen 30 and an adjustment member, the adjustment member may be provided with a knob 31 as shown, and of course other adjustment members such as a tie rod may be employed, wherein the display screen 30 and The knobs 31 are respectively connected to the processor, and each of the photometry units is respectively connected to the processor; in the actual lamp control application, each of the photometry units measures a plurality of brightness values in the illumination area that needs to be illuminated, and can be measured for different directions. Different brightness values, the processor receives and processes each test The plurality of brightness values measured by the unit obtain the current brightness value, and control the current brightness value to be transmitted in real time to the light control module set in the illumination area to be illuminated for real-time light control; the display screen 30 can display the real-time display required illumination under the control of the processor. a plan view of the illumination area and the current brightness value obtained by the processor, and the user can manually set a preset brightness value in the illumination area to be illuminated through the knob 31 (ie, the required illumination brightness value in the illumination area to be illuminated, such as setting The brightness is 550 lux for normal illumination and the preset brightness value is simultaneously displayed on the display 30.

Preferably, the central processing module 3 may include only a processor and a touch display screen, and the touch display screen is connected to the processor, and each of the light metering units is respectively connected to the processor. In the actual light control application, each metering The unit measures a plurality of brightness values in the illumination area that needs to be illuminated, the processor receives and processes a plurality of brightness values measured by each of the photometry units to obtain a current brightness value, and controls the current brightness value to be transmitted in real time to the light control set in the illumination area to be illuminated. The module is used for real-time lighting control; the touch display screen displays the floor plan of the illumination area to be illuminated and the current brightness value in real time under the control of the processor, and at the same time, the user can manually touch the illumination area in the illumination area to be illuminated through the touch display screen. Preset brightness value.

More preferably, the central processing module 3 may further include a first Wi-Fi communication module, and the first Wi-Fi communication module is connected to the processor, and each of the photometers 2 respectively includes a second Wi-Fi communication module. The second Wi-Fi communication module is respectively connected to each photometric unit, and the second Wi-Fi communication module is further connected to the processor, and the processor receives and processes the plurality of photometry unit measurements through the second Wi-Fi communication module. The brightness value obtains the current brightness value, and the current brightness value is transmitted in real time through the first Wi-Fi communication module to the light control module set in the illumination area to be illuminated for real-time light control.

The processor processes the brightness values measured by the light metering units to obtain the current brightness value, which may be: selecting the maximum value of the plurality of brightness values measured by each light metering unit, or obtaining an average of the plurality of brightness values measured by each light metering unit. The value, or the average value obtained after removing the maximum value and the minimum value, or other value calculation algorithm may be reasonably selected according to the actual application, and is not limited by the present invention.

The principle and specific description of the real-time lamp control using the lantern controller in the embodiment of FIG. 1 and FIG. 2 together with the lamp control module are as follows:

In practical applications, the lantern controller is first disposed in an illumination area that needs to be illuminated, and the photometry units respectively disposed on each photometer 2 respectively sense the brightness in the illumination area that needs to be illuminated and generate a plurality of brightness values; The processing module 3 receives a plurality of brightness values measured by each photometry unit and processes (such as selecting a maximum value or an average value) to obtain a current brightness value, and controls the current brightness value to be transmitted in real time (transmittable by Wi-Fi) to the illumination area. The light control module is set; the light control module determines whether the current brightness value satisfies the user lighting requirement. When the user lighting requirement is not met, the light control module controls the adjustment (lighting or dimming) the light in the illumination area that needs to be illuminated, and then the light is raised. The controller repeats the measurement to obtain a new real-time current brightness value, and controls the current brightness value to be transmitted to the lighting control module in real time for cyclic real-time lighting control until the current brightness value in the illumination area requiring illumination meets the user lighting requirements.

The lantern controller proposed by the invention shown in FIG. 1 adopts the structure of the circumferentially arranged photometer, has a simple structure, is compact, small in size, light in weight, convenient to carry, and is convenient to be placed at any position in an actual application place, and can be realized. 360° omnidirectional illumination brightness measurement and processing, which can obtain real-time accurate brightness values in the illumination area, and in actual lighting control applications, can be used with the lighting control module in the illumination area to realize the lighting electrical system in the illumination area Real-time, precise control of lighting energy consumption.

3 is a second preferred structural diagram of the lantern controller of the present invention. As shown in FIG. 3, the lantern controller in this embodiment includes a cylindrical pillar 1, a central processing module 3, and 24 photometers 2 (Fig. Only the 12 photometers 2) of the front side are shown in Fig. 2, the circumferential side faces of the cylindrical strut 1 are arranged in the circumferential direction, and the axially spaced intervals are repeatedly arranged three times for a total of 24 grooves, 8 grooves per turn. 24 photometers 2 are respectively embedded in 24 grooves, and each of the photometers 2 is respectively provided with 8

photometry units

20, and 8 photometry units 20 are circumferentially arranged at intervals in the photometer 2 The top portion, that is, the portion of the photometer 2 on which the photometry unit 20 is disposed is a transparent portion, and the other portion of the photometer 2 may be an opaque portion, and each of the photometry units 20 is respectively connected to the central processing module 3. The central processing module 3 is disposed on the upper end surface (or the top) of the cylindrical pillar 1 , and each of the photometry units 20 is respectively connected to the processor of the central processing module 3; in the actual lighting control application, each photometry unit 20 measures Several brightness values within the illuminated area that need to be illuminated, and can be for different parties To measure different brightness values, the processor of the central processing module 3 receives and processes a plurality of brightness values measured by each light metering unit 20 to obtain a current brightness value, and controls the current brightness value to be transmitted in real time to the light set in the illumination area to be illuminated. Control module for real-time lighting control.

As shown in the embodiment of FIG. 3, the lantern controller of the present invention, the circumferential side surface of the cylindrical pillar 1 may be arranged with a plurality of grooves in the circumferential direction, and the plurality of grooves are repeatedly arranged in the axial direction. Each of the photometers 2 is embedded in the groove, and the grooves are circumferentially spaced apart in a circumferential direction on the side surface of the cylindrical pillar and are sequentially spaced apart in the axial direction to form two or more turns, when the number of turns is three Circle (preferably, the number of turns can be reasonably set according to practical applications), and the number of grooves in one turn is preferably 8-12 (correspondingly, the number of photometers is the same as the number of grooves and preferably 8-12, Of course, the cylindrical pillar 1 can be about 30-40 cm in height and about 20-30 cm in diameter when it is reasonably set according to the actual application; accordingly, the photometer 2 has a height of about 8-12 cm and a diameter of about 6-10 cm. The position of the photometry unit 20 on the top of the photometer 2 is about 0.8-1.2 cm, preferably 8-12 photometric units 20 can be provided.

As shown in the embodiment of FIG. 3, the light controller of the present invention can be directly fixed and spaced apart on the side surface of the pillar, or can be embedded in the photometer through a groove provided on the pillar. Preferably, each of the photometers 2 embedded in the recesses can be configured to be pluggable. In the actual light control application, the fit type (ie, insert/embedded) or the split type (ie, pull-out type) can be arbitrarily selected according to the area of the illumination area to be illuminated and/or the illumination precision requirement, etc.; In the formula, the lantern controller is disposed in the illumination area to be illuminated, and the photometers 2 are embedded in the grooves one by one, and the photometry units 20 respectively disposed on the photometers 2 respectively sense the illumination areas that need to be illuminated. The brightness of the inside and the generation of a plurality of brightness values, the central processing module 3 receives and processes a plurality of brightness values measured by each of the photometry units 20 to obtain a current brightness value, and controls the current brightness value to be transmitted to the lighting control module set in the illumination area in real time for real-time operation. Light control; when the split type is selected, the lantern controller is disposed in the illumination area to be illuminated, and each photometer 20 is pulled out from the groove one by one and placed on the circumference centered on the cylinder pillar 1 The photometry unit 20 respectively disposed on each photometer 2 senses the brightness in the illumination area to be illuminated and generates a plurality of brightness values, and the central processing module 3 receives and processes the measurement of each photometry unit 20. The brightness value is obtained by the current brightness value, and the current brightness value is controlled to be transmitted to the light control module set in the illumination area in real time for real-time light control; further, when the split type is selected, the split type may be selected according to the actual application situation. The number of the ground photometers 20 is removed, and the central processing module 3 (i.e., the processor of the central processing module 3) is selected to allow only the unplugged photometer 20 to participate in the illumination measurement work, and the selection is not allowed to be unplugged. The photometer 20 participates in the illumination measurement work.

The lantern controller according to the present invention as shown in FIG. 3 adopts a circumferential and axial setting photometer, and further configures the structure of the combined or separated photometer to facilitate setting in any position in the actual lighting application place. Measure and process the illumination brightness in any orientation, which can further improve the real-time measurement accuracy of the brightness value in the illumination area, and in the actual light control application, can realize the lighting equipment in the illumination area with the light control module in the illumination area The lighting energy consumption of the system is adjusted in real time and precisely, and the key lighting can be focused on the key areas, and the energy-saving lighting function can be performed in the non-key areas. That is, before the lighting controller is placed in the lighting area that needs to be illuminated, the lighting needs to be first The lighting area is divided into a plurality of sub-areas, and then a plurality of lantern controllers are arranged and the lantern controllers are arranged in a sub-area in a one-to-one correspondence, for example, for aircraft and other aircraft maintenance sites, such as aircraft or vehicle brakes. When repairing parts such as wheels (these parts are usually in airplanes or steam) Below the bottom, that is, when there is an obstruction, a light controller can be placed and split, so that the photometer will not be blocked by the user or other obstructions for further accurate real-time measurement; In the daily office area such as the library, a lantern controller may be arranged; in the access area of the hangar, such as the passage leading to the restroom, a lantern controller may be arranged, and preset illumination levels are respectively set for the illumination areas of the different illumination requirements described above. Values, in turn, are each separately real-time lighted. In addition, each of the plurality of sub-areas may be displayed on the display screen 30 by using a color, a diagonal line or a dashed box to facilitate real-time monitoring, and may illuminate a special work area according to the brightness requirement of the illumination area, and may Adjust the brightness at any time.

4 is a schematic view showing a third preferred structure of the lantern controller of the present invention. As shown in FIG. 4, the lantern controller in this embodiment includes all the components/modules in FIG. 3, and all the components/modules and FIG. The embodiment shown in the figure is functionally identical. Furthermore, the lantern controller shown in Fig. 4 further comprises a base 4, wherein the cylindrical strut 1 is arranged on the base 4, which can be a circle as shown in Fig. 4. The larger base 4 of the disc-shaped structure can also be a "tumbler" type structure, and can also have a structure with a plurality of support legs, so as to be placed and stably prevented from falling, and the specific shape setting can be reasonably set according to practical applications. It is not limited by the present invention; of course, the lantern controller provided by the present invention can also be provided with a handle for carrying, realizing the "follow me" type lighting control in the true sense; in addition, the lantern controller proposed by the present invention is further A power source can be provided inside the cylindrical pillar 1 to supply power.

The invention also relates to an intelligent monitoring system for a lamp in an indoor area lighting area, comprising the lantern controller of the invention, and a lamp control module, which can be referred to FIG. 1, FIG. 3 or FIG. 4, a lantern controller and a lamp control module. The light controller is connected to the light control module through the central processing module, and the light control module is connected to the light in the illumination area, and the light controller outputs the current brightness value to the light control module in real time; The light control module compares the current brightness value with the brightness threshold required by the user illumination to determine whether the current brightness value satisfies the user lighting requirement, and controls the adjustment of the light in the illumination area to meet the user lighting requirement when the brightness threshold is deviated.

As shown in the working flow chart shown in FIG. 5, the above-mentioned lantern controller is disposed in an illumination area to be illuminated, and each photometer 2 is embedded in the groove one by one, and the photometry unit 20 respectively disposed on each photometer 2 is disposed. Sensing the brightness in the illumination area to be illuminated and generating a plurality of brightness values respectively; the central processing module 3 receives and processes the plurality of brightness values measured by each of the photometry units to obtain a current brightness value, and controls the current brightness value to be transmitted to the illumination area in real time. The light control module compares the current brightness value with the brightness threshold required by the user to determine whether the current brightness value satisfies the user lighting requirement, and does not satisfy the user lighting requirement when the current brightness value deviates from the brightness threshold, and the light control module Controlling and adjusting the light in the illumination area, as shown in FIG. 5, if the current brightness value is less than the brightness threshold, it is too dark, and the light control module controls the light in the illumination area that needs to be illuminated, and the light controller repeatedly monitors to obtain the current brightness value. And controlling the current brightness value to be transmitted to the lighting control module in real time for cyclic real-time lighting control until the lighting area that needs illumination The front brightness value satisfies the user lighting requirement; if the current brightness value is greater than the brightness threshold value, the light control module controls the light in the illumination area that needs to be illuminated, and then the light controller repeatedly monitors to obtain the current brightness value and controls the current brightness value. Real-time transmission to the light control module for cyclic real-time lighting control until the current brightness value in the illuminated area requiring illumination meets the user's lighting requirements.

Preferably, the above-mentioned lantern controller is disposed in an illumination area to be illuminated, and each photometer 2 is pulled out from the groove one by one and disposed on a circumference centered on the cylinder pillar 1 , and each photometer 2 The metering units 20 respectively disposed on the sensing area respectively sense the brightness in the illumination area to be illuminated and generate a plurality of brightness values; the central processing module 3 receives and processes the plurality of brightness values measured by the respective photometry units to obtain the current brightness value, and controls the current brightness. The value is transmitted in real time to the light control module set in the illumination area for real-time light control; further, when the split type is selected, the split type may be selected according to the actual application situation. The number of the ground photometers 20 is removed, and the central processing module 3 (i.e., the processor of the central processing module 3) is selected to allow only the unplugged photometer 20 to participate in the illumination measurement work, and the selection is not allowed to be unplugged. The photometer 20 participates in the illumination measurement work.

Preferably, the central processing module 3 processes the plurality of brightness values measured by the light metering units to obtain the current brightness value. Specifically, the maximum value of the plurality of brightness values measured by each of the photometry units 20 may be selected, or each of the photometric units 20 may be obtained. The average of several measured brightness values.

More preferably, the lantern controller can be configured as several, and the illumination area to be illuminated includes several sub-areas, as shown in FIG. 6, including the light control module 6 and the plurality of lantern controllers 5, each of the lantern controllers 5 and the lamps The control module 6 is connected (not shown in FIG. 6), and the illumination area 7 to be illuminated includes a plurality of sub-areas 8. In this embodiment, the illumination area 7 to be illuminated is equally divided into 12 sub-areas 8, each of which has A plurality of lighting devices, a lamp 9, each of the lantern controllers 5 are disposed one by one in the sub-area 8. At this time, it can be understood that before the lantern controller is disposed in the illumination area that needs to be illuminated, the illumination area that needs illumination can be first divided into several sub-areas, and then several lantern controllers are arranged and the lantern controllers are correspondingly arranged. It is disposed in the sub-area, thereby further improving the real-time measurement accuracy of the brightness value in the illumination area, and in the actual lamp control application, the lighting control system in the illumination area can be implemented with the lighting control module in the illumination area. It consumes real-time, precise control and adjustment, and can realize key lighting for key sub-areas and energy-saving lighting for non-key sub-areas. In addition, each of the plurality of sub-areas may be displayed on the display screen 30 by using a color, a diagonal line or a dashed box to facilitate real-time monitoring, and may illuminate a special work area according to the brightness requirement of the illumination area, and may Adjust the brightness at any time.

It should be noted that the above-described embodiments may enable those skilled in the art to more fully understand the present invention, but do not limit the invention in any way. Therefore, although the present invention has been described in detail with reference to the drawings and embodiments, it will be understood by those skilled in the art that the invention may be modified or equivalently substituted. The technical solutions and improvements of the spirit and scope should be covered by the scope of protection of the patents of the present invention.

Claims

A lantern controller is characterized in that it comprises a pillar, a central processing module and a plurality of photometers, wherein the plurality of photometers are fixed and spaced apart on a side surface of the pillar, each of the photometers Setting a photometric unit, each of the photometric units being respectively connected to the central processing module, and measuring, by each of the photometric units, a plurality of brightness values in an illumination area that needs to be illuminated; the central processing module is fixedly disposed in the An upper end surface of the pillar, the central processing module receives and processes a plurality of brightness values measured by each light metering unit to obtain a current brightness value, and controls the current brightness value to be transmitted in real time to the light control module disposed in the illumination area to be illuminated for performing Real-time light control.
The lantern controller according to claim 1, wherein the pillar is a cylindrical pillar, and the side surfaces of the cylindrical pillar are sequentially arranged with a plurality of grooves in the circumferential direction and the axial direction, and each of the measurements is performed. The photometers are embedded in the grooves one by one and each of the photometers can be inserted and removed.
The lantern controller according to claim 2, wherein the grooves are circumferentially spaced apart in a circumferential direction on a side surface of the cylindrical pillar and are sequentially spaced apart in the axial direction to form two or more turns. The number of grooves in one turn is 8-12, and accordingly the number of photometers in one turn is the same as the number of grooves.
The lantern controller according to claim 2, wherein each of the photometers is provided with a plurality of photometric units, and each of the photometric units is circumferentially spaced at a top of the photometer.
The lantern controller according to claim 1, wherein the central processing module receives and processes a plurality of luminance values measured by each photometric unit to obtain a current luminance value, where the central processing module receives each photometric unit. After measuring a plurality of brightness values, selecting a maximum value of the plurality of brightness values measured by each of the photometry units, or performing data processing to obtain an average value of the plurality of brightness values measured by the respective photometry units, thereby obtaining a current brightness value.
The lantern controller according to any one of claims 1 to 5, wherein the central processing module comprises a processor, a display screen and an adjustment component, the adjustment component is a knob or a lever, the display screen and the adjustment component Each of the photometric units is respectively connected to a processor, and the processor receives and processes a plurality of brightness values measured by each photometric unit to obtain a current brightness value, and controls the current brightness value to be transmitted to the current position in real time. a light control module disposed in an illumination area that requires illumination for real-time light control; the display screen displays a plan view of the illumination area to be illuminated and the current brightness value in real time under the control of the processor, through the knob or The pull rod sets a preset brightness value in the illumination area that needs to be illuminated;

Or the central processing module includes a processor and a touch display screen, the touch display screen is connected to the processor, each of the photometry units is respectively connected to a processor, and the processor receives and processes each test. The plurality of brightness values measured by the light unit obtain a current brightness value, and control the current brightness value to be transmitted in real time to the light control module disposed in the illumination area to be illuminated for real-time light control; the touch display screen is under the control of the processor Displaying a plan view of the illumination area to be illuminated and the current brightness value in real time, and setting a preset brightness value in the illumination area to be illuminated through the touch display screen.
The lantern controller according to claim 6, wherein the central processing module further comprises a first Wi-Fi communication module, the first Wi-Fi communication module is connected to the processor, and each of the photometry Each of the meters includes a second Wi-Fi communication module, the second Wi-Fi communication module is respectively connected to each of the photometric units, and the second Wi-Fi communication module is further connected to the processor, The processor receives and processes a plurality of brightness values measured by each photometric unit through the second Wi-Fi communication module to obtain a current brightness value, and transmits the current brightness value to the need in real time through the first Wi-Fi communication module. A lighting module provided in the illuminated lighting area for real-time lighting control.
The lantern controller according to any one of claims 1 to 5, wherein the lantern controller further comprises a base, and the cylindrical pillar is disposed on the base.
The lantern controller of claim 8 wherein said base is a tumbler base.
An intelligent monitoring system for a lamp in an indoor area illumination area, comprising the lantern controller according to any one of claims 1 to 9, further comprising a lamp control module, wherein the lamp controller and the lamp control module are both disposed on The lighting controller is required to be connected to the lighting control module through a central processing module, and the lighting control module is connected to a lamp in the illumination area, and the lighting controller transmits the obtained current brightness value to the lamp in real time. a control module; the light control module compares the current brightness value with a brightness threshold required by the user to determine whether the current brightness value satisfies a user lighting requirement, and controls the adjustment of the light in the illumination area to meet the user when the brightness threshold is deviated Lighting requirements.
The intelligent monitoring system according to claim 10, wherein the lighting control module compares the current brightness value with a brightness threshold required by the user lighting, and does not satisfy the user lighting requirement when the current brightness value deviates from the brightness threshold. When the brightness control value is less than the brightness threshold, the light control module controls the light in the illumination area that needs to be illuminated or the current brightness value is greater than the brightness threshold, the light control module controls to dim the light in the illumination area that needs illumination And the light controller repeatedly monitors and obtains the current brightness value and controls the current brightness value to be transmitted to the light control module in real time for cyclic real-time light control until the current brightness value in the illumination area requiring illumination meets the user illumination requirement. .
The intelligent monitoring system according to claim 10 or 11, wherein the lantern controller is configured as a plurality of, the illumination area to be illuminated comprises a plurality of sub-areas, and each of the lantern controllers is arranged in one-to-one correspondence In the sub-area, each of the lantern controllers is connected to the lamp control module.