CN113432051A

CN113432051A - Lamp module and lamp

Info

Publication number: CN113432051A
Application number: CN202110868815.1A
Authority: CN
Inventors: 杨带稳; 陈欢欢; 张潘儒; 李钧达; 姜运帅
Original assignee: Tcl Huarui Lighting Technology Huizhou Co ltd; Very Optoelectronics Huizhou Co Ltd
Current assignee: Tcl Huarui Lighting Technology Huizhou Co ltd; Very Optoelectronics Huizhou Co Ltd
Priority date: 2021-07-30
Filing date: 2021-07-30
Publication date: 2021-09-24

Abstract

The invention relates to a lamp module and a lamp, wherein the lamp module comprises: the LED driving power supply comprises a lighting assembly, a wireless module, an induction module and an LED driving power supply module; the induction module is electrically connected with the wireless module, the wireless module is electrically connected with the LED driving power supply module, and the LED driving power supply module is electrically connected with the lighting assembly. According to the lamp module and the lamp, the external signal can be collected and converted into the electric signal through the induction module, the electric signal is sent to the wireless module, the wireless module receives the electric signal and then sends the received electric signal to other terminal equipment, the function of data monitoring and reporting is achieved, the wireless module is also used for receiving the electric signal sent by other terminal equipment and sending a corresponding data command to the LED driving power supply module to control the illumination assembly to work, then the illumination assembly is controlled through the terminal equipment, the lamp module can be linked with other terminal equipment, and the lamp module can be adjusted through the terminal equipment.

Description

Lamp module and lamp

Technical Field

The invention relates to the technical field of lighting, in particular to a lamp module and a lamp.

Background

Along with the rapid growth of the internet of things technology, the popularization of the lamp gradually turns to the development of energy conservation and intellectualization. The traditional lamp is simple in structure, can only simply control the lighting assembly to be on or off according to the change of the environment, is single in function, and is difficult to adjust the lighting effect after the lamp is installed.

Disclosure of Invention

Accordingly, there is a need for a lamp module and a lamp.

A luminaire module, comprising: the LED driving power supply comprises a lighting assembly, a wireless module, an induction module and an LED driving power supply module; the induction module is electrically connected with the wireless module, the wireless module is electrically connected with the LED driving power supply module, and the LED driving power supply module is electrically connected with the lighting assembly.

In one embodiment, the wireless module comprises a first processor and a wireless communication sub-module, the wireless communication sub-module is electrically connected with the first processor, and the first processor is electrically connected with the LED driving power supply module and the induction module respectively.

In one embodiment, the lamp module further includes a second processor, the LED driving power module is electrically connected to the wireless module through the second processor, and the wireless module is further electrically connected to the sensing module through the second processor.

In one embodiment, the lamp module further comprises a standby power supply electrically connected with the wireless module.

In one embodiment, the sensing module includes a mobile object sensing circuit electrically connected to the wireless module.

In one embodiment, the sensing module includes an ambient light sensor electrically connected to the wireless module.

In one embodiment, the sensing module includes a temperature and humidity sensor, and the ambient light sensor is electrically connected to the wireless module.

In one embodiment, the wireless module comprises at least one of a bluetooth communication module, a WIFI communication module, and a ZigBee communication module.

A lamp comprises the lamp module as described in any one of the above embodiments.

In one embodiment, the luminaire further comprises a gateway, and the wireless module of each luminaire module is electrically connected with the gateway.

The invention has the beneficial effects that: by arranging the wireless module and the induction module, the lamp module can collect external signals through the induction module and convert the external signals into electric signals, then the electric signals are sent to the wireless module, the wireless module receives the electric signals and sends the received electric signals to other terminal equipment, the function of data monitoring and reporting is realized, the wireless module is also used for receiving the electric signals sent by other terminal equipment and sending corresponding data commands to the LED driving power supply module to control the illumination assembly to work, and then the illumination assembly is controlled through the terminal equipment; through setting up wireless module for the lamps and lanterns module can link with other terminal equipment, and the accessible terminal equipment adjusts the lamps and lanterns module, has solved the problem that response effect and control effect are difficult to the adjustment after lamps and lanterns installation.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

Fig. 1 is a schematic block diagram of a lamp module according to an embodiment;

fig. 2 is a schematic block diagram of a lamp module according to yet another embodiment;

fig. 3 is a schematic block diagram of a lamp module according to yet another embodiment;

fig. 4 is a schematic block diagram of a lamp module according to yet another embodiment;

fig. 5 is a schematic block diagram of a lamp module according to yet another embodiment;

FIG. 6 is a block diagram of a lamp according to an embodiment;

FIG. 7 is an exploded view of an embodiment of a lamp;

FIG. 8 is an exploded view of a lamp according to yet another embodiment;

FIG. 9 is an exploded view of a lamp according to yet another embodiment;

fig. 10 is an exploded view of a lamp according to yet another embodiment.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The invention discloses a lamp module, which comprises a lighting assembly, a wireless module, an induction module and an LED (light emitting diode) driving power module, wherein the lighting assembly comprises a Light Emitting Diode (LED) driving power module; the induction module is electrically connected with the wireless module, the wireless module is electrically connected with the LED driving power supply module, and the LED driving power supply module is electrically connected with the lighting assembly.

The lamp module is provided with the wireless module and the induction module, so that the lamp module can collect external signals through the induction module and convert the external signals into electric signals, and then sends the electric signals to the wireless module, the wireless module sends the received electric signals to other terminal equipment after receiving the electric signals, the function of data monitoring and reporting is realized, the wireless module is also used for receiving the electric signals sent by other terminal equipment and sending corresponding data commands to the LED driving power supply module to control the illumination assembly to work, and then the illumination assembly is controlled through the terminal equipment; through setting up wireless module for the lamps and lanterns module can link with other terminal equipment, and the accessible terminal equipment adjusts the lamps and lanterns module, has solved the problem that response effect and control effect are difficult to the adjustment after lamps and lanterns installation.

In order to facilitate understanding of the lamp of the present application, the lamp will be further described with reference to the accompanying drawings.

As shown in fig. 1, a lamp module 10 includes: a lighting assembly 100, a wireless module 200, a sensing module 300, and an LED driving power module 400; the sensing module 300 is electrically connected to the wireless module 200, the wireless module 200 is electrically connected to the LED driving power module 400, and the LED driving power module 400 is electrically connected to the lighting assembly 100.

The sensing module 300 is used for collecting external signals, converting the external signals into electric signals, and transmitting the electric signals to the wireless module 200. Specifically, the sensing module 300 is a sensor or a sensing component. When the external environment changes correspondingly, the sensing module 300 may receive a corresponding signal, convert the signal into an electrical signal, and send the electrical signal to the wireless module 200. In one embodiment, the sensing module 300 transmits the electrical signal to the wireless module 200 through a UART (Universal Asynchronous Receiver/Transmitter), an Inter-Integrated Circuit (IIC), or the like.

The wireless module 200 is configured to send the received electrical signal to other terminal devices after receiving the electrical signal, and is further configured to receive the electrical signal sent by other terminal devices and send a corresponding data command to the LED driving power module 400, so as to control the lighting assembly 100 through the terminal devices. Specifically, the wireless module 200 sends and reports data to the terminal device through radio frequency. Specifically, the wireless module 200 is a radio frequency circuit of an ad hoc network, and transmits the processed signal to other terminal devices through radio frequency or reports the processed signal to the master control platform.

In one embodiment, the wireless module 200 is connected to the internet through a wireless gateway, a router, and the like, and uploads data to the control system background.

In one embodiment, the Wireless module 200 includes at least one of a bluetooth communication module, a WIFI (Wireless Fidelity, Wireless communication technology) communication module, and a ZigBee (ZigBee technology) communication module.

The LED driving power module 400 is configured to receive a control signal of a terminal device, and drive the lighting assembly 100 to operate, so that the lighting assembly 100 performs control such as switching, dimming, and color mixing. Specifically, the LED driving power module 400 may be further electrically connected to the sensing module 300, so that the sensing module 300 is connected to an external power source through the LED driving power module 400. Specifically, the LED driving power module 400 may be electrically connected to the wireless module 200, so that the wireless module 200 is connected to an external power source through the LED driving power module 400.

The lighting assembly 100 is used to provide illumination to an environment. Specifically, the lighting assembly 100 is further configured to receive data commands sent by the terminal device through the wireless module 200 so as to execute switching, dimming, and other commands. In particular, the lighting assembly 100 comprises a switching module which can control the switching of the lighting assembly 100 when the switching module receives a data command of on or off of the wireless module. Specifically, the lighting assembly 100 comprises a dimming module, which can control the lighting condition of the lighting assembly 100 when receiving the dimming data command of the wireless module 200. In particular, the lighting assembly 100 may also comprise other existing modules with other functions, such as color matching. In particular, the lighting assembly 100 is a single or dual color LED lighting module.

It should be noted that the lighting assembly 100 capable of performing the switching activity and the dimming activity by receiving the data command is the prior art, and is not related to the improvement of the present application, and is not described herein again.

To facilitate control of the lighting assembly, as shown in fig. 2, in one embodiment, the wireless module 200 includes a first processor 210 and a wireless communication sub-module 220, the wireless communication sub-module 220 is electrically connected to the first processor 210, and the first processor 210 is electrically connected to the LED driving power module 400 and the sensing module 300, respectively. Therefore, the wireless module is provided with the first processor, the first processor can process the external signals detected by the sensing module, and when the external signals received by the first processor reach the triggering condition of the sensing triggering threshold set by the internal program of the first processor, the first processor is convenient to drive the power supply module through the LED to control the lighting assembly to execute instructions such as switching and dimming. For example, the person activity condition detected by the sensing module is sent to the first processor, and when the triggering conditions of switching, sensing delay, brightness change and the like set by the internal program of the first processor are reached, the first processor conveniently controls the lighting assembly to execute the instructions of switching, sensing delay, brightness change and the like through the LED driving power supply module. For example, the ambient light illumination condition detected by the sensing module is sent to the first processor, and when the triggering conditions of switching, sensing delay, brightness change and the like set by the internal program of the first processor are reached, the first processor conveniently controls the lighting assembly to execute instructions of switching, sensing delay, brightness change and the like through the LED driving power module. For example, the temperature and humidity conditions detected by the sensing module are sent to the first processor, and when the triggering conditions of switching, sensing delay, brightness change and the like set by the internal program of the first processor are reached, the first processor conveniently controls the lighting assembly to execute instructions of switching, sensing delay, brightness change and the like through the LED driving power module.

In one embodiment, the wireless communication sub-module comprises at least one of a bluetooth communication module, a WIFI communication module, a ZigBee communication module, and a wireless communication sub-module.

In order to integrate the wireless communication sub-module and the first processor, in one embodiment, the light fixture module further includes a first housing, and the wireless module and the first processor are both disposed in the first housing. In this way, the wireless communication sub-module and the first processor may be integrated.

In order to facilitate control of the lighting assembly, in another embodiment, as shown in fig. 3, the luminaire module further includes a second processor 500, the lighting assembly 100 is electrically connected to the wireless module 200 through the second processor 500, and the wireless module 200 is further electrically connected to the sensing module 300 through the second processor 500. Like this, through set up the second treater between wireless module and response module, can in time handle the information that the response module detected, when reaching the trigger condition of the response trigger threshold value that the inside procedure of second treater set for, conveniently pass through LED drive power module through the second treater and control lighting components and carry out instruction such as switch, adjust luminance. For example, the person activity condition detected by the sensing module is sent to the second processor, and when the triggering conditions of switching, sensing delay, brightness change and the like set by the internal program of the second processor are reached, the second processor conveniently controls the lighting assembly to execute the instructions of switching, sensing delay, brightness change and the like through the LED driving power supply module. For example, the ambient light illumination condition detected by the sensing module is sent to the second processor, and when the triggering conditions of switching, sensing delay, brightness change and the like set by the internal program of the second processor are reached, the second processor conveniently controls the lighting assembly to execute the instructions of switching, sensing delay, brightness change and the like through the LED driving power supply module. For example, the temperature and humidity conditions detected by the sensing module are sent to the second processor, and when the triggering conditions of switching, sensing delay, brightness change and the like set by the internal program of the second processor are reached, the second processor conveniently controls the lighting assembly to execute the instructions of switching, sensing delay, brightness change and the like through the LED driving power module.

To integrate the sensing module and the second processor together, in one embodiment, the light fixture module further comprises a second housing, wherein the sensing module and the second processor are both disposed within the second housing. In this way, the sensing module and the second processor can be integrated.

In order to make the wireless module still usable without an external power source, as shown in fig. 4, in one embodiment, the lamp module further includes a standby power source 600, and the standby power source 600 is electrically connected to the wireless module 200. The standby power supply is used for supplying power to the wireless module. Therefore, by arranging the external power supply, the wireless module can continue to work when the external power supply is not switched on, and receives the instruction of the induction module or other terminal equipment. And the standby power supply supplies power to the lighting assembly and the induction module through the wireless module. Therefore, the lamp module can still be used when no external power supply is available.

In order to make the sensing module still usable without an external power supply, in one embodiment, the standby power supply is further connected to the sensing module. The standby power supply is also used for supplying power to the induction module. Therefore, by arranging the external power supply, the induction line module can continue to work when the external power supply is not switched on, signals such as activity of detection personnel, ambient light intensity, temperature and humidity and the like are detected, and the detection signals are sent to the wireless module.

In order to integrate the LED driving power module and the standby power, in one embodiment, the lamp module further includes a third housing, and the LED driving power module and the standby power are both disposed in the third housing. The LED driving power supply module is used for driving the lighting assembly to work, and the standby power supply is used as a standby power supply to supply power to the modules needing to work when no external power supply exists. Thus, the two power supplies are arranged in the same shell and integrated together, so that the two power supplies are better protected.

In order to detect human activities, in one embodiment, as shown in fig. 5, the sensing module 300 includes a moving object sensing circuit 310, and the moving object sensing circuit 310 is electrically connected to the wireless module 200. Therefore, by arranging the moving object induction circuit, the movement of the moving object can be detected, the detected personnel movement information is sent to the wireless module, and the detected personnel movement information is sent to the lighting assembly or the terminal equipment through the wireless module, so that the lighting assembly executes a corresponding instruction set according to the personnel movement condition.

In one embodiment, the wireless module includes a first processor and a wireless communication sub-module electrically connected to the first processor, and the first processor is electrically connected to the lighting assembly and the moving object sensing circuit, respectively. The moving object sensing circuit can communicate with the processor in a UART and IIC manner to implement the setting of the sensing delay and the sensing range and the sensing triggering of the moving object, and can also implement the setting of the sensing delay and the sensing range and the sensing triggering of the moving object by the evaluation change of the duty ratio or frequency and the level voltage of the PWM (Pulse Width Modulation).

In one embodiment, the lamp module further includes a second processor, the lighting assembly is electrically connected to the wireless module through the second processor, and the wireless module is further electrically connected to the moving object sensing circuit through the second processor.

In one embodiment, the moving object sensing circuit is a microwave sensing circuit, and the microwave sensing circuit is electrically connected to the wireless module. In one embodiment, the moving object sensing circuit is a radar sensing circuit, and the radar sensing circuit is electrically connected to the wireless module. The microwave sensing circuit and the radar sensing circuit can be communicated with the processor in a UART and IIC mode to realize sensing delay, setting of a sensing range and sensing triggering of a moving object, and can also realize the setting of the sensing delay and the sensing range and the sensing triggering of the moving object through evaluation change of duty ratio or frequency of PWM and level voltage.

In one embodiment, the moving object sensing circuit is a pyroelectric infrared sensing circuit, and the pyroelectric infrared sensing circuit is electrically connected with the wireless module. The pyroelectric infrared sensing circuit realizes the setting of sensing time delay and sensing range and the sensing triggering of a moving object through the level voltage.

In order to detect the ambient light level, in one embodiment, as shown in fig. 5, the sensing module 300 includes an ambient light sensor 320, and the ambient light sensor 320 is electrically connected to the wireless module 200. Therefore, the ambient light sensor is arranged, the ambient light illumination can be detected, the detected ambient light illumination information is sent to the wireless module, and the wireless module sends the ambient light illumination information to the lighting assembly or the terminal equipment, so that the lighting assembly executes a corresponding instruction set according to the ambient light illumination condition. The ambient light sensor can realize the transmission of the illumination and temperature signals through the IIC and the voltage level.

In one embodiment, the wireless module includes a first processor and a wireless communication sub-module electrically connected to the first processor, the first processor being electrically connected to the lighting assembly and the ambient light sensor, respectively.

In one embodiment, the luminaire module further includes a second processor, the lighting assembly is electrically connected to the wireless module through the second processor, and the wireless module is further electrically connected to the ambient light sensor through the second processor.

In order to detect the ambient temperature and humidity, in one embodiment, as shown in fig. 5, the sensing module includes a temperature and humidity sensor 330, and the ambient light sensor 330 is electrically connected to the wireless module 200. Like this, through setting up temperature and humidity sensor, can detect environment humiture to send the environment humiture information that detects for wireless module, send illumination component or terminal equipment again through wireless module, thereby make illumination component carry out the corresponding instruction that sets up according to the environment humiture condition. The temperature and humidity sensor can realize the transmission of illumination and temperature signals through the IIC and the voltage level.

In one embodiment, the wireless module comprises a first processor and a wireless communication sub-module, the wireless communication sub-module is electrically connected with the first processor, and the first processor is electrically connected with the lighting assembly and the temperature and humidity sensor respectively.

In one embodiment, the lamp module further includes a second processor, the lighting assembly is electrically connected to the wireless module through the second processor, and the wireless module is further electrically connected to the temperature and humidity sensor through the second processor.

The application further provides a lamp, which comprises the lamp module in any one of the above embodiments.

Specifically, as shown in fig. 7 to 10, the light fixture includes a light-transmissive cover 810, a bracket 820, an end cap 830, a power supply jacket 840, a sensing module cover 880, and a light fixture module including a lighting assembly 100, a wireless module 200, a sensing module 300, and an LED driving power supply module 400; the sensing module 300 is electrically connected to the wireless module 200, the wireless module 200 is electrically connected to the LED driving power module 400, and the LED driving power module 400 is electrically connected to the lighting assembly 100. The LED driving power supply 400 is accommodated in the power supply casing 840, the lighting assembly 100, the wireless module 200, the sensing module 300 and the power supply casing 840 are respectively arranged on the bracket 820, the light-transmitting cover 810 covers the bracket 820 and covers the lighting assembly 100, the sensing module cover 880 covers the bracket 820 and covers the wireless module 200, the sensing module 300 and the power supply casing 840, and the end cover 830 covers the end of the bracket 820. In one embodiment, the support 820 is an aluminum tube.

In one embodiment, as shown in fig. 7 and 9, the number of the end caps 830 is two, and the two end caps 830 are respectively disposed at two ends of the bracket 820.

In one embodiment, as shown in fig. 7 and 8, the sensing module 300 is a microwave sensing circuit, and the microwave sensing circuit is electrically connected to the wireless module 200. In one embodiment, the sensing module 300 is a radar sensing circuit, and the radar sensing circuit is electrically connected to the wireless module 200.

In one embodiment, as shown in fig. 9 and 10, the sensing module 300 is a pyroelectric infrared sensing circuit, the pyroelectric infrared sensing circuit is electrically connected to the wireless module 200, and the lamp further includes a fresnel lens 890, and the fresnel lens 890 is disposed on the pyroelectric infrared sensing circuit in a covering manner.

According to the lamp, the wireless module and the induction module are arranged, so that the lamp module can collect external signals through the induction module and convert the external signals into electric signals, then the electric signals are sent to the wireless module, the wireless module sends the received electric signals to other terminal equipment after receiving the electric signals, the function of data monitoring and reporting is achieved, the wireless module is also used for receiving the electric signals sent by other terminal equipment and sending corresponding data commands to the LED driving power supply module to control the illumination assembly to work, and then the illumination assembly is controlled through the terminal equipment; through setting up wireless module for the lamps and lanterns module can link with other terminal equipment, and the accessible terminal equipment adjusts the lamps and lanterns module, has solved the problem that response effect and control effect are difficult to the adjustment after lamps and lanterns installation.

In one embodiment, the luminaire includes a plurality of luminaire modules 10, and the luminaire further includes a gateway 700, and the wireless module of each luminaire module 10 is electrically connected to the gateway. In one embodiment, the gateway 700 is also configured to wirelessly interface with the terminal device 900. For example, the gateway is also used for wireless connection with an APP (Application) of the terminal device. For example, the gateway is also used for wireless connection with a Web (World Wide Web) page of the terminal device. Because the traditional lamp has a single function and only can control the lighting assembly singly, wireless networking is increased by arranging the gateway, and the networking control function of the lamp is realized; and through network control, the induction effect of the induction module is not consistent due to individual difference of the illumination assembly, so that the illumination effect of the assembly is not consistent and the overall illumination effect is influenced.

Specifically, the wireless modules of the lamps form an ad hoc network through a gateway, a user can set a linkage effect that when any lamp senses that an object moves, other lamps in the network are lightened along with the lamp through an APP or Web page end of terminal equipment, when all sensed lamps are not occupied, all lamps enter a lightening state, and the lamp is turned off after the set time is delayed; and the state that the latter lamp is lighted up and turned off along with the former lamp tube can be set according to the installation position of the lamp.

Specifically, when the wireless module of one lamp module receives the data sensed by the sensing module, the data can be sent to the lighting assemblies of other lamp modules with the same wireless module, the brightness or the color temperature of the lamp tube can be controlled according to a preset scene, and the lamp is turned on or off. The user can also monitor the working condition of the lamp through the APP of the terminal equipment or the system webpage platform, and adjust the values of the trigger conditions such as ambient illuminance, temperature and humidity and the like and adjust the induction delay, the brightness value and the like according to the actual application scene.

Specifically, the wireless modules of the terminal devices may form a local area network, share data between the sensing modules, and simultaneously may be controlled by each other. The data of the local area network can be connected to the intelligent building system in a wired or wireless mode, and the data of personnel triggering, illumination and humidity can be shared in real time. If the moving object induction circuit senses that people move, the moving object induction circuit turns on or off a plurality of or a single lamp module in the lamp according to preset action and automatically turns off after delaying for a period of time, and whether the lamp needs to be turned on or not can be judged according to the brightness of the ambient light.

Data are accumulated in a certain time, corresponding relations among time periods, temperature and humidity, ambient light and activity heat of people can be obtained, and through data analysis, a user can more accurately customize an energy-saving scheme.

The induction lamp with the circuit technology can be applied to places such as parking lots, offices, hospitals and the like, and realizes high efficiency and energy conservation

In one embodiment, please refer to fig. 6 again, the light fixture further includes a WIFI communication module 800, and the gateway 700 is further electrically connected to the WIFI communication module 800. In one embodiment, the WIFI communication module 800 is further configured to wirelessly connect with the terminal device 900. For example, the WIFI communication module is further configured to wirelessly connect with an APP of the terminal device. For example, the WIFI communication module is further configured to wirelessly connect with a Web page of the terminal device.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. A luminaire module, comprising: the LED driving power supply comprises a lighting assembly, a wireless module, an induction module and an LED driving power supply module; the induction module is electrically connected with the wireless module, the wireless module is electrically connected with the LED driving power supply module, and the LED driving power supply module is electrically connected with the lighting assembly.

2. The lamp module of claim 1, wherein the wireless module comprises a first processor and a wireless communication sub-module, the wireless communication sub-module is electrically connected to the first processor, and the first processor is electrically connected to the LED driving power module and the sensing module, respectively.

3. The lamp module of claim 1, further comprising a second processor, wherein the LED driving power module is electrically connected to the wireless module through the second processor, and the wireless module is further electrically connected to the sensing module through the second processor.

4. The light fixture module of claim 1, further comprising a standby power supply electrically connected to the wireless module.

5. The luminaire module of claim 1, wherein the sensing module comprises a mobile object sensing circuit electrically connected to the wireless module.

6. The luminaire module of claim 1, wherein the sensing module comprises an ambient light sensor electrically connected to the wireless module.

7. The lamp module of claim 1, wherein the sensing module comprises a temperature and humidity sensor, and the ambient light sensor is electrically connected to the wireless module.

8. The luminaire module of claim 1, wherein the wireless module comprises at least one of a bluetooth communication module, a WIFI communication module, and a ZigBee communication module.

9. A luminaire comprising a luminaire module as claimed in any one of claims 1 to 8.

10. The lamp of claim 9, further comprising a gateway, wherein the wireless module of each lamp module is electrically connected to the gateway.