Ad-hoc network sensing controlled LED lamp
The LED lights controlled by self-organizing network sensors utilize wirelessly connected light-sensing and lighting control modules, combined with electric actuators and baffle designs, to solve the problem of light-sensing modules disturbing users' rest, achieving automatic adjustment and energy-saving effects for the lights.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- BEIJING TAIBAOLONG ENERGY TECH CO LTD
- Filing Date
- 2025-08-01
- Publication Date
- 2026-06-26
AI Technical Summary
In existing technologies, when the light sensor module detects insufficient light at night, it will control the lights to turn on, which will affect the user's rest. Moreover, after getting up, the user needs to manually turn the light sensor module off or on, which is quite troublesome.
The LED lights, which are controlled by a self-organizing network, achieve automatic adjustment of the lights through the wireless connection of the first and second light sensing modules, the light control module and the control module. Combined with the design of electric push rods and baffles, the lights are automatically controlled to turn on and off according to the lighting conditions.
While ensuring users' rest, the system automatically adjusts the on and off of the lights, improving the flexibility and energy efficiency of the device and reducing the hassle of manual operation.
Smart Images

Figure CN224418987U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of indoor lighting system technology, and in particular to an LED lamp with self-organizing network sensing control. Background Technology
[0002] Traditional indoor lights are controlled by wall switches. To save energy, some indoor lights are connected to light sensor switches. When the light intensity is high during the day, the illuminance sensor on the light sensor switch will detect this and control the indoor lights to turn off, thereby saving electricity.
[0003] For example, Chinese patent application number CN201920927885.8 discloses an intelligent dimming system for indoor lighting, comprising two LED lamps and a light-sensing module. One of the LED lamps is positioned near a window indoors, while the other is positioned away from the window. This device can save energy while making indoor lighting more suitable for human eyes, thus making the lighting system more user-friendly.
[0004] Regarding the above and existing related technologies, the inventors believe that the following defects often exist: At night, the light-sensing module will also sense insufficient light and control the lights near the window to turn on. If the user needs to sleep at this time, the turned-on lights will affect the user's rest. At this time, the light-sensing module needs to be turned off manually. After getting up, the light-sensing module needs to be turned on again so that it can continue to control the LED lights to turn on and off through the brightness, which is quite troublesome. Summary of the Invention
[0005] The technical problem to be solved by this utility model is that the existing technology has the disadvantage of requiring the light sensor module to be turned on or off when people rest or get up, which is quite troublesome. To address this, we propose a self-organizing network sensing control LED light.
[0006] To achieve the above objectives, this application adopts the following technical solution: a self-organizing network sensing-controlled LED light, comprising a first LED light fixture and a second LED light fixture: the first LED light fixture is installed indoors near a window, and the second LED light fixture is installed indoors away from the window. A first light-sensing module, an LED driver power supply, and a light control module are also installed indoors near the window, and a second light-sensing module is installed indoors away from the window. The light control module is wirelessly connected to both the first and second light-sensing modules. An installation box is installed indoors away from the window, and a control module is installed inside the installation box. A third light-sensing module is installed on the outer wall of the installation box, and the second light-sensing module is installed inside the installation box. An opening is provided in the installation box away from the window, and a baffle is provided therein. The top of the baffle is hinged to the installation box. An electric push rod is hinged inside the installation box, and the control module is electrically connected to the electric push rod. The telescopic end of the electric push rod is hinged to the baffle. A push rod driver power supply is installed inside the installation box.
[0007] Preferably, the first light-sensing module includes a first circuit board, on which a first microcontroller, a first 2.4G transceiver, a first 2.4G transceiver antenna, and an illuminance sensor are disposed.
[0008] Preferably, the first light-sensing module and the second light-sensing module have the same structure, with the illuminance sensor near the window facing the window and the illuminance sensor away from the window facing the second LED lamp.
[0009] Preferably, the lighting control module includes a second circuit board, on which a second microcontroller, a second 2.4G transceiver, a second 2.4G transceiver antenna, a power module, and a PWM control line are disposed, and the PWM control line is connected to the LED driver power supply.
[0010] Preferably, both the first light-sensing module and the second light-sensing module are wirelessly connected to the lighting control module via a first 2.4G transceiver and a second 2.4G transceiver.
[0011] Preferably, the control module and the lighting control module have the same structure, and the control module is electrically connected to the push rod drive power supply through a PWM control line.
[0012] Preferably, the third optical sensing module and the first optical sensing module have the same structure, and the control module achieves wireless connection with the third optical sensing module through the first 2.4G transceiver and the second 2.4G transceiver.
[0013] The technical effects and advantages of this utility model are as follows: This utility model allows personnel to conveniently turn off both the first and second lamps during rest to avoid disturbing their rest, and also allows the first lamp to turn on automatically according to the brightness without subsequent manual operation.
[0014] In this invention, the device can be configured to turn on both the first and second lights, or turn on the second light alone, depending on actual needs when indoor lighting is insufficient, greatly improving the flexibility of the device. Attached Figure Description
[0015] The disclosure of this utility model is illustrated with reference to the accompanying drawings. It should be understood that the drawings are for illustrative purposes only and are not intended to limit the scope of protection of this utility model. In the drawings, the same reference numerals are used to refer to the same parts:
[0016] Figure 1 This is a schematic diagram of the overall structure of this utility model; Figure 2 This is a schematic diagram of the mounting box in this utility model; Figure 3 This is a cross-sectional view of the mounting box in this utility model; Figure 4 This is a schematic diagram of the structure of the baffle and electric actuator in this utility model; Figure 5 This is a schematic diagram of the structure of the first light-sensing module in this utility model; Figure 6 This is a schematic diagram of the structure of the lighting control module in this utility model.
[0017] Legend: 1. First LED lamp; 2. Second LED lamp; 3. First light sensor module; 31. First circuit board; 32. First microcontroller; 33. First 2.4G transceiver; 34. First 2.4G transceiver antenna; 35. Illuminance sensor; 4. LED driver power supply; 5. Light control module; 51. Second circuit board; 52. Second microcontroller; 53. Second 2.4G transceiver; 54. Second 2.4G transceiver antenna; 55. Power module; 56. PWM control line; 6. Second light sensor module; 7. Mounting box; 8. Control module; 9. Third light sensor module; 10. Opening; 11. Baffle; 12. Electric actuator; 13. Actuator drive power supply. Detailed Implementation
[0018] It is readily understood that, based on the technical solution of this utility model, those skilled in the art can propose various interchangeable structural methods and implementations without altering the essential spirit of this utility model. Therefore, the following detailed embodiments and accompanying drawings are merely illustrative descriptions of the technical solution of this utility model and should not be considered as the entirety of this utility model or as limitations or restrictions on the technical solution of this utility model.
[0019] Reference Figure 1-6As shown, this utility model provides a technical solution: a self-organizing network sensing-controlled LED light, including a first LED light fixture 1 and a second LED light fixture 2. The first LED light fixture 1 is installed indoors near a window, and the second LED light fixture 2 is installed indoors away from the window. A first light-sensing module 3, an LED driver power supply 4, and a light control module 5 are also installed indoors near the window. A second light-sensing module 6 is also installed indoors away from the window. The light control module 5 is wirelessly connected to both the first light-sensing module 3 and the second light-sensing module 6. An installation box 7 is installed away from the window. A control module 8 is installed inside the installation box 7. A third light-sensing module 9 is installed on the outer wall of the installation box 7. A second light-sensing module 6 is installed inside the installation box 7. An opening 10 is provided in the installation box 7 away from the window. A baffle 11 is provided in the installation box 7 away from the window. The top of the baffle 11 is hinged to the installation box 7. An electric push rod 12 is hinged inside the installation box 7. The control module 8 is electrically connected to the electric push rod 12. The telescopic end of the electric push rod 12 is hinged to the baffle 11. A push rod drive power supply 13 is installed inside the installation box 7.
[0020] In order for the first light sensing module 3 to send signals to the lighting control module 5, the first light sensing module 3 includes a first circuit board 31, on which a first microcontroller 32, a first 2.4G transceiver 33, a first 2.4G transceiver antenna 34 and an illuminance sensor 35 are disposed.
[0021] To enable the second light-sensing module 6 to send signals to the lighting control module 5, the first light-sensing module 3 and the second light-sensing module 6 have the same structure. The illuminance sensor 35 near the window faces the window, while the illuminance sensor 35 away from the window faces the second LED light fixture 2. The first light-sensing module 3 and the second light-sensing module 6 are respectively positioned facing the window and the second LED light fixture 2, thereby making the detection more accurate.
[0022] In order to enable the lighting control module 5 to receive signals from the first light sensor module 3 and the second light sensor module 6, the lighting control module 5 includes a second circuit board 51. The second circuit board 51 is equipped with a second microcontroller 52, a second 2.4G transceiver 53, a second 2.4G transceiver antenna 54, a power supply module 55, and a PWM control line 56. The PWM control line 56 is connected to the LED driver power supply 4.
[0023] In order to enable the lighting control module 5 to wirelessly connect with the first light sensor module 3 and the second light sensor module 6, both the first light sensor module 3 and the second light sensor module 6 are wirelessly connected to the lighting control module 5 through the first 2.4G transceiver 33 and the second 2.4G transceiver 53.
[0024] To enable the control module 8 to be connected to the push rod drive power supply 13, the control module 8 has the same structure as the lighting control module 5, and the control module 8 is electrically connected to the push rod drive power supply 13 via the PWM control line 56.
[0025] In order to enable the control module 8 to receive signals emitted by the third optical sensor module 9, the third optical sensor module 9 has the same structure as the first optical sensor module 3. The control module 8 achieves wireless connection with the third optical sensor module 9 through the first 2.4G transceiver 33 and the second 2.4G transceiver 53.
[0026] Working Principle: In indoor lighting scenarios, two different lighting control logics exist to achieve flexible and energy-saving lighting effects. During the day, if the indoor lighting is sufficient near the window but insufficient further away, people can turn on the second LED light 2 to increase indoor brightness. Since the first light sensor module 3 can detect sufficient lighting near the window, even if the overall indoor brightness is insufficient further away from the window and the second LED light 2 is turned on, the first LED light 1 will not be turned on, thus saving power. At night, the first light sensor module 3 will detect insufficient lighting near the window, but the lighting control module 5 will not control the first LED light 1 to turn on. When people enter the room, due to insufficient overall indoor lighting, they will turn on the second LED light 2 to ensure sufficient lighting further away from the window. At this time, the light emitted by the second LED light 2 will be detected by the second light sensor module 6. The first light sensor module 3 and the second light sensor module 6 simultaneously send signals to the lighting control module 5, which then controls the first LED light 1 to turn on. When personnel need to rest, they can turn off the second LED light 2 by pressing a button. At this time, the second light sensor module 6 detects insufficient light in the room away from the window, and the lighting control module 5 will control the first LED light 1 to turn off. Therefore, the first LED light 1 will only turn on when the first light sensor module 3 detects insufficient light and the second light sensor module 6 detects sufficient light. This control method is convenient for personnel to turn off both the first LED light 1 and the second LED light 2 when resting, avoiding affecting their rest, and also allows the first LED light 1 to turn on automatically according to the light intensity without subsequent manual operation. In addition, in the initial state of the device, the baffle 11 covers the mounting box 7, blocking the opening 10, so that the second light sensor module 6 cannot detect light. When personnel turn on the second LED light 2, the third light sensor module 9 detects sufficient light and sends a command to the control module 8. The control module 8 controls the electric push rod 12 to start, pushing the baffle 11 to rotate, opening the opening 10, allowing the second light sensor module 6 to detect the light emitted by the second LED light 2. If the second LED light fixture 2 is turned off and then turned on again, the third light-sensing module 9 will detect sufficient light a second time. The control module 8 will then control the electric actuator 12 to pull the baffle 11 in the opposite direction, causing the baffle 11 to re-cover the mounting box 7 and block the opening 10. At this point, even if the second LED light fixture 2 is on, the third light-sensing module 9 will not detect any light, and the first LED light fixture 1, which was just turned on due to the third light-sensing module 9 detecting light, will turn off, leaving only the second LED light fixture 2 on indoors. In this way, depending on actual needs, when indoor lighting is insufficient, both the first LED light fixture 1 and the second LED light fixture 2 can be turned on, or only the second LED light fixture 2 can be turned on for illumination, greatly improving the flexibility of the device.
[0027] The technical scope of this utility model is not limited to the content described above. Those skilled in the art can make various modifications and variations to the above embodiments without departing from the technical concept of this utility model, and all such modifications and variations should fall within the protection scope of this utility model.
Claims
1. A self-organizing network induction-controlled LED light, characterized in that, The system includes a first LED light fixture and a second LED light fixture: the first LED light fixture is installed indoors near a window, and the second LED light fixture is installed indoors away from the window. A first light-sensing module, an LED driver, and a lighting control module are also installed indoors near the window. A second light-sensing module is installed indoors away from the window. The lighting control module is wirelessly connected to both the first and second light-sensing modules. An installation box is installed indoors away from the window, and a control module is installed inside the installation box. A third light-sensing module is installed on the outer wall of the installation box, and the second light-sensing module is installed inside the installation box. An opening is provided in the installation box away from the window, and a baffle is provided there. The top of the baffle is hinged to the installation box. An electric actuator is hinged inside the installation box, and the control module is electrically connected to the electric actuator. The telescopic end of the electric actuator is hinged to the baffle. A actuator driver power supply is installed inside the installation box.
2. The self-organizing network sensing-controlled LED light according to claim 1, characterized in that: The first light-sensing module includes a first circuit board, on which a first microcontroller, a first 2.4G transceiver, a first 2.4G transceiver antenna, and an illuminance sensor are disposed.
3. The self-organizing network sensing-controlled LED light according to claim 2, characterized in that: The first light-sensing module and the second light-sensing module have the same structure. The illuminance sensor near the window faces the window, and the illuminance sensor away from the window faces the second LED lamp.
4. The self-organizing network sensing-controlled LED light according to claim 1, characterized in that: The lighting control module includes a second circuit board, on which a second microcontroller, a second 2.4G transceiver, a second 2.4G transceiver antenna, a power module, and a PWM control line are provided. The PWM control line is connected to the LED driver power supply.
5. The self-organizing network induction-controlled LED light according to claim 1, characterized in that: Both the first light-sensing module and the second light-sensing module are wirelessly connected to the lighting control module via the first 2.4G transceiver and the second 2.4G transceiver.
6. The self-organizing network sensing-controlled LED light according to claim 1, characterized in that: The control module and the lighting control module have the same structure. The control module is electrically connected to the push rod drive power supply through a PWM control line.
7. The self-organizing network sensing-controlled LED light according to claim 1, characterized in that: The third optical sensing module has the same structure as the first optical sensing module, and the control module wirelessly connects with the third optical sensing module through the first 2.4G transceiver and the second 2.4G transceiver.