CN110602853A - Scene interaction energy-saving illuminating lamp and illuminating method - Google Patents

Abstract

The invention discloses a scene interaction energy-saving illuminating lamp and an illuminating method, wherein the scene interaction energy-saving illuminating lamp comprises the following components: the device comprises a main control panel, a photosensitive module, a human body detection module and a light module; the human body detection module includes: the human body induction modules are used for sending a trigger signal to the main control panel when the distance between the human body and the human body induction modules is a preset distance; the preset distances of the plurality of human body induction modules are different; the photosensitive module is used for detecting the brightness of the surrounding environment and transmitting the brightness to the main control mainboard; the photosensitive module has the highest priority, and the farther the preset distance of the trigger signal is, the higher the priority is; the main control board is used for receiving the brightness signal and the trigger signal and controlling whether the light module emits light or not and the light emitting brightness according to the priority. According to the scene interaction energy-saving illuminating lamp and the illuminating method, the light changes along with the distance between a person and a tree in different manners by adopting the control modes of different priorities of the plurality of human body induction modules, and the light illuminates the tree more hierarchically and more vividly.

Description

Scene interaction energy-saving illuminating lamp and illuminating method

Technical Field

The invention relates to the technical field of illumination, in particular to a scene interaction energy-saving illuminating lamp and an illuminating method.

Background

The lighting or brightening of the greening trees in the traditional parks, courtyards and landscape belts generally adopts an alternating current commercial power lighting mode, the lighting mode is very dull, the light always maintains one power, the electric energy is consumed in the whole night, and the light pollution is easily caused.

The existing illuminating lamp has the following defects:

1) the light is directly illuminated, and the lamp is monotonous, dull and uninteresting;

2) power supply is not managed, and electric energy waste is serious;

3) the emergency lamp, the flashlight and the like are inconvenient to illuminate, and the illuminating area is small;

4) the greening trees in the areas such as parks, courtyards, landscape belts along roads and the like are not beautified at night.

Therefore, it is urgently needed to provide an energy-saving lighting lamp with interactive scenes, which is energy-saving and humanized.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a scene interaction energy-saving illuminating lamp and an illuminating method, wherein the lighting is changed along with the distance between a person and a tree in a mode of controlling the priority of different induction modules, and the lighting is more layered and vivid on the tree.

In order to solve the technical problems, the invention is realized by the following technical scheme:

the invention provides a scene interaction energy-saving lighting lamp, which comprises: the device comprises a main control panel, a photosensitive module, a human body detection module and a light module; wherein the content of the first and second substances,

the human body detection module includes: the human body induction modules are used for sending a trigger signal to the main control panel when the distance between a human body and the human body induction modules is a preset distance; the preset distances of the human body induction modules are different;

the photosensitive module, the human body induction modules and the light module are respectively connected with the main control panel;

the photosensitive module is used for detecting the brightness of the surrounding environment and transmitting a brightness signal to the main control mainboard;

the main control board is used for receiving the brightness signal transmitted by the photosensitive module and the trigger signal transmitted by the human body detection module, and controlling whether the light module emits light or not and the brightness of the light according to the brightness signal and the trigger signal; the brightness signal is lower than a preset value and is the highest priority, and the trigger signal is effective only when the highest priority is met; the longer the preset distance corresponding to the trigger signal is, the higher the corresponding priority is, and the lower the priority is, the higher the priority is, the lower the priority is, the higher; when the highest priority is met, the main control board is used for controlling the light module to emit light to preset brightness according to the trigger signal, and the closer the preset distance corresponding to the trigger signal is, the brighter the corresponding preset brightness is.

Preferably, the plurality of human body sensing modules are: the device comprises a microwave radar sensing module and a pyroelectric sensing module;

the preset distance of the microwave radar sensing module is greater than that of the pyroelectric sensing module.

Preferably, the method further comprises the following steps: the sound detection module is connected with the main control panel;

the sound detection module is used for detecting the sound of a human body and transmitting a sound signal to the main control board;

the main control panel is used for receiving the sound signals of the sound detection module, the priority of the sound signals is lower than that of the trigger signals, and when all the trigger signals are met, the main control panel is also used for controlling the light module to change color according to the sound signals.

Preferably, the main control panel is further configured to control the light module to gradually go out after a preset time after the human body leaves a preset distance.

Preferably, the method further comprises the following steps: and the communication module is connected with the main control board.

Preferably, the communication module includes: a WIFI module and/or a Bluetooth module.

The invention also provides a scene interaction energy-saving lighting method, which comprises the following steps:

s71: detecting a brightness signal of a surrounding environment, sensing a human body by using a plurality of human body sensing modules with different sensing distances, and sending a trigger signal when the distance between the human body and the human body sensing modules is a preset distance;

s72: judging whether the brightness signal is lower than a preset value, if so, entering step S73, otherwise, entering step S71;

s73: the light emitting brightness of the light module is controlled according to different trigger signals, and the closer the preset distance corresponding to the trigger signals is, the brighter the light emitting brightness is.

Preferably, the human body sensing module in S71 includes: the pyroelectric infrared sensing device comprises a microwave radar sensing module and a pyroelectric sensing module, wherein the preset distance of the microwave radar sensing module is greater than that of the pyroelectric sensing module; in a corresponding manner, the first and second electrodes are,

the S73 specifically includes:

s731: when the microwave radar sensing module sends a trigger signal, the light module is controlled to gradually brighten to a first preset brightness;

s732: when the pyroelectric induction module sends out a trigger signal, the lamplight module is controlled to gradually brighten to a second preset brightness again;

the second preset brightness is larger than the first preset brightness.

Preferably, the step S73 is followed by:

s91: when the sound signal of the human body is detected and the trigger signals are all satisfied, the light module is controlled to change color.

Preferably, the step S73 is followed by:

s101: and controlling the light module to gradually go out after the preset time after the human body leaves the preset distance.

Compared with the prior art, the invention has the following advantages:

(1) the invention provides a scene interaction energy-saving illuminating lamp and an illuminating method, wherein a human body induction module comprises: the lighting is changed along with the distance between a person and a tree in a mode of controlling the priority of different induction modules, the lighting shines on the tree more hierarchically and more vividly, and the person and the greening tree generate a change in mutual response between the distances and are more vivid and interesting;

(2) according to the scene interaction energy-saving illuminating lamp and the illuminating method, the color of the light is controlled to change by arranging the sound detection module, so that the scene interaction energy-saving illuminating lamp is more vivid and interesting.

Of course, it is not necessary for any product in which the invention is practiced to achieve all of the above-described advantages at the same time.

Drawings

Embodiments of the invention are further described below with reference to the accompanying drawings:

fig. 1 is a schematic structural diagram of a scene interaction energy-saving lighting lamp according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a scene-interaction energy-saving lighting lamp according to a preferred embodiment of the invention;

fig. 3 is a schematic structural diagram of a scene-interaction energy-saving lighting lamp according to another preferred embodiment of the invention;

fig. 4 is a circuit diagram of a lighting module of a scene interaction energy-saving lighting lamp according to a preferred embodiment of the invention, which is an LED driving circuit;

fig. 5 is a circuit diagram of a lighting module of a scene interaction energy-saving lighting lamp according to a preferred embodiment of the present invention, which is an LED color string circuit;

fig. 6 is a schematic structural diagram of a scene-interaction energy-saving lighting lamp according to another preferred embodiment of the invention;

fig. 7 is a flowchart of a method for context-interactive energy-saving lighting according to an embodiment of the present invention;

fig. 8 is a schematic diagram of a scene-interaction energy-saving lighting method according to a preferred embodiment of the invention;

fig. 9 is a schematic diagram of a scene-interaction energy-saving lighting method according to another preferred embodiment of the invention.

Description of reference numerals: 1-a main control panel, 2-a photosensitive module, 3-a human body detection module, 4-a light module and 5-a sound detection module;

31-microwave radar sensing module, 32-pyroelectric sensing module.

Detailed Description

The following examples are given for the detailed implementation and specific operation of the present invention, but the scope of the present invention is not limited to the following examples.

Fig. 1 is a schematic structural diagram of a scene-interactive energy-saving lighting lamp according to an embodiment of the present invention.

Referring to fig. 1, the scene interactive energy-saving lighting lamp of the present embodiment includes: the device comprises a main control panel 1, a photosensitive module 2, a human body detection module 3 and a light module 4. Wherein, human detection module 3 includes: the human body induction modules are used for sending a trigger signal to the main control panel when the distance between the human body and the human body induction modules is a preset distance; the preset distances of the plurality of human body induction modules are different. The photosensitive module, the plurality of human body induction modules and the light module are respectively connected with the main control panel; the photosensitive module 2 is used for detecting the brightness of the surrounding environment and transmitting a brightness signal to the main control mainboard 1. The main control board 1 is used for receiving the brightness signal transmitted by the photosensitive module 2 and the trigger signal transmitted by the human body detection module 3, and controlling whether the light module emits light and the brightness of the light according to the brightness signal and the trigger signal. The method specifically comprises the following steps: the brightness signal is lower than the preset value and is the highest priority, and the trigger signal is effective only when the highest priority is met; the longer the preset distance corresponding to the trigger signal is, the higher the corresponding priority is, and the lower the priority is, the higher the priority is, the lower the priority is, the higher the priority is, the lower the priority is, the; when the highest priority is met, the main control board is used for controlling the light module to emit light to preset brightness according to the trigger signal, and the closer the preset distance corresponding to the trigger signal is, the brighter the corresponding preset brightness is.

In the above embodiment, the photosensitive module and each human body sensing module are not connected, the main control board determines whether each trigger signal is valid or not, and the determination can be realized by a hardware circuit (for example, the selection circuit, the luminance signal and each trigger signal are respectively used as an input end of the selection circuit, the corresponding input end 1 represents that the luminance signal is lower than a preset value, 0 represents that the luminance signal is not lower than the preset value or 1 represents that the trigger signal is received, and 0 represents that the trigger signal is not received, and then logical operation is performed to output a corresponding output signal to control the light module), or by a programming mode. In different embodiments, the photosensitive modules and the human body induction modules can be mutually connected, when the high-priority module meets the condition, the high-priority module sends an opening signal to the next-priority module, and the next-priority module starts to work after receiving the opening signal, so that the main control panel can directly control the light module according to the triggering signal without judging whether the higher priority is met or not when receiving the triggering signal.

In a preferred embodiment, the human body sensing module comprises: fig. 2 shows a schematic structural diagram of the microwave radar sensing module 31 and the pyroelectric sensing module 32. The preset distance of the microwave radar sensing module 31 is greater than the preset distance of the pyroelectric sensing module 32, that is, the priority of the microwave radar sensing module 31 is higher than that of the pyroelectric sensing module 32. When the brightness signal meets the condition, namely is lower than a preset value, the main control board receives a trigger signal of the microwave radar sensing module, namely controls the light module to gradually brighten to a first preset brightness; then the main control board receives a trigger signal of the pyroelectric induction module, namely the main control board controls the light module to gradually brighten to a second preset brightness; the second preset brightness is higher than the first preset brightness. Of course, in different embodiments, other human body induction modules can be adopted, and different preset distances can be set according to requirements; more than two human body induction modules can be included, which is not described herein again.

In the above embodiment, the photosensitive module 2, the microwave radar sensing module 31 and the pyroelectric sensing module 32 are not connected, and the priority determination is performed by the main control board. In different embodiments, the photosensitive module 2, the microwave radar sensing module 31 and the pyroelectric sensing module 32 are connected in sequence, as shown in fig. 3. When the brightness signal detected by the photosensitive module 2 is lower than a preset value, a starting signal is sent to the microwave radar sensing module 31, and the microwave radar sensing module 31 starts to work; when the microwave radar sensing module 31 sends a trigger signal, a start signal is sent to the pyroelectric sensing module 32, and the pyroelectric sensing module 32 starts to work, so that the main control board does not need to judge whether the priority higher than the main control board meets the requirement or not when receiving the trigger signal, and the main control board starts to work after the previous priorities meet the requirement.

In a preferred embodiment, the lighting module is an LED lamp, which is energy-saving and has high brightness, and fig. 4 shows an LED driving circuit thereof.

In a preferred embodiment, the light module comprises: the LED color lamp string can emit various beautiful change patterns, generate various aesthetic feeling effects and improve the aesthetic feeling experience of people. Fig. 5 shows a circuit diagram of an LED color light string.

In a preferred embodiment, the illumination lamp further comprises: the sound detection module 5 is connected with the main control board 1, and the structural schematic diagram of the sound detection module is shown in fig. 6. The sound detection module 5 is used for detecting the sound of a human body and transmitting a sound signal to the main control panel 1; the main control panel 1 is used for receiving the sound signal of sound detection module, and the priority of sound signal is less than trigger signal's priority, and when all trigger signals all satisfied, the main control panel still was used for changing colour according to sound signal control light module, and experience effect is better.

Similarly, the sound detection module 5 and the pyroelectric sensing module 32 of the above embodiment are not connected to each other, and the main control board 1 determines whether or not the priority is satisfied. In different embodiments, the sound detection module 5 and the pyroelectric sensing module 32 may be connected to each other, the pyroelectric sensing module 32 sends a trigger signal to send a start signal to the sound detection module 5, and the sound detection module 5 starts to operate, so that the main control board may not determine whether the priority higher than the sound detection module is satisfied when receiving the sound signal, because the main control board starts to operate after the previous priorities are satisfied.

In a preferred embodiment, the main control board 1 is further configured to control the light module 4 to gradually go off after a preset time after the human body leaves a preset distance, so as to save more energy.

In a preferred embodiment, the illumination lamp further comprises: and the communication module is connected with the main control board and can carry out remote control and signal transmission. Preferably, the communication module includes: a WIFI module and/or a Bluetooth module.

Fig. 7 is a flowchart illustrating a scene-interactive energy-saving lighting method according to the present invention.

Referring to fig. 7, the scene interaction energy-saving lighting method of the present embodiment includes the following steps:

s71: detecting a brightness signal of a surrounding environment, sensing a human body by using a plurality of human body sensing modules with different sensing distances, and sending a trigger signal when the distance between the human body and the human body sensing modules is a preset distance;

s72: judging whether the brightness signal is lower than a preset value, if so, entering step S73, otherwise, entering step S71;

s73: the light emitting brightness of the light module is controlled according to different trigger signals, and the closer the preset distance corresponding to the trigger signals is, the brighter the light emitting brightness is.

In a preferred embodiment, the human body sensing module in S71 includes: the device comprises a microwave radar sensing module and a pyroelectric sensing module, wherein the preset distance of the microwave radar sensing module is greater than that of the pyroelectric sensing module; correspondingly, S73 specifically includes:

s731: when the microwave radar sensing module sends a trigger signal, the light module is controlled to gradually brighten to a first preset brightness;

s732: when the pyroelectric induction module sends out a trigger signal, the lamplight module is controlled to gradually brighten to a second preset brightness again;

the second preset brightness (full brightness mode) is greater than the first preset brightness (half brightness mode), and the schematic diagram is shown in fig. 8.

In a preferred embodiment, S73 is followed by:

s91: when the sound signal of the human body is detected and the trigger signals are all satisfied, the light module is controlled to change color, and a schematic diagram of the light module is shown in fig. 9.

In a preferred embodiment, to save more energy, S73 further includes:

s101: and controlling the light module to gradually go out after the preset time after the human body leaves the preset distance.

The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, and not to limit the invention. Any modifications and variations within the scope of the description, which may occur to those skilled in the art, are intended to be within the scope of the invention.

Claims (10)

1. The utility model provides an interactive energy-saving light of sight which characterized in that includes: the device comprises a main control panel, a photosensitive module, a human body detection module and a light module; wherein the content of the first and second substances,

the human body detection module includes: the human body induction modules are used for sending a trigger signal to the main control panel when the distance between a human body and the human body induction modules is a preset distance; the preset distances of the human body induction modules are different;

the photosensitive module, the human body induction modules and the light module are respectively connected with the main control panel;

the photosensitive module is used for detecting the brightness of the surrounding environment and transmitting a brightness signal to the main control mainboard;

the main control board is used for receiving the brightness signal transmitted by the photosensitive module and the trigger signal transmitted by the human body detection module, and controlling whether the light module emits light or not and the brightness of the light according to the brightness signal and the trigger signal; the brightness signal is lower than a preset value and is the highest priority, and the trigger signal is effective only when the highest priority is met; the longer the preset distance corresponding to the trigger signal is, the higher the corresponding priority is, and the lower the priority is, the higher the priority is, the lower the priority is, the higher; when the highest priority is met, the main control board is used for controlling the light module to emit light to preset brightness according to the trigger signal, and the closer the preset distance corresponding to the trigger signal is, the brighter the corresponding preset brightness is.

2. The scene interaction energy-saving lighting lamp according to claim 1, wherein the plurality of human body induction modules are: the device comprises a microwave radar sensing module and a pyroelectric sensing module;

the preset distance of the microwave radar sensing module is greater than that of the pyroelectric sensing module.

3. The scene interaction energy-saving lighting lamp according to claim 1 or 2, characterized by further comprising: the sound detection module is connected with the main control panel;

the sound detection module is used for detecting the sound of a human body and transmitting a sound signal to the main control board;

the main control panel is used for receiving the sound signals of the sound detection module, the priority of the sound signals is lower than that of the trigger signals, and when all the trigger signals are met, the main control panel is also used for controlling the light module to change color according to the sound signals.

4. The lighting lamp of claim 1, wherein the main control panel is further configured to control the light module to gradually turn off after a preset time after the human body leaves a preset distance.

5. The scene interaction energy-saving lighting lamp according to claim 1, further comprising: and the communication module is connected with the main control board.

6. The interactive energy-saving lighting lamp as claimed in claim 5, wherein said communication module comprises: a WIFI module and/or a Bluetooth module.

7. A scene interaction energy-saving lighting method is characterized by comprising the following steps:

s71: detecting a brightness signal of a surrounding environment, sensing a human body by using a plurality of human body sensing modules with different sensing distances, and sending a trigger signal when the distance between the human body and the human body sensing modules is a preset distance;

s72: judging whether the brightness signal is lower than a preset value, if so, entering step S73, otherwise, entering step S71;

s73: the light emitting brightness of the light module is controlled according to different trigger signals, and the closer the preset distance corresponding to the trigger signals is, the brighter the light emitting brightness is.

8. The method of claim 7, wherein the human body sensing module in S71 comprises: the pyroelectric infrared sensing device comprises a microwave radar sensing module and a pyroelectric sensing module, wherein the preset distance of the microwave radar sensing module is greater than that of the pyroelectric sensing module; in a corresponding manner, the first and second electrodes are,

the S73 specifically includes:

s731: when the microwave radar sensing module sends a trigger signal, the light module is controlled to gradually brighten to a first preset brightness;

s732: when the pyroelectric induction module sends out a trigger signal, the lamplight module is controlled to gradually brighten to a second preset brightness again;

the second preset brightness is larger than the first preset brightness.

9. The method according to claim 7 or 8, further comprising after the step S73:

s91: when the sound signal of the human body is detected and the trigger signals are all satisfied, the light module is controlled to change color.

10. The method according to claim 7, further comprising, after the step S73:

s101: and controlling the light module to gradually go out after the preset time after the human body leaves the preset distance.