CN210807764U - double-Zigbee lamp box controller and lamp box control system - Google Patents

Abstract

The utility model discloses a two Zigbee lamp house controllers and lamp house control system, two Zigbee lamp house controllers include two Zigbee modules and relay module, two Zigbee modules include main Zigbee module and follow Zigbee module, through main Zigbee module is used for with controlgear wireless connection, in order to receive the control signal of controlgear output; the main zigbee module receives a control signal and sends the control signal to the intelligent lamp in a wireless mode so as to adjust and control the intelligent lamp; and the relay module controls the input power supply to be switched on or switched off under the control of the double zigbee module so as to control the input power supply of the intelligent lamp box to be switched on or switched off. The power supply of intelligence lamps and lanterns is directly cut off through the relay in long-range mode for the power supply of the lamps and lanterns in the lamp house is thoroughly closed, practices thrift the electric energy on the one hand, and on the other hand makes the lamp house life-span longer.

Description

double-Zigbee lamp box controller and lamp box control system

Technical Field

The utility model relates to the technical field of the thing networking, especially, relate to a two Zigbee lamp house controllers and lamp house control system.

Background

The intelligent lamp box mainly provides commodity exhibition or provides the illumination for the life for commercial service, because be equipped with a plurality of intelligent light in the intelligent lamp box, for the intelligent lamp box passes through sufficient illumination luminance, because the lighting power of intelligent lamps and lanterns is great. Therefore, the intelligent lamp box is a high-energy consumption product, and the energy consumption management of the lamp box is important. In the prior art, the intelligent lamp is controlled to be extinguished in a remote mode. Because the intelligent lamp still can consume more energy after being extinguished, the power consumption of the intelligent lamp cannot be thoroughly cut off by the method. Simultaneously, this mode also influences the life of intelligent lamps and lanterns.

SUMMERY OF THE UTILITY MODEL

The present invention aims at solving at least one of the technical problems in the related art to a certain extent. Therefore, an object of the present invention is to provide a dual Zigbee light box controller and light box control system.

On the one hand, for realizing above-mentioned purpose, according to the utility model discloses a two Zigbee lamp house controllers, two Zigbee lamp house controllers include:

the dual-zigbee module comprises a master zigbee module and a slave zigbee module, wherein the master zigbee module is used for being in wireless connection with a control device so as to receive a control signal output by the control device;

the slave zigbee module is connected with the master zigbee module, receives a control signal through the master zigbee module, and sends the control signal to the intelligent lamp in a wireless mode so as to adjust and control the intelligent lamp;

the relay module is respectively connected with the double-zigbee module, the input alternating current and the intelligent lamp and is used for conducting on or off control on the input alternating current under the control of the double-zigbee module.

Further, according to an embodiment of the present invention, the relay module includes:

the alternating current input and output module comprises an alternating current input interface and an alternating current output interface, the alternating current input interface is connected with input alternating current, and the alternating current output interface is connected with the intelligent lamp;

the input end of the relay switch is connected with the alternating current input interface, and the output end of the relay switch is connected with the alternating current output interface;

and the relay control module is respectively connected with the relay switch and the double-zigbee module and is used for controlling the on or off of the relay switch under the action of the double-zigbee module so as to control the on or off of the input alternating current.

Further, according to an embodiment of the present invention, the relay control module includes: triode Q9, triode Q9's base pass through resistance R2 with the relay control end of two zigbee modules is connected, triode Q9's projecting pole passes through resistance R3 and is connected with reference ground, triode Q9's collecting electrode with the first control end of relay switch is connected, the second control end of relay switch still is connected with first direct current (5V) through resistance R1.

Further, according to an embodiment of the present invention, the main zigbee module includes:

a first front-end signal amplification module;

the first zigbee main control module is connected with the first front-end signal amplification module, and the first zigbee main control module amplifies wireless signals through the first front-end signal amplification module.

Further, according to the utility model discloses an embodiment, first zigbee host system includes first zigbee chip and first zigbee chip peripheral circuit, first zigbee chip peripheral circuit with first zigbee host system connects:

the first front-end signal amplification module comprises a first front-end amplification chip and a first filter circuit, the first front-end amplification chip is respectively connected with the first zigbee main control module and one end of the first filter circuit, and the other end of the first filter circuit is connected with the first antenna.

Further, according to an embodiment of the present invention, the slave zigbee module includes:

a second zigbee main control module;

the second zigbee main control module is connected with the second front-end signal amplification module, and the second zigbee main control module is wirelessly connected with the intelligent lamp through the second front-end signal amplification module.

Further, according to the utility model discloses an embodiment, second zigbee host system includes second zigbee chip and second zigbee chip peripheral circuit, the second zigbee chip respectively with first zigbee chip and second zigbee chip peripheral circuit connect respectively:

the second front-end signal amplification module comprises a second front-end amplification chip and a second filter circuit, the second front-end amplification chip is respectively connected with the second zigbee main control module and the second filter circuit, and the filter circuit is connected with the second antenna.

Further, according to the utility model discloses an embodiment, two Zigbee lamp house controllers still include: a zigbee power supply module connected with the ac input interface for converting ac power to a second dc power (3V3) for supplying power to the dual zigbee modules.

Further, according to the utility model discloses an embodiment, two Zigbee lamp house controllers still include: and the key module is connected with the double zigbee modules and is used for inputting key control signals.

On the other hand, the utility model also provides a lamp house control system, include:

a Zigbee controller;

the Zigbee gateway is wirelessly connected with the Zigbee controller so as to receive a control instruction of the Zigbee controller;

in the dual Zigbee light box controller, the dual Zigbee light box controller is wirelessly connected to the Zigbee gateway, and receives the control instruction through the gateway to perform on/off control on an input power;

and the Zigbee intelligent lamp is wirelessly connected with the double Zigbee lamp box controllers so as to receive the control instruction through the double Zigbee lamp box controllers and adjust the light of the lamp.

The embodiment of the utility model provides a two Zigbee lamp house controllers, through main Zigbee module be used for with controlgear wireless connection, in order to receive the control signal of controlgear output; the main zigbee module receives a control signal and sends the control signal to the intelligent lamp in a wireless mode so as to adjust and control the intelligent lamp; and the relay module controls the input power supply to be switched on or switched off under the control of the double zigbee module so as to control the input power supply of the intelligent lamp box to be switched on or switched off. The power supply of intelligence lamps and lanterns is directly cut off through the relay in long-range mode for the power supply of the lamps and lanterns in the lamp house is thoroughly closed, practices thrift the electric energy on the one hand, and on the other hand makes the lamp house life-span longer.

Drawings

Fig. 1 is a block diagram of a light box control system with a dual Zigbee light box controller according to an embodiment of the present invention;

fig. 2 is a circuit diagram of a dual zigbee module according to an embodiment of the present invention;

fig. 3 is a circuit diagram of a relay module according to an embodiment of the present invention;

fig. 4 is a circuit diagram of a zigbee power supply module according to an embodiment of the present invention;

fig. 5 is a circuit diagram of a key module according to an embodiment of the present invention.

Reference numerals:

a Zigbee controller 10;

a Zigbee gateway 20;

a dual Zigbee light box controller 30;

a dual zigbee module 301;

a master zigbee module 3011;

a first zigbee main control module 30111;

a first front-end signal amplification module 30112;

from zigbee module 3012;

a second zigbee main control module 30121;

a second front-end signal amplification module 30122;

a relay module 302;

an alternating current input/output module 3021;

a relay switch 3022;

a relay control module 3023;

a zigbee power supply module 303;

a key module 304;

a Zigbee smart light fixture 40.

The objects, features and advantages of the present invention will be further described with reference to the accompanying drawings.

Detailed Description

In order to make the technical field person understand the scheme of the present invention better, the following will combine the drawings in the embodiments of the present invention to clearly and completely describe the technical scheme in the embodiments of the present invention. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the invention. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments.

Referring to fig. 1, in one aspect, an embodiment of the present invention provides a dual Zigbee light box controller 30, including: a dual zigbee module 301 and a relay module 302, wherein the dual zigbee module 301 comprises a master zigbee module 3011 and a slave zigbee module 3012, and the master zigbee module 3011 is configured to wirelessly connect with a control device to receive a control signal output by the control device; as shown in fig. 1, the master zigbee module 3011 is communicatively connected with the control device by wireless means. In an implementation of the present invention, the control device may be a Zigbee86 box or a Zigbee86 remote controller, and the Zigbee86 box or the Zigbee86 remote controller is connected to the main Zigbee module 3011 through a Zigbee wireless network in a wireless communication manner, so as to send a control command to the main Zigbee module 3011 in a wireless manner. In another embodiment of the present invention, the control device may also include a Zigbee86 box and a Zigbee gateway 20, and the wireless control signal (control command) sent by the Zigbee86 box is forwarded to the main Zigbee module 3011 through the Zigbee gateway 20.

The slave zigbee module 3012 is connected to the master zigbee module 3011, receives the control signal through the master zigbee module 3011, and sends the control signal to the zigbee intelligent lamp in a wireless manner, so as to adjust and control the zigbee intelligent lamp; the slave zigbee module 3012 is in electrical signal connection with the master zigbee module 3011 to receive a control signal output by the control device through the master zigbee module 3011, and the slave zigbee module 3012 is further in wireless communication connection with the zigbee intelligent lamp to send the received control signal to the zigbee intelligent lamp, so as to perform precise adjustment and control on the brightness and color temperature of the intelligent lamp. In an embodiment of the present invention, the master zigbee module 3011 and the slave zigbee module 3012 operate at different operating frequencies respectively. By setting the master zigbee module 3011 and the slave zigbee module 3012 at different operating frequencies, the master zigbee module 3011 can communicate with the control device through one operating frequency to receive the control signal output by the control device, and the slave zigbee module 3012 can communicate with the intelligent luminaire through another operating frequency to send a control command to the zigbee intelligent luminaire, so as to control the operating state of the zigbee intelligent luminaire. With two different operating frequencies, interference of communication signals between the master zigbee module 3011 and the slave zigbee module 3012 may be avoided. On one hand, the communication quality between the main zigbee module 3011 and the control device is guaranteed; on the other hand, the communication quality between the slave zigbee module 3012 and the intelligent lamp is also guaranteed. In the embodiment of the present invention, the master zigbee module can operate at 2405MHz frequency and the slave zigbee module can operate at 2410MHz frequency.

The relay module 302 is respectively connected to the dual zigbee module 301, the input ac power, and the intelligent lighting fixture, and is configured to control the on/off of the ac power under the control of the dual zigbee module 301, so as to control the on/off of the input power of the intelligent lighting fixture. The relay module 302 is electrically connected to the dual zigbee module 301, and the dual zigbee module 301 may perform on/off control on the relay after receiving the control instruction, so as to control on/off of the input ac power. Because the output end of the relay module 302 is connected with the power supply end of the intelligent lamp, the power supply on-off of the intelligent lamp can be directly controlled through the relay module 302. Because the intelligent lamps in the intelligent lamp box are high-energy-consumption devices, the input power supply is directly cut off by controlling the relay module 302, so that the power supply of the intelligent lamps in the intelligent lamp box is thoroughly turned off, and the service life of the intelligent lamps is longer. In addition, electrical energy can be saved.

The embodiment of the utility model provides a two Zigbee lamp house controllers, through main Zigbee module be used for with controlgear wireless connection, in order to receive the control signal of controlgear output; the main zigbee module receives a control signal and sends the control signal to the intelligent lamp in a wireless mode so as to adjust and control the intelligent lamp; and the relay module controls the input power supply to be switched on or switched off under the control of the double zigbee module so as to control the input power supply of the intelligent lamp box to be switched on or switched off. The power supply of the intelligent lamp is directly cut off in a remote mode through the relay, so that the power supply of the lamp in the lamp box is completely closed. On one hand, the electric energy is saved, and on the other hand, the service life of the lamp box is longer.

Referring to fig. 3, the relay module 302 includes: the relay control system comprises an alternating current input and output module 3021, a relay switch 3022, and a relay control module 3023, wherein the alternating current input and output module 3021 includes an alternating current input interface and an alternating current output interface; the alternating current input interface is used for being connected with alternating current of a mains supply so as to introduce the alternating current of the mains supply into the intelligent lamp box. The alternating current output interface is used for outputting alternating current to supply power for the intelligent lamp in the intelligent lamp box.

The input end of the relay switch 3022 is connected to the ac input interface, and the output end of the relay switch 3022 is connected to the ac output interface; that is, the relay switch 3022 is disposed between the ac power input interface and the ac power output interface to control on or off of the power supply of the intelligent luminaire.

The relay control module 3023 is connected to the relay switch 3022 and the dual zigbee module 301, respectively, and is configured to control the relay switch 3022 to be turned on or off under the action of the dual zigbee module 301, so as to control the input alternating current to be turned on or off. The control terminal of the relay is connected to the relay control terminal of the dual zigbee module 301 to control the on/off of the input ac power under the control of the dual zigbee module 301. That is, the dual zigbee module 301 may perform on or off control of the input ac power by outputting an on or off control signal to the relay control module 3023 after receiving an on or off control instruction of the control apparatus. Because a plurality of intelligent lamps are included in the intelligent lamp box, the total power of the intelligent lamps is larger. The input alternating current is controlled in a relay mode, and the high-current switch control can be realized.

Referring to fig. 3, the relay control module 3023 includes: and a transistor Q9, wherein a base of the transistor Q9 is connected to the relay control terminal of the dual zigbee module 301 through a resistor R2, an emitter of the transistor Q9 is connected to the reference ground through a resistor R3, a collector of the transistor Q9 is connected to the first control terminal of the relay switch 3022, and the second control terminal of the relay switch 3022 is further connected to the first direct current (5V) through a resistor R1. As shown in fig. 3, when the dual zigbee module 301 receives the control power on command, the dual zigbee module 301 outputs a high signal, and the high signal turns on the transistor Q9. At this time, the first control end and the second control end of the relay switch 3022 generate on-current, the relay switch 3022 is turned on, and the input ac power is output from the ac power output interface to supply power to the intelligent lamp. Similarly, after the dual zigbee module 301 receives the control command for controlling the power supply to be turned off, the dual zigbee module 301 outputs a low level signal, so that the triode Q9 is turned off by the low level signal, the relay switch 3022 is turned off, the output of the alternating current output interface has no power supply output, and the power supply of the intelligent lamp is turned off. The embodiment of the utility model provides an in, constitute relay switch 3022 drive circuit through triode Q9 to drive switching on or ending of relay switch 3022, the circuit is simple, and is with low costs.

Referring to FIG. 2, the master zigbee module 3011 includes: the wireless signal amplification system comprises a first front-end signal amplification module 30112 and a first zigbee main control module 30111, the first zigbee main control module 30111 is connected to the first front-end signal amplification module 30112, and the first zigbee main control module 30111 amplifies a wireless signal through the first front-end signal amplification module 30112. Since the main Zigbee module 3011 needs to perform wireless communication with a control device, such as the Zigbee86 gateway or the Zigbee86 box in fig. 1, the first front-end signal amplification module 30112 may perform power amplification on the input and output signals of the first Zigbee main control module 30111 to implement wireless communication at a longer distance, and the first Zigbee main control module 30111 performs Zigbee protocol wireless communication with the control device.

Referring to fig. 2, the first zigbee main control module 30111 includes a first zigbee chip and a first zigbee chip peripheral circuit, and the first zigbee chip peripheral circuit is connected to the first zigbee main control module 30111: the first zigbee chip realizes zigbee protocol communication. The peripheral circuit comprises a first power supply circuit, a first crystal oscillator and a first radio frequency output filter circuit, wherein the first radio frequency output filter circuit comprises a capacitor C24, a capacitor C25, an inductor L3 and a capacitor C26. One end of the capacitor C24, one end of the capacitor C25, and one end of the inductor L3 are respectively connected to the rf input/output end of the first zigbee chip, the other end of the capacitor C24 is connected to the reference ground, the other ends of the capacitor C25 and the inductor L3 are respectively connected to one end of the capacitor C26, and the other end of the capacitor C26 is connected to the first front-end signal amplification module 30112.

The first front-end signal amplification module 30112 includes a first front-end amplification chip and a first filter circuit, the first front-end amplification chip is connected to the first zigbee main control module 30111 and one end of the first filter circuit, and the other end of the first filter circuit is connected to the first antenna. As shown in fig. 2, the first front-end amplifier chip signal transceiver Terminal (TXRX) is connected to the first rf output filter circuit to receive the rf signal output from the first zigbee chip or transmit the rf signal received from the antenna to the first zigbee chip. The first zigbee main control module 30111 is further connected to the first front-end amplifier chip through a transceiving control line to control signal transceiving of the first zigbee chip. As shown in fig. 2, the first front-end amplifier chip signal transceiver Terminal (TXRX) is connected to the first rf output filter circuit to receive the rf signal output from the first zigbee chip or transmit the rf signal received from the antenna to the first zigbee chip. The first zigbee main control module 30111 is further connected to the first front-end amplifier chip through a transceiving control line to control signal transceiving of the first zigbee chip.

Referring to fig. 2, the slave zigbee module 3012 includes: a second zigbee main control module 30121 and a second front-end signal amplification module 30122, where the second zigbee main control module 30121 is connected to the second front-end signal amplification module 30122, and the second zigbee main control module 30121 is wirelessly connected to the zigbee intelligent lamp through the second front-end signal amplification module 30122. Since the slave Zigbee module 3012 needs to perform wireless communication with an intelligent controlled device, such as the Zigbee intelligent luminaire 40 in fig. 2, the input/output signal of the second Zigbee main control module 30121 can be power-amplified by the second front-end signal amplification module 30122 to implement wireless communication at a longer distance, and the second Zigbee main control module 30121 performs Zigbee protocol wireless communication with the intelligent light box.

Referring to fig. 2, the second zigbee main control module 30121 includes a second zigbee chip and a second zigbee chip peripheral circuit, and the second zigbee chip is respectively connected to the first zigbee chip and the second zigbee chip peripheral circuit: the second zigbee chip implements zigbee protocol communication. The peripheral circuit comprises a second power supply circuit, a second crystal oscillator and a second radio frequency output filter circuit, wherein the second radio frequency output filter circuit comprises a capacitor C50, a capacitor C51, an inductor L6 and a capacitor C52. One end of the capacitor C50, one end of the capacitor C51, and one end of the inductor L6 are connected to the rf input/output end of the second zigbee chip, the other end of the capacitor C50 is connected to the reference ground, the other ends of the capacitor C51 and the inductor L6 are connected to one end of the capacitor C52, and the other end of the capacitor C52 is connected to the second front-end signal amplification module 30112.

The second front-end signal amplification module 30122 includes a second front-end amplification chip and a second filter circuit, the second front-end amplification chip is connected to the second zigbee main control module 30121 and the second filter circuit, and the filter circuit is connected to the second antenna. As shown in fig. 2, the second front-end amplifier chip signal transceiver Terminal (TXRX) is connected to the second rf output filter circuit to receive the rf signal output from the second zigbee chip or transmit the rf signal received from the antenna to the second zigbee chip. The second zigbee main control module 30121 is further connected to the second front-end amplifier chip through a transceiving control line to control signal transceiving of the second zigbee chip. As shown in fig. 2, the second front-end amplifier chip signal transceiver Terminal (TXRX) is connected to the second rf output filter circuit to receive the rf signal output from the second zigbee chip or transmit the rf signal received from the antenna to the second zigbee chip. The second zigbee main control module 30121 is further connected to the second front-end amplifier chip through a transceiving control line to control signal transceiving of the second zigbee chip.

Referring to fig. 4, the dual Zigbee light box controller 30 further includes: the zigbee power supply module 303, the zigbee power supply module 303 is connected to the ac power input interface, and is configured to convert the ac power into a second dc power (3V3) to power the dual zigbee module 301. As shown in fig. 4, the zigbee power supply module 303 includes a first power conversion module J3 and a second power conversion module U6, the first power conversion module J3 is used for converting input alternating current into first direct current (5V), and the second power conversion module U6 is connected to the first power module for converting the first direct current (5V) into second direct current (3.3V) to supply power to the dual zigbee module 301.

Referring to fig. 5, the dual Zigbee light box controller 30 further includes: the key module 304, the key module 304 is connected to the dual zigbee module 301, and the key module 304 is configured to input a key control signal. The key module 304 receives a key control signal input by a user, and transmits the key input control signal to the dual zigbee module 301, so as to control the intelligent light box through the dual zigbee module 301.

Referring to fig. 1, on the other hand, the embodiment of the present invention further provides a light box control system, including: the Zigbee control system comprises a Zigbee controller 10, a Zigbee gateway 20, the above-mentioned dual Zigbee lamp box controller 30, and a Zigbee intelligent lamp 40, wherein the Zigbee gateway 20 is wirelessly connected to the Zigbee controller 10 to receive a control instruction of the Zigbee controller 10; when the user uses the Zigbee controller 10, the light box control instruction is sent, and the light box control instruction includes turning off or turning on of the power supply of the light box. And adjusting the brightness and color temperature of the lamp in the intelligent lamp box.

The dual Zigbee light box controller 30 is wirelessly connected to the Zigbee gateway 20, and receives a control instruction through the gateway to perform on/off control on an input power; the wireless gateway serves as a repeater and forwards a signal sent by the Zigbee controller 10 to the dual Zigbee light box controller 30, and the dual Zigbee light box controller 30 can perform disconnection or connection control on the power supply of the intelligent lamp according to the control instruction.

The Zigbee intelligent lamp 40 is wirelessly connected to the dual Zigbee light box controller 30 to receive a control command through the dual Zigbee light box controller 30, so as to adjust the light of the lamp. After receiving the control instruction forwarded by the Zigbee gateway 20 through the main Zigbee module 3011, the dual Zigbee light box controller 30 issues the control instruction to the intelligent lamp through the slave Zigbee module 3012, and the intelligent lamp adjusts the brightness and the color temperature according to the control instruction.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing detailed description, or equivalent replacements may be made for some of the technical features of the embodiments. All utilize the equivalent structure that the content of the utility model discloses a specification and attached drawing was done, direct or indirect application is in other relevant technical field, all is in the same way the utility model discloses within the patent protection scope.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

Although embodiments of the present invention have been shown and described, it is to be understood that the above embodiments are exemplary and should not be construed as limiting the present invention, and that changes, modifications, substitutions and alterations can be made to the above embodiments by those of ordinary skill in the art without departing from the principles and spirit of the present invention.

Claims (10)

1. The utility model provides a two Zigbee lamp house controllers which characterized in that includes:

the dual-zigbee module comprises a master zigbee module and a slave zigbee module, wherein the master zigbee module is used for being in wireless connection with a control device so as to receive a control signal output by the control device;

the slave zigbee module is connected with the master zigbee module, receives a control signal through the master zigbee module, and sends the control signal to the intelligent lamp in a wireless mode so as to adjust and control the intelligent lamp;

the relay module is respectively connected with the double-zigbee module, the input alternating current and the intelligent lamp and is used for conducting on or off control on the input alternating current under the control of the double-zigbee module.

2. The dual Zigbee light box controller of claim 1, wherein the relay module comprises:

the alternating current input and output module comprises an alternating current input interface and an alternating current output interface, the alternating current input interface is connected with the input alternating current, and the alternating current output interface is connected with the intelligent lamp;

the input end of the relay switch is connected with the alternating current input interface, and the output end of the relay switch is connected with the alternating current output interface;

and the relay control module is respectively connected with the relay switch and the double-zigbee module and is used for controlling the on or off of the relay switch under the action of the double-zigbee module so as to control the on or off of the input alternating current.

3. The dual Zigbee light box controller of claim 2, wherein the relay control module comprises: triode Q9, triode Q9's base pass through resistance R2 with the relay control end of two zigbee modules is connected, triode Q9's projecting pole passes through resistance R3 and is connected with reference ground, triode Q9's collecting electrode with the first control end of relay switch is connected, the second control end of relay switch still passes through resistance R1 and first direct current is connected.

4. The dual Zigbee light box controller according to claim 1, wherein the master Zigbee module comprises:

a first front-end signal amplification module;

the first zigbee main control module is connected with the first front-end signal amplification module, and the first zigbee main control module amplifies wireless signals through the first front-end signal amplification module.

5. The dual Zigbee light box controller according to claim 4, wherein the first Zigbee main control module comprises a first Zigbee chip and a first Zigbee chip peripheral circuit, the first Zigbee chip peripheral circuit is connected to the first Zigbee main control module:

the first front-end signal amplification module comprises a first front-end amplification chip and a first filter circuit, the first front-end amplification chip is respectively connected with the first zigbee main control module and one end of the first filter circuit, and the other end of the first filter circuit is connected with the first antenna.

6. The dual Zigbee light box controller according to claim 5, wherein the slave Zigbee module comprises:

a second zigbee main control module;

the second zigbee main control module is connected with the second front-end signal amplification module, and the second zigbee main control module is wirelessly connected with the intelligent lamp through the second front-end signal amplification module.

7. The dual Zigbee light box controller according to claim 6, wherein the second Zigbee main control module comprises a second Zigbee chip and a second Zigbee chip peripheral circuit, the second Zigbee chip is respectively connected to the first Zigbee chip and the second Zigbee chip peripheral circuit:

the second front-end signal amplification module comprises a second front-end amplification chip and a second filter circuit, the second front-end amplification chip is respectively connected with the second zigbee main control module and the second filter circuit, and the filter circuit is connected with the second antenna.

8. The dual Zigbee light box controller of claim 2, further comprising:

and the zigbee power supply module is connected with the alternating current input interface and used for converting alternating current into second direct current to supply power to the double zigbee modules.

9. The dual Zigbee light box controller of claim 1, further comprising:

and the key module is connected with the double zigbee modules and is used for inputting key control signals.

10. A light box control system, comprising:

a Zigbee controller;

the Zigbee gateway is wirelessly connected with the Zigbee controller so as to receive a control instruction of the Zigbee controller;

the dual Zigbee light box controller according to any one of claims 1 to 9, wherein the dual Zigbee light box controller is wirelessly connected to the Zigbee gateway, and receives the control command through the gateway to control on or off of an input power;

and the Zigbee intelligent lamp is wirelessly connected with the double Zigbee lamp box controllers so as to receive the control instruction through the double Zigbee lamp box controllers and adjust the light of the lamp.

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