CN112114525A

CN112114525A - Scene panel with wireless intelligent light resetting function and control method

Info

Publication number: CN112114525A
Application number: CN202010933755.2A
Authority: CN
Inventors: 潘君伦
Original assignee: Hangzhou Metis Intelligent Technology Co ltd
Current assignee: Hangzhou Metis Intelligent Technology Co ltd
Priority date: 2020-09-08
Filing date: 2020-09-08
Publication date: 2020-12-22
Anticipated expiration: 2040-09-08
Also published as: CN112114525B

Abstract

A scene panel with a wireless intelligent light resetting function comprises a shell, an MCU, an indicator light and a relay; the MCU and the indicator lamp are arranged on the shell; the MCU is electrically connected with the control end of the relay; the MCU is electrically connected with the indicator light; when the scene panel is connected with the intelligent lamp, the communication part of the MCU and the driving circuit of the intelligent lamp is connected in a wired or wireless way; the actuating end of the relay is electrically connected with an incoming line terminal of a driving circuit of the intelligent lamp; can switch one or more scenes through setting up a scene panel, control the relay of one or more intelligent lamps, realize not needing intelligent switch board to the one-to-many control of relay and intelligent lamp, practice thrift the cost, beautify the wall.

Description

Scene panel with wireless intelligent light resetting function and control method

Technical Field

The invention relates to the field of intelligent lamps, in particular to a scene panel with a wireless intelligent light resetting function and a control method.

Background

Along with the popularity of the intelligent home idea, intelligent electrical appliances in life are gradually increased, and part of intelligent electrical appliances can even realize remote operation, but numerous intelligent electrical appliances need to be controlled independently, so that the operation is very complicated, and a scene panel is appeared. The scene panel can confirm the types and the states of one or more intelligent electric appliances by setting scenes, and can simultaneously control a plurality of intelligent electric appliances by controlling whether the scenes are started or not; compared with separate and independent control, the control through the scene panel is more convenient.

Common intelligent electrical apparatus includes the intelligent lamp, and the intelligent lamp possesses the function of resetting usually, but the resetting of intelligent lamp is difficult to realize to traditional scene panel. The reset of the intelligent lamp at first needs to be realized by setting the on-off times of the power-on loop of the intelligent lamp, and the traditional method is that an electric worker directly short-circuits and disconnects the wiring of the power-on loop of the intelligent lamp to realize on-off, which is not only inconvenient but also very dangerous. The relay is connected in the power-on loop of the intelligent lamp afterwards, and the intelligent switch board realizes the resetting of the intelligent lamp by directly controlling the on-off of the relay. No matter be traditional short circuit or intelligent switch board, all need control personnel eyes to see the clock and watch, hand is according to certain break-make chronogenesis switch a plurality of times (generally for about 5) intelligent switch board, and the hand-eye cooperation is realized, and inconvenient operation and in case the hand-eye cooperation has a fault, will lead to resetting failure, must come again heavily, wastes time and energy. In addition, the intelligent switch board and the scene panel are mutually independent, and when a plurality of relays are arranged, one or more intelligent switch boards can be arranged, so that the attractiveness of the wall surface is influenced; and when through intelligent switch board control relay, the easy quilt of intelligent switch board is touched by child or old man, produces the mistake and touches and let the relay disconnection, and then makes the control of scene panel malfunctioning. On the other hand, the relay controlled by the intelligent switch board is difficult to determine whether the relay is disconnected or the driving circuit is controlled when the lamp is turned off. Therefore, a scene panel capable of controlling the on/off of the relay and effectively preventing the false touch is urgently needed.

Disclosure of Invention

The invention aims to overcome the defects of the prior art, and provides a scene panel with a wireless intelligent light resetting function and a control method, which can realize switching control of a plurality of scenes, effectively prevent mistaken touch, and have the advantages of simple structure and convenience in use.

A scene panel with a wireless intelligent light resetting function comprises a shell, an MCU, an indicator light and a relay; the MCU and the indicator lamp are arranged on the shell; the MCU is electrically connected with the control end of the relay; the MCU is electrically connected with the indicator light; when the scene panel is connected with the intelligent lamp, the communication part of the MCU and the driving circuit of the intelligent lamp is connected in a wired or wireless way; the execution end of the relay is electrically connected with the incoming line terminal of the driving circuit of the intelligent lamp.

Further, n +2 areas are distributed ON the housing, n represents the number of scenes and is respectively marked as an "ON" area, an "OFF" area, an "S1" area, an "S2" area, … and an "Sn" area, wherein the "S1" area, the "S2" area, … and the "Sn" area respectively correspond to an "S1" scene, an "S2" scene, … and an "Sn" scene; the n +2 areas of the shell are respectively provided with a key and an indicator light; the 'S1' area, the 'S2' area, the … or the 'Sn' area are required to be pressed for a long time to realize the reset of the corresponding intelligent lamp.

Further, the keys comprise touch-sensitive keys and/or micro switches.

A control method with a wireless intelligent light resetting function comprises the following steps:

step 1: an operator controls a scene panel in a contact or non-contact mode;

step 2: the MCU receives the control signal to judge and identify and generates a corresponding operation instruction;

and step 3: the MCU transmits the operation instruction to a driving circuit of a corresponding scene in a wired or wireless mode according to the type of the operation instruction, and transmits the operation instruction to a corresponding relay in a wired mode;

and 4, step 4: the relay and the drive circuit receive the operation instruction in a wired or wireless mode and execute corresponding actions;

the operation instruction in the step 3 comprises a distribution network instruction, a total opening instruction, a total closing instruction, a scene control instruction and a reset instruction.

Further, the distribution network instruction controls all the communication modules to be connected to the network, and the distribution network process includes the following steps:

step 11: the MCU receives a signal for controlling an 'ON' area by an operator;

step 12: the MCU judges whether the long-time pressing time of the 'ON' area reaches the set time t 1; if the time meets the set time t1, entering the step 13, otherwise, entering the total closed flow;

step 13: the MCU controls all the communication modules to enter a distribution network state, and an indicator light in an OFF area flickers at least once in a blue-white mode to prompt an operator that the communication modules enter the distribution network state;

step 14: carrying out distribution, judging whether the distribution is successful, and if the distribution is successful, displaying indicator lamps ON an 'ON' area, an 'OFF' area, an 'S1' area, an 'S2' area, a … area and an 'Sn' area in orange; otherwise, the MCU and the intelligent lamp are kept in the original state.

Furthermore, the total opening instruction controls all relays to be closed, and the relays enter a total closing state to enable the driving circuit to be conducted; the general closing flow of the relay is as follows:

step 21: the MCU receives a signal for controlling an 'ON' area by an operator;

step 22: the MCU judges whether the long-time pressing time of the 'ON' area reaches the set time t 1; if the time does not meet the set time t1, entering step 23; otherwise, entering a distribution network flow;

step 23: and the MCU controls all the relays to be closed, the relays enter a total closed state, and the indicator lights in the 'ON' area are controlled to keep orange after flickering once at least.

Further, the total closing instruction controls all the relays to be turned off, the relays enter a total off state, and the total off flow of the relays is as follows:

step 31: the MCU receives a signal for controlling an OFF area by an operator;

step 32: the MCU judges whether the long-pressed time of the OFF area reaches the set time t 2; if the time meets the set time t2, entering the step 33; otherwise, the MCU and the intelligent lamp keep the original state, and the total disconnection process of the relay is finished;

step 33: the MCU controls all relays to be switched OFF in a wired or wireless mode, the relays enter a total OFF state, and the indicator lights in the OFF area are controlled to be kept white after being flashed at least once in orange white.

Further, the scene control instruction can trigger a corresponding scene; the scene control flow is as follows:

step 41: the MCU receives signals of an operator controlling an 'S1' area, an 'S2' area, … or an 'Sn' area;

step 42: the MCU judges whether the long-pressed time of the 'S1' area, the 'S2' area, the … or the 'Sn' area does not reach the set time t 3; if the time does not reach the set time t3, then go to step 43; otherwise, entering a reset flow;

step 43: the MCU triggers the corresponding intelligent lamp in a wired or wireless mode, and the indicator lamp of the corresponding area in the 'S1' area, the 'S2' area, the … area or the 'Sn' area keeps orange after flickering at least once in orange and white.

Further, the reset instruction resets the intelligent lamp; the reset process comprises the following steps:

step 51: the MCU receives a signal of an operator operating an 'S1' area, an 'S2' area, … or an 'Sn' area;

step 52: the MCU judges whether the long-pressed time of the 'S1' area, the 'S2' area, the … or the 'Sn' area does not reach the set time t 3; if the time reaches the set time t3, go to step 53; otherwise, entering a scene control flow;

step 53: the MCU judges whether the relay is in a total closed state or a total open state; if the state is the total closed state, entering step 54; if the state is the total disconnection state, the original state is kept, and the resetting process is ended;

step 54: the MCU controls the on-off of the corresponding relay at least once through a wired or wireless connection mode; in the process of switching on and off the relay, the MCU judges whether the operator quickly and briefly presses the corresponding area twice; if the operator quickly and briefly presses the corresponding area twice in the process of switching on and switching off the relay, the next step is carried out; otherwise, keeping the original state and ending the reset process;

step 55: the relay is continuously switched on and off for a set number of times, and finally the relay keeps the power-on state to reset the intelligent lamp;

the quick and short pressing twice in the step 54 indicates that the time spent by the operator for pressing the corresponding area twice is less than the set time t 4; the corresponding area refers to the same area as the area operated by the operator in step 51.

Further, the contact mode in the step 1 comprises touch and pressing, the touch is induced by a touch induction key, the pressing is realized by a microswitch, and a control signal is generated by a capacitive element or the microswitch; the non-contact mode comprises networking control and infrared control, and the non-contact mode generates a control signal by an external device; in the step S3, the MCU also controls the operation of the indicator lights on the housing while outputting the operation command.

The invention has the beneficial effects that:

one or more scenes can be switched by arranging the scene panel to control the relay of one or more intelligent lamps, one-to-many control of the relay and the intelligent lamps is realized, an intelligent switch board is not needed, the cost is saved, and the wall surface is beautified;

by arranging the indicator light on the shell, the action of the operator or the scene being controlled can be prompted;

the on-off control of the relay is realized through the MCU, the full-on, the full-off and the resetting can be completed within a few seconds only by simple operation, and compared with the intelligent switch board for controlling the on-off of the relay or the direct short circuit of personnel for controlling the on-off, the operation can be greatly simplified, and the safety is higher;

in the disconnection process and the reset process of the multi-path relay, long-time pressing operation is required, so that the maintenance and use safety of a scene panel are ensured, the false touch is avoided, the failure of scene control is reduced, and the accuracy of the scene panel is ensured;

through the total opening flow and the total closing flow of the relay, the maintenance and the nursing of the intelligent lamp electrically connected with the relay can be facilitated, an air switch in a distribution box does not need to be operated, the influence of the maintenance of the intelligent lamp on other household electrical appliances can be reduced to the maximum extent while the safety is ensured, and the beneficial effect is very obvious in large houses and villas;

by adding the operation of confirming the reset in the reset process, along with the on-off of the relay, an operator can observe the on-off of the indicator lamp in the corresponding area and can also observe the state change of the corresponding intelligent lamp, so that the operator can timely find and stop the intelligent lamp with the reset error, and the error touch is avoided;

drawings

Fig. 1 is a block diagram of a closing process of a distribution network and four relays according to a first embodiment of the present invention;

fig. 2 is a block diagram of a disconnection process of a four-way relay according to a first embodiment of the present invention;

fig. 3 is a block diagram of a scenario control and reset process according to a first embodiment of the present invention.

Detailed Description

The embodiments of the present invention are described below with reference to specific embodiments, and other advantages and effects of the present invention will be easily understood by those skilled in the art from the disclosure of the present specification. The invention is capable of other and different embodiments and of being practiced or of being carried out in various ways, and its several details are capable of modification in various respects, all without departing from the spirit and scope of the present invention. It is to be noted that the features in the following embodiments and examples may be combined with each other without conflict.

It should be noted that the drawings provided in the following embodiments are only for illustrating the basic idea of the present invention, and the components related to the present invention are only shown in the drawings rather than drawn according to the number, shape and size of the components in actual implementation, and the type, quantity and proportion of the components in actual implementation may be changed freely, and the layout of the components may be more complicated.

The first embodiment is as follows:

a scene panel with a wireless intelligent light resetting function comprises a shell, an MCU, an indicator light and a relay. The MCU and the indicator light are arranged on the shell, and the shell is embedded in the wall body during installation; the MCU is electrically connected with the control end of the relay; the MCU is electrically connected with the indicator lamp, and the indicator lamp indicates the operation of the scene panel. When scene panel and intelligent lamp erection joint, the executive end of relay and drive circuit's inlet wire end electric connection, the break-make of drive circuit inlet wire end can be controlled to the relay, and then realizes the reset and the maintenance of intelligent lamp. The intelligent lamp is electrically connected with the output end of the driving circuit; the communication part of the MCU and the driving circuit of the intelligent lamp is connected in a wired or wireless way, the MCU can control the driving circuit, and the driving circuit can control the intelligent lamp; the driving circuit can control the intelligent lamp to change color temperature, tone, brightness and the like.

The shell is a partially semitransparent shell, and light rays of the indicator light can penetrate through the shell to be displayed. In this embodiment, six areas are distributed ON the enclosure, and are respectively marked as an "ON" area, an "OFF" area, an "S1" area, an "S2" area, …, and an "Sn" area, where n represents the number of scenes, and in this embodiment, n is 4, it should be noted that the scenes corresponding to each area ON the enclosure do not need to be set every time, and the setting is performed according to actual requirements. The six areas of the shell are respectively provided with a key, the keys are used for receiving signals of corresponding areas on the shell contacted or pressed by an operator, and the keys comprise touch sensing keys and/or microswitches, wherein the touch sensing keys are realized by means of capacitance elements. The "S1" region, "S2" region, "S3" region, and "S4" region correspond to four scenes, respectively, which are the "S1" scene, the "S2" scene, the "S3" scene, and the "S4" scene. In this embodiment, the scene is the type and state of the intelligent electrical appliance; in one scenario, control of the smart lights may not be included, or control of one or more smart lights may be included.

The MCU is provided with a communication module, the communication module comprises wired communication and wireless communication, and the wireless communication comprises a WiFi module, a ZigBee module, a Bluetooth module and the like. The MCU can be connected into a network through wireless communication, and the driving circuit is also provided with a communication module which can be connected into the network, so that the wireless connection between the MCU and the driving circuit is realized. The wireless communication device also comprises an infrared module, a remote controller is correspondingly configured with the infrared module, and the MCU can be wirelessly remotely controlled through the remote controller. In this embodiment, the MCU is wired to the relay.

The indicator lamp is an energy-saving LED lamp bead, and comprises indicator lamps with three colors in the embodiment, so that different operations of the scene panel can be distinguished. The indicator light can be the changeable LED lamp pearl of colour, also can adopt the LED lamp pearl of a plurality of different colours. The indicator lights are respectively arranged in six areas on the shell.

The relay and the intelligent lamp are respectively electrically connected with the driving circuit, share the region of 'S1', 'S2', 'S3' and 'S4' in the embodiment, and are correspondingly provided with four relays. In this embodiment, the control terminal of the relay is electrically connected to the MCU. The output end of the driving circuit is electrically connected with the intelligent lamp to realize power supply to the intelligent lamp; the incoming line end of the driving circuit can be connected with commercial power, and also can be connected with a power supply or a standby power supply. The driving circuit can realize accurate control on the intelligent lamp, and the control comprises the control of the color temperature, the tone, the brightness and other changes of the intelligent lamp. In this embodiment, the driving circuit is also provided with a communication module, and the driving circuit is connected to the network through the communication module, so as to realize network identification and connection between the MCU and the driving circuit.

In the embodiment, by pressing the "S1" region, the "S2" region, the "S3" region or the "S4" region for a long time, the on/off of the relay corresponding to the region can be realized, and the resetting of the intelligent lamp electrically connected with the relay is further realized, wherein the connection relationship between the relay and the intelligent lamp is determined when the relay and the intelligent lamp are installed, and one relay is connected with one or more intelligent lamps; and setting a confirmation step in the resetting process, wherein the confirmation step comprises quickly pressing the corresponding area twice, and continuing the resetting process after the confirmation is passed until the resetting is completed.

In the embodiment, the MCU is also associated with app software, the intelligent electrical appliances are identified and added in the network through the app software, and the scene is set, so that the remote networking control of the scene can be realized after the intelligent electrical appliances are identified and added in the network through the app software.

A control method with a wireless intelligent light resetting function based on the scene panel comprises the following steps:

step 1: an operator controls a scene panel in a contact or non-contact mode;

and 4, step 4: the relay and the drive circuit receive the operation instruction in a wired or wireless mode and execute corresponding actions.

The contact mode in the step 1 comprises touch and pressing, and the contact mode is sensed by a capacitance element or a microswitch and generates a control signal to be transmitted to the MCU; the non-contact mode comprises networking control and infrared control, the non-contact mode is that an external device generates a control signal and transmits the control signal to the MCU, and the external device comprises a mobile phone, a remote controller and the like.

In the embodiment, at most five types of operation instructions can be generated according to the operation mode of the operator. The system comprises a distribution network command, a total opening command, a total closing command, a scene control command and a resetting command which respectively correspond to a distribution network flow, a total closing flow, a total opening flow, a scene control flow and a resetting flow.

As shown in fig. 1, the distribution network instruction can control the MCU and the communication module of the driving circuit to access the network, and in this embodiment, the distribution network instruction controls the MCU and the wireless communication module of the driving circuit to access the network; the distribution network process comprises the following steps:

step 11: the MCU receives a signal for controlling an 'ON' area by an operator;

step 12: the MCU judges whether the long-pressed time of the 'ON' area reaches a set time t1, which is 10s in the embodiment; if the time meets the set time t1, which is 10s in the present embodiment, the flow goes to step 13, otherwise, the flow goes to the total closed flow;

step 13: the MCU controls all the wireless communication modules to enter a distribution network state, and an indicator light in an OFF area blinks blue and white for three times to prompt an operator to enter the distribution network state;

step 14: carrying out distribution, judging whether the distribution is successful, and if the distribution is successful, displaying indicator lamps ON an 'ON' area, an 'OFF' area, an 'S1' area, an 'S2' area, an 'S3' area and an 'S4' area in orange; otherwise, the MCU and the intelligent lamp are kept in the original state.

The MCU and the drive circuit are not connected with the network, and when the MCU and the drive circuit are not in the distribution network state, the indicator lamp in the OFF area is blue and is normally on.

The total opening command can control all relays electrically connected with the MCU to be closed, in this embodiment, the "S1" region, "S2" region, "S3" region and "S4" region on the housing correspond to four relays, the relays enter a total closing state, so that the driving circuit is turned on, and the total closing process of the relays is as follows:

step 21: the MCU receives a signal for controlling an 'ON' area by an operator;

step 22: the MCU judges whether the long-pressed time of the 'ON' area reaches a set time t1, which is 10s in the embodiment; if the time does not meet the set time t1, 10s in the present embodiment, go to step 23; otherwise, entering a distribution network flow;

step 23: the MCU controls the four paths of relays to be closed in a wired or wireless mode, the relays enter a total closed state, and the indicator lights in the 'ON' area are controlled to flicker orange and white for three times and then keep orange.

As shown in fig. 2, the total closing instruction can control the four-way relay to be turned off, the relay enters a total off state, and the total off flow of the relay is as follows:

step 31: the MCU receives a signal for controlling an OFF area by an operator;

step 32: the MCU judges whether the long-pressed time of the OFF area reaches the set time t2, which is 5s in the embodiment; if the time meets the set time t2, which is 5s in the present embodiment, the process goes to step 33; otherwise, the MCU and the intelligent lamp keep the original state, and the total disconnection process of the relay is finished;

step 33: the MCU controls the four relays to be switched OFF in a wired or wireless mode, the relays enter a total OFF state, and the indicator lights in the OFF area are controlled to flicker orange and white for three times and then keep white.

As shown in fig. 3, the scene control command can trigger a corresponding scene, for example, the scene control command "S1" triggers an intelligent appliance corresponding to the scene "S1". The scene control flow is as follows:

step 41: the MCU receives signals of an operator controlling an 'S1' area, an 'S2' area, an 'S3' area or an 'S4' area;

step 42: the MCU judges whether the long-pressed time of the 'S1' area, the 'S2' area, the 'S3' area or the 'S4' area is less than the set time t3, which is 5S in the embodiment; if the time does not reach the set time t3, which is 5s in the present embodiment, the step 43 is entered; otherwise, entering a reset flow;

step 43: the MCU triggers the corresponding scene in a wired or wireless manner, and keeps orange after the indicator lights of the respective regions among the "S1" region, the "S2" region, the "S3" region and the "S4" region blink orange and white three times.

It should be noted that the type and state of the intelligent electrical appliance in the scene can be changed by editing, for example, by editing the setting "S1" scene to turn on the intelligent lamp in the bathroom, turn on the water heater, and the like. There may be no smart lights in the scene.

The reset instruction can control the intelligent lamp connected with the relay to reset, and the intelligent lamp after being reset is wirelessly connected with the MCU. The reset process comprises the following steps:

step 51: the MCU receives a signal of an operator operating an 'S1' area, an 'S2' area, an 'S3' area or an 'S4' area;

step 52: the MCU judges whether the long-pressed time of the 'S1' area, the 'S2' area, the 'S3' area or the 'S4' area is less than the set time t3, which is 5S in the embodiment; if the time reaches the set time t3, which is 5s in the present embodiment, the step 53 is entered; otherwise, entering a scene control flow;

step 53: the MCU judges whether the relay is in a total closed state or a total open state; if the relay is in the total closed state, then step 54 is entered; if the relay is in a total disconnection state, the original state is kept, and the resetting process is ended;

step 54: the MCU controls the on-off of the corresponding relay three times in a wired or wireless connection mode; in the process of switching on and off the relay for three times, the MCU judges whether the operator quickly and briefly presses the corresponding area for two times; if the operator quickly and briefly presses the corresponding area twice in the process of switching on and switching off the relay three times, the next step is carried out; otherwise, keeping the original state and ending the reset process;

step 55: the relay is continuously switched on and off twice, and finally the relay keeps the power-on state, so that the resetting of the intelligent lamp is realized.

The relay corresponding to the step 54 is a relay corresponding to the region controlled by the operator in the step 51, it should be noted that the "S1" region, "S2" region, "S3" region, and "S4" region on the housing are all connected to the relay when the relay is mounted again, the actuating terminal of the relay is electrically connected to the power input terminal of the driving circuit of the smart lamp, and the relationship between the relay and the smart lamp is determined when the relay and the smart lamp are mounted. The corresponding region refers to the same region as the region operated by the operator in step 51. The quick short press twice indicates that the time taken for the operator to press the corresponding region is less than the set time t4, which is 3s in this embodiment. The on-off of the relay in the resetting process refers to that the MCU controls the relay to be closed for 2s and to be opened for 8 s; and when the relay is switched on and off, the indicator lamps in the corresponding areas alternate with orange-white light, wherein the white color is 2s, and the orange color is 8 s.

It should be noted that in this embodiment, the driving circuit of the smart lamp needs to be continuously turned on and off five times to achieve resetting, and in some other embodiments, the driving circuit also needs to be turned on and off four times or three times to achieve resetting.

In the implementation process, an operator can control the on-off state of the relays through the scene panel to control one or more relays without using an intelligent switch board; in the disconnection process and the reset process of the four-way relay, the operation of disconnecting the relay requires that an operator presses the corresponding area for a long time, so that the error touch is avoided, and because the intelligent lamp controlled by the traditional scene panel is turned off, the intelligent lamp controlled by the driving circuit or the intelligent lamp controlled by the relay is turned off is difficult to be accurately judged; in addition, in the resetting process, because the connection relation between the relay and the intelligent lamp is determined when the intelligent lamp is installed and is difficult to change, the connection relation needs to be observed firstly, along with the on-off of the relay, an operator can observe the state change of the corresponding intelligent lamp, and then whether the relay connected with the area on the shell corresponds to the intelligent lamp which is expected to be reset or not is determined, if the operator finds the resetting error at the moment, the relay can be stopped in time, and the mistaken touch is avoided.

The above description is only one specific example of the present invention and should not be construed as limiting the invention in any way. It will be apparent to persons skilled in the relevant art(s) that, having the benefit of this disclosure and its principles, various modifications and changes in form and detail can be made without departing from the principles and structures of the invention, which are, however, encompassed by the appended claims.

Claims

1. A scene panel with a wireless intelligent light resetting function is characterized by comprising a shell, an MCU, an indicator light and a relay; the MCU and the indicator lamp are arranged on the shell; the MCU is electrically connected with the control end of the relay; the MCU is electrically connected with the indicator light; when the scene panel is connected with the intelligent lamp, the communication part of the MCU and the driving circuit of the intelligent lamp is connected in a wired or wireless way; the execution end of the relay is electrically connected with the incoming line terminal of the driving circuit of the intelligent lamp.

2. The scene panel with the wireless intelligent light resetting function of claim 1, wherein n +2 areas are distributed ON the housing, n represents the number of scenes and is respectively marked as an "ON" area, an "OFF" area, an "S1" area, an "S2" area, … and an "Sn" area, wherein the "S1" area, the "S2" area, … and the "Sn" area respectively correspond to the "S1" scene, the "S2" scene, … and the "Sn" scene; the n +2 areas of the shell are respectively provided with a key and an indicator light; the 'S1' area, the 'S2' area, the … or the 'Sn' area are required to be pressed for a long time to realize the reset of the corresponding intelligent lamp.

3. The scene panel with wireless intelligent light resetting function according to claim 2, wherein the keys comprise touch-sensitive keys and/or micro switches.

4. A control method with a wireless intelligent light resetting function is characterized by comprising the following steps:

step 1: an operator controls a scene panel in a contact or non-contact mode;

5. The control method with the function of resetting the wireless intelligent light as claimed in claim 4, wherein the distribution network command controls all the communication modules to be connected into the network, and the distribution network process comprises the following steps:

step 11: the MCU receives a signal for controlling an 'ON' area by an operator;

6. The control method with the function of resetting the wireless intelligent light according to claim 4, wherein the total opening instruction controls all the relays to be closed, and the relays enter a total closing state to enable the driving circuit to be conducted; the general closing flow of the relay is as follows:

step 21: the MCU receives a signal for controlling an 'ON' area by an operator;

7. The control method with the function of resetting the wireless intelligent light as claimed in claim 4, wherein the total closing instruction controls all the relays to be opened, the relays enter a total opening state, and the total opening process of the relays is as follows:

step 31: the MCU receives a signal for controlling an OFF area by an operator;

8. The control method with the function of resetting the wireless intelligent light as claimed in claim 4, wherein the scene control instruction can trigger a corresponding scene; the scene control flow is as follows:

9. The control method with the function of resetting the wireless intelligent lamp according to claim 4, wherein the reset instruction resets the intelligent lamp; the reset process comprises the following steps:

10. The control method with the function of resetting the wireless intelligent light according to claim 4, wherein the contact mode in the step 1 comprises touch and pressing, the touch is sensed by a touch sensing key, the pressing is realized by a micro switch, and a control signal is generated by a capacitive element or the micro switch; the non-contact mode comprises networking control and infrared control, and the non-contact mode generates a control signal by an external device; in the step S3, the MCU also controls the operation of the indicator lights on the housing while outputting the operation command.