WO2019041969A1

WO2019041969A1 - Air deflector control device and control method therefor

Info

Publication number: WO2019041969A1
Application number: PCT/CN2018/091357
Authority: WO
Inventors: 王立乾; 林丹
Original assignee: 格力电器（武汉）有限公司; 珠海格力电器股份有限公司
Priority date: 2017-09-01
Filing date: 2018-06-14
Publication date: 2019-03-07
Also published as: CN107606755A

Abstract

An air deflector control device and control method. The air deflector control device comprises an induction part (1) and a trigger signal generating module (2); the trigger signal generating module (2) is used for generating a trigger signal when the induction part (1) is triggered; the trigger signal is used for adjusting an air deflector to a preset air deflection position corresponding to the triggered induction part (1).

Description

Air deflector control device and control method thereof

Related application

The present application claims the benefit of priority to the benefit of the benefit of the benefit of the benefit of the benefit of the benefit of the benefit of the benefit of the benefit of the benefit of the benefit of the benefit of the benefit of the benefit of the present disclosure.

Technical field

The present application relates to the field of air guiding direction control technology, and in particular to a wind deflector control device and a control method.

Background technique

At present, the air deflector of the air conditioner has an upper and lower air deflector and a left and right air deflector, and the upper and lower air deflectors are used to guide the wind in the up and down direction, and the left and right air deflectors are used to guide the wind in the left and right direction. The control of the direction of the air deflector by the air conditioner remote controller basically adopts a button mode in which the upper and lower air guides and the left and right air guides are independently adjusted. The air conditioner remote control has two buttons: the upper and lower air guiding buttons and the left and right air guiding buttons. When the direction of the air guiding plate is controlled, it is usually necessary to press the left and right air guiding buttons once, and then the left and right air guiding plates are moved to the appropriate positions and then pressed. One left and right air guide button will position the left and right air guide plates; press the upper and lower air guide buttons again, and then move the upper and lower air guide plates to the appropriate position, then press the upper and lower air guide buttons to position the upper and lower air guide plates. A total of four key presses are required. It takes a long time to complete the adjustment of the direction of the wind. In addition, there is another adjustment method, which continuously presses the left and right air guides or the upper and lower air guide buttons a plurality of times, sets the air outlet direction to an appropriate direction, and then sends a signal for adjustment, which also needs to be pressed a plurality of times to complete.

Summary of the invention

In view of this, the present application provides a wind deflector control device and a control method thereof, and the main object thereof is to solve the technical problem that the adjustment operation of the air guide direction of the prior air conditioner is cumbersome.

To achieve the above objectives, the present application mainly provides the following technical solutions:

In one aspect, an embodiment of the present application provides a wind deflector control device, including: a sensing portion and a trigger signal generating module;

The trigger signal generating module is configured to generate a trigger signal when the sensing portion is triggered; the trigger signal is used to adjust the air deflector to a preset air guiding position corresponding to the triggered sensing portion.

The purpose of the present application and solving the technical problems thereof can be further achieved by the following technical measures.

In the foregoing air deflector control device, optionally, the number of the sensing portions is two or more, and the trigger signal generating module generates different trigger signals when different sensing portions are triggered;

Each of the sensing portions corresponds to a different preset air guiding position.

In the foregoing air deflector control device, optionally, the sensing portion includes a sensor, and the trigger signal generating module is configured to generate a trigger signal when the sensor is triggered.

In the foregoing air deflector control device, optionally, the air deflector control device has a first area, and each of the sensors is distributed in the first area;

The first area has two or more second areas that do not overlap each other, and each of the sensors is disposed correspondingly in the corresponding second area.

In the above air deflector control device, optionally, the first area is a fan-shaped area, and the inside of the fan-shaped area has two or more sub-fan annular areas divided by an arc and a straight line, An arc coincides with a center of an outer arc of the fan annular region, and an extension of the straight line passes through a center of an outer arc of the fan annular region;

Wherein the sub-fan annular region serves as the second region.

In the foregoing air deflector control device, optionally, each of the sensors has an outer shape conforming to a corresponding second region.

In the foregoing air deflector control device, optionally, the air deflector control device further includes a display light;

The number of the display lamps is equal to the number of the sensors, and one-to-one correspondence.

In the foregoing air deflector control device, optionally, each of the display lamps is disposed in a corresponding second region in a one-to-one correspondence.

In the foregoing air deflector control device, optionally, the air deflector control device includes a housing, a bottom plate disposed on the housing, and a touch panel disposed on the bottom plate;

The bottom plate has the first area, and the sensor is located between the bottom plate and the touch panel.

On the other hand, an embodiment of the present application further provides a wind deflector control method, which includes the following steps:

When the sensing portion of the air deflector control device is triggered, the trigger signal generating module of the air deflector control device generates a trigger signal for adjusting the air deflector to a preset guide corresponding to the triggered sensing portion. Wind position.

In the foregoing air deflector control method, the number of the sensing portions is set to two or more, and each sensing portion corresponds to a different preset air guiding position, so that the trigger signal generating module is triggered when different sensing portions are triggered. Different trigger signals are generated to adjust the air deflector to a preset air guiding position corresponding to the triggered sensing portion.

In the air deflector control method, the air deflector includes upper and lower air deflectors, and the preset air guiding positions of the upper and lower air deflectors include a horizontal direction of 0°, a horizontal downward 20°, and a horizontal downward 40°. , 60 degrees horizontally down and 80 degrees horizontally down to five different positions;

And/or, the air deflector includes left and right air deflectors, and the preset air guiding positions of the left and right air deflectors include a middle left 60°, a middle left 30°, a middle direction, a middle right 30°, and a middle Right at 60° five different positions.

In the above air deflector control method, when each of the sensing units has no trigger for a set time, the air deflector control device enters a sleep mode.

In the foregoing air deflector control method, in the sleep mode, when any of the sensing sections is triggered for the first time, the trigger signal generating module does not generate a trigger signal, and the air deflector control device switches to the air guiding direction adjusting mode.

In the air deflector control method described above, when any of the sensing portions is triggered for the first time in the sleep mode, the area of the sensing portion corresponding to the current position of the air deflector is illuminated;

And/or, when any of the sensing portions is triggered in the air guiding direction adjustment mode, the area of the triggered sensing portion is illuminated.

In the above air deflector control method, when the sensing portion is triggered, the speaker of the air deflector control device emits a prompt sound.

In the foregoing air deflector control method, the trigger signal generating module generates a trigger signal to adjust the air deflector to a preset air guiding position corresponding to the triggered sensing portion: when the sensing portion is triggered, the trigger signal is generated. The module calculates an angular difference between the current position of the driving motor of the air deflector and the preset air guiding position corresponding to the triggered sensing portion 1, and generates a corresponding trigger signal according to the angular difference to control the output of the driving motor of the air deflector The shaft rotates by a corresponding angle to rotate the wind deflector to a preset air guiding position corresponding to the triggered sensing portion.

With the above technical solution, the air deflector control device and the control method of the present application have at least the following beneficial effects:

Compared with the trigger signal generated by the trigger signal generating module when the sensing portion is triggered in the prior art, the air deflector cannot be adjusted to a proper position at one time, and the trigger signal generating module of the air deflector control device in the technical solution of the present application is subjected to the sensing portion. When triggered, a trigger signal can be generated to adjust the air deflector to a preset air guiding position corresponding to the triggered sensing portion, so that the user can trigger the sensing portion only once, that is, the air deflector can be adjusted to the required pre-predetermined The guiding position is set, so that the operation part is not required to be operated multiple times, the operation process is saved, the operating efficiency of the air deflector control device of the present application is improved, and the technical effect of quickly guiding the air guiding direction of the air guiding plate is achieved.

The above description is only an overview of the technical solutions of the present application. In order to more clearly understand the technical means of the present application, and can be implemented in accordance with the contents of the specification, the following detailed description will be made with reference to the preferred embodiments of the present application and the accompanying drawings.

DRAWINGS

1 is a block diagram showing a partial structure of a wind deflector control device according to an embodiment of the present application;

2 is a partial schematic structural diagram of a wind deflector control device according to an embodiment of the present application;

3 is a schematic structural view of a panel of a wind deflector control device according to an embodiment of the present application;

4 is a schematic structural diagram of an air deflector control device according to an embodiment of the present application;

FIG. 5 is a flowchart of a wind deflector control method according to an embodiment of the present application.

Reference numerals: 1, sensing portion; 11, sensor; 2, trigger signal generating module; 3, bottom plate; 31, first region; 32, second region; 4, display light; 5, touch panel; 6, control circuit ; 7, housing; 8, display.

Detailed ways

The specific embodiments, structures, features and functions of the present application are described in detail below with reference to the accompanying drawings and preferred embodiments. In the following description, different "an embodiment" or "an embodiment" does not necessarily mean the same embodiment. Furthermore, the particular features, structures, or characteristics of one or more embodiments can be combined in any suitable form.

As shown in FIG. 1 , an embodiment of the present application provides a wind deflector control device including a sensing portion 1 and a trigger signal generating module 2 . The trigger signal generating module 2 is configured to generate a trigger signal when the sensing portion 1 is triggered. The trigger signal is used to adjust the air deflector to a preset air guiding position corresponding to the triggered sensing portion 1.

Compared with the trigger signal generated by the trigger signal generating module when the sensing portion is triggered in the prior art, the air deflector cannot be adjusted to a proper position at one time, and the trigger signal generating module 2 of the air deflector control device in the sensing portion of the present application is in the sensing portion. 1 When triggered, a trigger signal may be generated to adjust the air deflector to a preset air guiding position corresponding to the triggered sensing portion 1, so that the user can trigger the sensing portion 1 only once, that is, the air deflector can be adjusted to The preset guide air position is required, so that the operation of the sensing portion 1 is not required, the operation process is saved, the operation efficiency of the air deflector control device of the present application is improved, and the technology for quickly positioning the air guiding direction of the air deflector is achieved. effect.

The aforementioned air deflector may include upper and lower air deflectors and left and right air deflectors. It should be noted here that the "upper and lower air deflectors" herein refer to the air deflectors for guiding the wind up and down, and the "left and right air deflectors" refer to the wind deflectors for the left and right wind guides. In a specific application example, the aforementioned trigger signal is used to adjust the upper and lower air deflectors and/or the left and right air deflectors to a preset air guiding position corresponding to the triggered sensing portion 1.

Preferably, the trigger signal is used to adjust both the upper and lower air deflectors and the left and right air deflectors to a preset air guiding position corresponding to the triggered sensing portion 1 so that only one sensing portion 1 needs to be triggered once, The upper and lower air deflectors and the left and right air deflectors are all adjusted to the corresponding preset air guiding positions, thereby further improving the operating efficiency.

Further, the number of the sensing portions 1 may be two or more, and the trigger signal generating module 2 may generate different trigger signals when different sensing portions 1 are triggered. Each of the sensing portions 1 corresponds to a different preset air guiding position. In this way, the deflector can be adjusted to different preset air guiding positions by triggering different sensing portions 1 to meet the user's demand for different guiding directions.

Further, as shown in FIG. 2, the aforementioned sensing portion 1 may include a sensor 11 such as a pressure sensor or the like, and the trigger signal generating module 2 is configured to generate a trigger signal when the sensor 11 is triggered. Among them, the sensor 11 is a precision detecting member, and the accuracy of the trigger can be improved by the sensor 11 provided.

Further, as shown in FIG. 2, the wind deflector control device of the present application has a first region 31, and each of the aforementioned sensors 11 is distributed in the first region 31. The first region 31 has two or more second regions 32 that do not overlap each other, and the sensors 11 are disposed in the corresponding second regions 32 one by one, so that interference between the sensors 11 can be avoided, and also It is convenient for the user to trigger the corresponding sensor 11, such as pressing the corresponding pressure sensor 11.

In a specific application example, as shown in FIG. 2, the aforementioned first region 31 may be a fan-shaped region. The inside of the annular region has two or more sub-arc annular regions divided by an arc and a straight line, and the arc coincides with the center of the outer arc of the fan-shaped region, and the extension of the straight line passes through the outer arc of the fan-shaped region. Center of the circle. Here, the sub-fan annular region in the present example serves as the aforementioned second region 32. It should be noted here that both the "arc" and the "straight line" in this example may be virtual lines, just to facilitate the description of the relationship between the sub-ring annular area and the fan-shaped area. Of course, in order to facilitate the installation, the above-mentioned "arc" and "straight line" may also be solid lines formed by grooves, protrusions or marking materials, etc., mainly for indicating. In the present example, by providing the first region 31 and the second region 32 as a fan-shaped region, there is a technical effect that is convenient for the user to operate.

Further, as shown in FIG. 2, each of the aforementioned sensors 11 has an outer shape conforming to the corresponding second region 32 to detect the entire region in the corresponding second region 32.

Further, as shown in FIG. 2, the air deflector control device of the present application may further include a display light 4. The number of display lamps 4 is equal to the number of sensors 11, and one-to-one correspondence. The display light 4 is illuminated when the corresponding sensor 11 is triggered to alert the user that the corresponding sensor 11 has been triggered.

Further, as shown in FIG. 2, each of the foregoing display lamps 4 is disposed in the corresponding second region 32 in one-to-one correspondence. When the corresponding display lamp 4 is illuminated, the second region 32 in which the display lamp 4 is located is illustrated. The sensor 11 has been triggered.

In a specific application example, as shown in FIG. 2 to FIG. 4, the air deflector control device of the present application further includes a housing 7, a bottom plate 3 disposed on the housing 7, and a touch cover on the bottom plate 3. Panel 5. The bottom plate 3 has the aforementioned first region 31. The sensor 11 is disposed in the first region 31 on the bottom plate 3 and between the bottom plate 3 and the touch panel 5. In the present example, by the touch panel 5 provided, when the corresponding area on the touch panel 5 is touched by the user, the sensor 11 corresponding to the area can be triggered. The operation of the touch panel 5 is more convenient than the button operation.

It should be noted here that as shown in FIG. 2 and FIG. 3, both the foregoing bottom plate 3 and the touch panel 5 may be fan-shaped. The touch panel 5 may have a circular arc line and a straight line, and the circular arc line and the straight line are both solid lines, and the touch panel 5 is divided into a plurality of small fan-shaped regions, each of which has a sensor 11 on the bottom plate 3. Corresponding. When the small sector area on the touch panel 5 is touched, the sensor 11 on the bottom plate 3 corresponding to the small sector area is triggered. In the present example, by providing arc lines and straight lines on the touch panel 5, there is a technical effect that the user can recognize the corresponding small sector area.

In addition, the trigger signal generating module 2 described above may be a single chip microcomputer or a microprocessor.

The above air deflector control device may be a remote controller or the like.

An embodiment of the present application further provides a wind deflector control method, including the following steps: when the sensing portion 1 of the air deflector control device is triggered, the trigger signal generating module 2 of the wind deflector control device generates a trigger signal, The trigger signal is used to adjust the air deflector to a preset air guiding position corresponding to the triggered sensing portion 1.

Further, the number of the sensing portions 1 may be set to two or more, and each of the sensing portions 1 corresponds to a different preset air guiding position, so that the trigger signal generating module 2 generates different triggers when the different sensing portions 1 are triggered. The signal adjusts the air deflector to a preset air guiding position corresponding to the triggered sensing portion 1. For the specific effects, refer to the corresponding description in the above, and details are not described herein again.

In a specific application example, the aforementioned air deflector includes upper and lower air deflectors. The preset air guiding position of the upper and lower air guiding plates may include five different positions: 0° in the horizontal direction, 20° in the horizontal direction, 40° in the horizontal direction, 60° in the horizontal direction, and 80° in the horizontal direction. The preset air guiding position of the air deflector is accurately divided to meet the user's demand for different air guiding positions of the upper and lower air guiding plates.

Similarly, the aforementioned air deflector may further include left and right air deflectors. The preset air guiding position of the left and right air deflectors may include five different positions: a middle left 60°, a middle left 30°, a middle direction, a middle right 30°, and a middle right 60°, to guide the left and right winds. The preset air guiding position of the board is accurately divided to meet the user's demand for different air guiding positions of the left and right air guiding plates.

Further, when the foregoing sensing portions 1 are not triggered within the set time T, the wind deflector control device enters a sleep mode in which related components in the air deflector control device operate with minimum power Therefore, the power of the air deflector control device can be saved.

Further, in the sleep mode, when any of the sensing portions 1 is triggered for the first time, the trigger signal generating module 2 does not generate a trigger signal, and the air deflector control device switches to the air guiding direction adjusting mode to wake up the air deflector control device. Wherein, when the air deflector control device is in the air guiding direction adjusting mode, the trigger signal generating module 2 generates a trigger signal when the sensing portion 1 is triggered to adjust the position of the air guiding plate.

Further, when any of the sensing portions 1 is triggered for the first time in the sleep mode, the area of the sensing portion 1 corresponding to the current position of the air deflector is illuminated to prompt the user to set the current air deflector.

Similarly, when any of the sensing portions 1 is triggered in the air guiding direction adjusting mode, the area of the triggered sensing portion 1 is illuminated to prompt the user that the air deflector is to be adjusted to correspond to the bright sensing portion 1. status.

Further, when any of the sensing portions 1 is triggered, the speaker of the wind deflector control device emits a prompt tone to prompt the user that the sensing portion 1 has been triggered.

Further, the step of generating the trigger signal by the trigger signal generating module 2 to adjust the air deflector to the preset air guiding position corresponding to the triggered sensing portion 1 is: when the sensing portion 1 is triggered, the trigger signal generating module 2 Calculating an angular difference between the current position of the driving motor of the air deflector and the preset air guiding position corresponding to the triggered sensing portion 1, and generating a corresponding trigger signal according to the angular difference to control the output shaft of the driving motor of the air deflector Rotating the corresponding angle causes the wind deflector to rotate to a preset air guiding position corresponding to the triggered sensing portion 1.

Specifically, when the trigger signal generating module 2 only generates a trigger signal to adjust the position of the upper and lower air deflectors, when the sensing portion 1 is triggered, the trigger signal generating module 2 only calculates the driving motor of the upper and lower air deflectors. The angle difference between the current position and the preset air guiding position corresponding to the triggering sensing portion 1 is generated, and corresponding trigger signals are generated according to the angle difference, and the output shaft of the driving motor of the upper and lower air guiding plates is controlled to rotate by a corresponding angle to make the upper and lower guides The wind plate is rotated to a preset air guiding position corresponding to the triggered sensing portion 1. The step of adjusting the position of the left and right air deflectors by the trigger signal generating module 2 is the same as the step of adjusting the position of the upper and lower air deflectors. For details, refer to the corresponding description in the above, and details are not described herein again.

When the trigger signal generating module 2 generates a trigger signal to adjust the positions of the upper and lower air deflectors and the left and right air deflectors, the trigger signal generating module 2 calculates the upper and lower air deflectors on the one hand when the sensing unit 1 is triggered. a first angular difference between the current position and the preset air guiding position corresponding to the triggering sensing portion 1 , and generating a corresponding trigger signal according to the first angular difference to control an output shaft of the driving motor of the upper and lower air guiding plates Rotating the corresponding angle to rotate the upper and lower air deflectors to a preset air guiding position corresponding to the triggered sensing portion 1; the trigger signal generating module 2 described above also calculates the driving motor of the left and right air deflectors at the current position and the receiving position a second angle difference between the preset air guiding positions corresponding to the sensing portion 1 is generated, and corresponding trigger signals are generated according to the second angle difference, and the output shafts of the driving motors of the left and right air guiding plates are controlled to rotate corresponding angles, so that the left and right guides are The wind plate is rotated to a preset air guiding position corresponding to the triggered sensing portion 1.

The working principle and preferred embodiment of the present application are described below.

The technical solution provided above solves the following technical problems: 1. Solving the problem of rapid positioning of the upper and lower air guiding directions and the left and right air guiding directions of the air deflector of the air conditioner; 2. Solving the control logic problem of the touch control adjustment of the wind deflecting plate direction.

The technical solution provided by the application mainly includes: 1. controlling the direction of the air-conditioning deflector through the fan-shaped touch panel 5; 2. designing the fan-shaped touch bottom plate 3 with the pressure sensor 11 and its control circuit 6; 3. formulating a wind guide Control logic method for board direction touch control adjustment.

As shown in FIG. 1 to FIG. 4 , the air deflector control device of the present application mainly comprises a housing 7 , a display screen 8 , a touch panel 5 , a bottom plate 3 , a sensor 11 (such as a pressure sensor, etc.), a display lamp 4 , and a control circuit 6 . And a controller (ie, the aforementioned trigger signal generating module 2) and the like. Wherein, the width of the casing 7 of the air deflector control device is convenient for grasping by a human hand. The touch panel 5 is preferably designed as a fan ring shape, and is divided into a plurality of small fan ring regions by a plurality of arcs concentric with the outer arc of the fan ring and a plurality of straight lines passing through the center of the fan ring, and each of the small fan ring regions is below the bottom plate. 3 is provided with a fan-shaped pressure sensor 11 for detecting a finger touch point, and at the same time, a display lamp 4 is provided for displaying the currently selected small fan annular region. All small fan ring areas are connected to the controller through the control circuit 6, and the position of the touch point is judged by the built-in program of the controller and corresponding adjustment control is performed to position the upper and lower air deflectors and the left and right air deflectors of the electric appliance and the like. Make adjustments.

In this scheme, five gear positions are set in the upper and lower air guiding directions, and the left and right air guiding directions are specifically described.

As shown in FIG. 2 and FIG. 3, the fan-shaped touch panel 5 is sequentially arranged from the center of the circle to a zone, b zone, c zone, d zone and e zone, and the five zones are used for controlling the upper and lower guides of the upper and lower air deflectors. The wind position corresponds to "horizontal direction 0°", "horizontal down 20 °", "horizontal down 40 °", "horizontal down 60 °" and "horizontal down 80 °". The fan-shaped touch panel 5 is sequentially arranged from left to right as zone 1, zone 2, zone 3, zone 4, and zone 5, and the five zones are used to control the left and right wind guide positions of the left and right air deflectors, and sequentially correspond to the middle offset. Left 60°”, “middle left 30°”, “median direction”, “middle right 30°” and “middle right 60°”. As shown in FIG. 5, when any touch point on the fan-shaped touch panel 5 is detected, the control system controls the air deflector control device to enter the air guiding direction adjusting mode, and the display light 4 corresponding to the current position of the air guiding plate is illuminated. To display the current setting status, a startup tone is sounded at the same time. When the touch point is detected again, a combination of a letter line and a digital line is formed by judging the position of the touch point, thereby determining the setting positions of the upper and lower air deflectors and the left and right air deflectors, and issuing a control signal (ie, a trigger signal) Adjusting the upper and lower air deflectors and the left and right air deflectors to the set state, and the area display light 4 is illuminated, and an adjustment prompt sound is emitted. The specific control logic diagram is shown in Figure 5.

According to the above embodiments, the air deflector control device and the control method of the present application have at least the following advantages: 1. The touch panel 5 can be simply operated to quickly locate the direction of the air conditioner air deflector; 2. Adjust the position of the upper and lower air deflectors and the left and right air deflectors.

It should be noted here that in the case of no conflict, the technical features in the above examples can be combined with each other according to the actual situation to achieve the corresponding technical effects, specifically for various combinations. One by one.

The above description is only a preferred embodiment of the present application, and is not intended to limit the present application in any way. Any simple modifications, equivalent changes, and modifications made to the above embodiments in accordance with the technical spirit of the present application are still in the present invention. Apply within the scope of the technical solution.

Claims

A wind deflector control device, comprising: a sensing portion (1) and a trigger signal generating module (2);

The trigger signal generating module (2) is configured to generate a trigger signal when the sensing portion (1) is triggered; the trigger signal is used to adjust the air deflector to correspond to the triggered sensing portion (1) Preset guide air position.
The air deflector control device according to claim 1, wherein

The number of the sensing portions (1) is two or more, and the trigger signal generating module (2) generates different trigger signals when different sensing portions (1) are triggered;

Each of the sensing portions (1) corresponds to a different preset air guiding position.
The air deflector control device according to claim 1 or 2, wherein

The sensing portion (1) includes a sensor (11) for generating a trigger signal when the sensor (11) is triggered.
The air deflector control device according to claim 3, wherein

The air deflector control device has a first area (31), and each of the sensors (11) is distributed in the first area (31);

The first area (31) has two or more second areas (32) that do not overlap each other, and each of the sensors (11) is disposed in the corresponding second area (32) one by one.
The air deflector control device according to claim 4, wherein

The first area (31) is a fan-shaped area, and the inside of the fan-shaped area has two or more sub-fan annular regions divided by an arc and a straight line, and the arc and the outer circle of the fan-shaped area The centers of the arcs coincide, and the extension of the straight line passes through the center of the outer arc of the fan annular region;

Wherein the sub-fan annular region serves as the second region (32).
The air deflector control device according to claim 4 or 5, wherein

Each of the sensors (11) has an outer shape conforming to the corresponding second region (32).
The air deflector control device according to any one of claims 4 to 6, wherein

The air deflector control device further includes a display light (4);

The number of the display lamps (4) is equal to the number of the sensors (11) and corresponds one-to-one.
The air deflector control device according to claim 7, wherein

Each of the display lamps (4) is disposed in a corresponding one of the second regions (32).
The air deflector control device according to any one of claims 4 to 8, wherein

The air deflector control device comprises a housing (7), a bottom plate (3) disposed on the housing (7), and a touch panel (5) disposed on the bottom plate (3);

The bottom plate (3) has the first region (31), and the sensor (11) is located between the bottom plate (3) and the touch panel (5).
A method for controlling a wind deflector, characterized in that

When the sensing portion (1) of the air deflector control device is triggered, the trigger signal generating module (2) of the air deflector control device generates a trigger signal for adjusting the air deflector to the triggered sensing portion. (1) Corresponding preset wind guide position.
The air deflector control method according to claim 10, wherein

The number of the sensing portions (1) is set to two or more, and each sensing portion (1) corresponds to a different preset air guiding position to enable a trigger signal generating module when different sensing portions (1) are triggered ( 2) Generate different trigger signals to adjust the air deflector to the preset air guiding position corresponding to the triggered sensing portion (1).
The air deflector control method according to claim 11, wherein

The air deflector includes upper and lower air deflectors, and the preset air guiding positions of the upper and lower air deflectors include a horizontal direction of 0°, a horizontal downward 20°, a horizontal downward 40°, a horizontal downward 60°, and a horizontal downward direction. 80 different positions in 80°;

And/or, the air deflector includes left and right air deflectors, and the preset air guiding positions of the left and right air deflectors include a middle left 60°, a middle left 30°, a middle direction, a middle right 30°, and a middle Right at 60° five different positions.
The air deflector control method according to claim 11 or 12, characterized in that

When each of the sensing units (1) has no trigger for a set time, the air deflector control device enters a sleep mode.
The air deflector control method according to claim 13, wherein

In the sleep mode, when any sensing unit (1) is triggered for the first time, the trigger signal generating module (2) does not generate a trigger signal, and the air deflector control device switches to the air guiding direction adjusting mode.
The air deflector control method according to claim 14, wherein

When any sensing part (1) is triggered for the first time in the sleep mode, the area where the sensing part (1) corresponding to the current position of the air deflector is illuminated;

And/or, when any of the sensing portions (1) is triggered in the air guiding direction adjusting mode, the area of the triggered sensing portion (1) is illuminated.
The air deflector control method according to any one of claims 10 to 15, wherein

When the sensing portion (1) is triggered, the speaker of the wind deflector control device emits a prompt sound.
The air deflector control method according to any one of claims 10 to 16, wherein

The trigger signal generating module (2) generates a trigger signal to adjust the air deflector to a preset air guiding position corresponding to the triggered sensing portion (1): when the sensing portion (1) is triggered, the trigger signal generating module (2) calculating an angular difference between the current position of the driving motor of the air deflector and the preset air guiding position corresponding to the triggered sensing portion 1, and generating a corresponding trigger signal according to the angular difference to control the driving motor of the air guiding plate The output shaft rotates by a corresponding angle to rotate the wind deflector to a preset air guiding position corresponding to the triggered sensing portion (1).