WO2020015311A1 - Panel structure of air conditioner, and air conditioner - Google Patents

Abstract

Disclosed are a panel structure of an air conditioner, and an air conditioner, belonging to the technical field of air conditioners, and solving the problems of a greater speed of air being directly blown by an existing air conditioner and a poorer user experience effect. The panel structure of the air conditioner comprises an air guide plate (1) and a vertical swing blade assembly (2), wherein the air guide plate (1) is provided with a first microporous structure (11) penetrating through a thickness direction of the air guide plate, and swings up and down under the drive of an air guide plate electric motor; the vertical swing blade assembly (2) comprises a swing rod (21) and one or more vertical swing blades (22) of a bionic leaf structure; the vertical swing blades (22) are arranged on the swing rod (21); the swing rod (21) drives the vertical swing blades (22), under the driving of a swing rod drive electric motor, to swing to the left and to the right; and each vertical swing blade (22) is provided with a second microporous structure (221) penetrating through the thickness direction of the vertical swing blade.

Description

Panel structure of air conditioner and air conditioner

This application is based on a Chinese patent application with an application number of 201810806561.9 and an application date of July 20, 2018, and claims the priority of the Chinese patent application. The entire contents of this Chinese patent application are incorporated herein by reference.

Technical field

The invention relates to the technical field of air conditioners, and in particular to a panel structure of an air conditioner and an air conditioner.

Background technique

At present, most air conditioners blow directly, and the human experience is poor. Especially when the human body and the ambient temperature are relatively low, cold wind blowing on the body may cause discomfort. Even if some air conditioners with micro-hole air deflectors are partially alleviated or the wind-free feeling is pursued in the up-down direction, the wind blowing from the air deflectors still comes directly from the volute, and the wind speed from the micro holes of the outer air deflectors is still large. , The user experience is not good.

Summary of the invention

The embodiments of the present invention provide a panel structure of an air conditioner and an air conditioner, which are intended to solve the technical problems of a relatively high speed of direct air blowing from an existing air conditioner and a poor user experience effect. In order to have a basic understanding of some aspects of the disclosed embodiments, a brief summary is given below. This summary is not a general overview, nor is it intended to identify key / important constituent elements or to describe the scope of protection of these embodiments. Its sole purpose is to present some concepts in a simplified form as a prelude to the more detailed description that is presented later.

According to the embodiment of the present invention, a panel structure of an air conditioner and an air conditioner are provided. The vertical leaf is shaped like a natural leaf, and is driven to swing left and right by a motor, so that the wind coming from the volute is closer to the vertical leaf. Natural wind, the wind adjusted by the left and right vertical leaves and then adjusted up and down through the micro-hole wind deflector, so that the wind blown by the air conditioner is softer and meets the requirements of human comfort.

According to a first aspect of the embodiments of the present invention, a panel structure of an air conditioner is provided, including:

The wind deflector is provided with a first micro-hole structure penetrating through its thickness direction, and swings up and down under the drive of the wind deflector motor;

The vertical swing leaf assembly includes one or more vertical leaves and a swing lever of a bionic leaf structure, wherein the vertical swing leaf is arranged on the swing lever, and the swing lever is driven by a swing lever driving motor. The vertical swing leaf swings left and right, and the vertical swing leaf is provided with a second microporous structure penetrating through the thickness direction of the vertical swing leaf.

In some optional technical solutions, the width of the vertical swing leaf decreases from the middle to both ends, and the peripheral edge of the vertical swing leaf is streamlined.

In some optional technical solutions, the first microporous structure and / or the second microporous structure is configured as a structure in which a cross-sectional area of a cross section increases from a middle portion to both ends.

In some optional technical solutions, when there are multiple vertical swing leaves, any two adjacent vertical swing leaves have different blade sizes.

Further, the size of the leaves of the plurality of vertical swinging leaves decreases from the middle position of the swing lever to both sides; or, the size of the leaves of the plurality of vertical swinging leaves increases from the middle position of the swing lever to both sides.

In some optional technical solutions, a clamping member and a rotating member are provided on the vertical swing leaf, the vertical swing leaf is clamped and connected to the swing lever through the clamping piece, and the vertical swing leaf passes through The rotating member is rotatably connected to the panel frame of the panel structure, and the swing lever drives the vertical swing leaf to swing left and right relative to the panel frame under the driving of the swing lever driving motor.

In some optional technical solutions, the range of the maximum swing angle of the vertical swing leaf is [40 °, 160 °].

In some optional technical solutions, the panel structure further includes a pad disposed on an upper part of the vertical swing leaf assembly, and a width of the pad is not less than a maximum width of the vertical swing leaf.

In some optional technical solutions, the air deflector includes a plurality of first air deflectors arranged in parallel along the panel body of the panel structure, and the first air deflector is provided with a through The first microporous structure.

According to a second aspect of the embodiments of the present invention, there is provided an air conditioner including the panel structure of the air conditioner described above.

The technical solution provided by the embodiment of the present invention may include the following beneficial effects:

1. The vertical leaf bionics the shape of natural leaves, and is driven to swing left and right by the motor, so that the wind coming out of the volute is closer to the natural wind under the action of the vertical leaf. The wind adjusted by the left and right of the vertical leaf is then guided through the micro holes. The wind board is adjusted up and down, so that the wind from the air conditioner is softer and meets the requirements of human comfort.

2. The first microporous structure of the wind deflector and / or the second microporous structure of the vertical leaf is set to a structure in which the cross section increases from the middle to the two ends, and the two ends of the microporous structure diverge outward, which is not only conducive to the structural process Out of the mold, and the wind can be diffused outward through the microporous structure, the wind direction is different, closer to the natural wind.

It should be understood that the above general description and the following detailed description are merely exemplary and explanatory, and should not limit the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The drawings herein are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present invention, and together with the description serve to explain the principles of the present invention.

Fig. 1 is a schematic structural diagram of a panel structure of an air conditioner according to an exemplary embodiment;

2 is a front view of the panel structure shown in FIG. 1;

Figure 3 is a side view of the panel structure shown in Figure 1;

4 is a schematic structural diagram of wind direction adjustment of a wind deflector of the panel structure shown in FIG. 1;

5 is a schematic structural diagram of a wind deflector;

6 is an enlarged view of the structure A in FIG. 5;

7 is a schematic structural diagram of a vertical swing leaf;

Fig. 8 is a schematic structural diagram of a panel structure of an air conditioner according to an exemplary embodiment;

9 is a front view of the panel structure shown in FIG. 8;

10 is a side view of the panel structure shown in FIG. 8;

11 is a schematic structural diagram of wind direction adjustment of a wind deflector of the panel structure shown in FIG. 8;

Fig. 12 is a schematic structural diagram of a panel structure of an air conditioner according to an exemplary embodiment;

13 is a front view of the panel structure shown in FIG. 12;

14 is a side view of the panel structure shown in FIG. 12;

15 is a structural schematic diagram of wind direction adjustment of a wind deflector of the panel structure shown in FIG. 12;

Fig. 16 is a schematic flowchart of a method for controlling an air conditioner according to an exemplary embodiment;

17 is a schematic flowchart of a method for controlling an air conditioner according to an exemplary embodiment;

Fig. 18 is a schematic structural diagram of a device for controlling an air conditioner according to an exemplary embodiment;

Fig. 19 is a schematic structural diagram of a panel structure of an air conditioner according to an exemplary embodiment;

20 is a front view of the panel structure shown in FIG. 19;

21 is a rear view of the panel structure shown in FIG. 19;

22 is a side view of the panel structure shown in FIG. 19;

23 is a schematic structural diagram of a panel structure of an air conditioner according to an exemplary embodiment;

24 is a front view of the panel structure shown in FIG. 23;

25 is a rear view of the panel structure shown in FIG. 23;

Figure 26 is a side view of the panel structure shown in Figure 23;

Figure 27 is a schematic structural diagram of a vertical swing leaf;

Fig. 28 is a schematic flowchart of a method for controlling an air conditioner according to an exemplary embodiment;

Fig. 29 is a schematic flowchart of a method for controlling an air conditioner according to an exemplary embodiment;

Fig. 30 is a schematic structural diagram of a device for controlling an air conditioner according to an exemplary embodiment;

Fig. 31 is a schematic structural diagram of a panel structure of an air conditioner according to an exemplary embodiment;

32 is a front view of the panel structure shown in FIG. 31;

33 is a schematic structural diagram of wind direction adjustment of a wind deflector of the panel structure shown in FIG. 31;

Fig. 34 is a schematic structural diagram of a decorative board according to an exemplary embodiment;

Fig. 35 is a schematic structural diagram of assembling a decorative plate and a panel body according to an exemplary embodiment.

Reference sign description:

1- air deflector; 11- first micro-hole structure; 12- first air deflector; 13- second air deflector; 2- vertical swing leaf assembly; 21- swing lever; 22- vertical swing leaf; 221- Second micro-hole structure; 222-holding member; 223-rotating member; 3-panel body; 31-reinforcing rib; 4-panel frame; 5-pad; 6-body sensing device; 61-body sensor; 7 -Decorative board; 81- first acquisition module; 82- first control module; 83- second acquisition module; 84- second control module.

detailed description

The following description and the drawings sufficiently illustrate specific embodiments of the present invention to enable those skilled in the art to practice them. The embodiments represent only possible changes, unless explicitly required, individual components and functions are optional, and the order of operations may vary. Parts and features of some embodiments may be included in or replace parts and features of other embodiments. The scope of the embodiments of the invention includes the entire scope of the claims, and all available equivalents of the claims. Herein, the embodiments may be individually or collectively represented by the term "invention", this is for convenience only, and if more than one invention is actually disclosed, it is not intended to automatically limit the scope of the application to any A single invention or inventive idea. In this article, relational terms such as first and second are used only to distinguish one entity or operation from another entity or operation, and do not require or imply any actual relationship between these entities or operations or order.

It should be noted that descriptions such as “first” and “second” in the present invention are used for descriptive purposes only, and cannot be understood as indicating or suggesting their relative importance or implicitly indicating the number of technical features indicated. Therefore, the features defined as "first" and "second" may include at least one of these features explicitly or implicitly.

In the description of the present invention, it should be noted that the terms "installation" and "connection" should be understood in a broad sense unless otherwise specified and limited, for example, it may be a fixed connection, a detachable connection, or an integrated It can be a mechanical connection or an electrical connection; it can be a direct connection, or it can be indirectly connected through an intermediate medium, or it can be the internal connection of two components. For those of ordinary skill in the art, the specific meanings of the above terms in the present invention can be understood on a case-by-case basis.

The embodiments in this document are described in a progressive manner. Each embodiment focuses on the differences from other embodiments. For the same and similar parts between the embodiments, refer to each other.

Figs. 1 to 4 are schematic structural diagrams of a panel structure of an air conditioner according to an exemplary embodiment.

In this optional embodiment, a panel structure of an air conditioner is provided. The panel structure includes:

The wind deflector 1 is provided with a first micro-hole structure 11 penetrating through its thickness direction, and swings up and down under the driving of the motor of the wind deflector 1;

The vertical swing leaf assembly 2 includes a swing lever 21 and one or more bionic leaf structure vertical swing leaves 22, wherein the vertical swing leaf 22 is disposed on the swing lever 21, and the swing lever 21 is on the swing lever 21 The driving motor drives the vertical leaf 22 to swing left and right, and the vertical leaf 22 is provided with a second microporous structure 221 penetrating through the thickness direction.

In this optional embodiment, since the natural wind is generally softer after decelerating through the green shaded leaves, the vertical swing leaf 22 imitates the shape of a natural leaf, and the swing lever 21 drives a motor to drive the left and right to swing, so that the wind coming out of the volute The vertical leaf 22 is closer to the natural wind under the action of the vertical leaf 22, and the wind adjusted by the vertical leaf 22 is adjusted by the wind deflector 1 up and down to make the wind blown by the air conditioner softer. The first microporous structure 11 is provided on the wind deflector 1, and the second microporous structure 221 is provided on the vertical leaf 22. The wind oscillates on the wind deflector 1 and the vertical leaf 22. During the process, the first microporous structure 11 or the second microporous structure 221 penetrates, further disrupting the direction of airflow movement, reducing the wind speed in a specific direction, cooling without being cold, warm without being hot, and improving The physical comfort of the human body.

In some optional embodiments, when there are a plurality of vertical swing leaves 22, the blade sizes of any two adjacent vertical swing leaves 22 are different. When the airflow passing through one of the vertical leaves 22 is blown toward the vertical leaves 22 adjacent to the vertical leaves 22, the direction of airflow movement is different because the blade sizes of the two vertical leaves 22 are different. It will further change direction, reduce the wind speed in a specific direction, and make the airflow more gentle.

In some optional embodiments, the blade sizes of the plurality of vertical swing leaves 22 decrease from the middle position of the swing rod 21 to both sides; or, the blade sizes of the plurality of vertical swing leaves 22 decrease from the swing rod. The middle position of 21 increases to both sides. Optionally, a plurality of the vertical leaves 22 are provided in a similar shape structure. The vertical swing leaves 22 are set to be similar in shape, and the size of the blades is changed along the steps of the swing lever 21, and the direction of airflow movement is continuously changed, which can reduce the wind speed in a specific direction, and the indoor wind is softer or has no wind. Claim.

In some optional embodiments, the range of the maximum swing angle of the vertical swing blade 22 is [40 °, 160 °]. Optionally, the value of the maximum swing angle of the vertical swing blade 22 is 45. °, 60 °, 80 °, 120 °. The maximum swing angle of the vertical blade 22 is too small, and the adjustment range of the movement direction of the wind out of the volute is too small. The maximum swing angle of the vertical blade 22 is too large, and the direction of the wind out of the volute The adjustment frequency is too small, and the range of the maximum swing angle of the vertical blade 22 is [40 °, 160 °], which can better balance the adjustment range and adjustment frequency of the movement direction of the wind coming out of the volute , No wind feeling effect is better.

In some optional embodiments, the panel structure further includes a pad 5 disposed on an upper portion of the vertical leaf assembly 2, and a width of the pad 5 is not less than a maximum width of the vertical leaf 22. The pad 5 is provided on the upper part of the vertical leaf assembly 2 to prevent the air flow from being lost from the vertical leaf assembly 2 so that the wind coming out of the volute can be used for indoor temperature adjustment.

In some optional embodiments, the air deflector 1 includes a plurality of first air deflectors 12 arranged in parallel along the panel body 3 of the panel structure, and the first air deflector 12 is provided therethrough. The first microporous structure 11 in the thickness direction. A plurality of the first air deflectors 12 work together to achieve better wind direction adjustment effect. Further, the vertical swing directions of the two adjacent first air deflectors 12 are different, which can further disrupt the wind direction of the airflow passing through the vertical leaf assembly 2, so that the air from the air conditioner is closer to the natural wind. .

Figs. 5 to 6 are schematic structural diagrams of a wind deflector according to an exemplary embodiment.

In this alternative embodiment, a wind deflector 1 of the panel structure is provided, and the first microporous structure 11 of the wind deflector 1 is provided as a structure in which the cross-sectional area of the cross section increases from the middle to both ends.

Optionally, the second microporous structure 221 of the vertical swing leaf 22 is configured as a cross-sectional cross-sectional area that increases from the middle to the two ends.

In this optional implementation manner, the first microporous structure 11 of the wind deflector 1 and / or the second microporous structure 221 of the vertical leaf 22 are provided as a structure whose cross section increases from the middle to the two ends. The two ends of the pore structure diverge outward, which is not only conducive to the release of the structural process, but also can be radiated outward by the wind of the microporous structure, so that the wind direction passing through the first microporous structure 11 and / or the second microporous structure 221 Different, closer to the natural wind.

Fig. 7 is a schematic structural diagram of a vertical swing leaf according to an exemplary embodiment.

In this alternative embodiment, the width of the vertical leaf 22 decreases from the middle to the two ends, and the peripheral edge of the vertical leaf 22 is streamlined.

In this optional embodiment, since the natural wind is generally softer after decelerating through the green shaded leaves, the vertical leaf 22 is set in a bionic nature leaf shape that decreases in width from the middle to both ends, and the airflow passes through the vertical leaf 22 After deceleration, it is softer. Further, the peripheral edge of the vertical leaf 22 is set to be streamlined, and the resistance when the vertical leaf 22 swings left and right is smaller, and the airflow is softer.

In some optional embodiments, the vertical leaf 22 is provided with a clamping member 222 and a rotating member 223, and the vertical leaf 22 is clamped and connected to the swing lever 21 through the clamping member 222. The vertical leaf 22 is rotatably connected to the panel frame 4 of the panel structure through the rotating member 223. The swing lever 21 drives the vertical leaf 22 with respect to the drive of the swing lever 21 driving motor. The panel frame 4 swings left and right. Specifically, the holding member 222 includes a first groove that cooperates with the swing lever 21, the first groove is engaged with the swing lever 21, and the rotating member 223 includes a second groove. The panel frame 4 is provided with a protrusion that cooperates with the second groove. The rotating member 223 drives the vertical swing leaf 22 to rotate around the protrusion through the second groove. The swing lever 21 Driven by the drive motor of the swing lever 21, the vertical swing leaf 22 swings left and right about the protrusion driven by the swing lever 21. The vertical swing leaf 22 is movably connected to the swing lever 21 and the panel frame 4 through the holding member 222 and the rotating member 223, respectively, and is easy to assemble and disassemble.

In some optional embodiments, the ratio of the total area of the second microporous structure 221 of the vertical leaf 22 to the total area of the vertical leaf 22 ranges from [45%, 85%]. Optionally, the ratio of the total area of the second microporous structure 221 of the vertical leaf 22 to the total area of the vertical leaf 22 is 60%, 75%, 78%. The ratio of the total area of the second microporous structure 221 of the vertical leaf 22 to the total area of the vertical leaf 22 is too small. Insufficient, the total area of the second microporous structure 221 of the vertical leaf 22 is too large in the total area of the vertical leaf 22, and the effect of the breeze adjustment is poor. The value range of the ratio of the total area of the hole structure 221 to the total area of the vertical leaf 22 is set to [45%, 85%], which can better balance the air volume and the breeze of the second microhole structure 221 Adjust the effect.

In some optional embodiments, the maximum width of the second micropore structure 221 ranges from [5 mm, 10 mm]. Optionally, the maximum width of the second microporous structure 221 is 6mm, 7mm, 8mm, 9mm. By setting the value range of the maximum width of the second micropore structure 221 to [5mm, 10mm], the breeze adjustment effect is better.

In some optional embodiments, the thickness of the vertical leaf 22 decreases from the center position to the surroundings, and the difference between the maximum thickness and the minimum thickness of the vertical leaf 22 ranges from [3mm, 8mm]. Optionally, the difference between the maximum thickness and the minimum thickness of the vertical leaf 22 is 5 mm, 6 mm, or 7 mm. Setting the thickness of the vertical leaf 22 to a structure that decreases from the center position to the surroundings can increase the structural rigidity of the vertical leaf 22, and at the same time, the surface of the vertical leaf 22 also forms an airflow layer. The direction of the airflow is further disturbed, and the airflow is softer.

Fig. 8 to Fig. 11 are structural schematic diagrams of a panel structure of an air conditioner according to an exemplary embodiment.

In this optional embodiment, a panel structure of an air conditioner is provided. The panel structure includes:

The wind deflector 1 is provided with a first micro-hole structure 11 penetrating through its thickness direction, and swings up and down under the driving of the motor of the wind deflector 1;

The vertical swing leaf assembly 2 includes a swing lever 21 and one or more bionic leaf structure vertical swing leaves 22, wherein the vertical swing leaf 22 is disposed on the swing lever 21, and the swing lever 21 is on the swing lever 21 Driven by a driving motor, the vertical leaf 22 swings left and right, and the vertical leaf 22 is provided with a second microporous structure 221 penetrating through the thickness direction of the vertical leaf 22;

The panel body 3 is provided with a reinforcing rib 31.

In this alternative embodiment, on the one hand, a reinforcing rib 31 is provided on the panel body 3, which improves the structural strength of the panel structure and is not easily deformed. On the other hand, the vertical leaf 22 imitates the shape of a natural leaf The left and right swing is driven by a motor, so that the wind coming out of the volute is closer to the natural wind under the action of the vertical swing blade 22, and the wind adjusted by the vertical swing blade 22 left and right then passes through the micro-hole wind deflector 1 Adjusting up and down makes the wind from the air conditioner softer and meets the requirements of human comfort.

In some optional embodiments, the reinforcing ribs are provided as one or more first lateral reinforcing ribs along the length direction of the panel body 3, and / or one or more along the width direction of the panel body 3. First longitudinal ribs. Optionally, the first transverse stiffener and / or the first longitudinal stiffener are provided as a strip-shaped stiffener, and the strip-shaped stiffener is integrally formed with the panel body 3. The first transverse stiffener and / or the first longitudinal stiffener improve the overall strength of the panel body 3, and the strip-shaped stiffener is provided to simplify the lines of the entire strip-shaped panel body 3, optimizing The structure of the panel body 3 will be described.

In some optional embodiments, the length of the first transverse rib is equal to the length of the panel body 3, and the length of the first longitudinal rib is equal to the width of the panel body 3. The first transverse stiffener is provided through the length direction of the panel body 3, and the first longitudinal stiffener is provided through the width direction of the panel body 3. The structure of the panel body 3 is more compact and the processing technology is more For simplicity.

In some optional embodiments, the wind deflector 1 is provided with one or more second transverse ribs along its length direction, and / or one or more second longitudinal ribs along its width direction. The second transverse ribs and / or the second longitudinal ribs improve the overall strength of the wind deflector 1, and the entire strip-shaped wind deflector 1 has simple lines, which optimizes the structure.

In some optional embodiments, when the wind deflector 1 is closed, the first transverse rib and the second transverse rib are in the same straight line, and / or the first longitudinal rib and the second longitudinal rib The second longitudinal stiffeners are on the same straight line, and while improving the structural strength of the panel structure, the structural consistency of the panel structure is improved.

In some optional embodiments, the first micro-hole structure 11 is provided on the second transverse stiffener and / or the second longitudinal stiffener. The first microporous structure 11 is disposed through the thickness direction of the second lateral stiffener and / or the second longitudinal stiffener to play a breeze adjustment function.

In some optional embodiments, the panel body 3 includes a first portion located around the panel body 3 and a second portion located in a middle portion of the panel body 3, and a plurality of the first lateral portions of the first portion The density of the ribs is greater than the density of the plurality of first transverse ribs located in the second part, and / or the density of the plurality of first longitudinal ribs located in the first part is greater than the density of the first longitudinal ribs The density of a portion of a plurality of said first longitudinal ribs. During the use of the panel structure, the periphery of the panel body 3 is more susceptible to damage than the middle portion of the panel body 3, and the first lateral stiffeners and / or the first lateral ribs located in the first part of the panel body 3 will be more damaged. The distribution density of the second transverse stiffeners is set larger, which can further improve the structural stability of the panel body 3 located in the first portion, and for the panel body 3 located in the second portion, the structure The strength requirement is relatively low, and the distribution density of the first transverse stiffener and / or the second transverse stiffener located in the second part of the panel body 3 is set smaller, which can reduce the Quality, simplifying the manufacturing process of the panel body 3, and reducing production costs.

Fig. 12 to Fig. 15 are schematic structural diagrams of a panel structure of an air conditioner according to an exemplary embodiment.

In this optional embodiment, a panel structure of an air conditioner is provided. The panel structure includes:

The air deflector 1 includes a plurality of second air deflectors 13 arranged side by side along the panel body 3 of the panel structure. Each of the second air deflectors 13 is driven up and down by a drive motor of a wind deflector 1. Swinging, the second air deflector 13 is provided with a first microporous structure 11 penetrating through its thickness direction;

The vertical swing leaf assembly 2 includes a swing lever 21 and one or more bionic leaf structure vertical swing leaves 22, wherein the vertical swing leaf 22 is disposed on the swing lever 21, and the swing lever 21 is on the swing lever 21 Driven by a driving motor, the vertical leaf 22 swings left and right, and the vertical leaf 22 is provided with a second microporous structure 221 penetrating through the thickness direction of the vertical leaf 22;

The human body sensing device 6 is configured to sense the position of the human body and transmit the human body position information to a controller of the air conditioner, so that the controller controls the second wind deflector 1 and the vertical control panel according to the human body position information. How the swing leaf 22 operates.

In this alternative embodiment, on the one hand, the wind deflector 1 includes a plurality of second wind deflectors 13 arranged side by side along the panel body 3 of the panel structure, and the position information of the human body can be obtained according to the human body sensing device 6. Control the operation modes of the second air deflector 13 and the vertical leaf 22 to realize different air output requirements of different positions of the air conditioner and meet different air output requirements of users in different directions in the same room; on the other hand, the The vertical leaf 22 mimics the shape of a natural leaf, and is driven to swing left and right by a motor, so that the wind coming out of the volute is closer to the natural wind under the action of the vertical leaf 22, and the wind adjusted by the vertical leaf 22 is then Then the micro-hole air deflector is adjusted up and down to make the wind blown by the air conditioner softer and meet the requirements of human comfort.

In some optional embodiments, the human body sensor 61 of the human body sensing device 6 is embedded in the panel body 3. Optionally, the human body sensor 61 may be an infrared human body sensor 61. The human body sensor 61 is embedded in the panel body 3, and the structure of the panel structure is more compact.

Fig. 16 is a schematic flowchart of a method for controlling an air conditioner according to an exemplary embodiment.

In this optional embodiment, a method for controlling an air conditioner is provided. The method includes the following steps:

S161: Use human body sensing devices to obtain human position information.

S162: Control the operation mode of the second wind deflector and the vertical leaf according to the position information of the human body.

In this optional implementation manner, the operation modes of the second wind deflector 13 and the vertical leaf 22 are controlled according to the position information of the human body obtained by the human body sensing device 6, so as to achieve different air requirements in different positions of the air conditioner. To meet the different needs of users in different directions in the same room.

Fig. 17 is a schematic flowchart of a method for controlling an air conditioner according to an exemplary embodiment.

In this optional embodiment, a method for controlling an air conditioner is provided. The method includes the following steps:

S171: Use human body sensing devices to obtain human body position information.

The human body position information is determined according to the human body position obtained by the human body sensing device 6.

S172: Compare the human body position information with pre-stored position area information to obtain a pre-stored position area where the human body position is.

The area that can be perceived by the human sensing device 6 is partitioned in advance, and the coordinate information in the position information of the human body is compared with the pre-stored coordinate information in the position area information to obtain the position where the human body is located. Pre-stored location area.

For example, if the coordinate information in the position information of the human body is (5, 8, 6), and the coordinate information of the pre-stored first position area is (4-7, 7-9, 5-7), it can be determined that The human body position is in a pre-stored first position area.

S173: If the position of the human body is in a pre-stored first position area, control the second wind deflector on the first side of the center of the panel structure to swing up and down, and close the second wind deflector on the second side of the center of the panel structure. , Control the vertical swing leaf to swing left and right.

The position of the human body is in a pre-stored first position area, and the second wind deflector 13 on the first side of the center of the panel structure is controlled to swing up and down, and the second wind deflector on the second side of the center of the panel structure The plate 13 is closed, and the vertical leaf 22 is controlled to swing left and right, so that the space on the first side of the panel structure has a uniform and large air volume, and the space on the second side of the panel structure is soft.

S174: If the position of the human body is in a pre-stored second position area, control the second air deflector located on the first side of the center of the panel structure to close, and the second air guide located on the second side of the center of the panel structure. The wind board swings up and down to control the vertical swing leaf to swing left and right.

The human body position is in a pre-stored second position area, and the second wind deflector 13 located on the first side of the center of the panel structure is controlled to close, and the second wind deflector located on the second side of the center of the panel structure is closed. 13 swings up and down, and controls the vertical leaves 22 to swing left and right, so that the space on the first side of the panel structure is soft and the space on the second side of the panel structure is uniform and large.

S175: If the position of the human body is in a pre-stored first position area and a second position area, control the second wind deflector to be closed, and control the vertical leaf to swing left and right.

The position of the human body is in a pre-stored first position area and a second position area, and the second wind deflector 13 is controlled to be closed, and the vertical leaf 22 is controlled to swing left and right, so that the entire space is soft.

S176: if the position of the human body is in a pre-stored first position area, second position area, and third position area, control the second wind deflector to swing up and down, and control the vertical leaf to swing left and right; or, control the The second air deflector is horizontal, and controls the vertical leaf to stand upright.

The position of the human body is in a pre-stored first position area, second position area, and third position area, and controls the second wind deflector 13 to swing up and down, and controls the vertical leaf 22 to swing left and right; or, controls the first The two air deflectors 13 are horizontal, and the vertical leaves 22 are controlled to erect, so that the entire space has a large air volume.

In this optional implementation manner, the pre-stored first position area corresponds to the area located on the second side of the center of the panel structure, and the pre-stored second position area corresponds to the area located on the first side of the center of the panel structure. The three-position area is a specific area, which indicates that the spatial density of the human body is relatively large at this time. The air conditioner detects that the human body is located in the pre-stored first position area, so that the area located on the second side of the center of the panel structure is soft; the air conditioner detects that the human body is located in the pre-stored first location. The two-position area makes the area located on the first side of the center of the panel structure soft; the air conditioner detects that the human body is located in the pre-stored first location area and the second location area, so that the entire space is soft ; The air conditioner detects that the human body is located in the pre-stored first location area, second location area, and third location area, so that the entire space has a large air volume, and realizes different air requirements of different locations of the air conditioner, more Smart and flexible.

Fig. 18 is a schematic structural diagram of a device for controlling an air conditioner according to an exemplary embodiment.

In this optional embodiment, a device for controlling an air conditioner is provided, and the device includes:

A first acquiring module 81, configured to acquire human body position information using the human body sensing device 6;

The first control module 82 is configured to control the operation modes of the second wind deflector 13 and the vertical leaf 22 according to the position information of the human body.

In some optional embodiments, the first control module 82 is specifically configured to:

Comparing the human body position information with pre-stored position area information to obtain a pre-stored position area in which the human body position is located;

If the position of the human body is in a pre-stored first position area, the second wind deflector 13 on the first side of the center of the panel structure is controlled to swing up and down, and the second guide on the second side of the center of the panel structure The wind plate 13 is closed to control the vertical leaf 22 to swing left and right;

If the position of the human body is in the pre-stored second position area, control the second wind deflector 13 on the first side of the center of the panel structure to close, and the second wind deflector on the second side of the center of the panel structure The plate 13 swings up and down, and controls the vertical swing leaf 22 to swing left and right;

If the position of the human body is in the pre-stored first position area and second position area, controlling the second wind deflector 13 to be closed, and controlling the vertical swing leaf 22 to swing left and right;

If the position of the human body is in the pre-stored first position area, second position area, and third position area, controlling the second wind deflector 13 to swing up and down, controlling the vertical swing blade 22 to swing left and right; or, controlling the The second air deflector 13 stands horizontally, and controls the vertical swing leaf 22 to stand upright.

In some optional embodiments, an air conditioner control device is provided for an air conditioner, and the device includes:

processor;

Memory for storing processor-executable instructions;

The processor is configured to:

Use human body sensing device 6 to obtain human body position information;

The operation mode of the second wind deflector 13 and the vertical leaf 22 is controlled according to the position information of the human body.

Further, the processor is specifically configured to:

Acquiring human body position information by using the human body sensing device 6;

Comparing the human body position information with pre-stored position area information to obtain a pre-stored position area in which the human body position is located;

If the position of the human body is in a pre-stored first position area, the second wind deflector 13 on the first side of the center of the panel structure is controlled to swing up and down, and the second guide on the second side of the center of the panel structure The wind plate 13 is closed to control the vertical leaf 22 to swing left and right;

If the position of the human body is in the pre-stored second position area, control the second wind deflector 13 on the first side of the center of the panel structure to close, and the second wind deflector on the second side of the center of the panel structure The plate 13 swings up and down, and controls the vertical swing leaf 22 to swing left and right;

If the position of the human body is in the pre-stored first position area and second position area, controlling the second wind deflector 13 to be closed, and controlling the vertical swing leaf 22 to swing left and right;

If the position of the human body is in the pre-stored first position area, second position area, and third position area, controlling the second wind deflector 13 to swing up and down, controlling the vertical swing blade 22 to swing left and right; or, controlling the The second air deflector 13 stands horizontally, and controls the vertical swing leaf 22 to stand upright.

Figs. 19-22 are schematic structural diagrams of a panel structure of an air conditioner according to an exemplary embodiment.

In this optional embodiment, a panel structure of an air conditioner is provided. The panel structure includes:

The wind deflector 1 is provided with a first micro-hole structure 11 penetrating through its thickness direction, and swings up and down under the driving of the motor of the wind deflector 1;

A plurality of vertical leaf components 2 arranged parallel to each other along the panel body 3 of the panel structure. Each of the vertical leaf components 2 includes a swing rod 21 and one or more bionic leaf structure vertical leaves 22. The vertical leaf 22 is arranged on the swing lever 21, and the swing lever 21 drives the vertical leaf 22 to swing left and right under the drive of the swing lever 21 driving motor. The second micropore structure 221 in the thickness direction.

In this optional embodiment, the vertical leaves 22 imitate the shape of a natural leaf. Multiple rows of the vertical leaves 22 are driven to swing left and right by a motor. After the air conditioner passes through the evaporator, it passes through multiple rows of the vertical leaves 22. The left and right adjusted wind is then adjusted up and down through the micro-hole wind deflector 1 to change the wind direction and wind speed several times to make the wind more comfortable, closer to the natural wind, lower wind noise, and better user experience.

In some optional embodiments, the two vertical leaf blades 22 of any two adjacent vertical leaf blade assemblies 2 are staggered. The vertical leaves 22 of the two adjacent vertical leaves assemblies 2 are offset, and the airflow passing through one of the vertical leaves 22 flows through the vertical leaves 22 adjacent to the vertical leaves 22 Further deceleration and reorientation make the direction of airflow more chaotic, so as to achieve the purpose of no wind feeling.

In some optional embodiments, the blade sizes of the two vertical swing leaves 22 of any two adjacent vertical swing leaves components 2 are different. When the airflow passing through one of the vertical leaves 22 is blown toward the vertical leaves 22 adjacent to the vertical leaves 22, the direction of airflow movement is different because the blade sizes of the two vertical leaves 22 are different. It will further change direction, reduce the wind speed in a specific direction, and make the airflow more gentle.

In some optional embodiments, the distance between two adjacent vertical swing leaves 22 decreases from the middle position of the swing lever 21 to both sides; or, the distance between two adjacent vertical swing leaves 22 decreases. The distance increases from the middle position of the swing lever 21 to both sides. The distance between two adjacent vertical swing leaves 22 is gradually changing. When each vertical swing leaf 22 swings left and right, the wind from the volute passes non-uniformly through the vertical swing leaves 22, so that it passes through the vertical swing leaves 22. The airflow direction and size of the swing leaves 22 are different, making the airflow softer.

Optionally, the distance between two adjacent vertical swing leaves 22 satisfies the following relationship:

d = 1.7 * L (n-1) / [n * (N-1)]

Among them, L is the length of the swing lever 21, N is the number of the vertical swing leaves 22 located on the swing lever 21, n is the number of the distance between two adjacent vertical swing leaves 22 from the center position of the swing lever 21, d Is the distance between the two adjacent vertical swing leaves 22 in the nth segment.

Specifically, n is an integer number starting from the center position of the swing lever 21 and increasing from the integer 2, such as 2, 3, 4, 5, ...

When the distance between two adjacent vertical blades 22 satisfies the above relationship, when each of the vertical blades 22 swings left and right, the direction of the airflow changing from the volute through the vertical blades 22 becomes more chaotic. , The airflow is softer, and the structure of the vertical leaf 22 is more reasonable and compact.

Fig. 23-Fig. 26 are structural schematic diagrams of a panel structure of an air conditioner according to an exemplary embodiment.

In this optional embodiment, a panel structure of an air conditioner is provided. The panel structure includes:

The wind deflector 1 is provided with a first micro-hole structure 11 penetrating through its thickness direction, and swings up and down under the driving of the motor of the wind deflector 1;

The vertical swing leaf assembly 2 includes a swing lever 21 and one or more vertical swing leaves 22, wherein the vertical swing leaf 22 is disposed on the swing lever 21, and the swing lever 21 is driven by a drive motor of the swing lever 21 The vertical swinging leaf 22 is driven downward to swing left and right, and the vertical swinging leaf 22 is provided with a second microporous structure 221 penetrating through the thickness direction.

In this optional embodiment, the vertical leaf 22 is driven to swing left and right by a motor to adjust the wind coming out of the volute, and the wind adjusted left and right by the vertical leaf 22 is then adjusted up and down through the micro-hole wind deflector 1. By combining the vertical leaf 22, the wind deflector 1 and the microporous structure, the wind blown by the air conditioner is closer to the natural wind, which is clean and healthy, and improves human comfort.

Fig. 27 is a schematic structural diagram of a vertical swing leaf according to an exemplary embodiment.

In this alternative embodiment, the vertical swing leaf 22 is provided as a structure including a plurality of sub-lobes that are parallel to each other, and the second microporous structure 221 on any two adjacent sub-lobes is offset. The airflow passing through the vertical swinging blades 22 changes direction between the sub-blades of the vertical swinging blades 22, and the airflow further disturbs the movement direction of the airflow through the second micro-hole structures 221 which are arranged at different positions. The air flow passing through the vertical leaves 22 is chaotic and close to the natural wind, thereby improving the user experience.

In some optional embodiments, the second microporous structure 221 is provided with a rotatable blade, and the blade rotates under the action of external airflow. The airflow passing through the second microporous structure 221 is driven by the rotation of the blades, and the airflow direction changes significantly. The airflow direction is completely disrupted, making the airflow through the vertical leaves 22 more chaotic and close to natural wind. To meet the needs of a sense of wind, the user experience is good.

In some optional embodiments, the vertical swing leaf 22 has a triangular structure, and the peripheral edges of the triangular structure are streamlined, with high stability and low swing resistance.

Fig. 28 is a schematic flowchart of a method for controlling an air conditioner according to an exemplary embodiment.

In this optional embodiment, a method for controlling an air conditioner is provided. The method includes the following steps:

S281: Obtain an operating mode of the air conditioner.

S282: Control the operation modes of the air deflector and the vertical leaf according to the operation mode.

In this optional implementation manner, different operation modes of the wind deflector 1 and the vertical leaf 22 can be controlled according to the operation mode of the air conditioner, and different operation modes of the air conditioner can be controlled, which is flexible and convenient.

Fig. 29 is a schematic flowchart of a method for controlling an air conditioner according to an exemplary embodiment.

In this optional embodiment, a method for controlling an air conditioner is provided. The method includes the following steps:

S291: Obtain the operation mode of the air conditioner.

S292: If the operation mode is uniform high air volume operation, control the air baffle to swing up and down, and control the vertical blade to swing left and right.

The left and right winds adjusted by the vertical swing leaves 22 are blown out after being adjusted up and down by the wind deflector 1, so that the air conditioner can operate with a uniform large air volume.

S293: If the operation mode is gentle and small air volume operation, control the air baffle to swing up and down, and control the vertical swing leaf to close.

The breeze passing through the second microporous structure 221 of the vertical leaf 22 is blown out after being adjusted up and down by the wind deflector 1, so as to realize gentle and small air volume operation of the air conditioner.

S294: If the operation mode is gentle and large air volume operation, control the wind deflector to close, and control the vertical leaf to swing left and right.

The wind that is adjusted left and right through the vertical swing leaves 22 is blown out through the first micro-hole structure 11 of the wind deflector 1, so as to realize gentle and large air volume operation of the air conditioner.

S295: If the operation mode is gentle breeze operation, control the wind deflector to close and control the vertical swing leaf to close.

The breeze passing through the second microporous structure 221 of the vertical swing blade 22 and then blown out through the first microporous structure 11 of the wind deflector 1 can realize the gentle breeze operation of the air conditioner.

S296: If the operation mode is a high-air volume operation, control the wind deflector to stand upright, and control the vertical leaf to stand upright.

The vertical leaf 22 is erected, the wind deflector 1 is horizontal, and the wind diameter blown out from the volute of the air conditioner is blown out directly, so that the large air volume operation of the air conditioner can be realized.

In this optional embodiment, different operation modes of the air deflector 1 and the vertical vane 22 can be controlled according to the operation mode of the air conditioner, and different operation modes of the air conditioner can be controlled to meet user requirements. Demand for different operating modes of air conditioners.

Fig. 30 is a schematic structural diagram of a device for controlling an air conditioner according to an exemplary embodiment.

In this optional embodiment, a device for controlling an air conditioner is provided, and the device includes:

A second obtaining module 83, obtaining an operating mode of the air conditioner;

The second control module 84 controls the operation modes of the wind deflector 1 and the vertical swing blade 22 according to the operation mode.

Further, the second control module 84 is specifically configured to:

If the operation mode is uniform and large air volume operation, controlling the wind deflector 1 to swing up and down, and controlling the vertical swing blade 22 to swing left and right;

If the operating mode is gentle and small air volume operation, controlling the wind deflector 1 to swing up and down, and controlling the vertical swing blade 22 to close;

If the operation mode is gentle and large air volume operation, controlling the wind deflector 1 to be closed, and controlling the vertical swing blade 22 to swing left and right;

If the operation mode is gentle breeze operation, controlling the wind deflector 1 to be closed and controlling the vertical swing blade 22 to be closed;

If the operation mode is a high-air volume operation, the wind deflector 1 is controlled to be horizontal, and the vertical leaf 22 is controlled to be vertical.

In some optional embodiments, an air conditioner control device is provided for an air conditioner, and the device includes:

processor;

Memory for storing processor-executable instructions;

The processor is configured to:

Obtaining an operating mode of the air conditioner;

The operation modes of the wind deflector 1 and the vertical vane 22 are controlled according to the operation mode.

Further, the processor is specifically configured to:

Obtaining an operating mode of the air conditioner;

If the operation mode is uniform and large air volume operation, controlling the wind deflector 1 to swing up and down, and controlling the vertical swing blade 22 to swing left and right;

If the operating mode is gentle and small air volume operation, controlling the wind deflector 1 to swing up and down, and controlling the vertical swing blade 22 to close;

If the operation mode is gentle and large air volume operation, controlling the wind deflector 1 to be closed, and controlling the vertical swing blade 22 to swing left and right;

If the operation mode is gentle breeze operation, controlling the wind deflector 1 to be closed and controlling the vertical swing blade 22 to be closed;

If the operation mode is a high-air volume operation, the wind deflector 1 is controlled to be horizontal, and the vertical leaf 22 is controlled to be vertical.

Fig. 31-Fig. 33 are schematic structural diagrams of a panel structure of an air conditioner according to an exemplary embodiment.

In this optional embodiment, a panel structure of an air conditioner is provided. The panel structure includes:

The panel body 3 is provided with one or more first transverse ribs along its length direction, and / or one or more first longitudinal ribs along its width direction;

The wind deflector 1 includes a plurality of second wind deflectors 13 arranged side by side along the panel body 3, and each of the second wind deflectors 13 swings up and down under the driving of a wind deflector 1 driving motor. The second air deflector 13 is provided with a first micro-hole structure 11 penetrating in a thickness direction thereof;

The vertical swing leaf assembly 2 includes a swing lever 21 and one or more bionic leaf structure vertical swing leaves 22, wherein the vertical swing leaf 22 is disposed on the swing lever 21, and the swing lever 21 is on the swing lever 21 The driving motor drives the vertical leaf 22 to swing left and right, and the vertical leaf 22 is provided with a second microporous structure 221 penetrating through the thickness direction.

In this alternative embodiment, the panel body 3 is provided with one or more first transverse ribs along its length direction, and / or one or more first longitudinal ribs along its width direction, which improves the The structural strength of the panel makes it difficult for the panel to deform. In addition, the vertical leaf 22 imitates the shape of a leaf in nature and is driven to swing left and right by a motor, so that the wind coming out of the volute is closer to nature under the action of the vertical leaf 22 The wind is adjusted by the vertical swing leaves 22 and then adjusted by the micro-hole wind deflector 1 to make the wind blown by the air conditioner softer and meet the requirements of human comfort. In addition, the wind deflector 1 includes A plurality of second air deflectors 13 arranged side by side along the panel body 3, by controlling different operation modes of the second air deflectors 13 and the vertical leaves 22, different positions of different air conditioners are realized. The air output meets the different air output needs of users in different directions in the same room.

In some optional embodiments, the second wind deflector 13 is provided with one or more second transverse reinforcing ribs along its length direction, and / or one or more second longitudinal reinforcing ribs along its width direction. Tendons. The second transverse ribs and / or the second longitudinal ribs improve the overall strength of the second wind deflector 13 and optimize the structure of the second wind deflector 13.

In some optional embodiments, the length of the second transverse rib is equal to the length of the second wind deflector 13, and the length of the second longitudinal rib is equal to the width of the second wind deflector 13. equal. The second lateral stiffener is disposed through the length direction of the second wind deflector 13, and the second longitudinal stiffener is disposed through the width direction of the second air deflector 13, and the second wind deflector 13 The structure is more compact and the processing technology is simpler.

In some optional embodiments, the panel structure further includes a human body sensing device 6 for sensing a human body position and transmitting the human body position information to a controller of the air conditioner, so that the controller is based on the human body position. The information controls the operation modes of the second wind deflector 1 and the vertical vane 22. The operation mode of the second wind deflector 13 and the vertical leaf 22 is controlled according to the position information of the human body obtained by the human body sensing device 6, so as to achieve different airflow requirements in different positions of the air conditioner, which can meet different directions in the same room. Different outlet requirements of users.

Fig. 34-Fig. 35 are schematic structural diagrams of a decorative board according to an exemplary embodiment.

In this alternative embodiment, a decorative plate 7 for mounting with the panel body 3 is provided. The decorative plate 7 is provided with one or more third transverse reinforcing ribs along its length direction, and / or One or more third longitudinal ribs along its width. The third horizontal stiffener and / or the third vertical stiffener improve the overall strength of the decorative plate 7 and optimize the structure of the decorative plate 7, wherein the decorative plate plays a role in The protective role of the body.

In some optional embodiments, when the decorative plate 7 is installed with the panel body 3, the first transverse rib and the third transverse rib are in the same straight line, and / or, the first longitudinal The stiffener is in the same straight line as the third longitudinal stiffener. While improving the structural strength of the panel structure, the structural consistency of the panel structure is improved.

Further, when the decorative plate 7 and the panel body 3 are installed, the first transverse stiffener overlaps the third transverse stiffener, and / or, the first longitudinal stiffener and the third The longitudinal stiffeners overlap, making the structure more compact.

In some optional embodiments, a panel structure of an air conditioner is provided, including:

The wind deflector 1 is provided with a first micro-hole structure 11 penetrating through its thickness direction, and swings left and right under the drive of the motor of the wind deflector 1;

The oscillating leaf assembly includes a oscillating lever 21 and one or more oscillating leaves of a bionic leaf structure, wherein the oscillating leaf is disposed on the oscillating lever 21, and the oscillating lever 21 is disposed on the oscillating lever 21 driving motor. The yaw leaf is driven to swing up and down, and the yaw leaf is provided with a second microporous structure 221 penetrating through the thickness direction of the yaw leaf.

In this optional embodiment, since the natural wind is generally softer after decelerating through the green shaded leaves, the lateral leaves are imitated in the shape of natural leaves, and the swinging rod 21 drives the motor to drive up and down to swing, so that the wind coming out of the volute is in place. The yaw blade is closer to the natural wind under the action of the yaw blade, and the wind adjusted by the yaw blade is then adjusted left and right by the wind deflector 1 to make the wind blown by the air conditioner softer. At the same time, the wind guide The first microporous structure 11 is provided on the plate 1, and the second microporous structure 221 is provided on the yawing leaf. During the process of the wind deflector 1 and the yawing leaf swinging, the wind The first microporous structure 11 or the second microporous structure 221 is penetrated, further disrupting the direction of airflow movement, reducing the wind speed in a specific direction, being cold instead of cold, warm but not hot, and improving the physical comfort of the human body. .

Optionally, the width of the yaw leaf decreases from the middle to both ends, and the peripheral edge of the yaw leaf is streamlined.

Optionally, when there are multiple yawing leaves, any two adjacent yawing leaves have different sizes.

Optionally, the size of the blades of the plurality of oscillating leaves decreases from the middle position of the swing lever 21 to both sides; or, the size of the blades of the plurality of oscillating leaves decreases from the middle position of the swing lever 21 to both sides Incrementally.

Specifically, the distance between two adjacent yaw leaves satisfies the following relationship:

d = 1.7 * L (n-1) / [n * (N-1)]

Among them, L is the length of the swing bar 21, N is the number of yaw leaves located on the swing bar 21, n is the number of the distance between two adjacent yawing leaves from the center position of the swing bar 21, and d is the first The distance between n adjacent two yaw leaves.

Specifically, n is an integer number starting from the center position of the swing lever 21 and increasing from the integer 2, such as 2, 3, 4, 5, ...

Optionally, the swinging leaf is provided with a clamping member 222 and a rotating member 223, the swinging leaf is clamped and connected to the swing lever 21 through the clamping member 222, and the swinging leaf passes through The rotating member 223 is rotatably connected to the panel frame 4 of the panel structure, and the swing lever 21 drives the swing leaf to swing up and down relative to the panel frame 4 under the drive of the swing lever 21 driving motor.

Optionally, the range of the maximum swing angle of the yaw blade is [40 °, 160 °].

Optionally, the wind deflector 1 includes a plurality of first wind deflectors 12 arranged side by side along the panel body 3 of the panel structure, and the first wind deflector 12 is provided with a space extending through its thickness direction.述 第一 微孔 结构 11。 The first micropore structure 11.

In some optional embodiments, a panel structure of an air conditioner is provided, and the panel structure includes:

The wind deflector 1 is provided with a first micro-hole structure 11 penetrating through its thickness direction, and swings left and right under the drive of the motor of the wind deflector 1;

The oscillating leaf assembly includes a oscillating lever 21 and one or more oscillating leaves of a bionic leaf structure, wherein the oscillating leaf is disposed on the oscillating lever 21, and the oscillating lever 21 is disposed on the oscillating lever 21 driving motor. Driving the yaw leaf to swing up and down, and the yaw leaf is provided with a second microporous structure 221 penetrating through the thickness direction of the yaw leaf;

The panel body 3 is provided with a reinforcing rib 31.

In some optional embodiments, a panel structure of an air conditioner is provided, and the panel structure includes:

The wind deflector 1 includes a plurality of second wind deflectors 13 arranged side by side along the panel body 3 of the panel structure. Each of the second wind deflectors 13 is driven by a drive motor of a wind deflector 1 to the left and right. Swinging, the second air deflector 13 is provided with a first microporous structure 11 penetrating through its thickness direction;

The oscillating leaf assembly includes a oscillating lever 21 and one or more oscillating leaves of a bionic leaf structure, wherein the oscillating leaf is disposed on the oscillating lever 21, and the oscillating lever 21 is disposed on the oscillating lever 21 driving motor. Driving the yaw leaf to swing up and down, and the yaw leaf is provided with a second microporous structure 221 penetrating through the thickness direction of the yaw leaf;

The human body sensing device 6 is configured to sense the position of the human body and transmit the human body position information to a controller of the air conditioner, so that the controller controls the second wind deflector 1 and the crossbar according to the human body position information. Way of swinging leaves.

In some optional embodiments, a method for controlling an air conditioner is provided. The method includes:

Acquiring human body position information by using the human body sensing device 6;

The operation modes of the second wind deflector 13 and the yaw leaf are controlled according to the position information of the human body.

Optionally, the controlling the operation modes of the second wind deflector 13 and the yaw leaf according to the position information of the human body includes:

Comparing the human body position information with pre-stored position area information to obtain a pre-stored position area in which the human body position is located;

If the position of the human body is in a pre-stored first position area, control the second wind deflector 13 on the first side of the center of the panel structure to swing left and right, and the second guide on the second side of the center of the panel structure The wind plate 13 is closed to control the yaw leaf to swing up and down;

If the position of the human body is in the pre-stored second position area, control the second wind deflector 13 on the first side of the center of the panel structure to close, and the second wind deflector on the second side of the center of the panel structure The plate 13 swings left and right to control the yaw leaf to swing up and down;

If the position of the human body is in the pre-stored first position area and second position area, controlling the second wind deflector 13 to be closed, and controlling the yaw leaf to swing up and down;

If the position of the human body is in the pre-stored first position area, second position area, and third position area, control the second wind deflector 13 to swing left and right, and control the yaw blade to swing up and down; or, control the first Two air deflectors 13 are erected to control the yaw leaves to erection.

In some optional embodiments, a device for controlling an air conditioner is provided, and the device includes:

A third acquisition module, configured to acquire human body position information by using the human body sensing device 6;

A third control module is configured to control the operation modes of the second wind deflector 13 and the yaw leaf according to the position information of the human body.

Optionally, the third control module is specifically configured to:

Comparing the human body position information with pre-stored position area information to obtain a pre-stored position area in which the human body position is located;

If the position of the human body is in a pre-stored first position area, control the second wind deflector 13 on the first side of the center of the panel structure to swing left and right, and the second guide on the second side of the center of the panel structure The wind plate 13 is closed to control the yaw leaf to swing up and down;

If the position of the human body is in the pre-stored second position area, control the second wind deflector 13 on the first side of the center of the panel structure to close, and the second wind deflector on the second side of the center of the panel structure The plate 13 swings left and right to control the yaw leaf to swing up and down;

If the position of the human body is in the pre-stored first position area and second position area, controlling the second wind deflector 13 to be closed, and controlling the yaw leaf to swing up and down;

If the position of the human body is in the pre-stored first position area, second position area, and third position area, control the second wind deflector 13 to swing left and right, and control the yaw blade to swing up and down; or, control the first Two air deflectors 13 are erected to control the yaw leaves to erection.

In some optional embodiments, a panel structure of an air conditioner is provided, and the panel structure includes:

The wind deflector 1 is provided with a first micro-hole structure 11 penetrating through its thickness direction, and swings left and right under the drive of the motor of the wind deflector 1;

A plurality of yawing leaf components arranged in parallel along the panel body 3 of the panel structure. Each of the yawing leaf components includes a swing lever 21 and one or more yaw leaves with a bionic leaf structure. The swing leaf is arranged on the swing lever 21, and the swing lever 21 drives the swing leaf to swing up and down under the drive of the swing lever 21 driving motor. The swing leaf is provided with a second孔 结构 221。 Hole structure 221.

Optionally, the yawing leaves of any two adjacent yawing leaf components are dislocated.

Optionally, the blade sizes of any two adjacent yawing leaf components of the yawing leaf component are different.

Optionally, the distance between two adjacent yawing leaves decreases from the middle position of the swing bar 21 to both sides; or, the distance between two adjacent yawing leaves is from the swing bar The middle position of 21 increases to both sides.

Optionally, the range of the ratio of the total area of the second microporous structure 221 of the yaw leaf to the total area of the yaw leaf is [45%, 85%].

Optionally, the thickness of the yawing leaf decreases from the center position to the surroundings, and the difference between the maximum thickness and the minimum thickness of the yawing leaf ranges from [3mm, 8mm].

In some optional embodiments, a panel structure of an air conditioner is provided, and the panel structure includes:

The wind deflector 1 is provided with a first micro-hole structure 11 penetrating through its thickness direction, and swings left and right under the drive of the motor of the wind deflector 1;

The oscillating leaf assembly includes a oscillating rod 21 and one or more oscillating leaves, wherein the oscillating blade is disposed on the oscillating rod 21, and the oscillating rod 21 is driven by a driving motor of the oscillating rod 21 The yaw leaf swings up and down, and the yaw leaf is provided with a second microporous structure 221 penetrating through its thickness direction.

Optionally, the oscillating leaves are arranged as a structure including a plurality of sub-lobes that are parallel to each other, and the second microporous structures 221 on any two adjacent sub-lobes are staggered.

Optionally, the material of the yaw leaf is a PVC material.

In some optional embodiments, a method for controlling an air conditioner is provided. The method includes:

Obtaining an operating mode of the air conditioner;

The operation modes of the wind deflector 1 and the yaw blade are controlled according to the operation mode.

In this optional implementation manner, different operation modes of the air deflector 1 and the yaw blade can be controlled according to the operation mode of the air conditioner, and different operation modes of the air conditioner can be controlled, which is flexible and convenient.

Optionally, the controlling the operation modes of the wind deflector 1 and the yaw blade according to the operation mode includes:

If the operation mode is a uniform large air volume operation, controlling the wind deflector 1 to swing left and right, and controlling the yaw blade to swing up and down;

The wind that has been adjusted up and down by the yaw leaves and then blows out after being adjusted left and right by the air deflector 1 can achieve uniform and large air volume operation of the air conditioner.

If the operation mode is gentle and small air volume operation, controlling the wind deflector 1 to swing left and right, and controlling the yaw leaf to close;

The breeze passing through the second microporous structure 221 of the oscillating leaves is blown out after being adjusted left and right through the wind deflector 1, so as to realize gentle and small air volume operation of the air conditioner.

If the operation mode is gentle and large air volume operation, controlling the wind deflector 1 to be closed and controlling the yaw leaf to swing up and down;

The wind that has been adjusted up and down by the yaw leaves is then blown out through the first micro-hole structure 11 of the wind deflector 1, so that gentle and large air volume operation of the air conditioner can be realized.

If the operation mode is gentle breeze operation, controlling the wind deflector 1 to be closed and controlling the yaw leaf to be closed;

The breeze passing through the second microporous structure 221 of the oscillating leaves and then blown out through the first microporous structure 11 of the wind deflector 1 can realize the gentle breeze operation of the air conditioner.

If the operation mode is a high-air volume operation, the wind deflector 1 is controlled to stand up, and the yaw leaf is controlled to stand up.

The yaw leaves are erected, the wind deflector 1 is erected, and the wind path blown out from the volute of the air conditioner is blown out directly, which can realize the large air volume operation of the air conditioner.

In this optional implementation manner, different operation modes of the air deflector 1 and the yaw blade can be controlled according to the operation mode of the air conditioner, and different operation modes of the air conditioner can be controlled to meet users' requirements for air conditioners. Requirements of different operating modes of the processor.

In some optional embodiments, a device for controlling an air conditioner is provided, and the device includes:

A fourth obtaining module, obtaining an operating mode of the air conditioner;

A fourth control module controls the operation modes of the wind deflector 1 and the yaw blade according to the operation mode.

Optionally, the fourth control module is specifically configured to:

If the operation mode is a uniform large air volume operation, controlling the wind deflector 1 to swing left and right, and controlling the yaw blade to swing up and down;

If the operation mode is gentle and small air volume operation, controlling the wind deflector 1 to swing left and right, and controlling the yaw leaf to close;

If the operation mode is gentle and large air volume operation, controlling the wind deflector 1 to be closed and controlling the yaw leaf to swing up and down;

If the operation mode is gentle breeze operation, controlling the wind deflector 1 to be closed and controlling the yaw leaf to be closed;

If the operation mode is a high-air volume operation, the wind deflector 1 is controlled to stand up, and the yaw leaf is controlled to stand up.

In some optional embodiments, a panel structure of an air conditioner is provided, and the panel structure includes:

The panel body 3 is provided with one or more first transverse ribs along its length direction, and / or one or more first longitudinal ribs along its width direction;

The air deflector 1 includes a plurality of second air deflectors 13 arranged side by side along the panel body 3, and each of the second air deflectors 13 swings left and right under the drive of a drive motor of the air deflector 1. The second air deflector 13 is provided with a first micro-hole structure 11 penetrating in a thickness direction thereof;

The oscillating leaf assembly includes a oscillating lever 21 and one or more oscillating leaves of a bionic leaf structure, wherein the oscillating leaf is disposed on the oscillating lever 21, and the oscillating lever 21 is disposed on the oscillating lever 21 driving motor. The yaw leaf is driven to swing up and down, and the yaw leaf is provided with a second microporous structure 221 penetrating through the thickness direction of the yaw leaf.

It should be noted that, when the wind deflector 1 swings up and down, the vertical leaf 22 swings left and right; when the wind deflector 1 swings left and right, the yaw leaf swings up and down to realize the passage of the wind deflector 1 and the adjustment of the airflow in all directions of the swing blade. The swinging direction of the swinging leaf is different from the swinging direction of the swinging leaf 22. For the specific structure of the swinging leaf and its implementation, please refer to the specific structure of the swinging leaf 22 and its implementation.

In some exemplary embodiments, an air conditioner is further provided, and the air conditioner includes the panel structure described above.

In some exemplary embodiments, a non-transitory computer-readable storage medium including instructions, such as a memory including instructions, may be provided, which may be executed by a processor to implement the method described above. The non-transitory computer-readable storage medium may be a read-only memory (Read Only Memory, ROM), a random access memory (Random Access Memory, RAM), a magnetic tape, and an optical storage device.

Those skilled in the art may realize that the units and algorithm steps of each example described in combination with the embodiments disclosed herein can be implemented by electronic hardware, or a combination of computer software and electronic hardware. Whether these functions are performed in hardware or software depends on the specific application and design constraints of the technical solution. Those skilled in the art may use different methods to implement the described functions for each specific application, but such implementation should not be considered to be beyond the scope of the present invention. Those skilled in the art can clearly understand that, for the convenience and brevity of description, the specific working processes of the systems, devices, and units described above can refer to the corresponding processes in the foregoing method embodiments, and are not repeated here.

In the embodiments disclosed herein, it should be understood that the disclosed methods and products (including but not limited to devices, equipment, etc.) may be implemented in other ways. For example, the device embodiments described above are only schematic. For example, the division of the unit is only a logical function division. In actual implementation, there may be another division manner. For example, multiple units or components may be combined or Can be integrated into another system, or some features can be ignored or not implemented. In addition, the displayed or discussed mutual coupling or direct coupling or communication connection may be indirect coupling or communication connection through some interfaces, devices or units, which may be electrical, mechanical or other forms. The units described as separate components may or may not be physically separated, and the components displayed as units may or may not be physical units, may be located in one place, or may be distributed on multiple network units. Some or all of the units may be selected according to actual needs to achieve the objective of the solution of this embodiment. In addition, each functional unit in each embodiment of the present invention may be integrated into one processing unit, or each unit may exist separately physically, or two or more units may be integrated into one unit.

It should be understood that the flowchart and block diagrams in the figures illustrate the architecture, functionality, and operation of possible implementations of systems, methods and computer program products according to various embodiments of the present invention. In this regard, each block in the flowchart or block diagram may represent a module, a program segment, or a part of code, which contains one or more components for implementing a specified logical function Executable instructions. It should also be noted that in some alternative implementations, the functions noted in the blocks may also occur in a different order than those marked in the drawings. For example, two consecutive blocks may actually be executed substantially in parallel, and they may sometimes be executed in the reverse order, depending on the functions involved. It should also be noted that each block in the block diagrams and / or flowcharts, and combinations of blocks in the block diagrams and / or flowcharts, can be implemented in a dedicated hardware-based system that performs the specified function or action. , Or it can be implemented with a combination of dedicated hardware and computer instructions. The present invention is not limited to the processes and structures that have been described above and shown in the drawings, and various modifications and changes can be made without departing from the scope thereof. The scope of the invention is only limited by the appended claims.

Claims (10)

1. A panel structure of an air conditioner is characterized in that it includes:

   The wind deflector is provided with a first micro-hole structure penetrating through its thickness direction, and swings up and down under the drive of the wind deflector motor;

   A vertical swing leaf assembly includes a swing lever and one or more bionic leaf structure vertical swing leaves, wherein the vertical swing leaf is provided on the swing lever, and the swing lever drives the swing lever under the drive of a swing lever driving motor. The vertical swing leaf swings left and right, and the vertical swing leaf is provided with a second microporous structure penetrating through the thickness direction of the vertical swing leaf.
2. The panel structure according to claim 1, wherein a width of the vertical swing leaf decreases from a middle to both ends, and a peripheral edge of the vertical swing leaf is streamlined.
3. The panel structure according to claim 1, wherein the first microporous structure and / or the second microporous structure is provided as a structure in which a cross-sectional area of a cross section increases from a middle portion to both ends.
4. The panel structure according to claim 1, wherein when there are a plurality of vertical swing leaves, any two adjacent vertical swing leaves have different blade sizes.
5. The panel structure according to any one of claims 1 or 4, characterized in that the blade size of the plurality of vertical swinging leaves decreases from the middle position of the swinging lever to both sides; or, the plurality of vertical swinging leaves The leaf size of the leaf increases from the middle position of the swing bar to both sides.
6. The panel structure according to claim 1, wherein the vertical leaf is provided with a clamping member and a rotating member, and the vertical leaf is clamped and connected with the swing rod through the clamping member, so that The vertical leaf is rotatably connected to the panel frame of the panel structure through the rotating member, and the swing lever drives the vertical leaf to swing left and right relative to the panel frame under the driving of the swing lever driving motor.
7. The panel structure according to claim 1, wherein the range of the maximum swing angle of the vertical swing blade is [40 °, 160 °].
8. The panel structure according to claim 1, further comprising a pad provided on an upper portion of the vertical swing leaf assembly, and a width of the pad is not less than a maximum width of the vertical swing leaf.
9. The panel structure according to claim 1, wherein the air deflector comprises a plurality of first air deflectors arranged in parallel along the panel body of the panel structure, and the first air deflector is provided with The first microporous structure runs through its thickness direction.
10. An air conditioner, comprising the panel structure according to any one of claims 1 to 9.

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