CN116839098A - Air guide structure, air supply equipment and air supply control method - Google Patents

Abstract

The application relates to an air guide structure, air supply equipment and an air supply control method. The second air guide component is movably arranged between the air supply main body and the first air guide component, and the first air guide component and the second air guide component can be matched together to realize air flow layering blown out from the air supply port so as to realize dispersing air outlet, so that the indoor environment temperature is uniform and consistent, and the user experience is good; and the first wind guide component can cover and close the air supply opening, so that the second wind guide component is contained in the air supply main body, the probability that the second wind guide component is damaged by the outside is reduced, the integrity of the appearance of the air supply main body is facilitated, and the attractiveness of a product is improved.

Description

Air guide structure, air supply equipment and air supply control method

Technical Field

The application relates to the technical field of air supply equipment, in particular to an air guide structure, air supply equipment and an air supply control method.

Background

In the prior art, a household appliance capable of adjusting indoor environment temperature, such as an air conditioner and the like, has the working principle that air is sucked into the air conditioner from an air inlet, flows through a cross-flow wind wheel and an air guide mechanism in an air duct in sequence after heat exchange of an indoor heat exchanger, and is finally discharged from an air supply outlet, wherein the air guide mechanism is used for guiding air flowing out of the air conditioner. However, the conventional air guide mechanism has a single air supply direction, which is easy to cause inconsistent indoor environment temperature and affects comfort of users.

Disclosure of Invention

Accordingly, it is necessary to provide an air guide structure, an air blowing device, and an air blowing control method for realizing distributed air blowing of an air conditioner so that the indoor environment temperature is uniform.

An air guiding structure installed at an air supply port of an air supply main body, the air guiding structure comprising:

the first air guide component is rotatably connected to the air supply main body in a matching way so as to open and close the air supply port; a kind of electronic device with high-pressure air-conditioning system

The second air guide component is connected between the air supply main body and the first air guide component in a matching way;

the second air guide component is folded and arranged between the first air guide component and the air supply main body when the first air guide component closes the air supply port;

and the second air guide component moves to an air supply path of the air supply port along with the first air guide component when the first air guide component opens the air supply port, and divides the air flow blown out from the air supply port into at least two layers.

In one embodiment, the second air guiding component has a first surface facing the air supplying main body and a second surface facing the first air guiding component, a first diversion channel is formed between the first surface and the air supplying main body, and a second diversion channel is formed between the second surface and the first air guiding component;

The air supply directions of the first diversion channel and the second diversion channel are variably set according to the opening degree of the first air guide component relative to the air supply opening.

In one embodiment, a spoiler structure is disposed on either one of the first surface and the second surface.

In one embodiment, the second air guiding component comprises a first air guiding plate and a second air guiding plate, the first air guiding plate and one end of the second air guiding plate are hinged with each other and are rotatably arranged, and the first air guiding plate and the second air guiding plate can be folded when the first air guiding component closes the air supply opening or can be unfolded on an air supply path of the air supply opening to form a first preset included angle when the first air guiding component opens the air supply opening.

In one embodiment, the orthographic projection of the first air deflector in the horizontal direction entirely covers the orthographic projection of the second air deflector.

In one embodiment, the second air guiding component comprises an elastic component, and the elastic component is connected between the first air guiding plate and the second air guiding plate in a deformable manner, so that the first air guiding plate and the second air guiding plate are correspondingly controlled to be opened or closed when the first air guiding component opens and closes the air supplying opening.

In one embodiment, the air guiding structure further comprises a driving structure, the driving structure comprises a rotating component and a telescopic component, the telescopic component is sequentially connected with the air supply main body, the second air guiding component and the first air guiding component at intervals, the telescopic component can stretch out and draw back along the up-down direction, so that the first air guiding component is controlled to be opposite to the opening of the air supply opening and the inclination angle of the first air guiding component is adjusted, the rotating component is respectively connected with the telescopic rod and the second air guiding component, and the rotating component can adjust the inclination angle of the second air guiding component.

In one embodiment, the air guiding structure includes a third air guiding component, the third air guiding component is disposed between the air supply main body and the first air guiding component and hinged to the air supply main body, and the third air guiding component can rotate relative to the air supply main body along with rotation of the first air guiding component so as to adjust the opening of the air supply opening.

An air supply device comprises an air supply main body with an air supply port and an air guide structure arranged at the air supply port; wherein the air guiding structure is the air guiding structure of any one of the above claims 1-8.

An air supply control method for an air supply device, the air supply device including the air guiding structure according to any one of claims 1 to 8, the control method comprising:

acquiring a device starting instruction;

and controlling the air guide structure to change the air supply direction of the air supply device according to the starting instruction, wherein the first air guide component opens the air supply port, and the second air guide component moves to an air supply path of the air supply port so as to split air flow blown out from the air supply port into at least two layers.

In one embodiment, the step of controlling the air guiding structure to change the air supplying direction of the air supplying device according to the start command includes:

determining a current working mode of the air supply equipment;

and controlling the air guide structure to be in an air supply state corresponding to the current working mode according to the starting instruction, wherein the first air guide component rotates to an angle corresponding to the current working mode, and synchronously controlling the second air guide component to rotate so as to provide an air supply direction corresponding to the current working mode.

In one embodiment, the step of determining the current operation mode of the air supply device includes:

Determining the current working mode of the air supply equipment as a refrigerating mode;

controlling the air guide structure to be in a first air supply state according to the starting instruction, wherein the first air guide component is controlled to rotate to a first rotating angle, and the second air guide component is synchronously controlled to rotate to the first air guide angle; or (b)

Determining that the current working mode of the air supply equipment is a direct blowing prevention mode;

controlling the air guide structure to be in a second air supply state according to the starting instruction, wherein the first air guide component is controlled to rotate to a second rotation angle, and the second air guide component is synchronously controlled to rotate to the second air guide angle; or (b)

Determining that the current working mode of the air supply equipment is a gentle air mode;

and controlling the air guide structure to be in a third air supply state according to the starting instruction, wherein the first air guide component is controlled to rotate to a third rotation angle, and the second air guide component is synchronously controlled to rotate to the third air guide angle.

In one embodiment, after the controlling the air guiding structure according to the start command is in the second air supplying state, the air supplying control method further includes:

acquiring the current indoor temperature, determining that the current indoor temperature is not less than a first preset temperature, and controlling the air guide structure to be in a first air supply state;

When the air guide structure is in a first air supply state, acquiring first working time in real time, determining that the first working time is equal to first preset time, and controlling the air guide structure to be in a second air supply state.

In one embodiment, the method for controlling the air guiding structure to be in the third air supply state according to the start instruction further includes:

acquiring the current indoor temperature, determining that the current indoor temperature is not greater than a second preset temperature, and controlling the air guide structure to be in a first air supply state.

According to the air guide structure, the air supply equipment and the air supply control method, the first air guide component is rotatably connected to the air supply main body in a matching mode so as to open and close the air supply port, and the second air guide component is connected between the air supply main body and the first air guide component in a matching mode. When the first air guide part closes the air supply opening, the second air guide part is folded and arranged between the first air guide part and the air supply main body. And the second air guide component moves to the air supply path of the air supply port along with the first air guide component when the first air guide component opens the air supply port, and divides the air flow blown out from the air supply port into at least two layers. The second air guide component is movably arranged between the air supply main body and the first air guide component, and the first air guide component and the second air guide component can be matched together to realize air flow layering blown out from the air supply port so as to realize dispersing air outlet, so that the indoor environment temperature is uniform and consistent, and the user experience is good; and the first wind guide component can cover and close the air supply opening, so that the second wind guide component is contained in the air supply main body, the probability that the second wind guide component is damaged by the outside is reduced, the integrity of the appearance of the air supply main body is facilitated, and the attractiveness of a product is improved.

Drawings

Fig. 1 is a schematic structural diagram of an air supply device according to the present application at a first viewing angle.

Fig. 2 is a schematic structural diagram of an air supply device according to the present application at a second view angle.

Fig. 3 is a schematic structural diagram of an air supply device according to the present application at a first view angle in a cooling mode.

Fig. 4 is a schematic structural diagram of an air supply device according to the present application at a second view angle in a cooling mode, wherein an arrow indicates an air supply direction.

Fig. 5 is an enlarged partial schematic view of the area a in fig. 4, wherein a thick dotted line represents a horizontal plane.

Fig. 6 is a schematic structural diagram of the air supply device in the anti-blow-through mode according to the present application, wherein an arrow indicates a blowing direction.

Fig. 7 is a partially enlarged schematic view of the region B in fig. 6, wherein a thick dotted line indicates a horizontal plane.

Fig. 8 is a schematic structural view of the air supply device in the gentle air mode according to the present application, wherein an arrow indicates an air supply direction.

Fig. 9 is an enlarged partial schematic view of region C in fig. 7.

Fig. 10 is a schematic structural view of a second air guiding component according to the present application at a first viewing angle.

Fig. 11 is a schematic structural view of a second air guiding component according to the present application at a second viewing angle.

FIG. 12 is a flow chart of a method for controlling air supply of the air supply device shown in FIG. 1 in an embodiment.

Fig. 13 is a flowchart of an air supply control method of the air supply device shown in fig. 1 in another embodiment.

Fig. 14 is a flowchart of a method for controlling air supply of the air supply device shown in fig. 1 in yet another embodiment.

Fig. 15 is a flowchart of a method for controlling air supply of the air supply device shown in fig. 1 in yet another embodiment.

Fig. 16 is a flowchart of a method for controlling air supply of the air supply device shown in fig. 1 in yet another embodiment.

Reference numerals

An air guiding structure 100;

a first air guide member 11; a first rotation angle 11a; a second rotation angle 11b; a third rotation angle 11c;

a second air guide member 12; a first air deflector 121; a second air deflector 122; a spoiler structure 123; an elastic member 124; a first surface 12a; a second surface 12b; a first preset included angle 12c; a second preset included angle 12d; a first air conduction angle 12e; a second air guiding angle 12f; a third air guide angle of 12g;

a third air guide member 13; a first air supply angle 13a; a second air supply angle 13b; a third air supply angle 13c;

a drive structure 14; a rotating member 141; a telescopic member 142;

an air blowing device 200; a blower main body 21; an air supply port 21a; a first diversion passage 21b; a second shunt channel 21c.

Detailed Description

In order that the above objects, features and advantages of the application will be readily understood, a more particular description of the application will be rendered by reference to the appended drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application. The present application may be embodied in many other forms than described herein and similarly modified by those skilled in the art without departing from the spirit of the application, whereby the application is not limited to the specific embodiments disclosed below.

In the description of the present application, it should be understood that, if any, these terms "center", "longitudinal", "transverse", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc., are used herein with respect to the orientation or positional relationship shown in the drawings, these terms refer to the orientation or positional relationship for convenience of description and simplicity of description only, and do not indicate or imply that the apparatus or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the application.

Furthermore, the terms "first," "second," and the like, if any, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In the description of the present application, the terms "plurality" and "a plurality" if any, mean at least two, such as two, three, etc., unless specifically defined otherwise.

In the present application, unless explicitly stated and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly. For example, the two parts can be fixedly connected, detachably connected or integrated; can be mechanically or electrically connected; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art according to the specific circumstances.

In the present application, unless expressly stated or limited otherwise, the meaning of a first feature being "on" or "off" a second feature, and the like, is that the first and second features are either in direct contact or in indirect contact through an intervening medium. Moreover, a first feature being "above," "over" and "on" a second feature may be a first feature being directly above or obliquely above the second feature, or simply indicating that the first feature is level higher than the second feature. The first feature being "under", "below" and "beneath" the second feature may be the first feature being directly under or obliquely below the second feature, or simply indicating that the first feature is less level than the second feature.

It will be understood that if an element is referred to as being "fixed" or "disposed" on another element, it can be directly on the other element or intervening elements may also be present. If an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like as used herein, if any, are for descriptive purposes only and do not represent a unique embodiment.

Referring to fig. 1 to 3, in one aspect, the present application provides an air supply apparatus 200, where the air supply apparatus 200 includes an air supply main body 21 having an air supply port 21a. The air blowing main body 21 can generate an air flow having a specific temperature and flow out from the air blowing port 21a to improve the external temperature environment.

The specific type of air moving device 200 is not limited, for example: air conditioning, humidifiers, etc. In the embodiment of the application, the air supply device 200 is taken as a wall-mounted air conditioner as an example for writing.

Referring to fig. 1 to 3, another aspect of the present application provides an air guiding structure 100, which is installed at an air outlet 21a of an air supply main body 21, and the air guiding structure 100 includes a first air guiding member 11 and a second air guiding member 12.

The first air guiding member 11 is rotatably coupled to the air supply main body 21 to open and close the air supply port 21a. It can be understood that, on the one hand, the first air guiding component 11 can cover the air supply port 21a by rotating at different angles, so as to realize the closing of the air supply port 21a, thereby preventing external pollutants from entering the air supply main body 21 through the air supply port 21 a; on the other hand, the first air guide member 11 can change the air blowing direction of the air flow flowing out from the air blowing port 21a by adjusting the opening degree of the air blowing port 21a by rotating a different angle and changing the inclination angle thereof.

The second air guide member 12 is coupled between the air supply main body 21 and the first air guide member 11. The second air guide member 12 is disposed between the first air guide member 11 and the air blowing main body 21 when the first air guide member 11 closes the air blowing port 21 a. And the second air guiding member 12 also moves along the air supplying path of the air supplying port 21a along with the first air guiding member 11 when the air supplying port 21a is opened by the first air guiding member 11, and divides the air flow blown out from the air supplying port 21a into at least two layers.

It is understood that the opening degree between the second air guiding member 12 and the air supply main body 21 and the opening degree between the first air guiding member 11 are changed during the rotation of the first air guiding member 11.

Specifically, during the process of closing the air supply port 21a by the first air guide member 11 in a rotating manner, the opening degree between the second air guide member 12 and the air supply main body 21 and the opening degree between the second air guide member 12 and the first air guide member 11 are gradually reduced, and when the first air guide member 11 closes the air supply port 21a, the second air guide member 12 is disposed between the first air guide member 11 and the air supply main body 21 in a folded manner. During the process of the first air guide member 11 rotatably opening the air supply port 21a, the opening between the second air guide member 12 and the air supply main body 21 and the opening between the second air guide member 12 and the first air guide member 11 are gradually increased, and the second air guide member 12 is positioned between the air supply main body 21 and the first air guide member 11 at intervals so as to split the air flow blown out from the air supply port 21a into at least two layers. In this way, the second air guiding component 12 is movably arranged between the air supply main body 21 and the first air guiding component 11, and the first air guiding component 11 and the second air guiding component 12 can cooperate together to realize air flow layering blown out from the air supply port 21a so as to realize air distribution, so that the indoor environment temperature is uniform and consistent, and the user experience is good; and the first wind guiding component 11 can cover and close the air supply opening 21a, so that the second wind guiding component 12 is contained in the air supply main body 21, thereby reducing the probability of the second wind guiding component 12 being damaged by the outside, and being beneficial to the completeness of the appearance of the air supply main body 21, so as to improve the aesthetic property of the product.

In some embodiments, referring to fig. 1 and 2, the second air guiding member 12 has a first surface 12a facing the air supply main body 21 and a second surface 12b facing the first air guiding member 11.

A first diversion passage 21b is formed between the first surface 12a and the blower main body 21. And the first surface 12a can guide the flow direction of the air flow to change the blowing direction of the first diverting passage 21b.

The second diversion passage 21c is configured between the second surface 12b and the first air guiding member 11. The second surface 12b and the first air guiding member 11 are both capable of guiding the air flow direction, and cooperate with each other to change the air supply direction of the second diversion passage 21c.

The air blowing directions of the first and second diversion passages 21b and 21c are variably set according to the opening degree of the first air guide member 11 with respect to the air blowing port 21 a.

It will be appreciated that the opening degree of the first air guiding member relative to the air supply opening 21a may be changed during the rotation of the first air guiding member, and the opening degree of the second air guiding member 12 relative to the opening degree between the air supply main body 21 and the first air guiding member 11, that is, the opening degrees of the first and second diversion passages 21b and 21c may be changed along with the rotation of the first air guiding member, and meanwhile, the direction in which the air flows guided by the first and second surfaces 12a and 12b may be changed, so that the air supply direction of the first and second diversion passages 21b and 21c may be changed. In this way, the user can control the airflow flux of the air supply port 21a by adjusting the opening degrees of the first diversion channel 21b and the second diversion channel 21c according to the actual needs, and can control the air supply directions of the first diversion channel 21b and the second diversion channel 21c by adjusting the drainage directions of the first surface 12a and the second surface 12b, so that the airflows generated by the two diversion channels can flow to a specific area to meet the needs of the user. For example, the user can increase the opening of the first diversion channel 21b and the second diversion channel 21c, increase the airflow circulation, and adjust the first surface 12a and the second surface 12b so as to make the drainage directions of the two different, so as to realize the dispersed circulation of the airflow, improve the convective heat transfer effect of the room, and further make the indoor environment temperature change uniformly, and improve the comfort of the user.

In some embodiments, referring to fig. 1 and 2, a spoiler structure 123 is disposed on either one of the first surface 12a and the second surface 12 b. The turbulence structure can change the flow direction of the airflow to generate turbulence, that is, the airflow flowing through the turbulence structure 123 can generate irregular flow direction, so that the turbulence is softer and more comfortable than the airflow flowing in a single direction, and can be directly blown on the human body to improve the surface temperature of the human body.

In some embodiments, referring to fig. 3, 10 and 11, the second air guiding component 12 includes a first air guiding plate 121 and a second air guiding plate 122, where the first air guiding plate 121 and one end of the second air guiding plate 122 are hinged to each other and rotatably disposed.

The first air deflector 121 and the second air deflector 122 can be opened to form a first preset included angle 12c on the air supply path of the air supply port 21a when the air supply port 21a is opened by the first air guiding member 11. Thus, the first air deflector 121 and the second air deflector 122 have different diversion directions, so that the airflow can be dispersed and circulated, the indoor environment temperature is uniform and consistent, and the user experience is good.

The first air guide plate 121 and the second air guide plate 122 can be folded when the first air guide member 11 closes the air supply port 21 a. It can be appreciated that when the first air guiding component 11 closes the air supply opening 21a, the included angle between the first air guiding plate 121 and the second air guiding plate 122 is gradually folded and attached, so that the second air guiding component 12 is contained in the air supply main body 21, thereby reducing the probability that the second air guiding component 12 is damaged by the outside, and being beneficial to the integrity of the appearance of the air supply main body 21, so as to improve the aesthetic property of the product.

It can be appreciated that the first preset included angle 12c is used to make the first air deflector 121 and the second air deflector 122 form different flow guiding directions, so as to change the flow splitting directions of the first flow splitting channel 21b and the second flow splitting channel 21c, so as to achieve the effect of air dispersion flow.

The specific range of the first preset included angle 12c is not limited. In some embodiments, please refer to fig. 10 and 11, please refer to fig. 1 and 2, the value of the first predetermined included angle 12c is not less than 30 degrees, for example: 30 degrees, 35 degrees, 40 degrees, 45 degrees, etc. Preferably, the value of the first preset included angle 12c is 45 degrees.

It should be noted that, the specific value range of the first preset included angle 12c is obtained through experimental tests, and parameters, steps, etc. related to the experimental tests of the specific value range of the first preset included angle 12c are conventional technologies of those skilled in the art, and are not described herein.

The specific arrangement manner of the first air guide plate 121 and the second air guide plate 122 is not limited, for example, the first air guide plate 121 is disposed on one side of the second air guide plate 122 close to the air supply main body 21 or the first air guide plate 121 is disposed on one side of the second air guide plate 122 close to the first air guide member 11.

The specific positions where the first surface 12a and the second surface 12b are disposed are not limited, for example, the first surface 12a and the second surface 12b are disposed on the first air deflector 121 and the second air deflector 122, respectively, or the second surface 12b and the first surface 12a are disposed on the first air deflector 121 and the second air deflector 122, respectively.

The specific location where the spoiler structure 123 is disposed is not limited, for example, the spoiler structure 123 is disposed on the second surface 12b or the spoiler structure 123 is disposed on the first surface 12 a.

In some embodiments, referring to fig. 3, 10 and 11, the first air deflector 121 is disposed on a side of the second air deflector 122 near the air supply main body 21. The first surface 12a and the second surface 12b are respectively disposed on the first air deflector 121 and the second air deflector 122. A first diversion channel 21b is formed between the first air deflector 121 and the air supply main body 21, and the first surface 12a can guide the air flow direction so as to change the air supply direction of the first diversion channel 21 b; the second air deflector 122 and the first air guiding component 11 form a second diversion channel 21c therebetween, and the second surface 12b can cooperate with the first air guiding component 11 to guide the airflow in the airflow direction so as to change the air supply direction of the second diversion channel 21c, so that the second air guiding component 12 can layer the airflow blown out from the air supply port 21a to realize the dispersion of the air outlet.

The spoiler structure 123 is disposed on the second surface 12 b. It will be appreciated that the first diversion channel 21b is located above the second diversion channel 21c, and the air supply directions of the two channels are different, but in the specific air supply process, the air supply conditions of the first diversion channel 21b and the second diversion channel 21c can be roughly divided into three modes, namely, the first mode, the first diversion channel 21b and the second diversion channel 21c supply air upwards in the horizontal direction; in the second mode, both the first branch passage 21b and the second branch passage 21c supply air downward in the horizontal direction; in the third mode, the first diversion passage 21b supplies air upward with respect to the horizontal direction and the second diversion passage 21c supplies air downward with respect to the horizontal direction. Thus, when the user needs to control the airflow to the active area of the human body, the first mode or the third mode is generally needed, that is, the airflow needs to be blown downwards relative to the horizontal direction, and for this reason, the turbulence structure 123 is disposed on the second surface 12b, which is beneficial to changing the airflow flowing downwards relative to the horizontal direction into turbulence, so that the airflow can be blown directly onto the human body to improve the surface temperature of the human body and enhance the comfort of the user.

It should be noted that the three modes of dividing the air supply condition of the first diversion channel 21b and the second diversion channel 21c are not limited to this embodiment, but are exemplified for the convenience of understanding by those skilled in the art.

The specific style of the spoiler structure 123 is not limited. In some embodiments, referring to fig. 10 and 11, the turbulence structures 123 are uniformly distributed protrusions and depressions on the second surface 12b of the second air deflector 122, and when the airflow passes through the turbulence structures 123, different directions of the airflow are changed, so that irregular flow directions are generated to form turbulence.

In some embodiments, referring to fig. 10 and 11, the orthographic projection of the first air deflector 121 in the horizontal direction entirely covers the orthographic projection of the second air deflector 122. That is, the length of the first air guide plate 121 in the air blowing direction is not smaller than the length of the second air guide plate 122 in the air blowing direction, and thus the first air guide plate 121 and the second air guide plate 122 can be better accommodated in the air blowing main body 21.

In some embodiments, referring to fig. 10 and 11, the second air guiding component 12 includes an elastic member 124, where the elastic member 124 is deformably connected between the first air guiding plate 121 and the second air guiding plate 122, so as to correspondingly control the opening or closing of the first air guiding plate 121 and the second air guiding plate 122 when the first air guiding component 11 opens or closes the air supplying opening 21 a.

It can be understood that when the first air guiding component 11 closes the air supply opening 21a, the first air guiding plate 121 and the second air guiding plate 122 are extruded by the air supply main body 21 and the first air guiding component 11, so that the elastic piece 124 is compressed, and the first air guiding plate 121 and the second air guiding plate 122 are correspondingly folded; when the first air guiding member 11 opens the air supply opening 21a, the elastic member 124 rebounds to gradually open the first air guiding plate 121 and the second air guiding plate 122, and the first air guiding plate 121 and the second air guiding plate 122 open to form a first preset included angle 12c, and in a state that the first air guiding plate 121 and the second air guiding plate 122 are in the first preset included angle 12c, the elastic member 124 has a supporting force on the first air guiding plate 121 and the second air guiding plate 122 so as to maintain the first preset included angle 12c between the first air guiding plate 121 and the second air guiding plate 122.

In the embodiment in which some of the second air guiding members 12 include the elastic member 124, the elastic member 124 is deformably connected between the first air guiding plate 121 and the second air guiding plate 122, referring to fig. 1 and 2, when the first air guiding plate 121 and the second air guiding plate 122 are folded, a second predetermined included angle 12d is formed between the first air guiding plate 121 and the second air guiding plate 122.

It can be appreciated that when the first air deflector 121 and the second air deflector 122 are folded, the elastic member 124 occupies the space between the first air deflector 121 and the second air deflector 122, and the first air deflector 121 and the second air deflector 122 cannot be completely attached. Therefore, a second preset included angle 12d is formed between the first air deflector 121 and the second air deflector 122, the second preset included angle 12d needs to enable the first air deflector 121 and the second air deflector 122 to be accommodated in the air supply main body 21 when being folded, and the first air guiding component 11 can be covered on the air supply port 21a to seal the air supply port 21 a.

The specific range of the second preset included angle 12d is not limited. In some embodiments, referring to fig. 10 and 11, the second preset included angle 12d has a value not greater than 10 degrees, for example, 10 degrees, 8 degrees, 6 degrees, 4 degrees, and so on.

It should be noted that, the specific value range of the second preset included angle 12d is obtained through experimental tests, and parameters, steps, etc. related to the experimental tests of the specific value range of the second preset included angle 12d are conventional techniques of those skilled in the art, and are not described herein.

In some embodiments, referring to fig. 1, the air guiding structure 100 further includes a driving structure 14, the driving structure 14 includes a rotating member 141 and a telescopic member 142, the telescopic member 142 is sequentially connected to the air supply main body 21, the second air guiding member 12 and the first air guiding member 11 at intervals, and the telescopic member 142 can stretch in an up-down direction, so as to control the opening of the first air guiding member 11 relative to the air supply opening 21a and adjust the inclination angle of the first air guiding member 11, the rotating member 141 is respectively connected to the telescopic rod, the air supply main body 21 and the second air guiding member 12, and the rotating member 141 can adjust the inclination angle of the second air guiding member 12.

The specific style of the telescopic member 142 is not limited. In some embodiments, referring to fig. 1, the telescopic component 142 includes a gear and a rack, the gear is disposed on the air supply main body 21, the rack is provided with the second air guiding component 12 and the first air guiding component 11 at intervals, the rack can be retracted into the air supply main body 21 or be sent out of the air supply main body 21 through rotation of the gear, and the first air guiding component 11 is driven to open and close the air supply port 21a and the second air guiding component 12 is driven to be folded or unfolded.

The specific style of the rotating member 141 is not limited. In some embodiments, referring to fig. 1, the rotating member 141 includes a first rotating rod and a second rotating rod, the first rotating rod is respectively connected to the air supply main body 21 and the second air guiding member 12, the second rotating rod is respectively connected to the first air guiding member 11 and the second air guiding member 12, and the first rotating rod and the second rotating rod are mutually matched to adjust the inclination angle of the second air guiding member 12, so as to change the air supply direction of the first diversion channel 21b and the second diversion channel 21 c.

In some embodiments, referring to fig. 1 and 3, the air guiding structure 100 includes a third air guiding component 13, where the third air guiding component 13 is disposed between the air supplying main body 21 and the first air guiding component 11 and hinged to the air supplying main body 21, and the third air guiding component 13 can rotate relative to the air supplying main body 21 along with the rotation of the first air guiding component 11 to adjust the opening of the air supplying port 21 a.

It can be understood that the third air guiding component 13 has six functions on the air flow flowing out from the air supply port 21a, and the air outlet end of the third air guiding component 13 along the guiding direction is connected with the first air guiding component 11, when the first air guiding component 11 rotates to change the opening degree of the relative air supply port 21a, the third air guiding component 13 can correspondingly rotate to adjust the opening degree of the air supply port 21a, and can be matched with the first air guiding component 11 to change the flowing direction of the air flow.

The specific style of the first air guide member 11 is not limited. In some embodiments, referring to fig. 1 and 3, the first air guiding component 11 is an arc-shaped plate body, and an arc-shaped groove is formed on the arc-shaped plate body, and an extending direction of the arc is consistent with the guiding direction. The arc plate body can be matched with the appearance of the air supply main body 21 so as to improve the attractiveness of the product, and the arc grooves of the arc plate body can realize the guiding of air flow and provide more flexible air supply direction for the air guide structure 100. For example, the arc plate can make the air flow upward relative to the horizontal direction along the air outlet end of the diversion direction, and make the upward air flow intersect and converge with the air flow of the first diversion channel 21b, so as to form a slight up-down oscillation flow effect to form turbulence, and make the air flow softer and more comfortable.

The specific patterns of the first air deflection plates 121 and the second air deflection plates 122 are not limited. In some embodiments, referring to fig. 1 and 3, the first air deflector 121 and the second air deflector 122 are each plate bodies extending along the direction of flow.

The specific style of the third air guide member 13 is not limited. In some embodiments, referring to fig. 1 and 3, the third air guiding component 13 is a plate extending along the guiding direction.

Referring to fig. 1 and 12, a further aspect of the present application provides an air supply control method for an air supply device 200, where the air supply device 200 includes the air guiding structure 100 in the foregoing embodiment, and the control method includes steps S10 and S20.

S10: and acquiring a device starting instruction.

It should be understood that the air supply control method provided in the embodiment of the present application needs to be implemented when the air supply device 200 is in an operating state, that is, the air supply main body 21 of the air supply device 200 starts to generate an air flow with a specific temperature and flows out from the air supply port 21a to improve the state of the external temperature environment. Therefore, the device start command is acquired to determine that the air blowing device 200 is in an operating state, and then the air flow direction flowing out of the air blowing port 21a is changed by the air blowing control method, so as to achieve different effects on the external environment, human body, and the like.

S20: the air guiding structure 100 is controlled to change the air supplying direction of the air supplying device 200 according to the starting instruction, wherein the first air guiding component 11 opens the air supplying opening 21a, and the second air guiding component 12 moves onto the air supplying path of the air supplying opening 21a, so that the air flow blown out from the air supplying opening 21a is split to form at least two layers.

It can be appreciated that, the user can issue different starting instructions according to actual needs to control the air guiding structure 100 to change the air supplying direction of the air supplying device 200, so as to achieve different requirements. For example, the user can control the air guiding structure 100 to make the first diversion channel 21b and the second diversion channel 21c generate different air supply directions, so as to realize the dispersed circulation of air flow, improve the convection heat exchange effect of the room, thereby making the indoor environment temperature change uniformly and improving the comfort of the user; the user can also control the air guide structure 100 to deliver air flow to the human body active area so that the air flow can directly flow through the surface of the human body to achieve the effect of cooling the human body.

In some embodiments, referring to fig. 1 and 13, the step of controlling the wind guiding structure 100 to change the air blowing direction of the air blowing device 200 according to the start command includes steps S30 and S40.

S30: the current operation mode of the air moving device 200 is determined.

S40: the air guiding structure 100 is controlled to be in an air supply state corresponding to the current working mode according to the starting instruction, wherein the first air guiding component 11 rotates to an angle corresponding to the current working mode, and the second air guiding component 12 is synchronously controlled to rotate so as to provide an air supply direction corresponding to the current working mode.

It should be noted that, in the embodiment of the present application, the working mode of the air supply device 200 means that the air supply device 200 is in a working state, and the air guide structure 100 is controlled to adjust the rotation angles of the first air guide component 11 and the second air guide component 12, so that the air supply device 200 has different air supply directions, and correspondingly different functions are implemented. The operation modes of the air blowing device 200 include a cooling mode, a blow-through preventing mode, and a gentle air mode.

Specifically, in the three operation modes of the air supply device 200, the air supply main body 21 can generate low-temperature air flow for reducing the existing ambient temperature, wherein the air guiding structure 100 needs to realize convective heat exchange of the external air in the cooling mode so as to uniformly reduce the external temperature; the air guiding structure 100 in the anti-direct-blowing mode needs to avoid the air flow from directly flowing to the active region of the human body; the wind guiding structure 100 can realize the turbulent flow effect in the gentle wind mode, and send the turbulent flow to the human body activity area, promote user's comfort when realizing better cooling effect.

In some embodiments, referring to fig. 4, 5 and 14, the step of determining the current operation mode of the air supply device 200 includes steps S50 and S60.

S50: the current operation mode of the air blowing device 200 is determined to be the cooling mode.

S60: the air guiding structure 100 is controlled to be in the first air supplying state according to the starting instruction, wherein the first air guiding component 11 is controlled to rotate to the first rotating angle 11a, and the second air guiding component 12 is synchronously controlled to rotate to the first air guiding angle 12e.

In addition, in the cooling mode, the third air guide member 13 is synchronously controlled to rotate to the first air supply angle 13a.

It should be noted that, because the first air guiding member is an arc plate in the foregoing embodiment, the first rotation angle 11a refers to an angle between a line connecting two ends of the first air guiding member along the guiding direction and a horizontal plane; the first air guiding angle 12e is the angle of the first air guiding plate 121 relative to the horizontal plane.

The specific range of the first rotation angle 11a is not limited. In the embodiment of the present application, the value of the first rotation angle 11a is 0 to 20 degrees, for example, 0 degrees, 5 degrees, 10 degrees, 15 degrees, 20 degrees, etc., and preferably, the value of the first rotation angle 11a is 15 degrees.

The specific range of values of the first air guiding angle 12e is not limited. In the embodiment of the present application, the value of the first air guiding angle 12e is between minus 45 degrees and minus 15 degrees, for example, minus 40 degrees, minus 35 degrees, minus 30 degrees, minus 25 degrees, minus 20 degrees, minus 15 degrees, etc., and preferably, the value of the first air guiding angle 12e is between minus 30 degrees.

The specific range of the first air supply angle 13a is not limited. In the embodiment of the present application, the value of the first air supply angle 13a is preferably 5 degrees to 30 degrees, for example, 5 degrees, 10 degrees, 15 degrees, 20 degrees, 25 degrees, 30 degrees, and the like, and the value of the first air supply angle 13a is preferably 15 degrees.

It should be noted that, the specific value range of the first rotation angle 11a, the specific value range of the first air supply angle 13a, and the specific value range of the first air guide angle 12e are obtained through experimental tests, and relevant parameters, steps, and the like related to the experimental tests of the specific value range of the first rotation angle 11a, the specific value range of the first air supply angle 13a, and the specific value range of the first air guide angle 12e are all conventional technologies of those skilled in the art, and are not described herein.

It should be noted that, in the embodiment of the present application, the negative sign in the specific values of the first rotation angle 11a and the first air guiding angle 12e indicates that the connecting line of the two ends of the first air guiding member along the air guiding direction is upward relative to the horizontal plane, and the first air guiding plate 121 is upward relative to the horizontal plane; the positive sign in the specific values of the first rotation angle 11a and the first air guiding angle 12e indicates that the connecting line of the two ends of the first air guiding member along the guiding direction is downward relative to the horizontal plane, and the first air guiding plate 121 is downward relative to the horizontal plane. And the signs in the numerical representations of angles in the following examples are all subject to this meaning.

It can be understood that, in the cooling mode, the air guiding structure 100 is in the first air supplying state, that is, the first air guiding angle 12e is 15 degrees, the first rotating angle 11a is minus 30 degrees, and the first preset included angle 12c is 45 degrees, so that the first air guiding component 11, the third air guiding component 13 and the second air guiding plate 122 supply air downward, and the first air guiding plate 121 supplies air upward.

Specifically, after the air flows out through the air supply port 21a and the third air guiding component 13, the air flow forms air flow diversion at the front edge of the second air guiding component 12, the air flow of the first diversion channel 21b flows upwards along the first air guiding plate 121 to form room air flow circulation, the air flow of the second diversion channel 21c flows downwards along the first air guiding component 11 and the second air guiding plate 122, the angle of the turbulence structure 123 on the second air guiding plate 122 is horizontally downwards, and after the air flow flows through the turbulence structure 123, a small-scale air flow disturbance effect is formed, so that air supply comfort is improved. So, the air current forms double-deck reposition of redundant personnel effect, and the air current efflux of first reposition of redundant personnel passageway 21b encircles, and the air current disturbance of second reposition of redundant personnel passageway 21c blows out, forms better air supply effect, and then can be better adjust external temperature, realizes refrigeration effect sooner.

In other embodiments, referring to fig. 6, 7 and 15, the step of determining the current operation mode of the air supply device 200 includes steps S70 and S80.

S70: the current operation mode of the air blowing device 200 is determined to be the blow-through preventing mode.

S80: the air guiding structure 100 is controlled to be in the second air supplying state according to the starting instruction, wherein the first air guiding component 11 is controlled to rotate to the second rotating angle 11b, and the second air guiding component 12 is synchronously controlled to rotate to the second air guiding angle 12f.

In addition, in the blow-through preventing mode, the third air guide member 13 is synchronously controlled to rotate to the second air supply angle 13b.

The specific range of the second rotation angle 11b is not limited. In the embodiment of the present application, the value of the second rotation angle 11b is between minus 10 degrees and 0 degrees, for example, minus 10 degrees, minus 7 degrees, minus 5 degrees, minus 3 degrees, minus 0 degrees, etc., and preferably, the value of the second rotation angle 11b is minus 5 degrees.

The specific range of the second air guiding angle 12f is not limited. In the embodiment of the present application, the value of the second air guiding angle 12f is preferably between minus 60 degrees and minus 30 degrees, for example, between minus 60 degrees, minus 55 degrees, minus 50 degrees, minus 45 degrees, minus 40 degrees, minus 35 degrees, minus 30 degrees, and the like, and the value of the second air guiding angle 12f is preferably between minus 50 degrees.

The specific range of the second air supply angle 13b is not limited. In the embodiment of the present application, the value of the second air supply angle 13b is 0 degrees.

It should be noted that, the specific value range of the second rotation angle 11b, the specific value range of the second air supply angle 13b, and the specific value range of the second air guide angle 12f are obtained through experimental tests, and relevant parameters, steps, and the like related to the experimental tests of the specific value range of the second rotation angle 11b, the specific value range of the second air supply angle 13b, and the specific value range of the second air guide angle 12f are all conventional technologies of those skilled in the art, and are not described herein.

It can be understood that, in the cooling mode, the air guiding structure 100 is in the first air supplying state, that is, the second air guiding angle 12f is minus 50 degrees, the second rotating angle 11b is minus 5 degrees, and the first preset included angle 12c is 45 degrees, so that the first air guiding component 11, the first air guiding plate 121 and the second air guiding plate 122 all supply air upwards, the third air guiding component 13 does not rotate, and the air guiding direction of the third air guiding component 13 is horizontal.

Specifically, after the air flows out through the air supply port 21a and the third air guiding component 13, the air flow forms air flow split at the front edge of the second air guiding component 12, the air flow of the first split channel 21b flows upwards along the first air guiding plate 121, the air flow of the second split channel 21c flows upwards along the first air guiding component 11 and the second air guiding plate 122, and the two air flows are converged after a certain distance from the tail end of the second air guiding component 12, and a slight up-down oscillation flow effect is formed. At the moment, the air flow is disturbed upwards and blown out, so that the comfortable effect of wind non-direct blowing can be realized, and meanwhile, the convection heat exchange of a room is enhanced through the up-and-down oscillation of the air flow, and the overall comfort level is improved.

In still other embodiments, referring to fig. 8, 9 and 16, the step of determining the current operation mode of the air supply device 200 includes steps S90 and S100.

S90: determining that the current operation mode of the air supply device 200 is a gentle air mode;

s100: the air guiding structure 100 is controlled to be in the third air supplying state according to the starting instruction, wherein the first air guiding component 11 is controlled to rotate to the third rotating angle 11c, and the second air guiding component 12 is synchronously controlled to rotate to the third air guiding angle 12g.

In addition, in the gentle air mode, the third air guide member 13 is synchronously controlled to rotate to the third air supply angle 13c.

The specific range of the third rotation angle 11c is not limited. In the embodiment of the present application, the third rotation angle 11c has a value of 15 degrees to 35 degrees, for example, 15 degrees, 20 degrees, 25 degrees, 30 degrees, 35 degrees, etc., and preferably, the third rotation angle 11c has a value of 25 degrees.

The specific range of the third air guiding angle 12g is not limited. In the embodiment of the present application, the value of the third air guiding angle 12g is preferably from minus 15 degrees to minus 0 degrees, for example, minus 15 degrees, minus 10 degrees, minus 5 degrees, minus 0 degrees, and the like, and the value of the third air guiding angle 12g is preferably from minus 10 degrees.

The specific range of the third air supply angle 13c is not limited. In the embodiment of the present application, the third air supply angle 13c is preferably 15 degrees to 45 degrees, for example, 15 degrees, 20 degrees, 25 degrees, 30 degrees, 35 degrees, 40 degrees, 45 degrees, etc., and the third air guiding angle 12g is preferably 30 degrees.

It should be noted that, the specific value range of the third rotation angle 11c, the specific value range of the third air supply angle 13c, and the specific value range of the third air guide angle 12g are obtained through experimental tests, and parameters and steps related to the experimental tests of the specific value range of the third rotation angle 11c, the specific value range of the third air supply angle 13c, and the specific value range of the third air guide angle 12g are all conventional techniques of those skilled in the art, and are not described herein.

It can be understood that, in the cooling mode, the air guiding structure 100 is in the first air supplying state, that is, the second air guiding angle 12f is 25 degrees, the second rotating angle 11b is minus 10 degrees, and the first preset included angle 12c is 45 degrees, so that the first air guiding component 11, the third air guiding component 13 and the second air guiding plate 122 all supply air downwards, and the first air guiding plate 121 supplies air upwards.

Specifically, after the air flows out through the air supply port 21a and the third air guiding component 13, the air flow forms air flow split at the front edge of the second air guiding component 12, the air flow of the first split flow channel 21b flows upwards along the first air guiding plate 121, the air flow of the second split flow channel 21c flows upwards along the first air guiding component 11 and the second air guiding plate 122, the angle of the turbulence structure 123 on the second air guiding plate 122 is horizontally downward, and after the air flow flows through the turbulence structure 123, a small-scale air flow disturbance effect is formed, so as to improve air supply comfort, and meanwhile, two air flows are converged after a certain distance from the tail end of the second air guiding component 12, and a slight up-down oscillation flow effect is formed. At this time, the air flow flows to the human body active area of the room, and the gentle wind can be realized due to the disturbance effect formed by mixing the two air flows, so that the uncomfortable feeling of jet direct blowing can be prevented while cold air can be sensed.

In some embodiments, referring to fig. 6, 7 and 15, after the air guiding structure 100 is controlled to be in the second air supplying state according to the start command, the air supplying control method further includes steps S110 and S120.

S110: the current indoor temperature is obtained, the current indoor temperature is not less than the first preset temperature, and the air guiding structure 100 is controlled to be in the first air supply state.

It can be appreciated that in the indoor environment of the first preset temperature and in the indoor environment of the temperature greater than the first preset temperature, the human body can generate hotter temperature sensing, i.e. the current indoor temperature is higher, which is not beneficial to the comfort of the user. Therefore, in the anti-direct-blowing mode, after determining that the current indoor temperature is not less than the first preset temperature, the air guiding structure 100 needs to be controlled to be in the first air supply state, so that the air supply device 200 is automatically switched to the cooling mode, so that the indoor temperature is quickly reduced, and the comfort of the user is improved.

The specific range of the first preset temperature is not limited. In the embodiment of the present application, the value of the first preset temperature is not less than 27 degrees, for example, 27 degrees, 28 degrees, 29 degrees, 30 degrees, and the like, and preferably, the value of the first preset temperature is 28 degrees.

It should be noted that, the specific value range of the first preset temperature is obtained through experimental test, and parameters, steps and the like related to the experimental test of the specific value range of the first preset temperature are conventional technologies of those skilled in the art, and are not described herein.

S120: when the air guiding structure 100 is in the first air supply state, the first working time is obtained in real time, and the first working time is determined to be equal to the first preset time, so that the air guiding structure 100 is controlled to be in the second air supply state.

It can be appreciated that the first preset time is to ensure that the air supply device 200 has enough time to cool the indoor environment, adjust the indoor temperature to a more comfortable temperature range, and prevent the air structure from being in the first air supply state for too long, so that the indoor temperature is reduced too much, and discomfort is caused to the human body. Therefore, when it is determined that the first working time is equal to the first preset time, the air guiding structure 100 needs to be controlled to return to the second air supply state, so that a comfortable effect of air non-direct blowing is achieved, and meanwhile, convection heat exchange of a room is enhanced through up-and-down oscillation of air flow, so that overall comfort is improved.

The specific value range of the first preset time is not limited. In the embodiment of the present application, the value of the first preset time is not less than 10 minutes, for example, 10 minutes, 12 minutes, 14 minutes, 16 minutes, and the like, and preferably, the value of the first preset time is 10 minutes.

It should be noted that, the specific value range of the first preset time is obtained through experimental test, and parameters, steps and the like related to the experimental test of the specific value range of the first preset time are conventional technologies of those skilled in the art, and are not described herein.

In some embodiments, after controlling the air guiding structure 100 to be in the second air supplying state according to the start command, the air supplying control method further includes:

the current indoor temperature is obtained, and it is determined that the current indoor temperature is less than the first preset temperature, and the air guiding structure 100 is continuously controlled to be in the second air supplying state.

It can be appreciated that in an indoor environment with a temperature less than the first preset temperature, the user can have a more comfortable ambient temperature without additional cooling, so that the anti-direct-blowing mode of the air supply device 100 can be maintained to meet the needs of the user.

In some embodiments, referring to fig. 8, 9 and 16, according to the start command, the air guiding structure 100 is controlled to be in the third air supplying state, and the air supplying control method further includes step S130.

S130: the current indoor temperature is obtained, the current indoor temperature is determined to be not greater than the second preset temperature, and the air guide structure 100 is controlled to be in the second air supply state.

It can be appreciated that in the indoor environment of the second preset temperature and in the indoor environment of less than the second preset temperature, the human body can generate cooler temperature sensing, that is, the current indoor temperature is lower, which is not beneficial to the comfort of the user. Therefore, in the gentle mode, after determining that the current indoor temperature is not greater than the second preset temperature, the air guiding structure 100 needs to be controlled to be in the second air supply state, so as to automatically switch the air supply device 200 into the direct air blowing preventing mode, so that the air flow with too low temperature is prevented from directly flowing to the active area of the human body or even being blown onto the human body, and the comfort of the user is improved.

The specific value range of the second preset temperature is not limited. In the embodiment of the present application, the value of the first preset temperature is not greater than 25 degrees, for example, 25 degrees, 24 degrees, 23 degrees, 22 degrees, etc., and preferably, the value of the second preset temperature is 25 degrees.

It should be noted that, the specific value range of the second preset temperature is obtained through experimental test, and parameters, steps and the like related to the experimental test of the specific value range of the second preset temperature are conventional technologies of those skilled in the art, and are not described herein.

In some embodiments, according to the start instruction, the air guiding structure 100 is controlled to be in the third air supply state, and the air supply control method further includes:

the current indoor temperature is obtained, and it is determined that the current indoor temperature is greater than the second preset temperature, and the air guiding structure 100 is continuously controlled to be in the third air supplying state.

It is appreciated that in an indoor environment less than the second preset temperature, the user can have a more comfortable ambient temperature, so that the gentle air mode of the air supply device 100 can be maintained to meet the user's requirement.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above examples illustrate only a few embodiments of the application, which are described in detail and are not to be construed as limiting the scope of the claims. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the application, which are all within the scope of the application. Accordingly, the scope of protection of the present application is to be determined by the appended claims.

Claims (14)

1. An air guiding structure (100) mounted at an air supply port (21 a) of an air supply main body (21), characterized in that the air guiding structure (100) comprises:

the first air guide component (11) is rotatably connected to the air supply main body (21) in a matching way so as to open and close the air supply port (21 a); a kind of electronic device with high-pressure air-conditioning system

A second air guide member (12) coupled between the air supply main body (21) and the first air guide member (11);

wherein the second air guide member (12) is disposed between the first air guide member (11) and the air supply main body (21) in a folded state when the first air guide member (11) closes the air supply port (21 a);

and the second air guide component (12) moves to an air supply path of the air supply port (21 a) along with the first air guide component (11) when the first air guide component (11) opens the air supply port (21 a), and divides the air flow blown out from the air supply port (21 a) into at least two layers.

2. The air guiding structure (100) according to claim 1, wherein the second air guiding member (12) has a first surface (12 a) facing the air supply main body (21) and a second surface (12 b) facing the first air guiding member (11), a first diversion channel (21 b) is configured between the first surface (12 a) and the air supply main body (21), and a second diversion channel (21 c) is configured between the second surface (12 b) and the first air guiding member (11);

the air supply directions of the first diversion channel (21 b) and the second diversion channel (21 c) are variably set according to the opening degree of the first air guide component (11) relative to the air supply opening (21 a).

3. The air guiding structure (100) according to claim 2, wherein a spoiler structure (123) is provided on either of the first surface (12 a) and the second surface (12 b).

4. The air guiding structure (100) according to claim 1, wherein the second air guiding component (12) comprises a first air guiding plate (121) and a second air guiding plate (122), the first air guiding plate (121) and one end of the second air guiding plate (122) are hinged with each other and rotatably arranged, and the first air guiding plate and the second air guiding plate can be folded when the first air guiding component (11) closes the air supplying opening (21 a) or can be unfolded on an air supplying path of the air supplying opening (21 a) to form a first preset included angle (12 c) when the first air guiding component (11) opens the air supplying opening (21 a).

5. The air guiding structure (100) according to claim 4, wherein the orthographic projection of the first air guiding plate (121) in the horizontal direction entirely covers the orthographic projection of the second air guiding plate (122).

6. The air guiding structure (100) according to claim 4, wherein the second air guiding component (12) comprises an elastic piece (124), and the elastic piece (124) is connected between the first air guiding plate (121) and the second air guiding plate (122) in a deformable manner, so as to correspondingly control the first air guiding plate (121) and the second air guiding plate (122) to open or close when the first air guiding component (11) opens or closes the air supplying port (21 a).

7. The air guiding structure (100) according to claim 1, wherein the air guiding structure (100) further comprises a driving structure (14), the driving structure (14) comprises a rotating component (141) and a telescopic component (142), the telescopic component (142) is sequentially connected with the air supply main body (21), the second air guiding component (12) and the first air guiding component (11) at intervals, and the telescopic component (142) can stretch along the up-down direction so as to control the opening degree of the first air guiding component (11) relative to the air supply port (21 a) and adjust the inclination angle of the first air guiding component (11), the rotating component (141) is respectively connected with the telescopic rod and the second air guiding component (12), and the rotating component (141) can adjust the inclination angle of the second air guiding component (12).

8. The air guiding structure (100) according to claim 1, wherein the air guiding structure (100) comprises a third air guiding component (13), the third air guiding component (13) is disposed between the air supply main body (21) and the first air guiding component (11) and hinged to the air supply main body (21), and the third air guiding component (13) can rotate relative to the air supply main body (21) along with the rotation of the first air guiding component (11) so as to adjust the opening degree of the air supply opening (21 a).

9. An air supply device (200), wherein the air supply device (200) comprises an air supply main body (21) with an air supply port (21 a) and an air guide structure (100) arranged at the air supply port (21 a); wherein the air guiding structure (100) is an air guiding structure (100) according to any one of the preceding claims 1-8.

10. A method of controlling air supply for an air supply device (200), wherein the air supply device (200) comprises an air guiding structure (100) according to any one of claims 1-8, the method comprising:

acquiring a device starting instruction;

and controlling the air guide structure (100) to change the air supply direction of the air supply device (200) according to the starting instruction, wherein the first air guide component (11) opens the air supply port (21 a), and the second air guide component (12) moves to an air supply path of the air supply port (21 a) so as to split the air flow blown out from the air supply port (21 a) into at least two layers.

11. The air supply control method according to claim 10, wherein the step of controlling the air guide structure (100) to change the air supply direction of the air supply device (200) according to the start instruction includes:

determining a current operating mode of the air moving device (200);

and controlling the air guide structure (100) to be in an air supply state corresponding to the current working mode according to the starting instruction, wherein the first air guide component (11) rotates to an angle corresponding to the current working mode, and synchronously controlling the second air guide component (12) to rotate so as to provide an air supply direction corresponding to the current working mode.

12. The air supply control method according to claim 11, wherein the step of determining the current operation mode of the air supply device (200) includes:

determining that a current working mode of the air supply device (200) is a cooling mode;

controlling the air guide structure (100) to be in a first air supply state according to the starting instruction, wherein the first air guide component (11) is controlled to rotate to a first rotating angle (11 a), and the second air guide component (12) is synchronously controlled to rotate to a first air guide angle (12 e); or (b)

Determining that the current working mode of the air supply equipment (200) is a direct blowing prevention mode;

Controlling the air guide structure (100) to be in a second air supply state according to the starting instruction, wherein the first air guide component (11) is controlled to rotate to a second rotation angle (11 b), and the second air guide component (12) is synchronously controlled to rotate to a second air guide angle (12 f); or (b)

Determining that the current working mode of the air supply equipment (200) is a gentle air mode;

and controlling the air guide structure (100) to be in a third air supply state according to the starting instruction, wherein the first air guide component (11) is controlled to rotate to a third rotation angle (11 c), and the second air guide component (12) is synchronously controlled to rotate to a third air guide angle (12 g).

13. The air blowing control method according to claim 12, wherein after said controlling said air guiding structure (100) in the second air blowing state according to said start instruction, said air blowing control method further comprises:

acquiring the current indoor temperature, determining that the current indoor temperature is not less than a first preset temperature, and controlling the air guide structure (100) to be in a first air supply state;

when the air guide structure (100) is in a first air supply state, acquiring first working time in real time, determining that the first working time is equal to first preset time, and controlling the air guide structure (100) to be in a second air supply state.

14. The air blowing control method according to claim 12, wherein the air guiding structure (100) is controlled to be in a third air blowing state according to the start instruction, the air blowing control method further comprising:

and acquiring the current indoor temperature, determining that the current indoor temperature is not greater than a second preset temperature, and controlling the air guide structure (100) to be in a first air supply state.