CN115614981A - Air outlet assembly, control method thereof and air conditioner - Google Patents

Abstract

The invention relates to an air outlet assembly, a control method thereof and an air conditioner, relates to the technical field of air treatment equipment, and is used for solving the problems of complex structure and high manufacturing cost of the air conditioner. The air outlet assembly comprises an air outlet frame; a first air guide mechanism; and the second air guide mechanism. Under the condition of using a single fan blade, the same surrounding air supply effect is achieved by switching the states of the first air guide mechanism and the second air guide mechanism under the condition of reducing the structural complexity of the air conditioner, multiple air supply modes such as subarea air supply can be achieved, the requirements of different users and different use scenes are met, and the user experience is improved.

Description

Air outlet assembly, control method thereof and air conditioner

Technical Field

The invention relates to the technical field of air treatment equipment, in particular to an air outlet assembly, a control method of the air outlet assembly and an air conditioner.

Background

At present, in order to realize left-right distributed air supply of the existing air conditioner, two air outlets are usually arranged and distributed on two sides of the air conditioner. However, two motors and fan blades need to be arranged in a matched manner at the two air outlets, the using amount of other matched parts is doubled, the internal structure becomes complex relatively, and the problems of complex structure and high manufacturing cost of the air conditioner are caused.

Disclosure of Invention

The invention provides an air outlet assembly, a control method thereof and an air conditioner, which are used for solving the problems of complex structure and high manufacturing cost of the air conditioner.

The invention provides an air outlet assembly, comprising:

the air outlet frame is provided with an upper section air outlet and a lower section air outlet;

the first air guide mechanism is rotatably arranged at the upper-section air outlet and has a first state of closing the upper-section air outlet and a second state of opening the upper-section air outlet;

the second air guiding mechanism is rotatably arranged at the lower section air outlet and has a third state for closing the lower section air outlet and a fourth state for opening the lower section air outlet.

In one embodiment, the air outlet assembly further includes a third air guiding mechanism, and the third air guiding mechanism is disposed on the air outlet frame, and the airflow passing through the third air guiding mechanism enters the upper air outlet and/or the lower air outlet.

In one embodiment, the third air guiding mechanism has an upper air guiding state and a lower air guiding state, and when the third air guiding mechanism is in the upper air guiding state, the air flow passing through the third air guiding mechanism flows to the upper air outlet, and when the third air guiding mechanism is in the lower air guiding state, the air flow passing through the third air guiding mechanism flows to the lower air outlet.

In one embodiment, the first wind guiding mechanism includes at least one first wind guiding plate, the second wind guiding mechanism includes at least one second wind guiding plate, and the first wind guiding plate and the second wind guiding plate rotate relatively and independently.

In one embodiment, the first air guiding mechanism includes a first driving mechanism, the first air guiding plate is connected to the first driving mechanism, the second air guiding mechanism includes a second driving mechanism, the second air guiding plate is connected to the second driving mechanism, and the first driving mechanism and the second driving mechanism work independently.

In one embodiment, the air outlet assembly further includes a middle support frame, the first air guiding plate has a first rotating shaft, the second air guiding plate has a second rotating shaft, the first driving mechanism is connected to an upper end of the first rotating shaft, a lower end of the first rotating shaft is rotatably disposed on the middle support frame, the second driving mechanism is connected to a lower end of the second rotating shaft, and an upper end of the second rotating shaft is rotatably disposed on the middle support frame.

In one embodiment, the third air guiding mechanism includes a plurality of wind sweeping blades, the wind sweeping blades are rotatably connected to the wind outlet frame, and all the wind sweeping blades are arranged in parallel along a direction from the upper segment of the wind outlet to the lower segment of the wind outlet.

In one embodiment, the third air guiding mechanism further includes a wind sweeping connecting rod, all the wind sweeping blades are connected to the wind sweeping connecting rod, and the wind sweeping blades are driven by the wind sweeping connecting rod to move.

In one embodiment, the air outlet assembly further includes a door structure movably disposed on the air outlet frame, and the door structure has a closed state for shielding the upper air outlet and the lower air outlet and an open state for avoiding the upper air outlet and the lower air outlet.

In one embodiment, the door panel structure comprises a closing plate and a mounting rack, the mounting rack is arranged on the air outlet frame, and the closing plate is movably arranged on the mounting rack.

In one embodiment, a first guide matching part is arranged on the mounting frame, a second guide matching part is arranged on the closing plate, and the first guide matching part is matched with the second guide matching part.

The control method of the air outlet assembly comprises the following steps:

when the air outlet assembly is switched to the surrounding air supply mode, the first air guide mechanism is switched to the second state, the second air guide mechanism is switched to the fourth state, and the rotating direction of the first air guide mechanism is opposite to that of the second air guide mechanism.

In one embodiment, the air outlet assembly has a synchronous air supply mode:

when the air outlet assembly is switched to the synchronous air supply mode, the first air guide mechanism is switched to the second state, the second air guide mechanism is switched to the fourth state, and the rotating direction of the first air guide mechanism is the same as that of the second air guide mechanism.

In one embodiment, the first air guiding mechanism includes a first air guiding plate, the second air guiding mechanism includes a second air guiding plate, and when the air outlet assembly is in the synchronous air supply mode, the first air guiding plate and the second air guiding plate are in the same plane.

In one embodiment, the air outlet assembly has a set plane, and when the air outlet assembly is switched to the synchronous air supply mode, the first air guide mechanism and the second air guide mechanism rotate synchronously when both the first air guide plate and the second air guide plate reach the set plane.

In one embodiment, the air outlet assembly has an upper air outlet mode:

when the air outlet assembly is switched to the upper air outlet mode, the first air guide mechanism is switched to the second state, the second air guide mechanism is switched to the third state, and the first air guide mechanism performs directional air outlet or air sweeping.

In one embodiment, the air outlet assembly further includes a third air guiding mechanism, the third air guiding mechanism has an upper air guiding state, and when the third air guiding mechanism is in the upper air guiding state, the air flow passing through the third air guiding mechanism flows to the upper air outlet;

when the air outlet assembly is switched to the upper air outlet mode, the third air guide mechanism is switched to an upper air guide state.

In one embodiment, the air outlet assembly has a lower air outlet mode;

when the air outlet assembly is switched to the lower air outlet mode, the first air guide mechanism is switched to the first state, the second air guide mechanism is switched to the fourth state, and the second air guide mechanism carries out directional air outlet or air sweeping.

In one embodiment, the air outlet assembly further includes a third air guiding mechanism, the third air guiding mechanism has a downward air guiding state, and when the third air guiding mechanism is in the downward air guiding state, the air flow passing through the third air guiding mechanism flows to the lower air outlet;

when the air outlet assembly is switched to the lower air outlet mode, the third air guide mechanism is switched to a lower air guide state.

In one embodiment, the air outlet assembly has an upper air outlet mode:

when the air outlet assembly is switched to the upside air outlet mode, the first air guide mechanism is in the second state, the second air guide mechanism is in the fourth state, the air outlet of the first air guide mechanism faces one side of the air outlet frame, and the second air guide mechanism conducts directional air outlet or air sweeping.

In one embodiment, the air outlet assembly has a lower air outlet mode:

when the air outlet assembly is switched to the lower side air outlet mode, the first air guide mechanism is in the second state, the second air guide mechanism is in the fourth state, air outlet of the second air guide mechanism faces one side of the air outlet frame, and the first air guide mechanism conducts directional air outlet or air sweeping.

An air conditioner comprises the air outlet assembly or a control method applying the air outlet assembly.

Compared with the prior art, the air conditioner has the advantages that under the condition of using a single fan blade, the same surrounding air supply effect is realized under the condition of reducing the structural complexity of the air conditioner by using the state switching of the first air guide mechanism and the second air guide mechanism, various air supply modes such as subarea air supply and the like can be realized, the requirements of different users and different use scenes are met, and the user experience is increased.

Drawings

The invention will be described in more detail hereinafter on the basis of embodiments and with reference to the accompanying drawings.

Fig. 1 is an exploded view of an air outlet assembly according to an embodiment of the present invention;

fig. 2 is an exploded view of the first air guide mechanism and the second air guide mechanism in the embodiment of the present invention;

fig. 3 is a sectional view of the first air guide mechanism and the second air guide mechanism in the embodiment of the present invention;

FIG. 4 is a schematic view of a portion of FIG. 3 at A;

fig. 5 is a schematic structural view of a third wind guiding mechanism according to an embodiment of the present invention;

FIG. 6 is a schematic structural view of a door body structure according to an embodiment of the present invention;

FIG. 7 is an end schematic view of a door body structure according to an embodiment of the present invention;

fig. 8 is a schematic structural view of the air outlet assembly in the circular air supply mode according to the embodiment of the present invention;

fig. 9 is a schematic structural view of the air outlet assembly in the upper air outlet mode according to the embodiment of the present invention;

fig. 10 is a schematic structural view of the air outlet assembly in the lower air outlet mode according to the embodiment of the present invention;

reference numerals:

1. an air outlet frame; 11. an upper section air outlet; 12. a lower air outlet; 2. a first air guide mechanism; 3. a second wind guide mechanism; 4. a third air guide mechanism; 21. a first air deflector; 31. a second air deflector; 5. a middle support frame; 41. a wind sweeping blade; 61. a closing plate; 62. and (7) mounting frames.

Detailed Description

The invention will be further explained with reference to the drawings.

As shown in fig. 1 to 10, the present invention provides an air outlet assembly, including: the air outlet frame 1 is provided with an upper section air outlet 11 and a lower section air outlet 12; the first air guiding mechanism 2 is rotatably arranged at the upper section air outlet 11, and the first air guiding mechanism 2 has a first state of closing the upper section air outlet 11 and a second state of opening the upper section air outlet 11; and a second air guiding mechanism 3, wherein the second air guiding mechanism 3 is rotatably disposed at the lower air outlet 12, and the second air guiding mechanism 3 has a third state of closing the lower air outlet 12 and a fourth state of opening the lower air outlet 12. Under the condition of using single fan blade, utilize first wind guiding mechanism 2 and second wind guiding mechanism 3's state to switch, realize the same effect of encircleing the air supply under the condition that reduces air conditioner structure complexity, can also realize multiple air supply modes such as subregion air supply, satisfy the demand of different user demands and different use scenes, increase user experience.

When the air-out device is used, the states of the first air guide mechanism 2 and the second air guide mechanism can be respectively controlled according to user requirements and/or scene requirements to realize modes of independent air-out of the upper section air outlet 11, independent air-out of the lower section air outlet 12, synchronous air sweeping, asynchronous air sweeping, side-to-side air-out of the upper section air outlet 11 or side-to-side air-out of the lower section air outlet 12, so that various air-out effects are realized.

Optionally, the air outlet assembly further includes a third air guiding mechanism 4, the third air guiding mechanism 4 is disposed on the air outlet frame 1, and an air flow passing through the third air guiding mechanism 4 enters the upper air outlet 11 and/or the lower air outlet 12. The third air guide mechanism 4 is used for guiding the air flow in the vertical direction, and the air outlet assembly is enabled to realize more air outlet modes under the condition of being matched with the first air guide mechanism 2 and the second air guide mechanism. Meanwhile, when only the upper air outlet 11 is selected for air supply, the third air guiding mechanism 4 can be used for guiding the air flow to the upper air outlet 11 as much as possible, so that the internal turbulence of the air outlet assembly caused by the fact that the rear part of the air flow cannot pass through the air outlet assembly when the lower air outlet 12 is closed is avoided, the air supply quantity and the air supply speed of the upper air outlet 11 can also be improved, and the air outlet effect of the air outlet assembly is improved.

Specifically, the third air guiding mechanism 4 has an upper air guiding state and a lower air guiding state, and when the third air guiding mechanism 4 is in the upper air guiding state, the air flow passing through the third air guiding mechanism 4 flows to the upper air outlet 11, and when the third air guiding mechanism 4 is in the lower air guiding state, the air flow passing through the third air guiding mechanism 4 flows to the lower air outlet 12. The third air guide mechanism 4 can be switched between an upper air guide state and a lower air guide state as needed.

The third air guiding mechanism 4 can be freely switched between an upper air guiding state and a lower air guiding state to sweep air up and down.

In one embodiment, the first air guiding mechanism 2 includes at least one first air guiding plate 21, the second air guiding mechanism includes at least one second air guiding plate 31, and the first air guiding plate 21 and the second air guiding plate 31 rotate relatively independently. That is, the air outlet direction of the first air guiding mechanism 2 and the air outlet direction of the second air guiding mechanism can be independently adjusted, so that the air supply direction of the upper section air outlet 11 and the air supply direction of the lower section air outlet 12 can be respectively controlled, and various air supply effects can be realized.

The number of the first air deflectors 21 is multiple, all the first air deflectors 21 are arranged in parallel along the width direction of the upper section air outlet 11, and when the first air guiding mechanism 2 is in the first state, all the first air deflectors 21 are matched to seal the upper section air outlet 11.

The number of the second air guiding plates 31 is plural, all the second air guiding plates 31 are arranged in parallel along the width direction of the lower air outlet 12, and when the second air guiding mechanism is in the third state, all the second air guiding plates 31 cooperate to close the lower air outlet 12.

In one embodiment, the first wind guiding mechanism 2 includes a first driving mechanism, the first wind guiding plate 21 is connected to the first driving mechanism, the second wind guiding mechanism includes a second driving mechanism, the second wind guiding plate 31 is connected to the second driving mechanism, and the first driving mechanism and the second driving mechanism work independently.

In one embodiment, the air outlet assembly further includes a middle support frame 5, the first air guiding plate 21 has a first rotating shaft, the second air guiding plate 31 has a second rotating shaft, the first driving mechanism is connected to an upper end of the first rotating shaft, a lower end of the first rotating shaft is rotatably disposed on the middle support frame 5, the second driving mechanism is connected to a lower end of the second rotating shaft, and an upper end of the second rotating shaft is rotatably disposed on the middle support frame 5. The middle support frame 5 is used for limiting and fixing the first air deflector 21 and the second air deflector 31, and the first air deflector 21 and the second air deflector 31 are guaranteed to rotate reliably.

Preferably, the first air guiding mechanism 2 further includes a first support frame, all the first air guiding plates 21 are connected to the first support frame, and the first driving mechanism drives one of the first air guiding plates 21 to rotate and simultaneously drives the first support frame to rotate, so as to drive the other first air guiding plates 21 to rotate, thereby realizing synchronous rotation of all the first air guiding plates 21.

The second air guiding mechanism further comprises a second supporting frame, all the second air guiding plates 31 are connected to the second supporting frame, the second driving mechanism drives one of the second air guiding plates 31 to rotate, meanwhile, the second supporting frame is driven to rotate, and then other second air guiding plates 31 are driven to rotate, so that synchronous rotation of all the second air guiding plates 31 is achieved.

In one embodiment, the third air guiding mechanism 4 includes a plurality of wind sweeping blades 41, the wind sweeping blades 41 are rotatably connected to the air outlet frame 1, and all the wind sweeping blades 41 are arranged in parallel along a direction from the upper air outlet 11 to the lower air outlet 12. The airflow passing through the third air guiding mechanism 4 can flow to the upper air outlet 11 or the lower air outlet 12 by the guiding action of the air sweeping blades 41.

In order to ensure that all the wind sweeping blades 41 move synchronously, the third wind guiding mechanism 4 further includes a wind sweeping connecting rod, all the wind sweeping blades 41 are connected to the wind sweeping connecting rod, and the wind sweeping blades 41 are driven by the wind sweeping connecting rod to move.

The third air guiding mechanism 4 further includes a third driving mechanism, and the third driving mechanism can drive all the wind sweeping blades 41 to move through the wind sweeping connecting rod.

In one embodiment, the air outlet assembly further includes a door panel structure, the door panel structure is movably disposed on the air outlet frame 1, and the door panel structure has a closed state covering the upper air outlet 11 and the lower air outlet 12 and an open state avoiding the upper air outlet 11 and the lower air outlet 12. Utilize the door plant structure to shelter from upper segment air outlet 11 and hypomere air outlet 12 to the outward appearance that makes the air-out subassembly is more pleasing to the eye, improves the wholeness of air-out subassembly.

In one embodiment, the door panel structure includes a closing plate 61 and a mounting frame 62, the mounting frame 62 is disposed on the air outlet frame 1, and the closing plate 61 is movably disposed on the mounting frame 62. The closing plate 61 is moved to open and close the upper-stage air outlet 11 and the lower-stage air outlet 12, and when air supply is needed, the closing plate 61 opens the upper-stage air outlet 11 and the lower-stage air outlet 12 to supply air.

Preferably, the air-out subassembly still includes the casing, air-out frame 1 sets up in the casing, be formed with the supply-air outlet on the casing, upper segment air outlet 11 and hypomere air outlet 12 all are located supply-air outlet department, just the closing plate 61 can shelter from the supply-air outlet in order to shelter from upper segment air outlet 11 and hypomere air outlet 12, and the purpose that the supply-air outlet carries out the air supply is realized opening to one side that the closing plate 61 also can move inside the casing, air-out frame 1 simultaneously.

In one embodiment, the mounting bracket 62 is provided with a first guide engagement portion, and the closing plate 61 is provided with a second guide engagement portion, the first guide engagement portion engaging with the second guide engagement portion. The closing plate 61 can move according to a set path by the guiding cooperation of the first guiding cooperation part and the second guiding cooperation part, and the movement reliability of the closing plate 61 is ensured.

Specifically, first guide part includes the guide way, and second direction cooperation portion includes the slider, and the slider movably sets up in the guide way.

In one embodiment, the closing plate 61 has an arc-shaped cross section, the guide groove has an arc shape parallel to the arc shape of the closing plate 61, and the closing plate 61 moves along the arc shape.

The door body structure still includes mounting bracket and lower mounting bracket, it sets up in being located to go up the mounting bracket 11 top go out on the air-out frame 1, the mounting bracket sets up in being located the below of hypomere air outlet 12 go out on the air-out frame 1, the upper end of closing plate 61 movably connect in go up on the mounting bracket, the lower extreme of closing plate 61 movably connect in down on the mounting bracket.

As shown in fig. 8, the present invention further provides a control method of the air outlet assembly, where the air outlet assembly has a circular air supply mode:

when the air outlet assembly is switched to the surrounding air supply mode, the first air guide mechanism is switched to the second state, the second air guide mechanism is switched to the fourth state, and the rotating direction of the first air guide mechanism is opposite to that of the second air guide mechanism. That is, the air outlet direction of the upper section air outlet 11 is opposite to the air outlet direction of the lower section air outlet 12, so that air can be supplied from two sides at the same time, air circulation is realized, and arm-held air supply is realized.

In one embodiment, the air outlet assembly has a synchronous air supply mode:

when the air outlet assembly is switched to the synchronous air supply mode, the first air guide mechanism is switched to the second state, the second air guide mechanism is switched to the fourth state, and the rotating direction of the first air guide mechanism is the same as that of the second air guide mechanism. When a user needs to perform synchronous air sweeping, the guide direction of the first air guide mechanism and the guide direction of the second air guide mechanism can be kept the same, so that synchronous air supply is realized. That is, at this time, the first air guiding mechanism includes a first air guiding plate 21, the second air guiding mechanism includes a second air guiding plate 31, and when the air outlet assembly is in the synchronous air supply mode, the first air guiding plate 21 and the second air guiding plate 31 are in the same plane.

When the guiding direction of a first air guiding mechanism in the air outlet assembly is different from the guiding direction of a second air guiding mechanism, the air outlet assembly is provided with a set plane in order to realize that the air outlet assembly is switched to a synchronous air supply mode, and when the air outlet assembly is switched to the synchronous air supply mode, when the first air deflector 21 and the second air deflector 31 both reach the set plane, the first air guiding mechanism and the second air guiding mechanism synchronously rotate. Preferably, the setting plane is a plane of a central position in a range in which the first air deflector 21 can swing.

In one embodiment, as shown in fig. 9, the air outlet assembly has an upper air outlet mode:

when the air outlet assembly is switched to the upper air outlet mode, the first air guide mechanism 2 is switched to the second state, the second air guide mechanism is switched to the third state, and the first air guide mechanism 2 performs directional air outlet or air sweeping. Only adopt upper segment air outlet 11 to carry out the air-out this moment, hypomere air outlet 12 is in the enclosed condition, and the air current through the air-out subassembly all flows out through upper segment air outlet 11.

In order to avoid the generation of turbulence in the air outlet assembly, the air outlet assembly further comprises a third air guiding mechanism 4, the third air guiding mechanism 4 has an upper air guiding state, and when the third air guiding mechanism 4 is in the upper air guiding state, the air flow passing through the third air guiding mechanism 4 flows to the upper air outlet 11;

when the air outlet assembly is switched to the upper air outlet mode, the third air guide mechanism 4 is switched to an upper air guide state. The third air guiding mechanism 4 is used for guiding the air flow passing through the air outlet assembly to the upper air outlet 11, so that the air outlet effect of the air outlet assembly is improved.

In one embodiment, as shown in fig. 10, the air outlet assembly has a lower air outlet mode;

when the air outlet assembly is switched to the lower air outlet mode, the first air guide mechanism 2 is switched to the first state, the second air guide mechanism is switched to the fourth state, and the second air guide mechanism performs directional air outlet or air sweeping. At this time, only the lower air outlet 12 is used for air outlet, the upper air outlet 11 is in a closed state, and the air flow passing through the air outlet assembly flows out through the lower air outlet 12.

In order to avoid turbulence generated in the air outlet assembly, the air outlet assembly further includes a third air guiding mechanism 4, the third air guiding mechanism 4 has a downward air guiding state, and when the third air guiding mechanism 4 is in the downward air guiding state, the air flow passing through the third air guiding mechanism 4 flows to the lower air outlet 12;

when the air outlet assembly is switched to the lower air outlet mode, the third air guide mechanism 4 is switched to a lower air guide state. The third wind guiding mechanism 4 is used for guiding the air flow passing through the air outlet assembly to the lower section air outlet 12, so that the air outlet effect of the air outlet assembly is improved.

When the user does not need upper portion to openly go out the wind, the air-out subassembly has upside air-out mode:

when the air outlet assembly is switched to the upside air outlet mode, the first air guide mechanism 2 is in the second state, the second air guide mechanism is in the fourth state, the air outlet direction of the first air guide mechanism 2 faces one side of the air outlet frame 1, and the second air guide mechanism performs directional air outlet or air sweeping. At this time, the air outlet direction of the first air guiding mechanism 2 faces one side of the air outlet frame 1, so that the upper air outlet 11 performs lateral air outlet, and the lower air outlet 12 can perform air sweeping or directional air outlet as required.

When the user does not need the lower part to openly go out wind, the air-out subassembly has downside air-out mode:

when the air outlet assembly is switched to the lower side air outlet mode, the first air guide mechanism 2 is in the second state, the second air guide mechanism is in the fourth state, air outlet of the second air guide mechanism faces one side of the air outlet frame 1, and the first air guide mechanism 2 conducts directional air outlet or air sweeping. At this time, the air outlet direction of the second air guiding mechanism faces one side of the air outlet frame 1, so that the lower air outlet 12 performs lateral air outlet, and the upper air outlet 11 can perform air sweeping or directional air outlet as required.

An air conditioner comprises the air outlet assembly or a control method applying the air outlet assembly.

While the invention has been described with reference to a preferred embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, the technical features mentioned in the embodiments can be combined in any way as long as there is no structural conflict. It is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims (22)

1. The utility model provides an air-out subassembly which characterized in that includes:

the air outlet frame is provided with an upper section air outlet and a lower section air outlet;

the first air guide mechanism is rotatably arranged at the upper section air outlet and has a first state for closing the upper section air outlet and a second state for opening the upper section air outlet;

the second air guiding mechanism is rotatably arranged at the lower section air outlet and has a third state for closing the lower section air outlet and a fourth state for opening the lower section air outlet.

2. The air outlet assembly of claim 1, further comprising a third air guiding mechanism, wherein the third air guiding mechanism is disposed on the air outlet frame, and an air flow passing through the third air guiding mechanism enters the upper air outlet and/or the lower air outlet.

3. The air outlet assembly according to claim 2, wherein the third air guiding mechanism has an upper air guiding state and a lower air guiding state, and when the third air guiding mechanism is in the upper air guiding state, the air flow passing through the third air guiding mechanism flows toward the upper air outlet, and when the third air guiding mechanism is in the lower air guiding state, the air flow passing through the third air guiding mechanism flows toward the lower air outlet.

4. The air outlet assembly of any one of claims 1 to 3, wherein the first air guiding mechanism includes at least one first air guiding plate, the second air guiding mechanism includes at least one second air guiding plate, and the first air guiding plate and the second air guiding plate rotate relatively independently.

5. The air outlet assembly according to claim 4, wherein the first air guiding mechanism includes a first driving mechanism, the first air guiding plate is connected to the first driving mechanism, the second air guiding mechanism includes a second driving mechanism, the second air guiding plate is connected to the second driving mechanism, and the first driving mechanism and the second driving mechanism operate independently.

6. The air outlet assembly of claim 5, further comprising a middle support frame, wherein the first air guiding plate has a first rotating shaft, the second air guiding plate has a second rotating shaft, the first driving mechanism is connected to an upper end of the first rotating shaft, a lower end of the first rotating shaft is rotatably disposed on the middle support frame, the second driving mechanism is connected to a lower end of the second rotating shaft, and an upper end of the second rotating shaft is rotatably disposed on the middle support frame.

7. The air outlet assembly of claim 2 or 3, wherein the third air guiding mechanism includes a plurality of air sweeping blades, the air sweeping blades are rotatably connected to the air outlet frame, and all the air sweeping blades are arranged in parallel along a direction from the upper air outlet to the lower air outlet.

8. The air outlet assembly of claim 7, wherein the third air guiding mechanism further comprises a sweeping connecting rod, all the sweeping blades are connected to the sweeping connecting rod, and the sweeping blades are moved by the sweeping connecting rod.

9. The air outlet assembly of any one of claims 1 to 3, further comprising a door structure movably disposed on the air outlet frame, wherein the door structure has a closed state for shielding the upper air outlet and the lower air outlet and an open state for avoiding the upper air outlet and the lower air outlet.

10. The air outlet assembly of claim 9, wherein the door structure comprises a sealing plate and a mounting frame, the mounting frame is disposed on the air outlet frame, and the sealing plate is movably disposed on the mounting frame.

11. The air outlet assembly of claim 10, wherein a first guide matching portion is arranged on the mounting frame, a second guide matching portion is arranged on the closing plate, and the first guide matching portion is matched with the second guide matching portion.

12. A control method for an air outlet assembly according to any one of claims 1 to 11, wherein the air outlet assembly has a circulating air supply mode:

when the air outlet assembly is switched to the surrounding air supply mode, the first air guide mechanism is switched to the second state, the second air guide mechanism is switched to the fourth state, and the rotating direction of the first air guide mechanism is opposite to that of the second air guide mechanism.

13. The control method of claim 12, wherein the air outlet assembly has a synchronous air supply mode:

when the air outlet assembly is switched to the synchronous air supply mode, the first air guide mechanism is switched to the second state, the second air guide mechanism is switched to the fourth state, and the rotating direction of the first air guide mechanism is the same as that of the second air guide mechanism.

14. The control method of claim 13, wherein the first air guiding mechanism comprises a first air guiding plate, the second air guiding mechanism comprises a second air guiding plate, and when the air outlet assembly is in the synchronous air supply mode, the first air guiding plate and the second air guiding plate are in the same plane.

15. The control method of claim 14, wherein the air outlet assembly has a set plane, and when the air outlet assembly is switched to the synchronous blowing mode, the first air guiding mechanism and the second air guiding mechanism rotate synchronously when both the first air guiding plate and the second air guiding plate reach the set plane.

16. The control method according to any one of claims 12 to 15, wherein the air outlet assembly has an upper air outlet mode:

when the air outlet assembly is switched to the upper air outlet mode, the first air guide mechanism is switched to the second state, the second air guide mechanism is switched to the third state, and the first air guide mechanism performs directional air outlet or air sweeping.

17. The control method according to claim 16, wherein the air outlet assembly further includes a third air guiding mechanism, the third air guiding mechanism has an upward air guiding state, and when the third air guiding mechanism is in the upward air guiding state, the air flow passing through the third air guiding mechanism flows toward the upper air outlet;

when the air outlet assembly is switched to the upper air outlet mode, the third air guide mechanism is switched to an upper air guide state.

18. The control method of any one of claims 12 to 15, wherein the outlet assembly has a lower outlet mode;

when the air outlet assembly is switched to the lower air outlet mode, the first air guide mechanism is switched to the first state, the second air guide mechanism is switched to the fourth state, and the second air guide mechanism carries out directional air outlet or air sweeping.

19. The control method according to claim 18, wherein the air outlet assembly further includes a third air guiding mechanism, the third air guiding mechanism has a downward air guiding state, and when the third air guiding mechanism is in the downward air guiding state, the air flow passing through the third air guiding mechanism flows to the lower air outlet;

when the air outlet assembly is switched to the lower air outlet mode, the third air guide mechanism is switched to a lower air guide state.

20. The control method of any one of claims 12 to 15, wherein the air outlet assembly has an upper side air outlet mode:

when the air outlet assembly is switched to the upside air outlet mode, the first air guide mechanism is in the second state, the second air guide mechanism is in the fourth state, the air outlet of the first air guide mechanism faces one side of the air outlet frame, and the second air guide mechanism conducts directional air outlet or air sweeping.

21. The control method of any one of claims 12 to 15, wherein the outlet assembly has a lower outlet mode:

when the air outlet assembly is switched to the lower side air outlet mode, the first air guide mechanism is in the second state, the second air guide mechanism is in the fourth state, the air outlet of the second air guide mechanism faces one side of the air outlet frame, and the first air guide mechanism conducts directional air outlet or air sweeping.

22. An air conditioner, characterized in that: a control method comprising the air outlet assembly of any one of claims 1 to 11 or the air outlet assembly of any one of claims 12 to 21.

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