CN209910036U

CN209910036U - Air conditioner air outlet structure and air conditioner

Info

Publication number: CN209910036U
Application number: CN201920597581.XU
Authority: CN
Inventors: 李宗权; 李小怀; 姚刚; 陈寒冬; 胡树锋; 马江辉; 黄家璟; 宗冬友
Original assignee: Gree Electric Appliances Inc of Zhuhai
Current assignee: Gree Electric Appliances Inc of Zhuhai
Priority date: 2019-04-28
Filing date: 2019-04-28
Publication date: 2020-01-07
Anticipated expiration: 2029-04-28

Abstract

The utility model provides an air conditioner air outlet structure, air conditioner. The air outlet structure of the air conditioner comprises a shell, wherein an air outlet is formed in the shell, the air outlet is located at the downstream of an air outlet duct, the air guide plate is movably connected with the side wall of the air outlet duct, and the air guide plate is provided with a first state for closing the air outlet and a second state for guiding air outlet flow in the air outlet duct to the air outlet. According to the utility model discloses an air conditioner air outlet structure, air conditioner, compact structure, simple has bigger wind-guiding angle, is favorable to increasing the outflow distance of air-out air current.

Description

Air conditioner air outlet structure and air conditioner

Technical Field

The utility model belongs to the technical field of air conditioning, concretely relates to air conditioner air outlet structure, air conditioner.

Background

In order to ensure the comfort of the air outlet flow of the air conditioner, the air outlet structure of the air conditioner is mostly provided with an air deflector to change the air outlet angle according to the requirements of the refrigeration or heating working conditions, for example, the air deflector is adjusted to guide the air flow upwards during refrigeration, and the air deflector is adjusted to guide the air flow downwards during heating, so that the temperature of the air flow in the air conditioning space is three-dimensionally uniform. However, when the current air deflector is in an air guiding working condition (that is, the air deflector is opened), the air deflector structure is mostly located at the outer side of the air outlet, and the rotation angle of the air deflector in this way can be theoretically 90 degrees horizontally upward to 90 degrees horizontally downward, but the actual situation is far smaller than the aforementioned adjustment angle range, because the flow direction of the air outlet flow is limited to a great extent by the flow direction of the air outlet duct connected with the air outlet, that is, the air deflector located at the outer part of the air outlet cannot play the air guiding role at some angles, but forms a barrier to the air outlet flow led out by the duct, which greatly reduces the air guiding angle range of the existing air deflector; in the aspect of driving the rotation angle of the air deflector, a motor mode is mostly adopted at present, and although the electric mode is simple and convenient to control, the problems of large occupied space (large installation space is needed) and high manufacturing cost exist.

SUMMERY OF THE UTILITY MODEL

Therefore, the to-be-solved technical problem of the utility model is to provide an air conditioner air outlet structure, air conditioner, compact structure, simple has bigger wind-guiding angle, is favorable to increasing the outflow distance of air-out air current.

In order to solve the problem, the utility model provides an air outlet structure of air conditioner, which comprises a housin, the air outlet has been constructed on the casing, the air outlet is in the low reaches in air-out wind channel, still includes the aviation baffle, the aviation baffle with the lateral wall swing joint in air-out wind channel, the aviation baffle has and closes the first state of air outlet and will air-out air current in the air-out wind channel guides extremely the second state of air outlet.

Preferably, the air deflector has a first end located in the length direction thereof, the first end is configured with a first rotating shaft and a second rotating shaft, a first arc-shaped chute and a second arc-shaped chute are configured at a position of the air outlet duct corresponding to the first end, any plane perpendicular to the length direction of the air deflector is defined as a first plane, a projection on the first plane, the first arc-shaped chute and the second arc-shaped chute are centrosymmetric with respect to a point O, the first rotating shaft is located in the first arc-shaped chute, the second rotating shaft is located in the second arc-shaped chute, and the air deflector can rotate around the point O.

Preferably, the first end includes a connecting plate, the connecting plate extends in a direction perpendicular to the air guiding plane of the air deflector, and the first rotating shaft and the second rotating shaft are located on the connecting plate.

Preferably, the corresponding central angle of the arc wall of the first arc-shaped chute is A, and A is more than or equal to 35 degrees and less than or equal to 65 degrees.

Preferably, a closest distance between the second arc-shaped chute and the air outlet is greater than a farthest distance between the first arc-shaped chute and the air outlet, and the second arc-shaped chute and the first arc-shaped chute are respectively located on an air outlet path of the air outlet duct.

Preferably, an angle positioning piece is further arranged on the air deflector, and the angle positioning piece is detachably connected with the side wall of the air outlet duct.

Preferably, the angle positioning member includes an elastic buckle, and a clamping groove is configured on a side wall of the air outlet duct.

Preferably, the elastic buckle is connected with the first rotating shaft and/or the second rotating shaft into a whole; and/or the clamping grooves are provided with a plurality of clamping grooves which are arranged along the arc extending direction of the first arc-shaped sliding groove and/or the second arc-shaped sliding groove.

Preferably, a third arc-shaped chute and a fourth arc-shaped chute are further configured at the position of the air outlet duct corresponding to the first end, the third arc-shaped sliding chute is positioned between the first arc-shaped sliding chute and the second arc-shaped sliding chute, the curvature radius of the third arc-shaped sliding chute is larger than that of the first arc-shaped sliding chute, the fourth arc-shaped sliding chute is positioned at one side of the second arc-shaped sliding chute far away from the third arc-shaped sliding chute, and the first arc chute, the third arc chute, the second arc chute and the fourth arc chute are communicated in sequence, a first accommodating cavity for accommodating the second rotating shaft is formed at the tail end position of the fourth arc-shaped sliding chute, when the second rotating shaft is positioned in the first accommodating cavity and the first rotating shaft is positioned in the third arc-shaped sliding chute, the air deflector can rotate around the second rotating shaft, and the first rotating shaft slides along the third arc-shaped sliding groove.

Preferably, a curvature radius of the fourth arc-shaped chute is greater than a curvature radius of the first arc-shaped chute, a second accommodating cavity for accommodating the first rotating shaft is configured at a joint of the third arc-shaped chute and the first arc-shaped chute, when the first rotating shaft is located in the second accommodating cavity and the second rotating shaft is located in the fourth arc-shaped chute, the air deflector can rotate around the first rotating shaft, and the second rotating shaft slides along the fourth arc-shaped chute.

Preferably, the arc wall of the first arc-shaped chute and the arc wall of the second arc-shaped chute both have a central angle, the arc wall of the third arc-shaped chute has a central angle B, the arc wall of the fourth arc-shaped chute has a central angle C, and a ═ B ═ C ═ 45 °

Preferably, when the second rotating shaft is located in the first accommodating cavity, an air outlet gap is formed between the air outlet duct and one side of the air deflector, which is far away from the connecting plate, and an air outlet hole is further formed in the casing located on an air outlet airflow path in the air outlet gap.

The utility model also provides an air conditioner, including foretell air conditioner air outlet structure.

The utility model provides a pair of air conditioner air outlet structure, air conditioner, the air-out wind channel can some of casing also can be independent of a structure that the casing exists, the utility model discloses do not restrict very much. In the technical scheme, the installation position of the air deflector is associated with the air outlet duct, so that the air deflector can be in a first state of closing the air outlet, namely, the air deflector has the function of giving consideration to the attractive appearance of the air conditioner, and on the other hand, because the air deflector guides the air outlet flow in the air outlet duct, the defect that the tail end of the air deflector in the air outlet duct in the prior art is insufficient in the range of the guide angle of the air outlet flow is overcome, namely, the air outlet flow can be guided in advance, the interference of the wall body of the air outlet duct on the flow direction of the air outlet flow is prevented, and the increase of the outflow distance of the air outlet flow is facilitated.

Drawings

Fig. 1 is a schematic external structural view of an air conditioner according to an embodiment of the present invention;

FIG. 2 is a schematic view of the internal structure of FIG. 1 from the perspective A-A;

FIG. 3 is an enlarged view of a portion of FIG. 2 at A;

FIG. 4 is an enlarged view of a portion of FIG. 1 at B;

FIG. 5 is a schematic perspective view of the wind deflector of FIG. 1;

FIG. 6 is an enlarged view of a portion of FIG. 5 at C;

fig. 7 is a schematic view of an internal structure of an air outlet structure of an air conditioner according to an embodiment of the present invention in a wind guiding state on a wind deflector;

FIG. 8 is a schematic structural view of FIG. 3 without the air deflector;

fig. 9 is a schematic view illustrating a variation of an operation condition of an air outlet structure of an air conditioner according to an embodiment of the present invention;

fig. 10 is a schematic view illustrating another variation of the working condition of the air outlet structure of the air conditioner according to the embodiment of the present invention;

fig. 11 is a schematic view illustrating a further variation of the air outlet structure of the air conditioner according to the present invention.

The reference numerals are represented as:

1. a housing; 11. an air outlet; 12. an air outlet duct; 121. a first arc-shaped chute; 122. a second arc-shaped chute; 123. a third arc-shaped chute; 124. a fourth arc-shaped chute; 125. a card slot; 13. an air outlet; 2. an air deflector; 21. a first rotating shaft; 22. a second rotating shaft; 23. a connecting plate; 24. elastic buckle; 3. a fan; s1, closing the air outlet; s2, leading wind state under the wind deflector; s3, the horizontal air guiding state of the air guide plate; s4, leading wind state on the wind deflector; l1, first axis; l2, second axis; l3, third axis.

Detailed Description

Referring to fig. 1 to 11 in combination, according to the embodiment of the present invention, an air outlet structure of an air conditioner is provided, including a housing 1 and a fan 3, the fan 3 is in the housing 1, an air outlet 11 is configured on the housing 1, the air outlet 11 is located at the downstream of an air outlet duct 12, the fan 3 is located at the upstream of the air outlet duct 12, and further includes an air deflector 2, the air deflector 2 is movably connected to a side wall of the air outlet duct 12, and the air deflector 2 has a first state of closing the air outlet 11 and a second state of guiding the air outlet flow in the air outlet duct 12 to the air outlet 11. It is understood that the air outlet duct 12 may be a part of the housing 1 or a structure independent of the housing 1, and the present invention is not limited thereto. In the technical scheme, the installation position of the air deflector 2 is associated with the air outlet duct 12, so that the air deflector 2 can have a first state of closing the air outlet 11 on one hand, that is, the air deflector 2 has a function of giving consideration to the appearance of the air conditioner to be attractive, on the other hand, because the air deflector guides the air outlet flow in the air outlet duct 12, the defect that the tail end of the air deflector in the air outlet duct 12 in the prior art has an insufficient range of the guide angle of the air outlet flow is overcome, that is, the air outlet flow can be guided in advance, the interference of the wall body of the air outlet duct 12 on the flow direction of the air outlet flow is prevented, and the increase of the outflow distance of the air outlet flow is.

As a specific embodiment, it is preferable that the air guiding plate 2 has a first end in the length direction, the first end is configured with a first rotating shaft 21 and a second rotating shaft 22, the air outlet duct 12 is configured with a first arc-shaped chute 121 and a second arc-shaped chute 122 at a position corresponding to the first end, any plane perpendicular to the length direction of the air guiding plate 2 is defined as a first plane, a projection on the first plane is defined, the first arc-shaped chute 121 and the second arc-shaped chute 122 are centrosymmetric about a point O, the first rotating shaft 21 is located in the first arc-shaped chute 121, the second rotating shaft 22 is located in the second arc-shaped chute 122, and the air guiding plate 2 can rotate around the point O. In this technical solution, the first arc chute 121 and the second arc chute 122 are specifically located on the same circle, and the point O is a center of the same circle, it can be understood that a distance between axes of the first rotating shaft 21 and the second rotating shaft 22 is just a diameter of the same circle, and inner and outer sidewalls of the first arc chute 121 and the second arc chute 122 are respectively located on an inner side and an outer side of the same circle. Further, the air guiding plate 2 has a second end opposite to the first end, the first rotating shaft 21 and the second rotating shaft 22 are also configured on the second end, and the first arc-shaped chute 121 and the second arc-shaped chute 122 are also configured on the position of the air outlet duct 12 corresponding to the second end, so that the stress of the air guiding plate 2 in the length direction is more balanced, which can ensure the smoothness of the sliding of the air guiding plate 2 in the first arc-shaped chute 121 and the second arc-shaped chute 122.

The first end may include, for example, a connection plate 23 in a specific structure, the connection plate 23 extends in a direction perpendicular to the wind guide plane of the wind deflector 2, the first rotating shaft 21 and the second rotating shaft 22 are located on the connection plate 23, and the connection plate 23 is outside the installation carrier serving as the first rotating shaft 21 and the second rotating shaft 22, and more importantly, because of a distance extending in the direction perpendicular to the wind guide plane of the wind deflector 2, the wind deflector 2 can achieve the purpose of switching between the wind outlet duct 12 and the wind outlet 11, that is, the connection plate 23 enables the wind deflector 2 to have a swing distance.

Since the connecting position of the air deflector 2 is located in the air outlet duct 12, in order to ensure that the air deflector 2 has a larger air deflection angle range, and the size space of the air outlet duct 12 is not too large, one way of handling is to necessarily limit the arrangement positions of the first arc-shaped chute 121 and the second arc-shaped chute 122, for example, the closest distance between the second arc-shaped chute 122 and the air outlet 11 is greater than the farthest distance between the first arc-shaped chute 121 and the air outlet 11, and the second arc-shaped chute 122 and the first arc-shaped chute 121 are respectively located on the air outlet path of the air outlet duct 12, as shown in fig. 3, the first arc-shaped chute 121 and the second arc-shaped chute 122 extend along the duct extending direction of the air outlet duct 12, further, the central angle corresponding to the arc wall of the first arc-shaped chute 121 is a, a is more than or equal to 35 degrees and less than or equal to 65 degrees, so that the large size of the air outlet duct 12 in the length extending direction (left and right) can be fully utilized, and the air outlet duct can be prevented from occupying too much space in the up-down direction.

In terms of positioning after the wind guiding angle of the wind deflector 2 is determined, for example, the positioning may be determined by machining accommodating grooves matched with the first rotating shaft 21 and/or the second rotating shaft 22 on the arc walls of the first arc-shaped chute 121 and the second arc-shaped chute 122, and the plurality of accommodating grooves are arranged at intervals along the extending direction of the first arc-shaped chute 121 (i.e. the sliding direction of the first rotating shaft 21 or the second rotating shaft 22), but this way is relatively complicated in machining; more preferably, an angle positioning element is further disposed on the air guide plate 2, and the angle positioning element is detachably connected to a side wall of the air outlet duct 12. The angle positioning element includes, for example, an elastic buckle 24, and at this time, a corresponding slot 125 is configured on the side wall of the air outlet duct 12, and the elastic buckle 24 and the slot 125 are fastened to realize the rapid positioning of the air deflector 2 after the placement angle is determined. Preferably, the elastic buckle 24 is connected with the first rotating shaft 21 and/or the second rotating shaft 22 into a whole; and/or, the plurality of slots 125 are arranged along the arc extending direction of the first arc-shaped sliding chute 121 and/or the second arc-shaped sliding chute 122, and further, the plurality of slots 125 are disposed near the first arc-shaped sliding chute 121 and/or the second arc-shaped sliding chute 122, and may form a tooth socket with a plurality of slots corresponding to the first arc-shaped sliding chute 121 and the second arc-shaped sliding chute 122, respectively.

Preferably, a third arc-shaped chute 123 and a fourth arc-shaped chute 124 are further configured at a position of the air outlet duct 12 corresponding to the first end, the third arc-shaped chute 123 is located between the first arc-shaped chute 121 and the second arc-shaped chute 122, a curvature radius of the third arc-shaped chute 123 is greater than a curvature radius of the first arc-shaped chute 121, the fourth arc-shaped chute 124 is located at a side of the second arc-shaped chute 122 away from the third arc-shaped chute 123, the first arc-shaped chute 121, the third arc-shaped chute 123, the second arc-shaped chute 122 and the fourth arc-shaped chute 124 are sequentially communicated, a first accommodating cavity for accommodating the second rotating shaft 22 is configured at an end position of the fourth arc-shaped chute 124, when the second rotating shaft 22 is located in the first accommodating cavity and the first rotating shaft 21 is located in the third arc-shaped chute 123, the air deflector 2 can rotate around the second rotating shaft 22, the first rotating shaft 21 slides along the third arc-shaped sliding groove 123. Further, a curvature radius of the fourth arc-shaped sliding chute 124 is greater than a curvature radius of the first arc-shaped sliding chute 121, a second accommodating cavity for accommodating the first rotating shaft 21 is configured at a joint of the third arc-shaped sliding chute 123 and the first arc-shaped sliding chute 121, when the first rotating shaft 21 is located in the second accommodating cavity and the second rotating shaft 22 is located in the fourth arc-shaped sliding chute 124, the air deflector 2 can rotate around the first rotating shaft 21, and the second rotating shaft 22 slides along the fourth arc-shaped sliding chute 124. In this technical solution, the first arc-shaped chute 121, the second arc-shaped chute 122, the third arc-shaped chute 123 and the fourth arc-shaped chute 124 together form a chute of the air deflector 2 with a requirement for multi-angle adjustment, and more importantly, since the radii of curvature of the third arc-shaped sliding chute 123 and the fourth arc-shaped sliding chute 124 are both larger than that of the first arc-shaped sliding chute 121, because the first arc chute 121, the second arc chute 122, the third arc chute 123 and the fourth arc chute 124 are communicated in sequence, the chutes form an oval structure on the whole, and the major axis of the elliptical structure is in accordance with the flow direction of the outlet air flow of the outlet air duct 12, therefore, the air guide plate 2 has a large air guide angle adjustment range, and the height distance of the air outlet duct 12 is not additionally increased, so that the air outlet structure is more compact.

The arc wall of the first arc-shaped chute 121 and the arc wall of the second arc-shaped chute 122 both have a central angle, the arc wall of the third arc-shaped chute 123 has a central angle B, the arc wall of the fourth arc-shaped chute 124 has a central angle C, and a is B is C is 45 °, so that the air guide angle of the air guide plate 2 is wider, and specifically, the angle adjustment in the range of 0 ° to 135 ° can be realized.

With reference to fig. 8 to 11, in which fig. 9 shows that the air deflector changes from the position of the closed outlet (the air outlet closed state S1) to the state that the air outlet is in the downward air guiding state (the air guiding state S2), in this variation, the first rotating shaft 21 can only slide in the first arc-shaped sliding groove 121, meanwhile, the second rotating shaft 22 can only slide in the second arc chute 122, and the rotating center thereof is the above-mentioned point O (the rotating shaft axis is the first rotating axis L1 in fig. 6), since the first arc chute 121 and the third arc chute 123 have different radii of curvature and the second arc chute 122 and the fourth arc chute 124 have different radii of curvature, the first rotating shaft 21 and the second rotating shaft 22 cannot enter the third arc-shaped chute 123 and the fourth arc-shaped chute 124, and the angle variation range is 0 to 45 degrees; fig. 10 shows that the air guiding plate changes from the downward air guiding state (S2) to the horizontal air guiding state (air guiding plate horizontal air guiding state S3), in the process, the first rotating shaft 21 can only be located in the second accommodating cavity, and the second rotating shaft 22 can only be located in the fourth arc-shaped sliding groove 124, and the rotation center thereof is the axis of the first rotating shaft 21 (the third rotation axis L3 in fig. 6), and the angle change range is 45 ° to 90 °; fig. 11 shows that the air guiding plate changes from the horizontal air guiding state (S3) to the upward air guiding state (the air guiding state S4 on the air guiding plate), in this changing process, the second rotating shaft 22 can only be located in the first accommodating cavity, and the first rotating shaft 21 can only be located in the third arc-shaped chute 123, and the rotation center thereof is the axis of the second rotating shaft 22 (the second rotation axis L2 in fig. 6), and the angle change range at this time is 90 ° to 135 °, so that the air conditioner adopting the technical scheme of the present invention has the greatly increased air guiding angle range (135 °, maximum 75 ° in the prior art). It is understood that the first state is the S1, and the second state includes the S2, S3 and S4.

Preferably, when the second rotating shaft 22 is located in the first accommodating cavity, that is, the air deflector 2 is in an upward air guiding state, an air outlet gap is formed between the air outlet duct 12 and one side of the air deflector 2, which is far away from the connecting plate 23, and the housing 1 located on an air outlet path in the air outlet gap is further configured with an air outlet hole 13, so that air guiding effects on two sides of the air deflector 2 are achieved, and smooth outflow of air outlet airflow is ensured. Further, the air conditioner at this moment is the refrigeration operating mode, under this kind of operating mode, among the prior art very easily forms the condensation owing to crossing of cold warm air current on the aviation baffle, and the utility model provides an aviation baffle 2 then under this operating mode is owing to be in completely the inside of air outlet 11 (also in air-out wind channel 12) and the possibility of producing the condensation of very big probability have been stopped, on the other hand, when the condensation is produced to minimum probability, because aviation baffle 2 is in the inside of air-out wind channel 12, the condensation of formation will follow the surface flow of aviation baffle 2 extremely the downside of air-out wind channel 12, and then draw forth outdoor via structures such as water collector of air conditioner. In the technical scheme, the air guide angle of the air guide plate 2 can be adjusted in a manual mode, complex structures such as a motor and a connecting rod are not needed in the prior art, the structural design of the air outlet is greatly simplified, and the corresponding production and manufacturing cost is reduced.

According to the utility model discloses an embodiment still provides an air conditioner, including foretell air conditioner air outlet structure.

It is readily understood by a person skilled in the art that the advantageous ways described above can be freely combined, superimposed without conflict.

The above description is only exemplary of the present invention and should not be construed as limiting the present invention, and any modifications, equivalents and improvements made within the spirit and principles of the present invention are intended to be included within the scope of the present invention. The above is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of modifications and variations can be made without departing from the technical principle of the present invention, and these modifications and variations should also be regarded as the protection scope of the present invention.

Claims

1. The air outlet structure of the air conditioner is characterized by comprising a shell (1), wherein an air outlet (11) is formed in the shell (1), the air outlet (11) is located at the downstream of an air outlet duct (12), the air outlet structure further comprises an air deflector (2), the air deflector (2) is movably connected with the side wall of the air outlet duct (12), and the air deflector (2) is provided with a first state for closing the air outlet (11) and a second state for guiding air outlet flow in the air outlet duct (12) to the air outlet (11).

2. The air outlet structure according to claim 1, wherein the air deflector (2) has a first end in a length direction thereof, the first end is configured with a first rotating shaft (21) and a second rotating shaft (22), the air outlet duct (12) is configured with a first arc-shaped chute (121) and a second arc-shaped chute (122) at a position corresponding to the first end, a first plane is defined as any plane perpendicular to the length direction of the air deflector (2), a projection on the first plane is defined, the first arc-shaped chute (121) and the second arc-shaped chute (122) are centrosymmetric with respect to a point O, the first rotating shaft (21) is located in the first arc-shaped chute (121), the second rotating shaft (22) is located in the second arc-shaped chute (122), and the air deflector (2) can rotate around the point O.

3. The air outlet structure according to claim 2, wherein the first end comprises a connecting plate (23), the connecting plate (23) extends in a direction perpendicular to the air guiding plane of the air deflector (2), and the first rotating shaft (21) and the second rotating shaft (22) are located on the connecting plate (23).

4. An air outlet structure according to claim 2, wherein the arc wall of the first arc chute (121) has a central angle a of 35 ° or more and 65 ° or less.

5. The air outlet structure according to claim 2, wherein a closest distance between the second arc-shaped chute (122) and the air outlet (11) is greater than a farthest distance between the first arc-shaped chute (121) and the air outlet (11), and the second arc-shaped chute (122) and the first arc-shaped chute (121) are respectively located on an air outlet path of the air outlet duct (12).

6. The air outlet structure according to claim 2, wherein an angle positioning element is further disposed on the air deflector (2), and the angle positioning element is detachably connected to a side wall of the air outlet duct (12).

7. The air outlet structure according to claim 6, wherein the angle positioning element comprises an elastic buckle (24), and a clamping groove (125) is formed on a side wall of the air outlet duct (12).

8. The air outlet structure according to claim 7, wherein the elastic buckle (24) is connected with the first rotating shaft (21) and/or the second rotating shaft (22) into a whole; and/or the clamping grooves (125) are provided in a plurality, and the clamping grooves (125) are arranged along the arc extending direction of the first arc-shaped sliding groove (121) and/or the second arc-shaped sliding groove (122).

9. The air outlet structure according to claim 3, wherein a third arc-shaped chute (123) and a fourth arc-shaped chute (124) are further configured at a position of the air outlet duct (12) corresponding to the first end, the third arc-shaped chute (123) is located between the first arc-shaped chute (121) and the second arc-shaped chute (122), a radius of curvature of the third arc-shaped chute (123) is greater than a radius of curvature of the first arc-shaped chute (121), the fourth arc-shaped chute (124) is located at a side of the second arc-shaped chute (122) away from the third arc-shaped chute (123), the first arc-shaped chute (121), the third arc-shaped chute (123), the second arc-shaped chute (122) and the fourth arc-shaped chute (124) are sequentially communicated, and a first accommodating cavity for accommodating the second rotating shaft (22) is configured at a terminal position of the fourth arc-shaped chute (124), when the second rotating shaft (22) is located in the first accommodating cavity and the first rotating shaft (21) is located in the third arc-shaped sliding groove (123), the air deflector (2) can rotate around the second rotating shaft (22), and the first rotating shaft (21) slides along the third arc-shaped sliding groove (123).

10. The air outlet structure according to claim 9, wherein a radius of curvature of the fourth arc-shaped chute (124) is larger than a radius of curvature of the first arc-shaped chute (121), a second accommodating cavity for accommodating the first rotating shaft (21) is configured at a position where the third arc-shaped chute (123) is connected to the first arc-shaped chute (121), when the first rotating shaft (21) is located in the second accommodating cavity and the second rotating shaft (22) is located in the fourth arc-shaped chute (124), the air deflector (2) can rotate around the first rotating shaft (21), and the second rotating shaft (22) slides along the fourth arc-shaped chute (124).

11. The outlet structure according to claim 10, wherein the arc wall of the first arc-shaped chute (121) and the arc wall of the second arc-shaped chute (122) both have a central angle, the arc wall of the third arc-shaped chute (123) has a central angle B, and the arc wall of the fourth arc-shaped chute (124) has a central angle C, where a-B-C-45 °.

12. The air outlet structure according to claim 9, wherein when the second rotating shaft (22) is located in the first accommodating cavity, an air outlet gap is formed between the air outlet duct (12) and one side of the air deflector (2) away from the connecting plate (23), and an air outlet hole (13) is further formed in the casing (1) located on an air outlet flow path in the air outlet gap.

13. An air conditioner comprising an air outlet structure, wherein the air outlet structure is as claimed in any one of claims 1 to 12.