CN214581452U - Air outlet structure for air conditioner and air conditioner - Google Patents

Abstract

The utility model relates to an intelligence electrical apparatus technical field, concretely relates to an air outlet structure and air conditioner for air conditioner. The utility model discloses aim at solving the unsatisfactory problem of air outlet structure wind-guiding effect of current air conditioner. For this purpose, the utility model discloses an air outlet structure for an air conditioner, which comprises an air outlet frame, an air guide component and a push-pull component, wherein the air outlet frame is provided with an air outlet; the air guide assembly comprises at least one air guide panel, the air guide panel can cover the air outlet when in a closed state, and the total area of the air guide panel is larger than or equal to the area of the surface where the air outlet is located; the push-and-pull subassembly sets up on the air-out frame, and the push-and-pull subassembly is connected with at least one wind guide panel for it is flexible for the air outlet to drive at least one wind guide panel, thereby realizes opening or closing of air outlet, has increased wind guide assembly's total area, has promoted the wind-guiding effect, makes the outward appearance of tuber pipe machine more pleasing to the eye and brief, improves user's visual effect.

Description

Air outlet structure for air conditioner and air conditioner

Technical Field

The utility model relates to an intelligence electrical apparatus technical field, concretely relates to an air outlet structure and air conditioner for air conditioner.

Background

As air conditioners are widely used in thousands of households, users have higher and higher requirements on the use performance of the air conditioners. Taking the ducted air conditioner as an example, the air outlet of the volute in the ducted air conditioner is opposite to the air outlet of the ducted air conditioner, so that the blowing direction of the ducted air conditioner is single, and the ducted air conditioner can only blow straight ahead, and the air outlet cannot be upward or downward, and the air outlet direction cannot be effectively adjusted.

In order to solve the above problems, in the prior art, the ducted air conditioner is provided with an air outlet structure for guiding air, the air outlet structure comprises an air outlet frame, a decoration panel and an air deflector, the decoration panel is located on the outer side wall of the air outlet frame, an air outlet is arranged on the decoration panel, the air deflector is rotatably arranged at the air outlet, and the air outlet direction of the ducted air conditioner is adjusted through the air deflector. However, because the air outlet is arranged on the decorative panel, the air deflector is rotatably arranged at the air outlet, and compared with the whole decorative panel, the area of the air deflector is smaller, so that the air guiding effect is reduced, and the use experience of a user is influenced. And when the aviation baffle was in the closed state, just can seal the air outlet totally with the aviation baffle removal in the air outlet completely, can not leave the gap, increased the degree of difficulty of control.

Accordingly, there is a need in the art for a new outlet structure for an air conditioner and an air conditioner to solve the above problems.

SUMMERY OF THE UTILITY MODEL

In order to solve the above problems in the prior art, namely to solve the problem that the air guide effect of the air outlet structure of the existing air conditioner is not ideal, the utility model provides an air outlet structure for an air conditioner, which comprises an air outlet frame, an air guide component and a push-pull component, wherein the air outlet frame is provided with an air outlet; the air guide assembly comprises at least one air guide panel, the air guide panel can cover the air outlet when being in a closed state, and the total area of the air guide panel is larger than or equal to the area of the surface where the air outlet is located; the push-pull assembly is arranged on the air outlet frame and connected with the at least one air guide panel and used for driving the at least one air guide panel to stretch relative to the air outlet, so that the air outlet is opened or closed.

In a preferred technical solution of the above air outlet structure, the push-pull assembly includes a first driving mechanism disposed on the air outlet frame, the first driving mechanism is disposed at a first end of the air outlet frame along a length direction of the air outlet, and the first driving mechanism is connected to the at least one wind guide panel and is configured to drive the at least one wind guide panel to extend and retract relative to the air outlet.

In a preferred technical solution of the air outlet structure, the first driving mechanism includes a first box, and a first driving motor, a first lead screw, a first moving mechanism, a first nut and a first guide rail which are arranged on the first box, wherein an output shaft of the first driving motor is in transmission connection with the first lead screw, the first moving mechanism is connected with the first lead screw through the first nut, and the first moving mechanism can slide along the first guide rail; the at least one air guide panel can be rotatably connected to the first moving mechanism; the first driving motor can drive the first lead screw to rotate so as to enable the first nut to move relative to the first lead screw, and therefore the first moving mechanism is driven to slide along the first guide rail.

In a preferred technical scheme of the air outlet structure, a first connecting plate is arranged on the inner side surface of the air guide panel; the first moving mechanism comprises a first moving component and a first connecting arm, and the first moving component is connected with the first lead screw through the first nut; the first end of the first connecting arm is fixedly connected with the first moving component, and the second end of the first connecting arm is rotatably connected with the first connecting plate.

In a preferred technical solution of the air outlet structure, the push-pull assembly further includes a second driving mechanism disposed on the air outlet frame, the second driving mechanism is disposed at a second end of the air outlet frame along a length direction of the air outlet, and the second driving mechanism is connected to the at least one wind guide panel and is configured to drive the at least one wind guide panel to extend and retract relative to the air outlet; the second driving mechanism is further used for driving the at least one air guide panel to rotate so as to adjust the air outlet angle of the air outlet.

In a preferred technical solution of the above air outlet structure, the second driving mechanism includes a second box body, and a second driving motor, a driving member, a second screw, a second moving mechanism, a second nut and a second guide rail which are arranged in the second box body, wherein an output shaft of the second driving motor is in transmission connection with the second screw, the second moving mechanism is connected with the second screw through the second nut, and the second moving mechanism can slide along the second guide rail; the connecting end of the at least one air guide panel is provided with at least one driving component, and each driving component is arranged on the second moving mechanism and is in transmission connection with one air guide panel; the second driving motor can drive the second lead screw to rotate so as to enable the second nut to move relative to the second lead screw, and therefore the second moving mechanism is driven to slide along the second guide rail; the driving component is used for driving the air guide panel in transmission connection with the driving component to rotate.

In a preferred technical scheme of the air outlet structure, a second connecting plate is arranged on the inner side surface of the air guide panel; the second moving mechanism comprises a second moving component and a second connecting arm, the second moving component is connected with the second lead screw through the second nut, and the first end of the second connecting arm is fixedly connected with the second moving component; the driving member comprises a third driving motor, a gear and a driving rod, the third driving motor, the gear and the driving rod are arranged on the second connecting arm, an output shaft of the third driving motor is in transmission connection with the gear, the driving rod is in meshing connection with the gear, and an output end of the driving rod is connected with the second connecting plate in a non-relative-rotation mode.

In a preferred technical solution of the above air outlet structure, the number of the air guide panels is two, the two air guide panels can cover the air outlet when in a closed state, and the total area of the two air guide panels is equal to the area of the surface where the air outlet is located.

In a preferred technical solution of the above air outlet structure, the air outlet structure further includes a swing blade assembly, and the swing blade assembly is swingably disposed on the air outlet frame and is close to the air outlet.

Furthermore, the utility model also provides an air conditioner, this air conditioner include any one of above-mentioned preferred technical scheme the air outlet structure.

As can be understood by those skilled in the art, in the preferred technical solution of the present invention, the air outlet frame, the air guide assembly and the push-pull assembly are provided with an air outlet; the air guide assembly comprises at least one air guide panel, the air guide panel can cover the air outlet when in a closed state, and the total area of the air guide panel is larger than or equal to the area of the surface where the air outlet is located; the push-pull assembly is arranged on the air outlet frame and connected with the at least one air guide panel for driving the at least one air guide panel to stretch relative to the air outlet, so that the air outlet is opened or closed.

Compared with the technical scheme that the air outlet structure includes air-out frame, decoration panel and wind-guiding panel among the prior art, the utility model discloses an air outlet structure includes air-out frame and at least one wind-guiding panel, can cover the air outlet when at least one wind-guiding panel is in the closure state to at least one wind-guiding panel's total area is more than or equal to the area of air outlet place face, has increased wind-guiding component's total area, has promoted the wind-guiding effect, and then has promoted user experience. When the air outlet needs to be closed, the air outlet can be completely closed only by abutting all the air guide panels against the air outlet frame, and all the air guide panels do not need to be completely moved into the air outlet, so that the control difficulty is reduced, and the air leakage phenomenon is reduced; and because the decorative panels are reduced and only the air guide panel structure is adopted, the processing technology is simplified, the appearance of the air duct machine is more attractive and simple, and the visual effect of a user is improved.

Further, the air outlet structure is still including setting up the push-and-pull subassembly on the air-out frame, the push-and-pull subassembly is connected with at least one wind guide panel, a be used for driving at least one wind guide panel and stretch out and draw back for the air outlet, thereby realize opening or closing of air outlet, when the wind guide panel is released from air outlet by the push-and-pull subassembly, be located the technical scheme of air outlet department all the time for the wind guide panel, the distance between wind guide panel and the air outlet has been increased, the wind-guiding distance has been increased, can realize remote wind-guiding, further promoted the wind-guiding effect. When closing the air conditioner, the push-and-pull subassembly can pull back air guide panel air outlet department, and the flexible state of air guide panel can be adjusted according to the wind guide demand of reality in a flexible way to the technical personnel in the field, has further promoted user experience.

Further, the first driving mechanism comprises a first box body, a first driving motor, a first lead screw, a first moving mechanism, a first nut and a first guide rail, wherein the first driving motor, the first lead screw, the first moving mechanism, the first nut and the first guide rail are arranged on the first box body; at least one air guide panel is rotationally connected to the first moving mechanism; the first driving motor can drive the first lead screw to rotate so as to enable the first nut to move relative to the first lead screw, and therefore the first moving mechanism is driven to slide along the first guide rail. Compared with the technical scheme of gear rack or chain transmission in the prior art, the first driving mechanism adopts the technical scheme of lead screw and nut transmission, the rotary motion is converted into linear motion, and the transmission precision of the lead screw and the nut is higher than that of the gear rack or the chain transmission in the linear motion, so that at least one air guide panel can be accurately driven to stretch and retract relative to the air outlet along the linear direction; the transmission efficiency of the screw rod and the nut is higher than that of a rack and pinion or a chain, so that the energy consumption is reduced; the transmission mode of lead screw and nut can realize the auto-lock for the air guide panel can carry out the auto-lock better for the flexible in-process of air outlet, has avoided the in-process of air guide panel at the removal to take place to rock, has further promoted user experience.

Further, the second driving mechanism comprises a second box body, a second driving motor, a driving component, a second lead screw, a second moving mechanism, a second nut and a second guide rail, wherein the second driving motor, the driving component, the second lead screw, the second moving mechanism, the second nut and the second guide rail are arranged on the second box body; the connecting end of at least one air guide panel is provided with at least one driving component, and each driving component is arranged on the second moving mechanism and is in transmission connection with one air guide panel; the second driving motor can drive the second lead screw to rotate so as to enable the second nut to move relative to the second lead screw, and therefore the second moving mechanism is driven to slide along the second guide rail; the transmission efficiency of the screw rod and the nut is higher than that of a rack and pinion or a chain, so that the energy consumption is reduced; the transmission mode of lead screw and nut can realize the auto-lock for the air guide panel can carry out the auto-lock better for the flexible in-process of air outlet, has avoided the in-process of air guide panel at the removal to take place to rock, has further promoted user experience. In addition, the driving component is used for driving the air guide panel in transmission connection with the driving component to rotate, the air guide direction can be adjusted by 180 degrees to the maximum, large-range air sweeping of 180 degrees to the maximum can be realized, and the user experience is further improved.

Furthermore, under the combined action of the first driving mechanism and the second driving mechanism, at least one air guide panel can be stably driven to stretch out and draw back relative to the air outlet, the running stability is improved, the phenomenon that the air guide panel shakes in the stretching process is avoided, and the user experience is further improved.

Drawings

The air outlet structure for an air conditioner and the air conditioner of the present invention will be described with reference to the accompanying drawings. In the drawings:

fig. 1 is a schematic view of a first state of the air outlet structure of the present invention;

fig. 2 is a schematic view of the air outlet structure according to the present invention in a second state;

fig. 3 is an exploded view of the air outlet structure of the present invention;

fig. 4 is a schematic structural diagram of a first driving mechanism of the present invention;

FIG. 5 is a cross-sectional view taken along line I-I of FIG. 4;

fig. 6 is a schematic structural view of the air guide panel of the present invention;

fig. 7 is a schematic structural view of a second driving mechanism of the present invention;

FIG. 8 is a rotated cross-sectional view of FIG. 7;

fig. 9 is a schematic view illustrating a first angle adjustment of the air guide panel according to the present invention;

fig. 10 is a second angle adjustment schematic view of the air guide panel of the present invention;

fig. 11 is a third angle adjustment schematic diagram of the air guide panel of the present invention;

fig. 12 is a partial schematic view of the outlet structure of the present invention;

fig. 13 is a schematic structural view of the connecting rod of the present invention;

fig. 14 is a schematic view of a conventional air conditioner installed indoors;

fig. 15 is a schematic view of the air conditioner according to the present invention installed indoors.

List of reference numerals

1. An air outlet frame; 11. an air outlet; 12. a first mounting member; 13. a second mounting member; 131. a second mounting hole; 14. a third mounting member; 15. a fourth mounting member; 151. a fourth mounting hole;

2. an air guide assembly; 21. an air guide panel; 211. a first connecting plate; 2111. a first connection hole; 212. a second connecting plate; 2121. a fourth connection hole;

3. a push-pull assembly;

31. a first drive mechanism; 311. a first case; 3111. a first through hole; 3112. a first mounting hole; 312. a first drive motor; 313. a first lead screw; 314. a first moving mechanism; 3141. a first moving member; 31411. a first moving part; 314111, a first connecting via; 314112, a first mounting groove; 314113, a second connection hole; 31412. a first connection portion; 314121, a second connecting via; 31413. a first sliding bearing; 31414. a second sliding bearing; 3142. a first connecting arm; 31421. a connecting shaft; 31422. a third connection hole; 315. a first nut; 316. a first guide rail; 317. a first bearing; 318. a second bearing; 319. a first connecting member;

32. a second drive mechanism; 321. a second box body; 3211. a second through hole; 3212. a third mounting hole; 322. a second drive motor; 323. a drive member; 3231. a cover body; 32311. a third through hole; 3232. a third drive motor; 3233. a gear; 3234. a drive rod; 324. a second lead screw; 325. a second moving mechanism; 3251. a second moving member; 32511. a second moving part; 325111, a third connecting via; 325112, a second mounting groove; 325113, a fifth connecting hole; 32512. a second connecting portion; 325121, a fourth connecting via; 32513. a third sliding bearing; 32514. a fourth sliding bearing; 3252. a second connecting arm; 32521. a sixth connection hole; 326. a second nut; 327. a second guide rail; 328. a third bearing; 329. a fourth bearing; 330. a second connecting member;

4. a swing blade assembly; 41. a connecting rod; 411. a first portion; 4111. a seventh connection hole; 412. a second portion; 4121. an eighth connection hole; 42. a swing rod; 43. a fourth drive motor; 44. swinging the leaves; 441. a first pivot shaft; 442. a second pivot shaft;

5. a ducted air conditioner;

6. a light trough structure.

Detailed Description

Preferred embodiments of the present invention will be described below with reference to the accompanying drawings. It should be understood by those skilled in the art that these embodiments are only for explaining the technical principle of the present invention, and are not intended to limit the scope of the present invention. For example, although the first driving mechanism and the second driving mechanism are respectively disposed at the left and right sides of the air outlet frame in the drawings, the arrangement is not always the same, and those skilled in the art can adjust the driving mechanisms as required to suit the specific application. For example, the first driving mechanism and the second driving mechanism may be disposed on the upper and lower sides or the same side of the air outlet frame.

It should be noted that in the description of the present invention, the terms of direction or positional relationship indicated by the terms "inner", "outer", "upper", "lower", "left", "right", etc. are based on the direction or positional relationship shown in the drawings, which are only for convenience of description, and do not indicate or imply that the device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," "fourth," "fifth," "sixth," "seventh," and "eighth" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Furthermore, it should be noted that, in the description of the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

Based on the technical problem who provides among the background art, the utility model provides an air outlet structure for air conditioner, this air outlet structure includes air-out frame, at least one wind-guiding panel and push-and-pull subassembly, can cover the air outlet when at least one wind-guiding panel is in the closure state to at least one wind-guiding panel's total area is more than or equal to the area of air outlet place face, has increased wind-guiding subassembly's total area, has promoted the wind-guiding effect, and then has promoted user experience. When the air outlet needs to be closed, the air outlet can be completely closed only by abutting all the air guide panels against the air outlet frame, and all the air guide panels do not need to be completely moved into the air outlet, so that the control difficulty is reduced, and the air leakage phenomenon is reduced; because the decoration panel structure is reduced and only the air guide panel structure is adopted, the processing technology is simplified, the appearance of the ducted air conditioner is more attractive and concise, and the visual effect of a user is improved; the push-pull assembly is connected with at least one air guide panel for it is flexible for the air outlet to drive at least one air guide panel, can adjust air guide panel's wind-guiding distance, has further promoted the wind-guiding effect.

First, referring to fig. 1 and 2, the air outlet structure for an air conditioner according to the present invention will be described. Wherein, fig. 1 is a schematic view of a first state of the air outlet structure of the present invention; fig. 2 is a schematic view of a second state of the air outlet structure of the present invention.

As shown in fig. 1 and 2, the air outlet structure for an air conditioner of the present invention includes an air outlet frame 1, an air guide assembly 2 and a push-pull assembly 3, wherein the air outlet frame 1 is provided with an air outlet 11; the air guide assembly 2 comprises two air guide panels 21, the two air guide panels 21 can cover the air outlet 11 when being in a closed state, and the total area of the two air guide panels 21 is equal to the area of the surface where the air outlet 11 is located; the push-pull assembly 3 is arranged on the air outlet frame 1, and the push-pull assembly 3 is connected with the two air guide panels 21 and used for driving the two air guide panels 21 to stretch and retract relative to the air outlet 11, so that the air outlet 11 is opened (as shown in fig. 1) or closed (as shown in fig. 2).

The areas of the two air guide panels 21 may be the same, for example, the lengths (i.e., the directions from the left bottom to the right top in fig. 1) of the two air guide panels 21 are the same, and the widths (i.e., the directions from the right bottom to the left top in fig. 1) of the two air guide panels 21 are also the same. The areas of the two air guide panels 21 may also be different, for example, the lengths of the two air guide panels 21 are the same, but the widths of the two air guide panels 21 are different; or, the widths of the two air guide panels 21 are the same, but the lengths of the two air guide panels 21 are different, and a person skilled in the art can flexibly adjust and set the areas of the two air guide panels 21, so long as the two air guide panels 21 can cover the air outlet 11 when being in a closed state, and the total area of the two air guide panels 21 is equal to the area of the surface where the air outlet 11 is located.

Preferably, the air guide panel 21 is of an arc-shaped structure, which not only makes the appearance of the ducted air conditioner 5 more beautiful, but also reduces the resistance of the air guide panel 21 in the process of extending and retracting relative to the air outlet 11. Of course, the air guide panel 21 may have a planar structure, and those skilled in the art can flexibly adjust and set the structure of the air guide panel 21.

The number of the air guide panels 21 is not limited to two as described above, and may be one, three, four, or more, and the number of the air guide panels 21 may be adjusted, so long as each air guide panel 21 is connected to the push-pull module 3, can be extended and retracted relative to the outlet 11 by the action of the push-pull module 3, and can cover the outlet 11 when all the air guide panels 21 are in the closed state, and the total area of all the air guide panels 21 is equal to the area of the surface on which the outlet 11 is located. Of course, the total area of all the air guide panels 21 in the closed state may be larger than the area of the surface on which the air outlet 11 is located, and the total area of all the air guide panels 21 in the closed state may be adjusted as long as the air outlet 11 can be completely covered.

With continued reference to fig. 2, the push-pull assembly of the present invention will be described by taking two air guide panels as an example.

As shown in fig. 2, the push-pull assembly 3 includes a first driving mechanism 31 and a second driving mechanism 32 disposed on the air outlet frame 1, the first driving mechanism 31 is disposed at a first end (i.e., an end above and to the right of the paper surface in fig. 2) of the air outlet frame 1 along a length direction of the air outlet 11 (i.e., a direction from the left bottom to the right top in fig. 2), the first driving mechanism 31 is connected to the two air guide panels 21, and is configured to drive the two air guide panels 21 to extend and retract relative to the air outlet 11; the second driving mechanism 32 is disposed at a second end (i.e., an end at the lower left of the drawing sheet in fig. 2) of the air outlet frame 1 along the length direction of the air outlet 11, and the second driving mechanism 32 is connected to the two air guide panels 21, and is configured to drive the two air guide panels 21 to extend and retract relative to the air outlet 11, and further drive the two air guide panels 21 to rotate, so as to adjust the air outlet angle of the air outlet 11.

Of course, the installation positions of the first driving mechanism 31 and the second driving mechanism 32 are not limited to the above-mentioned positions, and the first driving mechanism 31 may be installed at the second end of the air outlet frame 1, and the second driving mechanism 32 may be installed at the first end of the air outlet frame 1, and those skilled in the art may flexibly adjust and install the installation positions of the first driving mechanism 31 and the second driving mechanism 32 in practical applications.

It should be noted that the push-pull assembly 3 may also include only the first driving mechanism 31, and the two first driving mechanisms 31 are respectively disposed at the first end and the second end of the air outlet frame 1 along the length direction of the air outlet 11; alternatively, the push-pull assembly 3 may only include the second driving mechanism 32, and the two second driving mechanisms 32 are respectively disposed at the first end and the second end of the air outlet frame 1 along the length direction of the air outlet 11, and those skilled in the art can flexibly adjust and set the combination manner of the first driving mechanism 31 and the second driving mechanism 32, as long as the two air guide panels 21 can be driven to extend and retract relative to the air outlet 11, so as to open or close the air outlet 11.

The first driving mechanism of the present invention will be further described with reference to fig. 3 to 6. Wherein, fig. 3 is an exploded view of the air outlet structure of the present invention; fig. 4 is a schematic structural diagram of a first driving mechanism of the present invention; FIG. 5 is a cross-sectional view taken along line I-I of FIG. 4; fig. 6 is a schematic structural view of the air guide panel of the present invention.

As shown in fig. 3 to 5, the first driving mechanism 31 includes a first box 311, and a first driving motor 312, a first lead screw 313, a first moving mechanism 314, a first nut 315 and a first guide rail 316 which are disposed on the first box 311, wherein the first driving motor 312 is fixedly mounted on the first box 311, an output shaft of the first driving motor 312 is in transmission connection with the first lead screw 313, the first moving mechanism 314 is connected with the first lead screw 313 through the first nut 315, and the first moving mechanism 314 can slide along the first guide rail 316; the two air guide panels 21 are rotatably connected to the first moving mechanism 314; the first driving motor 312 can drive the first lead screw 313 to rotate so as to enable the first nut 315 to move relative to the first lead screw 313, so as to drive the first moving mechanism 314 to slide along the first guide rail 316, so that the two air guide panels 21 can extend and retract relative to the air outlet 11, thereby opening or closing the air outlet 11.

Compared with the technical scheme of gear 3233 rack or chain transmission in the prior art, the first driving mechanism 31 adopts the technical scheme of lead screw and nut transmission, and converts the rotary motion into the linear motion of the first moving mechanism 314, and in the linear motion, the transmission precision of the lead screw and the nut is higher than that of the gear 3233 rack or chain transmission, so that the two air guide panels 21 can be accurately driven to stretch and retract relative to the air outlet 11 along the linear direction; the transmission efficiency of the screw rod and the nut is higher than that of a gear 3233 rack or chain, so that the energy consumption is reduced; the transmission mode of lead screw and nut can realize the auto-lock for wind guide panel 21 can carry out the auto-lock better for the flexible in-process of air outlet 11, has avoided wind guide panel 21 to take place to rock at the in-process that removes, has further promoted user experience.

As shown in fig. 5 and with reference to fig. 3, the first driving motor 312 is fixedly connected to an outer sidewall (i.e. a side of the right upper side of the paper in fig. 5) of the first box 311, and a first through hole 3111 is formed on the outer sidewall of the first box 311; a first mounting member 12 is arranged on an inner side surface (i.e. the side shown in fig. 3) of the air outlet frame 1, and the first mounting member 12 is arranged at a first end of the air outlet frame 1 along the length direction of the air outlet 11; the first driving mechanism 31 further includes a first bearing 317, a second bearing 318 and a first connecting member 319, a first end (i.e. the upper right end of the paper surface in fig. 5) of the first lead screw 313 extends out of the first through hole 3111 and is in transmission connection with the output end of the first driving motor 312 through the first connecting member 319, and the first bearing 317 is installed in the first through hole 3111 and located between the first through hole 3111 and the first lead screw 313; a second end (i.e., an end at the lower left of the paper in fig. 5) of the first lead screw 313 is rotatably connected to the first mounting member 12 via a second bearing 318. Wherein, the first connecting member 319 can be a coupling or other connecting structure; the first mounting member 12 may be a mounting structure such as a mounting groove, a mounting hole, an annular mounting protrusion, etc. taking the annular mounting protrusion as an example, the second end of the first lead screw 313 is rotatably connected with the second bearing 318 and the second bearing 318 is mounted into the annular mounting protrusion.

Preferably, the first driving motor 312 is fixedly connected to the outer side wall of the first box 311 by means of threads, welding, etc., so as to improve the connection stability of the first driving motor 312.

Preferably, the first driving motor 312 may be a stepping motor, and the telescopic distance of the air guide panel 21 relative to the air outlet 11 may be controlled by controlling the output steps of the stepping motor, for example, the air guide panel 21 extends 10cm relative to the air outlet 11, so as to accurately adjust the effective air guide area of the air guide panel 21; or the air guide panel 21 retracts 10cm relative to the air outlet 11, so as to completely close the air outlet 11. Of course, the first driving motor 312 may be a servo motor or other motor. The above-mentioned telescopic distance is only exemplary, but not limiting, and those skilled in the art can flexibly adjust and set the telescopic distance according to specific use requirements and installation environment in practical application, and the present invention does not limit the telescopic distance.

Preferably, the first lead screw 313 may be a ball screw, a trapezoidal screw, or other lead screws.

Preferably, the first nut 315 may be a bent tube nut, a circulator nut, an end cap nut, or other nuts.

Preferably, the first bearing 317 and the second bearing 318 may be rolling bearings, such as ball bearings, roller bearings, or the like.

As shown in fig. 3 to 6, the inner side surfaces (i.e., the side shown in fig. 6) of the two air guide panels 21 are each provided with a first connection plate 211, and the first connection plate 211 is disposed at a first end (i.e., the upper right end of the paper in fig. 6) of the air guide panel 21 along the length direction of the air guide panel 21; the first moving mechanism 314 includes a first moving member 3141 and two first connecting arms 3142, the first moving member 3141 is connected to the first lead screw 313 through a first nut 315, first ends (i.e., upper right ends in fig. 5) of the two first connecting arms 3142 are both fixedly connected to the first moving member 3141, and second ends (i.e., lower left ends in fig. 5) of the two first connecting arms 3142 are respectively rotatably connected to one first connecting plate 211. It should be noted that the number of the first connecting arms 3142 matches the number of the air guide panels 21, the number of the first connecting arms 3142 is adjusted and set according to the number of the air guide panels 21, and the inner side surface of each air guide panel 21 is provided with a first connecting plate 211 rotatably connected to the first connecting arm 3142.

With reference to fig. 3 to 6, the first connection plate 211 is provided with a first connection hole 2111, the second end of the first connection arm 3142 is provided with a connection shaft 31421, and the connection shaft 31421 is rotatably connected to the first connection hole 2111, so that the air guiding plate can rotate relative to the first connection arm 3142, the air guiding direction can be adjusted by 180 ° at most, large-range air sweeping by 180 ° at most can be realized, and user experience is further improved.

Referring to fig. 3 to 5 again, the first moving member 3141 includes a first moving portion 31411 and a first connecting portion 31412 connected to each other, and a first sliding bearing 31413 and a second sliding bearing 31414, the first moving portion 31411 is provided with a first connection through hole 314111, and an inner sidewall (i.e., a side shown in fig. 5) of the first case 311 is provided with a first mounting hole 3112; a second mounting member 13 is arranged on the inner side surface (i.e. the side shown in fig. 3) of the air outlet frame 1, and the second mounting member 13 is arranged at the first end of the air outlet frame 1 along the length direction of the air outlet 11; a first end (i.e., an end at the upper right of the paper plane in fig. 5) of the first guide rail 316 extends out of the first connection through hole 314111 and is fixedly connected to the first mounting hole 3112, the first sliding bearing 31413 and the second sliding bearing 31414 are mounted in the first connection through hole 314111 along the length direction of the first connection through hole 314111 (i.e., the direction from the lower left to the upper right in fig. 5) and are located between the first connection through hole 314111 and the first guide rail 316, and a second end (i.e., an end at the lower left of the paper plane in fig. 5) of the first guide rail 316 is fixedly connected to the second mounting member 13, so that the first guide rail 316 is stably fixed between the first box 311 and the outlet frame 1, and can perform a good guiding function. Of course, in the above structure, the first moving portion 31411 and the first connecting portion 31412 may be integrally formed, and the integrally formed structure is adopted, so as to facilitate the processing and manufacturing of the mold.

The second mounting member 13 may be a mounting structure such as a mounting groove, a mounting hole, a mounting block, and the like, and taking the mounting block as an example, the mounting block is provided with a second mounting hole 131, and the second end of the first rail 316 is fixedly connected with the second mounting hole 131.

Here, the first sliding bearing 31413 and the second sliding bearing 31414 may be a circular bearing, an elliptical bearing, a three-lobe bearing, a foil bearing, or other sliding bearings.

With reference to fig. 3 to 5, the first end of the first moving portion 31411 (i.e. the end on the left side of the paper surface in fig. 4) is provided with two first mounting grooves 314112, and the two first mounting grooves 314112 are respectively disposed on two sides of the first connecting through hole 314111 along the length direction of the first moving portion 31411 (i.e. the direction from bottom to top in fig. 4); the second end (i.e., the end at the lower right of the paper in fig. 3) of the first moving part 31411 is provided with four second connection holes 314113, wherein each two second connection holes 314113 are respectively communicated with one first mounting groove 314112, the first ends of the two first connection arms 3142 are respectively provided with two third connection holes 31422, the first ends of the two first connection arms 3142 are respectively inserted into one first mounting groove 314112, and one end of a bolt is sequentially inserted through one second connection hole 314113 and the third connection hole corresponding to the second connection hole 314113, thereby fixedly connecting the first connection arm 3142 and the first moving part 31411. Of course, the first connection arm 3142 and the first movement portion 31411 may be fixedly connected by welding or the like, or the first connection arm 3142 and the first movement portion 31411 may be integrally formed.

Further, a second connecting through hole 314121 is provided on the first connecting portion 31412, and a second end of the first lead screw 313 extends out of the second connecting through hole 314121 and is rotatably connected with the first mounting member 12 through the second bearing 318; the first nut 315 is installed in the second coupling through hole 314121, and the first lead screw 313 is coupled to the first coupling portion 31412 through the first nut 315.

The second driving mechanism of the present invention will be further described with reference to fig. 3, 6 to 11. Fig. 7 is a schematic structural diagram of a second driving mechanism of the present invention; FIG. 8 is a rotated cross-sectional view of FIG. 7; fig. 9 is a schematic view illustrating a first angle adjustment of the air guide panel according to the present invention; fig. 10 is a second angle adjustment schematic view of the air guide panel of the present invention; fig. 11 is a third angle adjustment diagram of the air guide panel of the present invention.

As shown in fig. 3, 7 and 8, the second driving mechanism 32 includes a second box 321, and a second driving motor 322, a driving member 323, a second lead screw 324, a second moving mechanism 325, a second nut 326 and a second guide rail 327 disposed on the second box 321, wherein an output shaft of the second driving motor 322 is in transmission connection with the second lead screw 324, the second moving mechanism 325 is connected with the second lead screw 324 through the second nut 326, and the second moving mechanism 325 can slide along the second guide rail 327; at least one driving component 323 is arranged at the connecting end of at least one air guide panel 21, and each driving component 323 is arranged on the second moving mechanism 325 and is in transmission connection with one air guide panel 21; the second driving motor 322 can drive the second lead screw 324 to rotate so as to enable the second nut 326 to move relative to the second lead screw 324, so as to drive the second moving mechanism 325 to slide along the second guide rail 327, so that the two air guide panels 21 can extend and retract relative to the air outlet 11, thereby opening or closing the air outlet 11; the driving component 323 is used for driving the air guide panel 21 in transmission connection with the driving component to rotate, the air guide direction can be adjusted by 180 degrees to the maximum, large-range air sweeping of 180 degrees to the maximum can be realized, and the user experience is further improved.

Compared with the technical scheme of gear 3233 rack or chain transmission in the prior art, the second driving mechanism 32 adopts the technical scheme of lead screw and nut transmission, the rotary motion is converted into linear motion, and in the linear motion, the precision of the lead screw and nut transmission is higher than that of the gear 3233 rack or chain transmission, so that at least one air guide panel 21 can be accurately driven to stretch and retract relative to the air outlet 11 along the linear direction; the transmission efficiency of the screw rod and the nut is higher than that of a gear 3233 rack or chain, so that the energy consumption is reduced; the transmission mode of lead screw and nut can realize the auto-lock for wind guide panel 21 can carry out the auto-lock better for the flexible in-process of air outlet 11, has avoided wind guide panel 21 to take place to rock at the in-process that removes, has further promoted user experience. In addition, the driving member 323 is used for driving the air guide panel 21 in transmission connection with the driving member to rotate, so that the air guide direction can be adjusted by 180 degrees at most, large-range air sweeping of 180 degrees at most can be realized, and the user experience is further improved.

As shown in fig. 8 and in combination with fig. 3, the second driving motor 322 is fixedly connected to an outer sidewall (i.e. a right side of the paper surface in fig. 8) of the second box 321, and a second through hole 3211 is formed on the outer sidewall of the second box 321; a third mounting member 14 is disposed on an inner side surface (i.e., a side shown in fig. 3) of the air outlet frame 1, and the third mounting member 14 is disposed at a second end of the air outlet frame 1 along a length direction of the air outlet 11; the second driving mechanism 32 further includes a third bearing 328, a fourth bearing 329 and a second connecting member 330, a first end (i.e., an end on the right side of the paper surface in fig. 8) of the second lead screw 324 extends out of the second through hole 3211 and is in transmission connection with the output end of the second driving motor 322 through the second connecting member 330, and the third bearing 328 is installed in the second through hole 3211 and located between the second through hole 3211 and the second lead screw 324; a second end (i.e., an end on the left side of the paper surface in fig. 8) of the second lead screw 324 is rotatably connected to the third mounting member 14 via a fourth bearing 329. Wherein, the second connecting member 330 may be a coupling or other connecting structure; the second mounting member 13 may be a mounting structure such as a mounting groove, a mounting hole, an annular mounting protrusion, etc., and taking the annular mounting protrusion as an example, the second end of the second lead screw 324 is rotatably connected with the fourth bearing 329 and the fourth bearing 329 is mounted into the annular mounting protrusion.

Preferably, the second driving motor 322 is fixedly connected to the outer sidewall of the second box 321 by means of threads, welding, etc., so as to improve the connection stability of the second driving motor 322.

Preferably, the second driving motor 322 may be a stepping motor, and the telescopic distance of the air guide panel 21 relative to the air outlet 11 may be controlled by controlling the output steps of the stepping motor, for example, the air guide panel 21 extends out 10cm relative to the air outlet 11, so as to accurately adjust the effective air guide area of the air guide panel 21; or the air guide panel 21 retracts by 10cm relative to the air outlet 11, so as to completely seal the air outlet 11, it should be noted that the first driving motor 312 and the second driving motor 322 synchronously drive the air guide panel 21 to retract relative to the air outlet 11, and the retraction distances are equal. Of course, the second driving motor 322 may be a servo motor or other motor. The above-mentioned telescopic distance is only exemplary, but not limiting, and those skilled in the art can flexibly adjust and set the telescopic distance according to specific use requirements and installation environment in practical application, and the present invention does not limit the telescopic distance.

Preferably, the second screw 324 may be a ball screw, a trapezoidal screw, or other screws.

Preferably, the second nut 326 may be a bent tube nut, a circulator nut, an end cap nut, or other nuts.

Preferably, the third and fourth bearings 328 and 329 may be rolling bearings, such as ball bearings, roller bearings, and the like.

As shown in fig. 3 and 6 to 8, the second moving mechanism 325 includes a second moving member 3251 and two second connecting arms 3252, the second moving member 3251 is connected to the second lead screw 324 through a second nut 326, first ends (i.e., one end on the right side of the paper surface in fig. 7) of the two second connecting arms 3252 are fixedly connected to the second moving member 3251, and second ends (i.e., one end on the left side of the paper surface in fig. 7) of the two second connecting arms 3252 are respectively provided with one driving member 323. It should be noted that the number of the second connecting arms 3252 is matched with the number of the air guide panels 21, the number of the second connecting arms 3252 is adjusted and set according to the number of the air guide panels 21, and the inner side surface of each air guide panel 21 is provided with a second connecting plate 212 rotatably connected with the second connecting arm 3252.

As shown in fig. 3 and 6 to 11, one second connecting plate 212 is provided on each of the inner side surfaces of the two air guide panels 21, and the second connecting plate 212 is provided at a second end of the air guide panel 21 (i.e., at an end on the left side of the paper surface in fig. 6) along the longitudinal direction of the air guide panel 21; the driving member 323 includes a cover 3231 disposed on the second connecting arm 3252, a third driving motor 3232, a gear 3233, and a driving rod 3234, and the cover 3231 is provided with a third through hole 32311; the third driving motor 3232, the gear 3233 and the driving rod 3234 are all located in the cover 3231, an output shaft of the third driving motor 3232 is in transmission connection with the gear 3233, a connection end (end close to the third driving motor 3232) of the driving rod 3234 is in meshing connection with the gear 3233 through a driven tooth arranged on an outer peripheral side, and an output end (end far away from the third driving motor 3232) of the driving rod 3234 extends out through a third through hole 32311 and is connected with the second connection plate 212 in a non-relative-rotation manner, so that the air guide panel 21 is driven to rotate, an air guide direction is adjusted by 180 ° at most, large-range air sweeping by 180 ° at most is realized, and user experience is further improved, as shown in fig. 9, the air guide panel 21 guides air downward, as shown in fig. 10, the air guide panel 21 guides air forward, as shown in fig. 11, and the air guide panel 21 guides air upward. Of course, the structure of the driving member 323 is not limited to the above-mentioned structure, and may include only the third driving motor 3232, the gear 3233 and the driving rod 3234 without the cover 3231, and those skilled in the art may flexibly adjust and set the specific structure of the driving member 323 according to the actual use requirement.

With continued reference to fig. 3, 6 and 7, the driving rod 3234 has a pentagonal prism structure, the second connecting plate 212 is provided with a fourth connecting hole 2121, the shape of the fourth connecting hole 2121 is adapted to the driving rod 3234 and is pentagonal, an output end of the driving rod 3234 is connected to the fourth connecting hole 2121, and the output end of the driving rod 3234 cannot rotate relative to the fourth connecting hole 2121. Of course, the structure of the driving rod 3234 and the shape of the fourth connection hole 2121 are not limited to the above-mentioned structures and shapes, and the driving rod 3234 may also have other polygonal column structures such as a triangular prism structure, a quadrangular prism structure, and a hexagonal prism structure, and accordingly, the shape of the fourth connection hole 2121 may be a triangular prism, a quadrangular prism, a hexagonal prism, or other polygonal shapes, and those skilled in the art can flexibly adjust and set the structure of the driving rod 3234 and the shape of the fourth connection hole 2121 as long as the output end of the driving rod 3234 is connected to the second connection plate 212 in a non-relative rotation manner.

Referring to fig. 3, 7 and 8 again, the second moving member 3251 includes a second moving portion 32511 and a second connecting portion 32512 connected to each other, and a third sliding bearing 32513 and a fourth sliding bearing 32514, the second moving portion 32511 is provided with a third connecting through hole 325111, and an inner side wall (i.e., the side shown in fig. 8) of the second case 321 is provided with a third mounting hole 3212; a fourth mounting member 15 is arranged on the inner side surface of the air outlet frame 1, and the fourth mounting member 15 is arranged at the second end of the air outlet frame 1 along the length direction of the air outlet 11; the first end (i.e., the end on the right side of the plane of the drawing in fig. 8) of the second rail 327 extends out of the third connecting through hole 325111 and is fixedly connected to the third mounting hole 3212, the third sliding bearing 32513 and the fourth sliding bearing 32514 are installed in the third connecting through hole 325111 along the length direction of the third connecting through hole 325111 (i.e., the direction from left to right in fig. 8) and are located between the third connecting through hole 325111 and the second rail 327, and the second end (i.e., the end on the left side of the plane of the drawing in fig. 8) of the second rail 327 is fixedly connected to the third mounting member 14, so that the second rail 327 is stably fixed between the second box 321 and the air outlet frame 1, and the guiding function can be well performed. Of course, in the above structure, the second moving portion 32511 and the second connecting portion 32512 may be integrally formed, and the integrally formed structure is adopted, so that the mold is convenient to process and manufacture.

The third mounting member 14 may be a mounting structure such as a mounting groove, a mounting hole, a mounting block, and the mounting block is provided with a fourth mounting hole 151, and a second end of the second rail 327 is fixedly connected to the fourth mounting hole 151.

The third sliding bearing 32513 and the fourth sliding bearing 32514 may be other sliding bearings such as a circular bearing, an elliptical bearing, a three-lobe bearing, and a foil bearing.

With continued reference to fig. 3, 7, and 8, the first end of the second moving portion 32511 (i.e., the end on the left side of the paper surface in fig. 7) is provided with two second installation grooves 325112, and the two second installation grooves 325112 are respectively disposed on two sides of the third connecting through hole 325111 along the length direction of the second moving portion 32511 (i.e., the direction from bottom to top in fig. 7); a second end (i.e., an end on the right side of the paper plane in fig. 7) of the second moving portion 32511 is provided with four fifth coupling holes 325113, wherein every two fifth coupling holes 325113 are respectively communicated with one second mounting groove 325112, first ends of two second coupling arms 3252 are respectively provided with two sixth coupling holes 32521, first ends of two second coupling arms 3252 are respectively inserted into one second mounting groove 325112, and one end of a bolt is sequentially inserted through one fifth coupling hole 325113 and the sixth coupling hole 32521 corresponding to the fifth coupling hole 325113, thereby fixedly coupling the second coupling arm 3252 with the second moving portion 32511. Of course, the second connection arm 3252 and the second moving portion 32511 may be fixedly connected by welding or the like, or the second connection arm 3252 and the second moving portion 32511 may be integrally formed.

Further, a fourth connecting through hole 325121 is provided on the second connecting portion 32512, and a second end of the second lead screw 324 extends out of the fourth connecting through hole 325121 and is rotatably connected to the first mounting member 12 through the second bearing 318; the second nut 326 is installed in the fourth connection through hole 325121, and the second lead screw 324 is connected to the second connection portion 32512 through the second nut 326.

The air outlet structure of the present invention will be further described with reference to fig. 3, 12 and 13. Wherein, fig. 12 is a partial schematic view of the air outlet structure of the present invention; fig. 13 is a schematic structural view of the connecting rod of the present invention.

As shown in fig. 12 and with reference to fig. 3, the air outlet structure further includes a swing blade assembly 4, and the swing blade assembly 4 is swingably disposed on the air outlet frame 1 and is disposed near the air outlet 11.

Preferably, the swing blade assembly 4 includes a connecting rod 41, a swing rod 42, a fourth driving motor 43 and a plurality of swing blades 44, the connecting rod 41 is disposed on the bottom plate (i.e., the panel below the paper surface in fig. 12) of the outlet frame 1, the fourth driving motor 43 is disposed at the first end of the outlet frame 1 along the length direction of the outlet 11, an output shaft of the fourth driving motor 43 is connected to the first end (i.e., the end on the right side of the paper surface in fig. 12) of the swing rod 42, the second end (i.e., the end on the left side of the paper surface in fig. 12) of the swing rod 42 is pivotally connected to the first end (i.e., the end on the right side of the paper surface in fig. 12) of the connecting rod 41, each swing blade 44 is pivotally connected to the connecting rod 41 by a first pivot shaft 441, and each swing blade 44 is pivotally connected to the bottom plate of the outlet frame 1 by a second pivot shaft 442. When the output shaft of the fourth driving motor 43 rotates, the swing rod 42 is driven to rotate around the output shaft of the fourth driving motor 43, and then the connecting rod 41 is driven to move, and when the connecting rod 41 moves, the swing blade 44 can be driven to swing left and right and rotate relative to the bottom plate of the air outlet frame 1, so that the wind direction of the wind passing through the air outlet 11 can be adjusted, and the wind blown out from the air outlet 11 is softer. The fourth driving motor 43 may be a stepping motor, a servo motor, or the like. In addition, the link 41 may be disposed on the top plate of the panel frame (i.e., the panel above the paper surface in fig. 12), or the fourth driving motor 43 may be disposed at the second end of the outlet frame 1 along the length direction of the outlet 11, and those skilled in the art may flexibly adjust and set the disposition positions of the link 41 and the fourth driving motor 43.

Further, the swinging direction of the swing blade 44 is opposite to the swinging direction of the wind guide panel 21, so that the wind passing through the air outlet 11 is sufficiently disturbed in the left, right, up and down directions under the dual action of the swing blade 44 swinging left and right and the wind guide plate swinging up and down, and the wind blown out from the air outlet 11 is softer. Of course, the swing direction of the swing blade 44 is not limited to the above-mentioned one, and the swing blade may be driven by the fourth driving motor 43 to swing up and down, and the swing direction of the swing blade 44 may be adjusted in any way as long as the wind direction of the wind passing through the outlet 11 can be adjusted.

Further, the plurality of swing vanes 44 are provided at equal intervals or at unequal intervals along the length direction of the link 41 (i.e., in the upper left-to-lower right direction in fig. 12).

As shown in fig. 13 in conjunction with fig. 12, the link 41 includes a first portion 411 and a second portion 412 connected to each other, a seventh connection hole 4111 is provided on the first portion 411, and an output shaft of the fourth driving motor 43 is connected to the first portion 411 through the seventh connection hole 4111; the second portion 412 is provided with a plurality of eighth connecting holes 4121, and each swing blade 44 is connected to the second portion 412 through one of the eighth connecting holes 4121. It should be noted that the number of the eighth connecting holes 4121 matches the number of the swing vanes 44, and the number of the eighth connecting holes 4121 is adjusted and set according to the number of the swing vanes 44.

The second portion 412 is formed by a plurality of arc structures, an avoidance space is formed inside each arc structure, and the second pivot shaft 442 can be disposed in the avoidance space, so that the flap 44 can be pivotally connected to the bottom plate of the air outlet frame 1 through the second pivot shaft 442, and the arc structures do not obstruct the rotation of the second pivot shaft 442, and therefore the flap 44 is not obstructed from rotating. Of course, the second portion 412 may be provided in a wave-shaped structure, a semi-circular structure, or other structures, no matter what structure is adopted, as long as the second pivot shaft 442 is not obstructed from rotating.

The following describes a method for using the air outlet structure of the present invention, with reference to fig. 9, fig. 10, fig. 11, fig. 14, and fig. 15, by taking as an example that the air outlet structure is installed on the ducted air conditioner 5, the ducted air conditioner 5 is installed indoors, and the light trough structure 6 is installed indoors. Among them, fig. 14 is a schematic view of a conventional air conditioner installed indoors; fig. 15 is a schematic view of the air conditioner according to the present invention installed indoors.

As shown in fig. 14, when the ducted type air conditioner 5 is installed indoors and the light trough structure 6 is installed indoors, the light trough structure 6 is located below the outlet 11 of the ducted type air conditioner 5, and the light trough structure 6 obstructs the downward blowing direction of the wind blown out from the outlet 11, so that the wind blown out from the outlet 11 cannot be directly blown into the room, and particularly, the hot wind cannot be directly blown to the ground during heating.

As shown in fig. 15 in conjunction with fig. 9, when the ducted air conditioner 5 operates in the heating mode, in order to allow the wind blown out from the wind outlet 11 to directly blow to the ground, first, the first driving motor 312 and the second driving motor 322 are controlled to synchronously drive the wind guide panel 21 to extend a preset distance relative to the wind outlet 11 to reach a target position (e.g., the position shown in fig. 15); secondly, controlling the third driving motor 3232 to drive the air guide panel 21 to rotate downward to a first set angle (for example, the angle shown in fig. 9, that is, the air guide panel located below the air outlet 11 is parallel to the horizontal direction, and the included angle between the air guide panel located above the air outlet 11 and the horizontal direction is 45 °), so that the wind energy blown out from the air outlet 11 can be directly blown to the ground; again, the fourth driving mechanism is controlled to drive the swing blade 44 to rotate, so that the wind blown out from the outlet 11 is made softer.

As shown in fig. 10 and fig. 11 in combination with the application scenario in fig. 15, when the duct machine 5 operates in the cooling mode, the wind blown out from the wind outlet 11 needs to be blown upwards, and the light trough structure 6 does not obstruct the upward blowing direction of the wind blown out from the wind outlet 11, then the third driving motor 3232 is controlled to drive the wind guide panel 21 to rotate upwards to a second set angle (for example, the angle shown in fig. 10) or a second set angle (for example, the angle shown in fig. 11), so that the wind blown out from the wind outlet 11 can be directly blown to the top of the room; again, the fourth driving mechanism is controlled to drive the swing blade 44 to rotate, so that the wind blown out from the outlet 11 is made softer.

It should be noted that the target position, the first setting angle and the second setting angle listed above are only exemplary, but not limiting, and those skilled in the art can flexibly adjust and set the target position, the first setting angle and the second setting angle according to specific use requirements, installation environment, etc. in practical application, the present invention is not limited to this.

It should be further noted that, the execution sequence of controlling the first driving motor 312 and the second driving motor 322 to synchronously drive the air guide panel 21 to extend relative to the air outlet 11, controlling the second driving motor 322 to drive the air guide panel 21 to rotate, and controlling the fourth driving mechanism to drive the swing blade 44 to rotate is only an example, and is not limited thereto, and in practical applications, a person skilled in the art can flexibly adjust and set the execution sequence of controlling the first driving motor 312 and the second driving motor 322 to synchronously drive the air guide panel 21 to extend relative to the air outlet 11, controlling the second driving motor 322 to drive the air guide panel 21 to rotate, and controlling the fourth driving mechanism to drive the swing blade 44 to rotate according to practical use requirements, which the present invention does not limit this.

Furthermore, the utility model also provides an air conditioner, this air conditioner includes the air outlet structure of any one of above-mentioned embodiment.

It will be appreciated by those of skill in the art that although some embodiments described herein include some but not other features included in other embodiments, combinations of features of different embodiments are meant to be within the scope of the invention and form different embodiments. For example, in the claims of the present invention, any of the claimed embodiments may be used in any combination.

So far, the technical solution of the present invention has been described with reference to the preferred embodiments shown in the drawings, but it is easily understood by those skilled in the art that the scope of the present invention is obviously not limited to these specific embodiments. Without departing from the principle of the present invention, a person skilled in the art can make equivalent changes or substitutions to the related technical features, and the technical solutions after these changes or substitutions will fall within the protection scope of the present invention.

Claims (10)

1. An air outlet structure for an air conditioner is characterized by comprising an air outlet frame, an air guide assembly and a push-pull assembly, wherein an air outlet is formed in the air outlet frame; wherein,

the air guide assembly comprises at least one air guide panel, the air guide panel can cover the air outlet when being in a closed state, and the total area of the air guide panel is larger than or equal to the area of the surface where the air outlet is located;

the push-pull assembly is arranged on the air outlet frame and connected with the at least one air guide panel and used for driving the at least one air guide panel to stretch relative to the air outlet, so that the air outlet is opened or closed.

2. The air outlet structure of claim 1, wherein the push-pull assembly comprises a first driving mechanism disposed on the air outlet frame, the first driving mechanism is disposed at the first end of the air outlet frame along the length direction of the air outlet, and the first driving mechanism is connected to the at least one air guiding panel for driving the at least one air guiding panel to extend and retract relative to the air outlet.

3. The air outlet structure according to claim 2, wherein the first driving mechanism comprises a first box, and a first driving motor, a first lead screw, a first moving mechanism, a first nut and a first guide rail arranged on the first box, wherein,

an output shaft of the first driving motor is in transmission connection with the first lead screw, the first moving mechanism is connected with the first lead screw through the first nut, and the first moving mechanism can slide along the first guide rail;

the at least one air guide panel can be rotatably connected to the first moving mechanism;

the first driving motor can drive the first lead screw to rotate so as to enable the first nut to move relative to the first lead screw, and therefore the first moving mechanism is driven to slide along the first guide rail.

4. The air outlet structure of claim 3, wherein the inner side surface of the air guide panel is provided with a first connecting plate;

the first moving mechanism comprises a first moving component and a first connecting arm, and the first moving component is connected with the first lead screw through the first nut;

the first end of the first connecting arm is fixedly connected with the first moving component, and the second end of the first connecting arm is rotatably connected with the first connecting plate.

5. The air outlet structure of claim 1, wherein the push-pull assembly further comprises a second driving mechanism disposed on the air outlet frame, the second driving mechanism is disposed at the second end of the air outlet frame along the length direction of the air outlet, and the second driving mechanism is connected to the at least one air guiding panel for driving the at least one air guiding panel to extend and retract relative to the air outlet;

the second driving mechanism is further used for driving the at least one air guide panel to rotate so as to adjust the air outlet angle of the air outlet.

6. The air outlet structure according to claim 5, wherein the second driving mechanism comprises a second box, and a second driving motor, a driving member, a second lead screw, a second moving mechanism, a second nut and a second guide rail arranged on the second box, wherein,

an output shaft of the second driving motor is in transmission connection with the second lead screw, the second moving mechanism is connected with the second lead screw through the second nut, and the second moving mechanism can slide along the second guide rail;

the connecting end of the at least one air guide panel is provided with at least one driving component, and each driving component is arranged on the second moving mechanism and is in transmission connection with one air guide panel;

the second driving motor can drive the second lead screw to rotate so as to enable the second nut to move relative to the second lead screw, and therefore the second moving mechanism is driven to slide along the second guide rail;

the driving component is used for driving the air guide panel in transmission connection with the driving component to rotate.

7. The air outlet structure of claim 6, wherein the inner side surface of the air guide panel is provided with a second connecting plate;

the second moving mechanism comprises a second moving component and a second connecting arm, the second moving component is connected with the second lead screw through the second nut, and the first end of the second connecting arm is fixedly connected with the second moving component;

the driving member comprises a third driving motor, a gear and a driving rod, the third driving motor, the gear and the driving rod are arranged on the second connecting arm, an output shaft of the third driving motor is in transmission connection with the gear, the driving rod is in meshing connection with the gear, and an output end of the driving rod is connected with the second connecting plate in a non-relative-rotation mode.

8. The air outlet structure according to claim 1, wherein the number of the air guide panels is two, the two air guide panels can cover the air outlet when in the closed state, and the total area of the two air guide panels is equal to the area of the surface where the air outlet is located.

9. The air outlet structure according to claim 1, further comprising a flap assembly swingably provided on the outlet frame and adjacent to the air outlet.

10. An air conditioner characterized in that it comprises an air outlet structure according to any one of claims 1 to 9.

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