CN215909380U - Air deflector driving device and air conditioner - Google Patents

Abstract

The utility model discloses an air deflector driving device and an air conditioner, wherein the driving device comprises a bracket component and a driving component, the driving component is arranged on the bracket component, the driving component comprises a driving part, a moving part and a rotating part, and the driving part is relatively and fixedly arranged on the bracket component; the moving part is movably connected with the bracket assembly and is driven by the driving part; the rotating part is arranged on the moving part and is configured to be connected with the air deflector and drive the air deflector to rotate. According to the air deflector driving device provided by the embodiment of the utility model, diversified air guiding of the air deflector can be realized.

Description

Air deflector driving device and air conditioner

Technical Field

The utility model relates to the technical field of air conditioning, in particular to an air deflector driving device and an air conditioner with the same.

Background

In traditional single through-flow air conditioner, generally all set up the aviation baffle, the aviation baffle is used for guiding the air supply direction of air conditioner, has reached the purpose of directional air supply, and the aviation baffle realizes the regulation to the air supply direction through rotating to can realize on a large scale air supply through the swing of aviation baffle, improve the scope of air supply, but only rely on the rotation of aviation baffle to be difficult to satisfy diversified air supply demand.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an air deflector driving device which can realize diversified air guiding of an air deflector.

Another objective of the present invention is to provide an air conditioner, which includes the above-mentioned air deflector driving device.

According to the air deflector driving device provided by the embodiment of the utility model, the driving device comprises a bracket component and a driving component, the driving component is arranged on the bracket component and comprises a driving part, a moving part and a rotating part, and the driving part is relatively and fixedly arranged on the bracket component; the moving part is movably connected with the bracket assembly and is driven by the driving part; the rotating part is arranged on the moving part and is configured to be connected with the air deflector and drive the air deflector to rotate.

According to the air deflector driving device provided by the embodiment of the utility model, diversified air guiding of the air deflector can be realized.

In addition, the air deflector driving device according to the above embodiment of the present invention may further have the following additional features:

optionally, the bracket assembly includes a drive box, the rotating portion is disposed in the drive box, and the drive box is provided with a wire passing hole suitable for leading out a wire harness of the rotating portion.

Optionally, the driving box comprises a box body, a wire pressing buckle and a box cover, wherein the box body is configured into a box shape with one open side, and a gap is arranged on the peripheral wall; the wire pressing buckle is embedded into the notch to position the wire harness; the box cover covers the box body and the gap.

Optionally, a protruding block is arranged on the bottom edge of the notch, a wire pressing groove is arranged on the wire pressing buckle, and the protruding block is embedded into the wire pressing groove to position the wire harness.

Optionally, the inner bottom surface of the box body is further provided with a lead slot, the wiring harness of the rotating part is suitable for being embedded into the lead slot and led out from the wire passing hole, and the moving part is suitable for covering the lead slot to position the wiring harness.

Optionally, a through groove is formed in the drive box, and the shaft portion of the rotating portion is adapted to penetrate through the through groove to connect the air deflector.

Optionally, the rotating portion includes a rotating motor and a crank shaft, the rotating motor is connected to the crank shaft, and the crank shaft is used for connecting the air deflector.

Optionally, the driving part includes a sliding motor and a gear connected to the sliding motor, and the moving part includes a rack engaged with the gear.

Optionally, the bracket assembly includes a drive box, the sliding motor is mounted on an outer side of the drive box, and the gear and the rack are both disposed in the drive box.

Optionally, the driving portion further includes a motor cover, the motor cover is fixedly connected to the driving box, the sliding motor is fixedly mounted on the motor cover, and ribs are arranged on an inner circumferential surface of the motor cover.

Optionally, the moving part further comprises a mounting bracket, the mounting bracket is fixedly connected with the rack, and the rotating part is mounted on the mounting bracket.

Optionally, the drive arrangement comprises a plurality of drive assemblies configured and adapted to drive a plurality of air deflectors respectively.

Optionally, the moving portions of the plurality of driving assemblies are adapted to drive the air deflector to move along the same curve.

The air conditioner comprises a machine body, a driving device and an air deflector, wherein the machine body is provided with an air supply outlet; the driving device is connected with the machine body and is a wind deflector driving device according to the above; the air deflector is arranged at the air supply opening and is in transmission connection with the rotating part, wherein the air deflector is suitable for being driven by the driving device to rotate and move along the width direction of the air supply opening.

Optionally, the air outlet is provided with a plurality of air deflectors along the width direction, and the driving device includes a plurality of driving assemblies corresponding to the plurality of air deflectors.

Optionally, both ends of the air supply outlet in the length direction are provided with the driving device.

Drawings

Fig. 1 is a schematic view of an air deflection panel driving apparatus according to an embodiment of the present invention.

Fig. 2 is a schematic view of an air deflection assembly according to an embodiment of the present invention.

Fig. 3 is a schematic view of an air deflection assembly according to an embodiment of the present invention.

Figure 4 is an exploded view of one embodiment of the deflector drive of the present invention.

Figure 5 is an exploded view of one embodiment of the deflector drive of the present invention.

Figure 6 is an exploded view of a deflector drive assembly according to one embodiment of the utility model.

Fig. 7 is a schematic view of the wind deflector driving apparatus according to an embodiment of the present invention after the cover is opened.

Figure 8 is a schematic view of an air deflection assembly according to one embodiment of the present invention.

Fig. 9 is a schematic view of an air conditioner according to an embodiment of the present invention.

Fig. 10 is a schematic view of an air conditioner according to an embodiment of the present invention.

Fig. 11a to 11i are sectional views of the air conditioner of fig. 10 at a section a-a in different states of the first and second air deflectors.

Fig. 12 is a schematic view illustrating the first air deflector, the second air deflector and the driving device of the air conditioner according to an embodiment of the present invention.

Fig. 13 is a front view of the first and second air deflectors and the driving device of the air conditioner according to the embodiment of the present invention.

Reference numerals: the air conditioner comprises an air conditioner 100, a machine body 10, an air supply outlet 101, a first air deflector 111, a second air deflector 112, a driving device 12, a first driving component 121, a second driving component 122, a driving part 12A, a sliding motor 1201, a gear 1202, a moving part 12B, a rack 1203, an installation frame 1204, a rotating part 12C, a rotating motor 1205, a crank shaft 1206, a motor cover 1207, a guide structure 13, a guide part 13A, a sliding part 13B, a driving box 14, a box body 14A, a box cover 14B, a wire pressing buckle 14C, a clamping groove 1401, a buckling position 1402, a lead wire groove 1403, a notch 1404 and a bump 1405.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the utility model and are not to be construed as limiting the utility model.

Referring to fig. 1-8, an air deflection system 12 according to an embodiment of the present invention includes a bracket assembly and a drive assembly. The driving component is connected with the bracket component, the driving component comprises a driving part 12A, a moving part 12B and a rotating part 12C, the driving part 12A can be arranged on the bracket component, and the driving part 12A can be fixed with the relative position of the bracket component. The moving part 12B is connected to the bracket assembly, the moving part 12B is movable relative to the bracket assembly, and the driving part 12A is in transmission connection with the moving part 12B, so that the moving part 12B can be driven by the driving part 12A, and the moving part 12B can move. The rotating portion 12C may be configured to drive the wind deflector to rotate, and the rotating portion 12C may move along with the moving portion 12B, that is, the rotating portion 12C may be disposed on the moving portion 12B, so that the moving portion 12B and the wind deflector are driven during the moving process of the moving portion 12B. Specifically, in the air conditioner 100 having the driving device 12, the turning portion 12C is connected to the air guide plate, and the turning portion 12C turns the air guide plate. The rotating portion 12C is connected to the air guiding plate, so that the air guiding plate is also driven to move during the moving process of the rotating portion 12C, that is, the air guiding plate can be driven to move by the driving portion 12A, and in addition, the rotating portion 12C can drive the air guiding plate to rotate.

According to the air deflector driving device 12 of the embodiment of the utility model, the driving device 12 can be used for driving the air deflector to realize the movement and rotation of the air deflector, so that the air supply direction of the air deflector can be optimized, and different air supply modes can be realized by the air deflector at different positions to meet the requirement of comfort.

In the present invention, the driving device 12 drives the air guiding plate to move through the driving portion 12A and drives the air guiding plate to rotate through the rotating portion 12C, and the driving portion 12A and the rotating portion 12C can drive the air guiding plate separately or simultaneously, that is, the air guiding plate can move separately, rotate separately or rotate and move simultaneously under the driving action of the driving device 12.

The driving device 12 of the present invention may include a driving assembly for driving an air deflector, and during the use process, the air supply condition may be adjusted by moving the position of the air deflector at the air supply opening 101, for example, the air deflector may divide the air flow into a plurality of strands, so as to implement more air supply modes; the driving device 12 may also include a driving assembly for driving the plurality of air deflectors, and during the use, the plurality of air deflectors move synchronously; the driving device 12 may further include a plurality of driving assemblies, and the plurality of driving assemblies are configured to drive the plurality of air deflectors to move and rotate the plurality of air deflectors, so that more air supply forms can be realized by adjusting positions and air guide angles of the plurality of air deflectors.

The bracket assembly of the present invention may be in the form of a plate, etc. for supporting the driving assembly, and may be integrated with the casing of the air conditioner 100 to simplify the structure, and of course, in order to facilitate the modular design, the bracket assembly of the present invention may include a driving box 14, and the driving assembly is integrated with the driving box 14 to facilitate the assembly and maintenance. The driving case 14 is provided to accommodate at least one of the rotating portion 12C, the moving portion 12B, and the driving portion 12A, so that the driving device 12 is constructed in an integrated structure for easy assembly and use.

Referring to fig. 4 to 6, in some embodiments of the present invention, the bracket assembly may include a driving box 14, and the driving box 14 may have a receiving space therein, which may receive the rotating portion 12C, that is, the rotating portion 12C may be mounted in the driving box 14. Thereby, the protection of the rotating part 12C can be realized, the assembly is convenient, and the service life of the rotating part 12C is prolonged.

In addition, a wire passing hole may be provided in the drive box 14, through which the wire harness of the rotating portion 12C or other wire harnesses may be led out. So as to lead out the wire harness. Facilitating connection and signal transmission of the drive device 12 to other structures.

Alternatively, the drive cartridge 14 includes a cartridge body 14A and a cartridge cover 14B, the cartridge body 14A being configured as a box shape with one side open, and the cartridge cover 14B covering the cartridge body 14A. To facilitate mounting of the components within the drive box 14. In addition, a notch 1404 may be provided in the peripheral wall of the case body 14A, and the notch 1404 may be covered with the cover 14B, so that the harness can be mounted, and specifically, after the harness is fitted into the notch 1404, the harness can be positioned by the covering action of the cover 14B.

The drive cartridge 14 also includes a cable clamp 14C, which 14C can be inserted into the notch 1404 to position the wiring harness. The lateral surface of the wire pressing buckle 14C can be further provided with a positioning groove, and the edge of the notch 1404 can be embedded into the positioning groove, so that the stable positioning of the wire pressing buckle 14C is realized.

Optionally, a protrusion 1405 is disposed at a bottom edge of the notch 1404, a wire pressing groove is disposed on the wire pressing buckle 14C, and the protrusion 1405 is embedded into the wire pressing groove to position the wire harness. Therefore, the positioning effect of the wire harness can be improved, certainly, the wire harness can be positioned by matching the wire pressing buckle 14C and the box body 14A, and the sufficient length of the wire harness can be reserved in the driving box 14 to facilitate the movement of the moving part 12B, so that the moving part 12B can be conveniently moved.

The peripheral wall of the box body 14A is provided with a clamping groove 1401, a part of the box cover 14B is embedded into the box body 14A and is provided with a buckling position 1402, and the buckling position 1402 is buckled with the clamping groove 1401 to be buckled and connected with the box cover 14B and the box body 14A.

Referring to fig. 4, in some embodiments of the present invention, the inner bottom surface of the box 14A is further provided with a lead groove 1403, the wiring harness of the rotating part 12C is adapted to be inserted into and drawn out from the lead groove 1403, and the moving part 12B is adapted to cover the lead groove 1403 to position the wiring harness. Can make things convenient for accomodating of pencil through lead wire groove 1403 lead the pencil, avoid the winding, through removal portion 12B's closing cap effect, improve the location effect to the pencil.

As shown in fig. 2, the driving box 14 is provided with a through slot, and the shaft portion of the rotating portion 12C is adapted to pass through the through slot to connect with the air deflector. Thereby facilitating the connection of the rotating part 12C and the air deflector, of course, the structure on the air deflector can also be arranged to penetrate through the through groove to extend into the connecting rotating part 12C.

In some embodiments of the present invention, the rotating portion 12C includes a rotating motor 1205 and a crank shaft 1206, the rotating motor 1205 is connected to the crank shaft 1206, and the crank shaft 1206 is used to connect the air deflector. Therefore, the rotating part 12C can drive the air deflector conveniently, the structure of the rotating part 12C is simplified, and stable driving of the air deflector is realized.

In some examples of the present invention, the driving portion 12A includes a sliding motor 1201 and a gear 1202, the gear 1202 is connected to the sliding motor 1201, the gear 1202 can be driven to rotate by the sliding motor 1201, and the moving portion 12B includes a rack 1203, and the rack 1203 is engaged with the gear 1202. The stable driving of the air deflector can be realized through the driving mode of the gear 1202 and the rack 1203.

Referring to fig. 1 and 4, the rack assembly includes a driving box 14, a sliding motor 1201 mounted on the driving box 14, the sliding motor 1201 disposed outside the driving box 14, a gear 1202 disposed in the driving box 14, and a rack 1203 disposed in the driving box 14. So that the gear 1202 and rack 1203 mechanism can stably transmit power.

Optionally, the driving portion 12A further includes a motor cover 1207, the motor cover 1207 is relatively fixedly connected to the driving box 14, the sliding motor 1201 is mounted on the motor cover 1207, and the sliding motor 1201 and the motor cover 1207 are relatively fixed in position, and ribs may be disposed on an inner circumferential surface of the motor cover 1207. Therefore, the driving portion 12A can be stably mounted, transmission of vibration is reduced, and power can be stably transmitted by the driving assembly, wherein ribs on the inner circumferential surface of the motor cover 1207 can be arranged to extend in a direction parallel to the axis of the sliding motor 1201, and a plurality of ribs are arranged on the inner circumferential surface of the motor cover 1207 and are arranged at intervals in the circumferential direction of the inner circumferential surface of the motor cover 1207.

As shown in fig. 4, the moving portion 12B further includes a mounting frame 1204, the mounting frame 1204 is relatively fixedly connected to the rack 1203, and the rotating portion 12C is mounted on the mounting frame 1204. It is thereby possible to stably drive the movement of the rotating portion 12C and to improve the stability of the rotating portion 12C.

In some embodiments of the present invention, the drive device 12 includes a plurality of drive assemblies configured and adapted to drive a plurality of air deflectors, respectively. The plurality of air deflectors are driven by the plurality of driving assemblies, so that the air supply form can be further increased, and the comfort of the air conditioner 100 is further optimized.

Optionally, the moving portions 12B of the plurality of driving assemblies are adapted to drive the air deflector to move along the same curve.

Referring to fig. 1 to 13, an air conditioner 100 according to an embodiment of the present invention includes a body 10, a driving device 12, and a wind guide plate, wherein the body 10 has a wind supply opening 101; the driving device 12 is connected with the machine body 10, and the driving device 12 is the air deflector driving device 12; the air deflector is arranged at the air supply opening 101 and is in transmission connection with the rotating part 12C, wherein the air deflector is suitable for being driven by the driving device 12 to rotate and move along the width direction of the air supply opening 101.

According to the air conditioner provided by the embodiment of the utility model, the air deflector driving device 12 is arranged, the movement and rotation of the air deflector can be realized through composite motion, so that the air supply direction of the air deflector can be optimized, different air supply modes can be realized by the air deflector at different positions, and the requirement of comfort is met.

Alternatively, a plurality of air deflectors are arranged at the air blowing opening 101 in the width direction, and the driving device 12 includes a plurality of driving assemblies corresponding to the plurality of air deflectors. The plurality of air deflectors can be driven by the driving assembly, so that the movement and rotation of the air deflectors are realized, and different air supply requirements are met. Further, the driving device 12 is provided at both ends of the air blowing port 101 in the longitudinal direction.

As an embodiment, the air conditioner 100 of the present invention includes a plurality of air deflectors, and by driving the plurality of air deflectors, more air blowing modes can be implemented, and the requirement for comfort can be improved.

For this reason, the present invention provides a specific embodiment, wherein a plurality of wind deflectors are provided, the plurality of wind deflectors include a first wind deflector 111 and a second wind deflector 112, and for convenience of description, a driving assembly for driving the first wind deflector 111 is named as a first driving assembly 121; the drive assembly that drives the second air deflection plate 112 is designated as the second drive assembly 122. A specific description of this embodiment follows.

Referring to fig. 1 to 11, the present invention provides an air conditioner 100 including: the air conditioner comprises a machine body 10, a first air deflector 111, a second air deflector 112 and a driving device 12. The body 10 may provide support for other components of the air conditioner 100, wherein an air conditioning module, such as a heat exchanger, a fan, etc., may be disposed in the body 10; the first air guiding plate 111 and the second air guiding plate 112 may have an air guiding function, and are suitable for guiding the air flow sent by the air conditioner 100, and may perform functions of increasing and decreasing pressure, and thus, various air supply modes may be implemented.

Specifically, the body 10 has a blowing port 101, and an air flow can be sent out through the blowing port 101, that is, an air flow entering the body 10 is sent out through the blowing port 101 after one or more operations such as heat exchange, filtration, sterilization, and disinfection are performed in the body 10.

The first air guiding plate 111 is connected to the machine body 10, and the first air guiding plate 111 is rotatable, and the first air guiding plate 111 can change the air blowing direction thereof by rotating, so as to blow air to the target position according to the actual use requirement, wherein the first air guiding plate 111 is disposed at the air blowing opening 101, that is, the first air guiding plate 111 can guide the airflow of the air blowing opening 101.

The second air guiding plate 112 is connected to the machine body 10, and the second air guiding plate 112 is rotatable, and the second air guiding plate 112 can change the air supply direction thereof by rotating, so as to supply air to the target position according to the actual use requirement, wherein the second air guiding plate 112 is disposed at the air supply opening 101, that is, the second air guiding plate 112 can guide the airflow of the air supply opening 101.

The first air deflector 111 and the second air deflector 112 are arranged along the width direction of the air inlet 101, and at least one of the first air deflector 111 and the second air deflector 112 is movable along the width direction of the air inlet 101. In other words, the first air deflection plate 111 can move in the width direction; or the second air deflection plate 112 can move along the width direction; alternatively, the first air deflection plate 111 may be movable in the width direction, and the second air deflection plate 112 may be movable in the width direction. The distance between the first air deflector 111 and the second air deflector 112 can be adjusted by the movement of the first air deflector 111 and/or the second air deflector 112 in the width direction, and in fact, the first air deflector 111 and the second air deflector 112 separate a plurality of air outlet regions at the air outlet 101, that is, there are air outlet regions between the first air deflector 111 and the side surface of the air outlet 101, between the second air deflector 112 and the other side surface of the air outlet 101, and between the first air deflector 111 and the second air deflector 112. In addition, because the wind guiding direction of the first wind guiding plate 111 and the wind guiding direction of the second wind guiding plate 112 can be adjusted, the wind blowing modes of a plurality of wind blowing areas divided by the first wind guiding plate 111 and the second wind guiding plate 112 may be different, and because the first wind guiding plate 111 and the second wind guiding plate 112 can rotate, a plurality of different wind blowing modes can be provided, and different use requirements can be met.

In addition, the driving device 12 of the present invention is in transmission connection with the first wind guiding plate, and the driving device 12 is in transmission connection with the second wind guiding plate 112. The driving device 12 can drive the first wind deflector 111 and the second wind deflector 112, so that the first wind deflector 111 and the second wind deflector 112 are combined to form different air blowing modes. According to the air conditioner 100 of the embodiment of the utility model, the first air deflector 111 and the second air deflector 112 are arranged, and the combination of the first air deflector 111 and the second air deflector 112 can provide multiple air outlet modes to meet different use requirements.

The first air deflector 111 and the second air deflector 112 can all blow air in the same direction, so that multiple air flows can be formed, and the comfort of blowing air is improved; in addition, the first air deflector 111 and the second air deflector 112 can also blow air in different directions, so that multiple air flows are formed, and different blowing effects can be generated, for example, a divergent or convergent channel is formed between the first air deflector 111 and the second air deflector 112.

The air conditioner 100 of the present invention may be a cabinet air conditioner, a floor air conditioner, a wall air conditioner, a split air conditioner, a mobile air conditioner, etc., and different air conditioners 100 have different width and length directions, but as a general principle, the air supply opening 101 is generally in a strip shape, so that the length direction thereof is an extending direction of a longer dimension of the air supply opening 101, and the width direction thereof is a direction corresponding to a narrower dimension thereof. Specifically, taking a cabinet air conditioner as an example, the length direction of the air supply opening 101 is the up-down direction shown in the drawing, and the width direction of the air supply opening 101 is the left-right direction in the drawing. In the drawings, a cabinet air conditioner is mainly illustrated as an example, but the utility model is not to be construed as being limited to the scope of the utility model, and it should be understood that the utility model is described in detail for clarity of the technical solution of the present application.

Fig. 11a to 11i are schematic views illustrating the first wind deflector 111 and the second wind deflector 112 in different states. In fig. 11a, the first air deflector 111 and the second air deflector 112 extend in a direction away from each other, and the first air deflector 111 and the second air deflector 112 are substantially perpendicular to the air blowing direction of the air blowing opening 101, so as to be suitable for sealing the air blowing opening 101. In fig. 11b, the first air deflector 111 and the second air deflector 112 extend in the same direction, and the first air deflector 111 and the second air deflector 112 are substantially perpendicular to the air blowing direction of the air blowing opening 101, so as to be suitable for sealing the air blowing opening 101. In fig. 11c, the first and second air deflectors 111 and 112 extend in the same direction and are inclined to the right in the air blowing direction. In fig. 11d, the first air deflection plate 111 and the second air deflection plate 112 extend in the same direction and are inclined to the left in the air blowing direction. In fig. 11e, the first air deflector 111 and the second air deflector 112 extend in the same direction and are inclined to the left in the air blowing direction, wherein the first air deflector 111 is close to the leftmost side of the air blowing opening 101, and the second air deflector 112 is close to the middle position of the air blowing opening 101 in the left-right direction. In fig. 11f, the first air guiding plate 111 and the second air guiding plate 112 extend in the same direction and extend along the air blowing direction, and both the first air guiding plate 111 and the second air guiding plate 112 have arc surfaces, and the arc surface of the first air guiding plate 111 is opposite to the arc surface of the second air guiding plate 112. In fig. 11g, the first air guiding plate 111 and the second air guiding plate 112 extend in the same direction and extend along the air blowing direction, and both the first air guiding plate 111 and the second air guiding plate 112 have arc-shaped surfaces, the arc-shaped surface of the first air guiding plate 111 is opposite to the arc-shaped surface of the second air guiding plate 112, and compared with fig. 11f, the distance between the first air guiding plate 111 and the second air guiding plate 112 in fig. 11g is increased. In fig. 11h, the first air guiding plate 111 and the second air guiding plate 112 extend in opposite directions, wherein the first air guiding plate 111 is inclined to the left in the air blowing direction, the second air guiding plate 112 is inclined to the right in the air blowing direction, both the first air guiding plate 111 and the second air guiding plate 112 have arc surfaces, and the arc surface of the first air guiding plate 111 is opposite to the arc surface of the second air guiding plate 112. In fig. 11i, the first air guiding plate 111 and the second air guiding plate 112 extend in opposite directions, wherein the first air guiding plate 111 is inclined to the left in the air blowing direction, the second air guiding plate 112 is inclined to the right in the air blowing direction, and both the first air guiding plate 111 and the second air guiding plate 112 have arc surfaces, the arc surface of the first air guiding plate 111 is opposite to the arc surface of the second air guiding plate 112, and the gap between the first air guiding plate 111 and the second air guiding plate 112 is reduced in fig. 11i compared with fig. 11 h.

The driving device 12 of the present invention includes a structure for driving the first air guiding plate 111, and may also have a structure for driving the second air guiding plate 112, wherein the driving device 12 may be configured to simultaneously drive the first air guiding plate 111 and the second air guiding plate 112, and the driving device 12 may also be configured to separately drive the first air guiding plate 111 and the second air guiding plate 112, for example, the first air guiding plate 111 and the second air guiding plate 112 share one set of driving structure, so that the first air guiding plate 111 and the second air guiding plate 112 are simultaneously driven, and the first air guiding plate 111 and the second air guiding plate 112 may also be separately configured with different driving structures, so that the first air guiding plate 111 and the second air guiding plate 112 can be separately controlled. Of course, when different driving structures are adopted for the first air guiding plate 111 and the second air guiding plate 112, the synchronous driving of the first air guiding plate 111 and the second air guiding plate 112 may also be realized based on a program, a synchronous structure, and the like.

Referring to fig. 1 to 13, in some embodiments of the present invention, the driving device 12 includes a first driving assembly 121, and the first driving assembly 121 may be configured to drive the first air guiding plate 111 to move and rotate, wherein the first driving assembly 121 is connected to the machine body 10, the first driving assembly 121 is connected to the first air guiding plate 111, and the first driving assembly 121 may drive the first air guiding plate 111 to perform a translational motion or a rotational motion with respect to the machine body 10, or the first driving assembly 121 may be configured to drive the machine body 10 to perform a combined motion of moving and rotating. Preferably, the first driving assembly 121 is used for driving the first air deflector 111 to move and rotate. Through the driving action of the first driving assembly 121, the first air deflector 111 can be conveniently moved and rotated to meet different air supply requirements.

Similarly, the driving device 12 may further include a second driving assembly 122, the second driving assembly 122 may be configured to drive the second wind deflector 112 to move and rotate, wherein the second driving assembly 122 is connected to the machine body 10, the second driving assembly 122 is connected to the second wind deflector 112, the second driving assembly 122 may drive the second wind deflector 112 to perform a translational motion or a rotational motion with respect to the machine body 10, and the second driving assembly 122 may also be configured to drive the machine body 10 to perform a combined movement of moving and rotating. Preferably, the second driving assembly 122 is used for driving the second air deflector 112 to move and rotate. Through the driving action of the second driving assembly 122, the second air deflector 112 can be conveniently moved and rotated to meet different air supply requirements.

In addition, the first air deflector 111 and the second air deflector 112 respectively adopt driving components corresponding to the first air deflector 111 and the second air deflector 112, so that the driving of the first air deflector 111 and the second air deflector 112 can be more flexible, and the air supply mode and the air supply effect of the air conditioner 100 are further increased. In addition, under the driving action of the driving device 12, both the first air deflector 111 and the second air deflector 112 can move and rotate, so that the air supply effect of the air conditioner 100 can be further optimized.

As shown in fig. 1 to 8, in some embodiments of the present invention, the first driving assembly 121 may include a driving portion 12A, and the fixing portion driving portion 12A of the first driving assembly 121 may be configured to be fixedly connected with the machine body 10, wherein the fixing portion driving portion 12A of the first driving assembly 121 may be directly connected with the machine body 10 or may be fixedly connected with the machine body 10.

The first driving assembly 121 may further include a moving portion 12B, the moving portion 12B of the first driving assembly 121 may be in transmission connection with the fixed portion driving portion 12A of the first driving assembly 121, wherein the moving portion 12B of the first driving assembly 121 may be configured to drive the first air deflector 111 to move. Under the driving action of the fixed driving part 12A of the first driving assembly 121, the moving part 12B of the first driving assembly 121 can move along a predetermined direction, wherein the predetermined direction can be the width direction of the air blowing opening 101, the moving part 12B of the first driving assembly 121 is connected to the first air deflector 111, and the movement of the moving part 12B of the first driving assembly 121 is transmitted to the first air deflector 111, so that the first air deflector 111 is driven. The first driving assembly 121 may further include a rotating portion 12C, the rotating portion 12C of the first driving assembly 121 is configured to drive the first air guiding plate 111 to rotate, wherein the rotating portion 12C of the first driving assembly 121 may be disposed on the moving portion 12B of the first driving assembly 121, and the first air guiding plate 111 is connected to the rotating portion 12C of the first driving assembly 121, so that the moving portion 12B of the first driving assembly 121 may drive the rotating portion 12C of the first driving assembly 121 to move, and then the rotating portion 12C of the first driving assembly 121 may drive the first air guiding plate 111 to move, and the rotating portion 12C of the first driving assembly 121 may drive the first air guiding plate 111 to rotate, so that the rotation and the movement of the first air guiding plate 111 may be achieved.

Similarly, the second driving assembly 122 may include a fixed portion driving portion 12A, and the fixed portion driving portion 12A of the second driving assembly 122 may be disposed to be fixedly connected with the machine body 10, wherein the fixed portion driving portion 12A of the second driving assembly 122 may be directly connected with the machine body 10, or may be fixedly connected with the machine body 10. The second driving assembly 122 may further include a moving portion 12B, the moving portion 12B of the second driving assembly 122 may be in transmission connection with the fixed portion driving portion 12A of the second driving assembly 122, wherein the moving portion 12B of the second driving assembly 122 may be configured to drive the second air guiding plate 112 to move. Under the driving action of the fixed driving part 12A of the second driving assembly 122, the moving part 12B of the second driving assembly 122 can move along a predetermined direction, wherein the predetermined direction can be the width direction of the air blowing opening 101, the moving part 12B of the second driving assembly 122 is connected to the second air guiding plate 112, and the movement of the moving part 12B of the second driving assembly 122 is transmitted to the second air guiding plate 112, so that the second air guiding plate 112 is driven. The second driving assembly 122 may further include a rotating portion 12C, and the rotating portion 12C of the second driving assembly 122 is configured to drive the second air guiding plate 112 to rotate, wherein the rotating portion 12C of the second driving assembly 122 may be disposed on the moving portion 12B of the second driving assembly 122, and connect the second air guiding plate 112 with the rotating portion 12C of the second driving assembly 122, so that the moving portion 12B of the second driving assembly 122 may drive the rotating portion 12C of the second driving assembly 122 to move, and then the rotating portion 12C of the second driving assembly 122 may drive the second air guiding plate 112 to move, and the rotating portion 12C of the second driving assembly 122 may drive the second air guiding plate 112 to rotate, so that the rotation and the movement of the second air guiding plate 112 may be achieved. In this way, the first air deflector 111 and the second air deflector 112 can be stably moved and rotated, the air deflectors are driven, air can be conveniently supplied by the air deflectors in a preset mode, and the intellectualization of the air conditioner 100 is improved.

In addition, in order to realize the stable movement of the first air guiding plate 111 and the second air guiding plate 112, the present invention further provides a guiding structure 13, and the air guiding plates can be guided by the guiding structure 13. Specifically, as shown in fig. 1 to 8, the driving device 12 can further include a guide structure 13, the guide structure 13 can include a guide 13A and a slider 13B, the guide 13A can extend in the width direction of the air blowing port 101, and the slider 13B can slide along the guide 13A. The guiding part 13A may be a sliding chute or a sliding rail, and the sliding part 13B may be a sliding block.

Wherein one of the guide 13A and the slider 13B may be provided on the moving portion 12B, and the other may be fixedly connected to the body 10. Specifically, the method comprises the following steps: the relative position of the guide piece 13A and the moving part 12B is fixed, and the relative position of the sliding piece 13B and the machine body 10 is fixed; or the slide member 13B and the moving portion 12B are fixed in relative position, and the guide member 13A and the body 10 are fixed in relative position. The guide structure 13 can stably move the moving part 12B, thereby improving the stability of the movement of the air guide plate.

For convenience of understanding, the following describes a guiding structure 13 of a specific structure in the present invention, wherein the sliding part 13B is disposed on the moving part 12B, the guiding part 13A is fixedly connected to the machine body 10 as an example, the guiding part 13A may be a sliding groove, the sliding part 13B is a sliding block, specifically, the guiding structure 13 includes a sliding groove and a sliding block, the sliding block is connected to the moving part 12B, the sliding groove is fixed relative to the machine body 10, the sliding groove extends along the width direction of the air blowing opening 101, and the sliding block is slidably inserted into the sliding groove along the width direction of the air blowing opening 101. Through the combination of the sliding block and the sliding groove, the stable movement of the moving part 12B can be realized, and the stability of the air deflector in the moving process is improved.

The guide structures 13 may be disposed corresponding to the moving portion 12B of the first driving assembly 121 and the moving portion 12B of the second driving assembly 122, respectively, so as to avoid mutual interference between the first driving assembly 121 and the second driving assembly 122, and further improve the stability of the movement of the first air guiding plate 111 and the second air guiding plate 112. Of course, in order to simplify the guide structure 13, the guide structure 13 of the first driving assembly 121 and the guide structure 13 of the second driving portion 12A may be partially shared to simplify the structure. Specifically, the moving portion 12B of the first driving assembly 121 is provided with a slider, the moving portion 12B of the second driving assembly 122 is also provided with a slider, and they can move along the same sliding slot, that is, the sliding slot is shared, that is, the driving device 12 includes the first driving assembly 121, the second driving assembly 122 and the sliding slot, the slider provided on the rotating portion 12C of the first driving assembly 121 is slidably inserted into the sliding slot, and the slider provided on the rotating portion 12C of the second driving assembly 122 is slidably inserted into the same sliding slot.

Of course, the above-mentioned detailed description of the guiding structure 13 is only one embodiment of the present invention, and is not intended to limit the scope of the present invention.

In addition, the driving assembly of the present invention may adopt a gear 1202 belt transmission mechanism, a pulley transmission mechanism, a sprocket transmission mechanism, etc., and the present invention provides some specific embodiments for clearly describing the technical solution of the present invention, which, of course, is not intended to limit the scope of the present invention.

In some specific examples of the present invention, one of the fixed portion driving portion 12A and the moving portion 12B is a gear 1202, and the other is a rack 1203 meshed with the gear 1202, the rack 1203 extending in the width direction of the air blowing opening 101. In other words, the fixed portion driving portion 12A is a gear 1202, and the moving portion 12B is a rack 1203 engaged with the gear 1202; alternatively, the moving portion 12B is a gear 1202, and the fixed portion driving portion 12A is a rack 1203 meshed with the gear 1202. The following description will be made separately.

As shown in fig. 1 to 8, in an example, the fixed portion driving portion 12A includes a gear 1202, the moving portion 12B includes a rack 1203, wherein the relative position of the gear 1202 and the machine body 10 is fixed, while the gear 1202 is rotatable relative to the machine body 10, the rack 1203 extends along the width direction of the air blowing opening 101, and the gear 1202 and the rack 1203 are engaged with each other, at this time, the guiding structure 13 in the driving device 12 can guide the rack 1203 to move along a predetermined track, the gear 1202 can be driven by a motor or the like, when the gear 1202 rotates, because the gear 1202 is engaged with the rack 1203, and the rack 1203 is limited by the guiding structure 13, therefore, during the rotation of the motor driving gear 1202, the rack 1203 will move along the predetermined track, thereby achieving the purpose of driving the air deflector to move.

In another example, the fixed portion driving portion 12A includes a rack 1203, the moving portion 12B includes a gear 1202, wherein the rack 1203 is fixed relative to the machine body 10, the gear 1202 is fixedly connected to the moving portion 12B, the gear 1202 extends along the width direction of the air blowing opening 101, and the rack 1203 and the gear 1202 are engaged with each other, at this time, the guiding structure 13 in the driving device 12 can guide the gear 1202 to move along a predetermined track, the gear 1202 can be driven by a motor or the like, when the gear 1202 rotates, because the rack 1203 is engaged with the gear 1202, the rack 1203 is fixed relative to the machine body 10, and the gear 1202 is limited by the guiding structure 13, therefore, during the rotation of the motor driving gear 1202, the gear 1202 will move along the predetermined track, and the purpose of driving the air deflector to move is achieved. The rack 1203 is engaged with the gear 1202 to stably move the guide plate, so that the position of the guide plate can be relatively accurately determined while the stability is improved. All of which are within the scope of the present application.

The rotating portion 12C of the present invention may further include a rotating motor 1205, and the rotating motor 1205 may drive the guide plate to rotate, so as to simplify driving of the guide plate and improve driving stability, and of course, the rotating portion 12C may further include a speed reducing mechanism.

The driving device 12 of the present invention can be exposed out of the machine body 10, or can be shielded by a corresponding structure on the machine body 10, and in addition, the present invention provides a specific embodiment,

as shown in fig. 1 to 8, the driving device 12 may further include a driving box 14, the first driving assembly 121 is accommodated in the driving box 14, and the first driving assembly 121 may be integrated by the driving box 14, so that the integration of the driving device 12 may be effectively improved, and the assembly and installation of the driving device 12 may be facilitated.

In addition, the driving device 12 may include the driving box 14, the second driving assembly 122 is accommodated in the driving box 14, and the second driving assembly 122 may be integrated through the driving box 14, so that the integration of the driving device 12 may be effectively improved, and the assembly and installation of the driving device 12 may be facilitated.

Of course, the driving box 14 accommodating the first driving assembly 121 and the driving box 14 accommodating the second driving assembly 122 may be the same box or different boxes. Preferably, in the present invention, the first driving assembly 121 and the second driving assembly 122 are disposed in the same driving box 14 in the same driving device 12, which further facilitates the integration of the driving device 12, protects the driving assemblies, and improves the stability of the air conditioner 100.

The driving box 14 includes a box body 14A and a box cover 14B, the box body 14A and the box body 14A are covered together, and a through groove is formed in a surface of one side of the driving box 14 to allow the rotating portion 12C to connect with a corresponding guide plate.

With reference to fig. 1 to 10, in some embodiments of the present invention, the first air guiding plate 111 extends along a length direction of the air outlet 101, the second air guiding plates 112 each extend along a length direction of the air outlet 101, and at least one end of the air outlet 101 along the length direction is provided with the driving device 12. In other words, the first guiding plate may be connected to the driving device 12 at one end, or both ends of the first guiding plate may be connected to the driving device 12; likewise, the second guide plate may be connected to the driving device 12 at one end or to the driving device 12 at both ends.

Taking a cabinet air conditioner as an example, the air outlet 101 extends along the vertical direction, so the length direction of the air outlet 101 is the vertical direction in the drawing, the first air guiding plate 111 extends along the vertical direction, the second air guiding plate 112 extends along the vertical direction, the first air guiding plate 111 is movable along the left-right direction, the second air guiding plate 112 is movable along the left-right direction, and the first air guiding plate 111 can rotate and the second air guiding plate 112 can rotate. A driving device 12 may be disposed at an upper end of the air supply opening 101, and the driving device 12 is connected to upper ends of the first air deflector 111 and the second air deflector 112 to drive the first air deflector 111 and the second air deflector 112; a driving device 12 may be further disposed at the lower end of the air supply opening 101, and the driving device 12 is connected to the lower ends of the first air deflector 111 and the second air deflector 112 to drive the first air deflector 111 and the second air deflector 112; the upper end and the lower end of the air supply opening 101 may be provided with a driving device 12, the driving device 12 located at the upper end of the air supply opening 101 is connected to the upper ends of the first air deflector 111 and the second air deflector 112, and the driving device 12 located at the lower end of the air supply opening 101 is connected to the lower ends of the first air deflector 111 and the second air deflector 112, so as to drive the first air deflector 111 and the second air deflector 112. When the upper end and the lower end of the air supply opening 101 are both connected with the driving devices 12, the driving devices 12 at the upper end and the lower end of the air supply opening 101 are connected with the same control module, so that the air deflector can be stably driven.

Of course, the driving device 12 in the present invention may be provided at other positions, for example, the driving device 12 may be provided at an intermediate position in the longitudinal direction of the air blowing port 101.

As shown in the drawings, in some embodiments of the present invention, in the width direction of the air blowing opening 101, the first air guiding plate 111 moves along an arc-shaped curve, that is, the moving track of the first air guiding plate 111 in the width direction of the air blowing opening 101 is an arc-shaped curve. In the width direction of the air blowing opening 101, the second air guiding plate 112 moves along an arc-shaped curve, that is, the moving track of the second air guiding plate 112 in the width direction of the air blowing opening 101 is an arc-shaped curve. Wherein the middle of the arc-shaped curve is convex toward the outside of the air blowing port 101. The blowing paths of the first and second air deflectors 111 and 112 may be adapted to the outer surface of the air conditioner 100, thereby improving the aesthetic appearance of the air conditioner 100. In addition, the air supply mode can be further optimized by arranging the arc-shaped motion track, and compared with the air guide plate moving along the linear direction, the air guide plate moving along the curve direction can have more air supply modes and meet different requirements of users.

The first air deflector 111 and the second air deflector 112 move along the same arc-shaped curve in the width direction of the air outlet 101. The consistency of the moving tracks of the first air deflector 111 and the second air deflector 112 can be improved, the structure is simplified, and the assembly efficiency of the air conditioner 100 is improved.

Optionally, the rotation central axis of the first air deflector 111 is located at the central position of the cross section of the first air deflector 111; or the rotation central axis of the first wind deflector 111 is close to the central position of the cross section of the first wind deflector 111. Similarly, the central axis of rotation of the second air deflector 112 is located at the center of the cross section of the second air deflector 112; or the rotation central axis of the second wind deflector 112 is close to the central position of the cross section of the second wind deflector 112. In this way, the rotation of the first wind deflector 111 can be facilitated, and the rotation of the second wind deflector 112 can be facilitated.

In some embodiments of the present invention, the first air guiding plate 111 is a single-layer plate structure, and in addition, the first air guiding plate 111 may also be a multi-layer plate structure. Similarly, the second air guiding plate 112 may also be a single-layer plate structure; the second air guiding plate 112 may also be a multi-layer plate structure.

The single-layer plate is of a single-layer plate structure, and the surface of the single-layer plate can be an arc surface, for example, one side surface of the single-layer plate is a convex arc, and the other side surface of the single-layer plate is a convex arc or a concave arc, so that different air guide modes are formed; the double-layer plate may be formed by laminating a plurality of plate bodies, for example, two plate bodies may be laminated with a hollow space therebetween. In addition, the air deflector may extend along the length direction of the air supply opening 101, and the arc surface of the air deflector may be arc-shaped along the air supply direction. Of course, the description of the specific structure of the air deflector in the present invention is only one embodiment of the present invention, and is not intended to limit the scope of the present invention.

In addition, in the present invention, the first air deflector 111 is rotatable at the air outlet 101, and the second air deflector 112 is rotatable at the air outlet 101, wherein at least one of the first air deflector 111 and the second air deflector 112 may be configured to be rotatable within a range of up to an angle, so as to achieve stable air supply, and the effect of utilizing the air deflectors to achieve the closing of the air outlet 101 may also be satisfied through reasonable configuration. In some embodiments of the present invention, an air outlet duct is disposed in the machine body 10, and air flow can be sent to the air supply opening 101 through the air outlet duct, and the air supply opening 101 and the air outlet duct are communicated with each other, that is, the air flow sent out through the air outlet duct will be sent to the air supply opening 101.

The width of the air supply opening 101 and the width of the air outlet duct in the present invention may be set to be different, for example, the width of the air supply opening 101 is set to be larger, that is, larger than the width of the air outlet duct, so as to form a flaring form, wherein both sides of the width direction of the air supply opening 101 protrude out of both sides of the width direction of the air outlet duct, and of course, the air supply opening 101 may also be set to have a width smaller than the air outlet duct.

In addition, when the width of the air outlet 101 is greater than that of the air outlet 101, the connection between the air outlet 101 and the air outlet is a step surface, that is, the inner side surface of the air outlet 101 and the inner side surface of the air outlet are connected by the step surface. In order to realize the 180 ° rotation of the air guiding plate, the position of the rotation central axis of the air guiding plate needs to be set to avoid interference, wherein the first air guiding plate 111 may be set to be capable of rotating 180 ° or the second air guiding plate 112 may be set to be capable of rotating 180 °.

When the first air guiding plate 111 can rotate 180 degrees, the distance between the rotation central axis of the first air guiding plate 111 and the step surface is D1, and the distance between the rotation central axis of the first air guiding plate 111 and one end surface of the air guiding plate is D2, wherein the rotation central axis of the first air guiding plate 111 can be arranged in an eccentric manner, that is, the distance between the rotation central axis of the first air guiding plate 111 and the first end surface of the first air guiding plate 111 is smaller than the distance between the rotation central axis of the first air guiding plate 111 and the second end surface of the first air guiding plate 111, and when the first air guiding plate 111 extends in the air blowing direction, the second end surface of the first air guiding plate 111 is located in front of the first end surface (in the air blowing direction). By setting the dimension D1 to be the same as D2, the first wind deflector 111 can be stably rotated to avoid interference, thereby facilitating the 180 ° rotation of the first wind deflector 111.

When the second air guiding plate 112 can rotate 180 °, the distance between the central rotation axis of the second air guiding plate 112 and the step surface is D, and the distance between the central rotation axis of the second air guiding plate 112 and one end surface of the air guiding plate is D, wherein the central rotation axis of the second air guiding plate 112 can be arranged eccentrically, that is, the distance between the central rotation axis of the second air guiding plate 112 and the second end surface of the second air guiding plate 112 is smaller than the distance between the central rotation axis of the second air guiding plate 112 and the second end surface of the second air guiding plate 112, and when the second air guiding plate 112 extends along the air blowing direction, the second end surface of the second air guiding plate 112 is located in front of the second end surface (along the air blowing direction). The stable rotation of the second air deflection plate 112 can be achieved by setting the dimension D1 to be the same as D2, avoiding interference, thereby facilitating the 180 ° rotation of the second air deflection plate 112.

In addition, the dimension D2 can be set to be smaller than the dimension D1, so that the problem that the assembly cannot be performed due to production and assembly errors can be avoided, excessive noise generated between the air deflector and the step surface in the rotating process can be effectively avoided, and the rotating stability of the air deflector is improved, wherein the difference between the dimension D2 and the dimension D1 can be set to be larger than millimeters, namely the difference between the dimension D1 and the dimension D2 is larger than millimeters. The difference between the dimension D and the dimension D may also be set to be less than millimeter, for example, the difference between the dimension D and the dimension D may also be set to be. In addition, preferably, in order to facilitate the rotation of the air deflector and improve the air guiding effect, the difference between the dimension D and the dimension D is set within the range of millimeters to millimeters.

The air supply outlet 101 of the utility model is provided with two air deflectors (more air deflectors can be adopted), and the upper part and the lower part of the air deflectors are provided with a movement mechanism for driving the air deflectors to move; the air deflector motion mechanism is a set of two motion modes, wherein one motion mode is a gear 1202 rack 1203 mechanism for driving the air deflector to slide left and right, the other motion mode is a motor direct-drive crank structure for driving the air deflector to rotate, the motor for driving the air deflector to rotate is arranged on the rack 1203 sliding left and right, and the crank is connected with the air deflector;

when the computer is started: the first air deflector 111 rotates anticlockwise under the driving of the rotating motor 1205, and the second air deflector 112 rotates clockwise to form a front-side wind sweeping state, wherein the wind sweeping state can sweep wind at 0-180 degrees; the air outlet quantity at the front side is the maximum state, the air deflector slides to the maximum from left to right, and simultaneously rotates to the target position to form an air channel for extension, the wind can be blown farther, and meanwhile, the wind can be swept from left to right in the state; the air guide plate is in a partitioned air supply state, the air guide plate rotates by a certain angle, and the rear air guide plate slides towards the middle by a certain distance to form a partitioned air supply state; in addition, the air deflector slides to both sides for a certain distance, so that an air port is added, three-wind air supply is realized, a partition air supply mode is added, and the problem of small front air volume is solved. Above, through aviation baffle and mechanism, reached 180 sweep wind, subregion air supply, multiple air supply forms such as big amount of wind super remote air supply, the travelling comfort is good, and the amount of wind is undamped, has improved user experience.

The air outlet 101 of the air conditioner 100 of the utility model is provided with two air deflectors (certainly, more than three air deflectors are also available), and the air deflectors are provided with a driving device 12 which drives the air deflectors to move up and down; the mode that the drive assembly drives the aviation baffle motion includes: the gear 1202 and the rack 1203 drive the air deflector to slide left and right; the motor on the rack 1203 drives the air deflector to rotate, and the two motions are independent and can move in a combined manner; the driving assembly consists of a sliding motor 1201, a gear 1202, a rack 1203, a rotating motor 1205, a crank shaft 1206, a wire pressing buckle 14C and a driving box 14; the left-right sliding motor 1201 drives the gear 1202 to rotate so as to drive the rack 1203 to move, the rack 1203 is provided with a rotating motor 1205, the rotating motor 1205 is provided with a crank shaft 1206, the crank shaft 1206 is connected with the air deflector, the left-right sliding motor 1201 can drive the air deflector to slide left and right on a target position, and the rack 1203 rotates on the drive box 14 according to a track; a rotating motor 1205 is arranged on the rack 1203, a crank shaft 1206 is arranged on the rotating motor 1205, and the motor rotates to drive the crank shaft 1206 and further drive the air deflector to rotate; the air deflector can slide left and right and rotate on the shell, and moves to a target position on the cabinet machine to realize different air outlet effects; the rack 1203 is provided with a wiring buckle for rotating the motor 1205 to route, the motor is installed on the rack 1203, a wire is arranged on the rack 1203 and installed on the driving box 14, a wire pressing buckle 14C is arranged on the motor wire, the wire and the buckle are installed on the driving box 14 together, after the other components are installed, the box, the cover, the wire pressing buckle 14C and the wire are compressed, the wire has a certain length in the driving box 14, and the wire is not pulled when the rack 1203 rotates. In summary, the air deflector driving mechanism can rotate and slide. Realize multiple air-out mode, improve the travelling comfort.

As mentioned above, the air conditioner of the utility model has a plurality of air deflectors at the air outlet 101, the air deflectors are connected with the motion mechanism up and down, and the air deflectors can slide left and right and rotate by themselves; the motion mechanism is simple and reliable, and the rotating motor 1205 is reliable in wiring and free of tearing. The wire pressing buckle 14C arranged on the driving box 14 is provided with a protruding rib, the wire pressing buckle 14C is pressed by the cover, and then the wire pressing buckle 14C presses the wire onto the protruding rib, so that the wire cannot run in disorder, the wire is designed to be long, when the rack 1203 drives the rotating motor 1205 to slide, the lengthened length of the wire in the driving box 14 can meet the requirement, the wire cannot pull the rack 1203, and abnormal sound cannot be generated because the wire outside the driving box 14 runs into the wire and runs out in disorder;

the utility model completes the wiring of the rotating motor 1205 through a series of structures such as the driving box 14, the wire pressing buckle 14C, the rack 1203, the rotating motor 1205 and the like, and realizes that the sliding mechanism comprises a rotating mechanism.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

Although embodiments of the present invention have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention, and that variations, modifications, substitutions and alterations can be made to the above embodiments by those of ordinary skill in the art within the scope of the present invention.

Claims (15)

1. An air deflection drive assembly (12), wherein the drive assembly (12) comprises a carriage assembly and a drive assembly, wherein the drive assembly is disposed on the carriage assembly, and wherein the drive assembly comprises:

the driving part (12A), the said driving part (12A) is relatively fixed and set up on the said bracket assembly;

a moving part (12B), wherein the moving part (12B) is movably connected with the bracket assembly and is driven by the driving part (12A);

a rotating portion (12C), the rotating portion (12C) being disposed on the moving portion (12B), the rotating portion (12C) being configured to connect to the air deflection plate and drive the air deflection plate to rotate.

2. The air deflection drive (12) of claim 1, wherein the bracket assembly includes a drive cassette (14), the rotating portion (12C) is disposed within the drive cassette (14), and the drive cassette (14) is provided with a wire passage hole adapted to guide a wire harness of the rotating portion (12C).

3. The air deflection drive (12) of claim 2, wherein the drive cassette (14) includes:

a case (14A), the case (14A) being configured in a box shape with one side open, and a notch (1404) being provided on a peripheral wall;

a wire clip (14C), the wire clip (14C) being inserted into the notch (1404) to position the wire harness;

a box cover (14B), wherein the box cover (14B) covers the box body (14A) and the gap (1404).

4. The air deflection drive (12) of claim 3, wherein the notch (1404) has a protrusion (1405) at a bottom edge thereof, and the wire clip (14C) has a wire slot, the protrusion (1405) engaging the wire slot to position the wire harness.

5. The air deflection drive (12) according to claim 3, wherein the inner bottom surface of the box (14A) is further provided with a lead slot (1403), the wiring harness of the rotating part (12C) is adapted to be inserted into the lead slot (1403) and led out from the lead slot, and the moving part (12B) is adapted to cover the lead slot (1403) to position the wiring harness.

6. The wind deflector drive arrangement (12) of claim 2, wherein the drive cassette (14) is provided with a through slot, the shaft portion of the rotating portion (12C) being adapted to pass out of the through slot for connection to the wind deflector.

7. Wind deflector drive (12) according to any of claims 1-6, wherein the rotating part (12C) comprises a rotating motor (1205) and a crank shaft (1206), the rotating motor (1205) being connected to the crank shaft (1206), the crank shaft (1206) being adapted for connection to the wind deflector.

8. The air deflection drive (12) according to any one of claims 1-6, wherein the drive portion (12A) comprises a slide motor (1201) and a gear (1202) coupled to the slide motor (1201), and the moving portion (12B) comprises a rack (1203) that engages the gear (1202).

9. The air deflection drive (12) of claim 8, wherein the carriage assembly includes a drive cassette (14), the slide motor (1201) is mounted on an exterior side of the drive cassette (14), and the gear (1202) and the rack (1203) are both disposed within the drive cassette (14).

10. The air deflector drive device (12) of claim 9, wherein the drive portion (12A) further comprises a motor cover (1207), the motor cover (1207) is fixedly connected to the drive box (14), the sliding motor (1201) is fixedly mounted to the motor cover (1207), and ribs are provided on an inner circumferential surface of the motor cover (1207).

11. The air deflection drive (12) of claim 8, wherein the moving portion (12B) further comprises a mounting bracket (1204), the mounting bracket (1204) being fixedly connected to the rack (1203), the rotating portion (12C) being mounted to the mounting bracket (1204).

12. The air deflection drive (12) of claim 1, wherein the drive (12) includes a plurality of drive assemblies configured to drive a plurality of air deflection panels, respectively.

13. The drive (12) of claim 12, wherein the moving portions (12B) of the drive assemblies are adapted to move the wind deflector along a common curve.

14. An air conditioner (100), comprising:

a body (10), wherein the body (10) has an air supply opening (101);

-a drive means (12), said drive means (12) being connected to said machine body (10), said drive means (12) being an air deflector drive means (12) according to any one of claims 1-13;

the air deflector is arranged at the air supply outlet (101) and is in transmission connection with the rotating part (12C),

the air deflector is suitable for being driven by the driving device (12) to rotate and move along the width direction of the air supply opening (101).

15. The air conditioner (100) of claim 14,

the air supply outlet (101) is provided with a plurality of air deflectors along the width direction, and the driving device (12) comprises a plurality of driving components corresponding to the air deflectors; and/or

The two ends of the air supply opening (101) along the length direction are provided with the driving devices (12).

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