CN214501669U - Air guide part, air outlet frame assembly and air conditioner - Google Patents

Abstract

The utility model discloses a wind-guiding part, play wind frame subassembly and air conditioner, the air-out passageway of air conditioner is rotationally located to the wind-guiding part, and the wind-guiding part includes: wind-guiding subassembly and water collector. A water receiving cavity is defined in the water receiving tray, and the water receiving tray is arranged on the bottom surface of the air guide assembly to receive condensed water on the air guide assembly; the part of the outer wall surface of the air guide assembly, which is adjacent to the water receiving disc, is formed into a flow guide surface, the flow guide surface extends to the bottom surface of the air guide assembly, and the projection of the bottom edge of the flow guide surface, which is adjacent to the water receiving disc, on the horizontal plane is positioned in the projection of the water receiving cavity on the horizontal plane. According to the utility model discloses wind-guiding part has avoided the condensate water on the wind-guiding subassembly to drip to other parts in subaerial and the air conditioner effectively to avoided the condensate water to drip to the inconvenience that brings for the user on ground effectively, also reduced the potential safety hazard simultaneously.

Description

Air guide part, air outlet frame assembly and air conditioner

Technical Field

The utility model belongs to the technical field of air treatment equipment technique and specifically relates to a wind-guiding part, play wind frame subassembly and air conditioner are related to.

Background

In the related art, when the air conditioner performs a cooling operation, condensed water is easily generated on the air guide assembly of the air conditioner. And the condensed water produced on the air guide component easily flows to the ground or other parts in the air conditioner, which brings inconvenience to users and has potential safety hazard.

SUMMERY OF THE UTILITY MODEL

The utility model discloses aim at solving one of the technical problem that exists among the prior art at least. Therefore, an object of the present invention is to provide a wind guiding component, which effectively prevents condensed water on the wind guiding component from dripping onto other components on the ground and in the air conditioner, thereby effectively preventing the condensed water from dripping onto the ground to bring inconvenience to the user and simultaneously reducing the potential safety hazard.

The utility model also provides an air-out frame subassembly of having above-mentioned wind-guiding part.

The utility model also provides an air conditioner of having above-mentioned air-out frame subassembly.

According to the utility model discloses wind-guiding part of first aspect embodiment, the air-out passageway of air conditioner is rotationally located to wind-guiding part, wind-guiding part includes: an air guide assembly; the water receiving tray is internally provided with a water receiving cavity and is arranged on the bottom surface of the air guide assembly so as to receive condensed water on the air guide assembly; the part of the outer wall surface of the air guide assembly, which is adjacent to the water receiving disc, is formed into a flow guide surface, the flow guide surface extends to the bottom surface of the air guide assembly, and the projection of the flow guide surface, which is adjacent to the bottom edge of the water receiving disc, on the horizontal plane is positioned in the projection of the water receiving cavity on the horizontal plane.

According to the air guide component provided by the embodiment of the utility model, the water receiving disc is arranged on the bottom surface of the air guide component, so that condensed water generated on the air guide component can be received, and in the rotating process of the air guide component, even if one part of the air guide component is positioned outside the air outlet of the air conditioner, the condensed water generated on the air guide component can still be received by the water receiving disc; and, the part through making the outer wall of wind guide component be close to the water collector forms the water conservancy diversion face, and make the projection of the base of water conservancy diversion face at the horizontal plane be located the water receiving chamber in the projection of horizontal plane, can make the comdenstion water that wind guide component produced pass through the water conservancy diversion face water conservancy diversion to the water receiving intracavity of water collector, avoided the comdenstion water on the wind guide component to drip to other parts on subaerial and in the air conditioner effectively, thereby avoided the comdenstion water to drip to the inconvenience that the ground brought for the user effectively, the potential safety hazard has also been reduced simultaneously.

According to some embodiments of the utility model, at least a part of water conservancy diversion face is located the water receiving intracavity, the inside wall in water receiving chamber with the part that the water conservancy diversion face is relative with the water conservancy diversion face is spaced apart to form the water conservancy diversion space.

According to some embodiments of the utility model, the part that the outer wall face of wind-guiding component is close to the water collector is sunken inwards to form the water conservancy diversion face.

According to some embodiments of the invention, at least a part of the flow guiding surface extends in an inward inclination in a direction from top to bottom.

According to some optional embodiments of the utility model, the water conservancy diversion face includes first water conservancy diversion portion and second water conservancy diversion portion, first water conservancy diversion portion is connected the upside of second water conservancy diversion portion, first water conservancy diversion portion and second water conservancy diversion portion all extend in the direction from top to bottom towards the leanin, first water conservancy diversion position in the top of water collector, at least some of second water conservancy diversion portion is located in the water receiving intracavity, contained angle between first water conservancy diversion portion and the vertical direction is greater than the second water conservancy diversion portion with contained angle between the vertical direction.

In some embodiments of the present invention, the portion of the outer wall surface of the wind guiding assembly excluding the flow guiding surface is an outer main body surface, the outer main body surface is connected to the upper side of the flow guiding surface, the flow guiding surface further includes a first transition portion located at the upper side of the first flow guiding portion, the first transition portion is connected to the outer main body surface and between the first flow guiding portions, and the first transition portion is an arc shape protruding outward.

In some embodiments of the present invention, the flow guiding surface further includes a third flow guiding portion located on the upper side of the second flow guiding portion, the third flow guiding portion is connected between the first flow guiding portion and the second flow guiding portion, and an included angle between the third flow guiding portion and the vertical direction is smaller than an included angle between the second flow guiding portion and the vertical direction.

In some optional embodiments of the present invention, the flow guiding surface further includes a second transition portion located on the upper side of the second flow guiding portion, the second transition portion is connected between the third flow guiding portion and the second flow guiding portion, and the second transition portion is an inward concave arc.

According to some embodiments of the utility model, the projection of water conservancy diversion face at the horizontal plane is located the water collector is in the projection of horizontal plane.

According to some embodiments of the utility model, at least a part of the inside wall in water receiving chamber forms to the drainage face, the drainage face extends to the up end of water collector, the drainage face is adjacent towards in the direction from top to bottom the direction slope in water receiving chamber's center extends.

According to some optional embodiments of the utility model, the water conservancy diversion face be located the part of water receiving intracavity with the drainage face is relative and the interval sets up.

According to some embodiments of the present invention, the air guide assembly comprises: the outer wall surface of the outer air deflector forms the outer wall surface of the air guide assembly, and a flow channel is defined between the bottom surface of the outer air deflector and the inner bottom wall surface of the water receiving cavity; the water receiving tray is arranged on the bottom surface of the inner air guide assembly and connected with the inner air guide assembly.

According to some optional embodiments of the present invention, the bottom surface of the outer air guide plate is spaced apart from the inner bottom wall surface of the water receiving chamber to form the flow passage.

According to some optional embodiments of the utility model, interior air guide component includes interior aviation baffle, interior aviation baffle with outer aviation baffle links to each other, the water collector is established the bottom surface of interior aviation baffle and with interior aviation baffle links to each other, interior aviation baffle with water collector integrated into one piece or interior aviation baffle with the water collector is independent formed part.

In some optional embodiments of the present invention, a bottom surface of the inner wind deflector is formed with a gap, and the gap communicates two portions of the water receiving cavity located at two opposite sides of the inner wind deflector.

According to some embodiments of the present invention, the air guide assembly comprises: the outer wall surface of the outer air deflector forms the outer wall surface of the air guide assembly, and an air dispersing structure for air flow to pass through is formed on the outer air deflector; the inner air guide assembly is arranged on the outer air guide plate and located on the inner side of the outer air guide plate, the inner air guide assembly comprises an inner air guide plate, a guide vane assembly and a shutter mechanism, the inner air guide plate is connected with the outer air guide plate, the guide vane assembly is arranged on the inner air guide plate, the guide vane assembly comprises a plurality of rotatable movable vanes, the movable vanes are arranged at intervals along the length direction of the inner air guide plate, the movable vanes are located between the outer air guide plate and the inner air guide plate, air passing holes are formed in the inner air guide plate at positions opposite to the movable vanes, the shutter mechanism is arranged on one side, far away from the outer air guide plate, of the inner air guide plate, and the water receiving disc is connected with at least one of the outer air guide plate and the inner air guide plate.

According to some embodiments of the utility model, the bottom surface of water collector is equipped with the piece that absorbs water.

According to some optional embodiments of the utility model, the bottom surface of water collector is formed with the holding tank, the piece that absorbs water is located in the holding tank.

According to the utility model discloses air-out frame subassembly of second aspect embodiment, include: the air outlet frame is provided with at least one air outlet channel; wind-guiding part, wind-guiding part is according to the utility model discloses above-mentioned first aspect embodiment, wind-guiding part rotationally locates the air-out passageway.

According to the utility model discloses air-out frame subassembly, through setting up foretell wind-guiding part, avoided the condensate water on the wind-guiding part to drip to other parts in subaerial and the air conditioner effectively to avoided the condensate water to drip the inconvenience that brings for the user to ground effectively, also reduced the potential safety hazard simultaneously.

According to the utility model discloses third aspect embodiment's air conditioner includes: according to the utility model discloses the air-out frame subassembly of above-mentioned second aspect embodiment.

According to the utility model discloses air conditioner, through setting up foretell air-out frame subassembly, avoided the condensate water on the air guide component to drip to other parts subaerial and in the air conditioner effectively to avoided the condensate water to drip the inconvenience that brings for the user to ground effectively, also reduced the potential safety hazard simultaneously.

Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 is a perspective view of an air conditioning indoor unit of an air conditioner according to some embodiments of the present invention, wherein the air conditioner is in a no-wind mode;

fig. 2 is a front view of the air conditioning indoor unit of fig. 1;

FIG. 3 is a cross-sectional view taken along line A-A of FIG. 2;

FIG. 4 is a cross-sectional view taken along line B-B of FIG. 2;

fig. 5 is a perspective view of an indoor unit of an air conditioner according to some embodiments of the present invention, wherein the air conditioner is in a normal blowing mode;

fig. 6 is a front view of the indoor unit of the air conditioner in fig. 5;

FIG. 7 is a cross-sectional view taken along line C-C of FIG. 6;

fig. 8 is a perspective view of an air-out frame assembly according to some embodiments of the present invention;

fig. 9 is a perspective view of a louver drive mechanism according to some embodiments of the present invention;

FIG. 10 is a top view of the louver drive mechanism of FIG. 9;

FIG. 11 is a cross-sectional view taken along line D-D of FIG. 10;

fig. 12 is a perspective view of an indoor unit of an air conditioner according to further embodiments of the present invention, wherein the air conditioner is in a normal blowing mode;

fig. 13 is a front view of the air conditioning indoor unit of fig. 12;

FIG. 14 is a cross-sectional view taken along line E-E of FIG. 13;

fig. 15 is a perspective view of an air conditioning indoor unit of an air conditioner according to further embodiments of the present invention, in which the air conditioner is in a no-wind mode;

fig. 16 is a front view of the air conditioning indoor unit of fig. 15;

FIG. 17 is a cross-sectional view taken along line F-F of FIG. 16;

fig. 18 is a front view of an air conditioning indoor unit of an air conditioner according to further embodiments of the present invention, wherein the air conditioner is in a no-wind mode;

FIG. 19 is a sectional view taken along line G-G of FIG. 18;

fig. 20 is a front view of an indoor unit of an air conditioner according to further embodiments of the present invention, wherein the air conditioner is in a normal blowing mode;

FIG. 21 is a sectional view taken along line H-H in FIG. 20;

fig. 22 is a front view of an indoor unit of an air conditioner according to further embodiments of the present invention, in which the air conditioner is in an off state;

FIG. 23 is a cross-sectional view taken along line I-I of FIG. 22;

fig. 24 is a rear view of a wind-directing component according to some embodiments of the present invention;

FIG. 25 is a cross-sectional view taken along line J-J of FIG. 24;

FIG. 26 is an enlarged view at L in FIG. 25;

FIG. 27 is a cross-sectional view taken along line K-K of FIG. 24;

fig. 28 is a perspective view of a wind-directing component according to some embodiments of the present invention;

FIG. 29 is an enlarged view at M in FIG. 28;

figure 30 is another angled perspective view of a wind-directing component according to some embodiments of the present invention;

FIG. 31 is an enlarged view at N of FIG. 30;

FIG. 32 is an enlarged view at O of FIG. 30;

fig. 33 is an exploded view of a wind-directing component according to some embodiments of the present invention;

figure 34 is a perspective view of a connector for an air deflection component according to some embodiments of the present invention.

Reference numerals:

an indoor air conditioner 1000;

a housing 100; a front panel 101; a rear back panel 102; a base 103; a top cover 104; an air inlet 105; an air outlet 106; opening and closing the door 107;

a heat exchange unit 200;

an air outlet frame 1; an air outlet channel 11;

an air guide driving mechanism 2;

a louver drive mechanism 3; a louver drive motor 31; a drive gear 32; a drive rack 33;

a wind guide member 4; an air guide assembly 50; an inner air guide component 501;

an outer air deflector 41; an outer air deflection body 410; a wind spreading structure 411; an outer body face 414; a flow guide surface 415; a first flow guide part 4151; the second flow guide portion 4152; a third flow guide part 4153; a first transition 4154; a second transition portion 4155; an outer plate part 420;

an inner air deflector 43; an inner air deflection body 430; an air passing hole 433; a notch 434; an elastic buckle 435; a first inner plate portion 440; a second inner plate portion 450; the mounting holes 451;

a guide vane assembly 46; the buckets 461; the movable blade rotating shaft 4611; a stationary blade 462; stationary blade hub 4621;

a shutter mechanism 47; a link 471; louvers 472; a louver spindle 4721;

a water pan 48; a water receiving cavity 481; a drainage surface 482; a flow-guiding space 483; a flow passage 484; accommodating grooves 485; a water absorbing member 486;

a slide assembly 49; a mounting block 491; a chute 4911; a slider 492; a slide cover 493;

a connecting member 40; a connecting portion 401; a shaft hole 4011; a positioning section 402; a limit protrusion 4021; a resilient opening 4022;

a fan section 5; a wind wheel 51; a heat exchanger component 6;

an air handling unit 300.

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 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 exemplary only for the purpose of explaining the present invention, and should not be construed as limiting the present invention.

The following describes the wind scooping parts 4 according to the embodiment of the present invention with reference to the drawings.

As shown in fig. 24-26 (the direction of the arrow in fig. 25 is the flowing direction of the condensed water), according to the air guiding component 4 of the embodiment of the present invention, the air guiding component 4 is rotatably disposed in the air outlet channel 11 of the air conditioner, and the air guiding component 4 includes: air guide assembly 50 and water pan 48.

The water receiving tray 48 may define a water receiving cavity 481 therein, the water receiving tray 48 may be disposed on a bottom surface of the air guide assembly 50, and the water receiving tray 48 is connected to the air guide assembly 50. The water receiving tray 48 can receive the condensed water on the air guiding assembly 50, and the condensed water on the air guiding assembly 50 can flow downwards into the water receiving cavity 481 of the water receiving tray 48.

When the air conditioner carries out refrigeration work, the comdenstion water that produces on the air guide component 50 flows to in the water collector 48 along air guide component 50, the comdenstion water that produces on the air guide component 50 can be accepted to the water collector 48, can effectively avoid the comdenstion water that produces on the air guide component 50 to drip to subaerial or other parts in the air conditioner (for example drip to the automatically controlled box in the air conditioner, wait on parts such as motor, cause the potential safety hazard easily), can avoid the comdenstion water to drip the inconvenience that brings for the user subaerial effectively, and can reduce the potential safety hazard. In the process of rotating the air guiding assembly 50, even if a part of the air guiding assembly 50 is positioned outside the air outlet 106 of the air conditioner, because the water receiving tray 48 is arranged on the bottom surface of the air guiding assembly 50, the water receiving tray 48 can receive the condensed water on the air guiding assembly 50 no matter the air guiding assembly 50 rotates to any position because the water receiving tray 48 and the air guiding assembly 50 rotate together.

The part of the outer wall surface of the air guide assembly 50, which is adjacent to the water receiving tray 48, may be formed as a flow guide surface 415, the flow guide surface 415 may extend to the bottom surface of the air guide assembly 50, and a projection of a bottom edge of the flow guide surface 415, which is adjacent to the water receiving tray 48, on a horizontal plane is located in a projection of the water receiving cavity 481 on the horizontal plane. In the process that the condensed water on the air guide assembly 50 flows downwards along the outer wall surface of the air guide assembly 50, because the projection of the bottom edge of the flow guide surface 415 on the horizontal plane is located in the projection of the water receiving cavity 481 on the horizontal plane, the condensed water can be guided into the water receiving cavity 481 of the water receiving tray 48 through the flow guide surface 415 at the bottom of the air guide assembly 50, and the condensed water on the outer wall surface of the air guide assembly 50 can be prevented from dropping to the ground. The "outer wall surface of the air guide assembly 50" refers to a wall surface of the air guide assembly 50 facing outward when the air guide assembly 50 is at a position closing the air outlet end of the air outlet duct 11.

Optionally, the wind guiding assembly 50 may be a wind guiding plate, and the wind guiding assembly 50 may also include a wind guiding plate and other wind guiding structures.

According to the air guiding component 4 of the embodiment of the present invention, the water receiving tray 48 is disposed on the bottom surface of the air guiding component 50, so as to receive the condensed water generated on the air guiding component 50, and even if a part of the air guiding component 4 is located outside the air outlet 106 of the air conditioner during the rotation process of the air guiding component 4, the water receiving tray 48 can still receive the condensed water generated on the air guiding component 50; moreover, the part of the outer wall surface of the air guide assembly 50, which is adjacent to the water receiving tray 48, is formed into the flow guide surface 415, the projection of the bottom edge of the flow guide surface 415 on the horizontal plane is positioned in the projection of the water receiving cavity 481 on the horizontal plane, so that the condensed water generated by the air guide assembly 50 can be guided into the water receiving cavity 481 of the water receiving tray 48 through the flow guide surface 415, the condensed water on the air guide assembly 50 is effectively prevented from dripping onto the ground and other parts in the air conditioner, the inconvenience brought to users due to the fact that the condensed water drips onto the ground is effectively avoided, and meanwhile, the potential safety hazard is reduced.

According to some embodiments of the present disclosure, the projection of the diversion surface 415 on the horizontal plane is located within the projection of the water pan 48 on the horizontal plane. Therefore, when the condensed water on the outer air deflector 41 flows downwards to the diversion surface 415, the condensed water on the diversion surface 415 can be ensured to flow into the water pan 48 uniformly, and the condensed water is better prevented from falling out of the water pan 48 to bring potential safety hazards and inconvenience.

According to some embodiments of the present invention, referring to fig. 26 and fig. 29, at least a portion of the flow guiding surface 415 is located in the water receiving cavity 481, for example, a portion of the flow guiding surface 415 may be located in the water receiving cavity 481, or the entire flow guiding surface 415 may be located in the water receiving cavity 481. By making at least a part of the flow guide surface 415 located in the water receiving cavity 481, it can be better ensured that the condensed water flowing downward on the wind guide assembly 50 to the flow guide surface 415 is guided into the water receiving cavity 481 of the water receiving tray 48. The portion of the inner sidewall of the water receiving chamber 481 opposite to the flow guide surface 415 may be spaced apart from the flow guide surface 415, so that a flow guide space 483 is formed between the inner sidewall of the water receiving chamber 481 and the flow guide surface 415. By making the inner side wall of the water receiving cavity 481 and the part opposite to the flow guide surface 415 spaced apart from the flow guide surface 415, when the condensed water on the air guide assembly 50 flows downwards onto the flow guide surface 415, the flow guide space 483 can provide a flow space for the condensed water flowing onto the flow guide surface 415, so as to prevent the condensed water flowing onto the flow guide surface 415 from falling down to the outside of the water receiving tray 48, and further, the condensed water on the air guide assembly 50 can be effectively prevented from falling down to the ground.

According to some embodiments of the present invention, referring to fig. 26 and 29, a portion of the outer wall surface of the wind guiding assembly 50 adjacent to the water receiving tray 48 is recessed inward (the "recessed inward" refers to a recess toward a direction adjacent to the center of the air conditioner, with respect to a position where the wind guiding member 4 is located at the wind outlet end of the wind outlet channel 11), so as to form the wind guiding surface 415. Therefore, the other parts of the outer wall surface of the guide surface 415, which are opposite to the guide assembly, are recessed inwards, so that condensed water on the air guide assembly 50 can flow inwards when flowing downwards to the guide surface 415, and flows into the water receiving cavity 481 of the water receiving tray 48 under the guide effect of the guide surface 415, and therefore the condensed water on the air guide assembly 50 can be effectively prevented from falling to the ground.

In some optional embodiments of the present invention, referring to fig. 26 and 29, at least a portion of the diversion surface 415 is located in the water receiving cavity 481, a portion of the outer wall surface of the wind guiding assembly 50 adjacent to the water receiving tray 48 is recessed inward to form the diversion surface 415, and a portion of the inner wall of the water receiving cavity 481 opposite to the diversion surface 415 can be conveniently spaced apart from the diversion surface 415. For example, a part of the flow guide surface 415 may be located in the water receiving cavity 481, or the whole flow guide surface 415 may be located in the water receiving cavity 481, so that at least a part of the flow guide surface 415 is located in the water receiving cavity 481, and it can be better ensured that the condensed water flowing downward on the air guide assembly 50 to the flow guide surface 415 is guided into the water receiving cavity 481 of the water receiving tray 48. The part of the inner side wall of the water receiving cavity 481 opposite to the flow guide surface 415 can be spaced from the flow guide surface 415, so that a flow guide space 483 is formed between the inner side wall of the water receiving cavity 481 and the flow guide surface 415, and the formation of the flow guide space 483 can be facilitated

According to some embodiments of the present invention, referring to fig. 26 and 29, at least a portion of the flow guiding surface 415 extends in an inward inclined direction in a direction from top to bottom (the "inward inclined extension" refers to an inclined extension in a direction adjacent to the center of the air conditioner, with respect to a position where the air guiding part 4 is located at the air outlet end of the air outlet channel 11. For example, a portion of the flow guide surface 415 may extend obliquely inward in the top-to-bottom direction, or the entire flow guide surface 415 may extend obliquely inward in the top-to-bottom direction. By extending at least a part of the flow guiding surface 415 in an inward inclined manner in the direction from top to bottom, when the condensed water on the air guiding assembly 50 flows downwards to the flow guiding surface 415, the flow guiding surface 415 can guide the condensed water downwards and inwards to the water receiving cavity 481 of the water receiving tray 48, so that the flow guiding surface 415 has a better flow guiding effect.

In some embodiments of the present invention, referring to fig. 26, the flow guiding surface 415 may include a first flow guiding portion 4151 and a second flow guiding portion 4152, the first flow guiding portion 4151 may be connected to an upper side of the second flow guiding portion 4152, both the first flow guiding portion 4151 and the second flow guiding portion 4152 may extend in an inward inclined manner in a direction from top to bottom, the first flow guiding portion 4151 extends in an inward inclined manner in a direction from top to bottom, and the second flow guiding portion 4152 extends in an inward inclined manner in a direction from top to bottom. First diversion part 4151 is located above water receiving tray 48, and at least a part of second diversion part 4152 is located in water receiving cavity 481, for example, a part of second diversion part 4152 may be located in water receiving cavity 481 of water receiving tray 48, or the whole second diversion part 4152 may be located in water receiving cavity 481. An included angle between the first flow guide portion 4151 and the vertical direction is greater than an included angle between the second flow guide portion 4152 and the vertical direction. Therefore, the included angle between the first flow guide part 4151 positioned on the upper side and the vertical direction is larger, so that condensed water on the air guide assembly 50 can be guided to be positioned right above the water receiving cavity 481 under the guiding effect of the first flow guide part 4151, the condensed water flows downwards to the second flow guide part 4152 from the first flow guide part 4151 and flows to the water receiving cavity 481 from the second flow guide part 4152, and the condensed water can quickly flow to the water receiving cavity 481 along the second flow guide part 4152 due to the fact that the included angle between the second flow guide part 4152 and the vertical direction is smaller.

In some optional embodiments of the present invention, referring to fig. 26, the portion of the outer wall surface of the wind guiding assembly 50 excluding the flow guiding surface 415 is an outer body surface 414, and the outer body surface 414 is connected to the upper side of the flow guiding surface 415. The flow guide surface 415 may further include a first transition portion 4154 located at an upper side of the first flow guide portion 4151, the first transition portion 4154 may be connected between the outer body surface 414 and the first flow guide portion 4151, and the first transition portion 4154 has an outwardly convex arc shape. The first diversion part 4151 is connected with the rest part (i.e., the outer body surface 414) of the outer wall surface of the air guide assembly 50 except for the diversion surface 415 through the first transition part 4154, and the first transition part 4154 is in an outward convex arc shape, so that the first diversion part 4151 and the outer body surface 414 can be in smooth transition, and thus, in the process that the condensed water on the outer body surface 414 flows to the first diversion part 4151, the condensed water can flow to the first diversion part 4151 along the first transition part 4154, the flow of the condensed water is smoother, and the flow resistance of the condensed water is reduced.

Alternatively, the angle between the first flow guide portion 4151 and the vertical direction may be 40-50 °, for example, the angle between the first flow guide portion 4151 and the vertical direction may be 45 °; the angle between the second flow guide portion 4152 and the vertical direction may be 25-35 °, for example, the angle between the second flow guide portion 4152 and the vertical direction may be 28 °.

In some optional embodiments of the present invention, referring to fig. 26, the flow guiding surface 415 may further include a third flow guiding portion 4153 located on an upper side of the second flow guiding portion 4152, the third flow guiding portion 4153 may be connected between the first flow guiding portion 4151 and the second flow guiding portion 4152, and an included angle between the third flow guiding portion 4153 and the vertical direction is smaller than an included angle between the second flow guiding portion 4152 and the vertical direction. The condensed water on the outer body surface 414 flows downwards to the first diversion part 4151, then flows through the third diversion part 4153, and then flows to the second diversion part 4152, and the third diversion part 4153 with a smaller included angle with the vertical direction is arranged between the first diversion part 4151 and the second diversion part 4152, so that the condensed water is guided to be positioned right above the water receiving cavity 481 by the first diversion part 4151, and then is guided to the second diversion part 4152 more quickly by the guide effect of the third diversion part 4153, and finally is guided to the water receiving cavity 481 by the quick guide of the second diversion part 4152.

Alternatively, the angle between the third flow guide portion 4153 and the vertical direction may be 0 to 10 °, for example, the angle between the third flow guide portion 4153 and the vertical direction may be 0 °, that is, the third flow guide portion 4153 extends in the vertical direction, so that the condensed water may more rapidly flow to the second flow guide portion 4152 along the third flow guide portion 4153.

Further, referring to fig. 26, the flow guiding surface 415 may further include a second transition portion 4155 located on an upper side of the third flow guiding portion 4153, the second transition portion 4155 is connected between the third flow guiding portion 4153 and the first flow guiding portion 4151, and the second transition portion 4155 is shaped as an inwardly concave arc. The third diversion portion 4153 is connected with the first diversion portion 4151 through the second transition portion 4155, and the second transition portion 4155 is shaped like an inwardly concave arc, so that smooth transition between the first diversion portion 4151 and the third diversion portion 4153 can be realized, and in the process that the condensed water flowing through the first diversion portion 4151 flows to the third diversion portion 4153, the condensed water can flow to the third diversion portion 4153 along the second transition portion 4155, the flow of the condensed water is smoother, and the flow resistance of the condensed water is reduced.

According to some embodiments of the present invention, referring to fig. 26, at least a portion of the inner sidewall of the water receiving chamber 481 is formed as a drainage surface 482, the drainage surface 482 extends to the upper end surface of the water receiving tray 48, and the drainage surface 482 extends in an inclined manner in a direction from top to bottom toward a direction adjacent to the center of the water receiving chamber 481. Can increase the water receiving area of water receiving chamber 481 like this to when the comdenstion water on the air guide component 50 fell to the drainage face 482 of water conservancy diversion subassembly water collector on, through the drainage effect of drainage face 482, can be with comdenstion water drainage to water receiving chamber 481 in, further reduce the comdenstion water on the air guide component 50 and fall to the probability outside water receiving tray 48, reduce the potential safety hazard, also reduce the inconvenience that causes the user.

Optionally, referring to fig. 26, a portion of the flow guide surface 415 located in the water receiving cavity 481 is opposite to and spaced from the flow guide surface 482, so that a space defined between the flow guide surface 415 and the flow guide surface 482 may form at least a portion of the flow guide space 483, and both the condensed water flowing downward on the flow guide surface 415 above the air guide assembly 50 and the condensed water falling onto the flow guide surface 482 above the air guide assembly 50 may be accommodated in the flow guide space 483 and guided into the water receiving cavity 481 quickly and smoothly.

For example, referring to fig. 26, in some embodiments of the present invention, the flow guiding surface 415 includes the first flow guiding portion 4151, the second flow guiding portion 4152, the third flow guiding portion 4153, the first transition portion 4154 and the second transition portion 4155, and an upper portion of an inner sidewall of the water receiving chamber 481 is formed as the flow guiding surface 482. The second flow guide parts 4152 are located in the water receiving cavity 481, the third flow guide parts 4153 are located right above the water receiving cavity 481, the flow guide surfaces 482 and the second flow guide parts 4152 are opposite and spaced, and at least one part of a flow guide space 483 is defined between the flow guide surfaces 482 and the second flow guide parts 4152. The condensed water on the outer wall surface of the wind guiding assembly 50 flows down to the flow guiding surface 415 along the outer body surface 414, and the condensed water on the outer body surface 414 flows through the first transition portion 4154, the first flow guiding portion 4151, the second transition portion 4155, the third flow guiding portion 4153 and the second flow guiding portion 4152 in sequence in the process of flowing down to the flow guiding surface 415, and finally flows into the water receiving cavity 481 of the water receiving tray 48. The condensed water falling to the drainage surface 482 on the air guide assembly 50 also flows into the water receiving cavity 481 of the water receiving tray 48 through the drainage function of the drainage surface 482, so that the probability that the condensed water falling to the outside of the water receiving tray 48 on the air guide assembly 50 is better reduced, the potential safety hazard is reduced, and the inconvenience caused to users is also reduced.

For another example, in other embodiments of the present invention, the flow guiding surface 415 includes the first flow guiding portion 4151 and the second flow guiding portion 4152, an included angle between the first flow guiding portion 4151 and the vertical direction may be 90 °, an included angle between the second flow guiding portion 4152 and the vertical direction may be 0 °, the first flow guiding portion 4151 and the outer body surface 414 may be in transition connection through a curved arc surface, and the first flow guiding portion 4151 and the second flow guiding portion 4152 may be in transition connection through a curved arc surface.

According to some embodiments of the present invention, referring to fig. 27-29 in combination with fig. 1-23, the outer wall surface of the air guiding part 4 is formed with an air dispersing structure 411 for allowing air flow to pass through, so that when the air guiding part 4 is used in an air conditioner, the air conditioner can have a normal air supply mode and a no-wind mode. In the normal air supply mode, the air guide part 4 rotates to the position of the air outlet end of the air outlet channel 11, and the air guide part 4 plays a role in adjusting the wind direction; in the non-wind-sensing mode, the wind guide part 4 rotates to the position of closing the wind outlet end of the wind outlet channel 11, and the airflow flows into the room through the wind dispersing structure 411 on the wind guide part 4, so that the airflow can be dispersed, and the non-wind sensing can be realized.

According to some embodiments of the present invention, referring to fig. 24-34, the air guide assembly 50 includes: an outer wind deflector 41 and an inner wind deflector assembly 501. The outer wall surface of the outer wind deflector 41 forms the outer wall surface of the wind guide assembly 50, a flow channel 484 through which water can pass is defined between the bottom surface of the outer wind deflector 41 and the inner bottom wall surface of the water receiving cavity 481, for example, the bottom surface of the outer wind deflector 41 may be spaced apart from the inner bottom wall surface of the water receiving cavity 481 to form the flow channel 484, and the two parts of the water receiving cavity 481 located at the two opposite sides of the outer wind deflector 41 can be communicated by defining the flow channel 484 through which water can pass between the bottom surface of the outer wind deflector 41 and the water receiving cavity 481.

Thus, a flow channel 484 is formed between the bottom surface of the outer air deflector 41 and the inner bottom wall surface of the water receiving cavity 481, so that when condensed water on the outer air deflector 41 flows into the water receiving cavity 481 of the water receiving tray 48 through the flow guide surface 415, the condensed water can timely flow to other parts in the water receiving cavity 481 through the flow channel 484, and the condensed water is prevented from accumulating in partial areas in the water receiving cavity 481 and overflowing outwards. The inner wind guiding assembly 501 is arranged on the outer wind guiding plate 41, the inner wind guiding assembly 501 is located on the inner side of the outer wind guiding plate 41 (the inner side refers to the side, adjacent to the center of the whole machine, of the outer wind guiding plate 41 when the wind guiding part 4 rotates to close the wind outlet end of the wind outlet channel 11), the water receiving tray 48 can be arranged on the bottom surface of the inner wind guiding assembly 501, the water receiving tray 48 can be connected with the inner wind guiding assembly 501, and therefore the connection between the water receiving tray 48 and the wind guiding assembly 50 can be achieved.

According to some optional embodiments of the present invention, referring to fig. 24 to 33, the inner wind guiding assembly 501 may include an inner wind guiding plate 43, the inner wind guiding plate 43 may be connected to the outer wind guiding plate 41, the water receiving tray 48 may be disposed on the bottom surface of the inner wind guiding plate 43, and the water receiving tray 48 is connected to the inner wind guiding plate 43, so that the connection between the water receiving tray 48 and the wind guiding assembly 50 may be achieved. The inner air deflector 43 and the water receiving tray 48 can be integrally formed, so that the assembling process of the air guide part 4 can be reduced; or, the inner air deflector 43 and the water pan 48 can be independent formed parts, and the inner air deflector 43 and the water pan 48 are respectively and independently processed and formed and then connected and assembled, so that the water pans 48 with different structures can be selected according to actual conditions under the condition that the air guide assemblies 50 are the same in structure.

In some optional embodiments of the present invention, the bottom surface of the inner wind deflector 43 may be formed with a notch 434, and the notch 434 may communicate with two portions of the water receiving cavity 481 located at two opposite sides of the inner wind deflector 43, so that two portions of the water receiving cavity 481 located at two opposite sides of the inner wind deflector 43 may communicate with each other, so that the condensed water falling into the water receiving cavity 481 may flow to other portions of the water receiving cavity 481 through the notch 434, so that the condensed water is uniformly distributed in the water receiving cavity 481, and the condensed water is prevented from being accumulated too much in the water receiving cavity 481.

According to some embodiments of the present invention, the bottom surface of the drip tray 48 may be provided with a water absorbing member 486. By providing the water absorbing member 486 on the bottom surface of the water receiving tray 48, the water absorbing member 486 can absorb the condensed water on the bottom surface of the water receiving tray 48, and the condensed water on the bottom surface of the water receiving tray 48 can be prevented from dropping onto the floor or other components in the air conditioner. For example, even if a part of the air guide member 4 is positioned outside the outlet 106 of the air conditioner during the rotation of the air guide member 4, the water absorbing member 486 is provided on the bottom surface of the air guide member 4, so that the water absorbing member 486 can absorb the condensed water on the bottom surface of the air guide member 4, and the condensed water on the bottom surface of the air guide member 4 can be prevented from falling to the ground. Alternatively, the water absorbing member 486 may be a sponge member.

According to some optional embodiments of the present invention, referring to fig. 26, the projection of the inner bottom wall surface of the water receiving cavity 481 on the horizontal plane is located in the projection of the water absorbing member 486 on the horizontal plane, so that the position of the bottom surface of the water receiving tray 48, where the condensed water is easily generated, is covered by the water absorbing member 486, and the condensed water generated on the bottom surface of the water receiving tray 48 can be better absorbed by the water absorbing member 486.

According to some optional embodiments of the utility model, refer to fig. 26, the bottom surface of water collector 48 is formed with holding tank 485, and the piece 486 that absorbs water is located in holding tank 485. The installation of the water absorbing member 486 is facilitated by the accommodating groove 485 provided. Alternatively, the bottom surface of the absorbent member 486 is flush with the bottom surface of the drip tray 48, which allows the absorbent member 486 to have a larger volume and thus a larger water absorbing capacity, even though the structure is compact.

According to some embodiments of the present invention, referring to fig. 24-33, the air guide assembly 50 includes: the air duct assembly comprises an outer air deflector 41 and an inner air deflector 501, wherein the inner air deflector 501 can be arranged on the outer air deflector 41, and the inner air deflector 501 is positioned at the inner side of the outer air deflector 41. The outer wall surface of the outer air guiding plate 41 forms the outer wall surface of the air guiding component 4, the outer air guiding plate 41 may be formed with an air dispersing structure 411 through which the air flow can pass, and the air dispersing structure 411 may include a plurality of air dispersing holes. The inner wind guiding assembly 501 may include an inner wind guiding plate 43, a guide vane assembly 46, and a louver mechanism 47, the inner wind guiding plate 43 may be connected to the outer wind guiding plate 41, and the guide vane assembly 46 may be disposed on the inner wind guiding plate 43. The guide vane assembly 46 may include a plurality of rotatable movable vanes 461, the movable vanes 461 are arranged along the length direction (for example, the vertical direction) of the inner wind guide plate 43, and the movable vanes 461 are located between the outer wind guide plate 41 and the inner wind guide plate 43. The inner wind guide plate 43 is provided with wind passing holes 433 at positions opposite to the movable blades 461, and the wind passing holes 433 correspond to the movable blades 461 in the same number one by one. The louver mechanism 47 is disposed on a side of the inner air guiding plate 43 away from the outer air guiding plate 41, and the louver mechanism 47 can adjust the direction of the air flow. The water pan 48 is connected to at least one of the outer air deflector 41 and the inner air deflector 43, for example, the water pan 48 may be connected to the outer air deflector 41, the water pan 48 may be connected to the inner air deflector 43, or the water pan 48 may be connected to both the outer air deflector 41 and the inner air deflector 43.

When the air guiding component 4 is used in an air conditioner, the air flow may first flow through the plurality of movable blades 461, the plurality of movable blades 461 rotating may make the air flow form a rotational flow, the air flow passing through the movable blades 461 passes through the air passing hole 433, then blows towards the outer air guiding plate 41 through the guiding function of the louver mechanism 47, and finally blows towards the indoor through the air dispersing structure 411 on the outer air guiding plate 41. After the airflow passes through the air guide assembly 50, the blown airflow can be softer and closer to natural wind.

For example, in some embodiments of the present invention, referring to fig. 24-33, the wind guiding assembly 50 includes an outer wind guiding plate 41 and an inner wind guiding assembly, wherein the inner wind guiding assembly includes an inner wind guiding plate 43, a guide vane assembly 46 and a louver mechanism 47, the inner wind guiding plate 43 can be connected to the outer wind guiding plate 41, the water receiving tray 48 is disposed on the bottom surface of the inner wind guiding plate 43, and the water receiving tray 48 is connected to the inner wind guiding plate 43. The guide vane assembly 46 and the louver mechanism 47 are both disposed on the inner wind deflector 43, the guide vane assembly 46 may include a stationary vane 462 and a rotatable movable vane 461, the movable vane 461 is a plurality of blades arranged at intervals in the vertical direction, and the movable vane 461 is located between the outer wind deflector 41 and the inner wind deflector 43. The inner wind guide plate 43 is provided with air passing holes 433 at positions corresponding to the movable blades 461, the number of the air passing holes 433 is the same as that of the movable blades 461, the air passing holes 433 correspond to the movable blades 461 one by one, each air passing hole 433 is provided with a stationary blade 462, and the stationary blade 462 is fixed relative to the inner wind guide plate 43.

The louver mechanism 47 is disposed on a side of the inner air guiding plate 43 away from the outer air guiding plate 41. The louver mechanism 47 includes a connecting rod 471 and a plurality of louvers 472, the connecting rod 471 extends in the up-down direction and can move in the up-down direction, the plurality of louvers 472 are arranged at intervals in the up-down direction, each louver 472 is rotatably connected with the connecting rod 471 and the inner air guiding plate 43, and the number of the louvers 472 is the same as that of the air passing holes 433 and corresponds to one another. Specifically, the stationary blade 462 disposed in each wind passing hole 433 has a stationary blade hub 4621, each movable blade 461 has a movable blade rotating shaft 4611, each louver 472 has a louver rotating shaft 4721, the louver rotating shaft 4721 of each louver 472 is connected and relatively fixed with the movable blade rotating shaft 4611 of the corresponding movable blade 461, the movable blade rotating shaft 4611 of each movable blade 461 is rotatably fitted in the corresponding stationary blade hub 4621, each movable blade 461 is connected with the louver rotating shaft 4721, and the louver rotating shaft 4721 can synchronously rotate the corresponding movable blade 461.

Wherein, referring to fig. 8-11, the louver driving mechanism 3 for driving the louver mechanism 47 to move may be disposed below the louver mechanism 47, and the louver driving mechanism 3 may include a louver driving motor 31, a driving gear 32, and a driving rack 33. The driving gear 32 is connected and fixed on the motor shaft of the louver driving motor 31, the driving gear 32 is meshed with the driving rack 33, and the driving rack 33 is connected with the connecting rod 471. When the louver driving motor 31 works, the driving gear 32 is driven to rotate, and the driving gear 32 is meshed with the driving rack 33 to drive the driving rack 33 to move in the vertical direction, so that the connecting rod 471 is driven to move in the vertical direction, the plurality of louvers 472 are driven to swing, the plurality of louvers 472 can swing to a set direction, and the plurality of louvers 472 can also swing in a reciprocating manner.

Further, referring to fig. 32 and 33, the wind guide member 4 may further include a sliding assembly 49, and the sliding assembly 49 is disposed at a lower end of the wind guide assembly 50. The sliding assembly 49 includes a mounting block 491, a slider 492, and a sliding cover 493, wherein the mounting block 491 may be removably mounted to the inner air deflector 43. For example, a notch 434 is formed at the lower end of the inner wind deflector 43, the mounting block 491 is matched with the notch 434, the mounting block 491 is fixed relative to the inner wind deflector 43, the bottom surface of the mounting block 491 and the inner bottom wall surface of the water receiving cavity 481 can be arranged at a distance, so that the notch 434 plays a role of mounting and accommodating the mounting block 491, and simultaneously the part of the notch 434 located at the lower side of the mounting block 491 can also play a role of communicating two parts of the water receiving cavity 481 located at two opposite sides of the inner wind deflector 43, that is, the part of the notch 434 located at the lower side of the mounting block 491 forms a communication port which can communicate two parts of the water receiving cavity 481 located at two opposite sides of the inner wind deflector 43, so that the two parts of the water receiving cavity 481 located at two opposite sides of the inner wind deflector 43 can communicate with each other parts of the water receiving cavity 481 through the notch 434, and the condensed water falling into the water receiving cavity 481 can flow to other parts of the water receiving cavity 481, so that the condensed water is uniformly distributed in the water receiving cavity 481 and the condensed water is prevented from accumulating too much in the local area of the water receiving cavity 481 and overflowing.

The mounting block 491 is formed with a sliding slot 4911 extending in the up-down direction, the sliding block 492 is slidably fitted to the sliding slot 4911 in the up-down direction, the connecting rod 471 is connected to the sliding block 492, the driving rack 33 is also connected to the sliding block 492, and the sliding cover 493 can cover the side of the sliding block 492 connected to the connecting rod 471. When the louver driving motor 31 works, the driving gear 32 is driven to rotate, the driving gear 32 is meshed with the driving rack 33, the driving rack 33 can be driven to move in the up-down direction, the sliding block 492 slides along the sliding groove 4911 in the moving process, the sliding block 492 can stably move in the up-down direction, the connecting rod 471 can also be driven to stably move in the up-down direction, the plurality of louvers 472 are driven to swing, the plurality of louvers 472 can swing to the set direction, and the plurality of louvers 472 can also swing in a reciprocating mode.

Referring to fig. 30, 31, 33, and 34, the wind guide driving mechanism 2 for driving the wind guide member 4 to rotate may be provided above the wind guide member 4, and the wind guide driving mechanism 2 may include a motor. The wind guide part 4 may further include a connecting member 40, and the connecting member 40 is disposed at an upper end of the wind guide assembly 50. The connecting piece 40 has a locking state and an unlocking state, the connecting piece 40 comprises a connecting part 401 and a positioning part 402, the positioning part 402 is switchable between a first position and a second position relative to the connecting part 401, and the wind guide driving mechanism 2 is suitable for being connected with the connecting part 401 to drive the wind guide part 4 to rotate. The air guide assembly 50 is formed with an installation positioning structure for installing and positioning the connector 40 on the air guide assembly 50, and the installation positioning structure includes a locking structure engaged with the positioning portion 402.

When the positioning portion 402 is engaged with the locking structure, the positioning portion 402 is located at the first position and the connecting member 40 is located in the locking state, so that the connecting member 40 is fixed relative to the air guide assembly 50, and the connecting member 40 connects the air guide assembly 50 and the air guide driving mechanism 2, thereby conveniently realizing the connection between the air guide component 4 and the air guide driving mechanism 2. When the positioning portion 402 is disengaged from the locking structure, the positioning portion 402 is located at the second position and the connecting member 40 is located in the unlocking state, at this time, the connecting member 40 can be detached from the air guide assembly 50 along the downward direction, and meanwhile, the connecting member 40 can be disengaged from the air guide driving mechanism 2, so that the air guide component 4 can be disengaged from the air guide driving mechanism 2, and the air guide component 4 is convenient to detach. For example, when the air guiding component 4 needs maintenance, the air guiding component 4 can be conveniently detached. When the air guiding component 4 needs to be installed, the connecting piece 40 can be installed on the air guiding assembly 50, for example, the connecting portion 401 can be connected with the air guiding driving mechanism 2, and the positioning portion 402 is matched with the locking structure, so that the connecting piece 40 can be installed and fixed on the air guiding assembly 50, and meanwhile, the connecting piece 40 is connected with the air guiding driving mechanism 2, and the installation of the air guiding component 4 can be conveniently realized.

Wherein the positioning part 402 can be switched between the first position and the second position by elastic deformation, and the positioning part 402 is in a natural state in the first position. By applying an acting force to the positioning portion 402, the positioning portion 402 is deformed, so that the positioning portion 402 is switched between the first position and the second position, and the positioning portion 402 is conveniently engaged with and disengaged from the locking structure, thereby conveniently unlocking and locking the connecting member 40. In addition, by making the positioning portion 402 in the natural state when being located at the first position, the connection member 40 is not affected by the elastic restoring force of itself when being located at the locked state, so that the connection member 40 is more reliably and stably mounted and fixed on the air guide assembly 50. Optionally, the positioning portion 402 is formed with an elastic opening 4022, so that the elastic deformability of the positioning portion 402 can be further increased.

Specifically, referring to fig. 30, 31, 33 and 34, the mounting and positioning structure includes a mounting hole 451 formed on the inner air guiding plate 43 and a locking structure, the locking structure includes an elastic buckle 435, the mounting hole 451 is formed on the second inner plate 450 of the inner air guiding plate 43, the connecting portion 401 is inserted into the mounting hole 451 and fixed relative to the mounting hole 451, and the positioning portion 402 is further formed with a limiting protrusion 4021.

When the connecting piece 40 is in a locked state, the connecting part 401 penetrates through the mounting hole 451 and is suitable for the connection of the air guide driving mechanism 2, the positioning part 402 is abutted to the inner air guide plate 43, the elastic buckles 435 are positioned on two opposite sides of the positioning part 402 in the left-right direction, the elastic buckles 435 are clamped with the positioning part 402, the limiting protrusions 4021 and the elastic buckles 435 are in limiting abutment in the up-down direction, so that the connecting piece 40 can be mounted and fixed on the air guide assembly 50, the connection of the air guide component 4 and the air guide driving mechanism 2 can be further realized, and the assembly of the air guide component 4 is convenient.

When the connector 40 is in the unlocked state, the connecting portion 401 can be separated from the mounting hole 451 in the downward direction, so that the air guide member 4 is separated from the air guide driving mechanism 2, and the air guide member 4 can be detached. Wherein, can be formed with shaft hole 4011 in connecting portion 401, in the drive shaft cooperation of wind guide actuating mechanism 2 to shaft hole 4011, exert the effort to connecting piece 40 along upper and lower direction, can make the drive shaft of wind guide actuating mechanism 2 and the shaft hole 4011 of connecting piece 40 break away from the cooperation, also make connecting piece 40 and mounting hole 451 break away from the cooperation simultaneously.

For example, when the air guiding component 4 needs to be detached, the positioning portion 402 and the elastic buckle 435 may be disengaged, so that the connecting member 40 is in an unlocked state, and at this time, a force in a direction away from the air guiding driving mechanism 2 may be applied to the connecting member 40 in a downward direction, so that the connecting member 40 may be disengaged from the air guiding driving mechanism 2, and the air guiding component 4 may be conveniently detached. When the air guiding component 4 needs to be installed on the whole machine, the connecting part 401 of the connecting piece 40 can be matched into the installation hole 451 on the inner air guiding plate 43, so that the positioning part 402 is matched with the elastic buckle 435, the connecting piece 40 is installed and fixed on the air guiding component 50, and meanwhile, the connecting part 401 of the connecting piece 40 is connected with the air guiding driving mechanism 2, and the air guiding component 4 is conveniently installed.

According to some embodiments of the present invention, the air guide assembly 50 includes: an outer wind deflector 41 and an inner wind deflector assembly 501. The inner air guiding assembly 501 is arranged on the outer air guiding plate 41, the inner air guiding assembly 501 is located on the inner side of the outer air guiding plate 41, one of the outer air guiding plate 41 and the inner air guiding assembly 501 is provided with a first limiting groove, and the other of the outer air guiding plate 41 and the inner air guiding assembly 501 is provided with a first limiting buckle. For example, a first limit groove is arranged on the outer air deflector 41, and a first limit buckle is arranged on the inner air deflector 501; or, a first limit groove is arranged on the inner air guiding assembly 501, and a first limit buckle is arranged on the outer air guiding plate 41. Wherein, first spacing groove includes sliding area and spacing district, and first spacing buckle is suitable for along sliding area slip spacing district and with spacing cooperation of distinguishing.

When the outer air deflector 41 and the inner air guiding assembly 501 are assembled, the first limiting buckle can slide into the limiting area through the sliding area of the first limiting groove, and the first limiting buckle is accommodated and matched in the limiting area of the first limiting groove, so that the assembly of the outer air deflector 41 and the inner air guiding assembly 501 can be conveniently realized; when the outer air deflector 41 is required to be detached from the inner air guide assembly 501, the outer air deflector 41 can be pushed, so that the first limiting buckle slides to the sliding area from the limiting area of the first limiting groove and finally breaks away from the sliding area, and the first limiting buckle and the first limiting groove are separated from each other to be matched, so that the outer air deflector 41 can be detached from the inner air guide assembly 501, and the outer air deflector 41 and the inner air guide assembly 501 can be cleaned and maintained conveniently. The design of the connecting structure between the outer air deflector 41 and the inner air deflector 501 enables the outer air deflector 41 to be easily disassembled and assembled, the outer air deflector 41 to be easily installed, and the problems that a fixed buckle connecting structure is difficult to disassemble and break a buckle, and the operation is poor in convenience are solved.

According to some optional embodiments of the present invention, the inner wind guiding assembly 501 comprises an inner wind guiding plate 43, a first limiting groove is formed on the side wall of the inner wind guiding plate 43, a first limiting buckle is formed on the outer wind guiding plate 41, and the sliding area penetrates through the side wall surface of the inner wind guiding plate 43 facing the outer wind guiding plate 41. When the outer air deflector 41 is installed on the inner air deflector 43, the first limiting buckle on the outer air deflector 41 firstly enters the sliding area of the first limiting groove, and after the first limiting buckle enters the sliding area of the first limiting groove, the first limiting buckle slides into the limiting area of the first limiting groove by pushing the outer air deflector 41, so that the outer air deflector 41 is convenient to disassemble and assemble.

In some embodiments of the present invention, a step surface is formed between the sliding region and the limiting region, at least a portion of the inner wall surface of the limiting region is formed as a guide surface, the guide surface extends to the step surface, and the guide surface extends obliquely toward a direction adjacent to the outer air deflector 41 in a direction from the limiting region to the sliding region. When the outer air deflector 41 is installed on the inner air deflector 43, the first limiting buckle on the outer air deflector 41 can enter the sliding area of the first limiting groove first, for example, the outer air deflector 41 can be pushed along the horizontal direction so that the first limiting buckle on the outer air deflector 41 enters the sliding area of the first limiting groove first, and in the process that the first limiting buckle enters the sliding area, the first limiting buckle slides along the step surface. After the first limiting buckle enters the sliding area of the first limiting groove, the outer air deflector 41 is pushed, for example, the outer air deflector 41 can be pushed in the vertical direction, so that the first limiting buckle smoothly slides into the limiting area of the first limiting groove under the guiding action of the guiding surface, and the outer air deflector 41 is conveniently mounted on the inner air deflector 43.

When the outer air deflector 41 needs to be detached, the outer air deflector 41 can be pushed, for example, the outer air deflector 41 can be pushed in the vertical direction, so that the first limiting buckle slides to the sliding region from the limiting region of the first limiting groove, and the first limiting buckle can smoothly slide into the sliding region from the limiting region through the guiding effect of the guiding surface in the process. Then, the outer air guiding plate 41 is pushed, for example, the outer air guiding plate 41 is pushed in the horizontal direction, so that the first limiting buckle is separated from the sliding region, and the first limiting buckle is separated from the first limiting groove, so that the outer air guiding plate 41 can be detached from the inner air guiding plate 43, and the outer air guiding plate 41 and the inner air guiding plate 43 can be conveniently cleaned and maintained.

In some optional embodiments of the utility model, the outer aviation baffle 41 is last still to be formed with the spacing buckle of second, still is formed with the second spacing groove on the inner aviation baffle 43, the spacing buckle of second is suitable for the cooperation to hold to the second spacing groove, the spacing buckle of second and the cooperation of second spacing groove can be spacing in the direction of difference to outer aviation baffle 41, for example the cooperation of first spacing groove and first spacing buckle, can realize spacing in the front and back direction, spacing in the left and right direction can be realized to the cooperation of the spacing buckle of second spacing groove and second. On the basis of the matching of the first limiting groove and the first limiting buckle, the matching of the second limiting groove and the second limiting buckle is added, so that the outer air deflector 41 can be limited in different directions, and the installation and the positioning of the outer air deflector 41 are more stable and reliable.

In some optional embodiments of the present invention, the outer wind deflector 41 is formed with a first fixing hole, the inner wind deflector 501 is formed with a second fixing hole, for example, the inner wind deflector 43 is formed with a second fixing hole, and the fastening member is disposed through the first fixing hole and the second fixing hole, so that on the basis of the above-mentioned buckle and the clamping groove, the outer wind deflector 41 and the inner wind deflector 501 are fixed by the fastening member, and the installation reliability of the outer wind deflector 41 can be further improved.

For example, when the outer air deflector 41 is installed, the primary positioning of the outer air deflector 41 can be realized by the cooperation of the first limiting groove and the first limiting buckle, or the cooperation of the first limiting groove and the first limiting buckle, and the cooperation of the second limiting groove and the second limiting buckle, and then the outer air deflector 41 can be reliably fixed on the inner air guiding assembly 501 by the fasteners penetrating through the first fixing hole and the second fixing hole. When the outer air deflector 41 needs to be detached, the fastener can be detached firstly, and then acting force is applied to the outer air deflector 41, so that the first limiting groove is disengaged from the first limiting buckle, or the first limiting groove is disengaged from the first limiting buckle, and the second limiting groove is disengaged from the second limiting buckle, so that the outer air deflector 41 can be detached conveniently.

In some embodiments of the present invention, the outer air guiding plate 41 includes an outer air guiding plate body 410 and an outer plate portion 420 disposed at one side of the outer air guiding plate body 410, the outer plate portion 420 is located at one side of the outer air guiding plate body 410 adjacent to the center of the inner air guiding plate body 430, and the first fixing hole is formed at the outer plate portion 420. The inner air guiding plate 43 includes an inner air guiding plate body 430 and an inner side plate portion disposed at one side of the inner air guiding plate body 430, the inner side plate portion includes a first inner side plate portion 440 and a second inner side plate portion 450 located at two opposite sides of the inner air guiding plate body 430, the first inner side plate portion 440 is located at one side of the inner air guiding plate body 430 close to the center of the outer air guiding plate body 410, the second fixing hole is formed on the first inner side plate portion 440, and the outer side plate portion 420 is located at one side of the first inner side plate portion 440 far away from the outer air guiding plate body 410. The surface of the outer plate portion 420 away from the outer air deflection body 410 is flush with the surface of the second inner plate portion 450 away from the inner air deflection body 430. Due to the structural arrangement, the connection between the outer air deflector 41 and the inner air deflector 43 is more convenient, and the whole air guiding component 4 is compact and attractive in structure.

Referring to fig. 1-23, an air-out frame assembly according to an embodiment of the second aspect of the present invention includes: the air-out frame 1 and wind-guiding part 4, be formed with at least one air-out passageway 11 on the air-out frame 1, for example can be formed with one air-out passageway 11 on the air-out frame 1, the air-out frame 1 also can be formed with a plurality of air-out passageways 11, for example is formed with two air-out passageways 11 on the air-out frame 1. Wind-guiding part 4 is according to the utility model discloses above-mentioned first aspect embodiment wind-guiding part 4, and wind-guiding part 4 rotationally locates air-out passageway 11. The air guide driving mechanism 2 for driving the air guide component 4 to rotate may be disposed on the air outlet frame 1 and located at one side of the air outlet channel 11.

According to the utility model discloses air-out frame subassembly, through setting up foretell wind-guiding part 4, avoided the condensate water on the wind-guiding part 50 to drip to other parts in subaerial and the air conditioner effectively to avoided the condensate water to drip the inconvenience that brings for the user to ground effectively, also reduced the potential safety hazard simultaneously.

In some optional embodiments of the present invention, the water receiving tray 48 may not have a drainage hole, and the condensed water received in the water receiving cavity 481 of the water receiving tray 48 of the wind guiding assembly 50 may be evaporated by natural air drying.

In other embodiments of the present invention, a drain hole may be disposed on the water receiving tray 48, the bottom surface of the air outlet channel 11 may be formed with an air-out frame water receiving tray, and the condensed water received in the water receiving cavity 481 of the water receiving tray 48 may be drained into the air-out frame water receiving tray through the drain hole. In the embodiment, the condensed water flowing into the water receiving tray of the air outlet frame can be evaporated by natural air drying; or a drainage channel is formed on the air outlet frame water receiving tray, condensed water flowing into the air outlet frame water receiving tray can flow into the heat exchanger water receiving tray on the bottom surface of the heat exchanger part 6 through the drainage channel, for example, the heat exchanger water receiving tray can be connected with the air outlet frame water receiving tray, and the heat exchanger water receiving tray is lower than the air outlet frame water receiving tray.

Referring to fig. 1 to 23, an air conditioner according to a third aspect of the present invention includes: according to the utility model discloses the air-out frame subassembly of above-mentioned second aspect embodiment.

According to the utility model discloses air conditioner, through setting up foretell air-out frame subassembly, avoided the condensate water on the air guide component 50 to drip to other parts subaerial and in the air conditioner effectively to avoided the condensate water to drip the inconvenience that brings for the user to ground effectively, also reduced the potential safety hazard simultaneously.

Alternatively, the air conditioner may be a split type air conditioner or an integrated type air conditioner. When the air conditioner is a split type air conditioner, the air conditioner may be a split wall-mounted air conditioner or a split floor type air conditioner. When the air conditioner is a split air conditioner, the air conditioner comprises an air conditioner indoor unit 1000 and an air conditioner outdoor unit, wherein the air conditioner indoor unit comprises the air outlet frame assembly.

Specifically, the air-conditioning indoor unit 1000 includes a casing 100, a heat exchanger component 6, a fan component 5, an air-out frame 1 and an air guide component 4, the casing 100 includes a front panel 101, a back panel 102, a top cover 104 and a base 103, the air-out frame 1 is connected to the front end of the back panel 102, the front panel 101 is connected to the front side of the air-out frame 1, and the top cover 104 and the base 103 are respectively connected to the upper and lower sides of the back panel 102. The heat exchanger component 6 and the fan component 5 are both arranged in the casing 100 and located in a space defined by the air outlet frame 1 and the casing 100, at least one air outlet channel 11 is formed on the air outlet frame 1, and the air guide component 4 is rotatably arranged on the air outlet channel 11. An air outlet 106 is formed on the casing 100 at a position opposite to the air outlet side of the air outlet channel 11, the air outlet 106 may be defined between the front panel 101 and the back panel 102, and an air inlet 105 is formed on the back panel 102. The air outlet 106 may further include an opening/closing door 107, the opening/closing door 107 may be slidably disposed on the casing 100 along a circumferential direction of the casing 100, and the opening/closing of the air outlet 106 may be achieved by sliding the opening/closing door 107.

When the air conditioner works, the switch door 107 opens the air outlet 106, the fan component 5 works to drive external air flow to enter the shell 100 from the air inlet 105 to exchange heat with the heat exchanger component 6, the air flow after heat exchange flows through the air outlet channel 11, and the air flow is blown out to the indoor from the air outlet 106 after the air flow passes through the air guiding function or the air dispersing function of the air guiding component 4 in the process that the air flow passes through the air outlet channel 11, so that the indoor environment temperature can be adjusted. When the air conditioner is turned off, the opening and closing door 107 closes the outlet port 106.

Optionally, the working mode of the air conditioner may include a normal air supply mode and a no-wind-sensing mode, when the air conditioner is in the normal air supply mode, the air guiding component 4 rotates to a position where the air outlet end of the air outlet channel 11 is opened, and the air flow mainly flows to the air outlet 106 from one side or two sides of the air guiding component 4; when the air conditioner is in the no-wind-sense mode, the wind guiding component 4 rotates to the position of closing the wind outlet end of the wind outlet channel 11, and the air flow passes through the wind guiding component 4 and is blown out from the wind outlet 106 more softly under the wind dispersing action of the wind guiding component 4.

Optionally, an air outlet channel 11 may be formed on the air outlet frame 1, at this time, the air outlet 106 is one and is opposite to the air outlet channel 11, the fan component 5 may include a wind wheel 51, and the wind wheel 51 may be a cross-flow wind wheel 51.

Optionally, two air outlet channels 11 may also be formed on the air outlet frame 1, at this time, the air outlets 106 are two, the two air outlets 106 are respectively opposite to the two air outlet channels 11, the fan component 5 may include two wind wheels 51, the two wind wheels 51 may both be cross-flow wind wheels 51, the two wind wheels 51 are respectively arranged corresponding to the two air outlet channels 11, and the two wind wheels 51 respectively drive the air flow into the corresponding air outlet channels 11.

In some embodiments of the present invention, the indoor unit 1000 of the air conditioner may include a heat exchange unit 200 and an air processing unit 300, the heat exchange unit 200 and the air processing unit 300 are located in the casing 100, and the heat exchange unit 200 and the air processing unit 300 may be arranged along the length direction of the casing 100. The heat exchange unit 200 includes the heat exchanger component 6, the fan component 5, the air outlet frame 1, and the air guide component 4. The air treatment unit 300 may have at least one of fresh air, humidification, and purification functions, and the air treatment unit 300 may improve indoor environmental quality.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an illustrative embodiment," "an example," "a specific example," or "some examples" or the like 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 present invention. In this specification, the schematic representations of the terms used above do not necessarily 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.

While embodiments of the present invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.

Claims (20)

1. The utility model provides an air guide part, its characterized in that, air guide part rotationally locates the air-out passageway of air conditioner, air guide part includes:

an air guide assembly;

the water receiving tray is internally provided with a water receiving cavity and is arranged on the bottom surface of the air guide assembly so as to receive condensed water on the air guide assembly;

the part of the outer wall surface of the air guide assembly, which is adjacent to the water receiving disc, is formed into a flow guide surface, the flow guide surface extends to the bottom surface of the air guide assembly, and the projection of the flow guide surface, which is adjacent to the bottom edge of the water receiving disc, on the horizontal plane is positioned in the projection of the water receiving cavity on the horizontal plane.

2. The wind guide component of claim 1, wherein at least a portion of the flow guide surface is located in the water receiving cavity, and a portion of an inner side wall of the water receiving cavity opposite to the flow guide surface is spaced apart from the flow guide surface to form a flow guide space.

3. The air guide component of claim 1, wherein a portion of the outer wall surface of the air guide assembly adjacent to the water pan is recessed inward to form the flow guide surface.

4. The wind guide component of claim 1, wherein at least a portion of the flow guide surface extends obliquely inward in a top-to-bottom direction.

5. The wind guide component according to claim 4, wherein the flow guide surface comprises a first flow guide part and a second flow guide part, the first flow guide part is connected to the upper side of the second flow guide part, the first flow guide part and the second flow guide part both extend in an inward inclined manner in the direction from top to bottom, the first flow guide part is located above the water receiving tray, at least one part of the second flow guide part is located in the water receiving cavity, and an included angle between the first flow guide part and the vertical direction is larger than an included angle between the second flow guide part and the vertical direction.

6. The wind guide component according to claim 5, wherein the portion of the outer wall surface of the wind guide assembly excluding the flow guide surface is an outer body surface, the outer body surface is connected to the upper side of the flow guide surface, the flow guide surface further comprises a first transition portion located on the upper side of the first flow guide portion, the first transition portion is connected between the outer body surface and the first flow guide portion, and the first transition portion is arc-shaped.

7. The air guide component according to claim 5, wherein the guide surface further comprises a third guide portion located on the upper side of the second guide portion, the third guide portion is connected between the first guide portion and the second guide portion, and an included angle between the third guide portion and the vertical direction is smaller than an included angle between the second guide portion and the vertical direction.

8. The wind guide component of claim 7, wherein the flow guide surface further comprises a second transition portion located on the upper side of the third flow guide portion, the second transition portion is connected between the third flow guide portion and the first flow guide portion, and the second transition portion is arc-shaped.

9. The wind guide component of claim 1, wherein a projection of the flow guide surface on a horizontal plane is located within a projection of the water pan on a horizontal plane.

10. The air guide part of claim 1, wherein at least a portion of an inner side wall of the water receiving cavity is formed into a flow guide surface, the flow guide surface extends to an upper end face of the water receiving tray, and the flow guide surface extends obliquely from top to bottom towards a direction adjacent to the center of the water receiving cavity.

11. The wind guide component of claim 10, wherein the portion of the flow guide surface located in the water receiving cavity is opposite to and spaced apart from the flow guide surface.

12. The wind guide component of claim 1, wherein the wind guide assembly comprises:

the outer wall surface of the outer air deflector forms the outer wall surface of the air guide assembly, and a flow channel is defined between the bottom surface of the outer air deflector and the inner bottom wall surface of the water receiving cavity;

the water receiving tray is arranged on the bottom surface of the inner air guide assembly and connected with the inner air guide assembly.

13. The wind deflector of claim 12, wherein the bottom surface of the outer wind deflector is spaced from the inner bottom wall surface of the water receiving chamber to form the flow channel.

14. The wind guide component of claim 12, wherein the inner wind guide assembly comprises an inner wind guide plate, the inner wind guide plate is connected with the outer wind guide plate, the water receiving tray is arranged on the bottom surface of the inner wind guide plate and connected with the inner wind guide plate, the inner wind guide plate and the water receiving tray are integrally formed or the inner wind guide plate and the water receiving tray are both independently formed pieces.

15. The wind scooper of claim 14, wherein a gap is formed in the bottom surface of the inner wind deflector, and the gap communicates two portions of the water receiving cavity located on opposite sides of the inner wind deflector.

16. The wind guide component of claim 1, wherein the wind guide assembly comprises:

the outer wall surface of the outer air deflector forms the outer wall surface of the air guide assembly, and an air dispersing structure for air flow to pass through is formed on the outer air deflector;

the inner air guide assembly is arranged on the outer air guide plate and located on the inner side of the outer air guide plate, the inner air guide assembly comprises an inner air guide plate, a guide vane assembly and a shutter mechanism, the inner air guide plate is connected with the outer air guide plate, the guide vane assembly is arranged on the inner air guide plate, the guide vane assembly comprises a plurality of rotatable movable vanes, the movable vanes are arranged at intervals along the length direction of the inner air guide plate, the movable vanes are located between the outer air guide plate and the inner air guide plate, air passing holes are formed in the inner air guide plate at positions opposite to the movable vanes, the shutter mechanism is arranged on one side, far away from the outer air guide plate, of the inner air guide plate, and the water receiving disc is connected with at least one of the outer air guide plate and the inner air guide plate.

17. The wind guide component according to any one of claims 1 to 16, wherein a water absorbing member is provided on the bottom surface of the water pan.

18. The air guide component of claim 17, wherein a receiving groove is formed in a bottom surface of the water pan, and the water absorbing member is disposed in the receiving groove.

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

the air outlet frame is provided with at least one air outlet channel;

the wind guide component is according to any one of claims 1-18, and is rotatably arranged on the wind outlet channel.

20. An air conditioner, comprising: a blower frame assembly according to claim 19.

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