CN220852334U - Air conditioner indoor unit and air conditioner - Google Patents
Air conditioner indoor unit and air conditioner Download PDFInfo
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- CN220852334U CN220852334U CN202322583263.7U CN202322583263U CN220852334U CN 220852334 U CN220852334 U CN 220852334U CN 202322583263 U CN202322583263 U CN 202322583263U CN 220852334 U CN220852334 U CN 220852334U
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- 230000005540 biological transmission Effects 0.000 claims description 10
- 238000009423 ventilation Methods 0.000 claims description 9
- 238000004378 air conditioning Methods 0.000 claims description 5
- 238000009434 installation Methods 0.000 description 7
- 238000010586 diagram Methods 0.000 description 3
- 238000000034 method Methods 0.000 description 3
- 238000004026 adhesive bonding Methods 0.000 description 2
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- 238000007664 blowing Methods 0.000 description 1
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Abstract
The utility model discloses an air conditioner indoor unit and an air conditioner, wherein the air conditioner indoor unit comprises a shell, an air guide assembly and a driving assembly, wherein the shell is provided with an air duct and an air outlet communicated with the air duct; the air guide assembly is arranged on the shell and is positioned at the air duct or the air outlet, and the air guide assembly comprises a first air guide module and a second air guide module; the driving assembly comprises a first driving source, a second driving source, a first switching shaft and a second switching shaft which are respectively distributed at two opposite ends of the air outlet. According to the technical scheme, the first switching shaft and the second switching shaft which are respectively used for driving the first air guide module and the second air guide module are arranged on two opposite sides of the air outlet of the shell, wherein the first switching shaft is in driving connection with the first air guide module and is in rotating connection with the second air guide module, and the second switching shaft is in driving connection with the second air guide module and is in rotating connection with the first air guide module.
Description
Technical Field
The utility model relates to the field of household appliances, in particular to an air conditioner indoor unit and an air conditioner.
Background
Because the existing air conditioner indoor unit has the requirements of multiple air outlet modes, two different air guide modules are usually arranged at the same air outlet, and the two air guide modules are driven to rotate by different driving motors to switch different air outlet modes, the two driving motors are usually arranged on the same side of the inner wall of the air conditioner indoor unit, and the corresponding driving motors are also required to be provided with structures for supporting and positioning the air guide modules on the other side of the air conditioner indoor unit, but the arrangement occupies a larger installation space, and the installation process is complicated and inconvenient.
Disclosure of utility model
The utility model mainly aims to provide an air conditioner indoor unit, which aims to reduce the installation space of a driving motor of the air conditioner indoor unit with two air deflectors.
In order to achieve the above object, an indoor unit of an air conditioner according to the present utility model includes:
The shell is provided with an air duct and an air outlet communicated with the air duct;
The air guide assembly is arranged on the shell and at least partially positioned at the air duct or the air outlet, and comprises a first air guide module and a second air guide module;
The driving assembly comprises a first driving source, a second driving source, a first switching shaft and a second switching shaft which are respectively distributed at two opposite ends of the air outlet, wherein the first driving source is in driving connection with the first switching shaft, the first switching shaft is in transmission connection with the first air guide module, and the first switching shaft is in rotary connection with the second air guide module; the second driving source is in driving connection with the second switching shaft, the second switching shaft is in rotating connection with the first air guide module, and the second switching shaft is in transmission connection with the second air guide module.
In an embodiment, the first rotating shaft comprises a first driving shaft and a first supporting shaft which are connected, the first driving shaft is in driving connection with the first air guiding module, and the first supporting shaft is in rotating connection with the second air guiding module; the second transfer shaft comprises a second driving shaft and a second supporting shaft which are connected, the second driving shaft is in driving connection with the second air guide module, and the second supporting shaft is in rotating connection with the first air guide module.
In an embodiment, the axes of the first driving shaft and the first supporting shaft are coincident, and the axes of the second driving shaft and the second supporting shaft are coincident.
In an embodiment, the first rotating shaft further comprises a first shaft seat, the first shaft seat is connected to the first driving shaft, and the first driving shaft is located between the first supporting shaft and the first shaft seat; the second transfer shaft further comprises a second shaft seat, the second shaft seat is connected to the second supporting shaft, and the second supporting shaft is located between the second shaft seat and the second driving shaft.
In an embodiment, the first driving shaft and the second driving shaft are arranged in a non-cylindrical shape, and the first supporting shaft and the second supporting shaft are arranged in a cylindrical shape.
In an embodiment, the first drive shaft and the second drive shaft are arranged in a prismatic shape.
In one embodiment, the first driving shaft has a first connecting surface connected with the first supporting shaft, and the first connecting surface at least partially extends out of the first supporting shaft laterally; the second support shaft has a second connection surface connected to the second drive shaft, the second connection surface extending at least partially laterally beyond the second drive shaft.
In an embodiment, the first driving shaft and the second driving shaft are arranged in a hexagonal prism shape.
In an embodiment, a first connecting shaft part and a first bearing part are arranged at one side of the first air guiding module at intervals, a first opening for the first driving shaft to extend in is formed in the first connecting shaft part, and a first round hole for the second supporting shaft to extend in is formed in the first bearing part; one side of the second air guide module is provided with a second connecting shaft part and a second bearing part at intervals, the second connecting shaft part is provided with a second opening for the second driving shaft to extend in, and the second bearing part is provided with a second round hole for the first supporting shaft to extend in.
In an embodiment, the second switching shaft is configured as a rotational flow module, the first air guiding module comprises an outer plate, an inner plate and a rotational flow structure positioned between the outer plate and the inner plate, the first switching shaft drives the first air guiding module to rotate and can move to the front side of the air outlet, and when the air flow passes through the rotational flow module, the rotational flow module breaks up the air flow in a rotating mode.
In an embodiment, the second wind guiding module is configured as a wind dispersing module, the second wind guiding module comprises a wind guiding plate, the second switching shaft drives the second wind guiding module to rotate and can move to the front side of the air outlet, a plurality of ventilation holes are formed in the wind dispersing module, and when the air flow passes through the wind dispersing module, the ventilation holes disperse the air flow.
The utility model also provides an air conditioner which comprises an air conditioner indoor unit, wherein the air conditioner indoor unit comprises a shell, an air guide assembly and a driving assembly, and the shell is provided with an air duct and an air outlet communicated with the air duct; the air guide assembly is arranged on the shell and at least partially positioned at the air duct or the air outlet, and comprises a first air guide module and a second air guide module; the driving assembly comprises a first driving source, a second driving source, a first switching shaft and a second switching shaft which are respectively distributed at two opposite ends of the air outlet, wherein the first driving source is in driving connection with the first switching shaft, the first switching shaft is in transmission connection with the first air guide module, and the first switching shaft is in rotary connection with the second air guide module; the second driving source is in driving connection with the second switching shaft, the second switching shaft is in transmission connection with the first air guide module, and the second switching shaft is in driving connection with the second air guide module.
According to the technical scheme, the first switching shaft and the second switching shaft which are respectively used for driving the first air guide module and the second air guide module are arranged on two opposite sides of the air outlet of the shell, wherein the first switching shaft is in driving connection with the first air guide module and is in rotating connection with the second air guide module, and the second switching shaft is in driving connection with the second air guide module and is in rotating connection with the first air guide module.
Drawings
In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to the structures shown in these drawings without inventive effort for a person skilled in the art.
FIG. 1 is a schematic view of an indoor unit of an air conditioner according to the present utility model;
FIG. 2 is a schematic structural diagram of the first wind guiding module, the second wind guiding module, the first connecting shaft and the second connecting shaft;
FIG. 3 is a schematic view of the first adapter shaft and the second adapter shaft after being close together;
FIG. 4 is an enlarged view of FIG. 2 at A;
FIG. 5 is an enlarged view at B in FIG. 2;
FIG. 6 is a schematic structural view of the first wind guiding module, the second wind guiding module and the first connecting shaft in a cross-sectional view;
FIG. 7 is a schematic view of the first wind guiding module, the second wind guiding module and the first connecting shaft in another cross-sectional view;
FIG. 8 is a schematic structural view of the first wind guiding module, the second wind guiding module and the second adaptor under a cross-sectional view;
FIG. 9 is a schematic structural view of the first wind guiding module, the second wind guiding module and the second adaptor under another cross-sectional view;
FIG. 10 is a schematic view of the inner and outer plates of the swirling structure and the cooperation of the swirling structure;
FIG. 11 is a schematic diagram of a structure of a wind dissipating module;
Fig. 12 is a schematic structural diagram of an indoor unit of an air conditioner at a cross-sectional view.
Reference numerals illustrate:
Reference numerals | Name of the name | Reference numerals | Name of the name |
100 | Shell body | 200 | First adapter shaft |
300 | Second adapter shaft | 400 | First air guide module |
500 | Second air guide module | 110 | Air duct |
120 | Air outlet | 210 | First drive shaft |
220 | First support shaft | 230 | First shaft seat |
310 | Second drive shaft | 320 | Second support shaft |
330 | Second shaft seat | 410 | First connecting shaft part |
411 | First open hole | 420 | First bearing part |
421 | First round hole | 430 | Inner plate |
440 | Rotational flow structure | 450 | Outer plate |
510 | Second connecting shaft part | 511 | Second open hole |
520 | Second bearing part | 521 | Second round hole |
530 | Vent hole |
The achievement of the objects, functional features and advantages of the present utility model will be further described with reference to the accompanying drawings, in conjunction with the embodiments.
Detailed Description
The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.
It should be noted that, if directional indications (such as up, down, left, right, front, and rear … …) are included in the embodiments of the present utility model, the directional indications are merely used to explain the relative positional relationship, movement conditions, etc. between the components in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are correspondingly changed.
In addition, if there is a description of "first", "second", etc. in the embodiments of the present utility model, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, if the meaning of "and/or" is presented throughout this document, it is intended to include three schemes in parallel, taking "a and/or B" as an example, including a scheme, or B scheme, or a scheme where a and B meet simultaneously. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present utility model.
The utility model provides an air conditioner indoor unit.
The air conditioning indoor unit illustrated in the present utility model is a wall-mounted air conditioning indoor unit, and of course, the air conditioning indoor unit may be a floor-mounted air conditioning indoor unit.
In the embodiment of the present utility model, as shown in fig. 1 to 5, the indoor unit of the air conditioner includes a housing 100, an air guide assembly and a driving assembly, wherein the housing 100 has an air duct 110 and an air outlet 120 communicating with the air duct 110; the air guiding assembly is installed on the housing 100 and at least partially located at the air duct 110 or the air outlet 120, and the air guiding assembly includes a first air guiding module 400 and a second air guiding module 500; the driving assembly comprises a first driving source, a second driving source, and a first adapting shaft 200 and a second adapting shaft 300 which are respectively distributed at two opposite ends of the air outlet 120, wherein the first driving source is in driving connection with the first adapting shaft 200, the first adapting shaft 200 is in transmission connection with the first air guiding module 400, and the first adapting shaft 200 is in rotational connection with the second air guiding module 500; the second driving source is in driving connection with the second switching shaft 300, the second switching shaft 300 is in rotational connection with the first air guiding module 400, and the second switching shaft 300 is in transmission connection with the second air guiding module 500.
Specifically, the housing 100 is used for accommodating and mounting internal components of the wall-mounted air conditioner indoor unit, and protecting the interior of the wall-mounted air conditioner indoor unit from the external environment. An air duct 110 and an air outlet 120 communicating the air duct 110 with the outside are formed in the housing 100. The wind guiding assembly comprises a first wind guiding module 400 and a second wind guiding module 500, wherein the first wind guiding module 400 and/or the second wind guiding module 500 can be a rotational flow wind guiding module, a scattered wind guiding module and other types of wind guiding modules.
The driving assembly includes a first driving source and a second driving source, which are specifically configured as driving motors, and which are conventional driving motors, and thus are not illustrated. The first driving source is in driving connection with the first rotating shaft 200, namely, the first driving source can drive the first rotating shaft 200 to rotate, and the specific matching mode is that a motor shaft of the first driving source stretches into an opening at one side of the first rotating shaft 200, and then the first rotating shaft 200 drives the first air guide module 400 to rotate; the first adapting shaft 200 is further configured to be in a rotational fit with the second wind guiding module 500, such that the second wind guiding module 500 can rotate relative to the first adapting shaft 200. The second driving source is in driving connection with the second switching shaft 300, namely the second driving source can drive the second switching shaft 300 to rotate, and the specific matching mode is that a motor shaft of the second driving source stretches into an opening on one side of the second switching shaft 300, and then the second switching shaft 300 drives the second air guide module 500 to rotate; the second adapting shaft 300 is further configured to be in rotation fit with the first wind guiding module 400, such that the first wind guiding module 400 can rotate relative to the second adapting shaft 300.
According to the technical scheme of the utility model, the first switching shaft 200 and the second switching shaft 300 for driving the first air guide module 400 and the second air guide module 500 are arranged on two opposite sides of the air outlet 120 of the shell 100, wherein the first switching shaft 200 is in transmission connection with the first air guide module 400 and is in rotation connection with the second air guide module 500, and the second switching shaft 300 is in transmission connection with the second air guide module 500 and is in rotation connection with the first air guide module 400, so that the installation space occupied by the first switching shaft 200 and the second switching shaft 300 is reduced.
In an embodiment, referring to fig. 1 to 5, the first rotating shaft 200 includes a first driving shaft 210 and a first supporting shaft 220 that are connected, the first driving shaft 210 is drivingly connected to the first air guiding module 400, and the first supporting shaft 220 is rotatably connected to the second air guiding module 500; the second adapter shaft 300 includes a second driving shaft 310 and a second supporting shaft 320, where the second driving shaft 310 is drivingly connected to the second air guiding module 500, and the second supporting shaft 320 is rotatably connected to the first air guiding module 400.
The first driving shaft 210 is connected with the first supporting shaft 220, wherein the first driving shaft 210 and the first supporting shaft 220 can be connected by gluing, screwing or welding, and the first driving shaft 210 and the first supporting shaft 220 can also be integrally formed; the second driving shaft 310 is connected to the second supporting shaft 320, the second driving shaft 310 and the second supporting shaft 320 may be connected by gluing, screwing or welding, and the second driving shaft 310 and the second supporting shaft 320 may be integrally formed. The axis of the first driving shaft 210 and the axis of the first supporting shaft 220 may or may not overlap; the second driving shaft 310 is connected to the second supporting shaft 320, where the axis of the second driving shaft 310 and the axis of the second supporting shaft 320 may or may not overlap.
It is considered that the first driving shaft 210 and the second supporting shaft 320 are respectively used to support opposite ends of the first wind guiding module 400, and thus, the axis of the first driving shaft 210 and the axis of the second supporting shaft 320 coincide; similarly, the second driving shaft 310 and the first supporting shaft 220 are respectively used for supporting opposite ends of the second wind guiding module 500, and thus, the axis of the second driving shaft 310 and the axis of the first supporting shaft 220 coincide.
It should be noted that, the first rotating shaft 200 is used for driving the first wind guiding module 400 to rotate, the first rotating shaft 200 includes a first driving shaft 210 and a first supporting shaft 220, wherein the first driving shaft 210 is used for driving the first wind guiding module 400 to rotate, and the first supporting shaft 220 is used for forming a rotating fit with the second wind guiding module 500. The second adaptor shaft 300 is used for driving the second wind guiding module 500 to rotate, the second adaptor shaft 300 includes a second driving shaft 310 and a second supporting shaft 320, wherein the second driving shaft 310 is used for driving the second wind guiding module 500 to rotate, and the second supporting shaft 320 is used for forming a rotating fit with the first wind guiding module 400.
In an embodiment, referring to fig. 2 and 3, the axes of the first driving shaft 210 and the first supporting shaft 220 are coincident, and the axes of the second driving shaft 310 and the second supporting shaft 320 are coincident.
Specifically, the installation space occupied by the first adapter shaft 200 and the second adapter shaft 300 can be further reduced by providing the axes of the first drive shaft 210 and the first support shaft 220 to coincide, and further providing the axes of the second drive shaft 310 and the second support shaft 320 to coincide as well. In addition, the axes of the first driving shaft 210 and the first supporting shaft 220 are overlapped, so that the processing technology of the first driving shaft 210 and the first supporting shaft 220 can be simplified, and the first driving shaft 210 and the first supporting shaft 220 can be formed integrally; similarly, the overlapping of the axes of the second driving shaft 310 and the second supporting shaft 320 may simplify the processing process of the second driving shaft 310 and the second supporting shaft 320, so that the second driving shaft 310 and the second supporting shaft 320 may be integrally formed.
In an embodiment, referring to fig. 3, the first adapter shaft 200 further includes a first shaft seat 230, the first shaft seat 230 is connected to the first driving shaft 210, and the first driving shaft 210 is located between the first supporting shaft 220 and the first shaft seat 230; the second adaptor shaft 300 further includes a second shaft seat 330, the second shaft seat 330 is connected to the second support shaft 320, and the second support shaft 320 is located between the second shaft seat 330 and the second driving shaft 310.
Further, by disposing the first driving shaft 210 between the first shaft seat 230 and the first supporting shaft 220 and disposing the second supporting shaft 320 between the second driving shaft 310 and the second shaft seat 330, the installation position of the second wind guiding module 500 may be located inside the first wind guiding module 400.
It should be noted that, a jack is provided on a side of the first shaft seat 230 away from the first driving shaft 210, a motor shaft of the motor is connected to the first shaft seat 230 through the jack, and similarly, a jack is also provided on a side of the second shaft seat 330 away from the second driving shaft 310, and a motor shaft of another motor is connected to the second shaft seat 330 through the jack. Wherein the motor and motor shaft are of conventional construction for driving the motor and therefore not shown here.
In an embodiment, referring to fig. 3, the first driving shaft 210 and the second driving shaft 310 are disposed in a non-cylindrical shape, and the first supporting shaft 220 and the second supporting shaft 320 are disposed in a cylindrical shape.
Specifically, the first and second driving shafts 210 and 310 are provided in a non-circular shape, so that the first and second driving shafts 210 and 310 are easily engaged with the first and second wind guiding modules 400 and 500, wherein the first and second driving shafts 210 and 310 may be provided in a prismatic shape, a semi-cylindrical shape, an elliptical shape, or a semi-cylindrical shape, and the shape of the first and second driving shafts 210 and 310 is not particularly limited.
Additionally, according to the above embodiment, the first wind guiding module 400 is rotatably connected to the second supporting shaft 320, the second wind guiding module 500 is rotatably connected to the first supporting shaft 220, and in order to make the rotation fit of the first wind guiding module 400 and the second supporting shaft 320 smoother, the rotation fit of the second wind guiding module 500 and the first supporting shaft 220 is smoother, and the first supporting shaft 220 and the second supporting shaft 320 are arranged in a cylindrical shape.
In one embodiment, referring to fig. 3, the first driving shaft 210 and the second driving shaft 310 are disposed in a prismatic shape.
Specifically, the first driving shaft 210 and the second driving shaft 310 are disposed in a prismatic shape, and the prisms are more easily molded than other shapes, and specifically, as described with reference to the above embodiments, the first driving shaft 210 and the second driving shaft 310 are disposed in a polygonal prismatic shape, and considering that the prisms with odd prisms are difficult to clamp and process, the prisms with even prisms are easier to clamp and process than the prisms with even prisms, in this embodiment, both the first driving shaft 210 and the second driving shaft 310 are disposed in a hexagonal prism shape, and of course, the first driving shaft 210 and the second driving shaft 310 may be disposed in a quadrangular prism shape, the first driving shaft 210 and the second driving shaft 310 may be disposed in an octaprism shape, and the first driving shaft 210 and the second driving shaft 310 may be disposed in a polygonal prism shape with more prisms.
In one embodiment, referring to fig. 3, in one embodiment, the first driving shaft 210 has a first connecting surface connected to the first supporting shaft 220, and the first connecting surface extends at least partially laterally beyond the first supporting shaft 220; the second support shaft 320 has a second connection surface connected to the second drive shaft 310, which extends at least partially laterally beyond the second drive shaft 310.
It should be noted that, according to the above embodiment, the first wind guiding module 400 is connected to the first driving shaft 210, the second wind guiding module 500 is rotatably connected to the first supporting shaft 220, and in order to limit the relative position of the second wind guiding module 500, the second wind guiding module 500 should be prevented from sliding from the first supporting shaft 220 to the first driving shaft 210. In view of this, the first driving shaft 210 has a first connection surface connected to the first supporting shaft 220, and the first connection surface extends at least partially laterally beyond the first supporting shaft 220, so as to limit the relative position of the end of the second wind guiding module 500 connected to the first rotating shaft 200, and also to position the installation position of the second wind guiding module 500. The first connecting surface may partially extend out of the first supporting shaft 220, or may extend out of the first supporting shaft 220 entirely.
Similarly, the second wind guiding module 500 is connected to the second driving shaft 310, and the first wind guiding module 400 is rotatably connected to the second supporting shaft 320, so that the second wind guiding module 500 should be prevented from sliding from the second driving shaft 310 to the second supporting shaft 320 in order to limit the relative position of the second wind guiding module 500. In the above embodiment, the second supporting shaft 320 has a second connecting surface connected to the second driving shaft 310, at least part of the second connecting surface extends laterally from the second driving shaft 310, the radius of the circumcircle of the third connecting surface should be smaller than that of the fourth connecting surface, so as to limit the relative position of the end of the second wind guiding module 500 connected to the second adapting shaft 300, and also locate the installation position of the second wind guiding module 500. The second connecting surface may extend partially from the second driving shaft 310, or may extend fully from the second driving shaft 310. In this embodiment, the first connection surface and the second connection surface are both planes connected to each other, and therefore, are not labeled in fig. 3.
In an embodiment, referring to fig. 2 to 11, a first connecting shaft portion 410 and a first bearing portion 420 are disposed on one side of the first air guiding module 400 at intervals, a first opening 411 into which the first driving shaft 210 extends is formed on the first connecting shaft portion 410, and a first circular hole 421 into which the second supporting shaft 320 extends is formed on the first bearing portion 420; a second shaft connecting portion 510 and a second bearing portion 520 are disposed at a side of the second air guiding module 500 at intervals, a second opening 511 into which the second driving shaft 310 extends is formed in the second shaft connecting portion 510, and a second circular hole 521 into which the first supporting shaft 220 extends is formed in the second bearing portion 520.
Specifically, the first connecting shaft portion 410 and the first bearing portion 420 are convexly disposed at one side of the first wind guiding module 400, wherein the first connecting shaft portion 410 and the first bearing portion 420 are near opposite ends of the first wind guiding module 400. The first connecting shaft portion 410 is configured to allow the first driving shaft 210 to extend into the first connecting shaft portion 410, and a first opening 411 is formed in the first connecting shaft portion 410, so that the first driving shaft 210 can extend from the first opening 411 into the first connecting shaft portion 410 for cooperation, and it should be noted that in the above embodiment, the first driving shaft 210 is configured to have a hexagonal prism shape, and correspondingly, the first opening 411 is also configured to have a hexagonal prism shape, so that the first driving shaft 210 can drive the first air guiding module 400 to rotate. The first bearing portion 420 is in rotational fit with the second support shaft 320, a first circular hole 421 is formed in the first bearing portion 420, and the second support shaft 320 extends into the first circular hole 421, wherein the first circular hole 421 corresponds to the second bearing portion 520 in shape.
Similarly, the second shaft connection part 510 and the second bearing part 520 are convexly disposed at one side of the second wind guiding module 500, wherein the second shaft connection part 510 and the second bearing part 520 are near opposite ends of the second wind guiding module 500. The second connecting shaft portion 510 is matched with the second driving shaft 310, and the second connecting shaft portion 510 is provided with a second opening 511, so that the second driving shaft 310 can extend from the second opening 511 to be matched with the second connecting shaft portion 510, and it should be noted that in the above embodiment, the second driving shaft 310 is configured to have a hexagonal prism shape, and correspondingly, the second opening 511 is also configured to have a hexagonal prism shape, so that the second driving shaft 310 can drive the second air guiding module 500 to rotate. The second bearing portion 520 is rotatably engaged with the first bearing portion 220, and a second circular hole 521 is formed in the second bearing portion 520, and the first bearing portion 220 extends into the second circular hole 521, wherein the second circular hole 521 corresponds to the shape of the first bearing portion 420.
Optionally, referring to fig. 10 and 12, in an embodiment, the first air guiding module 400 is configured as a cyclone module, the first air guiding module 400 includes an outer plate 450, an inner plate 430, and a cyclone structure 440 located between the outer plate 450 and the inner plate 430, the first adaptor shaft 200 drives the first air guiding module 400 to rotate and can move to the front side of the air outlet 120, and when the airflow passes through the cyclone module, the cyclone module breaks up the airflow.
Considering that the direct air-out at the air outlet 120 has stronger wind sense, the user can feel uncomfortable when directly blowing, so, the cyclone module rotationally connected to the shell 100 is arranged, when the cyclone module rotates to the front side of the air outlet 120, the airflow passes through the cyclone module, and the cyclone module breaks up the airflow in a rotating way, so that the wind speed is reduced, and the user has no obvious wind sense. The cyclone module at least comprises a cyclone structure 440, and in addition, the cyclone module further comprises an outer plate 450 and an inner plate 430 for fixing the cyclone structure 440, wherein ventilation structures for leading air out of the air conditioner indoor unit to the outer side of the air conditioner indoor unit are arranged on the outer plate 450 and the inner plate 430.
Further, referring to fig. 11 and 12, the second air guiding module 500 is configured as a wind dispersing module, the second air guiding module 500 includes an air guiding plate, the second switching shaft 300 drives the second air guiding module 500 to rotate and can move to the front side of the air outlet 120, a plurality of ventilation holes 530 are provided on the wind dispersing module, and when the air flows through the wind dispersing module, the plurality of ventilation holes 530 disperse the air flow.
On the basis of the functions, the air outlet mode of the indoor unit of the air conditioner is further increased, a plurality of ventilation holes 530 are formed in the air dispersing module, when the air dispersing module rotates to the front side of the air outlet 120, air flows are discharged through the plurality of ventilation holes 530 to be dispersed, even if the air outlet 120 cools and blows air to a user, the user has no obvious wind receiving sense, the user is prevented from being winded, and the use experience of the user is improved. The air dispersing module is provided with a plurality of air vents 530 for dispersing air flow and reducing air speed, wherein the air vents 530 are square holes in the embodiment, of course, the air vents 530 can also be round holes, the air vents 530 can also be shaped holes, and the air vents 530 are not particularly limited herein.
The utility model also provides an air conditioner which comprises an air conditioner indoor unit, and the specific structure of the air conditioner indoor unit refers to the embodiment, and because the air conditioner adopts all the technical schemes of all the embodiments, the air conditioner at least has all the beneficial effects brought by the technical schemes of the embodiments, and the detailed description is omitted.
The foregoing description is only of the optional embodiments of the present utility model, and is not intended to limit the scope of the utility model, and all the equivalent structural changes made by the description of the present utility model and the accompanying drawings or the direct/indirect application in other related technical fields are included in the scope of the utility model.
Claims (11)
1. An air conditioning indoor unit, comprising:
The shell is provided with an air duct and an air outlet communicated with the air duct;
The air guide assembly is arranged on the shell and at least partially positioned at the air duct or the air outlet, and comprises a first air guide module and a second air guide module;
The driving assembly comprises a first driving source, a second driving source, a first switching shaft and a second switching shaft which are respectively distributed at two opposite ends of the air outlet, wherein the first driving source is in driving connection with the first switching shaft, the first switching shaft is in transmission connection with the first air guide module, and the first switching shaft is in rotary connection with the second air guide module; the second driving source is in driving connection with the second switching shaft, the second switching shaft is in rotating connection with the first air guide module, and the second switching shaft is in transmission connection with the second air guide module.
2. The indoor unit of claim 1, wherein the first adapter shaft comprises a first drive shaft and a first support shaft that are connected, the first drive shaft is connected to the first air guiding module, and the first support shaft is rotatably connected to the second air guiding module; the second transfer shaft comprises a second driving shaft and a second supporting shaft which are connected, the second driving shaft is connected with the second air guide module, and the second supporting shaft is rotationally connected with the first air guide module.
3. The indoor unit of claim 2, wherein the axes of the first drive shaft and the first support shaft are coincident, and the axes of the second drive shaft and the second support shaft are coincident.
4. The indoor unit of claim 2, wherein the first adapter shaft further comprises a first shaft seat, the first shaft seat is connected to the first driving shaft, and the first driving shaft is located between the first supporting shaft and the first shaft seat; the second transfer shaft further comprises a second shaft seat, the second shaft seat is connected to the second supporting shaft, and the second supporting shaft is located between the second shaft seat and the second driving shaft.
5. The indoor unit of claim 4, wherein the first driving shaft and the second driving shaft are disposed in a non-cylindrical shape, and the first supporting shaft and the second supporting shaft are disposed in a cylindrical shape.
6. The indoor unit of claim 5, wherein the first driving shaft and the second driving shaft are disposed in a hexagonal prism shape.
7. The indoor unit of claim 5, wherein the first driving shaft has a first connection surface connected to the first supporting shaft, and the first connection surface extends at least partially laterally beyond the first supporting shaft; the second support shaft has a second connection surface connected to the second drive shaft, the second connection surface extending at least partially laterally beyond the second drive shaft.
8. The indoor unit of claim 5, wherein a first connecting shaft portion and a first bearing portion are disposed at a side of the first air guiding module at intervals, a first opening for the first driving shaft to extend in is formed in the first connecting shaft portion, and a first round hole for the second supporting shaft to extend in is formed in the first bearing portion; one side of the second air guide module is provided with a second connecting shaft part and a second bearing part at intervals, the second connecting shaft part is provided with a second opening for the second driving shaft to extend in, and the second bearing part is provided with a second round hole for the first supporting shaft to extend in.
9. The indoor unit of claim 1, wherein the first air guiding module is configured as a cyclone module, the first air guiding module includes an outer plate, an inner plate, and a cyclone structure between the outer plate and the inner plate, the first rotating shaft drives the first air guiding module to rotate and can move to the front side of the air outlet, and when the airflow passes through the cyclone module, the cyclone module breaks up the airflow.
10. The indoor unit of claim 9, wherein the second air guiding module is configured as a wind dispersing module, the second air guiding module includes an air guiding plate, the second switching shaft drives the second air guiding module to rotate and can move to the front side of the air outlet, and a plurality of ventilation holes are formed in the wind dispersing module, and when the air flows through the wind dispersing module, the plurality of ventilation holes disperse the air flow.
11. An air conditioner comprising the air conditioner indoor unit according to any one of claims 1 to 10.
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CN202322583263.7U CN220852334U (en) | 2023-09-21 | 2023-09-21 | Air conditioner indoor unit and air conditioner |
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CN202322583263.7U CN220852334U (en) | 2023-09-21 | 2023-09-21 | Air conditioner indoor unit and air conditioner |
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CN202322583263.7U Active CN220852334U (en) | 2023-09-21 | 2023-09-21 | Air conditioner indoor unit and air conditioner |
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