CN212930404U - Air outlet module and air conditioner - Google Patents

Abstract

The utility model discloses an air-out module and air conditioner, the air-out module is including going out wind frame and choking layer, the choking layer install in go out the wind frame, the choking layer includes the post that flows that hinders that a plurality of intervals were arranged, adjacent two it is formed with the air-out clearance to hinder the interval between the post. At least one of the two adjacent flow blocking columns is rotatably connected with the air outlet frame, and the width of an air outlet gap between the two flow blocking columns can be adjusted when the rotatable flow blocking columns rotate. The utility model discloses an air-out module can provide multiple air-out mode to satisfy the user and to the demand of air-out, improve the comfort level of air-out module.

Description

Air outlet module and air conditioner

Technical Field

The utility model relates to an air conditioning equipment technical field, in particular to air-out module and air conditioner.

Background

In a conventional air conditioner, an air deflector with a micro-hole is generally disposed at an air outlet, so that the micro-hole on the air deflector is utilized to reduce the air speed, thereby achieving non-wind-induced air outlet and preventing strong air outlet flow from directly blowing a user. However, the airflow blown out from the micropores of the air deflector is still blown forward, and the air outlet direction is basically unchanged, so that the effect of soft wind or natural wind is difficult to achieve, and the comfort without wind feeling is poor.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main objective provides an air-out module, aims at providing multiple air-out mode to satisfy the user to the demand of air-out, improve the no wind sense comfort level of air-out module.

In order to achieve the above object, the utility model provides an air-out module, the air-out module is including going out wind frame and choking layer, the choking layer install in go out the wind frame, the choking layer includes the post that hinders that a plurality of intervals were arranged, adjacent two it is formed with the air-out clearance to hinder the interval between the post. At least one of the two adjacent flow blocking columns is rotatably connected with the air outlet frame, and the width of an air outlet gap between the two flow blocking columns can be adjusted when the rotatable flow blocking columns rotate.

Optionally, in two adjacent flow blocking columns, the flow blocking column rotationally connected to the air outlet frame is arranged in a flat shape.

Optionally, a plurality of flow blocking portions arranged at intervals along the length direction of the flow blocking column are convexly arranged on the side surface of the flow blocking column.

Optionally, the side surface of the current blocking column is arranged in a wavy manner along the length direction of the current blocking column so as to form a current blocking part at the position of the wave crest of the current blocking column; or the side surface of the flow blocking column is arranged in a concave-convex shape along the length direction of the flow blocking column so as to form the flow blocking part at the convex part position of the flow blocking column.

Optionally, a concave portion is formed between two adjacent choke portions on each side surface of the choke column, and the choke column is provided with a flow guide hole penetrating through the concave portion in the width direction thereof.

Optionally, the air outlet module includes a first driving assembly, the first driving assembly is installed on the air outlet frame, and the first driving assembly is connected to the flow blocking column to drive the flow blocking column to rotate.

Optionally, the first drive assembly comprises a first motor and a plurality of first gears; each first gear correspondingly penetrates through and is fixed on one flow blocking column, and the first gears on any two adjacent flow blocking columns are meshed; the first motor is connected with one of the first gears.

Optionally, the air outlet module includes a plurality of flow blocking layers, and the flow blocking layers are arranged at intervals along the air outlet direction of the air outlet frame.

Optionally, in two adjacent choke layers, the multiple choke columns in one choke layer and the multiple choke columns in another choke unit are arranged in a staggered manner in the interlayer arrangement direction.

Optionally, the air outlet module has a natural wind mode, and the air outlet module is in the natural wind mode: a plurality of flow blocking columns in the flow blocking layer positioned at the upstream of the air outlet are all arranged in a flat laying manner; the flow blocking columns in the flow blocking layer positioned at the downstream of the air outlet face the same side and are arranged in an inclined mode.

Optionally, the outlet module has a turbulent wind mode, and the outlet module is in the turbulent wind mode: a plurality of flow blocking columns in the flow blocking layer positioned at the upstream of the air outlet face the same side and are arranged in an inclined manner; and a plurality of flow blocking columns in the flow blocking layer positioned at the downstream of the air outlet are all arranged in a tiled manner.

Optionally, the outlet module has a soft wind mode, and the outlet module is in the soft wind mode: a plurality of flow blocking columns in the flow blocking layer positioned at the upstream of the air outlet face the same side and are arranged in an inclined manner; and a plurality of flow blocking columns in the flow blocking layer positioned at the downstream of the air outlet are all arranged towards the other side in an inclined manner.

Optionally, the outlet module has a turbulent no-wind mode, and when the outlet module is in the turbulent no-wind mode: a plurality of flow blocking columns in the flow blocking layer positioned at the upstream of the air outlet are all arranged in a flat laying manner; and a plurality of flow blocking columns in the flow blocking layer positioned at the downstream of the air outlet are all arranged in a tiled manner.

Optionally, the distance between two adjacent fluid barrier layers is less than or equal to 200 mm.

The utility model also provides an air conditioner, which is characterized in that the air conditioner comprises a shell and an air outlet module; wherein, the shell is provided with an air outlet; the air outlet module is installed on the shell and is suitable for shielding the air outlet. The air outlet module comprises an air outlet frame, a flow blocking layer and a driving assembly; the flow blocking layer is arranged on the air outlet frame and comprises a plurality of flow blocking columns which are arranged at intervals, and the flow blocking columns are rotationally connected with the air outlet frame; a drive assembly connected with the choke post to drive the choke post to rotate.

Optionally, the air conditioner is provided with the air outlet module at the front side of the air outlet, so as to be suitable for shielding the front side of the air outlet; and/or, the air conditioner is in the downside of air outlet disposes the air-out module to be applicable to and shelter from the downside in the air outlet.

Optionally, the air outlet module disposed at the front side of the air outlet is a first air outlet module, and the first air outlet module is movably mounted in the housing along the vertical direction, so that the first air outlet module can be switched between a working position and an idle position, where: in the working position, the first air outlet module is positioned at the front side of the air outlet; in the idle position, the first air outlet module is hidden in the shell.

Optionally, the air conditioner further comprises a second driving assembly, wherein the second driving assembly comprises a rack, a second motor and a second gear; the rack is arranged on the first air outlet module; the second motor is arranged inside the shell; the second gear is connected with the second motor and meshed with the rack.

Optionally, the air outlet module disposed at the lower side of the air outlet is a second air outlet module, and the second air outlet module is rotatably mounted on the chassis, so that the second air outlet module can adjust an angle blocking the air outlet by rotating.

Optionally, the second air outlet module further comprises a wind shield, the wind shield is configured at an end of an air outlet frame of the second air outlet module, and the wind shield is provided with a plurality of air outlet holes.

Optionally, the air conditioner is any one of a wall-mounted air conditioner indoor unit, a floor-type air conditioner indoor unit, a mobile air conditioner, and a ceiling-mounted air conditioner.

The technical scheme of the utility model, through set up the choking layer in the air-out frame at the air-out module, this choking layer includes the post that hinders that a plurality of intervals were arranged, it can be rotated by the drive assembly drive to hinder the post to when the laminar flow air current that gets into the air-out frame hits the choking layer, the laminar flow air current strikes on a plurality of posts that hinder of this choking layer and scatters, thereby becomes the torrent from the laminar flow, and the direction of air current is broken up, realizes the no wind sense air-out. On the basis, the flow blocking column is driven to rotate through the driving assembly, the rotating flow blocking column accelerates disturbance of the air outlet flow, and then the air outlet flow is further disturbed by rotation of the flow blocking column, so that soft wind or turbulent air outlet is achieved. Therefore, the utility model discloses an air-out module can realize multiple air-out mode, can satisfy the user to the demand of air-out, effectively improves the comfort level of air-out module.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

Fig. 1 is a schematic structural view of an embodiment of an air outlet module of the present invention;

FIG. 2 is an enlarged view taken at A in FIG. 1;

fig. 3 is a front view of the air outlet module in fig. 1;

FIG. 4 is a cross-sectional view taken along line I-I of FIG. 3;

fig. 5 is a top view of the air outlet module in fig. 1;

fig. 6 is a schematic view of a partial structure of the air outlet module in fig. 5;

FIG. 7 is a schematic diagram of the arrangement of multiple flow-blocking pillars in a single flow-blocking layer in FIG. 1;

FIG. 8 shows the arrangement of two fluid blocking layers in FIG. 1;

FIG. 9 is a schematic view of a flow barrier column of the flow barrier layer of FIG. 1;

FIG. 10-A is a schematic view of the air outlet module of FIG. 1 in a natural wind mode;

FIG. 10-B is a schematic view of the air outlet module of FIG. 1 in a turbulent wind mode;

FIG. 10-C is a schematic view of the outlet module of FIG. 1 in a soft mode;

FIG. 10-D is a schematic view of the blower module of FIG. 1 in a turbulent no-wind mode;

fig. 11 is a schematic structural view of another embodiment of the air outlet module of the present invention;

fig. 12 is a schematic view of a partial structure of the air outlet module in fig. 11;

fig. 13 is a schematic structural view of another embodiment of the air outlet module of the present invention;

fig. 14 is a schematic view of a partial structure of the air outlet module in fig. 13;

fig. 15 is a schematic structural view of the air conditioner of the present invention;

FIG. 16 is a front view of the air conditioner of FIG. 15;

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

fig. 18 is a schematic view of the first air outlet module and the second air outlet module in fig. 15.

The reference numbers illustrate:

the purpose of the present invention is to provide a novel and improved method and apparatus for operating a computer.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

It should be noted that, if directional indications (such as upper, lower, left, right, front and rear … …) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative position relationship between the components, the motion situation, etc. in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are changed accordingly.

In addition, if there is a description relating to "first", "second", etc. in the embodiments of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

Fig. 1 to 18 are drawings of an air outlet module 100 and an air conditioner 200 according to the present invention. The air outlet module 100 may be installed on an air outlet device to guide an air flow to be blown out. The air flow blown out from the air duct of the air outlet device is generally laminar flow flowing along the same plane, and after the laminar flow is blown out from the air outlet module, the laminar flow can be changed into soft wind or turbulent wind, so that various air outlet modes are realized, the requirement of a user on air outlet can be met, and the comfort level of the air outlet module is effectively improved. As for the type of the air outlet device, the air outlet device may be an air outlet device such as an air conditioner, an air machine, an air purifier, etc.; the air conditioner can be any one of a wall-mounted air conditioner indoor unit, a floor type air conditioner indoor unit, a mobile air conditioner and a ceiling type air conditioner. The following description will mainly use a floor type air conditioner as an example.

Referring to fig. 1 to 3, in an embodiment of the air outlet module, the air outlet module 100 includes an air outlet frame 110 and a blocking layer 120, the blocking layer 120 is installed on the air outlet frame 110, the blocking layer 120 includes a plurality of blocking columns 121 arranged at intervals, and an air outlet gap 101 is formed between two adjacent blocking columns 121 at intervals. At least one of the two adjacent flow blocking columns 121 is rotatably connected to the air outlet frame 110, and the width of the air outlet gap 101 between the two flow blocking columns 121 can be adjusted when the rotatable flow blocking column 121 rotates.

Specifically, the air outlet frame 110 may be disposed in a square or round shape or other shape structure, and specifically, the air outlet frame 110 is disposed in a rectangular shape. The blocking layer 120 is installed in the air-out frame 110 (as shown in fig. 4), a plurality of flow blocking columns 121 of the blocking layer 120 are arranged at intervals along the length direction of the air-out frame 110, an air-out gap 101 is formed between two adjacent flow blocking columns 121 at intervals, and the air-out gap 101 is suitable for air flow to pass through.

For the blocking layer 120, an air outlet gap 101 is formed between every two adjacent blocking columns 121 of the blocking layer 120 at intervals, and the two adjacent blocking columns 121 can be rotatably connected with the air outlet frame 110; only one of the flow blocking columns 212 may be rotatably connected to the air outlet frame 110, and the other may be fixedly connected to the air outlet frame 110. Specifically, two adjacent current blocking columns 121 may be both rotatably connected to the air outlet frame 110. When at least one of the two adjacent flow blocking columns 121 rotates, the width of the air outlet gap 101 changes accordingly, and the air outlet amount is adjusted. That is, as the choke columns 121 rotate, the width of the air outlet gap 101 between two adjacent choke columns 121 changes periodically (e.g., increases or decreases, or decreases and increases). For example, by reasonably designing the shape of the flow blocking column 121, the width of the air outlet gap 101 can be adjusted by rotating the flow blocking column 121, which will be described later.

The technical scheme of the utility model, through set up the choking layer 120 in the air-out frame 110 at air-out module 100, this choking layer 120 includes the choked flow post 121 that a plurality of intervals were arranged to when the laminar flow air current that gets into air-out frame 110 collided with choking layer 120, the laminar flow air current bumped on a plurality of choked flow posts 121 of this choking layer 120 and dispersed, thereby become the torrent from the laminar flow, the direction of air current is broken up, realizes the no wind and feels the air-out. On this basis, at least one of the flow blocking columns 121 in two adjacent flow blocking columns 121 is rotatably connected to the air outlet frame 110, so that when the rotatable flow blocking column 121 is driven to rotate, the width of the air outlet gap 101 between the two adjacent flow blocking columns 121 is changed, on one hand, the rotating flow blocking column 121 accelerates disturbance to the outlet air flow, and on the other hand, the width change of the outlet air gap 101 forces the wind speed and wind direction of the outlet air flow to change, so that the outlet air flow forms turbulence, and soft wind or turbulent air outlet is realized (as shown in fig. 7). Therefore, the utility model discloses an air-out module 100 can realize multiple air-out mode, can satisfy the user to the demand of air-out, effectively improves air-out module 100's comfort level.

Referring to fig. 5 and 6, in an embodiment, the air outlet module 100 includes a first driving assembly 140, the first driving assembly 140 is mounted on the air outlet frame 110, and the first driving assembly 140 is connected to the flow blocking column 121 to drive the flow blocking column 121 to rotate.

For a specific structure type of the first driving assembly 140, optionally, the first driving assembly 140 includes a first motor 141 and a plurality of first gears 142; each first gear 142 correspondingly penetrates through and is fixed on one flow blocking column 121, and the first gears 142 on any two adjacent flow blocking columns 121 are meshed; the first motor 141 is connected to one of the first gears 142. One of the first gears 142 is driven by the first motor 141 to rotate, and the first gear 142 further drives the other gears to synchronously rotate, so that the plurality of current blocking columns 121 are simultaneously driven to synchronously rotate.

Of course, the structural composition of the first driving assembly 140 is not limited thereto. In other embodiments, the first driving assembly 140 further comprises a second motor, a crank, and a connecting rod; wherein, the connecting rod is connected with a plurality of flow blocking columns 121 in sequence; the second motor is connected with the crank, and the crank is hinged to the connecting rod, so that the crank is driven by the second motor to rotate and swing, and the current blocking column 121 is pulled to rotate through the connecting rod.

Referring to fig. 1, 7 and 9, for each flow blocking layer 120 of the air outlet module 100, the shape of the flow blocking pillar 121 can be reasonably designed, so that the width of the air outlet gap 101 can be adjusted by rotating the flow blocking pillar 121. In the present embodiment, of the two adjacent flow blocking pillars 121, the flow blocking pillar 121 rotatably connected to the air-out frame 110 is disposed in a flat shape, and the other flow blocking pillar 121 may be disposed in a flat shape, a cylindrical shape, or a prism shape.

Specifically, the obstructing pillar 121 is disposed in a flat shape (as shown in fig. 2, 13 and 14), that is, the width of the obstructing pillar 121 is larger than the thickness of the obstructing pillar 121. The current blocking post 121 has two wind shielding surfaces perpendicular to the thickness direction thereof, and a side surface connecting the two wind shielding surfaces. The distance between the two wind-shielding surfaces of the choke post 121 (i.e., the thickness of the choke post 121) is smaller than the distance between the two side surfaces (i.e., the width of the choke post 121).

Therefore, when two adjacent flow blocking columns 121 rotate to be tiled, the side surfaces of the two flow blocking columns 121 are opposite, at this time, the air outlet gap 101 is formed between the side surfaces of the two flow blocking columns 121, and the width of the air outlet gap 101 is the smallest; when two adjacent flow blocking columns 121 rotate to be parallel to each other, the wind shielding surfaces of the two flow blocking columns 121 are opposite to each other, at this time, the wind outlet gap 101 is formed between the wind shielding surfaces of the two flow blocking columns 121, and the width of the wind outlet gap 101 is the largest. Therefore, the width of the air outlet gap 101 can be adjusted by rotating the flow blocking column 121. Similarly, the current-blocking column 121 may be designed to have a rectangular, oval, flower-shaped or other irregular cross-section.

Based on the above embodiments, the flow blocking column 121 is disposed in a flat shape, and a plurality of flow blocking portions 1211 disposed at intervals along the length direction of the flow blocking column 121 are protruded from the side surface of the flow blocking column 121. When the laminar airflow collides with the plurality of flow blocking portions 1211 of the flow blocking column 121, the laminar airflow is forcibly dispersed by the plurality of flow blocking portions 1211, so that the collision effect of the airflow and the flow blocking column 121 is greatly enhanced, the conversion efficiency from the laminar airflow to the turbulent airflow is improved, and the comfort level of the turbulent airflow is improved.

As for the formation manner of the choked portions 1211 on the current blocking column 121, in an embodiment, the sides of the current blocking column 121 may be arranged in a wave shape along the length direction thereof to form the choked portions 1211 at the peak positions thereof (as shown in fig. 1 and 2); alternatively, in another embodiment, the side surface of the flow blocking pillar 121 is provided in a concave-convex shape along the length direction thereof to form a flow blocking portion 1211 at a convex portion position thereof (as shown in fig. 11 and 12). Of course, in other embodiments, the flow blocking portion 1211 on the flow blocking column 121 may also be a protrusion (e.g., a convex hull, a convex pillar, or a convex rib) protruding from the lateral side of the flow blocking column 121.

Further, a recess 1212 is formed between adjacent two flow blocking portions 1211 on each side of the flow blocking post 121, and the flow blocking post 121 is provided with flow guide holes 1213 penetrating the recess 1212 in a width direction thereof. In the process that the air flow blows through the diversion holes 1213, the air flow of the diversion holes 1213 is blown away in a rotating manner along with the rotation of the flow blocking columns 121, so that the air supply direction of the diversion holes 1213 is changed in real time, the opposite impact effect of the air flow blown out from the diversion holes 1213 and the air flow blown out from the air outlet gap 101 is enhanced, and the turbulent air effect is greatly improved.

Referring to fig. 1, fig. 6 and fig. 8, based on any of the above embodiments, for the air outlet module 100, the air outlet module 100 may only include one or more flow blocking layers 120. Specifically, in the present embodiment, the air outlet module 100 includes a plurality of blocking layers 120, and the blocking layers 120 are arranged at intervals along the air outlet direction of the air outlet frame 110. The plurality of fluid blocking layers 120 may be two or more fluid blocking layers 120.

The rotation directions of the flow blocking layers 120 at different positions on each air outlet module 100 may be the same or different, and when the rotation directions are different, the turbulence generated by the flow blocking layers 120 is more effective and the wind is softer. For the driving manner of the plurality of blocking pillars 121 in the blocking layer 120, the plurality of blocking pillars 121 may rotate independently, or may rotate synchronously.

Referring to fig. 8, in an embodiment, in two adjacent flow blocking layers 120, a plurality of flow blocking columns 121 in one flow blocking layer 120 and a plurality of flow blocking columns 121 in another flow blocking unit are arranged in a staggered manner in the interlayer arrangement direction. For convenience of explanation, it is assumed that two adjacent barrier layers 120 are a first barrier layer 120a and a second barrier layer 120b, respectively, and then the plugs 121 of the first barrier layer 120a are opposite to the air outlet gap 101 of the second barrier layer 120b, and correspondingly, the plugs 121 of the second barrier layer 120b are also opposite to the plugs 121 of the second barrier layer 120 b.

In the process of the airflow passing through the air outlet module 100, the laminar airflow is firstly scattered by the flow blocking columns 121 of the first flow blocking layer 120a, and flows forward from the air outlet gaps 101 on both sides of the flow blocking columns 121; then, the air flow on the two sides collides with the flow blocking columns 121 of the second flow blocking layer 120b forwards, so that the air flow is broken up again, the collision effect of the air flow and the flow blocking columns 121 is greatly enhanced, the efficiency of converting the laminar flow into the turbulent flow is improved, and the comfort level of turbulent wind is improved.

It is considered that, if the distance between two adjacent flow blocking layers 120 (indicated as D in fig. 18) is too large, the volume of the air outlet module 100 is increased accordingly, which takes up a large space. Thus, optionally, the spacing between two adjacent fluid barrier layers 120 is less than or equal to 200mm, such as 180mm, 150mm, 120mm, 100mm, 80mm, 50mm, and so forth. The minimum value of the distance between two adjacent flow blocking layers 120 is not limited herein, and may be designed accordingly according to actual needs, so as to ensure that the flow blocking columns 121 of two adjacent flow blocking layers 120 can normally rotate.

Based on any of the above embodiments, by driving the choke columns 121 of different choke layers 120 to rotate to different positions, a plurality of different air outlet modes can be realized. Along the air outlet direction of the air outlet module 100, the flow blocking layer 120 located at the upstream of the air outlet is defined as a first flow blocking layer 120a, and the flow blocking layer 120 located at the downstream of the air outlet is defined as a second flow blocking layer 120 b. By driving the flow blocking columns 121 of the first flow blocking layer 120a and the second flow blocking layer 120b to face different directions, any one or more air outlet modes of a natural wind mode, a turbulent wind mode, a soft wind mode and a turbulent non-wind-sensation mode (see fig. 10-a to 10-D) can be realized.

Referring to fig. 10-a, in an embodiment, the air outlet module 100 has a natural wind mode, and the air outlet module 100 is in the natural wind mode, and the plurality of flow blocking columns 121 in the flow blocking layer 120 located at the upstream of the outlet air are all disposed in a tiled manner; the plurality of flow blocking columns 121 in the flow blocking layer 120 located downstream of the outlet air are all disposed in an inclined manner toward the same side.

That is, in the natural wind mode, the plurality of flow blocking columns 121 in the first flow blocking layer 120a are all disposed in a flat manner, and at this time, the air outlet gap 101 of the first flow blocking layer 120a is the smallest, and the air volume is smaller. The airflow scattered and passed through the first flow blocking layer 120a is guided by the flow blocking columns 121 of the second flow blocking layer 120b to be sent out towards the same direction, and natural wind blowing is achieved.

Referring to fig. 10-B, in an embodiment, the air outlet module 100 has a turbulent wind mode, and the air outlet module 100 is in the turbulent wind mode, a plurality of flow blocking columns 121 in the flow blocking layer 120 located upstream of the outlet wind are all disposed in an inclined manner facing the same side, and a plurality of flow blocking columns 121 in the flow blocking layer 120 located downstream of the outlet wind are all disposed in a flat manner.

That is, in the turbulent wind mode, the plurality of flow blocking columns 121 in the first flow blocking layer 120a are all disposed in an inclined manner toward the same side, and the air outlet gap 101 of the second flow blocking layer 120b is the smallest, so that the air volume is small. Therefore, the airflow scattered and passed through the first flow blocking layer 120a is guided by the flow blocking columns 121 of the first flow blocking layer 120a and sent out towards the flow blocking columns 121 of the second flow blocking layer 120b, so that the airflow collides with the flow blocking columns 121 of the second flow blocking layer 120b, is scattered by the flow blocking columns 121 of the second flow blocking layer 120b and then is sent out outwards, and thus, strong turbulence can be formed, and the turbulence can be quickly sent into indoor rooms, so that turbulent air supply is realized.

Referring to fig. 10-C, in an embodiment, the air outlet module 100 has a soft wind mode, and in the soft wind mode of the air outlet module 100, the plurality of flow blocking columns 121 in the flow blocking layer 120 located upstream of the air outlet are all disposed in an inclined manner toward the same side, and the plurality of flow blocking columns 121 in the flow blocking layer 120 located downstream of the air outlet are all disposed in an inclined manner toward the other side.

That is, in the soft wind mode, the flow blocking pillars 121 of the first flow blocking layer 120a are disposed in an inclined manner toward the same side, and the flow blocking pillars 121 of the second flow blocking layer 120b are disposed in an inclined manner toward the other side. Accordingly, the airflow scattered and passing through the first barrier layer 120a is guided by the plugs 121 of the first barrier layer 120a and sent out toward the plugs 121 of the second barrier layer 120b, so that the airflow collides against the plugs 121 of the second barrier layer 120b, is scattered by the plugs 121 of the second barrier layer 120b and then is sent out outward, and is guided by the plugs 121 and sent out toward the same side. Therefore, the direction of the airflow can be changed for many times, so that the airflow and the two layers of flow blocking columns 121 are in opposite impact, a stronger turbulent flow is generated, the wind feeling is softer, and the soft wind air supply is realized.

Referring to fig. 10-D, in an embodiment, the outlet module 100 has a turbulent non-wind-sensing mode, and when the outlet module 100 is in the turbulent non-wind-sensing mode, the flow blocking columns 121 in the flow blocking layer 120 located upstream of the outlet are all disposed in a tiled manner, and the flow blocking columns 121 in the flow blocking layer 120 located downstream of the outlet are all disposed in a tiled manner.

That is to say, in the turbulence non-wind-sensation mode, the plurality of flow blocking columns 121 in the first flow blocking layer 120a and the second flow blocking layer 120b are all disposed in a tiled manner, and at this time, the air outlet gaps 101 of the two flow blocking layers 120 are both the smallest, and the air volume is smaller. Therefore, the air flow is blocked by the double-layer blocking layer 120, so that the air flow can be dispersed to realize turbulent flow, the air outlet speed can be effectively reduced, and the air supply without wind sense of turbulent flow is realized.

Referring to fig. 15, the present invention further provides an air conditioner 200, wherein the air conditioner 200 includes a housing 210 and an air outlet module 100; wherein, the housing 210 is provided with an air outlet; the air outlet module 100 is installed on the housing 210, and the air outlet module 100 is adapted to shield the air outlet. The specific structure of the air outlet module 100 refers to the above embodiments, and since the air conditioner 200 adopts all technical solutions of all the above embodiments, at least all the beneficial effects brought by the technical solutions of the above embodiments are achieved, and no further description is given here. It should be noted that the air conditioner 200 may be any one of a wall-mounted air conditioner indoor unit, a floor-mounted air conditioner indoor unit, a mobile air conditioner 200, and a ceiling-mounted air conditioner 200. To avoid redundancy, the following embodiments are mainly explained by taking a wall-mounted air conditioner indoor unit as an example.

Referring to fig. 15 to 17, in an embodiment, a housing 210 of the air conditioner 200 is provided with an air inlet 211 and an air outlet, an air duct 212 is formed inside the housing 210, and the air duct 212 communicates the air inlet 211 and the air outlet. The air conditioner 200 further includes a heat exchanger 220 and a wind wheel 230, and both the heat exchanger 220 and the wind wheel 230 are installed in the case 210.

In an embodiment, the number of the air outlet modules 100 may be one or two or more. For example, the air conditioner 200 is configured with the air outlet module 100 at the front side of the air outlet, so as to be suitable for shielding the front side of the air outlet; and/or, the air conditioner 200 is provided with the air outlet module 100 at the lower side of the air outlet, so as to be suitable for shielding the lower side of the air outlet.

Specifically, in this embodiment, the air outlet module 100 is disposed in front of the air outlet of the air conditioner 200, and the air outlet module 100 disposed in front of the air outlet is the first air outlet module 100 a. The air outlet module 100 is disposed below the outlet of the air conditioner 200, and the air outlet module 100 disposed below the outlet is a second air outlet module 100 b.

Referring to fig. 17 and 18, there may be a plurality of design manners for the installation manner of the first air outlet module 100 a. Here, the first air outlet module 100a is installed in the casing 210 in a vertically movable manner, so that the first air outlet module 100a can be switched between the working position and the idle position. In the working position, the first air outlet module 100a is located at the front side of the air outlet; in the idle position, the first outlet module 100a is hidden inside the casing 210.

Specifically, when the conventional air outlet is needed, the first air outlet module 100a is moved to the idle position, so that the air outlet is exposed, and the air outlet can normally supply air to the front side; when no wind sense or other wind sense modes are needed, the first air outlet module 100a is moved to a working position to shield the front side of the air outlet, so that the airflow blown out forwards is changed into a turbulent flow through the first air outlet module 100a to form softer wind to be blown out.

Of course, the installation manner of the first outlet module 100a is not limited to this. In other embodiments, the first outlet module 100a may be rotatably mounted on the upper portion of the outlet to be rotated to switch between the working position and the idle position.

Further, the air conditioner 200 further includes a second driving assembly 240, wherein the second driving assembly 240 includes a rack 241, a second motor and a second gear; wherein, the rack 241 is installed on the first air outlet module 100 a; the second motor is installed inside the housing 210; the second gear is connected to the second motor and engaged with the rack gear 241.

In other embodiments, the second driving assembly 240 may include a second motor, a reel, and a pull-cord; the reel is rotatably mounted in the casing 210, the pulling rope is wound on the reel, and the other end of the pulling rope is connected to the first air outlet module 100 a; the second motor is connected to the reel to drive the reel to wind the pulling rope and drive the first air outlet module 100a to move up and down.

Referring to fig. 17 and 18, there may be a plurality of design manners for the installation manner of the second air outlet module 100 b. Optionally, the second air outlet module 100b is rotatably mounted on the chassis, so that the second air outlet module 100b can adjust the angle for shielding the air outlet by rotating.

Specifically, when no wind sensation or other wind sensation modes are required, the second air outlet module 100b is moved to the lower side of the air outlet to shield the lower side of the air outlet, so that the airflow blown out downwards is changed into a turbulent flow through the second air outlet module 100b to form a softer wind to be blown out. The first air outlet module 100a and the second air outlet module 100b form two-side turbulent air supply, so that the turbulent air supply range can be effectively enlarged. When the indoor unit of the air conditioner is turned off, the second outlet module 100b is moved to completely shield the outlet, so as to close the outlet.

Of course, the installation manner of the second outlet module 100b is not limited to this. In other embodiments, the second outlet module 100b may be movably installed at the bottom of the casing 210 back and forth, so that when no wind sensation or other wind sensation modes are required, the second outlet module 100b is moved to the lower side of the air outlet, and when regular wind outlet is required, the second outlet module 100b is moved back into the casing 210 to hide the second outlet module 100 b.

Further, the second air outlet module 100b further includes a wind screen 130, the wind screen 130 is configured at an end of the air outlet frame 110 of the second air outlet module 100b, and the wind screen 130 penetrates through the wind screen 130 to form a plurality of air outlet holes. Specifically, wind deflectors 130 are disposed at two ends of the wind outlet frame 110 of the second wind outlet module 100 b. The air flow blown out from the air duct 211 of the air conditioner 200 may be partially blown out forward through the first air outlet module 100a, partially blown out downward through the second air outlet module 100b, and the rest blown out laterally from the air outlet holes of the two air deflectors 130, so that air is blown out at least four sides, and the air outlet area is greatly enlarged.

The above is only the optional embodiment of the present invention, and not therefore the limit of the patent scope of the present invention, all of which are in the concept of the present invention, the equivalent structure transformation of the content of the specification and the drawings is utilized, or the direct/indirect application is included in other related technical fields in the patent protection scope of the present invention.

Claims (21)

1. The utility model provides an air-out module, its characterized in that, air-out module includes:

an air outlet frame; and

the flow blocking layer is arranged on the air outlet frame and comprises a plurality of flow blocking columns which are arranged at intervals, and an air outlet gap is formed between every two adjacent flow blocking columns at intervals;

at least one of the two adjacent flow blocking columns is rotatably connected with the air outlet frame, and the width of an air outlet gap between the two flow blocking columns can be adjusted when the rotatable flow blocking columns rotate.

2. The air outlet module of claim 1, wherein, in two adjacent flow blocking columns, the flow blocking column rotatably connected with the air outlet frame is arranged in a flat shape.

3. The air outlet module of claim 2, wherein a plurality of flow blocking parts are arranged at intervals along the length direction of the flow blocking column in a protruding manner on the side surface of the flow blocking column.

4. The air outlet module of claim 3, wherein the side surface of the flow blocking column is arranged in a wavy shape along the length direction thereof so as to form a flow blocking part at the position of the wave crest thereof;

or the side surface of the flow blocking column is arranged in a concave-convex shape along the length direction of the flow blocking column so as to form the flow blocking part at the convex part position of the flow blocking column.

5. The air outlet module of claim 3, wherein a concave portion is formed between two adjacent flow blocking portions on each side surface of the flow blocking column, and the flow blocking column is provided with a flow guide hole penetrating through the concave portion in a width direction of the flow blocking column.

6. The air outlet module of any one of claims 1 to 5, wherein the air outlet module comprises a first driving assembly, the first driving assembly is mounted on the air outlet frame, and the first driving assembly is connected with the flow blocking column to drive the flow blocking column to rotate.

7. The air outlet module of claim 6, wherein the first driving assembly comprises a first motor and a plurality of first gears; each first gear correspondingly penetrates through and is fixed on one flow blocking column, and the first gears on any two adjacent flow blocking columns are meshed; the first motor is connected with one of the first gears.

8. The air outlet module of any one of claims 1 to 5, wherein the air outlet module comprises a plurality of air blocking layers, and the air blocking layers are arranged at intervals along the air outlet direction of the air outlet frame.

9. The air outlet module of claim 8, wherein in two adjacent air blocking layers, a plurality of flow blocking columns in one of the air blocking layers and a plurality of flow blocking columns in the other air blocking unit are arranged in a staggered manner in the interlayer arrangement direction.

10. A wind outlet module according to claim 8, wherein the wind outlet module has a natural wind mode, and the wind outlet module is in the natural wind mode:

a plurality of flow blocking columns in the flow blocking layer positioned at the upstream of the air outlet are all arranged in a flat laying manner;

the flow blocking columns in the flow blocking layer positioned at the downstream of the air outlet face the same side and are arranged in an inclined mode.

11. A wind outlet module according to claim 8, characterised in that the wind outlet module has a turbulent wind mode, in which the wind outlet module is:

a plurality of flow blocking columns in the flow blocking layer positioned at the upstream of the air outlet face the same side and are arranged in an inclined manner;

and a plurality of flow blocking columns in the flow blocking layer positioned at the downstream of the air outlet are all arranged in a tiled manner.

12. A wind outlet module according to claim 8, wherein the wind outlet module has a soft wind mode, and the wind outlet module is in the soft wind mode:

a plurality of flow blocking columns in the flow blocking layer positioned at the upstream of the air outlet face the same side and are arranged in an inclined manner;

and a plurality of flow blocking columns in the flow blocking layer positioned at the downstream of the air outlet are all arranged towards the other side in an inclined manner.

13. A wind module according to claim 8, wherein the wind module has a turbulent no-wind mode, and when the wind module is in the turbulent no-wind mode:

a plurality of flow blocking columns in the flow blocking layer positioned at the upstream of the air outlet are all arranged in a flat laying manner;

and a plurality of flow blocking columns in the flow blocking layer positioned at the downstream of the air outlet are all arranged in a tiled manner.

14. The air outlet module of claim 8, wherein the distance between two adjacent air blocking layers is less than or equal to 200 mm.

15. An air conditioner, characterized in that the air conditioner comprises:

the air conditioner comprises a shell, a fan and a controller, wherein the shell is provided with an air outlet; and

the air outlet module of any one of claims 1 to 14, which is mounted to the housing and adapted to shield the air outlet.

16. The air conditioner according to claim 15, wherein the air outlet module is disposed at a front side of the air outlet so as to be adapted to be shielded from the front side of the air outlet; and/or the presence of a gas in the gas,

the air conditioner is in the downside of air outlet disposes the air-out module to be applicable to and shelter from in the downside of air outlet.

17. The air conditioner according to claim 16, wherein the air outlet module disposed at the front side of the air outlet is a first air outlet module, and the first air outlet module is movably installed in the housing in an up-down direction, so that the first air outlet module can be switched between a working position and a rest position, wherein:

in the working position, the first air outlet module is positioned at the front side of the air outlet;

in the idle position, the first air outlet module is hidden in the shell.

18. The air conditioner of claim 17, further comprising a second drive assembly, the second drive assembly comprising:

the rack is arranged on the first air outlet module;

a second motor mounted inside the housing;

and the second gear is connected with the second motor and meshed with the rack.

19. The air conditioner according to claim 16, wherein the air outlet module disposed at the lower side of the air outlet is a second air outlet module, and the second air outlet module is rotatably mounted at the bottom of the housing, so that the second air outlet module can rotate to adjust an angle for shielding the air outlet.

20. The air conditioner as claimed in claim 19, wherein the second outlet module further comprises a wind screen, the wind screen is configured at an end of the outlet frame of the second outlet module, and the wind screen has a plurality of outlet holes therethrough.

21. The air conditioner according to any one of claims 15 to 20, wherein the air conditioner is any one of a wall-mounted air conditioner indoor unit, a floor-mounted air conditioner indoor unit, a mobile air conditioner, and a ceiling-mounted air conditioner.

Images