CN217109770U - Air outlet mechanism and cabinet air conditioner - Google Patents

Abstract

The utility model provides an air-out mechanism and cabinet air conditioner, air-out mechanism includes: the two air outlets are communicated with the through-flow channel and are arranged at intervals along the circumferential direction of the through-flow channel; the flow distribution plate is movably arranged in the through-flow channel along the distribution direction of the two air outlets, and has a shielding state and an avoiding state between the two air outlets; when the flow distribution plate is in a shielding state, the flow distribution plate is arranged opposite to one of the two air outlets so as to shield the air outlet. The air-out mode of the cabinet air conditioner that has the air-out mechanism of this application is diversified, has solved the problem that the air-out mode of the cabinet air conditioner among the prior art is more single.

Description

Air outlet mechanism and cabinet air conditioner

Technical Field

The utility model relates to an air conditioner technical field particularly, relates to an air-out mechanism and cabinet air conditioner.

Background

At present, the air outlet of the existing cylindrical cross-flow fan is single, and the problems of direct blowing of cold air, narrow air supply range and the like exist.

In order to solve the problems, the cabinet air conditioner with the air outlet is pushed out, and the cabinet air conditioner with the air outlet structurally comprises double air ducts and double fans, so that the production cost is increased, the production efficiency is reduced, and the after-sale maintenance difficulty is increased.

Moreover, the existing cabinet air conditioner with double air outlets has a single air supply mode, and only one air channel is effective when air is discharged from a single air outlet, so that the air quantity is small, and the comfort of people is further reduced.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main aim at provides an air-out mechanism and cabinet air conditioner to solve the air-out mode of the cabinet air conditioner among the prior art problem more single.

In order to achieve the above object, according to an aspect of the present invention, there is provided an air outlet mechanism, including: a through-flow channel; the two air outlets are communicated with the through-flow channel and are arranged at intervals along the circumferential direction of the through-flow channel; the flow distribution plate is movably arranged in the through-flow channel along the distribution direction of the two air outlets and has a shielding state and an avoiding state between the two air outlets; when the flow distribution plate is in a shielding state, the flow distribution plate is arranged opposite to one of the two air outlets so as to shield the air outlet.

Furthermore, the flow distribution plate is arranged around a preset axis in a swinging mode, the preset axis is located on the outer side of the flow distribution plate, and the extending direction of the preset axis is parallel to the extending direction of the through-flow channel.

Furthermore, a rack is arranged on the flow distribution plate, the rack extends along the distribution direction of the two air outlets, and the air outlet mechanism further comprises a driving gear meshed with the rack to drive the flow distribution plate to move.

Furthermore, the plate surface of the flow distribution plate is parallel to the extending direction of the through-flow channel, and the plate surface of the flow distribution plate is a plane or a smooth curved surface.

Furthermore, the plate surface of the splitter plate is an arc-shaped surface, the central angle of the arc-shaped surface is theta, and the value range of the theta is 50 degrees to 90 degrees.

Furthermore, a fan is arranged in the cross-flow channel, the extending direction of the central axis of the fan is parallel to the extending direction of the cross-flow channel, and a plurality of fan blades of the fan are arranged around the central axis of the fan; the minimum vertical distance between each air outlet and the central axis of the fan is L ₁ The minimum vertical distance between the cylindrical surface where the tooth root of the driving gear is positioned and the central axis of the fan is L ₂ ， L ₂ ＝C ₁ L ₁ (ii) a Wherein, C ₁ Is in the range of 1/2 to 2/3.

Furthermore, a fan is arranged in the cross-flow channel, the extending direction of the central axis of the fan is parallel to the extending direction of the cross-flow channel, and a plurality of fan blades of the fan are arranged around the central axis of the fan; along the direction vertical to the extending direction of the central axis of the fan, the vertical distance between the end part of each fan blade and the central axis of the fan is R; the minimum vertical distance between the cylindrical surface of the root of the driving gear and the central axis of the fan is L ₂ (ii) a The two air outlets are arranged on the air outlet panel, the air outlet panel comprises a volute tongue panel part protruding in the through-flow channel, and the protruding direction of the volute tongue panel part is perpendicular to the extending direction of the through-flow channel; the volute tongue panel part is provided with a first end and a second end which are oppositely arranged along the protruding direction of the volute tongue panel part; the two air outlets are respectively a first air outlet and a second air outlet, and the volute tongue panel part is positioned on one side of the first air outlet, which is far away from the second air outlet, along the circumferential direction of the through-flow channel; the first end of the volute tongue panel part is used for enclosing a first air outlet, the second end of the volute tongue panel part is used for being close to the fan, and the minimum vertical distance between the volute tongue panel part and the central axis of the fan is L ₃ ，(R-L ₃ )<5mm, andL ₃ <0.5L ₂ 。

furthermore, a fan is arranged in the cross-flow channel, the extending direction of the central axis of the fan is parallel to the extending direction of the cross-flow channel, and a plurality of fan blades of the fan are arranged around the central axis of the fan; the two air outlets are arranged on the air outlet panel, the air outlet panel comprises side coamings and a volute tongue panel part protruding in the through-flow channel, and the protruding direction of the volute tongue panel part is perpendicular to the extending direction of the through-flow channel; the two air outlets are respectively a first air outlet and a second air outlet, and the volute tongue panel part is positioned on one side of the first air outlet, which is far away from the second air outlet, along the circumferential direction of the through-flow channel and is used for enclosing into the first air outlet; the side wall plate is used for enclosing a through-flow channel and a second air outlet and is positioned on one side of the second air outlet, which is far away from the first air outlet; the minimum vertical distance between the cylindrical surface where the tooth root of the driving gear is located and the volute tongue panel portion is equal to the minimum vertical distance between the cylindrical surface where the tooth root of the driving gear is located and the side wall plate.

Furthermore, along the direction perpendicular to the extending direction of the through-flow channel, the arc-shaped surface of the flow distribution plate is provided with two ends which are oppositely arranged, and the chord length between the two ends of the arc-shaped surface is L ₅ The minimum vertical distance between the cylindrical surface where the tooth root of the driving gear is positioned and the volute tongue panel part is L ₆ ，L ₅ ＝L ₆ 。

According to the utility model discloses a further aspect provides a cabinet air conditioner, and it includes foretell air-out mechanism.

By applying the technical scheme of the utility model, the air outlet mechanism comprises a through-flow channel, a splitter plate and two air outlets, and the two air outlets are communicated with the through-flow channel and are arranged at intervals along the circumferential direction of the through-flow channel; the flow distribution plate is movably arranged in the through-flow channel along the distribution direction of the two air outlets, and has a shielding state and an avoiding state between the two air outlets; when the flow distribution plate is in a shielding state, the flow distribution plate is arranged opposite to one of the two air outlets so as to shield the air outlet.

In a specific implementation process, the two air outlets are respectively a first air outlet and a second air outlet, when the flow distribution plate moves to a position between the first air outlet and the second air outlet, the flow distribution plate avoids both the first air outlet and the second air outlet, namely the flow distribution plate cannot shield the first air outlet and the second air outlet, and air flow in the through-flow channel can flow out through the first air outlet and the second air outlet; when the flow distribution plate moves to a position opposite to the first air outlet, the flow distribution plate can be stopped between the through-flow channel and the first air outlet so as to shield the first air outlet, the first air outlet is further closed, and the air flow in the through-flow channel only flows out through the second air outlet; when the flow distribution plate moves to the position opposite to the second air outlet, the flow distribution plate can stop between the through-flow channel and the second air outlet so as to shield the second air outlet, the second air outlet is in a closed state, and the air flow in the through-flow channel only flows out through the first air outlet at the moment. The flow distribution plate can also be kept in a moving state, so that each air outlet is periodically switched between a closed state and an open state, and dynamic flow air supply is realized. It can be seen that the air-out mode of the cabinet air conditioner with the air-out mechanism of this application is diversified, and the problem that the air-out mode of the cabinet air conditioner in the prior art is single is solved.

Drawings

The accompanying drawings, which form a part of the present application, are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 shows a schematic structural view of a cabinet air conditioner according to the present invention;

fig. 2 is a schematic structural diagram illustrating the first air outlet of the cabinet air conditioner according to the present invention in an open state and the second air outlet in a closed state;

fig. 3 is a schematic structural diagram illustrating a first air outlet of the cabinet air conditioner in a closed state and a second air outlet of the cabinet air conditioner in an open state according to the present invention;

fig. 4 is a schematic structural view illustrating the first air outlet and the second air outlet of the cabinet air conditioner according to the present invention in an open state;

FIG. 5 shows an L of a cabinet air conditioner according to the present invention ₁ 、L ₂ 、L ₅ A plot of (a);

FIG. 6 shows an L of a cabinet air conditioner according to the present invention ₃ A plot of (a);

FIG. 7 shows an L of a cabinet air conditioner according to the present invention ₆ 、L ₇ Is a plot of (a).

Wherein the figures include the following reference numerals:

10. a through-flow channel; 20. an air outlet; 21. a first air outlet; 22. a second air outlet; 24. a first wind sweeping part; 25. a second air sweeping part; 30. a flow distribution plate; 40. a gear; 51. an air intake panel; 52. an air outlet panel; 521. a volute tongue panel part; 522. side coaming plates; 523. presetting a point; 60. a fan; 70. an evaporator; 80. a heating component.

Detailed Description

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present invention will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

It should be noted that the following detailed description is exemplary and is intended to provide further explanation of the disclosure. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of example embodiments according to the present application. As used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, and it should be understood that when the terms "comprises" and/or "comprising" are used in this specification, they specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof, unless the context clearly indicates otherwise.

The utility model provides an air outlet mechanism, please refer to fig. 1 to 7, the air outlet mechanism comprises a through-flow channel 10, a splitter plate 30 and two air outlets 20, the two air outlets 20 are both communicated with the through-flow channel 10 and are arranged along the circumferential direction of the through-flow channel 10 at intervals; the flow distribution plate 30 is movably arranged in the through-flow channel 10 along the distribution direction of the two air outlets 20, and the flow distribution plate 30 has a shielding state and an avoiding state between the two air outlets 20; when the flow distribution plate 30 is in the shielding state, the flow distribution plate 30 is disposed opposite to one of the two outlets 20, so as to shield the outlet 20.

In a specific implementation process, as shown in fig. 2 to 4, the two air outlets 20 are a first air outlet 21 and a second air outlet 22, respectively, when the flow distribution plate 30 moves to a position between the first air outlet 21 and the second air outlet 22, the flow distribution plate 30 avoids both the first air outlet 21 and the second air outlet 22, that is, the flow distribution plate 30 does not shield the first air outlet 21 and the second air outlet 22, and the air flow in the through-flow channel 10 can flow out through the first air outlet 21 and the second air outlet 22; when the flow distribution plate 30 moves to a position opposite to the first air outlet 21, the flow distribution plate 30 is stopped between the through-flow channel 10 and the first air outlet 21 to shield the first air outlet 21, so that the first air outlet 21 is in a closed state, and at this time, the airflow in the through-flow channel 10 only flows out through the second air outlet 22; when the flow distribution plate 30 moves to a position opposite to the second air outlet 22, the flow distribution plate 30 is stopped between the through-flow channel 10 and the second air outlet 22 to shield the second air outlet 22, so that the second air outlet 22 is in a closed state, and at this time, the airflow in the through-flow channel 10 only flows out through the first air outlet 21. The diversion plate 30 may also be kept in a moving state, so that each air outlet 20 is periodically switched between a closed state and an open state to realize dynamic flow air supply. It can be seen that the air-out mode of the cabinet air conditioner with the air-out mechanism of this application is diversified, and the problem that the air-out mode of the cabinet air conditioner in the prior art is single is solved.

In addition, compared with the existing cabinet machine with double air outlets, the air outlet mechanism is only provided with one air channel and one fan, so that the problems of direct cold air blowing, narrow air supply range, short air supply distance, high heat exchange energy consumption and the like are solved, and meanwhile, the air outlet mechanism is simple in structure, and is beneficial to reducing the production cost and improving the production efficiency; and, under the prerequisite that cabinet air conditioner's overall structure is the same basically, each wind channel when setting up two wind channels is inevitable to be less than the wind channel when setting up a wind channel, so even the air-out mechanism of this application when an air outlet 20 is opened, also can guarantee great amount of wind, and then improved human travelling comfort and energy utilization.

Specifically, the extending direction of the through-flow passage 10 is parallel to the vertical direction, and the circumferential direction of the through-flow passage 10 is perpendicular to the extending direction of the through-flow passage 10.

Specifically, the air outlet mechanism comprises an air inlet panel 51 and an air outlet panel 52, the air inlet panel 51 and the air outlet panel 52 are connected with each other to form a through-flow channel 10, and the distribution directions of the air inlet panel 51 and the air outlet panel 52 are perpendicular to the extension direction of the through-flow channel 10; the two air outlets 20 are both arranged on the air outlet panel 52, and the air inlets are arranged on the air inlet panel 51.

Specifically, the plate surface of the flow distribution plate 30 is parallel to the extending direction of the through-flow channel 10, and the plate surface of the flow distribution plate 30 is a plane or a smooth curved surface; for example, when the plate surface of the flow distribution plate 30 is a smooth curved surface, the plate surface of the flow distribution plate 30 is preferably an arc-shaped surface.

Specifically, as shown in fig. 6, when the plate surface of the splitter plate 30 is an arc surface, the central angle of the arc surface is θ, and θ is in a range from 50 degrees to 90 degrees.

In the present embodiment, the dividing plate 30 is arranged swingably about a predetermined axis located outside the dividing plate 30, the predetermined axis extending in a direction parallel to the direction of extension of the through-flow passage 10.

Specifically, when the plate surface of the flow distribution plate 30 is an arc surface, the central axis of the cylindrical surface where the arc surface of the flow distribution plate 30 is located forms the preset axis.

In this embodiment, the splitter plate 30 is provided with a rack, the rack extends along the distribution direction of the two air outlets 20, the air outlet mechanism further includes a driving gear 40 engaged with the rack to drive the splitter plate 30 to move, that is, the driving gear 40 drives the splitter plate 30 to swing around a preset axis; wherein the central axis of the driving gear 40 is parallel to the preset axis.

Specifically, the driving gear 40 is rotatably mounted on the air outlet panel 52 around its central axis, and the extending direction of the central axis of the driving gear 40 is parallel to the extending direction of the through-flow passage 10.

Specifically, the air outlet mechanism further comprises a driving motor, an output shaft of the driving motor is connected with the driving gear 40 to drive the driving gear 40 to rotate, and a central axis of the output shaft of the driving motor coincides with a central axis of the driving gear 40.

Optionally, a plurality of driving gears 40 are provided, and the plurality of driving gears 40 are all meshed with the rack and arranged at intervals along the extending direction of the rack so as to drive the rack to move together; wherein a plurality of drive gears 40 are provided so as to be rotatable in synchronism.

In this embodiment, a fan 60 is disposed in the cross-flow passage 10, an extending direction of a central axis of the fan 60 is parallel to an extending direction of the cross-flow passage 10, and a plurality of blades of the fan 60 are disposed around the central axis of the fan 60.

In the present embodiment, the minimum vertical distance between each air outlet 20 and the central axis of the fan 60 is L ₁ The minimum vertical spacing between the cylindrical surface on which the roots of the drive gear 40 lie and the central axis of the fan 60 is L ₂ ，L ₂ ＝C ₁ L ₁ (ii) a Wherein, C ₁ Is in the range of 1/2 to 2/3.

Specifically, as shown in fig. 5, along the distribution direction of the two air outlets 20, each air outlet 20 has a first end and a second end that are arranged oppositely, and the first end of each air outlet 20 is located on one side of the second end of the air outlet 20 close to the other air outlet 20; the vertical distance between the central axis of the fan 60 and the first end of each air outlet 20 is the minimum vertical distance L between the air outlet 20 and the central axis of the fan 60 ₁ 。

Specifically, as shown in fig. 5, when the plate surface of the splitter plate 30 is an arc-shaped surface, the arc-shaped surface moves along a preset radial line and is tangent to the cylindrical surface where the tooth root of the driving gear 40 is located, so as to generate a tangent line N on the cylindrical surface where the tooth root of the driving gear 40 is located, and the preset radial line passes through the central axis of the arc-shaped surface and the central axis of the driving gear 40And the preset radial line is vertical to the central line of the arc-shaped surface and vertical to the central axis of the driving gear 40; the vertical distance between the central axis of the fan 60 and the tangent line N is the minimum vertical distance L between the cylindrical surface on which the tooth root of the driving gear 40 is located and the central axis of the fan 60 ₂ . Wherein, the central axis of the arc surface refers to the central axis of the cylindrical surface on which the arc surface is positioned.

Specifically, along a direction perpendicular to the extending direction of the central axis of the fan 60, a vertical distance between an end of each fan blade and the central axis of the fan 60 is R, that is, a vertical distance between an end of a free end of each fan blade and the central axis of the fan 60 is R.

In the present embodiment, the two air outlets 20 are configured to be disposed on the air outlet panel 52, the air outlet panel 52 includes a volute tongue panel portion 521 protruding in the through-flow channel 10, and a protruding direction of the volute tongue panel portion 521 is perpendicular to an extending direction of the through-flow channel 10; the cross section of the volute tongue panel 521 is in the shape of a volute tongue, and the cross section of the volute tongue panel 521 is perpendicular to the extending direction of the through-flow channel 10.

Specifically, in the protruding direction of the volute tongue panel portion 521, the volute tongue panel portion 521 has a first end and a second end which are oppositely arranged; along the circumferential direction of the through-flow channel 10, the volute tongue panel portion 521 is located on one side of the first air outlet 21 away from the second air outlet 22; the first end of the volute tongue panel 521 is used for enclosing a first air outlet 21, and the second end of the volute tongue panel 521 is used for being close to the fan 60; the minimum vertical distance between the volute tongue panel part 521 and the central axis of the fan 60 is L ₃ ，(R-L ₃ )<5mm, and L ₃ <0.5L ₂ 。

Specifically, as shown in fig. 6, the second end of the cross section of the volute tongue panel 521 has a predetermined point 523, and the vertical distance between the predetermined point 523 and the central axis of the fan 60 is the minimum vertical distance L between the volute tongue panel 521 and the central axis of the fan 60 ₃ 。

Specifically, the two air outlets 20 are a first air outlet 21 and a second air outlet 22, respectively, and the air outlet panel 52 further includes a side wall plate 522; along the circumferential direction of the through-flow channel 10, the volute tongue panel portion 521 is located on one side of the first air outlet 21 away from the second air outlet 22 and is used for enclosing the first air outlet 21; the side enclosing plate 522 is used for enclosing the through-flow channel 10 and the second air outlet 22, and the side enclosing plate 522 is located at one side of the second air outlet 22 far away from the first air outlet 21; the minimum vertical spacing between the cylindrical surface on which the roots of the drive gear 40 are located and the volute tongue panel portion 521 is equal to the minimum vertical spacing between the cylindrical surface on which the roots of the drive gear 40 are located and the side gusset 522.

Specifically, the minimum vertical distance between the cylindrical surface on which the tooth root of the drive gear 40 is located and the volute tongue panel portion 521 is L ₆ The minimum vertical spacing between the cylindrical surface on which the roots of the drive gear 40 lie and the side wall plate 522 is L ₇ ，L ₆ ＝L ₇ . As shown in FIG. 7, the minimum vertical spacing between the tangent line N and the volute tongue panel portion 521 is L ₆ The minimum vertical spacing between tangent line N and side wall 522 is L ₇ 。

Specifically, as shown in fig. 5 and 7, the arc-shaped surface of the flow distribution plate 30 has two ends that are oppositely arranged in a direction perpendicular to the extending direction of the through-flow channel 10, and the chord length between the two ends of the arc-shaped surface is L ₅ ，L ₅ ＝L ₆ I.e. L ₅ ＝L ₆ ＝L ₇ 。

Through the above limitation on the position relation among the splitter plate 30, the two air outlets 20 and the fan 60, the problems of overlarge air supply distance, large air quantity loss, overlarge noise increase and the like are avoided, and the air supply efficiency is ensured.

Specifically, each air outlet 20 is provided extending in a direction parallel to the extending direction of the through-flow passage 10.

Specifically, each air outlet 20 is provided with an air outlet grille.

Specifically, each air outlet 20 is provided with a first air sweeping part 24, and the first air sweeping parts 24 sweep air along the circumferential direction of the through-flow channel 10; each air outlet 20 is provided with a second air sweeping portion 25, and the second air sweeping portion 25 sweeps air along the extending direction of the through-flow channel 10.

Specifically, the first wind sweeping portion 24 includes a first wind sweeping blade, and the second wind sweeping portion 25 includes a second wind sweeping blade.

Specifically, each first wind sweeping portion 24 is driven to move by a corresponding motor, and each second wind sweeping portion 25 is driven to move by a corresponding motor.

Specifically, the driving gear 40 is located on a side of the dividing plate 30 close to the fan 60, or the driving gear 40 is located on a side of the dividing plate 30 far from the fan 60.

The utility model also provides a cabinet air conditioner, it includes foretell air-out mechanism.

Specifically, the cabinet air conditioner further includes a fan 60.

Specifically, the cabinet air conditioner further includes an evaporator 70, and the evaporator 70 is disposed in the through-flow passage 10 to cool the air flow in the through-flow passage 10.

Specifically, the cabinet air conditioner further includes a heating part 80, and the heating part 80 is disposed in the through-flow passage 10 to heat the airflow in the through-flow passage 10.

Alternatively, the heating member 80 is electrically heated.

From the above description, it can be seen that the above-mentioned embodiments of the present invention achieve the following technical effects:

in the air outlet mechanism provided by the utility model, the air outlet mechanism comprises a through-flow channel 10, a splitter plate 30 and two air outlets 20, wherein the two air outlets 20 are both communicated with the through-flow channel 10 and are arranged at intervals along the circumferential direction of the through-flow channel 10; the flow distribution plate 30 is movably arranged in the through-flow channel 10 along the distribution direction of the two air outlets 20, and the flow distribution plate 30 has a shielding state and an avoiding state between the two air outlets 20; when the flow distribution plate 30 is in the shielding state, the flow distribution plate 30 is disposed opposite to one of the two outlets 20, so as to shield the outlet 20.

In a specific implementation process, the two air outlets 20 are respectively a first air outlet 21 and a second air outlet 22, and when the flow distribution plate 30 moves to a position between the first air outlet 21 and the second air outlet 22, the flow distribution plate 30 avoids both the first air outlet 21 and the second air outlet 22, that is, at this time, the flow distribution plate 30 does not shield the first air outlet 21 and the second air outlet 22, and the airflow in the through-flow channel 10 can flow out through the first air outlet 21 and the second air outlet 22; when the flow distribution plate 30 moves to a position opposite to the first air outlet 21, the flow distribution plate 30 is stopped between the through-flow channel 10 and the first air outlet 21 to shield the first air outlet 21, so that the first air outlet 21 is in a closed state, and at this time, the airflow in the through-flow channel 10 only flows out through the second air outlet 22; when the flow distribution plate 30 moves to a position opposite to the second air outlet 22, the flow distribution plate 30 is stopped between the through-flow channel 10 and the second air outlet 22 to shield the second air outlet 22, so that the second air outlet 22 is in a closed state, and at this time, the airflow in the through-flow channel 10 only flows out through the first air outlet 21. The diversion plate 30 may also be kept in a moving state, so that each air outlet 20 is periodically switched between a closed state and an open state to realize dynamic flow air supply. It can be seen that the air-out mode of the cabinet air conditioner with the air-out mechanism of this application is diversified, and the problem that the air-out mode of the cabinet air conditioner in the prior art is single is solved.

It should be noted that the terms "first," "second," and the like in the description and claims of this application and in the accompanying drawings are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the application described herein are, for example, capable of operation in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

Spatially relative terms, such as "above … …," "above … …," "above … … surface," "above," and the like, may be used herein for ease of description to describe one device or feature's spatial relationship to another device or feature as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if a device in the figures is turned over, devices described as "above" or "on" other devices or configurations would then be oriented "below" or "under" the other devices or configurations. Thus, the exemplary term "above … …" can include both an orientation of "above … …" and "below … …". The device may be otherwise variously oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides an air-out mechanism which characterized in that includes:

a through-flow channel (10);

the two air outlets (20) are communicated with the through-flow channel (10) and are arranged at intervals along the circumferential direction of the through-flow channel (10);

the flow distribution plate (30) is movably arranged in the through-flow channel (10) along the distribution direction of the two air outlets (20), and the flow distribution plate (30) has a shielding state and an avoiding state between the two air outlets (20); when the flow distribution plate (30) is in the shielding state, the flow distribution plate (30) is arranged opposite to one air outlet (20) of the two air outlets (20) so as to shield the air outlet (20).

2. Air outlet mechanism according to claim 1, characterized in that the splitter plate (30) is arranged swingably around a preset axis which is located outside the splitter plate (30), and the extension direction of the preset axis is parallel to the extension direction of the through-flow channel (10).

3. The air outlet mechanism of claim 1, wherein a rack is disposed on the splitter plate (30), the rack extends along the distribution direction of the two air outlets (20), and the air outlet mechanism further includes a driving gear (40) engaged with the rack to drive the splitter plate (30) to move.

4. The air outlet mechanism of claim 1, wherein the plate surface of the flow dividing plate (30) is parallel to the extending direction of the through-flow channel (10), and the plate surface of the flow dividing plate (30) is a plane or a smooth curved surface.

5. The air outlet mechanism of claim 3, wherein the plate surface of the splitter plate (30) is an arc-shaped surface, the central angle of the arc-shaped surface is θ, and the θ ranges from 50 degrees to 90 degrees.

6. The air outlet mechanism of claim 3, characterized in that a fan (60) is arranged in the cross-flow passage (10), the extension direction of the central axis of the fan (60) is parallel to the extension direction of the cross-flow passage (10), and a plurality of blades of the fan (60) are arranged around the central axis of the fan (60);

the minimum vertical distance between each air outlet (20) and the central axis of the fan (60) is L ₁ The minimum vertical distance between the cylindrical surface where the tooth root of the driving gear (40) is located and the central axis of the fan (60) is L ₂ ，L ₂ ＝C ₁ L ₁ (ii) a Wherein, C ₁ Is in the range of 1/2 to 2/3.

7. The air outlet mechanism of claim 3, characterized in that a fan (60) is arranged in the cross flow channel (10), the extension direction of the central axis of the fan (60) is parallel to the extension direction of the cross flow channel (10), and the fan (60) has a fan motor (60)The fan blades are arranged around the central axis of the fan (60); along the direction vertical to the extending direction of the central axis of the fan (60), the vertical distance between the end part of each fan blade and the central axis of the fan (60) is R; the minimum vertical distance between the cylindrical surface where the tooth root of the driving gear (40) is positioned and the central axis of the fan (60) is L ₂ ；

The two air outlets (20) are arranged on an air outlet panel (52), the air outlet panel (52) comprises a volute tongue panel part (521) protruding in the through-flow channel (10), and the protruding direction of the volute tongue panel part (521) is perpendicular to the extending direction of the through-flow channel (10); the volute tongue panel part (521) is provided with a first end and a second end which are oppositely arranged along the protruding direction of the volute tongue panel part (521); the two air outlets (20) are respectively a first air outlet (21) and a second air outlet (22), and the volute tongue panel part (521) is located on one side, far away from the second air outlet (22), of the first air outlet (21) along the circumferential direction of the through-flow channel (10); the first end of volute tongue panel portion (521) is used for enclosing into first air outlet (21), the second end of volute tongue panel portion (521) is used for being close to fan (60), the minimum vertical interval between volute tongue panel portion (521) and the central axis of fan (60) is L ₃ ，(R-L ₃ )<5mm, and L ₃ <0.5L ₂ 。

8. The air outlet mechanism of claim 3, characterized in that a fan (60) is arranged in the cross-flow passage (10), the extension direction of the central axis of the fan (60) is parallel to the extension direction of the cross-flow passage (10), and a plurality of blades of the fan (60) are arranged around the central axis of the fan (60);

the two air outlets (20) are arranged on an air outlet panel (52), the air outlet panel (52) comprises a side coaming (522) and a volute tongue panel part (521) protruding in the through-flow channel (10), and the protruding direction of the volute tongue panel part (521) is perpendicular to the extending direction of the through-flow channel (10);

the two air outlets (20) are respectively a first air outlet (21) and a second air outlet (22), and along the circumferential direction of the through-flow channel (10), the volute tongue panel part (521) is located on one side, away from the second air outlet (22), of the first air outlet (21) and is used for enclosing the first air outlet (21); the side enclosing plate (522) is used for enclosing the through-flow channel (10) and the second air outlet (22), and the side enclosing plate (522) is positioned on one side of the second air outlet (22) far away from the first air outlet (21);

the minimum vertical distance between the cylindrical surface where the tooth root of the driving gear (40) is located and the volute tongue panel portion (521) is equal to the minimum vertical distance between the cylindrical surface where the tooth root of the driving gear (40) is located and the side coaming (522).

9. The air outlet mechanism of claim 8, characterized in that the arc-shaped surface of the flow dividing plate (30) has two opposite ends along a direction perpendicular to the extending direction of the through-flow channel (10), and the chord length between the two ends of the arc-shaped surface is L ₅ The minimum vertical distance between the cylindrical surface where the tooth root of the driving gear (40) is located and the volute tongue panel part (521) is L ₆ ，L ₅ ＝L ₆ 。

10. A cabinet air conditioner characterized by comprising the air outlet mechanism of any one of claims 1 to 9.

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