CN110726239B - Hanging air conditioner - Google Patents

Abstract

The invention provides an air conditioner hanging machine, which comprises two air supply assemblies, wherein each air supply assembly comprises: the first air supply part is annular, a first central hole with a hole axis is defined in the center of the first air supply part, the first air supply part is provided with a first air inlet, a first air outlet and a first annular cavity, the first air outlet and the first annular cavity extend around the hole axis of the first central hole, the first air inlet is used for introducing airflow into the first annular cavity, and the airflow in the first annular cavity is sprayed out from the first air outlet; the second air supply part is positioned behind the first air supply part and is provided with a second air outlet; the first air outlet and the second air outlet are respectively configured to spray airflow forwards along the hole axis of the first central hole, and the airflow sprayed by the second air outlet passes through the first central hole and then is guided by the airflow sprayed by the first air outlet, so that the whole air supply amount of the air supply assembly is increased, and the whole air supply effect of the air conditioner hanging machine is better.

Description

Hanging air conditioner

Technical Field

The invention relates to a temperature adjusting device, in particular to an air conditioner hanging machine.

Background

An on-hook air conditioner is an indoor unit of an air conditioner, which is connected to an outdoor unit of the air conditioner, is generally installed on an indoor wall, and is provided with an evaporator therein, and a cooling liquid in the evaporator is evaporated to take away indoor heat (in a cooling mode) to achieve the purpose of cooling.

Still be provided with the air supply subassembly in the air conditioning room built-in, the air supply subassembly has the fan that can produce the air current, and the fan carries out the heat transfer through in with ambient air suction air conditioning built-in and the evaporimeter of flowing through, and it is indoor that the fan blows in after the ambient air heat transfer to the realization is to room air refrigeration or heat. The existing air conditioner hanging machine generally has the problems of small air supply flow and short air supply distance.

Disclosure of Invention

The invention aims to provide an air conditioner hanging machine with large air outlet quantity and long air supply distance.

In particular, the invention provides an on-hook air conditioner, which comprises two air supply assemblies, wherein each air supply assembly comprises:

the first air supply part is annular, a first central hole with a hole axis is defined in the center of the first air supply part, the first air supply part is provided with a first air inlet, a first air outlet and a first annular cavity, the first air outlet and the first annular cavity extend around the hole axis of the first central hole, the first air inlet is used for introducing airflow into the first annular cavity, and the airflow in the first annular cavity is sprayed out from the first air outlet;

the second air supply part is positioned behind the first air supply part and is provided with a second air outlet;

the first air outlet and the second air outlet are respectively configured to spray airflow forwards along the hole axis of the first central hole, and the airflow sprayed by the second air outlet passes through the first central hole and then is guided by the airflow sprayed by the first air outlet, so that the whole air supply amount of the air supply assembly is increased.

Furthermore, the second air supply part is annular and comprises a second annular cavity and a second air inlet communicated with the second annular cavity, a second central hole with a hole axis is defined in the center of the second air supply part, the second air outlet and the second annular cavity extend around the hole axis of the second central hole, the second air inlet is used for introducing airflow into the second annular cavity, and the airflow in the second annular cavity is sprayed out from the second air outlet.

Further, the first blowing part includes:

a first inner peripheral wall defining a first central aperture;

the first outer peripheral wall extends around the first inner peripheral wall, and the rear end edge of the first outer peripheral wall is connected with the rear end edge of the first inner peripheral wall;

a front end wall extending along a front end edge of the first outer peripheral wall in a direction towards the hole axis of the first central hole, the front end edge of the first inner peripheral wall and a distal end of the front end wall collectively defining a first air outlet, the first inner peripheral wall, the first outer peripheral wall and the front end wall collectively defining a first annular cavity;

the second air supply part includes:

a second inner peripheral wall defining a second central aperture;

the second outer circumferential wall extends around the second inner circumferential wall, the rear end edge of the second outer circumferential wall is connected with the rear end edge of the second inner circumferential wall, the front end edge of the second outer circumferential wall is connected with the first inner circumferential wall, a second air outlet is defined between the front end edge of the second inner circumferential wall and the first inner circumferential wall, and a second annular cavity is defined by the second inner circumferential wall, the second outer circumferential wall and the first inner circumferential wall.

Further, still include:

the guide part extends forwards along the inner edge of the front end wall and expands outwards to guide the airflow sprayed out of the first air outlet.

Further, the first blowing part includes:

a first inner peripheral wall defining a first central aperture;

the front end edge of the first outer peripheral wall is connected with the front end edge of the first inner peripheral wall;

the rear end wall extends to the inner side of the first inner circumferential wall along the rear end edge of the first outer circumferential wall in the direction close to the hole axis of the first center hole, the inner edge of the rear end wall and the wall surface of the first inner circumferential wall close to the hole axis of the first center hole jointly define a first air outlet, and the first inner circumferential wall, the first outer circumferential wall and the rear end wall jointly define a first annular cavity;

the second air supply part includes:

a second inner peripheral wall defining a second central aperture;

the second outer peripheral wall extends around the second inner peripheral wall, the rear end edge of the second outer peripheral wall is connected with the rear end edge of the second inner peripheral wall, the front end edge of the second outer peripheral wall is connected with the rear end wall, the front end edge of the second inner peripheral wall and the rear end wall jointly define a second air outlet, and the second inner peripheral wall, the second outer peripheral wall and the rear end wall jointly define a second annular cavity.

Furthermore, the first air inlet and the second air inlet are respectively arranged at the same circumferential positions of the first air supply part and the second air supply part.

Further, still include:

the air supply channel is used for guiding air flow into a first air inlet and a second air inlet of the two air supply assemblies;

and the fan is configured to supply air to the air supply channel.

Further, still include:

the two air supply channels respectively and correspondingly guide the air flow into a first air inlet and a second air inlet of the two air supply assemblies;

and the two fans are configured to supply air to the two air supply channels correspondingly.

Further, still include:

and one fan supplies air to the first air inlets of the two air supply assemblies, and the other fan supplies air to the second air inlets of the two air supply assemblies.

Furthermore, one fan conveys airflow subjected to heat exchange through a heat exchange part of the air conditioner hanging machine, and the other fan conveys ambient airflow.

According to the air conditioner hanging machine, the two air supply assemblies are arranged on the air conditioner hanging machine, each air supply assembly is provided with the first air supply part and the second air supply part, airflow is sprayed out of the first air outlet in the first air supply part, negative pressure is generated behind the first central hole, the negative pressure generates forward thrust on the airflow sprayed out of the second air outlet in the second air supply part, the air outlet effect of the second air supply part is further enhanced, and the integral air outlet effect of the air conditioner hanging machine is further enhanced.

The above and other objects, advantages and features of the present invention will become more apparent to those skilled in the art from the following detailed description of specific embodiments thereof, taken in conjunction with the accompanying drawings.

Drawings

Some specific embodiments of the invention will be described in detail hereinafter, by way of illustration and not limitation, with reference to the accompanying drawings. The same reference numbers in the drawings identify the same or similar elements or components. Those skilled in the art will appreciate that the drawings are not necessarily drawn to scale. In the drawings:

FIG. 1 is a schematic perspective view of an air delivery assembly according to one embodiment of the present invention;

FIG. 2 is a cross-sectional schematic view of the air delivery assembly shown in FIG. 1;

FIG. 3 is a cross-sectional schematic view of an air delivery assembly according to another embodiment of the present invention;

FIG. 4 is a schematic perspective view of an air delivery assembly according to yet another embodiment of the present invention;

FIG. 5 is a schematic perspective view of the blower assembly shown in FIG. 4;

FIG. 6 is a cross-sectional schematic view of an air delivery assembly according to yet another embodiment of the present invention;

FIG. 7 is a schematic rear view of an air conditioning hook according to one embodiment of the present invention;

fig. 8 is a perspective view of the on-hook air conditioner shown in fig. 7.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

In the following description, the terms "front" and "rear" and the like indicating the directions refer to the air outlet direction, and when the air outlet direction changes, the direction indicated by "front" and "rear" also changes with the air outlet direction, the direction located downstream is the front, and the direction located upstream is the rear.

As shown in fig. 1-8, a preferred embodiment of the present invention is shown.

The air-conditioning hanging machine 70 comprises two air supply assemblies 60, wherein the air supply assemblies 60 are used for guiding ambient air into the air-conditioning hanging machine 70, so that the ambient air flows through heat exchange parts in the air-conditioning hanging machine 70 and is sprayed indoors after exchanging heat with the heat exchange parts, an air outlet 71 is formed in the air-conditioning hanging machine 70, and air flow sprayed in the air supply assemblies 60 is sprayed out of the air-conditioning hanging machine 70 through the air outlet 71. Each air blowing assembly 60 specifically includes a first air blowing part 10 and a second air blowing part 20.

The first air supply part 10 is annular, and may be circular, the center of the first air supply part 10 defines a first central hole 16 having a hole axis X, and the first central hole 16 may be a kidney-shaped hole or a circular hole, and the hole axis X may be understood as a central axis of the first central hole 16 regardless of the shape of the first central hole 16. The first air supply part 10 has a first air inlet 14, a first air outlet 15, and a first annular cavity 13, the first air inlet 14 is used for introducing airflow into the first annular cavity 13, and the airflow in the first annular cavity 13 is ejected from the first air outlet 15. The first outlet 15 and the first annular chamber 13 are arranged to extend around the hole axis X of the first central hole 16, and the position of the first inlet 14 is not limited herein, and it is sufficient to introduce the airflow into the first annular chamber 13.

The second blowing part 20 is located behind the first blowing part 10 and has a second outlet 25, and the specific structure of the second blowing part 20 may be any structure capable of ejecting an air flow outward in the prior art.

The first air outlet 15 and the second air outlet 25 are respectively configured to spray air flow forward along the hole axis X of the first central hole 16, and the sprayed air flow may be parallel to the hole axis X of the first central hole 16 or form a certain angle with the hole axis X of the first central hole 16. In the process of ejecting the air flow, the first air outlet 15 and the second air outlet 25 form a negative pressure behind the first central hole 16, so that the ambient air behind the first air supply part 10 is brought into the first central hole 16 by the negative pressure, and is ejected forward along the hole axis X of the first central hole 16 together with the air flow ejected from the first air outlet 15. The air flow sprayed out of the air supply assembly 60 is mixed with the ambient air flow, so the air supply effect is better.

The heat exchange air (cold air during refrigeration and hot air during heating) ejected from the first air outlet 15 and exchanging heat with the heat exchange component in the air-conditioning hanging machine 70 can be mixed with indoor ambient air and ejected, so that on one hand, ambient air flow can be better guided, normal-temperature air in the environment is mixed with the air after heat exchange, and the heat exchange efficiency of the normal-temperature air and the heat exchange air in the environment is accelerated; on the other hand, the cool air jetted out of the first air outlet 15 mixes with the ambient air flow, and the temperature is moderate, so that when the temperature of the cool air jetted out of the first air outlet 15 is too low and blows directly to the user, the user can be effectively prevented from catching a cold.

In this embodiment, since the first air outlet 15 sprays the air flow forward, a negative pressure is generated behind the first central hole 16, and this negative pressure will generate a forward thrust on the air flow sprayed in the second air supply part 20 behind the first air supply part 10, thereby enhancing the air supply effect of the second air supply part 20. Therefore, compared with the conventional structure with a single air outlet, the structure with two air outlets can increase the air supply distance of the whole air supply assembly 60 and increase the air supply amount of the whole air supply assembly 60.

The simulation experiment shows that under the same other conditions, the air outlet distance of one larger air outlet is obviously smaller than the air outlet distance of two smaller air outlets (wherein the sum of the areas of the two smaller air outlets is basically equal to the area of the larger air outlet), and the experimental data also shows that the air outlet quantity of the two smaller air outlets is 20% higher than the air outlet quantity of the larger air outlet.

The second air supply part 20 is located behind the first air supply part 10, on one hand, in order to prevent the second air supply part 20 from blocking the first central hole 16 and affecting the flow of the external air to the first central hole 16, and on the other hand, in order to increase the diversion effect of the external air, in an embodiment, the second air supply part 20 is annular and comprises a second annular cavity 23 and a second air inlet 24 communicated with the second annular cavity 23, the center of the second air supply part 20 defines a second central hole 26 having a hole axis Y, and the hole axis Y of the second central hole 26 may be parallel to the hole axis X of the first central hole 16 or may coincide with the hole axis X of the first central hole 16. The second air outlet 25 and the second annular chamber 23 both extend around the hole axis Y of the second central hole 26, the second air inlet 24 is used for introducing air flow into the second annular chamber 23, the air flow in the second annular chamber 23 is ejected from the second air outlet 25, and the ejected air flow flows into the first central hole 16 and extends forward along the direction parallel to the hole axis X of the first central hole 16.

When the second air supply part 20 is also annular, the second air supply part 20 does not block the flow of the external air flowing into the first central hole 16, and meanwhile, the air flow ejected from the second air outlet 25 can form negative pressure behind the second central hole 26, so that the air flow ejected from the second air outlet 25 can also guide the external air, and the annular structure of the second air supply part 20 enhances the flow guiding effect of the whole air supply assembly 60 on the external air.

The first air supply part 10 and the second air supply part 20 can be two mutually independent parts, and when the two parts are mutually independent, the relative positions of the two parts can be set to be adjustable, so that the air outlet direction and the air outlet size can be finely adjusted according to the needs of users, in another embodiment, the first air supply part 10 and the second air supply part 20 can be integrally arranged, the processing and manufacturing costs of the two parts can be reduced, and the first air supply part 10 and the second air supply part 20 can be fixed at the optimal relative positions when the first air supply part 10 and the second air supply part 20 are designed, so that the optimal air supply effect is achieved.

As shown in fig. 1 to 3, when the first blowing part 10 and the second blowing part 20 are integrally provided, the first blowing part 10 may be provided to include a first inner peripheral wall 11, a first outer peripheral wall 12, and a front end wall 17. The first inner circumferential wall 11 is annular, and the first center hole 16 of the first blowing part 10 is defined by the first inner circumferential wall 11. The first outer circumferential wall 12 extends around the first inner circumferential wall 11, and a rear end edge of the first outer circumferential wall 12 is curved outward (the "outer" referred to herein means a direction away from the hole axis X of the first center hole 16) and connected to a rear end edge of the first inner circumferential wall 11. The front end wall 17 extends along a front end edge of the first outer circumferential wall 12 in a direction toward the hole axis X near the first center hole 16, and the front end edge of the first inner circumferential wall 11 and a distal end of the front end wall 17 (the distal end referred to herein means an inner end edge of the front end wall 17 near the hole axis X of the first center hole 16, which is annular) together define the aforementioned first air outlet 15 therebetween. The first annular cavity 13 is defined by an inner space surrounded by the first inner peripheral wall 11, the first outer peripheral wall 12 and the front end wall 17.

The second blowing section 20 includes a second inner peripheral wall 21 and a second outer peripheral wall 22. The second inner circumferential wall 21 defines a second central hole 26, the second outer circumferential wall 22 extends around the second inner circumferential wall 21, a rear end edge of the second outer circumferential wall 22 is bent outward and connected to a rear end edge of the second inner circumferential wall 21, a front end edge of the second outer circumferential wall 22 is connected to the first inner circumferential wall 11, specifically, the second inner circumferential wall 11 may be connected to a rear end edge of the first inner circumferential wall 11, the front end edge of the second inner circumferential wall 21 and the first inner circumferential wall 11 together define the aforementioned second air outlet 25, and the second inner circumferential wall 21, the second outer circumferential wall 22 and the first inner circumferential wall 11 together define a second annular cavity 23.

In order to increase the diffusion area of the air flow ejected from the first outlet 15 and the second outlet 25 when the first air blowing part 10 and the second air blowing part 20 are configured as described above, in one embodiment, the front end of the first air blowing part 10 is provided with the flow guiding part 30, the flow guiding part 30 extends forward along the inner edge of the front end wall 17, and the flow guiding part 30 extends forward while expanding outward, that is, the diameter of the flow guiding part 30 increases as it goes away from the front end wall 17. When the airflow ejected from the first outlet 15 and the second outlet 25 flows through the flow guiding portion 30, the airflow attached to the inner surface of the flow guiding portion 30 flows forward, and the airflow guided out by the flow guiding portion 30 spreads in a substantially conical shape due to the outward expansion of the flow guiding portion 30, and the spreading area of the airflow is larger as the airflow is farther away from the flow guiding portion 30. To further increase the diffusion area of the airflow, in one embodiment, the portion of the flow guide 30 farther from the front end wall 17 may be configured such that the increase rate of the aperture thereof is faster.

As shown in fig. 4 to 5, when the first blowing part 10 and the second blowing part 20 are integrally formed, the first blowing part 10 may further include a first inner peripheral wall 11, a first outer peripheral wall 12, and a rear end wall 18. The first inner circumferential wall 11, the first outer circumferential wall 12 and the rear end wall 18 are all annular, the interior of the first inner circumferential wall 11 defining the aforementioned first central aperture 16. The first outer circumferential wall 12 extends around the first inner circumferential wall 11, and a front end edge of the first outer circumferential wall 12 is connected to a front end edge of the first inner circumferential wall 11. The rear end wall 18 extends inwardly along the rear end edge of the first outer circumferential wall 12, and an edge of the rear end wall 18 close to the hole axis X of the first center hole 16 is bent forward and extends to the inside of the first inner circumferential wall 11, an inner edge of the rear end wall 18 and an inner wall surface of the first inner circumferential wall 11 together define the first air outlet 15, and the first inner circumferential wall 11, the first outer circumferential wall 12, and the rear end wall 18 together define the first annular chamber 13. Specifically, the airflow in the first annular chamber 13 is ejected from the gap between the surface of the rear end wall 18 facing the first annular chamber 13 and the surface of the first inner circumferential wall 11 facing the first central bore 16.

The second blowing section 20 includes a second inner peripheral wall 21 and a second outer peripheral wall 22. The second inner circumferential wall 21 defines the second center hole 26 described above. The second outer peripheral wall 22 extends around the second inner peripheral wall 21, and a rear end edge of the second outer peripheral wall 22 is connected to a rear end edge of the second inner peripheral wall 21, a front end edge of the second outer peripheral wall 22 is connected to the rear end wall 18, the front end edge of the second inner peripheral wall 21 and the rear end wall 18 jointly define the second air outlet 25, and the second inner peripheral wall 21, the second outer peripheral wall 22 and the rear end wall 18 jointly define the second annular cavity 23.

No matter what kind of structure is adopted for the air supply assemblies 60, the hole axes X of the first central holes 16 in the two air supply assemblies 60 in the hanging air conditioner 70 can be located in the same horizontal plane, that is, the two central holes are arranged transversely and oppositely, so that the size of the hanging air conditioner 70 in the vertical direction can be reduced.

No matter which structure the first air supply part 10 and the second air supply part 20 have, the first air inlet 14 and the second air inlet 24 may be respectively opened at the same circumferential position of the first air supply part 10 and the second air supply part 20, so that the initial positions of the air flows sprayed into the first annular cavity 13 and the second annular cavity 23 are the same, and the directions of the air flows sprayed into the first annular cavity 13 and the second annular cavity 23 are better kept the same. When the initial positions and directions of the airflows sprayed into the first annular cavity 13 and the second annular cavity 23 are consistent, the internal airflow change laws of the first annular cavity 13 and the second annular cavity 23 are the same, so that the airflows sprayed out of the first air outlet 15 and the second air outlet 25 cannot move along the circumferential direction of the first air outlet 15 and the second air outlet 25, and the overall air outlet effect of the first air outlet 15 and the second air outlet 25 is further enhanced.

The on-hook air conditioner 70 further includes an air supply channel 40 and a fan 50 (the fan 50 may be a centrifugal fan 50 or an axial flow fan 50), and the fan 50 generates an air flow and then guides the air flow to the first air inlet 14 and the second air inlet 24 through the air supply channel 40, that is, the air flow guided into the first air inlet 14 and the second air inlet 24 is provided by one fan 50, so that the manufacturing cost and the use cost can be reduced. Specifically, one air supply passage 40 may be utilized to direct air flow to the first air inlet 14 and the second air inlet 24 of two air supply assemblies 60, respectively. Two air supply passages 40 may also be provided, and each air supply passage 40 is respectively communicated with the first air inlet 14 and the second air inlet 24 of one of the air supply assemblies 60. Whether there is one air supply passage 40 or two air supply passages 40, only one fan 50 may be provided for air supply. When there are two air supply passages 40, preferably, two fans 50 may be provided, each fan 50 being separately communicated with one air supply passage 40, so that the two air supply assemblies 60 are completely independent, thereby allowing the relative positions of the two to be flexibly arranged.

In order to avoid the air flow at the first air inlet 14 and the second air inlet 24 from moving mutually and reducing the air outlet effect, a partition plate 43 may be disposed in the air supply channel 40, the partition plate 43 is used for isolating the first air inlet 14 and the second air inlet 24 to form a first chamber 41 communicated with the first air inlet 14 and a second chamber 42 communicated with the second air inlet 24, the first chamber 41 and the second chamber 42 make the port supplying air to the first air inlet 14 and the second air inlet 24 far away from the first annular chamber 13 and the second annular chamber 23 as possible, and the air outlet processes of the first air supplying part 10 and the second air supplying part 20 are relatively independent.

In order to make the air outlet conditions of the two air supply assemblies 60 consistent and enhance the air supply effect of the air conditioner on-hook 70, in a specific embodiment, two fans 50 are provided for supplying air, one fan 50 supplies air to the first air inlets 14 of the two air supply assemblies 60, the other fan 50 supplies air to the second air inlets 24 of the two air supply assemblies 60, and how the fan 50 is specifically communicated with the first air inlets 14 or the second air inlets 24 is not described herein.

When the air-conditioning hook 70 has two fans 50 for supplying air, in an embodiment, one fan 50 supplies an air flow after heat exchange through the heat exchange component in the air-conditioning hook 70, and the other fan 50 supplies an ambient air flow (i.e. an air flow generated by the fan 50 extracting ambient air outside the air-conditioning hook 70 and not exchanging heat through the heat exchange component in the air-conditioning hook 70), preferably, the fan 50 connected to the first air inlet 14 supplies the ambient air flow, and the fan 50 connected to the second air inlet 24 supplies the air flow after heat exchange, so that when the temperature of the ambient air is reduced or increased (reduced when cooling or increased when heating) to be very close to a set temperature, the ambient air can be extracted by the fan 50 connected to the first air inlet 14 and ejected from the first air outlet 15, the air flow ejected from the first air outlet 15 guides the heat exchange air flow ejected from the second air outlet 25, the power of the fan 50 communicated with the second air inlet 24 can be reduced, and the electric power cost is saved.

In particular, in some modes of the on-hook air conditioner 70, it is also possible to operate only the fan 50 for drawing the ambient air flow, so that the on-hook air conditioner 70 has a function of only blowing air and not cooling, like an electric fan, and thus the function can be turned on under the condition of low external temperature, thereby saving a large amount of electricity charges.

Thus, it should be appreciated by those skilled in the art that while a number of exemplary embodiments of the invention have been illustrated and described in detail herein, many other variations or modifications consistent with the principles of the invention may be directly determined or derived from the disclosure of the present invention without departing from the spirit and scope of the invention. Accordingly, the scope of the invention should be understood and interpreted to cover all such other variations or modifications.

Claims (9)

1. An on-hook air conditioner comprising two air supply assemblies, each air supply assembly comprising:

the first air supply part is annular, a first central hole with a hole axis is defined in the center of the first air supply part, the first air supply part is provided with a first air inlet, a first air outlet and a first annular cavity, the first air outlet and the first annular cavity extend around the hole axis of the first central hole, the first air inlet is used for introducing airflow into the first annular cavity, and the airflow in the first annular cavity is sprayed out from the first air outlet;

the second air supply part is positioned behind the first air supply part and is provided with a second air outlet;

the first air outlet and the second air outlet are respectively configured to spray airflow forwards along the hole axis of the first central hole, and the airflow sprayed out by the second air outlet passes through the first central hole and then is guided by the airflow sprayed out by the first air outlet, so that the air supply quantity of the whole air supply assembly is increased;

the second air supply part is annular and comprises a second annular cavity and a second air inlet communicated with the second annular cavity, a second central hole with a hole axis is defined in the center of the second air supply part, the second air outlet and the second annular cavity both extend around the hole axis of the second central hole, the second air inlet is used for introducing airflow into the second annular cavity, and the airflow in the second annular cavity is sprayed out from the second air outlet;

the fan generates airflow and then leads the airflow to the first air inlet and the second air inlet through the air supply channel.

2. The on-hook air conditioner of claim 1,

the first air supply part includes:

a first inner peripheral wall defining the first central aperture;

a first outer peripheral wall extending around the first inner peripheral wall, a rear end edge of the first outer peripheral wall being connected to a rear end edge of the first inner peripheral wall;

a front end wall extending along a front end edge of the first outer peripheral wall in a direction proximate to the aperture axis of the first central aperture, the front end edge of the first inner peripheral wall and a terminal end of the front end wall collectively defining the first air outlet, the first inner peripheral wall, first outer peripheral wall and the front end wall collectively defining the first annular cavity;

the second air supply part includes:

a second inner circumferential wall defining the second central bore;

the second outer circumferential wall extends around the second inner circumferential wall, the rear end edge of the second outer circumferential wall is connected with the rear end edge of the second inner circumferential wall, the front end edge of the second outer circumferential wall is connected with the first inner circumferential wall, the second air outlet is defined between the front end edge of the second inner circumferential wall and the first inner circumferential wall together, and the second annular cavity is defined by the second inner circumferential wall, the second outer circumferential wall and the first inner circumferential wall together.

3. The on-hook air conditioner of claim 2, further comprising:

and the flow guide part extends forwards along the inner edge of the front end wall and expands outwards to guide the airflow sprayed out of the first air outlet.

4. The on-hook air conditioner of claim 1, wherein:

the first air supply part includes:

a first inner peripheral wall defining the first central aperture;

a first outer peripheral wall whose front end edge is connected to the front end edge of the first inner peripheral wall;

a rear end wall extending to an inner side of the first inner peripheral wall along a rear end edge of the first outer peripheral wall in a direction close to the hole axis of the first center hole, an inner edge of the rear end wall and a wall surface of the first inner peripheral wall close to the hole axis of the first center hole together defining the first air outlet, the first inner peripheral wall, the first outer peripheral wall and the rear end wall together defining the first annular cavity;

the second air supply part includes:

a second inner circumferential wall defining the second central bore;

the second outer peripheral wall extends around the second inner peripheral wall, the rear end edge of the second outer peripheral wall is connected with the rear end edge of the second inner peripheral wall, the front end edge of the second outer peripheral wall is connected with the rear end wall, the front end edge of the second inner peripheral wall and the rear end wall jointly define the second air outlet, and the second inner peripheral wall, the second outer peripheral wall and the rear end wall jointly define the second annular cavity.

5. The on-hook air conditioner of any one of claims 2-4,

the first air inlet and the second air inlet are respectively arranged at the same circumferential position of the first air supply part and the second air supply part.

6. The on-hook air conditioner of claim 1, further comprising:

the air supply channel is used for guiding air flow into the first air inlet and the second air inlet of the two air supply assemblies;

a fan configured to supply air to the air supply passage.

7. The on-hook air conditioner of claim 1, wherein:

the two air supply channels are used for guiding air flow into the first air inlet and the second air inlet of the two air supply assemblies respectively; and is

The number of the fans is two, and the two fans are configured to supply air to the two air supply channels correspondingly.

8. The on-hook air conditioner of claim 1, further comprising:

and one fan supplies air to the first air inlets of the two air supply assemblies, and the other fan supplies air to the second air inlets of the two air supply assemblies.

9. The on-hook air conditioner of claim 8,

one of the fans conveys airflow after heat exchange through a heat exchange part of the air conditioner hanging machine, and the other fan conveys ambient airflow.

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