CN210624723U - Multi-air outlet cabinet type air conditioner indoor unit - Google Patents

Abstract

The utility model provides a machine in many air outlets cabinet air conditioner, include: the air inlet is communicated with the lower cavity, and a connecting channel for communicating the upper air outlet and the lower air outlet is formed in the upper cavity; the fan assembly is arranged in the lower cavity; and the air duct switching mechanism is used for sealing the lower outlet and conducting the connecting channel or opening the lower air outlet and sealing the connecting channel. According to the technical scheme, the air conditioner can realize air outlet of only the upper air outlet during refrigeration, the lower air outlet does not output air, the upper air outlet and the lower air outlet simultaneously output air during heating, the indoor temperature field is more uniform due to the air outlets, and the refrigeration efficiency and the heating efficiency are obviously improved.

Description

Multi-air outlet cabinet type air conditioner indoor unit

Technical Field

The utility model relates to an air conditioning technology field particularly, relates to a machine in many air outlets cabinet air conditioner.

Background

The existing indoor unit of split floor cabinet air conditioner includes casing, evaporator, air inlet and outlet, air duct, fan unit, etc. it operates by fan, and sucks the indoor air from the air inlet and passes through the heat exchanger to reach a certain temperature, then blows out through the air duct and air outlet, most of them have only one air outlet, and they are generally arranged on the upper half of the indoor cabinet. The air conditioner with the structure mainly has the following defects:

1: when heating, because the density of the hot air is lower than that of the normal temperature air, the hot air floats upwards, the air outlet is positioned at the upper half part of the indoor cabinet, the blown hot air is difficult to sink to the ground, and is difficult to press down by the air deflector, so that the average indoor temperature is higher than the outside, but the temperature is lower than the place close to the ceiling at the height close to the ground, and the indoor temperature is in a layered distribution state. The feet of the user are at the lowest part, so when the air conditioner is started, the feet still feel cold, and the comfort is poor;

2: when heating, refrigeration, the air outlet is located the first half of indoor cabinet-type air conditioner, and when the aviation baffle luffing motion, the air has certain kinetic energy behind the fan, and the air blows to people's face with certain speed, extremely influences the travelling comfort.

SUMMERY OF THE UTILITY MODEL

In view of the above problems in the prior art, an indoor unit of a multi-outlet cabinet air conditioner is provided to achieve the air outlet at the upper and lower outlets simultaneously when the air conditioner is used for cooling and heating, so as to overcome the technical defects.

The specific technical scheme is as follows:

a multi-outlet cabinet air-conditioner indoor unit, comprising:

the air conditioner comprises a main machine body, a front side plate of the main machine body is provided with an upper air outlet and a lower air outlet, an air inlet is also formed in the front side plate or the rear side plate of the main machine body, an evaporator is arranged in the main machine body and divides the interior of the main machine body into an upper cavity and a lower cavity, the upper air outlet and the lower air outlet are respectively communicated with the upper cavity, the air inlet is communicated with the lower cavity, and a connecting channel for communicating the lower air outlet and the upper air outlet is formed in the upper cavity;

the fan assembly is arranged in the lower cavity and used for sending the air flow entering the lower cavity from the air inlet out of the upper air outlet and the lower air outlet through the evaporator;

and the air duct switching mechanism is arranged in the upper cavity and used for sealing the lower air outlet and conducting the connecting channel or opening the lower air outlet and sealing the connecting channel.

Preferably, the air duct switching mechanism includes a sliding door, and the sliding door is vertically disposed above the lower air outlet for closing or opening the lower air outlet.

Preferably, the air duct switching mechanism further comprises a sliding block, the sliding block can be longitudinally arranged in the upper cavity in a lifting mode, and the lower portion of the sliding block is matched with the connecting channel in shape and used for closing or opening the connecting channel.

Preferably, the air duct switching mechanism further comprises: the transmission component is movably arranged in the main machine body, is respectively connected with the sliding door and the sliding block in a transmission way, and is used for synchronously driving the sliding door and the sliding block to ascend and descend in different directions;

the driving mechanism is fixedly arranged in the main machine body, and the output end of the driving mechanism is in transmission connection with the transmission member and used for driving the transmission member to move.

Preferably, the air duct switching mechanism comprises two driving members fixedly mounted inside the main body, and output ends of the two driving members are respectively in transmission connection with the sliding door and the sliding block.

Preferably, the air duct switching mechanism further comprises a support plate; the bracket plate is fixedly arranged on the inner side wall of the main machine body or is a part of a front side shell of the main machine body, the sliding door and the sliding block can be longitudinally arranged on the bracket plate in a lifting way, and the driving mechanism is fixedly arranged on the bracket plate;

but drive member be circumferential direction's at least one gear of installing on the mounting panel, the sliding door sets up in opposite directions and one side in opposite directions with the slider all sets up the spur rack structure with gear engaged with.

Preferably, the evaporator is obliquely arranged, the lower cavity is horizontally and fixedly provided with a turnover motor, an output shaft of the turnover motor is hinged with a partition plate, the upper end of the partition plate can be overturned towards the evaporator to abut against the lower side face of the evaporator, the lower cavity is divided into a second air channel and a first air channel which are arranged in the front and at the back, and the lower end of the partition plate abuts against the upper edge of the fan assembly.

Preferably, the fan assembly comprises a first centrifugal fan and a second centrifugal fan, the second centrifugal fan is located in the front side direction of the position below the first centrifugal fan, the air inlet is formed in the rear side plate of the main body, and the air inlet ends of the two centrifugal fans are opposite to the air inlet.

Preferably, the fan assembly comprises two motors horizontally and fixedly arranged in the lower cavity and arranged in a back-to-back manner, and the output shaft of each motor is respectively sleeved with a fan blade;

the number of the air inlets is two, the two air inlets are respectively arranged on the front side plate and the rear side plate of the main body, and the air inlet ends of the two fan blades are respectively opposite to the two air inlets.

The beneficial effects of the above technical scheme are that:

(1) the multi-air-outlet cabinet air conditioner indoor unit comprises a main machine body, a fan assembly and an air duct switching mechanism, air outlet air of an upper air outlet can be realized when the air conditioner is refrigerated, air outlet air of a lower air outlet can not be discharged, the upper air outlet and the lower air outlet simultaneously discharge air when the air conditioner is heated, the indoor temperature field is more uniform due to the multiple air outlets, an air outlet channel of the air duct switching mechanism in a refrigerating and heating state can be effectively switched, air outlet quantity of the lower air outlet 4 is effectively guaranteed under a heating condition, refrigerating and heating efficiency is obviously improved, and comfort of a user brought by the air conditioner is greatly.

(2) The two centrifugal fans are arranged in the lower cavity at positions of one above the other and one behind the other, so that the two centrifugal fans can absorb enough air quantity during operation and do not interfere with each other.

Drawings

FIG. 1 is a schematic structural view of a first embodiment of a multi-outlet cabinet type air conditioner indoor unit of the present invention;

FIG. 2 is a perspective view of an air duct switching mechanism in an embodiment of the indoor unit of a multi-outlet cabinet air conditioner of the present invention;

FIG. 3 is a side view of an air duct switching mechanism in an embodiment of an indoor unit of a multi-outlet cabinet air conditioner of the present invention;

FIG. 4 is a side view of the indoor unit of a multi-outlet cabinet air conditioner of the present invention in another state;

FIG. 5 is a view showing a structure of the multi-outlet cabinet type air conditioner indoor unit of the present invention under a refrigeration condition;

FIG. 6 is a view showing the structure of the multi-outlet cabinet type air conditioner indoor unit of the present invention under a heating condition;

FIG. 7 is a schematic structural view of a second embodiment of the multi-outlet cabinet type air conditioner indoor unit of the present invention;

FIG. 8 is a perspective view of each part inside the main body of a second embodiment of the multi-outlet cabinet type air conditioner indoor unit of the present invention;

fig. 9 is a schematic structural view of a third embodiment of the indoor unit of a multi-outlet cabinet air conditioner of the present invention.

Description of reference numerals:

1. a main body; 2. an evaporator; 3. an upper air outlet; 4. a lower air outlet; 5. an air inlet; 6. an air duct switching mechanism; 7. a partition plate; 8. an upper cavity; 9. a lower cavity; 10. a first air duct; 11. a second air duct; 12. a first centrifugal fan; 13. a second centrifugal fan; 14. a mounting plate; 15. a sliding door; 16. a slider; 17. a transmission member; 18. a drive mechanism; 19. a longitudinal guide rail; 20. turning over a motor; 21. a fan assembly; 22. a connecting channel.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention more comprehensible, embodiments of the present invention are described in detail with reference to fig. 1 to 9.

In the first embodiment, the first step is,

referring to fig. 1 to 6, the directions of arrows shown in fig. 5 and 6 indicate the air flow directions under various operating conditions, and the left-to-right direction as viewed on the paper surface in fig. 1 is defined as the back-to-front direction in the present embodiment.

In this embodiment, the multi-outlet cabinet air conditioner indoor unit includes:

the air conditioner comprises a main body 1, an upper air outlet 3 and a lower air outlet 4 are formed in the front side plate of the main body 1, an air inlet 5 is further formed in the front side plate or the rear side plate of the main body 1, an evaporator 2 is installed inside the main body 1, the inside of the main body 1 is divided into an upper cavity 8 and a lower cavity 9 by the evaporator 2, the upper air outlet 3 and the lower air outlet 4 are respectively communicated with the upper cavity 8, the air inlet 5 is communicated with the lower cavity 9, and a connecting channel 22 for communicating the lower air outlet 4 with the upper air outlet 3 is formed in the upper cavity 8;

the fan assembly 21 is arranged in the lower cavity 9 in the main machine body 1 and used for sending the air flow entering the lower cavity 9 from the air inlet 5 out of the upper air outlet 3 and the lower air outlet 4 through the evaporator 2;

and the air duct switching mechanism 6 is arranged in the upper cavity 8 and used for sealing the lower air outlet 4 and conducting the connecting channel 22 or opening the lower air outlet 4 and cutting off the connecting channel 22.

Based on the technical scheme, many air outlets cabinet air conditioner indoor set includes the main frame body 1, fan subassembly 21, wind channel switching mechanism 6, only go up 3 air-out of air outlet when can realizing the air conditioner refrigeration, and air outlet 4 does not go out the air down, the air outlet goes out simultaneously about during heating, and a plurality of air outlets make the indoor temperature field more even, wind channel switching mechanism can effectively switch the air-out passageway under refrigeration and the state of heating, and effectively guarantee the air output of air outlet 4 under the condition of heating, refrigeration, the efficiency of heating obviously promotes, the travelling comfort that the air conditioner brought for the user has been improved greatly.

In a preferred embodiment, as shown in fig. 2 to 4 in particular, the air duct switching mechanism includes a sliding door 15, and the sliding door 15 is vertically disposed above the lower air outlet 4 for closing or opening the lower air outlet 4. Further, the air duct switching mechanism further comprises a sliding block 16, the sliding block 16 is longitudinally arranged in the upper cavity 8 in a lifting manner, and the lower part of the sliding block 16 is matched with the shape of the connecting channel 22 to close or open the connecting channel 22. Further, the air duct switching mechanism further comprises: the transmission component 17 is movably arranged inside the main machine body 1, is respectively connected with the sliding door 15 and the sliding block 16 in a transmission way, and is used for synchronously driving the sliding door 15 and the sliding block 16 to ascend and descend in different directions; the driving mechanism 18 is fixedly installed inside the main body 1, and the output end of the driving mechanism is connected with the transmission member 17 in a transmission manner, so as to drive the transmission member 17 to move. Or, the air duct switching mechanism comprises two driving components fixedly installed inside the main body 1, and output ends of the two driving components are respectively in transmission connection with the sliding door 15 and the sliding block 16 to respectively drive the sliding door and the sliding block to operate. Specifically, the driving mechanism 18 and the driving member may be both motors.

As a further preferred embodiment, the air duct switching mechanism further comprises a supporting plate 14, the supporting plate 14 is fixedly mounted on the inner side wall of the main machine body 1 or is a part of the front side shell of the main machine body 1, the sliding door 15 and the sliding block 16 can be vertically installed on the supporting plate 14, and the driving mechanism 18 is fixedly mounted on the supporting plate 14; the transmission component 17 is at least one gear which can rotate circumferentially and is arranged on the support plate 14, and the sliding door 15 and the sliding block 16 are arranged in opposite directions, and one opposite sides of the sliding door and the sliding block are provided with spur rack structures which are meshed with the gears. When the driving mechanism 18 drives the transmission member 17 to rotate, the sliding door 15 and the sliding block 16 can be driven to lift synchronously and in different directions, and the purpose of quickly switching the air flow direction of the air outlet 4 downwards during the switching of cold and hot working conditions is effectively realized.

Obviously, the number of the transmission members 17 and the driving mechanisms 18 is not limited to one except for the sliding door 15 and the sliding block 16, for example, the two sets of driving members described above respectively drive the sliding door 15 and the sliding block 16, and the effect of synchronous and opposite movement can be achieved in an electrically controlled manner, and further, the transmission members 17 can also achieve the purpose of synchronous and opposite movement in a manner that rollers are arranged above the supporting plate 14 and hinges are wound around the rollers. Furthermore, the entire supporting plate 14 is a hollow frame-shaped plate structure, the sliding door 15 is slidably mounted in the hollow channel of the supporting plate 14 from bottom to top, the sliding mounting can be realized through a rail groove structure, the detailed description is omitted, a longitudinal guide rail 19 is further arranged on one side of the supporting plate 14 facing the evaporator 2, and a sliding groove matched with the longitudinal guide rail 19 is arranged on one side of the sliding block 16 facing the supporting plate 14, so as to realize the purpose of longitudinal lifting. In addition, in this embodiment, the number of the gears is two, the gears are rotatably connected to the hollow channel through the pin shaft, the rear side of the supporting plate 14 is further provided with a notch allowing the gears to protrude backward to match with the spur rack on the front side of the sliding block 16, at least one of the gears is sleeved on the output shaft of the driving motor serving as the driving mechanism 18, and correspondingly, the spur racks on opposite sides of the sliding block 16 and the sliding door 15 are both two. The selection of the driving mechanism 18 is not limited to the motor, for example, the driving mechanism 18 may be an electric push rod or a cylinder corresponding to the above-mentioned two sets of driving mechanisms 18 and the transmission member 17 to control the slider 16 and the sliding door 15, and the driving mechanism 18 may be an electric push rod or a cylinder corresponding to the above-mentioned transmission member 17 being a hinge or a roller, and thus, the selection is not limited thereto. As a further preferred embodiment, as shown in fig. 1, 5 and 6, the evaporator 2 is obliquely arranged, the lower cavity 9 is further horizontally and fixedly provided with a turnover motor 20, an output shaft of the turnover motor 20 is hinged with a partition plate 7, an upper end of the partition plate 7 can be turned over towards the evaporator 2 to abut against a lower side surface of the evaporator 2, and the lower cavity 9 is divided into a second air duct 11 and a first air duct 10 which are arranged in a front-back manner. Further, the position where the partition 7 abuts the evaporator 2 and the position where the evaporator 2 faces the connecting passage 22 are separated from the opposite sides of the evaporator 2. Further, the lower end of the baffle plate 7 is abutted against the upper edge of the fan assembly 21.

In specific use, as shown in fig. 5 and fig. 6, by the air duct switching mechanism, under the refrigeration condition: the sliding door 15 descends to close the lower air outlet 4, the sliding block 16 correspondingly moves upwards to enable the connecting channel 22 to be in a conducting state, the partition plate 7 is turned to be in a vertical state (at least separated from a position where the partition plate is propped against the evaporator 2), and air flow can enter the upper cavity 8 from the lower cavity 9 through the evaporator 2 and flow out from the upper air outlet 3 under the action of the fan assembly 21; and under the heating condition: the sliding door 15 is lifted to open the lower air outlet 4, the sliding block 16 correspondingly moves downwards to enable the connecting channel 22 to be in a cut-off state, the partition plate 7 is turned to abut against the evaporator 2 and divides the lower cavity into the second air duct 11 and the first air duct 10, so that on one hand, air flow can flow out from the second air duct 11 to the upper air outlet 3 through the evaporator 2, and on the other hand, the air flow enters a region close to the lower air outlet 4 through the evaporator 2 and flows out from the lower air outlet 4 through the first air duct 10. This makes the air output of air outlet 4 under the heating condition guarantee to the air conditioner heating efficiency is higher.

In a preferred embodiment, the fan assembly 21 comprises a first centrifugal fan 12 and a second centrifugal fan 13, arranged in the lower chamber 9 in a position one above the other and one behind the other. Specifically, the second centrifugal fan 13 is located in the front side direction of the position below the first centrifugal fan 12, the air inlet 5 is arranged on the rear side plate of the main body 1, and the air inlet ends of the two centrifugal fans are opposite to the air inlet 5, so that the two centrifugal fans can suck enough air quantity during operation and do not interfere with each other.

In addition, the fan assembly 21, the driving motor, the turnover motor 20 and the evaporator 2 are electrically connected to a central controller in the main body 1 through wires, respectively, so as to control the operating states of the components in a unified manner. Obviously, the upper outlet 3 and the lower outlet 4 are arranged in the vertical direction.

In the second embodiment, the first embodiment of the method,

referring to fig. 7 and 8, the structure and content of this embodiment are substantially the same as those of the first embodiment, except that in this embodiment, the fan assembly 21 includes only one large-diameter centrifugal fan. Specifically, on the basis of the arrangement mode of the turning motor 20 and the partition plate 7 in the first embodiment, the lower end of the partition plate 7 is also abutted against the upper end edge of the centrifugal fan, and specifically, the output shaft of the turning motor 20 drives the partition plate 7 to turn relative to the lower end thereof; alternatively, the lower end of the partition 7 may be pivotally connected to the upper end edge of the centrifugal fan by a pin structure, and the turning motor 20 drives the partition to turn. The above object is not limited thereto.

In the third embodiment, the first step is that,

referring to fig. 9, the structure and content of the present embodiment are substantially the same as those of the first embodiment, and the difference is that in the present embodiment, the fan assembly 21 includes two motors (not shown in the figure) horizontally and fixedly installed inside the lower cavity 9 of the main body 1 and arranged in a back direction, and the output shaft of each motor is respectively sleeved with a fan blade; the number of the air inlets 5 is two, the two air inlets 5 are respectively arranged on the front side plate and the rear side plate of the main body 1, obviously, the two air inlets 5 are communicated to the inside of the lower cavity 9, and the air inlet ends of the two fan blades are respectively opposite to the two air inlets 5.

In the fourth embodiment, the first step is that,

the embodiment also discloses an operation method of the multi-air-outlet cabinet type air conditioner indoor unit provided by the first embodiment or the second embodiment or the third embodiment, which comprises a heating working condition process and a refrigerating working condition process, wherein the heating working condition process comprises the following steps:

step a, a central controller in a main machine body 1 controls an air conditioner indoor unit to enter a heating working condition;

b, driving a motor to drive a sliding door 15 and a sliding block 16 to synchronously lift in different directions, moving the sliding door 15 upwards to open the lower air outlet 4, and moving the sliding block 16 downwards to cut off the connecting channel 22;

c, the overturning motor 20 drives the partition plate 7 to overturn to be abutted against the lower side surface of the evaporator 2;

d, the fan assembly 21 and the evaporator 2 operate, and air is fed from the air inlet 5 and hot air is simultaneously fed from the upper air outlet 3 and the lower air outlet 4;

the refrigeration working condition process comprises the following steps:

step one, a central controller in a main machine body 1 controls an indoor unit of an air conditioner to enter a refrigeration working condition;

step two, the driving mechanism 18 drives the sliding door 15 and the sliding block 16 to synchronously lift in different directions, the sliding door 15 moves downwards to close the lower air outlet 4, and the sliding block 16 moves upwards to the conduction connecting channel 22;

step three, the overturning motor 20 drives the partition plate 7 to overturn to a vertical state;

and step four, the fan assembly 21 and the evaporator 2 operate, air is fed from the air inlet 5, and cold air is sent out from the upper air outlet 3.

Although the present invention is disclosed above, the present invention is not limited thereto. Various changes and modifications may be effected therein by one of ordinary skill in the pertinent art without departing from the scope or spirit of the present invention, and the scope of the present invention is defined by the appended claims.

Claims (10)

1. A multi-air outlet cabinet type air conditioner indoor unit is characterized by comprising:

the air conditioner comprises a main machine body (1), wherein an upper air outlet (3) and a lower air outlet (4) are formed in a front side plate of the main machine body (1), an air inlet (5) is formed in the front side plate or a rear side plate of the main machine body (1), an evaporator (2) is installed inside the main machine body (1), the evaporator (2) divides the inside of the main machine body (1) into an upper cavity (8) and a lower cavity (9), the upper air outlet (3) and the lower air outlet (4) are respectively communicated with the upper cavity (8), the air inlet (5) is communicated with the lower cavity (9), and a connecting channel (22) for communicating the lower air outlet (4) and the upper air outlet (3) is formed in the upper cavity (8);

the fan assembly (21) is arranged in the lower cavity (9) and used for sending the air flow entering the lower cavity (9) from the air inlet (5) out of the upper air outlet (3) and the lower air outlet (4) through the evaporator (2);

and the air duct switching mechanism (6) is arranged in the upper cavity (8) and is used for sealing the lower air outlet (4) and conducting the connecting channel (22) or opening the lower air outlet (4) and sealing the connecting channel (22).

2. The indoor unit of a multi-outlet cabinet air-conditioner according to claim 1, wherein the air duct switching mechanism (6) comprises a sliding door (15), and the sliding door (15) is vertically arranged above the lower outlet (4) in a lifting manner for closing or opening the lower outlet (4).

3. The indoor unit of a multi-outlet cabinet air conditioner as claimed in claim 2, wherein the air duct switching mechanism (6) further comprises a slider (16), the slider (16) is vertically disposed in the upper chamber (8), and the lower portion of the slider (16) is matched with the shape of the connecting channel (22) to close or open the connecting channel (22).

4. The indoor unit of a multi-outlet cabinet air-conditioner according to claim 3, wherein the air duct switching mechanism (6) further comprises:

the transmission component (17) is movably arranged in the main machine body (1), is respectively connected with the sliding door (15) and the sliding block (16) in a transmission way, and is used for synchronously driving the sliding door (15) and the sliding block (16) to lift in different directions;

and the driving mechanism (18) is fixedly arranged in the main machine body (1), and the output end of the driving mechanism is in transmission connection with the transmission member (17) and is used for driving the transmission member (17) to move.

5. The indoor unit of a multi-outlet cabinet air-conditioner according to claim 3, wherein the air duct switching mechanism comprises two driving members fixedly mounted inside the main body (1), and output ends of the two driving members are respectively connected with the sliding door (15) and the sliding block (16) in a transmission manner.

6. The indoor unit of a multi-outlet cabinet air-conditioner according to claim 4, wherein the air duct switching mechanism (6) further comprises a bracket plate (14), and the bracket plate (14) is fixedly mounted on the inner side wall of the main body (1) or is a part of the front side casing of the main body (1).

7. The indoor unit of a multi-outlet cabinet air-conditioner of claim 6,

the sliding door (15) and the sliding block (16) can be vertically arranged on the support plate (14) in a lifting way, and the driving mechanism (18) is fixedly arranged on the support plate (14);

the transmission component (17) is at least one gear which can rotate circumferentially and is arranged on the support plate (14), and the sliding door (15) and the sliding block (16) are arranged in opposite directions, and one opposite side of the sliding door is provided with a spur rack structure which is meshed with the gear.

8. The indoor unit of the multi-air-outlet cabinet air conditioner as claimed in claim 1, wherein the evaporator (2) is arranged obliquely, a turnover motor (20) is horizontally and fixedly installed inside the lower cavity (9), a partition plate (7) is hinged to an output shaft of the turnover motor (20), the upper end of the partition plate (7) can be turned over towards the evaporator (2) to abut against the lower side surface of the evaporator (2) and divides the lower cavity (9) into a second air duct (11) and a first air duct (10) which are arranged in the front and at the back, and the lower end of the partition plate (7) abuts against the upper edge of the fan assembly (21).

9. The indoor unit of a multi-outlet cabinet air conditioner as claimed in any one of claims 1 to 8, wherein the fan assembly (21) comprises a first centrifugal fan (12) and a second centrifugal fan (13), the second centrifugal fan (13) is located at the front side direction of the position below the first centrifugal fan (12), the air inlet (5) is arranged on the rear side plate of the main body (1), and the air inlet ends of both centrifugal fans are opposite to the air inlet (5).

10. The indoor unit of a multi-air-outlet cabinet air-conditioner as claimed in any one of claims 1 to 8, wherein the fan assembly (21) comprises two motors horizontally fixed inside the lower cavity (9) and arranged in a back-to-back manner, and a fan blade is sleeved on an output shaft of each motor;

the number of the air inlets (5) is two, the two air inlets (5) are respectively arranged on the front side plate and the rear side plate of the main machine body (1), and the air inlet ends of the two fan blades are respectively opposite to the two air inlets (5).

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