CN219283474U - Global air conditioner - Google Patents

Abstract

The utility model discloses a global air conditioner, which comprises a shell and an air deflector assembly, wherein an air duct is arranged in the shell, an air outlet cavity and a first air outlet are arranged on the shell, the air outlet cavity is provided with an air outlet surface, and the first air outlet and the air outlet cavity are communicated with the air duct; the air guide plate assembly comprises a first air guide plate, a second air guide plate and a third air guide plate, the third air guide plate is arranged at the first air outlet, the first air guide plate is arranged in the air outlet cavity and forms an air guide channel with the air outlet surface at intervals, the second air outlet is formed at intervals between the periphery of the first air guide plate and the inner wall of the air outlet cavity, the second air outlet is provided with a first air outlet section communicated with the first air outlet, and the second air guide plate is arranged on the first air outlet section. The air deflector assembly provided by the utility model can rotate relative to the air outlet or the air outlet section, so that air flow is guided out along different air outlets and different directions, simultaneously, a multi-surface air outlet effect is realized, the air supply range is widened, and the use experience of users is improved.

Description

Global air conditioner

Technical Field

The utility model relates to the field of air conditioners, in particular to a global air conditioner.

Background

At present, an air conditioner is an indispensable part of people in modern life, and is used as equipment for adjusting the temperature and humidity of indoor air, and is visible everywhere in the home or in public places; along with the improvement of the living standard of people, the use demands of people on the air conditioner are diversified.

In the prior art, for a wall-mounted air conditioner indoor unit, the air outlets are all horizontal air outlets formed in the bottom of a front panel of the indoor unit, and the air deflector arranged at the air outlets is controlled to rotate relative to the air outlets, so that air flow is guided out along the direction of the air deflector, and air supply adjustment in the up-down direction is realized.

However, the air supply direction can only supply air along the front of the air outlet, and the air outlet angle is limited, so that the air supply range is smaller; and the air-out mode of single air outlet, it is slower to indoor temperature's regulation speed, can't satisfy the user demand of user's diversity.

Therefore, a global air conditioner is needed to overcome the above-mentioned drawbacks.

Disclosure of Invention

In order to overcome the defects of the prior art, the utility model aims to provide a global air conditioner which can realize multiple air outlets and a multidirectional air supply mode and simultaneously realize a multi-surface air outlet effect so as to solve the problem that the air outlet mode in the prior art is single, so that the user experience is poor.

The utility model adopts the following technical scheme:

a global air conditioner comprises,

the shell is internally provided with an air duct, the shell is provided with an air outlet cavity and a first air outlet, the first air outlet is communicated with the air duct, and the first air outlet is used for guiding air flow to be led out along a first direction; the air outlet cavity is provided with an air outlet surface;

the air guide plate assembly comprises a first air guide plate, a second air guide plate and a third air guide plate, wherein the first air guide plate is arranged in the air outlet cavity and forms an air guide channel with the air outlet surface at intervals, and the air guide channel is communicated with the air duct; the periphery of the first air deflector and the inner wall of the air outlet cavity are spaced to form a second air outlet, and the second air outlet is provided with a first air outlet section communicated with the first air outlet; the first air outlet section is used for guiding the air flow to be guided out along the second direction;

the second air deflector is rotatably arranged on the first air outlet section, and the third air deflector is rotatably arranged at the first air outlet.

Further, the bottom end of the first air deflector is spaced from the bottom end of the shell to form the first air outlet section, and the second air deflector is used for opening or closing the first air outlet section.

Further, the two sides of the second air deflector are respectively provided with a first rotating shaft, and the axis of the first rotating shaft and the central axis of the first air outlet section in the height direction are eccentrically arranged.

Further, the axis of the first rotating shaft is located above the central axis of the first air outlet section.

Further, the air conditioner comprises a first motor, wherein the first motor is connected with a first rotating shaft so as to drive the second air deflector to rotate.

Further, the bottom of the second air deflector and the bottom of the shell are separated to form a first air outlet, and the third air deflector is used for opening or closing the first air outlet.

Further, the wind turbine comprises a second motor, second rotating shafts are respectively arranged on two sides of the third wind deflector, and the second motor is connected with the second rotating shafts so as to drive the third wind deflector to rotate.

Further, the second air outlet further comprises a second air outlet section, a third air outlet section and a fourth air outlet section, and the first air outlet section, the second air outlet section, the third air outlet section and the fourth air outlet section are connected end to end in sequence.

Further, the air outlet cavity further comprises an outer frame, the air outlet surface is arranged in the outer frame, and the first air deflector is arranged on the outer frame.

Further, the top end of the shell is provided with an air inlet which is communicated with the air duct, and a fan is arranged in the air duct.

Compared with the prior art, the utility model has the beneficial effects that: the air conditioner is provided with a plurality of air outlets, the air deflector assembly comprises a plurality of air deflectors, the periphery of the first air deflector and the inner wall of the air outlet cavity form an annular air outlet at intervals, and the second air deflector and the third air deflector are rotatably arranged at the air outlet of the air conditioner, so that the air supply effect of a plurality of air outlet surfaces and a plurality of air outlets is realized, and the diversification of the use demands of users is met.

Drawings

FIG. 1 is a schematic diagram of a front view of an embodiment of the present utility model;

FIG. 2 is a schematic cross-sectional view of A-A of FIG. 1;

FIG. 3 is a schematic diagram illustrating a disassembled structure according to an embodiment of the present utility model;

FIG. 4 is a schematic cross-sectional view of an air outlet chamber according to an embodiment of the present utility model;

FIG. 5 is a schematic view of a structure without air deflection assemblies in accordance with embodiments of the present utility model;

FIG. 6 is a schematic view of a structure without a second air deflector according to an embodiment of the present utility model;

FIG. 7 is a schematic view of a structure without a third air deflector according to an embodiment of the present utility model;

FIG. 8 is a schematic diagram of a horizontal air-out state according to an embodiment of the present utility model;

fig. 9 is a schematic structural diagram of the embodiment of the present utility model in a tilted air-out state.

In the figure: 1. a housing; 101. a first air outlet section; 102. a first air outlet; 103. a second air outlet; 104. the second air outlet section; 105. a middle frame; 106. an air inlet; 107. a bottom plate; 108. a blower; 109. a third air outlet section; 110. a fourth air outlet section; 2. an air deflector assembly; 201. a first air deflector; 202. a second air deflector; 203. a third air deflector; 3. an air outlet cavity; 301. an air outlet surface; 302. an air guide channel; 303. and an outer frame.

Detailed Description

The utility model will be further described with reference to the accompanying drawings and detailed description below:

in the description of the present utility model, it should be noted that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, merely to facilitate description of the present utility model and simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

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 utility model belongs. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model.

Referring to fig. 1 and 3, the present embodiment discloses a global air conditioner, which includes a casing 1, wherein an air duct is provided in the casing 1, and the air duct is used for sending out air flow in the casing 1 after temperature or humidity adjustment treatment to the outside of the casing 1; the shell 1 is provided with an air outlet cavity 3 and a first air outlet 102, the air outlet cavity 3 is provided with an air outlet surface 301, the first air outlet 102 is communicated with the air duct, and the first air outlet 102 can send out a part of air flow sent by the air duct along a first direction.

Referring to fig. 2, the air conditioner further includes an air guide plate assembly 2, specifically including a first air guide plate 201, a second air guide plate 202, and a third air guide plate 203, where the first air guide plate 201 is installed on the air outlet cavity 3 and forms an air guide channel 302 with an air outlet surface 301 at intervals, the air guide channel 302 is communicated with the air channel, and a part of air flow is sent from the air channel to enter the air guide channel 302; the outer periphery of the first air deflector 201 and the inner wall of the air outlet cavity 3 form a second air outlet 103 at intervals, and air flow entering the air guide channel 302 is sent out along the second air outlet 103; the second air outlet 103 has a first air outlet section 101 extending through the first air outlet 102, and the first air outlet section 101 is configured to guide a portion of the airflow to be directed in the second direction.

Referring to fig. 6 and 7, the second air deflector 202 is rotatably installed on the first air outlet section 101, and the second air deflector 202 moves relative to the first air outlet section 101, so as to open or close the first air outlet section 101; similarly, the third air deflector 203 is rotatably installed at the first air outlet 102 and moves relative to the first air outlet 102, thereby opening or closing the first air outlet 102.

Based on the structure, the user can set the air conditioner into a plurality of modes such as refrigeration, heating or ventilation through the air conditioner remote controller, after the air conditioner is started, the second air deflector 202 and the third air deflector 203 rotate to open the air outlet or the air outlet section at the corresponding positions, the air conditioner guides indoor air into the shell 1, after temperature and humidity adjustment treatment, the air channel sends the treated air flow to the air outlet or the air guide channel 302 communicated with the air channel, and the air flow can be sent out from different air outlets;

in this way, when the air conditioner is started, the air flow after temperature or humidity adjustment treatment in the casing 1 can be sent out from the second air outlet 103 and the first air outlet 102 around the first air deflector 201, so as to realize multi-outlet and multi-directional air supply.

In addition, the user can control the second air deflector 202 and the third air deflector 203 to rotate through the remote controller, so that the position of the second air deflector 202 relative to the first air outlet section 101 and the position of the third air deflector 203 relative to the first air outlet 102 can be adjusted, and the air flow can be guided to be guided out along the direction of the air deflector, so that the air flow can be sent out along different angles in the same direction.

After the air conditioner is turned off, the air inlet and the air outlet are stopped in the shell 1, the second air deflector 202 and the third air deflector 203 rotate to return to the original positions, and the first air outlet section 101 and the first air outlet 102 are respectively closed.

It should be noted that, because the second air deflector 202 is installed on the first air outlet section 101, the second air deflector 202 can also rotate up and down relative to the first air outlet section 101 while guiding the air flow to be guided out along the second direction, so as to widen the air supply range when the air flow is guided out along the second direction, so that the first air outlet section 101 can supply air horizontally and also supply air up and down; similarly, the third air deflector 203 is mounted at the first air outlet 102, and when guiding the air flow to be guided out along the first direction, the third air deflector 203 rotates relative to the first air outlet 102, so that the air supply range of the air flow guided out along the first direction can be widened, and the first air outlet 102 can supply air vertically and also supply air front and back.

Thus, the air conditioner can realize multi-direction and multi-angle air supply effect while realizing multi-outlet air supply.

Wherein the first direction refers to a vertical direction, and the second direction refers to a horizontal direction.

Normally, when the movable air deflector is not installed in the air conditioner, the air flow subjected to refrigeration or heating treatment is directly sent out from the air outlet, the air outlet faces the lower side of the air conditioner, the air outlet is in a vertical direction, and the air outlet faces the front side of the air conditioner, and the air outlet is in a horizontal direction.

When the movable air deflector is additionally arranged on the air conditioner, the air deflector moves relative to the air outlet, an included angle is formed between the air deflector and the air outlet, and when the included angles are different, the angle of air flow guided out along the direction of the air deflector is also different, so that the angle of the air flow in the air outlet direction is widened, and a larger air supply range is obtained.

Further, the bottom end of the first air deflector 201 and the bottom end of the housing 1 are spaced to form the first air outlet section 101, and the second air outlet 103 is disposed around the first air deflector 201, that is, the portion of the second air outlet 103 disposed at the lower end of the first air deflector 201 overlaps with the portion of the first air outlet section 101, and the second air deflector 202 is rotatably disposed at the first air outlet section 101.

On the basis of the structure, as the first air outlet section 101 faces to the front of the shell 1, when the second air deflector 202 is not installed, the air duct sends out a part of air flow along the horizontal direction; after the second air deflection 202 is installed, the air flow is directed in the direction of the second air deflection 202. Since the second air deflector 202 can rotate relative to the first air outlet section 101, the air flow can be exhausted in the up-down direction and the horizontal direction at the first air outlet section 101.

Specifically, referring to fig. 2 and 8, the first air outlet section 101 has the following air outlet modes:

and (3) horizontally discharging air: when the second air deflector 202 rotates 90 ° clockwise or anticlockwise relative to the first air outlet section 101 in the initial position state, the second air deflector 202 rotates and flattens, so that the horizontal air outlet of the first air outlet section 101 can be realized, at this time, the upper and lower sides of the second air deflector 202 respectively form a horizontal air outlet, and the air flow is led out along the two horizontal air outlets.

Downward air outlet: when the second air deflector 202 is in the initial position state, the clockwise rotation angle of the second air deflector 202 relative to the first air outlet section 101 is not more than 90 degrees, or the anticlockwise rotation angle is more than 90 degrees, one end of the second air deflector 202, which is close to the first air deflector 201, can be turned into the housing 1, and the other end is turned out of the housing 1; at this time, an air outlet is formed at the lower end of the second air deflector 202, and the air flow is guided out from the air outlet along the direction of the second air deflector 202, so as to realize downward air outlet.

Upward air outlet: when the second air deflector 202 is in the initial position state, the clockwise rotation angle of the second air deflector 202 relative to the first air outlet section 101 exceeds 90 degrees, or the anticlockwise rotation angle of the second air deflector 202 does not exceed 90 degrees, one end of the second air deflector 202, which is close to the first air deflector 201, can be rotated out of the housing 1, and the other end of the second air deflector is rotated into the housing 1; at this time, an air outlet is formed at the upper end of the second air deflector 202, and the air flow is guided out from the air outlet along the direction of the second air deflector 202, so as to realize upward air outlet.

In the three air guiding states of the first air outlet section 101, since the air guiding channel 302 is always kept through the air duct, a part of air flow enters the air guiding channel 302 from the air duct and is sent out from the second air outlet 103.

Further, in order to realize the rotation of the second air deflector 202 relative to the first air outlet section 101, first rotating shafts may be respectively disposed at two sides of the second air deflector 202, and a central axis is disposed in the height direction of the first air outlet section 101, where the axis of the first rotating shaft is eccentrically disposed with the central axis of the first air outlet section 101.

On the basis of the structure, because the axis of the first rotating shaft and the central axis of the first air outlet section 101 are eccentrically arranged, when the second air deflector 202 rotates 90 degrees clockwise or anticlockwise from an initial position state and rotates to a horizontal position, the second air deflector 202 separates the first air outlet section 101 into an upper air outlet and a lower air outlet with different widths;

when the axis of the first rotating shaft is located above the central axis of the first air outlet section 101, the width of the upper air outlet is smaller than that of the lower air outlet; conversely, when the axis of the first rotating shaft is located below the central axis of the first air outlet section 101, the width of the upper air outlet is greater than that of the lower air outlet.

It should be noted that, the upper air outlet is located between the first air deflector 201 and the second air deflector 202, and therefore, the upper air outlet is an overlapping portion between the second air deflector 202 and the first air outlet section 101.

Further, the axis of the first rotating shaft is located above the central axis of the first air outlet section 101, so that the second air deflector 202 moves eccentrically upwards when rotating.

Based on this structure, referring to fig. 2 and 8, since the axis of the first rotating shaft is located above the central axis of the first air outlet section 101, the maximum angle of counterclockwise rotation of the second air deflector 202 is 180 °, when the second air deflector 202 rotates clockwise, one end of the second air deflector 202 near the first air deflector 201 is blocked by the first air deflector 201, and the second air deflector 202 can rotate clockwise until touching the first air deflector 201.

At this time, the air conditioner has four air outlet modes, and the specific operation is as follows:

four-side air outlet: when the second air deflector 202 rotates 180 ° anticlockwise from the initial position state, the second air deflector 202 is in the vertical position, and since the axis of the first rotating shaft is eccentrically arranged above the central axis of the first air outlet section 101, the lower end of the second air deflector 202 generates a step difference, thereby forming an air outlet, and a part of air flow is sent out from the air outlet; meanwhile, after part of air flow is sent into the air guide channel 302 by the air channel, the air is sent out from the left side, the upper side and the right side of the first air guide plate 201, and at the moment, the air conditioner realizes four-side air outlet;

in addition, the second air deflector 202 may be rotated clockwise from the initial position state until one end close to the first air deflector 201 contacts the first air deflector 201, at this time, an air opening is formed on one side of the second air deflector 202 away from the first air deflector 201, and a part of air flow is sent out from the air opening; meanwhile, after a part of air flow is sent into the air guide channel 302 by the air duct, the air is sent out from the left side, the upper side and the right side of the first air guide plate 201, and at this time, the air conditioner realizes four-side air outlet.

And (3) horizontally discharging air: when the second air deflector 202 rotates 90 degrees clockwise or anticlockwise from the initial position state, the second air deflector 202 is positioned at the horizontal position, and the second air deflector 202 divides the first air outlet section 101 into an upper air outlet and a lower air outlet with different widths; at this time, the air flow is sent out from the two air outlets, and the first air outlet section 101 also forms a horizontal air outlet.

Downward air outlet: when the second air deflector 202 is in the initial position state, the clockwise rotation angle of the second air deflector 202 relative to the first air outlet section 101 is not more than 90 degrees, or the anticlockwise rotation angle is more than 90 degrees, one end of the second air deflector 202, which is close to the first air deflector 201, can be turned into the housing 1, and the other end is turned out of the housing 1; at this time, an air outlet is formed at the lower end of the second air deflector 202, and the air flow is guided out from the air outlet along the direction of the second air deflector 202, so as to realize downward air outlet.

Upward air outlet: when the second air deflector 202 is in the initial position state, the clockwise rotation angle of the second air deflector 202 relative to the first air outlet section 101 is larger than 90 degrees until the second air deflector contacts the first air deflector 201, or the anticlockwise rotation angle is not larger than 90 degrees, one end, close to the first air deflector 201, of the second air deflector 202 can be rotated out of the shell 1, and the other end of the second air deflector 202 can be rotated into the shell 1; at this time, an air outlet is formed at the upper end of the second air deflector 202, and the air flow is guided out from the air outlet along the direction of the second air deflector 202, so as to realize upward air outlet.

Further, the air conditioner of the embodiment further includes a first motor, where the first motor is connected to the first rotating shaft of the second air deflector 202, so as to drive the second air deflector 202 to rotate relative to the first air outlet section 101, and control the rotation angle of the second air deflector 202.

Based on the structure, a user selects different air outlet modes through an air conditioner remote controller, and the air conditioner controls the first motor to rotate, so that the second air deflector 202 is driven to rotate; when the user selects the horizontal outlet mode, the operation of the air conditioner is as follows:

when the axis of the first rotating shaft is coincident with the central axis of the second air deflector 202, the first motor drives the second air deflector 202 to rotate 90 degrees clockwise or 90 degrees anticlockwise, so that the second air deflector 202 is flattened to realize horizontal air outlet, at the moment, horizontal air outlets are formed between the first air deflector 201 and the second air deflector 202, and between the second air deflector 202 and the third air deflector 203, so that the first air outlet section 101 can realize horizontal air outlet from the two air outlets.

When the axis of the first rotating shaft is eccentrically disposed with the center axis of the second air guide plate 202, the same is true for the case where the axis coincides with the center axis, and will not be described here;

the operation mode for starting the four-side air outlet mode is as follows: the first motor drives the second air deflector 202 to rotate 180 degrees anticlockwise, so that after the second air deflector 202 rotates, the lower end forms a step, an air outlet is formed between the second air deflector 202 and the third air deflector 203, and four-side air outlet is realized at the moment; the second air deflector 202 may be driven by a motor to rotate clockwise until the second air deflector 202 contacts with the first air deflector 201, and at this time, an air gap is formed between the second air deflector 202 and the third air deflector 203, so that four-side air outlet may be realized.

In addition, the first motor can also drive the second air deflector 202 to rotate clockwise or anticlockwise by other angles, so that the second air deflector 202 forms one or two air outlets at the first air outlet section 101 to realize air supply of the first air outlet section 101 in other angles or directions.

Further, when the second air deflector 202 is in the initial position state, the bottom end of the second air deflector 202 and the bottom end of the housing 1 are spaced to form the first air outlet 102, and the third air deflector 203 is rotatably disposed at the first air outlet 102 and is used for opening or closing the first air outlet 102.

On the basis of the structure, as the first air outlet 102 is positioned at the bottom end of the shell 1, the first air outlet 102 faces to the lower side of the shell 1, and when the third air deflector 203 is not installed, the air duct sends out a part of air flow along the vertical downward direction; after the third air guide plate 203 is installed, the air flow is guided out along the direction of the third air guide plate 203.

Since the third air guide plate 203 can rotate relative to the first air outlet 102, the air flow can realize forward, backward and vertical downward air outlet at the first air outlet 102.

Specifically, the three air outlet modes of the first air outlet 102 are as follows:

vertical air outlet: referring to fig. 2, when the third air deflector 203 is in the initial position state and rotates 90 ° counterclockwise relative to the first air outlet 102, the third air deflector 203 rotates from the horizontal state to the vertical state, so as to realize the vertical air outlet of the first air outlet 102; in this state, since the second air guide plate 202 is also in the initial position state, one end of the third air guide plate 203 is blocked by the second air guide plate 202 and cannot perform the clockwise rotational movement.

Referring to fig. 8, the first motor may be further driven to rotate the second air deflector 202 counterclockwise by 180 °, and due to the eccentric driving arrangement of the second air deflector 202, the lower end of the second air deflector 202 forms a step, and the second air deflector 202 moves upward a distance relative to the third air deflector 203, so that a space is formed between the second air deflector 202 and the third air deflector 203.

Because of the existence of the interval, one end of the third air deflector 203 is not blocked by the second air deflector 202, so that the third air deflector 203 can rotate clockwise relative to the first air outlet 102, the third air deflector 203 rotates 90 degrees clockwise, and the third air deflector 203 rotates from a horizontal state to a vertical state, thereby realizing vertical air outlet.

And (3) forward air outlet: the second air deflector 202 is in an initial position state, the third air deflector 203 is anticlockwise smaller than 90 degrees, one end of the third air deflector 203, which is close to the second air deflector 202, is rotated out of the shell 1, and the other end of the third air deflector 203 is rotated into the shell 1; at this time, the air flow is guided out along the direction of the third air deflector 203, so as to realize forward air outlet;

or, the second air deflector 202 rotates 180 degrees anticlockwise, the third air deflector 203 rotates more than 90 degrees clockwise, the left end of the third air deflector 203 rotates out of the shell 1, and the right end rotates into the shell 1; at this time, the air flow is guided out along the direction of the third air guiding plate 203, so as to realize forward air outlet.

Front and back air outlet: the second air deflector 202 is in an initial position state, the third air deflector 203 is anticlockwise larger than 90 degrees, one end of the third air deflector 203, which is close to the second air deflector 202, is turned into the shell 1, and the other end is turned out of the shell 1; at this time, the air flow is guided out along the direction of the third air deflector 203, so as to realize backward air outlet;

or, the second air deflector 202 rotates 180 degrees anticlockwise, the third air deflector 203 rotates less than 90 degrees clockwise, the left end of the third air deflector 203 rotates into the shell 1, and the right end rotates out of the shell 1; at this time, the air flow is guided out along the direction of the third air guiding plate 203, so that the air is discharged backward.

Further, the air conditioner of the embodiment further includes a second motor, and second rotating shafts are respectively disposed on two sides of the third air deflector 203, and the second motor is connected with the second rotating shafts to drive the second rotating shafts to rotate, so as to drive the third air deflector 203 to rotate relative to the first air outlet 102.

Based on the structure, a user selects different air outlet modes through an air conditioner remote controller, and the air conditioner controls the second motor to rotate, so that the third air deflector 203 is driven to rotate; when a user selects a vertical air outlet mode, the second motor drives the third air deflector 203 to rotate 90 degrees anticlockwise, or the first motor drives the second air deflector 202 to rotate 180 degrees anticlockwise, and then the second motor drives the third air deflector 203 to rotate 90 degrees clockwise, so that the third air deflector 203 rotates from a horizontal position to a vertical position, and vertical air outlet is realized;

when the user selects front and back air outlets, the second motor drives the third air deflector 203 to rotate anticlockwise by less than 90, so that the front air outlets are realized; the second motor drives the third air deflector 203 to anticlockwise be larger than 90 degrees, so that backward air outlet is realized.

Or the first motor drives the second air deflector 202 to rotate 180 degrees anticlockwise, and then the second motor drives the third air deflector 203 to rotate more than 90 degrees clockwise, so that forward air outlet is realized; the second motor drives the third air deflector 203 to rotate clockwise by less than 90 degrees, so that backward air outlet is realized.

In addition, through the rotation of the second air deflector 202 and the third air deflector 203 together, the air conditioner of the embodiment can realize inclined air outlet, and the specific operation is as follows: the first motor rotates the second air guide plate 202 clockwise by 90 degrees or anticlockwise by 90 degrees, so that the second air guide plate 202 is in a horizontal position like the third air guide plate 203, the first motor drives the second air guide plate 202 and the second motor drives the third air guide plate 203, and the second air guide plate 202 and the third air guide plate 203 synchronously rotate by the same angle, so that an inclined air outlet mode can be realized.

In the air outlet mode, air outlets are formed between the first air deflector 201 and the second air deflector 202, between the second air deflector 202 and the third air deflector 203 and between the third air deflector 203 and the bottom plate 107, and air flow is led out from the three air outlets along the directions of the second air deflector 202 and the third air deflector 203, so that downward air outlet and forward air outlet of the air flow are realized; or the air flow is discharged upwards and is discharged backwards at the same time.

Further, the second air outlet 103 further includes a second air outlet section 104, a third air outlet section 109 and a fourth air outlet section 110, where the second air outlet section 104, the third air outlet section 109 and the fourth air outlet section 110 are respectively located at the left side, the upper side and the right side of the first air deflector 201, and the first air outlet section 101, the second air outlet section 104, the third air outlet section 109 and the fourth air outlet section 110 are sequentially connected end to end, and are commonly arranged around the first air deflector 201 and form the second air outlet 103.

Based on the structure, the second air outlet section 104, the third air outlet section 109 and the fourth air outlet section 110 are communicated with the air guide channel 302, and the first air outlet section 101 is communicated with the air duct; when the second air deflector 202 rotates 180 ° anticlockwise, the second air deflector 202 forms an air port at the lower end of the first air outlet section 101, and after part of the airflow enters the air guide channel 302, the airflow is sent out from the air port, the second air outlet section 104, the third air outlet section 109 and the fourth air outlet section 110, so that the air conditioner realizes a four-side air outlet mode.

When the first air outlet section 101 is air-exhausted upwards, a part of air flow enters the air guide channel 302 and is sent out from the second air outlet section 104, the third air outlet section 109 and the fourth air outlet section 110, and at this time, the air quantity of the second air outlet section 104, the third air outlet section 109 and the fourth air outlet section 110 is increased.

When the first air outlet section 101 is down-flowing, because the end of the second air deflector 202, which is close to the first air deflector 201, is turned into the housing 1 and is located at the lower end of the air outlet surface 301, the second air deflector 202 blocks the air channel from blowing into the air guide channel 302, so that the air quantity entering the air guide channel 302 is reduced, and at this time, an air outlet is formed between the second air deflector 202 and the third air deflector 203, that is, the non-overlapping portion of the first air outlet section 101 and the second air outlet 103 is opened.

Referring to fig. 3, further, the air outlet cavity 3 further includes an outer frame 303, the outer frame 303 has a certain thickness, the outer frame 303 is used for being installed and connected with the housing 1, the air outlet surface 301 is disposed in the outer frame 303, the outer contour of the first air deflector 201 is smaller than the outer contour of the outer frame 303, and the first air deflector 201 is disposed on the outer frame 303 and is spaced from the air outlet surface 301.

Based on this structure, the housing 1 includes the middle frame 105, the outer frame 303 has a first installation surface facing the housing 1 and a second installation surface facing the first air deflector 201, and when assembling, referring to fig. 4, the outer frame 303 is installed on the middle frame 105 through the first installation surface, then the first air deflector 201 is installed on the second installation surface of the outer frame 303, and the first air deflector 201 and the air outlet surface 301 in the outer frame 303 are arranged at intervals to form the air guiding channel 302, so that the first air deflector 201, the outer frame 303 and the air outlet surface 301 together form the air outlet cavity 3.

When the air conditioner is in use, air flow in the air duct enters the air guide channel 302 from the air outlet area at the lower end of the air outlet face 301, and is guided out from the interval between the periphery of the first air deflector 201 and the outer frame 303.

In this way, the air flow is sent out from a plurality of air outlet sections on the periphery of the first air deflector 201 after being scattered in the guiding-out process, so that the air flow is more uniform and is easier to mix with the air in the indoor environment; and the multi-face air outlet can accelerate the response speed of temperature regulation and improve the use experience of a user.

It should be noted that, the mounting manner of the outer frame 303 and the middle frame 105 may be detachable, specifically, a circle of positioning grooves may be formed around the first mounting surface of the outer frame 303, a circle of positioning convex edges may be formed around the middle frame 105, and the positioning grooves and the positioning convex edges may be in snap connection, so that the outer frame 303 may be mounted on the middle frame 105;

on the basis of the structure, the positioning convex edge can also be annularly arranged on the periphery of the first mounting surface, the positioning groove is annularly arranged on the periphery of the middle frame 105, and the outer frame 303 can be mounted on the middle frame 105.

Further, a ring of iron pieces may be looped around the first mounting surface of the outer frame 303, and correspondingly, a ring of magnets may be looped around the middle frame 105, and the magnets and the patches may attract each other when they approach each other, so that the outer frame 303 may be mounted on the middle frame 105.

The detachable mounting modes are convenient to detach and mount, and the parts are convenient to clean or replace.

In addition, it should be noted that, since the outer contour of the first air deflector 201 is smaller than the outer contour of the outer frame 303, the mounting manner of the first air deflector 201 covering the outer frame 303 may be: one or more mounting holes are formed in the air outlet face 301, one or more protruding shafts are formed in the back face of the first air deflector 201, the protruding shafts are in one-to-one corresponding insertion connection with the mounting holes, and therefore the first air deflector 201 can be covered on the air outlet face 301 and arranged at intervals with the air outlet face 301.

Further, referring to fig. 2 and 3, an air inlet 106 is provided at the top end of the housing 1, the air inlet 106 is used for introducing air flow, the air inlet 106 is communicated with an air duct, a fan 108 is provided in the air duct, and the fan 108 is used for realizing heat exchange.

On the basis of the structure, air in the indoor environment enters the air conditioner shell 1 through the air inlet 106, and after heat exchange is carried out at the fan 108, the air is guided out into the indoor environment through the air outlet or the air outlet section, so that primary indoor air circulation is realized.

In addition, a filter assembly can be additionally arranged on the outer side or the inner side of the air inlet 106, dust particles and odor molecules in the air can be filtered and absorbed through the filter assembly, and the filtered air can be introduced into the shell 1 and released into the indoor environment after the temperature or humidity adjustment of the indoor unit of the air conditioner. Thus, the user can obtain fresh and comfortable air, and the use experience of the user is improved.

It will be apparent to those skilled in the art from this disclosure that various other changes and modifications can be made which are within the scope of the utility model as defined in the appended claims.

Claims (10)

1. A global air conditioner is characterized by comprising,

the air conditioner comprises a shell, wherein an air duct is arranged in the shell, an air outlet cavity and a first air outlet are arranged on the shell, the first air outlet is communicated with the air duct, and the first air outlet is used for guiding air flow to be led out along a first direction; the air outlet cavity is provided with an air outlet surface;

the air guide plate assembly comprises a first air guide plate, a second air guide plate and a third air guide plate, wherein the first air guide plate is arranged in the air outlet cavity and forms an air guide channel with an air outlet surface at intervals, and the air guide channel is communicated with the air channel; the periphery of the first air deflector and the inner wall of the air outlet cavity are separated to form a second air outlet, and the second air outlet is provided with a first air outlet section communicated with the first air outlet; the first air outlet section is used for guiding the air flow to be guided out along the second direction;

the second air deflector is rotatably arranged on the first air outlet section; the third air deflector is rotatably arranged at the first air outlet.

2. The global air conditioner of claim 1, wherein the first air outlet section is formed by a bottom end of the first air deflector and a bottom end of the housing at intervals, and the second air deflector is used for opening or closing the first air outlet section.

3. The universal air conditioner according to claim 2, wherein first rotating shafts are respectively arranged on two sides of the second air deflector, and the axis of the first rotating shafts is eccentrically arranged with the central axis in the height direction of the first air outlet section.

4. A global air conditioner as defined in claim 3, wherein an axis of said first rotating shaft is located above a central axis of said first air outlet section.

5. A global air conditioner as defined in claim 3, including a first motor coupled to said first axis of rotation for driving said second air deflector in rotation.

6. The global air conditioner of claim 2, wherein the bottom end of the second air deflector is spaced from the bottom end of the housing to form the first air outlet, and the third air deflector is used to open or close the first air outlet.

7. The global air conditioner of claim 6, comprising a second motor, wherein two sides of the third air deflector are respectively provided with a second rotating shaft, and the second motor is connected with the second rotating shaft to drive the third air deflector to rotate.

8. The global air conditioner of claim 1, wherein the second air outlet further comprises a second air outlet section, a third air outlet section, and a fourth air outlet section, wherein the first air outlet section, the second air outlet section, the third air outlet section, and the fourth air outlet section are connected end to end in sequence.

9. The global air conditioner of claim 1, wherein the air outlet chamber further comprises an outer frame, the air outlet surface is disposed in the outer frame, and the first air deflector is disposed on the outer frame.

10. The global air conditioner according to claim 1, wherein an air inlet is formed in the top end of the housing, the air inlet is communicated with the air duct, and a fan is arranged in the air duct.

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