CN215260452U - Air guide device and air conditioner with same - Google Patents

Abstract

The utility model discloses an air ducting and air conditioner that has it, the ascending both sides of air ducting's width direction have first vent and second vent respectively, inject the airflow channel in the first vent of intercommunication and second vent in the air ducting, cross the central point on air ducting's the length direction and put and make perpendicular to length direction's perpendicular to face that hangs down, airflow channel constructs: when the airflow enters the airflow channel from the first ventilation opening and flows out of the airflow channel from the second ventilation opening, the airflow is diverged and sent out towards the direction away from the vertical plane, and when the airflow enters the airflow channel from the second ventilation opening and flows out of the airflow channel from the first ventilation opening, the airflow is converged and sent out towards the direction close to the vertical plane. According to the utility model discloses an air ducting can present and disperse and assemble the wind-guiding effect of two kinds of differences.

Description

Air guide device and air conditioner with same

Technical Field

The utility model belongs to the technical field of the ventilation technique and specifically relates to an air ducting and air conditioner that has it.

Background

In the air conditioner in the related art, the air deflector is arranged at the air outlet and is in a simple plate form, and the air supply direction is adjusted by rotating the air deflector. However, the air guide plate has a single air supply effect and cannot meet different actual requirements.

SUMMERY OF THE UTILITY MODEL

The utility model discloses aim at solving one of the technical problem that exists among the prior art at least. Therefore, the utility model provides an air ducting, air ducting can present and disperse and assemble the wind-guiding effect of two kinds of differences.

The utility model discloses still provide an air conditioner with above-mentioned air ducting.

According to the utility model discloses air ducting, the ascending both sides in air ducting's the width direction have first vent and second vent respectively, inject the intercommunication in the air ducting first vent with the airflow channel in second vent crosses the perpendicular to is made to the central point on air ducting's the length direction's the perpendicular plane, airflow channel constructs into: when the airflow enters the airflow channel from the first ventilation opening and flows out of the airflow channel from the second ventilation opening, the airflow is dispersed and sent out towards the direction away from the vertical plane, and when the airflow enters the airflow channel from the second ventilation opening and flows out of the airflow channel from the first ventilation opening, the airflow is converged and sent out towards the direction close to the vertical plane.

According to the utility model discloses air ducting, under the wind-guiding state of difference, can present and disperse and assemble the wind-guiding effect of two kinds of differences to satisfy different in-service use demands. For example, when carrying out the water conservancy diversion to cold air, can make cold air flow through airflow channel along the direction from first vent to second vent, do benefit to cold air flow and can follow air ducting's length direction through air ducting and disperse to both sides and send out, avoid cold wind gathering direct-blowing user, cause the user to be uncomfortable, improve comfortable experience. For example, when hot air is guided, cold air can flow through the airflow channel along the direction from the second vent to the first vent, hot air can be sent out along the length direction of the air guide device to the center through the air guide device, the air supply distance can be prolonged, the hot air can reach the ground directly, the foot warming effect is achieved, and comfortable experience is improved.

In some embodiments, the air guiding device defines a plurality of air flow channels therein, the air flow channels being spaced apart along the length of the air guiding device.

In some embodiments, in the length direction of the air guiding device, the farther from the central vertical plane, the larger the included angle between the air supply direction of the air flow channel and the central vertical plane is.

In some embodiments, a plurality of the airflow channels are symmetrically arranged about the mid-vertical axis of the air guiding device.

In some embodiments, the area of the first vent is less than the area of the second vent.

In some embodiments, the flow area of the airflow passage becomes gradually larger in a direction from the first ventilation opening to the second ventilation opening.

In some embodiments, the size of the airflow channel in the thickness direction of the air guiding device gradually increases along the direction from the first ventilation opening to the second ventilation opening, and/or the size of the airflow channel in the length direction of the air guiding device gradually increases.

In some embodiments, the air guiding device comprises: the first air deflector and the second air deflector extend along the length direction of the air guide device, and the first air deflector and the second air deflector are arranged at intervals along the thickness direction of the air guide device; the air guide device comprises at least two third air deflectors which are arranged along the length direction of the air guide device at intervals, an air flow channel is defined between each two adjacent third air deflectors and the first air guide device and the second air guide device, and at least one of the two third air deflectors on two sides of any air flow channel is inclined to the vertical plane.

In some embodiments, the distance between the first air deflector and the second air deflector in the thickness direction of the air guiding device gradually increases along the direction from the first air vent to the second air vent.

In some embodiments, at least two third air deflectors are respectively arranged on two sides of the vertical plane, wherein an included angle between each third air deflector which is farther away from the vertical plane and the vertical plane is larger in all the third air deflectors on the same side of the vertical plane.

In some embodiments, the airflow channel includes a lateral channel located on one side of the vertical plane, and an included angle between the third air deflector farther from the vertical plane and the vertical plane is greater than an included angle between the third air deflector closer to the vertical plane and the vertical plane, among the two third air deflectors on two sides of at least one lateral channel.

In some embodiments, the airflow channel comprises a central channel which crosses the vertical plane to be positioned at two sides of the vertical plane, and the included angles between the two third wind deflectors at two sides of the central channel and the vertical plane are the same and are symmetrically arranged.

In some embodiments, the wind guiding device has a pivot portion at each of two ends in the length direction.

In some embodiments, the third air guiding plate is integrated with one of the first air guiding plate and the second air guiding plate, and is in insertion fit with the other of the first air guiding plate and the second air guiding plate.

According to the utility model discloses an air conditioner of second aspect embodiment, including the air conditioner body and according to the utility model discloses the air ducting of first aspect embodiment, the air conditioner body includes the air outlet, air ducting movably locates the air outlet to switch over first wind-guiding state and second wind-guiding state, under the first wind-guiding state, first vent is located the upstream of second vent, and the air current that reaches air outlet department is suitable for getting into the air current passageway from the first vent, and flow out the air current passageway from the second vent; and in the second air guide state, the second air vent is positioned at the upstream of the first air vent, and the air flow reaching the air outlet is suitable for entering the air flow channel from the second air vent and flowing out of the air flow channel from the first air vent.

According to the utility model discloses air conditioner, through setting up the air ducting of above-mentioned first aspect embodiment, utilize air ducting under the air guiding state of difference, can present and disperse and assemble the wind-guiding effect of two kinds of differences to satisfy different in-service use demands. For example, when carrying out the water conservancy diversion to cold air, can make cold air flow through airflow channel along the direction from first vent to second vent, do benefit to cold air flow and can follow air ducting's length direction through air ducting and disperse to both sides and send out, avoid cold wind gathering direct-blowing user, cause the user to be uncomfortable, improve comfortable experience. For example, when hot air is guided, cold air can flow through the airflow channel along the direction from the second vent to the first vent, hot air can be sent out along the length direction of the air guide device to the center through the air guide device, the air supply distance can be prolonged, the hot air can reach the ground directly, the foot warming effect is achieved, and comfortable experience is improved.

In some embodiments, the air conditioner comprises a bathroom air conditioner, an air conditioner body of the bathroom air conditioner comprises an air outlet frame, the air outlet frame is provided with the air outlet, and the air guiding device is rotatably installed on the air outlet frame.

Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

Drawings

Fig. 1 is a perspective view of an air guiding device according to a first embodiment of the present invention;

fig. 2 is a side perspective view of the air guiding device shown in fig. 1;

fig. 3 is an orthographic view of the air guiding device shown in fig. 1 in a first air guiding state;

fig. 4 is an orthographic view of the air guiding device shown in fig. 1 in a second air guiding state;

fig. 5 is a front view of the air guide device shown in fig. 2;

fig. 6 is a plan view of the air guide device shown in fig. 5;

fig. 7 is an exploded view of the air guide device shown in fig. 5;

fig. 8 is an exploded view of an air guide device according to another embodiment of the present invention;

FIG. 9 is an enlarged view of portion F encircled in FIG. 8;

fig. 10 is a perspective view of an air guide device according to a second embodiment of the present invention;

fig. 11 is a perspective view of an air guiding device according to a third embodiment of the present invention;

fig. 12 is a perspective view of an air guiding device according to a fourth embodiment of the present invention;

fig. 13 is a perspective view of an air conditioner according to an embodiment of the present invention;

fig. 14 is a reference diagram of a use state of the air conditioner shown in fig. 13.

Reference numerals:

an air conditioner 1000;

an air guide device 100; the longitudinal direction F1; the width direction F2; the thickness direction F3; median vertical plane S1;

a first ventilation opening 11; a second ventilation opening 12; an airflow passage 13; a side channel a; a central passage b;

a first channel 131; a second channel 132; a third channel 133; a fourth channel 134; a fifth passage 135;

a first air deflector 21; a second air deflector 22; a groove 23;

a third air deflector 3; an end plate c; a partition plate d; a tenon structure e;

a first side plate 31; a second side plate 32; a third side plate 33;

a fourth side plate 34; a fifth side plate 35; a sixth side plate 36;

a pivot portion 4;

an air conditioner body 200; an air outlet frame 201; an air outlet 202;

a ceiling 2000.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention.

The following disclosure provides many different embodiments, or examples, for implementing different features of the invention. In order to simplify the disclosure of the present invention, the components and arrangements of specific examples are described below. Of course, they are merely examples and are not intended to limit the present invention. Furthermore, the present invention may repeat reference numerals and/or letters in the various examples. This repetition is for the purpose of simplicity and clarity and does not in itself dictate a relationship between the various embodiments and/or configurations discussed. In addition, the present disclosure provides examples of various specific processes and materials, but one of ordinary skill in the art may recognize the applicability of other processes and/or the use of other materials.

Next, with reference to the drawings, an air guiding device 100 according to an embodiment of the first aspect of the present invention is described.

As shown in fig. 1 and 2, the air guiding device 100 has a long strip-shaped structure, and has a length direction F1, a width direction F2, and a thickness direction F3, wherein any two of the length direction F1, the width direction F2, and the thickness direction F3 are perpendicular to each other. The air guide device 100 has a first vent 11 and a second vent 12 on both sides in the width direction F2, that is, the first vent 11 is formed on one side in the width direction F2 of the air guide device 100, and the second vent 12 is formed on the other side in the width direction F2 of the air guide device 100. An airflow channel 13 communicating the first ventilation opening 11 and the second ventilation opening 12 is defined in the air guiding device 100, that is, the airflow channel 13 is formed in the air guiding device 100, and the airflow channel 13 communicates with both the first ventilation opening 11 and the second ventilation opening 12.

As shown in fig. 3 and 4, the center of the air guiding device 100 in the longitudinal direction F1 is a vertical plane S1 perpendicular to the longitudinal direction F1, that is, the vertical plane S1 is located at the center of the air guiding device 100 and perpendicular to the longitudinal direction F1 of the air guiding device 100. In the embodiment of the present invention, the airflow passage 13 is configured as follows.

As shown in fig. 3, when the airflow enters the airflow path 13 from the first ventilation opening 11 and flows out of the airflow path 13 from the second ventilation opening 12, the airflow is divergently sent in a direction away from the vertical plane S1 (abbreviated as a first air guiding state). For example, in the specific example shown in fig. 3, on the left side of the vertical center plane S1, when the airflow enters the airflow path 13 from the first ventilation opening 11 and exits the airflow path 13 from the second ventilation opening 12, the airflow is sent obliquely leftward to be sent divergently in a direction away from the vertical center plane S1, and on the right side of the vertical center plane S1, when the airflow enters the airflow path 13 from the first ventilation opening 11 and exits the airflow path 13 from the second ventilation opening 12, the airflow is sent obliquely rightward to be sent divergently in a direction away from the vertical center plane S1. This makes it possible to present a blowing tendency that diverges toward both sides in the longitudinal direction F1 of the air guide device 100.

For example, when the air guiding device 100 is used for the air outlet 202 of the air conditioner 1000, and when the air conditioner 1000 is used for cooling, the air guiding device 100 can be used to make the airflow at the air outlet 202 enter the airflow channel 13 from the first air vent 11 and be emitted and sent out from the second air vent 12 away from the vertical plane S1, at this time, the cold airflow can be emitted and sent out to both sides along the length direction F1 of the air guiding device 100 through the air guiding device 100, so as to avoid the cold air from being gathered and directly blown to the user, cause discomfort to the user, and improve the comfort experience.

As shown in fig. 4, when the airflow enters the airflow path 13 from the second ventilation opening 12 and flows out of the airflow path 13 from the first ventilation opening 11, the airflow is converged and sent in a direction close to the vertical center plane S1 (abbreviated as a second air guiding state). For example, in the specific example shown in fig. 4, on the left side of the vertical center plane S1, when the airflow enters the airflow path 13 from the second ventilation opening 12 and flows out of the airflow path 13 from the first ventilation opening 11, the airflow is sent out obliquely rightward to converge in a direction close to the vertical center plane S1, and on the right side of the vertical center plane S1, when the airflow enters the airflow path 13 from the second ventilation opening 12 and flows out of the airflow path 13 from the first ventilation opening 11, the airflow is sent out obliquely leftward to converge in a direction close to the vertical center plane S1. This makes it possible to present a tendency of air blowing toward the center in the longitudinal direction F1 of the air guide device 100.

For example, when the air guiding device 100 is used for the air outlet 202 of the air conditioner 1000, and when the air conditioner 1000 heats, the air guiding device 100 can be used to make the air flow at the air outlet 202 enter the air flow channel 13 from the second air outlet 12 and converge and send out from the first air outlet 11 to the vertical plane S1, at this time, the hot air flow can converge and send out to the center along the length direction F1 of the air guiding device 100 through the air guiding device 100, which is beneficial to extending the air supply distance, making the hot air reach the ground directly, realizing the foot warming effect, and improving the comfortable experience.

Therefore, according to the utility model discloses air ducting 100, under the wind-guiding state of difference, can present different wind-guiding effects to satisfy different in-service use demands. For example, when cold air is guided, cold air can flow through the airflow channel 13 along the direction from the first vent 11 to the second vent 12, and the cold air flow can be diffused and sent out to both sides along the length direction F1 of the air guiding device 100 through the air guiding device 100, so that cold air is prevented from being gathered and directly blown to a user, discomfort of the user is avoided, and comfortable experience is improved. For example, when hot air is guided, cold air can flow through the airflow channel 13 along the direction from the second vent 12 to the first vent 11, which is beneficial for hot air to pass through the air guide device 100 and be sent out to the center along the length direction F1 of the air guide device 100, and is beneficial for prolonging the air supply distance, so that the hot air can directly reach the ground, thereby realizing the foot warming effect and improving the comfortable experience.

Furthermore, in the embodiment of the present invention, since the airflow channel 13 is only opened on two sides in the width direction F2 of the air guiding device 100 to communicate with the first ventilation opening 11 and the second ventilation opening 12, respectively, and the airflow channel 13 is closed on two sides in the thickness direction F3 of the air guiding device 100 (for example, closed by the first air deflector 21 and the second air deflector 22 described later), the airflow channel 13 can be used for air intake by one of the first ventilation opening 11 and the second ventilation opening 12 and air outtake by the other, so that the airflow channel 13 can form a constraint on the airflow in the three-dimensional space, and further, the limitation and constraint on the air guiding direction can be better realized, and the switching between different air supply effects can be better satisfied.

In some embodiments of the present invention, as shown in fig. 1, a plurality of airflow channels 13 are defined in the air guiding device 100 and are spaced apart along the length direction F1 of the air guiding device 100. It is understood that, when a plurality of airflow channels 13 are formed in the air guiding device 100, a corresponding number of first ventilation openings 11 and a corresponding number of second ventilation openings 12 are formed in the air guiding device 100, so that each airflow channel 13 corresponds to one first ventilation opening 11 and one second ventilation opening 12, respectively.

From this, can be through setting for every airflow channel 13's air supply direction respectively for the holistic air supply effect of a plurality of airflow channels 13 can, better satisfy: the air flow sent out from the plurality of second air vents 12 has a blowing tendency of diverging toward both sides as a whole in the longitudinal direction F1 of the air guiding device 100, and the air flow sent out from the plurality of first air vents 11 has a blowing tendency of converging toward the center as a whole in the longitudinal direction F1 of the air guiding device 100.

It should be noted that the specific number of the airflow channels 13 is not limited, and may be an odd number or an even number, for example, in the first embodiment shown in fig. 1 to fig. 7, the number of the airflow channels 13 may be five. For example, in the second embodiment shown in fig. 10, the number of the airflow channels 13 may be four. For example, in the third embodiment shown in fig. 11, there may be three airflow channels 13. Of course, the present invention is not limited thereto, and only one airflow channel 13 may be defined in the air guiding device 100, for example, in the fourth embodiment shown in fig. 12.

In some embodiments of the present invention, as shown in fig. 3 and 4, in the length direction F1 of the air guiding device 100, the farther from the middle vertical plane S1, the larger the included angle between the air supply direction of the airflow channel 13 and the middle vertical plane S1 is. As a result, as shown in fig. 3, when the air flows are all dispersed in the plurality of air flow paths 13, the air flow interference between the adjacent two air flow paths 13 can be reduced, and the air flow effect of dispersing toward both sides can be achieved in the longitudinal direction F1 of the air guide device 100. As shown in fig. 4, when the air flows are converged in the plurality of air flow paths 13, the air supply interference between the adjacent two air flow paths 13 can be reduced, and the air supply effect of converging toward the center in the entire length direction F1 of the air guide device 100 can be realized.

For example, in the second embodiment shown in fig. 10, there may be four air flow channels 13, and two air flow channels 13 are respectively disposed on the left and right sides of the middle vertical plane S1, wherein, for the two air flow channels 13 on the left side of the middle vertical plane S1, the included angle between the blowing direction of the air flow channel 13 closer to the middle vertical plane S1 and the middle vertical plane S1 is smaller than the included angle between the blowing direction of the air flow channel 13 farther from the middle vertical plane S1 and the middle vertical plane S1. In the two airflow channels 13 on the right side of the middle vertical plane S1, the air blowing direction of the airflow channel 13 closer to the middle vertical plane S1 forms an angle with the middle vertical plane S1 smaller than the air blowing direction of the airflow channel 13 farther from the middle vertical plane S1 forms an angle with the middle vertical plane S1.

In some embodiments of the present invention, as shown in fig. 3 and 4, the airflow channels 13 are disposed in an axisymmetric manner with respect to the vertical plane S1 of the wind guiding device 100. Thus, when the plurality of airflow channels 13 all diverge the supply air away from the median vertical plane S1, both sides of the median vertical plane S1 may diverge the supply air symmetrically toward both sides, and when the plurality of airflow channels 13 all converge the supply air close to the median vertical plane S1, both sides of the median vertical plane S1 may converge the supply air symmetrically toward the center. Therefore, the air guide device 100 is convenient to process, air flows on two sides of the middle vertical plane S1 are symmetrical and balanced, air supply effects on two sides of the middle vertical plane S1 are the same, and the air guide device 100 is convenient to place through the position of the middle vertical plane S1 according to indoor application scenes.

For example, in the first embodiment shown in fig. 1-7, the number of the airflow channels 13 may be five, one airflow channel 13 crosses the middle vertical plane S1 and is symmetrical about the middle vertical plane S1, the other four airflow channels 13 are respectively located at the left and right sides of the middle vertical plane S1, and the two airflow channels 13 at the left side of the middle vertical plane S1 are symmetrically arranged with the two airflow channels 13 at the right side of the middle vertical plane S1. For example, in the second embodiment shown in fig. 10, four airflow channels 13 may be provided, two airflow channels 13 are respectively provided on the left and right sides of the middle vertical plane S1, and the two airflow channels 13 on the left side of the middle vertical plane S1 are symmetrically arranged with the two airflow channels 13 on the right side of the middle vertical plane S1. For example, in the third embodiment shown in fig. 11, there may be three air flow passages 13, wherein one air flow passage 13 crosses the middle vertical plane S1 and is symmetrical with respect to the middle vertical plane S1, the other two air flow passages 13 are respectively located at the left and right sides of the middle vertical plane S1, and the air flow passage 13 at the left side of the middle vertical plane S1 is arranged symmetrically with the air flow passage 13 at the right side of the middle vertical plane S1.

In some embodiments of the present invention, as shown in fig. 2, 3 and 4, the area of the first ventilation opening 11 is smaller than the area of the second ventilation opening 12. Therefore, when the airflow enters the airflow channel 13 from the first ventilation opening 11 and flows out of the airflow channel 13 from the second ventilation opening 12, the airflow can be sent out in a flaring mode, the wind speed can be reduced to a certain degree, and the problem that people are blown by cold wind is further avoided. When the airflow enters the airflow channel 13 from the second ventilation opening 12 and flows out of the airflow channel 13 from the first ventilation opening 11, the airflow can be sent out in a necking mode, so that the wind speed can be increased to a certain degree, the hot air can further directly reach the ground, and the foot warming effect is achieved.

In some embodiments of the present invention, as shown in fig. 2, 3 and 4, the flow area of the airflow channel 13 gradually increases in the direction from the first ventilation opening 11 to the second ventilation opening 12. Therefore, when the airflow enters the airflow channel 13 from the first ventilation opening 11 and flows out of the airflow channel 13 from the second ventilation opening 12, the airflow can be better flared and sent out, so that the wind speed can be reduced to a certain extent, and the problem that cold wind blows people is further avoided. When the airflow enters the airflow channel 13 from the second ventilation opening 12 and flows out of the airflow channel 13 from the first ventilation opening 11, the airflow can be better sent out in a necking mode, so that the wind speed can be increased to a certain degree, the hot air can further directly reach the ground, and the foot warming effect is achieved. Of course, the present invention is not limited thereto, and in other embodiments of the present invention, the flow area of the airflow channel 13 may be gradually increased or gradually decreased along the direction from the first ventilation opening 11 to the second ventilation opening 12, and the like, which are not described herein again.

In order to realize that the flow area of the airflow passage 13 becomes gradually larger in the direction from the first ventilation opening 11 to the second ventilation opening 12, there may be various ways, for example, in the example shown in fig. 2, the airflow passage 13 may be set as: the dimension H of the airflow passage 13 in the thickness direction F3 of the air guide device 100 gradually increases along the direction from the first ventilation opening 11 to the second ventilation opening 12. For example, in the example shown in fig. 2, a dimension H1 of the airflow channel 13 in the thickness direction F3 of the air guiding device 100 near the first ventilation opening 11 is smaller than a dimension H2 of the airflow channel 13 in the thickness direction F3 of the air guiding device 100 near the second ventilation opening 12, that is, H1 < H2. Thereby, the processing and the manufacturing are facilitated, and it is advantageous to realize that the flow area of the air flow passage 13 becomes gradually larger in the direction from the first ventilation opening 11 to the second ventilation opening 12.

For another example, in the example shown in fig. 3, the airflow passage 13 may also be provided as: the dimension W of the airflow passage 13 in the longitudinal direction F1 of the air guide device 100 gradually increases along the direction from the first ventilation opening 11 to the second ventilation opening 12. For example, in the example shown in fig. 3, a dimension W1 of the airflow channel 13 in the longitudinal direction F1 of the air guiding device 100 near the first air vent 11 is smaller than a dimension W2 of the airflow channel 13 in the longitudinal direction F1 of the air guiding device 100 near the second air vent 12, that is, W1 < W2. Thereby, the processing and the manufacturing are facilitated, and it is advantageous to realize that the flow area of the air flow passage 13 becomes gradually larger in the direction from the first ventilation opening 11 to the second ventilation opening 12.

In addition, as shown in fig. 2 and 3, when the airflow passage 13 is provided: when the dimension H of the airflow channel 13 in the thickness direction F3 of the air guiding device 100 gradually increases along the direction from the first vent 11 to the second vent 12, and the dimension W of the airflow channel 13 in the length direction F1 of the air guiding device 100 gradually increases, the flow area of the airflow channel 13 can be effectively ensured to be gradually increased along the direction from the first vent 11 to the second vent 12, and the processing and manufacturing are convenient.

The specific configuration of the air guide device 100 is not limited, and for example, some specific embodiments will be given below.

As shown in fig. 5 to 7, the air guiding device 100 may include: the first air deflector 21 and the second air deflector 22 extend along the length direction F1 of the air guide device 100, that is, the first air deflector 21 extends along the length direction F1 of the air guide device 100, the second air deflector 22 also extends along the length direction F1 of the air guide device 100, and the first air deflector 21 and the second air deflector 22 are arranged at a distance along the thickness direction F3 of the air guide device 100, so that an air flow passing space can be formed between the first air deflector 21 and the second air deflector 22. As shown in fig. 5, the air guiding device 100 may further include: at least two third air deflectors 3 are arranged at intervals along the length direction F1 of the air guiding device 100, and an air flow channel 13 is defined between each two adjacent third air deflectors 3 and the first air deflector 21 and the second air deflector 22.

Accordingly, the air guide device 100 has a simple structure, a light weight, and a low cost, and the air flow passage 13 can be simply and effectively constructed. Moreover, the airflow channel 13 is only opened at two sides in the width direction F2 of the air guide device 100 to be respectively communicated with the first vent 11 and the second vent 12, and the two sides of the airflow channel 13 in the thickness direction F3 of the air guide device 100 are respectively sealed by the first air deflector 21 and the second air deflector 22, so that the airflow channel 13 can form constraint on airflow in a three-dimensional space, and the limitation and constraint on the air guide direction can be better realized, and the switching of different air supply effects can be better satisfied.

For simplicity of design, one of the first air guiding plate 21 and the second air guiding plate 22 may be selected as a reference air guiding plate, the longitudinal direction of the reference air guiding plate may be defined as the longitudinal direction of the air guiding device 100, the width direction of the reference air guiding plate may be defined as the width direction F2 of the air guiding device 100, and the thickness direction of the reference air guiding plate may be defined as the thickness direction F3 of the air guiding device 100.

It can be understood that the number of the third air deflectors 3 may be determined according to the number of the air flow channels 13, for example, the number of the third air deflectors 3 may be set to be one more than the number of the air flow channels 13, in this case, two adjacent air flow channels 13 share the third air deflector 3, so that the number of the third air deflectors 3 may be reduced, and the cost may be reduced. For example, in the first embodiment shown in fig. 1 to 7, when the number of the airflow channels 13 is five, the number of the third air deflectors 3 may be six. For example, in the second embodiment shown in fig. 10, when the number of the airflow channels 13 is four, the number of the third air deflectors 3 may be five. For example, in the third embodiment shown in fig. 11, when there are three airflow channels 13, there may be four third air deflectors 3. For example, in the fourth embodiment shown in fig. 12, when there is one airflow channel 13, there may be two third air deflectors 3. Of course, the present invention is not limited to this, the number of the third air deflectors 3 may be more, for example, the number of the third air deflectors 3 may also be twice the number of the airflow channels 13, at this time, two adjacent airflow channels 13 may not share the third air deflector 3, so as to better design the air supply angle of each airflow channel 13.

Referring to fig. 6, at least one of the two third air deflectors 3 on both sides of any air flow channel 13 is inclined to the vertical plane S1 (i.e. intersects the vertical plane S1 at a non-zero included angle). Thereby, convergent or divergent delivery of the air flow can be achieved. For example, as shown in fig. 6, the airflow channels 13 are five in sequence along the length direction F1 of the air guiding device 100: a first channel 131, a second channel 132, a third channel 133, a fourth channel 134, and a fifth channel 135. An included angle β 1(β 1 ≠ 0) formed by the intersection of the third air deflector 3 on one side of the first channel 131 and the vertical plane S1, and an included angle β 2(β 2 ≠ 0) formed by the intersection of the third air deflector 3 on the other side of the first channel 131 and the vertical plane S1. An included angle β 2(β 2 ≠ 0) formed by the intersection of the third air guiding plate 3 on one side of the second channel 132 and the vertical plane S1, and an included angle β 3(β 3 ≠ 0) formed by the intersection of the third air guiding plate 3 on the other side of the second channel 132 and the vertical plane S1. An intersection angle β 2(β 2 ≠ 0) between the third air guiding plate 3 on one side of the second channel 132 and the middle vertical plane S1, and an intersection angle β 3(β 3 ≠ 0) between the third air guiding plate 3 on the other side of the second channel 132 and the middle vertical plane S1, and the rest of the description will be omitted herein.

Of course, the present invention is not limited thereto, and in other embodiments of the present invention, the airflow channel 13 having the above-mentioned features may also be constructed by other manners, for example, a plurality of airflow channels 13 may be run through on a whole block of strip-shaped material along the width direction of the material. Also for example, a plurality of through holes may be formed in a strip of material, each through hole having a nozzle disposed therein, the nozzles defining the air flow channels 13. For another example, a plurality of air deflectors extending in the longitudinal direction F1 of the air guiding device 100 may be additionally provided between the first air deflector 21 and the second air deflector 22, so that each air flow channel 13 is divided into a plurality of air flow channels 13 arranged at intervals in the thickness direction F3 of the air guiding device 100.

In some embodiments of the present invention, referring to fig. 2, the distance H between the first wind deflector 21 and the second wind deflector 22 in the thickness direction F3 of the wind deflector 100 gradually increases along the direction from the first ventilation opening 11 to the second ventilation opening 12. For example, as shown in fig. 2, an intersection angle α (α ≠ 0) between the first wind deflector 21 and the second wind deflector 22 can simply and effectively ensure that the distance H between the first wind deflector 21 and the second wind deflector 22 in the thickness direction F3 of the wind deflector 100 gradually increases. Therefore, when the airflow enters the airflow channel 13 from the first ventilation opening 11 and flows out of the airflow channel 13 from the second ventilation opening 12, the airflow can be flared and sent out, so that the wind speed can be reduced to a certain extent, and the problem that cold wind blows people is further avoided. When the airflow enters the airflow channel 13 from the second ventilation opening 12 and flows out of the airflow channel 13 from the first ventilation opening 11, the airflow can be sent out in a necking mode, so that the wind speed can be improved to a certain degree, the hot air can further directly reach the ground, and the foot warming effect is achieved.

In some embodiments of the present invention, referring to fig. 6, in the length direction F1 of the air guiding device 100, at least two third air deflectors 3 are respectively disposed on both sides of the middle vertical plane S1, wherein, in all the third air deflectors 3 located on the same side of the middle vertical plane S1, the farther the third air deflector 3 from the middle vertical plane S1 is, the larger the included angle between the middle vertical plane S1 is.

For example, in the embodiment shown in fig. 6, three third air guiding plates 3 are provided on the left side of the vertical plane S1, and the following are provided in the longitudinal direction F1 of the air guiding device 100 in order along the direction close to the vertical line: the novel multifunctional folding chair comprises a first side plate 31, a second side plate 32 and a third side plate 33, wherein the first side plate 31 is farthest from a middle vertical plane S1, an included angle beta 1 (beta 1 is not equal to 0) formed by the intersection of the first side plate 31 and the middle vertical plane S1 is formed by the intersection of the second side plate 32 and the middle vertical plane S1, the second side plate 32 is second farthest from the middle vertical plane S1, an included angle beta 2 (beta 2 is not equal to 0) formed by the intersection of the second side plate 32 and the middle vertical plane S1, the third side plate 33 is closest to the middle vertical plane S1, and an included angle beta 3 (beta 3 is not equal to 0) formed by the intersection of the third side plate 33 and the middle vertical plane S1, wherein beta 1 is larger than beta 2 and larger than beta 3. The right side of the vertical surface S1 also has three third wind deflectors 3, which are symmetrically arranged with the three third wind deflectors 3 on the left side, and are not described herein again.

Therefore, the included angle between the third air deflector 3 and the middle vertical plane S1, which is farther from the middle vertical plane S1, is larger, so that as shown in fig. 3, when the air is dispersed and blown by all of the air flow channels 13, the air blowing interference of two adjacent air flow channels 13 can be reduced, and the air blowing effect of dispersing toward both sides can be realized in the length direction F1 of the air guide device 100. As shown in fig. 4, when the air flows are converged in the plurality of air flow paths 13, the air supply interference between the adjacent two air flow paths 13 can be reduced, and the air supply effect of converging toward the center in the entire length direction F1 of the air guide device 100 can be realized.

In some embodiments of the present invention, referring to fig. 6, the airflow channel 13 includes a side channel a located on one side of the middle vertical plane S1, and in two third wind deflectors 3 on two sides of at least one side channel a, an included angle between the third wind deflector 3 relatively far away from the middle vertical plane S1 and the middle vertical plane S1 is greater than an included angle between the third wind deflector 3 relatively near the middle vertical plane S1 and the middle vertical plane S1. Therefore, the third air deflectors 3 on both sides of the airflow channel 13 can effectively cooperate with each other to guide the airflow, so that when the airflow enters the airflow channel 13 from the first ventilation opening 11 and flows out of the airflow channel 13 from the second ventilation opening 12, the airflow can better diverge and be sent out in the direction away from the vertical plane S1, and when the airflow enters the airflow channel 13 from the second ventilation opening 12 and flows out of the airflow channel 13 from the first ventilation opening 11, the airflow can better converge and be sent out in the direction close to the vertical plane S1.

For example, in the embodiment shown in fig. 6, the left side of the vertical plane S1 has two side channels a, which are: a first channel 131 and a second channel 132, a third air guiding plate 3 (e.g. a first side plate 31) at the left side of the first channel 131 is far away from the median plane S1 compared with the third air guiding plate 3 (e.g. a second side plate 32) at the right side of the first channel 131, an intersection angle β 1(β 1 ≠ 0) between the first side plate 31 and the median plane S1 is larger than an intersection angle β 2(β 2 ≠ 0) between the second side plate 32 and the median plane S1, β 1> β 2, a third air guiding plate 3 (e.g. a second side plate 32) at the left side of the second channel 132 is far away from the median plane S1 compared with the third air guiding plate 3 (e.g. a third side plate 33) at the right side of the second channel 132, and an intersection angle β 2(β 2 ≠ 0) between the second side plate 32 and the median plane S1 is larger than an intersection angle β 3(β 3 ≠ 0) between the third side plate 33 and the median plane S1, β 2> β 3, the right side channel S1 a is provided symmetrically with the two side channels a, and will not be described in detail herein. Further, it is noted that, in the specific example shown in fig. 6, the third passage 133 crosses the median plane S1 to be located on both sides of the median plane S1, not belonging to the side passage a located on the side of the median plane S1.

In some embodiments of the present invention, referring to fig. 6, the airflow channel 13 includes a central channel b crossing the middle vertical plane S1 to be located at two sides of the middle vertical plane S1, and the included angles between the two third wind deflectors 3 at two sides of the central channel b and the middle vertical plane S1 are the same and are symmetrically arranged. For example, in the specific example shown in fig. 6, the third channel 133 crosses the midperpendicular plane S1 to be located on both sides of the midperpendicular plane S1, the third air deflection plate 3 (e.g., the third side plate 33) on the left side of the third channel 133 is located on the left side of the midperpendicular plane S1, the third air deflection plate 3 (e.g., the fourth side plate 34) on the right side of the third channel 133 is located on the right side of the midperpendicular plane S1, the third side plate 33 and the fourth side plate 34 are symmetrically arranged about the midperpendicular plane S1, the third side plate 33 intersects the midperpendicular plane S1 at an angle β 3(β 3 ≠ 0), and the fourth side plate 34 also intersects the midperpendicular plane S1 at an angle β 3.

Thus, when the central passage b diverges the supply air away from the median vertical plane S1, the portions of the central passage b on both sides of the median vertical plane S1 may diverge the supply air symmetrically toward both sides, and when the central passage b converges the supply air close to the median vertical plane S1, the portions of the central passage b on both sides of the median vertical plane S1 may converge the supply air symmetrically toward the center. Therefore, the air guide device is convenient to process, the air supply of the parts of the central channel b, which are positioned at the two sides of the middle vertical plane S1, is symmetrical and balanced, the air supply effect is the same, and the air guide device 100 is convenient to arrange through the position of the middle vertical plane S1 according to indoor application scenes.

In some embodiments of the present invention, as shown in fig. 7, the two ends of the air guiding device 100 in the length direction F1 are respectively provided with a pivot portion 4, for example, the pivot portion 4 may be a pivot shaft or a pivot hole, etc., so as to facilitate the pivotal installation of the air guiding device 100, and switch different air guiding states through pivoting. For example, in some specific scenarios, the pivot portion 4 is adapted to be pivotally mounted to the air conditioner body 200 of the air conditioner 1000, so as to facilitate the pivotal connection between the air guiding device 100 and the air conditioner body 200, so that the width direction F2 of the air guiding device 100 can rotate around the pivot axis of the pivot portion 4, and thus air can be switched between air intake from the first air vent 11 and air intake from the second air vent 12.

For example, in some embodiments of the present invention, as shown in fig. 7, the number of the third air deflectors 3 is at least two, and the third air deflectors 3 include two end plates c, and among all the third air deflectors 3, along the length direction F1 of the air guiding device 100, the two third air deflectors 3 located at both ends are respectively end plates c, each end plate c is respectively provided with the above-mentioned pivot portion 4, and the pivot portion 4 is pivotally installed on the air conditioner body 200 of the air conditioner 1000. Therefore, the structure is simple and the processing is convenient.

Further, as shown in fig. 7, the number of the third air guiding plates 3 is at least three, and the third air guiding plates include the two end plates c and at least one partition plate d, and the two end plates c are located on two sides of all the partition plates d in the length direction F1 of the air guiding device 100, that is, all the partition plates d are located between the end plates c on two sides, so that the air guiding device 100 defines at least two air flow channels 13.

It will be appreciated that the maximum number of airflow channels 13 that can be defined is the number of third air deflectors 3 minus one. For example, in the specific example shown in fig. 7, the number of the third air deflectors 3 is six, and the three third air deflectors 3 include two end plates c and four partition plates d located between the two end plates c, and one air flow channel 13 is defined between adjacent two third air deflectors 3, so that five air flow channels 13 are defined. Thereby, the plurality of air flow passages 13 can be simply and efficiently constructed.

The first air deflector 21, the second air deflector 22 and each third air deflector 3 can be all split pieces and are assembled and connected, so that the processing and the manufacturing are convenient. Or, the at least one third air deflector 3 is integrated with one of the first air deflector 21 and the second air deflector 22, and is assembled and connected with the other one of the first air deflector 21 and the second air deflector 22, so that the processing is convenient to a certain extent, and the assembly can be simplified to a certain extent.

In some embodiments of the present invention, the third air guiding plate 3 is integrated with one of the first air guiding plate 21 and the second air guiding plate 22, and is inserted into and matched with the other of the first air guiding plate 21 and the second air guiding plate 22. Thereby, the machining and assembly can be simplified.

For example, in the specific example shown in fig. 7, the second air guiding plate 22 and each third air guiding plate 3 may be processed into one part, the first air guiding plate 21 may be processed into another part, the groove 23 is provided on the first air guiding plate 21 at the position corresponding to each third air guiding plate 3, after the two parts are processed, each third air guiding plate 3 is inserted into the groove 23 at the corresponding position on the first air guiding plate 21, and then the two parts are integrally connected by bonding and/or welding. Alternatively, for example, in the specific example shown in fig. 8, the first air guiding plate 21 and each third air guiding plate 3 may be processed into one part, the second air guiding plate 22 may be processed into another part, the groove 23 may be provided at a position corresponding to each third air guiding plate 3 on the second air guiding plate 22, after the two parts are processed, each third air guiding plate 3 may be inserted into the groove 23 at a corresponding position on the first air guiding plate 21, and then the two parts may be integrally connected by bonding and/or welding.

In addition, when the third air deflector 3 is in inserting fit with the other one of the first air deflector 21 and the second air deflector 22, in order to facilitate the inserting fit and the limiting of the third air deflector 3 and the groove 23, in combination with fig. 9, a tenon structure e may be disposed at a free end of the third air deflector 3 (for example, a part below a dotted line L shown in fig. 9 is the tenon structure e), and the length of the tenon structure e is matched with the length of the groove 23 and is smaller than the length of the free end of the third air deflector 3, so that the inserting limiting effect may be achieved, at this time, the inserting limiting may be achieved no matter the groove 23 is a blind groove or a through groove, the assembling efficiency is improved, and the processing difficulty of the groove 23 is reduced.

An air guiding device 100 according to an embodiment of the present invention is described below with reference to fig. 1 to 7.

The air guide device 100 includes: the air-guiding plate comprises two face air deflectors (a first air deflector 21 and a second air deflector 22 respectively), six third air deflectors 3 (a first side plate 31, a second side plate 32, a third side plate 33, a fourth side plate 34, a fifth side plate 35 and a sixth side plate 36 respectively) and two pivoting parts 4, wherein the first side plate 31 and the sixth side plate 36 are two end plates c, the second side plate 32, the third side plate 33, the fourth side plate 34 and the fifth side plate 35 are four partition plates d, and the pivoting parts 4 are rotating shafts and are arranged on the outer sides of the two end plates c respectively. An air flow channel 13 is defined between two adjacent third air deflectors 3 and two adjacent third air deflectors.

Referring to fig. 2, an included angle between the first air guiding plate 21 and the second air guiding plate 22 is α, and α is greater than or equal to 45 degrees and greater than or equal to 0 degrees. With reference to fig. 6, the included angle between the first side plate 31 and the middle vertical plane S1 is β 1, and the included angle between the sixth side plate 36 and the middle vertical plane S1 is also β 1; the included angle between the second side plate 32 and the middle vertical plane S1 is beta 2, and the included angle between the fifth side plate 35 and the middle vertical plane S1 is also beta 2; the included angle between the third side plate 33 and the middle vertical plane S1 is beta 3, the included angle between the fourth side plate 34 and the middle vertical plane S1 is beta 3, and beta 1 is more than or equal to beta 2 and more than or equal to beta 3.

When α >0 °, and β 1> β 2> β 3, as shown in fig. 3, when the air flow enters from the side of the air flow passage 13 on the air guide device 100 with a small area and is blown out from the side with a large area, the air guide device 100 has a flow dispersion effect on the air flow, and during cooling, the air guide device 100 rotates to a state where the side with the small area of the air flow passage 13 faces the inside of the air conditioner 1000 and the side with the large area faces the outside of the air conditioner 1000, and the speed of the cold air flow passing through the air guide dispersion is reduced, thereby preventing cold air from blowing people.

When α >0 °, and β 1> β 2> β 3, with reference to fig. 4, when the air flow enters from the side of the air flow channel 13 on the air guiding device 100 with a large area and blows out from the side with a small area, the air guiding device 100 has an acceleration effect on the air flow, and during heating, the air guiding device 100 rotates to a state where the side with the large area of the air flow channel 13 faces the inside of the air conditioner 1000 and the side with the small area faces the outside of the air conditioner 1000, and the speed of the hot air flow passing through the air guiding device is higher, which is beneficial for the hot air to directly reach the ground, thereby achieving a foot warming effect.

When α >0 °, and β 1> β 2> β 3, the mold cannot be removed by the integral casting method because of the inclination angles in the plurality of directions, and the air guide device 100 needs to be welded together after being cast separately. As shown in fig. 7, the second air guiding plate 22, six third air guiding plates 3 and the pivot portion 4 may be processed into one part, the first air guiding plate 21 may be processed into another part, and a groove 23 is disposed on the first air guiding plate 21 corresponding to each third air guiding plate 3; after casting the parts, the third air guiding plates 3 are inserted into the grooves 23 at the corresponding positions on the first air guiding plates 21, and the air guiding device 100 is connected into a whole by adopting an ultrasonic welding mode and the like.

Or, as shown in fig. 8, the first air guiding plate 21, six third air guiding plates 3 and the pivot 4 may be further processed into one part, and with reference to fig. 9, a tenon structure e is disposed on one side of each third air guiding plate 3 away from the first air guiding plate 21, meanwhile, the second air guiding plate 22 is separately processed into another part, and a groove 23 is disposed on the second air guiding plate 22 corresponding to each third air guiding plate 3; after the parts are cast, the tenon structures e on the third air deflectors 3 are inserted into the grooves 23 at the corresponding positions on the second air deflectors 22. The air guiding device 100 is then connected into a whole by ultrasonic welding or the like.

Therefore, according to the utility model discloses air ducting 100, under the wind-guiding state of difference, can present different wind-guiding effects to satisfy different in-service use demands. For example, when carrying out the water conservancy diversion to cold air, do benefit to cold air flow and can follow air ducting 100's length direction F1 and disperse to both sides and send out through air ducting 100, and air supply speed can reduce to can avoid cold wind gathering direct-blowing user, cause the user uncomfortable, improve comfortable experience. For example, when hot air is guided, the hot air flow can be conveniently sent out through the air guide device 100 and can be converged towards the center along the length direction F1 of the air guide device 100, the air supply speed can be increased, the air supply distance can be conveniently prolonged, the hot air can directly reach the ground, the foot warming effect is achieved, and the comfortable experience is improved.

Furthermore, in the embodiment of the present invention, since the two sides of the airflow channel 13 only in the width direction F2 of the air guiding device 100 are open to communicate with the first ventilation opening 11 and the second ventilation opening 12, respectively, and the two sides of the airflow channel 13 in the thickness direction F3 of the air guiding device 100 are closed by the first air deflector 21 and the second air deflector 22, respectively, the airflow channel 13 can be made to be air-in by one of the first ventilation opening 11 and the second ventilation opening 12 and air-out by the other, so that the airflow channel 13 can form a constraint on the airflow in the three-dimensional space, and further the limitation and constraint on the air guiding direction can be better realized, and the switching of different air supply effects can be better satisfied. In addition, the air guiding device 100 has a simple structure, light weight and low cost, and the air flow channel 13 can be simply and effectively constructed.

Next, an air conditioner 1000 according to an embodiment of the second aspect of the present invention is described with reference to the drawings.

As shown in fig. 13, the air conditioner 1000 may include an air conditioner body 200 and the air guiding device 100 according to the embodiment of the present invention, the air conditioner body 200 includes an air outlet 202, the air guiding device 100 is movably disposed at the air outlet 202 to switch between a first air guiding state and a second air guiding state, in the first air guiding state, the first ventilation opening 11 is located upstream of the second ventilation opening 12, and the air flow reaching the air outlet 202 is adapted to enter the air flow passage 13 from the first ventilation opening 11 and flow out of the air flow passage 13 from the second ventilation opening 12; in the second wind guiding state, the second ventilation opening 12 is located upstream of the first ventilation opening 11, and the airflow reaching the wind outlet 202 is suitable for entering the airflow channel 13 from the second ventilation opening 12 and flowing out of the airflow channel 13 from the first ventilation opening 11.

Therefore, according to the utility model discloses air conditioner 1000, air ducting 100 can present different wind-guiding effects under the wind-guiding state of difference to satisfy different in-service use demands.

For example, when guiding the flow of the cold air, the air guiding device 100 may be switched to the first air guiding state, at this time, the first vent 11 is located at the upstream of the second vent 12, the airflow reaching the air outlet 202 is suitable for entering the airflow channel 13 from the first vent 11 and flowing out of the airflow channel 13 from the second vent 12, so that the cold air can be emitted and sent out to both sides along the length direction F1 of the air guiding device 100 through the air guiding device 100, thereby preventing cold air from being collected and directly blown to a user, causing discomfort to the user, and improving comfort experience.

For example, when hot air is guided, the air guiding device 100 may be switched to the second air guiding state, at this time, the second air vent 12 is located at the upstream of the first air vent 11, and the air flow reaching the air outlet 202 is suitable for entering the air flow channel 13 from the second air vent 12 and flowing out of the air flow channel 13 from the first air vent 11, so that the hot air flow can be sent out through the air guiding device 100 and converged toward the center along the length direction F1 of the air guiding device 100, which is beneficial to extending the air supply distance, so that the hot air can reach the ground directly, thereby achieving the foot warming effect and improving the comfortable experience.

In addition, since the airflow channel 13 is only opened at two sides in the width direction F2 of the air guiding device 100 to be respectively communicated with the first ventilation opening 11 and the second ventilation opening 12, and the airflow channel 13 is respectively closed at two sides in the thickness direction F3 of the air guiding device 100, the airflow channel 13 can be used for air intake from one of the first ventilation opening 11 and the second ventilation opening 12 and air exhaust from the other, so that the airflow channel 13 can form constraint on airflow in a three-dimensional space, and further the limitation and constraint on the air guiding direction can be better realized, and the switching of different air supply effects can be better satisfied.

In some embodiments of the present invention, as shown in fig. 13 and 14, the air conditioner 1000 may include a sanitary air conditioner, the air conditioner body 200 of the sanitary air conditioner includes an air outlet frame 201, the air outlet frame 201 has an air outlet 202 thereon, and the air guiding device 100 is rotatably installed on the air outlet frame 201. From this, because bathroom air conditioner sets up according to the utility model discloses air ducting 100, and set up air ducting 100 into rotatable form to switch different wind-guiding states, thereby can present different wind-guiding effects, satisfy different in-service use demands. In addition, the air conditioner 1000 may further include a split wall-mounted air conditioner, a split cabinet air conditioner, and the like.

It is understood that the outlet frame 201 may be disposed above the ceiling or at least partially below the ceiling as desired. Therefore, the installation requirements of different bathroom air conditioners can be met. In addition, it should be noted that other configurations of the bathroom air conditioner according to the embodiment of the present invention, such as the heat exchanger and the fan, and the operation thereof, are known to those skilled in the art, and will not be described in detail herein.

Therefore, the present invention relates to the field of ventilation technology, and more particularly, to an air guiding device 100 and an air conditioner 1000 having the same, wherein the air conditioner 1000 may include a bathroom air conditioner used in a bathroom space. In the air conditioner 1000 in the related art, a single-chip air guide sheet is mostly adopted, and the air guide sheet has the characteristics of simple structure, easiness in processing and the like. However, the single-sheet air guiding sheet is only composed of a flat plate or an arc-shaped plate, cannot form three-dimensional constraint on the flowing air flow, can only simply change the direction of the air flow, has poor air guiding effect, and is difficult to adapt to the requirement of a special scene on changeful air flow organization.

For at least solving not enough one of above-mentioned technique, the utility model provides an air ducting 100 the utility model discloses an in at least one embodiment, the utility model discloses an air ducting 100 is injectd a plurality of airflow channel 13 through a plurality of third aviation baffles 3 and two face aviation baffles, and airflow channel 13 can carry out three-dimensional restraint to the air current that flows through, makes the air current gathering that flows through with higher speed or the diffusion scattered stream and directive property stronger, effectively satisfies the changeable demand of special scene to the air current tissue.

In the description of the present invention, it is to be understood that the terms "length", "width", "thickness", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

In the present application, unless otherwise expressly stated or limited, the terms "mounted," "connected," and "secured" are to be construed broadly, e.g., as meaning directly connected to one another, indirectly connected through intervening media, communicating between two elements, or interacting between two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In the present application, unless expressly stated or limited otherwise, the first feature may be directly on or directly under the second feature or indirectly via intermediate members. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

While embodiments of the present invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.

Claims (16)

1. An air guide device is characterized in that a first vent and a second vent are respectively arranged on two sides of the air guide device in the width direction, an airflow channel communicated with the first vent and the second vent is defined in the air guide device, a median vertical plane perpendicular to the length direction is formed by passing through the center of the air guide device in the length direction, and the airflow channel is structured as follows:

when the airflow enters the airflow channel from the first ventilation opening and flows out of the airflow channel from the second ventilation opening, the airflow is divergently sent out towards the direction far away from the vertical plane,

when the airflow enters the airflow channel from the second ventilation opening and flows out of the airflow channel from the first ventilation opening, the airflow is converged and sent out towards the direction close to the vertical plane.

2. The air guide device according to claim 1, wherein a plurality of the airflow passages are defined in the air guide device and are spaced apart in a longitudinal direction of the air guide device.

3. The air guide device according to claim 2, wherein an angle between an air blowing direction of the air flow passage farther from the vertical center plane and the vertical center plane is larger in a longitudinal direction of the air guide device.

4. The air guide device according to claim 3, wherein a plurality of the airflow passages are provided symmetrically with respect to the mid-vertical axis of the air guide device.

5. The air guiding device as recited in claim 1, wherein an area of the first ventilation opening is smaller than an area of the second ventilation opening.

6. The air guiding device as recited in claim 5, wherein an area of the airflow passage gradually increases in a direction from the first air vent to the second air vent.

7. The air guide device according to claim 6, wherein a dimension of the air flow channel in a thickness direction of the air guide device is gradually increased and/or a dimension of the air flow channel in a length direction of the air guide device is gradually increased along a direction from the first vent to the second vent.

8. The air guiding device according to any one of claims 1 to 7, comprising:

the first air deflector and the second air deflector extend along the length direction of the air guide device, and the first air deflector and the second air deflector are arranged at intervals along the thickness direction of the air guide device;

the air guide device comprises at least two third air deflectors which are arranged along the length direction of the air guide device at intervals, an air flow channel is defined between each two adjacent third air deflectors and the first air guide device and the second air guide device, and at least one of the two third air deflectors on two sides of any air flow channel is inclined to the vertical plane.

9. The air guide device according to claim 8, wherein a distance between the first air deflector and the second air deflector in a thickness direction of the air guide device gradually increases in a direction from the first air vent to the second air vent.

10. The air guiding device as claimed in claim 8, wherein at least two third air guiding plates are respectively disposed on two sides of the vertical plane, and an included angle between each third air guiding plate located on the same side of the vertical plane and the vertical plane is larger as the third air guiding plate is farther from the vertical plane.

11. The air guide device according to claim 8, wherein the air flow channel includes a side channel located on one side of the vertical plane, and an included angle between the third air deflector farther from the vertical plane and the vertical plane is larger than an included angle between the third air deflector closer to the vertical plane and the vertical plane, of the two third air deflectors on both sides of at least one of the side channels.

12. The air guiding device as claimed in claim 8, wherein the air flow channel comprises a central channel crossing the vertical plane to be located on both sides of the vertical plane, and the two third air deflectors on both sides of the central channel are arranged symmetrically and at the same included angle with the vertical plane.

13. The air guide device according to claim 8, wherein each of both ends of the air guide device in a longitudinal direction has a pivot portion.

14. The air guide device according to claim 8, wherein the third air deflector is integrated with one of the first air deflector and the second air deflector, and is in plug fit with the other of the first air deflector and the second air deflector.

15. An air conditioner, characterized in that, it comprises an air conditioner body and the wind guiding device according to any one of claims 1-14, the air conditioner body comprises an air outlet, the wind guiding device is movably arranged at the air outlet to switch between a first wind guiding state and a second wind guiding state,

in the first wind guiding state, the first ventilation opening is positioned at the upstream of the second ventilation opening, and the airflow reaching the air outlet is suitable for entering the airflow channel from the first ventilation opening and flowing out of the airflow channel from the second ventilation opening;

and in the second air guide state, the second air vent is positioned at the upstream of the first air vent, and the air flow reaching the air outlet is suitable for entering the air flow channel from the second air vent and flowing out of the air flow channel from the first air vent.

16. The air conditioner as claimed in claim 15, wherein the air conditioner comprises a bathroom air conditioner, the air conditioner body of the bathroom air conditioner comprises an air outlet frame, the air outlet frame has the air outlet, and the air guiding device is rotatably mounted on the air outlet frame.

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