CN114061134A - Air treatment equipment and air conditioner with same - Google Patents

Abstract

The invention discloses an air treatment device and an air conditioner with the same, wherein the air treatment device comprises: the rotating body is rotatably connected to the fixed shell through the rotating bearing, and the rotating bearing is obliquely arranged on the fixed shell. The rotating body includes: rotatory shell, first wind channel spare and first fan, the interval is equipped with air outlet and first side air intake on the rotatory shell. First wind channel spare is connected in rotatory shell, and first wind channel spare communicates with air outlet and first side air intake respectively. The first fan is arranged in the first air duct piece to blow the air sucked from the first side air inlet to the air outlet. According to the air treatment equipment provided by the embodiment of the invention, the rotating shell, the first air channel piece and the first fan can rotate relative to the fixed shell at the same time, so that the rotating body is used as an independent part, and air in different directions can enter the first air channel piece and be blown out towards different directions. The rolling bearing is installed obliquely, so that air can enter and exit from a plurality of indoor areas, and the air can be quickly and uniformly mixed in the whole house.

Description

Air treatment equipment and air conditioner with same

Technical Field

The invention belongs to the technical field of air treatment, and particularly relates to air treatment equipment and an air conditioner with the same.

Background

The air conditioner can adjust the properties of indoor air such as temperature, humidity, cleanliness and the like, thereby improving the comfort of the indoor environment.

In the related art, the air conditioner indoor unit has the defects of limited air outlet range or insufficient air outlet distance when air is exhausted. When the temperature of indoor air is adjusted, some air-conditioning indoor units are limited by arrangement positions, the whole indoor temperature cannot be quickly and uniformly regulated, and the problems of over-low local temperature or uneven overheated temperature often occur. For the occasions with large space to be cooled or heated, a plurality of air conditioner indoor units are often needed to achieve uniform adjustment of the temperature of the whole house, and a long time is also needed to ensure that the temperature of each position of the whole house is within a preset threshold value.

Disclosure of Invention

The present invention is directed to solving at least one of the problems of the prior art. Therefore, the invention provides air treatment equipment which can realize air outlet and air inlet in multiple directions, realize rapid circulation of indoor air and solve the technical problem that air cannot be rapidly and uniformly adjusted due to fixed arrangement position of an air conditioner indoor unit in the prior art.

The invention also aims to provide an air conditioner with the air treatment equipment.

An air treatment device according to an embodiment of the present invention includes: the rotating body is rotatably connected to the fixed shell through the rotating bearing, and the rotating bearing is obliquely arranged on the fixed shell; the rotating body includes: the rotary shell is provided with an air outlet and a first side air inlet at intervals; the first air channel piece is connected in the rotating shell and is respectively communicated with the air outlet and the first side air inlet; and the first fan is arranged in the first air channel piece so as to blow the air sucked from the first side air inlet to the air outlet.

According to the air treatment equipment provided by the embodiment of the invention, the rotating shell, the first air duct piece and the first fan can rotate relative to the fixed shell at the same time, so that the rotating body is used as an independent part, and when the first fan works, indoor air can be quickly sucked from the air inlet on the first side and can be quickly discharged to the air outlet. Because the rotator can constantly rotate for the set casing, consequently the air inlet direction of first side air intake and the air-out direction of air outlet also can constantly change to can flow into the air inlet of equidirectional in making first wind channel spare, and make the wind in the first wind channel spare blow out to the different directions, effectively promoted the ability of rotator switching-over air delivery. The rotary bearing is provided with a rotary axis which is vertical to the bearing surface of the rotary bearing, and the rotary axis is obliquely arranged relative to the horizontal plane at the moment, so that the air inlet direction of the rotary body after rotation can be continuously changed; or the air outlet of the air outlet can be taken into consideration to more areas after the rotating body rotates, so that the air can be quickly and uniformly mixed in the whole house.

According to the air treatment equipment provided by the embodiment of the invention, the rotating shell is an asymmetric shell, the air outlet is formed in the top of the rotating shell, and the first side air inlet is formed in the side of the rotating shell.

According to some embodiments of the air treatment apparatus of the present invention, an inclination angle of the bearing surface of the rotary bearing to the horizontal plane is greater than 0 degree and equal to or less than 45 degrees.

An air treatment device according to some embodiments of the present invention further includes a rotational drive mechanism that rotates the rotating body relative to the stationary case. According to some embodiments of the present invention, the rotation driving mechanism includes a rotation driving motor, a first gear, and a gear ring, the rotation driving motor is connected to the fixed case, an output end of the rotation driving motor is connected to the first gear, the gear ring is connected to the first air duct member, and the first gear is engaged with the gear ring.

According to some embodiments of the invention, the air treatment equipment further comprises a stopper, the stopper can move relative to the first air duct member to open or close the first side air inlet, the fixed shell is provided with an air inlet, and when the stopper closes the first side air inlet, the air inlet is communicated with the air outlet; when the first side air inlet is opened by the blocking piece, the air inlet and the first side air inlet are respectively communicated with the air outlet.

Optionally, the stopper is capable of moving up and down relative to the fixed casing, and when the stopper closes the first side air inlet, at least part of the stopper is located between the rotating casing and the first air duct member; when the first side air inlet is opened by the blocking piece, the blocking piece is accommodated in the fixed shell.

Optionally, a second side air inlet is disposed on a side of the stationary housing close to the rotating housing, and the stopper may open or close the first side air inlet and the second side air inlet simultaneously.

Optionally, the air treatment equipment further comprises a second air duct piece, the second air duct piece is connected in the fixed shell, and the second air duct piece is respectively communicated with the air inlet, the air outlet, the first side air outlet and the second side air inlet.

Optionally, a first rib is arranged on the periphery of the first air duct piece, a second rib is arranged on the periphery of the second air duct piece, and when the first air duct piece rotates relative to the second air duct piece, at least part of the first rib is overlapped with the second rib.

Advantageously, the first air duct piece is provided with a first communication port communicated with the first side air inlet, and the first communication port is arranged on the side wall of the first air duct piece close to the first flange; and a second communication port communicated with the air outlet is arranged on the first air channel piece, and the second communication port is arranged at the top of the first air channel piece.

Optionally, a first through groove is formed in the first rib, a second through groove is formed in the second rib, and when the first through groove and the second through groove are parallel to each other, the blocking piece penetrates through the second through groove and the first through groove to shield the first communication hole.

Optionally, a third communication port communicated with the second side air inlet is formed in the second air duct member, and the blocking member shields the third communication port while shielding the first communication port.

Optionally, the stopper is disposed between the fixed casing and the second air duct member in a manner of being movable up and down.

According to some embodiments of the invention, the air treatment equipment further comprises a lifting driving mechanism, one end of the lifting driving mechanism is connected with the fixed shell, and the lifting driving mechanism drives the stopper to move up and down.

An air treatment device according to some embodiments of the present invention further includes a second fan disposed within the second air duct member.

An air treatment device according to some embodiments of the present invention further includes an air treatment module disposed in the stationary housing proximate the air intake.

An air conditioner according to an embodiment of the present invention includes: the air conditioner main machine is provided with a heat exchange module, and air subjected to heat exchange by the heat exchange module is blown out of the air conditioner main machine; the air treatment equipment is the air treatment equipment of the previous embodiments; the air treatment equipment is separately arranged on the air conditioner host, and the air treatment equipment can independently work relative to the air conditioner host.

According to the air conditioner provided by the embodiment of the invention, when the air subjected to heat exchange in the air conditioner main machine is blown outwards, the air processing equipment can suck the air blown out by the air conditioner main machine and quickly blow the air towards different directions, so that the wind energy of the air conditioner main machine is blown towards more directions, the heat exchange is quickly carried out on the whole house, and the dead angle of the heat exchange is reduced. Meanwhile, the air treatment equipment is combined with the air conditioner main machine, and wind relay can be formed, so that the wind after heat exchange in the air conditioner main machine can be blown to a farther place, and the air supply range of the air conditioner main machine is improved.

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

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 is a schematic perspective view of an air treatment device according to some embodiments of the present invention in a cleaning mode.

FIG. 2 is a schematic perspective view of an air treatment device in accordance with some embodiments of the present invention in a wind relay mode.

FIG. 3 is a schematic perspective view of another angle of an air treatment device in a wind relay mode according to some embodiments of the present invention.

FIG. 4 is a cross-sectional view of an air treatment device of some embodiments of the present invention in a cleaning mode.

FIG. 5 is a cross-sectional view of an air treatment device in a wind force mode according to some embodiments of the present invention.

FIG. 6 is a sectional view of an air treatment device in accordance with some embodiments of the present invention in a wind relay mode and a cleaning mode.

FIG. 7 is an exploded view of an air treatment device according to some embodiments of the present invention.

Fig. 8 is a schematic perspective view of the first air duct member, the second air duct member, the rotational bearing, and the rotational driving mechanism according to some embodiments of the present invention.

Fig. 9 is a perspective view of the first air channel member, the second air channel member, the rotational bearing and the rotational driving mechanism according to another embodiment of the present invention.

FIG. 10 is a cross-sectional view of the first air duct member, the second air duct member, the rotational bearing, and the rotational drive mechanism in accordance with some embodiments of the present invention.

Fig. 11 is a schematic perspective view of the first air duct member, the second air duct member, the third air duct member, the stopper member, and the lifting driving mechanism of the present invention in a purification mode.

Fig. 12 is a schematic perspective view of the blocking member opening the first communication port of the first air duct member and opening the third communication port of the second air duct member according to some embodiments of the present invention.

Fig. 13 is a schematic perspective view of the blocking member in the air relay mode after the first communicating opening of the first air duct member is opened and the third communicating opening of the second air duct member is opened according to some embodiments of the present invention.

Fig. 14 is a schematic structural diagram of an air processing device and a main air conditioner unit according to some embodiments of the present invention.

Fig. 15 is a schematic diagram of an air treatment device separated from a main air conditioner according to some embodiments of the present invention.

Fig. 16 is a schematic view of a rotary bearing according to some embodiments of the present invention.

Reference numerals:

2000. an air conditioner;

2100. an air treatment device;

100. a stationary case; 110. an air inlet; 120. a second side air inlet;

130. a first stationary case; 140. a second stationary case;

200. a rotating body; 201. a rotation axis;

210. rotating the housing; 211. an air outlet; 212. a first side air inlet;

220. a first air duct member; 221. a first flange; 2211. a first through groove;

222. a first communication port; 223. a second communication port;

230. a first fan; 231. a first motor; 232. a first impeller;

310. a rotating bearing;

311. a fixed support part; 312. a rotation support; 3121. a first rotation support portion; 3122. a second rotation support portion; 320. a rotation driving mechanism; 321. rotating the drive motor; 322. a first gear; 323. a ring gear;

400. a stopper; 410. a support plate;

500. a second air duct member; 510. a second flange; 520. a second through groove; 530. a third communication port; 540. a first mounting bracket; 550. a second mounting bracket; 560. a third mounting bracket;

600. a lifting drive mechanism; 610. a lifting drive motor; 620. a second gear; 630. a rack; 640. a fourth mounting bracket;

700. a second fan; 710. a second motor; 720. a second impeller;

800. an air treatment module; 810. a purifying member; 820. a fixed mount; 821. clamping a pin;

900. moving the chassis; 1000. a third air duct member;

2200. an air conditioner main machine; 2210. and (6) butting the bins.

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 or similar 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 accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "center", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be considered as limiting the present invention.

The air treatment device 2100 according to embodiments of the present invention is described below with reference to the drawings, and the air treatment device 2100 according to the present application may change the direction and speed of the airflow, and in some examples, may also change the physical and chemical properties of the air, such as cleanliness.

An air treatment device 2100 according to an embodiment of the invention includes: as shown in fig. 1, which shows the stationary case 100, the rotary body 200, and the rotary bearing 310 shown in fig. 4, the rotary body 200 is rotatably coupled to the stationary case 100 by the rotary bearing 310, so that the rotary body 200 can be integrally rotated with respect to the stationary case 100, that is, the rotary body 200 as a whole can be rotated with respect to the stationary case 100.

As shown in fig. 4, the rotating body 200 includes a rotating case 210, a first air duct member 220, and a first fan 230, which are all rotated with respect to the stationary case 100.

Further, as shown in fig. 1 and 3, the rotary casing 210 is provided with an air outlet 211 and a first side air inlet 212 at intervals, and in order to prevent the air inlet of the first side air inlet 212 and the air outlet of the air outlet 211 from interfering with each other, the air outlet 211 and the first side air inlet 212 are selectively provided on different surfaces of the rotary casing 210, so as to form an interval arrangement; alternatively, the air outlet 211 and the first side air inlet 212 may be selectively disposed at positions spaced far apart from each other on the same surface of the rotary case 210.

As shown in fig. 4, 5 and 6, the first air duct member 220 is connected inside the rotary casing 210, and the first air duct member 220 is respectively communicated with the air outlet 211 and the first side air inlet 212, so that the air entering from the first side air inlet 212 is blown out from the air outlet 211 through the first air duct member 220.

As shown in fig. 4, the first fan 230 is disposed in the first air duct member 220 to blow the air sucked from the first side air inlet 212 to the air outlet 211, and the first fan 230 can provide a driving force for the airflow.

As shown in fig. 4, 5 and 6, the rotation bearing 310 is obliquely installed on the stationary casing 100, so that a rotation center line, which is referred to as a rotation axis 201, can be formed perpendicular to a bearing surface of the rotation bearing 310, and the rotation body 200 can rotate along the rotation axis 201. When the rotation bearing 310 is installed obliquely, the bearing surface thereof forms an included angle with the horizontal plane, and the rotation axis 201 is disposed obliquely with respect to the horizontal plane, in the case that the stationary housing 100 is vertically placed on the horizontal plane, and the rotation plane formed by the rotation of the rotation body 200 is not perpendicular to the horizontal plane, so that the rotation body 200 rotates obliquely with respect to the horizontal plane. Or it may also be understood that the horizontal plane is a reference plane parallel to the ground on which the product is located.

As apparent from the above structure, in the air treatment apparatus 2100 according to the embodiment of the present invention, the rotary casing 210, the first air duct member 220, and the first fan 230 may be simultaneously rotated with respect to the stationary casing 100, so that the rotary body 200 may be generally regarded as an independent part, the stationary casing 100 may provide stable support for the rotation of the rotary body 200, and the height of the rotary body 200 with respect to the ground may be increased, thereby increasing the range of adjustable air flow thereof.

The first side intake vent 212 and the exhaust vent 211 are communicated through the first air duct member 220, and form a predetermined air flow path. When the first fan 230 is operated, the indoor air is rapidly sucked from the first side air inlet 212 and is rapidly discharged to the air outlet 211, so that the air flow passing through the rotating body 200 can be rapidly circulated.

In the present invention, since the rotating body 200 can rotate continuously relative to the fixed casing 100, the air inlet direction of the first side air inlet 212 and the air outlet direction of the air outlet 211 can be changed continuously, so that the inlet air in different directions can flow into the first air duct member 220, and the air in the first air duct member 220 can be blown out in different directions, thereby effectively improving the capability of the rotating body 200 to change the direction of the supplied air.

In the present invention, since the rotation bearing 310 is obliquely installed on the stationary case 100, the rotation axis 201 is obliquely arranged with respect to the horizontal plane, the rotation bearing 310 provides sufficient support for installation of the rotation body 200, and the stationary case 100 provides support for installation of the rotation bearing 310, so that the rotation body 200 can be stably rotated with respect to the stationary case 100 without misalignment. The wind direction of the wind entering from the first side wind inlet 212 after the rotation of the rotating body 200 can be changed continuously; or the air outlet of the air outlet 211 on the rotating body 210 after rotating can be changed in multiple directions such as front, back, left and right, and further the air supply of multiple indoor areas is considered, so that the air can be quickly and uniformly mixed in the whole house.

It can be understood that, compared with the prior art that only part of the housing rotates to change the air outlet direction, the rotating body 200 of the present application can be used as an independent component to continuously and rapidly suck and blow air, does not need to rely on the air supply of the bottom fixed housing 100, and can form rapid and uniform indoor air. Compare in prior art only can be towards the indoor rotatory casing of blowing with high, the rotator 200 of this application can realize that not equidirectional, not co-altitude induced drafts fast and blow, is favorable to promoting the even regulation of indoor air property, and the rotator 200 of this application need not to rely on parts such as wind-guiding tripe, simple structure.

In some embodiments of the present invention, as shown in FIG. 2, the rotating housing 210 is an asymmetric shell. That is, after the rotating casing 210 rotates, the distance between different parts of the rotating casing 210 and the horizontal plane changes differently, so that the height of the first side air inlet 212 relative to the horizontal plane or the height of the first side air inlet relative to the fixed casing 100 changes continuously; the height of the air outlet 211 relative to the horizontal plane or the height of the air outlet 211 relative to the fixed casing 100 can be changed continuously, so that the orientations of the first side air inlet 212 and the air outlet 211 can be changed, the air inlet range and the air inlet flexibility of the rotary casing 210 are greatly improved, and the air supply range and the air supply flexibility of the rotary casing 210 are improved.

Further, as shown in fig. 3, the air outlet 211 is provided at the top of the rotary case 210, and the first side air inlet 212 is provided at the side of the rotary case 210. In these examples, after rotatory shell 210 rotates, the contained angle between the air-out direction of air outlet 211 and the horizontal direction can constantly change, under the asymmetric structure size reasonable in design's of rotatory shell 210 condition, air outlet 211 can rotate first angle at rotatory shell 210, blow towards the top, air outlet 211 still can rotate the second angle at rotatory shell 210, blow towards the lateral part slope, and then reach and rely on rotatory a process and realize the effect that the air-out was commutates simultaneously, shifted simultaneously, need not to rely on the part drive air outlet 211 luffing motion of upper and lower drive. Similarly, after the rotating shell 210 rotates, the included angle between the air intake direction of the first side air intake 212 and the horizontal direction may also be changed continuously, for example, in a specific example, when the rotating shell 210 rotates by a certain angle, the first side air intake 212 draws air horizontally from the side; when the rotary casing 210 rotates to another angle, the first side intake vent 212 slantly sucks air from the side. The air inlet scope and the air outlet scope of the rotating shell 210 of the present application are improved.

Alternatively, as shown in fig. 4, the inclination angle of the bearing surface of the rotational bearing 310 to the horizontal plane is greater than 0 degree and equal to or less than 45 degrees, that is, the inclination angle of the rotation axis 201 to the horizontal plane is greater than or equal to 45 degrees and less than 90 degrees. It is understood that, when the inclination angle of the bearing surface of the rotary bearing 310 to the horizontal plane is greater than 45 degrees, that is, the inclination angle of the rotation axis 201 to the horizontal plane is less than 45 degrees, the rotary body 200 may be inclined to a greater degree with respect to the stationary housing 100 at a certain position during the rotation, easily causing the center of gravity of the entire air processing apparatus 2100 to be unstable. When the inclination angle of the bearing surface of the rotational bearing 310 to the horizontal plane is equal to 0 degree, the bearing surface is parallel to the horizontal plane, that is, when the inclination angle of the rotational axis 201 to the horizontal plane is equal to 90 degrees, the rotational axis 201 is perpendicular to the horizontal plane, so that the rotational housing 210 can only suck air against the air flow within the same height range, and the rotational housing 210 can only blow air against the air flow within the same height range. The angle selected by the present application enables the rotating body 200 to stably rotate relative to the stationary case 100, and is not easily turned over; also make the rotator 200 in the process of rotating for the set casing 100, the air inlet direction of first side air intake 212 and the air-out direction of air outlet 211 can constantly be adjusted in the height scope of difference to only rely on under the condition of rotary motion, and realize promoting by a wide margin of air inlet scope and air-out scope. Here, the inclination of the rotation axis 201 with respect to the horizontal plane in the present application may be an inclination in any direction, for example, an oblique left direction toward the fixed housing 100, an oblique right direction toward the fixed housing 100, an oblique forward direction toward the fixed housing 100, an oblique rearward direction toward the fixed housing 100, or the like. When the inclination angle of the rotation axis 201 and the horizontal plane is greater than 90 degrees and equal to or less than 135 degrees in the same plane, the design direction of the inclination of the rotation axis 201 and the horizontal plane changes, and the present application shall also fall within the protection scope.

For example, in a specific example, when the inclination angle of the rotating bearing 310 to the horizontal plane is 5 degrees, 10 degrees, 20 degrees, 25 degrees, 30 degrees, 35 degrees, or 45 degrees, the inclination angle of the rotating axis 201 to the horizontal plane is 85 degrees, 80 degrees, 70 degrees, 65 degrees, 60 degrees, 55 degrees, or 45 degrees, and the like, which is not limited herein.

In some examples, as shown in fig. 10 and 16, the rotation bearing 310 includes a fixed support 311 and a rotation support 312, the fixed support 311 is provided on the fixed casing 100, as shown in fig. 7, and in some specific examples, the fixed support 311 may be connected to a third mounting bracket 560 of the second air duct member 500 provided in the fixed casing 100 (the structures of the second air duct member 500 and the third mounting bracket 560 will be described in detail later).

As shown in fig. 10 and 16, the plurality of rotation support portions 312 are provided, the plurality of rotation support portions 312 are rotatably provided in the circumferential direction of the fixed support portion 311, each rotation support portion 312 is in rolling connection with the first air duct member 220, so that when the first air duct member 220 rotates relative to the fixed casing 100, the rotation support portions 312 can reduce friction between the first air duct member 220 and the fixed casing 100 (or specifically, the second air duct member 500 connected to the fixed casing 100), and the rotation support portions 312 also enable the first air duct member 220 to stably rotate relative to the fixed casing 100 without shaking.

As shown in fig. 10, the rotation support portion 312 includes a first rotation support portion 3121 and a second rotation support portion 3122, the first rotation axis of the first rotation support portion 3121 is perpendicular to the bearing surface of the fixed support portion 311, that is, the first rotation axis extends along the axial direction of the fixed support portion 311, and as shown in fig. 10, the first rotation support portions 3121 are in rolling contact with the side wall of the first air duct member 220, so that the first air duct member 220 smoothly rotates in the circumferential direction with respect to the fixed support portion 311.

Further, the second rotation shafts of the second rotation supports 3122 are parallel to the bearing surfaces of the fixed support 311, that is, the second rotation shafts extend along the radial direction of the fixed support 311, and these second rotation supports 3122 are in rolling contact with the bottom wall or the top wall of the first air duct member 220, so that the rotation of the rotating body 200 relative to the fixed support 311 can be further performed smoothly in the circumferential direction, and finally the first air duct member 220 drives the rotating shell 210 and the first fan 230 to rotate smoothly relative to the fixed shell 100, and during the rotation, the rotation mainly takes the rotation axis 201 perpendicular to the rotation bearing 310 as the axis, and the rotating body 200 can be positioned relative to the fixed shell 100, so as to reduce the friction force.

Alternatively, the rotation supporting portion 312 is a rollable bearing body, a roller or a ball, and is not particularly limited as long as the rotation supporting portion 312 can be rollably supported between the fixed supporting portion 311 and the first air duct member 220, and the rotation supporting portion 312 is rotatably connected to the fixed supporting portion 311. For example, in a specific example, the bearing body and the roller may be connected to the fixed support portion 311 through a rotating shaft, and the ball may be disposed in the groove of the fixed support portion 311.

Advantageously, in order to reduce the weight of the rotary bearing 310, the rotary bearing 310 may be designed to have a circular cross-section, and at the same time, it is convenient to avoid other components (for example, in a specific example, the second air duct member 500 and the second fan 700 mounted on the second air duct member 500 may be avoided).

Of course, in other examples, the rotary bearing 310 of the present invention is not limited to the form of the rotary support portion 312 and the fixed support portion 311, and other common bearings such as ball bearings may be used as the rotary bearing 310.

Alternatively, in order to enable the air processing apparatus 2100 to automatically rotate, as shown in fig. 7, the air processing apparatus 2100 further includes a rotation driving mechanism 320, the rotation driving mechanism 320 drives the rotating body 200 to rotate relative to the fixed casing 100, the whole air processing apparatus 2100 can be more intelligent through the rotation driving mechanism 320, the rotation process and the rotation angle of the rotating body 200 can be further controlled, and convenience in rotation control of the rotating body 200 is improved.

Alternatively, the rotation driving mechanism 320 includes a rotation driving motor 321, a first gear 322 and a gear ring 323, an output end of the rotation driving motor 321 is connected to the first gear 322, the first gear 322 is engaged with the gear ring 323, one end of the rotation driving motor 321 is fixed to the lower fixed casing 100 and other components, the gear ring 323 is designed on the first air channel member 220, and the rotary casing 210 is connected to the first air channel member 220, so that during the rotation of the rotation driving motor 321, the first gear 322 and the gear ring 323 are sequentially driven, thereby realizing the simultaneous rotation of the first air channel member 220 and the rotary casing 210 relative to the fixed casing 100.

In other examples, the ring gear 323 may be designed on the rotating case 210 instead of the first air duct member 220, which is not particularly limited herein. In these examples, the rotation driving motor 321 is disposed flexibly, and is not required to be disposed at the center of the first air duct member 220, so that the layout of each component inside the rotating body 200 can be more reasonable and compact. Further, by providing the first gear 322 and the ring gear 323 for the transmission driving, the driving force output from the rotation driving motor 321 can be effectively controlled, and thus the rotation angle and the rotation progress of the rotating body 200 can be more easily controlled.

In other embodiments, the aforementioned gear ring 323 may be replaced by an arc-shaped rack, the arc-shaped rack is engaged with the first gear 322, and the arc-shaped rack may be designed on the first air channel member 220 or the rotating shell 210, so that when the rotation driving motor 321 works, the first air channel member 220 and the rotating shell 210 are driven to rotate relative to the fixed shell 100.

In other examples, the aforementioned first gear 322, the gear ring 323, and the like may be omitted, and only the rotation driving motor 321 may be provided, and an output shaft of the rotation driving motor 321 is connected to a middle portion of the first air duct member 220 to drive the first air duct member 220.

In some embodiments of the present invention, as shown in FIG. 7, the air treatment apparatus 2100 further comprises a barrier 400, the barrier 400 being movable relative to the first air duct member 220 to open or close the first side air intake vent 212. It should be noted that the stopper 400 may be, for example, in a form of translation, rotation, or the like, or may be a combination of the translation and the rotation, as long as the stopper 400 can move relative to the first air duct member 220, and the working state of the stopper 400 is not particularly limited herein, as long as the first side air inlet 212 can be opened or closed.

The fixed casing 100 is provided with the air inlet 110, when the blocking member 400 closes the first side air inlet 212, the air inlet 110 is communicated with the air outlet 211, and at this time, the air inlet position and the air inlet and outlet circulation path of the air treatment device 2100 are changed, so that the air treatment device 2100 switches the working mode. Since the distance between the first side intake port 212 and the outlet port 211 is closer than the distance between the intake port 110 and the outlet port 211, the circulation path between the first side intake port 212 and the outlet port 211 is shorter than the circulation path between the intake port 110 and the outlet port 211. Meanwhile, the first side air inlet 212 is disposed on the rotating body 200, and the air inlet 110 is disposed on the stationary housing 100, so that the air inlets of the two paths are separated by a relatively large distance, which is beneficial to further increase the effective air inlet range and the air inlet amount of the air processing apparatus 2100, and the air inlets of the first side air inlet 212 and the air inlet 110 are not interfered with each other.

When the stopper 400 opens the first side inlet 212, the inlet 110 and the first side inlet 212 are respectively communicated with the outlet 211, and the air handling device 2100 has a longer air inlet and outlet path and a shorter air inlet and outlet path, and the air handling device 2100 is switched to another operation mode.

Alternatively, the stopper 400 may be movable up and down with respect to the stationary casing 100, and when the stopper 400 closes the first side air inlet 212, at least a portion of the stopper 400 is located between the rotating casing 210 and the first air duct member 220. At this time, the blocking member 400 can prevent the air from entering the channel of the first air duct member 220 from the first side air inlet 212, so that the air cannot enter the first air duct member 220, and the short air inlet and outlet path between the first side air inlet 212 and the air outlet 211 is cut off, and at this time, only the long air inlet and outlet path formed between the air inlet 110 and the air outlet 211 remains. In addition, when the blocking member 400 is located between the rotating shell 210 and the first air duct member 220, a certain flow guiding effect can be formed on the flowing wind, so that the wind energy flowing upwards in the wind inlet 110 can be quickly guided to the wind outlet 211, the sealing performance is good, and the wind outlet efficiency is high.

Further, referring to fig. 5 and 6 again, when the stopper 400 opens the first side air inlet 212, the stopper 400 is received in the fixed casing 100, and at this time, the stopper 400 does not occupy the rotation space of the rotating body 200, and when the rotating body 200 rotates relative to the fixed casing 100, the stopper 400 is not obstructed, which is also beneficial to reducing the weight of the rotating body 200 and saving the driving force of the rotation driving mechanism 320. In these examples, the shorter air inlet and outlet path between the first side air inlet 212 and the air outlet 211 is communicated with the longer air inlet and outlet path between the air inlet 110 and the air outlet 211, so as to realize smooth switching of the mode of the air treatment device 2100.

In other examples, the stopper 400 is still located in the rotating body 200 when the first side air inlet 212 is opened, and is not particularly limited herein.

Advantageously, as shown in fig. 6 and 7, the second side intake vent 120 is provided at a side of the stationary housing 100 adjacent to the rotary housing 210, and as shown in fig. 5, the stopper 400 may open or close both the first side intake vent 212 and the second side intake vent 120. By providing the second side air inlet 120, the air inlet path of the air handling device 2100 may be further increased, so that the air inlet range of the air handling device 2100 may be wider and the air inlet mode may be more flexible. Since the second side intake vent 120 is closer to the rotary case 210, an air inlet and outlet path formed between the second side intake vent 120 and the outlet vent 211 is shorter than an air inlet and outlet path formed between the intake vent 110 and the outlet vent 211. When the first side air inlet 212 and the second side air inlet 120 cooperate, the efficiency of the rotary body 200 for performing multi-directional quick air exchange is greatly improved. For example, as shown in fig. 5, when the first side air inlet 212 and the second side air inlet 120 are located on the same side, the first side air inlet 212, the second side air inlet 120 and the air outlet 211 jointly form air inlet with approximately the same direction, so that the air inlet area and the air inlet efficiency of one side of the air processing device 2100 are improved, and the air processing device 2100 is favorable for being matched with other devices to perform wind relay. Meanwhile, in these examples, the air handling device 2100 may implement the wind relay mode when the first side intake vent 212 and the second side intake vent 120 are both located on the same side.

Optionally, as shown in fig. 6 and 7, the air treatment apparatus 2100 further includes a second air duct member 500, the second air duct member 500 is connected in the stationary casing 100, and the second air duct member 500 is communicated with the air inlet 110, the air outlet 211, the first side air outlet 211, and the second side air inlet 120, respectively. In these examples, the second air duct 500 is used as an intermediate air duct, which can guide the wind from the wind inlet 110 to the wind outlet 211 and control the wind direction, and also can provide necessary support for other components.

For example, in a specific example, as shown in fig. 7, a first mounting rack 540 is provided on the second air duct member 500 on a side facing the first air duct member 220, and the first mounting rack 540 can be used for mounting the rotation driving motor 321 in the previous example, so that the rotation driving motor 321 is reliably supported.

Alternatively, as shown in fig. 8, 9 and 10, the first air duct member 220 is provided with a first rib 221 at the periphery thereof, where the first rib 221 can block the air inlet and outlet path in the rotating body 200 from the circumferential direction of the air inlet and outlet path in the stationary casing 100.

The second air duct member 500 is provided with a second blocking edge 510 at the periphery thereof, and the second blocking edge 510 therein can block the circumferential portion of the air inlet/outlet path in the stationary casing 100 from the air inlet/outlet path of the rotating body 200, so that the air inlet/outlet is more concentrated and the air outlet path is prevented from being interfered. The first rib 221 also facilitates to form a certain supporting cooperation with the second rib 510, so as to ensure that the first air duct member 220 stably rotates relative to the second air duct member 500.

Further, when the first air duct member 220 rotates relative to the second air duct member 500, at least a portion of the first rib 221 and the second rib 510 are overlapped, so that the second rib 510 can always support the first rib 221 during the rotation of the first air duct member 220, thereby improving the stability of the rotation of the first air duct member 220.

Advantageously, as shown in fig. 7 and 8, the first rib 221 is provided with a first through slot 2211, and the second rib 510 is provided with a second through slot 520. When the first air duct member 220 is rotated relative to the second air duct member 500, the first through slot 2211 may be offset from the second through slot 520 and the first through slot 2211 may also be aligned with the second through slot 520.

In some specific examples, the first rib 221 and the second rib 510 are both formed as axisymmetrical polygons, so that the first rib 221 can be completely overlapped only after being rotated 180 degrees with respect to the second rib 510; for example, when the rotating body 200 is at 0 degree with respect to the stationary housing 100, the first rib 221 and the second rib 510 are overlapped, and the first through groove 2211 and the second through groove 520 are aligned up and down, the stopper 400 can move with respect to the rotating body 200; when the rotating body 200 is at 180 degrees with respect to the stationary housing 100, the first rib 221 and the second rib 510 can be completely overlapped again, but at this time, the first through groove 2211 and the second through groove 520 are staggered with each other, and the stopper 400 cannot move with respect to the rotating body 200. Thus, the angle that the air treatment apparatus 2100 needs to be rotated when switching modes is made more definite.

In other specific examples, the first rib 221 and the second rib 510 are both formed in a circular shape with central symmetry, so that the first rib 221 may be stacked all the time during the rotation process with respect to the second rib 510, and only the first through groove 2211 and the second through groove 520 may be staggered or aligned during the rotation process, thereby enabling the rotation of the rotating body 200 to be more flexible and enabling the appearance of the rotating body 200 to be beautiful after the rotation.

Optionally, as shown in fig. 7 and 8, the first air duct member 220 is provided with a first communicating opening 222 communicated with the first side air inlet 212, and the first communicating opening 222 is provided on the side wall of the first air duct member 220 near the first rib 221, so that the first communicating opening 222 can be directly opposite to the first side air inlet 212 on the rotating casing 210 at a certain time, and it is ensured that the path of the air entering the first communicating opening 222 from the first side air inlet 212 is short, and better air inlet efficiency is ensured. It is also convenient for the blocking member 400 to block the path between the first side intake vent 212 and the first communication port 222 and close the intake air of the first side intake vent 212.

As shown in fig. 7 and 11, when the first through slot 2211 and the second through slot 520 are parallel to each other, the first through slot 2211 may also be aligned with the second through slot 520, and the stopper 400 covers the first communication port 222 through the second through slot 520 and the first through slot 2211. The first through groove 2211 and the second through groove 520 can both move away from the stopper 400, and provide guidance and path limitation for the movement of the stopper 400, so that the stopper 400 can rapidly move to between the rotating shell 210 and the first air duct member 220 according to a preset path, and further, the first side air inlet 212 and the first communication port 222 can be effectively blocked while the communication port 222 is effectively shielded. The stopper 400 is located at the inner side of the rotating case 210 or the stationary case 100 at all times during the movement, which improves the aesthetic appearance of the air treatment apparatus 2100.

Further, as shown in fig. 6 and 7, the first air duct member 220 is provided with a second communication port 223 communicating with the air outlet 211, and the second communication port 223 is provided at the top of the first air duct member 220. In these examples, the second communication port 223 may be aligned with the air outlet 211, and the wind resistance therebetween is small, so that the wind outlet efficiency of the rotating body 200 is high.

Alternatively, as shown in fig. 4, 5, and 6, the first fan 230 is provided at the second communication port 223 so that the wind in the rotating body 200 can be quickly blown out toward the wind outlet 211 when the first fan 230 rotates.

Specifically, the first fan 230 includes a first motor 231 and a first impeller 232, the first motor 231 is fixed on the first air duct member 220, an output shaft of the first motor 231 is connected to the first impeller 232, and when the first motor 231 rotates, the first impeller 232 can be driven to rapidly rotate and exhaust air towards the air outlet 211. In these examples, since the first fan 230 is closer to the air outlet 211, it has priority to exhaust the air flow in the shorter air inlet and outlet path, that is, the air flowing from the first side air inlet 212 to the air outlet 211 in the foregoing examples can be driven to flow by the first fan 230 preferentially and rapidly; the wind flowing from the second side wind inlet 120 to the wind outlet 211 in the above examples may also be driven by the first fan 230 to flow; while the air inlet 110 in the foregoing examples flows into the air outlet 211, the driving force of the first fan 230 is weaker.

Optionally, the first fan 230 is an axial flow fan or a centrifugal fan, so that the wind energy in the first side wind inlet 212 can be discharged to the wind outlet 211 quickly.

Alternatively, as shown in fig. 6, 7 and 10, the second air duct member 500 is provided with a third communication port 530 communicating with the second side air inlet 120, and the stopper 400 shields the third communication port 530 while shielding the first communication port 222. Then, in these examples, the third communication port 530 may be disposed opposite to the second side intake vent 120, so that the intake air between the second side intake vent 120 and the third communication port 530 is fast and the efficiency is guaranteed; but also ensures that the stopper 400 moves inside the fixing case 100, and improves the integrity and the aesthetic property of the outside of the fixing case 100. The blocking member 400 can control whether the first side air inlet 212 enters air or not and whether the second side air inlet 120 enters air or not at the same time, and the blocking member 400 has various functions, thereby saving the number of components required to be arranged due to the need of closing the first side air inlet 212 and the second side air inlet 120.

Alternatively, the cross section of the blocking member 400 is circular, as shown in fig. 4 and 7, the side wall of the blocking member 400 for shielding the third communicating opening 530 is higher than the side wall for shielding the first communicating opening 222, so that when the rotating body 200 rotates to make the first communicating opening 222 and the third communicating opening 530 respectively located at two sides, after the blocking member 400 moves upwards, the lower end of the blocking member 400 can shield the first communicating opening 222 which is rotated in place, and the higher end of the blocking member 400 can shield the third communicating opening 530 which is rotated in place, so that both the first side air inlet 212 of the rotating body 200 which rotates obliquely and the second side air inlet 120 of the fixed casing 100 can be closed by the blocking member 400.

Of course, in other examples, it is not limited to simultaneously shielding two communication ports after one stopper 400 moves, for example, in a specific example, a plurality of stoppers 400 may be provided to respectively shield the third communication port 530 and the first communication port 222, so that the stoppers 400 respectively shield the first side air inlet 212 and the second side air inlet 120.

Alternatively, the stopper 400 may be disposed between the fixed casing 100 and the second air duct member 500 to be movable up and down, so that the stopper 400 is always located in the fixed casing 100 during the movement, and the stopper 400 does not interfere with the flow of the air in the second air duct member 500.

Further, as shown in fig. 7, the air treatment apparatus 2100 further includes a third air duct member 1000, the third air duct member 1000 is connected to the lower side of the second air duct member 500, and the peripheral side of the third air duct member 1000 is connected to the fixing shell 100 (for example, the third air duct member 1000 may be connected to the fixing shell 100 by bolts or connected to the fixing shell 100 by welding), and the third air duct member 1000 may support the second air duct member 500 and guide the wind in the wind inlet 110 into the second air duct member 500, so as to define an airflow path from the wind in the wind inlet 110 into the second air duct member 500, and to make the arrangement of the second air duct member 500 more stable. The blocking member 400 in the previous example may be further disposed in the gap formed between the third air duct member 1000, the second air duct member 500 and the fixed casing 100.

Optionally, as shown in fig. 7, 12 and 13, the air processing apparatus 2100 further includes a lifting driving mechanism 600, one end of the lifting driving mechanism 600 is connected to the fixing housing 100, and the lifting driving mechanism 600 drives the stopper 400 to move up and down, so that the movement of the stopper 400 is more intelligent and the moving position is more precise and controllable.

Optionally, as shown in fig. 7, the lifting driving mechanism 600 includes a lifting driving motor 610, a second gear 620, a rack 630 and a fourth mounting frame 640, the fourth mounting frame 640 may be mounted on the third air duct member 1000, the lifting driving motor 610 is fixedly connected to the fourth mounting frame 640, an output end of the lifting driving motor 610 is connected to the second gear 620, the second gear 620 is engaged with the rack 630, and an output end of the rack 630 is connected to the stopper 400, so that the lifting position of the stopper 400 can be effectively controlled by controlling the rotation of the lifting driving motor 610, and the stopper 400 is controlled to open the third communicating port 530 and the first communicating port 222 in time, or the stopper 400 is controlled to shield the third communicating port 530 and the first communicating port 222 in time, thereby facilitating the accurate replacement of the operation mode of the air treatment apparatus 2100.

In the description of the invention, features defined as "first", "second", "third" and "fourth" may explicitly or implicitly include one or more of the features for distinguishing between the described features, whether sequential or not.

Advantageously, as shown in fig. 7, a plurality of supporting plates 410 are disposed on the outer wall perpendicular to the stopper 400, and a plurality of sets of lifting driving mechanisms 600 are correspondingly disposed, each set of lifting driving mechanism 600 correspondingly drives one supporting plate 410, and the sets of lifting driving mechanisms 600 cooperate with each other to improve the stability of the lifting movement of the stopper 400. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

Advantageously, in order to improve the air outlet performance of the long air inlet and outlet path formed between the air inlet 110 and the air outlet 211 after the first side air inlet 212 and the second side air inlet 120 of the air treatment device 2100 are shielded, the air treatment device 2100 further includes a second fan 700, the second fan 700 is disposed in the second air duct member 500, and when the second fan 700 is operated, the second fan 700 can provide a large air inducing capacity, so that the wind energy in the air inlet 110 can be effectively discharged towards the air outlet 211.

Of course, the second fan 700 and the first fan 230 of the present application work simultaneously, and the first side air inlet 212 and the second side air inlet 120 are in the open state, the air processing apparatus 2100 may have both the air outlet in the longer air inlet and outlet path and the air outlet in the shorter air inlet and outlet path.

Optionally, the second fan 700 is a centrifugal fan or an oblique flow fan, which is beneficial to quickly divert the wind sucked in the wind inlet 110 and blow out from the wind outlet 211 at the top. In some examples, the centrifugal fan selects a rear centrifugal fan that enhances the induced air capability of the second fan 700.

In a specific example, the second fan 700 includes a second motor 710 and a second impeller 720, as shown in fig. 7, a second mounting frame 550 is disposed on the second air duct 500, the second mounting frame 550 is located in the middle of the second air duct 500 and is connected to the side portion of the second air duct 500 through a plurality of supporting plates 410, so that wind energy passes through the second air duct 500 from top to bottom, the second motor 710 can be mounted in the second mounting frame 550, the output end of the second motor 710 is connected to the second impeller 720, and a portion of the second impeller 720 can extend into the third air duct 1000, so that the wind force of the second fan 700 can better drive the wind in the third air duct 1000 to flow.

Optionally, as shown in fig. 7, a third mounting rack 560 is further disposed on the second air duct member 500, the third mounting rack 560 is disposed around the circumference of the second mounting rack 550, and the rotary bearing 310 in the previous example can be mounted on the third mounting rack 560, so that the rotary bearing 310 can be effectively fixed.

In some embodiments of the present invention, as shown in fig. 7, the air treatment apparatus 2100 further includes an air treatment module 800, and the air treatment module 800 is disposed in the stationary housing 100 near the inlet 110, so that wind discharged toward the outlet 211 via the inlet 110 can be treated by the air treatment module 800, and the quality of air discharged from the outlet 211 is improved. Since the air treatment apparatus 2100 disposed at the wind inlet 110 may generate a certain wind resistance to the wind flowing from the wind inlet 110, the air treatment module 800 needs to cooperate with the second fan 700, so that the wind energy from the wind inlet 110 is effectively processed by the air treatment module 800 and then enters the stationary housing 100 and the rotating body 200.

Alternatively, as shown in fig. 7, the air treatment apparatus 2100 includes a purification unit 810 and a fixing frame 820, the fixing frame 820 is connected in the fixing housing 100, and the purification unit 810 is further disposed in the fixing frame 820, so that the position of the purification unit 810 relative to the intake vent 110 is fixed.

Optionally, as shown in fig. 7, a plurality of air inlets 110 are formed in the fixing casing 100, a plurality of mounting holes are formed in the fixing frame 820 corresponding to the air inlets 110, and a clamping pin 821 is further disposed at each mounting hole of the fixing frame 820, so that the purifying elements 810 can be limited at the mounting holes, and each purifying element 810 is ensured to be stably mounted and will not be inclined under the action of the second fan 700.

Optionally, the purifying member 810 may be a filter screen assembly, or may also be a filter element, which is not limited specifically herein, the purifying member 810 may improve the cleanliness of air, and when the second fan 700 operates, the cleanliness of the air discharged from the air outlet 211 is high, so that the air processing apparatus 2100 of the present application enters a purifying mode.

For another example, the purifying member 810 may further include a formaldehyde removing member and a particulate adsorbing member, so that formaldehyde and particulate matters can be removed in a targeted manner.

Alternatively, the purifying member 810 may be replaced with a humidifying member, a fragrance member, or the like, so that the humidity and the taste of the wind blown out from the outlet 211 can be effectively adjusted.

Alternatively, as shown in fig. 7, the fixing case 100 includes a first fixing case 130 and a second fixing case 140, wherein the second fixing case 140 is disposed corresponding to the air treatment module 800, the first fixing case 130 is disposed corresponding to the second air duct member 500 and the third air duct member 1000, the first fixing case 130 is connected to an upper portion of the second fixing case 140, and the fixing case 100 has a complete structure and a certain height.

Alternatively, the top of the first stationary case 130 forms an inclined interface to rotatably cooperate with the rotating case 210 to form a complete outer case without a gap when the rotating case 210 is rotated to a specific position.

Optionally, four sets of air inlets 110 are disposed on the side wall of the second fixing case 140, and each air inlet 110 includes a plurality of air inlet holes, so that the air inlets 110 have a certain impurity trapping capability, and the cleanliness of the air entering the air treatment module 800 is improved. For example, reliable entrapment of matter such as hair can be achieved.

In some embodiments of the present invention, as shown in fig. 7, the air treatment device 2100 further includes a mobile chassis 900, and the fixed housing 100, the air treatment module 800, and other components are connected to the mobile chassis 900, so that the mobile chassis 900 can move along with the air treatment device 2100, thereby improving the flexibility and intelligence of the movement of the air treatment device 2100, and enabling the air treatment device 2100 to move to more positions in a room to treat wind.

Optionally, a traveling wheel assembly is provided on the moving chassis 900 so that the moving chassis 900 can smoothly travel.

Optionally, a positioning detector is further disposed on the mobile chassis 900, and the positioning detector is configured to detect a position of the mobile chassis 900, and position the mobile chassis 900 relative to a certain space, so as to improve the intelligence of the mobile chassis 900 in movement.

For example, the positioning detector includes an infrared ranging sensor, a laser ranging sensor, or an ultrasonic ranging sensor, which is not particularly limited herein. For example, in a specific example, the positioning detector employs two infrared distance measuring sensors, and the two infrared distance measuring sensors are assembled on the side surface of the mobile machine body, so that the reliability of obstacle avoidance of the mobile chassis 900 during the advancing process is effectively improved.

For another example, a laser ranging sensor is disposed at the rear side of the mobile body, so that ranging and positioning during recharging of the mobile chassis 900 are facilitated.

Optionally, a battery pack is disposed in the mobile chassis 900, so that certain electric energy can be stored for each component in the mobile chassis 900.

The air conditioner 2000 according to the embodiment of the present invention is described below with reference to the drawings, and the air conditioner 2000 according to the present invention can achieve effective adjustment of the physicochemical properties of the air, such as adjustment of the temperature of the air, cleanliness of the air, and humidity or taste of the air.

An air conditioner 2000 according to an embodiment of the present invention, as shown in fig. 14 and 15, includes: the air conditioner host 2200 and the air processing device 2100, the air processing device 2100 is the air processing device 2100 in any of the previous examples, and the structure of the air processing device 2100 is not described herein in detail.

The air conditioner main unit 2200 is provided with a heat exchange module, and air subjected to heat exchange by the heat exchange module is blown out of the air conditioner main unit 2200, so that the temperature of indoor air can be rapidly adjusted, for example, in the heating mode, the air conditioner main unit 2200 can blow the heated indoor air into the room again; in the cooling mode, the main air conditioner 2200 may cool the air in the room and then blow the air toward the room again.

As shown in fig. 14 and 15, the air treatment apparatus 2100 is separately provided to the air conditioner main unit 2200, and the air treatment apparatus 2100 may be independently operated with respect to the air conditioner main unit 2200. Then, the air treatment device 2100 may adjust its position relative to the main air conditioner 2200 and then start operating its internal components, such as the aforementioned cleaning mode and/or the wind relay mode.

As can be seen from the above structure, in the air conditioner 2000 according to the embodiment of the present invention, when the air after heat exchange in the air conditioner host 2200 is blown out, the air processing device 2100 located within the blowing range of the air conditioner host 2200 can suck the air blown out by the air conditioner host 2200 and blow the air quickly toward different directions, so that the wind energy of the air conditioner host 2200 is blown toward more directions, the heat exchange is performed quickly for the whole house, the dead angle of the heat exchange is reduced, and the heat exchange is uniform for the whole house. Meanwhile, the air handling device 2100 and the air conditioner host 2200 are used together to form a wind force, so that the wind after heat exchange in the air conditioner host 2200 can be blown to a farther place, and the air supply range of the air conditioner host 2200 is widened.

Specifically, as shown in fig. 4, when the air processing apparatus 2100 is in the aforementioned air purification mode, the blocking member 400 simultaneously blocks the first side air inlet 212 and the second side air inlet 120, the second fan 700 is turned on, and the first fan 230 is optionally turned on or off, so that air can only be blown out from the air inlet 110 toward the air outlet 211 after passing through the air processing module 800, and then the air of the main air conditioner 2200 is purified and blown to the whole house, so that the air quality of the whole house is cleaner.

As shown in fig. 5, when the air processing apparatus 2100 is in the aforementioned wind relay mode, the blocking member 400 opens the first side air inlet 212 and the second side air inlet 120, only the first fan 230 is turned on, and the second fan 700 is turned off, so that the air at this time can enter the first air duct member 220 from the first side air inlet 212 and the second side air inlet 120 and be guided out toward the air outlet 211, and the air of the main air conditioner 2200 is guided to a further position, and the wind relay of the main air conditioner 2200 is sent out, so that directional air supply toward a specific area can be formed, and further, local airflow can be adjusted quickly. When the rotating body 200 rotates relative to the stationary casing 100, air supply in a plurality of directions is formed, which is advantageous for efficient air supply of the whole house.

As shown in fig. 6, the air processing apparatus 2100 may be in an air relay mode and a cleaning mode at the same time, the blocking member 400 opens the first side air inlet 212 and the second side air inlet 120, the first fan 230 is turned on, and the second fan 700 is also turned on, at this time, air may enter the first air duct member 220 from the first side air inlet 212 and the second side air inlet 120 and be led out toward the air outlet 211, so as to guide the air of the main air conditioner 2200 to a further position, and send the air of the main air conditioner 2200 outwards; air can also be blown out from the air inlet 110 to the air outlet 211 after passing through the air treatment module 800, so that the air of the air conditioner host 2200 is cleaned and then blown to the whole house, and the air quality of the whole house is cleaner.

The air conditioner 2000 of the present invention can satisfy various air temperature requirements and quality requirements of users.

Alternatively, the air treatment device 2100 may be detachably connected to the air conditioner host 2200, the connection manner between the air treatment device 2100 and the air conditioner host 2200 may be determined according to actual conditions, and the air treatment device 2100 may be connected to the inside of the air conditioner host 2200 or may be connected to the outside of the air conditioner host 2200. For example, in the specific example, as shown in fig. 15, the air conditioner host 2200 has a docking bay 2210, and the air treatment device 2100 may be automatically entered into the docking bay 2210 by a positioning recognition system, enabling the integration of the air treatment device 2100 with respect to the air conditioner host 2200. The air treatment device 2100 and the air conditioner host 2200 can be communicated with each other or independent from each other, so that the air treatment device 2100 and the air conditioner host 2200 can not affect the heat exchange effect of the heat exchange module when being combined with or separated from each other, and the heat exchange stability of the whole air conditioner 2000 is ensured.

Optionally, a receiving cavity is formed in the docking pod 2210, the shape of which is adapted to the shape of the air treatment apparatus 2100, i.e., in a non-operational state, such that the air treatment apparatus 2100 is entirely received within the receiving cavity. Of course, it is also possible to make part of the air processing device 2100 be located inside the receiving cavity, and part be located outside the receiving cavity, that is, part be exposed to the main air conditioner 2200. By disposing the air treatment device 2100 at least partially within the receiving cavity of the air conditioner host 2200, it is easier to maintain the overall consistency of the air treatment device 2100 and the air conditioner host 2200 after the connection, compared to the case where the air treatment device 2100 is integrally spliced with the air conditioner host 2200, thereby improving the user experience.

Alternatively, the specific connection structure between the air processing device 2100 and the air conditioner host 2200 may be a snap connection, a magnetic connection, or a plug connection.

After the air processing device 2100 is separated from the air conditioner host 2200, the air processing device 2100 may move indoors relative to the air conditioner host 2200 to meet different air conditioning requirements of the indoor, for example, when the air conditioner host 2200 exchanges heat with a space of a certain indoor area, the air processing device 2100 may relay air supply to other indoor areas, so that the air of other areas can also be exchanged heat quickly, and the air heat exchange conditioning range is enlarged; or when the air-conditioning host 2200 is not started, the air processing device 2100 independently supplies air for adjustment, so as to play a role in independently adjusting air; or when a plurality of people gather in the indoor area, the air supply can be realized in a long distance, fixed point and orientation way, and the air treatment effect is improved.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Two lift drive mechanisms 600 are shown in fig. 7 for illustrative purposes, but it will be apparent to one of ordinary skill after reading the above disclosure that it is within the scope of the present invention to apply this configuration to other numbers of lift drive mechanisms 600.

The heat exchange principle of the heat exchange module of the air treatment apparatus 2100 and the air conditioner 2000 having the same according to the embodiment of the present invention and the operation principle of the fan are well known to those skilled in the art and will not be described in detail herein.

In the description herein, references to the description of the terms "embodiment," "example," 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 do not necessarily 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.

While embodiments of the 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 (18)

1. An air treatment device, comprising: the rotating body is rotatably connected to the fixed shell through the rotating bearing, and the rotating bearing is obliquely arranged on the fixed shell;

the rotating body includes:

the rotary shell is provided with an air outlet and a first side air inlet at intervals;

the first air channel piece is connected in the rotating shell and is respectively communicated with the air outlet and the first side air inlet;

and the first fan is arranged in the first air channel piece so as to blow the air sucked from the first side air inlet to the air outlet.

2. The air treatment apparatus of claim 1, wherein the rotating housing is an asymmetric housing, the air outlet is disposed at a top portion of the rotating housing, and the first side air inlet is disposed at a side portion of the rotating housing.

3. The air treatment apparatus according to claim 1, wherein an inclination angle of a bearing surface of the rotary bearing to the horizontal plane is greater than 0 degrees and 45 degrees or less.

4. The air treatment apparatus according to claim 1, further comprising a rotational drive mechanism that rotates the rotating body relative to the stationary housing.

5. The air treatment apparatus according to claim 4, wherein the rotary drive mechanism includes a rotary drive motor, a first gear, and a ring gear, the rotary drive motor being connected to the stationary housing, an output of the rotary drive motor being connected to the first gear, the ring gear being connected to the first air duct member, the first gear being engaged with the ring gear.

6. The air treatment device according to claim 1, further comprising a stopper, wherein the stopper is movable relative to the first air duct member to open or close the first side air inlet, an air inlet is provided in the stationary housing, and the air inlet communicates with the air outlet when the stopper closes the first side air inlet; when the first side air inlet is opened by the blocking piece, the air inlet and the first side air inlet are respectively communicated with the air outlet.

7. The air treatment apparatus according to claim 6, wherein said stopper is movable up and down with respect to said stationary housing, at least a portion of said stopper being positioned between said rotating housing and said first air duct member when said stopper closes said first side air inlet; when the first side air inlet is opened by the blocking piece, the blocking piece is accommodated in the fixed shell.

8. The air treatment apparatus according to claim 7, wherein a second side air inlet is provided at a side of the stationary housing adjacent to the rotary housing, and the stopper opens or closes the first side air inlet and the second side air inlet simultaneously.

9. The air treatment device according to claim 8, further comprising a second air duct member connected within the stationary housing, the second air duct member communicating with the air inlet, the air outlet, the first side air outlet, and the second side air inlet, respectively.

10. The air treatment device according to claim 9, wherein the first air duct member has a first rim on a periphery thereof and the second air duct member has a second rim on a periphery thereof, and wherein at least a portion of the first rim overlaps the second rim when the first air duct member rotates relative to the second air duct member.

11. The air treatment device according to claim 10, wherein the first air duct member is provided with a first communication port communicated with the first side air inlet, and the first communication port is provided on a side wall of the first air duct member adjacent to the first rib; and a second communication port communicated with the air outlet is arranged on the first air channel piece, and the second communication port is arranged at the top of the first air channel piece.

12. The air treatment device according to claim 11, wherein a first through slot is provided on the first rib, a second through slot is provided on the second rib, and when the first through slot and the second through slot are parallel to each other, the blocking member shields the first communication port through the second through slot and the first through slot.

13. The air treatment apparatus according to claim 12, wherein the second air duct member is provided with a third communication port communicating with the second side air inlet, and the blocking member blocks the third communication port while blocking the first communication port.

14. The air treatment apparatus according to claim 13, wherein said stopper is provided between said stationary case and said second air duct member so as to be movable up and down.

15. The air treatment device according to claim 6, further comprising a lifting driving mechanism, wherein one end of the lifting driving mechanism is connected to the fixed shell, and the lifting driving mechanism drives the stopper to move up and down.

16. The air treatment apparatus of claim 9, further comprising a second fan disposed within the second air duct member.

17. The air treatment apparatus of claim 6, further comprising an air treatment module disposed in the stationary housing proximate the air intake.

18. An air conditioner, comprising:

the air conditioner main machine is provided with a heat exchange module, and air subjected to heat exchange by the heat exchange module is blown out of the air conditioner main machine;

an air treatment device according to any one of claims 1-17; the air treatment equipment is separately arranged on the air conditioner host, and the air treatment equipment can independently work relative to the air conditioner host.

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