CN216716498U - Air treatment device - Google Patents

Abstract

The utility model discloses an air treatment device, which comprises a top cover, a side plate and a bottom plate, wherein the top cover, the side plate and the bottom plate are mutually enclosed to form a machine shell, an upper air duct and a lower air duct which are mutually spaced are formed in the machine shell, the upper air duct is provided with a first air treatment module, and the lower air duct is provided with a second air treatment module; the upper air duct comprises an air inlet cavity and a fan installation cavity; the shell comprises a first air inlet, a first air outlet, a second air inlet and a second air outlet, wherein the first air inlet is arranged on the side plate and communicated with the air inlet cavity; the first air outlet is arranged on the top cover and communicated with the fan installation cavity; the second air inlet is formed in the side plate and communicated with the lower air duct; the second air outlet is arranged on the top cover and/or the side plate and is communicated with the lower air duct; an axial flow fan is arranged in the fan mounting cavity, a first air inlet side of the axial flow fan is communicated with the air inlet cavity, and a first air outlet side of the axial flow fan is communicated with the first air outlet. The air treatment device can realize multiple air treatment functions, simultaneously increases the total air output and improves the air treatment effect.

Description

Air treatment device

Technical Field

The utility model relates to the technical field of air treatment, in particular to an air treatment device.

Background

The air treatment device is used for purifying or disinfecting air and the like. In the related art, an air duct is formed in a housing of an air processing apparatus, and a plurality of air processing modules and a fan assembly for driving air flows to sequentially flow through the plurality of air processing modules are disposed in the air duct. However, since the air treatment device is only provided with one air duct and the fan assembly is arranged in the air duct, the total air intake of the air treatment device is relatively small, and the air flow in the air duct sequentially passes through the plurality of air treatment modules and also causes certain air volume loss, so that the total air output of the air treatment device is finally small, and the air treatment effect of the air treatment device is poor.

The above is only for the purpose of assisting understanding of the technical solution of the present invention, and does not represent an admission that the above is the prior art.

SUMMERY OF THE UTILITY MODEL

The utility model mainly aims to provide an air treatment device, and aims to solve the technical problem that the air treatment effect of the air treatment device in the prior art is poor.

In order to achieve the purpose, the utility model provides an air treatment device, which comprises a machine shell formed by mutually enclosing a top cover, side plates and a bottom plate, wherein an upper air channel and a lower air channel which are mutually spaced are formed in the machine shell, the upper air channel is provided with a first air treatment module, and the lower air channel is provided with a second air treatment module; the upper air duct comprises an air inlet cavity and a fan installation cavity which are communicated with each other; the housing includes:

the first air inlet is formed in the side plate and communicated with the air inlet cavity;

the first air outlet is arranged on the top cover and communicated with the fan installation cavity;

the second air inlet is formed in the side plate and communicated with the lower air duct;

the second air outlet is arranged on the top cover and/or the side plate and is communicated with the lower air duct;

the fan mounting cavity is internally provided with an axial flow fan, the axial flow fan is provided with a first air inlet side and a first air outlet side which are communicated with each other, the first air inlet side is communicated with the air inlet cavity, and the first air outlet side is communicated with the first air outlet.

In an embodiment, the side plate includes a front panel, and the second air outlet is opened in the front panel.

In an embodiment, an air guide grille is arranged at the second air outlet, and the air guide grille comprises a first air guide part and/or a second air guide part, wherein the first air guide part is arranged obliquely from bottom to top forwards and is used for guiding air forwards and downwards; the second air guide part is obliquely arranged from top to bottom forwards and is used for guiding air forwards and upwards.

In an embodiment, the second air outlet is arranged on the top cover, a communicating pipe is further arranged in the casing, one end of the communicating pipe is communicated with the lower air duct, and the other end of the communicating pipe is communicated with the second air outlet.

In an embodiment, an air processing chamber adjacent to the first air inlet and a middle chamber communicated with the air processing chamber are formed in the air inlet chamber, the first air processing module is disposed in the air processing chamber, and the middle chamber is communicated with the first air inlet side.

In an embodiment, a centrifugal fan is disposed in the lower air duct, the centrifugal fan has a second air inlet side and a second air outlet side that are communicated with each other, the second air inlet side is communicated with the second air inlet, and the second air outlet side is communicated with the second air outlet.

In one embodiment, the first air treatment module is arranged at the first air inlet;

or the first air processing module is arranged on a first air inlet side of the axial flow fan.

In one embodiment, the first air treatment module comprises at least one of a filtration module, a sterilization module, a formaldehyde removal module, and a deodorization module.

In an embodiment, the first air treatment module includes a filter module and a sterilization module, the filter module is disposed near the first air inlet, and the sterilization module is disposed on a side of the filter module facing away from the first air inlet.

In an embodiment, the second air treatment module comprises a humidification module.

In one embodiment, the humidifying module comprises a water tank, an electrode module and a wet membrane assembly, wherein the water tank is used for supplying water to the wet membrane assembly, and the electrode module at least partially extends into the water tank and is used for electrolyzing the water in the water tank.

In one embodiment, the wet film assembly includes a wheel support, a wet film body, and a driving device, the wheel support is rotatable relative to the water tank, the wet film body is mounted on the wheel support and at least partially extends into the water tank, and the driving device is configured to drive the wheel support to rotate.

In one embodiment, the runner bracket comprises a first runner frame and a second runner frame, the wet film body is arranged between the first runner frame and the second runner frame, and the first runner frame and/or the second runner frame are/is provided with a water suction port for sucking water from the water tank;

or a water suction port is formed between the first rotary wheel frame and the second rotary wheel frame and is used for sucking water from the water tank.

In an embodiment, a first partition plate is arranged in the casing, and the first partition plate is located between the air inlet cavity and the lower air duct.

According to the technical scheme, an upper air duct and a lower air duct which are mutually spaced are formed in a shell, a first air treatment module is installed in the upper air duct, a second air treatment module is installed in the lower air duct, the upper air duct comprises an air inlet cavity and a fan installation cavity which are mutually communicated, a first air inlet communicated with the air inlet cavity and a second air inlet communicated with the lower air duct are arranged on a side plate of the shell, a first air outlet communicated with the fan installation cavity is arranged on a top cover of the shell, and a second air outlet communicated with the lower air duct is arranged on the top cover and/or the side plate of the shell; so, wind channel on some air can follow first air intake entering, flows out from first air outlet after handling through first air treatment module, and wind channel under another some air can follow the second air intake entering is handled through the second air treatment module, flows out from the second air outlet, can realize multiple air treatment function. In addition, an axial flow fan is arranged in the fan installation cavity, the axial flow fan is provided with a first air inlet side and a first air outlet side which are communicated with each other, the first air inlet side is communicated with the air inlet cavity, the first air outlet side is communicated with the first air outlet, so that the axial flow fan can drive air to enter the air inlet cavity from the first air inlet and further flow into the first air inlet side of the axial flow fan from the air inlet cavity, and finally flow to the first air outlet from the first air outlet side of the axial flow fan, so that the air inlet amount entering the upper air duct from the first air inlet is increased, the air outlet amount blown out from the first air outlet is increased, and the total air outlet amount of the air treatment device is increased; on the other hand can realize the top air-out, has avoided directly blowing to user's head from the air-out air current that first air outlet blew out, has improved user's use comfort, has still increased the air supply scope from first air outlet in addition, realizes the bigger farther distance air supply, has further improved the air treatment effect.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of an air treatment device according to the present invention;

FIG. 2 is a schematic view of the air treatment device of FIG. 1 from another perspective;

FIG. 3 is a detailed view of the interior of the air treatment device of FIG. 1;

FIG. 4 is a cross-sectional view of the air treatment device of FIG. 1;

FIG. 5 is an air flow diagram of the air treatment device of FIG. 1;

FIG. 6 is a schematic view of a portion of the air treatment apparatus of FIG. 1;

FIG. 7 is a block diagram of the air treatment device of FIG. 6 from another perspective;

FIG. 8 is a schematic structural view of another embodiment of an air treatment device according to the present invention;

FIG. 9 is a schematic view of the air treatment device of FIG. 8 from another perspective;

FIG. 10 is a detailed view of the interior of the air treatment device of FIG. 8;

FIG. 11 is a cross-sectional view of the air treatment device of FIG. 8;

FIG. 12 is an air flow diagram of the air treatment device of FIG. 8;

FIG. 13 is a schematic view of a portion of the air treatment device of FIG. 8;

FIG. 14 is a block diagram of the air treatment device of FIG. 13 from another perspective;

FIG. 15 is an assembly view of the rotor holder and the wet film body in the air treatment device according to the present invention;

FIG. 16 is an exploded view of the wheel support and the wet film body of the air treatment device according to the present invention.

The reference numbers illustrate:

the implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that, if directional indications (such as up, down, left, right, front, and back … …) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative positional relationship between the components, the movement situation, and the like in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indications are changed accordingly.

In addition, if there is a description relating to "first", "second", etc. in the embodiments of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or to implicitly indicate the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, if appearing throughout the text, "and/or" is meant to include three juxtaposed aspects, taking "a and/or B" as an example, including either the a aspect, or the B aspect, or both the a and B aspects. In addition, technical solutions between the embodiments may be combined with each other, but must be based on the realization of the technical solutions by a person skilled in the art, and when the technical solutions are contradictory to each other or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

The utility model provides an air treatment device.

Referring to fig. 1 to 5, an air treatment device 100 according to the present invention includes a housing 110, wherein the housing 110 is formed by enclosing a top cover 111, a side plate 113, and a bottom plate 112, an upper duct 120 and a lower duct 130 are formed in the housing 110, the upper duct 120 is provided with a first air treatment module 140, and the lower duct 130 is provided with a second air treatment module 150; the upper air duct 120 comprises an air inlet cavity 121 and a fan installation cavity 124 which are communicated with each other; the casing 110 includes a first air inlet 114, a first air outlet 116, a second air inlet 115 and a second air outlet 117, the first air inlet 114 is disposed on the side plate 113 and is communicated with the air inlet chamber 121; the first air outlet 116 is arranged on the top cover 111 and communicated with the fan installation cavity 124; the second air inlet 115 is arranged on the side plate 113 and is communicated with the lower air duct 130; the second air outlet 117 is arranged on the top cover 111 and/or the side plate 113 and is communicated with the lower air duct 130; an axial flow fan 160 is arranged in the fan mounting cavity 124, the axial flow fan 160 has a first air inlet side 161 and a first air outlet side 162 which are communicated with each other, the first air inlet side 161 is communicated with the air inlet cavity 121, and the first air outlet side 162 is communicated with the first air outlet 116.

In the embodiment of the present invention, the casing 110 has a substantially cylindrical structure extending in a vertical direction, for example, a cylindrical structure or a square cylindrical structure (e.g., a rectangular parallelepiped). The housing 110 may be an integrally formed structure, and certainly, in order to facilitate the detachment and installation, the housing 110 may also be a split structure, which is not particularly limited. An upper air duct 120 and a lower air duct 130 are formed in the housing 110, and the upper air duct 120 and the lower air duct 130 may be arranged in an up-down direction, for example, the upper air duct 120 is located above the lower air duct 130. It should be noted that the upper air duct 120 and the lower air duct 130 may be communicated with each other, and of course, the upper air duct 120 and the lower air duct 130 may also be spaced apart from each other, which is not particularly limited.

Referring to fig. 1 to 5, if the upper air duct 120 and the lower air duct 130 are communicated with each other, that is, the upper air duct 120 and the lower air duct 130 are communicated to form an air duct which is through up and down, the second air outlet 117 and the first air outlet 116 are the same air outlet, so that a part of air enters the lower air duct 130 from the second air inlet 115, is processed by the second air processing module 150, then flows into the upper air duct 120, and finally flows out from the first air outlet 116 (the second air outlet 117); meanwhile, another part of the air flows into the upper air duct 120 from the first air inlet 114, and flows out from the first air outlet 116 after being processed by the first air processing module 140, so that the total air output of the air processing device 100 is increased, and the air processing effect of the air processing device 100 is further improved. Referring to fig. 8 to 12, if the upper air duct 120 and the lower air duct 130 are spaced apart from each other, that is, the upper air duct 120 and the lower air duct 130 are independent from each other, such that a portion of air enters the upper air duct 120 from the first air inlet 114, flows out from the first air outlet 116 after being processed by the first air processing module 140, and another portion of air enters the lower air duct 130 from the second air inlet 115, and flows out from the second air outlet 117 after being processed by the second air processing module 150, the total air output of the air processing device 100 can also be increased, thereby improving the air processing effect of the air processing device 100.

It should be noted that by spacing the upper duct 120 and the lower duct 130 from each other, the first air treatment module 140 installed in the upper duct 120 and the second air treatment module 150 installed in the lower duct 130 are not affected by each other, and air can flow into the room after being treated only by the air treatment modules of the upper duct 120 or the lower duct 130. Specifically, when air passes through only the upper duct 120, only the first air handling module 140 may be turned on without turning on the second air handling module 150, so that the first air handling module 140 may be separately controlled to be turned on while the second air handling module 150 is controlled to be turned off; at this time, the air enters the upper duct 120 from the first air inlet 114, is processed by the first air processing module 140, and then flows out from the first air outlet 116. When the air passes through only the lower duct 130, only the second air treatment module 150 may be turned on without turning on the first air treatment module 140, so that the second air treatment module 150 may be separately controlled to be turned on while the first air treatment module 140 is controlled to be turned off; at this time, the air enters the upper duct 120 through the second air inlet 115, is processed by the second air processing module 150, and then flows out of the second air outlet 117. In this way, the air treatment device 100 achieves the effect of controlling the opening or closing of a certain air module, thereby providing a user with a plurality of selection modes. In addition, when the second air processing module 150 is a humidification and disinfection module, the upper air duct 120 and the lower air duct 130 are spaced from each other, so that the disinfectant released by the second air processing module 150 in the lower air duct 130 cannot enter the upper air duct 120, the effect of independently controlling the opening or closing of the second air processing module 150 in the lower air duct 130 can be realized, the disinfectant released by the second air processing module 150 is prevented from being adhered to the first air processing module 140 or the first air outlet 116 of the upper air duct 120, and the situation that after the second air processing module 150 is closed, the pungent smell is still released indoors can be prevented.

Of course, it can be understood that, when the user needs the first air treatment module 140 and the second air treatment module 150 to purify the air at the same time, the first air treatment module 140 and the second air treatment module 150 may also be turned on at the same time, and at this time, a portion of the air enters the upper air duct 120 from the first air inlet 114, flows out from the first air outlet 116 after being treated by the first air treatment module 140, and another portion of the air enters the lower air duct 130 from the second air inlet 115, and flows out from the second air outlet 117 after being treated by the second air treatment module 150. Thus, multiple air treatment functions can be realized simultaneously, and the air flow can be prevented from flowing through multiple different air treatment modules in sequence to cause large air volume loss, so that the total air volume of the air treatment device 100 is increased.

In the embodiment of the present invention, the housing 110 further has a first air inlet 114, a first air outlet 116, a second air inlet 115, and a second air outlet 117. The first air inlet 114 is arranged on the side plate 113 and is communicated with the upper air duct 120; the second air inlet 115 is disposed on the side plate 113 and is communicated with the lower air duct 130. Here, the first air inlet 114 and the second air inlet 115 may jointly form a large air inlet, and the air inlet simultaneously communicates with the upper air duct 120 and the lower air duct 130; of course, the first air inlet 114 and the second air inlet 115 may be two small air inlets spaced apart from each other, and are not limited in particular. Specifically, the shapes of the first air inlet 114 and the second air inlet 115 may be the same or different. Alternatively, the shape of the first intake vent 114 and/or the second intake vent 115 may be circular, rectangular, or other irregular shapes. In addition, the first air inlet 114 may be arranged in a grid shape, and the second air inlet 115 may also be arranged in a grid shape.

The housing 110 is formed by enclosing a top cover 111, a side plate 113 and a bottom plate 112, taking the cylindrical housing 110 as an example, the side plate 113 includes a front panel 113a and a back panel 113b which are oppositely arranged, and a left side plate 113c and a right side plate 113d which connect the front panel 113a and the back panel 113 b. Optionally, the left side plate 113c and the right side plate 113d are both provided with a first air inlet 114 and a second air inlet 115. So set up, then make the user after finishing the installation of air treatment facilities 100, even the backplate 113b of casing 110 and one of them curb plate 113 all press close to the wall setting, still can guarantee that at least 50% air can get into inside casing 110 from the air intake that another curb plate 113 that deviates from the wall was seted up, and then guarantee a certain amount of intake. Of course, if only the back panel 113b of the housing 110 is close to the wall, and the left side panel 113c and the right side panel 113d are not shielded by the wall, the intake air amount can be further increased, thereby ensuring better air intake effect and further realizing higher air processing efficiency. Certainly, in order to achieve a better air intake effect and avoid the wall from blocking the air intake, the first air intake 114 and/or the second air intake 115 may be disposed on the front panel 113a, so that no matter how the air processing apparatus 100 is disposed, as long as the front panel 113a faces the user, the indoor air can enter the upper air duct 120 from the first air intake 114 disposed on the front panel 113 a; and/or, the air enters the lower air duct 130 through the second air inlet 115 of the front panel 113 a.

In addition, in order to avoid discomfort of the user caused by the airflow blown out from the first outlet 116 directly blowing to the head of the user, the first outlet 116 may be provided on the top cover 111 and communicated with the upper duct 120; so, through the top air-out, effectively avoided directly blowing to user's head from the air-out air current that first air outlet 116 blew out, simultaneously, can also further increase the air supply scope, realize handling indoor air in wider range, and then improve the air treatment effect. Meanwhile, considering that the second outlet 117 is disposed at the middle-lower portion of the housing 110, the outlet airflow from the second outlet 117 is generally not directly blown to the head of the user, which may cause discomfort to the user, so the second outlet 117 may be disposed on the top cover 111 and/or the side plate 113 and communicate with the lower duct 130. Specifically, the shapes of the first air outlet 116 and the second air outlet 117 may be the same or different. Optionally, the shape of the first air outlet 116 and/or the second air outlet 117 may be circular, rectangular or other irregular shapes. In addition, the first air outlet 116 may be arranged in a grid shape, and the second air outlet 117 may also be arranged in a grid shape.

It should be noted that, in the embodiment of the present invention, please refer to fig. 3 to fig. 5, the upper duct 120 includes an air inlet cavity 121 and a fan installation cavity 124 which are communicated with each other, the first air inlet 114 is communicated with the air inlet cavity 121, and the first air outlet 116 is communicated with the fan installation cavity 124. Specifically, the air inlet cavity 121 is disposed close to the lower air duct 130, that is, the air inlet cavity 121 is located between the fan installation cavity 124 and the lower air duct 130. The axial flow fan 160 is arranged in the fan mounting cavity 124, the axial flow fan 160 has a first air inlet side 161 and a first air outlet side 162 which are communicated with each other, the first air inlet side 161 is communicated with the air inlet cavity 121, and the first air outlet side 162 is communicated with the first air outlet 116, so that the axial flow fan 160 can drive air to enter the air inlet cavity 121 from the first air inlet 114, and further flow into the first air inlet side 161 of the axial flow fan 160 from the air inlet cavity 121, and finally flow into the first air outlet 116 from the first air outlet side 162 of the axial flow fan 160. By arranging the upper air duct 120 into two parts, namely the air inlet cavity 121 and the fan installation cavity 124 and arranging the axial flow fan 160 in the fan installation cavity 124, on one hand, the air inlet amount entering the upper air duct 120 from the first air inlet 114 can be increased, the air outlet amount blown out from the first air outlet 116 is increased, and the total air outlet amount of the air processing device 100 is increased; on the other hand can realize the top air-out, has avoided directly blowing to user's head from the air-out air current that first air outlet 116 blew out, has improved user's use comfort, can also increase simultaneously from first air outlet 116 air supply scope, realizes the farther distance air supply more greatly, has further improved the air treatment effect.

According to the technical scheme, an upper air duct 120 and a lower air duct 130 are formed in a machine shell 110, a first air treatment module 140 is installed in the upper air duct 120, a second air treatment module 150 is installed in the lower air duct 130, the upper air duct 120 comprises an air inlet cavity 121 and a fan installation cavity 124 which are mutually communicated, meanwhile, a first air inlet 114 communicated with the air inlet cavity 121 and a second air inlet 115 communicated with the lower air duct 130 are arranged on a side plate 113 of the machine shell 110, a first air outlet 116 communicated with the fan installation cavity 124 is arranged on a top cover 111 of the machine shell 110, and a second air outlet 117 communicated with the lower air duct 130 is arranged on the top cover 111 and/or the side plate 113 of the machine shell 110; thus, a portion of air may enter the upper duct 120 from the first air inlet 114, and flow out from the first air outlet 116 after being processed by the first air processing module 140, and another portion of air may enter the lower duct 130 from the second air inlet 115, and flow out from the second air outlet 117 after being processed by the second air processing module 150, so as to implement multiple air processing functions. In addition, by disposing the axial flow fan 160 in the fan mounting cavity 124, the axial flow fan 160 has a first air inlet side 161 and a first air outlet side 162 which are communicated with each other, the first air inlet side 161 is communicated with the air inlet cavity 121, and the first air outlet side 162 is communicated with the first air outlet 116, so that the axial flow fan 160 can drive air to enter the air inlet cavity 121 from the first air inlet 114, and further flow into the first air inlet side 161 of the axial flow fan 160 from the air inlet cavity 121, and finally flow into the first air outlet 116 from the first air outlet side 162 of the axial flow fan 160, on one hand, the air inlet amount entering the upper air duct 120 from the first air inlet 114 is increased, further the air outlet amount blown out from the first air outlet 116 is increased, and the total air outlet amount of the air processing device 100 is increased; on the other hand can realize the top air-out, has avoided directly blowing to user's head from the air-out air current that first air outlet 116 blew out, has improved user's use comfort, has still increased the air supply scope from first air outlet 116 in addition, realizes bigger farther distance air supply, has further improved the air treatment effect.

The type and installation position of the first air treatment module 140 are various, and are not particularly limited.

Referring to fig. 4 and 5, in the present embodiment, the first air handling module 140 is disposed at the first air inlet 114. Specifically, the first air treatment module 140 may be disposed in the first air inlet 114 or in the air inlet chamber 121, so that the air entering the air inlet side of the axial flow fan 160 has been treated by the first air treatment module 140 in advance, thereby avoiding the cleanliness of the axial flow fan 160 and prolonging the service life of the axial flow fan 160.

In another embodiment, the first air treatment module 140 can also be disposed on the first air inlet side 161 of the axial fan 160. Specifically, the first air treatment module 140 may be disposed in the fan installation cavity 124, or may be disposed in the air intake cavity 121, which is not particularly limited. By positioning the first air treatment module 140 adjacent to the first air inlet side 161 of the axial fan 160, it is ensured that air flowing from the air inlet chamber 121 into the air inlet side of the axial fan 160 has been treated by the first air treatment module 140, and the cleanliness of the axial fan 160 is ensured, extending the service life of the axial fan 160.

Of course, in another embodiment, the first air treatment module 140 can also be disposed between the first air outlet side 162 of the axial flow fan 160 and the first air outlet 116.

Specifically, referring to fig. 4 and 5, the first air treatment module 140 includes at least one of a filtering module 141, a sterilizing module 142, a formaldehyde removing module 400, and a deodorizing module. For example, but not limited to, the first air treatment module 140 includes a filtering module 141 and a sterilization module 142, and the filtering module 141 is used for filtering dust, particles, impurities and the like in the air. The sterilization module 142 is a module capable of killing bacteria, viruses and the like in the air, the filtering module 141 can be arranged near the first air inlet 114, the sterilization module 142 can be arranged on one side of the filtering module 141 departing from the first air inlet 114, so that after the air enters the first air inlet 114, the air can be firstly filtered by the filtering module 141 for some dust, impurities and the like, and then is sterilized by the sterilization module 142, thereby further ensuring that the air entering from the first air inlet 114 is relatively clean. The sterilization module 142 may include, but is not limited to, a plasma screen 142a and a self-friction screen 142b, the plasma screen 142a is disposed between the filter module 141 and the self-friction screen 142b, the plasma screen 142a is mainly used for generating positive and negative charges for bacteria and viruses in the air, and the self-friction screen 142b is mainly used for adsorbing bacteria and viruses with positive and negative charges.

In addition, referring to fig. 6, in order to facilitate cleaning or replacement of the first air treatment module 140, a mounting/dismounting opening 118 may be formed in the housing 110, so that the first air treatment module 140 can be drawn out from the mounting/dismounting opening 118. Specifically, the detachable opening 118 may be opened on the back plate 113b of the housing 110.

There may be various types and installation positions of the second air treatment module 150, and the second air treatment module is not particularly limited.

Referring to fig. 3 to 6, in the present embodiment, the second air processing module 150 includes a humidifying module 151. By providing the humidification module 151 in the lower duct 130, the relatively dry air can be humidified, and air having an appropriate humidity can be blown out. Of course, in other embodiments, the second air treatment module 150 may also include the filtering module 141 or the sterilization module 142, which is not limited in particular.

Further, the humidification module 151 is an electrolytic humidification module 151. Specifically, the electrolytic humidification module 151 includes a water tank 158, a water tank 157, and an electrode module 156, wherein the water tank 158 is used for supplying water to the water tank 157, and the electrode module 156 at least partially extends into the water tank 157 for electrolyzing the water in the water tank 157. By communicating the water tank 158 with the water tank 157, the water tank 158 can provide a certain amount of water into the water tank 157, and the electrode module 156 can electrolyze water in the water tank 157 and generate hypochlorous acid (disinfectant), so that the generated hypochlorous acid is blown out from the second air outlet 117 under the driving of air entering the lower air duct 130, and the air disinfection effect is achieved.

Referring to fig. 3 to 5, the electrolytic humidification module 151 further includes a wet film assembly disposed above the water tank 157, and the water tank 157 is used for supplying water to the wet film assembly. By arranging the wet film assembly above the water tank 157 and using the water tank 157 to supply water to the wet film assembly, the water on the wet film assembly can be taken away when the air passes through the wet film assembly after the wet film assembly is wetted by the water in the water tank 157, thereby achieving the humidifying effect.

Among them, the water tank 157 supplies water to the wet film assembly in various ways. For example, in the present embodiment, referring to fig. 6 and 7, the wet film assembly is a disc-shaped structure, the wet film assembly is rotatably installed in the water tank 157, and different portions of the wet film assembly sequentially extend into the water tank 157 to be wetted by water during the rotation of the wet film assembly, so as to wet the entire wet film assembly.

Specifically, referring to fig. 15 and 16, the wet film assembly includes a roller bracket 152, a wet film body 154 and a driving device 155, the roller bracket 152 is rotatable relative to the water tank 157, the wet film body 154 is mounted on the roller bracket 152 and at least partially extends into the water tank 157, and the driving device 155 is configured to drive the roller bracket 152 to rotate. So, it is rotatory through drive arrangement 155 drive runner support 152, runner support 152 drives wet membrane body 154 and rotates, and wet membrane body 154 is at the rotation in-process, and its different positions stretch into in the basin 157 in proper order and are soaked by the water, when runner support 152 rotates the round, wet membrane body 154 can fully absorb the water in the basin 157, and then realizes the effect of soaking whole wet membrane body 154 completely.

It should be noted that, in the present embodiment, the wet film body 154 rotates together with the wheel support 152, and even if the wet film body 154 becomes hard due to crystallization on the wet film body 154 after water (typically, salt water) contained in the water tank 157 is adsorbed by the wet film body 154, the rotation of the wet film body 154 is not affected, so that the rotation reliability of the wet film body 154 is improved, the wet film body 154 can be ensured to be always kept in a good wet state, and the air treatment effect of the air treatment apparatus 100 is effectively ensured.

Further, referring to fig. 15 and 16, the rotating wheel bracket 152 includes a first rotating wheel frame 1521 and a second rotating wheel frame 1522, the wet film body 154 is disposed between the first rotating wheel frame 1521 and the second rotating wheel frame 1522, and the first rotating wheel frame 1521 and/or the second rotating wheel frame 1522 are provided with water suction ports 153 for sucking water from the water tank 157;

alternatively, a water suction port 153 is formed between the first and second rotating wheel frames 1521 and 1522 to suck water from the water tank 157.

The first and second wheel frames 1521 and 1522 may be wheel discs. In this way, the wet film can be sandwiched between the first rotating wheel frame 1521 and the second rotating wheel frame 1522, and the sides of the first rotating wheel frame 1521 and the second rotating wheel frame 1522 opposite to each other cooperate to form the water suction port 153. Of course, the first and second wheel frames 1521 and 1522 may also be wheel housings. For example, the wheel housing cover includes a main body portion and a connecting portion extending from the main body portion to one side thereof, so that the first wheel frame 1521 and the second wheel frame 1522 can enclose to form an installation cavity, the wet film body 154 is installed in the installation cavity, the water suction port 153 includes a first semi-water suction groove 157 arranged on the first wheel frame 1521 and a second semi-water suction groove 157 arranged on the second wheel frame 1522, and the first semi-water suction groove 157 is abutted to the second semi-water suction groove 157. Specifically, the number of the water suction ports 153 is multiple, and the multiple water suction ports 153 are arranged at intervals along the circumferential direction of the wheel support 152. In addition, considering that the wet film body 154 needs to be cleaned or replaced after being used for a long time to ensure a humidifying effect, the first runner bracket 1521 and the second runner bracket 1522 may be detachably connected.

In order to improve the humidification effect of the humidification rotor, the rotor bracket 152 further includes a separation frame, the separation frame is disposed between the first rotor frame 1521 and the second rotor frame 1522, the number of the wet film bodies 154 is two, and the two wet films are respectively located at two sides of the separation frame. That is, one of the wet film bodies 154 is located between the first runner frame 1521 and the separation frame, and the other wet film body 154 is located between the separation frame and the second runner frame 1522. In this way, when the air enters the lower air duct 130 from the second air inlet 115, the air can be sequentially humidified by the two wet film bodies 154, so that the humidification effect can be effectively improved. The number of the wet film bodies 154 may also be three, four or more, and may be selected and designed according to the use requirement.

In this embodiment, the driving device 155 includes a driving motor and a driving gear disposed on an output shaft of the driving motor, an annular tooth portion 1523 (as shown in fig. 15 and 16) is disposed on the wheel support 152, and the annular tooth portion 1523 is engaged with the driving gear, so that the driving motor drives the driving gear to rotate, and the driving gear is engaged with the annular tooth portion 1523 on the wheel support 152, so as to drive the rotating support to rotate.

For another example, in another embodiment, the water tank 157 may supply water to the wet membrane module by a water pump. Specifically, the water pump pumps water in the water tank 157 to the upper end of the wet membrane module through a water pipe so that the water can flow down the wet membrane module and wet the entire wet membrane module. In yet another embodiment, the wet film assembly is a rolling curtain structure, a part of the wet film assembly is immersed in the water tank 157, and the wet film assembly can rotate, so that each part of the wet film assembly is sequentially immersed in the water tank 157, and the whole wet film assembly is soaked.

Referring to fig. 7 and 14, in order to facilitate the water tank 158 to be filled with water, the water tank 158 is disposed near the front panel 113a, and the water tank 158 can slide back and forth, so that the water tank 157 can be pulled out by sliding after the user opens the front panel 113a, thereby facilitating the user to replace the water in the water tank 158 or to add water into the water tank 158.

Considering that if the electrode module 156 is fixedly installed in the housing 110, the wall of the water tank 157 may contact the electrode module 156 and be stopped by the electrode module 156 during the sliding and withdrawing process of the water tank 157, thereby limiting the sliding of the water tank 157. Therefore, in order to facilitate the extraction of the water tank 157, the electrode module 156 can swing back and forth with respect to the housing 110,

and has an avoiding station for avoiding the drawing of the water tank 157 and an electrolysis station extending into the water tank 157. Thus, by arranging the electrode module 156 in the casing 110 and swinging back and forth, when the user opens the front panel 113a and pulls the water tank 157 to slide back and forth, the wall of the water tank 157 touches the electrode module 156 and then drives the electrode module 156 to rotate, and the electrode module 156 rotates to an avoidance position, which provides an avoidance space for the movement of the water tank 157, and facilitates the water tank 157 to be drawn out from the lower air duct 130 or clamped into the lower air duct 130. In addition, in the process of drawing or clamping the water tank 157 into the lower air duct 130, the water tank 158 can be driven to draw or clamp the water tank 158 into the lower air duct 130 from the lower air duct 130, so that the user can conveniently replace the water in the water tank 158 or conveniently add water into the water tank 158.

Referring to fig. 3 to 5, a centrifugal fan 170 is disposed in the lower air duct 130, the centrifugal fan 170 has a second air inlet side 171 and a second air outlet side 172 that are communicated with each other, the second air inlet side 171 faces the second air inlet 115, and the second air outlet side 172 is communicated with the second air outlet 117. It can be understood that, if the upper air duct 120 is communicated with the lower air duct 130, the second air outlet side 172 is communicated with the second air outlet 117, which means that the second air outlet side 172 is directly communicated with the second air outlet 117; if the upper air duct 120 and the lower air duct 130 are spaced from each other, the second air outlet side 172 is communicated with the second air outlet 117, which means that the second air outlet side 172 is indirectly connected to the second air outlet 117, for example, the second air outlet side 172 is communicated with the upper air duct 120, and the upper air duct 120 is communicated with the second air outlet 117, that is, the first air outlet 116.

When the second air inlet 115 is one, for example, the second air inlet is disposed on the left side plate 113c or the right side plate 113d, the centrifugal fan 170 may be a single-side suction centrifugal fan 170, the single-side suction centrifugal fan 170 has only one air inlet side, and the single-side suction second air inlet side 171 faces the second air inlet 115. When the number of the second air inlets 115 is two, for example, when the second air inlets 115 are disposed on the left side plate 113c and the right side plate 113d, the centrifugal fan 170 may be a double-sided suction centrifugal fan 170, the double-sided suction centrifugal fan 170 has two air inlet sides, and the two air inlet sides of the double-sided suction centrifugal fan 170 face the two second air inlets 115 respectively. Of course, when there are two second air inlets 115, for example, when the two second air inlets 115 are disposed on the left side plate 113c and the right side plate 113d, the centrifugal fan 170 may also be a single-side air-suction centrifugal fan 170, and the double-side air-suction second air inlet side 171 faces one of the second air inlets 115.

Further, referring to fig. 3 to 5, in order to better communicate the second air outlet side 172 of the centrifugal fan 170 with the second air outlet 117, a diversion air duct 173 may be disposed on the air outlet side of the centrifugal fan 170, and the diversion air duct 173 is communicated with the second air outlet 117. The air guide channel 173 may be directly communicated with the second air outlet 117, and of course, the air guide channel 173 may also be communicated with the second air outlet 117, that is, the first air outlet 116, through the upper air channel 120.

Referring to fig. 1 to 7, in some embodiments, the upper air duct 120 and the lower air duct 130 are spaced apart from each other.

In this embodiment, the first outlet 116 and the second outlet 117 are different outlets. The second outlet 117 may be disposed on the front panel 113a (as shown in fig. 1 and 2). By opening the second air outlet 117 communicating with the lower duct 130 on the front panel 113a, it is ensured that the wind can be directly blown into the room when the lower duct 130 is blown out. It can be understood that, since the second outlet 117 is communicated with the lower duct 130, when the second outlet 117 is opened on the front panel 113a, the second outlet 117 is at a lower position, and the wind blown out from the second outlet 117 does not directly blow to the head of the user, so as to improve the comfort level of the user; in addition, when the second outlet 117 is opened in the front panel 113a, the indoor air can be directly sterilized by the air blown out from the second outlet 117, thereby improving the sterilization effect. Of course, in other embodiments, the second air outlet 117 may also be disposed on other side plates 113.

The second air outlet 117 may also be disposed on the top cover 111. By disposing the second air outlet 117 in the top cover 111, the air passing through the lower air duct 130 can be discharged upwards, thereby preventing the disinfectant released from the lower air duct 130 from directly blowing to the user. Specifically, the first outlet 116 and the second outlet 117 may be the same outlet, or the first outlet 116 and the second outlet 117 are different outlets.

Based on the second air outlet 117 is disposed on the top cover 111, a communicating pipe is further disposed in the housing 110, one end of the communicating pipe communicates with the lower air duct 130, and the other end communicates with the second air outlet 117. One end of the communicating pipe is communicated with the lower air duct 130, and the other end of the communicating pipe is communicated with the second air outlet 117, so that the lower air duct 130 and the upper air duct 120 can be spaced from each other, thereby preventing air mixing of the upper air duct 120 and the lower air duct 130, and ensuring that the first air outlet 116 and the second air outlet 117 respectively send out air with different requirements. The communicating pipe may be a structure separated from the lower duct 130, and when the communicating pipe is damaged or leaked, the communicating pipe may be replaced independently. Specifically, the communicating pipe may be connected to the lower duct 130 by a flange connection or a plug connection. Of course, the communicating tube may be integrated with the lower duct 130.

Further, the communicating pipe may be disposed between the centrifugal fan 170 and the front panel 113a, or the communicating pipe may be disposed between the centrifugal fan 170 and the back panel 113b, so that the communicating pipe may avoid the first air inlet 114 and the second air inlet 115, thereby avoiding the first air inlet 114 and the second air inlet 115 from being blocked, and ensuring that the air inlet is smoother.

It should be noted that, in this embodiment, please refer to fig. 1 to 3, an air guiding grille 119 is disposed at the second air outlet 117, the air guiding grille 119 includes a first air guiding portion 119a and/or a second air guiding portion 119b, the first air guiding portion 119a is disposed obliquely from bottom to top for guiding air downward; the second air guiding portion 119b is disposed to be inclined forward from top to bottom, for guiding air upward. That is, the first air guiding portion 119a and the second air guiding portion 119b form an included angle.

By arranging the air guide grille 119 at the second air outlet 117, and the air guide grille 119 comprises the first air guide part 119a guiding air to the front lower part and the second air guide part 119b guiding air to the front upper part, the air outlet airflow blowing from the second air outlet 117 can be effectively prevented from directly blowing forwards to the user, meanwhile, the airflow blowing from the first air guide part 119a collides with the airflow blowing from the second air guide part 119b, the airflow can be further scattered, and the air outlet effect without wind feeling is realized.

Specifically, the first air guiding portion 119a is provided with a plurality of first air dissipating holes, and the second air guiding portion is provided with a plurality of second air dissipating holes. The shape of the first air dispersing hole can be circular, oval, square, triangular, kidney-shaped or other special-shaped shapes, and the shape of the second air dispersing hole can be circular, oval, square, triangular, kidney-shaped or other special-shaped shapes, and the like, and is not limited specifically.

Of course, in other embodiments, a planar air guiding grille 119 may be disposed at the second air outlet 117, which is not limited in particular.

In order to ensure better air outlet quality, in the present embodiment, please refer to fig. 3 to fig. 5, the first air outlet 116 is installed with a formaldehyde removing module 400. By installing the formaldehyde removing module 400 at the first air outlet 116, after the treatment is performed by the first air treatment module 140 in the upper air duct 120, the formaldehyde gas can be removed by the formaldehyde removing module 400, so as to further ensure that the air blown out from the air treatment device 100 is clean air. Specifically, this remove formaldehyde module 400 can be manganese net module, and the setting of this manganese net module can avoid frequently being changed to through setting to formaldehyde module 400 and to network structure, then avoid changing this module many times, and can also prevent that outside debris from falling into in last wind channel 120 through first air outlet 116 and influencing the normal work of other parts. Of course, in other embodiments, the formaldehyde removal module 400 may be a module having a formaldehyde removal function, such as activated carbon, in order to achieve the effect of removing formaldehyde.

Referring to fig. 8 to 14, in other embodiments, the upper duct 120 is communicated with the lower duct 130.

The second outlet 117 and the first outlet 116 are the same outlet. Specifically, the lower air duct 130 is communicated with the air inlet cavity 121, so that a part of air enters the lower air duct 130 from the second air inlet 115, is processed by the second air processing module 150, can further flow into the air inlet cavity 121, enters the first air inlet side 161 of the axial flow fan 160 from the air inlet cavity 121, and finally flows to the first air outlet 116 from the first air outlet side 162 of the axial flow fan 160; meanwhile, another portion of the air enters the air inlet cavity 121 from the first air inlet 114, enters the first air inlet side 161 of the axial flow fan 160 after being processed by the first air processing module 140, and finally flows to the first air outlet 116 from the first air outlet side 162 of the axial flow fan 160.

It is worth mentioning that, by making the upper air duct 120 and the lower air duct 130 communicate with each other, the air processed by the second air processing module 150 can enter the air inlet chamber 121 to be fully mixed with the air entering from the first air inlet 114, which is beneficial to uniformly distribute the disinfectant released by the second air processing module 150 into the outlet air flow, and further beneficial to uniformly distribute the disinfectant released by the second air processing module 150 into the indoor environment, thereby further improving the sterilization effect on the indoor environment.

Referring to fig. 11 to 13, an air processing chamber 122 adjacent to the first air inlet 114 and an intermediate chamber 123 communicated with the air processing chamber 122 are formed in the air inlet chamber 121, the first air processing module 140 is disposed in the air processing chamber 122, and the intermediate chamber 123 is communicated with a first air inlet side 161 of the axial flow fan 160.

Specifically, the intermediate chamber 123 and the air treatment air chamber are arranged in a horizontal direction. Thus, the air entering from the first air inlet 114 is first treated by the first air treatment module 140, and then the treated air flows into the middle chamber 123, flows into the first air inlet side 161 of the axial flow fan 160 from the middle chamber 123, and finally flows toward the first air outlet 116 from the first air outlet side 162 of the axial flow fan 160. In this way, it is ensured that the air entering the air processing chamber 122 from the first air inlet 114 is completely processed by the first air processing module 140 and then flows into the intermediate chamber 123, so that it is ensured that the air blown out from the first air outlet 116 is relatively clean.

In one embodiment, the intermediate chamber 123 may be in communication with the lower duct 130 in order to communicate the upper duct 120 with the lower duct 130. Thus, the air entering the lower duct 130 from the second air inlet 115 flows into the middle chamber 123 after being processed by the second air processing module 150, then flows into the first air inlet side 161 of the axial flow fan 160 from the middle chamber 123, and finally flows into the first air outlet 116 from the first air outlet side 162 of the axial flow fan 160.

By arranging the air inlet chamber 121 as two parts of the air treatment chamber 122 and the middle chamber 123 and communicating the middle chamber 123 with the lower air duct 130, on one hand, the disinfectant released by the second air treatment module 150 can be prevented from sticking to the first air treatment module 140 and affecting the use of the first air treatment module 140; on the other hand, the air entering the upper air duct 120 from the lower air duct 130 can be prevented from passing through the first air treatment module 140 again, so that the air volume loss is large, the total air outlet volume from the first air outlet 116 is increased, and the air treatment effect is improved.

Specifically, when the number of the first air inlets 114 is two, the number of the air processing chambers 122 and the number of the first air processing modules 140 are two, the two air processing chambers 122 are respectively located at two opposite sides of the middle chamber 123, and the two first air processing modules 140 are respectively located in the two air processing chambers 122. When the number of the first air inlets 114 is one, the number of the air processing chambers 122 and the number of the first air processing modules 140 are both one. The material is not particularly limited, and may be selected and designed according to actual use requirements.

Referring to fig. 11 to 13, in order to prevent the upper duct 120 and the lower duct 130 from wind cross, a first partition plate 180 may be disposed in the casing 110, and the first partition plate 180 is located between the air inlet chamber 121 and the lower duct 130. Further, in order to communicate the upper duct 120 with the lower duct 130, a first air passing opening 181 for communicating the middle chamber 123 with the lower duct 130 is disposed on the first partition plate 180.

By arranging the first partition 180 in the cabinet 110, the disinfectant in the air of the lower air duct 130 can be effectively prevented from entering the air treatment chamber 122 of the upper air duct 120, and thus the disinfectant in the air of the lower air duct 130 can be effectively prevented from adhering to the first air treatment module 140 to affect the use of the first air treatment module 140.

In addition, referring to fig. 11, in order to prevent the disinfectant in the air of the lower air duct 130 from adhering to the first air treatment module 140 and affecting the use of the first air treatment module 140, a protective grid 125 may be further disposed between the air treatment chamber 122 and the intermediate chamber 123, so that the disinfectant in the air of the lower air duct 130 can be better prevented from entering the intermediate chamber 123 and then entering the air treatment chamber 122 from the intermediate chamber 123 and adhering to the first air treatment module 140.

Referring to fig. 11 to 13, a second partition plate 190 is disposed in the casing 110, the second partition plate 190 is located between the fan installation cavity 124 and the air inlet cavity 121, and a second air passing opening 191 communicating the fan installation air cavity and the middle cavity 123 is disposed on the second partition plate 190.

Through the second partition plate 190 arranged in the casing 110, the intermediate cavity 123 can be communicated with the fan installation cavity 124, and meanwhile, the air treatment cavity 122 is prevented from being directly communicated with the fan installation cavity 124, so that it can be ensured that all air entering from the first air inlet 114 is treated by the first air treatment module 140 and then flows into the first air inlet side 161 of the axial flow fan 160, and thus the cleanliness of the axial flow fan 160 can be ensured, and the service life of the axial flow fan 160 can be prolonged.

Based on the above embodiments, the upper air duct 120 is further provided with a display assembly 200 (as shown in fig. 1 and fig. 2), the lower air duct 130 is provided with an electronic control box assembly 300 (as shown in fig. 13), the display assembly 200 is installed on the front panel 113a or the back panel 113b, and the electronic control box assembly 300 is installed on the back panel 113 b.

By arranging the electrical control box assembly 300 in the lower air duct 130 and installing the electrical control box assembly 300 on the back plate 113b, the electrical control box assembly 300 can be prevented from blocking the first air outlet 116 and the second air outlet 117. Similarly, the display module 200 is disposed in the upper duct 120, and the display module 200 is mounted on the front panel 113a, so that the user can conveniently observe some data displayed on the display module 200 at any time. Of course, the display module 200 may be provided on the back plate 113b without considering visibility.

Further, the display module 200 is installed at a side of the cabinet 110 away from the communication pipe.

By providing the display module 200 in the upper duct 120, the display module 200 is disposed on a side of the casing 110 away from the communication pipe, so that a concentrated installation of components on a side where the communication pipe is disposed is avoided. Specifically, when the communication pipe is disposed between the centrifugal fan 170 and the front panel 113a, the communication pipe is closer to the front panel 113a, and at this time, the display module 200 may be mounted on the back panel 113b opposite to the front panel 113a, so as to avoid overcrowding of the display module 200 and the communication pipe after mounting. When the communication pipe is disposed between centrifugal fan 170 and back panel 113b, the communication pipe is closer to back panel 113b, and display module 200 can be mounted on front panel 113a opposite to back panel 113b, thereby avoiding overcrowding of display module 200 and the communication pipe after mounting.

Of course, in other embodiments, the display module 200 is disposed in the upper duct 120, and when the connection pipe is not disposed, the display module 200 may be preferably disposed on the front panel 113a, so that the user can view the display module 200 at any time, and then monitor some information displayed on the display module 200.

The above description is only an alternative embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (14)

1. An air treatment device is characterized by comprising a machine shell which is formed by mutually enclosing a top cover, side plates and a bottom plate, wherein an upper air channel and a lower air channel which are mutually spaced are formed in the machine shell, the upper air channel is provided with a first air treatment module, and the lower air channel is provided with a second air treatment module; the upper air duct comprises an air inlet cavity and a fan installation cavity which are communicated with each other; the housing includes:

the first air inlet is formed in the side plate and communicated with the air inlet cavity;

the first air outlet is arranged on the top cover and communicated with the fan installation cavity;

the second air inlet is arranged on the side plate and communicated with the lower air duct;

the second air outlet is arranged on the top cover and/or the side plate and communicated with the lower air duct;

the fan mounting cavity is internally provided with an axial flow fan, the axial flow fan is provided with a first air inlet side and a first air outlet side which are communicated with each other, the first air inlet side is communicated with the air inlet cavity, and the first air outlet side is communicated with the first air outlet.

2. The air treatment device of claim 1, wherein the side panel comprises a front panel, and the second air outlet is open to the front panel.

3. The air processing device as claimed in claim 2, wherein the second air outlet is provided with an air guide grille, the air guide grille comprises a first air guide part and/or a second air guide part, and the first air guide part is arranged obliquely from bottom to top towards the front and is used for guiding air towards the front lower part; the second air guide part is obliquely arranged from top to bottom forwards and is used for guiding air forwards and upwards.

4. The air processing device as claimed in claim 1, wherein the second air outlet is disposed at the top cover, a communicating pipe is further disposed in the housing, one end of the communicating pipe is communicated with the lower air duct, and the other end of the communicating pipe is communicated with the second air outlet.

5. The air treatment device as claimed in claim 1, wherein an air treatment chamber adjacent to the first air inlet and an intermediate chamber communicated with the air treatment chamber are formed in the air inlet chamber, the first air treatment module is disposed in the air treatment chamber, and the intermediate chamber is communicated with the first air inlet side.

6. The air treatment device according to any one of claims 1 to 5, wherein a centrifugal fan is arranged in the lower air duct, the centrifugal fan has a second air inlet side and a second air outlet side which are communicated with each other, the second air inlet side is communicated with the second air inlet, and the second air outlet side is communicated with the second air outlet.

7. The air treatment device of any one of claims 1-5, wherein the first air treatment module is disposed at the first air inlet;

or, the first air treatment module is arranged at the first air inlet side.

8. The air treatment device of any one of claims 1-5, wherein the first air treatment module comprises at least one of a filtration module, a sterilization module, a formaldehyde removal module, and a deodorization module.

9. The air treatment device of claim 8, wherein the first air treatment module includes a filter module disposed proximate the first air intake opening and a sterilization module disposed on a side of the filter module facing away from the first air intake opening.

10. An air treatment device as claimed in any one of claims 1 to 5, wherein the second air treatment module comprises a humidification module.

11. The air treatment device of claim 10, wherein the humidification module comprises a water tank for supplying water to the wet membrane assembly, an electrode module extending at least partially into the water tank for electrolyzing the water in the water tank, and a wet membrane assembly.

12. The air treatment device of claim 11, wherein the wet film assembly comprises a wheel support, a wet film body, and a driving device, the wheel support being rotatable with respect to the tank, the wet film body being mounted on the wheel support and extending at least partially into the tank, the driving device being configured to drive the wheel support to rotate.

13. The air treatment device according to claim 12, wherein the runner bracket comprises a first runner bracket and a second runner bracket, the wet film body is arranged between the first runner bracket and the second runner bracket, and the first runner bracket and/or the second runner bracket is provided with a water suction port for sucking water from the water tank;

or a water suction port is formed between the first rotary wheel frame and the second rotary wheel frame and is used for sucking water from the water tank.

14. The air treatment device of any one of claims 1-5, wherein a first partition is disposed within the housing, the first partition being positioned between the air intake chamber and the lower air duct.

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