CN217677810U - Cleaning device for electrolysis device and air conditioner - Google Patents

Abstract

The application relates to the technical field of air treatment and discloses a cleaning device for an electrolysis device. Electrolytic device includes positive plate portion and negative pole portion, and positive plate portion and negative pole portion interval set up, and cleaning device includes: a brush capable of extending into a gap between the positive electrode part and the negative electrode part; and the third driving device is in driving connection with the hairbrush and can drive the hairbrush to move in the gap and along the extending direction of the gap so as to clean the positive electrode part and/or the negative electrode part. The third driving device and the brush can clean the electrolysis device at high frequency, and effectively prevent scale from being generated. The application also discloses an air conditioner.

Description

Cleaning device for electrolysis device and air conditioner

Technical Field

The present application relates to the field of air treatment technology, and for example, to a cleaning device for an electrolysis device and an air conditioner.

Background

At present, with the higher living standard of people, the higher requirements on living environment are. Therefore, more and more household appliances have functions of humidifying, fresh air and the like, and how to make the air outlet of the household appliances meet the requirements of people becomes a problem to be solved urgently.

Disclose a reaction unit for electrolytic copper production in the correlation technique, including the reaction tank, the top of reaction tank is equipped with the apron, the top fixed mounting of apron has the bottom to be open-ended box, fixed mounting has the motor on the inner wall of the bottom in the box, rotate on the apron and install the dwang, the top of dwang extends to in the box and with the output shaft fixed connection of motor, the bottom of dwang extends to in the reaction tank and fixed mounting has the clean soft brush of second, the clean soft brush of second contacts with the bottom inner wall of reaction tank, fixed mounting has four connecting rods that are located the reaction tank on the outer wall of dwang, the one end fixed mounting that the dwang was kept away from to the connecting rod has first clean soft brush, first clean soft brush contacts with the inner wall of reaction tank, the top fixed mounting of box has the water pump, the delivery port fixed mounting of water pump has the water service pipe, fixed mounting has the one end of two connecting pipes on the water service pipe, the other end of two connecting pipes all extends to the reaction tank and fixed mounting has the shower nozzle.

In the process of implementing the embodiments of the present disclosure, it is found that at least the following problems exist in the related art:

the cleaning soft brush in the related art can be used only for cleaning the reaction tank, and it is impossible to clean the electrolysis apparatus itself, such as the electrode and the like.

SUMMERY OF THE UTILITY MODEL

The following presents a simplified summary in order to provide a basic understanding of some aspects of the disclosed embodiments. This summary is not an extensive overview nor is intended to identify key/critical elements or to delineate the scope of such embodiments but rather as a prelude to the more detailed description that is presented later.

The embodiment of the disclosure provides a cleaning device for an electrolysis device and an air conditioner, so that the electrolysis device can be cleaned.

The disclosed embodiment provides a cleaning device for electrolytic device, electrolytic device includes positive pole portion and negative pole portion, positive pole portion with negative pole portion interval sets up, cleaning device includes: a brush capable of extending into a gap between the positive electrode part and the negative electrode part; and the third driving device is in driving connection with the hairbrush and can drive the hairbrush to move in the gap and along the extending direction of the gap so as to clean the positive electrode part and/or the negative electrode part.

The embodiment of this disclosure also discloses an air conditioner, including air treatment facilities, air treatment facilities includes: the water tank is used for containing a conductive solution; the electrolytic device is positioned in the water tank; the cleaning device for the electrolysis device is positioned in the water tank.

The cleaning device for the electrolysis device and the air conditioner provided by the embodiment of the disclosure can realize the following technical effects:

after the anode part and the cathode part of the electrolysis device are used for a long time, scale can be formed on the surfaces of the anode part and the cathode part, and the normal operation of the electrolysis device can be influenced. By providing the brush and the third driving means, the third driving means drives the brush to move along the gap between the positive electrode portion and the negative electrode portion to clean the surfaces of the positive electrode portion and the negative electrode portion and the gap between the positive electrode portion and the negative electrode portion. The third driving device and the hairbrush can clean the electrolysis device at high frequency, so that the generation of scale is effectively prevented, and the service life of the electrolysis device is further prolonged.

The foregoing general description and the following description are exemplary and explanatory only and are not restrictive of the application.

Drawings

One or more embodiments are illustrated in the accompanying drawings, which correspond to the accompanying drawings and not in a limiting sense, in which elements having the same reference numeral designations represent like elements, and in which:

fig. 1 is a schematic structural diagram of an air conditioner according to an embodiment of the present disclosure;

FIG. 2 is a schematic diagram of an air treatment device according to an embodiment of the present disclosure;

FIG. 3 is a schematic structural diagram of a purification assembly provided by embodiments of the present disclosure;

FIG. 4 is a schematic structural diagram of a support frame engaged with a purification membrane according to an embodiment of the disclosure;

FIG. 5 is a schematic cross-sectional view of an air treatment device provided in accordance with an embodiment of the present disclosure;

FIG. 6 is a schematic view of a portion of an air treatment device according to an embodiment of the present disclosure;

FIG. 7 is a schematic structural diagram of a feeding device provided in the embodiments of the present disclosure;

FIG. 8 is a schematic view of a cooperating structure of a charging mechanism and a water tank according to an embodiment of the disclosure;

FIG. 9 is a schematic view of a portion of a charging mechanism provided in accordance with an embodiment of the present disclosure;

FIG. 10 is a schematic cross-sectional view taken along line C-C of FIG. 9;

FIG. 11 is an enlarged schematic view of portion D of FIG. 10;

FIG. 12 is a schematic view of another embodiment of the present disclosure showing the structure of the water tank cooperating with the first driving device;

FIG. 13 is a schematic view of the internal structure of another water tank provided by the embodiment of the present disclosure;

FIG. 14 is a schematic structural view of another stand according to an embodiment of the present disclosure;

FIG. 15 is a schematic structural view of another tank provided by an embodiment of the present disclosure from one perspective;

FIG. 16 is a schematic structural diagram illustrating another perspective of another tank provided by embodiments of the present disclosure;

FIG. 17 is a schematic structural view of a cleaning device for an electrolysis device according to an embodiment of the present disclosure;

FIG. 18 is a schematic cross-sectional view of a cleaning device provided in accordance with an embodiment of the present disclosure;

FIG. 19 is a schematic structural view of a housing according to an embodiment of the present disclosure;

FIG. 20 is a schematic structural view of another electrolysis apparatus provided by an embodiment of the present disclosure;

FIG. 21 is a schematic structural view from another perspective of another tank provided by embodiments of the present disclosure;

FIG. 22 is a schematic view of a portion of another air treatment device provided in accordance with an embodiment of the present disclosure;

FIG. 23 is a schematic view of a purification disk assembly according to an embodiment of the present disclosure;

FIG. 24 is a schematic cross-sectional view of another air treatment device according to an embodiment of the present disclosure.

Reference numerals:

100. an air conditioner; 10. a housing;

20. an air treatment device; 201. a water box; 202. a first driving device;

30. a water tank; 301. an air inlet; 302. an air outlet; 303. an accommodating chamber; 304. a first cover body; 305. a water tank body; 307. a grid; 3071. a grid post;

40. a purification assembly; 401. a purification membrane; 402. purifying the wheel set; 4021. an annular wheel plate; 403. a support frame; 4031. A support pillar; 4032. a first end portion; 4033. a second end portion; 404. a rotating shaft; 405. a purifying member; 406. a first gear; 407. a second gear;

50. a fan; 501. a support;

60. an electrolysis device; 601. a positive electrode part; 602. a negative electrode part; 603. a first contact; 6033. a first conductive post; 6034. a second conductive post; 604. a second contact; 6043. a third conductive pillar; 6044. a fourth conductive post;

70. a feeding mechanism; 701. a feeding channel; 7011. an outlet of the feeding channel; 702. a feeding device; 7021. a helicoid; 7022. a central shaft; 703. a second driving device; 704. a turntable; 7041. a release port; 705. a feeding cavity; 706. a second cover body;

80. a cleaning device; 801. a brush; 8011. a disc; 8012. a bristle group; 802. a third driving device; 803. a housing; 8031. a motor cavity; 8032. an entrance and an exit; 8033. a boss portion; 8034. a chute; 8035. a housing body; 804. An electric control board; 805. a clamping pin; 806. a routing channel; 807. a moving assembly; 8071. a rack; 8072. a gear; 8073. and a fourth drive device.

Detailed Description

So that the manner in which the features and elements of the disclosed embodiments can be understood in detail, a more particular description of the disclosed embodiments, briefly summarized above, may be had by reference to the embodiments, some of which are illustrated in the appended drawings. In the following description of the technology, for purposes of explanation, numerous details are set forth in order to provide a thorough understanding of the disclosed embodiments. However, one or more embodiments may be practiced without these details. In other instances, well-known structures and devices may be shown in simplified form in order to simplify the drawing.

The terms "first," "second," and the like in the description and in the claims, and the above-described drawings of embodiments of the present disclosure, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It should be understood that the data so used may be interchanged under appropriate circumstances such that embodiments of the present disclosure described herein may be made. Furthermore, the terms "comprising" and "having," as well as any variations thereof, are intended to cover non-exclusive inclusions.

In the embodiments of the present disclosure, terms "upper", "lower", "inner", "middle", "outer", "front", "rear", and the like indicate orientations or positional relationships based on orientations or positional relationships shown in the drawings. These terms are used primarily to better describe the disclosed embodiments and their examples and are not intended to limit the indicated devices, elements or components to a particular orientation or to be constructed and operated in a particular orientation. Moreover, some of the above terms may be used in other meanings besides orientation or positional relationship, for example, the term "upper" may also be used in some cases to indicate a certain attaching or connecting relationship. The specific meanings of these terms in the embodiments of the present disclosure can be understood by those of ordinary skill in the art as appropriate.

In addition, the terms "disposed," "connected," and "secured" are to be construed broadly. For example, "connected" may be a fixed connection, a detachable connection, or a unitary construction; can be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements or components. Specific meanings of the above terms in the embodiments of the present disclosure can be understood by those of ordinary skill in the art according to specific situations.

The term "plurality" means two or more unless otherwise specified.

The term "and/or" is an associative relationship that describes objects, meaning that three relationships may exist. For example, a and/or B, represents: a or B, or A and B.

It should be noted that, in the case of no conflict, the embodiments and features in the embodiments of the present disclosure may be combined with each other.

The thick arrows in the drawing indicate the flow direction of the airflow inside the air treatment device 20 with the purification membrane 401 in the first embodiment, and the thin arrows in the drawing indicate the flow direction of the airflow inside the air treatment device 20 with the purification wheel set 402 in the fourth embodiment.

Example one

Referring to fig. 1, an embodiment of the present disclosure provides an air conditioner 100, which includes a casing 10, a heat exchanging device and an air processing device 20, wherein the heat exchanging device and the air processing device 20 are both located in the casing 10.

The casing 10 is provided with a main air inlet and a main air outlet, the heat exchange device comprises an indoor heat exchanger and an indoor fan, and after the indoor fan drives airflow to flow in from the main air inlet, the airflow exchanges heat with the heat exchanger and then flows out from the main air outlet.

The air conditioner 100 may be a cabinet air conditioner, a wall-mounted air conditioner, or a window air conditioner, etc.

Taking the air conditioner 100 as a cabinet air conditioner as an example, the air treatment device 20 is located below the heat exchange device, so that the space at the lower part of the casing 10 is fully utilized, and the air treatment device 20 has the functions of purification and humidification, so that the air conditioner 100 has the functions of temperature regulation and purification and humidification.

Alternatively, the air treatment device 20 is in communication with the main air inlet and the main air outlet, that is, after the air flow flows into the housing 10 through the main air inlet, the air flow can also flow through the air treatment device 20 and then flow out through the main air outlet.

In this embodiment, the air treatment device 20 and the heat exchange device share the main air inlet and the main air outlet, so that the strength of the casing 10 can be increased, and the air treatment device 20 and the heat exchange device can be conveniently mixed to output air.

Optionally, the housing 10 is further provided with an auxiliary air inlet and an auxiliary air outlet, both of which are communicated with the air treatment device 20, and the air flow flows in through the auxiliary air inlet, then flows through the air treatment device 20, and then flows out through the auxiliary air outlet.

In this embodiment, air treatment device 20 sets up independently and assists air intake and auxiliary air outlet for air treatment device 20's air-out is not influenced by heat transfer device, has increased the flexibility that air treatment device 20 set up.

As shown in fig. 2 to 6, the air treatment device 20 includes a water tank 30, a blower 50, a purification assembly 40, and a driving device 202 (hereinafter, referred to as a first driving device 202 for convenience of distinction), wherein the water tank 30 defines a containing cavity 303 (also referred to as an inside of the water tank 30) having an air inlet 301 and an air outlet 302, the containing cavity 303 is used for containing purification water, and the purification assembly 40 is rotatably located in the containing cavity 303 and used for purifying air flowing through the purification assembly 40; the first driving device 202 is in driving connection with the purifying assembly 40, and can drive the purifying assembly 40 to rotate, and the purifying assembly 40 can purify and humidify the air flow passing through the purifying assembly 40. The fan 50 can drive the airflow to flow in the water tank 30, specifically, the air flow is driven to flow into the accommodating cavity 303 from the air inlet 301, and then the air flow is driven to flow through the purifying assembly 40 and then flow out of the accommodating cavity 303 through the air outlet 302.

The fans 50 may be located at the air inlet 301 or the air outlet 302, the number of the fans 50 may be one or multiple, and the number of the positions of the fans 50 may be set by a user as required.

When the air treatment device 20 and the heat exchange device share the main air inlet and the main air outlet, the air inlet 301 is communicated with the main air inlet, and the air outlet 302 is communicated with the main air outlet.

Under the condition that the shell 10 is provided with the auxiliary air inlet and the auxiliary air outlet, the air inlet 301 is communicated with the auxiliary air inlet, and the air outlet 302 is communicated with the auxiliary air outlet.

The first driving device 202 may be an electric motor, a motor, or the like.

Alternatively, the purification assembly 40 is cylindrical, and the purification assembly 40 comprises a purification member 405, wherein the purification member 405 is located on the circumferential wall surface of the purification assembly 40, that is, the purification member 405 is also cylindrical, wherein the purification member 405 can generate a water film for purification and humidification, or the purification member 405 itself can purify and humidify the gas flow.

Purification subassembly 40 is the cylinder, and purification piece 405 limits the inner space, and the inner space is the cylinder type, and the air current can flow into the inner space from at least one axial terminal surface of purification subassembly 40, or flows into the inner space from the circumference wall of purification subassembly 40, and then flows out the inner space, and the air current all contacts with the circumference wall of purification subassembly 40 at the flow in-process, also just can contact with purification piece 405, and purification piece 405 can purify and/or the humidification to the air current to improve purification humidification effect.

Optionally, the purifying assembly 40 further comprises a supporting frame 403, and the supporting frame 403 is connected with the purifying member 405 and the first driving device 202, and is used for transmitting the power of the first driving device 202 to drive the purifying member 405 to rotate along its own circumferential direction.

Alternatively, as shown in fig. 3 to 6, the purifying member 405 includes a purifying membrane 401, the purifying membrane 401 is cylindrical, the purifying membrane 401 is axially and horizontally disposed in the accommodating cavity 303 (which can also be understood as being in the water tank 30), at least a part of the purifying membrane 401 can be soaked in the purifying water, and the lower end of the purifying membrane 401 is located in the purifying water; the first driving device 202 is configured to controllably drive the purifying membrane 401 to rotate circumferentially, so that the circumferential wall surface of the purifying membrane 401 is soaked with the purified water in turn, and the purifying membrane 401 can absorb the purified water.

In this embodiment, the purification membrane 401 is cylindrical, that is, the interior of the purification membrane 401 defines a cylindrical interior space, so that the airflow can flow into the interior space of the purification membrane 401, the contact area between the airflow and the purification membrane 401 is increased, and the purification and humidification effects are improved. The purification membrane 401 is axially horizontally disposed in the water tank 30, so that the contact area between the purification membrane 401 and the purified water is large, and the purification membrane 401 can absorb more water. The first driving device 202 drives the purification membrane 401 to rotate circumferentially, so that the circumferential wall surface of the purification membrane 401 contacts with the purification water in turn, and the purification membrane 401 can be always kept in a "water saturated" state. When the air flow passes through the purification membrane 401, the purification and humidification effects of the purification membrane 401 on the air flow can be improved.

Alternatively, as shown in fig. 5, at least one axial end surface of the purification membrane 401 is communicated with the air inlet 301, and the fan 50 can drive air to flow into the purification membrane 401 through the air inlet 301, then flow out to the air outlet 302 through the circumferential wall surface of the purification membrane 401, and then flow out to the room from the air outlet 302.

In this embodiment, the air flow is driven by the fan 50 above the water tank 30, flows into the accommodating cavity 303 from the air inlet 301 on the side wall of the water tank 30, then flows into the inner space of the purification membrane 401 from at least one axial end surface of the purification membrane 401, and then flows out from the circumferential wall surface of the purification membrane 401. In the process of passing through the circumferential wall surface of the purification membrane 401, the purification membrane 401 can adsorb and block impurities in the airflow, and the function of purifying the airflow is achieved. Similarly, the purification membrane 401 absorbing the purified water can humidify the air flowing therethrough, thereby realizing the purification and humidification functions. Thus, the air flow can flow in from one axial end face or two axial end faces of the purifying membrane 401 and then flow out from the circumferential wall face, the flow rate of the air flow is increased, and the purifying and humidifying effects of the air treatment device 20 are increased. Similarly, because the fan 50 is located above the water tank 30, the air flows can flow into both axial end faces, and there is no "flow dead angle", so that the contact area between the air flows and the purification membrane 401 can be further increased, and the purification and humidification effects are improved.

Optionally, at least one side wall of the water tank 30 is provided with an air inlet 301, the top wall of the water tank 30 is provided with an air outlet 302, and both the air inlet 301 and the air outlet 302 are communicated with the accommodating cavity 303; the blower 50 is located above the water tank 30 and is communicated with the air outlet 302 to drive the air flow in the water tank 30 to flow from the air inlet 301 to the air outlet 302.

The air flow flows in from an air inlet 301 provided in a side wall of the water tank 30 and flows out from an air outlet 302 provided in a top wall of the water tank 30. Taking the air treatment device 20 as an example, which is located at the bottom of the casing 10, the air flow is more widely flowed into the room after flowing out of the casing 10, and the loss of the air flow in the flowing process is reduced.

It can be understood that: the air outlet 302 may also be disposed on a side wall of the water tank 30, the air inlet 301 is disposed on a top wall of the water tank 30, and the blower 50 may be disposed at the air outlet 302 or the air inlet 301.

Optionally, the number of the air inlets 301 is multiple, and at least two air inlets 301 of the multiple air inlets 301 are respectively disposed on two opposite side walls of the water tank 30; the two axial end surfaces of the purification membrane 401 correspond to the at least two air inlets 301, respectively, and the fan 50 can drive air to flow into the purification membrane 401 through the at least two air inlets 301, and then flow into the interior (which may be understood as an interior space) of the purification membrane 401 through the two axial end surfaces of the purification membrane 401, and then flow out to the air outlet 302 through the circumferential wall surface of the purification membrane 401.

In this embodiment, the sidewall of the water tank 30 may be provided with a plurality of air inlets 301, two opposite sidewalls of the water tank 30 are respectively provided with the air inlets 301, two axial end surfaces of the purification membrane 401 respectively correspond to the at least two air inlets 301, that is, the axial direction of the purification membrane 401 is consistent with the direction of the two opposite sidewalls of the water tank 30, so that the flow path of the air flowing into the accommodating cavity 303 can be reduced, the loss of the air in the flowing process is avoided, and the air output of the air processing device 20 is ensured. In addition, in this embodiment, the air flow flows into the inner space of the purification membrane 401 from the axial end surfaces of both sides of the purification membrane 401, so that the contact area between the air flow and the purification membrane 401 is further ensured, and the purification and humidification effects of the air treatment device 20 are improved.

Optionally, as shown in fig. 3 and 4, the air treatment device 20 further includes a support frame 403, and the purification membrane 401 is sleeved outside the support frame 403; the supporting frame 403 is in driving connection with the first driving device 202, and the first driving device 202 can drive the supporting frame 403 to rotate, so that the supporting frame 403 drives the purifying membrane 401 to rotate around the circumference of the purifying membrane 401.

In this embodiment, the supporting frame 403 on the one hand plays a role of supporting the purification membrane 401, so that the purification membrane 401 can be cylindrical. On the other hand, the support frame 403 plays a role of transmitting power, and the first driving device 202 drives the support frame 403 to rotate, so as to drive the purification membrane 401 to rotate circumferentially.

Optionally, the support frame 403 is also cylindrical, and the support frame 403 includes a first end 4032, a second end 4033, and a support column 4031 connected between the first end 4032 and the second end 4033; the number of the support columns 4031 is plural, and the plural support columns 4031 are arranged at intervals in the circumferential direction of the support frame 403, which not only facilitates the formation of the cylindrical support frame 403, but also facilitates the support of the cylindrical purification membrane 401. For example, the number of the support columns 4031 may be three, four or five, wherein if the number of the support columns 4031 is too small, for example, less than three, the support frame 403 has poor stability and cannot stably support the purification membrane 401. The number of the support columns 4031 cannot be too large, for example, if there are more than five support columns 4031, the gap between the support columns 4031 is small, which may affect the gas flow to the purification membrane 401 through the support columns 4031.

The first and second ends 4032 and 4033 are rounded to facilitate connection to a plurality of support columns 4031.

Optionally, the first drive device 202 is drivingly connected to the first end 4032 and/or the second end 4033.

The first driving device 202 is in driving connection with the first end 4032 and/or the second end 4033, so that the first driving device 202 can be arranged conveniently, the arrangement position of the purification membrane 401 cannot be occupied, and the size of the purification membrane 401 is ensured.

Optionally, in a case where the air inlet 301 is disposed corresponding to an axial end surface of the purification membrane 401, an outer diameter of the first end 4032 and/or the second end 4033 is greater than or equal to a size of the air inlet 301, so that the purification module 40 can be prevented from falling off from the air inlet 301 during the transportation process.

It should be noted that: the size of the air inlet 301 cannot be too small, so as to avoid insufficient air intake. The aperture of the air inlet 301 may be three-quarters, two-thirds, or four-fifths of the outer diameter of the first end face and/or the second end face.

Optionally, the air inlet 301 is further provided with a grating 307, and the grating 307 can prevent the purification module 40 from falling off from the air inlet 301, so as to increase the aperture of the air inlet 301.

Optionally, the grill 307 includes a plurality of grill posts 3071, and the plurality of grill posts 3071 are spaced along the circumference of the intake vent 301. To increase the setting stability of the grating 307. Wherein, the quantity of grid post 3071 is greater than three, and is less than five, and when the quantity of grid post 3071 is less than three, the connection stability of grid 307 is relatively poor, and when the quantity of grid post 3071 is greater than five, the clearance between grid post 3071 is less, can hinder the air inlet.

Alternatively, in the case that the axial end surface of the purification membrane 401 is disposed corresponding to the air inlet 301, the first driving device 202 is disposed at the air inlet 301 so as to drive the purification membrane 401 to rotate along the circumferential direction thereof.

Optionally, the first driving device 202 is disposed outside the grating 307, and an output shaft of the first driving device 202 passes through the grating 307 and is connected to the supporting frame 403.

Optionally, as shown in fig. 6, the support frame 403 further includes a rotation shaft 404, an outer wall surface of the rotation shaft 404 is connected to the support 4031, and an inner wall surface of the rotation shaft 404 is drivingly connected to the first driving device 202.

In this embodiment, the rotating shaft 404 is used to drive the supporting frame 403 to rotate along the circumferential direction thereof, and the supporting frame 403 drives the purifying membrane 401 to rotate along the circumferential direction thereof, so as to purify or humidify the flowing air stream.

Alternatively, the rotating shaft 404 is aligned with the axis of the support frame 403 and the axis of the purification membrane 401. When the first driving device 202 drives the supporting frame 403 to rotate by driving the rotating shaft 404, the supporting frame 403 rotates around the rotating shaft 404, and the rotating shaft 404 is aligned with the axis of the purifying membrane 401, so that the purifying membrane 401 can also rotate around the axis. The required space of the rotation of the purification membrane 401 can be reduced, so that the outer diameter of the purification membrane 401 can be increased, the surface area of the purification membrane 401 can be increased, the contact area between the purification membrane 401 and the air flow can be further increased, and the purification and humidification effects can be improved.

Optionally, as shown in fig. 5, the air processing apparatus 20 further includes a bracket 501, the bracket 501 is disposed at the air outlet 302, and the fan 50 is disposed above the bracket 501.

In this embodiment, the bracket 501 enables the fan 50 to be stably placed above the air outlet 302, and the fan 50 is directly communicated with the air outlet 302, so as to reduce the flow path between the air outlet 302 and the fan 50, thereby ensuring the suction force of the fan 50 to the air inlet 301 and the purification membrane 401, and ensuring the smoothness of the airflow flowing through the air treatment device 20.

Alternatively, as shown in fig. 6, the water tank 30 includes a water tank body 305 and a cover 304 (hereinafter, referred to as a first cover 304 for convenience of distinction), the water tank body 305 defines an accommodating cavity 303 with an opening (hereinafter, referred to as a first opening for convenience of distinction) facing upwards, and the accommodating cavity 303 is used for accommodating purified water; the first cover 304 covers the first opening, the first cover 304 has an air outlet 302, and the support 501 is connected to the first cover 304.

In this embodiment, the first cover 304 is disposed to reduce the processing difficulty of the water tank 30, and the air outlet 302 is disposed on the first cover 304, so that the size of the air outlet 302 can be conveniently adjusted without adjusting the whole water tank 30.

Optionally, the bracket 501 is detachably connected to the first cover 304, so as to facilitate installation, removal and maintenance of the bracket 501 and the first cover 304.

The bracket 501 and the first cover 304 may be connected by means of a snap, a screw, or the like.

The wall surface of the first cover 304 facing the bracket 501 is provided with a screw, and the bracket 501 is provided with a trepan boring which can be sleeved on the screw, so as to realize the connection between the cover and the bracket 501. It should be noted that: the bracket 501 and the first cover 304 may also be fixedly connected to facilitate transportation and ensure stability of the placement of the fan 50.

Optionally, the bracket 501 is hollowed out, so that the airflow passes through the bracket 501 and flows to the fan 50, and the airflow resistance is reduced. For example, the support 501 includes a plurality of annular rings, and the annular rings are sequentially sleeved at intervals so that the airflow can flow between two adjacent annular sleeves.

Optionally, the bracket 501 further comprises a connecting rib connected between the plurality of annular rings to fix the plurality of annular rings. Wherein, the quantity of splice bar is a plurality of, and a plurality of splice bars set up along support 501's circumference interval to increase the fixed action to the annular ring.

Alternatively, the number of the connecting ribs is greater than or equal to three, less than or equal to five, for example, three, four or five, the number of the connecting ribs is too small, the fixing effect on the annular ring is poor, and the number of the connecting ribs is too large, which may hinder the flow of the air flow.

Optionally, the first cover 304 is detachably connected to the tank body 305.

The first cover 304 is detachably connected to the tank body 305, so that the first cover 304 or the tank 30 can be replaced or maintained conveniently. Also, the first cover 304 is detachable to facilitate the addition of purified water to the water tank 30 or the replacement of purified water in the water tank 30 through the first opening. Thus, the size of the air outlet 302 can be guaranteed, and the convenience of replacing purified water can be guaranteed.

Optionally, as shown in fig. 6, the air treatment device 20 further includes a water box 201, the water box 201 is located in the accommodating cavity 303, and an outlet of the water box 201 is communicated with the accommodating cavity 303 to provide purified water into the accommodating cavity 303; wherein, the outlet of the water box 201 is arranged downwards, and when the water level of the purified water in the water tank 30 is lower than the set water level, the purified water in the water box 201 can automatically flow into the accommodating cavity 303.

In this embodiment, the water box 201 holds purified water therein for replenishing water to the water tank 30. The side wall of the water tank 30 is provided with the air inlet 301, so that the water contained in the water tank 30 is limited, and the water level cannot be higher than the lower end of the air inlet 301. The water level can be kept constant by using the principle of pressure balance.

Optionally, water box 201 includes water box body, first moisturizing device and second moisturizing device, and first moisturizing device and second moisturizing device all are located the exit of water box 201, and when the water level that holds in chamber 303 equals to predetermine the water level, first moisturizing device and second moisturizing device all with hold chamber 303 and water box 201 and be linked together, and fill up the purification water in first moisturizing device and the second moisturizing device, hold chamber 303 and water box 201 and be encapsulated situation. When the water level in the accommodating cavity 303 is smaller than the preset water level, the first water replenishing device is communicated with the outside, air flows into the water box 201 through the first water replenishing device, and water in the water box 201 flows into the accommodating cavity 303 through the second water replenishing device until the water level in the accommodating cavity 303 reaches the preset water level.

In this embodiment, when the water level that holds in the chamber 303 reaches the settlement water level, water box 201 realizes sealedly, and the air no longer gets into water box 201, and the water in the water box 201 can not flow into yet and holds chamber 303, and then guarantees to hold the water level invariant in the chamber 303. The water is not required to be added into the water tank 30 frequently by manpower, and the manpower and the time are saved.

Optionally, the first cover 304 is provided with a notch to avoid the water box 201, so that the water box 201 can extend to the upper side of the water tank 30. This can increase the amount of the purified water contained in the water tank 201 and reduce the number of times of water exchange.

Alternatively, the fan 50 includes a centrifugal fan, and the axis of the fan 50 is disposed in the vertical direction. The centrifugal fan has good effect of driving airflow to flow, and has the advantages of low cost, low noise, high efficiency and long service life.

The axis of the fan 50 is arranged in the vertical direction, and the air flow can be driven to flow out of the air outlet 302 with the highest efficiency.

Optionally, the air outlet 302 is located in the middle of the first cover 304, and the axis of the fan 50 is aligned with the center of the air outlet 302, so that the suction forces of the fan 50 to the two axial end surfaces of the purification membrane 401 are the same or similar, so that the air flow can uniformly flow through the purification membrane 401.

Optionally, the air processing apparatus 20 further includes a blower housing, the blower housing is covered on the outer side of the blower 50, and the side wall of the blower housing extends downward and is connected to the outer side of the water tank 30, so as to increase the connection stability between the blower 50 and the water tank 30 and prevent the blower 50 from falling off.

Optionally, the blower housing is removably attached to the water tank 30 to facilitate installation, replacement, and removal of the water tank 30.

Optionally, the purification membrane 401 comprises an elastic membrane.

In this embodiment, the purification membrane 401 is an elastic membrane, which facilitates installation and replacement of the purification membrane 401. Meanwhile, the purification membrane 401 has functions of adsorbing impurities and purifying water. The purification membrane 401 can be an organic wet membrane, an inorganic glass fiber wet membrane, a metal aluminum alloy wet membrane, a metal stainless steel wet membrane, and the like.

Optionally, the water tank 30 is further provided with a feeding port, the feeding port is communicated with the accommodating cavity 303, and the feeding port is used for adding the conductive product to the accommodating cavity 303 so as to enable the purified water and the conductive product to form a conductive solution.

Optionally, as shown in fig. 17 to 21, the air treatment device 20 further comprises an electrolysis device 60, the electrolysis device 60 is at least partially located in the accommodating chamber 303, and the electrolysis device 60 can be in contact with the conductive solution for electrolyzing the conductive solution to generate the sterilizing water.

In this embodiment, a conductive product is added into the accommodating cavity 303 of the water tank 30, and the conductive product is mixed with the purified water to form a conductive solution. The electrolysis device 60 electrolyzes the conductive solution to generate water for disinfection, so that the air treatment device 20 has the functions of sterilization and disinfection of air on the basis of purifying and humidifying the air. In addition, because purification subassembly 40 and the contact of purification water, that is to say, purification subassembly 40 can contact with the disinfection water that the electrolysis produced, the disinfection water can carry out degerming disinfection to purification subassembly 40, avoids purification subassembly 40 long-term use to lead to bacterium breeding.

Under the condition that purification unit 40 includes purification membrane 401, purification membrane 401 also can contact with the disinfection water that the electrolysis produced in holding chamber 303, and then the disinfection water can carry out degerming virus killing to purification membrane 401, avoids purification membrane 401's bacterial growing.

Alternatively, the water tank 30 may not be provided with a feeding port, the air outlet 302 includes a feeding port, and/or the air inlet 301 includes a feeding port, that is, the conductive product may be added into the water tank 30 through the air outlet 302 and/or the air inlet 301.

Optionally, a pre-prepared conductive solution may be placed in the containing cavity 303 to reduce the post-adding work of the conductive product.

Alternatively, the conductive article may be a chloride salt, such as sodium chloride, potassium chloride. The generated water for disinfection contains hypochlorous acid, such as a sodium hypochlorite solution after electrolysis of a sodium chloride solution, a potassium hypochlorite solution generated after electrolysis of a potassium chloride solution, and the like.

Alternatively, as shown in fig. 20, the electrolysis device 60 includes a positive electrode portion 601 and a negative electrode portion 602, one end of the positive electrode portion 601 being communicable with a power supply; one end of the negative part 602 can be connected to a power supply, and the negative part 602 is spaced from the positive part 601; when the other end of the positive electrode portion 601 and the other end of the negative electrode portion 602 are in contact with the conductive solution and the conductive solution is in contact with both the other end of the positive electrode portion 601 and the other end of the negative electrode portion 602, the positive electrode portion 601 and the negative electrode portion 602 respectively electrolyze the conductive solution.

In this embodiment, when the other end of the positive electrode portion 601 and the other end of the negative electrode portion 602 are both connected to the conductive solution, the positive electrode portion 601, the conductive solution, and the negative electrode portion 602 form a series circuit, and the conductive solution can be electrolyzed.

Taking the conductive product as sodium chloride and the conductive solution as sodium chloride solution as an example, the sodium chloride in the sodium chloride solution is completely ionized, and water molecules are weakly ionized, so that four ions of Na +, H +, cl and OH-exist. Namely:

NaCl＝Na ⁺ +Cl ^-

H ₂ O□H ⁺ +OH ^- (reversible)

And (3) reaction at the positive electrode: 2Cl ^- -2e＝Cl ₂ ↓ (oxidation reaction)

And (3) carrying out reaction on the negative electrode: 2H ⁺ +2e＝H ₂ ↓ (reduction reaction)

H ⁺ Electrons are continuously obtained on the cathode to generate hydrogen to be discharged, the ionization balance of nearby water is destroyed, and thus a great amount of water molecules are ionized into H ⁺ And OH ^- And OH is formed ^- Is much greater than its directional motion to the anode. Thus, OH in the vicinity of the cathode ^- A large increase, sodium hydroxide production in solution:

OH ^- +Na ⁺ ＝NaOH

therefore, the general chemical equation for electrolyzing saturated brine (sodium chloride solution) can be expressed as follows:

2NaCl+2H ₂ O＝2NaOH+H ₂ ↑+Cl ₂ ↑

reacting chlorine gas with a sodium hydroxide solution: 2NaOH solution of Cl ₂ ＝NaCl+NaClO+H ₂ O, the generated NaClO (sodium hypochlorite) has strong oxidizing property, and salts of hypochlorous acid can be used as bleaching agent and disinfectant.

As shown in fig. 15 to 21, the electrolysis apparatus 60 includes a positive electrode portion 601 and a negative electrode portion 602, and one end of the positive electrode portion 601 is capable of communicating with a power supply; one end of the negative electrode portion 602 can communicate with a power supply; wherein, positive pole portion 601 and negative pole portion 602 set up at interval in proper order, and when the other end of positive pole portion 601 and the other end of negative pole portion 602 all conducting solution contacted, positive pole portion 601 and negative pole portion 602 respectively electrolyze the conducting solution as the example:

alternatively, the positive electrode 601 is in a ring shape, the negative electrode 602 is in a ring shape, and the positive electrode 601 and the negative electrode 602 are sequentially sleeved at intervals.

In this embodiment, the positive electrode portion 601 and the negative electrode portion 602 are both annular, and the contact area between the electrolysis apparatus 60 and the conductive solution is further increased, thereby improving the electrolysis efficiency. The positive electrode portion 601 and the negative electrode portion 602 are sequentially fitted at intervals, and the electroconductive solution is electrolyzed in the gap between the positive electrode portion 601 and the negative electrode portion 602.

Optionally, the electrolytic device 60 is located at the bottom of the accommodating cavity 303, which can ensure that the electrolytic device 60 is in sufficient contact with the conductive solution, thereby improving the electrolytic efficiency of the electrolytic device 60.

It can be understood that: the electrolyzer 60 may also be located on the side wall of the housing chamber 303.

Optionally, the number of the positive electrode portions 601 and the negative electrode portions 602 is multiple, and the positive electrode portions 601 and the negative electrode portions 602 are sequentially sleeved in a staggered manner at intervals, so that the electrolysis range of the positive electrode portions 601 and the negative electrode portions 602 is increased, and the electrolysis efficiency of the electrolysis device 60 is improved.

Alternatively, one ends of the plurality of positive electrode portions 601 are all connected so that the plurality of positive electrode portions 601 are all in communication with the power supply. One ends of the plurality of negative electrode portions 602 are connected so that the plurality of negative electrode portions 602 are all in communication with electrolysis.

As shown in fig. 20, the plurality of positive electrode portions 601 are integrally formed, and the plurality of negative electrode portions 602 are also integrally formed.

Optionally, the first electrical contact 603 is connected to both one end of the positive electrode portion 601 and one end of the negative electrode portion 602, the first electrical contact 603 includes a first conductive column 6033 and a second conductive column 6034, one end of the positive electrode portion 601 is connected to the first conductive column 6033, and one end of the negative electrode portion 602 is connected to the second conductive column 6034.

Optionally, the second electrical contact 604 is located outside the water tank 30, wherein the second electrical contact 604 includes a third conductive pillar 6043 and a fourth conductive pillar 6044, and one end of the third conductive pillar 6043 and one end of the fourth conductive pillar 6044 are both communicated with the power supply, and wherein the third conductive pillar 6043 and the fourth conductive pillar 6044 penetrate through a sidewall of the water tank 30, so that the other end of the third conductive pillar 6043 and the other end of the fourth conductive pillar 6044 are located inside the water tank 30.

The power supply to the electrolysis device 60 can be realized by the arrangement of four electrically conductive columns. Thereby ensuring proper operation of the electrolyzer 60 within the water tank 30.

Optionally, the air treatment device 20 further comprises a cleaning device 80 for the electrolysis device 60, the cleaning device 80 comprises a brush 801 and a third driving device 802, the brush 801 can extend into the gap between the positive electrode part 601 and the negative electrode part 602; the third driving device 802 is in driving connection with the brush 801, and can drive the brush 801 to move in the gap and along the extending direction of the gap so as to clean the positive electrode portion 601 and/or the negative electrode portion 602.

In this embodiment, after the electrolytic device 60 is used for a period of time, a layer of scale is formed on the surfaces of the positive electrode portion 601 and the negative electrode portion 602, and with the cleaning device 80 of this embodiment, the third driving device 802 can drive the brush 801 to move along the extending direction of the gap, so as to clean the scale on the positive electrode portion 601 and/or the negative electrode portion 602. But also can 'clean' the electrode at high frequency to effectively prevent the generation of scale.

Optionally, the cleaning device 80 further includes a moving component 807, and the moving component 807 is disposed at an end of the third driving device 802 away from the brush 801, and is connected to the third driving device 802, and can drive the brush 801 to extend into the gap or separate from the gap by driving the third driving device 802 to move.

In this embodiment, when the electrolysis device 60 is in operation, the conductive solution needs to be electrolyzed in the gap, so that the brush 801 is always located in the gap, which affects the electrolysis of the electrolysis device 60. Therefore, the moving assembly 807 can drive the brush 801 to be separated from the gap when the electrolysis device 60 works, so as to ensure the electrolysis of the electrolysis device 60. When cleaning is necessary, brush 801 is moved into the gap to clean the gap, positive electrode portion 601 and negative electrode portion 602.

Alternatively, moving assembly 807 can also bring brush 801 into contact with the upper surfaces of positive electrode portion 601 and negative electrode portion 602 to sweep the upper surfaces of positive electrode portion 601 and negative electrode portion 602 of scale.

Alternatively, as shown in fig. 17 and 18, the moving assembly 807 comprises a rack 8071, a gear 8072 and a fourth driving device 8073, the rack 8071 is disposed at an end of the third driving device 802 away from the brush 801, and is connected to the third driving device 802; the gear 8072 is meshed with the rack 8071; the fourth driving device 8073 is in driving connection with the gear 8072, and can drive the rack 8071 to move in the direction towards the electrolysis device 60 or in the direction away from the electrolysis device 60 through the gear 8072, so as to drive the brush 801 to extend into the gap or separate from the gap.

In this embodiment, the rack 8071 is connected to the third driving device 802, and the rack 8071 can drive the third driving device 802 and the brush 801 to move together. The fourth driving device 8073 and the gear 8072 are used for driving the rack 8071 to move, and finally, the brush 801 moves. The arrangement of the gear 8072, the rack 8071 and the fourth driving device 8073 makes the movement process of the moving assembly 807 accurate and reliable.

Specifically, the rack 8071 extends in a direction from the brush 801 to the electrolyzer 60 to effect movement of the brush 801 into and out of the gap.

The rack 8071, the third driving device 802, and the brush 801 are sequentially arranged in a direction from the brush 801 to the electrolysis device 60 to realize the movement of the brush 801 into or out of the gap.

The movement of the rack 8071 towards the electrolysis device 60 means that: the rack 8071 moves in the direction from the brush 801 to the electrolyzer 60. The rack 8071 is moved in a direction away from the electrolyzer 60, which means that: the rack 8071 moves in the direction from the electrolyzer 60 to the brush 801.

Optionally, as shown in fig. 18, the cleaning device 80 further comprises a housing 803, the housing 803 defining a motor cavity 8031 having an access opening 8032; both moving assembly 807 and third drive 802 are located within motor cavity 8031; wherein, the brush 801 is movably arranged at the entrance 8032.

In this embodiment, the cover 803 facilitates the arrangement of the moving assembly 807 and the third driving device 802, and the brush 801 needs to be inserted into the gap for cleaning, so that the inlet/outlet 8032 of the motor cavity 8031 facilitates the movement of the brush 801.

Optionally, the housing 803 further defines a chute 8034, and the rack 8071 is adapted to the chute 8034, and the rack 8071 can move in the chute 8034.

In this embodiment, the chute 8034 provides a space for the movement of the rack 8071, so that the movement of the rack 8071 is facilitated, and the movement of the brush 801 is further realized.

The chute 8034 also extends in the direction from the brush 801 to the electrolyzer 60 to facilitate movement of the rack 8071.

The rack 8071 is matched with the chute 8034, and means that: the rack 8071 and the chute 8034 are identical or similar in shape and size.

Optionally, the housing 803 includes a housing body 8035 and a boss 8033, the housing body 8035 defines a motor cavity 8031, and the boss 8033 is located in the motor cavity 8031 and is connected to the housing body 8035; wherein, the sliding slot 8034 is arranged on the boss 8033.

Taking the electrolytic device 60 disposed at the bottom of the accommodating cavity 303 as an example, the cleaning device 80 is disposed above the electrolytic device 60, wherein the brush 801, the third driving device 802 and the rack 8071 are sequentially disposed along a direction from bottom to top, and the moving assembly 807 can drive the brush 801 to move along an up-and-down direction to extend into the gap or separate from the gap.

Wherein the rack 8071 and the gear 807 are vertically disposed to facilitate the engagement of the gear 8072 and the rack 8071. The fourth driving means 8073 is located on one side of the gear 8072 to facilitate driving the gear 8072 to rotate.

Specifically, the third driving device 802 and the fourth driving device 8073 may be a stepping motor or a motor or the like.

Optionally, the cleaning device 80 further includes an electronic control board 804, the electronic control board 804 is located in the motor cavity 8031 and electrically connected to the third driving device 802 and the fourth driving device 8073, and the electronic control board 804 is configured to control operations of the third driving device 802 and the fourth driving device 8073.

Optionally, as shown in fig. 19, the cleaning device 80 further includes a locking foot 805, the locking foot 805 is disposed on a wall surface of the housing 803 facing the electrolyzer 60; the number of the locking feet 805 is multiple, the locking feet 805 are sequentially arranged on the wall surface of the outer cover 803 facing the electrolysis device 60 at intervals along the circumferential direction of the outer cover 803, at least one of the locking feet 805 defines a routing channel 806, and the routing channel 806 is communicated with the motor cavity 8031, so that the electric control board 804 is electrically connected with the circuit in the routing channel 806.

In this embodiment, the plurality of clamping pins 805 facilitate the cleaning device 80 to be stably placed in the water tank 30, and one of the clamping pins is provided with a wiring channel 806 for facilitating power supply of the electric control board 804.

Alternatively, when the electrolyzer 60 is disposed at the bottom of the containing cavity 303, the inlet of the wiring channel 806 communicates with the outside of the bottom wall of the water tank 30, so that the wiring is disposed from the bottom of the water tank 30 and is connected to the electronic control board 804.

Optionally, the brush 801 comprises a disc 8011 and a group 8012 of bristles, the disc 8011 being in driving connection with a third drive 802; the bristle group 8012 is arranged on the side of the disc 8011 facing the electrolysis device 60; the bristle group 8012 comprises a plurality of bristles, and the bristle group 8012 is annular and is matched with the gap.

In this embodiment, the brush set 8012 is matched with the gap, that is, the shape and size of the brush set 8012 are the same as or similar to the gap, so that the brush set 8012 can sweep the gap and the positive and negative electrode portions more fully. For example, the gap may be annular and each bristle group 8012 may be annular.

Optionally, the number of the positive electrode portions 601 and the negative electrode portions 602 is multiple, and when a plurality of gaps are formed by alternately sleeving the positive electrode portions 601 and the negative electrode portions 602 at intervals, the number of the bristle groups 8012 is multiple, and the number of the bristle groups 8012 is the same as the number of the gaps and corresponds to one another.

In this embodiment, the plurality of brush groups 8012 can clean a plurality of gaps, and thus can clean the entire surface of the electrolyzer 60, thereby ensuring the cleanliness of the electrolyzer 60.

Optionally, the air treatment device 20 further comprises a detection device and a controller, the detection device is used for detecting the current information of the electrolysis device 60; the controller is connected with the detection device and is configured to obtain the water level information in the accommodating cavity 303 according to the current information of the electrolysis device 60.

In this embodiment, when the electrolytic device 60 is in contact with the conductive solution, the positive electrode portion 601 and the negative electrode portion 602 form a series circuit, and a current flows through the electrolytic device 60. When the electrolytic device 60 is separated from the conductive solution, the positive electrode 601 and the negative electrode 602 are disconnected, and no current flows through the electrolytic device 60, so that the water level in the water tank 30 can be determined by detecting the current in the electrolytic device 60, and the user can be reminded to replace the conductive solution or purify the water.

Optionally, as shown in fig. 7-11, the air treatment device 20 further includes a charging mechanism 70, the charging mechanism 70 being used to add the conductive article into the water tank 30 (which may be understood as the receiving cavity 303). Wherein the housing 10 defines a feeding channel 701, an outlet 7011 of which communicates with the water tank 30 (which can be understood as the accommodation chamber 303); the feeding mechanism 70 comprises a feeding device 702 and a driving device (for convenience of distinction, hereinafter, referred to as a second driving device 703), an outlet of the feeding device 702 is communicated with an inlet of the feeding channel 701, and the feeding device 702 is spiral and used for containing conductive products; the second driving device 703 is in driving connection with the feeding device 702, and can drive the feeding device 702 to rotate around the axis thereof, so that the feeding device 702 pushes the conductive product into the feeding channel 701.

In this embodiment, the feeding device 702 is helical, the conductive product is located in the gap of the feeding device 702, and when the second driving device 703 drives the feeding device 702 to rotate around the axis of the feeding device 702, the helical feeding device 702 will push the conductive product in the gap to move, and finally the conductive product is fed into the feeding channel 701. The feeding of the air treatment device 20 is accurately controlled by the arrangement of the second driving device 703 and the feeding device 702.

The second driving device 703 may be a stepping motor, a motor, or the like.

Optionally, the feeding device 702 includes a central shaft 7022 and a plurality of helicoids 7021, the central shaft 7022 is in driving connection with the second driving device 703, the plurality of helicoids 7021 are sequentially arranged on the central shaft 7022 at intervals along the circumferential direction of the central shaft 7022, the conductive product is located in a gap between adjacent helicoids 7021, and when the second driving device 703 drives the central shaft 7022 to rotate, the helicoids 7021 rotate, and then the conductive product in the gap between adjacent helicoids 7021 can be driven to move.

Optionally, as shown in fig. 7, the charging mechanism 70 further includes a rotating disc 704, the rotating disc 704 is disposed at a communication position between an outlet of the charging device 702 and an inlet of the charging channel 701, and the rotating disc 704 is provided with a release port 7041; when the feeding device 702 rotates, the feeding device 702 can push the conductive product to enter the feeding channel 701 through the release port 7041.

In this embodiment, the conductive product pushed by the feeding device 702 can only enter the feeding channel 701 through the release port 7041 of the rotating disc 704, and the conductive product of the feeding device 702 can be prevented from flowing into the feeding channel 701 uncontrollably.

Optionally, the dial 704 is circular-like and the release port 7041 is sector-like.

In this embodiment, the feeding device 702 is spiral and can rotate around its axis, and the rotating disc 704 is circular-like, so as to better prevent the conductive product of the feeding device 702 from flowing out. The release port 7041 is fan-shaped and is matched with the spiral feeding device 702, so that the quantity of the conductive product passing through the release port 7041 every time is the same, and the addition quantity of the conductive product is controlled conveniently.

Optionally, a second driving device 703 is provided on a side of the feeding device 702 facing away from the turntable 704.

The second driving device 703 is located on one side of the feeding device 702 departing from the rotating disc 704, so that the feeding device 702 is driven to rotate conveniently, the space of the rotating disc 704 is not occupied, and the flowing smoothness of the conductive product is ensured.

The housing 10 further defines a feeding cavity 705 having an opening (hereinafter referred to as a second opening for convenience of distinction), and the feeding device 702 and the second driving device 703 are both disposed in the feeding cavity 705; the feeding mechanism 70 further includes a cover (hereinafter, referred to as a second cover 706 for convenience of distinction), and the second cover 706 covers the second opening.

In this embodiment, the second opening is convenient for a user to add a conductive product into the feeding cavity 705, and the second cover 70 can prevent external dust, impurities and the like from entering the feeding cavity 705.

Optionally, one end of the second cover 706 is rotatably connected to the housing 10, and the other end of the second cover 706 is a free end. So that the second cover 706 can be opened to add the conductive product to the feeding cavity 705.

Optionally, the second cover 706 further includes an elastic member connected between the second cover 706 and the housing 10, wherein the elastic member is elastically deformed when the second cover 706 is opened. In this embodiment, after the second cover 706 is opened, when the user has added the conductive product, the second cover 706 can be automatically closed to prevent the second cover 706 from being covered in place, which may cause dust to enter the feeding chamber 705. The elastic element can be a spring or a rubber band and the like.

Alternatively, as shown in fig. 10 and 11, the feeding device 702 is located above the water tank 30, and in the case where the electrolysis device 60 is provided on the side wall of the water tank 30, the feeding passage 701 is inclined in the direction from the top to the bottom toward the electrolysis device 60.

In this embodiment, the feeding channel 701 is provided to facilitate the conductive product to smoothly slide into the water tank 30 in the feeding channel 701 by using its own gravity.

Optionally, the dosing channel 701 comprises an arcuate channel to reduce the loss of conductive product during flow, further facilitating the flow of conductive product into the water tank 30.

Optionally, the controller is electrically connected to the electrolysis device 60, the first driving device 202 and the second driving device 703, the controller receives the water level information in the accommodating cavity 303 detected by the detecting device, the controller controls the second driving device 703 to rotate for a preset number of turns, and then the controller controls the electrolysis device 60 to be powered on and controls the first driving device 202 to work simultaneously. Wherein the electrolysis device 60 is controlled to be powered on to electrolyze the conductive solution, and the first driving device 202 is controlled to operate so as to rotate the purification assembly 40 in the water tank 30, so as to accelerate the mixing of the conductive product and the purification water, and accelerate the diffusion of the disinfection water in the water tank 30.

The second embodiment is different from the first embodiment in that:

as shown in fig. 12 to 15, the purifying module 40 is axially and horizontally disposed in the accommodating cavity 303, at least one side wall of the water tank 30 is provided with an air inlet 301, the first driving device 202 is disposed on the at least one side wall of the water tank 30 and is in driving connection with at least one axial end surface of the purifying module 40 to drive the purifying module 40 to rotate along the circumferential direction of the purifying module 40, and the at least one axial end surface of the purifying module 40 is disposed corresponding to and communicated with the air inlet 301 as an example:

in the case that the first driving device 202 and the air inlet 301 are disposed on the same side wall, the first driving device 202 is located outside the air inlet 301.

The purge assembly 40 has a cylindrical shape, and the interior of the purge assembly 40 defines an inner space.

At least one side wall of the water tank 30 is provided with an air inlet 301, the purification assembly 40 is axially and horizontally arranged in the accommodating cavity 303, and the air inlet 301 is correspondingly arranged and communicated with at least one axial end surface of the purification assembly 40. Therefore, when the airflow flowing in from the air inlet 301 can flow to the inner space in the purification assembly 40, the airflow can flow through the middle part and the upper part of the purification assembly 40, compared with the related art in which the airflow only flows through the upper part of the purification assembly 40, in the air treatment device 20 of the embodiment, the contact area between the airflow and the purification assembly 40 is increased, and the purification and/or humidification effect of the purification assembly 40 on the airflow is improved. Because the lateral wall of water tank 30 is located to air intake 301, in order to guarantee that purification subassembly 40 can follow its circumferential direction, first drive arrangement 202 need be connected with the drive of at least one axial terminal surface of purification subassembly 40, and when drive arrangement and air intake 301 were located same lateral wall, drive arrangement located the outside of air intake 301, can enough guarantee the normal rotation of purification subassembly 40, still can not occupy the space of air intake 301, avoid drive arrangement to influence the air inlet of air intake 301.

Optionally, the first drive device 202 is drivingly connected to the circumferential wall of the first end 4032 and/or the second end 4033.

Since the axial end face of the purifying module 40 is disposed corresponding to the air inlet 301, it can be understood that: the first end 4032 and/or the second end 4033 is provided corresponding to the air inlet 301. The first driving device 202 is in driving connection with the circumferential wall surface of the first end surface and/or the second end surface, so that the first driving device 202 is arranged outside the air inlet 301, and the first driving device 202 is prevented from interfering with the inlet air of the air inlet 301.

Optionally, as shown in fig. 13, the first end 4032 and/or the second end 4033 includes a first gear 406, which may be understood to be: the first end 4032 and/or the second end 4033 is/are in the form of a gear, the air treatment device 20 further includes a second gear 407, the output shaft of the first drive device 202 is drivingly connected to the second gear 407, and the second gear 407 is in meshing engagement with the first gear 406.

In this embodiment, the first driving device 202 drives the second gear 407 to rotate, the second gear 407 drives the first gear 406 to rotate, the first gear 406 rotates, and the first gear 406 rotates to drive the supporting frame 403 to rotate circumferentially, so as to finally realize circumferential rotation of the purification membrane 401.

Optionally, the outer diameter of the first gear 406 is larger than the outer diameter of the second gear 407.

In this embodiment, since the first end 4032 and/or the second end 4033 includes the first gear 406, the outer diameter of the first gear 406 is larger, that is, the outer diameter of the first end 4032 and/or the second end 4033 is larger. Thus, the outer diameter of the supporting frame 403 can be larger, so that the inner diameter of the purifying element 405 sleeved outside the supporting frame 403 can be increased. The inner diameter of the purification member 405 is increased, the surface area of the purification member 405 is increased, the contact area between the purification member 405 and the purification water and the air flow is further increased, and the purification and humidification effects are improved.

The second gear 407 is engaged with the first gear 406, the first gear 406 is located in the accommodating cavity 303, and the second gear 407 is at least partially located in the accommodating cavity 303. The second gear 407 has a small size, so that the space in the accommodating chamber 303 occupied by the second gear 407 can be reduced, and the size of the purifying member 405 can be ensured.

The third embodiment is different from the first and second embodiments in that,

as shown in fig. 22 to 24, the purifying assembly 40 includes a purifying wheel set 402, the purifying wheel set 402 includes a plurality of annular wheel pieces 4021 (which can be understood as a purifying member 405) arranged at intervals in an axial direction of the purifying wheel set 402, the purifying wheel set 402 is arranged horizontally in the accommodating chamber 303 in the axial direction, at least a part of the purifying wheel set 402 can be soaked in the purifying water, and a lower end of the purifying wheel set 402 is always located in the purifying water; the first driving device 202 is configured to controllably drive the purifying disc set 402 to rotate circumferentially, so that the circumferential wall surface of the purifying disc set 402 infiltrates the purifying water in turn, so that a water film is formed on the surface of each annular disc 4021, that is, the surface of each annular disc 4021 in the circumferential direction can be adhered with the water film; the fan 50 can drive airflow to flow into the accommodating cavity 303 from the air inlet 301, and then flow into or out of the interior of the purification wheel set 402 through the gap between two adjacent annular wheel sheets 4021, and then flow to the air outlet 302 after contacting with a water film.

In this embodiment, each annular wheel plate 4021 forms a water film, and in the process of flowing through the gap between two adjacent annular wheel plates 4021, the air flow contacts with the water film on the surface of the annular wheel plate 4021, so that impurities or pollutants in the air flow can be blocked by the water film and/or the annular wheel plates 4021, and the function of purifying the air flow is further achieved. Similarly, after the air flow contacts with the water film and the water film on the surface of the annular wheel 4021, the water content is increased, and the humidifying function is realized.

As shown in fig. 23, the plurality of annular wheel plates 4021 make the cleaning wheel set 402 have a hollow cylindrical shape, that is, the plurality of annular wheel plates 4021 jointly define an internal space, which is cylindrical, the fan 50 can drive the airflow flowing into the accommodating chamber 303 to flow into the internal space, and during the process of flowing into or out of the internal space, the airflow will pass through the gap between adjacent annular wheel plates 4021 and then flow out of the internal space, so as to contact with the water film on the surface of each annular wheel plate 4021, and the water film can clean impurities in the airflow and humidify the airflow.

The inner side (towards one side of the inner space) and the outer side (away from one side of the inner space) of each annular wheel plate 4021 can be in contact with water, and the inner side and the outer side of each annular wheel plate 4021 and the wheel plate surface connected to the inner side and the outer side can form a water film, so that the contact area between the air flow and the water film is increased, and the purification and humidification effects of the purification wheel plate set 402 on the air flow are improved.

Optionally, at least one axial end surface of the purification wheel set 402 is communicated with the air inlet 301, and the fan 50 can drive air to flow into the accommodating cavity 303 through the air inlet 301, flow into the purification wheel set 402 through at least one axial end surface, flow to the air outlet 302 through a gap between two adjacent annular wheel pieces 4021, and flow out to the air outlet 302 after contacting with a water film.

In this embodiment, the airflow may flow out from one axial end surface or two axial end surfaces of the purifying vane set 402, and then flow out from the gap between two adjacent vanes (i.e. the circumferential wall surface of the purifying vane set 402), so as to increase the flow rate of the air inlet 301, and increase the purifying and humidifying effects of the air treatment device 20. And the two axial end surfaces can flow in air flow, so that no flowing dead angle exists, the contact area of the air flow and the purification wheel set 402 can be further increased, and the purification and humidification effects are improved.

Optionally, a plurality of annular blades 4021 are coaxially disposed.

In this embodiment, the plurality of annular wheel plates 4021 are coaxially arranged, so that the plurality of annular wheel plates 4021 rotate synchronously, the space required by rotation is small, and the space in the water tank 30 is saved.

Optionally, the supporting frame 403 is connected to all the plurality of annular wheel plates 4021, and is in driving connection with the first driving device 202, and the first driving device 202 can drive the supporting frame 403 to rotate so as to drive the purifying wheel set 402 to rotate circumferentially.

In this embodiment, the supporting frame 403 is used to connect the plurality of annular wheel plates 4021, so that the rotation of the plurality of annular wheel plates 4021 is synchronized, and the flowing direction of the airflow is relatively stable.

Optionally, the support bracket 403 includes a support column 4031, and the support column 4031 extends along the axial direction of the purification wheel set 402 and is connected between the plurality of annular wheel plates 4021.

In this embodiment, the supporting column 4031 is used to drive the plurality of annular wheel plates 4021 to rotate synchronously, so as to realize the synchronous rotation of the plurality of wheel plates. The number of the support columns 4031 is multiple, and the support columns 4031 are sequentially arranged along the circumferential direction of the purification wheel disc set 402 at intervals, so that the support columns are convenient for supporting the plurality of annular wheel discs 4021. For example, the number of the support columns 4031 may be three, four or five, and when the number of the support columns 4031 is too small, for example, less than three, the stability of the support frame 403 is poor, and the annular wheel plate 4021 cannot be stably supported. The number of support columns 4031 cannot be too large, for example, more than five, and the gaps between the support columns 4031 are small, which may affect the flow of gas through the support columns 4031 to the gaps between adjacent annular blades 4021.

Optionally, the support frame 403 is also cylindrical, and the support frame 403 further includes a first end 4032 and a second end 4033, the support column 4031 is connected between the first end 4032 and the second end 4033, and the first end 4032 and the second end 4033 are rounded to facilitate connection of a plurality of support columns 4031.

Optionally, the first drive device 202 is drivingly connected to the first end 4032 and/or the second end 4033.

The connection between the first driving device 202 and the first end 4032 and/or the second end 4033 includes the connection between the first driving device and the second driving device in the first embodiment and the second embodiment, which are not described again.

Optionally, the number of the air inlets 301 is multiple, and at least two air inlets 301 of the multiple air inlets 301 are respectively disposed on two opposite side walls of the water tank 30; the two axial end surfaces of the purification wheel set 402 are respectively communicated with the at least two air inlets 301, and the fan 50 can drive air to flow into the purification wheel set 402 through the at least two air inlets 301, flow into the purification wheel set 402 through the two axial end surfaces of the purification wheel set 402, and flow out to the air outlet 302 through the water film.

In this embodiment, the sidewall of the water tank 30 may be provided with a plurality of air inlets 301, two opposite sidewalls of the water tank 30 are respectively provided with the air inlets 301, two axial end surfaces of the purification membrane 401 respectively correspond to the at least two air inlets 301, that is, the axial direction of the purification wheel set 402 is the same as the setting direction of the two opposite sidewalls of the water tank 30, so that the flow path of the air flowing into the accommodating cavity 303 can be reduced, the loss of the air in the flowing process is avoided, and the air output of the air processing device 20 is ensured. In addition, in this embodiment, the airflow flows into the purification membrane 401 from the axial end surfaces on both sides of the purification wheel set 402, so as to further ensure the contact area between the airflow and the purification membrane 401, and improve the purification and humidification effects of the air treatment device 20.

Optionally, each annular wheel 4021 is provided with an orange peel texture structure or a polygonal structure, so that the surface area of each annular wheel 4021 can be increased, the area of a water film formed on the surface of each annular wheel 4021 is increased, the contact area of the air flow and the water film is increased, and the purification and humidification effects are further improved.

Optionally, purge wheel set 402 is an integrally formed structure. The purification wheel set 402 is integrally formed, so that the purification wheel set is convenient to produce, transport and install.

Alternatively, the plurality of annular wheel plates 4021 and the supporting frame 403 may be detachable, so as to facilitate cleaning of each annular wheel plate 4021 and replacement and maintenance of each annular wheel plate 4021. The plurality of annular wheel plates 4021 and the support frame 403 can be detachably connected by adopting a buckle, a screw and the like.

Purify subassembly 40 and include under the condition of purifying wheel piece group 402, purify wheel piece group 402 and in holding chamber 303, also can contact with the disinfection water that the electrolysis produced, and then disinfection water can carry out degerming virus killing to purifying film 401, avoids purifying film 401's bacterial growing.

The embodiment of the present disclosure also provides an air conditioner 100, and the air conditioner 100 includes the air processing device 20 in any one of the above embodiments.

The air conditioner 100 according to the embodiment of the present disclosure includes the air processing device 20 according to any one of the above embodiments, so that all the advantages of the air processing device 20 according to any one of the above embodiments are achieved, and are not described herein again.

The above description and the drawings sufficiently illustrate embodiments of the disclosure to enable those skilled in the art to practice them. Other embodiments may include structural and other changes. The examples merely typify possible variations. Individual components and functions are optional unless explicitly required, and the sequence of operations may vary. Portions and features of some embodiments may be included in or substituted for those of others. The embodiments of the present disclosure are not limited to the structures that have been described above and shown in the drawings, and various modifications and changes may be made without departing from the scope thereof. The scope of the present disclosure is limited only by the appended claims.

Claims (10)

1. A cleaning device for an electrolysis device, the electrolysis device comprising a positive portion and a negative portion, the positive portion and the negative portion being spaced apart, the cleaning device comprising:

a brush capable of extending into a gap between the positive electrode part and the negative electrode part;

and the third driving device is in driving connection with the hairbrush and can drive the hairbrush to move in the gap and along the extending direction of the gap so as to clean the positive electrode part and/or the negative electrode part.

2. The cleaning device for electrolytic devices of claim 1, further comprising:

and the moving assembly is arranged at one end of the third driving device, which deviates from the brush, is connected with the third driving device, and can drive the brush to extend into the gap or separate from the gap by driving the third driving device to move.

3. The cleaning device for electrolytic devices of claim 2, wherein said moving assembly comprises:

the rack is arranged at one end of the third driving device, which is far away from the hairbrush, and is connected with the third driving device;

the gear is meshed with the rack;

and the fourth driving device is in driving connection with the gear, and can drive the rack to move along the direction towards the electrolysis device or move along the direction deviating from the electrolysis device through the gear, so as to drive the brush to extend into the gap or separate from the gap.

4. The cleaning device for electrolysis devices according to claim 3, further comprising:

a housing defining a motor chamber having an inlet and an outlet;

the moving assembly and the third driving device are both positioned in the motor cavity;

wherein the brush is movably arranged at the entrance and the exit.

5. The cleaning device for electrolytic apparatus according to claim 4,

the outer cover further limits a sliding groove, the rack is matched with the sliding groove, and the rack can move in the sliding groove.

6. The cleaning device for electrolytic devices of claim 4, further comprising:

and the electric control board is positioned in the motor cavity and is electrically connected with the third driving device and the fourth driving device.

7. The cleaning apparatus for an electrolysis apparatus according to claim 6, further comprising:

the clamping feet are arranged on the wall surface of the outer cover facing the electrolytic device;

the quantity of screens foot is a plurality of, and is a plurality of the screens foot is followed the circumference of dustcoat is located at interval in proper order the dustcoat orientation electrolytic device's wall, and is a plurality of at least one in the screens foot is injectd the line passageway, the line passageway with the motor chamber is linked together, so that automatically controlled board with the line electricity in the line passageway is connected.

8. The cleaning device for an electrolysis device according to any one of claims 1 to 7,

the positive electrode part and the negative electrode part are both annular, and are sleeved at intervals in sequence;

the brush includes:

the disc is in driving connection with the third driving device;

the brush bristle group is arranged on one side of the disc, which faces the electrolytic device;

wherein the bristle group comprises a plurality of bristles, and the bristle group is annular and is suitable for being matched with the gap.

9. The cleaning device for electrolytic apparatus according to claim 8,

the number of the positive electrode parts and the negative electrode parts is multiple, and the positive electrode parts and the negative electrode parts are alternately sleeved at intervals to form multiple gaps which are sequentially sleeved;

the number of the bristle groups is multiple, and the number of the bristle groups is suitable for being the same as the number of the gaps and corresponding to the number of the gaps one by one.

10. An air conditioner comprising an air treatment device, the air treatment device comprising:

the water tank is used for containing a conductive solution;

the electrolytic device is positioned in the water tank and is used for electrolyzing the conductive solution into water for disinfection;

the cleaning device for electrolytic apparatus of any one of claims 1 to 9, located within the water tank.

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