CN116408214B - Atomizing device - Google Patents

Abstract

The invention relates to the technical field of ultrasonic atomization devices, in particular to an atomization device, which comprises a shell assembly, wherein the shell assembly is provided with a liquid storage cavity and a mist outlet, and the liquid storage cavity is communicated with the mist outlet; the atomization piece is used for atomizing the liquid in the liquid storage cavity; the air duct assembly is detachably arranged on the shell assembly, an air supply cavity is formed by surrounding the air duct assembly and the shell assembly, and the air supply cavity is communicated with the liquid storage cavity; and the fan assembly is communicated with the air supply cavity. The detachable mode is used to the wind channel subassembly, and atomizing device when normal use, wind channel subassembly set up on the casing subassembly and enclose between the two and have closed and have formed the air supply chamber, when wind channel subassembly was dismantled, can clean respectively to enclosing casing subassembly and the wind channel subassembly that forms the air supply chamber, and the convenience of use personnel dismantles the wind channel subassembly and washs, avoids influencing out fog quality because other debris such as the dust of wind channel subassembly.

Description

Atomizing device

Technical Field

The invention relates to the technical field of ultrasonic atomization devices, in particular to an atomization device.

Background

The conventional atomizing device mainly uses ultrasonic waves to convert liquid into ultrafine particles, which are then discharged into air. The ultrasonic atomizing sheet commonly used in the existing atomizing device atomizes liquid, ultrasonic waves are emitted in the liquid through vibration of a piezoelectric ceramic transducer (atomizing sheet), the liquid is finally torn into tiny liquid drops by ultrasonic energy to form atomization, then mist is conveyed to the outside of the atomizing device through a fan assembly, the fan assembly is communicated with an air duct assembly, the air duct assembly is generally integrally formed with a base, the air duct assembly cannot be regularly cleaned, and accordingly pollution is caused to mist-emitting objects, and the using effect of the atomizing device is reduced.

Disclosure of Invention

Based on this, it is necessary to provide an atomizer device which is directed to the problem that the air duct assembly used in the atomizer device is generally difficult to disassemble, and thus the fog is easily polluted during use.

An atomizing device, comprising: the shell assembly is provided with a liquid storage cavity and a mist outlet, and the liquid storage cavity is communicated with the mist outlet; the atomizing piece is arranged on the shell assembly, is at least partially positioned in the liquid storage cavity and is used for atomizing liquid in the liquid storage cavity; the air duct assembly is detachably arranged on the shell assembly, an air supply cavity is formed by surrounding the air duct assembly and the shell assembly, and the air supply cavity is communicated with the liquid storage cavity; the fan assembly is arranged on the shell assembly and is communicated with the air supply cavity.

The application discloses an atomization device, which is characterized in that an atomization piece is arranged on a shell component, the atomization piece is at least partially contacted with liquid stored in a liquid storage cavity, the atomization piece is used for atomizing the liquid stored in the liquid storage cavity, an air duct component is detachably arranged on the shell component, an air supply cavity is formed between the air duct component and the shell component when the air duct component is arranged on the shell component in a covering manner, and air flow is formed in the air duct component under the action of a fan component, and mist generated at the position of the liquid storage cavity can be conveyed to the outside of the shell component by the air flow. Wherein, the wind channel subassembly uses detachable mode, and atomizing device when normal use, wind channel subassembly set up on the casing subassembly and enclose between the two and have closed and have formed the air supply chamber, when wind channel subassembly was dismantled, can clean respectively the casing subassembly and the wind channel subassembly that enclose and form the air supply chamber, and the convenience of use personnel dismantles the wind channel subassembly and washs, avoids influencing out fog quality because other debris such as the dust of wind channel subassembly.

In one embodiment, the housing assembly comprises a base, a water kettle bottle and a handle, the water kettle bottle is arranged on the base, the water kettle bottle is provided with the liquid storage cavity, the handle is arranged on the base and/or the water kettle bottle, the air duct assembly is detachably arranged on the handle, and the air supply cavity is formed between the air duct assembly and the handle. The application sets the handle part outside the kettle bottle body, and the detachable mode between the air duct component and the handle component is faster and more convenient by arranging the handle part and the air duct component on the handle part.

In one embodiment, the two ends of the handle portion are respectively arranged on the shell component and the water kettle bottle body, the fan component is arranged on the base, a first air outlet communicated with the fan component is arranged on the base, the water kettle bottle body is provided with a second air outlet, the first air outlet, the air supply cavity and the second air outlet are sequentially communicated, the water kettle bottle body is provided with a nozzle, the nozzle is provided with a mist outlet, and the second air outlet and the nozzle are oppositely arranged. The first air outlet and the second air outlet are respectively arranged at two ends of the handle, which are respectively connected with the shell component and the kettle bottle body, wherein the first air outlet is communicated with the fan component, the second air outlet is used as an air outlet of the air supply cavity to be communicated with the liquid storage cavity, and mist generated at the liquid storage cavity is conveyed to the outside of the atomizing device through the mist outlet, wherein the atomizing device is provided with a nozzle which is arranged opposite to the second air outlet, and the nozzle is provided with the mist outlet, so that the mist can be conveyed to the outside of the shell component more intensively through the nozzle, and the spraying conveying distance and the mist outlet effect can be improved.

Specifically, the kettle bottle includes bottle and lid, and the bottle is equipped with the stock solution chamber, and the lid sets up on the bottle for the fog body that the stock solution intracavity produced can spill over through the nozzle. When the cover body is opened, the mist is conveyed to the outside of the atomizing device through the opening at the cover body, and compared with the mist outlet of the nozzle, the cover opening and the mist outlet can improve the coverage area of the mist.

In one embodiment, the base is provided with a plurality of air inlets, the air inlets are located on the bottom wall and/or the side wall of the base, and the air inlets are arranged close to the fan assembly. Through be equipped with a plurality of air intakes on the base is close to one side that fan subassembly set up, for example, the air intake can set up simultaneously in the diapire and the lateral wall department of base to improve the intake of wind channel subassembly, and then improve out fog effect, for example go out fog time, go out fog conveying distance and the cover effect in the certain space.

In one embodiment, the handle portion is provided with a first opening, the first opening is matched with the air duct assembly, the air duct assembly comprises an air duct shell and a clamping piece, the air duct shell is arranged on the handle portion and located at the first opening, the clamping piece is arranged on the air duct shell, the shell assembly or the handle portion is provided with a limiting hole, and the clamping piece is clamped with the side wall of the limiting hole. Through be equipped with on the handle portion be used for with the first opening of wind channel subassembly looks adaptation for after the wind channel subassembly was dismantled from the handle portion, can directly clean the air supply chamber lateral wall of handle portion department through first opening, likewise, set up on the wind channel subassembly with the second opening of first opening looks adaptation, can clean the air supply chamber lateral wall of wind channel subassembly department through the second opening. Further, the handle part and the air duct component adopt a clamping detachable structure, and the clamping piece and the limiting hole are matched and clamped through the air duct component, so that the air duct component is assembled on the handle part, and the clamping detachable structure is simpler and occupies small space.

In one embodiment, the clamping piece comprises a clamping piece body and a sliding part, the clamping piece body is arranged on the air duct shell, the sliding part is arranged on the clamping piece body, the sliding part extends towards the limiting hole, and the sliding part forms a first sliding cambered surface. Through being equipped with sliding part on the joint spare body, this sliding part extends towards spacing hole for sliding part can the joint on the lateral wall of spacing hole, further, be formed with first slip cambered surface on the sliding part, when assembling between wind channel subassembly and handle portion, sliding part slides along the lateral wall of spacing hole, this slip cambered surface can carry out the butt with the lateral wall of spacing hole, through being equipped with the slip cambered surface on the sliding part, friction in the reduction assembly process, and when the user dismantles wind channel subassembly from the handle portion, thereby can make the first slip cambered surface of sliding part slide along the lateral wall of spacing hole through specific promotion angle can break away from with spacing hole lateral wall's joint relation, the dismantlement and the washing of wind channel subassembly have been made things convenient for to a greater extent to above-mentioned detachable joint structure.

In one embodiment, the liquid storage device further comprises a backflow part, wherein the backflow part is arranged on the shell assembly, one end of the backflow part is located on the side wall of the shell assembly, and the other end of the backflow part extends towards the liquid storage cavity. In order to further improve atomizing device's use interest, through being provided with the backward flow portion on the inside wall of casing subassembly, because this backward flow portion can extend along the direction of lateral wall towards the stock solution chamber, atomizing piece can rise at the in-process fog to the liquid in stock solution chamber, the fog bumps between the in-process that rises and the backward flow portion, thereby make a portion fog can liquefy and assemble into the liquid droplet on the lateral wall of backward flow portion, liquid can drip to the stock solution intracavity again, produce the drip sound of liquid drip, thereby atomizing device's interest has been improved.

In one embodiment, the end of the backflow portion away from the side wall of the housing assembly forms a bump, and the bump forms a second sliding arc surface. The fog forms a convex block on the backflow part in the rising process, and part of the fog can be liquefied and fall back into the liquid storage cavity along a second sliding cambered surface formed on the convex block. Preferably, a plurality of projections are formed on the same side of the backflow portion, so that the effect of falling back to the liquid storage cavity after mist liquefaction is enhanced.

In one embodiment, the backflow portion is disposed opposite to the atomizing member, and the backflow portion is located on a side close to the atomizing hole of the atomizing member. In order to further improve the effect of falling back to the liquid storage cavity after the fog liquefaction, the backflow part is arranged opposite to the atomization piece, and the backflow part is positioned above the atomization piece.

In one embodiment, the device further comprises a baffle assembly, wherein the baffle assembly is arranged on the shell assembly, the baffle assembly is at least partially positioned in the liquid storage cavity, the baffle assembly divides the liquid storage cavity into a first liquid storage cavity and a second liquid storage cavity, the second liquid storage cavity is communicated with the first liquid storage cavity, and the atomization piece is at least partially positioned in the second liquid storage cavity; still include the conveying subassembly, conveying subassembly sets up on the baffle subassembly, conveying subassembly is used for with the liquid in first stock solution chamber is carried to the second stock solution chamber, the baffle subassembly or the casing subassembly is equipped with scale removal device, scale removal device is used for reducing water hardness. Because the atomization amount of the atomization piece receives the influence of the liquid storage amount of the liquid storage cavity where the atomization piece is located, through being equipped with the baffle assembly inside the casing assembly, this baffle assembly can separate the liquid storage cavity and form first liquid storage cavity and second liquid storage cavity, wherein first liquid storage cavity is used for storing the liquid that the second liquid storage cavity needs to atomize in advance, be equipped with the conveying component and be used for carrying the liquid of first liquid storage cavity to the second liquid storage cavity, and second liquid storage cavity department is equipped with the atomization piece, the atomization piece atomizes the liquid of second liquid storage cavity only, thereby can regulate and control the liquid output of second liquid storage cavity according to the control of conveying component, on the one hand can improve the atomization effect of atomization piece, on the other hand is equipped with first liquid storage cavity and second liquid storage cavity through separately, avoid singly carrying or the excessive liquid that adds to influence the atomization piece atomization amount is low, avoid simultaneously to add the repetitive work of liquid many times, and the live time after the single liquid feeding of atomization component is longer.

Further, when the liquid atomized by the atomizing device is water, the atomizing effect can be greatly influenced by the scaling problem in the atomizing process of the atomizing piece, so the descaling device is additionally arranged, the conveying component conveys the liquid in the first liquid storage cavity to the second liquid storage cavity, and after the content of free calcium ions and magnesium ions in the liquid is reduced by the descaling device, the liquid treated by the descaling device is conveyed to the second liquid storage cavity, so the service life of the atomizing piece is prolonged, and the mist outlet effect of the atomizing piece is improved.

In one embodiment, the conveying assembly comprises a water pump assembly, a conveying pipeline and a four-way valve assembly, the water pump assembly and the four-way valve assembly are arranged on the partition assembly or the shell assembly, the conveying pipeline comprises a first conveying pipeline, a second conveying pipeline, a third conveying pipeline and a fourth conveying pipeline, the first conveying pipeline is communicated with the first liquid storage cavity and the four-way valve assembly, the second conveying pipeline is communicated with the four-way valve assembly and the water inlet end of the descaling device, the third conveying pipeline is communicated with the four-way valve assembly and the water outlet end of the descaling device, and the fourth conveying pipeline is communicated with the four-way valve assembly and the second liquid storage cavity; the water pump assembly comprises a first water pump and a second water pump, the first water pump is arranged on the first conveying pipeline, and the second water pump is arranged on the second conveying pipeline. The four-way valve assembly is internally provided with a valve core, the valve core is communicated with a conveying pipeline, the communicating conveying pipeline comprises a first conveying pipeline, a second conveying pipeline, a third conveying pipeline and a fourth conveying pipeline, when the four-way valve assembly is communicated with the first conveying pipeline and the second conveying pipeline, the first water pump conveys liquid in the first liquid storage cavity to the four-way valve assembly, and the second water pump enables the first conveying pipeline communicated with the four-way valve assembly to be communicated with the second conveying pipeline, so that the liquid is conveyed to the descaling device, and the water hardness of the liquid can be reduced through the descaling device; when the four-way valve assembly is communicated with the second conveying pipeline and the third conveying pipeline, liquid can circulate between the descaling device and the four-way valve, so that the descaling effect of the descaling device on the liquid is further improved; when the four-way valve assembly is communicated with the third conveying pipeline and the fourth conveying pipeline, the liquid treated by the descaling device can be conveyed into the second liquid storage cavity; when the atomized liquid does not need to be subjected to the reaction of the descaling device, for example, other liquid or treated water is stored in the liquid storage cavity, the first conveying pipeline and the fourth conveying pipeline can be communicated through the control four-way valve assembly, so that the liquid in the first liquid storage cavity is directly conveyed into the second liquid storage cavity.

In one embodiment, the four-way valve assembly comprises a base assembly, a valve core and a motor, the four-way valve assembly is arranged on the partition plate assembly, the four-way valve assembly is at least provided with four communication holes, the communication holes are respectively communicated with corresponding conveying pipelines, the valve core is arranged on the base assembly and is provided with an infusion channel, the motor is connected with the valve core, and when the valve core rotates relative to the base assembly, the four-way valve assembly is communicated with the conveying pipelines and the communication holes. Four communication holes are formed in the base assembly and are respectively communicated with the first conveying pipeline, the second conveying pipeline, the third conveying pipeline and the fourth conveying pipeline, the valve core is arranged inside the base assembly and is driven by the motor to rotate, so that the conveying pipelines and the infusion channels are communicated, and liquid in the first liquid storage cavity can be conveyed to the descaling device or the second liquid storage cavity through the four-way valve assembly. In one embodiment, the device further comprises a control component, wherein the control component is used for the four-way valve component to be communicated with the conveying pipelines, and the control component can circulate the second conveying pipeline and the third conveying pipeline according to the set conditions, so that circulating flow is realized between liquid in the conveying pipelines and the descaling device, the descaling device can perform descaling reaction on the liquid in the conveying pipelines for many times, free calcium ion magnesium ion and the like in the liquid are reduced, and the service life of the atomization piece and the mist outlet efficiency are further prolonged.

In one embodiment, the descaling device comprises a mounting housing, a storage box and a stirring assembly, wherein the storage box is arranged on the mounting housing, the stirring assembly is arranged on the mounting housing, and the stirring assembly can move relative to the mounting housing. The liquid outlets of the descaling device, the four-way valve assembly and the fourth conveying pipeline adopt a liquid level difference design mode, the setting height of the descaling device is larger than that of the four-way valve assembly, and the setting height of the four-way valve assembly is larger than that of the liquid outlet of the fourth conveying pipeline; through be equipped with stirring subassembly on scale removal device, can drive the inside liquid flow of scale removal device when stirring subassembly rotates to improve the reaction efficiency between storage box and the liquid. Further, the stirring assembly is arranged at the bottom of the descaling device. The cartridge may use a replaceable activated carbon cartridge to reduce the water hardness of the liquid by adsorption.

In one embodiment, still include heating element, heating element is located the second stock solution intracavity is equipped with heating element through in the second stock solution intracavity for heating element only needs to heat the liquid or the fog of second stock solution chamber department, compares with the whole stock solution chamber of heating element direct heating, and this design mode can reduce the heat energy consumption, and because the heating volume is less relatively, can further improve heating efficiency. By setting the heating temperature of the heating assembly, a hot mist with a set temperature can be obtained, for example, when the atomizing device is used to atomize water, a mist with a set temperature can be generated.

In one embodiment, the heating assembly is disposed on a side wall of the second reservoir, the heating assembly being located on a side of the side wall remote from the atomizer. Because the atomization efficiency of atomizing piece probably receives heating element's influence, make heating element can directly heat the fog through setting up heating element in the one side of keeping away from the atomizing piece to reduce heating element and to the liquid temperature influence of second stock solution intracavity, consequently reduce heating element and model the circumstances that atomization efficiency and atomization volume of atomizing piece descend under the too high condition of heating temperature.

In one embodiment, the diaphragm assembly is provided with a vacuum insulation layer. Through being equipped with the vacuum heat preservation on the baffle subassembly, to a great extent can block the second stock solution chamber and pass through vacuum heat preservation heat transfer to improve the temperature thermal insulation performance in the second stock solution chamber.

In one embodiment, the baffle assembly is made of an insulating material. Similarly, the separator assembly can also be made of a thermally insulating material having a low coefficient of thermal conductivity, such as polystyrene resin, foam insulation panels, and the like.

Drawings

FIG. 1 is a schematic view of an atomizer according to an embodiment of the present application;

FIG. 2 is a first cross-sectional view of an atomizer according to an embodiment of the present application;

FIG. 3 is a second cross-sectional view of an atomizer according to an embodiment of the present application;

FIG. 4 is an enlarged view of area A of FIG. 2;

FIG. 5 is an exploded view of an atomizer according to an embodiment of the present application;

FIG. 6 is a second schematic diagram of an atomization device according to an embodiment of the present application;

FIG. 7 is a third cross-sectional view of an atomizer according to an embodiment of the present application;

FIG. 8 is a fourth cross-sectional view of an atomizer according to an embodiment of the present application;

FIG. 9 is an enlarged view of region B of FIG. 8;

FIG. 10 is a schematic view of a waterway connection structure of a four-way valve assembly according to an embodiment of the present application;

FIG. 11 is a schematic view of the waterway connection of a four-way valve assembly in accordance with an embodiment of the present application;

FIG. 12 is an exploded view of a four-way valve assembly according to one embodiment of the present application.

Wherein, the correspondence between the reference numerals and the component names is:

1 a shell component, 101 a liquid storage cavity, 1011 a first liquid storage cavity, 1012 a second liquid storage cavity, 102 a first air outlet, 103 a second air outlet, 104 a first opening, 105 a limiting hole, 106 an air inlet, 107 a fog outlet, 11 a base, 12 a water kettle bottle, 13 a handle and 14 nozzles;

2, atomizing piece;

the air duct assembly comprises a 3 air duct assembly, a 301 air supply cavity, a 302 first sliding cambered surface, a 31 air duct shell piece, a 32 clamping piece, a 321 clamping piece body and a 322 sliding part;

4, a fan assembly;

a second sliding cambered surface of the reflux part 501;

6, a baffle plate assembly;

7 conveying components, 71 water pump components, 711 first water pump, 712 second water pump, 72 four-way valve components, 721 base components, 722 valve cores, 723 motors, 73 conveying pipelines, 731 first conveying pipelines, 732 second conveying pipelines, 733 third conveying pipelines and 734 fourth conveying pipelines;

8 scale removal device, 81 installation casing, 82 storage box, 83 stirring subassembly.

Detailed Description

In order that the above-recited objects, features and advantages of the present application will be more clearly understood, a more particular description of the application will be rendered by reference to the appended drawings and appended detailed description. It should be noted that, without conflict, the embodiments of the present application and features in the embodiments may be combined with each other.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application, however, the present application may be practiced in other ways than those described herein, and therefore the scope of the present application is not limited to the specific embodiments disclosed below.

Some embodiments of the atomizing device according to the present application are described below with reference to the accompanying drawings.

As shown in fig. 1 to 12, the present embodiment discloses an atomizing device including: the device comprises a shell assembly 1, wherein the shell assembly 1 is provided with a liquid storage cavity 101 and a mist outlet 107, and the liquid storage cavity 101 is communicated with the mist outlet 107; the atomizing piece 2 is arranged on the shell assembly 1, the atomizing piece 2 is at least partially positioned in the liquid storage cavity 101, and the atomizing piece 2 is used for atomizing liquid in the liquid storage cavity 101; the air duct assembly 3 is detachably arranged on the shell assembly 1, an air supply cavity 301 is formed by surrounding the air duct assembly and the shell assembly 1, and the air supply cavity 301 is communicated with the liquid storage cavity 101; fan assembly 4, fan assembly 4 sets up on casing subassembly 1, and fan assembly 4 communicates with air supply cavity 301.

The application discloses an atomization device, which is characterized in that an atomization piece 2 is arranged on a shell component 1, the atomization piece 2 is at least partially contacted with liquid stored in a liquid storage cavity 101, the atomization piece 2 is used for atomizing the liquid stored in the liquid storage cavity 101, an air duct component 3 is detachably arranged on the shell component 1, when the air duct component 3 is arranged on the shell component 1 in a covering mode, an air supply cavity 301 is formed between the air duct component 3 and the shell component 1, and air flow is formed in the air duct component 3 under the action of a fan component 4, and the air flow can convey mist generated at the position of the liquid storage cavity 101 to the outside of the shell component 1. Wherein, wind channel subassembly 3 uses detachable mode, atomizing device when normal use, wind channel subassembly 3 set up on casing subassembly 1 and enclose between the two and have formed air supply cavity 301, when wind channel subassembly 3 was dismantled, can clean respectively to enclosing casing subassembly 1 and wind channel subassembly 3 that form air supply cavity 301, and the convenience of use personnel dismantles wind channel subassembly 3 and washs, avoids influencing out fog quality because other debris such as dust of wind channel subassembly 3.

As shown in fig. 2 and 3, this embodiment further defines, in addition to the features of the above-described embodiment: the shell assembly 1 comprises a base 11, a kettle bottle body 12 and a handle part 13, wherein the kettle bottle body 12 is arranged on the base 11, the kettle bottle body 12 is provided with a liquid storage cavity 101, the handle part 13 is arranged on the base 11 and/or the kettle bottle body 12, the air duct assembly 3 is detachably arranged on the handle part 13, and an air supply cavity 301 is formed between the air duct assembly 3 and the handle part 13. The overall structure of the shell assembly 1 adopts the appearance of the kettle, the shell assembly 1 comprises the base 11, the fan assembly 4 and other circuit assemblies are arranged on the base 11, the liquid storage cavity 101 for storing liquid is arranged on the kettle bottle body 12, and compared with the built-in air duct assembly 3 or the shell assembly 1 and the air duct assembly 3 which are integrally formed, the handle 13 is arranged on the outer side of the kettle bottle body 12, and the handle 13 and the air duct assembly 3 are arranged on the handle 13, so that the detachable mode between the air duct assembly 3 and the handle assembly is quicker and more convenient.

In addition to the features of the above embodiments, the present embodiment further defines: the both ends of handle portion 13 set up respectively on casing subassembly 1 and kettle bottle 12, and fan subassembly 4 sets up on base 11, be equipped with on the base 11 with fan subassembly 4 the first air outlet 102 of intercommunication, kettle bottle 12 is equipped with second air outlet 103, first air outlet 102, air supply cavity 301 and second air outlet 103 communicate in proper order, and kettle bottle 12 is equipped with nozzle 14, and nozzle 14 is equipped with outlet 107, and second air outlet 103 sets up with nozzle 14 relatively. Through be equipped with first air outlet 102 and second air outlet 103 on the both ends that handle portion 13 is connected with casing subassembly 1 and kettle bottle 12 respectively, wherein, first air outlet 102 communicates with fan subassembly 4, second air outlet 103 is as air outlet and the liquid storage cavity 101 intercommunication of air supply cavity 301, and carry the fog that liquid storage cavity 101 department produced to atomizing device outside through the play fog mouth 107, wherein, be equipped with the nozzle 14 that sets up relatively with second air outlet 103 on the atomizing device, and be equipped with out fog mouth 107 on the nozzle 14, make fog can more concentrate and carry outside casing subassembly 1 through nozzle 14, can improve spraying conveying distance and play fog effect simultaneously.

Specifically, the kettle bottle 12 comprises a bottle body provided with a liquid storage cavity 101 and a cover body arranged on the bottle body, so that fog generated in the liquid storage cavity 101 can overflow through the nozzle 14. When the cover body is opened, the mist is conveyed to the outside of the atomizing device through the opening at the cover body, and compared with the mist discharged from the nozzle 14, the cover opening and the mist discharging can improve the coverage area of the mist.

As shown in fig. 7, this embodiment further defines, in addition to the features of the above-described embodiment: the base 11 is provided with a plurality of air inlets 106, the plurality of air inlets 106 are located on the bottom wall and/or the side wall of the base 11, and the air inlets 106 are arranged close to the fan assembly 4. Through being equipped with a plurality of air intakes 106 on the base 11 is close to the one side that fan subassembly 4 set up, for example, air intake 106 can set up in the diapire and the lateral wall department of base 11 simultaneously to improve the intake of wind channel subassembly 3, and then improve out fog effect, for example go out fog time, go out fog conveying distance and the cover effect in the certain space.

As shown in fig. 2, 4 and 5, this embodiment further defines, in addition to the features of the above-described embodiment: the handle part 13 is provided with a first opening 104, the first opening 104 is matched with the air duct assembly 3, the air duct assembly 3 comprises an air duct shell 31 and a clamping piece 32, the air duct shell 31 is arranged on the handle part 13 and located at the first opening 104, the clamping piece 32 is arranged on the air duct shell 31, the shell assembly 1 or the handle part 13 is provided with a limiting hole 105, and the clamping piece 32 is clamped with the side wall of the limiting hole 105. By arranging the first opening 104 on the handle portion 13 for matching with the air duct assembly 3, after the air duct assembly 3 is detached from the handle portion 13, the side wall of the air supply cavity 301 at the handle portion 13 can be cleaned directly through the first opening 104, and likewise, the air duct assembly 3 is provided with the second opening matching with the first opening 104, and the side wall of the air supply cavity 301 at the air duct assembly 3 can be cleaned through the second opening. Further, a clamping detachable structure is adopted between the handle part 13 and the air duct component 3, and the air duct component 3 is assembled on the handle part 13 through the clamping piece 32 and the limiting hole 105 which are arranged on the air duct component 3, so that the clamping detachable structure is simpler and occupies small space.

As shown in fig. 4, this embodiment further defines, in addition to the features of the above-described embodiment: the clamping piece 32 comprises a clamping piece body 321 and a sliding part 322, wherein the clamping piece body 321 is arranged on the air duct shell 31, the sliding part 322 is arranged on the clamping piece body 321, the sliding part 322 extends towards the limiting hole 105, and the sliding part 322 forms a first sliding cambered surface 302. Through be equipped with sliding part 322 on joint spare 32 body, this sliding part 322 extends towards spacing hole 105, make sliding part 322 can the joint on the lateral wall of spacing hole 105, further, be formed with first slip cambered surface 302 on the sliding part 322, when air duct assembly 3 and handle portion 13 are assembled, sliding part 322 slides along the lateral wall of spacing hole 105, this slip cambered surface can carry out the butt with the lateral wall of spacing hole 105, through being equipped with the slip cambered surface on sliding part 322, reduce the frictional force in the assembly process, and when the user is dismantled air duct assembly 3 from handle portion 13, can make sliding part 322's first slip cambered surface 302 follow the lateral wall of spacing hole 105 through specific push angle thereby can break away from with spacing hole 105 lateral wall's joint relation, the dismantlement and the washing of air duct assembly 3 have been made things convenient for to a greater extent to above-mentioned detachable joint structure.

As shown in fig. 2 and 3, this embodiment further defines, in addition to the features of the above-described embodiment: the liquid storage device further comprises a backflow part 5, the backflow part 5 is arranged on the shell assembly 1, one end of the backflow part 5 is located on the side wall of the shell assembly 1, and the other end of the backflow part 5 extends towards the liquid storage cavity 101. In order to further improve atomizing device's use interest, through be provided with backward flow portion 5 on the inside wall of casing subassembly 1, because this backward flow portion 5 can extend along the direction of lateral wall towards stock solution chamber 101, atomizing piece 2 can rise to the in-process fog of atomizing the liquid of stock solution chamber 101, collide between fog and backward flow portion 5 in the in-process that rises, thereby make a portion fog can liquefy and assemble into the liquid droplet on the lateral wall of backward flow portion 5, the liquid can drip again to stock solution chamber 101 in, produce the drip sound of liquid drip, thereby atomizing device's interest has been improved.

As shown in fig. 3, this embodiment further defines, in addition to the features of the above-described embodiment: the end of the reflow portion 5 away from the side wall of the housing assembly 1 forms a bump, and the bump forms a second sliding arc surface 501. The mist encounters the backflow part 5 to form a bump in the rising process, and part of the mist is liquefied and falls back into the liquid storage cavity 101 along the second sliding cambered surface 502 formed on the bump. Preferably, a plurality of projections are formed on the same side of the return portion 5, thereby enhancing the effect of the mist falling back to the liquid storage chamber 101 after liquefaction.

In addition to the features of the above embodiments, the present embodiment further defines: the backflow part 5 is arranged opposite to the atomizing piece 2, and the backflow part 5 is positioned on one side of the atomizing hole close to the atomizing piece 2. In order to further improve the effect of the mist falling back into the liquid storage cavity 101 after liquefaction, the backflow portion 5 is disposed opposite to the atomizing member 2, and the backflow portion 5 is located above the atomizing member 2.

As shown in fig. 6 to 10, this embodiment further defines, in addition to the features of the above-described embodiment: the atomization device further comprises a baffle assembly 6, wherein the baffle assembly 6 is arranged on the shell assembly 1, the baffle assembly 6 is at least partially positioned in the liquid storage cavity 101, the baffle assembly 6 divides the liquid storage cavity 101 into a first liquid storage cavity 1011 and a second liquid storage cavity 1012, the second liquid storage cavity 1012 is communicated with the first liquid storage cavity 1011, and the atomization piece 2 is at least partially positioned in the second liquid storage cavity 1012; still include conveying subassembly 7, conveying subassembly 7 sets up on baffle subassembly 6, and conveying subassembly 7 is used for carrying the liquid of first stock solution chamber 1011 to second stock solution chamber 1012, and baffle subassembly 6 or casing subassembly 1 are equipped with scale removal device 8, and scale removal device 8 is used for reducing water hardness. Because the atomization amount of the atomization piece 2 is influenced by the liquid storage amount of the liquid storage cavity 101 where the atomization piece 2 is located, through the baffle assembly 6 arranged in the shell assembly 1, the baffle assembly 6 can separate the liquid storage cavity 101 to form the first liquid storage cavity 1011 and the second liquid storage cavity 1012, wherein the first liquid storage cavity 1011 is used for pre-storing liquid which needs to be atomized in the second liquid storage cavity 1012, the conveying assembly 7 is arranged for conveying the liquid of the first liquid storage cavity 1011 to the second liquid storage cavity 1012, the atomization piece 2 is only used for atomizing the liquid of the second liquid storage cavity 1012, so that the liquid outlet amount of the second liquid storage cavity 1012 can be regulated and controlled according to the control of the conveying assembly 7, on one hand, the atomization effect of the atomization piece 2 can be improved, on the other hand, the repeated work that the liquid needs to be added for multiple times is avoided, the atomization piece 2 is influenced by excessive liquid which is conveyed or added for multiple times, and the service time of the atomization assembly after single liquid adding is longer is avoided.

Further, when the liquid atomized by the atomizing device is water, the atomizing effect is greatly affected by the scaling problem in the atomizing process of the atomizing piece 2, so the descaling device 8 is additionally arranged, the conveying component 7 firstly conveys the liquid in the first liquid storage cavity 1011 to the second liquid storage cavity 1012, and after the content of free calcium ions and magnesium ions in the liquid is reduced by the descaling device 8, the liquid treated by the descaling device 8 is conveyed to the second liquid storage cavity 1012, so the service life of the atomizing piece 2 is prolonged, and the mist outlet effect of the atomizing piece 2 is improved.

As shown in fig. 7, 10 and 11, this embodiment further defines, in addition to the features of the above-described embodiment: the conveying assembly 7 comprises a water pump assembly 71, a conveying pipeline 73 and a four-way valve assembly 72, the water pump assembly 71 and the four-way valve assembly 72 are arranged on the partition plate assembly 6 or the shell assembly 1, the conveying pipeline comprises a first conveying pipeline 731, a second conveying pipeline 732, a third conveying pipeline 733 and a fourth conveying pipeline 734, the first conveying pipeline 731 is communicated with the first liquid storage cavity 1011 and the four-way valve assembly 72, the second conveying pipeline 732 is communicated with the four-way valve assembly 72 and the water inlet end of the descaling device 8, the third conveying pipeline 733 is communicated with the four-way valve assembly 72 and the water outlet end of the descaling device 8, and the fourth conveying pipeline 734 is communicated with the four-way valve assembly 72 and the second liquid storage cavity 1012; the water pump assembly 71 includes a first water pump 711 and a second water pump 712, the first water pump 711 being disposed on the first delivery line 731 and the second water pump 712 being disposed on the second delivery line 732. By arranging the valve core in the four-way valve assembly 72, and connecting the conveying pipelines through the valve core, wherein the connecting conveying pipelines comprise a first conveying pipeline 731, a second conveying pipeline 732, a third conveying pipeline 733 and a fourth conveying pipeline 734, when the four-way valve assembly 72 is connected with the first conveying pipeline 731 and the second conveying pipeline 732, the first water pump 711 conveys the liquid of the first liquid storage cavity 1011 to the four-way valve assembly 72, and the second water pump 712 enables the first conveying pipeline 731 communicated with the four-way valve assembly 72 to be communicated with the second conveying pipeline 732, so that the liquid is conveyed to the descaling device 8, and the water hardness of the liquid can be reduced through the descaling device 8; when the four-way valve assembly 72 is communicated with the second conveying pipeline 732 and the third conveying pipeline 733, liquid can circulate between the descaling device 8 and the four-way valve, so that the descaling effect of the descaling device 8 on the liquid is further improved; when the four-way valve assembly 72 is communicated with the third conveying pipeline 733 and the fourth conveying pipeline 734, the liquid treated by the descaling device 8 can be conveyed into the second liquid storage cavity 1012; when the atomized liquid does not need to be subjected to the reaction of the descaling device 8, for example, other liquid or treated water is stored in the liquid storage cavity 101, the four-way valve assembly 72 can be controlled to communicate the first conveying pipeline 731 with the fourth conveying pipeline 734, so that the liquid in the first liquid storage cavity 1011 is directly conveyed into the second liquid storage cavity 1012.

As shown in fig. 12, in addition to the features of the above embodiment, the present embodiment further defines: the four-way valve assembly 72 includes a base assembly 721, a valve element 722 and a motor 723, the four-way valve assembly 72 is disposed on the partition assembly, the four-way valve assembly 72 is provided with at least 4 communication holes, the communication holes are respectively communicated with corresponding conveying pipelines, the valve element 722 is disposed on the base assembly 721, the valve element 722 is provided with an infusion channel, the motor 723 is connected with the valve element 722, and when the valve element 722 rotates relative to the base assembly 721, the conveying pipelines and the communication holes are communicated. The base component is provided with 4 communication holes which are respectively communicated with the first conveying pipeline, the second conveying pipeline, the third conveying pipeline and the fourth conveying pipeline, the valve core is arranged inside the base component and is driven by the motor to rotate, so that the conveying pipelines and the transfusion channels are communicated, and liquid in the first liquid storage cavity 1011 can be conveyed to the descaling device 8 or the second liquid storage cavity 1012 through the four-way valve component 72.

In addition to the features of the above embodiments, the present embodiment further defines: still include control assembly, control assembly is used for four-way valve subassembly 72 and pipeline's intercommunication, control assembly can circulate second pipeline and third pipeline according to setting for realize circulation flow between the liquid in the pipeline and the scale removal device 8, and then make scale removal granule dissolution of scale removal device 8, the liquid of output can finally get into in the second stock solution chamber 1012 and carry out scale removal reaction and get rid of the incrustation scale on the atomizing piece 2, promote the availability factor of atomizing piece 2, thereby reduce free calcium ion magnesium ion etc. in the liquid, further improve the life and the fog efficiency of atomizing piece 2.

As shown in fig. 8 and 9, this embodiment further defines, in addition to the features of the above-described embodiment: the descaling device 8 includes a mounting housing 81, a magazine 82, and a stirring assembly 83, the magazine 82 is provided on the mounting housing 81, the stirring assembly 83 is provided on the mounting housing 81, and the stirring assembly 83 is movable relative to the mounting housing 81. The liquid outlets of the descaling device 8, the four-way valve assembly 72 and the fourth conveying pipeline adopt a liquid level difference design mode, the setting height of the descaling device 8 is larger than that of the four-way valve assembly 72, and the setting height of the four-way valve assembly 72 is larger than that of the liquid outlet of the fourth conveying pipeline. Through be equipped with stirring subassembly 83 on scale removal device 8, stirring subassembly 83 can drive the inside liquid flow of scale removal device 8 when rotating to improve the reaction efficiency between magazine 82 and the liquid. Further, a stirring assembly 83 is provided at the bottom of the descaling device 8. When the atomizing device atomizes tap water, scale is generated due to the fact that more free calcium ions, magnesium ions and other ions exist in the tap water, the normal atomization work of an atomization piece can be influenced by the scale, so that the problems of poor atomization effect, even atomization failure and the like can occur, replaceable descaling particles are contained in the storage box 82, and the water hardness of liquid is reduced through adsorption.

In addition to the features of the above embodiments, the present embodiment further defines: and also includes a heating assembly positioned within the second reservoir 1012. Through being equipped with heating element in second stock solution chamber 1012 for heating element only needs to heat the liquid or the fog of second stock solution chamber 1012 department, compares with the whole stock solution chamber 101 of heating element direct heating, and this design mode can reduce the heat energy consumption, and because the heating volume is less relatively, can further improve heating efficiency. By setting the heating temperature of the heating assembly, a hot mist with a set temperature can be obtained, for example, when the atomizing device is used to atomize water, a mist with a set temperature can be generated.

In addition to the features of the above embodiments, the present embodiment further defines: a heating element is provided on the side wall of the second reservoir 1012, the heating element being located on the side of the side wall remote from the atomising member 2. Because the atomization efficiency of the atomization member 2 may be affected by the heating element, the heating element is arranged on one side far away from the atomization member 2 so that the heating element can directly heat the mist, thereby reducing the influence of the heating element on the liquid temperature in the second liquid storage cavity 1012, and reducing the situations that the atomization efficiency and the atomization amount of the modeling atomization member 2 are reduced under the condition that the heating temperature of the heating element is too high.

In addition to the features of the above embodiments, the present embodiment further defines: the diaphragm assembly 6 is provided with a vacuum insulation layer. By providing a vacuum insulating layer on the baffle assembly 6, the second fluid chamber 1012 can be blocked from heat transfer through the vacuum insulating layer to a large extent, thereby improving the temperature insulating performance in the second fluid chamber 1012.

In addition to the features of the above embodiments, the present embodiment further defines: the diaphragm assembly 6 is made of a heat insulating material. Similarly, the separator assembly 6 can also be made of a heat insulating material having a small coefficient of thermal conductivity, such as polystyrene resin, foam insulation board, or the like.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above examples illustrate only a few embodiments of the invention, which are described in detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (9)

1. An atomizing device, comprising:

the device comprises a shell assembly (1), wherein the shell assembly (1) is provided with a liquid storage cavity (101) and a mist outlet (107), and the liquid storage cavity (101) is communicated with the mist outlet (107);

an atomizing piece (2), wherein the atomizing piece (2) is arranged on the shell assembly (1), the atomizing piece (2) is at least partially positioned in the liquid storage cavity (101), and the atomizing piece (2) is used for atomizing liquid in the liquid storage cavity (101);

the air duct assembly (3), the air duct assembly (3) is detachably arranged on the shell assembly (1), an air supply cavity (301) is formed by enclosing the air duct assembly and the shell assembly (1), and the air supply cavity (301) is communicated with the liquid storage cavity (101);

the fan assembly (4) is arranged on the shell assembly (1), and the fan assembly (4) is communicated with the air supply cavity (301);

the shell assembly (1) comprises a base (11), a kettle bottle body (12) and a handle part (13), wherein the kettle bottle body (12) is arranged on the base (11), the kettle bottle body (12) is provided with a liquid storage cavity (101), the handle part (13) is arranged on the base (11) and/or the kettle bottle body (12), the air duct assembly (3) is detachably arranged on the handle part (13), and an air supply cavity (301) is formed between the air duct assembly (3) and the handle part (13);

The utility model discloses a water kettle, including casing subassembly (1), kettle bottle (12), fan subassembly (4) set up on base (11), be equipped with on base (11) with first air outlet (102) of fan subassembly (4) intercommunication, kettle bottle (12) are equipped with second air outlet (103), first air outlet (102) supply air chamber (301) with second air outlet (103) communicate in proper order, kettle bottle (12) are equipped with nozzle (14), nozzle (14) are equipped with outlet (107), second air outlet (103) with nozzle (14) set up relatively.

2. An atomising device according to claim 1, characterised in that the base (11) is provided with a plurality of air inlets (106), a plurality of the air inlets (106) being located on a bottom wall and/or a side wall of the base (11), the air inlets (106) being arranged close to the fan assembly (4).

3. The atomizing device according to claim 1, characterized in that the handle portion (13) is provided with a first opening (104), the first opening (104) is adapted to the air duct assembly (3), the air duct assembly (3) comprises an air duct shell (31) and a clamping piece (32), the air duct shell (31) is arranged on the handle portion (13) and located at the first opening (104), the clamping piece (32) is arranged on the air duct shell (31), the housing assembly (1) or the handle portion (13) is provided with a limiting hole (105), and the clamping piece (32) is clamped with the side wall of the limiting hole (105).

4. An atomising device according to claim 3, wherein the clamping member (32) comprises a clamping member body (321) and a sliding portion (322), the clamping member body (321) is arranged on the air duct housing (31), the sliding portion (322) is arranged on the clamping member body (321), and the sliding portion (322) extends towards the limiting aperture (105), and the sliding portion (322) forms a first sliding arc surface (302).

5. An atomising device according to claim 1 further comprising a return (5), the return (5) being provided on the housing assembly (1), one end of the return (5) being located on a side wall of the housing assembly (1), the other end of the return (5) extending towards the reservoir (101).

6. An atomising device according to claim 5, characterised in that the return portion (5) forms a projection at the end remote from the side wall of the housing assembly (1), the projection forming a second sliding arc (501);

and/or the reflux part (5) is arranged opposite to the atomizing piece (2), and the reflux part (5) is positioned at one side close to the atomizing hole of the atomizing piece (2).

7. The atomizing device according to claim 1, further comprising a baffle assembly (6), said baffle assembly (6) being provided on said housing assembly (1), said baffle assembly (6) being at least partially located within said reservoir (101), said baffle assembly (6) dividing said reservoir (101) into a first reservoir (1011) and a second reservoir (1012), said second reservoir (1012) being in communication with said first reservoir (1011), said atomizing member (2) being at least partially located within said second reservoir (1012);

still include conveying component (7), conveying component (7) set up on baffle subassembly (6), conveying component (7) are used for with the liquid of first stock solution chamber (1011) is carried to second stock solution chamber (1012), baffle subassembly (6) or casing subassembly (1) are equipped with scale removal device (8), scale removal device (8) are used for reducing water hardness.

8. The atomizing device according to claim 7, wherein the conveying assembly (7) comprises a water pump assembly (71), a four-way valve assembly (72) and a conveying pipeline (73), the water pump assembly (71) and the four-way valve assembly (72) are arranged on the partition assembly (6) or the shell assembly (1), the conveying pipeline (73) comprises a first conveying pipeline (731), a second conveying pipeline (732), a third conveying pipeline (733) and a fourth conveying pipeline (734), the first conveying pipeline (731) is communicated with the first liquid storage cavity (1011) and the four-way valve assembly (72), the second conveying pipeline (732) is communicated with the four-way valve assembly (72) and the water inlet end of the descaling device (8), the third conveying pipeline (733) is communicated with the four-way valve assembly (72) and the water outlet end of the descaling device (8), and the fourth conveying pipeline (734) is communicated with the valve assembly (72) and the second liquid storage cavity (1012); the water pump assembly (71) comprises a first water pump (711) and a second water pump (712), the first water pump (711) is arranged on the first conveying pipeline (731), and the second water pump (712) is arranged on the second conveying pipeline (732);

And/or descaling device (8) are including installation casing (81), storage box (82) and stirring subassembly (83), storage box (82) set up on installation casing (81), stirring subassembly (83) can be for installation casing (81) motion.

9. The atomizing device of claim 7, further comprising a heating assembly located within the second reservoir (1012);

and/or the partition board component (6) is provided with a vacuum heat-insulating layer;

or the baffle plate component (6) is made of heat insulation materials.