CN116273650B - Hot fog atomizer - Google Patents

Abstract

The application relates to the technical field of atomizers, in particular to a hot fog atomizer, which comprises: the shell assembly is provided with a first mounting cavity; the water tank is arranged on the shell component, a liquid storage cavity is formed in the water tank, a first mist outlet channel is formed by enclosing the side wall of the water tank and the side wall of the first installation cavity, and a mist outlet is formed in the water tank; an atomizing assembly disposed on a bottom wall of the housing assembly; and the heating module is arranged on the shell assembly. According to the hot fog atomizer, the adding module is arranged in the first fog outlet channel and is positioned close to the fog outlet, so that the heating module is not in direct contact with water in a large area, scale on the surface of the heating module is avoided, the heating module is positioned close to the fog outlet, heat loss of fog in the first fog outlet channel due to flowing is reduced, the hot fog temperature discharged to the environment is better than the temperature required by a user, and the user experience is better.

Description

Hot fog atomizer

Technical Field

The application relates to the technical field of atomizers, in particular to a hot fog atomizer.

Background

The traditional hot fog atomizer heats water to 40 ℃ through PTC heating elements or heating copper pipes, and then utilizes ultrasonic high-frequency vibration to make fog, and takes away heat through water evaporation, so as to achieve the purposes of cooling and radiating the PTC heating elements. In the prior art, the PTC heating element needs to be arranged at the bottom of the water tank, is contacted with water in a large area, works for a long time, can generate scale on the surface of the PTC heating element, and reduces the heat transmission efficiency between the PTC heating element and the water.

Disclosure of Invention

In view of the above, it is necessary to provide a hot mist atomizer capable of relatively efficiently realizing humidification of hot mist.

A hot mist atomizer, comprising: the shell assembly is provided with a first mounting cavity; the water tank is arranged on the shell assembly, a liquid storage cavity is formed in the water tank, the water tank is located in the first installation cavity, the liquid storage cavity is communicated with the first installation cavity, the side wall of the water tank and the side wall of the first installation cavity are enclosed to form a first mist outlet channel, the first mist outlet channel is communicated with the first installation cavity, a mist outlet is formed in the water tank, the mist outlet is opposite to the first mist outlet channel, and the mist outlet is communicated with the first mist outlet channel; the atomization assembly is arranged on the bottom wall of the shell assembly, the atomization assembly is at least partially positioned in the first mounting cavity, and the atomization assembly is arranged opposite to the first mist outlet channel; the heating module is arranged on the shell assembly and is positioned at one end of the first mist outlet channel close to the mist outlet.

The application discloses a hot fog atomizer, wherein a liquid storage cavity is arranged on a water tank and is used for storing water used for atomization, the water tank is arranged in a first installation cavity, and the liquid storage cavity is communicated with the first installation cavity, so that the water in the liquid storage cavity can flow to an atomization assembly, the atomization assembly is arranged on the bottom of a shell assembly, a first fog outlet channel is formed by enclosing the side wall of the water tank and the side wall of the shell assembly, the atomization assembly is arranged opposite to the first fog outlet channel, so that the water in the liquid storage cavity flows out of the first installation cavity and enters the atomization assembly, the atomization assembly atomizes water into small water drops and is discharged to the external environment through the atomization channel and a fog outlet, a heating module is arranged on the side wall of the first fog outlet channel and is positioned close to the fog outlet, when the fog in the atomization channel is discharged to the fog outlet, the fog outlet is heated through a heating area of the heating module, and finally the hot fog is discharged from the fog outlet.

According to the hot fog atomizer, the adding module is arranged in the first fog outlet channel and is positioned close to the fog outlet, so that the heating module is not in direct contact with water in a large area, scale on the surface of the heating module is avoided, the heating module is positioned close to the fog outlet, heat loss of fog in the first fog outlet channel due to flowing is reduced, the hot fog temperature discharged to the environment is better than the temperature required by a user, and the user experience is better.

In some embodiments, the fan module is arranged on the shell assembly, the shell assembly is further provided with a second mounting cavity, the first mounting cavity is communicated with the second mounting cavity, and the fan module is positioned at the bottom of the second mounting cavity.

The hot fog atomizer is further limited by arranging the second mounting cavity on the shell component for mounting the fan module, forming the air duct in the second mounting cavity, separating the air duct from the first mounting cavity, avoiding the fan module from being contacted with water, and enabling wind energy flowing in the air duct to enter the first mounting cavity by arranging the vent holes on the side wall between the first mounting cavity and the second mounting cavity, so that fog in the first fog outlet channel is accelerated to be discharged outside, and the humidifying efficiency is improved.

In some embodiments, the outer side wall of the water tank is recessed toward the direction of the liquid storage cavity to form a groove, the side wall of the groove and the side wall of the shell component enclose to form the first mist outlet channel, and the top wall of the groove is provided with the mist outlet.

The hot fog atomizer further limits that the first fog outlet channel is formed by recessing the water tank to form a groove and matching with the side wall of the shell component, and the fog outlet is formed in the bottom wall of the groove, so that the fog outlet is opposite to and communicated with the first fog outlet channel, the additional channel is omitted from being arranged on the shell component, the space is saved, and the volume of the atomizer is reduced.

In some embodiments, the water tank further comprises a valve body assembly, the valve body assembly is arranged on the bottom wall of the water tank, a liquid outlet is formed in the water tank, the liquid outlet is respectively communicated with the liquid storage cavity and the first installation cavity, the valve body assembly is at least partially positioned at the liquid outlet, and the valve body assembly can open or close the liquid outlet.

The hot fog atomizer is further limited in that the liquid outlet is formed in the bottom of the water tank, and the valve body assembly is arranged at the liquid outlet on the water tank, so that part of water is prevented from leaking in advance in the process of placing the water tank in the first installation cavity, the hot fog atomizer can be used for controlling the amount of liquid in the liquid storage cavity flowing out of the first installation cavity, and the water in the water tank is prevented from excessively entering the first installation cavity to cause the heating module to be in contact with the water in a large area.

Optionally, the valve body subassembly includes valve body and float, the valve body sets up on the water tank, and is located liquid outlet department, and the float sets up on the casing subassembly, and the float is located first installation intracavity, and the top of float pushes away portion and offsets with the valve body.

The valve body is used for shutoff liquid outlet, when first installation intracavity does not have water, the top portion jack-up valve body of float under the effect of gravity to open the liquid outlet, the water of stock solution intracavity enters into first installation intracavity, when the water yield of first installation intracavity reaches the certain degree, the buoyancy of water to float is greater than the gravity of float self, thereby the top portion of float is to the top of valve body, the valve body is reset the back and is plugged again the liquid outlet, the water of stock solution intracavity stops getting into first installation intracavity.

In some embodiments, the device further comprises a filter module, wherein the filter module is arranged on the water tank, and the filter module is positioned in the liquid storage cavity and opposite to the liquid outlet.

The hot fog atomizer further limits that through setting up filtration module in stock solution chamber liquid outlet department for impurity of filtration water avoids impurity to get into first installation intracavity and blocks up or damage atomizing subassembly, and still avoids the little drop of water after the atomizing to carry in the impurity discharge outside by the human body suction.

In some embodiments, the heating module includes a first heating element, two heat conducting members, and a first heat resistant bracket, the first heating element being mounted between the two heat conducting members, the heat conducting members being disposed on the first heat resistant bracket, the first heat resistant bracket being disposed on the housing assembly.

The above-mentioned hot fog atomizer further limits, and heating element sets up between two heat conduction spare to avoid first heating element direct contact with water, the heat conduction spare is used for in the heat transfer of first heating element goes out fog passageway, thereby realizes for fog heating, through setting up the heat conduction spare on first heat-resisting support, again sets up first heat-resisting support on housing assembly, avoids the heat conduction spare and the housing assembly direct contact of high temperature state, promotes housing assembly's durability.

Alternatively, the heating element is a PTC ceramic heating element.

In some embodiments, the heat conducting piece is formed with a plurality of heat conducting fins, the plurality of heat conducting fins are located in the first mist outlet channel, and the plurality of heat conducting fins are far away from the first heat-resistant support and the side wall of the water tank.

The hot mist atomizer further limits that the heat transfer area of the heat conducting piece is increased by forming the plurality of heat conducting fins on the heat conducting piece, the heating efficiency is improved, and one end of the heat conducting fins extending outwards does not touch any part of the hot mist atomizer.

In some embodiments, the heat-resistant housing further comprises a second heat-resistant bracket arranged on the housing assembly, the second heat-resistant bracket being positioned in the first mist outlet passage, the second heat-resistant bracket being positioned on a side of the heat conducting member adjacent to the side wall of the water tank.

The hot fog atomizer further limits that the water tank damage caused by high-temperature transmission of the heat conducting piece to the side wall of the water tank is avoided by arranging the second heat-resistant bracket on one side of the heat conducting piece close to the water tank, and the service life of the water tank is prolonged.

In some embodiments, the atomizing assembly includes an atomizing sheet disposed on the housing assembly, the atomizing sheet at least partially disposed within the first mounting cavity, and an energy concentrating ring assembly disposed on the housing assembly, the energy concentrating ring assembly at least partially disposed within the first mist outlet passage, the energy concentrating ring assembly disposed opposite the atomizing sheet.

The hot mist atomizer is further limited in that the hot mist atomizer can continuously and stably generate mist at different water levels through the cooperation of the atomizing sheet and the energy collecting ring assembly.

In some embodiments, the portable device further comprises a hand piece, the hand piece is in clamping connection with the water tank, the hand piece is located near the opening of the water tank, and the hand piece can rotate relative to the water tank.

The hot fog atomizer is further limited, and the portable piece is arranged at the opening of the water tank, so that a user can conveniently extract the water tank from the shell assembly, and the use experience of the user is improved.

In some of these embodiments, a pressure sensor is also included, the pressure sensor being disposed on the bottom wall of the housing assembly, the pressure sensor being located on a side remote from the first mounting cavity.

The hot fog atomizer further limits that through set up pressure sensor on the diapire of casing subassembly for the water yield of indirect monitoring first installation intracavity, pressure sensor is on data transmission to information panel that the real-time measured, and the user can in time make up water according to the suggestion, thereby avoids not having fog to produce and the heating module continues to heat and thereby leads to the inside high temperature's of atomizer condition to take place.

In some embodiments, the fan assembly further comprises a base, the base is arranged on the housing assembly, the base is located at one end, close to the fan module, of the housing assembly, a third installation cavity is formed by enclosing the base and the housing assembly, the third installation cavity is communicated with the second installation cavity, a plurality of air inlets are formed in the base, and the air inlets are communicated with the third installation cavity.

The hot fog atomizer further limits that the base is arranged on the shell component and used for protecting components arranged on the bottom of the shell component, the base and the shell component are enclosed to form a third installation cavity, the base is provided with a plurality of air inlets, and accordingly an air channel is formed by matching with the second installation cavity, and the fan module blows fog out of the atomization channel.

In some embodiments, the device further comprises a first cover component, the first cover component is covered on the housing component, the first cover component is located at one end of the housing component, which is close to the mist outlet, a second mist outlet channel is formed in the first cover component, the second mist outlet channel is opposite to the mist outlet, and the second mist outlet channel is communicated with the mist outlet.

The hot fog atomizer is further limited in that the first cover body assembly is arranged at the top of the shell assembly, so that the liquid storage cavity and the first installation cavity form a relatively airtight space, and water quality pollution caused by external impurity dust and the like is avoided.

In some of these embodiments, the air pump is provided with an air outlet section, a negative pressure section and an air inlet section, the air outlet section, the negative pressure section and the air inlet section are sequentially communicated, the air inlet section is communicated with the air outlet opening, the inner diameter of the air outlet section is smaller than the inner diameter of the air inlet section, and the inner diameter of the negative pressure section is reduced along the direction close to the air outlet section.

The hot fog atomizer further limits that a negative pressure area can be formed in the pneumatic conveyer after the pneumatic conveyer is pumped by the air pump in the pneumatic conveyer through arranging the pneumatic conveyer at the fog outlet, so that fog at the fog outlet is discharged to the external environment in an accelerating way, the conveying efficiency of the fog is improved, the pneumatic conveyer is internally divided into an air outlet section, a negative pressure section and an air inlet section, the negative pressure section is positioned between the air outlet section and the air inlet section, the inner diameter of the air outlet section is smaller than that of the air inlet section, after the negative pressure section is communicated with the air pump and pumps air into the negative pressure section, the negative pressure is generated at the negative pressure section, and the fog at the air inlet section enters the air outlet section in an accelerating way after passing through the negative pressure section and is output to the outside, so that the fog outlet efficiency is improved.

In some embodiments, the pneumatic conveyor comprises an outer shell, an inner shell and a second heating element, wherein the outer shell is provided with the air outlet section, the inner shell is provided with the air inlet section, the inner shell is arranged in the outer shell, the outer shell is further provided with an air inlet channel, the air inlet channel is communicated with the negative pressure section, and the second heating element is arranged on the inner shell.

The hot fog atomizer is further limited in that the air inlet channel is formed in the outer shell and is communicated with the air pump, so that air pumped by the air pump can enter the negative pressure section through the air inlet channel, and the second heating element is arranged in the inner shell and can keep the temperature of passing fog, so that the heat loss of the fog in the conveying process is avoided, and the temperature required by a user is not reached.

Drawings

FIG. 1 is one of the cross-sectional views of a hot mist atomizer according to the present application;

FIG. 2 is a second cross-sectional view of the hot mist atomizer of the present application;

FIG. 3 is an enlarged view of FIG. 2A;

fig. 4 is a perspective view of a water tank according to the present application;

FIG. 5 is a third cross-sectional view of the hot mist atomizer of the present application;

FIG. 6 is a fourth cross-sectional view of the hot mist atomizer of the present application;

FIG. 7 is a fifth cross-sectional view of the hot mist atomizer of the present application;

FIG. 8 is a cross-sectional view of the pneumatic conveyor of the present application;

fig. 9 is an exploded view of the pneumatic conveyor of the present application.

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

1 a shell assembly, 101 a first installation cavity, 102 a second installation cavity, 103 a first mist outlet channel and 104 a third installation cavity;

2 a water tank, a liquid storage cavity 201, a fog outlet 202 and a liquid outlet 203;

3 an atomization assembly, 31 an atomization sheet and 32 an energy-gathering ring assembly;

4 a heating module, 41 a first heating element, 42 a heat conducting member, 43 a first heat-resistant bracket, 44 a second heat-resistant bracket, 421 a heat conducting sheet;

5 a fan module; 6 valve body assembly, 61 valve body, 62 float; 7, a filtering module; 8, a hand piece;

9, a pressure sensor; 11 base, 1101 air intakes; 12 first cap assembly 1201 second mist outlet duct.

13 second cover assembly, 131 cover body, 132 pneumatic conveyor, 1301 air outlet section, 1302 negative pressure section, 1303 air inlet section, 1321 outer housing, 1322 inner housing, 1323 second heating element, 1304 air inlet channel.

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.

The following describes some embodiments of the hot mist atomizer according to the present application with reference to the accompanying drawings.

As shown in fig. 1 to 4, a hot mist atomizer, comprising: a housing assembly 1, the housing assembly 1 being provided with a first mounting cavity 101; the water tank 2 is arranged on the shell assembly 1, a liquid storage cavity 201 is formed in the water tank 2, the water tank 2 is positioned in the first installation cavity 101, the liquid storage cavity 201 is communicated with the first installation cavity 101, the side wall of the water tank 2 is enclosed with the side wall of the first installation cavity 101 to form a first mist outlet channel 103, the first mist outlet channel 103 is communicated with the first installation cavity 101, a mist outlet 202 is formed in the water tank 2, the mist outlet 202 is arranged opposite to the first mist outlet channel 103, and the mist outlet 202 is communicated with the first mist outlet channel 103; the atomization assembly 3 is arranged on the bottom wall of the shell assembly 1, the atomization assembly 3 is at least partially positioned in the first mounting cavity 101, and the atomization assembly 3 is arranged opposite to the first mist outlet channel 103; the heating module 4, the heating module 4 sets up on the casing subassembly 1, and the heating module 4 is located the one end that first fog passageway 103 is close to fog outlet 202.

The application discloses a hot mist atomizer, wherein a liquid storage cavity 201 is arranged on a water tank 2 and is used for storing water used for atomization, the water tank 2 is arranged in a first installation cavity 101, the liquid storage cavity 201 is communicated with the first installation cavity 101, so that the water in the liquid storage cavity 201 can flow to an atomization component 3, the atomization component 3 is arranged on the bottom of a shell component 1, a first mist outlet channel 103 is formed by surrounding the side wall of the water tank 2 and the side wall of the shell component 1, the atomization component 3 is arranged opposite to the first mist outlet channel 103, so that the water in the liquid storage cavity 201 flows out into the first installation cavity 101 and enters the atomization component 3, the atomization component 3 atomizes water into small water drops and then discharges the small water drops to the external environment through the atomization channel 103 and a mist outlet 202, and when the air in the atomization channel 103 is discharged to the mist outlet 202, the air is heated through a heating area of the heating module 4, and finally the hot mist is discharged from the mist outlet 202.

According to the hot fog atomizer, the adding module 4 is arranged in the first fog outlet channel 103 and is positioned close to the fog outlet 202, so that the heating module 4 is not in direct contact with water in a large area, scale on the surface of the heating module 4 is avoided, the heating module 4 is positioned close to the fog outlet 202, heat loss of fog in the first fog outlet channel 103 due to flowing is reduced, the hot fog temperature discharged to the environment is better than the temperature required by a user, and the user experience is better.

As shown in fig. 1 and 2, in the present embodiment, the fan module 5 is further included, the fan module 5 is disposed on the housing assembly 1, the housing assembly 1 is further provided with a second mounting cavity 102, the first mounting cavity 101 is communicated with the second mounting cavity 102, and the fan module 5 is located at a position of the second mounting cavity 102 away from the mist outlet 202.

The above-mentioned hot fog atomizer further defines, through setting up the second installation cavity 102 on casing subassembly 1 for install fan module 5, make the interior wind channel that forms of second installation cavity 102, and make the wind channel separate with first installation cavity 101, avoid fan module 5 and water contact, through set up the ventilation hole on the lateral wall between first installation cavity 101 and second installation cavity 102, make the wind energy that accelerates the flow in the wind channel get into in the first installation cavity 101, thereby accelerate in the fog discharge external world in the first fog passageway 103, promote humidification efficiency.

As shown in fig. 1 and 4, in this embodiment, the outer side wall of the water tank 2 is recessed toward the direction of the liquid storage cavity 201 to form a groove, the side wall of the groove and the side wall of the housing assembly 1 enclose to form a first mist outlet channel 103, and a mist outlet 202 is formed on the bottom wall of the groove.

The above-mentioned hot fog atomizer further defines, through sunken recess formation recess and with casing subassembly 1 lateral wall on water tank 2 to form first fog passageway 103, and set up fog outlet 202 on the diapire of recess, make fog outlet 202 and first fog passageway 103 set up relatively and communicate, remove from setting up the passageway in addition on casing subassembly 1, practice thrift the space, reduce the atomizer volume.

As shown in fig. 1 and fig. 6, in this embodiment, the device further includes a valve body assembly 6, the valve body assembly 6 is disposed on the water tank 2, a liquid outlet 203 is formed on the water tank 2, the liquid outlet 203 is respectively communicated with the liquid storage cavity 201 and the first installation cavity 101, the valve body assembly 6 is at least partially located at the liquid outlet 203, and the valve body assembly 6 can open or close the liquid outlet 203.

The above-mentioned hot mist atomizer further limits that, because the liquid outlet 203 is arranged at the bottom of the water tank 2, by arranging the valve body assembly 6 at the liquid outlet 203 on the water tank 2, part of water is prevented from leaking in advance during the process of placing the water tank 2 in the first installation cavity 101, and the hot mist atomizer can also be used for controlling the amount of liquid in the liquid storage cavity 201 flowing out of the first installation cavity 101, so that the water in the water tank 2 is prevented from excessively entering the first installation cavity 101 to cause the heating module 4 to be in contact with water in a large area.

Optionally, the valve body assembly 6 includes a valve body 61 and a float member 62, the valve body 61 is disposed on the water tank 2 and is located at the liquid outlet 203, the float member 62 is disposed on the housing assembly 1, the float member 62 is located in the first mounting cavity 101, and the pushing portion of the float member 62 abuts against the valve body 61.

When the first installation cavity 101 is free of water, the valve body 61 is jacked up by the pushing part of the floating piece 62 under the action of gravity, so that the liquid outlet 203 is opened, water in the liquid storage cavity 201 enters the first installation cavity 101, when the water quantity in the first installation cavity 101 reaches a certain degree, the buoyancy of the water to the floating piece 62 is greater than the gravity of the floating piece 62, so that the valve body 61 is jacked by the pushing part of the floating piece 62, the liquid outlet 203 is plugged again after the valve body 61 is reset, and the water in the liquid storage cavity 201 stops entering the first installation cavity 101.

As shown in fig. 1 and 5, in this embodiment, the filter module 7 is further included, where the filter module 7 is disposed on the water tank 2, and the filter module 7 is located in the liquid storage cavity 201 and opposite to the liquid outlet 203.

The above-mentioned hot fog atomizer has further defined, through setting up filtration module 7 in liquid storage cavity 201 liquid outlet 203 department for the impurity of filtration water avoids impurity to get into in the first installation cavity 101 to block up or damage atomizing subassembly 3, and still avoids the little drop of water after the atomizing to carry in the impurity discharge outside by the human body to inhale.

As shown in fig. 1 to 3, in the present embodiment, the heating module 4 includes a first heating element 41, at least two heat conductive members 42, and a first heat resistant bracket 43, the first heating element 41 being bridged between the two heat conductive members 42, the heat conductive members 42 being disposed on the first heat resistant bracket 43, the first heat resistant bracket 43 being disposed on the housing assembly 1.

The above-mentioned hot mist atomizer further defines that the first heating element 41 is disposed between the two heat conducting members 42, so as to avoid the first heating element 41 from directly contacting with water, the heat conducting members 42 are used for transferring heat of the first heating element 41 into the first mist outlet channel 103, thereby realizing mist heating, and the heat conducting members 42 are disposed on the first heat-resistant bracket 43, and then the first heat-resistant bracket 43 is disposed on the housing assembly 1, so that the heat conducting members 42 in a high temperature state are prevented from directly contacting with the housing assembly 1, and the durability of the housing assembly 1 is improved.

Alternatively, the first heating element 41 is a PTC ceramic heating element.

As shown in fig. 1 to 3, in the present embodiment, a plurality of heat conductive sheets 421 are formed on the heat conductive member 42, the plurality of heat conductive sheets 421 are located in the first mist outlet duct 103, and the plurality of heat conductive sheets 421 are away from the first heat resistant bracket 43 and the side wall of the water tank 2.

The above-mentioned hot mist atomizer further defines that by forming a plurality of heat conductive fins on the heat conductive member 42, the heat transfer area of the heat conductive member 42 is increased, the heating efficiency is improved, and one end of the heat conductive fin 421 extending outward is not touched with any part of the hot mist atomizer.

As shown in fig. 1 to 3, in the present embodiment, a second heat-resistant bracket 44 is further included, the second heat-resistant bracket 44 being provided on the housing assembly 1, the second heat-resistant bracket 44 being located in the first mist outlet duct 103, the second heat-resistant bracket 44 being located on a side of the heat conductive member 42 close to the side wall of the water tank 2.

The above-mentioned hot mist atomizer further defines that by providing the second heat-resistant bracket 44 on the side of the heat-conducting member 42 close to the water tank 2, damage to the water tank 2 due to high temperature transfer of the heat-conducting member 42 to the side wall of the water tank 2 is avoided, and the service life of the water tank 2 is prolonged.

As shown in fig. 2, in the present embodiment, the atomizing assembly 3 includes an atomizing sheet 31 and an energy collecting ring assembly 32, the atomizing sheet 31 is disposed on the housing assembly 1, the atomizing sheet 31 is at least partially disposed in the first mounting cavity 101, the energy collecting ring assembly 32 is disposed on the housing assembly 1, the energy collecting ring assembly 32 is at least partially disposed in the first mist outlet duct 103, and the energy collecting ring assembly 32 is disposed opposite to the atomizing sheet 31.

The hot mist atomizer further defines that the hot mist atomizer can continuously and stably generate mist at different water levels through the cooperation of the atomizing sheet 31 and the energy collecting ring assembly 32.

As shown in fig. 1 and 6, in this embodiment, the portable device further includes a hand piece 8, the hand piece 8 is connected with the water tank 2 in a clamping manner, the hand piece 8 is located near the opening of the water tank 2, and the hand piece 8 can rotate relative to the water tank 2.

The hot fog atomizer is further limited, and the portable piece 8 is arranged at the opening of the water tank 2, so that a user can conveniently extract the water tank 2 from the shell assembly 1, and the use experience of the user is improved.

As shown in fig. 6, in the present embodiment, a pressure sensor 9 is further included, the pressure sensor 9 being provided on the bottom wall of the housing assembly 1, the pressure sensor 9 being located on a side remote from the first mounting chamber 101.

The above-mentioned hot fog atomizer has further defined, through set up pressure sensor 9 on the diapire of casing subassembly 1 for the water yield in the indirect monitoring first installation cavity 101, pressure sensor 9 is on the data transmission information panel that the real-time measured, and the user can in time make up water according to the suggestion, thereby avoids not having fog to produce and heating module 4 continue to heat and thereby lead to the inside high condition emergence of temperature of atomizer.

As shown in fig. 1, in this embodiment, the fan assembly further includes a base 11, the base 11 is disposed on the housing assembly 1, the base 11 is located at one end of the housing assembly 1 near the fan module 5, the base 11 and the housing assembly 1 enclose to form a third installation cavity 104, the third installation cavity 104 is communicated with the second installation cavity 102, a plurality of air inlets 1101 are formed in the base 11, and the plurality of air inlets 1101 are communicated with the third installation cavity 104.

The above-mentioned hot mist atomizer further defines, through setting up base 11 on housing assembly 1 for the part of setting up on housing assembly 1 bottom, and base 11 encloses with housing assembly 1 and closes and form third installation cavity 104, sets up a plurality of air intakes 1101 on the base 11, thereby forms the wind channel with the cooperation of second installation cavity 102, realizes that fan module 5 blows out fog outside atomizing passageway 103.

As shown in fig. 1 and 2, in this embodiment, the device further includes a first cover component 12, where the first cover component 12 is covered on the housing component 1, the first cover component 12 is located at one end of the housing component 1 near the mist outlet 202, a second mist outlet 1201 is formed in the first cover component 12, the second mist outlet 1201 is opposite to the mist outlet 202, and the second mist outlet 1201 is communicated with the mist outlet 202.

The above-mentioned hot fog atomizer further limits, through set up first lid subassembly 12 at the top of casing subassembly 1, makes stock solution chamber 201 and first installation cavity form relatively airtight space, avoids outside impurity dust etc. to pollute quality of water.

As shown in fig. 7 to 9, in this embodiment, the air pump is further provided with a second cover assembly 13, the second cover assembly 13 includes a cover body 131, a pneumatic conveyer 132, and an air pump, the pneumatic conveyer 132 is disposed on the cover body 131, the pneumatic conveyer 132 is at least partially disposed in the first mounting cavity 101, the pneumatic conveyer 132 is communicated with the mist outlet 202, the air pump is disposed on the cover body 131, the air pump is communicated with the pneumatic conveyer 132, an air outlet section 1301, a negative pressure section 1302, and an air inlet section 1303 are disposed in the pneumatic conveyer 132, the air outlet section 1301, the negative pressure section 1302, and the air inlet section 1303 are sequentially communicated, the air inlet section 1303 is communicated with the mist outlet 202, the inner diameter of the air outlet section 1301 is smaller than the inner diameter of the air inlet section 1303, and the inner diameter of the negative pressure section 1302 is reduced along the direction approaching the air outlet section 1301.

The above-mentioned hot fog atomizer further limits that, through setting up air conveyer 132 in fog outlet 202, the air pump can form the negative pressure region in air conveyer 132 after the pump pumps into air conveyer 132, thereby can make fog in fog outlet 202 discharge to the external environment with higher speed, promote the conveying efficiency of fog, the part is in air outlet section 1301, negative pressure section 1302 and air inlet section 1303 in air conveyer 132, negative pressure section 1302 is located between air outlet section 1301 and air inlet section 1303, and the internal diameter of air outlet section 1301 is less than air inlet section 1303, when negative pressure section 1302 and air pump intercommunication and pump into gas to negative pressure section 1302, negative pressure can be produced in negative pressure section 1302 department, after the fog in air inlet section department can accelerate entering air outlet section 1301 and export to the external world, thereby promoted fog outlet efficiency.

As shown in fig. 7 to 9, in the present embodiment, the pneumatic conveyer 132 includes an outer shell 1321, an inner shell 1322 and a second heating element 1323, the outer shell 1321 is provided with an air outlet section 1301, the inner shell 1322 is provided with an air inlet section 1303, the inner shell 1322 is disposed in the outer shell 1321, the outer shell 1321 is further provided with an air inlet channel 1304, the air inlet channel 1304 is communicated with the negative pressure section 1302, and the second heating element 1323 is disposed on the inner shell 1322.

The above-mentioned hot mist atomizer further defines, through setting up inlet channel 1304 in shell 1321 for with the air pump intercommunication, thereby the gas that the air pump pumps can get into in the negative pressure section 1302 through inlet channel 1304, through setting up second heating element 1323 in inner shell 1322, can keep warm for the fog that passes through, avoid the fog heat loss and can not reach user's required temperature in the transportation process.

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 application, which are described in detail and are not to be construed as limiting the scope of the application. 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 application, which are all within the scope of the application. Accordingly, the scope of protection of the present application is to be determined by the appended claims.

Claims (8)

1. A thermal mist atomizer, comprising:

a housing assembly (1), the housing assembly (1) being provided with a first mounting cavity (101);

the water tank (2), water tank (2) set up on casing subassembly (1), set up stock solution chamber (201) on water tank (2), water tank (2) are located first installation cavity (101), stock solution chamber (201) with first installation cavity (101) intercommunication, the lateral wall of water tank (2) with the lateral wall of first installation cavity (101) encloses and closes and form first fog passageway (103), first fog passageway (103) with first installation cavity (101) intercommunication, set up fog outlet (202) on water tank (2), fog outlet (202) with first fog passageway (103) set up relatively, fog outlet (202) with first fog passageway (103) intercommunication;

the atomization assembly (3) is arranged on the bottom wall of the shell assembly (1), the atomization assembly (3) is at least partially positioned in the first mounting cavity (101), and the atomization assembly (3) is arranged opposite to the first mist outlet channel (103);

the heating module (4) is arranged on the shell assembly (1), and the heating module (4) is positioned at one end of the first mist outlet channel (103) close to the mist outlet (202);

the second cover body assembly (13), the second cover body assembly (13) comprises a cover body (131), a pneumatic conveyer (132) and an air pump, the pneumatic conveyer (132) is arranged on the cover body (131), the pneumatic conveyer (132) is at least partially positioned in the first mounting cavity (101), the pneumatic conveyer (132) is communicated with the mist outlet (202), the air pump is arranged on the cover body (131), the air pump is communicated with the pneumatic conveyer (132), an air outlet section (1301), a negative pressure section (1302) and an air inlet section (1303) are arranged in the pneumatic conveyer (132), the air outlet section (1301), the negative pressure section (1302) and the air inlet section (1303) are sequentially communicated, the air inlet section (1303) is communicated with the mist outlet (202), the inner diameter of the air outlet section (1301) is smaller than the inner diameter of the air inlet section (1303), and the inner diameter of the negative pressure section (1302) is reduced along the direction approaching to the air outlet section (1301);

pneumatic conveyer (132) include shell (1321), inner shell (1322) and second heating element (1323), shell (1321) have been seted up give vent to anger section (1301), inner shell (1322) have been seted up inlet section (1303), inner shell (1322) set up in shell (1321), inlet channel (1304) have still been seted up to shell (1321), inlet channel (1304) with negative pressure section (1302) intercommunication, second heating element (1323) set up on inner shell (1322).

2. The hot mist atomizer according to claim 1, further comprising a fan module (5), said fan module (5) being arranged on said housing assembly (1), said housing assembly (1) being further provided with a second mounting cavity (102), said first mounting cavity (101) being in communication with said second mounting cavity (102), said fan module (5) being located at the bottom of said second mounting cavity (102).

3. The hot mist atomizer according to claim 1, characterized in that an outer side wall of the water tank (2) is recessed towards the direction of the liquid storage cavity (201) to form a groove, a side wall of the groove and a side wall of the shell component (1) enclose to form the first mist outlet channel (103), and the mist outlet (202) is formed in a top wall of the groove.

4. The hot mist atomizer according to claim 1, further comprising a valve body assembly (6), wherein the valve body assembly (6) is arranged on the bottom wall of the water tank (2), a liquid outlet (203) is formed in the water tank (2), the liquid outlet (203) is respectively communicated with the liquid storage cavity (201) and the first mounting cavity (101), the valve body assembly (6) is at least partially positioned at the liquid outlet (203), and the valve body assembly (6) can open or close the liquid outlet (203); and/or

The water tank is characterized by further comprising a filtering module (7), wherein the filtering module (7) is arranged on the water tank (2), and the filtering module (7) is positioned in the liquid storage cavity (201) and is opposite to the liquid outlet (203).

5. A hot mist atomizer according to claim 1, characterized in that the heating module (4) comprises a first heating element (41), two heat conducting members (42) and a first heat resistant bracket (43), the first heating element (41) being arranged between the two heat conducting members (42), the heat conducting members (42) being arranged on the first heat resistant bracket (43), the first heat resistant bracket (43) being arranged on the housing assembly (1).

6. The hot mist atomizer according to claim 5, characterized in that the heat conducting member (42) is formed with a plurality of heat conducting fins (421), the plurality of heat conducting fins (421) being located in the first mist outlet duct (103), the plurality of heat conducting fins (421) being away from the first heat-resistant bracket (43) and the side wall of the water tank (2); and/or

The heat-resistant water tank further comprises a second heat-resistant support (44), the second heat-resistant support (44) is arranged on the shell assembly (1), the second heat-resistant support (44) is located in the first mist outlet channel (103), and the second heat-resistant support (44) is located on one side, close to the side wall of the water tank (2), of the heat conducting piece (42).

7. A hot mist atomizer according to claim 1, characterized in that the atomizing assembly (3) comprises an atomizing plate (31) and an energy collecting ring assembly (32), the atomizing plate (31) being arranged on the housing assembly (1), the atomizing plate (31) being at least partially located in the first mounting cavity (101), the energy collecting ring assembly (32) being arranged on the housing assembly (1), the energy collecting ring assembly (32) being at least partially located in the first mist outlet channel (103), the energy collecting ring assembly (32) being arranged opposite to the atomizing plate (31); and/or

The water tank is characterized by further comprising a hand piece (8), wherein the hand piece (8) is connected with the water tank (2) in a clamping way, the hand piece (8) is positioned at the position close to the opening of the water tank (2), and the hand piece (8) can rotate relative to the water tank (2); and/or

The device further comprises a pressure sensor (9), wherein the pressure sensor (9) is arranged on the bottom wall of the shell assembly (1), and the pressure sensor (9) is positioned on one side away from the first mounting cavity (101).

8. The hot mist atomizer according to claim 2, further comprising a base (11), wherein the base (11) is arranged on the housing assembly (1), the base (11) is positioned on one end of the housing assembly (1) close to the fan module (5), the base (11) and the housing assembly (1) enclose to form a third mounting cavity (104), the third mounting cavity (104) is communicated with the second mounting cavity (102), a plurality of air inlets (1101) are formed in the base (11), and a plurality of air inlets (1101) are communicated with the third mounting cavity (104).