CN113598420A - Supporting block for supporting atomizing element of atomizing device, atomizing device and equipment - Google Patents

Abstract

The application provides a supporting block for supporting an atomizing element of an atomizing device, wherein a gas passing cavity is arranged in the supporting block, and a gas passing hole communicated with the gas passing cavity is formed in the side wall of the supporting block; the side wall of the supporting block is also provided with a distribution groove for positioning and mounting the atomization element; the air flow in the air passing cavity can flow to the arrangement groove through the air passing hole to provide working air flow for the atomizing element. This application aim at is convenient for process the assembly, and the inside air cavity of crossing that is equipped with of supporting shoe simultaneously, during operation, the air cavity of crossing that external air current was equipped with through air cavity and supporting shoe lateral wall does atomizing element provides working air current, and external air current supplys and preheats in the air cavity, and the heat of supporting shoe gives off with higher speed simultaneously.

Description

Supporting block for supporting atomizing element of atomizing device, atomizing device and equipment

Technical Field

The invention belongs to the technical field of electronic atomization, and particularly relates to a supporting block for supporting an atomization element of an atomization device, the atomization device and atomization equipment.

Background

The electronic atomization device comprises an atomization device and a power supply device for supplying power to the atomization device, and a liquid storage cavity, an airflow channel and an electronic atomization assembly are built in the atomization device. The holding tank has been seted up to the power supply ware, and atomizing device installs in the holding tank to establish electric connection with the power supply ware. When the power supply device supplies power for the electronic atomization assembly in the atomization device, the atomization assembly atomizes the solution stored in the liquid storage cavity into aerosol and discharges the aerosol.

However, the atomization assembly of the conventional atomization device needs to wrap the cotton material on the atomization element, and the assembly process is complicated.

Disclosure of Invention

An object of the embodiment of this application is to provide an atomizing device atomizing element's supporting shoe, the processing assembly of being convenient for.

In order to achieve the above object, a first aspect of the present application provides a supporting block for supporting an atomizing element of an atomizing device, wherein a gas passing cavity is arranged in the supporting block, and a gas passing hole communicated with the gas passing cavity is formed in a side wall of the supporting block; the side wall of the supporting block is also provided with a distribution groove for positioning and mounting the atomization element;

the air flow in the air passing cavity can flow to the arrangement groove through the air passing hole to provide working air flow for the atomizing element.

Optionally, two side walls of the supporting block are provided with laying grooves, the supporting block is further provided with wire passing grooves, and one ends of the two laying grooves are communicated with each other through the wire passing grooves.

Optionally, the two laying grooves are formed in two opposite side walls of the supporting block, and the wire passing groove is formed in the end face of the top of the supporting block.

Optionally, the dimension of the wire passing groove is larger than that of the laying groove.

Optionally, the layout groove is formed in a first side wall of the supporting block, the air passing hole is formed in a second side wall of the supporting block, the first side wall and the second side wall are arranged adjacent to each other, a junction of the first side wall and the second side wall is obliquely arranged to form an air flow guide surface, and the external air flow flows to the layout groove through the air passing cavity, the air passing hole and the air flow guide surface.

Optionally, the supporting block further includes a third side wall facing the second side wall, and the third side wall is provided with an air passing hole and an airflow guide surface which are consistent with the second side wall.

Optionally, the lower end of the supporting block is further provided with a mounting edge for being fixed to the atomizing assembly by an external fixing seat, and the layout groove penetrates through the mounting edge to form a wire passing hole for the external atomizing element to pass through.

Optionally, the support block is made of a ceramic material.

The second aspect, this application still provides an atomizing device, including atomization component and liquid storage bullet, be provided with the grafting chamber of stock solution chamber and confession atomization component installation in the liquid storage bullet, atomization component can pull out to insert peg graft in the grafting intracavity, atomization component includes base, atomizing element and as above the supporting shoe, the one end rigid coupling of supporting shoe in the base, the other end stretches out outside the base, atomizing element fixed mounting in lay the groove, the base be used for peg graft in the grafting chamber makes the cotton contact of lock liquid in atomization element and the liquid storage bullet.

In a third aspect, the present application further provides an atomizing apparatus, which includes the power supply device and the above atomizing device, wherein when the atomizing device is plugged in the power supply device, the atomizing assembly is electrically connected to the power supply device.

The beneficial effect of this application lies in: the atomizing component does not have the cotton material design, need not artifical package cotton, during the installation, erects atomizing component in the supporting shoe to through electrically conductive electrode with electrically conductive lead wire establish electric connection can, simple to operate, the processing production of being convenient for, the inside air cavity of crossing that is equipped with of supporting shoe simultaneously, during operation, the external air current through cross the air cavity and the supporting shoe lateral wall be equipped with cross the gas pocket do atomizing component provides working air, and external air current supplements to cross the air cavity and preheat, and the heat of supporting shoe gives off with higher speed simultaneously.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the embodiments or the prior art descriptions will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise.

FIG. 1 is an exploded view of the connection structure of the electronic atomizing device of the present application;

FIG. 2 is an exploded view of the connection structure of the atomizing device of the present application;

FIG. 3 is a schematic cross-sectional view of the connection structure of the atomizing device of the present application;

FIG. 4 is a schematic front view of the attachment structure of the atomizing assembly of the present application;

FIG. 5 is a perspective view of the connection structure of the atomizing assembly of the present application;

FIG. 6 is a schematic cross-sectional view of the attachment structure of the atomizing assembly of the present application;

FIG. 7 is a perspective view of the support block connection structure of the present application;

FIG. 8 is a schematic bottom view of a cartridge base of the present application;

FIG. 9 is a cross-sectional view of the attachment of the cartridge base of the present application in the direction A-A of FIG. 8;

FIG. 10 is a cross-sectional view of the attachment of the cartridge base of the present application in the direction B-B of FIG. 8;

FIG. 11 is a cross-sectional exploded view of the attachment structure of the cartridge base of the present application in the direction A-A of FIG. 8;

FIG. 12 is a perspective view of the connection structure of the cartridge base of the present application;

fig. 13 is a schematic cross-sectional view of the connection structure of the power supply device in the present application;

FIG. 14 is a schematic cross-sectional view of the connection structure of the atomizing assembly independently locked to the power supply of the present application;

FIG. 15 is an enlarged partial schematic view at A of FIG. 14 of the subject application;

fig. 16 is a schematic view of the connection structure of the inner frame in the present application.

Wherein, in the figures, the respective reference numerals:

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present application clearer, the present application is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

It will be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like, as used herein, refer to an orientation or positional relationship indicated in the drawings that is solely for the purpose of facilitating the description and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be considered as limiting the present application.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

Referring to fig. 1 to 16, the present invention provides an electronic atomization apparatus 10000, wherein the electronic atomization apparatus 10000 comprises an atomization device 1000 and a power supply device 3000 for supplying power to the atomization device 1000. The atomization device 1000 comprises a liquid storage bomb 100 and an atomization assembly 200, wherein the liquid storage bomb 100 comprises a liquid storage cup 10 and a base 20 inserted in the liquid storage cup 10. The open setting of stock solution cup 10 one end to supply base 20 to peg graft, just base 20 with the inner wall of stock solution cup 10 encloses into stock solution chamber 11, 11 contents in the stock solution chamber have the solution, the solution can be water, mosquito repellent liquid, fragrant liquid, cosmetic liquid, liquid medicine, tobacco juice etc. do not do here and prescribe a limit to, different atomization plant 10000 of formation is corresponded according to the kind that the solution is different to electron atomization plant 10000, for example, humidifier, mosquito repellant, champignon, facial steaming appearance, medicinal atomizer and electron cigarette, and this application uses the electron cigarette as an example.

Specifically, as shown in fig. 9 to 11, in the embodiment of the present invention, the base 20 includes a base body 21 and a liquid locking member 22, the base body 21 is made of plastic or silica gel, and the bottom of the base body is provided with an insertion groove 211 for inserting the external atomizing assembly 200, the top of the base body is provided with an installation groove 212, the installation groove 212 and the insertion groove 211 are arranged in a staggered manner, and an opening on one side wall of the base body is arranged to communicate the installation groove 212 with the insertion groove 211. The liquid locking piece 22 is made of porous materials such as cotton or ceramics and is used for adsorbing the solution in the liquid storage cavity 11. In this embodiment, taking the liquid absorbent cotton as an example, the liquid absorbent cotton is inserted along the mounting groove 212 to fill the mounting groove 212, since one side of the mounting groove 212 is communicated with the insertion groove 211, the liquid absorbent cotton filled in the mounting groove 212 is exposed from the insertion groove 211, and when the external atomizing assembly 200 is inserted into the insertion groove 211, the atomizing element 210 of the atomizing assembly 200 contacts with the liquid absorbent cotton.

Specifically, as shown in fig. 12, in the embodiment of the present invention, since the mounting groove 212 is disposed at the top, it is effectively convenient for a user to mount the absorbent cotton in the mounting groove 212, and meanwhile, to prevent the size of the liquid storage bomb 100 from being large, the bottom size of the seat body 21 is larger than the top size, so as to form a large diameter section and a small diameter section, the large diameter section is used for sealing the opening of the liquid storage cup 10, and the small diameter section is inserted into the liquid storage cup 10. And a liquid storage cavity 11 is formed between the periphery of the small-diameter section and the liquid storage cup 10, a liquid passing hole 213 is formed at the lower end of the small-diameter section close to the large-diameter section, and the liquid passing hole 213 is communicated with the mounting groove 212, so that the phenomenon that the solution at the lower end of the top cannot enter the mounting groove 212 through the mounting groove 212 and is adsorbed by the liquid locking piece 22 can be prevented.

Further, as shown in fig. 11, in the embodiment of the present invention, in order to prevent the solution in the storage chamber 11 from directly leaking through the gap between the liquid through hole 213 and the liquid locking member 22, the solution leaking rate is fast, and the liquid leakage phenomenon occurs. The edge of the liquid passing hole 213 avoiding the installation groove 212 is opened, that is, the lowest position of the installation groove 212 is lower than the lowest position of the liquid passing hole 213, the width of the installation groove 212 is larger than the width of the liquid passing hole 213, and when the liquid locking piece 22 is inserted, the liquid passing hole 213 is completely covered and blocked, so that the solution in the liquid storage cavity 11 can only be absorbed through the liquid locking piece 22. Simultaneously, insert along mounting groove 212 through sealed plug 23 interference fit's mode again, with lock liquid spare 22 compaction, further reduce the risk of weeping, and behind the installation sealed plug 23, the inside solution of stock solution chamber 11 only flows to lock liquid spare 22 through crossing liquid hole 213. The adsorption rate is relatively uniform, and the taste is ensured. Under the condition of avoiding not having sealed plug 23, when solution is more, the synchronous liquid of crossing of mounting groove 212 notch and the liquid hole 213 that crosses of bottom at the top, when solution is less, can only cross liquid through crossing liquid hole 213. The phenomena of large difference of adsorption rate and inconsistent mouthfeel are caused.

Specifically, as shown in fig. 10, in the embodiment of the present invention, a first side surface 221 of the liquid locking member 22 contacts with the atomizing element 210, and a second side surface 222 opposite to the first side surface covers the liquid passing hole 213; therefore, when the atomization assembly 200 is inserted, the first side surface 221 of the liquid locking member 22 is pressed, so that the second side surface 222 is tightly attached to the liquid passing hole 213, and the solution in the storage chamber 11 is further prevented from directly seeping out from the gap between the liquid passing hole 213 and the liquid locking member 22.

Further, as shown in fig. 9 and fig. 5, in the embodiment of the present invention, in order to ensure that the atomizing element 210 contacts the liquid-locking member 22, the atomizing element 210 protrudes from the surface of the atomizing assembly 200, and at the same time, in order to prevent the atomizing element 210 from pressing the liquid-locking member 22 with a large force, the liquid-locking member 22 bulges at the liquid-passing hole 213. In this embodiment, a first portion of the first side surface 221 contacts the atomizing element 210, a second portion of the second side surface 222 covers the liquid passing hole 213, and the second portion opposite to the liquid passing hole 213 is offset from the first portion. Therefore, the direct pressing force of the atomizing element 210 acts on the liquid-locking member 22 away from the portion facing the liquid through hole 213, so that the liquid-locking member 22 is pressed against the edge of the liquid through hole 213 without bulging toward the inside of the liquid through hole 213.

Specifically, as shown in fig. 3, in the embodiment of the present invention, since the atomizing element 210 and the liquid passing hole 213 are disposed in a staggered manner, in order to increase the atomizing area, the atomizing element 210 extends in the depth direction of the insertion groove 211. Meanwhile, the phenomenon that heat generated by deviation of the atomizing element 210 is transmitted to the shell of the atomizing device 1000 to be uneven and overheated at one side is avoided; the atomizing element 210 faces the middle of the mounting groove 212 in the width direction and is abutted against the middle of the liquid locking piece 22 in the width direction; the liquid passing hole 213 is disposed to be deviated from the middle position of the mounting groove 212.

Specifically, as shown in fig. 8 and 10, in the embodiment of the present invention, an avoiding groove 214 is further formed on the sidewall of the insertion groove 211 on the bottom surface of the seat body 21, so that the insertion groove 211 forms a wide section 2141 and a narrow section 2142, and the narrow section 2142 is fixed to the side structure of the outer atomizing assembly 200 in an interference fit manner, so as to prevent the solution from leaking out from the gap. The wide diameter section 2141 is communicated with the mounting groove 212, so that the atomizing element 210 of the outer atomizing assembly 200 can pass through to contact with the liquid locking member 22. Meanwhile, the size of the avoiding groove 214 is larger than the size of the atomizing element 210, so that the atomizing element 210 is accommodated in the avoiding groove 214, an atomizing air passage 2143 for the air flow to pass through is formed at the periphery, and the air passage of the atomizing assembly 200 is communicated with the atomizing air passage 2143.

Specifically, as shown in fig. 8 in conjunction with fig. 10, in the embodiment of the present invention, since the avoiding groove 214 communicates with the installation groove 212, the liquid locking member 22 covers the bottom groove wall of the installation groove 212 facing the notch in the present embodiment. And the bottom groove wall is further provided with a liquid suction notch 2121 communicated with the avoiding groove 214. When the atomization assembly 200 is prevented from being pulled out or inserted, the liquid locking piece 22 deviates towards the installation groove 212, so that part of the bottom groove wall is not covered by the liquid locking piece 22, solution residue is caused, and when the atomization assembly 200 is pulled out, the solution leaks out of the outside. Causing pollution to the outside articles. By providing the fluid suction notch 2121, when the atomizing assembly 200 is inserted, the liquid locking member 22 still completely covers the bottom groove wall after the atomizing element 210 presses the liquid locking member 22, so that the solution is always adsorbed by the liquid locking member 22 and does not remain, thereby avoiding the risk of fluid leakage during extraction.

Specifically, as shown in fig. 3, in the embodiment of the present invention, the top of the seat body 21 is further provided with a mist outlet 215, and the depth of the avoiding groove 214 along the inserting direction of the atomizing element 200 is greater than the height of the atomizing element 210 in the corresponding direction, so that a mist outlet channel 2144 is formed in the space between the top end of the avoiding groove 214 and the atomizing element 210, which is convenient for the atomized gas to flow, and prevents the occurrence of whistling caused by the flow of a narrow space. Meanwhile, the end of the avoiding groove 214 is inclined to form a guide surface for guiding the air flow to the mist outlet 215 to be discharged, so as to enhance the smoothness of the air flow passing through.

The technical scheme of the invention also provides a liquid storage bomb 100 of the atomizing device 1000, which comprises a liquid storage cup 10 and the base 20 of the atomizing device 1000, wherein the base 20 is inserted into an opening of the liquid storage cup 10, and a liquid storage cavity 11 is formed by surrounding the base 20 and the liquid storage cup 10. The specific structure of the base 20 refers to the above embodiments, and since the liquid storage bullet 100 adopts all technical solutions of all the above embodiments, at least all the beneficial effects brought by the technical solutions of the above embodiments are achieved, and are not described in detail herein.

Specifically, as shown in fig. 1 and fig. 3, in the embodiment of the present invention, one end of the liquid storage cup 10 is open, the other end of the liquid storage cup is provided with the mist discharge port 12, the inner wall of the liquid storage cup 10 surrounds the mist discharge port 12 and is provided with the air duct 13, and the air duct 13 is inserted into the mist discharge port 215, so that the air flow discharged from the mist discharge port 215 flows out to the outside only through the mist discharge port 12.

Further, as shown in fig. 3 and fig. 11, in the embodiment of the present invention, in order to prevent the solution in the liquid storage chamber 11 from leaking out from the gap between the mist outlet 215 and the air duct 13, a sealing sleeve 24 is sleeved on the air duct 13 or the sealing sleeve 24 is installed on the mist outlet 215, in this embodiment, the sealing sleeve 24 is installed on the mist outlet 215, the seat body 21 is provided with a plurality of bosses 216 at intervals around the mist outlet 215, the sealing sleeve 24 includes a sleeve body 241 inserted into the mist outlet 215 and a sleeve edge 242 clamped at the edge of the mist outlet 215, and the sleeve edge 242 is provided with a plurality of notches 2421 corresponding to the plurality of bosses 216 for the bosses 216 to be inserted. By arranging the plurality of bosses 216, the bosses 216 have interference force on the side walls of the notches 2421, so that the phenomenon that the sealing effect is weakened as the sleeve edge 242 is pulled into the mist outlet 215 under the stress when the air duct 13 is inserted into the sealing sleeve 24 is prevented; specifically, the portion of the limiting edge clamped between two adjacent protrusions is in a fan-shaped ring shape, the portion is a narrow end close to the mist outlet 215 and a wide end far away from the mist outlet 215, so as to ensure that the sleeve edge 242 does not deform during insertion.

Specifically, as shown in fig. 11, in the embodiment of the present invention, a stop edge is protruded on the inner wall of the mist outlet 215, and the side of the sealing sleeve 24 away from the sleeve edge 242 is hermetically disposed and starts to have a through hole for passing the air flow. When the air duct 13 is inserted into the sealing sleeve 24, the end face of the bottom of the sealing sleeve 24 is pressed against the stop edge, and the side wall of the sealing sleeve 24 is pressed against the inner wall of the mist outlet 215. Thereby achieving a seal from multiple surfaces and preventing over-insertion of the airway tube 13 into the mist outlet 215. In order to improve the sealing effect, the inner wall of the sealing sleeve 24 is also convexly provided with a sealing convex rib for being sleeved on the outer wall of the air duct 13.

Specifically, as shown in fig. 11, in the embodiment of the present invention, a flexible sealing ring 25 is further sleeved on the large diameter section at the bottom of the seat body 21, and when the seat body is inserted into the opening of the liquid storage cup 10, the seat body is sealed with the inner wall of the opening edge of the liquid storage cup 10 in an interference manner.

The invention also provides an atomizing device 1000, which comprises an atomizing assembly 200 and the liquid storage bomb 100; one end of the atomizing assembly 200 is inserted into the insertion groove 211, and the other end thereof is exposed to the outside and is provided with a conductive electrode 240 for electrically connecting the external power supply 3000 and the atomizing element 210. The specific structure of the liquid storage bullet 100 refers to the above embodiments, and since the liquid storage bullet 100 adopts all technical solutions of all the above embodiments, at least all the beneficial effects brought by the technical solutions of the above embodiments are achieved, and no further description is given here.

Specifically, as shown in fig. 4 to 7, in the embodiment of the present invention, the atomizing assembly 200 includes a base 220, a supporting block 230, an atomizing element 210 and a conductive electrode 240, wherein the supporting block 230 is made of an insulating and heat-resistant material. For example, ceramic, glass, etc., in this embodiment, taking ceramic as an example, one end of the supporting block 230 is fixed to the base 220, and the other end thereof protrudes out of the base 220, and the atomizing element 210 is a heating wire or a heating sheet. The application takes a heating wire as an example, the heating wire comprises a heating part 2101 and two conductive leads 2103 positioned at two ends of the heating part 2101. The heat generating parts 2101 are arranged upward along the side walls of the supporting blocks 230. The two conductive leads 2103 are used to establish electrical connection with the two conductive electrodes 240. The heat generating portion 2101 may be bent, S-shaped, or N-shaped. And are not intended to be unduly limiting herein.

Specifically, as shown in fig. 4 to 7, in the embodiment of the present invention, a distribution groove 2301 is formed in a side wall of the supporting block 230, and the heating portion 2101 is distributed along the distribution groove 2301, so that the heating portion 2101 is positioned and distributed, and a phenomenon that a contact position with the liquid locking member 22 is changed due to deviation of the heating portion 2101, so that an atomization effect is affected is avoided. Meanwhile, the outer side surface of the heat generating part 2101 protrudes from the notch of the layout groove 2301 and protrudes out of the side wall of the supporting block 230. Thereby effectively ensuring that the heat generating part 2101 is in close contact with the locking liquid 22.

Specifically, as shown in fig. 4 to 8, in the embodiment of the present invention, the seat body 21 is provided with two mounting grooves 212 around the insertion groove 211, and both of the two mounting grooves 212 are communicated with the insertion groove 211 and are filled with the liquid locking member 22; the heating part 2101 of the atomizing element 210 is attached to the supporting block 230 and extends along the supporting block 230 to the other surface, so that when the atomizing assembly 200 is inserted into the insertion groove 211, the heating part 2101 contacts with the two liquid locking members 22, thereby improving the atomizing effect.

Specifically, as shown in fig. 6 to 8, in the embodiment of the present invention, two of the mounting grooves 212 are located at both sides of the supporting block 230, and when the heat generating portion 2101 extends upward along one side of the supporting block 230 and then extends to the other side through the top end surface, since the top end surface of the supporting block 230 is not in contact with the locking element 22, the direct dry-burning temperature is high. Therefore, the atomizing element 210 includes two heat generating portions 2101 and a conductive portion 2102 connecting the two heat generating portions 2101, the two heat generating portions 2101 are located on two side surfaces of the supporting block 230, the conductive portion 2102 connects upper ends of the two heat generating portions 2101 and is erected on a top end surface of the supporting block 230, and the whole atomizing element is n-shaped. The two heat generating parts 2101 are connected in series by the conductive part 2102, and the lower ends of the heat generating parts 2101 at the two sides of the n-type are electrically connected with the conductive electrode 240 by two conductive leads 2103. Thereby reducing the temperature of the top end surface of the supporting block 230 and preventing the continuous dry burning phenomenon. Meanwhile, the supporting block 230 is provided with a line passing groove 2302 corresponding to the conductive part 2102, two ends of the line passing groove 2302 are respectively communicated with the two arrangement grooves 2301, and the intersection is smoothly and transitionally arranged, when the device is installed, the n-shaped atomizing element 210 is pre-erected on the supporting block 230 in a manner that the conductive part 2102 corresponds to the line passing groove 2302, and then the device exerts an action on the heat generating part 2101 so as to be arranged along the arrangement grooves 2301. The installation is convenient, and the atomizing element 210 and the supporting block 230 are not easy to deviate and separate. Furthermore, the intersection of the line passing groove 2302 and the arrangement groove 2301 is arranged in a smooth transition manner, so that when the right-angle sharp transition of the line passing groove 2302 and the arrangement groove 2301 occurs, and when the atomizing assembly 200 is inserted into the liquid storage bomb 100, a shearing force is formed at the intersection of the line passing groove 2302 and the arrangement groove 2301 by an acting force between the heating part 2101 protruding out of the arrangement groove 2301 and the liquid locking member 22, and the heating part 2101 and the conducting part 2102 are prevented from being broken.

Specifically, as shown in fig. 5, in the embodiment of the present invention, the wire passing groove 2302 is opened from the middle of the top end surface of the supporting block 230. And the size of the wire passing groove 2302 is larger than that of the layout groove 2301, and the notch is designed to be gradually enlarged, so that when a user places the atomizing element 210 approximately in the middle of the top end surface of the supporting block 230, the atomizing element automatically slides down to the bottom of the wire passing groove 2302. And the depth of the wire passing groove 2302 is larger than or equal to the diameter of the conductive part 2102, so that when the conductive part 2102 is installed in the wire passing groove 2302, the outer side surface of the conductive part 2102 is lower than the wire passing groove 2302, and the probability that the conductive part 2102 is separated from the wire passing groove 2302 in the installation process is reduced.

Furthermore, the diameter of the conductive part 2102 is larger than the notch diameter of the wire passing groove 2302, so that the conductive part 2102 cannot be pressed into the wire passing groove 2302, and the phenomenon that the conductive part 2102 is biased towards one side and is partially pressed into the arrangement groove 2301 and the heat generating part 2101 on the other side is pressed into the wire passing groove 2302 during installation is avoided.

Specifically, as shown in fig. 6, in the embodiment of the present invention, an air passing cavity 2303 is disposed inside the supporting block 230, an air passing hole 2304 communicated with the air passing cavity 2303 is disposed on a side wall of the supporting block 230, an air inlet hole communicated with the outside and the air passing cavity 2303 is disposed on the base 220, and an outside air flow flows to the heat generating portion 2101 through the air inlet hole, the air passing cavity 2303, and the air passing hole 2304 to provide a working air flow for the heat generating portion 2101. Through being provided with air cavity 2303 in the inside of the supporting shoe 230, make the structure more compact, reduce product volume, the mode of air cavity 2303 is formed to the inside cavity of supporting shoe 230 simultaneously, and when sucking, outside low temperature air is inhaled to air cavity 2303 in from the inlet port in, accelerates the heat dissipation in air cavity 2303, promotes the heat dispersion of supporting shoe 230, prevents that the position temperature that supporting shoe 230 and generate heat 2101 contact from lasting higher. Meanwhile, the heat of the inner wall of the air passing cavity 2303 is conducted to the external air flow, so that the external air flow is preheated at the position and then flows to the heating part 2101 through the air passing hole 2304, the phenomenon that the heating part 2101 is incompletely atomized due to the fact that low-temperature air is directly blown to the heating part 2101 is prevented, and energy consumption can be reduced under a constant-temperature output state when the air is sucked for multiple times in unit time.

Specifically, as shown in fig. 5, in the embodiment of the present invention, the first side wall 2305 of the supporting block 230 is provided with the layout groove 2301, and the second side wall 2306 adjacent to the first side wall 2305 is provided with the air passing hole 2304; and the first side wall 2305 and the second side wall 2306 meet to form an inclined airflow guiding surface 2308, and the airflow guiding surface 2308 guides the airflow discharged from the air vent 2304 to the heat generating portion 2101 mounted on the first side wall 2305. The air passing holes 2304 and the arrangement grooves 2301 are arranged on two adjacent side walls of the supporting block 230, namely, the air passing holes 2304 avoid the surface of the heat generating part 2101 which directly works, so that the spray beads and the condensed water generated when the heat generating part 2101 and the liquid locking part 22 are atomized are prevented from splashing from the air passing holes 2304. Meanwhile, when the atomization is stopped, the residual fog at the heating part 2101 is directly converged into the air passing cavity 2303 from the air passing hole 2304 to generate condensate when the fog is cooled.

Further, as shown in fig. 5, in the embodiment of the present invention, the supporting block 230 further includes a third side wall 2307 opposite to the second side wall 2306, and the third side wall 2307 is opened with a gas passing hole 2304 and an airflow guiding surface 2308 which are consistent with the second side wall 2306. Therefore, working air flows are supplied to two sides of the heating part 2101 at the same time, and the phenomena that condensate and burnt are easily generated due to large temperature difference of the other side caused by only one-side supplementary air flow are prevented.

Further, the supporting block 230 is further provided with an air blocking rib (not shown) located above the air passing hole 2304, and when the supporting block 230 is inserted into the liquid storage cup 10, the air blocking rib is in interference fit with the inner wall structure of the liquid storage cup 10 and encloses an air flow guiding space 2505 communicated with the air flow guiding surface 2308, so as to limit the flow direction of the air flow discharged from the air passing hole 2304, and the air flow discharged from the air passing hole 2304 flows to the heat generating portion 2101 along the air flow guiding space 2505 and the air flow guiding surface 2308. Therefore, the phenomenon that the liquid locking member 22 is burnt due to the fact that external air flows upwards directly after flowing out of the air passing hole 2304 and atomized aerial fog is not mixed in the heating part 2101 is avoided.

It should be understood that, in practical applications, the air blocking ribs are protruded on the supporting block 230 to limit the flow direction of the air flow, which is not limited to the above embodiments. For example, in other embodiments of the present application, an airflow guide groove (not shown) may be formed on the surface of the supporting block 230, the air passing hole 2304 is formed in a bottom groove wall in the depth direction of the groove, the outer surface of the supporting block 230 is matched with the inner wall structure of the external liquid storage cup 10, so that the airflow guide groove forms an airflow guide space 2505 communicated with the airflow guide surface 2308, the airflow flowing direction discharged from the air passing hole 2304 is limited, and a manner that the airflow discharged from the air passing hole 2304 flows to the heat generating portion 2101 along the airflow guide space 2505 and the airflow guide surface 2308 is also within the protection scope of the present application.

Further, as shown in fig. 5, in the embodiment of the present invention, the supporting block 230 is fixedly mounted to the base 220. In this embodiment, the atomizing assembly 200 further includes a fixing seat 250, a mounting edge 2309 is convexly disposed at a lower end of the supporting block 230, a through hole 2501 for the end of the supporting block 230 to pass through is disposed on the fixing seat 250, an assembling groove 2201 is disposed on an upper end surface of the base 220, one end of the supporting block 230 having the mounting edge 2309 is received in the assembling groove 2201, the fixing seat 250 is sleeved on the supporting block 230 and presses the mounting edge 2309 into the assembling groove 2201, and the other end of the supporting block 230 passes through the through hole 2501 of the fixing seat 250 and is exposed to the outside for the atomizing element 210 to be mounted. The air vent 2304 is disposed on a portion of the surface of the support block 230 exposed to the outside. The end part of the lower end of the supporting block 230 is provided with a mounting edge 2309 in a side protruding manner, the mounting edge 2309 can be a single convex block or can be a whole peripheral ring of flanges, and the mounting edge 2309 is pressed in the assembling groove 2201 through the fixing seat 250 so as to firmly fix the supporting block 230, so that the phenomenon that the supporting block 230 is loosened after the external atomization device 1000 is repeatedly pulled out and inserted in the long-time use process is prevented.

Further, as shown in fig. 6, in the embodiment of the present invention, the connection firmness is enhanced. In this embodiment, an ultrasonic groove 2202 is further formed in a groove wall of the assembling groove 2201 facing the groove opening, and an ultrasonic rib 2502 is convexly arranged on an edge of the fixing base 250 and used for being inserted into the ultrasonic groove 2202 and connected through ultrasonic hot melting. It is understood that, in the practical application, the connection is not limited to the above-mentioned embodiment, and is fixed by means of ultrasound. For example, in other embodiments of the present invention, in order to facilitate the later disassembly, maintenance, and replacement of the components, it is also within the scope of the present invention that the fixing base 250 and the base 220 are detachably physically connected, for example, by means of snap-fit connection.

Specifically, as shown in fig. 5, in the embodiment of the present invention, the connection stability of the supporting block 230 is improved. The fixing base 250 is further provided with an extension arm 2503 in a protruding manner, and the extension arm 2503 extends out towards the assembling slot 2201 and clamps the side wall of the supporting block 230. The number of the extension arms 2503 is two, and the two extension arms 2503 respectively protrude from two sides of the fixing seat 250 and are clamped on the second side wall 2306 and the third side wall 2307 of the supporting block 230. Meanwhile, the cross section of the supporting block 230 is approximately elliptical, the first side wall 2305 of the supporting block 230 is disposed at two sides of the long shaft end of the ellipse, and the second side wall 2306 and the third side wall 2307 are disposed at two ends of the short shaft end. The surface of the extension arm 2503 contacting the support block 230 presents an arc surface that fits the support block 230, thereby preventing the support block 230 from being misaligned.

Further, as shown in fig. 5, in the embodiment of the present invention, in order to prevent the supporting block 230 from directly contacting the liquid storage cup 10, a phenomenon that the temperature of the outer wall of the liquid storage cup 10 is high may occur. In this embodiment, an air blocking arm 2504 further extends laterally from the extending tail end of the extending arm 2503, the air blocking arm 2504, the extending arm 2503 and the base 20 enclose an airflow guiding space 2505 in airflow communication with the airflow guiding surface 2308, and the portion of the side wall of the supporting block 230 facing the airflow guiding space 2505 is provided with the air passing hole 2304. An airflow guide space 2505 is defined by the air blocking arm 2504 and the inner wall of the insertion slot 211, so that the airflow in the air passing hole 2304 is limited to flow to the heat generating part 2101 through the airflow guide surface 2308. The phenomenon that the supporting block 230 is provided with an air blocking rib to form an air flow guiding space 2505 with the inner wall of the inserting groove 211 to cause high heat is avoided.

Further, as shown in fig. 6, in the embodiment of the present invention, in order to prevent the fixing seat 250 from crushing the mounting edge 2309, a flexible pad 260 is further disposed between the fixing seat 250 and the mounting edge 2309, and the flexible pad 260 is made of a material such as silicon rubber, or flexible resin, which is not limited herein. By adding the flexible pad 260, the phenomenon that the fixing seat 250 and the mounting edge 2309 are pressed to be damaged due to hard contact is prevented.

Specifically, as shown in fig. 6, in the embodiment of the present invention, the layout groove 2301 extends through the mounting edge 2309 to form a wire passing hole 23091, the base 220 has a through hole corresponding to the wire passing hole 23091, and the conductive lead 2103 of the atomizing element 210 passes through the wire passing hole 23091 and the through hole and then is electrically connected to the conductive electrode 240; the flexible pad 260 is sleeved on the periphery of the supporting block 230 and presses the conductive leads 2103 into the layout groove 2301; the fixing seat 250 presses the flexible pad 260 to the surface of the mounting edge 2309, seals the wire passing hole 23091, and presses the conductive lead 2103 of the flexible pad 260 to the layout groove 2301, so that the conductive lead 2103 passes through the wire passing hole 23091 during mounting, and then the flexible pad 260 is sleeved, thereby preventing the conductive lead 2103 from deviating during flowing of subsequent stations and playing a role of pre-fixing. Meanwhile, when the fixing seat 250 presses the flexible pad 260 against the surface of the mounting flange 2309, the wire passing hole 23091 is sealed, and the phenomenon that condensate leaks out from the wire passing hole 23091 along the conductive lead 2103 is prevented.

Specifically, as shown in fig. 6, in the embodiment of the present invention, a sealing rubber ring 270 is further sleeved on an outer periphery of the fixing seat 250 or the base 220 for being elastically connected with an inner wall of the insertion groove 211 in an interference fit manner, so that the atomizing assembly 200 is fixed to the external liquid storage bomb 100.

Further, as shown in fig. 1, in the embodiment of the present invention, a power supply device 3000 of an atomizing apparatus 10000 of the present application is provided with an accommodating groove 321, one end of the atomizing device 1000, which is provided with a conductive electrode 240, is inserted into the accommodating groove 321, and one end, which is provided with a mist discharge port 12, is exposed to the outside; to discharge the mist; the atomizing assembly 200 of the atomizing device 1000 is further provided with a locking structure, the locking structure is used for locking with the power supply device 3000, so that after the liquid storage cartridge 100 of the atomizing device 1000 is separated from the atomizing assembly 200 under the action of an external force, the atomizing assembly 200 is independently fixed to the power supply device 3000, and at this time, the supporting block 230 of the atomizing assembly 200 and the atomizing element 210 mounted on the supporting block 230 are independently exposed in the air. When the power supply device 3000 supplies power to the atomizing element 210 of the atomizing assembly 200, the heat generating portion 2101 generates heat to dry, so as to remove carbon deposits and dirt attached to the surface of the heat generating portion 2101.

Specifically, as shown in fig. 14, in the embodiment of the present invention, the base 220 is provided with the locking structure to form a fixing portion locked with the power supply device 3000, the supporting block 230 and the heat generating portion 2101 extending out of the fixing seat 250 form an atomizing portion inserted into the liquid storage bullet 100, and atomize the solution adsorbed by the liquid locking member 22 into an aerosol under the action of electric energy; in order to avoid scalding users or external articles when the water is dried and burnt cleanly. The depth of the accommodating groove 321 is greater than the height of the atomizing part, so that when the atomizing assembly 200 is locked in the accommodating groove 321 independently, the atomizing part is completely accommodated in the accommodating groove 321 and is lower than the plane of the notch of the accommodating groove 321, and when the liquid storage bullet 100 is installed in the accommodating groove 321, the end provided with the mist discharge port 12 is exposed from the accommodating groove 321 to be held by a user.

Specifically, as shown in fig. 5, in the embodiment of the present invention, the side wall of the base 220 is opened with the insertion groove 2203, the insertion groove 2203 forms an insertion notch on the bottom end surface of the base 220, and the insertion groove 2203 extends along the direction in which the atomization device 1000 is inserted into the receiving groove 321. The extended end of the insertion groove 2203 is laterally provided with a locking groove 2204, and the insertion groove 2203 and the locking groove 2204 are integrally in an inverted L shape. The power supply device 3000 is provided with a locking block 332, when the locking block 332 is inserted into the locking groove 2204 along the insertion groove 2203 along the locking block 332 and slides into the locking groove 2204, the atomization assembly 200 is locked on the power supply device 3000, and the atomization assembly 200 is independently locked by sliding the locking block 332 into the locking groove 2204, so that the atomization assembly 200 is effectively prevented from being separated from the power supply device 3000.

Specifically, the atomization device 1000 has a rotational degree of freedom in the accommodation groove 321 consistent with the extending direction of the locking groove 2204, for example, the base 220 is cylindrical, the accommodation groove 321 is a circular hole, so that when the atomization device 1000 rotates, the locking block 332 can slide along the locking groove 2204, when the locking block 332 slides into the locking groove 2204, a locking state is formed, and when the locking block 332 slides into the insertion groove 2203, an unlocking state is formed;

in the locked state, the liquid storage cartridge 100 is independently separated from the accommodating groove 321 under the action of external force;

in the unlocked state, the liquid storage cartridge 100 is separated from the accommodating groove 321 together with the atomizing assembly 200 under the action of an external force.

It is understood that, in practical applications, the shape of the base 220 is not limited to the cylindrical design, and the locking block 332 can be locked or unlocked with the locking slot 2204 by rotating. For example, as shown in FIG. 14,

in other embodiments of the present application, it can also be adopted that the power supply device 3000 is provided with a locking slide button 330, the outer wall of the power supply device 3000 is provided with a sliding window 3101, one end of the locking slide button 330 is slidably mounted in the sliding window 3101 and exposed to the outside, and the other end extends into the accommodating groove 321 to form a locking block 332, when the locking slide button 330 is located on one side of the sliding window 3101, the insertion notch of the fixing portion is just opposite to the locking block 332, the locking block 332 slides along the insertion groove 2203 to be aligned with the locking groove 2204, the locking slide button 330 can slide along the sliding window 3101 to drive the locking block 332 to slide into the locking groove 2204, so as to lock the fixing portion in the accommodating groove 321, and the mode of sliding unlocking the locking slide button 330 is adopted, and the locking slide button is not easily triggered by mistake during the accommodating.

Specifically, as shown in fig. 14, in the embodiment of the present invention, the locking slide button 330 includes a toggle block and a locking block 332 protruding from an inner side of the toggle block, two opposite side walls of the locking block 332 are provided with a fastening portion 333 in a protruding manner, an end surface of the locking block 332 protruding is provided with a shape-changing groove, and the fastening portion 333 is used for fastening to an inner side edge of the sliding window 3101; and the buckling part 333 deflects towards the deformation groove under the action of external extrusion force, during installation, a user only needs to insert the locking block 332 of the locking slide button 330 into the power supply device 3000 along the sliding window 3101, the buckling part 333 deflects towards the sliding groove under the action of lateral extrusion force of the sliding window 3101, when the locking part is inserted into the power supply device 3000, the locking part restores deformation, is buckled on the inner wall structure of the power supply device 3000, is convenient to install and prevents the locking slide button 330 from being separated, and simultaneously, for the convenience of inserting the buckling part 333, one side of the buckling part departing from the 333 fluctuation block 331 is arranged in an inclined plane, and is prevented from abutting against the lateral wall of the sliding window 3101 during insertion. Thereby facilitating the user to mount the lock slide button 330 to the power supply device 3000 from the outside.

Further, as shown in fig. 14 and fig. 15, in the embodiment of the present invention, the sliding window is in a shape of a counterbore, a large diameter section of the counterbore is used for accommodating the dial block, a small diameter section of the counterbore is used for allowing the locking block 332 to pass through, the locking slide button 330 further includes a flexible slide button pad 334, the slide button pad 334 is installed on the large diameter section of the counterbore or on the inner side of the dial block, and a damping convex rib 335 is convexly provided towards a step surface of the counterbore or towards the inner side of the dial block. Smooth button pad 334 adopts flexible silica gel preparation, through being equipped with smooth button pad 334 elasticity butt the step face of undulant piece 331 and counter bore to effectively prevent that undulant piece 331 from rocking the phenomenon production that produces the abnormal sound. Meanwhile, the damping convex ribs 335 are convexly arranged on the sliding button pad 334, so that the phenomenon that the whole surface is contacted to cause large damping and difficult fluctuation is prevented.

Specifically, as shown in fig. 14, in the embodiment of the present invention, the power supply device 3000 includes an inner bracket 320 and an outer housing 310 sleeved on the inner bracket 320, one end of the outer housing 310 is open, the accommodating groove 321 is opened at one end of the inner bracket 320 facing the opening, the outer housing 310 starts the large diameter section of the sliding window 3101, the inner bracket 320 is opened with the small diameter section of the sliding window 3101, the small diameter section is communicated with the accommodating groove 321, one end of the locking block 332 is inserted into the accommodating groove 321, and the fastening portion 333 is fastened to the inner wall of the accommodating groove 321. The portion of the inner bracket 320 far away from the receiving groove 321 is used for mounting electronic components such as batteries and circuit boards. The inner support 320 is provided with a part of the accommodating groove 321, and the inner support 320 and the outer shell 310 are fixed through the buckling part 333 of the locking block 332, so that the inner support 320 and the outer shell 310 are fixed without additionally arranging a locking screw, and the hidden fixing mode effectively prevents potential safety hazards caused by self-disassembly of a user.

Specifically, as shown in fig. 15, in the embodiment of the present invention, in order to avoid the occurrence of the phenomenon that the size of the outer housing 310 of the power supply device 3000 protruding from the dial block is large, which results in the unattractive appearance of the product, a containing groove 3311 is formed on the inner side of the wave block 331, and the slide button pad 334 is sleeved on the locking block 332 and embedded inside the containing groove 3311.

Further, as shown in fig. 15, in the embodiment of the present invention, an air supplement groove 3312 is further formed on the inner side of the dial block, a first gap exists between the sidewall of the dial block and the large diameter section, a second gap exists between the sidewall of the inner bracket 320 having the small diameter section and the sidewall of the outer housing 310 having the large diameter section, the air supplement groove 3312 communicates the first gap and the second gap, and an external air flow can flow into the accommodating groove 321 through the first gap, the air supplement groove 3312, and the second gap to provide a working air flow for the atomization device 1000, so as to form a hidden air intake manner, supplement the air flow for the atomization device 1000, and facilitate pressing the slide button pad 334 to prevent the generation of a choke phenomenon during pressing.

Further, as shown in fig. 16, in the embodiment of the invention, the side wall of the receiving groove 321 is further convexly provided with a retaining member 3211, and when the fixing portion is inserted into the receiving groove 321, the retaining member 3211 retains the side wall of the fixing portion. The retaining member 3211 is a protruding wave point or an interference ridge formed on the inner wall of the accommodating groove 321. The connection firmness is enhanced, and the phenomenon that the atomizing device 1000 is separated from the power supply device 3000 when the locking block 332 is separated from the atomizing assembly 200 is prevented.

Further, as shown in fig. 16, in the embodiment of the present invention, an enclosing plate 3212 is further disposed in the accommodating groove 321, the enclosing plate 3212 encloses an insertion space 3213 for inserting the fixing portion into the accommodating groove 321, the enclosing plate 3212 is provided with an air inlet slot 3214, the outer housing 310 is provided with an air inlet hole, external air flows into the insertion space 3213 through the air inlet hole and the air inlet slot 3214 and then enters an internal air path of the fixing portion, the number of the retaining members 3211 is multiple, and at least two retaining members 3211 of the plurality of retaining members 3211 are respectively located at two sides of the air inlet slot 3214. An airflow sensor is arranged in the power supply device 3000, and a trigger port of a trigger air path of the airflow sensor is positioned in the insertion hole piece. When a user sucks the mist through the mist discharge port 12, airflow in the trigger air path is pumped out to the insertion space 3213 and flows into the atomizing assembly 200, and high-speed airflow forms negative pressure to trigger the airflow sensor, so that the power supply device 3000 is driven to supply power to the atomizing assembly 200. A smaller splicing space 3213 is formed in the accommodating groove 3311 by arranging the surrounding plate 3212, so that the triggering sensitivity is effectively improved. Meanwhile, an air inlet slot 3214 is formed in the enclosing plate 3212, and an airflow inflow hole is formed in the outer shell 310 to achieve air inlet, so that air inlet smoothness is improved. A plurality of clamping pieces 3211 are further arranged, and the fixing parts are fixed by the plurality of clamping pieces 3211, so that the connection stability is enhanced. Meanwhile, at least two clamping pieces 3211 of the plurality of clamping pieces 3211 are located on two sides of the notch groove, so that the phenomenon that the connecting strength is weak and the enclosing plate 3212 is easy to deform after the notch groove is formed is avoided.

The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (10)

1. A supporting block for supporting an atomizing element of an atomizing device is characterized in that a gas passing cavity is arranged in the supporting block, and a gas passing hole communicated with the gas passing cavity is formed in the side wall of the supporting block; the side wall of the supporting block is also provided with a distribution groove for positioning and mounting the atomization element;

the air flow in the air passing cavity can flow to the arrangement groove through the air passing hole to provide working air flow for the atomizing element.

2. A support block for supporting an atomizing element of an atomizing device according to claim 1, wherein: the supporting block is provided with two side walls, wherein the two side walls are provided with laying grooves, the supporting block is also provided with wire passing grooves, and one ends of the two laying grooves are communicated with each other through the wire passing grooves.

3. A support block for supporting an atomizing element of an atomizing device according to claim 2, wherein: the two laying grooves are formed in two opposite side walls of the supporting block, and the wire passing grooves are formed in the end faces of the tops of the supporting blocks.

4. A support block for supporting an atomizing element of an atomizing device according to claim 2, wherein: the size of the wire passing groove is larger than that of the laying groove.

5. A support block for supporting an atomizing element of an atomizing device according to claim 2, wherein: the distribution groove is formed in a first side wall of the supporting block, the air passing hole is formed in a second side wall of the supporting block, the first side wall and the second side wall are arranged adjacently, the intersection of the first side wall and the second side wall is obliquely arranged to form an air flow guide surface, and external air flows flow to the distribution groove through the air passing cavity, the air passing hole and the air flow guide surface.

6. A support block for supporting an atomizing element of an atomizing device according to claim 5, wherein: the supporting block further comprises a third side wall opposite to the second side wall, and the third side wall is provided with an air passing hole and an airflow guide surface which are consistent with the second side wall.

7. A support block for supporting an atomizing element of an atomizing device according to claim 1, wherein: the lower end of the supporting block is also provided with a mounting edge used for being fixed on the atomizing component by an external fixing seat, and the distributing groove penetrates through the mounting edge to form a wire passing hole for the conductive lead of the external atomizing element to pass through.

8. A support block for supporting an atomizing element of an atomizing device according to claim 1, wherein: the supporting block is made of ceramic materials.

9. An atomizing device characterized by: the atomizing device comprises an atomizing component and a liquid storage bullet, wherein a liquid storage cavity and a plug cavity for installing the atomizing component are arranged in the liquid storage bullet, the atomizing component can be plugged in the plug cavity in a pulling mode, the atomizing component comprises a base, an atomizing element and the supporting block according to any one of claims 1 to 8, one end of the supporting block is fixedly connected to the base, the other end of the supporting block extends out of the base, the atomizing element is installed in the arranging groove in a positioning mode, and the base is used for being plugged in the plug cavity to enable the atomizing element to be in contact with liquid locking cotton in the liquid storage bullet.

10. An atomizing apparatus characterized by: comprising a power supply device and an atomizing device as claimed in claim 9, wherein the atomizing assembly is electrically connected to the power supply device when the atomizing device is plugged into the power supply device.

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