CN113768193A - Electronic atomizer and atomizing device thereof - Google Patents

Abstract

The invention relates to an electronic atomizer and an atomizing device thereof, relating to the technical field of electronic cigarettes, and comprising an oil guide part for guiding the flow of tobacco tar, a separation part provided with a plurality of oil passing holes according to a preset mode, and a heating part for heating and atomizing the tobacco tar; the isolating piece is arranged between the oil guiding piece and the heating piece, and when the oil guiding device works, the smoke oil on the oil guiding piece is guided to the heating piece through each oil hole to be heated and atomized; therefore, the isolating piece is arranged between the oil guide piece and the heating piece, and the isolating piece is provided with the plurality of oil passing holes, so that the direct contact between the oil guide piece and the heating piece is avoided, and in the working process, the smoke oil on the oil guide piece can uniformly flow to the working area of the heating piece after passing through the oil passing holes, so that the smoke oil is heated and atomized; so, not only avoided leading the phenomenon that oil spare appears dry combustion method, can also reduce the processing and the assembly degree of difficulty to leading oil spare and heating member, reduced manufacturing cost.

Description

Electronic atomizer and atomizing device thereof

Technical Field

The invention relates to the technical field of electronic atomizers, in particular to an electronic atomizer and an atomizing device thereof.

Background

The present electronic atomizer generally heats and atomizes the tobacco tar through an atomizing device, specifically, the tobacco tar is soaked to a middle position from the outer side of the oil guide cotton, and then is heated and atomized by a heating wire wound outside the oil guide cotton.

In the process of atomizing the tobacco tar, the oil guiding uniformity of the tobacco tar is very important, and the oil guiding cotton with poor oil guiding uniformity can be burnt when the heating wire heats, SO that harmful gases such as CO2 and SO2 harmful to human bodies are generated, the taste is seriously influenced, and even the health of the human bodies is threatened; the cause of this problem is not unique, for example: the thickness and density of the cotton layers mutually wrapped on the oil guide cotton, the uniformity of the distance between the turns of the heating wire are inconsistent or the assembly precision of the oil guide cotton and the heating wire is poor, and the like;

in this respect, if the production and assembly accuracy of the oil guide cotton and the heating wire is optimized, the production cost is inevitably increased; if the oil guide uniformity of the oil guide cotton is not optimized, dry burning is easy to occur to generate gas harmful to human bodies.

Disclosure of Invention

The invention aims to provide an electronic atomizer capable of preventing dry burning and an atomization device thereof.

The technical scheme adopted by the invention for solving the technical problems is as follows:

the invention provides an atomization device, which comprises an oil guide part for guiding the flow of tobacco tar, a separation part provided with a plurality of oil passing holes according to a preset mode, and a heating part for heating and atomizing the tobacco tar;

the separator set up in lead oily spare with between the heating member, during operation, lead the tobacco tar on the oily spare through each the oilhole is led and is heated the atomizing on the heating member.

In some embodiments, the spacer is made of high temperature resistant food grade silicone.

In some embodiments, each of the oil passing holes is sequentially tapped on the partition to form at least one oil passing hole group, and gaps between two adjacent oil passing holes in the same oil passing hole group are equal.

In some embodiments, the at least one oil through hole group comprises a plurality of oil through hole groups, and the interval between every two adjacent oil through hole groups is equal.

In some embodiments, the atomizing device further includes a seat body, the seat body defines a receiving groove, a sidewall of the receiving groove defines at least one oil inlet, and the oil guiding member, the separating member and the heating member are disposed in the receiving groove.

In some embodiments, the outer side wall of the seat body is recessed inwards to form a smoke and oil guiding surface, and each oil inlet hole is located at the bottom of the smoke and oil guiding surface.

In some embodiments, the atomization device further includes an auxiliary positioning member, and the auxiliary positioning member includes a limiting portion adapted to the accommodating groove, and an alignment portion disposed on the limiting portion;

when the positioning part is inserted into the bottom of the accommodating groove, the limiting part is abutted against the wall of the accommodating groove, and the oil guide part, the isolating part and the heating part are pushed by the positioning part to move to a preset position in the accommodating groove.

In some embodiments, the oil guiding member has an accommodating passage, the heating member is disposed in the accommodating passage, and the separating member is disposed between a sidewall of the accommodating passage and the heating member.

In some embodiments, the separator is sleeved on an outer side wall of the oil guide member, and the heating member is disposed on an outer side wall of the separator.

The application also provides an electronic atomizer, which comprises a shell and the atomizing device, wherein the atomizing device is arranged in the shell.

The beneficial effects of the invention at least comprise:

according to the electronic atomizer and the atomization device thereof, the isolating piece is arranged between the oil guide piece and the heating piece, and the isolating piece is provided with the plurality of oil passing holes, so that the direct contact between the oil guide piece and the heating piece is avoided, and in the working process, the smoke on the oil guide piece can uniformly flow to the working area of the heating piece after passing through each oil passing hole, so that the smoke is heated and atomized; so, not only avoided leading the phenomenon that oil spare appears dry combustion method, can also reduce the processing and the assembly degree of difficulty to leading oil spare and heating member, reduced manufacturing cost.

Drawings

The invention will be further described with reference to the accompanying drawings and examples, in which:

FIG. 1 is a schematic diagram of the construction of an electronic atomizer in accordance with a preferred embodiment of the present invention;

FIG. 2 is a schematic view of the electronic atomizer of FIG. 1 with the housing removed;

FIG. 3 is a schematic structural view of an atomizing device in the electronic atomizer shown in FIG. 1;

FIG. 4 is a cross-sectional view of an atomizing device in accordance with a preferred embodiment of the present invention;

FIG. 5 is an enlarged schematic view at A of the electronic atomizer of FIG. 2;

fig. 6 is a schematic structural view of an atomizing device in another preferred embodiment of the present invention.

Detailed Description

For a more clear understanding of the technical features, objects and effects of the present invention, embodiments of the present invention will now be described in detail with reference to the accompanying drawings.

Fig. 1 shows an electronic atomizer 10 according to some embodiments of the present invention, where the electronic atomizer 10 is used for heating and atomizing tobacco tar, and includes a housing 1, an atomizing device 2, and an auxiliary positioning member 3. Atomizing device 2 sets up in casing 1, and this atomizing device 2 is used for heating the atomizing to the tobacco tar. The auxiliary positioning piece 3 is used for assisting the alignment and assembly of each part of the atomization device 2.

Understandably, the shape and the outline of the shell 1 can be flexibly arranged; the shell 1 can be provided with a cavity or a groove body for accommodating the atomization device 2; the shell 1 can be manufactured by adopting an injection molding mode, and can also be formed by adopting split injection molding and then assembled by split injection molding parts; of course, the housing 1 may be made of other materials such as metal. After the auxiliary positioning piece 3 is used to complete the alignment assembly of the atomization device 2, the auxiliary positioning piece 3 can be taken down, and then the atomization device 2 is sent into the subsequent assembly processing procedure.

As shown in fig. 2, 3, 4 and 5, the atomizing device 2 may include an oil guiding member 21, a heating member 22 and a separating member 23 in some embodiments, the heating member 22 is used for heating and atomizing the soot, and the separating member 23 is used for preventing the oil guiding member 21 and the heating member 22 from being in direct contact. The partition 23 is provided between the oil guide 21 and the heating member 22, and the oil guide 21 serves to guide the flow of the soot. A plurality of oil passing holes 232 are formed in the isolating piece 23 according to a preset mode, and each oil passing hole 232 is used for guiding the flow of the tobacco tar; in operation, the soot on the oil guiding member 21 is guided to the heating member 22 through the oil passing holes 232 for heating and atomization.

It is understood that the heating element 22 may be a heating wire, a heating net or a heating sheet, which are used to heat and atomize the tobacco tar in the prior art. A power supply unit, for example, a lithium battery or the like, for supplying power to the heating member 22 may be provided in the housing 1. The spacer 23 is made of a high temperature resistant material in the prior art; the high-temperature resistant material can prevent the isolating piece 23 from being deformed by the high temperature generated by the heating piece 22 in work, so that the oil passing holes 232 are prevented from being distorted and deformed due to the deformation of the isolating piece 23, the aperture and hole wall profile of each oil passing hole 232 and the relative position between the oil passing holes 232 are ensured to be unchanged, and the oil guiding uniformity of the isolating piece 23 is ensured. The oil guide member 21 may be made of multi-layer cotton, single-layer cotton or non-woven fabric in some embodiments, and may be a structure capable of adsorbing and guiding the tobacco tar;

in particular, the spacer 23 may be made of high temperature resistant food grade silicone in some embodiments.

Understandably, the high-temperature-resistant food-grade silica gel has the advantages of no toxicity and no odor, and is widely applied to the medical field; and the isolator 23 is made of the high-temperature-resistant food-grade silica gel, so that the isolator 23 can be prevented from generating harmful substances, and the use safety factor of the product is improved. The specific selection of high temperature resistant food grade silica gel can be selected according to the heating temperature of heating member 22 in the course of the work and in a flexible way to can tolerate the temperature of heating member 22 when normally working.

As shown in fig. 5, each oil passing hole 232 may be sequentially formed in the spacer 23 as at least one oil passing hole group 231 in some embodiments, and the gaps between two adjacent oil passing holes 232 in the same oil passing hole group 231 are equal.

It is understood that the oil through holes 232 in each oil through hole group 231 are used for guiding the flow of the smoke oil; the gaps D1 between two adjacent oil passing holes 232 in each oil passing hole group 231 are equal, so that the uniformity of the smoke oil passing through the partition 23 can be further improved; secondly, the size of D1 can also be flexibly adjusted, as long as the tobacco tar can uniformly flow through the separator 23 in a predetermined manner, and the separator 23 is prevented from being used abnormally due to too low mechanical strength caused by too dense oil passing holes 232; thus, products of different configurations and different design requirements may employ different sizes of D1.

It will also be appreciated that the arrangement of the oil through hole sets 231 can be flexibly adjusted according to the structure of the separator 23, for example:

first, when the separator 23 is cylindrical, the oil through hole groups 231 may be circumferentially distributed along the outer sidewall of the cylindrical separator 23, may be arranged along the longitudinal direction of the cylindrical separator 23, or may be arranged along a curved line on the sidewall of the cylindrical separator 23;

second, when the separator 23 has a prism shape such as a triangular prism or a quadrangular prism, the oil through hole groups 231 may be arranged and distributed along the width direction or the length direction of each side surface of the prism, or may be arranged and distributed along a curved line or an oblique line on each side surface of the prism.

As shown in fig. 5, the oil through hole sets 231 may be provided in a plurality in some embodiments, and the intervals D2 between two adjacent oil through hole sets 231 are equal.

It can be understood that, setting the interval D2 between two adjacent oil through hole sets 231 equal can improve the distribution uniformity of each oil through hole 232 on the partition 23, avoid the concentrated smoke oil from passing through some oil through holes 232 on the partition 23, and further improve the oil through uniformity of the partition 23.

As shown in fig. 2, 3 and 4, the atomizing device 2 further includes a seat body 24 in some embodiments, and the seat body 24 functions to support and fix the rest of the components. The base 24 has a receiving groove 241, and the oil guide member 21, the separating member 23 and the heating member 22 are disposed in the receiving groove 241. At least one oil inlet hole 242 is formed in the side wall of the accommodating groove 241, and the oil inlet hole 242 is formed so that the smoke oil can enter the accommodating groove 241 and infiltrate the oil guide member 21.

It is understood that the groove body profile of the receiving groove 241 may be configured according to the assembled oil guiding member 21, the heating member 22 and the separating member 23 to achieve a good fixing effect. A corresponding oil guiding structure may be further disposed in the receiving groove 241, so that the oil smoke flowing along the oil inlet 242 does not directly flow onto the heating element 22, and only flows to the oil guiding element 21 and then passes through the separating element 23, and then is heated and atomized by the heating element 22.

As shown in fig. 3 and 4, the outer sidewall of the seat body 24 may be recessed inward to form a soot guiding surface 243 in some embodiments, each oil inlet hole 242 is located at the bottom of the soot guiding surface 243, and the soot guiding surface 243 plays a role of guiding the soot to flow to each oil inlet hole 242.

It can be understood that the soot guiding surface 243 can collect soot, so that the soot can be collected and flow into the oil inlet 242, thereby ensuring that the soot can be supplied to the soot guiding member 21 in time and further flow onto the heating member 22, avoiding the heating member 22 from being heated to an excessive temperature continuously under the condition of no soot, and thus avoiding damage to other parts, and improving the use safety and durability of the product.

As shown in fig. 1, 2 and 4, the auxiliary positioning member 3 may include a position-limiting portion 31 and an aligning portion 32 in some embodiments. The position-limiting portion 31 is adapted to the receiving groove 241, and the position-limiting portion 31 is used for positioning the relative position of the auxiliary positioning element 3 and the seat body 24. The positioning portion 32 is connected to the stopper portion 31, and the positioning portion 32 is used to assist the assembly of the atomizing device 2. When the positioning portion 32 is inserted into the bottom of the receiving groove 241, the stopper 31 is abutted against the wall of the receiving groove 241, and the oil guide 21, the spacer 23, and the heating element 22 are pushed by the positioning portion 32 and moved to a predetermined position in the receiving groove 241.

It can be understood that, in order to ensure that the oil guiding element 21, the separating element 23 and the heating element 22 can be accurately installed and fixed at the predetermined positions in the receiving groove 241, the auxiliary positioning element 3 is inserted into the receiving groove 241, in this process, the position-limiting part 31 will first contact with the groove wall of the receiving groove 241 to achieve the effect of positioning the relative position of the position-limiting part 31 and the seat body 24, so as to position the relative position of the positioning part 32 and the seat body 24, and then, along with the continuous penetration of the positioning part 32, the positioning part 32 will gradually push and hold the oil guiding element 21, the separating element 23 and the heating element 22 to the predetermined positions in the receiving groove 241; thus, the assembly of the atomizing device 2 is completed quickly and accurately, and the processing efficiency of the product is improved.

It can be understood that the limiting portion 31 can be just inserted into the receiving groove 241, that is, the cross-sectional area of the limiting portion 31 is slightly smaller than the area of the permanent surface of the receiving groove 241, and the cross-sectional profiles of the two are similar; in this way, when the stopper 31 is inserted into the receiving groove 241, the relative position between the seat body 24 and the auxiliary retainer 3 can be determined more accurately, and the assembling accuracy can be further improved.

As shown in fig. 2, in some embodiments, the atomizing device 2 may have an accommodating passage 211a on the oil guiding member 21, the heating member 22 is disposed in the accommodating passage 211a, and the partition 23 is disposed between the side wall of the accommodating passage 211a and the heating member 22.

It can be understood that, during the use process, the soot on the oil guiding member 21 will be collected towards the center of the oil guiding member 21, and then flow to the oil passing holes 232 on the separating member 23 respectively and flow uniformly to the heating member 22 through the oil passing holes 232, and the soot is heated and atomized by the heating member 22; it should be noted that the soot may be atomized by heat only when entering the working area of the heating element 22, and does not fall onto the heating element 22.

It is also understood that the receiving passage 211a may extend completely through the oil guide 21; one end of which is used for inserting the heating element 22 into the accommodating passage 211a and the other end of which is used for discharging the atomized tobacco tar. The lateral surface of separator 23 and the lateral wall in close contact with that holds passageway 211a for lead in the tobacco tar that oil piece 21 moved towards the center that holds passageway 211a can in time get into each oil passing hole 232 on separator 23, avoid the tobacco tar to concentrate because of the dead weight and converge to the lower part and lead to the tobacco tar to distribute unevenly on attaching to separator 23, guaranteed good oil of leading degree of consistency.

As shown in fig. 6, in other embodiments of the atomizing device 2, the partition 23 is sleeved on the outer sidewall of the oil guiding member 21, and the heating member 22 is disposed on the outer sidewall of the partition 23.

It can be understood that, during the use process, the smoke oil flows into the center of the oil guiding member 21 and spreads from the center of the oil guiding member 21 to the periphery, and then is guided to the heating member 22 through the oil passing holes 232 on the separating member 23 outside the oil guiding member 21 for heating and atomizing; it should be noted that the soot may be atomized by heat only when entering the working area of the heating element 22, and does not fall onto the heating element 22.

It can be understood that the spacer 23 is coated on the outer side of the oil guide 21, so that the oil guide uniformity of the product is ensured.

In summary, compared with the mode of continuously improving the processing precision in order to ensure the transmission uniformity of the tobacco tar in the prior art, the method has the advantages that the isolation piece is arranged between the oil guide piece and the heating piece, and the isolation piece is provided with the plurality of oil passing holes, so that the transmission uniformity of the tobacco tar can be improved, and the dry burning phenomenon is avoided; meanwhile, the processing and assembling difficulty of the atomization device is reduced, the production efficiency is improved, and the production cost is reduced.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and are intended to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the scope of the present invention. All equivalent changes and modifications made within the scope of the claims of the present invention should be covered by the claims of the present invention.

Claims (10)

1. An atomization device is characterized by comprising an oil guide member (21) for guiding the flow of tobacco tar, a spacing member (23) provided with a plurality of oil passing holes according to a preset mode, and a heating member (22) for heating and atomizing the tobacco tar;

the isolating piece (23) is arranged between the oil guiding piece (21) and the heating piece (22), and during operation, the tobacco tar on the oil guiding piece (21) is guided to the heating piece (22) through the oil passing holes (232) to be heated and atomized.

2. The atomizing device according to claim 1, wherein the spacer 23 is made of high-temperature-resistant food-grade silicone.

3. The atomizing device according to claim 1, wherein each of the oil passing holes (232) is formed in the partition (23) in a sequential manner as at least one oil passing hole group (231), and the gaps between two adjacent oil passing holes (232) in the same oil passing hole group (231) are equal.

4. An atomizing device according to claim 3, characterized in that said at least one oil through hole group (231) includes a plurality of said oil through hole groups (231), and the interval between two adjacent oil through hole groups (231) is equal.

5. The atomizing device according to claim 1, wherein the atomizing device (2) further comprises a seat body (24), the seat body (24) defines a receiving groove (241), a sidewall of the receiving groove (241) defines at least one oil inlet hole (242), and the oil guide member (21), the separating member (22) and the heating member (23) are disposed in the receiving groove (241).

6. The atomizing device according to claim 5, characterized in that the outer side wall of the seat body (24) is recessed inward to form a soot guiding surface (243), and each of the oil inlet holes (242) is located at the bottom of the soot guiding surface (243).

7. The atomizing device according to claim 5, characterized in that the atomizing device (2) further comprises an auxiliary positioning member (3), the auxiliary positioning member (3) comprises a limiting portion (31) adapted to the receiving groove (241), and an aligning portion (32) provided on the limiting portion (31);

when the positioning part (32) is inserted into the bottom of the accommodating groove (241), the limiting part (31) is abutted against the wall of the accommodating groove (241), and the oil guide member (21), the spacer member (23) and the heating member (22) are pushed by the positioning part (32) to move to a preset position in the accommodating groove (241).

8. The atomizing device according to claim 1, wherein the oil guide member (21) has an accommodating passage (211a), the heating member (22) is disposed in the accommodating passage (211a), and the partition member (23) is disposed between a side wall of the accommodating passage (211a) and the heating member (22).

9. The atomizing device according to claim 1, characterized in that the partition (23) is fitted over an outer side wall of the oil guide (21), and the heating member (22) is provided over an outer side wall of the partition (23).

10. An electronic atomizer, characterized in that it comprises a housing and an atomizing device (2) according to any one of claims 1 to 8, said atomizing device (2) being arranged in said housing (1).

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