KR20230098095A - Atomization core with air flow chamber - Google Patents

Abstract

The present invention provides an atomization core, which includes a heating element and a liquid guide body made of a porous material used to absorb and transfer liquid, and the liquid guide body includes an air guide portion and a base portion connected to and surrounding the air guide portion And, the gap between the air guide part and the base part forms an air flow chamber, and an air inlet communicating with the air flow chamber, an air outlet communicating with the air flow chamber, and a liquid entry part used to contact the liquid are installed in the liquid guide body. The heating element includes a heating unit that generates heat when electricity is applied and an electrical connection used to transmit current to the heating unit by connecting the heating unit, and the heating unit is installed on the inner wall of the air flow chamber to contact the liquid guide body. Since the atomization core installs the air flow chamber inside the liquid guide body, which is a porous material, and installs the heating part of the heating element inside the air flow chamber, the size, flow rate and path of the air flow are mainly determined by the structure of the liquid guide body, It is advantageous to ensure the consistency of the atomization effect because it is not affected by other members and assembly relationships.

Description

Atomization core with air flow chamber

The present invention relates to the field of atomization technology, and more particularly to an atomization core having an airflow chamber.

The atomization core is a core member of an atomizer, and usually includes a liquid guide body and a heating element. The liquid guide body mainly serves to heat and atomize by transferring liquid to the heating element, and is used as an atomizer for electronic cigarettes. mainly serves to deliver the e-cigarette liquid and to heat and vaporize the e-cigarette liquid.

After the conventional atomization core is assembled with other members to form an atomizer, the atomization core and other members must determine the range for the atomization chamber and the air entry hole of the atomization chamber, and the heating part of the heating element heats the liquid to produce aerosol. and the airflow entrains the aerosol; However, since the range of the atomization chamber and the air entry/exit hole of the atomization chamber is determined by the atomization core and other members, the air flow of the air entering the atomization chamber and the air entry/exit hole affects the atomization effect, and the air flow is more or less , both the speed and the slowness of the flow indirectly affect the effectiveness and stability of atomization. In assembling the atomization core and other members, lack of precision or poor consistency affect the atomization effect of the atomization core.

The present invention was created to solve the above deficiencies in the related art, and its object is to provide an atomizing core with a more improved air flow chamber.

The technical solutions used by the present invention to solve the technical problems include the following.

Provides an atomization core, which includes a heating element and a liquid guide body made of a porous material used to absorb and transfer liquid, wherein the liquid guide body includes an air guide portion and a base portion connected to and surrounding the air guide portion, , The gap between the air guide part and the base part forms an air flow chamber, and the liquid guide body has an air inlet communicating with the air flow chamber, an air outlet communicating with the air flow chamber, and a liquid used to contact the liquid. An entry part is installed, and the heating element includes a heating part that generates heat when electricity is applied and an electrical connection part used to transmit current to the heating part by connecting the heating part, and the heating part is brought into contact with the liquid guide body. Installed on the inner wall of the airflow chamber, when the liquid entry part of the liquid guide body contacts the liquid, the liquid guide body transfers the liquid to the heating part and heats it to generate aerosol, and the external air flow flows through the air entry hole. enters the airflow chamber from the airflow chamber and draws aerosol out of the air outlet.

Preferably, the air flow chamber is annular or an annular space with corners.

Preferably, the base part includes a first part and a second part, the first part and the second part surround both sides of the air guide part, respectively, and one end of the first part and the second part are mutually connected to connect the air guide part.

Preferably, in the airflow chamber, the heat generating unit is installed in the base unit, and the liquid entry unit is installed outside the base unit.

Preferably, the liquid entry portion is a location of a liquid entry groove provided on the outside of the base portion.

Preferably, in the air flow chamber, the heating unit is installed in the air guide unit.

Preferably, the liquid entry part is a position of a liquid entry groove installed outside the air guide part.

Preferably, the air inlet is installed at a connection point between the base part and the air guide part.

Preferably, the other end of the first part and the other end of the second part define a range of the air outlet.

Preferably, the air inlet is installed on the lower side of the liquid guide body, and the liquid guide body is connected to the base part and/or the air guide part and protrudes downward to be used to lift the air inlet high. includes

When implementing the technical solution of the present invention, at least the following advantageous effects are achieved.

Since the atomization core installs the air flow chamber inside the liquid guide body, which is a porous material, and installs the heating part of the heating element inside the air flow chamber, the size, flow rate and path of the air flow are mainly determined by the structure of the liquid guide body, It is advantageous to ensure the consistency of the atomization effect because it is not affected by other members and assembly relationships.

Hereinafter, in order to more clearly explain the technical solutions of the embodiments according to the present invention, the drawings to be used in the description of the embodiments or the prior art will be briefly described. The drawings described below are only some embodiments of the present invention, and the present invention It is obvious that those skilled in the art can obtain other drawings based on these drawings under the premise that they do not proceed with progressive labor.
1 is a three-dimensional view of an atomizing core of an embodiment according to the present invention;
Figure 2 is a cross-sectional view of position AA in Figure 1;
Figure 3 is a three-dimensional view of the heating element of the atomizing core shown in Figure 1;
Figure 4 is a three-dimensional view of the liquid guide body of the atomizing core shown in Figure 1;
Figure 5 is a three-dimensional view of the liquid guide body of the atomization core according to another embodiment of the present invention;
Figure 6 is a three-dimensional view of another embodiment of the atomization core according to the present invention;
Fig. 7 is a cross-sectional view of a position BB in Fig. 6;
Figure 8 is a three-dimensional view of the heating element of the atomizing core shown in Figure 6;
Figure 9 is a three-dimensional view of the liquid guide body of the atomization core shown in Figure 6;

In order to more clearly understand the technical features, objects and effects of the present invention, specific embodiments of the present invention will be described in detail in comparison with the drawings. The direction or positional relationship indicated by “top”, “bottom”, “longitudinal”, “lateral”, “top”, “bottom”, “inside”, “outside”, etc. in the sentence is the direction shown in the drawing or It is configured and operated in a specific orientation based on the positional relationship, and is only intended to conveniently describe the technical solution, and does not indicate that the indicated device or element must necessarily have a specific orientation, and therefore, What cannot be understood as a limitation of the present invention should be understood. What should be further explained is that, unless otherwise clearly defined and limited, terms such as “mounting”, “interconnection”, “connection”, and “installation” are used in a sentence to be understood in a broad sense. For example, it can be fixedly connected, connected separately or formed integrally; It may be directly interconnected, indirectly interconnected through an intermediate medium, or may be an internal communication between two elements or an interaction relationship between two elements. When an element is described as being positioned “above” or “below” another element, the element may be positioned “directly” or “indirectly” on top of the other element, or one Or there may be more intermediate elements. When the terms “first”, “second”, “third”, etc. are written in the sentence, it is only for the purpose of conveniently describing the technical solution, and the relative importance is indicated, implied, or the number of indicated technical features is not indicated. It is not to be understood as implicitly pointed out, and therefore, a feature defined as "first", "second", "third", etc., may expressly or implicitly include one or more of the above features. Those skilled in the art may understand the specific meaning of the above terms in the present invention based on specific circumstances.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The following description presents specific details, such as specific system architectures and techniques, for purposes of explanation and not limitation, so that embodiments of the present invention may be clearly understood. However, those skilled in the art should appreciate that the present invention may be practiced in other embodiments that do not have these specific details. In other instances, detailed descriptions of systems, devices, circuits, and methods well known to those skilled in the art are omitted so that unnecessary detail does not obscure the description of the present invention.

As shown in Figures 1 to 4, the atomization core according to the embodiment of the present invention includes a heating element 2 and a liquid guide body 1 of a porous material used to absorb and transfer liquid, and a porous material (micro hole material) realizes liquid absorption and transmission by distributing numerous micro holes like a porous ceramic material; The liquid guide body 1 includes an air guide part 12 and a base part 11 connected to and surrounding the air guide part 12, and between the air guide part 12 and the base part 11 The gap forms an air flow chamber 17, and the liquid guide body 1 has an air inlet 15 communicating with the air flow chamber 17, an air outlet 16 communicating with the air flow chamber 17, and a contact with the liquid. The liquid entry part 14 used to transfer the current to the heating part 21 by connecting the heating part 21 and the heating part 21 that generates heat when electricity is applied to the heating element 2. The heating unit 21 is installed on the inner wall of the air flow chamber 17 so as to contact the liquid guide body 1, and the electrical connection 22 is connected to the outside of the air flow chamber 17. By extending to, when the liquid entry part 14 of the liquid guide body 1 contacts the liquid, the liquid guide body 1 transfers the liquid to the heating part 21 and heats it to generate an aerosol, The air flow enters the air flow chamber (17) from the air inlet (15) and draws the aerosol out from the air outlet (16). Here, the porous material may be a porous ceramic material.

The atomization core of the present invention contacts the liquid through the liquid entry part 14 of the liquid guide body 1, and the liquid guide body 1 transfers the liquid to the heating part 21 of the heating element 2 for heating and atomization. to form an aerosol, and the airflow flows through the atomization screen (the part where the heating part 21 of the heating element 2 heats the liquid to generate aerosol), but draws the atomized aerosol.

The atomization core of the present invention achieves beneficial technical effects as follows.

1. Since the air flow chamber 17 is installed inside the porous liquid guide body 1, and the heating part 21 of the heating element 2 is installed inside the air flow chamber 17, the size and flow rate of the air flow And the path is mainly determined by the structure of the liquid guide body 1, and is not affected by other members and assembly relationships, so it is advantageous to ensure the consistency of the atomization effect.

2. Since the liquid guide body 1 is a porous material, the entire interior of the air flow chamber 17 is a porous material, and the condensate generated inside the air flow chamber 17 is absorbed by the liquid guide body 1, The generation of condensate can be effectively reduced.

3. When the atomization core of the present invention is applied to an atomization device, the air flow chamber 17 is mainly determined by the structure of the liquid guide body 1, so that the liquid guide body 1 and other members jointly air flow chamber 17 ), the structural configuration of the atomizer can be reduced, and the assembly is convenient, quick, stable and reliable.

The atomizing core of the present invention can be applied to an atomizing device of an electronic cigarette and used to heat and atomize an electronic cigarette liquid. The specific operation process is as follows, the liquid entry part (14) of the liquid guide body (1) of the atomization core is in contact with the electronic cigarette liquid of the atomizing device, and the liquid guide body (1) transfers the electronic cigarette liquid to the heating element (2). It is transmitted to the heating part 21 to heat and atomize to form smoke, and the external airflow enters from the air inlet and draws the smoke out from the air outlet so that the smoker can inhale it.

Preferably, the liquid guide body 1 is integrally molded.

The structure of the airflow chamber 17 of the atomization core may be any shape, and the airflow chamber 17 may be an annular space so as to facilitate molding of the heating element 2 (see FIGS. 1 to 4). ), it may be a ring-shaped space with corners, such as a polygonal ring shape (see FIG. 5). The heating part 21 of the heating element 2 includes a plurality of planar no-screens, in this case, the conformity of molding of the heating element 2 can be easily controlled, and the inlaid stability of the porous material is better. . Other various shapes of non-screen and air flow chamber 17 are not exemplified again. The heating part 21 of the heating element 2 includes at least one heating circuit, and the heating circuit is bent into an annular shape.

As shown in FIGS. 1 to 4 , in the airflow chamber 17 of some embodiments, the sidewalls of the heating unit 21 and the air guide unit 12 and the sidewalls of the base unit 11 correspond in shape to all of them. It forms a ring shape, the heating part 21 of the heating element 2 is installed on the side wall of the base part 11, and the liquid entry part 14 is installed on the outside of the base part 11. The liquid entry part 14 may be a position of a liquid entry groove installed on the outside of the base part 11 .

As shown in FIGS. 6 to 9 , in the air flow chamber 17 of some other embodiments, the side walls of the heating unit 21 and the air guide unit 12 and the side walls of the base unit 11 correspond in shape to each other. All form an annular shape, and the heating part 21 of the heating element 2 is installed on the sidewall of the air guide part 12. In the airflow chamber 17, it will be understood that the heating unit 21 can be installed on both sides of the air guide unit 12 and the base unit 11. The liquid entry part 14 is a position of a liquid entry groove installed on the outside of the air guide part 12 .

Preferably, the base part 11 includes a first part 111 and a second part 112, and the first part 111 and the second part 112 are opposite sides of the air guide part 12, respectively. It surrounds both sides, and ends of the first part 111 and the second part 112 are connected to each other to connect the air guide part 12 .

Preferably, the air inlet 15 is installed at a connection point between the base part 11 and the air guide part 12.

Preferably, the other end of the first part 111 and the other end of the second part 112 are separated and floated in the air to determine the range of the air outlet 16.

Preferably, the air inlet 15 is installed on the lower side of the liquid guide body 1, and the liquid guide body 1 is connected to the base part 11 and/or the air guide part 12 and protrudes downward to air It includes a support 13 used to lift the inlet 15 high, one of its roles is to support the atomization core, and the other is to support and raise the atomization core to expose the air inlet 15. there is The air guide unit 12 can allow the air flow that has risen vertically from the air inlet 15 to move toward the non-screen on both sides, the air guide unit 12 is also made of a porous material, and the air flow chamber 17 The atomized aerosol in the air is not easily condensed, and even if condensed, the condensate may be absorbed by the liquid guide body 1 again.

Overall, the atomization core of the present invention achieves the following advantageous technical effects.

1. Since the air flow chamber 17 is installed inside the porous liquid guide body 1, and the heating part 21 of the heating element 2 is installed inside the air flow chamber 17, the size and flow rate of the air flow And the path is mainly determined by the structure of the liquid guide body 1, and is not affected by other members and assembly relationships, so it is advantageous to ensure the consistency of the atomization effect.

2. Since the liquid guide body 1 is a porous material, the entire interior of the air flow chamber 17 is a porous material, and the condensate generated inside the air flow chamber 17 is absorbed by the liquid guide body 1, The generation of condensate can be effectively reduced.

3. When the atomization core of the present invention is applied to an atomization device, the air flow chamber 17 is mainly determined by the structure of the liquid guide body 1, so that the liquid guide body 1 and other members jointly air flow chamber 17 ), the structural configuration of the atomizer can be reduced, and the assembly is convenient, quick, stable and reliable.

The above is merely a preferred embodiment of the present invention, and is not used to limit the present invention, and those skilled in the art can make various changes, combinations, and changes to the present invention. All modifications, equivalent substitutions, and improvements made within the spirit and principles of the present invention should all be included within the scope of the claims of the present invention.

1: liquid guide body
11: base part
111 first part
112 second part
12: air guide part
13: support
14: liquid entry point
15: air inlet
16: air outlet
17: air flow chamber
2: heating element
21: heating part
22: electrical connection

Claims (10)

In the atomization core,
It includes a heating element (2) and a liquid guide body (1) made of a porous material used to absorb and transfer liquid, and the liquid guide body (1) is an air guide part (12) and It includes a base part 11 connected to and surrounding the periphery, and the gap between the air guide part 12 and the base part 11 forms an air flow chamber 17, and the liquid guide body 1 has the An air inlet 15 communicating with the air flow chamber 17, an air outlet 16 communicating with the air flow chamber 17, and a liquid entry portion 14 used to contact liquid are installed, and the heating element 2 ) includes a heating unit 21 that generates heat when electricity is applied and an electrical connection unit 22 used to transmit current to the heating unit 21 by connecting the heating unit 21, and the heating unit ( 21) is installed on the inner wall of the air flow chamber 17 to contact the liquid guide body 1, so that when the liquid entry portion 14 of the liquid guide body 1 contacts liquid, the liquid guide body (1) transfers and heats the liquid to the heating part 21 to generate an aerosol, and an external air flow enters the air flow chamber 17 from the air inlet 15 and releases aerosol from the air outlet 16 A drawing core characterized by dragging and exporting. According to claim 1,
The air flow chamber 17 is an atomizing core, characterized in that a circular (圓環) shape or a ring-shaped space having a corner. According to claim 2,
The base part 11 includes a first part 111 and a second part 112, and the first part 111 and the second part 112 are both sides of the air guide part 12, respectively. Enclosed, one end of the first part 111 and the second part 112 are connected to each other to connect the air guide part 12, characterized in that the atomization core. According to claim 3,
In the airflow chamber (17), the heating part (21) is installed on the base part (11), and the liquid entry part (14) is installed outside the base part (11). According to claim 4,
The liquid entry part 14 is an atomization core, characterized in that the position of the liquid entry groove installed on the outside of the base part 11. According to claim 3,
In the air flow chamber (17), the heating part (21) is atomized core, characterized in that installed in the air guide part (12). According to claim 6,
The atomization core, characterized in that the liquid entry portion 14 is a liquid entry groove position installed outside the air guide portion 12. According to claim 3,
The atomization core, characterized in that the air inlet (15) is installed at the connection point between the base part (11) and the air guide part (12). According to claim 3,
The other end of the first part (111) and the other end of the second part (112) determine the range of the air outlet (16). According to claim 3,
The air inlet 15 is installed on the lower side of the liquid guide body 1, and the liquid guide body 1 is connected to the base part 11 and/or the air guide part 12 and protrudes downward. It is characterized in that it comprises a support portion 13 used to lift the air inlet 15 high.

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