KR20230008608A - Electronic atomization device and atomizer thereof - Google Patents

Abstract

Disclosed in the present invention are an electronic atomization device and an atomizer thereof. The atomizer of the present invention includes a first exhaust passage and an atomization cavity connected thereto, and further includes a guiding member, wherein the guiding member is installed at an end of the first exhaust passage close to the atomizing cavity, and the guiding member can be in contact with the condensate drifting in the first exhaust passage, destroy the surface tension of the condensate through downward pulling force, and prevent or reduce the generation of condensate by being guided to the atomizing cavity, and at the same time, make secondary atomization performed on the flowing condensate to improve the user's experience.

Description

Electronic atomization device and its atomizer {ELECTRONIC ATOMIZATION DEVICE AND ATOMIZER THEREOF}

The present invention relates to the field of electronic atomizing device technology, and particularly relates to an electronic atomizing device and its atomizer.

Today's electronic atomization devices form a matrix into a liquid aerosol that is not completely atomized during heating. During the suctioning process, as the number of suctioned openings increases, some condensed liquid droplets and liquid surfaces are generated on the sidewall of the airflow passage. As the condensate continues to increase, a liquid column is formed, which can easily escape to the nozzle end by subsequent suction. Therefore, because of this, the user's experience of use is deteriorated, and the formed liquid surface may interfere with the output of the aerosol.

The technical problem to be solved in the present invention is to provide an electronic atomizing device and an atomizer thereof by focusing on conventional technical deficiencies.

The technical solution adopted by the present invention to solve the technical problem is as follows. In the atomizer of the present invention, it includes a first exhaust passage and an atomizing cavity connected thereto, and further includes a guiding member;

the guiding member is installed at an end of the first exhaust passage close to the atomizing cavity; The guiding member can contact the condensate drifting in the first exhaust passage, break the surface tension of the condensate through a downward pulling force, and guide the condensate to the atomizing cavity.

Preferably, in the atomizer of the present invention, the guiding member includes at least one guiding vane installed vertically.

Preferably, in the atomizer of the present invention, at least one side of the buckling vane is in close contact with an end of the first exhaust passage close to the atomizing cavity.

Preferably, in the atomizer of the present invention, the flow vane is installed in close contact with the end of the first exhaust passage close to the atomizing cavity in the circumferential direction, and the distance extends in the direction of the central axis of the first exhaust passage. .

Preferably, in the atomizer of the present invention, the flow vane crosses both sides of an end of the first exhaust passage close to the atomizing cavity, and is in close contact with both ends of the first exhaust passage close to the atomizing cavity.

Preferably, in the atomizer of the present invention, the buckling vane is located on the central axis of the first exhaust passage.

Preferably, in the atomizer of the present invention, the guiding member includes a plurality of guiding vanes, and the guiding vanes are spaced apart from each other.

Preferably, in the atomizer of the present invention, the guiding member includes a guiding column.

Preferably, in the atomizer of the present invention, the buckling column is installed at an end hollow point of the first exhaust passage close to the atomizing cavity.

Preferably, in the atomizer of the present invention, the buckling column is located on the central axis of the first exhaust passage.

Preferably, in the atomizer of the present invention, an end face of the baffle column close to the first exhaust passage is collinear with or higher than an end face of the first exhaust passage close to the atomizing cavity.

Preferably, in the atomizer of the present invention, an end of the guiding member close to the first exhaust passage is a pointed end.

Preferably, in the atomizer of the present invention, a plurality of guiding grooves are installed on the outer wall of the guiding member.

Preferably, in the atomizer of the present invention, the atomizer further comprises an atomizing sheet;

The atomizing seat is connected to the first exhaust passage and an exhaust port corresponding thereto is installed, the exhaust port and the atomizing cavity are connected to each other, and the guiding member is installed in the exhaust port.

The present invention further discloses an electronic atomizing device, including a power supply, and further includes any one of the atomizers described above.

The present invention has the following advantageous effects.

The atomizer designed in the present invention includes a guiding member. The guiding member of the present invention is installed at the end of the first exhaust passage close to the atomizing cavity, and the guiding member can contact the drifting condensate in the first exhaust passage, breaking the surface tension of the condensate through a downward pulling force, , It is possible to prevent or reduce the generation of condensate by flowing through to the atomizing cavity, and at the same time to improve the user's experience by performing secondary atomization on the flowing condensate.

The following describes the present invention further by combining drawings and embodiments.
1 is a schematic diagram of the overall structure of an atomizer according to the present invention.
Figure 2 is an exploded view of the atomizer according to the present invention.
3 is a structural schematic diagram of a first baffle vane according to the present invention.
4 is a structural schematic diagram showing a cross section of a first baffle vane according to the present invention.
5 is a schematic structural diagram of a second buckling vane according to the present invention.
6 is a structural schematic diagram showing a cross section of a second baffle vane according to the present invention.
7 is a schematic structural diagram of a baffle according to the present invention.
8 is a structural schematic diagram showing a cross section of a baffle according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail with reference to the drawings in order to more clearly understand the technical features, objects and effects of the present invention.

"Before", "After", "Up", "Bottom", "Left", "Right", "Longitudinal", "Longitudinal", "Landscape", "Vertical", "Horizontal", "Top", " Technical terms indicating directions or positional relationships, such as "bottom", "inside", "outside", "head", "end", etc., are derived from the direction or positional relationship shown in the drawings, are configured and manipulated in a specific direction, It is only intended to conveniently and briefly describe the contents of the present invention, and does not mean that all indicated devices or elements necessarily have a specific direction, so it should not be understood as a limitation on the present invention.

As shown in FIGS. 1 to 2, the atomizer disclosed in the present invention penetrates the base 2, the atomization assembly 4 installed in the base 2, and the base 2 to electrically The electrode assembly (3) connected to the atomization assembly (4) and the atomization seat (5) matching each other, the atomization seat (5) and the housing (6) installed on the outer circumference of the base (2), the housing (6) It includes a bottom cover 1 covering and installed on the lower part and the bottom of the air flow passage. Here, the atomizing assembly 4 includes a porous matrix 41 and a heating element installed in the porous matrix 41, and the atomizing sheet 5 supports the porous matrix 41. For example, the porous matrix 41 is a porous ceramic body, and the heating element is a heating film or filament formed on the porous matrix 41 by thin film printing, thick film printing, or screen printing, but is not limited thereto. . The airflow passage includes an inflow passage, an atomizing cavity 7, and an exhaust passage, and the exhaust passage includes a first exhaust passage 61 opened in the housing 6 and a second exhaust passage opened in the atomizing seat 5 ( 52). The atomizer forms an aerosol by heating and atomizing the substrate generated from the aerosol in a liquid state, and is inhaled into the user's mouth along the airflow passage.

The atomizer further includes a guiding member, and this guiding member is installed at an end of the first exhaust passage 61 close to the atomizing cavity 7. The guiding member can contact the condensate drifting in the first exhaust passage 61, and the guiding member destroys the continuity of the condensate, that is, the surface tension, through a downward pulling force, and guides it to the atomizing cavity 7, The condensate remaining inside the atomizer can be reduced by secondary atomization of the condensate upon inhalation.

Here, the atomizing seat 5 is connected to the bottom of the first exhaust passage 61 and an exhaust port 51 corresponding thereto is further installed, and the exhaust port 51 and the atomizing cavity 7 communicate with each other, A guiding member is installed in the exhaust port (51). In some embodiments, the exhaust port 51 communicates with the atomizing cavity 7 through the second exhaust passage 52.

In some embodiments, in order to further progress the secondary atomization of the condensate, the exhaust port 51 communicates with the porous matrix 41, and the guiding member conducts the condensate into the porous matrix 41 to absorb and absorb the condensate. When it becomes, the condensate is secondarily atomized.

As shown in Figs. 3 and 4, in the first embodiment, the guiding member includes at least one guiding vane 53 installed vertically. At least one side of the buckling vane 53 is in close contact with the end of the first exhaust passage 61 close to the atomizing cavity 7.

In some embodiments, the buckling vane 53 is installed in close contact along the circumferential direction of the end of the first exhaust passage 61 close to the atomization cavity 7, and is installed at a distance in the direction of the central axis of the first exhaust passage 61. is extended Preferably, the guiding member includes at least two guiding vanes 53 installed oppositely.

In some embodiments, the buckling vane 53 crosses both sides of the end of the first exhaust passage 61 close to the atomizing cavity 7, while crossing both sides of the end of the first exhaust passage 61 close to the atomizing cavity 7. In other words, the cross section of the buckling vane 53 and the cross section of the first exhaust passage 61 intersect each other. Preferably, the buckling vane (53) is located on the central axis of the first exhaust passage (61).

Based on the above-described embodiment, the guiding member may include a plurality of guiding vanes 53, and the plurality of guiding vanes 53 are spaced apart, preferably evenly spaced apart. Here, it should be explained that the above-described embodiments can be used in any combination. For example, the buckling vane 53 is installed in close contact along the circumferential direction of the end of the first exhaust passage 61 close to the atomization cavity 7, and has a distance in the direction of the central axis of the first exhaust passage 61. The extended embodiment crosses both sides of the baffle vane 53 and the end of the first exhaust passage 61 close to the atomizing cavity 7, and on both sides of the end of the first exhaust passage 61 close to the atomizing cavity 7 Used in matching with the close-fitting embodiment, the two flow-through vanes are alternately spaced apart.

As shown in Figs. 7 and 8, in the second embodiment, the guiding member includes a guiding column 55. The baffle column 55 is installed at an end hollow point of the first exhaust passage 61 close to the atomization cavity 7.

Here, in order to break the surface tension of the condensate drifting in the first exhaust passage 61 in a timely manner, the end face of the buckling column 55 close to the first exhaust passage 61 is close to the atomizing cavity 7. 1 on the same line as the end face of the exhaust passage 61 or higher than the end face. Preferably, the buckling column 55 is located at the central axis point of the first exhaust passage 61 .

In some other embodiments, the guiding member may include a guiding column 55 and at least one guiding vane 53 extending vertically outward along a circumferential direction of the guiding column 55, and the guiding column 55 ) is installed at the end hollow point of the first exhaust passage 61 close to the atomizing cavity 7, and the flow vane 53 is in close contact with the end of the first exhaust passage 61 close to the atomizing cavity 7, Between the flow vanes 53 are installed in a relative manner.

Based on the above embodiment, in order to more easily break the surface tension of the condensate, the end of the guiding member close to the first exhaust passage 61 is a sharp end, for example, an inclined surface.

In addition, a plurality of guiding grooves are further installed on the outer wall of the guiding member to better guide the condensate to the atomizing cavity 7 after the surface tension of the condensate is destroyed.

The present invention further discloses an electronic atomizing device, and includes a power device and the atomizer of any one of the above-described embodiments.

As shown in Figures 1 to 2, the atomizer of the present invention penetrates the base 2, the atomization assembly 4 installed in the base 2, and the base 2 to be electrically connected to the atomization assembly 4 The electrode assembly (3), the atomizing seat (5) matching the atomizing assembly (4), the atomizing seat (5) and the housing (6) installed on the outer circumference of the base (2), the lower part of the housing (6) It includes a bottom cover 1 covering the side and the bottom and an airflow passage. Here, the atomization assembly 4 includes a porous matrix 41 and a heating element installed on the porous matrix 41, and the atomization sheet 5 supports the porous matrix 41. For example, the porous matrix 41 is a porous ceramic body, and the heating element is a heating film or filament formed on the porous matrix 41 by thin film printing, thick film printing, or screen printing, but is not limited thereto. . The airflow passage includes an inlet passage, an atomizing cavity 7, and an exhaust passage, and the exhaust passage includes a first exhaust passage 61 opened in the housing 6 and a second exhaust passage opened in the atomizing seat 5 ( 52). The atomizer forms an aerosol by heating and atomizing the substrate generated from the aerosol in a liquid state, and is inhaled into the user's mouth along the airflow passage.

The atomizer further includes a guiding member, and this guiding member is installed at an end of the first exhaust passage 61 close to the atomizing cavity 7. The guiding member can contact the condensate drifting in the first exhaust passage 61, and the guiding member destroys the continuity of the condensate, that is, the surface tension, through a downward pulling force, and guides it to the atomizing cavity 7, The condensate remaining inside the atomizer can be reduced by secondary atomization of the condensate upon inhalation.

Here, the atomizing seat 5 is connected to the bottom of the first exhaust passage 61 and an exhaust port 51 corresponding thereto is further installed, and the exhaust port 51 and the atomizing cavity 7 are connected to each other, A guiding member is installed in the exhaust port (51). In some embodiments, the exhaust port 51 communicates with the atomizing cavity 7 through the second exhaust passage 52.

In some embodiments, in order to further progress the secondary atomization of the condensate, the exhaust port 51 communicates with the porous matrix 41, and the guiding member conducts the condensate into the porous matrix 41 to absorb and absorb the condensate. When it becomes, the condensate is secondarily atomized.

As shown in Figs. 3 and 4, in the first embodiment, the guiding member includes at least one guiding vane 53 installed vertically. At least one side of the buckling vane 53 is in close contact with the end of the first exhaust passage 61 close to the atomizing cavity 7.

In some embodiments, the flow-through vane 53 is installed along the circumferential direction of the end of the first exhaust passage 61 close to the atomizing cavity 7, and is installed in the direction of the central axis of the first exhaust passage 61. distance is extended. Preferably, the guiding member includes at least two guiding vanes 53 installed oppositely.

In some embodiments, the flow vane 53 crosses both sides of the end of the first exhaust passage 61 close to the atomizing cavity 7, while crossing both sides of the end of the first exhaust passage 61 close to the atomizing cavity 7. In other words, the cross section of the buckling vane 53 and the cross section of the first exhaust passage 61 intersect each other. Preferably, the buckling vane (53) is located on the central axis of the first exhaust passage (61).

Based on the above-described embodiment, the guiding member may include a plurality of guiding vanes 53, and the plurality of guiding vanes 53 are spaced apart, preferably evenly spaced apart. Here, it should be explained that the above-described embodiments can be used in any combination. For example, the buckling vane 53 is installed in close contact along the circumferential direction of the end of the first exhaust passage 61 close to the atomization cavity 7, and has a distance in the direction of the central axis of the first exhaust passage 61. The extended embodiment crosses both sides of the baffle vane 53 and the end of the first exhaust passage 61 close to the atomizing cavity 7, and on both sides of the end of the first exhaust passage 61 close to the atomizing cavity 7 Used in matching with the close-fitting embodiment, the two flow-through vanes are alternately spaced apart.

As shown in Figs. 7 and 8, in the second embodiment, the guiding member includes a guiding column 55. The baffle column 55 is installed at an end hollow point of the first exhaust passage 61 close to the atomization cavity 7.

Here, in order to break the surface tension of the condensate drifting in the first exhaust passage 61 in a timely manner, the end face of the buckling column 55 close to the first exhaust passage 61 is close to the atomizing cavity 7. 1 on the same line as the end face of the exhaust passage 61 or higher than the end face. Preferably, the buckling column 55 is located at the central axis point of the first exhaust passage 61 .

In some other embodiments, the guiding member may include a guiding column 55 and at least one guiding vane 53 extending vertically outward along a circumferential direction of the guiding column 55, and the guiding column 55 ) is installed at the end hollow point of the first exhaust passage 61 close to the atomizing cavity 7, and the flow vane 53 is in close contact with the end of the first exhaust passage 61 close to the atomizing cavity 7, Between the flow vanes 53 are installed in a relative manner.

Based on the foregoing embodiment, in order to more easily break the surface tension of the condensate, the end of the guiding member close to the first exhaust passage 61 is a sharp end, such as an inclined surface.

In addition, a plurality of guiding grooves are further installed on the outer wall of the guiding member to further guiding the condensate to the atomizing cavity 7 after the surface tension of the condensate is destroyed.

The present invention has the following advantageous effects.

The atomizer designed in the present invention includes a guiding member. The guiding member of the present invention is installed at the end of the first exhaust passage close to the atomizing cavity; The guiding member can contact the condensate drifting in the first exhaust passage, destroy the surface tension of the condensate through a downward pulling force, and flow to the atomizing cavity to prevent or reduce the condensate from being produced, while at the same time reducing the flowing condensate to 2 It is possible to improve the user's experience by proceeding with tea atomization.

The above-described embodiment is only a more specific and detailed description of the preferred embodiment of the present invention, but should not be understood as limiting the scope of the patent of the present invention. A person skilled in the art may freely combine, as well as modify and improve, the above technical features without departing from the idea of the present invention, which shall fall within the protection scope of the present invention. Therefore, all equivalents and modifications to the scope of the claims of the present invention should be included in the scope of the claims of the present invention.

Claims (15)

In the atomizer,
comprising a first exhaust passage 61 and an atomizing cavity 7, and further comprising a guiding member;
the guiding member is installed at an end of the first exhaust passage (61) close to the atomizing cavity (7); The guiding member can contact the condensate drifting in the first exhaust passage 61, destroy the surface tension of the condensate through a downward pulling force, and flow to the atomizing cavity 7. Characterized in that atomizer. According to claim 1,
The atomizer, characterized in that the guiding member includes at least one guiding vane (53) installed vertically. According to claim 2,
The atomizer, characterized in that at least one side of the flow vane (53) is connected to an end of the first exhaust passage (61) close to the atomization cavity (7). According to claim 3,
The buckling vane 53 is installed along the circumferential direction of the end of the first exhaust passage 61 close to the atomizing cavity 7, and has a distance in the direction of the central axis of the first exhaust passage 61. An atomizer characterized in that it is extended. According to claim 3,
While the flow vane 53 crosses both sides of the end of the first exhaust passage 61 close to the atomizing cavity 7, both sides of the end of the first exhaust passage 61 close to the atomizing cavity 7 Atomizer, characterized in that connected to. According to claim 5,
The atomizer, characterized in that the flow vane (53) is located on the central axis of the first exhaust passage (61). According to claim 2,
The atomizer, characterized in that the guiding member includes a plurality of guiding vanes (53), and is spaced apart between the guiding vanes (53). According to claim 1,
The atomizer, characterized in that the guiding member comprises a guiding column (55). According to claim 8,
The atomizer, characterized in that the guiding column (55) is installed at the end hollow point of the first exhaust passage (61) close to the atomizing cavity (7). According to claim 9,
The atomizer, characterized in that the guiding column (55) is located on the central axis of the first exhaust passage (61). According to claim 8,
Characterized in that the end face of the buckling column (55) close to the first exhaust passage (61) is on the same line as or higher than the end face of the first exhaust passage (61) close to the atomizing cavity (7). atomizer to do. According to any one of claims 1 to 11,
The atomizer characterized in that the end of the guiding member close to the first exhaust passage (61) is a sharp end. According to any one of claims 1 to 11,
An atomizer, characterized in that a plurality of guiding grooves are installed on the outer wall of the guiding member. According to any one of claims 1 to 11,
The atomizer further includes an atomization sheet 5;
The atomizing seat 5 is connected to the first exhaust passage 61 and has an exhaust port 51 corresponding thereto, the exhaust port 51 and the atomizing cavity 7 are connected to each other, and the guiding member Atomizer, characterized in that is installed in the exhaust port (51). In the electronic atomization device,
An electronic atomizing device comprising the atomizer of any one of claims 1 to 14.

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