KR101282900B1 - Structure for Keeping Nicotine Solution from Leaking in Electric Cigarette and Electric Cigarette with the Same - Google Patents

Abstract

The present invention relates to a leak prevention structure of the nicotine solution for the electronic cigarette and an electronic cigarette having the same, specifically, the nicotine solution may leak into the air inlet pipe for supplying air that is introduced from the outside and installed inside the vaporization room. The present invention relates to a leakage preventing structure of nicotine solution which can be prevented from being present, and an electronic cigarette having the same. The leak-proof structure of the nicotine solution remaining in the vaporization assembly applied to the electronic cigarette that introduces external air into the heater in which the nicotine solution is vaporized is characterized in that a flow change medium is installed between the air induction furnace for inducing air to the heater and the heater. do.

Description

Structure for Keeping Nicotine Solution from Leaking in Electric Cigarette and Electric Cigarette with the Same}

The present invention relates to a leak prevention structure of the nicotine solution for the electronic cigarette and an electronic cigarette having the same, specifically, the nicotine solution may leak into the air inlet pipe for supplying air that is introduced from the outside and installed inside the vaporization room. The present invention relates to a leakage preventing structure of nicotine solution which can be prevented from being present, and an electronic cigarette having the same.

Electronic cigarettes of various forms are known in the art. For example, Patent Publication No. 2009-0005139 'Aerosol Electronic Cigarette' Patent Publication No. 2009-0018039 The 'emulation aerosol inhaler' operates the sensor by introducing external air, while vaporized nicotine solution is absorbed into the mouth. Disclosed is an electronic cigarette that can be used. Known e-cigarettes have a structure similar to that shown in FIG. 3. Referring to FIG. 3, the electronic cigarette includes a battery assembly 31 in which a battery 311 is provided for supplying power, a housing 321, an air induction path 322 for inducing air introduced from the outside, and a battery 311. Vaporized in the vaporizer 324 and vaporizer 324 which vaporizes the nicotine solution supplied from the supply container 326 by using the heater 323 heated by the electric power supplied from the heater, and the heat transferred from the heater 323. A vaporization assembly 32 consisting of a smoke induction furnace 325 for inducing nicotine smoke, a heating element 323 operated by the operation of a device such as a switch, and an intake passage 341 and a suction passage for inducing nicotine smoke to the mouth ( A suction assembly 34 consisting of an outlet 342 connected to 341. In the known electronic cigarette having the above structure, the outside air flows into the point indicated by the arrow A and flows into the vaporization assembly 32. The vaporized air is led to the smoke induction furnace 325 through the point indicated by arrow B together with the vaporized nicotine solution in the vaporizer 324 and supplied to the intake assembly 34 indicated by arrow C. And nicotine smoke may enter the mouth through the intake assembly 34. In addition, the known electronic cigarette may include a light emitter 33 that can indicate whether or not smoking.

Known e-cigarettes are all supplied to the smoke induction furnace 325 indicated by B together with nicotine solution supplied to the heating element 323 through the air induction furnace 322 and again vaporized as indicated by A. It has a structure. On the other hand, the nicotine solution contained in the supply container 526 may be supplied to the heating element 323 through the vaporizer 324. Alternatively, the nicotine solution is vaporized in the vaporizer 324 by the heat supplied from the heating element 323. In order to supply the nicotine solution from the supply vessel 326 to the vaporizer 324 or from the vaporizer 324 to the heating element 323, a material capable of supplying liquid by capillary action, for example, a fiber assembly, is used. Since the nicotine solution must be continuously supplied to the heating element 323 or the vaporizer 324, the nicotine solution supply material is in a state containing the nicotine solution to a certain degree. As a result, the nicotine solution may flow into the air induction furnace 322 and leak even when smoking is not performed or even when smoking is being performed. The leakage of nicotine solution through the air induction furnace 322 corresponds to a common problem of known electronic cigarettes.

The present invention is to solve the problems with such a known electronic cigarette has the following object.

An object of the present invention is to provide a leakage preventing structure of the nicotine solution for the electronic cigarette that can prevent the nicotine solution from leaking into the air inlet passage for supplying the outside air to the vaporizer.

Another object of the present invention is to provide an electronic cigarette having a structure that can prevent the leakage of nicotine solution to the outside of the vaporization room or heater assembly.

According to a preferred embodiment of the present invention, the leak-proof structure of the nicotine solution remaining in the vaporization assembly applied to the electronic cigarette for introducing the external air into the heater in which the nicotine solution is vaporized is provided between the air induction furnace for inducing air to the heater and the heater. It characterized in that the flow change medium is installed in.

According to another suitable embodiment of the present invention, the flow altering medium is a membrane installed to be able to move up and down in accordance with the inflow of air.

According to another suitable embodiment of the invention, the flow altering medium comprises a medium for blocking the air induction path and a communication hole formed in the medium and connected to the air induction path.

According to another suitable embodiment of the invention, the flow altering medium is a water vapor barrier.

According to another suitable embodiment of the present invention, in an electronic cigarette consisting of a battery assembly, a heater, a vaporization assembly and a suction assembly, the heater is accommodated inside the vaporization assembly, and the outside air is passed through an air induction path that guides the air to the heater. It enters the heater and a flow change medium is installed between the air induction furnace and the heater.

The structure according to the present invention has the advantage that the nicotine solution can be prevented from leaking to the outside to improve the cleanliness of the electronic cigarette. In addition, the electronic cigarette according to the present invention has the advantage that the leakage of the nicotine solution is prevented from malfunctioning and at the same time the external leakage of the smell of the nicotine solution is prevented to increase the smoking satisfaction of the electronic cigarette.

1 illustrates an embodiment of an electronic cigarette to which the leakage preventing structure according to the present invention is applied.
Figure 2a shows an embodiment of a leak proof structure according to the present invention.
Figure 2b shows another embodiment of the leak-proof structure according to the present invention.
Figure 3 schematically shows the structure of a known electronic cigarette.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

1 illustrates an embodiment of an electronic cigarette to which a leak-proof structure according to the present invention is applied.

The leakage preventing structure of the nicotine solution for the electronic cigarette according to the present invention is characterized in that the flow change medium is installed between the air induction furnace and the heater to induce air to the heater.

This will be described in detail below.

Referring to FIG. 1, an electronic cigarette to which a leakage preventing structure according to the present invention may be applied may be an external housing 111, a battery 113 for power supply, an electromagnetic plate 112 installed at a front side, and a connection portion 114. A battery assembly 11 formed; A fastening part 121a coupled to the connection part 114 has a casing 121 formed at the front, a fixing means 122 having an air induction path 124 formed therein, a heater fixing means 128, a heater fixing means 128 Evaporation induction pipe for inducing vaporized nicotine solution in the heater 126 fixed to the heater, the vaporization room (R) in which the heater 126 is accommodated, the storage room (S) in which the nicotine solution is stored, and the vaporization room (R). And a suction assembly 13 coupled to the vaporization assembly 12 consisting of 123 and connected to the vaporization induction tube 123.

The battery 113 may be connected to the associated device by a switch or may be driven for operation of the associated device by a sensor, for example an air sensor. The electromagnetic plate 112 may include light emitting means such as an LED lamp, and whether the light emitting means emits light may be controlled by an operation switch. The operation of the electromagnetic plate 112 may be operated by a switch in the form of a button exposed to the outside or by a sensor. An air inlet gap G may be formed in front of the battery assembly 11 as necessary for operation by the air sensor. The air introduced through the air inlet gap G may enter the vaporization room R through an appropriate path. The connecting portion 114 and the fastening portion 121a may be screwed together and an air inlet hole 116 may be formed in the connecting portion 114. On the other hand, the air connection hole 116a may be formed in the fastening portion 121a, and when the connection portion 114 and the fastening portion 121a are coupled, the air inlet hole 116 and the air connection hole 116a may be connected to each other. Can be. In addition, an induction groove 127 through which air introduced through the air connection hole 116a may flow may be formed along the inner wall surface of the fastening portion 121a. The air inlet hole 116 and the air connection hole 116a may be formed in plural along the circumferential surface of the connection portion 114 and the fastening portion 121a, and the guide groove 127 may be plural in number. The connecting means 115 may be installed in the connecting portion 114. The connecting means 115 may be made of a conductive material while becoming a hollow cylindrical shape. The hollow cylindrical shape of the connecting means 115 is for inducing air introduced through the air inflow gap G, and the conductive material 115 is made of a conductive material to connect one electrode of the battery 113 to the heater 126. It is for. One end of the connecting means 115 and one end of the air induction path 124 may be in contact with each other, a gap for inflow of air may be formed on the surface in contact with each other. External air introduced through the air inlet hole 116 and the air connection hole 116a is introduced into the fastening portion 121a through the induction groove 127. In addition, the connection means 115 may be introduced into the air induction path 124 through a gap formed at a surface where the air induction path 124 is in contact with the connection means 115 and transferred to the heater 126. The circumferential surface of the air induction furnace 124 may be made of a conductive material to have a wiring function for connecting one electrode of the heater 126 and the battery 113. The heater fixing means 128 may be installed to fix the heater 126 such as, for example, nichrome wire. If the heater 126 is a nichrome wire and the nicotine solution is supplied to the heater 126 by the fiber assembly F, both ends of the fiber assembly F may be fixed to the heater fixing means 128. Nicotine solution stored in the storage room (S) can be delivered to the fiber aggregate (F) through the supply passage (P). In the fiber assembly F, the nicotine solution may be delivered to the heater 126 in a capillary phenomenon. The power is transferred from the battery 113 to the heater 126 by the operation of the switch, and thus the nicotine solution is vaporized when the heater 126 is heated. The vaporized nicotine solution may be delivered to the suction assembly 13 through the vaporization induction tube 123 and sucked into the mouth of a person.

The nicotine solution delivered to the heater 126 through the supply passage P will remain in the fiber assembly F and if no smoking occurs, some nicotine solution will enter the heater fixing means 128 or into the vaporization room R. It falls off and flows along the floor. In addition, some nicotine solution may be introduced into the air induction path 124 and leaked to the outside. As described above, the nicotine solution introduced into the air induction furnace 124 may leak the outside while polluting the electronic cigarette and may cause product defects. On the other hand, it may cause malfunction of the electronic device. In order to solve this problem, according to the present invention, a flow change medium 125 is installed between the air induction path 124 and the heater 126. The flow change medium 125 refers to a means for changing the direction of the air flow of the air induction path 124, changing the flow path flowing therein, or changing the flow rate. The flow change medium 125 may be coupled to the air induction furnace 124 or installed above the air induction furnace 124 or may be installed between the air induction furnace 124 and the heater 126 by a separate fixing means. have.

The embodiment shown in FIG. 1 corresponds to an example of an electronic cigarette to which the flow change medium 125 according to the present invention can be applied. The flow change medium 125 according to the present invention may be applied to an electronic cigarette having various structures and is not limited to an electronic cigarette having a suggested structure. In addition, the air induction furnace may be made in various forms and is not necessarily limited to inducing air to the heater 126. The flow altering medium 125 according to the invention can be applied to a conduit for any air induction that can lead air substantially into the interior of the vaporization room R.

Hereinafter, the specific form of such a flow change medium 125 will be described.

2A illustrates an embodiment of a flow change medium 125 in accordance with the present invention.

Referring to (a) of FIG. 2A, the flow change medium 125 may be installed above the air induction path 124 for supplying air to the heater H or the vaporization room. In e-cigarettes, the outside air helps to vaporize the nicotine solution, but on the other hand it is to guide the vaporized nicotine solution into the inhalation assembly. Therefore, the air induction furnace 124 does not necessarily need to be directly connected to the heater H or the vaporization room. Various types of additional induction furnaces may be formed to guide the air of the air induction furnace 124 to the heater H, the vaporization room, or the suction assembly, and the present invention is not limited by the formation of such an induction furnace.

The flow change medium 125 may include a blocking membrane 21 fixed to the air induction path 124 and a moving membrane 22 attached to the blocking membrane 21 to be movable up and down. The blocking membrane 21 may be, for example, a thin film of synthetic resin, plastic or metal material, but may be made of any material that is not permeable to liquids and gases. The blocking membrane 21 may include an attachment surface 211 attached to the circumferential surface of the air induction passage 124 or other fixing means, and a through hole 212 corresponding to the inner diameter of the air induction passage 124. The through hole 212 may be appropriately determined in consideration of the inner diameter of the air induction path 124 and is not particularly limited in size. The blocking film 21 may be fixed to the upper portion of the air induction path 124 by means such as, for example, an adhesive. The moving membrane 22 may be fixed to the blocking membrane 21 to enable vertical movement. As shown in (b) of FIG. 2A, the movable membrane 22 includes a movable surface 221 for blocking the through hole 212, an elastic band 222 extending in a band shape on both sides of the movable surface 221, and elasticity. It may be formed of an attachment strip 223 extending from the strip 222 and attached to the edge of the blocking film 21. The moving surface 221 may be made of a material such as synthetic resin, plastic, or metal, through which liquid and gas are not permeable, and the elastic band 222 may be made of an elastic material. For example, the elastic strip 222 may be made of rubber, polyurethane, or polyester fibers, but is not limited thereto. Since the attachment strip 223 is only for attaching the moving membrane 22 to the edge of the blocking membrane 21, it may be made of any material attachable to the blocking membrane 21, for example, with the elastic band 222. It can be made of the same material.

The air A introduced into the air induction path 124 applies pressure to the moving surface 221 while flowing through the through hole 212, thereby moving the moving surface 221 slightly upward. Air flows laterally along the gap made by the attachment surface 211 and the moving surface 221. In the above air flow structure, the moving surface 221 may advantageously have a larger diameter than the through hole 212.

2A illustrates another embodiment of the flow change medium 125.

Referring to (a) of FIG. 2A, the blocking film 21 may be formed of an attachment surface 211 and a through hole 212, and at the same time, a plurality of fixing portions 213 may be formed at an edge portion thereof. On the other hand, the moving membrane 22 may consist only of the moving surface 221 having a diameter smaller or equal to that of the attachment surface 211. The moving surface 221 may be made of an elastic material and may have an adhesive portion 222a corresponding to the fixing portion 213. The blocking layer 21 and the moving membrane 22 may be coupled by fixing the fixing portion 213 to the adhesive portion 222a. The blocking film 211 may be attached above the air induction path 124. Air introduced through the air induction path 124 may be introduced into the heater H through a gap formed by the blocking membrane 211 and the moving membrane 221.

In the embodiment shown in FIG. 2A, the nicotine solution leaked from the fiber assembly F fixed to the heater H is not introduced into the air induction furnace 124 by the flow change medium 125, and thus the nicotine solution. Leakage can be prevented. If necessary, the nicotine solution accumulated in the heater fixing means can be removed by a suitable method.

Hereinafter, another embodiment of the flow change medium will be described.

2B illustrates another embodiment of a flow change medium according to the present invention.

Referring to FIG. 2B, the flow change medium 23 may include means for changing a direction in which air flowing into the air induction path 124 flows. The flow change medium 23 is formed above the blocking body 232 and the blocking body 232 to block the upper inlet of the air induction path 124 fixed by the fixing means 122 to prevent the inflow of nicotine solution. It may be composed of an inflow preventing ceiling 231 and a communication hole 234. The blocking body 232 has a structure in which air flowing into the air induction furnace 124 in a hollow form can flow therein, and the inflow preventing ceiling 231 is a cone or pyramid that can completely cover the air induction furnace 124. It can be shaped or shaped like a truncated cone or a truncated pyramid. The inflow preventing ceiling 231 may have a hollow shape connected to the inside of the blocking body 232.

In the embodiment illustrated in FIG. 2B, air introduced into the air induction path 124 may be introduced into the blocking body 232 and discharged into the communication hole 234 through the inflow preventing ceiling 231. have. And the discharged air can be delivered to the heater (H).

As shown in FIG. 2B, the communication holes 234 and 235 may be formed on the side of the blocking body 242 or the inflow preventing ceiling 231, and the upper portion of the blocking body 242 is an inflow preventing ceiling ( 231 may extend to the interior. As shown in FIG. 2C, the communication hole 234 may be formed on the bottom surface of the inflow preventing ceiling 242.

In the embodiment shown in FIG. 2B, the air introduced into the air induction path 124 is introduced into the blocking body 232 and discharged to the outside through the communication holes 234 and 235, and is prevented by the inflow preventing ceiling 231. The nicotine solution may be prevented from entering the air induction furnace 124. The flow alteration medium 23 can be made rigid or fixed to the air induction furnace.

Although not shown in FIGS. 2A and 2B, the flow altering medium can be a moisture-permeable fiber. Water-permeable waterproof fiber refers to a fiber which can be made from a polyurethane resin or a poly-tetrafluoroethylene film and which does not permeate water but allows water vapor or air to permeate. Flow altering media of moisture-permeable fibers can be made in the form of a membrane and attached to the top of an air induction furnace. The pore size of the moisture-permeable waterproof fiber is not particularly limited and the thickness may be, for example, 1 to 10 mm, but is not particularly limited.

The structure according to the present invention has the advantage that the nicotine solution can be prevented from leaking to the outside to improve the cleanliness of the electronic cigarette. In addition, the electronic cigarette according to the present invention has the advantage that the leakage of the nicotine solution is prevented from malfunctioning and at the same time the external leakage of the smell of the nicotine solution is prevented to increase the smoking satisfaction of the electronic cigarette.

Although described in detail above with reference to the embodiments of the present invention, those skilled in the art will be able to make various modifications and modifications to the invention without departing from the spirit of the present invention with reference to the embodiments presented. . The invention is not limited by these variations and modifications, but is only limited by the scope of the appended claims.

11: battery assembly 111: outer housing
112: electronic substrate 113: battery
114: connecting portion 115: connecting means 116: air inlet hole
116a: air connection hole 121a: fastening portion
121: casing 122: fixing means
123: vaporization induction pipe 124: air induction furnace
125, 23: flow change medium 126: heater
127: induction groove 128: heater fixing means
13: suction assembly
21: blocking film 211: attachment surface
212: through hole 213: fixed portion
22: moving membrane 221: moving surface
222: elastic band 222a: adhesive portion
223: attachment strip 231: inflow prevention ceiling
232: blocking body 234, 235: communication hole
31: battery assembly 311: battery
32: vaporization assembly 321: housing
322: air induction furnace 323: heater
326: supply container 324: vaporizer
325: smoke induction furnace 33: light emitter
34: suction assembly 341: suction passage
342: outlet
R: Vaporization Room S: Storage Room
G: air inlet gap F: fiber assembly
P: Supply passage H: Heater

Claims (5)

In the leakage preventing structure of the nicotine solution remaining in the vaporization assembly applied to the electronic cigarette for introducing the outside air to the heater to which the nicotine solution is vaporized,
A fiber assembly F for delivering a nicotine solution and a heater H through which the fiber assembly F penetrates therein;
An air induction path 124 installed below the heater H to transfer air introduced from the outside to the heater H; And
A flow change medium 125 coupled to the air induction furnace 124 or installed above the air induction furnace 124,
The flow altering medium 125 prevents the nicotine solution from leaking from the fiber assembly F to the air induction 124 and changes the flow of air introduced from the outside to be transferred to the heater H. Leak-proof structure of the solution. The method of claim 1, the flow change medium 125 is a barrier membrane 21 is fixed to the air induction path 124 and a movable membrane 22 that is movable up and down relative to the barrier membrane 21, the barrier membrane ( 21 is a leakage prevention structure of the nicotine solution, characterized in that consisting of the attachment surface 211 and the through hole 212 corresponding to the inner diameter of the air induction path 124. The nicotine for e-cigarette according to claim 1, wherein the flow alteration medium 125 comprises a medium for blocking the air induction path 124 and communication holes 234 and 235 formed in the medium and connected to the air induction path 124. Leak-proof structure of the solution. delete In the electronic cigarette consisting of a battery assembly, a heater, a vaporization assembly and a suction assembly,
The heater H is accommodated in the vaporization assembly to receive the nicotine solution by the fiber assembly F, and the outside air is supplied to the heater H through an air induction path 124 that guides the air to the heater H. A flow change medium 125 is installed which is introduced and coupled to the air induction furnace 124 or installed above the air induction furnace 124 between the air induction furnace 124 and the heater H,
The flow altering medium 125 prevents the nicotine solution from leaking from the fiber assembly F to the air induction 124 and changes the flow of air introduced from the outside to be transferred to the heater H. Leak-proof structure of the solution.

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