KR20120080284A - Structure for evaporating nicotine solution in electric cigarette - Google Patents

Abstract

The present invention relates to a heating structure for vaporizing nicotine solution of an e-cigarette, and more specifically an nicotine solution of an e-cigarette capable of vaporizing an amount of nicotine solution supplied from a storage housing together with air introduced from the outside in an e-cigarette. It relates to a heating body structure for vaporization. The heating structure for vaporizing nicotine solution of an electronic cigarette comprising a battery assembly for supplying power, a heating body for vaporizing nicotine solution, and a storage housing for supplying nicotine solution, has an electrode connection terminal formed at both ends and at least one A receiving plate 21, 21a in which the insertion groove 25 is formed and nicotine solution supply means fixed to the insertion grooves 25, 26.

Description

Structure for Evaporating Nicotine Solution in Electric Cigarette

The present invention relates to a heating structure for vaporizing nicotine solution of an e-cigarette, and more specifically an nicotine solution of an e-cigarette capable of vaporizing an amount of nicotine solution supplied from a storage housing together with air introduced from the outside in an e-cigarette. It relates to a heating body structure for vaporization.

Electronic cigarettes are electronic devices made by inhalation by making aerosol or gaseous a solution containing nicotine filled in a replaceable cartridge as an alternative to smoking methods such as cigarettes, cigarettes or pipe tobacco. Such an e-cigarette can satisfy smoking desires in place of ordinary cigarettes and does not contain harmful ingredients such as tar, thereby reducing the harmful effects on the human body caused by cigarettes and at the same time not inducing the indirect damage of smoking. Has Because of this, the electronic cigarette has the advantage that it is possible to smoke indoors and to have the same effect as smoking a cigarette while preventing the damage of cigarettes that cause various diseases.

In general, the e-cigarette is supplied to a battery storage assembly in which a light emitting device such as an LED (LED) is installed while the battery is stored, and is supplied by a power supplied from the battery storage assembly to supply a vaporizing assembly and a vaporizing assembly to vaporize the nicotine solution. And a storage assembly that releases the vaporized nicotine liquid to the outside. The battery assembly may include an electronic circuit board for controlling power supply to the vaporization assembly and driving of the light emitting device, and the vaporization assembly may include a heating device for vaporizing nicotine solution supplied in a predetermined amount by using externally supplied air. It may include. The storage assembly may have a storage container for supplying nicotine liquid to the vaporization assembly and a discharge passage for releasing vaporized nicotine smoke to the outside.

Since the e-cigarette has a structure in which nicotine solution is vaporized together with air to the heating body, the air inlet structure and the heating body structure are important factors for determining the product performance of the e-cigarette. The present invention is to improve the structure of the heating body of the electronic cigarette has the following object.

It is an object of the present invention to provide a heating structure for vaporizing nicotine solution in which the nicotine solution can be constantly supplied.

Another object of the present invention is to provide a heating structure for vaporizing nicotine solution which can prevent leakage of the nicotine solution.

According to a suitable embodiment of the present invention, a heating structure for vaporizing nicotine solution of an electronic cigarette comprising a battery assembly for supplying power, a heating body for vaporizing nicotine solution and a storage housing for supplying nicotine solution, And a receiving plate having an electrode connection terminal and having at least one insertion groove formed therein and a nicotine solution supply means fixed to the insertion groove.

According to another suitable embodiment of the present invention, the receiving plate is a planar heating element.

According to another suitable embodiment of the invention, the receiving plate comprises a nanocarbon heating element.

According to another suitable embodiment of the present invention, a discharge membrane having a discharge gap is attached to the upper or lower surface of the receiving plate.

According to another suitable embodiment of the present invention, a plurality of air inlet holes penetrating the insertion grooves are formed.

The heating structure for vaporizing nicotine solution of the electronic cigarette according to the present invention has the advantage that the manufacturing process can be simplified since it can be produced in units. In addition, the heating structure according to the present invention has the advantage that the nicotine solution can be supplied constantly. In addition, the heating structure according to the present invention has the advantage that the nicotine solution can be prevented from leaking to the outside when smoking is not allowed.

1A, 1B and 1C show an embodiment of an electronic cigarette to which the heating structure of the electronic cigarette according to the present invention can be applied, and an enlarged view of the partial and vaporized supply structure of FIG. 1A, respectively.
2 illustrates an embodiment of a heating body structure according to the present invention.

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.

The heating structure for vaporizing nicotine solution according to the present invention is applied to an electronic cigarette 10 including a battery assembly 11 for supplying power, a heating element for vaporizing nicotine solution, and a storage container for supplying nicotine solution. May be applied to any e-cigarette structure that operates in an electronic manner without being limited thereto.

Hereinafter, the structure of the electronic cigarette to which the heating body structure according to the present invention can be applied will be described first, and the heating body structure will be described in detail.

1A, 1B and 1C, the nicotine solution vaporization structure of the electronic cigarette 10 includes a storage housing 13 containing a nicotine solution; A vaporization unit 14 fixed inside the storage housing 13 and having a vaporization chamber 143; A heating element 133 installed inside the vaporization chamber 143; Supply means for supplying a nicotine solution to the heating body 133; And a discharge tube 144 extending from the vaporization chamber 143 to the outside of the storage housing 13, wherein the nicotine solution is stored inside the storage housing 13 and outside the vaporization chamber 143. Silver may be introduced into the vaporization chamber 143 through the supply means.

The electronic cigarette 10 may include a battery assembly 11, a vaporization assembly and a supply assembly, the vaporization assembly may include a heating body 133, and the supply assembly may include a storage housing 13.

The battery assembly 11 may include an electrical circuit board 111, a battery 112, and a connection chamber 113 that connects another assembly while introducing air from the outside. A light emitting device L such as an LED may be installed on the electronic circuit board 111, and a cover C may be installed at one end of the battery assembly 11 so that light of the light emitting device L may be emitted to the outside. The light emitting device L is not necessarily installed because light is emitted to the outside to increase the visual effect of smoking. The electronic circuit board 111 may be connected to the battery 112 through the connection terminal T, and the opening and closing may be controlled by the switch (S). The opening and closing of the switch S can be controlled by manual inlet or for example by the inflow of air. The opening and closing method of the switch S may be appropriately selected by a method known in the art or by those skilled in the art, and the present invention is not limited thereto.

The connection chamber 113 may be formed at one end of the battery assembly 11. The connection chamber 113 may have a hollow cylindrical shape, and a connection screw surface 116 may be formed at a portion of the circumferential surface and a contact piece 114 may be formed therein. The contact piece 114 may have a cylindrical shape and an air induction path 115 is formed therein so that air introduced through the inlet hole D may be introduced into the induction chamber 12. As shown in FIG. 1A, an empty space is formed between the circumferential surface of the connection chamber 113 and the contact piece 114, and the inlet hole D allows the external air to flow into the connection chamber 113. The circumferential surface of the connection chamber 113 may be formed to penetrate from the outside to the inside, and may be a plurality. The battery assembly 11 may be coupled to the induction chamber 12 using the connection screw surface 116 formed in the connection chamber 113.

The induction chamber 12 may have a hollow cylindrical shape as a whole and may have a shape and a structure corresponding to the connection chamber 113. The connection chamber 12 may have a coupling screw surface 123 extending in a cylindrical shape from the contact ring 121 formed at the front side and coupled to the connection screw surface 116 at a portion of the extension circumferential surface 122. A plurality of guide grooves D1 may be formed in the circumferential surface 122 extending from the contact ring 121 to at least a portion of the coupling screw surface 123 along the length direction of the guide chamber 12. The guide groove D1 may be formed to extend by an appropriate length from the contact ring 121 along the inner surface of the extension circumferential surface 121 to allow external air to enter and the width or extension length is not particularly limited. When the connection chamber 113 and the induction chamber 12 are combined, external air flows through the inlet hole D and flows along the induction groove D1 to the interior of the connection chamber 113 and the induction chamber 12. Can be introduced. In the coupled state, the connection chamber 113 and the induction chamber 12 overlap each other. A connecting piece 124 in contact with the contact piece 114 may be formed on the other side of the induction chamber 12. The connecting piece 124 may have a cylindrical shape having a shape corresponding to the contact piece 114, and an air inflow path 127 penetrated in the longitudinal direction may be formed at the central portion thereof. On the other hand, an insulating ring 126 made of an insulator such as, for example, ceramic or rubber, may be installed on the lower peripheral surface of the connecting piece 124. The insulating ring 126 allows the connecting piece 124 and the outer surface of the induction chamber 12 to be electrically insulated from each other. In the electronic cigarette, wiring for supplying power from the battery 112 to the electronic circuit board 111 and the heating element 133 may be made in various ways. For example, a contact piece 114 made of the same or similar conductive material and a connection connected thereto by making the peripheral surfaces of the connection chamber 113 and the induction chamber 12 a conductive material for supplying power to the heating element 133. It may be electrically insulated from the piece 124. One pole of the battery 112 may be connected to the connection chamber 113 or the induction chamber 12, and the other pole may be connected to the contact piece 114. Then, both ends of the heating body 133 may be connected to the circumferential surface of the induction chamber 12 and the connecting piece 124. And the power supply to the electronic circuit board 111 may be made by using a wire. The power supply method for the electronic circuit board 111 or the heating element 133 may be made in various ways and is not limited to the embodiments shown.

The structure of the connecting piece 124 through which the air flowing through the inflow hole D and flowing along the induction groove D1 may be introduced into the air inflow path 127 is shown in FIGS. 1B and 2B. Is shown.

(A) and (b) of FIG. 1B show a cross-sectional view and a plan view, respectively, in the longitudinal direction of the connecting piece 124. Referring to (a) and (b) of FIG. 1B, an inflow groove G may be formed on a surface where the connecting piece 124 contacts the contact piece 114. The inflow groove G may have a groove shape having a predetermined width across the contact surface of the connecting piece 124 and may pass through the air inflow path 127. The structure of the inflow groove G as described above allows the air existing in the connection chamber 113 or the induction chamber 12 to flow along the inflow groove G to be introduced into the air inflow path 127. .

The air inlet 127 is connected to the interior of the storage housing 13.

The storage housing 13 having a shape corresponding to the induction chamber 12 may include a separation plate 131 contacting one side of the induction chamber 12 and a support having an empty cylindrical shape that extends from the separation plate 131. 132, an air conduit 127a formed inside the support 132, and a heater 133 disposed in front of the support 132. The separating plate 131 physically separates the induction chamber 12 and the storage housing 13. The support 132 extending from the separating plate 131 may be installed to support the supply means of the nicotine solution described below which is inserted into the heating body 133 to supply the nicotine solution to the heating body 133. have. In addition, the support 132 may be connected to one terminal of the heating body 133. As shown in FIG. 1B, one terminal of the heating body 133 may be connected to the support 132, and the other terminal may be connected to the air conduit 127a. An insulating ring 126a may be inserted between the support 132 and the air conduit 127a to electrically separate the support 132 and the air conduit 127a from each other. The air inlet 127 and the air conduit 127a may be integral and the two insulating rings 126, 126a may likewise be made integral as shown in FIG.

Air introduced into the storage housing 13 through the air conduit 127a may be supplied to the heating body 133, and the heating body 133 vaporizes and vaporizes the nicotine solution supplied from the storage housing 13 with the air. The nicotine solution may be discharged to the outside of the storage housing 13. The nicotine solution stored in the storage housing 13 may be delivered to the heating body 133 through the nicotine solution supply means. The nicotine solution supply means may be the fiber aggregate F described below, but is not limited thereto, and various nicotine solution supply means may be used depending on the structure of the heating body 133. In the embodiment illustrated in FIGS. 1A and 1B, the nicotine solution stored in the storage housing 13 has a structure penetrating the inside of the heating body 133 such as a nichrome wire, but the present invention is not limited thereto. The vaporization unit 14 may be coupled to the inside of the storage housing 13.

Figure 1c shows an embodiment of a vaporization unit applied to the electronic cigarette.

Referring to FIG. 1C, the vaporization unit 14 includes a fixed plate 141 coupled to the separating plate 131, a vaporization chamber 142 extending from the fixed plate 141, and a supply passage 143 for supplying nicotine solution. And a discharge tube 144 coupled to one side of the vaporization chamber 142. The fixing plate 141 may have any plate shape that may be firmly coupled to or detachably coupled to the separating plate 131 and may be firmly fixed to the separating plate 131 by, for example, an adhesive. . The vaporization chamber 142 may be a hollow cylinder shape, the heating body 133 is accommodated. The supply passage 143 may have, for example, a shape of a through hole formed in a circumferential surface of the vaporization chamber 142. As shown in FIG. 1C, when the nicotine solution is supplied to the heating body 133 by the fiber assembly F, the supply passage 143 has two through holes formed in the circumferential surface to allow the fiber assembly F to pass therethrough. This can be The nicotine solution stored inside the storage housing 13 and outside the vaporization unit 14 may be supplied to the heating body 133 disposed inside the vaporization unit 14 through the supply passage 143. The nicotine solution supplied to the heating element 133 may be vaporized together with the air introduced through the air conduit 127a and discharged to the outside of the vaporization unit 14 and the storage housing 13 through the discharge tube 144. .

The vaporized nicotine solution exiting the vaporization unit 14 and the storage housing 13 through the discharge tube 144 may be sucked through the suction piece 15, as shown in FIG. 1A. The suction piece 14 may consist of a coupling portion 151 and a discharge portion 152 and may be detachably coupled to the storage housing 13. The engagement structure or shape of the suction piece 14 can be made in any form known in the art, without limitation.

2 illustrates an embodiment of a heating body structure according to the present invention.

Referring to (a) and (b) of FIG. 2, the heating element structure according to the present invention includes accommodation plates 21 and 21a and insertion grooves having electrode connecting terminals formed at both ends and at least one insertion groove 25. Nicotine solution supply means secured to (25, 26).

As shown in FIG. 2A, the receiving plate 21 includes a plurality of insertion grooves 25 having a plate shape and arranged at regular intervals. The receiving plate 21 may have a rectangular shape, but may be any shape known in the art without being limited thereto. The accommodating plate 21 may be a resistive heating element having conductivity, or a resistive heating element may be installed therein. For example, the receiving plate 21 may be a planar heating element such as a carbon planar heating element or a ceramic planar heating element, or may have a form in which a carbon fiber heating element or a nano carbon heating element is installed in the insertion groove 25. On the other hand, the receiving plate 21 may be an insulating material. When the accommodating plate 21 is made of an insulating material, a resistance heating element may be installed in the supply means of the nicotine solution such as the fiber assembly F. For example, the nano carbon heating element may be installed inside the fiber assembly (F).

The nicotine solution supply means may be fixed to the receiving groove 25. As shown in FIG. 2A, when the fiber assembly F becomes a nicotine solution supply means, the fiber assembly F can be fixed to the receiving groove 25. The fiber assembly F may be fixed to the receiving groove 25 in the form of being bound by the binding devices 23 and 23a or in an unbound form. The binding devices 23 and 23a can be annular (indicated by 23) or hollow cylindrical (indicated by 23a). In the case of the cylindrical binding device 23a, the discharge holes 231a may be formed at regular intervals, and the air inlet holes 251 may be formed in the accommodation grooves 25 at regular intervals. The nicotine solution supplied through the nicotine solution supply means may be vaporized and discharged to the outside of the receiving plate 21 by the air introduced through the air inlet hole 251.

The receiving plate 21 may have electrode connection terminals 24a and 24b. If the receiving plate 21 is an insulator and the resistance heating element H, which is a conductor together with the fiber assembly F, is fixed to the receiving groove 25, the electrode connection terminals 24a and 24b may be connected to the resistance heating element H. have.

Discharge membranes 22a and 22b may be attached to upper or lower surfaces of the receiving plate 21. The discharge films 22a and 22b may be made of a material having a predetermined coefficient of thermal expansion and may be, for example, an insulating material such as ceramic or a conductive thin film such as aluminum. When the discharge films 22a and 22b become conductive thin films, each of the discharge films 22a and 22b may be formed in a strip form in order to prevent current flowing to the receiving plate 21 from flowing into the discharge films 22a and 22b. Can be. Each discharge film 22a, 22b made in the form of a strip can be electrically insulated from the receiving plate 21, for example by coating a peripheral surface. As such, the discharge membranes 22a and 22b should be electrically insulated from the receiving plate 21 as needed, and various methods of insulation may be applied. Discharge gaps 221a and 221b arranged at regular intervals may be formed in the discharge films 22a and 22b. The discharge gaps 221a and 221b may be made linear and may be formed to have a gap enough to release air or vaporized nicotine solution when the discharge membranes 22a and 22b are expanded by heat. The discharge gaps 221a and 221b may be formed in a plurality of suitable discharge membranes 22a and 22b and the present invention is not limited by the structure of the discharge membranes 22a and 22b or the structure of the discharge gaps 221a and 221b. Do not.

Referring to FIG. 2B, a receiving groove 26 having upper and lower surfaces open to the receiving plate 21a may be formed. Unlike the embodiment illustrated in FIG. 2A, when the upper and lower sides of the receiving groove 26 are opened, the air inlet hole 251 does not need to be formed separately. Supply holes 27 may be formed on the side surfaces of the receiving plates 21a corresponding to both ends of the respective receiving grooves 26. The supply hole 27 may function to fix the supply means of the nicotine solution such as the fiber aggregate F, and to supply the nicotine solution as needed. If the nicotine solution stored in the storage housing 13 (see FIG. 1A) is supplied to the heating body in a sprayed form, the supply hole 27 has a function for supplying the nicotine solution. The receiving plate 21a shown in FIG. 2B may have the same or similar function and structure as the receiving plate 21 shown in FIG. 2A. The same or similar to the nicotine solution supply means secured to the demand groove 25 as shown in FIG. 2A may be fixed to the receiving groove 26 shown in FIG. F) or the fiber assembly F including the resistance heating element H may be fixed.

The heating structure shown in (a) and (b) of FIG. 2 may be manufactured in units and fixed to the storage housing 13.

The heating structure for vaporizing nicotine solution of the electronic cigarette according to the present invention has the advantage that the manufacturing process can be simplified since it can be produced in units. In addition, the heating structure according to the present invention has the advantage that the nicotine solution can be supplied constantly. In addition, the heating structure according to the present invention has the advantage that the nicotine solution can be prevented from leaking to the outside when smoking is not allowed.

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 12: induction chamber 13: storage housing
14: vaporization unit 15: suction filter
111: electronic circuit board 112: battery 113: connection chamber
114: contact piece 115: air induction furnace 116: connecting screw surface
117: pressure switch
121: contact ring 122: extension peripheral surface 123: coupling screw surface
124: connecting piece 126: insulating ring 127: air inlet
131: separation plate 132: support 127a: air conduit
133: heating element 134: supply piece 126, 126a: insulating ring
127: air inlet 141: fixed plate 142: vaporization chamber
143: supply passage 144: discharge tube
15: suction piece 151: coupling portion 152: suction portion
21, 21a: receiving plate, 25, 26: insertion groove 23, 23a: binding device
251: air inflow hole 24a, 24b: electrode connection terminal
22a, 22b: discharge film 221a, 221b: discharge gap
27: supply hole
C: cover L: light emitting device S: switch H: resistance heating element
D: Inflow hole D1: Induction groove G: Inflow groove

Claims (5)

In the heating structure for evaporating nicotine solution of the electronic cigarette comprising a battery assembly for supplying power, a heating body for vaporizing the nicotine solution and a storage housing for supplying the nicotine solution,
The nicotine solution vaporization of the e-cigarette comprises an accommodating plate 21 and 21a having electrode connecting terminals formed at both ends and at least one insertion groove 25 and nicotine solution supply means fixed to the insertion grooves 25 and 26. Heating body structure. The heating element structure for vaporizing nicotine solution of an electronic cigarette according to claim 1, wherein the receiving plate (21) is a planar heating element. The heating element structure for vaporizing nicotine solution of an electronic cigarette according to claim 1, wherein the receiving plate (21) comprises nanocarbon heating elements. The heating element structure for evaporating nicotine solution of the electronic cigarette according to claim 1, wherein the discharge films 22a and 22b having the discharge gaps 221a and 221b are attached to the upper or lower surface of the receiving plate 21. . The heater structure according to claim 1, wherein a plurality of air inlet holes (251) penetrating the insertion groove (21) are formed.

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