KR102210810B1 - Modularized vaporizer - Google Patents

Abstract

The present invention relates to a vaporizer, and a fuel module room, a heating module room, or a vaporization module room is provided in a main body housing, so that a fuel module, a heating module, or a vaporization module can be easily combined and separated in a drawer type in the main body housing. The heating energy (light, beam, heat) oscillated (irradiated) from the heating member of the heating module evenly heats (irradiates) a specific surface of the fuel or absorbing member, thereby suppressing carbonization of the fuel or the absorbing member.

Description

Modularized vaporizer {Modularized vaporizer}

The present invention relates to a vaporizer that vaporizes fuel, and more particularly, to a vaporizer applied to a smoking cessation aid, an electronic cigarette, a fumigator, etc. that vaporizes a solution (fuel) using a vaporization device for electric energy generated from a battery. .

Vaporizers such as smoking cessation aids, e-cigarettes, and fumigation treatment devices have been developed and used for smoking cessation assistance.

These devices are generally structured as a suction part, a cartridge, and a battery part, and the cartridge includes a solution receiving space and a vaporization device, and the vaporizer contains an absorbing member that holds a solution in contact with the solution receiving space to hold the solution. The absorbing member is wound with a heating line that converts the electrical energy of the battery into thermal energy, and when power is applied to the battery, thermal energy is generated from the heating line, and the solution contained in the absorbing member is vaporized. It is structured to be discharged through.

1 and 2 illustrate a conventional vaporizer.

The configuration of a conventional vaporizer is a structure in which a heating wire is wound around an absorbing member as shown in 101 of FIG. 1 and 102, 103 of FIG. 2, and the material of the heating wire (heating member) is generally provided with a platinum wire, a nickel chromium alloy, or a rare earth element. It is made of iron, chrome and aluminum alloy wire.

The heating wire (heating member) converts the electric energy supplied from the battery into heat energy, and the heating wire (heating member) vaporizes the contacting solution, and a heat-resistant absorbing member containing a solution to bring the solution into contact with the heating wire. (Glass fiber, silica wick, mesh, cotton, Korean paper, etc.) are used.

However, in the conventional technology as described above, carbides (hazardous substances) are generated due to the close contact between the heating wire and the absorbing member or the high-temperature heating wire that is exposed to the air without contacting the solution, and there is a risk due to overmixing of certain components when using liquid fuel. (Especially, accidents due to overmixing of nicotine), structural inconvenience when charging fuel, and a heating wire wrapped around an absorbing member to vaporize the fuel by transferring the fuel to the heating wire, and the fuel is limited to liquid form. There was this.

Korean Patent Registration No. 10-1119356 "Emulation Aerosol Inhaler" Korean Patent Registration No. 10-1375315 "Wick module for electronic cigarette and electronic cigarette equipped with the same"

The present invention was devised to solve the problems of the prior art as described above,

1. Avoiding the close contact between the heating energy supply member, the absorbing member, and the solution, which is a problem of the heating line vaporization method, by evenly inputting heating energy to a certain surface of the fuel (solution) to suppress the generation of carbides, and It eliminates the power structure, breakdown caused by disconnection, and the inconvenience that must be produced by winding the heating wire around the absorbing member.

2. By converting the fuel into a quantified solid (including solidified fuel) form, it prevents excessive mixing of certain components to ensure product stability and relieves the inconvenience of filling.

3. Configure the vaporizer to be easily and conveniently replaced from the outside,

4. Even when liquid fuel is used, it is to provide a modular vaporizer that is configured to conveniently replace the absorbing member that needs to be replaced periodically and the fuel filling is convenient.

In order to achieve the above object, the modular vaporizer according to the present invention

1. In the vaporization method in which the vaporizer is wound around the conventional heating wire on the absorbing member, the light (beam) vaporization method such as laser, infrared, ultraviolet rays, halogen, etc., or the heating energy receiving surface of the fuel (or absorbing member) by fixing the heating wire on a certain surface Is configured in such a way that it can be heated evenly,

2. The fuel is solidified as a quantitative component and stored in the fuel module, while the fuel module is configured to be easily coupled and separated in a drawer type in the fuel module compartment of the housing.

3. A heating module including a heating member is constructed so that the heating module can be easily coupled and separated in a drawer type to the heating module chamber of the housing,

4. Even when using liquid fuel, the fuel module for liquid is configured so that the fuel module for liquid is easily coupled and separated in the fuel module compartment of the housing in a drawer type, and the absorption member module is configured to conveniently drawer type in the absorption member module compartment of the housing. It is configured to be coupled and separated, or the absorption member is configured to be coupled and separated from the fuel module for liquid in a spiral manner.

According to the present invention as described above

1. The heating member, which is a heating energy supply member, irradiates a certain surface of the fuel (or absorbing member) evenly, so that the generation of carbides (hazardous substances) can be suppressed, and a power connection structure is not required for the fuel module receiving heating energy. Therefore, inconveniences such as failure due to disconnection in manufacturing or having to be manufactured by winding a heating wire around an absorbing member are eliminated.

2. Quantified solid fuel is used to prevent excessive mixing of specific components, thus guaranteeing product stability and reliability, and charging fuel by storing solid fuel in the fuel module and combining and separating it into the fuel module compartment of the housing in a drawer type. It becomes easier and more convenient than this,

3. Since the heating module is connected and separated in the heating module room of the housing in a drawer type, it is not only easy and convenient to replace, but also it is possible to replace and apply the heating module according to the property or intensity of heating energy if necessary.

4. Even when using liquid fuel, the liquid fuel is stored in the liquid fuel module, and it is configured to be connected and separated in the fuel module compartment of the housing in a drawer type, making it easier and more convenient to fill the fuel and receive the heating energy after absorbing the liquid fuel. The absorbent member to be vaporized is composed of an absorbent member module, which is coupled to and separated from the absorbent member module chamber of the housing in a drawer type, thereby making it convenient to replace the absorbent member that needs to be replaced periodically.

1 and 2 are vaporization apparatus of an electronic cigarette according to the prior art,
3 is a vaporizer according to a first embodiment of the present invention,
4 is a separate front view of a suction unit, a body unit, a fuel module, and a heating module according to the first embodiment of the present invention;
5 is a configuration diagram of a suction unit, a fuel module, a fuel module chamber, a heating module, and a heating module chamber according to the first embodiment of the present invention;
6 is a configuration diagram b of a suction unit, a fuel module, a fuel module chamber, a heating module, and a heating module chamber according to the first embodiment of the present invention;
Figure 7 is a combined use of a fuel module and a heating module according to the first embodiment of the present invention,
8 is an operation diagram of the vaporizer according to the first embodiment of the present invention;
9 is an application diagram of a functional lens of the heating member according to the first embodiment of the present invention,
10 is a separate configuration diagram of the main body according to the first embodiment of the present invention;
11 is a configuration diagram of a rechargeable liquid fuel module according to a second embodiment of the present invention;
12 is a configuration diagram of a rechargeable liquid fuel module and a fuel module chamber according to a second embodiment of the present invention;
13 is a combined and separated use of a rechargeable liquid fuel module according to a second embodiment of the present invention,
14 is a configuration diagram of a fuel module and a fuel module chamber according to a third embodiment of the present invention;
15 is a configuration diagram of an absorbent member module and an absorbent member module chamber according to a fourth embodiment of the present invention;
16 is an application view of the fixing member according to the first embodiment of the present invention,
17 is a configuration diagram of a fuel module according to a first embodiment of the present invention;
18 is a vaporizer according to a fifth embodiment of the present invention,
FIG. 19 is a diagram showing a combination and separation of a vaporization module according to a fifth embodiment of the present invention;
20 is a partial view of a vaporization module and a vaporization module chamber according to a fifth embodiment of the present invention;
21 is a perspective view 1 of a vaporization module according to a fifth embodiment of the present invention,
22 is a perspective view 2 of a vaporization module according to a fifth embodiment of the present invention,
23 is a cross-sectional view of a vaporization module according to a fifth embodiment of the present invention;
24 is a block diagram of an absorption member module including an airflow hole according to a fifth embodiment of the present invention;
25 is an application diagram of an absorption member module including an airflow hole according to a fifth embodiment of the present invention;
26 is a configuration diagram of a heating module for heating multiple surfaces of an absorbent member according to a fifth embodiment of the present invention;
27 is an exploded view of a fuel module chamber and a fuel module according to a fifth embodiment of the present invention;
28 is a vaporizer according to a sixth embodiment of the present invention,
29 is a diagram showing a combination of a vaporization module, a fuel module, and a heating module according to a sixth embodiment of the present invention;
30 is a cross-sectional view illustrating a configuration of a vaporization module according to a sixth embodiment of the present invention,
31 is an interior view of a vaporization module configuration 2 according to a sixth embodiment of the present invention;
32 is another configuration diagram of a vaporization module according to a sixth embodiment of the present invention;
Figure 33 is a configuration diagram of a plurality of heating energy generation unit contention of the present invention 1,
Figure 34 is a configuration diagram of a plurality of heating energy generating unit contention of the present invention 2,
35 is a diagram illustrating a fuel injection use of a vaporization module coupled to the side of the housing of the main body of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. However, unless otherwise noted below,'heating energy' and'energy' mean'light energy', and'heating' means'irradiation' of light energy.

Embodiment 1

Referring to Figs. 3 and 4, a modular vaporizer 2500 according to a first embodiment of the present invention,

The overall shape is composed of a square shape as shown in Fig. 3, and is composed of a combination of the suction unit 2000 and the body unit 2100 as shown in Fig. 4, and the suction hole 2001 is formed in the suction unit 2000. (2002) is configured to pass through the interior of the vaporized fuel to discharge,

The main body 2100 includes a fuel module chamber 2124, a heating module chamber 2125, and a button 2109, and external air flows into the vaporization space 2109 at a portion of the side of the housing 2123. A hole 2118 is configured.

In addition, the fuel module chamber 2124 and the heating module chamber 2125 are configured to open both sides of the corresponding portion of the housing 2123, and one open surface of the housing 2123 is the fuel module 2200 and the heating module ( The size is configured so that the 2300 is inserted in a drawer type, and the other open surface is configured to be smaller in size than the fuel module 2200 and the heating module 2300 so that the fuel module 2200 and the heating module 2300 are fixed.

In addition, magnets 2114 and 2119 may be installed on each inner surface of the fuel module chamber 2124 and the heating module chamber 2125, and the fuel module 2200 and the heating module in contact with the magnets 2114 and 2119 The surface of the 2300 may be made of a material that is coupled with a magnet, or a magnet is attached to the fuel module chamber 2124 and the heating module chamber 2125 to be magnetically fixed to the fuel module chamber 2124 and the heating module chamber 2125. A magnet may be configured on the joint of the module with the open surface or on the outer surface of the module chamber)

In addition, as shown in FIG. 4, the fuel module 2200 and the heating module 2300 may be configured in a square shape, and the fuel module 2200 may be configured in plural.

Looking at the internal structure or coupling structure of the vaporizer 2500 based on the basic structure as above,

First, FIGS. 5 and 6 are views as viewed from two directions in a state in which the suction unit 2000, the fuel module 2200, and the heating module 2300 are separated.

* The coupling portion 2006 of the suction portion 2000 is configured to be coupled and separated from the coupling groove 2101 of the body portion 2100 in the form of a male or a female, and vaporized fuel is discharged inside the coupling portion 2006 It is hollow so as to be, and an airflow hole 2102 through which the vaporized fuel generated in the vaporization space 2106 is discharged is formed at a portion of the closed surface of the coupling groove 2101.

The fuel module chamber 2124 is opened on both sides of the housing 2123, the first open surface 2116 into which the fuel module 2200 enters and the second open surface open to remove the entered fuel module 2200 Consisting of (2117), in the interior of the fuel module chamber (2124), a concave line (2115) for fixing the fuel module (2200) may be formed in a portion of the side wall, and the fuel module (2200) is fixed. A frame 2130 is formed around the vaporization space 2106 so as to be.

The fuel module 2200 has one side of the same length as the first open side 2116 of the fuel module chamber 2124, and has a hollow square shape with one side open, and the hollow portion is for fuel storage. The space 2201 is configured to store fuel, and the open surface 2203 may be configured to receive heating energy.

Alternatively, one surface of the fuel module 2200 receiving heating energy is composed of a transmission member 2215 through which heating energy passes, and airflow holes a and b (2213, 2214) are formed on both sides, and the above airflow Holes a, b (2213, 2214) and the airflow hole 2218 of the housing are horizontally aligned, and the external air introduced from the airflow hole 2218 of the housing is airflow hole a (2213) of the fuel module 2200 It passes through and enters the interior of the fuel module 2200, is mixed with the fuel 2212 vaporized by the heating energy that has passed through the transmission member 2215, passes through the airflow hole b 2214, and passes through the airflow pipe 2103 of the main body. )-It can be configured to be discharged through the airflow pipe (2003) of the suction unit. In addition, the heating energy transmitting member 2215 is composed of a half mirror, so that the heating energy enters only the inside of the fuel module 2200 and does not come out of the fuel module 2200 to increase the vaporization efficiency. Can (see Fig. 17)

In addition, a convex line 2202 formed of a convex line on the side of the fuel module 2200 is configured and combined with a concave line 2115 formed of a concave line of the fuel module chamber 2124, the fuel module 2200 It can be configured to fix. The combination of concave and convex lines can be used not only for fixing the module and the module chamber, but also for sealing (waterproof) bonding. The fuel module 2200 may be composed of one or more, and the fuel module 2200 composed of a plurality of fuel modules is replaced with another fuel module by changing its position when the fuel of one fuel module is exhausted, and the exhausted fuel module is also It has the advantage of being able to store it.

In addition, instead of the coupling structure of the convex line 2202 and the concave line 2115, a material having an elastic force such as a spring is built into the housing on one side of the fuel module chamber 2124, and the fuel module ( A fixing member 2137 for pressing to fix the 2200 may be provided (the configuration of such a fixing member may be applied equally to a heating module room, an absorbing member module room, etc.). Further, by configuring a button 2135 for adjusting the fixing member 2137, the fixing member 2137 may be adjusted by hand to a height suitable for the number of fuel modules 2200 (see FIG. 16), The shape of the fixing member 2137 is configured to accommodate solid fuel (hereinafter, solid fuel is a concept including natural plants or solidified fuel, meaning fuel that generates water vapor or fine particles when light energy is received). Only fuel may be directly charged, or in order to protect the fixing member button 2135 and the fuel module 2200 from the outside, a protective cover may be additionally configured on the housing 2123 (not shown). The button 2135 may be configured as a push type button as well as a slide type movement method.

The heating module chamber 2125 is opened on both sides of the housing 2123, and the third open surface 2121 into which the heating module 2300 enters and the fourth open surface open to remove the entering heating module 2300. Consisting of (2122), the interior of the heating module room (2125), a concave line (2120) for fixing the heating module (2300) is formed in a portion of the side wall, vaporized to fix the heating module (2300) A frame 2130 is formed around the space 2106, and a ground 2107 is formed on a surface in the direction of the button 2109.

The heating module 2300 has one side in the same square shape as the third open surface 2121 of the heating module chamber 2125, and a heating member 2301 is formed on the surface abutting the vaporization space 2106, and heating A ground 2306 is configured on the opposite side of the member 2301, and when it is connected to the ground 2107 of the heating module room 2125, power is supplied, and a convex line 2303 is formed on the side of the heating module room 2125. ) May be configured to fix the heating module 2300 by combining with the concave line 2120, and the internal module 2302 and the circuit board 2305 of the heating module combined with the heating member 2301 are formed therein. (See FIG. 8) The heating member 2301 may be configured in the form of a lamp in which laser, infrared, ultraviolet, halogen, etc., having the property of light (beam) oscillate, and a heating wire (tube) that emits high heat. ), and the laser, infrared, ultraviolet, halogen lamps or heating wires (tubes) are in the form of points, lines, and partial surfaces on a specific part of the heating module 2300 in single, multiple, or complex It can also be composed of.

Looking at the degree of use of the modular vaporizer 2500 configured as above in FIG. 7, when the fuel module 2200 is coupled, the fuel module 2200 is pushed to the first open surface 2116 by hand as shown by arrow A. Insert it, and when removing the fuel module 2200, simply remove it from the second open surface 2117 by pushing it by hand as shown by arrow B.

Also, in the case of the heating module 2300, when the heating module 2300 is coupled to the heating module chamber 2125, the heating module 2300 is pushed by hand as shown in the arrow C toward the third open surface 2121. When removing the heating module 2300, simply push the heating module 2300 from the fourth open surface 2122 by hand as shown in the arrow D to separate it.

Conventionally, in order to replace the vaporizer, the parts wetted with liquid fuel must be replaced by releasing the double-helical connection between the exterior and the interior of the cartridge, or the cartridge (fuel storage housing) fastened by a helical connection must be released to fill the liquid fuel. However, the drawer-type coupling and separation method of the present invention can be easily replaced by simply pressing a hand from the outside of the housing 2123 by removing the inconvenience of the conventional method.

In addition, when the fuel module 2200 is composed of a plurality of fuel modules 2200, as well as the replacement of defective parts, fuel modules 2200 of various components can be stored in the fuel module compartment 2124 and can be easily selected and applied as needed. In the case of the heating module 2300, there is an advantage that various heating modules 2300 having different heating energy intensity, irradiation area, or shape can be simply combined and separated to be selected.

As described above, looking at the operation diagram of the vaporizer according to the first embodiment of the present invention in FIG. 8, the battery cells 2111 of the main body 2100 are connected by a power module 2108 and an electric wire 2110, and the The power module 2108 is connected to the heating module 2300 and grounds 2306, 2107, and when power is applied by pressing the button 2109 of the power module 2108, the battery cell 2111-the power module 2108 )-Power is supplied to the heating module 2300 to generate (irradiate) heating energy from the heating member 2301.

The power module 2108 may be composed of a button-type module or a module composed of a suction pressure sensor, and in the case of a suction pressure sensor, it flows into the airflow hole 2118 (see FIG. 3). It should be configured such that the external air to pass through the vaporization space 2106 via the suction pressure recognition sensor module. Hereinafter, a button type module will be used as an example.

The heating energy generated in the heating module chamber 2125 evaporates the fuel by irradiating the fuel module open surface 2203 of the fuel module chamber 2124, and the vaporized fuel is discharged into the vaporization space 2106,

When the suction hole 2001 of the suction part 2000 is sucked in, as shown in the arrow of FIG. 8, external air is introduced into the airflow hole 2118 of the main body and mixed with the vaporized fuel discharged to the vaporization space 2106, The vaporized fuel mixed with air is discharged from the vaporization space 2106 to the airflow space 2105, the airflow pipe 2103 of the main body, the airflow pipe 2003 of the suction part, and the suction hole 2001 in that order.

In the present invention, the use of the heating energy can be configured to be limited only to the vaporizer of the vaporizer.

For example, if a sensor set to apply heating by detecting an object within the focal length of vaporization from the heating member is configured inside the heating module 2300 or the housing 2123, heating energy is only when the fuel module 2200 is coupled. Since is oscillated, the device can be protected from physical hazards or high-temperature heating energy due to the heating energy oscillated while the fuel module 2200 is separated, or as shown in FIG. 9, the heating member 2301 By permanently attaching the functional lens 2307 to the front of the light generator 2678, the wavelength is canceled when the heating energy passes a certain distance, thereby preventing misuse of heating energy that can be used other than the vaporizing of the present invention. I can. In addition, the lens 2307 is configured to appropriately transform light energy to irradiate an absorbing member or fuel (the functional lens of FIG. 9 is not limited to a concave lens, and the heating member is a plurality or partial lines of the lamp) In the case of a planar configuration, only the corresponding portion may be configured in a convex or concave shape) or a colored lens may be applied to visually see colorless light energy.

In addition, as shown in FIG. 10, the main body 2100 is formed of a main body a, a main body b, and a main body c divided into a fuel module room, a heating module room, and a battery part, It can be configured to facilitate cleaning, replacement, and repair by configuring the coupling and separation between parts c.

In addition, the method of constituting the solid fuel can be constructed in the same way as the process of tableting or jelly food, which is a known technique, and can be used as a constituent ingredient, flavoring, polyethylene glycol, glycerol, sorbitol, smoking cessation aid, nicotine, Excessive mixing of specific ingredients is prevented by standardizing and quantifying the content of excipients, binders, and coloring agents.

After storing fuel in the fuel module 2200, the open surface 2203 of the fuel module is hygienically packaged and distributed by unit, making it easier to manage and store more hygienic, as well as guaranteeing reliability in the safety of fuel products. can do.

Since such a solid fuel method has a structure that is impossible in the conventional heating wire method, it can be said to be a unique feature of the present invention in which the fuel (or absorbing member) is configured to irradiate heating energy to the fuel (or absorbing member) without contacting the fuel. In addition, it is significant in removing inconveniences such as external contamination caused by leakage caused by the use of conventional liquid fuel.

In addition, in the first embodiment of the present invention, not only hard solid fuel but also soft jelly-type fuel may be used, and since the soft fuel may be produced by a known method, a detailed method will be omitted.

Example 2

The following is a description of a modular vaporizer using liquid fuel.

First, (A) of FIG. 11 is an illustration of a portion receiving heating energy of the liquid fuel module 2200d, and (B) is an illustration of a portion in which liquid is injected.

The liquid fuel module 2200d is configured in a hollow square shape, and liquid fuel is stored in the hollow, and a circular coupling part 2210 formed with a screw thread so that the absorbing member 2204 can be replaced is configured on one side. , A clearance space 2211 is formed on the outer circumferential surface of the coupling part 2210 to facilitate rotation of the absorbing member 2205 (FIG. 11(A)), and an injection hole 2206 capable of filling liquid fuel on the other side. ) Is configured, and an elastic member 2208 having a sealing (waterproof) function may be formed at the rim of the injection hole 2206 (Fig. 11(b)).

In addition, the absorbing member 2204 is a heat-resistant material (glass fiber, cotton wool, Korean paper, natural wood, natural stone, heat-resistant carbon processing material, heat-resistant alloy, etc.) that can absorb liquid and then vaporize it by receiving heating energy. It is formed of a mixture of these), and is fixed to a coupling portion 2209 having a screw wire on a circular rim to enable coupling and separation with the liquid fuel module 2200d, and the absorption member 2204 in the liquid fuel module 2200d The bay can be configured to be replaced periodically.

As shown in Fig. 12, similar to the first embodiment, the liquid fuel module 2200d is also configured to be coupled to the fuel module chamber 2124 in a drawer type, but corresponding to the inlet 2206 of the liquid fuel module 2200d, A semicircular injection port plug 2113 is configured on one side of the fuel module chamber 2124, and when the liquid fuel module 2200d is coupled, the injection port plug 2113 closes the injection port 2206 to thereby the liquid fuel module 2200d. ) The liquid inside is sealed (waterproof).

The injection port plug 2113 is formed of a spherical body, the other side of the spherical body is exposed to the fuel module chamber 2124, and the rest is fixed inside the housing, and the injection port plug is made of an elastic member such as a spring inside the housing. (2113) can be fixed (not shown)

Looking at the degree of use of the second embodiment configured as above in FIG. 13, in order to fill the liquid fuel, the liquid fuel module 2200d from the second open surface 2117 is pushed in the direction of the arrow only enough to expose the injection port 2206. After exposure, fuel (liquid) is charged, and simply pushed back into the fuel module compartment 2124 in a drawer type.

In addition, the injection port 2206 and the injection port plug 2113 for charging the fuel as described above are not limited to the shape of a circular or spherical shape as an example, and the open surface on the fuel module to charge fuel due to the drawer-type coupling structure. Is configured, and may be variously formed as a structure that closes the open surface in the fuel module room, and in case heating energy is oscillated while the liquid fuel module 2200d is removed, the fuel module room 2124 A heating energy absorbing member 2128 may be formed on a surface capable of receiving internal heating energy to prevent danger due to reflection of heating energy.

Embodiment 3

In the present invention, the configuration to separate the fuel module to the housing in a drawer type, as shown in FIG. 14, separating the suction part 2000 and the main body 2100, and the fuel module chamber configured in the main body 2100 It may be configured by inserting the fuel module 2200e into the fifth open surface 2129 of (2124).

In addition, in the coupling and separation of the fuel module 2200e and the fuel module chamber 2124, as in the first embodiment, the coupling can be secured by a magnet or a structure of a concave line and a convex line. The module 2200e does not limit solid or liquid fuel, and a handle 2207 may be configured on one side to facilitate coupling and separation of the fuel module 2200e.

Embodiment 4

A fourth embodiment of the present invention relates to a configuration in which only a fuel chamber and an absorption member including a filling inlet and a cover can be simply replaced.

When the absorbing member 2401, which absorbs and vaporizes fuel, is exposed to heating energy for a long time at a high temperature, the material hardens and the absorption rate of the liquid fuel decreases, or the liquid fuel may leak out due to aging, so it needs to be replaced periodically. Therefore, the absorbent member module 2400 to which the absorbent member 2401 is fixed may be configured to be coupled and separated from the outside in a simple drawer type.

As shown in FIG. 15, the fuel chamber 2139 of the main body 2100 is composed of a transparent member 2133, so that the fuel storage space 2201 is visually confirmed, and a portion of the transparent member 2133 is filled with liquid. A cover 2131 for opening and closing the injection port 2132 and the injection port 2132 is configured inside the sliding door 2138 so that the cover 2131 and the transparent member 2133 are interposed with an elastic body (spring) or a magnetic material. By configuring a (magnet), the cover 2131 may be configured to be open only when charging, while maintaining the inlet 2132 in a closed state.

The position of the injection port 2132 and the cover 2131 is not limited to the transparent member 2133, and may be configured in the housing 2123 around the transparent member by connecting a tube to the fuel chamber 2139, and the same method By forming at least one airflow hole with a smaller hole than the inlet 2132 and configuring a cover, the air pressure inside the liquid fuel module is controlled by opening or closing the hole of the airflow hole with the cover to control the flow of stored fuel. Can be configured to

In addition, one surface of the inside of the fuel chamber 2139 is opened with the vaporization space 2106, and an absorption member module chamber 2134 is formed between the fuel chamber 2139 and the vaporization space 2106, and the fuel In order to adjust the pressure inside the chamber 2139, an airflow hole through the fuel chamber 2139 and the transparent member 2133 or the housing 2123 may be additionally configured (not shown).

In addition, the absorbent member module chamber 2134 is configured to be opened to both sides of the housing 2123, so that the absorbent member module 2400 may be configured to be coupled and separated from the absorbent member module chamber 2134 in a drawer type, and the absorbent member The module 2400 is configured in a square shape, and an absorbing member 2401 is fixed to the central portion.

The absorbent member module 2400 is coupled and separated as a whole as in the fuel module 2200 and the heating module 2300 of the first embodiment, by simply pushing the absorbent member module 2400 into the absorbent member module chamber 2134. Combine or separate.

Embodiment 5

In the fifth embodiment of the present invention, the vaporization module 2602 is coupled and separated in a drawer type in the vaporization module chamber 2611 opened on both sides of the main body 2100 and the housing 2608, and further, an absorbent member module configured independently ( It relates to a configuration in which the 2603 and the heating module 2631 are coupled to and separated from the absorbing member module chamber 2639 and the heating module chamber 2640 opened on both sides of the vaporization module 2602 in a drawer manner.

18 is a view showing a state in which the vaporization module 2602 is coupled to the vaporization module chamber 2611, FIG. 19 is a diagram showing the vaporization module 2602 separated from the vaporization module chamber 2611, and the vaporization module 2602 It is inserted into the sixth open surface 2609 of the vaporization module chamber 2611 in the direction of the arrow A, and the vaporization module 2602 is moved in the direction of the arrow B at the seventh open surface 2610 of the vaporization module chamber 2611. When pushed, it is separated from the vaporization module chamber 2611.

Looking at the detailed configuration of coupling and separating the vaporization module 2602 and the vaporization module chamber 2611 with reference to FIG. 20,

The vaporization module chamber 2611 is opened on both sides of the main body housing 2608 so that the vaporization module 2602 is inserted into a portion of the fuel chamber 2607, and the sixth open side 2609 into which the vaporization module 2602 is inserted. ) To separate the vaporization module 2602 from the seventh side (2610) is composed of a stepped rim, and a waterproof concave line (2612) is formed on the stepped rim, and the vaporization module 2602 is coupled panels a, b (2621, 2635) can be configured to be waterproofly coupled with the convex waterproof convex line 2618 (the combination by the waterproof concave line and the waterproof convex line is used not only for waterproofing but also as a rigid fixing function of the module and the module room),

A fuel transfer hole a 2604 through which fuel in the fuel storage space 2606 moves to the vaporization module room 2611 is formed on an inner side of the vaporization module chamber 2611,

At the stepped portion of the sixth open surface 2615, the center is opened while being connected to the fuel transfer hole a 2604, and a female concave-convex coupling part 2614 is configured, and a part of the edge of the three sides is recessed, and the vaporization module The center is opened on one outer surface of the 2602 and a part of the three-sided rim is configured to be waterproofly coupled with the demand iron coupling part 2620 that is convex,

On the other inner side, while being connected to the airflow pipe 2601 for discharging water vapor to the suction unit 2000, the center is opened and a part of the protruding three-sided rim is concave and a female concave-convex coupling part 2613 is configured, and vaporization A demand iron coupling part 2632 (refer to FIG. 22) configured to discharge water vapor generated from the vaporization module 2602 by opening the center on one outer surface of the module 2602 and convex on the edge of the three sides. It is configured to combine waterproof with,

On the other inner side, a ground for connecting the power of the battery cell to the vaporization module 2602 is configured (not shown).

Looking at the detailed configuration of the vaporization module 2602 with reference to FIGS. 21, 22 and 23,

The vaporization module 2602 is configured in a square shape, and a combination panel a and b (2621, 2635) are formed on the two outer surfaces, and the end of the sixth and seventh surfaces (2615, 2617) of the vaporization module chamber 2611 A waterproof concave line (2612) is formed on the edge of the bonding panels a and b (2621, 2635), and a convex waterproof convex line (2618) is formed on the sixth and seventh sides (2615, 2617). ) And may be configured to be waterproofly coupled, and an airflow hole 2603 may be configured to allow external air to be introduced into the vaporization space 2629 on some of the surfaces of the coupling panels a and b (2621, 2635),

On the other outer side, the center is open and a part of the protruding three-sided rim is convex, a demand-convex coupling part 2620 is configured, and the stepped rim of the sixth open surface 2615 of the vaporization module chamber 2611 It is configured to be waterproofly coupled with the configured arm uneven coupling portion 2614,

On the other outer side, the center is opened and a part of the three-sided rim is formed with a convex demand-and-iron coupling part 2634, which is connected to the airflow pipe 2601 on the inner side of the vaporization module chamber 2611 while the three sides protruding. A part of the rim is configured to be waterproofly coupled with the concave female uneven coupling portion 2613,

Another outer surface is configured with a ground, and may be configured to be connected to the ground configured on the inner surface of the vaporization module chamber 2611.

Inside the vaporization module 2602, a fuel transfer hole b (2619) into which the fuel of the fuel chamber (2607) is introduced, an absorption member module chamber (2639) into which the absorption member module (2603) is inserted, and a vaporization space (2629) , The heating module chamber 2640 into which the heating module 2631 is inserted is configured to be sequentially opened, and an open channel a 2654 between the absorption member module chamber 2639 and the vaporization space 2629, and the An open channel b (2655) is formed between the vaporization space (2629) and the heating module (2631), and a demand iron coupling part (2634) for discharging the generated water vapor is formed in a part of the inner wall of the vaporization space (2629). Is composed.

In addition, the absorption member module chamber 2639 and the heating module chamber 2640 are configured to open both sides of the housing of the vaporization module 2602,

The absorbent member module chamber 2639 has an eighth opening 2622 for inserting the absorbent member module 2630 in a drawer type and a ninth opening 2638 separated by a stepped rim, and the heating module chamber ( The tenth open surface 2628 for inserting the heating module 2631 in the 2640 and the eleventh open surface 2628 for separating the heating module 2631 in a drawer type are formed with a stepped edge.

In addition, looking at the absorption member module 2630 and the heating module 2261, which are coupled to and separated from the vaporization module 2602,

The absorbent member module 2630 is configured in a square shape, and coupling panels c and d (2624, 2636) are formed on the two outer surfaces thereof, so that the eighth and ninth surfaces (2622, 2638) of the absorbent member module chamber 2639 It is waterproofly coupled with the stepped edge of the panel, and a convex waterproof convex line is formed on the edges of the bonding panels c and d (2624, 2636), so that it is waterproofly coupled with the concave waterproof concave lines of the 8th and 9th sides (2622, 2638). It may be configured, and an absorbent member 2623 is inserted inside.

In addition, the absorbing member 2623 is composed of materials such as glass fiber, cotton wool, Korean paper, natural wood, natural stone, heat-resistant carbon processed material, heat-resistant alloy, or a mixture thereof, and absorbs and stores fuel or (2607) can be configured to discharge the fuel in an osmotic structure.

The heating module 2631 is configured in a square shape, and coupling panels e and f (2627, 2632) are formed on the two outer surfaces, and the ends of the tenth and eleventh surfaces (2628, 2637) of the heating module chamber 2640 It is watertightly coupled with the shockproof edge, and a convex waterproof convex line is formed on the edges of the bonding panels e and f (2627, 2632) to be configured to be waterproofly coupled with the concave waterproof concave lines of the 10th and 11th open surfaces (2628, 2637). In addition, a ground 2633 is configured on the other side of the outer surface and connected to a ground formed on the inner side of the vaporization module chamber 2611, and a heating member 2625 is configured inside the heating module 2261.

In addition, the heating member 2625 may be composed of a laser beam lamp or an infrared lamp or an ultraviolet lamp or a halogen lamp or a heating wire (tube) single, multiple or complex, and points, lines, surfaces (or multiple points, It can also be configured in the form of lines, planes).

According to the above configuration, looking at the operation method of the fifth embodiment with reference to FIGS. 18 and 23,

The fuel injected into the fuel inlet 2605 is absorbed by the absorbing member of the absorbing member module 2630 through the fuel moving hole a 2604 of the fuel chamber 2607 and the fuel moving hole b 2619 of the vaporization module 2602. When moving to 2623 and pressing the button 2109 of the main body 2100 to supply power to the heating module 2261, energy (light, beam, heat) from the heating member 2625 is transferred to the absorbing member 2623. The stored fuel is vaporized and vaporized into the vaporization space (2629), and when air is sucked in through the suction unit (2000), air flows into the airflow hole (2603) of the vaporization module (2602) and vaporizes. An air flow pipe 2601 through the open demand-convex coupling part 2632 of the vaporization space 2629 and the dark concave-convex coupling part 2613 of the vaporization module room 2611 by mixing with the vaporized fuel (water vapor) in the space 2629. ) And discharged to the suction unit (2000).

In addition, a drawer-type vaporization module or an absorption member module may be configured so that fuel in the fuel chamber is more smoothly supplied to the absorption member by using the oil input of the air flow passing through the absorption member.

Referring to FIGS. 24 and 25, fuel transfer holes c and d (2672, 2675) through which the fuel in the fuel chamber 2607 moves to the absorbing member 2676 are configured in the absorption member module 2630,

Between the fuel transfer holes c and d (2672, 2675), the fuel chamber (2607) is blocked, the airflow passage is connected to the outer airflow hole (2671), and the surface into which the absorbing member (2676) is inserted is open. Became,

The inner airflow hole 2674 is configured so that external air introduced into the outer airflow hole 2671 flows through the absorbing member 2676,

An absorbent member receiving groove 2673 into which an absorbing member 2676 can be inserted is formed in the open surface portion of the inner airflow hole 2674 and the fuel moving holes c and d (2672, 2675),

In order to fix the absorbent member 2676 inserted in the absorbent member receiving groove 2673, a cover whose part is open so that fuel or water vapor passes may be fitted to the open surface of the absorbent member receiving groove 2673 (Not shown), the outer airflow hole 2671 includes a demand-convex coupling part 2670 in which a part of the protruding three-sided edge is convex, and an airflow hole composed of a dark concave-convex coupling part of the vaporization module 2602 It is configured to be water-resistant (not shown).

Referring to FIG. 25 for the operation of the vaporization module 2602 having the above configuration, the fuel in the fuel chamber 2607 is the fuel movement hole b 2619 of the vaporization module 2602 and the fuel movement hole of the absorption member module 2630 It is absorbed and stored in the absorbing member 2676 inserted in the absorbing member receiving groove 2673 through c, d (2672, 2675),

When air is sucked in from the suction unit 2000, the external air introduced into the outer airflow hole 2671 passes through the inner airflow hole 2674 and passes through the absorption member 2676, as shown in the arrow in FIG. 2629), and due to the flow or oil input of the air that sucks in the absorption member 2676 as above, the fuel in the fuel chamber 2607 or the fuel in the fuel transfer holes c, d (2672, 2675) is Inflow into the absorbing member 2676 adjacent to the inner airflow hole 2674 is activated, and fuel is continuously supplied to the surface of the absorbing member 2676 that receives the heating energy of the heating member 2625.

In addition, in order to further increase the vaporization efficiency, the absorbing member 2623 may be configured to receive heating energy in multiple facets, and referring to FIG. 26 as an embodiment of such a configuration, it is inserted into the vaporization module 2657. The absorbing member module 2658 is configured to be surrounded by the heating module 2659, so that the absorbing member may be configured to receive energy in a larger area on two or three sides, and the absorbing member and the heating member as shown in the arrow direction The air flow path can be configured so that the air flow flows through the air flow path, and when the heating energy is composed of only a single lamp of light (beam), it can be configured to be irradiated on two or three surfaces using a reflector, etc. By switching the positions of the absorbing member module 2658 and the heating module 2659 of, it can be configured to emit energy from both sides of the heating member and receive the absorbing member surrounding it. The configuration may be implemented with two or more modules. (In addition, the present invention may be composed of a plurality of heating members that heat one absorbing member on both sides, and a vaporization module composed of an absorbing member and a heating member is composed of a plurality of On the other hand, as above, when the heating energy is configured to irradiate the absorbing member to multiple surfaces, each surface of the absorbing member can be heated and vaporized independently, or a plurality of heating energy transmitted into the absorbing member It may be configured to reach the vaporization temperature by competing, or may be configured to achieve a stronger vaporization efficiency by additionally competing heating energy. Looking at another embodiment of this configuration with reference to Figs. 33 and 34, as shown in Fig. 33, toward the targeted point T of the absorbing member, the heating energy generating units G1 and G2 of the heating member are configured at an oblique angle. , The energy generated from G1 and G2 crosses and competes at point T, and the heating energy generated from G1 and G2 competes to achieve a heating temperature, or use G2 as an option after using it as the heating energy generated from G1. It can be configured to generate a stronger vaporization power by activating, and, as shown in FIG. 34, a heating energy generating part G2 of the heating member corresponding horizontally to the targeted point T of the absorbing member is configured, and A reflector 2680 is formed in the vicinity of the targeting point T, and a heating energy generator G1 of the heating member corresponding horizontally to the reflector is configured, and the heating energy oscillated at G2 and the reflecting mirror 2680 oscillated at G1 ), the heating energy can compete to achieve the heating temperature, or it can be configured to generate more powerful vaporization power as an option. Further, according to the same principle, the heating energy generating unit G and the reflecting mirror may be composed of two or more, and the contention configuration of the heating generating unit can be applied in all embodiments of the present invention.

In addition, as shown in FIG. 27, the fuel chamber may be composed of a fuel module 2662, and may be configured to be coupled and separated from the 14th and 15th open surfaces 2666 and 2667 that are opened on both sides of the housing. In the configuration of 2662), the center is open at the portions of the fuel injection port 2605 and the fuel transfer hole a 2604, respectively, and a part of the protruding three-sided edge is recessed, the female concave-convex coupling portions 2665, 2668. And, the fuel module 2662 has a central open and a part of the three-sided edge is convexly formed demand-convex coupling portions 2661 and 2663 so as to be waterproofly coupled with the female concave-convex coupling portions 2665 and 2668. I can.

In addition, the fuel transfer hole a (2604) of the housing and the fuel transfer hole b (2619) of the vaporization module are configured in the direction A in FIG. 23, and the conventional fuel transfer holes a and b are formed with a light reflector in a closed structure. , The light energy oscillated from the heating member may be configured to pass through the absorbing member and then be reflected from the reflecting plate to secondly heat the absorbing member. (Hereinafter, the fuel module of the sixth embodiment or the vaporization module to which the absorbing member is attached may also be configured as well. Reflector may be configured)

Embodiment 6

A sixth embodiment of the present invention relates to a configuration in which a fuel chamber is omitted, and fuel is stored in a fuel module and coupled to and separated from the vaporization module in a drawer manner. Such a configuration can be more useful for application of solid fuels such as solids, gels, herbs and tobacco leaves, and when liquid fuels are applied, the fuel module opening to receive heating energy or the absorbing member is coupled to the fuel. Thus, it can be configured to prevent leakage of solids or liquids.

FIG. 28 is a diagram illustrating a state in which the vaporization module 2641 is coupled to the vaporization module chamber 2642 of the main body 2100, and FIG. 29 illustrates the vaporization module 2641 separated from the vaporization module chamber 2642 and the heating module ( 2631) and the fuel module 243 are shown in a state separated from the vaporization module 2451,

The fuel module 2443 and the heating module 2261 are combined with the vaporization module 2461 in the direction of arrow A in FIG. 29 and separated in the direction of arrow B, and the vaporization module 2451 is a vaporization module chamber 2642 ) Is combined in the direction of arrow C, and separated in the direction of arrow D.

The detailed configuration and operation method of the sixth embodiment are the same as those of the absorbent member module 2603, the heating module 2631, and the vaporization module 2602 in the fifth embodiment, but the technical idea is The member module 2603 is constituted by the fuel module 2443, so that the fuel chamber 2607 is omitted so that it is more compact and can be applied to a solid fuel.

Looking at the internal configuration of the square-shaped fuel module 2443 with reference to FIG. 30, a fuel support 2647 in which an elastic member 2646 having an elastic force such as a spring is coupled is formed at an inner part, and the fuel support ( The fuel 2648 is stored in the remaining internal space from 2647, and the outer surface in contact with the channel a 2654 is composed of an open fuel module open surface 2656, so that the heating energy emitted from the heating member 2625 is When the fuel is evaporated through the fuel module opening surface 2656, water vapor is discharged to the vaporization space 2629 and discharged to the suction unit 2000 through the airflow pipe 2601, and the fuel is exhausted by the heating energy. When shortened, the fuel support 2647 is pushed by the elastic force of the elastic member 2646 so that the fuel 2648 moves in the direction of the fuel module opening surface 2656.

In addition, the fuel module open surface 2656 or the portion of the fuel that is in contact with the fuel module open surface 2656 may be configured with an absorbing member 2649, and the absorbing member 2649 absorbs and stores fuel. It is composed of a material, or a material through which heating energy (light, beam, heat) is transmitted while a small hole for discharging water vapor is formed, or the fuel 2648 is not drawn into the vaporization space 2629 in the form of'+'. Can be configured to deter,

In addition, the elastic member 2646 may be omitted by using an adhesion force or an internal vacuum force between the fuel support 2647 and the fuel 2648 and the absorbing member 2649 of the fuel module 2443.

In this embodiment, in which the elastic member 2646 is omitted, the heating energy generated in the heating member 2625 passes through the fuel 2648 stored in the absorbing member 2649 or the absorbing member 2649 to reach the fuel 2648. ), the fuel 2648 inside the fuel module 2642 is kept in close contact with the absorbing member 2649 due to the attraction force generated while evaporating into the vaporization space 2629, and the fuel module 2642 ) Due to the internal vacuum force (or adhesion or attraction), the fuel 2648 and the fuel support 2647 are also kept in close contact. As a result, the fuel support 2647 is reduced by the volume of the fuel consumed due to vaporization. The fuel 2648 is pushed in the direction of the absorbing member 2649 (or the absorbing member pulls the fuel and the fuel pulls the fuel support), so that the fuel 2648 and the absorbing member 2649 maintain a continuous close contact state. It works. In such a configuration, in order for the fuel support 2647 to move more smoothly, an airflow passage may be configured to allow external air to be introduced into a space in which the elastic member 2646 is omitted (not shown).

In addition, as shown in FIG. 31, in the case where the fuel 2648 is attached or fixed to the inner surface of the fuel module 2443, a plurality of airflow holes are formed on the inner partial surface of the fuel module 2443 It can allow outside air to enter. When the length of the fuel 2648 is not exhausted and the length is long, the vaporized water vapor is attracted to the vaporization space 2629 through the airflow hole b 2652 on the inner side, and the fuel 2648 is exhausted and the length is the airflow hole a When the position is shortened by the position of (2651), water vapor is drawn into the vaporization space (2629) by external air flowing into the airflow hole a (2651). (The configuration of such a plurality of airflow holes may be useful in applications where the length of the fuel does not change due to use, or when an airflow passage is formed inside the fuel itself, such as a herb leaf.)

In addition, in Figs. 28 and 29, the vaporization module 2641 is installed in a form in which the longitudinal direction of the main body housing and the longitudinal direction of the vaporization module are vertically coupled, but by modifying the positions of the grounding and airflow holes and airflow pipes, It can also be configured in the form of coupling (refer to (A) of FIG. 32), and a plurality of fuel modules 2443 coupled to and separated from the vaporization module 2641 can be configured, and additional fuel to the fuel module 2443 It may be configured to fill the fuel by configuring the inlet, and in order for the user to recognize the replacement timing of the fuel module 2641, a special fragrance may be included at the end of the fuel 2648, and the fifth and The embodiment 6 may be implemented in a complex configuration (e.g., a fuel support and absorption member combined with an elastic member, and a plurality of airflow holes inside the fuel module).

In addition, in the above embodiments 5 and 6, the vaporization module is omitted, and the absorbing member module (fuel module) and the heating module are separately in the module chamber opened on both sides of the housing as in the above 1 to 4 embodiments. It may be configured to be combined or separated, or the absorption member module (fuel module) or the heating module may be attached to the vaporization module without being separated, so that only the vaporization module may be configured to be combined and separated in the module chamber that is open on both sides of the housing. In the embodiments (including the 1st, 2nd, 3rd, 4th embodiments), the support of the mesh is formed inside the fuel, or the fuel storage space of the fuel module is composed of a plurality of internal partition walls similar to the honeycomb, so that the consumption of fuel during use It can be configured to prevent pulling.

When implementing the first to sixth embodiments of the present invention described above, the following should be noted.

The shape of the vaporizer may be configured such that modules are coupled and separated according to a housing shape such as a cylindrical shape and a triangular shape as well as a square shape, and a part of the module may be configured to protrude to the outside of the module room. The design of the structure of which one side or both sides are open includes not only the front and rear surfaces of the housing having a relatively long length or a wide area, but also the side surfaces of the housing having a relatively short length or a narrow area. For example, in the case of the sixth embodiment, as shown in (B) of FIG. 32, the housing side is coupled in the direction of arrow A and separated in the direction of arrow B. Likewise, looking at the side coupling in the fifth embodiment in which the fuel storage space and the vaporization module are included in the body portion, the vaporization module 2602-1 is pushed in the side A direction of the body portion 2100 to be coupled, The module can be separated by pushing the module in the side B direction, and it can be configured to more conveniently inject fuel into the fuel storage space 2606 by pushing the vaporization module only up to the fuel transfer hole 2604-1. Further, as an example of the side opening method, in the case of the fifth embodiment (refer to FIG. 20), one side is opened by a coupling/separation method of a puah-out module, or three surfaces of the housing portion of the main body into which the module is inserted (front , Rear, side) open and configured to be coupled to the side, but the method of separation may be configured to be separated by pulling in the direction of the open side by hand using the open surface of the front and rear, and the configuration of the fifth and sixth embodiments In (refer to Figs. 18 and 28), the vaporization modules 2602 and 2641 are not separately configured, and the absorbing member module (or fuel module) or the heating module is coupled and separated in a drawer type with both sides of the main body housing open. Includes that it can be configured to

In the coupling between the module and the module room, the sealing or waterproof coupling may include not only liquid but also gas, light, beam, and heat not leaking out, and constitute one or more magnets, or a fixing member having elasticity in the module room or It can be configured to firmly fix the coupling of the module by configuring a fixing clip, and it can be composed of a (male and female) concave-convex combination or a convex and convex combination to prevent the discharge of liquid and gas to the outside. And battery cells also form a power module compartment and a battery cell module compartment in the main body housing so that they are waterproof and separated by a drawer type, and various power modules (click type, electronic type, fingerprint recognition type, etc.)and battery cells of various types and capacities Can be applied to select replacement,

The vaporization module may have a structure in which the absorbing member module (or fuel module) and the heating module are not coupled and separated, or only the absorbing member module (or fuel module) may be coupled and separated, or only the heating module may be coupled and separated,

The fuel module stores fuel inside the hollow, and one side is open or consists of a light (beam) transmitting member (including a half mirror) on one open side, or an absorbing member on one open side. Can be configured,

The rim of the heating member or the heating module or vaporization module may be composed of a heat dissipating material (heating plate), and the heat dissipating material may be composed of multiple structures, and in the case of a multiple structure, the inner structure may be made of a material with high thermal conductivity (e.g. , Graphene sheet or graphite sheet, etc.) to alleviate internal heat generation to protect the heating member,

The heating member may be composed of a (lamp) member that generates light energy such as laser, infrared, ultraviolet rays, halogen, etc., or may be composed of a member that generates microwaves, or may be composed of a heating wire (tube), and the heating member is a heating wire. In the case of (tube), it may be configured in the form of a dense spiral circle or zigzag-shaped net on the surface of a specific part of the heating module, or may be composed of a heating wire printed board, and the heating member and the absorbing member may be very close to each other or in contact with each other. In this configuration, since the fuel can be configured between the surface of the absorbing member and the surface of the heating member, the heating wire is not exposed to air, so that carbonization and harmful gases can be suppressed, and a heating module is used. Thus, the characteristic that can be configured to fix the heating line (pipe), the characteristic that heat can be supplied in proximity to the absorbing member by the heating line (pipe), and the characteristic that the heating line (pipe) is wound around glass fiber as in the prior art The heating line (including the case where the heating line is wound around the absorption member) can be modularized and sealed (waterproof) and separated from the outside of the housing, and the heating line ( The configuration of the tube) is also included in the present invention, and when the heating line (tube) is in close proximity to or in contact with the fuel (or absorption member), the interior of the vaporization module may be formed in the order of the absorption member-the heating member-the vaporization space. There,

The absorbing member (or fuel) may be composed of a color (eg, black) sensitive to light (beam) according to the heating energy properties of the heating member, and a light receiving panel 2679 (see FIG. 9) is placed inside the absorbing member. The light-receiving panel can be configured to receive light energy more effectively by inserting it, and the light-receiving panel is a heat-resistant material, and converts it to vaporization (heat) energy by receiving the light energy that has passed through the absorbing member (in this case, As energy heats the front surface of the light receiving panel evenly, it is contrasted with the conventional heating line vaporization method), and it can be configured to reflect the received light energy and irradiate the absorbing member that was first irradiated first (double heating). In addition, a plurality of holes are perforated on the surface of the light receiving panel to allow fuel to move freely within the absorbing member, and may be configured as a plurality of light receiving panels,

In the heating (light) energy irradiation method, a continuous wave (CW) in which heating (light) energy is continuously irradiated while the power button is pressed, and a pulse wave (PW) irradiated at regular intervals like a pulse (Or a non-continuous wave), a circuit for controlling it may be incorporated in the heating module or the power module, and may be configured to be selected by a selection button provided on the outside of the housing. For example, when applied as a pulse wave, if the main component of the raw material to be vaporized by heating (light) energy is a mixed solution of Propylene Glycol and Vegetable Glycerin, each vaporization temperature is 190 degrees Celsius for Propylene Glycol and 290 degrees Celsius for Vegetable Glycerin. , Since the ignition temperature is 420 degrees Celsius for Propylene Glycol and 390 degrees Celsius for Vegetable Glycerin, a pulse wave is applied to maintain the temperature of the heating (light) energy within 190 to 390 degrees Celsius so as not to approach the ignition temperature When the light) energy approaches 390 degrees, the temperature data and the pulse are interlocked to form an internal circuit so that the pulse is slowed down so that the temperature does not increase any more, and the control circuit to select the intensity or wavelength of the light energy according to the applied fuel. A selection button designed can be configured,

8, 23, 30, a moisture storage space 2677 into which a member for absorbing and storing moisture is inserted, and the air flow pipe 2003 of the suction unit 2000 and the air flow pipes 2103 and 2601 of the fuel chamber 2607 ) Or the residual water vapor flowing down from the vaporization spaces 2106 and 2629 can be absorbed and stored, and the moisture storage space 2677 is configured as a moisture storage module room, and a moisture storage module containing a member for absorbing and storing moisture While configuring, by opening the housing of the module or the main body to both sides, pushing or pulling the module in a drawer type to seal (waterproof) and separate (male and female uneven coupling part or waterproof convex line and waterproof concave wire structure) to the moisture storage module. When moisture is absorbed and stored, it may be configured to prevent a'water retention phenomenon' or a'humidification phenomenon' that occurs when water vapor remaining in the suction part of the conventional vaporizer or the airflow pipe of the cartridge flows back into the vaporizer.

Furthermore, the configuration of the coupling and separation of the housing opened on both sides, which is the basic principle of the present invention, allows the circuit board to be coupled to the module or the housing in a drawer manner, so that the circuit board configured with various functions can be easily replaced as needed. It could be. For example, in the heating module separated in a drawer type from the vaporization module of the fifth embodiment, a circuit board module chamber opened again to both sides of the heating module housing is configured so that a circuit board of another function is inserted as necessary, or a battery It may be configured such that the circuit board is inserted into the housing at the connection portion between the cell and the heating module. For reference, examples of other functions of the circuit board may include differently limited heating temperature ranges, including a smartphone interlocking function (Bluetooth), a guide voice for the visually impaired, or a GPS function. .

In the present invention, the shape of the vaporizer 2500 and the module and the module chamber is not limited to a square shape, and the coupling method between the components may be variously configured such as a spiral type, a magnetic type, etc., and the fuel module chamber, the heating module chamber, The absorbent member module chamber, etc., is formed in an open form on one side of the housing, and the fuel module, heating module, and absorbent member module are pushed in once to connect and fix, and when pressed again, the push-out button is separated and discharged. In case the module is accidentally pressed and discharged, a protective cover can be added to the housing to protect the module, and liquid, gas, or heating energy ( A waterproof member, a closing member, and a heating energy reflective member may be additionally configured to prevent the leakage of light, beam, heat, etc., and the solid fuel (or jelly type fuel) is itself a fuel chamber without the fuel module. Can be used in conjunction with or filled.

In addition, for the safety management of the user, the material of the composition may be made of tempered glass, etc., which has a function of offsetting the wavelength of applied heating energy, and in order to limit the use of heating energy safely only for vaporization of the present invention, Convex, concave, etc.), so that the lens is not separated from the heating member from the initial module manufacturing, so that when the heating energy is out of the vaporization focus, the wavelength gradually expands or decreases to weaken or disappear, and the fuel module is installed in the housing. The grounding circuit can be configured so that power is applied to the heating module only when it is combined, or the heating energy can be generated only when an object is recognized within a certain distance (focal distance) by attaching a sensor inside the heating module or housing.

In addition, the type of heating element applied to the present invention and the range of the wavelength, vibration, and frequency of the heating energy are not limited,

Various modifications are possible within the limit not departing from the scope of the present invention, and the scope of the present invention is limited to the described embodiments and should not be defined, as well as the claims to be described later, as well as the claims and equivalents. Should.

2000: suction part 2001: suction hole
2002: suction body 2003: air flow pipe
2004: Airflow Hall 2005: Combined body
2006: coupling portion 2100: body portion
2101: coupling groove 2102: airflow hole
2103: air flow pipe 2104: air flow hole
2105: airflow space 2106: vaporization space
2107: ground 2108: power module
2109: button 2110: wire
2111: battery cell 2112: charging terminal
2113: injection port plug 2114: magnet
2115: Ohmok-seon 2116: First open area
2117: 2nd open side 2118: Airflow hole
2119: magnet 2120: concave line
2121: 3rd open area 2122: 4th open area
2123: housing 2124: fuel module compartment
2125: heating module room 2126: coupling part
2127: coupling portion 2128: absorbent member
2129: fifth open side 2130: frame
2131: cover 2132: inlet
2133: transparent member 2134: absorption member module room
2135: fixing member button 2136: button moving line
2137: fixing member 2138: sliding door
2139: fuel chamber 2200: fuel module
2200a: fuel module a 2200b: fuel module b
2200c: fuel module c 2200d: liquid fuel module
2200e: fuel module e 2201: fuel storage space
2202: convex line 2203: open surface
2204: absorbent member 2205: injection port plug
2206: inlet 2207: handle
2208: elastic member 2209: coupling portion
2210: coupling part 2211: free space
2212: fuel 2213: airflow hole a
2214: airflow hole b 2215: transmission member
2216: absorption member module 2300: heating module
2301: heating member 2302: internal module
2303: convex wire 2304: electric wire
2305: circuit board 2306: ground
2307: lens 2400: absorption member module
2401: absorbent member 2500: vaporizer
2601: air flow pipe 2602: vaporization module
2602-1: vaporization module
2603: airflow hole 2604: fuel transfer hole a
2604-1: Fuel transfer hole
2605: fuel injection port 2606: fuel storage space
2607: fuel chamber 2608: housing
2609: 6th opening 2610: 7th opening
2611: vaporization module room 2612: waterproof concave line
2613: uneven coupling portion 2614: uneven coupling portion
2615: 6th opening 2617: 7th opening
2618: waterproof convex line 2619: fuel transfer hole b
2620: Soo-cheol coupling part 2621: coupling panel a
2622: eighth opening 2623: absorbent member
2624: bonding panel c 2625: heating member
2627: bonding panel e 2628: 10th open side
2629: vaporization space 2630: absorption member module
2631: heating module 2632: combination panel f
2633: ground 2634: demand-cheol coupling
2635: bonding panel b 2637: 11th open side
2638: 9th open side 2639: Absorbing member module room
2640: heating module room 2641: vaporization module
2642: vaporization module room 2643: fuel module
2644: 13th open 2645: 12th open
2646: elastic member 2647: fuel support
2648: fuel 2649: absorption member
2650: airflow hole 2651: airflow hole a
2652: airflow hole b 2653: coupling panel g
2654: channel a 2655: channel b
2656: fuel module opening 2657: vaporization module
2658: absorption member module 2659: heating module
2660: steam outlet 2661: demand iron coupling
2662: fuel module 2663: demand iron coupling unit
2664: coupling panel 2665: arm uneven coupling portion
2666: 14th direction 2667: 15th direction
2668: arm uneven coupling part 2669: fuel module room
2670: demand iron coupling part 2671: outer airflow hole
2672: fuel moving hole c 2673: absorption member receiving groove
2674: inner airflow hole 2675: fuel transfer hole d
2676: absorbent member 2677: moisture storage space
2678: light generator 2679: light receiving panel
2680: reflector

Claims (2)

A vaporizer comprising a suction unit and a body unit for inhaling steam,

The body part,

A fuel chamber or a fuel module whose one side is open or one side is composed of a light transmitting member or one side is composed of an absorbing member to store fuel and receive light energy,

A heating module configured at a position spaced apart from the fuel chamber or the fuel module and including a heating member for oscillating the light energy;

It corresponds to the space separated from the fuel chamber or the fuel module and the heating module, is formed inside the housing of the main body so that the light energy moves, and water vapor is emitted by the light energy irradiated to the fuel chamber or the fuel module. Vaporization space and

As a passage for moving the steam discharged from the vaporization space to the suction unit, an air flow pipe formed in or around the fuel chamber or the fuel module,

A power module for applying power to the heating module,

Modular vaporizer, characterized in that consisting of a battery cell electrically connected to the power module.
The method of claim 1,
The fuel module is a modular vaporizer, characterized in that coupled to and separated from the main body.

Images