KR20200109782A - Electronic cigarette utilizing electromagnetic induction - Google Patents

Abstract

The present invention relates to an electromagnetic induction type electronic cigarette. The electromagnetic induction type electronic cigarette according to the present invention includes a cylinder having an inlet through which air is introduced and an outlet through which vaporized tobacco components are discharged; A magnet provided inside the cylinder and performing reciprocating motion between the inlet and the outlet; A spring having one end connected to the inlet and the other end connected to the magnet; A magnetic induction coil installed between the inlet and the outlet and generating electric power according to the reciprocating motion of the magnet; A power storage device that stores the power; When the power is applied, the heating element vaporizes the tobacco component; And it characterized in that it comprises a switch on / off in accordance with the reciprocating motion of the magnet.

Description

Electromagnetic induction type electronic cigarette {ELECTRONIC CIGARETTE UTILIZING ELECTROMAGNETIC INDUCTION}

The present invention relates to an electromagnetic induction type electronic cigarette.

Electronic cigarettes that are less harmful to the health of smokers and secondhand smokers have been developed and used due to various harmful effects of smoking.

Electronic cigarettes include a vaporizer that vaporizes a liquid solution and a battery that supplies power to the vaporizer.

In the electronic cigarette, a liquid solution is vaporized by a vaporizer, and the generated gas is sucked into the mouth of the user to make smoking.

In order to vaporize the liquid solution, the heater coil included in the vaporizer needs to be heated, so that the electronic cigarette requires a battery. In addition, since most of the electronic cigarettes employ rechargeable batteries, a battery charging circuit is also required. Accordingly, there is a problem in that the volume of the electronic cigarette increases and the production cost increases.

Patent Document 1: Patent Publication 10-2018-0000347 Patent Document 2: Patent Publication 10-2012-0074596

An object of the present invention is to provide an electromagnetic induction type electronic cigarette capable of sufficiently vaporizing a liquid tobacco component without a battery.

The electromagnetic induction type electronic cigarette according to the present invention includes a cylinder having an inlet through which air is introduced and an outlet through which vaporized tobacco components are discharged; A magnet provided inside the cylinder and performing reciprocating motion between the inlet and the outlet; A spring having one end connected to the inlet and the other end connected to the magnet; A magnetic induction coil installed between the inlet and the outlet and generating electric power according to the reciprocating motion of the magnet; A power storage device that stores the power; When the power is applied, the heating element vaporizes the tobacco component; And it characterized in that it comprises a switch on / off in accordance with the reciprocating motion of the magnet.

It is preferable that the magnet reciprocate within the magnetic induction coil.

The switch and the magnet are coupled by magnetic force of the magnet, and the switch is preferably turned on/off in synchronization with the reciprocating motion of the magnet.

When the magnet moves toward the outlet due to the difference between the pressure inside the cylinder and the pressure outside, the magnetic induction coil generates a current of the first polarity, and the magnet moves toward the inlet port by the tension of the spring. It is preferable that the magnetic induction coil generates a current of a second polarity opposite to the first polarity.

When the magnet moves toward the outlet, the switch is turned on so that the current of the first polarity and the power stored in the power storage element are applied to the heating element, and when the magnet moves toward the inlet, the switch is turned on. It is preferable that it is turned off so that a current of the second polarity is applied to the power storage device.

Preferably, the spring includes a tension spring.

The electromagnetic induction type electronic cigarette according to the present invention further comprises a diode, the magnetic induction coil and the power storage element are connected in series, the heating element and the switch are connected in series, the magnetic induction coil connected in series And the power storage element; The heating element and the switch connected in series; And the diodes are preferably connected in parallel.

It is preferable that the power storage element includes a capacitor.

It is preferable that the magnetic induction coil is wound around the outer surface of the cylinder.

Preferably, the magnet includes a permanent magnet.

It is preferable that the heating element includes a heating wire.

The switch includes a first contact and a second contact; A sliding part that moves according to the reciprocating motion of the magnet to electrically short or disconnect the first contact and the second contact; And a first stopper and a second stopper for limiting a moving range of the sliding unit, wherein the first stopper is configured to slide immediately after the sliding unit is moved toward the inlet and the first and second contacts are electrically disconnected. It is preferable that the movement of the negative is stopped, and the second stopper stops the movement of the sliding part immediately after the sliding part moves toward the outlet and the first and second contacts are electrically shorted.

The electromagnetic induction type electronic cigarette according to the present invention has the following advantages.

(1) The electromagnetic induction type electronic cigarette according to the present invention does not require a battery and a charging circuit because the smoker's suction force and the spring restoring force generate current.

(2) Since a large amount of power can be supplied to the heating element even if the battery is not used, tobacco components can be sufficiently vaporized.

(3) Since the electromagnetic induction type electronic cigarette according to the present invention does not require a battery and a charging circuit, production cost can be reduced.

1 is a cross-sectional view of an electromagnetic induction type electronic cigarette according to the present invention.
2A and 2B are schematic diagrams illustrating the operation of the electromagnetic induction type electronic cigarette according to the present invention.
3A and 3B are circuit diagrams showing a circuit of an electromagnetic induction type electronic cigarette according to the present invention.
4 is a view showing charging and discharging occurring in the electromagnetic induction type electronic cigarette according to the present invention.

Hereinafter, with reference to the accompanying drawings, the electromagnetic induction type electronic cigarette according to the present invention will be described in detail.

1 is a cross-sectional view of an electromagnetic induction type electronic cigarette according to the present invention.

Referring to Figure 1, the electromagnetic induction type electronic cigarette 1000 according to the present invention is a cylinder 100, a magnet 200, a spring 300, a magnetic induction coil 400, a power storage element 500, a heating element 600 and a switch 700. In addition, the electromagnetic induction type electronic cigarette 1000 according to the present invention may further include a filter 130 and a diode 800.

The cylinder 100 includes a hollow pipe. In addition, preferably, the cylinder 100 includes an inlet 110 through which air is introduced and an outlet 120 through which vaporized tobacco components are discharged.

The magnet 200 is installed inside the cylinder 100 and performs a reciprocating motion between the inlet 110 and the outlet 120 in the magnetic induction coil 400. It is preferable that the magnet 200 includes a permanent magnet.

Specifically, the magnet 200 performs a piston motion in the interior of the magnetic induction coil 400 along the longitudinal direction of the cylinder 100 (arrow direction in FIG. 1 ). More specifically, when the smoker starts inhaling through the outlet 120, a difference between the pressure inside the cylinder 100 and the pressure outside occurs, and the magnet 200 moves the outlet 120 due to the difference in pressure. Move towards. In addition, when the smoker stops inhaling the tobacco component, the difference in pressure disappears, and the magnet 200 moves toward the inlet 110 by the tensile force (or restoring force) of the spring 300. That is, the magnet 200 performs a piston motion within the magnetic induction coil 400 according to whether or not the smoker inhales. Electromotive force is generated in the magnetic induction coil 400 by the piston motion (Faraday's law of electromagnetic induction).

The spring 300 has one end connected to the end of the cylinder 100 provided with the inlet 110 and the other end connected to the magnet 200. It is preferable that the spring 300 includes a tension spring. The tensile force of the spring 300 generates a piston motion of the magnet 200 together with the suction force of the smoker.

The magnetic induction coil 400 is installed between the inlet 110 and the outlet 120 and generates electric power according to the reciprocating motion of the magnet 200. Specifically, the magnetic induction coil 400 is wound on the outer surface of the cylinder 100, and when the magnet 200 makes a piston motion therein, it generates an electromotive force according to Faraday's law of electromagnetic induction.

The power storage device 500 stores power generated by the magnetic induction coil 400. The power storage device 500 may include a capacitor.

The heating element 600 vaporizes the tobacco component when power is applied from the magnetic induction coil 400 and/or the power storage element 500. The heating element 600 may include a heating wire (heater coil).

The switch 700 is coupled to the magnet 200 by the magnetic force of the magnet 200 and is turned on/off according to the reciprocating motion of the magnet 200. Specifically, when the magnet 200 reciprocates, the switch 700 performs a reciprocating motion together, and is turned on/off according to the reciprocating motion.

More specifically, the switch 700 includes a sliding unit 710, a first contact point 720a, a second contact point 720b, a first stopper 730a and a second stopper 730b. Specifically, when the sliding unit 710 moves and the first contact 720a is electrically connected to the second contact 720b, the switch 700 is turned on, and the sliding unit 710 moves When the first contact point 720a is electrically disconnected from the second contact point 720b, the switch 700 is turned off. The sliding part 710 performs a reciprocating motion between the first stopper 730a and the second stopper 730b, and when the sliding part 710 moves toward the inlet 110, it is moved by the first stopper 730a. It is stopped, and when moving toward the discharge port 120, the movement is stopped by the second stopper (730b). In particular, the first stopper 730a and the second stopper 730b allow the switch 700 to be quickly turned on/off. Specifically, when the sliding portion 710 moves toward the outlet 120, the second stopper immediately after the first contact point 720a and the second contact point 720b are electrically shorted by the sliding portion 710. Movement of the sliding part 710 is stopped by (730b). That is, even when the moving distance of the magnet 200 is longer than the moving distance of the sliding unit 710, the sliding unit 710 does not move any more by the second stopper 730b. In order for the magnetic induction coil 400 to generate a sufficient amount of electromotive force, the length of the magnetic induction coil 400 must be not less than a certain length, and the moving distance of the magnet 200 moving in the magnetic induction coil 400 It must be over a certain distance. If the second stopper 730b does not exist and the sliding part 710 moves toward the outlet 120 by the distance the magnet 200 moves, the sliding part 710 moves in the opposite direction toward the inlet 110 When moving to, the time it takes for the switch 700 to be turned off increases. That is, the second stopper 730b causes the switch 700 to be turned off immediately after the sliding part 710 starts moving toward the inlet 110. Accordingly, the time it takes for the switch 700 to be turned off is reduced.

Likewise, when the sliding part 710 moves toward the inlet 110, the first stopper 730a immediately after the first contact point 720a and the second contact point 720b are electrically disconnected by the sliding part 710. ), the movement of the sliding part 710 is stopped.

If the first stopper 730a does not exist and the sliding part 710 moves toward the inlet 110 by the distance the magnet 200 moves, the sliding part 710 moves in the opposite direction toward the outlet 120 When moving to, the time it takes for the switch 700 to be turned on increases. That is, the first stopper 730a allows the switch 700 to be turned on immediately after the sliding part 710 starts moving toward the outlet 120. Accordingly, the time it takes for the switch 700 to be turned on is reduced. In addition, by reducing the distance between the first contact point 720a and the second contact point 720b, the time required for on/off may be reduced.

Hereinafter, the operation of the electromagnetic induction type electronic cigarette according to the present invention will be described in detail with reference to FIGS. 2A, 2B, 3A, and 3B.

Figures 2A and 3A are schematic diagrams and circuit diagrams showing the operation of the electromagnetic induction type electronic cigarette according to the present invention when the user inhales the tobacco component, respectively, Figures 2B and 3B are the present invention when the user ends the inhalation, respectively It is a schematic diagram and a circuit diagram showing the operation of the electromagnetic induction type electronic cigarette according to.

Initially, as shown in FIG. 1, the spring 300 is in a fully retracted state. When the user starts to suck, a difference between the pressure inside the cylinder 100 and the pressure outside occurs. Specifically, when the user starts inhaling, the pressure at the outlet 120 is lowered, and air is introduced through the inlet 110, while the magnet 200 moves toward the outlet 120 due to the pressure difference. (In the direction of the dotted arrow in Fig. 2A). When the magnet 200 moves within the magnetic induction coil 400, an electromotive force is generated in the magnetic induction coil 400. As shown in FIGS. 2A and 3A, the magnetic induction coil 400 generates a current of a first polarity, and immediately after the user starts inhaling, the sliding part 710 is discharged as the magnet 200 moves. ) To electrically connect the first contact point 720a and the second contact point 720b. That is, the switch 700 is turned on, and a current of the first polarity generated by the magnetic induction coil 400 is applied to the heating element 600. Immediately after the switch 700 is turned on, the sliding part 710 is stopped moving by the second stopper 730b. The magnet 200 moves toward the outlet 120 until it reaches one end of the magnetic induction coil 400, regardless of whether the sliding part 710 is stopped. This is possible because the magnet 200 and the sliding part 710 are not physically coupled, but are coupled by magnetic force.

When current is applied to the heating element 600, the tobacco component supplied from the tank (not shown) storing the liquid tobacco component is vaporized by the heat of the heating element 600, and the vaporized tobacco component passes through the outlet 120. Is discharged through. Initially, assuming that there is no current generated by the power storage element 500, only the electromotive force generated by the magnetic induction coil 400 is applied to the heating element 600 (in this case, the first suction is indicated by the dashed-dotted line arrow in FIG. 3A). Current only exists).

Next, as shown in Figs. 2B and 3B, when the user ends the suction, the magnet 200 moves toward the inlet 110 by the tensile force (or restoring force) of the spring 300 (Fig. 2B). Dotted arrow direction). When the magnet 200 moves within the magnetic induction coil 400, an electromotive force is generated in the magnetic induction coil 400. 2B and 3B, the magnetic induction coil 400 generates a current of a second polarity opposite to the first polarity, and the sliding part according to the movement of the magnet 200 immediately after the user ends the suction. The 710 moves toward the inlet 110 to electrically disconnect the first contact point 720a and the second contact point 720b. That is, the switch 700 is turned off, and the current of the second polarity generated by the magnetic induction coil 400 is not applied to the heating element 600, but is applied to the power storage element 500 and stored (Fig. 3B. Dashed line arrows). Immediately after the switch 700 is turned off, the sliding part 710 is stopped moving by the first stopper 730a. The magnet 200 moves toward the inlet 110 until it reaches the other end of the magnetic induction coil 400, regardless of whether the sliding part 710 is stopped. This is possible because the magnet 200 and the sliding part 710 are not physically coupled, but are coupled by magnetic force.

When the user starts suction again, the magnet 200 and the sliding unit 710 move in the direction of the dotted arrow, and the switch 700 is turned on, and the current of the first polarity generated by the magnetic induction coil 400 and The current generated by the power storage element 500 is applied to the heating element 600 (dotted arrow and dashed-dotted arrow in FIG. 3A). Immediately after the user starts inhaling, the sliding part 710 moves toward the outlet 120 as the magnet 200 moves to electrically connect the first contact point 720a and the second contact point 720b. That is, the switch 700 is turned on, and the current generated by the magnetic induction coil 400 and the current generated by the power storage element 500 are simultaneously applied to the heating element 600.

Immediately after the switch 700 is turned on, the sliding part 710 is stopped moving by the second stopper 730b. Regardless of whether the sliding part 710 is stopped, the magnet 200 moves toward the outlet 120 until it reaches one end of the magnetic induction coil 400. This is possible because the magnet 200 and the sliding part 710 are not physically coupled, but are coupled by magnetic force.

Since the current generated by the magnetic induction coil 400 and the current generated by the power storage element 500 are simultaneously applied to the heating element 600, the heating element 600 is heated to a higher temperature. That is, as shown in FIG. 3A, since the magnetic induction coil 400 and the storage element 500 are connected in series, twice the electric current is applied to the heating element 600. Therefore, the tobacco component is vaporized more smoothly.

Next, when the user ends the suction, the current generated in the magnetic induction coil 400 by the magnet 200 moving by the tension (or restoring force) of the spring 300 is applied to the power storage element 500 and stored. do. Immediately after the user finishes the suction, the sliding part 710 moves toward the inlet 110 as the magnet 200 moves to electrically disconnect the first contact point 720a and the second contact point 720b. That is, since the switch 700 is turned off, it is not applied to the heating element 600.

Immediately after the switch 700 is turned off, the sliding part 710 is stopped moving by the first stopper 730a. The magnet 200 moves toward the inlet 110 until it reaches the other end of the magnetic induction coil 400, regardless of whether the sliding part 710 is stopped. This is possible because the magnet 200 and the sliding part 710 are not physically coupled, but are coupled by magnetic force.

When the above-described process is repeated by the user's inhalation and termination of the inhalation, a high current (or voltage) is applied to the heating element 600 only when the user inhales, thereby improving vaporization of tobacco components.

3A and 3B, the electromagnetic induction type electronic cigarette according to the present invention includes a diode 800.

The magnetic induction coil 400 and the power storage element 500 are connected in series, and the heating element 600 and the switch 700 are connected in series. A magnetic induction coil 400 and a power storage element 500 connected in series; A heating element 600 and a switch 700 connected in series; And diodes 800 are connected in parallel. Here, the diode 800 allows the current generated by the magnetic induction coil 400 and the current generated by the power storage element 500 to be simultaneously applied to the heating element 600 only during suction.

4 is a view showing charging and discharging occurring in the electromagnetic induction type electronic cigarette according to the present invention.

Referring to FIG. 4, when a user starts inhaling, the switch 700 is immediately turned on by moving the magnet 200 toward the outlet 120, and the current generated by the induction coil 400 is heated. It is applied to the device 600 (generation #1). Initially, since electric charges are not charged in the power storage element 500, only the current (or voltage) generated by the induction coil 400 is applied to the heating element 600.

When the user finishes inhalation, the switch 700 is immediately turned off by moving the magnet 200 toward the inlet 110, and the current generated by the magnetic induction coil 400 is transferred to the power storage element 500. (Charge #1).

When the user starts suction again after a while, the switch 700 is immediately turned on, and the current from the induction coil 400 (generation #2) and the current from the power storage element 500 (discharge #1) are heated. It is applied simultaneously to the device 600. That is, about twice the current (or voltage) of power generation #1 is applied to the heating element 600.

When the user finishes inhalation, the switch 700 is immediately turned off by moving the magnet 200 toward the inlet 110, and the current generated by the magnetic induction coil 400 is transferred to the power storage element 500. (Charge #2).

When the user starts suction again after a while, the switch 700 is immediately turned on, and the current (discharge #2) from the induction coil 400 and the current from the power storage element 500 (generation #3) are heated. It is applied simultaneously to the device 600. That is, about twice the current (or voltage) is applied to the heating element 600 compared to the first suction.

When the user finishes inhalation, the switch 700 is immediately turned off by moving the magnet 200 toward the inlet 110, and the current generated by the magnetic induction coil 400 is transferred to the power storage element 500. (Charge #3).

Then, the above-described process is repeated. That is, the process of applying about twice the current to the heating element 600 and the process of charging the power storage element 500 are repeated according to the user's suction.

1000: electromagnetic induction type electronic cigarette 100: cylinder
130: filter 200: magnet
300: spring 400: magnetic induction coil
500: power storage element 600: heating element
700: switch 710: sliding part
720a: first contact 720b: second contact
730a: first stopper 730b: second stopper
800: diode

Claims (12)

A cylinder having an inlet through which air is introduced and an outlet through which vaporized tobacco components are discharged;
A magnet provided inside the cylinder and performing reciprocating motion between the inlet and the outlet;
A spring having one end connected to the inlet and the other end connected to the magnet;
A magnetic induction coil installed between the inlet and the outlet and generating electric power according to the reciprocating motion of the magnet;
A power storage device that stores the power;
When the power is applied, the heating element vaporizes the tobacco component; And
Switch on/off according to the reciprocating motion of the magnet
Electromagnetic induction type electronic cigarette comprising a. The method of claim 1,
The magnet is an electromagnetic induction type electronic cigarette, characterized in that the reciprocating motion inside the magnetic induction coil. The method of claim 1,
The switch and the magnet are coupled by magnetic force of the magnet, and the switch is turned on/off in synchronization with the reciprocating motion of the magnet. The method of claim 1,
When the magnet moves toward the outlet due to the difference between the pressure inside the cylinder and the pressure outside, the magnetic induction coil generates a current of the first polarity, and the magnet moves toward the inlet port by the tension of the spring. When the magnetic induction coil generates a current of a second polarity opposite to the first polarity electromagnetic induction type electronic cigarette. The method of claim 4,
When the magnet moves toward the outlet, the switch is turned on so that the current of the first polarity and the power stored in the power storage element are applied to the heating element, and when the magnet moves toward the inlet, the switch is turned on. Electromagnetic induction type electronic cigarette, characterized in that it is turned off and the current of the second polarity is applied to the power storage element. The method of claim 1,
The spring is electromagnetic induction type electronic cigarette, characterized in that it comprises a tension spring. The method of claim 1,
Further comprising a diode,
The magnetic induction coil and the power storage element are connected in series,
The heating element and the switch are connected in series,
The magnetic induction coil and the power storage element connected in series; The heating element and the switch connected in series; And the diodes are connected in parallel. The method of claim 1,
The power storage device electromagnetic induction type electronic cigarette comprising a capacitor. The method of claim 1,
The electromagnetic induction type electronic cigarette, characterized in that the magnetic induction coil is wound around the outer surface of the cylinder. The method of claim 1,
The magnet is electromagnetic induction type electronic cigarette, characterized in that it comprises a permanent magnet. The method of claim 1,
The heating element electromagnetic induction type electronic cigarette comprising a heating wire. The method of claim 1,
The switch is
A first contact and a second contact;
A sliding part that moves according to the reciprocating motion of the magnet to electrically short or disconnect the first contact and the second contact;
Including a first stopper and a second stopper limiting the moving range of the sliding part,
The first stopper stops the movement of the sliding part immediately after the sliding part moves toward the inlet and the first contact and the second contact are electrically disconnected, and the second stopper moves the sliding part toward the outlet. Thus, the movement of the sliding unit is stopped immediately after the first contact point and the second contact point are electrically shorted.

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