CN104114049A - Atomization control unit and a portable atomizing apparatus having the same - Google Patents

Abstract

A portable atomizing apparatus according to the present invention includes a battery case, an atomizing device, a body case, a control unit, and a suction adjustment. The battery case receives a battery, and the atomizing device includes a heating member electrically connected to the battery for generating heat to atomize a source material. The body case is connected between the battery case and atomizing device. Besides, the control unit is mounted inside the body case, electrically connected to the battery and to the heating member, so that the control unit receives an electrical power from the battery to control the output signal delivered to the heating member. Also the suction adjustment opens or closes an air inlet of the atomizing apparatus so as to adjust the amount of air entering the atomizing apparatus.

Description

Atomization control unit and portable atomization device including the atomization control unit

technical field

The present invention relates to an atomization technology, and in more detail, relates to an atomization control unit for adjusting the atomization of raw materials and a portable atomization device including the atomization control unit.

Background technique

Portable atomizing devices have been developed in a portable manner, and people inhale smoke generated from the above-mentioned portable atomizing devices to satisfy preferences, or as a means to achieve other intended purposes. An example of a portable atomizing device may include an electronic cigarette, which can replace smoking or assist smoking cessation. E-cigarettes have characteristics similar to ordinary cigarettes in terms of the method of use and the effects produced during use, so users can feel the sensation of smoking ordinary cigarettes by inhaling e-cigarettes.

In terms of the purpose of use of the portable atomizing device, there are many factors that determine the preference, in addition to the substance to add the raw material, and the conditions under which the atomizer atomizes the raw material. Even if the same raw material is atomized, the taste, aroma and inhalation feeling experienced by the user during the inhalation process will also change when the portable atomization device atomizes the raw material under different conditions. In this case, the user may replace consumable components such as the nebulizer, the cartridge, and the battery, which may cause an additional cost for the user to use the portable nebulizer.

Moreover, the inhalation time for each user to inhale the portable atomizing device varies from person to person. At this time, if the user continues to inhale for a long time, the heating element in the atomizer will be damaged due to overheating, or the flavor or aroma of the smoke will be damaged due to excessive burning of the liquid raw material in the atomizer.

Contents of the invention

(1) Technical problems to be solved

The technical problem to be solved by the present invention is to provide an atomization control unit that can dynamically adjust atomization conditions and adjust atomization performance corresponding to various source components during the process of inhaling smoke.

Another technical problem to be solved by the present invention is to provide an atomization control unit capable of producing fresh smoke by preventing overheating of the heating element and not deteriorating the flavor or aroma of the liquid material.

Another technical problem to be solved by the present invention is to provide a portable atomization device including the atomization control unit with the above advantages.

(2) Technical solution

The atomization control device of the embodiment of the present invention that solves the above-mentioned technical problems, as a portable atomization device including an atomizer having a heating member for heating raw materials and a battery case for storing batteries, includes an atomization control unit, An atomization control unit for solving the problems of the present invention includes a main body case, a control unit, and an inhalation adjustment unit.

One side of the main body casing is combined with the battery casing, and the other side is combined with the atomizer. The control unit is housed inside the main body casing, is electrically connected to the battery and the heating unit, receives a power supply voltage from the battery, and controls an output signal to the heating unit side. In addition, the suction amount adjusting unit opens or closes an air inflow port leading from the outside to the side of the nebulizer to adjust the amount of air flowing into the side of the nebulizer.

A portable atomizing device for solving another technical problem of the present invention includes a battery case, an atomizer, a main body case, a control unit, and an inhalation volume adjustment unit. The battery casing is used to store the battery, and the atomizer is electrically connected to the battery, and the atomizer includes a heating component for generating heat for atomizing the raw material. The main shell is combined with the battery shell and the atomizer between the battery shell and the atomizer.

In addition, the control unit is housed inside the main body casing, is electrically connected to the battery and the heating unit, receives power from the battery, and controls an output signal to the heating unit side. In addition, the inhalation amount adjusting unit opens or closes an air inflow port leading from the outside to the nebulizer side to adjust the amount of air flowing into the nebulizer side.

The portable atomizing device of the embodiment of the present invention for solving another technical problem includes: an atomizer electrically connected to a battery, the atomizer includes a heating component for generating heat for atomizing raw materials; a control unit , including a detection component capable of identifying the continuous pressing action of the user, during the continuous period of the pressing action of the detection component, output to the heating component an output signal alternately at least once during the heating operation period and the heating stop period, the heating operation period has a first voltage level, There is a second voltage level lower than the first voltage level during heating off.

In some embodiments, the detection component may be a button type or a touch type. In some embodiments, the first voltage level may be defined based on a measured resistance of the heating element. In some embodiments, the second voltage level is preferably 0V. In some embodiments, there may be a heating standby period. The heating standby period means that the output signal is not turned on within a predetermined period of time from the starting point of the user's continuous pressing action. In some embodiments, the heating standby period may have a duration ranging from 0.01 second to 1 second. In some embodiments, the heating working period may have a duration ranging from 0.1 second to 20 seconds, and the heating stop period may have a duration ranging from 0.05 second to 5 seconds.

In some embodiments, a display part is also included, and the display part displays a user setting interface for setting one or both of the heating working period and the heating stop period; the control part uses the detection component as a user input interface, According to the pressing action of the user, the value during the heating operation period and the heating stop period is adjusted.

In some embodiments, when the pressing operation of the detection member stops for a predetermined standby time or longer, the control unit may output an output signal generated based on the subsequent pressing operation of the detection member from the heating standby period. In some embodiments, the output of the output signal may be limited to a preset maximum working time. In some embodiments, the maximum working time is preferably 0.15 seconds to 25 seconds.

In some embodiments, it may also include: a battery case for storing the battery; a main body case, which is combined with the battery case and the atomizer between the battery case and the atomizer; The outside leads to the air inlet on the side of the nebulizer to adjust the amount of air flowing into the side of the nebulizer. In some embodiments, the portable atomizing device can be one of electronic cigarettes, aromatherapy instruments, sterilizers, insecticides, and respirator therapeutic instruments.

(3) Beneficial effects

According to the present invention, the output signal can be adjusted according to the magnitude of the power supply voltage of the battery or the magnitude of the resistance of the heating element, so that the electric power supplied to the heating element side can be kept constant. Therefore, it is possible to solve the problem that the heating part is cut off due to high power consumption, or the amount of smoke in the portable atomizing device decreases as the power drops, or the aroma and taste of the smoke change.

Moreover, according to some embodiments of the present invention, the user can directly control the output signal according to the user's preference. Thus, the smoke condition more suitable for the user's preference can be selected through the operation of the user.

Also, the amount of outside air mixed with the atomized raw material can be easily adjusted by the suction amount adjustment unit. Therefore, the user can easily adjust the amount of smoke by using the inhalation amount adjustment part.

Moreover, the printed circuit board of the control part can not only be fastened to the coupling groove of the main body casing, support the display part and the switch mounted on the printed circuit board, but also directly or indirectly contact with the battery and a plurality of output terminals, and are electrically connected to each other. Therefore, there is an effect that the circuit structure and mechanical assembly of the portable atomizing device can be easily assembled without additional connecting parts or joining parts.

Therefore, it can have the environmental protection characteristic of eliminating harmful substances such as lead, and can produce the effect of saving the production cost due to the simplification of the production process.

In addition, the user can use touch switches such as detection components to drive the portable atomizing device. Therefore, when a portable atomizing device is applied to an electronic cigarette, even if it does not continue to be pressed like an ordinary button, the portable atomizing device can be driven only by holding the main body of the portable atomizing device equipped with a detection component. User convenience can be improved.

Moreover, the heating component is controlled by using the output signal during the heating operation period with the first voltage level and the heating stop period with the second voltage level lower than the first voltage level, thereby preventing the heating component from being heated for a long time and causing Damage to the atomizer and waste of raw materials.

Moreover, the user can adjust the duration of the heating period and the stop period according to the user's inhalation time or inhalation habits, so that the user can choose/adjust the smoke conditions that are more suitable for the user's preference, and can obtain the taste, aroma and inhalation feeling of the changed raw materials .

In addition, setting the maximum operating time of the output signal and the standby time for stopping the pressing operation of the detection member has the advantage of reducing power consumption supplied to the heating member and ultimately increasing battery usage time.

Description of drawings

Fig. 1a is an exploded perspective view of a portable atomizing device according to an embodiment of the present invention.

Fig. 1b is a front view of the portable atomizing device shown in Fig. 1a.

Fig. 2a is a cross-sectional view showing a portion taken along line I-I' of Fig. 1b.

Fig. 2b is an enlarged view showing the intake volume adjustment unit shown in Fig. 1a.

Fig. 2c is a diagram showing the operation of the intake volume regulator shown in Fig. 2b.

Fig. 3 is a cross-sectional view showing a portion taken along line II-II' of Fig. 2c.

4a and 4b are enlarged views showing information displayed on the display unit shown in FIG. 1a.

Fig. 5 is a block diagram of the portable atomizing device shown in Fig. 2a.

Fig. 6 is a timing chart for explaining output signals having a heating operation period and a heating stop period.

Fig. 7 is a timing chart for explaining an output signal for setting a maximum operation time.

FIG. 8 is a timing chart for explaining output signals for setting a standby time.

Detailed ways

The portable atomizing device of the present invention comprises: a battery casing, used for storing batteries; an atomizer, electrically connected to the battery, and the atomizer includes heating components for generating heat for atomizing raw materials; a main body casing, connected to the battery The shell and the atomizer are combined with the battery shell and the atomizer; the control part is stored inside the main body shell, electrically connected to the battery and the heating component, and receives power from the battery to control the output to the heating component side. an output signal; and an inhalation volume adjustment unit that opens or closes an air inflow port leading from the outside to the nebulizer side to adjust the volume of air flowing into the nebulizer side.

Moreover, another portable atomizing device of the present invention includes: an atomizer including a heating component connected to a battery for generating heat to atomize the raw material; a control unit including a detection component capable of recognizing the user’s continuous pressing action , during the continuous period of the pressing action of the detection part, output to the heating part an output signal alternately at least once during the heating operation period and the heating stop period, the heating operation period has a first voltage level, and the heating stop period has a voltage level lower than the first voltage level the second voltage level.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The embodiments of the present invention are provided for more complete description to those skilled in the art, the following embodiments can be modified in many different ways, and the scope of the present invention is not limited to the following embodiments. On the contrary, these embodiments make the present disclosure more substantial and complete, and are used to more completely convey the idea of the present invention to those skilled in the art.

Also, the thickness or size of each layer in the drawings is exaggerated for convenience and clarity of description, and the same reference numerals in the drawings refer to the same elements. The term "and/or" used in this specification includes any one of the listed corresponding items and all combinations of more than one.

The terms used in this specification are used to describe specific embodiments, and are not intended to limit the present invention. In this specification, a singular form may include a plural form as long as it is not distinguished by a clearly specified term. And, when used in this specification, "comprise" and/or "comprising" are used to specifically refer to shapes, numbers, steps, actions, components, elements and/or combinations thereof. Exists and does not preclude the presence or addition of more than one other shape, number, act, component, element and/or combination.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings that briefly show ideal embodiments of the present invention. In the drawings, for example, the size and shape of components have been exaggerated for convenience and clarity of illustration, and when actually embodied, various modifications of the illustrated shapes are contemplated. Thus, embodiments of the invention should not be construed as limited to the specific shapes of regions illustrated in this specification.

Fig. 1a is an exploded view of a portable atomizing device 200 according to an embodiment of the present invention, and Fig. 1b is a front view of the portable atomizing device 200 shown in Fig. 1a.

Referring to Fig. 1a and Fig. 1b, the portable atomizing device 200 is used to atomize raw materials to generate smoke, and allow users to inhale the smoke, thereby satisfying people's preferences or achieving predetermined purposes such as treatment. For example, like an electronic cigarette, the portable atomizing device 200 can be used to replace the inhalation of ordinary cigarettes. In this case, the above-mentioned raw material may be a liquid material containing nicotine. However, the portable atomizing device 200 of the present invention is not limited to the embodiment of the electronic cigarette. For example, the portable atomizing device 200 can be applied to a smoking cessation aid device that atomizes a liquid material that does not contain nicotine to generate smoke, and can also be applied to a health aid device that contains ingredients beneficial to health such as vanilla extract. atomization of raw materials. Moreover, substances that have pharmacologically active effects on respiratory diseases such as bronchitis and pneumonia, such as raw materials containing Ventolin or Pulmicort, can also be atomized and inhaled by people, thereby using the portable atomizing device 200 for therapeutic purposes . These examples are only for illustration, not for limiting the present invention, and it is obvious that the application of the portable atomizing device 200 can vary according to the composition of the above-mentioned raw materials.

The portable atomizing device 200 includes a battery case 150, a battery cap 190, an atomizer 50, an inhalation mouthpiece 10 and an atomization control unit ACU. The battery case 150 has a hollow shape with a hollow inside, and can store the battery BT. In some embodiments, the inside of the battery casing 150 can have a structure that communicates with the main body casing 110 of the atomization control unit ACU, so that the exposed electrode of the battery BT, such as the anode, can directly connect with the electrode of the atomization control unit ACU. The plates are in contact and electrically connected. In this case, the other electrode of the battery BT, such as the cathode, can be in contact with the battery case 150, and can be connected with the atomization control unit ACU by fastening between the main body case 110 of the atomization control unit ACU and the battery case 150. Electrical connections are made to form a circuit. But this is just an example, and the battery BT can be concealed in the battery case 150 . In some embodiments, one end of the battery housing 150 may be covered by a battery cap 190 .

In some embodiments, the parts where the battery case 150 , the battery cap 190 and the main body case 110 are fastened to each other can be screwed together. Thus, the user can easily separate the battery case 150 or the battery cap 190 from the portable atomizing device 200, and can also easily combine the battery case 150 or the battery cap 190 with the portable atomizing device 200, so that it is easy to periodically replace the batteries that have reached the end of their life. battery bt.

Moreover, the inhalation mouthpiece 10 is suitable for electronic cigarettes or respirator therapy, and can be omitted when applied to aroma generators, sterilizers or insecticides, or replaced by nozzles in order to promote the dispersion of smoke in the air .

The atomization control unit ACU includes a control unit ( FIG. 2 a 100 ) and an inhalation volume adjustment unit 80 , and the control unit has a main body case 110 and a display unit 90 . The main body case 110 has a hollow shape, and its interior communicates with the battery case 150, and stores a control unit inside (FIG. 2a100). 1a and 1b show the display unit 90 among the components of the control unit, and the display unit 90 is exposed to the outside through an opening formed in a part of the main body case 110 . The display unit 90 may include self-luminous or non-self-luminous display units such as liquid crystals, organic light-emitting devices, and vacuum fluorescent displays.

The inhalation volume adjustment part 80 is combined with one end of the main body casing 110, and opens or closes the air inflow port communicating with the outside and the atomizer 50 when the main body casing 110 is combined with the atomizer 50 (Fig. 2a H2) . Therefore, the amount of mist atomized in the nebulizer 50 and discharged to the outside through the inhalation mouthpiece 10 changes according to the state of opening or closing the air inflow port of the inhalation volume adjusting part 80 .

In some embodiments, the intake volume adjustment part 80 may have a ring shape combined with the end of the main body casing 110 formed with the above-mentioned air inlet. In this case, the intake amount adjusting part 80 is movable from the end of the main body housing 110 in the longitudinal direction, and opens or closes the air inflow port while passing over the air inflow port. The structure and function of the suction volume adjustment unit 80 will be described in detail later with reference to FIGS. 2b and 2c.

The atomizer 50 is coupled to the atomization control unit ACU so as to face the battery case 150 via the atomization control unit ACU. The atomizer 50 is electrically connected to the battery BT through the atomization control unit ACU, and atomizes raw materials to generate smoke. In some embodiments, the atomizer 50 can be combined with the atomization control unit ACU through the joint part 40 formed with threads on the inner surface, so that the user can easily separate the atomizer 50 from the portable atomization device 200 or replace the atomizer. device 50. Therefore, the user can easily replace the nebulizer 50 when the performance of the nebulizer 50 deteriorates due to long-term use.

The inhalation mouthpiece 10 is combined with one end of the nebulizer 50 so that the smoke generated in the nebulizer 50 can be discharged to the outside through the inhalation mouthpiece 10 . That is, the user can inhale the mist generated in the nebulizer 50 through the mouthpiece 10 . In some embodiments, the inhalation mouthpiece 10 can be formed of durable materials such as metal materials, and can be formed of flexible materials such as silicone polymer resin, so as to improve the user's sense of use. Hereinafter, the internal structure of the portable atomizing device 200 will be described in more detail with reference to FIG. 2a and FIG. 2b.

Fig. 2a is a cross-sectional view of a part taken along I and I' of Fig. 1b, Fig. 2b is an enlarged view of the suction volume adjustment part 80 shown in Fig. 1a, and Fig. 2c is used to illustrate the suction volume adjustment shown in Fig. 2b A diagram of the function of section 80. The structural elements shown have the same reference numerals as the structural elements of the preceding figures, as long as there is no contradiction. You can refer to the above description.

Referring to FIGS. 2 a to 2 c , the main housing 110 of the atomization control unit ACU includes an output terminal 88 and a first connecting portion 115 . The output terminal 88 is provided at the part where the main body casing 110 is connected to the atomizer 50 , and supplies power to the atomizer 50 through the control unit 100 .

The first connecting portion 115 extends from one end of the main body case 110 toward the atomizer 50 , and has an open upper portion. The first connecting portion 115 has a hollow shape surrounding the output terminal 88 . A part of the output terminal 88 may be exposed through the first bonding portion 115 . Moreover, one or more (more than one) air inlets H2 communicating with the outside are formed on the side wall of the first joint part 115, and the second joint part 40 with the atomizer 50 is formed on the inner surface of the first joint part 115. The first thread S1 combined with the third thread S3 of the first joint part 115 forms the second thread S2 combined with the suction volume adjustment part 80 on the outside of the first joint part 115 . According to the structure of the first joint part 115, the second joint part 40 of the atomizer 50 is inserted and combined inside the first joint part 115, so that the atomization control unit ACU and the atomizer 50 can be fastened to each other.

In addition, a plurality of air holes H1 for penetrating through the second joint portion 40 may be formed on the second joint portion 40 , and one or more air holes H3 may be formed at the end of the atomizer shell 20 . Therefore, external air can be supplied to the inside of the atomizer 50 through the plurality of vents H3 , the plurality of air inlets H2 and the plurality of air holes H1 in sequence.

The atomizer 50 includes a second joint part 40 , an atomizer shell 20 , a barrel 21 , an electrode tube 45 , a core 35 , a heating element 30 and an exhaust pipe 25 . The second coupling part 40 is arranged at one end of the atomizer outer case 20 . The upper part of the second joint part 40 is opened, and the second joint part 40 has a hollow shape surrounding the periphery of the electrode tube 45. Therefore, when the second joint part 40 is inserted into the inside of the first joint part 115, the electrode tube 45 may be combined with an output terminal 88 and be electrically connected to the output terminal 88 .

A cylinder 21 is provided inside the atomizer outer case 20, and the cylinder 21 accommodates the raw material TL. In some embodiments, the raw material TL may be in a liquid state, and the composition of the raw material TL may be determined according to the use of the portable atomizing device 200 . Furthermore, the inside of the cartridge 21 has an atomization chamber 28 separated from the material TL, and the core 35 , the heating member 30 and the electrode tube 45 surrounding the outside of the core 35 are provided inside the atomization chamber 28 . The electrode tube 45 is made of a conductive material and is electrically connected to the output terminal 88 . A part of the core 35 is exposed to the material TL, and the material TL is sucked through the core 35 and supplied to the heating member 30 side.

The heating component 30 can be a conductive coil such as a filament, and the heating component 30 receives an output signal from the output terminal 88, such as a controlled voltage signal or a current signal, to generate heat. The output signal can be direct current (DC) or alternating current (AC) or pulse, preferably direct current for easy power control. The aforementioned pulses can control power by controlling the size or width of the pulses. When an output signal is applied to the heating member 30, the heating member 30 is heated, the raw material TL permeated in the core 35 wound around the heating member 30 is atomized, and the atomization chamber 28 is filled with the mist. The output signal will be described later with reference to FIG. 6 .

In addition, an exhaust pipe 25 is provided inside the cylinder 21 , one end of the exhaust pipe 25 is connected to the suction pipe 5 of the suction mouthpiece 10 , and the other end of the exhaust pipe 25 is connected to the atomization chamber 28 . Therefore, the liquid raw material TL is atomized, and the atomization chamber 28 is filled with smoke, and if a person inhales the inhalation mouthpiece 10 , the smoke filling the atomization chamber 28 can be inhaled through the exhaust pipe 25 and the suction pipe 5 .

In other embodiments, the portable atomizing device 200 may include an atomizer with other structures instead of the atomizer 50 that works in the above-mentioned heating mode. For example, the portable atomizing device 200 may include an atomizer that includes a vibrator to generate smoke by means of ultrasonic vibration.

The suction volume adjusting part 80 has a ring shape surrounding the outer surface of the first coupling part 115, and a screw thread (not shown) combined with the second thread S2 is formed on the inner surface of the suction volume regulating part 80 of the suction volume adjusting part 80, so as to be connected with the first coupling part 115. Combine. Therefore, when the user rotates the suction amount adjusting part 80, the suction amount adjusting part 80 can move in the first direction D1 or the second direction D2, thereby fully opening, partially opening or closing the plurality of air inflow ports H2. For example, Fig. 2b shows the state where the suction amount adjusting part 80 moves to the maximum in the second direction D2. H2 will be fully opened.

In contrast, FIG. 2c shows a state where the suction volume adjusting part 80 rotates along the second screw thread S2 and moves in the first direction D1. In this case, the suction amount adjusting part 80 overlaps approximately half of the air inlet H2, and closes about half of the air inlet H2. Therefore, when the amount of air supplied from the outside to the atomizing chamber 28 side through a plurality of air inflow ports H2 at the position of the inhalation amount adjusting part 80 shown in FIG. The position of the quantity adjusting part 80 is such that the quantity of air supplied from the outside to the mist chamber 28 side through the plurality of air inflow ports H2 becomes a second quantity greater than the above-mentioned first quantity.

Therefore, when it is assumed that the user inhales the inhalation mouthpiece 10 with the same pressure, a larger amount of inhalation can be inhaled at the position of the inhalation volume adjustment part 80 shown in FIG. 2b than at the position of the inhalation volume adjustment part 80 shown in FIG. smoke. This means that the user can easily adjust the amount of smoke inhaled by adjusting the position of the inhalation amount adjusting part 80 .

In some embodiments, the portable atomizing device 200 may further include an elastic member 85 . Like a spring formed of a metallic material, the elastic member 85 may have conductivity and elasticity. The elastic member 85 is interposed between the output terminal 88 and the printed circuit board 70 , ensures electrical connection between the output terminal 88 and the printed circuit board 70 , and corrects contact between the output terminal 88 and the electrode tube 45 . The output terminal 88 can be electrically connected to the battery BT through the printed circuit board 70 . In more detail, the elastic member 85 is in contact with the output terminal 88, the second conductive layer C2 of the printed circuit board 70, and the first conductive layer C1 of the printed circuit board 70 is in contact with the terminal of the battery BT, thereby, the power supply of the battery BT Voltage can be output through the printed circuit board 70 to the output terminal 88 .

A plurality of conductive layers are formed on the printed circuit board 70 itself, and only the contact between the battery BT and the printed circuit board 70 and the contact between the printed circuit board 70 and the electrode tube 45 are used to form a circuit for supplying power to the atomizer 50, thereby By fastening the atomizer 50, the atomization control unit ACU and the battery case 150, the electrical connection can be realized. As a result, according to the embodiments of the present invention, it is possible to provide an atomizing device with a simplified circuit structure and easy manufacture and assembly without complicated lead members such as metal wires.

In addition, the atomizer 50 is separated from the portable atomizing device 200 and combined with the portable atomizing device 200 at any time in order to fill the cylinder 21 with the raw material TL. Therefore, without the elastic member 85, the portable atomizing device 200 As the usage time becomes longer, a gap is generated between the output terminal 88 and the second conductive layer C2, so that the electrical contact between the second conductive layer C2 becomes unstable. However, according to the embodiment of the present invention, even if a space is generated between the output terminal 88 and the second conductive layer C2, the reliability of electrical contact between the output terminal 88 and the second conductive layer C2 can be improved by the elastic member 85 .

Fig. 3 is a cross-sectional view of a portion taken along II, II' of Fig. 2c.

Referring again to FIG. 2 a together with FIG. 3 , the control unit 100 is stored inside the main body casing 110 . The control unit 100 is electrically connected to the battery BT and the heating member 30 , receives electric power from the battery BT, and controls the electrical output to the heating member 30 side, for example, the magnitude of the output voltage.

The control unit 100 includes a printed circuit board 70 , a resistance measurement unit 71 , a voltage correction unit 74 , a microcomputer element 72 , a detection unit 75 , a light source 95 , and a display unit 90 . Although the resistance measurement unit 71, the voltage correction unit 74, the microcomputer element 72, the detection unit 75, and the light source 95 have been shown as being independent from each other, this is only an example, and at least two of them can be combined with each other. chip into a system IC (integrated circuit) to achieve thinner and smaller size, the present invention is not limited thereto. The printed circuit board 70 is inserted into the coupling groove 112 formed on the inner surface of the main body case 110 to be stored inside the main body case 110 and is electrically connected to the battery BT and the heating unit 30 . In more detail, a first conductive layer C1 is formed on one side of the printed circuit board 70 adjacent to the battery case 150, and the first conductive layer C1 is electrically connected to a terminal of the battery BT. Moreover, a second conductive layer C2 is formed on the other side of the printed circuit board 70 adjacent to the atomizer 50, and the second conductive layer C2 can be in contact with the output terminal 88 through the conductive elastic member 85, and is connected to the output terminal 88. The heating member 30 is electrically connected. The first conductive layer C1 and the second conductive layer C2 may be solder layers or printed conductive plates formed on the side of the printed circuit board 70 .

According to the above structure, the printed circuit board 70 can be electrically connected to the battery BT and the heating member 30 through the first conductive layer C1 and the second conductive layer C2 without additional metal wires or soldering. Moreover, the printed circuit board 70 not only completes the circuit structure, but also functions as a mechanical support for the components 71, 74, 72, 75, 95, 90, thereby simplifying the internal structure of the main body casing 110 into a single body. Therefore, it can have the environmental protection characteristic of eliminating harmful substances such as lead, and can also have the effect of saving production cost due to the simplification of the production process.

A resistance measurement unit 71 , a voltage correction unit 74 , a microcomputer element 72 , a detection unit 75 , a light source 95 , and a display unit 90 are mounted on a printed circuit board 70 . In some embodiments, the resistance measurement unit 71 may include a circuit formed on the printed circuit board 70 for detecting the resistance of the heating member 30, and the voltage correction unit 74 may include a power supply for correcting the battery BT like a voltage stabilizing circuit or a boosting circuit. The magnitude of the voltage and the circuit that outputs the power signal. Furthermore, in other embodiments, the resistance measurement unit 71 and the voltage correction unit 74 may be built in the microcomputer element 72 . The resistance measuring unit 71 can apply a measuring current to the heating element 30, and measure the resistance of the heating element 30 by measuring the voltage level of the heating element 30, or conversely, apply a measuring voltage to the heating element 30, and measure the resistance of the heating element 30 by measuring the voltage level of the heating element 30. The resistance is measured by the output current flowing.

According to the above-mentioned structure, the resistance of the heating part 30 is smaller than a predetermined value according to the standard of the atomizer 50 or the reliability of the product, for example, the resistance of the applied power condition compared to the atomizer adjusted by the user to suit his own conditions. When the value is small, the resistance measuring unit 71 detects the resistance of the heating member 30, and the voltage correcting unit 74 corrects the output voltage to be lower than a predetermined value based on the measured resistance value of the heating member 30. Therefore, irrespective of the resistance value of the heating member 30, it is possible to constantly supply the electric power with the adjusted set value to the heating member 30 side, for example, supply the same electric power to the atomizer, thereby being able to maintain the same atomization performance and smoke. quantity. Moreover, the magnitude of the supplied electric power can be adjusted according to the magnitude of the resistance, thus preventing the heating element 30 from being cut off due to high power consumption. This will be described in detail later with reference to FIG. 5 .

The detection unit 75 is supported by a support member 73 made of silicon and mounted on the printed circuit board 70 , exposed to the outside through the opening 111 formed in the main body case 110 , and generates an input signal corresponding to a touch event. The input signal generated by the detection unit 75 is input to the microcomputer element 72 side mentioned later, and is used to control the overall operation of the portable atomizing device 200 . In other embodiments, the detection component 75 can be replaced by a touch switch that works in other ways, such as an electrostatic switch and a decompression switch.

The microcomputer element 72 uses a large-scale integrated circuit (LSI) that integrates a large number of circuits, and has a central operation circuit, a storage circuit, and an input and output control circuit to perform simple arithmetic calculations and logic calculations, and receives the above-mentioned input signals to control the portable mist. The overall operation of the device 200. For example, in some embodiments, the microcomputer element 72 can turn on or off the voltage of the portable atomizing device 200 in response to an input signal, or control the power of the battery to supply to the heating component 30 side, or change the voltage of the portable atomizing device 200. working mode, or adjust the size of the above-mentioned electric power according to the above-mentioned working mode. In some embodiments, the control unit 100 may also include nonvolatile memories such as Electrically Erasable Programmable Read-Only Memory (EEPROM, Electrically Erasable Programmable Read-Only Memory), flash memory, and phase change memory. Mounted on the microcomputer element 72 or installed separately. A user setting value or a database section described later may be stored in the above-mentioned storage element or a nonvolatile memory.

In more detail, when the user touches the detection part 75 multiple times, the microcomputer element 72 can turn on the power of the portable atomizing device 200 . Then, after the power is turned on, while the user touches the detection member 75, the microcomputer device 72 can supply the above-mentioned electric power to the heating member 30 side, thereby starting atomization of the raw material.

Moreover, after turning on the portable atomizing device 200, the user can touch the detection part 75 in a predetermined manner, and the microcomputer element 72 can set the working mode of the portable atomizing device 200 to automatically control the electric power corresponding to the above touch. The size of the first working model. In this case, the power applied to the nebulizer 50 can be constantly maintained or changed by the functions of the voltage correction unit 74 and the resistance measurement unit 71 as described above.

Moreover, after turning on the portable atomizing device 200, the user can touch the detection part 75 in other predetermined ways, and the microcomputer element 72 can set the working mode of the portable atomizing device 200 to be controlled by the user's action corresponding to the above touch. The second working mode is manually operated to control the size of the above electric power. For example, in this case, the microcomputer element 72 can manually control the magnitude of the above-mentioned electric power according to the number of touch events of the user. Therefore, the user can easily increase or decrease the above-mentioned power according to the preference of inhaling smoke.

In some embodiments, the microcomputer element 72 detects the power supply voltage of the battery BT power supply, and adjusts the output voltage to a default value according to the detected power supply voltage. For example, if it is assumed that the default value of the output voltage is 5.1V, and the power supply voltage of the battery BT power supply is 3.7V, then the microcomputer element 72 detects the power supply voltage, and corrects the above-mentioned output voltage by the voltage correction unit 74, so that the above-mentioned output voltage is consistent with the above-mentioned default value. same value.

The display unit 90 is mounted on the above-mentioned printed circuit board 70 , exposed to the outside through the opening 111 formed in the main body casing 150 , and receives light from the light source 95 to display various information that the portable atomizing device 200 is driven. In some embodiments, the display unit 90 can display the power supply voltage, the output voltage, the resistance of the heating element (30), the remaining amount of the power supply of the battery BT, a warning sign based on the remaining amount, the temperature of the heating element 30, and a warning on the temperature. Logo, first working mode and second working mode and other information.

As mentioned above, on the printed circuit board 70, the resistance measurement unit 71, the voltage correction unit 74, the microcomputer element 72, the detection unit 75, the light source 95, and the display unit 90 are mounted, When the coupling grooves 112 are fastened, not only the circuit structure of the components mounted on the printed circuit board 70 becomes easy, but also the printed circuit board 70 can play a role of mechanically supporting the detection part 75 and the display part 90 . Therefore, the effect of making the circuit structure and mechanical assembly of the portable atomizing device easier can be produced as a whole.

4a and 4b are enlarged diagrams showing information displayed on the display unit 90 shown in FIG. 1. First, referring to FIG. 4a, the display unit 90 displays various information for driving the portable atomizing device. In more detail, the display part 90 includes a first display window DP1 and a second display window DP2, and the first display window DP1 can display the above-mentioned first working mode, that is, a picture or text notifying the automatic mode.

And, the second display window DP2 may display the numerical value of the output voltage supplied to the heating member (FIG. 2a 30) side or a picture representing the magnitude of the output voltage. Therefore, the user can easily grasp that the portable atomizing device 200 is currently driven in the automatic mode through the information displayed on the first display window DP1 and the second display window DP2, and the above-mentioned output voltage is 5.1V.

Referring to FIG. 4b, the display part 90 may display information informing of the second operation mode as described above. For example, the third display window DP3 can display the above-mentioned second working mode, that is, a picture or text informing the manual mode, and the second display window DP2 can display the output voltage provided to the side of the heating component (Fig. 2a30). Therefore, the user can easily grasp that the portable atomizing device 200 is currently driven in the manual mode and the above-mentioned output voltage is 4.1V through the information displayed on the second display window DP2 and the third display window DP3 . And, in the case where the user touches the detection part (FIG. 375) in the second operation mode, the user can directly confirm the above-mentioned increase or decrease of the output voltage from 4.1V through the second display window DP2.

In other embodiments, the microcomputer element (Fig. 372) can be designed in such a way that the power of the portable atomizing device is turned on or off according to the touch time of the detection part (Fig. 375). For example, in order to prevent the power supply of the portable atomizing device from being turned on due to inadvertent touches by the user, for example, when only holding the portable atomizing device, it can be designed to continuously touch the above-mentioned device three times or five times within 0.5 seconds. In the case of inspecting parts, use the menu mode and use the menu mode to turn on or off the power.

And, in other embodiments, in addition to the above-mentioned output voltage, the residual amount of the battery (Fig. 2a BT ) power supply, the size of the heating element (Fig. 2a 30), the temperature of the heating element or temperature-related warning signs and other information. The information can be displayed on the display unit 90 at the same time, and can be displayed in a mutually divided manner according to a plurality of display modes that change according to the number of times the detection member is touched. Furthermore, in addition to various information displayed on the display unit 90 , other information related to the driving of the portable atomizing device such as the number of inhalations and the method of displaying them can be changed according to the design of the microcomputer element and the display unit 90 .

Fig. 5 is a block diagram of the portable atomizing device 200 shown in Fig. 2a, and Fig. 6 is a timing diagram for illustrating the output signal S2 of the control unit 100 during a heating operation period and a heating stop period.

5 and 6, the detection part 75 generates an input signal S1 during the user's continuous pressing action (hereinafter referred to as the touch-on period S1_t1), and the control part 100 outputs an output signal S2 to the heating part 50 in response to the input signal S1. . The output signal S2 has a waveform in which the heating operation period (S2_t1) and the heating stop period (S2_t2) alternate with the touch-on period (S1_t1) of the input signal S1, and the heating operation period (S2_t1) has a first voltage level. (V1), the above heating stop period (S2_t2) has a second voltage level (V2) lower than the first voltage level (V1). For this purpose, the control unit 100 may include an exchange element (not shown), which is turned on during the heating operation period ( S2_t1 ) and turned off during the heating stop period ( S2_t2 ).

The output signal S2 may include a square wave pulse waveform whose cycle is repeated by a period having a voltage of a high level and a period of a voltage having a low level. But this is only for illustration, and the output signal S2 including the heating operation period (S2_t2) and the heating stop period (S2_T2) can have any waveform during the rising period and/or falling period of linear or curved lines such as triangular wave, sawtooth wave and semicircular wave, In this case, the average value can be used to determine the voltage level in each period.

The duration of the heating-on period (S2_t1) of the output signal S2 may be longer than the duration of the heating-off period (S2_t2). For example, the heating operation period (S2_t1) has a duration in the range of 0.1 seconds to 20 seconds, preferably, has a duration in the range of 0.5 seconds to 2 seconds to produce a gasification or sublimation action, while the heating is stopped The period (S2_t2) may have a duration in the range of 0.01 seconds to 5 seconds, preferably, in order to produce optimal vaporization and sublimation, protect the heating element, and prevent the burning of the liquid raw material, it may have a duration of 0.5 seconds to durations in the range of 0.2 seconds.

In some embodiments, the duration of the heating working period ( S2_t1 ) and the heating stop period ( S2_t2 ) can be preset by the user. For example, if the heating operation period (S2_t1) is lengthened and the heating stop period (S2_t2) is shortened, the amount of smoke can be increased because the time for heating the liquid raw material is prolonged. Moreover, if each of the above-mentioned times listed is adjusted, the original taste of the liquid raw material will change with time, and the user can adjust this time arbitrarily according to his own preferences, and obtain the adjusted taste of the liquid raw material. To this end, the portable atomizing device 200 may also include a display unit 90 for displaying a user setting interface, the user setting interface is used to set the heating working period (S2_t1) and the heating stop period (S2_t2), and the control unit 100 uses the detection The part 75 serves as a user input interface, and receives the values of the heating working period (S2_t1) and the heating stop period (S2_t2) according to the user's pressing action, and adjusts these. In other embodiments, at least one of the heating operation period (S2_t1) and the heating stop period (S2_t2), preferably, the heating stop period (S2_t2) can prevent the heating stop period (S2_t2) from heating according to the resistance value of the heating member 30. The mode of heat loss is automatically set or a recommended value is provided.

In some embodiments, the first voltage level ( V1 ) may have a specific voltage level provided from the battery BT, such as the voltage of the battery or a set value. In other embodiments, the first voltage level ( V1 ) may be defined in a variable manner depending on the measured resistance of the heating element 50 . As described above, for example, when the resistance value (referred to as a reference resistance value) of the applied power condition is smaller than that of an atomizer adjusted to the user's own style, the resistance measurement unit 71 detects the resistance of the heating member 30. The resistance and voltage correction unit 74 corrects the first voltage level ( V1 ) of the output signal S2 to be lower than a predetermined value based on the detected measured resistance value of the heating member 30 . Conversely, in the case where the resistance measurement value of the heating member 50 is greater than the above reference resistance value, the first voltage level ( V1 ) of the output signal S2 may be corrected to be higher than a predetermined value.

In some embodiments, the control unit 100 may refer to a lookup table that defines the measured resistance value and the first voltage level ( V1 ) based on the resistance value. The look-up table may be digitized or stored in a memory or a storage.

Table 1 is an exemplary look-up table of measured resistance values and first voltage levels.

Referring to Table 1, the control unit 100 may measure a resistance value, and search for a first voltage level corresponding to the measured resistance value, thereby outputting a voltage signal. For example, if the measured resistance value is 1Ω, the first voltage level can be defined as 2V and output. In the case that the measured resistance value is not in the look-up table, an intermediate value or an approximate value in the look-up table may be determined as the first voltage level by linear interpolation.

Table 1

serial number Measured resistance value (Ω) First voltage level (V) 1 1 2 2 1.5 2.5 3 2 3 : : :

In other embodiments, the control unit 100 can calculate the first voltage level corresponding to the resistance value measured by Mathematical Formula 1 or Mathematical Formula 2.

Mathematical formula 1

V _out =R+A

Here, V _out is the first voltage level, R is the measured resistance value, and A is an arbitrary constant such as 1.

In Mathematical Expression 1, although the units of the first voltage level V _out and the measured resistance value R are V and Ω, respectively, Mathematical Expression 1 can be a code that can actually run in a computer, and in this case , the formula for calculating the output of the first voltage level can be determined only algebraically regardless of the unit.

Mathematical formula 2

${\mathrm{<span\; class="notranslate">\; V</span>}}_{\mathrm{<span\; class="notranslate">\; out</span>}}<span\; class="notranslate">\; =</span>\mathrm{<span\; class="notranslate">\; k</span>}{<span\; class="notranslate">\; (</span>\mathrm{<span\; class="notranslate">\; R</span>}<span\; class="notranslate">\; )</span>}^{\frac{\mathrm{<span\; class="notranslate">\; 1</span>}}{\mathrm{<span\; class="notranslate">\; 2</span>}}}$

Here, V _out is the first voltage level, R is the measured resistance value, and K is an arbitrary proportional constant. Like Mathematical Formula 1, Mathematical Formula 2 can be a code that can actually be run by a computer, and since electricity determines the Joule heat of the heating component, the output voltage V _out can determine the first voltage in a manner proportional to the square root of the resistance value level.

The above look-up table method and algebraic determination method are just examples, and the embodiments of the present invention are not limited thereto. For example, codes with other algebraic relationships for determining the first voltage level from the measured resistance value R may be used.

In other embodiments, the tables or decision methods related to power control can be downloaded to the control unit 100 through a wired or wireless network. In addition, the user can choose according to the commodity, specification and type of the liquid raw material, or by comprehensively considering the identification information such as the barcode and data value used to identify the commodity, specification or type of the liquid raw material, and the resistance value measured based on the above identification information. Multiple ways of automatically selecting the first voltage level are configured according to corresponding raw materials. To this end, the portable atomizing device 200 may also include a data scanner, a USB (Universal Serial Bus) interface, Bluetooth or WiFi (Wireless High Fidelity) and other wireless interfaces.

In order to completely block the electric signal E from the battery BT and prevent overheating of the heating element 30, the second voltage level is 0V, and power can be intermittently supplied to the heating element side while the user keeps pressing the detection element. In some embodiments, the second voltage level may not be 0, but lower than the first voltage level.

In some embodiments, the output signal S2 may have a heating standby period (S2_t0). The above-mentioned heating standby period (S2_t0) means that the output signal S2 is not turned on within a specified time from the start point of the user's continuous pressing action. . For example, when the standby heating period (S2_t0) is set to 0.5 seconds, if the user maintains the state of touching the touch button of the detection part 75 for more than 0.5 seconds, then after 0.5 seconds, the atomizer with the first output voltage of a voltage level (V1). The heating standby period (S2_t0) can be determined in the range of 0.01 second to 1 second, but the present invention is not limited thereto. During this heating standby period (S2_t0), the pressing action is performed by judging whether the pressing event generated by the detection part indicates that the user needs atomization, so as to prevent the output signal S2 from being lost due to careless touch or contact with things. The expected touch is transmitted to the atomizer.

The control unit 100 repeats the voltage output cycle while the user maintains the pressing action or touch, but the duration of the heating operation period ( S2_t1 ) may be constant. For example, when the user removes the touch and the input of the input signal S1 is interrupted, and the output signal S2 is located in the heating operation period (S2_t1), the output of the output signal S2 can be at the beginning of the end of the corresponding heating operation period (S2_t1). interruption. In this case, the overall cycle of the output signal S2 may be longer than the touch-on period ( S1_t1 ) of the input signal S1 . However, when the output signal ( S2 ) at which the user interrupts the input of the input signal S1 is in the heating standby period ( S2_t0 ), the output of the output signal S2 may be interrupted at the same time. In other embodiments, when the output cycle is more than 3 times, 1 to 2 cycles can be added according to the user's touch habit and residual voltage.

As described above, according to an embodiment of the present invention, the output signal S2 having a heating-on period (S2_t1) of a first voltage level and a heating-stop period (S2_t2) of a second voltage level lower than the first voltage level is utilized. By controlling the heating member 50, the damage of the atomizer 30 and waste of raw materials caused by the heating of the heating member 50 for a long time can be prevented. Moreover, the user can adjust the duration of the heating working period (S2_t1) and the heating stop period (S2_t2) according to the inhalation time or inhalation habit, so that the user can select/adjust the smoke condition that is more in line with his preferences, and obtain the effect of the changed raw materials. Taste, aroma and inhalation.

FIG. 7 is a timing chart for explaining an output signal for setting a maximum operating time, and FIG. 8 is a timing chart for explaining an output signal for setting a standby time. As long as there is no conflict with each other, structural elements having the same reference numerals as the above-mentioned structural elements can refer to the above-mentioned disclosures, and repeated description will be omitted.

Referring to FIG. 7 , in order to prevent overheating and excessive smoking of the atomizer 30 , the output of the output signal S2 may be limited within a preset maximum working time ( S2_t4 ). Even if the touch-on period (S1_t1) of the input signal S1 based on the user's touch input continues to exceed the maximum operating time (S2_t4), if the total output time of the output signal S2 reaches the maximum operating time (S2_t4), the output signal S2 is automatically interrupted. apply. The maximum working time (S2_t4) can be in the range of 0.15 seconds to 22 seconds, preferably in the range of 9 seconds to 13 seconds, and can be selectively adjusted by the user. For example, when the maximum operating time (S2_t4) is set to 11 seconds, even if the touch-on period (S1_t1) of the input signal S1 lasts for more than 11 seconds from the touch start point, the output signal S2 will output for a total output time of The starting point of 11 seconds is disconnected. This prevents the damage of the atomizer 30 and the waste of raw materials caused by the long-time heating of the heating member 50, and limits the inhalation time and capacity of the user's smoke components or vaporized pharmacologically active substances regardless of the user's operation, and also Can control inhalation habits.

Referring to FIG. 8 , when the predetermined waiting time for stopping the pressing operation of the detection member 75 is longer than (S1_w), the control unit 100 can start from the heating standby period (S2_t0) based on the subsequent pressing operation of the detection member 75 (S1_A). An output signal S2 is output. For example, when the touch-off period (S1_t2) of the input signal S1 exceeds the standby time (S1_w), if the input signal S1 is turned on later, the output signal S2 may have a heating standby period (S2_t0). (S2_t0) means that the output signal S2 is not turned on within a predetermined time from the start point of turning on the input signal S1. Conversely, when the input signal S1 is turned on while the touch-off period (S1_t2) of the input signal S1 is interrupted within the standby time (S1_w), the output signal S2 is turned on immediately without the standby period (S2_t0), And output from the heating working period (S2_t1).

For example, when the heating standby period (S2_t0) is set to 0.5 seconds and the standby time (S1_w) is set to 3 seconds, if the touch of the detection part 75 is continued for 3 seconds, the touch cannot be recognized, Then the output signal S2 is initialized and converted to the standby mode. After that, when the touch is recognized and converted to the working mode, after 0.5 seconds after the touch, the output signal S2 is turned on and enters the alternate heating working period (S2_t1) and During the heating stop period (S2_t2).

As described above, setting the maximum operation time (S2_max) of the output signal and the standby time (S1_w) of the suspension of the pressing operation of the detection member reduces the power consumption supplied to the heating member 50, and finally has the advantage of increasing the battery life. .

The present invention described above is not limited to the above-described embodiments and drawings, and various substitutions, deformations, and changes are possible without departing from the technical idea of the present invention.

Claims (37)

1. a portable vaporization device, is characterized in that, comprising:

Battery case, for depositing battery;

Atomizer, is electrically connected with above-mentioned battery, and described atomizer comprises for generation of the heater block that makes raw material atomization heat;

Main body cover combines with above-mentioned battery case, above-mentioned atomizer between above-mentioned battery case and above-mentioned atomizer;

Control part, leaves the inside of aforementioned body shell in, is electrically connected, and accepts electric power from above-mentioned battery with above-mentioned battery, above-mentioned heater block, controls to the output signal of above-mentioned heater block side output; And

Soakage adjusting portion, opens or closes the air inflow aperture that leads to above-mentioned atomizer side from outside, regulates to the amount of the air of above-mentioned atomizer side inflow.

2. portable vaporization device according to claim 1, is characterized in that, above-mentioned control part detects the resistance sizes of above-mentioned heater block, and controls above-mentioned output signal according to the resistance sizes of detected above-mentioned heater block.

3. portable vaporization device according to claim 2, is characterized in that,

Be greater than predetermined value at the resistance of above-mentioned heater block, above-mentioned control part increases the output voltage of above-mentioned output signal,

Be less than predetermined value at the resistance of above-mentioned heater block, above-mentioned control part reduces the output voltage of above-mentioned output signal.

4. portable vaporization device according to claim 1, is characterized in that, above-mentioned control part detects the size of the supply voltage of above-mentioned battery, and controls above-mentioned output signal according to the size of detected above-mentioned supply voltage.

5. portable vaporization device according to claim 4, is characterized in that,

In the situation that above-mentioned supply voltage is less than predetermined value, above-mentioned control part rises above-mentioned supply voltage,

In the situation that above-mentioned supply voltage is greater than predetermined value, above-mentioned control part declines above-mentioned supply voltage.

6. according to the portable vaporization device described in claim 2 or 4, it is characterized in that, above-mentioned control part comprises:

Printed circuit board (PCB), leaves the inside of main body cover in, and is electrically connected with above-mentioned battery, above-mentioned heater block;

Resistance measurement portion, is arranged on above-mentioned printed circuit board (PCB), for measuring the resistance of above-mentioned heater block; And

Voltage correction portion, is arranged on above-mentioned printed circuit board (PCB), for proofreading and correct above-mentioned supply voltage.

7. portable vaporization device according to claim 6, is characterized in that, above-mentioned control part also comprises:

Switch, is arranged on above-mentioned printed circuit board (PCB), exposes to the outside of above-mentioned main body cover, generates accordingly input signal with touch event;

Microcomputer element, is arranged on above-mentioned printed circuit board (PCB), responds above-mentioned input signal and controls above-mentioned output signal; And

Display part, be arranged on above-mentioned printed circuit board (PCB), expose to outside by the peristome that forms aforementioned body shell, for showing the temperature of the caution sign of the charge volume of the resistance of the voltage of above-mentioned supply voltage, above-mentioned output signal, above-mentioned heater block, above-mentioned battery, charge volume to above-mentioned battery, above-mentioned heater block, caution sign to said temperature and at least one of mode of operation.

8. portable vaporization device according to claim 7, is characterized in that,

Above-mentioned mode of operation is divided into the first mode of operation or the second mode of operation according to above-mentioned input signal,

Under above-mentioned the first mode of operation, control above-mentioned output signal according to the size of above-mentioned supply voltage or the resistance sizes of above-mentioned heater block,

Under above-mentioned the second mode of operation, the above-mentioned input signal of above-mentioned microcomputer element responds and control above-mentioned output signal.

9. portable vaporization device according to claim 7, is characterized in that, above-mentioned resistance measurement portion and above-mentioned voltage correction portion are built in above-mentioned microcomputer element.

10. portable vaporization device according to claim 6, is characterized in that,

Aforementioned body shell comprises lead-out terminal, and above-mentioned lead-out terminal is arranged on the position combining with above-mentioned atomizer, for transmitting above-mentioned output signal;

Above-mentioned printed circuit board (PCB) comprises:

The first conductive layer, is formed at a side adjacent with above-mentioned battery case, is electrically connected with the terminal of above-mentioned battery, and

The second conductive layer, is formed at the opposite side adjacent with above-mentioned atomizer, is electrically connected with above-mentioned lead-out terminal.

11. portable vaporization device according to claim 10, is characterized in that, above-mentioned the first conductive layer directly contacts with the terminal of above-mentioned battery, and above-mentioned the second conductive layer directly contacts with above-mentioned lead-out terminal.

12. portable vaporization device according to claim 10, is characterized in that,

Also comprise elastomeric element, above-mentioned elastomeric element has electric conductivity and elasticity, between above-mentioned lead-out terminal and above-mentioned the second conductive layer, above-mentioned lead-out terminal is electrically connected with above-mentioned the second conductive layer;

Above-mentioned the first conductive layer directly contacts with above-mentioned battery terminal, and above-mentioned elastomeric element directly contacts with above-mentioned lead-out terminal, above-mentioned the second conductive layer.

13. portable vaporization device according to claim 1, is characterized in that,

Aforementioned body shell comprises joint portion, and extend from an end of aforementioned body shell above-mentioned joint portion, and combine with above-mentioned atomizer, and the sidewall of above-mentioned joint portion is formed with above-mentioned air inflow aperture;

Above-mentioned soakage adjusting portion moves along the length direction of above-mentioned joint portion, opens or closes above-mentioned air inflow aperture.

14. portable vaporization device according to claim 1, is characterized in that, above-mentioned raw material are electronic cigarette liquid material.

15. 1 kinds of atomization control modules, comprise and having for the atomizer of the heater block of heating raw materials and for depositing the portable vaporization device of battery case of battery, it is characterized in that, comprising:

Main body cover, a side combines with above-mentioned battery case, and opposite side combines with above-mentioned atomizer;

Control part, deposits the inside that is arranged on main body cover, is electrically connected with above-mentioned battery and above-mentioned heater block, accepts supply voltage from above-mentioned battery, controls to the output signal of above-mentioned heater block side output; And

Soakage adjusting portion, opens or closes the air inflow aperture that leads to above-mentioned atomizer side from outside, regulates to the amount of the air of above-mentioned atomizer side inflow.

16. portable atomization control modules according to claim 15, is characterized in that, above-mentioned control part detects the resistance sizes of above-mentioned heater block, and controls above-mentioned output signal according to the resistance sizes of detected above-mentioned heater block.

17. portable atomization control modules according to claim 15, is characterized in that, above-mentioned control part detects the size of above-mentioned supply voltage, and controls above-mentioned output signal according to the size of detected above-mentioned supply voltage.

18. according to the portable atomization control module described in claim 16 or 17, it is characterized in that, above-mentioned control part comprises:

Printed circuit board (PCB), deposits the inside that is arranged on main body cover, is electrically connected with above-mentioned battery and above-mentioned heater block;

Resistance measurement portion, is installed on above-mentioned printed circuit board (PCB), for measuring the resistance of above-mentioned heater block; And

Voltage correction portion, is installed on above-mentioned printed circuit board (PCB), for proofreading and correct above-mentioned supply voltage.

19. portable atomization control modules according to claim 18, is characterized in that, above-mentioned control part comprises:

Switch, is installed on above-mentioned printed circuit board (PCB), exposes to the outside of main body cover, generates accordingly input signal with touch event;

Microcomputer element, is installed on above-mentioned printed circuit board (PCB), controls above-mentioned output signal in response to above-mentioned input signal; And

Display part, be installed on above-mentioned printed circuit board (PCB), expose to outside by the peristome that forms aforementioned body shell, for showing the temperature of the charge volume of the resistance of the voltage of above-mentioned supply voltage, above-mentioned output signal, above-mentioned heater block, above-mentioned battery, the caution sign based on above-mentioned charge volume, above-mentioned heater block, caution sign based on said temperature and at least one of mode of operation.

20. portable atomization control modules according to claim 19, is characterized in that,

Above-mentioned mode of operation is divided into the first mode of operation or the second mode of operation according to above-mentioned input signal,

Under above-mentioned the first mode of operation, control above-mentioned output signal according to the size of above-mentioned supply voltage or the resistance sizes of above-mentioned heater block,

Under above-mentioned the second mode of operation, the above-mentioned input signal of above-mentioned microcomputer element responds and control above-mentioned output signal.

21. portable atomization control modules according to claim 18, is characterized in that, above-mentioned printed circuit board (PCB) comprises:

The first conductive layer, is formed at a side adjacent with above-mentioned battery case, is electrically connected with the terminal of above-mentioned battery; And

The second conductive layer, is formed at the opposite side adjacent with above-mentioned atomizer, is electrically connected with above-mentioned atomizer.

22. portable atomization control modules according to claim 18, is characterized in that, above-mentioned resistance measurement portion and above-mentioned voltage correction portion are built in above-mentioned microcomputer element.

23. portable atomization control modules according to claim 15, is characterized in that,

Aforementioned body shell comprises joint portion, and extend from an end of aforementioned body shell above-mentioned joint portion, and combine with above-mentioned atomizer, and the sidewall of above-mentioned joint portion forms above-mentioned air inflow aperture;

Above-mentioned soakage adjusting portion moves along the length direction of above-mentioned joint portion, opens or closes above-mentioned air inflow aperture.

24. 1 kinds of portable vaporization device, is characterized in that, comprising:

Atomizer, is electrically connected with above-mentioned battery, and this atomizer comprises for generation of the heater block that makes raw material atomization heat;

Control part, comprise the detection part of the lasting push action that can identify user, the duration of the push action of above-mentioned detection part, to the output of above-mentioned heater block at least alternately during a heating work and the output signal of heating stopping period, during above-mentioned heating work, have the first voltage level, above-mentioned heating stopping period has the second voltage level lower than above-mentioned the first voltage level.

25. portable vaporization device according to claim 24, is characterized in that, above-mentioned detection part is push button or touch.

26. portable vaporization device according to claim 24, is characterized in that, above-mentioned control part defines above-mentioned the first voltage level according to the resistance measurement value of above-mentioned heater block.

27. portable vaporization device according to claim 24, is characterized in that, the above-mentioned second voltage level of above-mentioned control part is 0V.

28. portable vaporization device according to claim 24, is characterized in that, longer than above-mentioned heating stopping period during above-mentioned heating work.

29. portable vaporization device according to claim 24, is characterized in that, have the duration within the scope of 0.1 second to 20 seconds during above-mentioned heating work, and above-mentioned heating stopping period has the duration within the scope of 0.05 second in second to 5.

30. portable vaporization device according to claim 24, is characterized in that, during having heating standby, during described heating standby, refer to, from the starting point of above-mentioned user's lasting push action, at the appointed time, above-mentioned output signal is disconnected.

31. portable vaporization device according to claim 30, is characterized in that, have the duration within the scope of 0.01 second in second to 1 during above-mentioned heating standby.

32. portable vaporization device according to claim 24, is characterized in that,

Also comprise display part, above-mentioned display part shows during setting above-mentioned heating work sets interface with one or two user who all sets of above-mentioned heating stopping period;

Above-mentioned control part uses above-mentioned detection part as user's inputting interface, during regulating above-mentioned heating work according to above-mentioned user's push action and the value of above-mentioned heating stopping period.

33. portable vaporization device according to claim 24, is characterized in that, the output of above-mentioned output signal was defined in the predefined maximum operating time.

34. portable vaporization device according to claim 33, is characterized in that, the above-mentioned maximum operating time is within the scope of 0.15 second in second to 25.

35. portable vaporization device according to claim 24, is characterized in that, also comprise:

Battery case, for depositing above-mentioned battery;

Main body cover combines with above-mentioned battery case, above-mentioned atomizer between above-mentioned battery case and above-mentioned atomizer; And

Soakage adjusting portion, opens or closes the air inflow aperture that leads to above-mentioned atomizer side from outside, regulates to the amount of the air of above-mentioned atomizer side inflow.

36. portable vaporization device according to claim 24, is characterized in that, above-mentioned portable vaporization device is the one in electronic cigarette, fragrance generator, aroma-therapeutic instrument, sterilizer, disinsector and respirator therapeutic equipment.

37. 1 kinds of atomization control modules, comprise and there is the portable vaporization device being electrically connected with battery for the atomizer of the heater block of heating raw materials, it is characterized in that, comprise control part, described control part comprises the detection part of the lasting push action that can identify user, during the push action of above-mentioned detection part continues, to the output of above-mentioned heater block at least alternately during a heating work and the output signal of heating stopping period, during above-mentioned heating work, there is the first voltage level, above-mentioned heating stopping period has the second voltage level lower than above-mentioned the first voltage level.