An electronic cigarette with a detachable battery, the electronic cigarette comprising an atomization assembly (100) and a battery assembly (200). The atomization assembly (100) comprises a mouthpiece shell (1), an e-liquid chamber (2) and a heating unit (3). The battery assembly (200) comprises a battery assembly shell (4), a battery holder (5), a circuit control board (6) and a detachable battery (7), wherein the battery holder (5) is connected to the inner wall of the battery assembly shell (4) in a sleeved manner; a battery accommodating cavity (50) is provided in the battery holder (5); the battery (7) is sleeved in the battery accommodating cavity (50) via a bottom opening; and a sliding cover (8) is connected to the bottom of the battery (7), and the sliding cover (8) can horizontally slide relative to the battery holder (5) to a snap-fitting position or a separation position. When at the snap-fitting position, the sliding cover (8) is snap-fitted with the battery holder (5), such that the battery (7) is mounted and fixed in the battery holder (5). When at the separation position, the sliding cover (8) is separated from the battery holder (5), such that the battery (7) can be detached from the battery holder (5). The detachable battery (7) is convenient to mount and detach and can be mounted firmly, and resources can be fully utilized to avoid waste; moreover, the battery (7) can be independently taken out for recycling, thereby avoiding long-term environmental pollution.
An electronic cigarette vaporizer equipped with a soft vaporizing core comprises a mouthpiece housing, a vaporization assembly fitted inside the mouthpiece housing, and a bottom cap disposed on a bottom portion of the mouthpiece housing. The vaporization assembly comprises an upper vaporizing seat, and a base vaporizing seat which are connected, a bottom portion of the upper vaporizing seat is provided with a concave and upward-extending vaporizing core cavity, in which the soft vaporizing core is accommodated. The base vaporizing seat supports a bottom portion of the soft vaporizing core from below. The soft vaporizing core comprises a vaporizing core support, a heating element, and a soft liquid guiding element. The heating element comprises a sheet-like heating resistance provided with a conductive path, the heating resistance is disposed in the support through hole of the vaporizing core support, and the soft liquid guiding element is disposed on the heating resistance.
A soft vaporizing core comprises a support (1), a heating element (2), and a soft liquid guiding element (3). The support (1) has an upper flat surface (11) and a lower flat surface (12) and is provided with a support through hole (10) in middle. The heating element (2) comprises a sheet-like heating resistance (21) having a conductive path, the heating resistance (21) is disposed in the support through hole (10) and is aligned with the upper flat surface (11) of the support (1), and the soft liquid guiding element (3) is disposed on the upper flat surface (11) of the support. The soft vaporizing core can achieve a low material cost, a simple structure, and a high production efficiency, and achieve sufficient liquid supply and great vaporization amount. It can provide pure taste and is not prone to a burned taste, improving user experience.
Provided are a circuit for generating a supply voltage from a chip communication terminal and a chip. The circuit includes electronic components provided in a chip and an energy storage capacitor (CAP) provided in the chip or externally attached to the chip. The electronic components include a diode, first P-channel metal-oxide-semiconductor (PMOS) transistor, and voltage comparator; an anode of the diode, a drain of the first PMOS transistor, and a negative input terminal of the voltage comparator are connected to a chip communication terminal; a cathode of the diode, a source and substrate of the first PMOS transistor, and a positive input terminal of the voltage comparator are connected to a chip power terminal; a gate of the first PMOS transistor is connected to an output terminal of the voltage comparator; and the CAP includes one terminal connected to the chip power terminal, and the other terminal grounded.
H03K 5/24 - Circuits présentant plusieurs entrées et une sortie pour comparer des impulsions ou des trains d'impulsions entre eux en ce qui concerne certaines caractéristiques du signal d'entrée, p. ex. la pente, l'intégrale la caractéristique étant l'amplitude
G05F 1/625 - Régulation de la tension ou de l'intensité là où la variable effectivement régulée est indifféremment du type alternatif ou continu
A vaporizer allowing for transversely guiding liquid comprises a housing, in which a liquid storage chamber is defined. The housing is centrally provided with a flow path extending there-through, separated from the liquid storage chamber and having a vaporizing chamber, in which a vaporizing core is transversely disposed. The vaporizing core has a center through hole extending transversely with two ends being in communication with the liquid storage chamber, and comprises a porous body having a vaporizing surface, on which a heating layer is applied. Two distal ends of the heating layer are respectively connected with an electrode disk, and the heating layer is provided with vapor through-holes. Thus, the to-be-vaporized liquid is allowed to transversely flow into the center through hole, permeate to the vaporizing surface, be vaporized into vapor fog when the heating layer is electrified to generate heat, and flow out through the flow path.
Disclosed in the present invention is an electronic cigarette having high sensitivity, comprising a mouthpiece part, an outer housing, an atomization assembly and a battery assembly; the atomization assembly and the battery assembly are arranged in the outer housing; the atomization assembly comprises a liquid storage compartment storing an atomization liquid and an atomization core used for heating and evaporating the atomization liquid; the battery assembly comprises a battery providing power supply for the atomization core, and a PCB control board; the mouthpiece part is arranged at one end of the outer housing and is connected to the atomization assembly; an airflow sensing channel and an airflow sensor are provided in the mouthpiece part, the airflow sensor being arranged in the airflow sensing channel. The present invention has the advantage that the airflow sensor is provided in the mouthpiece part to maximally shorten the distance between the airflow sensor and a vaping opening, such that airflow generated when a user vapes can be sensed more quickly, and the airflow sensor can be triggered more quickly, thus improving the operation sensitivity of electronic cigarettes.
Disclosed is an atomizer having an offset atomization core, comprising a housing and an atomization assembly. The housing comprises a mouthpiece end and a connection end; the mouthpiece end is provided with a mouthpiece opening, and the connection end is provided with an opening; the atomization assembly is inserted into the housing through the opening and sleeved on the inner wall of the housing; the atomization assembly comprises an atomization seat, an atomization core and a base; the atomization seat and the base are connected one above the other; the upper end of the atomization seat is provided with a flat upper end face; the flat upper end face is provided with a vapor outlet through hole downwardly; at least one side of the vapor outlet through hole is provided with a liquid inlet downwardly; the bottom end of the atomization seat is provided with an upwardly recessed bottom cavity; the vapor outlet through hole is communicated with the bottom cavity; the bottom cavity is further provided with an atomization core accommodating cavity upwardly; the atomization core accommodating cavity is communicated with the liquid inlet; and the atomization core is sleeved upwardly from the bottom cavity into the atomization core accommodating cavity. The present invention has the following beneficial effects: the number of internal components of the atomizer is reduced, thereby not only reducing the production cost, but also greatly improving the production efficiency; in addition, the atomizer has higher atomization efficiency, and can avoid leakage of atomized liquid waste and its inhalation into the mouth.
Disclosed is an atomizer provided with an integrated atomization base, said atomizer comprising a housing, an integrated atomization base, an atomization core, and a base. The integrated atomization base and the base are connected top to bottom and then sleeve an inner wall of the housing from an opening. The integrated atomization base is a columnar body having a roughly oval cross section. A vapor outlet is provided in the center of an upper end of the integrated atomization base, and liquid inlets are provided on two sides of the vapor outlet. An atomization cavity is provided at a bottom end of the integrated atomization base so as to be recessed upward, an atomization core accommodating cavity and a vapor discharge cavity are further upwardly provided in the atomization cavity, and a liquid intake cavity is communicatingly provided at an upper portion of the atomization core accommodating cavity. The liquid intake cavity separately communicates with the liquid inlets on the two sides of the vapor outlet hole. The atomization core is upwardly sleevingly mounted in the atomization core accommodating cavity. A vapor discharge channel communicating with the vapor outlet is provided at an incline above the vapor discharge cavity. The described atomizer has the beneficial effects that components in the interior of the atomizer are reduced, and the structure is simple. Not only can production costs can be reduced, but also automatic assembly and production are facilitated during assembly and production, thereby greatly improving the production efficiency.
An atomizer base having a chip inside, and an atomizer. The atomizer base having a chip inside comprises a base body, a circuit board, a chip and an electrode post, wherein the chip and the electrode post are arranged on the circuit board; the circuit board and the chip are embedded in the base body; the bottom of the electrode post is exposed from the bottom of the base body, and the upper part of the electrode post protrudes toward the upper part of the base body; and the electrode post comprises a positive electrode post and a negative electrode post. It is advantageous in that the circuit board and the base body are integrally injection-molded, such that the chip and the circuit board are embedded in the base body, which can prevent failure due to the chip being exposed and corroded by atomization liquid or condensed liquid, and can also prevent harmful substances contained in the chip and the circuit board from volatilizing into the aerosol and thus being inhaled by users, thereby protecting human health.
The disclosure provides a control method of an electronic cigarette with child lock function, wherein a microcontroller of the electronic cigarette is set with child lock control program which comprises steps of: S1. in a locked state of the electronic cigarette, monitoring a signal which indicates that a touch button is touched in real time by the microcontroller; S2. determining whether a duration of time during which the touch button is touched exceeds a first set time by the microcontroller; S3. controlling an LED indicator to light up for a second set time and meanwhile continuously monitoring whether the touch button is consecutively touched by the microcontroller; S4. determining whether a number of times the touch button is consecutively touched in the second set time reaches a set number by the microcontroller; S5. unlocking the electronic cigarette by the microcontroller, to allow the electronic cigarette to enter a stand-by state.
A cocoa/tea polyphenol e-liquid having an antidepressant effect, having the following formulation ingredients in parts by weight: 2 to 10 parts cocoa extract, 0.02 to 0.2 parts tea polyphenol, 0.1 to 2 parts peppermint oil, 0.1 to 1 part rosemary oil, 5 to 15 parts ethanol, 10 to 30 parts micromolecular water, 15 to 30 parts glycerin, and 30 to 50 parts of propylene glycol. The cocoa/tea polyphenol e-liquid has the effects of combating depression, and to a certain extent relieving anxiety, nervousness, irritability, and other such symptoms. Further provided is a preparation method for the cocoa/tea polyphenol e-liquid having an antidepressant effect.
A24B 15/167 - Caractéristiques chimiques du tabac ou des succédanés du tabac des succédanés du tabac sous forme liquide ou vaporisable, p. ex. compositions liquides pour cigarettes électroniques
15.
BERBERINE LIMONENE ELECTRONIC CIGARETTE ATOMIZED LIQUID HAVING ANTIVIRAL AND ANTIDEPRESSANT EFFECTS
Disclosed is a berberine limonene electronic cigarette atomized liquid having antiviral and antidepressant effects. The berberine limonene electronic cigarette atomized liquid having antiviral and antidepressant effects is prepared from the following ingredients: 0.5-5 parts by weight of berberine hydrochloride, 0.1-5 parts by weight of limonene, 0.1-5 parts by weight of nicotine, 1-5 parts by weight of vanillin, 60-80 parts by weight of propylene glycol, and 10-30 parts by weight of glycerol. The berberine limonene electronic cigarette atomized liquid having antiviral and antidepressant effects of the present invention has the beneficial effect that the electronic cigarette atomized liquid has antiviral and antidepressant effects to a certain extent.
A61K 31/4375 - Composés hétérocycliques ayant l'azote comme hétéro-atome d'un cycle, p. ex. guanéthidine ou rifamycines ayant des cycles à six chaînons avec un azote comme seul hétéro-atome d'un cycle condensés en ortho ou en péri avec des systèmes hétérocycliques le système hétérocyclique contenant un cycle à six chaînons ayant l'azote comme hétéro-atome du cycle, p. ex. quinolizines, naphtyridines, berbérine, vincamine
A24B 15/167 - Caractéristiques chimiques du tabac ou des succédanés du tabac des succédanés du tabac sous forme liquide ou vaporisable, p. ex. compositions liquides pour cigarettes électroniques
A24B 15/34 - Traitement du tabac ou des succédanés du tabac par des substances chimiques par des substances organiques comportant un carbocycle autre qu'un cycle aromatique à six chaînons
A24B 15/40 - Traitement du tabac ou des succédanés du tabac par des substances chimiques par des substances organiques comportant un hétérocycle comportant uniquement de l'oxygène ou du soufre comme hétéro-atomes
16.
ELECTRONIC CIGARETTE ATOMIZED LIQUID HAVING EFFECT OF INHIBITING MONOAMINE OXIDASES
An electronic cigarette atomized liquid having the effect of inhibiting monoamine oxidases. The electronic cigarette atomized liquid is prepared from the following components in parts by weight: 1-5 parts of ethyl vanillin, 1-5 parts of limonene, 1-5 parts of linalool, 0.2-3 parts of leaf alcohol, 0.2-3 parts of geraniol, 1-5 parts of methyl cinnamate, 1-5 parts of peppermint oil, and 0.5-3 parts of benzoic acid. The electronic cigarette atomized liquid has the effect of inhibiting monoamine oxidases, solves the problem of addiction caused by a large amount of electronic cigarette vapor needing to be vaped to reach satisfaction because the electronic cigarette atomized liquid containing nicotine on the current market is insufficient in monoamine oxidase inhibition activity, thereby gradually achieving vaping quitting, and also has the functions of memory enhancement, thinking improvement, anxiety resistance, and depression resistance after adding a monoamine oxidase inhibitor.
A24B 15/167 - Caractéristiques chimiques du tabac ou des succédanés du tabac des succédanés du tabac sous forme liquide ou vaporisable, p. ex. compositions liquides pour cigarettes électroniques
17.
ELECTRONIC CIGARETTE HAVING STRUCTURE CAPABLE OF SIMULTANEOUSLY BLOCKING LIQUID PATH AND TURNING OFF CIRCUIT OR OPENING LIQUID PATH AND TURNING ON CIRCUIT
An electronic cigarette having a structure capable of simultaneously blocking a liquid path and turning off a circuit or opening the liquid path and turning on the circuit. One end of a mouthpiece housing (1) of the electronic cigarette is sleeved in one end of a battery assembly housing (7); relative positions after the mouthpiece housing (1) is connected to the battery assembly housing (7) comprise a first position (A) and a second position (B), the second position (B) is a working position where the mouthpiece housing (1) is sleeved in the battery assembly housing (7), and the first position is a non-working position where the mouthpiece housing (1) is some distance away from the second position where the mouthpiece housing (1) is sleeved in the battery assembly housing (7). In the first position (A), a liquid guide valve (212) blocks a liquid guide valve seat (211) so that a liquid guide channel is blocked, and an electrode column (3) is out of contact with an electrode reed (92) so that a circuit is turned off; and in the second position (B), the liquid guide valve (212) is separated from the liquid guide valve seat (211) under the action of an ejector rod (213) so that the liquid guide channel is opened, and the electrode column (3) abuts against and is connected to the electrode reed (92) so that the circuit is turned on. The electronic cigarette has the following beneficial effects: when the electronic cigarette is in the first position (A), liquid to be atomized of the electronic cigarette is not prone to leakage, and power of the battery is not prone to loss, thereby facilitating long-term storage and long-distance transportation.
An electronic cigarette atomization liquid having an antidepressant effect, prepared from the following components in parts by weight: 0.1-4 parts of limonene, 0.1-5 parts of nicotine, 1-8 parts of menthol, 70-80 parts of propylene glycol, and 10-30 parts of glycerol. The electronic cigarette atomization liquid having the antidepressant effect overcomes the defects that existing electronic cigarette atomization liquids containing nicotine on the market do not have any antidepressant effect and depressive symptom alleviation effect; additionally, because limonene has an anti-inflammatory effect on lung inflammation, the inflammation and damage of lung, trachea, and bronchus caused by long-term smoking of smokers can be alleviated. In addition, a preparation method for the electronic cigarette atomization liquid having the antidepressant effect is provided.
A24B 15/167 - Caractéristiques chimiques du tabac ou des succédanés du tabac des succédanés du tabac sous forme liquide ou vaporisable, p. ex. compositions liquides pour cigarettes électroniques
19.
ELECTRONIC-CIGARETTE ATOMIZING LIQUID HAVING EFFECT OF INHIBITING ACTIVITY OF MONOAMINE OXIDASE
An electronic-cigarette atomizing liquid having an effect of inhibiting the activity of monoamine oxidase. The electronic-cigarette atomizing liquid is prepared from the following components, in parts by weight: 1-5 parts of limonene, 1-5 parts of linalool, 1-5 parts of vanillin, 0.3-3 parts of leaf alcohol, 0.3-3 parts of geraniol, 1-5 parts of methyl cinnamate, 1-5 parts of menthol, 1-5 parts of maltol, 1-5 parts of benzoic acid, 1-5 parts of Danshensu, 50-80 parts of propylene glycol and 10-30 parts of glycerol. The electronic-cigarette atomizing liquid has an effect of inhibiting monoamine oxidase. By means of the present invention, the problem whereby the nicotine-containing electronic-cigarette atomizing liquid currently on the market is inadequate in inhibiting the activity of monoamine oxidase and thus it is necessary to absorb a large amount of electronic-cigarette smoke to achieve a level of satisfaction is solved; the problem of eventually leading to addiction is solved and the effect of quitting smoking is gradually achieved; and the effects of improving memory, improving thinking, anti-anxiety and anti-depression of a monoamine oxidase inhibitor are also increased.
A24B 15/167 - Caractéristiques chimiques du tabac ou des succédanés du tabac des succédanés du tabac sous forme liquide ou vaporisable, p. ex. compositions liquides pour cigarettes électroniques
20.
ELECTRONIC-CIGARETTE ATOMIZATION DEVICE AND ELECTRONIC-CIGARETTE ATOMIZER HAVING SAME
An electronic-cigarette atomization device and an electronic-cigarette atomizer having same. The electronic-cigarette atomization device comprises an atomization base (1), electrode columns (2), a heating mesh (3) and a soft liquid guide sheet (4), wherein the atomization base (1) comprises an atomization cavity (10), which is recessed downwards; first air intake through holes (11) are provided in the bottom of the atomization cavity (10); two electrode columns (2) are provided and are arranged on two sides of the bottom of the atomization cavity (10), bottom ends of the electrode columns (2) penetrate the bottom of the atomization base (1), and upper ends of the electrode columns (2) extend upwards and are arranged above the atomization cavity (10); the heating mesh (3) is transversely mounted on the upper ends of the two electrode columns (2), and the heating mesh (3) comprises electrically conductive portions (31) on two sides and a heating portion (32) in the middle; the electrically conductive portions (31) are fixedly connected to the upper ends of the electrode columns (2); and the soft liquid guide sheet (4) is laid flat on an upper surface of the heating mesh (3). The electronic-cigarette atomization device and the electronic-cigarette atomizer having same have the beneficial effects of reducing the production cost and having a good atomization effect.
A vaporizer having a vaporization cavity at an inner bottom of a vaporization core comprises a housing (1), which includes a mouthpiece end (11) provided with a mouthpiece tube (111), and a connecting end (12) closed by a bottom cap (3). A vaporizing assembly (2) is provided between the mouthpiece tube (111) and the bottom cap (3) inside the housing (1). The vaporizing assembly (2) comprises a vaporization core (21), and a vaporizing base (23). The lower portion of the vaporization core (21) is inserted in a central accommodation cavity (232) of the vaporizing base (23), and the upper end of the vaporization core (21) is sleeved on the lower end of the mouthpiece tube (111). The vaporization cavity is provided at the inner bottom of the vaporization core (21), and the vaporization core (21) is provided with a central through-hole extending vertically.
The present invention relates to a use of jojoba oil in preparation of e-liquid of an electronic cigarette. The jojoba oil is used as a solvent in the process of preparing the e-liquid of an electronic cigarette. The present invention has the beneficial effects that the jojoba oil, which is used as a solvent of the e-liquid of an electronic cigarette to replace propylene glycol and glycerol or reduce the usage thereof, has no toxicity, has the functions of carrying and atomizing nicotine, can well protect the lung, bronchial and tracheal cells, has no stimulation effect on skin, and shows high resistance to rancidity.
A24B 15/167 - Caractéristiques chimiques du tabac ou des succédanés du tabac des succédanés du tabac sous forme liquide ou vaporisable, p. ex. compositions liquides pour cigarettes électroniques
A61P 25/34 - Médicaments pour le traitement des troubles du système nerveux des états d'abus ou de dépendance au tabac
A heating piece (1) for and a heating body for an atomization core. The heating piece (1) for an atomization core comprises a first electrode sheet (11), a second electrode sheet (12), and a heating mesh (2) connected therebetween. The heating mesh (2) comprises at least two electrically conductive heating lines (21) arranged in parallel in the longitudinal direction; each two adjacent electrically conductive heating lines (21) have an axisymmetric zigzag path shape; a plurality of thermally conductive lines (22) are connected in the lateral direction between different equipotential points on each two adjacent electrically conductive heating lines (21); the thermally conductive lines (22) are used for conducting and dissipating heat from the electrically conductive heating lines (21); the electrically conductive heating lines (21) and the thermally conductive lines (22) are connected to each other to form mesh lines which are approximately uniformly distributed; gaps are provided among the mesh lines. The present invention has the beneficial effects that the heating meshes (2) of the heating piece (1) and of the heating body have mesh lines which are approximately uniformly distributed and generate uniform heat when electrified; the heat of the mesh lines can be quickly and uniformly distributed to the whole heating mesh (2), rapidly atomizing an large amount of atomization liquid in a timely manner and realizing good atomization effects.
An electronic cigarette atomizer for a solid e-liquid, comprising an upper assembly (100) and a lower assembly (200) connected to each other. The upper assembly (100) comprises a mouthpiece housing (1), a mouthpiece base (2), and an elastic push rod mechanism (3) connected below the mouthpiece base (2); the elastic push rod mechanism (3) comprises a spring (31), a push rod (32), and a push rod head (33) connected to the bottom of the push rod (32); the lower assembly (200) comprises an outer tube (4), an inner tube (5) nested in the outer tube (4), a porous atomizing core (6) provided inside the inner tube (5), and a connecting member (7) connected to the bottom end of the outer tube (4); a gap between the outer tube (4) and the inner tube (5) forms a vapor discharge channel (45); the push rod head (33) extends into the inner tube (5); an e-liquid storage cavity (50) for accommodating a solid e-liquid is provided inside the inner tube (5) and between the push rod head (33) and the porous atomizing core (6); and the push rod (32) pushes the solid e-liquid under the action of the elastic force of the spring (31), so that the solid e-liquid abuts against the upper portion of the porous atomizing core (6). The beneficial effects are that: the elastic push rod mechanism (3) provided in the electronic cigarette atomizer can solve the problems of poor atomization and dry puffs, and the use of the porous atomizing core (6) can avoid e-liquid leakage.
A control method for an electronic cigarette having a child-lock function. A child-lock control program is set in a microcontroller in an electronic cigarette, and the child-lock control program comprises the following unlocking steps: S1, when an electronic cigarette is in a locked state, a microcontroller monitoring, in real time, a signal indicating that a touch key is touched; S2, the microcontroller determining whether a duration, in which the touch key is touched, exceeds a first set time; S3, the microcontroller controlling an LED indicator lamp to be turn on, with a turn-on time being a second set time, and also continuing monitoring whether the touch key is touched; S4, the microcontroller determining whether the number of times the touch key is continuously touched within the second set time reaches a set number of times; and S5, the microcontroller controlling the electronic cigarette to be unlocked, and making the LED indicator lamp be turn on to give a prompt, or making a vibration motor vibrate to give a prompt, so that the electronic cigarette enters a standby state. By means of the method, a child can be effectively prevented from vaping an electronic cigarette without permission, thereby protecting the child from the harm of vaping the electronic cigarette.
An atomizing assembly (3) and an electronic cigarette atomizer with the atomizing assembly (3). The atomizing assembly (3) comprises an atomizing seat (31), a heating body (32) and a liquid guide body (33), wherein the atomizing seat (31) comprises an atomizing groove (310) which is provided downwards in an upper end surface of the atomizing seat; a first air intake through hole (311) is provided in the bottom of the atomizing groove (310); the heating body (32) comprises two electrode sheets (321) and a heating mesh sheet (322) which are integrally constructed; the two electrode sheets (321) are respectively connected to and arranged on two sides of the heating mesh sheet (322); the heating body (32) is arranged on the upper end surface of the atomizing seat (31) and positioned above the atomizing groove (310); the liquid guide body (33) is arranged on the heating body (32); and at least one side of the liquid guide body (33) does not cover the atomizing groove (310). The heating body (32) of the atomizing assembly (3) has a relatively large heating area and can come into full contact with the liquid guide body (33), such that electronic cigarette liquid can be rapidly atomized and be discharged after being fully mixed with air in the atomizing groove (310); therefore, the atomizing efficiency can be improved, the atomization amount can be increased, and the atomizing effect is good.
The disclosure provides an electronic vaporizing device with digital air pressure sensor chip and a controlling method thereof. The device comprises a vaporizer part, a power output unit, a microcontroller, and a digital air pressure sensor chip. The digital air pressure sensor chip is disposed in the air inlet channel of the vaporizer part, and comprises an air pressure sensing unit for detecting air pressure difference, an air pressure processing unit, a switching signal output unit, and a digital signal output unit. The switching signal output unit is configured to output a switch signal to activate the microcontroller which is in a sleep state, when the air pressure difference value reaches the set activation threshold. The output switch unit is configured to control the power output unit to provide or not provide output voltage when the air pressure difference value reaches or is lower than the set working threshold.
An electronic cigarette having a tubular atomizing core (6), comprising a mouthpiece (1), a housing (2), a base (5), and a battery assembly (4) and an atomizing assembly (3) provided in the housing (2). The mouthpiece (1) is disposed at the upper end of the housing (2); the base (5) is disposed at the lower end of the housing (2); the battery assembly (4) comprises a battery (41) and an airflow sensor (42); the atomizing assembly (3) comprises the tubular atomizing core (6); the tubular atomizing core (6) comprises an atomizing tube (61), liquid guide cotton (62), a heating sheet (63), and a hollow tube plug (64); the heating sheet (63) is composed of a sheet-shaped heating resistor having a conductive path; a resistance lead (631) is connected to the two sides of the heating sheet (63); the heating sheet (63) is rolled into a tubular shape having two unconnected sides; the outer wall of the heating sheet (63) is coated with the liquid guide cotton (62) and then is sleeved in the middle of the inner wall of the atomizing tube (61); an inverted U-shaped notch (611) is formed in the tube wall of the atomizing tube (61); the hollow tube plug (64) is sleeved at the lower end of the atomizing tube (61); and an inner wall portion (6422) of the hollow tube plug (64) supports the liquid guide cotton (62) upwards. The electronic cigarette has the beneficial effects that the atomizing amount is large, the smoking mouthfeel is consistent, the taste is pure, the burnt smell is prevented from being suctioned out, and better use experience is brought to a user.
A tubular atomization core, comprising an atomization tube (1), liquid guide cotton (2), a heating sheet (3), and a hollow tube plug (4), wherein the heating sheet (3) is composed of a sheet-shaped heating resistor, which is provided with an electrically conductive path; two sides of the heating sheet (3) are connected to and provided with resistor leads (31); the heating sheet (3) is rolled into a tubular shape, two sides of which are not connected; the liquid guide cotton (2) wraps an outer wall of the heating sheet (3), and the heating sheet is then sleeved in the middle of an inner wall of the atomization tube (1); a tube wall of the atomization tube (1) is provided with an inverted U-shaped notch (11); the hollow tube plug (4) is sleeved on an inner wall and an outer wall of a lower end of the atomization tube (1); and a wall portion of the side of the hollow tube plug (4) sleeved on the inner wall of the atomization tube (1) upwardly abuts and supports the liquid guide cotton (2). The tubular atomization core has a simple structure and is easily assembled to an atomizer, such that the production efficiency can be improved. In addition, the tubular atomization core has a relatively large amount of atomization, the vaping taste is consistent, the flavor is pure, a burnt smell is prevented from being generated during vaping, and a better usage experience is provided to a user.
A simple electronic cigarette, comprising a housing (1) provided with a mouthpiece (10) at the upper end and an opening at the lower end. An atomization assembly (3) and a battery assembly (4) are provided in the housing (1) from top to bottom; the atomization assembly (3) comprises an outer liquid storage tube (32), an upper cover (31), a lower cover (33), an atomization tube (34, 35), and an atomization core (36); the upper cover (31) is provided at the upper end of the outer liquid storage tube (32); the lower cover (33) is provided at the lower end of the outer liquid storage tube (32); an upper cover through hole (310) is formed in the center of the upper cover (31); a lower cover through hole (330) is formed in the center of the lower cover (33); the upper end of the atomization tube (34) is connected to the upper cover through hole (310); the lower end of the atomization tube (34) is connected to the lower cover through hole (330); symmetrical liquid inlet holes (350) are formed in the middle section of the atomization tube (34, 35); the battery assembly (4) comprises a battery (41), a battery holder (42), and an airflow sensor (43); the upper end of the battery holder (42) supports the lower cover (33) upwards; and the lower end of the battery holder (42) is fitted over the opening of the housing (1). The beneficial effects of the present invention are that: by means of improvement of the overall structure of the electronic cigarette, internal components can be reduced, such that the structure is simple, a production technological process is reduced, the production efficiency is improved, costs are greatly reduced, and impure taste caused by blockage of the atomization core (36) can be prevented.
The disclosure provides a vaporizer having an integrated vaporizing assembly, which comprises a housing having a connecting end provided with an opening, and an integrated vaporizing assembly. The integrated vaporizing assembly is disposed into the housing via the opening. The integrated vaporizing assembly comprises, from top to bottom, a vaporizing core base, a vaporizing core, and a base part connected with the vaporizing core base. The lower portion of the vaporizing core base is provided with a cavity concaving upward, in which the vaporizing core is mounted. The vaporizing core comprises a vaporizing core body for absorbing the to-be-vaporized liquid and a heating resistance for heating the to-be-vaporized liquid. The vaporizing core body is provided with a vaporizing passage. An air chamber in communication with the vaporizing passage is further provided between the vaporizing core and the base part. The base part closes the opening of the housing.
A soft atomization core, comprising a support (1), a heating body (2) and a soft liquid guide body (3), wherein the support (1) comprises an upper plane (11), a lower plane (12), and a support through hole (10) formed in the middle; the heating body (2) comprises a sheet-shaped heating resistor (21) provided with a conductive path, and the heating resistor (21) is arranged in the support through hole (10) and is flush with the upper plane (11) of the support (1); and the soft liquid guide body (3) is arranged on the upper plane (11) of the support. The soft atomization core has a low material cost, a simple structure, a high production efficiency, and an adequate liquid supply; provides a large smoke amount, and a pure flavor; and does not easily produce a burnt taste, and provides a good usage experience for a user.
Disclosed in the prevent invention is an electronic cigarette atomizer having a soft atomization core. The electronic cigarette atomizer comprises a mouthpiece shell, an atomization head assembly sleeved on an inner wall of the mouthpiece shell, and a bottom cap provided at the bottom of the mouthpiece shell, wherein the atomization head assembly comprises an atomization upper base, a soft atomization core and an atomization bottom base; the atomization upper base is connected to the atomization bottom base one on top of the other; an atomization core accommodating cavity is upwardly recessed in the bottom of the atomization upper base; the soft atomization core is accommodated in the atomization core accommodating cavity; the atomization bottom base upwardly supports the bottom of the soft atomization core; the soft atomization core comprises an atomization core support, a heating element and a soft e-liquid guide; the atomization core support comprises an upper planar face, a lower planar face, and a support through hole provided in the middle; the heating element comprises a sheet-like heating resistor provided with a conductive path; the heating resistor is arranged in the support through hole; and the soft e-liquid guide is arranged on top of the heating resistor. The atomizer has the beneficial effects of sufficient e-liquid supply and a large vapor amount, a pure flavor and good consistency, being less prone to generating a burnt smell, a good usage experience, low cost, and high production efficiency.
The present disclosure discloses a nanoporous ceramic for an atomization core, and a preparation method thereof. The nanoporous ceramic includes: nano-silica 1 to 60 parts, a ceramic powder 10 to 80 parts, a pore-forming agent 1 to 50 parts, and a sintering additive 1 to 40 parts. The preparation method includes: (1) weighing raw materials, and mixing and ball-milling the raw materials in a ball mill; (2) bake-drying the ball-milled raw materials to obtain a dried mixed powder; (3) adding the dried mixed powder to molten paraffin under stirring, and continuously stirring a resulting mixture to obtain a paraffin slurry; (4) injecting the paraffin slurry into a mold, cooling the mold for forming, and performing demolding to obtain a paraffin mold; (5) preheating the paraffin mold for paraffin removal to obtain a paraffin-removed sample; and (6) sintering and cooling the paraffin-removed sample to obtain the nanoporous ceramic.
An atomizer for transverse liquid guide, comprising a housing (1). A liquid storage cavity (13) is provided on an upper part inside the housing (1); a base (4) and an electrode base (5) which are vertically connected is sleeved on a bottom part inside the housing (1); an airflow channel (7) which is vertically communicated and is separated from the liquid storage cavity (13) is provided at the center of the housing (1); an atomization cavity (201) is provided in the airflow channel (7); an atomization core (3) is transversely provided in the atomization cavity (201); the atomization core (3) is provided with a transverse central through hole (30); both ends of the central through hole (30) are communicated with the liquid storage cavity (13); the atomization core (3) comprises a porous body (31); at least one surface of the porous body (31) is provided as an atomization surface (311); a heating layer (32) is laid on the atomization surface (311); electrode disks (33) are respectively connected to two distal ends of the heating layer (32); the heating layer (32) is provided with an atomization through hole (320) allowing for an atomized liquid or aerosol to flow out; the atomized liquid can transversely enter the central through hole (30) and permeate into the atomization surface (311) of the porous body (31); when the heating layer (32) is energized to generate heat, the atomized liquid is evaporated into an aerosol and is discharged from the airflow channel (7). The beneficial effects are that rapid and sufficient liquid supply is achieved, enough atomization amount is ensured, and the structure is simple, so that the automatic production of atomizers is facilitated.
An atomization core provided with a liquid-guiding central through-hole, comprising a porous body (1) through which an atomization liquid can penetrate; the interior of the porous body (1) is provided with a central through-hole (10), and at least one surface of the porous body (1) is an atomization surface (11); the atomization surface (11) is coated with a heating layer (2), the two distal ends of the heating layer (2) are each connected to an electrode disc (3), and the heating layer (2) is provided with atomization through-holes (20); the atomization liquid can enter the porous body (1) by means of two ends of the central through-hole (10) and penetrate into the atomization surface (11), and the atomization liquid on the atomization surface (11) evaporates into vapor and is emitted from the atomization through-holes (20) when the heating layer (2) is electrified and heated. The benefits of the described atomization core lie in liquid guiding being rapid and complete, a sufficient amount of atomization being guaranteed, the structure being simple, and the atomization core being conveniently assembled into an atomizer, facilitating automatic manufacturing.
An anti-counterfeiting electronic cigarette having a limited service life, and a control method therefor. The electronic cigarette comprises a liquid storage device (1), an atomizer (2) and a battery assembly (3), which are detachably connected in sequence, wherein the liquid storage device (1) is provided with an NFC electronic tag and a first information memory, the NFC electronic tag is internally provided with a dynamic anti-counterfeiting code, and the first information memory is used for storing data which comprises a first simulated e-liquid consumption count; the atomizer (2) is provided with an ID encryption unit and a second information memory, the ID encryption unit is provided with an identity identification code, and the second information memory is used for storing data which comprises a second simulated e-liquid consumption count; and the battery assembly (3) is provided with a microcontroller, an airflow sensor and an NFC antenna, the microcontroller comprising an NFC identification module, an NFC read-write control module, an ID encryption unit communication module, an ID encryption unit identification module and an ID encryption unit read-write control module. The present invention has the advantages of an atomizer being capable of being used multiple times to avoid waste, avoiding dry burn damage, and being capable of limiting the service life of the atomizer and preventing the use of counterfeit products.
An electronic vaporizing device capable of analyzing solution composition and content comprises a cartridge and a battery device comprising a connector, a battery housing, an electrically connected battery, a circuit control board, a light source element, and a spectral sensor element. The circuit control board is arranged with a microcontroller and a power control circuit. The microcontroller comprises a storage unit, an analysis and comparison unit, and a control unit. The storage unit stores calibration spectral information related to a plurality of sample solutions. The light source element emits light rays which may pass through the transparent window and to-be-vaporized solution and then received by the spectral sensor element. After the spectral sensor element receives light rays, it sends corresponding detection spectral information. The analysis and comparison unit performs analysis and comparison of the detection spectral information with the calibration spectral information, and the control unit sends a control signal.
A split-type atomizer capable of preventing liquid leakage, the split-type atomizer comprising a liquid storage member (100) and an atomization member (200), which are detachably connected to each other, wherein the liquid storage member (100) is internally provided with a ventilation tube (3), and a movable tube (4), which is axially positioned and is circumferentially rotatable, is sleeved in the ventilation tube (3); and the atomization member (200) comprises an atomization tube (5) and an atomization core (6) provided in the atomization tube (5). When the liquid storage member (100) and the atomization member (200) are assembled, the atomization tube (5) is sleeved in the movable tube (4) from the outside and is circumferentially locked, and then same drives the movable tube (4) to circumferentially rotate by a set angle to a fitting position, so that a liquid outlet (30) provided in the ventilation tube (3), a liquid through port (40) provided in the movable tube (4), and a liquid inlet (50) provided in the atomization tube (5) are in communication with each other. When the liquid storage member (100) and the atomization member (200) are disassembled, the atomization tube (5) reversely drives the movable tube (4) to rotate to a detaching position, so that the liquid outlet (30) and the liquid through port (40) are staggered and not in communication with each other; and after the atomization tube (5) is pulled out of the movable tube (4), the liquid outlet (30) and the liquid through port (40) are still not in communication with each other. The benefit of the split-type atomizer lies in that, during use, the atomization member (200) and the liquid storage member (100) can be detached from each other without liquid leakage.
An atomization core with a nano metal coating layer (2), the atomization core comprising a porous body (1) and a heating body, wherein two ends of the heating body are connected to and provided with a resistance lead or an electrode plate; the porous body (1) is provided with a plurality of micropores (10) for absorption, penetration and conduction of an atomization liquid; the porous body (1) comprises at least one evaporation surface (11) for heating and evaporating the atomization liquid to generate an aerosol; and the heating body comprises the nano metal coating layer (2) arranged on the evaporation surface (11) of the porous body (1), wherein the nano metal coating layer (2) is provided with through film holes (20) at positions corresponding to the micropores (10) in the evaporation surface (11), two distal ends of the nano metal coating layer (2) are electrically connected to the resistance lead or the electrode plate, and the nano metal coating layer (2) generates heat and evaporates the atomization liquid after being energized. The atomization core has the beneficial effects of: the actual effective heating area being large, thus the atomization amount being greatly improved; carbon deposition and liquid leakage not being prone to occurring; there being no unbalanced thermal stress when the atomization core operates at a high temperature; and the nano metal coating layer (2) having no risk of disconnection, such that the consistency of a product during use is improved, thus bringing a good usage experience to a user.
Disclosed in the present invention is an atomization core having directional micropores. The atomization core is used for an atomizer of an electronic atomization apparatus, and the atomization core comprises a liquid guide body and a heating body, wherein the liquid guide body comprises a liquid absorption surface and an atomization surface; the heating body is arranged on the atomization surface of the liquid guide body; and the liquid guide body is provided with a plurality of directional micropores, which directly communicate with the atomization surface from the liquid absorption surface. The atomization core has the beneficial effects of: components of an atomization liquid not causing blockages in the directional micropores, such that the atomization amount can be increased, the degree of reduction of an aerosol can be increased, and a burnt smell is not easily generated when at a high temperature; and the liquid guide body being made of a monocrystalline silicon and a glass material, thus achieving high purity with few impurities, and not precipitating components, such as a heavy metal, which are harmful to health.
A transverse atomizing core, comprising a base body (1), a tubular porous body (2) and a heating body (3). An accommodating cavity (10) is formed in the base body (1). A liquid inlet (11) in communication with the accommodating cavity (10) is formed in the upper portion of the base body (1). Multiple micropores for absorbing and conducting atomized liquid are provided in the tubular porous body (2). The tubular porous body (2) comprises an atomizing hole (20) having a hollow middle portion. The heating body (3) is arranged on the inner wall of the atomizing hole (20). The tubular porous body (2) is transversely arranged in the accommodating cavity (10) of the base body (1). The two ends of the tubular porous body (2) are tightly connected to the inner walls of the two sides of the accommodating cavity (10). The two sides of the base body (1) are respectively provided with vent holes (12) in communication with the atomizing hole (20). The transverse atomizing core has the benefits of a simple structure, improved production efficiency, sufficient liquid supply, large smoke amount, little scorch smells, no inhalation of high-temperature smoke, prevention of liquid leakage, and good heat insulation effects.
An atomization core having a wave-shaped evaporation surface, comprising a microporous body (1) used for absorbing and conducting an atomized liquid, and a heating body (2) used for heating the atomized liquid. The microporous body (1) comprises a liquid absorption surface (11) and an evaporation surface (12), the heating body (2) is disposed on the evaporation surface (12), and the evaporation surface (12) is provided with a wave-shaped concave-convex wall portion (120). The beneficial effects are that when airflow passes through the wave-shaped evaporation surface (12), the wave-shaped concave-convex wall portion (120) causes the airflow to generate gentle and sharp fluctuations to form turbulent flow, and aerosol and heat generated by the evaporation surface (12) are quickly taken away by the airflow under the interference of the turbulent flow, such that the atomization efficiency can be improved, a burnt smell caused by deposition and burning of part of the atomized liquid due to high-temperature aggregation can be avoided, and the damage of the atomization core due to high-temperature ablation can be avoided, thereby improving use experience of customers.
An atomizer having a wave-shaped atomization air passage (42), comprising an atomization core (3), a liquid storage cavity (6) and the wave-shaped atomization air passage (42). The liquid storage cavity (6) is used for storing an atomization liquid; the atomization core (3) is provided between the liquid storage cavity (6) and the wave-shaped atomization air passage (42); the atomization core (3) comprises a porous body (32) and a heating body (33); the porous body (32) comprises a liquid absorption surface (321) and an evaporation surface (322); the liquid absorption surface (321) is communicated with the liquid storage cavity (6) for absorbing and conducting the atomization liquid; the evaporation surface (322) is communicated with the wave-shaped atomization air passage (42) for generating aerosol; the heating body (33) is provided on the evaporation surface (322); and a wave-shaped concave-convex bottom wall (41) is provided in the wave-shaped atomization air passage (42) along the flowing direction of airflow.
An atomizer having a hollowed-out atomization cover, the atomizer comprising a mouthpiece cap (1) and an atomization shell (2), wherein an upper end of the mouthpiece cap (1) is provided with a mouthpiece hole (10); the atomization shell (2) comprises an inhalation end (21) and an open end (22); the mouthpiece cap (1) is sleeved on the inhalation end (21) of the atomization shell (2); the inhalation end (21) of the atomization shell (2) is closed and is centrally provided with a vaping tube (210) that extends downward into the atomization shell (2); the atomization shell (2) is internally provided with a hollowed-out atomization cover (3), a tubular atomization core (4) and a base (6); the hollowed-out atomization cover (3) is internally provided with an accommodating cavity (30), and an intermediate wall portion of the hollowed-out atomization cover (3) is provided with a hollowed-out opening (320), the accommodating cavity (30) being in communication with a liquid storage cavity (23) in an open manner through the opening (320), and the tubular atomization core (4) is vertically arranged in the accommodating cavity (30); an upper end of the tubular atomization core (4) is connected to the hollowed-out atomization cover (3) and in communication with the vaping tube (210), and a lower end thereof is in communication with a first air intake hole (60); and an outer wall of the middle of the tubular atomization core (4) is completely open to the accommodating cavity (30). The beneficial effect lies in that the hollowed-out atomization cover (3) is provided with the accommodating cavity (30) and the opening (320), so that an atomization liquid in the liquid storage cavity (23) can be quickly replenished to the surface of the tubular atomization core (4) to prevent dry burning of the tubular atomization core (4) during operation.
An atomization core having a microporous heating piece (2), used for an atomizer of an electronic atomization device. The atomization core comprises a liquid guiding body (1) and a heating piece (2). The liquid guiding body (1) is a solid microporous structure and can be used for absorbing, guiding, and storing an atomization liquid. The liquid guiding body (1) is at least provided with an atomization surface (10) for heating and evaporating the atomization liquid and then generating an aerosol. The heating piece (2) is arranged on the atomization surface (10), and a plurality of micropores penetrating through the heating piece (2) are formed on the heating piece (2). In the atomization core having the microporous heating piece (2), the heating piece (2) is provided with micropores, such that atomization is smooth, the atomization efficiency can be greatly improved, and because one part of the blank body of the liquid guiding body (1) can permeate into the microporous structure, two parts are more tightly and firmly combined, thereby preventing deformation caused by high temperature during operation.
An atomization core having an atomization groove (10), disposed in an electronic atomization device and comprising a liquid guiding body (1) and a heating element (2). The liquid guiding body (1) is used to absorb and conduct an atomization liquid, and one side of the liquid guiding body (1) is provided with an atomization groove (10). A portion of the heating element (2) is embedded in the liquid guiding body (1), while another portion is exposed at the bottom of the atomization groove (10). The heating element (2) can heat atomization liquid in the liquid guiding body (1) when powered on. The atomized liquid evaporates from the surface of the exposed portion of the heating element (2) into a mist and is emitted by means of the atomization groove (10). The atomization core having an atomization groove (10) has the benefit of a portion of the heating element (2) being embedded in the liquid guiding body (1), ensuring close combination of the heating element (2) and the liquid guiding body (1), so that deformation of the heating element (2) when heating at a high temperature is restrained by the liquid guiding body (1). Furthermore, another portion is exposed at the bottom of the atomization groove (10), such that the heating element (2) can still contact the air. Mist can directly evaporate on the surface of the heating element (2) at the bottom of the atomization groove (10), thereby avoiding a reduction in atomization efficiency.
An atomization body being convenient to assemble and having a heating metal mesh (22). The atomization body comprises an atomization housing (1) and an atomization core (2) provided in the atomization housing (1), wherein the atomization housing (1) is internally provided with an atomization channel (13) that penetrates longitudinally; an atomization core accommodation cavity (14) is expanded in the middle of the atomization channel (13), and the atomization core (2) is arranged in the atomization core accommodation cavity (14); a wall portion of the atomization core accommodation cavity (14) is provided with a liquid supply hole (140); the atomization housing (1) is provided with a vapor output interface (15) at the upper end thereof, and an air intake interface (16) at the lower end thereof; the vapor output interface (15) and the air intake interface (16) are respectively in communication with the atomization channel (13); the atomization core (2) comprises a liquid store (21) and a heating metal mesh (22); electrode leads (23) are connected to two ends of the heating metal mesh (22); and the electrode leads (23) are led out through the lower end of the atomization housing (1). The atomization body has the beneficial effects of a simple structure, being convenient to assemble into an atomizer, and being beneficial for realizing automatic production.
An atomization body convenient to assemble and having a heating ceramic core (22), comprising an atomization cover (1) and an atomizing core (2) arranged therein. An atomization channel (13) longitudinally penetrating is provided inside the atomization cover (1). An atomizing core accommodation cavity (14) is arranged in the middle of the atomization channel (13) in an extending manner. The atomizing core (2) is provided in the atomizing core accommodation cavity (14). The wall part of the atomizing core accommodation cavity (14) is provided with a liquid supply hole (140). The upper end of the atomization cover (1) is provided with a vapor outlet port (15) and the lower end of the atomization cover (1) is provided with an air inlet port (16). The vapor outlet port (15) and the air inlet port (16) are respectively communicated with the atomization channel (13). The atomizing core (2) comprises a liquid storage body (21) and the heating ceramic core (22). Both ends of the heating ceramic core (22) are connected to electrode leads (23). The electrode leads (23) are led out by means of the lower end of the atomization cover (1). The atomization body has the beneficial effects of being simple in structure, convenient to assemble into an atomizer, and beneficial to realizing automated production.
An easy-to-assemble atomization body provided with a spiral heating wire, said atomization body comprising an atomization cover (1) and an atomization core (2) provided in the atomization cover (1); an atomization channel (13) that penetrates through longitudinally is disposed at the interior of the atomization cover (1); the middle of the atomization channel (13) expands to form an atomization core accommodating cavity (14), the atomization core (2) is disposed in the atomization core accommodating cavity (14), and a wall part of the atomization core accommodating cavity (14) is provided with a liquid supply hole (140); the upper end of the atomization cover (1) is provided with a mist discharge interface (15) and the lower end is provided with an air intake interface (16); the mist discharge interface (15) and the air intake interface (16) each communicate with the atomization channel (13); the atomization core (2) comprises a liquid storage body (21) and a spiral heating wire (22); both ends of the spiral heating wire (22) are provided with an electrode lead (23), and the electrode leads (23) are led out from the lower end of the atomization cover (1). The easy-to-assemble atomization body provided with a spiral heating wire has the advantages of a simple structure and being easy to assemble into an atomizer, thereby facilitating automated production.
An electronic atomization device easy for liquid injection, comprising a mouthpiece (1), a hole plug (2), a liquid storage tube (3), a porous body atomization core (4), an atomization core sealing element (5), an atomization core support (6), a battery tube (7), and a battery (8). The lower part of the mouthpiece (1) is sleeved on the inner wall of the upper end of the liquid storage tube (3). The upper part of the battery tube (7) is sleeved on the outer wall of the lower end of the liquid storage tube (3). The battery (8) is sleeved in the battery tube (7). A mouthpiece hole (10) passing through the top and bottom is provided in the mouthpiece (1). The upper part of the hole plug (2) is sleeved on the lower part of the mouthpiece hole (10). A longitudinal partition plate (30) is provided in the liquid storage tube (3). The longitudinal partition plate (30) divides a tube hole of the liquid storage tube (3) into a large tube hole (31) and a small tube hole (32). The upper section of the large tube hole (31) is provided with a transverse partition plate (33). A liquid inject hole (330) is formed on the transverse partition plate (33). The bottom of the hole plug (2) covers the liquid injection hole (330). The porous body atomization core (4) is sleeved on the lower end of the large tube hole (31). The atomization core support (6) is sleeved on the inner wall of the lower end of the liquid storage tube (3) and supports the porous body atomization core (4) and the atomization core sealing element (5) upwards. The large tube hole (31) is located in a cavity between the transverse partition plate (33) and the porous body atomization core (4) to form a liquid storage cavity (34). The small tube hole (32), a radial hole (21) and a central hole (20) of the hole plug (2), and the mouthpiece hole (10) form a smoke channel (35).
A24F 40/10 - Dispositifs utilisant des précurseurs inhalables liquides
A24F 40/48 - Moyens de transfert de fluide, p. ex. pompes
A61M 11/02 - Pulvérisateurs ou vaporisateurs spécialement destinés à des usages médicaux agissant par pression d'air sur les liquides à pulvériser ou vaporiser
A61M 15/06 - Appareils à inhalation en forme de cigares, de cigarettes ou de pipes
Disclosed is an easy-injection atomizer, comprising a mouthpiece, a hole plug, an e-liquid storage tube, a porous atomizing core, an atomizing core seal, and a connecting seat. The lower part of the mouthpiece is sleevingly connected to an inner wall of the upper end of the e-liquid storage tube, and the upper part of the connecting seat is sleevingly connected to an inner wall of the lower end of the e-liquid storage tube. The mouthpiece is internally provided with a mouthpiece hole which penetrates up and down, and the upper part of the hole plug is sleevingly connected to the lower part of the mouthpiece hole. The interior of the e-liquid storage tube is axially provided with a longitudinal partition plate. The longitudinal partition plate divides a tube hole of the e-liquid storage tube into a large tube hole and a small tube hole. An upper section of the large tube hole is provided with a transverse partition plate, the transverse partition plate being provided with an e-liquid injection hole. The bottom part of the hole plug abuts against the transverse partition plate and tightly covers the e-liquid injection hole, the upper part of the hole plug is provided with a central hole, and the lower part is provided with a radial hole. The porous atomizing core is sleevingly connected to the lower end of the large tube hole, and the atomizing core seal is provided between the porous atomizing core and an inner wall of the large tube hole. A cavity in the large tube hole located between the transverse partition plate and the porous atomizing core forms an e-liquid storage cavity. The small tube hole, the radial hole of the hole plug, the central hole, and the mouthpiece hole form a vapor discharge channel.
An aerosol generation device having an induction heating tube. The aerosol generation device comprises an outer tube (1), an electromagnetic coil (2), an insulating tube (3), an induction heating tube (4), an inner tube (5) and a bottom cover (6) which are sleeved from outside to inside, wherein the inner tube (5) is provided with an internal cavity for accommodating a solid fume-generating material; the electromagnetic coil (2) surrounds an outer wall of the insulating tube (3) in an axial direction and can heat the induction heating tube (4) when same is energized; a plurality of outer ribs are provided on an outer side wall of the induction heating tube (4) in a protruding manner; a gap between the insulating tube (3) and the induction heating tube (4) forms a second airflow channel (82), and a gap between the induction heating tube (4) and the inner tube (5) forms a first airflow channel (81); when the induction heating tube (4) heats, external air sequentially enters the second airflow channel (82) and the first airflow channel (81) and is heated to form a hot airflow; and the hot airflow converges at the bottom of the inner tube (5) and then flows upwards through the interior of the solid fume-generating material to heat and bake the solid fume-generating material. The present invention has the beneficial effects of uniform heating, a better airflow heating effect, and not being prone to generating a burnt smell due to burning; moreover, a hand scalding sensation is avoided, and the user experience is good.
Disclosed is an electronic atomizer, comprising a housing, a sealing sleeve, a porous atomizing core, a limiting support, and a bottom cover. The upper end of the housing is provided with an inhalation port and the lower end is provided with an opening. The inhalation port extends downward in the housing to form a smoke inhalation tube. The sealing sleeve, the porous atomizing core, the limiting support, and the bottom cover are connected in sequence and sleeved inside the housing from bottom to top from the opening of the housing. The sealing sleeve, the inner wall of the housing, and the smoke inhalation tube define a liquid storage cavity. The upper end of the sealing sleeve is provided with a central vent hole connected to the smoke inhalation tube, the inner bottom of the sealing sleeve is sleeved on the porous atomizing core, the outer sidewall of the upper part of the sealing sleeve is sleeved on the inner sidewall of the housing, and the outer sidewall of the lower middle part of the sealing sleeve is sleeved on the inner sidewall of the limiting support. The outer sidewall of the limiting support is connected to the upper part of the bottom cover. The bottom cover is packaged in the opening of the housing, and the upper end of the bottom cover is provided with an atomizing cavity. The present invention has the following beneficial effects: atomized liquid that has not been atomized is not directly taken out by the airflow and inhaled into a mouth, thereby greatly improving the user experience.
The disclosure provides an electronic cigarette having an encryption chip for anti-counterfeiting and an anti-counterfeiting method thereof. The electronic cigarette comprises a vaporizer and a battery assembly connected in a detachable manner. The vaporizer comprises an encryption chip preset with an anti-counterfeiting code. The battery assembly comprises a battery and a control circuit board arranged with a microcontroller and a switching circuit. A circuit connection between the encryption chip and the microcontroller is achieved. The microcontroller and the encryption chip are configured in such a manner that, the microcontroller reads the anti-counterfeiting code preset in the encryption chip, compares it with the anti-counterfeiting code preset in the microcontroller, controls switching on of the switching circuit to allow the electronic cigarette to enter a standby state if the anti-counterfeiting code is correct, and controls switching off of the switching circuit if the standby time exceeds the preset standby time.
The disclosure provides an electronic cigarette vaporizer capable of preheating cigarette liquid, comprising a mouthpiece housing, wherein a mouthpiece opening is provided at the center of one end of the mouthpiece housing, and an opening is provided at the other opposite end thereof. The mouthpiece opening extends inwardly to connect with a vapor outlet tube. Inside the mouthpiece housing, a sealing sleeve, a heat conductive tube, a vaporizing unit, a vaporizing base, and a base member are provided and are connected sequentially from the side where the vapor outlet tube is provided to the side where the opening is provided. The liquid storage chamber is defined by the inner wall of mouthpiece housing, the outer wall of the vapor outlet tube, the outer wall of heat conductive tube, and the upper end of the vaporizing base.
An electronic atomization device capable of preventing repeated liquid injection usage, and a control method therefor. The electronic atomization device comprises a power supply apparatus (A) and an atomizer (B), which are detachably connected to each other, wherein the power supply apparatus (A) comprises a battery (A1) and a control circuit (A2); the control circuit (A2) comprises a micro-controller (1), a start switch (2), a power control module (3) and an atomization liquid consumption statistics module (4), which are electrically connected to each other; the atomizer (B) comprises a liquid storage cavity (B1) for storing an atomization liquid, an atomization resistor (5) and an ID chip (6), which is electrically connected to the control circuit; the ID chip (6) comprises an identification code storage module (61) and a cumulative number storage module (62); the identification code storage module (61) is used for storing an identification code which represents the unique identity code of the atomizer (B); the cumulative number storage module (62) is used for dynamically storing a cumulative amount of consumed atomization liquid; the power control module (3) outputs power to the atomization resistor (5); the atomization resistor (5) is powered on to operate, so as to atomize the atomization liquid; and the atomization liquid consumption statistics module (4) performs simulation calculation on the consumption of the atomization liquid, and accumulates the consumption of the atomization liquid to the cumulative number storage module (62) by means of the micro-controller (1).
An electronic atomization device for preventing repeated liquid injection use. The electronic atomization device comprises a power supply apparatus (A) and an atomizer (B) which are detachably connected. The power supply apparatus (A) comprises a battery (A1) and a control circuit (A2). The control circuit (A2) comprises a microcontroller (1), a resistance detection module (7), a starting switch (2), a power control module (3) and an atomization liquid consumption statistics module (4) which are electrically connected. The atomizer (B) comprises a liquid storage cavity (B1) which stores an atomization liquid, an atomization resistor (5) and an ID chip (6) electrically connected to the control circuit. The ID chip (6) comprises an identification code storage module (61) and a cumulative amount storage module (62). The identification code storage module (61) is used for storing an identification code representing the unique identity code of the atomizer (B). The cumulative amount storage module (62) is used for dynamically storing the cumulative amount of atomization liquid consumption. The power control module (3) outputs power to the atomization resistor (5). The atomization resistor (5) is electrified to atomize the atomization liquid. The atomization liquid consumption statistics module (4) simulates and calculates the consumption amount of the atomization liquid, and accumulates the consumption amount of the atomization liquid to the cumulative amount storage module (62) by means of the microcontroller (1).
Disclosed are an electronic cigarette, e-cigarette, for preventing minors from using and a control method thereof. The e-cigarette includes a vaporization assembly and a battery assembly, where the vaporization assembly is provided therein with a vaporization device; the battery assembly includes a casing, a holder, a battery, and a control circuit; the control circuit includes an output power control unit, a storage control unit, a personal biometric information acquisition unit, a prompt unit, and a communication unit; the personal biometric information acquisition unit is configured to acquire and input a user's personal biometric information into the storage control unit; and when the storage control unit stores or changes the user's authorized personal biometric information, the storage control unit utilizes an external device and special software that are authorized to complete the storage or change. The personal biometric information acquisition unit acquires personal biometric information for verification and authorization.
Disclosed is an electronic cigarette with a two-wire encryption chip for anti-counterfeiting, including an vaporizer assembly and a battery assembly, where the vaporizer assembly includes a two-wire encryption chip preset with an anti-counterfeit code and a heating element for heating and vaporizing cigarette liquid, the two-wire encryption chip is provided with two pins respectively connected to positive and negative electrodes of the vaporizer assembly, a circuit board is provided with a microcontroller preset with an anti-counterfeit code and a switching circuit, when the vaporizer assembly and the battery assembly are connected, the microcontroller reads the anti-counterfeit code preset in the two-wire encryption chip and compares it with the anti-counterfeit code preset in the microcontroller for verification, if the two anti-counterfeit codes are the same, the microcontroller turns on the switching circuit, and the electronic cigarette enters a standby state.
(1) Cannabidiol (CBD) oil for oral vaporizers for smoking; cartridges sold filled with chemical flavorings in liquid form for electronic cigarettes; cartridges sold filled with propylene glycol for electronic cigarettes; cartridges sold filled with vegetable glycerin for electronic cigarettes; cases for electronic cigarettes; chemical flavourings in liquid form used to refill electronic cigarette cartridges; electric cigarettes; electronic cigarette boxes; electronic cigarette cases; electronic hookahs; electronic smoking pipes; liquid nicotine solutions for use in e-cigarettes; liquid nicotine solutions for use in electronic cigarettes; liquid solutions for use in electronic cigarettes; oral vaporizers for smokers; oral vaporizers for smoking purposes; tetrahydrocannabinol [THC] oil for electronic cigarettes; tetrahydrocannabinol [THC] oil for oral vaporizers for smoking; vaping pens for smoking purposes
Cartomizers, namely, combination electronic cigarette refill cartridges sold empty and atomizers, sold as a component of electronic cigarettes; Cartridges sold filled with chemical flavorings in liquid form for electronic cigarettes; Cases for electronic cigarettes and electronic cigarette accessories; Devices for heating tobacco substitutes for the purpose of inhalation; Electric cigarettes; Electric cigars; Electronic cigarette atomizers sold empty; Electronic cigarette boxes; Electronic cigarette holders; Electronic cigarette liquid (e-liquid) comprised of flavorings in liquid form, other than essential oils, used to refill electronic cigarette cartridges; Electronic cigarette liquid (e-liquid) comprised of propylene glycol; Electronic cigarette liquid (e-liquid) comprised of vegetable glycerin; Electronic cigarettes; Electronic cigarettes for use as an alternative to traditional cigarettes; Electronic hookahs; Electronic shisha pipes; Electronic smoking pipes; Flavorings, other than essential oils, for use in electronic cigarettes; Liquid nicotine solutions for use in electronic cigarettes
71.
Electronic cigarette having electronic child lock and controlling method thereof
The disclosure provides an electronic cigarette having an electronic child lock and a control method thereof. The electronic cigarette comprises a vaporizer, a battery assembly, and an electronic child lock for controlling power-on and power-off of the electronic cigarette. The battery assembly comprises a battery and a control circuit board. The electronic child lock comprises a microcontroller, a switching circuit, a readable and writable NFC chip, and an NFC antenna, which are arranged on the control circuit board, and comprises a mobile device having NFC function and installed with an electronic cigarette application program. The application program reads the power-on password preset in the NFC chip and compares it with the power-on password preset in the electronic cigarette application program. If the power-on password is correct, the microcontroller controls switching on of the switching circuit to perform power-on operation such that the electronic cigarette enters the standby state.
The disclosure provides an electronic cigarette with NFC anti-counterfeiting code and an anti-counterfeiting method thereof. The electronic cigarette comprises a vaporizer arranged with an insertion portion, and a battery rod arranged with a receiving portion for accommodating the insertion portion. The battery rod comprises a battery, and a control circuit board arranged with a microcontroller and a switching circuit. When the insertion portion is inserted in the receiving portion such that the NFC tag and the NFC tag antenna of the insertion portion are close to the NFC card reader and the NFC card reader antenna of the receiving portion, the NFC card reader automatically reads the anti-counterfeiting code preset in the NFC tag and sends it to the microcontroller for identification. If the anti-counterfeiting code is correct, the microcontroller MCU controls switching on of the switching circuit to allow the electronic cigarette to enter a standby state.
G06K 7/10 - Méthodes ou dispositions pour la lecture de supports d'enregistrement par radiation électromagnétique, p. ex. lecture optiqueMéthodes ou dispositions pour la lecture de supports d'enregistrement par radiation corpusculaire
An integrated atomization core having a shell (1). The integrated atomization core is arranged in an atomization base of an electronic atomization apparatus, and comprises the shell (1), a liquid guide body (2), a heating wire (3) and electrode leads (4), wherein the shell (1) is provided with an upper opening (11), a lower opening (12) and a side wall through hole (10); the liquid guide body (2) is sleeved inside the shell (1); the side wall through hole (10) is blocked by the outer wall of the liquid guide body (2); the liquid guide body (2) is provided with a vertical middle through hole (21) in communication with the upper opening (11) and the lower opening (12) of the shell; and the heating wire (3) is arranged on the liquid guide body (2), and the electrode leads (4) are arranged at two ends of the heating wire (3). The shell (1) of the atomization core can protect the liquid guide body (2) inside same, thereby prolonging the service life of a product; and the shell (1) made of a metal material has good heat conductivity, and can rapidly heat a liquid to be atomized when in use and improve the fluidity thereof. The atomization core has a simple structure, is convenient to be assembled into an atomizer, and facilitates automated production of the atomizer.
An atomizer with an atomization core having a protection cover. The atomizer comprises a shell (1), wherein a mouthpiece end (11) of the shell (1) is provided with a suction port (110) and a suction port pipe (111); a connecting end (12) is provided with an opening (120) and a bottom cover (3) for blocking the opening; an atomization assembly (2) is connected between the suction port pipe (111) and the bottom cover (3); and a liquid storage cavity (10) is provided between the atomization assembly (2) and an inner wall of the shell (1). The atomization assembly (2) comprises an isolation piece (21), an atomization base (22) and an atomization core (23), wherein the isolation piece (21) is arranged on an upper planar surface of the atomization base (22); the bottom of the atomization base (22) is provided with a central accommodating cavity (2200); the atomization core (23) is arranged in the central accommodating cavity (2200); the isolation piece (21) and the atomization base (22) are each provided, at the same position, with liquid through holes (211, 221) which vertically penetrate through same; the liquid through holes (211, 221) are in communication with the liquid storage cavity (10); the atomization base (22) is arranged on the bottom cover (3); the atomization core (23) comprises a flat liquid guide body (231) for absorbing and guiding a liquid to be atomized; a protection cover (232) is tightly attached to an upper surface and side surfaces of the liquid guide body (231); the liquid guide body (231) and the protection cover (232) are provided with a vertically-penetrating vapor output channel (230); the vapor output channel (230) is in communication with the suction port pipe (111); a throttling hole (2321) is further provided in an upper surface of the protection cover (232); the throttling hole (2321) is in communication with the liquid through holes (211, 221); and a heating body (233) is arranged at the bottom of the liquid guide body (231). The atomization assembly (2) has few parts and has a simple structure, and the atomization core (23) uses the protection cover (232), which is made of metal or compact ceramic, to protect the liquid guide body (231), which is made of porous ceramic, thereby preventing the problem of the atomization core (23) being prone to cracking during use due to the action of an external force or being soaked in a liquid to be atomized.
An atomizing core having an open atomizing cavity, which is disposed in an atomizing base of an electronic atomizing device and comprises: a casing (1), a liquid guide body (2), and a heating piece (3). The casing (1) is provided with an upper end opening (11), a lower end opening (12), and side wall through holes (10); slots (15) are provided in the wall of the lower part of the casing (1); an upper part (21) of the liquid guide body (2) is fitted onto the inner wall of the casing (1); the side wall through holes (10) are blocked by the outer wall of the liquid guide body (2); the lower part of the liquid guide body (2) laterally projects from the slots (15) in the wall of the lower part of the casing; the liquid guide body (2) is provided with a vertical center through hole (23) in communication with the upper end opening (11) and lower end opening (12) of the casing (1); the heating piece (3) is disposed at the bottom of the liquid guide body (2); an open atomizing cavity (24) is formed under the heating piece (3); and a cavity for forming a vapor outlet passage (16) is provided inside the casing (1) and above the liquid guide body (2). The advantages of the present invention are: the heating is uniform, and thus the atomization effect is better; the structure is simple, and thus the assembly is convenient, thereby facilitating the automatic production of atomizers; and the provision of the casing can prevent the breakage and damage of the liquid guide body, and thus the service life is prolonged.
An atomization core having a protective cover (2), the atomization core being arranged on an atomization seat of an electronic atomization device, and comprising a flat liquid guide (1) used for adsorbing and conducting liquid to be atomized, the protective cover (2) being attached to the top and sides of the liquid guide (1); the liquid guide (1) and the protective cover (2) are provided with vertical and penetrating vapor outlet through holes (10), or the outer side of the protective cover (2) is provided with a vertical vapor outlet groove (20); the top of the protective cover (2) is also provided with orifices (21), the orifices (21) being used to guide the liquid into the liquid guide (1); the lower surface of the liquid guide (1) or the part in the liquid guide (1) close to the lower surface is provided with a heating body (3), wherein the heating body (3) can heat the liquid in the liquid guide (1) after being energized, and an aerosol formed by the evaporation of the liquid from the lower surface of the liquid guide (1) is discharged upward from the vapor outlet through holes (10) or the vapor outlet groove (20). The advantages of the atomization core lie in that: the protective cover (2) can protect the internal liquid guide (1) made of porous ceramic material, thereby preventing damage caused by fragmentation, and prolonging the service life of a product; the structure is simple, and is conveniently assembled in an atomizer, which facilitates automatic production of the atomizer.
An atomization core having a support. The atomization core is provided in the atomization seat of an electronic atomization device, and comprises a support (1) and a heating piece (2); the support (1) comprises a support flat plate (11) and a support wall (12); the support wall (12) is vertically provided on the periphery of the lower portion of the support flat plate (11); the lower portion of the support flat plate (11) and the support wall (12) define an atomization cavity (10); an atomization through hole (110) leading to the atomization cavity (10) is downwardly formed in the support flat plate (11); the heating piece (2) is provided on the support flat plate (11) and the atomization through hole (110) thereof; the heating piece (2) is used for heating and atomizing a liquid to be atomized, and generating vapor in the atomization cavity (10) by means of the atomization through hole (110); the two sides of the support wall (12) are provided with vapor discharge ports (120); and the two ends of the heating piece (2) are provided with electrode lead wires (3). The present invention has the following beneficial effects: the heating area is large, heating is uniform, and the generated atomization amount is large; and small droplets or water vapor is prevented from being vaped into the mouth of a user.
An atomizer having an atomizing cavity at the inner bottom of an atomizing core, comprising a housing (1). The housing (1) comprises a mouthpiece end (11) and a connecting end (12). The mouthpiece end (11) is provided with a suction port (110) and a suction port tube (111). The connecting end (12) is provided with an opening (120). The opening (120) is provided with a bottom cap (3) for blocking the opening (120). The connecting end (12) can be connected to a battery assembly to form an electronic atomizing device. An atomizing assembly (2) is provided between the suction port tube (111) and the bottom cap (3) in the housing (1). A liquid storage cavity (10) is provided between the atomizing assembly (2) and the inner wall of the housing (1). The atomizing assembly (2) comprises an atomizing core (21) and an atomizing seat (23). The bottom of the atomizing seat (23) is arranged on the bottom cap (3). The lower portion of the atomizing core (21) is inserted in a central accommodating cavity (232) of the atomizing seat (23). The upper portion of the atomizing core (21) is sealed and fitted over the lower end portion of the suction port tube (111). The inner bottom of the atomizing core (21) is provided with the atomizing cavity. A vertical middle through hole is formed in the atomizing core (21). The atomizer has a simple structure, and automated production and mounting are facilitated. The inner bottom of the atomizing core (21) is provided with the atomizing cavity, effectively preventing small droplets or water mist from being suctioned into a user's mouth. A heating piece has a large area, heat is evenly generated and a large amount of atomization is generated.
An atomizer having an atomization core (22) with a sleeve (221). The atomizer comprises a shell (1), wherein a mouthpiece end (11) of the shell (1) is provided with a suction port (110) and a suction port pipe (111); a connecting end (12) of the shell is provided with an opening (120) and a bottom cover (3) for blocking the opening; an atomization assembly (2) is connected between the suction port pipe (111) and the bottom cover (3); a liquid storage cavity (10) is provided between the atomization assembly (2) and an inner wall of the shell (1); the atomization assembly (2) comprises a sealing sleeve (21), the atomization core (22) and an atomization base (23), the bottom of the atomization base (23) being arranged on the bottom cover (3); the atomization core (22) comprises the sleeve (221), a liquid guide body (222), a heating wire (223) and electrode leads (224); an upper end portion (2211) of the sleeve (221) is connected to the lower end portion of the suction port pipe (111) in a sleeved manner, and a lower portion of the sleeve is inserted into a center accommodation cavity (231) of the atomization base (23); the sleeve (221) is provided with a side wall through hole (2210); the liquid guide body (222) is arranged inside the sleeve (221); the side wall through hole (2210) is shielded by an outer wall of the liquid guide body (222); a vertical middle through hole (2221) is provided in the liquid guide body (222); an upper cavity (2213) and a lower cavity (2214) are provided at positions inside the sleeve (221) and located at two ends of the liquid guide body (222); the heating wire (223) is arranged on the liquid guide body (222); and the electrode leads (224) are connected to two ends of the heating wire (223).
An atomizing core having a bottom atomizing cavity, arranged in an atomizing seat of an electronic atomizing device, and comprising a shell (1), a liquid guide (2), and a heating piece (3). The shell (1) is provided with an upper opening (11), a lower opening (12), and sidewall through holes (10) in the middle; the liquid guide (2) is sleeved on the inner wall of the shell (1); the sidewall through holes (10) are blocked by the outer wall of the liquid guide (2); the liquid guide (2) is provided with a vertical middle through hole (21); the middle through hole (21) is communicated with the upper opening (11) and the lower opening (12) of the shell (1); the heating piece (3) is provided at the bottom of the liquid guide (2); a bottom cavity for constituting an atomizing cavity (16) is formed below the heating piece (3) at the lower end of the inside of the shell (1); an upper cavity for constituting a vapor outlet cavity (17) is formed above the liquid guide (2) at the upper end of the inside of the shell (1). Heating is uniform and a large amount of vapor is generated; small droplets or water vapor can be effectively prevented from being smoked into the mouth of a user and use experience of the user is improved; the shell (1) is provided, such that the liquid guide (2) made of a porous ceramic material inside the shell (1) can be protected and the service life of a product is prolonged.
A24F 40/46 - Forme ou structure des moyens de chauffage électrique
A24F 40/40 - Détails de construction, p. ex. connexion des cartouches et des batteries
A24F 40/10 - Dispositifs utilisant des précurseurs inhalables liquides
B05B 17/00 - Appareils de pulvérisation ou d'atomisation de liquides ou d'autres matériaux fluides, non couverts par les autres groupes de la présente sous-classe
81.
ATOMISER WITH ATOMISING CHAMBER ARRANGED IN ATOMISING CORE BRACKET
An atomiser with an atomising chamber arranged in an atomising core bracket, comprising an outer shell (1), a nozzle end (11) of the outer shell (1) being provided with a suction port (110), the suction port (110) being integrally formed downward with a suction port tube (111), a connecting end (12) being provided with an opening (120), the opening (120) being provided with a bottom cover (3) for plugging same, the connecting end (12) being capable of connecting to a battery assembly, an atomising assembly (2) being connected between the suction port tube (111) and the bottom cover (3), a liquid storage chamber (10) being arranged between the atomising assembly (2) and the inner wall of the outer shell (1), the atomising assembly (2) comprising a throttle cover (21) and an atomising base (22) connected from top to bottom, and being internally provided with a cavity for installing an atomising core (23), the atomising core (23) comprising a bracket (231), a heating plate (232), and a liquid guide plate (234), the bracket (231) comprising a bracket plane (2311) and a bracket wall (2312), and the lower part of the bracket plane (2311) and the bracket wall (2312) enclosing an atomising chamber (2310). The present atomiser has uniform heating and a large amount of atomisation, and enhances the user experience.
The disclosure provides an electronic cigarette capable of dose control and a control method thereof. The electronic cigarette includes a housing, a liquid storage chamber, a vaporizing device, a battery, an airflow sensor, and a control circuit. The control circuit includes a microcontroller, a power control unit, a timing unit, an energy statistics and conversion unit, and an indication unit. The microcontroller is preset with preset parameters including a preset dose threshold. The airflow sensor detects airflow during vaping, then the power control unit supplies power for a heating unit, and the timing unit starts timing, the power control unit detects power of the heating unit, the energy statistics and conversion unit calculates and converts consumption of electric energy into a dose of consumed cigarette liquid, when the dose of consumed cigarette liquid reaches the preset dose threshold, the indication unit provides an indication.
A24F 40/60 - Dispositifs avec des interfaces utilisateur intégrées
G01R 27/16 - Mesure de l'impédance d'un élément ou d'un réseau dans lequel passe un courant provenant d'une autre source, p. ex. câble, ligne de transport de l'énergie
G06F 1/26 - Alimentation en énergie électrique, p. ex. régulation à cet effet
H05B 1/02 - Dispositions de commutation automatique spécialement adaptées aux appareils de chauffage
83.
ELECTRONIC ATOMIZATION DEVICE WITH HUMIDITY-SENSITIVE ELEMENT, AND DRY-BURNING PREVENTION CONTROL METHOD FOR ELECTRONIC ATOMIZATION DEVICE
An electronic atomization device with a humidity-sensitive element, and a dry-burning prevention control method for the electronic atomization device. The electronic atomization device comprises an atomization assembly and a battery assembly which are connected to each other, wherein the atomization assembly comprises an atomization core (1). The atomization core (1) comprises a liquid guide body (11), a heating element (12) and a humidity-sensitive element (13), wherein the humidity-sensitive element (13) is used for measuring the humidity of a liquid to be atomized which is contained in the liquid guide body (11). A micro-controller (2), a humidity-sensitive element measurement circuit (3) and a power output control circuit (4) are arranged on a circuit control board, wherein the micro-controller (2) comprises a humidity processing module (20); the humidity-sensitive element measurement circuit (3) is connected to the humidity-sensitive element (13) and the humidity processing module (20); the power output control circuit (4) is connected to the micro-controller (2) and the heating element (12); the humidity-sensitive element measurement circuit (3) is used for measuring a resistance value of the humidity-sensitive element (13) and transmitting the resistance value to the humidity processing module (20), and the humidity processing module (20) is used for converting the resistance value of the humidity-sensitive element (13) into a corresponding humidity value; the micro-controller (2) outputs a control signal according to the humidity value; and according to the control signal, the power output control circuit (4) outputs a corresponding power to the heating element (12) or turns off the output power.
224425232222O, MgO, and CaO. The atomization core comprises a liquid guide body and a heating element; the liquid guide body is made of the humidity-sensitive porous ceramic. The preparation method comprises (1) weighing a component A, a component B, a component C, a pore-forming agent, and a sintering aid, and performing mixing and ball-milling in a ball-milling device; (2) performing baking and drying to obtain mixed powder; (3) heating paraffin to melt, and adding the mixed powder while stirring to obtain paraffin slurry; (4) injecting the paraffin slurry into a mold, and performing cooling to obtain a wax mold; (5) putting the wax mold into a furnace for dewaxing to obtain a dewaxed sample; and (6) performing sintering in a protective atmosphere to obtain the humidity-sensitive porous ceramic.
C04B 35/12 - Produits céramiques mis en forme, caractérisés par leur compositionCompositions céramiquesTraitement de poudres de composés inorganiques préalablement à la fabrication de produits céramiques à base d'oxydes à base d'oxyde de chrome
C04B 35/622 - Procédés de mise en formeTraitement de poudres de composés inorganiques préalablement à la fabrication de produits céramiques
C04B 38/06 - Mortiers, béton, pierre artificielle ou articles de céramiques poreuxLeur préparation en éliminant par brûlage des substances ajoutées
C04B 38/02 - Mortiers, béton, pierre artificielle ou articles de céramiques poreuxLeur préparation par addition d'agents chimiques gonflants
An atomizing core (1) having a humidity sensing element, comprising a liquid guiding member (11), a heating element (12) and the humidity sensing element (13). The liquid guiding member (11) is used for absorbing and storing a liquid to be atomized, and guiding the liquid to be atomized to the heating element (12). The heating element (12) heats and atomizes the liquid to be atomized. The humidity sensing element (13) is used for measuring the humidity of the liquid to be atomized in the liquid guiding member (11). The present atomizing core having the humidity sensing element can quickly prevent, without delay, the atomizing core from dry burning.
B05B 1/24 - Buses, têtes de pulvérisation ou autres dispositifs de sortie, avec ou sans dispositifs auxiliaires tels que valves, moyens de chauffage avec des moyens pour chauffer le liquide ou autre matériau fluide, p. ex. électriquement
B05B 12/08 - Aménagements de commande de la distributionAménagements de réglage de l’aire de pulvérisation sensibles à l'état du liquide ou d'un autre matériau fluide expulsé, du milieu ambiant ou de la cible
86.
MANUFACTURING METHOD FOR HEAVY METAL-REMOVED POROUS CERAMIC, HEAVY METAL-REMOVED POROUS CERAMIC, AND ATOMIZING CORE
A manufacturing method for a heavy metal-removed porous ceramic, the heavy metal-removed porous ceramic, and an atomizing core. The manufacturing method comprises: (1) placing a mineral powder in a high-temperature furnace and roasting in a reductive protective atmosphere, controlling the temperature of the furnace between 1000-2000 °C so that heavy metals are vaporized, when roasted and cooled, regrinding to produce a heavy metal-removed powder; (2) weighing, according to parts by weight, 20-80 parts of the heavy metal-removed powder, 1-30 parts of a pore-forming agent, and 1-20 parts of a sintering aid, and placing in a ball milling apparatus for mixing and ball milling; (3) baking and draying the mixture, heating paraffin to a melted state, adding the ground and dried mixed powder while stirring, and continuously stirring for 1-8 h after the addition to produce a paraffin slurry; (4) injecting the paraffin slurry into a mold prepared in advance, cooling and forming to produce a wax mold; (5) pre-heating the wax mold for dewaxing to produce a dewaxed blank; and (6) sintering and cooling the dewaxed blank to produce a heavy metal-removed porous ceramic.
An electronic atomizing device having a humidity-sensitive component. The electronic atomizing device comprises an atomizing assembly and a battery assembly connected to each other. The atomizing assembly comprises an atomizing core (1). The atomizing core (1) comprises a liquid-guiding body (11), a heat-generating component (12), and a humidity-sensitive component (13). The humidity-sensitive component (13) is used for detecting the humidity of a liquid to be atomized that the liquid-guiding body (11) comprises. A microcontroller (2), a humidity-sensitive component detection circuit (3), and a power output control circuit (4) are provided on a circuit control board. The microcontroller (2) comprises a humidity processing module (20). The humidity-sensitive component detection circuit (3) is connected to the humidity-sensitive component (13) and to the humidity processing module (20). The power output control circuit (4) is connected to the microcontroller (2) and to the heat-generating component (12). The humidity-sensitive component detection circuit (3) is used for detecting the resistance of the humidity-sensitive component (13) and transmitting to the humidity processing module (20). The humidity processing module (20) is used for converting the resistance of the humidity-sensitive component (13) into a corresponding humidity value. The microcontroller (2) outputs a control signal on the basis of the humidity value. The power output control circuit (4) outputs a corresponding power to the heat-generating component (12) or cuts off output power on the basis of the control signal.
242324244 with ZnO, the pore-forming agent and the sintering aid, and grinding and drying same to obtain a mixed powder material; (3) heating paraffin, and adding the mixed powder material while stirring to obtain a paraffin slurry; (4) injecting the paraffin slurry into a mold to obtain a wax mold after molding; (5) removing wax to obtain a wax-free sample; and (6) placing the wax-free sample into a furnace, and sintering same in a protective atmosphere to obtain the humidity-sensitive porous ceramic.
C04B 35/12 - Produits céramiques mis en forme, caractérisés par leur compositionCompositions céramiquesTraitement de poudres de composés inorganiques préalablement à la fabrication de produits céramiques à base d'oxydes à base d'oxyde de chrome
C04B 35/622 - Procédés de mise en formeTraitement de poudres de composés inorganiques préalablement à la fabrication de produits céramiques
C04B 38/06 - Mortiers, béton, pierre artificielle ou articles de céramiques poreuxLeur préparation en éliminant par brûlage des substances ajoutées
C04B 38/02 - Mortiers, béton, pierre artificielle ou articles de céramiques poreuxLeur préparation par addition d'agents chimiques gonflants
89.
HUMIDITY-SENSITIVE POROUS CERAMIC AND PREPARATION METHOD THEREFOR, AND ATOMIZATION CORE
23243232433, a ceramic powder material, a pore-forming agent, and a sintering aid, and performing mixing and ball-milling in a ball-milling device; (2) performing baking and drying to obtain mixed powder; (3) heating paraffin to melt, and adding the mixed powder while stirring to obtain paraffin slurry; (4) injecting the paraffin slurry into a mold, and performing cooling and demolding to obtain a wax mold; (5) performing dewaxing to obtain a dewaxed sample; and (6) performing sintering in a protective atmosphere to obtain the humidity-sensitive porous ceramic.
C04B 35/12 - Produits céramiques mis en forme, caractérisés par leur compositionCompositions céramiquesTraitement de poudres de composés inorganiques préalablement à la fabrication de produits céramiques à base d'oxydes à base d'oxyde de chrome
C04B 35/622 - Procédés de mise en formeTraitement de poudres de composés inorganiques préalablement à la fabrication de produits céramiques
C04B 38/06 - Mortiers, béton, pierre artificielle ou articles de céramiques poreuxLeur préparation en éliminant par brûlage des substances ajoutées
C04B 38/02 - Mortiers, béton, pierre artificielle ou articles de céramiques poreuxLeur préparation par addition d'agents chimiques gonflants
An atomizing core (1) having a humidity-sensitive element, comprising a liquid guide piece (11), a heating element (12), and a humidity-sensitive element (13). The liquid guide piece (11) is used for absorbing and storing a liquid to be atomized and guiding said liquid to the heating element (12); the heating element (12) heats and atomizes said liquid; and the humidity-sensitive element (13) is used for measuring the humidity of said liquid contained in the liquid guide piece (11). The present application has the beneficial effect that because the humidity-sensitive element (13) has a resistance value sensitive to humidity, the humidity of the atomizing core (1) can be measured by measuring the resistance, such that when said liquid in the liquid guide piece is not sufficient, a reduction in humidity will occur and can be detected quickly, and thus, the power can be lowered or a power supply can be turned off in a timely manner, thereby quickly and immediately preventing heating of the atomizing core (1) without e-liquid.
An electronic cigarette preheating method and preheating system are provided. The preheating method performs data interaction by communication connection established between an intelligent terminal and the electronic cigarette, allows for displaying and changing preheating parameters on a control software interface of the intelligent terminal, and sends the updated preheating parameters to the microcontroller MCU to replace previous preheating parameters preset in the microcontroller MCU. When the electronic cigarette is turned on, based on real-time temperature value detected by temperature sensor, determining whether preheating is required by means of the microcontroller MCU. If yes, based on preheating parameters and preset routine, controlling the heating device of the electronic cigarette by means of the microcontroller MCU to perform heating for the preset heating time or until the preset target temperature value is reached. Then, ending the preheating and entering the available stand-by state of the electronic cigarette.
An electronic cigarette preheating control method and preheating control system are provided. The method performs data interaction by communication connection established between an intelligent terminal and the electronic cigarette, allows for displaying and changing preheating parameters on a control software interface of the intelligent terminal, and sends the updated preheating parameters to the microcontroller MCU to replace previous preheating parameters preset in the microcontroller MCU. When the electronic cigarette is turned on, based on real-time temperature value detected by temperature detection unit, determining whether preheating is required by means of the microcontroller MCU. If yes, based on preheating parameters and preset routine, controlling the heating device of the electronic cigarette by means of the microcontroller MCU to perform heating for the preset heating time or until the preset target temperature value is reached. Then, ending the preheating and entering the available stand-by state of the electronic cigarette.
A graphene porous ceramic capable of heating, an atomization core, and a preparation method for the graphene porous ceramic capable of heating, the ceramic being prepared from a base material and comprising the following components in parts by weight: 1-60 parts graphene oxide powder, 10-80 parts ceramic powder, 1-50 parts of a pore forming agent and 1-40 parts of a sintering aid. The atomization core comprises a heating body (1) and positive and negative electrodes (3) arranged at two ends of the heating body (1), the heating body (1) being made of the graphene porous ceramic that is capable of heating. The preparation method comprises: (1) weighing graphene oxide powder, ceramic powder, a pore-forming agent and a sintering aid, and mixing and ball-milling same; (2) baking and drying to obtain a mixed powder; (3) heating paraffin to a molten state, adding the mixed powder and stirring at the same time, and continuously stirring for 1-8h to obtain a paraffin slurry; (4) injecting the paraffin slurry into a pre-prepared mold, cooling and molding, and demolding to obtain a wax mold; (5) placing the wax mold into a furnace for preheating to remove the wax so as to obtain a wax-removed sample; and (6) placing the wax-removed sample into the furnace to perform sintering, heating, maintaining the temperature, and cooling to obtain the graphene porous ceramic.
An electronic cigarette preheating method comprises setting preheating parameters and preheating routine in a microcontroller MCU. The preheating parameters at least include preset temperature value, and preset heating time or preset target temperature value. The preheating routine comprises: after turning on the electronic cigarette, activating preheating function when preheating button arranged on the electronic cigarette is pressed, detecting real-time temperature value by means of a temperature sensor; by means of the microcontroller MCU, comparing the real-time temperature value with the preset temperature value, and determining whether preheating of the cigarette liquid stored inside the liquid storage chamber is required. If no, directly entering an available stand-by state. If yes, controlling a heating device by means of the microcontroller MCU to perform preheating for the preset heating time or until the preset target temperature value is reached, and then ending the preheating and entering the available stand-by state.
An electronic cigarette preheating control method comprises setting preheating parameters and preheating routine in a microcontroller MCU. The preheating parameters at least include preset temperature value, and preset heating time or preset target temperature value. The preheating routine comprises: after turning on the electronic cigarette, activating preheating function when preheating button arranged on the electronic cigarette is pressed, detecting real-time temperature value by means of a temperature detection unit; by means of the microcontroller MCU, comparing the real-time temperature value with the preset temperature value, and determining whether preheating of the cigarette liquid stored inside the liquid storage chamber is required. If no, directly entering an available stand-by state. If yes, controlling a heating device by means of the microcontroller MCU to perform preheating for the preset heating time or until the preset target temperature value is reached, and then ending the preheating and entering the available stand-by state.
The present invention is a porous nanoceramic for use in an atomizing core and a manufacturing method. The ceramic comprises: nano silicon oxide 1-60 parts, a ceramic powder 10-80 parts, a pore-forming agent 1-50 parts, and a sintering aid 1-40 parts. The manufacturing method comprises: (1) weighing nano silicon dioxide, a ceramic powder, a pore forming agent, and a sintering aid raw material and placing in a ball milling apparatus for mixing and ball milling; (2) baking and drying the ball-milled mixture to produce a mixed powder; (3) heating paraffin to a melted state, adding the mixed powder while stirring, and continuously stirring for 1-8 h after the addition to produce a paraffin slurry; (4) injecting the paraffin slurry into a mold prepared in advance, cooling and forming, and demolding to produce a wax mold; (5) pre-heating the wax mold for dewaxing to produce a dewaxed blank; and (6) sintering and cooling the dewaxed blank to produce a porous nanoceramic. The beneficial effects are: the problem in the prior art in which demands for high porosity and high strength cannot be satisfied at the same time is solved, and the problem of impurities and heavy metals being easily precipitated is solved.
A fingerprint input method for an atomization device and an atomization device, the method comprising: a charger is used to charge an atomization device, in a charging state, a finger is pressed on a fingerprint sensor (4) and continued for a set first duration, and a microcontroller (1) is enabled to control the atomization device to enter a fingerprint input mode; in the fingerprint input mode, the finger is pressed on the fingerprint sensor (4), the fingerprint sensor (4) reads local information of a fingerprint, and it is determined by means of a fingerprint information microprocessor (5) whether the local information is successfully read; if successfully read once, then same is inputted into a fingerprint information memory (6), and then the local information of the fingerprint is repeatedly read; and if the local information of the fingerprint may be successfully read multiple times within a set second duration, then the fingerprint information microprocessor (5) of the atomization device combines the local information of the fingerprint read multiple times into complete fingerprint information and same is inputted into the fingerprint information memory (6)。 In the fingerprint input method, fingerprints may be input in an atomization device without the help of an intelligent terminal, which is convenient for users to use.
An atomizing device having a fingerprint sensor (4), comprising an atomizer and a battery assembly. The battery assembly comprises a battery, a microcontroller (1), a charging control unit (2), an indication unit (3), a fingerprint sensor (4), a fingerprint information microprocessor (5), and a fingerprint information memory (6). The microcontroller (1) is electrically connected to the charging control unit (2) and the indication unit (3), separately. The microcontroller (1) is connected to the fingerprint information microprocessor (5) by means of a serial port communication interface. The fingerprint information microprocessor (5) is electrically connected to the fingerprint sensor (4) and the fingerprint information memory (6), separately. The fingerprint sensor (4) is used for reading fingerprint information. The fingerprint information microprocessor (5) is used for performing computing processing on same. The fingerprint information memory (6) is used for storing the fingerprint information performed computing processing. The microcontroller (1) is used for controlling the reading, computing and storing processes of the fingerprint information. The beneficial effects are: by adding the fingerprint sensor (4) in the atomizing device, a method for unlocking by using fingerprint is specially dedicated to prevent an abnormal user from using without authorization, so that a minor can also be prevented from using.
The disclosure provides a vaporizing device capable of controlling administration amount and a controlling method thereof. The control circuit board is arranged with a microcontroller, an air flow calculating unit, an energy statistics unit, an energy and vaporizing amount conversion unit, and a power control unit, which are electrically connected with each other. The air flow calculating unit calculates corresponding air flow quantity based on the modeling volume of the detecting air passage and the change of suction pressure. The power control unit controls the power output to the heating resistor based on the air flow quantity. The energy statistics unit calculates output energy based on the output power and the time. The energy and vaporizing amount conversion unit calculates corresponding value of aerosol intake from the energy. The microcontroller compares it with preset limit value of aerosol intake and then sends corresponding control signal to the power control unit.
An electronic atomization device having a digital air pressure sensing chip, comprising an atomization apparatus (1) and an atomization unit (11) in the atomization apparatus (1), a power output unit (3), a microcontroller (4) and a digital air pressure sensing chip (5); the power output unit (3) is used for outputting a voltage to the atomization unit (11) for operation, the microcontroller (4) is electrically connected to the atomization unit (11), the power output unit (3) and the digital air pressure sensing chip (5); the digital air pressure sensing chip (5) is arranged in an air inlet channel (10) of the atomization apparatus (1) or is in communication with the air inlet channel (10), the digital air pressure sensing chip (5) comprises an air pressure sensing module (51), an air pressure processing module (52), a switch signal output module (53) and a digital signal output module (54); the air pressure sensing module (51) is used for detecting the air pressure difference between the air pressure in the air inlet channel (10) and the external air pressure, the air pressure processing module (52) is used for performing operation processing on the air pressure difference detected by the air pressure sensing module (51) and transmitting the operation processed air pressure difference value to the switch signal output module (53), the switch signal output module (53) is used for outputting a switch signal to wake up the dormant microcontroller (4) when the air pressure difference value reaches a set wake-up threshold, and the digital signal output module (54) is used for outputting the operation processed air pressure difference value to the microcontroller (4); and the microcontroller (4) comprises an output switch module (41), and when the air pressure difference value reaches a set operation threshold, the output switch module (41) controls the power output unit (3) to output a voltage, and when the air pressure difference value is lower than the operation threshold, the output switch module (41) controls the power output unit (3) to stop outputting the voltage. Also provided is a control method for an electronic atomization device having a digital air pressure sensing chip (5).
