CN112931970B - Self-adaptive oral-pulmonary conversion type multi-atomization core atomizer and control method thereof - Google Patents

Self-adaptive oral-pulmonary conversion type multi-atomization core atomizer and control method thereof Download PDF

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Publication number
CN112931970B
CN112931970B CN201911177478.0A CN201911177478A CN112931970B CN 112931970 B CN112931970 B CN 112931970B CN 201911177478 A CN201911177478 A CN 201911177478A CN 112931970 B CN112931970 B CN 112931970B
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negative pressure
core
atomizing
airflow
atomization core
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CN112931970A (en
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谭会民
崔涛
乐雷
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Shenzhen Innokin Technology Co Ltd
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Shenzhen Innokin Technology Co Ltd
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Priority to PCT/CN2020/131803 priority patent/WO2021104379A1/en
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    • AHUMAN NECESSITIES
    • A24TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
    • A24FSMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
    • A24F40/00Electrically operated smoking devices; Component parts thereof; Manufacture thereof; Maintenance or testing thereof; Charging means specially adapted therefor
    • A24F40/10Devices using liquid inhalable precursors
    • AHUMAN NECESSITIES
    • A24TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
    • A24FSMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
    • A24F40/00Electrically operated smoking devices; Component parts thereof; Manufacture thereof; Maintenance or testing thereof; Charging means specially adapted therefor
    • A24F40/40Constructional details, e.g. connection of cartridges and battery parts
    • AHUMAN NECESSITIES
    • A24TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
    • A24FSMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
    • A24F40/00Electrically operated smoking devices; Component parts thereof; Manufacture thereof; Maintenance or testing thereof; Charging means specially adapted therefor
    • A24F40/40Constructional details, e.g. connection of cartridges and battery parts
    • A24F40/46Shape or structure of electric heating means
    • AHUMAN NECESSITIES
    • A24TOBACCO; CIGARS; CIGARETTES; SIMULATED SMOKING DEVICES; SMOKERS' REQUISITES
    • A24FSMOKERS' REQUISITES; MATCH BOXES; SIMULATED SMOKING DEVICES
    • A24F47/00Smokers' requisites not otherwise provided for

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  • Disinfection, Sterilisation Or Deodorisation Of Air (AREA)

Abstract

The invention discloses a self-adaptive oral-pulmonary conversion multi-atomization core atomizer. Comprises two or more groups of atomizing cores; the control circuit, the airflow channel and the oil inlet channel of each group of atomizing cores are respectively and independently arranged. The negative pressure switch is arranged on the airflow channel of at least one atomizing core of the two or more atomizing cores. By arranging a plurality of groups of atomizing cores which are controlled relatively and independently, the working switch of each group of atomizing cores and the opening and closing of the air flow channel can be controlled independently, and independent atomization and independent control are realized. And then the negative pressure switch is arranged on the airflow channel to sense the suction negative pressure of the smoker, and the working quantity and the working state of the atomizing core are controlled according to the magnitude of the negative pressure, so that the process of self-adaptive adjustment according to the suction quantity is realized.

Description

Self-adaptive oral-pulmonary conversion type multi-atomization core atomizer and control method thereof
Technical Field
The invention relates to an aerosol atomizer, in particular to an atomizer with multiple atomizing cores, which can automatically adapt to oral-pulmonary intake conversion.
The invention also relates to a control method of the atomizer.
Background
When the electronic smoke sol is sucked, two modes of oral suction and lung suction exist. By oral inhalation is meant that only the electronic aerosol is inhaled into the inlet chamber and then directly exhaled, and the volume of the oral cavity is small, so that the amount of aerosol required is also small. The desired e-cigarette operating conditions at this time produce a smaller amount of aerosol. Pulmonary inhalation is the inhalation of aerosols into the lungs through the mouth and filling the alveoli as much as possible, followed by exhalation. Because of the large internal volume of the lung, the required intake is also large, and the electronic cigarette is required to generate a large amount of aerosol. The mouth sucking and lung sucking states can be converted, and for an electronic cigarette smoker, the electronic cigarette is easy to suck and is in a random state, so that the conversion from mouth sucking to lung sucking is likely to be an occasional idea conversion sometimes, the conversion time is quick, the burst is strong, and the conversion can be performed just after the start of sucking. Therefore, the manual adjustment and the program adjustment are not convenient to perform, and the manual adjustment and the program adjustment can not achieve the function of freely switching between oral inhalation and pulmonary inhalation in time. This requires the electronic cigarette to have a self-detecting and self-adapting function, and to determine lung inhalation when the user is detected to have a large inhalation amount and to determine mouth inhalation when the user is detected to have a small inhalation amount and to have a slow inhalation amount. And the working state is automatically adjusted according to the detection and judgment result, so that the function is not really realized in the current electronic cigarette field.
If only be provided with single atomizing core in the general atomizer, the electron smog spinning disk atomiser of single atomizing core can only be through changing the heating power of parameter change such as power supply voltage, electric current when using, realizes the regulation effect of atomizing effect and atomizing volume. However, the adjusting mode has strong limitation, the length and the diameter of the resistance of the heating wire of the electronic cigarette are determined, the resistance value of the resistance is also determined, even though the heating power can be changed through adjustment of the power supply voltage and the current, the common resistance heating wire is difficult to bear the voltage or the current which are increased by multiple, otherwise, the problems of high temperature fusing and the like are easy to occur, the adjusting quantity is limited, the transformation between the aerosol volume required by sucking the mouth to the lung is generally increased by more than several times, and the heating power is also required to be increased by several times. Therefore, the atomization core of the single heating body can not adapt to the instant conversion from mouth suction to lung suction of the electronic cigarette even through self-adaptive adjustment.
In the later atomizer, a plurality of heating elements can be arranged, the working quantity of the heating elements is set according to the demand of the intake, and the atomization amount and the intake are adjusted. The atomizing core is provided with a plurality of heating wires which are connected in parallel, and the atomizing core is provided with a uniform oil inlet hole, an uniform air inlet hole and an uniform air outlet hole. When a heating wire is opened to work in general smoking demands, simple small smoke sucking is carried out, and the oil inlet and the air inlet are both in work. When the intake needs to be increased, two or more heating wires need to be adjusted to be opened for simultaneous operation, and the oil inlet and the air inlet at the moment still keep the same working state, and oil or air can be fed in an original mode. The same air inlet hole and oil inlet hole are used from heating of one heating wire to heating of a plurality of heating wires. For each group of heating wires, only one most suitable oil inlet air inflow is needed, and only the oil inlet amount and the air inflow are matched with the working quantity of the heating wires, the best atomization effect can be achieved. In the structure of the same oil inlet and the same air inlet, the oil inlet amount and the air inlet amount are difficult to be in the optimal working state no matter the sizes. If the relative oil inlet amount and air inlet amount of a group of heating wires during operation can be larger, the atomization temperature can be insufficient, the atomization effect is affected, and even a large amount of tobacco tar is submerged, so that the atomization temperature can not be reached. The problem of small oil inlet amount can occur relatively when a plurality of groups of heating wires work, and the phenomenon of dry combustion can occur due to insufficient tobacco tar supply. The air flow speed is low when the relative air inflow is small, the aerosol sucking speed is low, the atomization effect is also affected, and the problem of too low concentration of the atomized aerosol is caused by the large relative air inflow.
Therefore, although a plurality of atomizing heating wires are provided, the best atomizing purpose is not achieved because independent control cannot be realized. Moreover, the switching on or off of the heating wires is still realized through manual adjustment or program control, and cannot be automatically adjusted according to the size of the intake.
The inventor combines the structure of multiple atomizing cores according to the defects, and develops an atomizer capable of self-adapting to the inhalation amount and switching between mouth and lung so as to overcome the defects.
Disclosure of Invention
The invention aims to provide a multi-atomization core atomizer capable of self-adapting to oral-pulmonary conversion. Meanwhile, the self-adaptive oropulmonary conversion control method of the atomizer is provided.
The invention discloses a self-adaptive oral-pulmonary conversion multi-atomization-core atomizer, which comprises two or more groups of atomization cores; each group of atomizing core control circuits and air flow channels are respectively and independently arranged and independently controlled; and negative pressure switches are arranged on air flow channels of part or all of the two or more groups of atomizing cores.
In the self-adaptive oral-pulmonary conversion multi-atomization-core atomizer, the two or more groups of all atomization-core airflow channels are provided with airflow sensors.
In the self-adaptive oral-pulmonary conversion multi-atomization-core atomizer, the airflow sensor may be disposed in such a way that the first, second to nth atomization cores are provided with air inlets, the air inlets are shared air inlets to form a shared air inlet cavity, the airflow channel of each atomization core is communicated with the shared air inlet cavity, and the airflow sensor is disposed at the communication position of the airflow channel of each atomization core and the shared air inlet cavity.
In the self-adaptive multi-atomization-core atomizer for oral-pulmonary conversion, the air flow sensor can be arranged in such a way that the air inlet holes of the first atomization core, the second atomization core and the N atomization core are respectively and independently arranged, and the air flow sensor is arranged at the air inlet hole of each atomization core.
In the self-adaptive oral-pulmonary conversion multi-atomization-core atomizer, the atomizer further comprises a suction nozzle, the suction nozzle is in butt joint connection with the atomization-core shell, and an air flow buffer cavity is arranged at the joint of the suction nozzle and the atomization-core shell; the airflow channel of each atomization core is communicated with the airflow buffer cavity; the atomizing core negative pressure switch is arranged at the communication position of the airflow channel and the airflow buffering cavity, and the airflow channel is communicated with the airflow buffering cavity through the negative pressure switch.
In the self-adaptive oral-pulmonary conversion multi-atomization-core atomizer, each group of atomization cores is provided with an independent heating body, an oil guide body, an airflow channel, an air inlet hole and an oil inlet hole; the oil inlet of each atomizing core is communicated with the oil storage bin, and the airflow sensor of each atomizing core is respectively and independently connected with the power supply control device.
In the self-adaptive oral-pulmonary conversion multi-atomization-core atomizer, the atomization core part is provided with a negative pressure switch, and two or more groups of atomization cores are defined as a first atomization core, a second atomization core and an N atomization core; negative pressure switches are arranged at the outlets of the second to N atomizing core airflow channels.
In the self-adaptive atomization core atomizer for oral-pulmonary conversion, the negative pressure switch is a mechanical switch or an electronic switch, the negative pressure in the airflow buffer cavity is sensed, and the negative pressure thresholds of the negative pressure switches of the second to N atomization cores are sequentially increased.
In the self-adaptive oral-pulmonary conversion multi-atomization-core atomizer, all atomization cores are provided with negative pressure switches, and two or more groups of atomization cores are defined as a first atomization core, a second atomization core and an N atomization core; negative pressure switches are arranged at the outlets of the first atomizing core airflow channel, the second atomizing core airflow channel and the Nth atomizing core airflow channel.
In the self-adaptive oral-pulmonary conversion type multi-atomization-core atomizer, the negative pressure switch is a mechanical switch or an electronic switch, the negative pressure in the airflow buffer cavity is sensed, and the negative pressure thresholds of the negative pressure switches of the first atomization core, the second atomization core and the N atomization core are sequentially increased.
The invention discloses a control method of a self-adaptive oral-pulmonary conversion multi-atomization core atomizer, which comprises the following steps:
a: starting smoking, generating negative pressure by the airflow buffer cavity, and enabling the first atomization core to work to absorb aerosol atomized by the first atomization core;
b: increasing smoke absorption amount, increasing negative pressure of the airflow buffer cavity, opening a second atomization core negative pressure switch, and enabling the second atomization core to work to absorb aerosol atomized by the first atomization core and the second atomization core together;
c: and the smoke sucking amount is continuously increased, the negative pressure of the airflow buffering cavity is continuously increased until an N-th atomization core negative pressure switch is turned on, the N-th atomization core works, and the first aerosol, the second aerosol and the N-th aerosol core are sucked to atomize the aerosol.
The invention relates to a control method of a self-adaptive oral-pulmonary conversion multi-atomization core atomizer, which comprises the following steps:
a: starting smoking, generating negative pressure by the airflow buffer cavity, opening a first atomization core negative pressure switch and an airflow channel, enabling the first atomization core airflow sensor to sense airflow to pass through, controlling the first atomization core to work and atomize by the control device, and sucking aerosol atomized by the first atomization core;
b: the smoke suction amount is increased, the negative pressure of the airflow buffer cavity is increased, a second atomization core negative pressure switch and an airflow channel are opened, the second atomization core airflow sensor senses airflow to pass, and the control device controls the second atomization core to work and atomize, so that aerosol atomized by the first atomization core and the second atomization core is sucked;
c: and the smoke sucking amount is continuously increased, the negative pressure of the airflow buffering cavity is continuously increased until an N-th atomization core negative pressure switch and an airflow channel are opened, the airflow sensor of the N-th atomization core senses airflow to pass, and the control device controls the N-th atomization core to work and atomize, so that the aerosol atomized by the first atomization core and the second atomization core is sucked until the N-th atomization core is added.
The invention further discloses a control method of the self-adaptive oral-pulmonary conversion multi-atomization core atomizer, which comprises the following steps of:
a: starting smoking, generating negative pressure by the airflow buffer cavity, generating smoking airflow by the first atomization core airflow channel, sensing airflow passing by the first atomization core airflow sensor, controlling the first atomization core to work and atomize by the control device, and sucking aerosol atomized by the first atomization core;
b: the smoke suction amount is increased, the negative pressure of the airflow buffer cavity is increased, a second atomization core negative pressure switch and an airflow channel are opened, the second atomization core airflow sensor senses airflow to pass, and the control device controls the second atomization core to work and atomize, so that aerosol atomized by the first atomization core and the second atomization core is sucked;
c: and the smoke sucking amount is continuously increased, the negative pressure of the airflow buffering cavity is continuously increased until an N-th atomization core negative pressure switch and an airflow channel are opened, the airflow sensor of the N-th atomization core senses airflow to pass, and the control device controls the N-th atomization core to work and atomize, so that the aerosol atomized by the first atomization core and the second atomization core is sucked until the N-th atomization core is added.
In the atomizer and the control method, the on-off of the power-on switch, the on-off of the airflow channel and the on-off of the tobacco tar channel of each group of atomizing cores are realized by arranging a plurality of groups of atomizing cores which are controlled relatively and independently. Independent atomization and independent control are realized, and then the negative pressure switch is arranged on the airflow channel to sense the suction negative pressure of a user, so that the working quantity and the working state of the atomization core are controlled according to the magnitude of the negative pressure, and the process of self-adaptive adjustment according to the suction quantity is realized. When the inhalation amount is large, the lung inhalation is judged, a plurality of atomizing cores work simultaneously, and when the inhalation amount is small, the mouth inhalation is judged, and one or a few atomizing cores work. The state transition between the self-adaptive oral inhalation and the pulmonary inhalation is realized.
Drawings
Fig. 1 is a schematic view showing a three-dimensional exploded structure of an atomizer according to embodiment 1 of the present invention;
fig. 2 is a schematic cross-sectional structure of the atomizer of embodiment 1 of the present invention;
FIG. 3 is a schematic cross-sectional view of a mechanical negative pressure switch of the present invention;
FIG. 4 is a schematic cross-sectional view of a bipolar electrode of the present invention.
The figure shows: 1 is a suction nozzle; 2 is an atomizer shell; 3 is an airflow buffer cavity; 4 is a double air passage; 5 is a negative pressure switch; 6 is an atomization core double cover body; 7 is an oil guide body; 8 is an atomization core double shell; 9 is an atomization core double air inlet hole; 10 is an atomizing core double electrode; 11 is a base.
21 is an internal space; 41 is the first airway; 42 is the second airway; 51 is a return spring; 52 is a valve cover; 53 is the valve body. 54 is a vent; 71 is a first oil guide; 72 is a second oil guide; 81 is a first oil inlet hole; 82 is a second oil inlet; 91 is a first air inlet; 92 is the second inlet aperture.
100 is a negative plate; 101 is a first double electrode; 102 is a second double electrode; 711 is a first atomizing core gas flow channel; 721 is the second atomizing core gas flow channel; 1011 is the first electrode column; 1021 is a first electrode insulating ring; 1021 is a second electrode column; 1022 is the second electrode insulating ring.
Detailed Description
The present invention will be described in detail below with reference to the drawings by way of specific embodiments, but the drawings and the specific embodiments are limited to the explanation of the technical solutions of the present invention, wherein any description does not affect the limitation of the protection scope.
Example 1: this embodiment is described in terms of a two-pack atomizing core configuration.
As shown in fig. 1 and 2, the atomizer body of the present embodiment is composed of a housing 2, a base 11, and a suction nozzle 1. Wherein the suction nozzle 1 and the shell 2 are integrally formed or are in a sealing and fixing connection structure. The housing 2 is a rectangular parallelepiped case, and the base 11 is also rectangular parallelepiped, and two sets of atomizing cores are arranged in parallel in the longitudinal direction in the housing 2.
The space between the housing 2 and the base 11 constitutes an atomizer inner space 21 for an oil reservoir for storing tobacco tar and an atomizing core accommodation space. Two groups of atomizing cores are arranged in the space 21 in parallel and integrated.
The structure of the two sets of atomizing cores is such that an atomizing core double housing 8 is provided, which is divided into a first housing part and a second housing part which are independent of each other, each housing part is provided with a housing space for housing the oil guiding body 7, a first oil guiding body housing space and a second oil guiding body housing space are formed, as in the cylindrical region shown in fig. 1, a first oil inlet hole 81 is provided on the wall surface of the first housing part of the double housing 8, and a second oil inlet hole 82 is provided on the wall surface of the second housing part. The first oil inlet hole 81 and the second oil inlet hole 82 are also independently provided, and are not communicated with each other.
The bottom of the atomizing core double-shell 8 is provided with a transverse double air inlet hole 9, as shown in the figure, the air inlet hole 9 is also divided into a first air inlet hole 91 and a second air inlet hole 92, and the first air inlet hole 91 and the second air inlet hole 92 are communicated in the base to form a common air inlet cavity, that is, the inlet air is intersected in the common air inlet cavity. It is of course also possible to provide the first air intake hole 91 and the second air intake hole 92 separately, for example, in a state of being spaced apart from each other, that is, not intersecting each other but being led out separately. Are respectively positioned at the left side and the right side of the lower end of the double shell 8 and extend outwards. The first air intake holes 91 and the second air intake holes 92 are respectively connected inwardly to the interiors of the first housing and the second housing.
The lower side of the double shell 8 is provided with double electrodes 10 assembled and connected with the double shell 8, the double electrodes are respectively provided with a first double electrode 101 and a second double electrode 102, each double electrode is provided with a double-layer electrode state of an inner electrode column and an outer electrode ring, and the outer ring electrodes of the first double electrode 101 and the second double electrode 102 can be integrally arranged. The double electrode 10 and the double shell 8 are assembled in a sealing butt joint mode.
The cross-sectional structure of the bipolar electrode 10 is shown in fig. 4, in which the first bipolar electrode 101 and the second bipolar electrode 102 are disposed on a conductive material plate 100, and are generally used as a common negative electrode. Two corresponding holes are formed in the board 100, and each hole is provided with a conductor electrode column 1011 and 1021, which is generally used as a positive electrode. Insulating fixing rings 1012 and 1022 are provided between the electrode columns 1011 and 1021 and the board body 100, respectively, to insulate and fix the electrode columns 1011 and 1021 from the board body 100. At this time, two groups of electrodes of positive electrodes and uniform negative electrodes are formed, so that the state of connecting the independently controlled heating bodies can be realized.
When the heating element is specifically connected, the electrodes at the two ends of the heating element can be respectively inserted into the inner side and the outer side of the insulating fixing ring, so that the circuit connection of the heating element can be realized.
In this embodiment, the oil guiding bodies are also divided into two groups, a first oil guiding body 71 and a second oil guiding body 72, wherein a first heating body (not depicted in the drawing) is disposed inside the first oil guiding body 71, a second heating body is disposed inside the second oil guiding body, a first air flow channel 711 is formed inside the first heating body, and a second air flow channel 721 is formed inside the second heating body. The first heating body and the second heating body may be heating resistance wire spirals or cylindrical heating wire meshes, and although the structures of the first heating body and the second heating body are not shown in the drawings of the present embodiment, it is entirely conceivable to those skilled in the art.
The upper side of the double shell 8 is provided with a double cover 6, the double cover 6 is in sealing butt joint with the double shell 8, the first oil guide body 71 and the second oil guide body 72 are sealed in the double shell 8 after being in sealing butt joint with the double shell 8, an independent first atomization core and an independent second atomization core are respectively formed, and a first air outlet channel and a second air outlet channel are arranged on the double cover 6.
The double air passage assembly 4 is arranged, the double air passage assembly is in an integral structure and is in butt joint with the double cover body 6, a first air passage 41 and a second air passage 42 are formed in the double air passage assembly, the first air passage 41 is communicated with the first atomization core air passage 711, and the second air passage 42 is communicated with the second atomization core air passage 721.
The first air passage 41 and the second air passage 42 form a common chamber at the upper end part of the double air passage 4, and the air flows of the double air passages are mixed, converged and buffered to form an air flow buffer chamber 3. A negative pressure switch 5 is arranged at the communication position of the second air passage 42 and the air flow buffer cavity 3, and the negative pressure switch is a mechanical switch and can sense the pressure state of the air flow buffer cavity 3. The upper end of the double air passages 4 is in sealing butt joint with the suction nozzle 1.
The bottom fixed seal of double casing 8 sets up on base 11, and base 11 sets up double casing 8 bottom accommodation space to set up horizontal inlet port, be first intake duct 111 and second intake duct 112 respectively, communicate with horizontal first inlet port 91 and the second inlet port 92 of double casing 8 bottom respectively, and base 11 horizontal inlet duct communicates with the atmosphere. This embodiment is perforated from the end face of the base 11 after being bent downward.
In this embodiment, a power supply control device is also required, and after the power supply control device is in butt joint with the atomizer, power is respectively supplied to the double electrodes 10, and the power supply control device can be respectively controlled. The heating control system of the second atomizing core is linked with the negative pressure switch 5, and when the negative pressure switch 5 is closed, the second double electrode 102 is not powered, that is, the second atomizing core does not work. When the negative pressure switch 5 is turned on, the second atomizing core works, and the negative pressure switch 5 is set to be in a normally closed state.
As shown in fig. 3, the negative pressure switch 5 of the present embodiment is a mechanical switch, is a spring pressure valve provided at the outlet of the second air passage 42, and is composed of a return spring 51, a valve cap 52, a valve body 53, and a vent hole 54. The valve body 53 is of a cylindrical structure and slides in cooperation with the inner wall of the second air passage 42, the cylindrical hollow part of the valve body 53 is communicated with the air passage 42, a vent hole 54 is arranged on the wall surface of the valve body 53, the valve cover 52 is arranged on the upper part of the valve body 53, the whole can cover the upper end surfaces of the valve body 53 and the second air passage 42, and the reset spring 51 presses the valve cover 52 from the upper side. When the negative pressure of the air flow buffer chamber 3 does not reach the threshold value of the negative pressure switch 5, the pressure of the return spring 51 is larger than the negative pressure, at this time, the valve cover 52 and the valve body 53 do not act, and the air flow cannot be communicated at this time in a state that the valve cover 52 covers the air passage 42 and the valve body 53. Once the negative pressure of the air flow buffer cavity is larger than the elastic force of the return spring, the valve body 53 and the valve cover 52 can be moved upwards against the spring pressure until the vent hole 54 is exposed to the position of the air flow buffer cavity 3, and at the moment, the air flow buffer cavity and the air channel 42 can be communicated through the vent hole 54, so that the ventilation effect of the negative pressure switch is realized.
When the product of this embodiment is assembled, after the double electrode 10 is in sealing butt joint with the double shell 8, the oil guide body 7 and the heating body are installed, the heating body is electrically connected with the electrode, the double cover 6 is sealed and covered from the upper side, and the double air passage 4 and the negative pressure switch 5 are installed. The integral atomizing core is then assembled to the belt base 11. The housing 2 and the mouthpiece 1 are assembled to form a complete atomizer. When the atomizer is used, the cigarette oil is poured and the power supply is turned on, and the smoking function can be realized by turning on the switch.
The atomizer of this embodiment sets up two sets of mutually independent control's atomizing core in the atomizing chamber, and two sets of atomizing cores can control operating condition respectively, change operating condition when needs, make be in single atomizing core work and two sets of atomizing core simultaneous working two kinds of states respectively.
The working procedure of the product of this example is as follows: when the power supply starts to be turned on for sucking, the negative pressure switch 5 is in a normally closed state, the second atomization core does not work at the moment, only the first atomization core works, and the electronic cigarette is automatically in a conventional small-amount sucking state and is equivalent to a single atomization core electronic cigarette. When the smoker suddenly increases the smoke suction amount, namely the smoke suction amount and the smoke suction speed are increased, the air flow speed is also increased, at the moment, larger negative pressure is generated at the air flow buffer cavity 3, and when the threshold value of the negative pressure switch 5 is reached, the negative pressure switch 5 is turned on, and the air flow channel of the second atomization core is smooth. The second atomizing core controller which is linked with the negative pressure switch 5 is opened to control the heating work of the second atomizing core. The second atomizing core starts to work, the smoke quantity is increased, and a lung sucking state with large smoke quantity is formed. When the sucking quantity and the sucking speed are restored to the sucking state again, the air flow pressure of the air flow buffer cavity 3 returns to normal, and is automatically closed when the air flow pressure is lower than the threshold value of the negative pressure switch 5. The linked second atomizing core controller stops working and restores the mouth sucking state. Thereby achieving the function of self-adaptive oral-pulmonary conversion.
Example 2:
the present embodiment is a structural change based on embodiment 1, the connection structure is not changed, but the number of groups of atomizing cores can be increased, and the number of atomizing cores can be increased to three groups, four groups or more groups according to the overall space requirement of the atomizer. And a negative pressure switch is arranged at the communication position of the airflow channel of the subsequent atomizing core of the second group of atomizing cores and the airflow buffer cavity, and the threshold value of the negative pressure switch is gradually increased. If the threshold value of the negative pressure switch of the second atomizing core is 950 hundred pascals, the threshold value of the third atomizing core is 900 hundred pascals, and the like. The numerical values herein are merely illustrative of the principles, and may be specifically set according to the intake amount.
Example 3:
the basic structure of this embodiment is the same as that of embodiment 1, and in order to realize the real self-adaptive oral-pulmonary inhalation conversion, a negative pressure switch 5 may be further disposed at the communication position of the air passage 41 of each group of atomizing cores and the air flow buffer cavity 3, that is, a negative first pressure switch is disposed at the communication position of the first air passage 41 and the air flow buffer cavity 3, and a second negative pressure switch is disposed at the communication position of the second air passage 42 and the air flow buffer cavity 3. And the negative pressure switches are respectively in linkage control with the heating controllers of the atomizing cores, namely when the corresponding negative pressure switches are turned on, the corresponding atomizing cores start to heat. The starting threshold values of the first negative pressure switch and the second negative pressure switch are generally different, and the first starting with the small starting threshold value starts to work. If the first atomizing core is arranged to work first, the starting pressure of the first atomizing core can be set to be 1000 hundred Pa, and the starting pressure of the second atomizing core can be set to be 950 hundred Pa.
Example 4:
the negative pressure switch 5 described in embodiments 1 to 3 is a mechanical switch, is an elastic valve, overcomes the elastic force of the spring 51 when the negative pressure reaches a threshold value, is compressed and opened, and returns to the closed state under the pressure of the spring 51 when the negative pressure is below the threshold value, and is a normally closed mechanical switch.
If the negative pressure switch is linked to the atomizing core heating controller at this time, the action of the negative pressure switch 5 needs to be converted into an electric signal, and thus a corresponding device such as a connecting wire or the like needs to be added. A more complex electrical connection structure is required. In order to avoid a complex electrical connection structure, an air flow sensor can be arranged in the air flow channel of each atomizing core, and the air flow sensor can be particularly arranged at the air inlet hole 9 of the atomizing core, and heating is controlled to be opened when sensing that air flow passes through the air flow channel. Since the position of the air inlet 9 is relatively close to the power control means, it is relatively easy to provide an electrical connection. Specifically, if the first air intake hole 91 and the second air intake hole 92 are merged at the base 11 to form a common air intake chamber, the air flow sensor is disposed at a communication position of the air flow passage of the first atomizing core or the second atomizing core, respectively, with the common air intake chamber. If the first air inlet hole 91 and the second air inlet hole 92 are respectively and independently arranged, the air flow sensor is directly arranged at the first air inlet hole 91 and the second air inlet hole respectively, and the purpose is to respectively arrange in the air flow channels of the atomizing cores.
The self-adaptive capability of the structure of this embodiment is more strengthened, when just starting smoking action, is in standby state, and when no air current passed through first atomizing core, the air current sensor of 91 department of first atomizing core air current inlet port was unable to be perceived the air current and is passed through, and first atomizing core is not heated the work this moment, and when smoking air current produced, first atomizing core just begins to work, heats the atomizing, avoids the atomizing core department operating condition when not smoking. Meanwhile, only after the negative pressure switch 5 is opened, when air flows through the second atomization core, the second atomization core starts to heat, so that misoperation is avoided.
Example 5:
on the basis of the above embodiment, more groups of atomizing cores may be provided, and a third through nth atomizing cores may be provided in addition to the first and second atomizing cores. Negative pressure switches are arranged at the communication positions of the air passages of all the atomizing cores and the air flow buffer cavity, and air flow sensors are arranged at the positions of the air inlets of all the atomizing cores. The threshold value of the negative pressure switch of the atomizing core is gradually increased, such as a first atomizing core negative pressure switch threshold value of 1000 hundred Pa, a second atomizing core negative pressure switch threshold value of 950 hundred Pa, a third atomizing core negative pressure switch threshold value of 900 hundred Pa and the like. Only if so arranged will a gradual opening occur with increasing suction pressure. And along with the difference of suction pressure, first atomizing core work can also appear in the operating condition of atomizing core, and second atomizing core and first atomizing core simultaneous working, and the state such as third atomizing core and second, first atomizing core simultaneous working.
Example 6:
in this embodiment, an electronic negative pressure switch is used instead of a mechanical negative pressure switch, specifically, an electronic air pressure gauge may be disposed at the air flow buffer cavity 3, and an air flow valve is disposed at a position where the air flow channel communicates with the air flow channel through the air flow channel 41 or 42, so as to open or close the air flow channel. And the electronic air press is linked with the air flow valve, and the corresponding air flow valve is opened when a certain proper negative pressure value is reached, so that self-adaptive control is realized. In this embodiment, an air flow sensor at the air inlet hole can be omitted, and the pressure sensed by the electronic pressure gauge is used to control the current on-off of the atomizing core heating body.
The atomizer of example 1 of the present invention works as follows:
firstly, an electronic cigarette switch is turned on to start sucking, a first atomization core starts working, aerosol generated by the first atomization core is sucked, and the electronic cigarette is in a mouth sucking state. Meanwhile, the negative pressure switch 5 detects the suction pressure of the airflow buffer cavity 3, when the suction pressure reaches the negative pressure starting threshold value of the negative pressure switch 5, the negative pressure switch 5 is started, the second atomization core starts to work, aerosol is generated by the second atomization core, and the second atomization core is in a lung suction state. When the lung sucking state is finished and the sucking pressure is reduced, the negative pressure of the airflow buffer cavity 3 is reduced, and when the negative pressure is lower than the opening negative pressure threshold value of the negative pressure switch 5, the negative pressure switch 5 is closed again and the sucking state is entered again. Stopping the mouth suction state requires closing the electronic cigarette switch.
The atomizer of example 2 of the present invention works as follows:
firstly, an electronic cigarette switch is turned on, a standby state is entered, negative pressure switches of a first atomization core and a second atomization core are in a closed state, and the atomization cores do not work. When the first mouth sucking starts, the negative pressure switch detects the smoking negative pressure of the airflow buffer cavity 3, and when the negative pressure reaches the opening threshold value of the first atomization core negative pressure switch, the first atomization core negative pressure switch is opened, and the first atomization core is controlled to be opened to start heating atomization. Meanwhile, the second atomization core negative pressure switch detects the negative pressure of the airflow buffer cavity 3, and when the negative pressure is not changed or does not reach the opening threshold value of the second atomization core negative pressure switch, the second atomization core negative pressure switch still works and is in a mouth sucking state. When the negative pressure of the airflow buffer cavity 3 reaches the opening threshold value of the second atomization core negative pressure switch, the second atomization core negative pressure switch is turned on, and the second atomization core is controlled to heat, so that the lung sucking state is achieved. When the lung sucking state is finished and the sucking pressure is reduced, the negative pressure of the airflow buffering cavity is reduced, and when the negative pressure is lower than the opening negative pressure threshold value of the second negative pressure switch, the second negative pressure switch is closed again and enters a standby state, and then the air flow buffering cavity is also in the sucking state. When the smoking pressure continues to be reduced to the opening threshold pressure of the first atomization core negative pressure switch, the first atomization core negative pressure switch is closed again, and the whole electronic cigarette enters a standby state.
The structure of embodiment 2 adds a workflow after the airflow sensor is provided.
Firstly, an electronic cigarette switch is turned on, a standby state is entered, negative pressure switches of a first atomization core and a second atomization core are in a closed state, and the atomization cores do not work. When the first mouth sucking starts, the negative pressure switch detects the smoking negative pressure of the airflow buffering cavity 3, when the negative pressure reaches the opening threshold value of the first atomization core negative pressure switch, the first atomization core negative pressure switch is opened, and meanwhile, the first atomization core airflow sensor senses that airflow passes through, and the first atomization core is controlled to be opened to start heating atomization. Meanwhile, the second atomization core negative pressure switch detects the negative pressure of the airflow buffer cavity 3, and when the negative pressure is not changed or does not reach the opening threshold value of the second atomization core negative pressure switch, the second atomization core negative pressure switch still works and is in a mouth sucking state. When the negative pressure of the air flow buffer cavity 3 reaches the opening threshold value of the second atomization core negative pressure switch, the second atomization core negative pressure switch is turned on, the second atomization core air flow sensor detects that the second atomization core passes through the air flow, and the second atomization core is controlled to heat and work, so that the air flow buffer cavity is in a lung suction state. When the lung sucking state is finished and the sucking pressure is reduced, the negative pressure of the air flow buffer cavity is reduced, when the negative pressure is lower than the opening negative pressure threshold value of the second negative pressure switch, the second negative pressure switch is closed again, meanwhile, the second atomization core air flow disappears, the second atomization core air flow sensor controls the second atomization core to stop heating, the second atomization core air flow sensor enters a standby state, and the second atomization core air flow sensor enters the sucking state again. When the smoking pressure continues to be reduced to the opening threshold pressure of the first atomization core negative pressure switch, the first atomization core negative pressure switch is closed again, the first atomization core airflow disappears, the first atomization core airflow sensor controls the first atomization core to stop working, and the whole electronic cigarette enters a standby state.
Workflow of the structure of example 5.
Firstly, an electronic cigarette switch is turned on, a standby state is entered, negative pressure switches of a first atomization core, a second atomization core and an N atomization core are all in a closed state, and the atomization cores do not work. When the first mouth sucking starts, the negative pressure switch detects the smoking negative pressure of the airflow buffering cavity 3, when the negative pressure reaches the opening threshold value of the first atomization core negative pressure switch, the first atomization core negative pressure switch is opened, and meanwhile, the first atomization core airflow sensor senses that airflow passes through, and the first atomization core is controlled to be opened to start heating atomization. Meanwhile, the second atomization core negative pressure switch detects the negative pressure of the airflow buffer cavity 3, and when the negative pressure is not changed or does not reach the opening threshold value of the second atomization core negative pressure switch, the second atomization core negative pressure switch still works and is in a mouth sucking state. When the negative pressure of the air flow buffer cavity 3 reaches the opening threshold value of the second atomization core negative pressure switch, the second atomization core negative pressure switch is turned on, the second atomization core air flow sensor detects that the second atomization core passes through the air flow, and the second atomization core is controlled to heat and work, so that the air flow buffer cavity is in a lung suction state. When the smoking amount is increased again, the negative pressure of the airflow buffer cavity is increased again to reach the negative pressure switch threshold value of the nth atomizing core, the nth atomizing core is opened to work, and aerosols generated by all atomizing core works are sucked. When the lung sucking state is finished and the sucking pressure is reduced, the negative pressure of the airflow buffering cavity is reduced, when the negative pressure is lower than the opening negative pressure threshold value of the N negative pressure switch, the N negative pressure switch is closed again, and meanwhile the N atomizing core airflow disappears, the N atomizing core airflow sensor controls the N atomizing core to stop heating, the N atomizing core enters a standby state, and the process is continuously reduced and repeated until the first atomizing core stops working. The whole electronic cigarette enters a standby state.
In summary, according to the invention, a plurality of independent atomizing cores are arranged in an atomizer, a common airflow buffering cavity is arranged at the same time, and a negative pressure switch is arranged at the communication position of each atomizing core and the airflow buffering cavity. Through the setting of negative pressure switch, can detect the negative pressure of smoking, when smoking negative pressure reaches certain threshold value, negative pressure switch opens and controls corresponding atomizing core work, and then can realize the multiple improvement of atomizing volume according to the automatic operating condition of natural control atomizing core of the size of suction pressure. The state conversion of sucking large smoke and small smoke can be realized according to the suction pressure, namely the state conversion of sucking mouth and lung is realized, complicated manual adjustment and program control adjustment are not needed, and the natural adaptation process is realized.
According to the self-adaptive structure, the working states of the atomizing cores are adjusted by automatically detecting the negative pressure generated during sucking according to the sucking pressure of a person, so that the conversion of the amount of atomized smoke is realized. In practical use, the man skilled in the art can completely carry out improvement on the basis of the above structure according to the basic idea of the invention, but the man skilled in the art shall fall within the protection scope of the invention as long as the man does not deviate from the basic idea of the invention of alternative heating.

Claims (6)

1. A self-adaptive oral-pulmonary conversion multi-atomization core atomizer is characterized in that,
the atomizer comprises more than two groups of atomizing cores, a control circuit and an air flow channel of each group of atomizing cores are respectively and independently arranged and controlled, and the atomizer also comprises a power supply control device;
the upper end part of each air flow channel of the atomizing cores of more than two groups is provided with a common cavity, and the common cavity is formed into an air flow buffer cavity for mixing, converging and buffering air flows of the air flow channels;
each airflow channel of some or all of the atomizing cores in more than two groups is respectively provided with a negative pressure switch, each negative pressure switch is respectively arranged at the communication position of each airflow channel and the airflow buffering cavity and used for sensing the negative pressure in the airflow buffering cavity, and each airflow channel is communicated with the airflow buffering cavity through each corresponding negative pressure switch; the atomizer further comprises a suction nozzle and an atomization core shell, wherein the suction nozzle is in butt joint connection with the atomization core shell, and the air flow buffer cavity is arranged at the joint of the suction nozzle and the atomization core shell; the negative pressure switch is a mechanical switch, all airflow channels of more than two groups of atomizing cores are provided with airflow sensors, and the airflow sensors of each atomizing core are respectively and independently connected with the power supply control device;
the two or more groups of atomizing cores are defined as a first atomizing core and a second atomizing core, negative pressure switches are arranged at the outlets of the airflow channels of the second atomizing cores and the N atomizing cores, and negative pressure thresholds of the negative pressure switches of the second atomizing cores and the N atomizing cores are sequentially increased; or negative pressure switches are arranged at the outlets of the airflow channels of the first atomizing core, the second atomizing core and the N atomizing core, and negative pressure thresholds of the negative pressure switches of the first atomizing core, the second atomizing core and the N atomizing core are sequentially increased;
the negative pressure switch is a spring pressure valve and is composed of a reset spring, a valve cover, a valve body and an air vent, wherein the valve body is of a cylindrical structure and is matched with the inner wall of the air flow channel to slide, a hollow cylindrical part of the valve body is communicated with the air flow channel, the air vent is arranged on the wall surface of the valve body, the valve cover is arranged on the upper part of the valve body, the valve cover can be integrally covered on the upper end surfaces of the valve body and the air flow channel, the reset spring is tightly pressed from the upper side, when the negative pressure of the air flow buffer cavity does not reach the threshold value of the negative pressure switch, the pressure of the reset spring is larger than the negative pressure, the valve cover and the valve body are not operated, the valve cover is in a state of covering the air flow channel and the valve body, at the moment, air flow cannot be communicated, and once the negative pressure of the air flow buffer cavity is larger than the elastic force of the reset spring, the spring pressure can be overcome, the valve body and the valve cover can be moved upwards until the air vent is exposed to the position of the air flow buffer cavity, and the air flow channel are communicated through the air vent.
2. The adaptive oropulmonary switching multiple aerosolized core nebulizer of claim 1, wherein: more than two groups of atomizing cores are provided with air inlets, the air inlets are shared air inlets to form a shared air inlet cavity, an air flow channel of each atomizing core is communicated with the shared air inlet cavity, and an air flow sensor is arranged at the communication position of the air flow channel of each atomizing core and the shared air inlet cavity.
3. The adaptive oropulmonary switching multiple aerosolized core nebulizer of claim 1, wherein: more than two groups of air inlets of the atomizing cores are respectively and independently arranged, and an air flow sensor is arranged at each air inlet of each atomizing core.
4. A self-adaptive oropulmonary switching multiple-nebulizing core nebulizer according to claim 2 or 3, characterized in that: each group of atomizing cores is provided with an independent heating body, an oil guide body, an airflow channel and an oil inlet; and the oil inlet of each atomizing core is communicated with the oil storage bin, and the airflow sensor of each atomizing core is respectively and independently connected with the power supply control device.
5. A method of controlling an adaptive oropulmonary switching multiple atomizing core atomizer according to any one of claims 1 to 4, comprising the steps of:
a: starting smoking, generating negative pressure by the airflow buffer cavity, and enabling the first atomization core to work to absorb aerosol atomized by the first atomization core;
b: increasing smoke absorption amount, increasing negative pressure of the airflow buffer cavity, opening a second atomization core negative pressure switch, and enabling the second atomization core to work to absorb aerosol atomized by the first atomization core and the second atomization core together;
c: and the smoke sucking amount is continuously increased, the negative pressure of the airflow buffering cavity is continuously increased until an N-th atomization core negative pressure switch is turned on, the N-th atomization core works, and the first aerosol, the second aerosol and the N-th aerosol core are sucked to atomize the aerosol.
6. A method of controlling an adaptive oropulmonary switching multiple atomizing core atomizer according to any one of claims 1 to 4, comprising the steps of:
a: starting smoking, generating negative pressure by the airflow buffer cavity, opening a first atomization core negative pressure switch and an airflow channel, enabling the first atomization core airflow sensor to sense airflow to pass through, controlling the first atomization core to work and atomize by the control device, and sucking aerosol atomized by the first atomization core;
b: the smoke suction amount is increased, the negative pressure of the airflow buffer cavity is increased, a second atomization core negative pressure switch and an airflow channel are opened, the second atomization core airflow sensor senses airflow to pass, and the control device controls the second atomization core to work and atomize, so that aerosol atomized by the first atomization core and the second atomization core is sucked;
c: and the smoke sucking amount is continuously increased, the negative pressure of the airflow buffering cavity is continuously increased until an N-th atomization core negative pressure switch and an airflow channel are opened, the airflow sensor of the N-th atomization core senses airflow to pass, and the control device controls the N-th atomization core to work and atomize, so that the aerosol atomized by the first atomization core and the second atomization core is sucked until the N-th atomization core is added.
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