CN111887487A - Working method of electronic atomizer, storage device and electronic atomizer - Google Patents

Abstract

The invention discloses an electronic atomizer, a storage device and a working method of the electronic atomizer, wherein the working method can prevent an atomizing element from being burnt. The technical scheme adopted by the invention is as follows: an operating method of an electronic atomizer, comprising the steps of: a. acquiring a signal for supplying power to the atomization element; b. if the power supply signal is acquired, the power supply supplies power to the atomization element, and whether airflow passes through the airflow channel within the set time or not or/and whether the suction nozzle is contacted within the set time or not are further detected; c. if the situation that air flow passes through the air flow channel or/and the suction nozzle is contacted is detected within set time, the power supply source continuously supplies power to the atomization element, and otherwise, the power supply source is controlled not to supply power to the atomization element.

Description

Working method of electronic atomizer, storage device and electronic atomizer

Technical Field

The invention relates to the technical field of electronic atomizers, in particular to a working method of an electronic atomizer, a storage device and the electronic atomizer.

Background

In recent years, the electronic atomizer is accepted and favored by more and more smokers as a substitute for cigarettes due to the characteristics of convenience in use, safety, health and the like. In the use process, the atomizing element in the electronic atomizer generates heat, so that the smoke generating substance is atomized to form smoke for smokers to inhale. When not in use, the electronic atomizer can be directly stored and put into a pocket or a backpack.

Common electronic atomizer in the existing market, the consumer makes atomizing element get into operating condition through pressing the job key, and atomizing element heating smoke substance produces smog, if the user does not suck the heat that atomizing element produced for a long time this moment in the electronic atomizer, atomizing element easily is burnt out because of the high temperature to influence the follow-up use experience to electronic atomizer of user.

Disclosure of Invention

In light of the deficiencies of the prior art, the technical problem underlying the present invention is to provide a method of operating an electronic atomizer, a storage device, an electronic atomizer, which can prevent burning-out of an atomizing element at a high probability.

In order to solve the technical problems, the technical scheme adopted by the invention is as follows: an operating method of an electronic atomizer, comprising the steps of: a. acquiring a signal for supplying power to the atomization element; b. if the power supply signal is acquired, the power supply supplies power to the atomization element, and whether airflow passes through the airflow channel within the set time or not or/and whether the suction nozzle is contacted within the set time or not are further detected; c. if the situation that air flow passes through the air flow channel or/and the suction nozzle is contacted is detected within set time, the power supply source continuously supplies power to the atomization element, and otherwise, the power supply source is controlled not to supply power to the atomization element.

Further, in the technical scheme, in the step b, the step of detecting whether the airflow passes through the airflow channel is to obtain a signal indicating whether the air pressure or the air pressure change in the airflow channel reaches a set value.

Further, in the technical scheme, in the step b, the step of detecting whether the airflow passes through the airflow channel is to obtain a signal whether an airflow switch communicated with the airflow channel is triggered.

Further, the scheme for detecting whether the suction nozzle is contacted in the step b is to acquire a signal indicating whether the temperature change or temperature at the suction nozzle reaches a predetermined value.

Further, the scheme for detecting whether the suction nozzle is contacted in the step b is to acquire the brightness change of the light signal at the suction nozzle or whether the light signal is blocked.

Further, the scheme for detecting whether the suction nozzle is contacted in the step b is to acquire whether a contact switch on the suction nozzle is touched.

Further, the power supply signal obtained in step a in the present technical solution is given by a push switch or a touch switch on the power supply.

Further, in the present embodiment, the set time is preferably a value within a time range in which the atomization element is not burned under the operating voltage when no air flows through the air flow passage.

Further, in the present embodiment, the setting time is preferably a value within 0 to 2 seconds.

In order to solve the above technical problem, another aspect of the present invention provides a working method of an electronic atomizer, including the steps of: a. acquiring a signal for supplying power to the atomization element; b. if the power supply signal is acquired, detecting whether the airflow passes through the airflow channel within the set time or/and detecting whether the suction nozzle is contacted within the set time; c. if the situation that air flow passes through the air flow channel or/and the suction nozzle is contacted is detected within set time, the power supply supplies power to the atomization element, otherwise, the power supply is controlled not to supply power to the atomization element.

Further, in the technical scheme, in the step b, the step of detecting whether the airflow passes through the airflow channel is to obtain a signal indicating whether the air pressure or the air pressure change in the airflow channel reaches a set value.

Further, in the technical scheme, in the step b, the step of detecting whether the airflow passes through the airflow channel is to obtain a signal whether an airflow switch communicated with the airflow channel is triggered.

Further, the scheme for detecting whether the suction nozzle is contacted in the step b is to acquire a signal indicating whether the temperature change or temperature at the suction nozzle reaches a predetermined value.

Further, the scheme for detecting whether the suction nozzle is contacted in the step b is to acquire the brightness change of the light signal at the suction nozzle or whether the light signal is blocked.

Further, the scheme for detecting whether the suction nozzle is contacted in the step b is to acquire whether a contact switch on the suction nozzle is touched.

Further, the power supply signal obtained in step a in the present technical solution is given by a push switch or a touch switch on the power supply.

Further, in the present embodiment, the set time is preferably a value within a time range in which the atomization element is not burned under the operating voltage when no air flows through the air flow passage.

Further, in the present embodiment, the setting time is preferably a value within 0 to 2 seconds.

In order to solve the above technical problem, another aspect of the present invention provides a working method of an electronic atomizer, including the steps of: a. acquiring a signal for supplying power to the atomization element; b. if the power supply signal is acquired, detecting whether air flow passes through the air flow channel or/and detecting whether the suction nozzle is contacted; c. if the situation that air flow passes through the air flow channel or/and the suction nozzle is contacted is detected, the power supply supplies power to the atomization element, otherwise, the power supply does not supply power to the atomization element.

Further, in the technical scheme, in the step b, the step of detecting whether the airflow passes through the airflow channel is to obtain a signal indicating whether the air pressure or the air pressure change in the airflow channel reaches a set value.

Further, in the technical scheme, in the step b, the step of detecting whether the airflow passes through the airflow channel is to obtain a signal whether an airflow switch communicated with the airflow channel is triggered.

Further, the scheme for detecting whether the suction nozzle is contacted in the step b is to acquire a signal indicating whether the temperature change or temperature at the suction nozzle reaches a predetermined value.

Further, the scheme for detecting whether the suction nozzle is contacted in the step b is to acquire the brightness change of the light signal at the suction nozzle or whether the light signal is blocked.

Further, the scheme for detecting whether the suction nozzle is contacted in the step b is to acquire whether a contact switch on the suction nozzle is touched.

Further, the power supply signal obtained in step a in the present technical solution is given by a push switch or a touch switch on the power supply.

Further, in the present embodiment, the set time is preferably a value within a time range in which the atomization element is not burned under the operating voltage when no air flows through the air flow passage.

Further, in the present embodiment, the setting time is preferably a value within 0 to 2 seconds.

In order to solve the above technical problem, another aspect of the present invention provides a working method of an electronic atomizer, including the steps of: a. detecting whether air flow passes through the air flow channel or/and detecting whether the suction nozzle is contacted; b. if the airflow in the airflow channel passes through or/and is contacted with the suction nozzle, acquiring a signal for supplying power to the atomization element; c. if the power supply signal is acquired, the power supply supplies power to the atomization element, otherwise, the power supply does not supply power to the atomization element.

Further, in the technical scheme, in the step a, the step of detecting whether the airflow passes through the airflow channel is to obtain a signal indicating whether the air pressure or the air pressure change in the airflow channel reaches a set value.

Further, in the technical scheme, in the step a, the step of detecting whether the airflow passes through the airflow channel is to obtain a signal indicating whether an airflow switch communicated with the airflow channel is triggered.

Further, the scheme of detecting whether the suction nozzle is contacted in the step a is to acquire a signal indicating whether the temperature change or the temperature at the suction nozzle reaches a predetermined value.

Further, the scheme for detecting whether the suction nozzle is contacted in the step a is to acquire the brightness change of the light signal at the suction nozzle or whether the light signal is blocked.

Further, the scheme of detecting whether the suction nozzle is contacted in step a is to acquire whether a contact switch on the suction nozzle is touched.

Further, the power supply signal obtained in step b in the present technical solution is given by a push switch or a touch switch on the power supply.

Further, in the present embodiment, the set time is preferably a value within a time range in which the atomization element is not burned under the operating voltage when no air flows through the air flow passage.

Further, in the present embodiment, the setting time is preferably a value within 0 to 2 seconds.

In order to solve the technical problem, another aspect of the present invention provides a storage device, in which a plurality of instruction codes are stored, and the instruction codes are suitable for being loaded by a processor to execute the working method according to any one of the above technical solutions.

In order to solve the technical problem, in another aspect, the present invention provides an electronic atomizer, including a power supply and an atomizer, where the power supply includes a battery cell, a power supply switch, and a control circuit, the atomizer includes a suction nozzle, an atomizing element, and an airflow channel, the power supply switch is electrically connected to the control circuit for a user to actively trigger a signal for supplying power to the atomizing element, the control circuit includes a memory and a microprocessor, the atomizing element generates heat to generate smoke, the memory stores multiple instruction codes, and the microprocessor can call the instruction codes stored in the memory to execute the operating method according to any one of the above technical solutions.

The technical scheme provided by the invention has the main beneficial effects that: because the atomizing element only has airflow passing through or/and the suction nozzle to be contacted (which indicates that the user is smoking or has strong smoking willing) in the airflow channel and the power supply source continuously supplies power to the atomizing element after the power supply signal of the atomizing element is obtained, the atomizing element can be effectively prevented from being burnt, the smoke taste is ensured, and the use experience of the user on the electronic atomizer is enhanced.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings required to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

FIG. 1 is a front view of an electronic atomizer according to an embodiment of the present invention;

FIG. 2 is a sectional view of the power supply of FIG. 1;

FIG. 3 is a cross-sectional view of the atomizer of FIG. 1;

FIG. 4 is a flow chart of a method of operating an electronic atomizer according to one embodiment;

FIG. 5 is a flowchart of a method of operating an electronic atomizer according to a second embodiment;

fig. 6 is a flow chart of a working method of the electronic atomizer according to the third embodiment.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects to be solved by the present invention more clearly apparent, the present invention is further described in detail below with reference to the embodiments and the accompanying drawings. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.

Detailed description of the preferred embodiment

As shown in fig. 1, fig. 2, and fig. 3, which are schematic views of an implementation environment of an electronic atomizer according to a preferred embodiment of the present invention. The electronic atomizer 100 includes a power supply 110 and an atomizer 120, and the power supply 110 and the atomizer 120 are connected by a detachable connection structure. The power supply 110 includes a housing 111, a rechargeable battery cell 112, a PCBA board 113, a power supply switch 114 and an air duct 115, wherein the rechargeable battery cell 112, the PCBA board 113 and the air duct 115 are disposed in the housing 111, and the power supply switch 114 is disposed on the PCBA board 113. The atomizer 120 comprises a storage compartment 121 for storing a smoking substance, an atomizing element 122, a connecting electrode 123, an airflow channel 124 and a mouthpiece 125. The electric core 112 is used for supplying power for the PCBA board 113 and the atomizing element 122. The atomizing element 122 is electrically connected with the connecting electrode 123 to obtain electric energy, and the atomizing element 122 is used for sucking the smoking substance in the storage chamber 121 and heating and atomizing the sucked smoking substance to generate smoke; the airflow channel 124 is used for allowing airflow to pass through so that smoke generated by the aerosol heating of the smoking substance by the atomizing element 122 flows out through the airflow channel 124 and then through the suction nozzle 125 for being sucked by a user. When the atomizer 120 is connected to the power supply 110, the airflow passage 124 communicates with the air duct 115 while the electrical connection is completed. The power switch 114 is used to provide a signal to the control circuitry on the PCBA board 113 to power the atomizing element 122, and the power switch 114 is preferably a push switch or a touch switch. In this embodiment, the power switch 114 is a touch switch, and the atomizing element 122 is a heating element.

As shown in fig. 2, the PCBA board 113 is provided with electronic components such as a memory 1131 and a processor 1132, which are connected by wires to form a control circuit. The memory 1131 stores a plurality of instruction codes, which include various preset conditions (e.g., set time). Processor 1132 can invoke instruction code stored in memory 1131 to perform the following operations: a. acquiring a signal to power the atomizing element 122; b. if the power supply signal is acquired, the electric core 112 is not prevented from supplying power to the atomizing element 122, so that the atomizing element 122 is preheated in a short time; c. detecting whether the air flow channel 124 passes through the air flow channel within a set time and detecting whether the suction nozzle 125 is contacted within a set time (in other embodiments, only one of the two conditions may be selected); d. if it is detected that the airflow in the airflow channel 124 passes through and is contacted with the suction nozzle 125 within the set time, it is determined that the user is sucking the electronic atomizer 100, and the electric core 112 continuously supplies power to the atomizing element 122, otherwise, the processor 1132 controls the electric core 112 not to supply power to the atomizing element 122, so as to prevent the atomizing element 122 from being burnt. In the present embodiment, the set time is set to 2 seconds after the power supply signal is acquired (i.e., the contact between the suction nozzle 125 and the airflow is detected within 2 seconds after the power supply switch 114 is triggered). An airflow switch 116 is further arranged in the power supply 110, the airflow switch 116 is electrically connected with the PCBA board 113 and then located in the air passage 115 and used for detecting whether airflow passes through the air passage 124, and the airflow switch 116 can be used for selecting a microphone commonly used in the field of electronic atomizers. Because air path 115 is in communication with air flow path 124, when a user draws on electronic atomizer 100, air path 115 and air flow path 124 both generate a certain negative pressure, and air flow switch 116 is triggered to signal processor 1132 that air is flowing through air flow path 124.

In the present embodiment, the principle of selecting the set time is preferably within a time range in which the atomizing element 122 is not burned at the operating voltage (rated voltage) when no air flows through the air flow passage 124. In the conventional data, the setting time is preferably a value within 0 to 2 seconds.

In this embodiment, the mouthpiece 125 may further be provided with a touch switch, and the touch switch is preferably provided at a position where the lips of the user can easily touch the mouthpiece when smoking. After the atomizer 120 is connected to the power supply 110, the contact switch electrically connects the PCBA board 113 to pass a contact signal to the processor 1132. The scheme for detecting whether the suction nozzle 125 is touched in operation c at this time is to acquire whether a touch switch on the suction nozzle 125 is touched. The touch switch is a touch switch.

In other embodiments, a pressure sensor may be disposed within flow path 124 or airway 115 to detect changes in pressure within flow path 124 or airway 115, and the pressure sensor may transmit the detected pressure information to processor 1132. The scheme for detecting whether there is air flow in the air flow channel 124 in operation c may be to obtain a signal whether the air pressure in the air flow channel 124 is reduced to a set value or whether the air pressure change in the air flow channel 124 reaches a set value.

In other embodiments, the suction nozzle 125 may further include a temperature sensor, and the temperature sensor may be a temperature sensing module for measuring the temperature of the human body. After power supply 110 is connected to nebulizer 120, the temperature sensor is electrically connected to PCBA board 113 to communicate the sensed temperature information to processor 1132. The scheme of detecting whether the suction nozzle 125 is contacted in operation c at this time may be to acquire a signal whether the temperature or the temperature variation at the suction nozzle 125 reaches a predetermined value.

In other embodiments, a light signal sensor may be further disposed on the suction nozzle 125, and the light signal sensor is used to detect the brightness change or the blockage of the light signal at the suction nozzle 125. After power supply 110 is connected to nebulizer 120, the optical signal sensor is electrically connected to PCBA board 113 to transmit the detected optical signal to processor 1132. The optical signal sensor may be an infrared transmitting and receiving device for detecting whether the optical signal is blocked at the suction nozzle 125. The scheme of detecting whether the suction nozzle 125 is touched in operation c at this time may be to acquire whether the optical signal at the suction nozzle 125 is blocked.

Fig. 4 is a schematic flow chart of a working method of an electronic atomizer according to the present embodiment. Specifically, the working method comprises the following steps:

s11, processor 1132 obtaining a signal for powering the atomizing element 122; if the power supply signal is acquired, the process proceeds to step S12. In this embodiment, the triggering of the power supply signal is given by the user actively pressing the power supply switch 114.

S12, the electric core 112 supplies power to the atomizing element 122, and further detects whether the airflow channel 124 passes through within a set time, and detects whether the suction nozzle 125 is contacted within a set time.

S13, if it is detected that the air flow in the air flow channel 124 passes through and is contacted with the suction nozzle 125 within the set time, the step S14 is proceeded, otherwise, the step S15 is proceeded.

S14, the power supply 110 continuously supplies power to the atomizing element 122.

S15, the power supply 110 is controlled not to supply power to the atomizing element 122.

Because the power supply 110 continuously supplies power to the atomization element 114 only after the atomization element 112 has airflow in the airflow channel 124 to contact the suction nozzle 125 and the power supply switch 114 is triggered by the atomization element 112 to obtain a power supply signal, the atomization element 112 can be effectively prevented from being burnt, the smoke taste is not influenced by the damage of the atomization element 112 during smoking every time, and the use experience of the user on the electronic atomizer 100 is enhanced.

Detailed description of the invention

The main differences between this embodiment and the first embodiment are: the process of preheating the atomizing element 112 is eliminated. The operation executed by processor 1132 at this time by calling the instruction code stored in memory 1131 is changed to: a. acquiring a signal to power the atomizing element 122; b. if the power supply signal is obtained, detecting whether the airflow channel 124 passes through the set time and detecting whether the suction nozzle 125 is contacted within the set time (in other embodiments, only one of the two conditions may be selected); c. if it is detected that the airflow in the airflow channel 124 passes through and is contacted with the suction nozzle 125 within a set time, it is determined that the user is sucking the electronic atomizer 100, and the electric core 112 supplies power to the atomizing element 122, otherwise, the processor 1132 controls the electric core 112 not to supply power to the atomizing element 122, so as to prevent the atomizing element 122 from being burnt.

Fig. 5 is a schematic flow chart of a working method of an electronic atomizer according to the present embodiment. Specifically, the working method comprises the following steps:

s21, acquiring a signal for supplying power to the atomization element 112; if the power supply signal is acquired, the process proceeds to step S22. In this embodiment, the triggering of the power supply signal is given by the user actively pressing the power supply switch 114.

S22, detecting whether the airflow channel 124 passes through within a set time, and detecting whether the suction nozzle 125 is contacted within a set time.

S23, if it is detected that the air flow in the air flow channel 124 passes through and is contacted with the suction nozzle 125 within the set time, the step S24 is proceeded, otherwise, the step S25 is proceeded.

S24, the power supply 110 supplies power to the atomizing element 122.

S25, the power supply 110 is controlled not to supply power to the atomizing element 122.

In other embodiments, the condition of "setting time" added in this embodiment may also be deleted, so that this embodiment only needs to "acquire a signal for supplying power to the atomizing element 112", and "detect that an airflow in the airflow channel 124 passes through and is contacted with the suction nozzle 125", then the power supply 110 is controlled to supply power to the atomizing element 122, otherwise, the power supply 110 is controlled not to supply power to the atomizing element 122.

Because the atomizing element 112 only supplies power to the atomizing element 114 after the airflow in the airflow channel 124 passes through and is contacted with the suction nozzle 125 and the power supply switch 114 is triggered by the atomizing element 112 to obtain the power supply signal, the power supply 110 can supply power to the atomizing element 114, so that the atomizing element 112 can be effectively prevented from being burnt, the smoke taste is not influenced due to the damage of the atomizing element 112 during smoking every time, and the use experience of a user on the electronic atomizer 100 is enhanced.

Detailed description of the preferred embodiment

The main difference between this embodiment and the second embodiment is that the processor 1132 performs the change of the operation sequence. In particular, processor 1132 calls instruction code stored in memory 1131 to perform the following operations: a. detecting whether the air flow passes through the air flow channel 124 and detecting whether the suction nozzle 125 is contacted; b. if the airflow in the airflow channel 124 is contacted with the suction nozzle 125, acquiring a signal for supplying power to the atomization element 122; c. if the power supply signal is acquired, the battery cell 112 supplies power to the atomization element 122, otherwise, the battery cell 112 does not supply power to the atomization element 122, and the atomization element 122 is prevented from being burnt.

Fig. 6 is a schematic flow chart of a working method of an electronic atomizer according to the present embodiment. Specifically, the working method comprises the following steps:

s31, detecting whether the airflow channel 124 passes through within a set time, and detecting whether the suction nozzle 125 is contacted within a set time.

S32, acquiring a signal for supplying power to the atomizing element 122 if it is detected that the air flow in the air flow channel 124 is contacted with the suction nozzle 125 within a set time; if the power supply signal is acquired, the process proceeds to step S33, otherwise, the process proceeds to step S34.

And S33, the electric core 112 supplies power to the atomization element 122.

S34, the electric core 112 does not supply power to the atomizing element 122.

Because the atomizing element 112 only supplies power to the atomizing element 114 after the airflow in the airflow channel 124 passes through and is contacted with the suction nozzle 125 and the power supply switch 114 is triggered by the atomizing element 112 to obtain the power supply signal, the power supply 110 can supply power to the atomizing element 114, so that the atomizing element 112 can be effectively prevented from being burnt, the smoke taste is not influenced due to the damage of the atomizing element 112 during smoking every time, and the use experience of a user on the electronic atomizer 100 is enhanced.

Through the above description of the embodiments, those skilled in the art will clearly understand that the embodiments may be implemented by software plus a necessary general hardware platform, and may also be implemented by hardware. With this understanding in mind, the above-described technical solutions may be embodied in the form of a software product, which may be stored in a computer-readable storage medium, such as a ROM/RAM, a magnetic disk, an optical disk, etc., and portions thereof that essentially contribute to the prior art. In addition, the program instruction codes may be stored in only one storage medium, or may be stored separately in several storage media, so that several instructions may execute the working methods described in various embodiments or some parts of embodiments with one device (which may be a personal computer, a server, or a network device).

While the principles and embodiments of this invention have been described above using specific examples, it is to be understood that the above embodiments are merely provided to assist in understanding the invention and are not to be construed as limiting the invention. Any minor modifications or equivalent alterations to the structural form or configuration of the present invention according to the idea of the present invention shall be included in the protection scope thereof for a person skilled in the art.

Claims (10)

1. An operating method of an electronic atomizer, comprising the steps of: a. acquiring a signal for supplying power to the atomization element; b. if the power supply signal is acquired, the power supply supplies power to the atomization element, and whether airflow passes through the airflow channel within the set time or not or/and whether the suction nozzle is contacted within the set time or not are further detected; c. if the situation that air flow passes through the air flow channel or/and the suction nozzle is contacted is detected within set time, the power supply source continuously supplies power to the atomization element, and otherwise, the power supply source is controlled not to supply power to the atomization element.

2. The method of operation of claim 1, wherein: in the step b, the scheme for detecting whether the airflow passes through the airflow channel is to obtain a signal whether the air pressure or the air pressure change in the airflow channel reaches a set value; or in the step b, the scheme for detecting whether the airflow passes through the airflow channel is to obtain a signal for judging whether an airflow switch communicated with the airflow channel is triggered; or the scheme for detecting whether the suction nozzle is contacted in the step b is to acquire a signal of temperature change or whether the temperature at the suction nozzle reaches a preset value; or the scheme for detecting whether the suction nozzle is contacted in the step b is to acquire the brightness change or the blockage of the optical signal at the suction nozzle; or the scheme for detecting whether the suction nozzle is contacted in the step b is to acquire whether a contact switch on the suction nozzle is touched; or the power supply signal obtained in the step a is given by a push switch or a touch switch on the power supply; or the set time is preferably a value within a time range in which the atomization element is not burnt at the operating voltage when no air flow passes through the air flow channel; or the set time is preferably a value within 0-2 seconds.

3. An operating method of an electronic atomizer, comprising the steps of: a. acquiring a signal for supplying power to the atomization element; b. if the power supply signal is acquired, detecting whether the airflow passes through the airflow channel within the set time or/and detecting whether the suction nozzle is contacted within the set time; c. if the situation that air flow passes through the air flow channel or/and the suction nozzle is contacted is detected within set time, the power supply supplies power to the atomization element, otherwise, the power supply is controlled not to supply power to the atomization element.

4. The method of operation of claim 10, wherein: further comprising the additional technical features of any one of claims 2 to 9.

5. An operating method of an electronic atomizer, comprising the steps of: a. acquiring a signal for supplying power to the atomization element; b. if the power supply signal is acquired, detecting whether air flow passes through the air flow channel or/and detecting whether the suction nozzle is contacted; c. if the situation that air flow passes through the air flow channel or/and the suction nozzle is contacted is detected, the power supply supplies power to the atomization element, otherwise, the power supply does not supply power to the atomization element.

6. The method of operation of claim 12, wherein: further comprising the additional technical features of any one of claims 2 to 7.

7. An operating method of an electronic atomizer, comprising the steps of: a. detecting whether air flow passes through the air flow channel or/and detecting whether the suction nozzle is contacted; b. if the airflow in the airflow channel passes through or/and is contacted with the suction nozzle, acquiring a signal for supplying power to the atomization element; c. if the power supply signal is acquired, the power supply supplies power to the atomization element, otherwise, the power supply does not supply power to the atomization element.

8. The method of operation of claim 14, wherein: in the step a, the scheme for detecting whether the airflow passes through the airflow channel is to obtain a signal whether the air pressure or the air pressure change in the airflow channel reaches a set value; or in the step a, the scheme for detecting whether the airflow passes through the airflow channel is to obtain a signal for judging whether an airflow switch communicated with the airflow channel is triggered; or the scheme for detecting whether the suction nozzle is contacted in the step a is to acquire a signal of temperature change at the suction nozzle or whether the temperature reaches a preset value; or the scheme for detecting whether the suction nozzle is contacted in the step a is to acquire the brightness change or the blockage of the optical signal at the suction nozzle; or the scheme for detecting whether the suction nozzle is contacted in the step a is to acquire whether a contact switch on the suction nozzle is touched; or the power supply signal obtained in the step b is given by a push switch or a touch switch on the power supply; or the set time is preferably a value within a time range in which the atomization element is not burnt at the operating voltage when no air flow passes through the air flow channel; or the set time is preferably a value within 0-2 seconds.

9. A storage device, characterized by: a plurality of instruction codes stored therein, the instruction codes being adapted to be loaded by a processor to perform the working method as claimed in any one of claims 1 to 22.

10. The utility model provides an electronic atomizer, includes power supply and atomizer, power supply includes electric core, power switch and control circuit, the atomizer includes suction nozzle, atomizing element and air current channel, the power switch electricity is connected the control circuit is used for supplying user's initiative to trigger give to the signal of atomizing element power supply, control circuit includes memory and microprocessor, atomizing element generates heat and makes the fuming substance produce smog, its characterized in that: a plurality of instruction codes are stored in the memory, the microprocessor being capable of calling the instruction codes stored in the memory to perform the method of any one of claims 1 to 22.

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