CN215189405U - Alternate heating type atomizer and atomizing device - Google Patents

Abstract

The utility model discloses an add hot type atomizer and atomizing device in turn, this add hot type atomizer in turn includes: the device comprises a shell, a negative pressure sensor, a concentration sensor, a control module and at least two atomizing cores, wherein the shell is provided with an accommodating cavity and an air outlet channel; the negative pressure sensor is arranged on the inner wall of the air outlet channel; the atomizing core is respectively communicated with the air inlet of the air outlet channel so as to atomize the liquid entering the atomizing core to form atomized liquid; the concentration sensor is arranged on the inner wall of the air outlet channel so as to detect concentration data of the atomized liquid in the air outlet channel; the control module is respectively electrically connected with the negative pressure sensor, the concentration sensor and the atomizing core so as to receive the air flow signal and control at least one atomizing core to start working according to the air flow signal, and when the concentration data is received and reaches a set value, the control module controls the atomizing core to stop working and switches to another atomizing core. The utility model discloses an atomizer can alternate heating, is favorable to the thermal diffusion and can reduce atomizing core carbon deposit, and then promotes the performance of atomizer.

Description

Alternate heating type atomizer and atomizing device

Technical Field

The utility model relates to an atomizing device especially relates to an add hot type atomizer and atomizing device in turn.

Background

Existing atomizers typically include one or two atomizing cores. The atomizer atomizes liquid by simultaneously operating one or two atomizing cores. During the atomization process, the atomizing core is often required to be heated continuously. When the atomizing core continuously works, liquid cannot conveniently and fully enter the atomizing core, so that the problem that the atomizing core is pasted with the atomizing core is easily caused; the heat that the atomizing core that lasts the work produced is difficult for diffusing, forms heat accumulation easily, leads to the problem that the nozzle is scalded to the suction nozzle of atomizer.

In view of the above, there is a need for further improvements in the current atomizer configurations.

SUMMERY OF THE UTILITY MODEL

In order to solve at least one of the above technical problems, the present invention provides an alternately heating atomizer and an atomizing device.

In order to achieve the above object, the utility model discloses a technical scheme do: there is provided an alternately heating atomizer comprising:

the shell is provided with an accommodating cavity and an air outlet channel communicated with the accommodating cavity;

the negative pressure sensor is arranged on the inner wall of the air outlet channel so as to detect an air flow signal of an air outlet in the air outlet channel;

the atomizing cores are respectively communicated with the air inlets of the air outlet channels so as to atomize the liquid entering the atomizing cores to form atomized liquid;

the concentration sensor is arranged on the inner wall of the air outlet channel so as to detect concentration data of atomized liquid in the air outlet channel;

and the control module is respectively electrically connected with the negative pressure sensor, the concentration sensor and the atomization core to receive an air flow signal and control at least one atomization core to start working according to the air flow signal, and to receive concentration data and control the atomization core to stop working and switch to another atomization core when the concentration data reaches a set value.

Wherein, consistency transmitter including respectively with first consistency transmitter and the second consistency transmitter that the control module electricity is connected, first consistency transmitter is arranged in detecting the effective material in the atomized liquid, second consistency transmitter is arranged in detecting the second consistency transmitter of harmful substance in the atomized liquid, control module is used for receiving effective material concentration and harmful substance concentration, and when effective material concentration equals harmful substance concentration, control atomizing core stop work.

The device also comprises an indicating module and a manual change-over switch which are respectively electrically connected with the control module, wherein the indicating module is used for generating a warning signal when the other atomizing core is not switched to; the manual change-over switch is used for responding to clicking, shifting, sliding and pressing operations and manually switching to another atomizing core.

The device also comprises a counter electrically connected with the control module, wherein the counter is used for recording the suction action times corresponding to the airflow signal and alternately switching the atomizing core according to different suction action times.

The device comprises a control module, a timer and an atomization core, wherein the control module is electrically connected with the control module, the timer is used for detecting the heating time of the atomization core in a period, and when the heating time of the atomization core reaches a set value, the atomization core is controlled to stop working and is switched to another atomization core.

Wherein each atomizing core comprises a heating loop electrically connected with the control module.

The heating circuit comprises a positive connecting column, a negative connecting column and at least two negative connecting columns shared by the heating circuits.

Wherein, the number of the atomizing cores is three or more, and the three or more atomizing cores are uniformly distributed in a ring shape.

Wherein, three or more than three atomizing cores are divided into at least two groups, and each group of atomizing cores are heated simultaneously.

In order to achieve the above object, the utility model discloses a another technical scheme does: an atomizing apparatus is provided, which comprises the above-mentioned alternately heating atomizer.

The technical scheme of the utility model mainly comprises a shell, a negative pressure sensor, a concentration sensor, a control module and at least two atomizing cores, wherein the shell is provided with a holding cavity and an air outlet channel, and the negative pressure sensor is arranged on the inner wall of the air outlet channel; the atomizing core is respectively communicated with the air inlet of the air outlet channel so as to atomize the liquid entering the atomizing core to form atomized liquid; the concentration sensor is arranged on the inner wall of the air outlet channel so as to detect concentration data of the atomized liquid in the air outlet channel; the control module is respectively and electrically connected with the negative pressure sensor, the concentration sensor and the atomizing core. When the air outlet device works, the negative pressure sensor is used for detecting an airflow signal of the air outlet channel; the control module is used for receiving an air flow signal and controlling at least one atomization core to start working according to the air flow signal, the concentration sensor is used for detecting the concentration of atomized liquid in the air outlet channel, the control module is also used for receiving concentration data and controlling the atomization cores to stop working and switch to another atomization core when the concentration data reaches a set value, the atomization cores can be controlled to heat alternately by the technical scheme, each atomization core maintains the atomization work of the whole atomizer, the continuous working time of each atomization core is favorably shortened, and therefore heat diffusion is favorably realized, and heat accumulation is favorably avoided; the liquid can flow into the atomizer, carbon deposition of the atomizing core is reduced, dry burning is avoided, the service life of the atomizing core is prolonged, and the service performance of the atomizer can be improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

Fig. 1 is a block diagram of an alternative heating atomizer in accordance with an embodiment of the present invention;

fig. 2 is an internal structural view of an alternate heating type atomizer according to an embodiment of the present invention;

FIG. 3 is a cross-sectional view of an alternate heating atomizer in accordance with an embodiment of the present invention;

fig. 4 is another cross-sectional view of an alternate heating atomizer in accordance with an embodiment of the present invention;

fig. 5 is a block diagram of an atomizing device according to an embodiment of the present invention.

The objects, features and advantages of the present invention will be further described with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

It should be noted that the description of the invention referring to "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implying any number of indicated technical features. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

The problem that the atomization core in the prior art is not convenient to enter fully when the atomization core works continuously, and the atomization core is easy to be pasted with the core is solved; and the difficult diffusion of heat that the atomizing core of continuous work produced, the easy heat accumulation that forms leads to the problem that the suction nozzle of atomizer scalded the mouth, the utility model provides an add hot type atomizer in turn. The alternate heating type atomizer avoids the problem caused by continuous work of the atomizing core by controlling different atomizing cores to work at different time intervals. The following embodiments are referred to for specific configurations of the alternately heating atomizer.

Referring to fig. 1 and 2, fig. 1 is a block diagram of an alternative heating atomizer according to an embodiment of the present invention; fig. 2 is an internal structure view of an alternate heating type atomizer according to an embodiment of the present invention. In the embodiment of the present invention, the alternate heating atomizer mainly includes a housing 800, a negative pressure sensor 100, a concentration sensor 300, a control module 200, and at least two atomizing cores 701. In this embodiment, the negative pressure sensor 100 detects the airflow signal during suction, the concentration sensor 300 detects the concentration data of the atomized liquid in the housing 800, and the control module 200 controls the at least two atomizing cores 701 to alternately work according to the airflow signal and the concentration data, so that the working time of a single atomizing core 701 can be reduced, and the liquid can conveniently and fully enter the atomizing core 701.

Specifically, the housing 800 has an accommodating cavity 801 and an air outlet channel 802 communicated with the accommodating cavity 801; the negative pressure sensor 100 is arranged on the inner wall of the air outlet channel 802 to detect an air flow signal of an air outlet 803 in the air outlet channel 802; the atomizing cores 701 are respectively communicated with the air inlets of the air outlet channels 802 so as to atomize the liquid entering the atomizing cores 701 to form atomized liquid; the concentration sensor 300 is arranged on the inner wall of the air outlet channel 802 to detect concentration data of the atomized liquid in the air outlet channel 802; the control module 200 is electrically connected with the negative pressure sensor 100, the concentration sensor 300 and the atomization core 701 respectively to receive an air flow signal and control at least one atomization core 701 to start working according to the air flow signal, and when concentration data is received and reaches a set value, the atomization core 701 is controlled to stop working and is switched to another atomization core 701.

In this embodiment, the negative pressure sensor 100 is disposed near the air outlet 803 of the air outlet channel 802, and senses an air flow signal caused by a user's suction action, that is, when the air flow signal at the air outlet 803 of the air outlet channel 802 changes, the negative pressure sensor 100 directly detects the air flow signal, which indicates that the user is performing the suction action. The airflow signal detected by the negative pressure sensor 100 is directly transmitted to the control module 200, and the control module 200 controls any one of the atomizing cores 701 to perform heating operation according to the airflow signal, so that the atomizing core 701 can heat the atomized liquid and generate the atomized liquid. The concentration data of the atomized liquid is detected by the concentration sensor 300, and when the concentration of the atomized liquid reaches a set value, the atomization core 701 is controlled to stop working and is switched to another atomization core 701. When the negative pressure sensor 100 detects another airflow signal, another atomizing core 701 starts to operate, and the previous control process is repeated. Through foretell scheme can avoid single atomizing core 701 to work continuously, be favorable to the heat diffusion, can also be favorable to liquid fully to get into atomizing core 701, reduce atomizing core 701 and produce the carbon deposit to promote atomizing core 701's performance.

In a specific embodiment, the concentration sensor 300 includes a first concentration sensor 310 and a second concentration sensor 320 respectively electrically connected to the control module 200, the first concentration sensor 310 is configured to detect an effective substance in the atomized liquid, the second concentration sensor 320 is configured to detect a second concentration sensor 320 of a harmful substance in the atomized liquid, the control module 200 is configured to receive the concentration of the effective substance and the concentration of the harmful substance, and when the concentration of the effective substance is equal to the concentration of the harmful substance, the atomizing core 701 is controlled to stop working.

In consideration of the problem that the effective component decreases with the atomization time and the harmful component increases with the atomization time when the atomization core 701 atomizes the liquid, in the embodiment, two concentration sensors 300 are provided, namely a first concentration sensor 310 and a second concentration sensor 320. The first concentration sensor 310 is used for detecting the concentration of an effective substance, the second concentration sensor 320 is used for detecting the concentration of harmful atomization, and when the concentration of the effective substance is greater than the concentration of the harmful substance, the atomization core 701 is controlled to stop working, so that the atomization core 701 atomizes liquid as much as possible to generate the effective substance. In an actual process, when the difference between the concentration of the effective substance and the concentration of the harmful substance is a set threshold, the atomizing core 701 may be controlled to stop working, so as to increase the concentration of the effective substance in the atomized liquid.

In a specific embodiment, the atomizing device further comprises an indication module 410 and a manual switch 420 electrically connected to the control module 200, respectively, wherein the indication module 410 is configured to generate a warning signal when the atomization core 701 is not switched; the manual switch 420 is used for responding to clicking, shifting, sliding and pressing operations and manually switching to another atomizing core 701. In this embodiment, when the indication module 410 mainly satisfies the switching condition, and the atomization core 701 needs to be switched, a warning signal is generated when the atomization core 701 is not switched to another atomization core 701, so as to remind a user of attention. It is understood that the indication module 410 may be replaced by a vibration module, and the user may be alerted by a vibration signal. The atomizing core 701 can also switch the current atomizing core 701 to another atomizing core 701 according to the clicking, dialing, sliding and pressing operations of the user.

In a specific embodiment, the device further comprises a counter 600 electrically connected to the control module 200, wherein the counter 600 is configured to record the number of suction actions corresponding to the airflow signal, and to alternately switch the atomizing core 701 according to different numbers of suction actions.

In this embodiment, the switching of the atomizing core 701 is not limited to the concentration data of the atomized liquid, but may be switched according to the number of times of pumping operations. The switching of the concentration data checked by the concentration sensor 300 to the atomizing core 701 and the switching according to the pumping action times are not influenced mutually, and the atomizing core 701 can be switched by the concentration data and the pumping action times to meet different switching requirements.

In a specific embodiment, the apparatus further includes a timer 500 electrically connected to the control module 200, where the timer 500 is configured to detect a heating time period of the atomizing core 701 in one period, and when the heating time period of the atomizing core 701 reaches a set value, control the atomizing core 701 to stop working and switch to another atomizing core 701.

Considering that the time length of each suction of the user is different, in the present embodiment, the heating time length of the atomizing core 701 in a single period is detected by the timer 500. When the heating time period reaches a set value, the atomizing core 701 is switched once. Specifically, the switching period may be 0.5s, 1s, or the like. The switching of the concentration data checked by the concentration sensor 300 to the atomizing core 701 and the switching according to the switching cycle of the timer 500 are not affected by each other, and both can switch the atomizing core 701 to meet different switching requirements.

In a specific embodiment, each atomizing core 701 includes a heating circuit electrically connected to the control module 200. Furthermore, the heating circuit comprises a positive connecting column and a negative connecting column, and at least two negative connecting columns are shared by the heating circuit. Each atomizing core 701 is controlled by the control module 200 independently, and the atomizing cores 701 are not affected mutually. Specifically, the heating circuit includes a positive connection post and a negative connection post, and at least two negative connection posts shared by the heating circuit, so that the control circuit of the atomizing core 701 can be simplified.

Referring to fig. 2, in this embodiment, there are two atomization cores, which are a first atomization core and a second atomization core respectively, and the first atomization core and the second atomization core are connected to the control module 200 through the electrode posts respectively. The electrode column comprises a positive connecting column and a negative connecting column, the first atomization core is electrically connected with the control module 200 through the first positive connecting column 921 and the first negative connecting column, and the second atomization core is electrically connected with the control module 200 through the second positive connecting column 922 and the second negative connecting column. To simplify the circuit, the first negative connection post and the second negative connection post are a common negative connection post 910. It is understood that when the number of atomizing cores is three or more, the control module 200 can utilize a single positive connection post and a common negative connection post to supply power to each atomizing core. For the atomizer described above, there may be a plurality of independently operating atomizing cores, there may be an atomizing core having a plurality of heating elements, wherein the plurality of heating elements may operate independently or in combination.

Referring to fig. 3 and 4, fig. 3 is a cross-sectional view of an alternative heating atomizer according to an embodiment of the present invention; fig. 4 is another cross-sectional view of an alternative heating atomizer in accordance with an embodiment of the present invention.

In a specific embodiment, the number of the atomizing cores 701 is three or more, and the three or more atomizing cores 701 are uniformly distributed in a ring shape. In this embodiment, the atomizing cores 701 are arranged in a ring shape, and the working sections having different ring-shaped distributions are heated, respectively, to improve the uniformity of heating.

In a specific embodiment, three or more atomization cores 701 are divided into at least two groups, and each group of atomization cores 701 is heated simultaneously. In this embodiment, the plurality of atomizing cores 701 may be correspondingly divided into at least two groups, which are the first group of atomizing cores 701 and the second group of atomizing cores 702, respectively, and the first group of atomizing cores 701 and the second group of atomizing cores 702 may be independently controlled to heat, so that the requirements of high-power heating and heating uniformity can be satisfied.

The above-described embodiment describes a configuration in which the atomizer has a plurality of atomizing cores that operate independently. It will be appreciated that the structure may also be a single atomizing cartridge having multiple heating elements, wherein each heating element may operate independently or in combination.

Referring to fig. 5, fig. 5 is a block diagram of an atomizing device according to an embodiment of the present invention. In the embodiment of the present invention, the atomizing device 20 includes the above-mentioned alternate heating type atomizer 10. Referring to the above-described embodiment, the present atomizing apparatus 20 employs the above-described alternately heating atomizer 10, and thus has all the advantages and effects of the alternately heating atomizer 10.

The above only is the preferred embodiment of the present invention, not therefore the limitation of the patent scope of the present invention, all the technical solutions of the present invention are conceived to utilize the equivalent structure transformation made by the contents of the specification and the drawings, or directly/indirectly applied to other related technical fields all included in the patent protection scope of the present invention.

Claims (10)

1. An alternately heating atomizer, characterized in that it comprises:

the shell is provided with an accommodating cavity and an air outlet channel communicated with the accommodating cavity;

the negative pressure sensor is arranged on the inner wall of the air outlet channel so as to detect an air flow signal of an air outlet in the air outlet channel;

the atomizing cores are respectively communicated with the air inlets of the air outlet channels so as to atomize the liquid entering the atomizing cores to form atomized liquid;

the concentration sensor is arranged on the inner wall of the air outlet channel so as to detect concentration data of atomized liquid in the air outlet channel;

and the control module is respectively electrically connected with the negative pressure sensor, the concentration sensor and the atomization core to receive an air flow signal and control at least one atomization core to start working according to the air flow signal, and to receive concentration data and control the atomization core to stop working and switch to another atomization core when the concentration data reaches a set value.

2. The alternately heating atomizer of claim 1, wherein said concentration sensor comprises a first concentration sensor and a second concentration sensor electrically connected to said control module, respectively, said first concentration sensor being adapted to detect an active substance in the atomized liquid, said second concentration sensor being adapted to detect a second concentration sensor of a hazardous substance in the atomized liquid, said control module being adapted to receive the active substance concentration and the hazardous substance concentration, and to control said atomizing core to stop operating when the active substance concentration equals the hazardous substance concentration.

3. The alternately heating atomizer of claim 2 further comprising an indicator module and a manual switch electrically connected to said control module, respectively, said indicator module being adapted to generate a warning signal when not switched to another atomizing cartridge; the manual change-over switch is used for responding to clicking, shifting, sliding and pressing operations and manually switching to another atomizing core.

4. The alternately heating atomizer of claim 1 further comprising a counter electrically connected to said control module, said counter for recording a number of puffs corresponding to said airflow signal and alternately switching atomizing tips according to different numbers of puffs.

5. The alternately heating atomizer of claim 1 further comprising a timer electrically connected to said control module, said timer being adapted to detect the length of time said atomizing core is heated during a cycle, and to control said atomizing core to cease operation and switch to another atomizing core when the length of time said atomizing core is heated reaches a set value.

6. An alternately heating atomizer according to any one of claims 1 to 5 wherein each of said atomizing wicks comprises a heating circuit in electrical communication with said control module.

7. An alternately heated atomizer according to claim 6 wherein said heating circuit comprises a positive connection post and a negative connection post, at least two of said heating circuits sharing a common negative connection post.

8. The alternately heating atomizer of claim 6 wherein said atomizing cores are three or more in number and wherein three or more atomizing cores are uniformly distributed in an annular pattern.

9. The alternately heating atomizer of claim 8 wherein three or more of said atomizing orifices are divided into at least two groups, each group of atomizing orifices being heated simultaneously.

10. An atomizing apparatus comprising an alternately heated atomizer according to any one of claims 1 to 9.

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