CN220587515U - Photoelectric control electronic atomization device - Google Patents

Abstract

The utility model discloses a photoelectric control electronic atomization device, which comprises a power supply main body and an atomization main body detachably and electrically connected with the power supply main body, wherein a power board for supplying power to the atomization main body is arranged in the power supply main body, a photoelectric switch for starting up and shutting down is arranged on the power board, a light sensing probe for controlling the photoelectric switch to start the power board to electrify the atomization main body after light is sensed by the photoelectric switch, a shell made of a light-permeable material is arranged on the periphery of the power supply main body, and the shell corresponds to the light sensing probe. By adopting the technical scheme, the light sensing probe cannot sense light in the luggage in the traveling carrying process, so that the photoelectric switch can start the power panel to conduct power-off protection on the atomizing main body.

Description

Photoelectric control electronic atomization device

Technical Field

The utility model relates to the technical field of electronic atomization, in particular to a photoelectric control electronic atomization device.

Background

At present, current electron atomizing device, including the atomizing main part that is used for oil storage and atomizing tobacco tar and the power supply main part that is used for supplying power, can all set up in the power supply main part generally and start the ignition button that ignites through pressing to the ignition button is all exposed at the power supply main part outer wall, and the ignition button often can receive the extrusion of luggage at the trip in-process of carrying, leads to the power supply main part always to supply power for the atomizing main part, thereby causes the heating element of atomizing main part always to generate heat and accomplish the tobacco tar atomization, then the heating element spontaneous combustion arouses the conflagration.

Disclosure of Invention

The utility model aims to provide an electronic atomization device controlled by photoelectricity, which solves the problems that in the prior art, an ignition key is extruded by luggage in the traveling carrying process, so that a heating core continuously heats and then self-ignites to cause fire.

The technical scheme adopted by the utility model for solving the technical problems is as follows: the utility model provides a photoelectric control's electron atomizing device, includes the power supply main part and with the atomizing main part that the electricity is connected can be dismantled to the power supply main part, be equipped with in the power supply main part be used for the power strip of atomizing main part power supply, be equipped with the photoelectric switch who is used for starting the switching machine on the power strip, be equipped with on the photoelectric switch and sense the light after control the photoelectric switch starts the power strip gives atomizing main part energized light sensing probe, the power supply main part periphery is equipped with the casing of being made by the printing opacity material, the casing with light sensing probe is corresponding.

As one implementation mode, the shell is made of one light-permeable material selected from PC material, glass material, acrylic material, PCTG material and diamond material.

As an implementation mode, be equipped with on the power supply main part and be used for the adaptation chamber of atomizing main part, be equipped with first detachable construction on the atomizing main part, the chamber diapire that the adaptation chamber corresponds be equipped with first detachable construction corresponding second detachable construction, the atomizing main part inserts the adaptation intracavity is through first detachable construction with second detachable construction with the power supply main part can dismantle the connection.

As an implementation mode, the atomizing main body is further provided with a first conductive connection structure, the bottom wall of the adapting cavity is further provided with a second conductive connection structure corresponding to the first conductive connection structure, and the atomizing main body is inserted into the adapting cavity and is electrically connected with the power supply main body through the first conductive connection structure and the second conductive connection structure.

As an implementation mode, the power supply main body includes support and electric core, the power strip is established on the support, the through channel that runs through to the bottom has been seted up on the casing top, the through channel is as the adaptation chamber, atomizing main body inserts in the through channel, the support is as the chamber diapire in adaptation chamber is equipped with in the through channel, the indent space is formed to casing bottom indent, the electric core is established in the indent space, just the electric core with the power strip electricity is connected.

As an implementation mode, the bottom of the atomizing main body is provided with at least one first magnet, the top of the support is provided with at least one second magnet corresponding to the first magnet, each first magnet forms a first detachable structure, each second magnet forms a second detachable structure, and the atomizing main body is inserted into the through channel and is in detachable connection with the power supply main body through the attraction of the first magnet and the corresponding second magnet.

As an implementation mode, the bottom of the atomizing main body is further provided with a first electrode and a second electrode, the top of the support is further provided with a third electrode and a fourth electrode which are electrically connected with the power panel, the first electrode and the second electrode form a first conductive connection structure, the third electrode and the fourth electrode form a second conductive connection structure, the atomizing main body is inserted into the through channel and is abutted to the third electrode through the first electrode, and the second electrode and the fourth electrode are abutted to form an electrical connection with the power supply main body.

As an implementation mode, an oil storage cavity for storing tobacco tar is formed in the atomization main body, a fog pipe is arranged in the oil storage cavity, a fog channel is formed in the fog pipe, a heating core electrically connected with the first electrode and the second electrode is arranged in the fog channel, an oil inlet corresponding to the heating core is formed in the outer wall of the fog pipe, and a fog outlet corresponding to and communicated with the fog channel is formed in the top end of the atomization main body.

As an implementation mode, the bottom end of the shell is provided with a bottom shell for covering the lower end of the through channel and the concave space, a sealing ring is arranged between the inner wall of the through channel and the outer wall of the support, a groove for ventilation flow is formed in the support, an air guide channel communicated with the groove is formed in the top end of the support, and the air guide channel is also communicated with the through channel.

As an implementation mode, an air inlet hole communicated with the through channel is formed in the outer wall of the shell, the air inlet hole is communicated with the air guide channel through the through channel, a microphone for controlling a power core to electrify the power panel after sensing air flow is further arranged on the power panel, and the microphone stretches into the groove to correspond to the air guide channel.

The photoelectric control electronic atomization device has the following beneficial effects: according to the photoelectric control electronic atomizing device, the photoelectric switch is designed, so that the light sensing probe cannot sense light in luggage in the traveling carrying process, and the photoelectric switch can start the power panel to conduct power-off protection on the atomizing main body.

Drawings

The present utility model will be described in detail below with reference to the attached drawings, so that the above advantages of the present utility model will be more apparent. Wherein,

FIG. 1 is an exploded view of an electronic atomizing device of the present utility model;

FIG. 2 is a schematic perspective view of an electronic atomizing device according to the present disclosure;

FIG. 3 is a schematic cross-sectional view of an electronic atomizing device of the present disclosure;

fig. 4 is a schematic structural view of a power supply body of the electronic atomizing device according to the present utility model.

Detailed Description

The following will describe embodiments of the present utility model in detail with reference to the drawings and examples, thereby solving the technical problems by applying technical means to the present utility model, and realizing the technical effects can be fully understood and implemented accordingly. It should be noted that, as long as no conflict is formed, each embodiment of the present utility model and each feature of each embodiment may be combined with each other, and the formed technical solutions are all within the protection scope of the present utility model.

It should be noted that, in the description of the present utility model, a large number of technical features are described, and are distributed in each technical solution, and if all possible combinations of technical features (i.e. technical solutions) of the present application are to be listed, the description is too lengthy. In order to avoid this problem, the technical features of the utility model in the above summary of the utility model, the technical features of the utility model in the following embodiments and examples, and the technical features of the utility model in the drawings may be freely combined with each other to constitute various new technical solutions (these technical solutions are regarded as already described in the present specification) unless such a combination of technical features is technically impossible. For example, in one example, feature a+b+c is invented, in another example, feature a+b+d+e is invented, and features C and D are equivalent technical means that perform the same function, so long as they are used alternatively, it is not possible to use them simultaneously, feature E can be combined with feature C technically, the solution of a+b+c+d should not be considered as already described because it is technically infeasible, and the solution of a+b+c+e should be considered as already described.

In the present utility model, the terms "upper", "lower", "top", "bottom", "inner", "outer", and the like are based on the orientation or positional relationship shown in the drawings, and are merely for convenience of description and understanding of the technology of the present utility model, and do not limit the apparatus or components referred to have a specific orientation or to be constructed and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

As shown in fig. 1-4, the utility model provides a photoelectric control electronic atomization device, which comprises a power supply main body 100 and an atomization main body 1 detachably and electrically connected with the power supply main body 100, wherein a power board 9 for supplying power to the atomization main body 1 is arranged in the power supply main body 100, a photoelectric switch 901 for starting up and shutting down is arranged on the power board 9, a light sensing probe 902 for controlling the photoelectric switch 901 to start the power board 9 to electrify the atomization main body 1 after light is sensed is arranged on the photoelectric switch 901, a shell 2 made of a light-permeable material is arranged on the periphery of the power supply main body 100, and the shell 2 corresponds to the light sensing probe 902. It should be noted that, through designing photoelectric switch 901, light sense probe 902 can't sense light in the luggage in the trip carrying process to photoelectric switch 901 can start power supply board 9 and give atomizing main part 1 outage protection, compares current electron atomizing device, starts the switching machine through outlying ignition button, can solve and receive luggage extrusion to lead to power supply board 9 to switch on for atomizing main part 1 always in the trip carrying process, thereby causes atomizing main part 1 to appear dry combustion method and arouse the problem of conflagration.

In some embodiments, the housing 2 is made of one of a PC material, a glass material, an acryl material, a PCTG material, and a diamond material. The casing 2 of this embodiment is preferably made of PC, so that not only is the light-transmitting effect good, but also the toughness and ductility are good, firm and durable, and the manufacturing cost is low.

In some embodiments, an adapting cavity for adapting to the atomizing body 1 is provided on the power supply body 100, a first detachable structure is provided on the atomizing body 1, a second detachable structure corresponding to the first detachable structure is provided on a cavity bottom wall corresponding to the adapting cavity, and the atomizing body 1 is inserted into the adapting cavity and detachably connected with the power supply body 100 through the first detachable structure and the second detachable structure. The first detachable structure and the second detachable structure may be a magnetic structure, a threaded structure, a fastening structure, a sticking structure, an interference fit structure, or the like, but are not limited thereto, and the preferred magnetic structure is adopted in the present embodiment, so that the connection between the atomizing main body 1 and the power supply main body 100 is stable, and the disassembly is convenient.

In some embodiments, the atomizing body 1 is further provided with a first conductive connection structure, the bottom wall of the adapting cavity is further provided with a second conductive connection structure corresponding to the first conductive connection structure, and the atomizing body 1 is inserted into the adapting cavity and electrically connected with the power supply body 100 through the first conductive connection structure and the second conductive connection structure. The first conductive connection structure and the second conductive connection structure can be a conductive electrode, a conductive plug, a conductive socket, a wire, a conductive contact and the like respectively, but are not limited thereto, and the first conductive connection structure and the second conductive connection structure are all conductive electrodes, are simple in structural design, are convenient to assemble and can be detached.

In some embodiments, the power supply main body 100 includes a support 7 and a battery core 8, the power panel 9 is disposed on the support 7, a through channel 201 penetrating to the bottom end is provided at the top end of the housing 2, the through channel 201 is used as an adapting cavity, the atomizing main body 1 is inserted into the through channel 201, the support 7 is provided in the through channel 201 as a cavity bottom wall of the adapting cavity, the bottom end of the housing 2 is concaved inwards to form a concave space 202, the battery core 8 is disposed in the concave space 202, and the battery core 8 is electrically connected with the power panel 9. It should be noted that, after the bracket 7 is installed in the through channel 201, the light sensing probe 902 on the photoelectric switch 901 may be opposite to the housing 2, the housing 2 is made of PC material and may be transparent, and after the light is sensed by the light sensing probe 902, the photoelectric switch 901 may be started to control the power board 9 to energize the atomizing main body 1. The concave space 202 is used for installing and fixing the battery core 8, and the battery core 8 is used for supplying power to the power board 9 and the photoelectric switch 901 so as to enable the power board 9 and the photoelectric switch to respectively start a power supply function and a power on-off function.

In some embodiments, at least one first magnet 103 is disposed at the bottom end of the atomizing body 1, at least one second magnet 5 corresponding to the first magnet 103 is disposed at the top end of the support 7, each first magnet 103 forms a first detachable structure, each second magnet 5 forms a second detachable structure, and the atomizing body 1 is inserted into the through channel 201 to be detachably connected with the power supply body 100 through magnetic attraction between the first magnet 103 and the corresponding second magnet 5. The first magnet 103 and the second magnet 5 are aluminum iron boron magnets, the magnetism is strong, the atomization main body 1 and the power supply main body 100 can be stably connected, the number of the first magnet 103 and the second magnet 5 can be one or more, the first magnet and the second magnet can be arranged at the top end of the bracket 7 or the side wall of the concave space 202, and the second magnet can be arranged at the bottom end or the side wall of the atomization main body 1, so long as the opposite poles of the first magnet and the second magnet are corresponding.

In some embodiments, the bottom end of the atomizing body 1 is further provided with a first electrode 101 and a second electrode 102, the top end of the support 7 is further provided with a third electrode 3 and a fourth electrode 4 electrically connected with the power panel 9, the first electrode 101 and the second electrode 102 form a first conductive connection structure, the third electrode 3 and the fourth electrode 4 form a second conductive connection structure, the atomizing body 1 is inserted into the through channel 201 and is abutted against the third electrode 3 through the first electrode 101, and the second electrode 102 is abutted against the fourth electrode 4 to form an electrical connection with the power supply body 100. Wherein the first electrode 101 and the second electrode 102, and the third electrode 3 and the fourth electrode 4 are made of conductive metal materials, and the power board 9 energizes the heating core 107 of the atomizing body 1 through the first electrode 101 and the second electrode 102, and the third electrode 3 and the fourth electrode 4.

In some embodiments, an oil storage cavity 104 for storing tobacco tar is formed in the atomization main body 1, a mist pipe 105 is arranged in the oil storage cavity 104, a mist channel 106 is formed in the mist pipe 105, a heating core 107 electrically connected with the first electrode 101 and the second electrode 102 is arranged in the mist channel 106, an oil inlet hole 108 corresponding to the heating core 107 is formed in the outer wall of the mist pipe 105, and a mist outlet 109 corresponding to and communicated with the mist channel 106 is formed in the top end of the atomization main body 1. The mist pipe 105 is used for isolating the oil storage cavity 104 and the mist channel 106, after the heating core 107 is electrified by the power panel 9, the heating core 107 heats the tobacco tar in the oil storage cavity 104 to generate smoke, the oil inlet 108 is used for guiding the tobacco tar in the oil storage cavity 104 into the heating core 107, and the mist outlet 109 is used for discharging the smoke generated by heating the tobacco tar by the heating core 107 in the mist channel 106.

In some embodiments, the bottom end of the housing 2 is provided with a bottom shell 10 for covering the lower end of the through channel 201 and the concave space 202, a sealing ring 6 is arranged between the inner wall of the through channel 201 and the outer wall of the bracket 7, a groove 701 for ventilation is formed in the bracket 7, an air guide channel 702 communicated with the groove 701 is formed in the top end of the bracket 7, and the air guide channel 702 is also communicated with the through channel 201. The bottom shell 10 is used for preventing the battery core 8 and the bracket 7 from falling off from the concave space 202 and the through channel 201, the sealing ring 6 is used for sealing the through channel 201 to prevent oil leakage generated by the atomization main body 1 from flowing to the power panel 9 to cause short circuit, and the groove 701 and the air guide channel 702 are both used for ventilation.

In some embodiments, the outer wall of the housing 2 is provided with an air inlet 203 which is communicated with the through channel 201, the air inlet 203 is communicated with the air guide channel 702 through the through channel 201, the power panel 9 is further provided with a microphone 903 for controlling the battery core 8 to energize the power panel 9 after sensing air flow, and the microphone 903 extends into the groove 701 to correspond to the air guide channel 702. It should be noted that, the microphone 903 is an airflow switch, when airflow enters the through channel 201 from the air inlet 203, the airflow can enter the groove 701 from the air guide channel 702 to be sensed by the microphone 903, then the microphone 903 will start the input circuit of the power board 9 to be opened, and then the battery core 8 will supply power to the power board 9.

The following is a detailed description of the preferred embodiments.

As shown in fig. 1 to 4, the electronic atomizing device of the present utility model includes: the atomization body 1, the shell 2, the third electrode 3, the fourth electrode 4, the second magnet 5, the sealing ring 6, the bracket 7, the battery cell 8, the power panel 9 and the bottom shell 10, wherein an oil storage cavity 104 is formed in the atomization body 1 and used for storing tobacco tar, a fog pipe 105 is arranged in the oil storage cavity 104 and used for isolating the tobacco tar in the oil storage cavity 104, a fog channel 106 is formed in the fog pipe 105 and used for ventilation flow and smoke discharging, a heating core 107 is arranged in the fog channel 106 and used for heating the tobacco tar in the oil storage cavity 104 until generating smoke, an oil inlet 108 corresponding to the heating core 107 is formed in the outer wall of the fog pipe 105 and used for guiding the tobacco tar in the oil storage cavity 104 into the heating core 107, a fog outlet 109 which corresponds to the fog channel 106 and is communicated is formed in the top end of the atomization body 1 and used for discharging fog, a first electrode 101 and a second electrode 102 which are electrically connected with the heating core 107 are arranged at the bottom end of the atomization body 1 and play a role of electrically connecting the heating core 107, the bottom end of the atomizing main body 1 is also provided with two first magnets 103 which are used for connecting the atomizing main body 1 by magnetic attraction, a through channel 201 penetrating to the bottom end is arranged at the top end of the shell 2 and used for installing the atomizing main body 1 and the support 7, the lower end of the atomizing main body 1 is inserted into the through channel 201 from the top end of the shell 2, the support 7 is inserted into the through channel 201 from the bottom end of the shell 2 and fixed, the top end of the support 7 corresponds to the bottom end of the atomizing main body 1, the sealing ring 6 is arranged between the inner wall of the through channel 201 and the outer wall of the support 7 and used for sealing the through channel 201 to prevent oil leakage generated by the atomizing main body 1 from flowing to the power supply board 9 to cause short circuit, the third electrode 3, the fourth electrode 4 and the two second magnets 5 are arranged at the top end of the support 7 and fixed, a concave space 202 is formed at the bottom end of the shell 2 and used for accommodating the battery core 8, the battery core 8 is arranged in the concave space 202 and the power supply board 9 is arranged on the support 7 and fixed, the electric core 8 is electrically connected with the electric source plate 9 for supplying power to the electric source plate 9, the electric source plate 9 is electrically connected with the third electrode 3 and the fourth electrode 4, the atomizing main body 1 is inserted into the through channel 201 and is abutted against the third electrode 3 through the first electrode 101, the second electrode 102 is abutted against the fourth electrode 4 to form electric connection with the electric source plate 9, the atomizing main body 1 is magnetically attracted with the corresponding second magnet 5 through the first magnet 103 and is detachable in the through channel 201, the electric source plate 9 is provided with a photoelectric switch 901 for starting up and shutting down, the photoelectric switch 901 is provided with a light sensing probe 902 for controlling the photoelectric switch 901 to start up the electric source plate 9 for powering on the atomizing main body 1 after sensing light, the shell 2 is made of PC material and is transparent, the shell 2 corresponds to the light sensing probe 902, the bottom end of the shell 2 is provided with a bottom shell 10 for covering the lower end of the through channel 201 and the concave space 202 to prevent the electric core 8 and the bracket 7 from falling off, the power panel 9 is provided with a microphone 903 for controlling the electric core 8 to electrify the power panel 9 after sensing air flow, the support 7 is provided with a groove 701 for ventilation, the top end of the support 7 is provided with an air guide channel 702 communicated with the groove 701 for ventilation, the air guide channel 702 is also communicated with the through channel 201, the microphone 903 stretches into the groove 701 and corresponds to the air guide channel 702, the outer wall of the shell 2 is provided with an air inlet 203 communicated with the through channel 201 for air inlet, the air inlet 203 is communicated with the air guide channel 702 through the through channel 201, wherein after the air enters the through channel 201 from the air inlet 203, the air can enter the groove 701 from the air guide channel 702 to be sensed by the microphone 903, then the microphone 903 can start an input circuit of the power panel 9 to be opened, and then the electric core 8 can supply power to the power panel 9.

Finally, it should be noted that: the above is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, but it is to be understood that the present utility model is described in detail with reference to the foregoing embodiments, and modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (10)

1. The utility model provides a photoelectric control's electron atomizing device, includes the power supply main part and with the atomizing main part that the electricity is connected can be dismantled to the power supply main part, its characterized in that, be equipped with in the power supply main part be used for the power strip of atomizing main part power supply, be equipped with the photoelectric switch who is used for starting the switching-on machine on the power strip, be equipped with on the photoelectric switch and sense the light after control the photoelectric switch starts the power strip gives atomizing main part energized light-sensitive probe, the power supply main part periphery is equipped with the casing of being made by the printing opacity material, the casing with light-sensitive probe is corresponding.

2. The electronic atomizing device according to claim 1, wherein the housing is made of one of a PC material, a glass material, an acryl material, a PCTG material, and a diamond material.

3. The electronic atomizing device according to claim 1, wherein an adapting cavity for adapting to the atomizing body is provided on the power supply body, a first detachable structure is provided on the atomizing body, a second detachable structure corresponding to the first detachable structure is provided on a cavity bottom wall corresponding to the adapting cavity, and the atomizing body is inserted into the adapting cavity and detachably connected to the power supply body through the first detachable structure and the second detachable structure.

4. The electronic atomizing device according to claim 3, wherein the atomizing body is further provided with a first conductive connection structure, the bottom wall of the adapting cavity is further provided with a second conductive connection structure corresponding to the first conductive connection structure, and the atomizing body is inserted into the adapting cavity and electrically connected with the power supply body through the first conductive connection structure and the second conductive connection structure.

5. The electronic atomizing device according to claim 4, wherein the power supply main body includes a bracket and a battery cell, the power supply board is provided on the bracket, a through passage penetrating to a bottom end is provided at a top end of the housing, the through passage serves as the adapting cavity, the atomizing main body is inserted into the through passage, the bracket serves as a bottom wall of the adapting cavity and is provided in the through passage, a concave space is formed in a bottom end of the housing in a concave manner, the battery cell is provided in the concave space, and the battery cell is electrically connected with the power supply board.

6. The electronic atomizing device according to claim 5, wherein the atomizing body is provided with at least one first magnet at a bottom end thereof, at least one second magnet corresponding to the first magnet is provided at a top end thereof, each of the first magnets constitutes the first detachable structure, each of the second magnets constitutes the second detachable structure, and the atomizing body is inserted into the through passage and detachably connected to the power supply body by magnetically attracting the first magnet to the corresponding second magnet.

7. The electronic atomizing device according to claim 6, wherein a first electrode and a second electrode are further provided at a bottom end of the atomizing body, a third electrode and a fourth electrode are further provided at a top end of the holder, the first electrode and the second electrode form the first conductive connection structure, the third electrode and the fourth electrode form the second conductive connection structure, the atomizing body is inserted into the through-passage to be abutted to the third electrode by the first electrode, and the second electrode is abutted to the fourth electrode to be electrically connected to the power supply body.

8. The electronic atomizing device according to claim 7, wherein an oil storage cavity for storing tobacco tar is formed in the atomizing main body, a fog pipe is arranged in the oil storage cavity, a fog channel is formed in the fog pipe, a heating core electrically connected with the first electrode and the second electrode is arranged in the fog channel, an oil inlet corresponding to the heating core is formed in the outer wall of the fog pipe, and a fog outlet corresponding to and communicated with the fog channel is formed in the top end of the atomizing main body.

9. The electronic atomizing device according to claim 5, wherein a bottom shell for covering the lower end of the through passage and the concave space is provided at the bottom end of the housing, a sealing ring is provided between the inner wall of the through passage and the outer wall of the bracket, a groove for ventilation is provided on the bracket, an air guide passage communicating with the groove is provided at the top end of the bracket, and the air guide passage is also communicating with the through passage.

10. The electronic atomizing device according to claim 9, wherein an air inlet hole communicated with the through passage is formed in the outer wall of the housing, the air inlet hole is communicated with the air guide passage through the through passage, a microphone for controlling the power supply board to be electrified by the electric core after sensing air flow is further arranged on the power supply board, and the microphone extends into the groove to correspond to the air guide passage.