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CN-224219435-U - Electronic atomizing device

CN224219435UCN 224219435 UCN224219435 UCN 224219435UCN-224219435-U

Abstract

The application relates to the technical field of electronic atomization, and discloses electronic atomization equipment. The electronic atomization device comprises a liquid storage bin, an atomization bin, a liquid inlet channel, a liquid guide tube and an electromagnetic valve assembly. The atomizing storehouse sets up in the one end in stock solution storehouse, and the atomizing storehouse is equipped with the atomizing chamber that atomizes to atomizing matrix. The liquid inlet channel is arranged between the atomizing bin and the liquid storage bin and is used for communicating the atomizing bin and the liquid storage bin. The catheter is arranged in the atomization bin, one end of the catheter is communicated with the liquid inlet channel, and a liquid guide hole is formed in the wall of the catheter. The solenoid valve assembly is at least partially disposed within the catheter and is configured to block or expose the catheter opening. When the liquid guide hole is exposed, at least part of atomized matrix in the liquid storage bin can flow into the atomized bin. The electronic atomizing equipment solves the problem that atomized matrix is easy to leak when the pressure in the cavity of the atomizing cavity is increased, is convenient to operate, cannot paste cores, and can save cost.

Inventors

  • Request for anonymity
  • FU YAO
  • Request for anonymity

Assignees

  • 爱奇迹创造有限公司

Dates

Publication Date
20260512
Application Date
20250402

Claims (10)

  1. 1. An electronic atomizing device, characterized by comprising: The liquid storage bin is used for storing the atomized substrate; the atomization bin is arranged at one end of the liquid storage bin and is provided with an atomization cavity for atomizing the atomization matrix; the liquid inlet channel is arranged between the atomization bin and the liquid storage bin and is used for communicating the atomization bin and the liquid storage bin; One end of the liquid guide pipe is communicated with the liquid inlet channel, and a liquid guide hole is formed in the pipe wall of the liquid guide pipe; and a solenoid valve assembly at least partially within the catheter configured to block or expose the fluid port; when the liquid guide hole is exposed, at least part of atomized matrix in the liquid storage bin can flow into the atomized bin.
  2. 2. The electronic atomizing apparatus of claim 1, wherein the solenoid valve assembly is configured to be switchable between a first position and a second position; when the electromagnetic valve assembly is in the first position, the electromagnetic valve assembly is at least partially accommodated in the liquid guide tube so as to seal the liquid guide hole; when the electromagnetic valve assembly is in the second position, the electromagnetic valve assembly moves towards one end far away from the liquid inlet channel so as to expose the liquid guide hole.
  3. 3. The electronic atomizing apparatus of claim 2, wherein the solenoid valve assembly comprises: The induction piece is arranged at one end of the atomization bin, which is far away from the liquid storage bin, and is configured to generate a variable magnetic field; a magnetic attraction member disposed within the catheter configured to displace in response to the variable magnetic field; The elastic piece is at least partially arranged in the liquid guide tube and is respectively abutted with the induction piece and the magnetic attraction piece; wherein the magnetically attractable member is displaceable from the first position to the second position in response to the variable magnetic field.
  4. 4. The electronic atomizing apparatus of claim 3, wherein the solenoid valve assembly further comprises a guide member having one end connected to the sensing member and the other end extending into the catheter; Wherein the guide is configured to define a displacement path of the magnetic attraction.
  5. 5. The electronic atomizing apparatus of claim 3, wherein the magnetic attraction member comprises: A first seal disposed within the catheter, the first seal configured to conform to an inner wall of the catheter; A magnetic member disposed within the first seal member configured to displace in response to the variable magnetic field; When the magnetic piece is positioned at the first position, the side wall of the first sealing piece can seal the liquid guide hole.
  6. 6. The electronic atomizing apparatus of claim 3, further comprising a second seal disposed between the sensing member and the atomizing cartridge for sealing the atomizing cartridge.
  7. 7. The electronic atomizing apparatus of claim 1, further comprising a liquid storage member disposed within the atomizing chamber for adsorbing the atomized substrate; the atomizing assembly is arranged in the atomizing cavity and is used for atomizing the atomized substrate; Wherein the reservoir is configured to at least partially cover the liquid guide aperture to direct the atomized substrate to the atomizing assembly.
  8. 8. The electronic atomizing apparatus of claim 1, further comprising a third seal disposed between the atomizing chamber and the reservoir chamber, the liquid inlet passage being formed therethrough; wherein, the liquid guiding tube is at least partially accommodated in the liquid inlet channel.
  9. 9. The electronic atomizing apparatus of claim 8, wherein the reservoir defines an air outlet passage therethrough, and wherein an end of the air outlet passage extends through the third seal and communicates with the atomizing chamber.
  10. 10. The electronic atomizing device of claim 1, wherein the reservoir is provided with a fluid refill port configured to refill the reservoir with atomizing medium.

Description

Electronic atomizing device Technical Field The application relates to the technical field of electronic atomization, in particular to electronic atomization equipment. Background The electronic atomization device generally comprises a liquid storage bin and an atomization bin, an atomization cavity is arranged in the atomization bin, and an atomization assembly is arranged in the atomization cavity. The liquid storage cavity is used for storing the atomized matrix, is communicated with the atomized cavity and supplements the atomized matrix for the atomized cavity. Because the atomization cavity is not in a completely sealed structure, the problem of atomized substrate leakage easily occurs due to the increase of the pressure in the cavity of the atomization cavity under the negative pressure or high temperature environment. In order to solve the above problems, the prior art generally adopts two means, the first is to set up corresponding switch structure in electronic atomization equipment, when the liquid outlet of liquid storage cavity is opened to toggle switch when sucking is needed, and after sucking is finished, the liquid storage port is closed to toggle switch, and this kind of design is troublesome for the consumer to if forget to toggle switch during sucking, the problem of burnt core appears easily to atomizing subassembly dry combustion method. The second is to set up the pump structure on the electronic atomization plant, trigger and start the pump to suck the feed liquor when sucking, because the volume of the pump is great, with high costs, apply it to the electronic atomization plant in economic benefits low. Disclosure of utility model Compared with the arrangement of the containing channel communicated with the outside so as to be connected with the driving switch of the outside, the internal blocking piece drives, so that the atomized matrix in the inside is easy to leak through the gap of the containing channel. The first aspect of the application provides electronic atomization equipment, which comprises a liquid storage bin, an atomization bin, a liquid inlet channel, a liquid guide pipe, a solenoid valve assembly and a solenoid valve assembly, wherein the liquid storage bin is used for storing an atomization substrate, the atomization bin is arranged at one end of the liquid storage bin and is provided with an atomization cavity for atomizing the atomization substrate, the liquid inlet channel is arranged between the atomization bin and the liquid storage bin and is used for communicating the atomization bin and the liquid storage bin, the liquid guide pipe is arranged in the atomization bin, one end of the liquid guide pipe is communicated with the liquid inlet channel, liquid guide holes are formed in the pipe wall of the liquid guide pipe, and the solenoid valve assembly is at least partially positioned in the liquid guide pipe and is configured to be capable of blocking or exposing the liquid guide holes, and when the liquid guide holes are exposed, at least part of the atomization substrate in the liquid storage bin can flow into the atomization bin. In some embodiments, the solenoid valve assembly is configured to be switchable between a first position and a second position, the solenoid valve assembly being at least partially received in the catheter to block the drain hole when the solenoid valve assembly is in the first position, and the solenoid valve assembly being movable toward an end remote from the inlet passage to expose the drain hole when the solenoid valve assembly is in the second position. In some embodiments, the solenoid valve assembly includes a sensing member disposed at an end of the atomizing cartridge remote from the reservoir and configured to generate a variable magnetic field, a magnetically attractive member disposed within the catheter and configured to be displaced in response to the variable magnetic field, and an elastic member disposed at least partially within the catheter and in abutment with the sensing member and the magnetically attractive member, respectively, wherein the magnetically attractive member is displaceable from a first position to a second position in response to the variable magnetic field. In some embodiments, the solenoid valve assembly further comprises a guide member having one end connected to the sensing member and the other end extending into the catheter, wherein the guide member is configured to define a displacement path of the magnetic attraction member. In some embodiments, the magnetic element includes a first seal disposed within the catheter, the first seal configured to conform to an inner wall of the catheter, and a magnetic element disposed within the first seal and configured to displace in response to a variable magnetic field, wherein a sidewall of the first seal is configured to seal the catheter aperture when the magnetic element is in the first position. In some embodiments, the device further comprises