Patent Application
20240398023
The present disclosure relates to atomization apparatuses, and in particular, to an atomizer and an atomization apparatus.
Atomizers are devices that use heat generating elements to heat an aerosol matrix to produce an aerosol. The atomizer includes a heat generating element, an electrode connected to the heat generating, a corresponding circuit for supplying power to the heat generating element, and an air path for supplying air to the heating of the aerosol matrix to produce the aerosol.
In the existing atomizer, both the circuit and the air path are kept connected/unobstructed. When the atomizer is not in use, the connection of the circuit is prone to unintentional conduction, and the conduction of the air path is also prone to contamination of the aerosol matrix by contacting the air at the heat generating element.
The present disclosure provides an atomizer and an atomizing apparatus, which solve the problem of the susceptible contamination of the existing atomizer.
To solve the above technical problem, the present disclosure provides an atomizer comprising a housing assembly in which a liquid storage compartment is formed, wherein an air outlet is formed at a top portion of the housing assembly, and an air intake channel is formed at a bottom portion of the housing assembly; an air guide tube disposed in the liquid storage compartment and in communication with the air outlet; and a heating assembly disposed in the liquid storage compartment and in communication with the air intake channel and the air guide tube. An elastic electrode is disposed in the housing assembly, and the elastic electrode is capable of blocking the air intake channel and is spaced apart from the heating assembly; and the elastic electrode is movable under an external force to open the air intake channel and is electrically connected to the heating assembly.
According to an embodiment of the present disclosure, the housing assembly comprises: a liquid storage housing in which a liquid storage compartment is formed, wherein the air outlet is formed at a top end of the liquid storage housing; and a support base disposed at a bottom end of the liquid storage housing, wherein the support base comprises the air intake channel and an air inlet communicating with the air intake channel; and the elastic electrode is disposed in the support base and is capable of plugging the air inlet.
According to an embodiment of the present disclosure, the elastic electrode comprises a spring and an electrode post, the spring is connected to the electrode post, the electrode post is capable of blocking the air intake channel under an action of the spring; and the electrode post moves due to driving caused by contraction of the spring under an external force to open the air intake channel.
According to an embodiment of the present disclosure, an air inlet groove is disposed on a bottom end of the electrode post that plugs the air inlet, and when the electrode post opens the air inlet, the air inlet groove communicates with the air intake channel.
According to an embodiment of the present disclosure, the heating assembly comprises an elastic pin and an atomizing core connected to the elastic pin; the elastic pin is disposed in the support base to connect with the elastic electrode; and the atomizing core is disposed in the liquid storage compartment and communicates with the air guide tube and the air intake channel.
According to an embodiment of the present disclosure, the air guide tube is sleeved on the heating assembly and is slidable relative to the heating assembly to plug or expose a liquid inlet of the heating assembly; and the atomizer further comprises a silicone rod, the silicone rod is connected in the air guide tube and extends out of the air outlet; the air guide tube slides relative to the heating assembly to expose the liquid inlet when the silicone rod is pulled; and the silicone rod is capable of being pulled out of the air guide tube.
According to an embodiment of the present disclosure, the air guide tube comprises a sleeve tube and an air tube, a size of the sleeve tube is greater than a size of the air tube such that a stepped surface is formed between the sleeve tube and the air tube; the sleeve tube is sleeved on the heating assembly, and the air tube is connected to the air outlet; and the silicone rod is filled in the air tube and the sleeve tube, and the silicone rod acts on the stepped surface to drive the air guide tube to slide relative to the heating assembly.
According to an embodiment of the present disclosure, a silicone sleeve is sleeved on an outer side of the sleeve tube.
According to an embodiment of the present disclosure, an air outlet tube that is in communication with the air outlet is formed in the liquid storage compartment, and the air guide tube is slidably disposed in the air outlet tube.
According to an embodiment of the present disclosure, a sealing silicone is disposed between the air outlet tube and the air guide tube.
To solve the above technical problem, the present disclosure further provides an electronic atomizing apparatus including the atomizer and an atomizing host, wherein the atomizing host comprises: a host housing having a connection opening at a top end and an air entry hole on a side wall; and a conductive electrode disposed in the host housing and exposed by the connection opening; wherein an air passage is formed in the conductive electrode to communicate with the air inlet; the atomizer is connected to the connection opening of the atomizing host, and the conductive electrode abuts against the elastic electrode to open the air inlet and communicate with the air passage and the air intake channel.
Differing from the prior art, the atomizer of the present disclosure includes a housing assembly in which a liquid storage compartment is formed, wherein an air outlet is formed at a top portion of the housing assembly, and an air intake channel is formed at a bottom portion of the housing assembly; an air guide tube disposed in the liquid storage compartment and in communication with the air outlet; and a heating assembly disposed in the liquid storage compartment and in communication with the air intake channel and the air guide tube. An elastic electrode is disposed in the housing assembly, and the elastic electrode is capable of blocking the air intake channel and is spaced apart from the heating assembly; and the elastic electrode is movable under an external force to open the air intake channel and is electrically connected to the heating assembly. The atomizer of the present disclosure utilizes the heating assembly to heat the aerosol matrix in the liquid storage compartment to effect atomization. In the present disclosure, the air inlet is formed at a bottom portion of the housing assembly for communicating with the air intake channel, and the elastic electrode is disposed in the housing assembly to plug the air inlet and is provided at an interval from the heating assembly. The elastic electrode moves under an external force to open the air inlet and is connected to the heating assembly. When the atomizer is not in use, the air path is closed to avoid contamination caused by contact of the heating assembly with the air. The circuit is also closed to avoid misoperation and conduction. When the atomizer is to use, the circuit is turned on and the air circuit is opened, thereby realizing safe use.
These and other purposes, features, and advantages of the embodiments of the present disclosure will become readily understood by reading the following detailed description with reference to the accompanying drawings. In the accompanying drawings, several embodiments of the present disclosure are shown in an exemplary and not limiting manner, and the same or corresponding symbols denote the same or corresponding portions, wherein:
The embodiments of the present disclosure will be described clearly and fully below in connection with the accompanying drawings in the embodiments of the present disclosure. It will be apparent that the described embodiments are a part, but not all, of the embodiments of the present disclosure. All other embodiments made by a person skilled in the art, based on the embodiments in the present disclosure, without involving any inventive effort, are within the scope of the present disclosure.
The following describes in detail the embodiments disclosed herein with reference to the accompanying drawings.
A liquid storage compartment 111 is formed in the liquid storage housing 11, and an air outlet 112 is formed at the top portion of the liquid storage housing 11. The liquid storage compartment 111 is configured to store an aerosol matrix. The aerosol matrix is heated by a heating assembly 14 that is located in the liquid storage compartment 111, so as to generate an aerosol. The generated aerosol may be discharged from the air outlet 112.
The liquid storage housing 11 is plugged at the bottom portion by the support base 12. The support base 12 is configured to connect with an atomizing host of the atomizing apparatus, so as to realize the power supply for the heating assembly 14. The liquid storage housing 11 is plugged with the support base 12, facilitating production assembly, and the liquid storage compartment 111 together with the support base 12 forms a closed chamber, i.e., the liquid storage compartment. The support base 12 and the liquid storage housing 11 may also be integrally formed. Further, an air intake channel 121 is formed in the support base 12 to communicate with the external air. After the atomization heating is completed with the heating assembly 14 and an aerosol is generated, an air flow enters through the air intake channel 121, and in turn drives the aerosol generated by the heating to be discharged from the air outlet 112.
The air guide tube 13 communicates with the air outlet 112, is located in the liquid storage compartment 111, and communicates with the heating assembly 14. After the heating assembly 14 atomizes the aerosol matrix, the generated aerosol is led out of the air guide tube 13 and then discharged from the air outlet 112.
The heating assembly 14 is disposed on the support base 12 and is located in the liquid storage compartment 111. The heating assembly 14 communicates the air guide tube 13 with the air intake channel 121, so that the air flow drives the generated aerosol out of the air guide tube 13.
In the present embodiment, an elastic electrode 123 is disposed on the support base 12 for blocking the air intake channel 121. Specifically, an air inlet 122 is formed at the bottom portion of the support base 12 to communicate with the air intake channel 121. The elastic electrode 123 is disposed in the support base 12 for plugging the air inlet 122 and is spaced apart from the heating assembly 14. The elastic electrode 123 may also be provided in the air intake channel 121. For example, in the embodiment, an aperture channel is formed on the side wall of the through hole in which the elastic electrode 123 is provided in the support base 12 for communicating the air inlet 122 and the air intake channel 121, and the clastic electrode 123 may also block the aperture channel.
That is, when the atomizer 100 is not in use, the air inlet 122 is plugged, the air path is disconnected, and the heating assembly 14 will not come into contact with the outside air to avoid contamination. The clastic electrode 123 is spaced apart from the heating assembly 14, and the circuit is also open, thereby preventing the heating assembly 14 from energizing due to misoperation.
Furthermore, the elastic electrode 123 in the embodiment is movable. The elastic electrode 123 can move under an external force to open the air inlet 122 while connecting to the heating assembly 14. Therefore, when the atomizer 100 is in use, a force is applied to the clastic electrode 123 so that both the air path and the circuit are conductive. At this time, the heating assembly 14 generates heat by energization of the elastic electrode 123, and air enters the air intake channel 121, thereby achieving atomization of the aerosol matrix by heating.
Specifically, the clastic electrode 123 in the embodiment includes a spring 1231 and an electrode post 1232. The spring 1231 is sleeved on the electrode post 1232. One end of the spring 1231 abuts against the electrode post 1231, and the other end of the spring 1231 abuts against the support base 12 and is insulated from an elastic pin 141. The elastic pin 141 may be disposed in a direction corresponding to a central position of the spring 1231. The electrode post 1232 is configured to plug the air inlet 122 under the action of the spring 1231, and to open the air inlet 122 under an external force while driving the spring 1231 to compress.
The heating assembly 14 includes the elastic pin 141 and an atomizing core 142 connected to the elastic pin 141. The elastic pin 141 is disposed in the support base 12 to connect with the clastic electrode 123. The atomizing core 142 is disposed in the liquid storage compartment 111 to communicate the air guide tube 13 and the air intake channel 121.
In the present embodiment, a conductive electrode on the atomizing host is used to act on the elastic electrode 123. When the atomizer is mounted on the atomizing host, the conductive electrode abuts against the clastic electrode 123 through the air inlet 122, and then the air inlet 122 is substantially plugged. Therefore, it is necessary to provide an air drain on the clastic electrode 123 or the conductive electrode so that air can flow into the air intake channel 121. Detailed description will be given in particular in the embodiments of the atomizing apparatus.
Accordingly, referring to
In the present embodiment, the air outlet 112 may be plugged before use, for example, with a silicone rod 15. The silicone rod 15, in cooperation with the air guide tube 13, may be used to plug or open a liquid inlet of the heating assembly 14. The silicone rod 15 according to the present embodiment enables the air intake channel 121 and the heating assembly 14 of the atomizer 100 to be further isolated from the outside, effectively avoiding deterioration of the aerosol matrix due to air pollution. Reference is made in detail to
The liquid inlet 143 of the heating assembly 14 is configured to communicate with the liquid storage compartment 111 to achieve heating of the aerosol matrix in the liquid storage compartment 111. In the present embodiment, the air guide tube 13 is sleeved on the heating assembly 14, and is slidable with respect to the heating assembly 14 to plug or expose the liquid inlet 143 of the heating assembly 14.
When the atomizer is not in use, the air guide tube 13 plugs the liquid inlet 143 to prevent aging damage of the apparatus duc to contact of the heating assembly 14 with the aerosol matrix. When the atomizer is in use, the air guide tube 13 opens the liquid inlet 143 to enable the heating assembly 14 to contact with the aerosol matrix.
The atomizer 100 further includes the silicone rod 15 that enables the air guide tube 13 to move relative to the heating assembly 14. More specifically, the silicone rod 15 is connected in the air guide tube 13 and extends out of the air outlet 112. The pulling of the silicone rod 15 causes the air guide tube 13 to slide relative to the heating assembly 14 to expose the liquid inlet 143.
The silicone rod 15 may be pulled out of the air guide tube 13. When the atomizer is in use, the silicone rod 15 is pulled out of the atomizer 100. The silicone rod 15 is a disposable piece for the user. In other embodiments, a stiffer silicone rod may be used, which can also be reinserted into the air guide channel 13 after it has been pulled out. A pushing structure may be disposed on the air guide tube 13 so that the air guide tube 13 is re-sleeved on the heating assembly 14.
The air guide tube 13 includes a sleeve tube 131 and an air tube 132. The sleeve tube 131 is larger in size than the air tube 132, and a stepped surface is formed between the sleeve tube 131 and the air tube 132. The sleeve tube 131 is sleeved on the heating assembly 14, and the air tube 132 is connected to the air outlet 112. The silicone rod 15 is filled in the air tube 132 and the sleeve tube 131, and acts on the stepped surface to slide the air guide tube 13 relative to the heating assembly 14.
Since the sleeve tube 131 of the air guide tube 13 is slid relative to the heating assembly 14 and there is a gap between the sleeve tube 131 and the heating assembly 14, a silicone sleeve 133 is disposed on the outside of the sleeve tube 131 to achieve a seal between the sleeve tube 131 and the heating assembly 14 according to the present embodiment.
Further, an air outlet tube 113 is disposed on a portion of the liquid storage compartment 11 close to the air tube 132 to communicate with the air outlet 112. The air guide tube 13 is slidably disposed in the air outlet tube 113. Further, a sealing silicone is provided between the air guide tube 13 and the air outlet tube 113.
A connection opening 211 is disposed on the top end of the host housing 21 to connect with the atomizer 100. Specifically, the atomizer 100 is inserted into the connection opening 211.
Since the atomizer 100 is inserted into the host 200 and air cannot directly enter the atomizer 100, an air entry hole 212 is formed on the side wall of the host housing 21 for air to enter the atomizer 100.
The conductive electrode 23 is configured to supply power to the atomizer 100. The conductive electrode 23 is disposed in the host housing 21 and exposed by the connection opening 211. An air passage 231 is formed on the conductive electrode 23 to communicate with the air entry hole 212. That is, air running through the air entry hole 212 enters the atomizer 100 through the air passage 231 of the conductive electrode 23.
According to the present embodiment, the conductive electrode 23 of the atomizer 100 is inserted into the air outlet 112, and thus the air drain is provided on the elastic electrode 123 or the conductive electrode 23 so that air can flow into the air intake channel 121.
The conductive electrode 23 has two primary structures, as shown in
Referring to
In addition, the atomizing host 200 includes a bracket 22 for supporting the conductive electrode 23 and forming an air flow channel to communicate the air entry hole 212 with the air passage 231. In this embodiment, the bracket 22 is disposed corresponding to the air entry hole 212. The bracket 22 may be made of silicone to seal the air flow channel.
The atomizing host 200 further includes a battery 24 and a PCB board 25 for power supply and control, respectively. The conductive electrode 23 is electrically connected to the PCB board 25. The atomizing host 200 further includes a respiration monitor, which in communication with the air passage 231 or the air entry hole 212. The respiration monitor is used to monitor the airflow generated by the user's suction action, and the PCB board 25 supplies power to the atomizer when the airflow is monitored.
The atomizer 100 is connected to the connection opening 211 of the atomizing host 200, and the conductive electrode 23 abuts against the clastic electrode 123. At the time of insertion, the conductive electrode 23 runs through the air inlet and acts on the clastic electrode 123, thereby opening the air inlet 122 and communicating the air passage 231 with the air intake channel 121.
According to the present disclosure, the atomizer includes: the liquid storage housing in which the liquid storage compartment is formed, and the air outlet being formed at the top end of the liquid storage housing; the support base which blocks the bottom end of the liquid storage housing and on which the air intake channel is formed; the air guide tube which is in communication with the air outlet and located in the liquid storage compartment; the heating assembly that is disposed on the support base and is located in the liquid storage compartment to communicate the air guide tube with the air intake channel. The atomizer of the present disclosure utilizes the heating assembly to heat the aerosol matrix in the liquid storage compartment to effect atomization. In the present disclosure, the air inlet is formed at the bottom end of the support base to communicate with the air intake channel, and the clastic electrode is disposed in the support base to plug the air inlet and to be spaced from the heating element. The clastic electrode moves under an external force to open the air inlet and to connect to the heating assembly. When the atomizer is not in use, the air path is closed to avoid contact of the heating assembly with the air, eliminating contamination, and the circuit is also closed to avoid energization due to misoperation; while when the atomizer is to be used, the circuit is turned on and the air path is opened also, the use of the atomizer is therefore safer.
In the description of the present disclosure, it should be understood that terms that indicate orientations or position relationships, such as “upper”, “lower”, “front”, “rear”, “left”, “right”, “length”, “width”, “thickness”, “vertical”, “horizontal”, “top”, “bottom”, “inside”, “outside”, “axial”, “radial”, “circumferential”, “center”, “longitudinal”, “lateral”, “clockwise”, or “counter-clockwise”, are based on orientations or position relationships illustrated in the drawings. The terms are used to facilitate and simplify the description of the present disclosure, rather than indicate or imply that the devices or elements referred to herein are required to have specific orientations or be constructed or operate in the specific orientations. Accordingly, the terms should not be construed as limiting the present disclosure.
In addition, the terms “first” or “second”, and the like, used in this specification to refer to numbers or series are used for the purpose of descriptive only, and are not to be construed as expressing or implying relative importance or implying the number of technical features indicated. Thus, a feature defined with “first” or “second” may expressly or impliedly include at least one such feature. In the description of the specification, “plurality” means at least two, e.g., two, three or more, unless expressly and specifically defined otherwise.
While the specification has illustrated and described various embodiments of the present disclosure, it will be apparent to those skilled in the art that such embodiments are provided by way of example only. Many modifications, changes, and alternatives may be made to those skilled in the art without departing from the idea and spirit of the present disclosure. It is to be understood that various alternatives to the embodiments of the present disclosure described herein may be employed in the practice of the present disclosure. The appended claims are intended to limit the scope of the present disclosure and, therefore, to cover modular compositions, equivalents, or alternatives within the scope of these claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 202111339585.6 | Nov 2021 | CN | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/CN2022/107842 | 7/26/2022 | WO |
