The present invention relates to an electronic cigarette device, and in particular, to an electronic cigarette atomizing core and an atomizer.
During ultrasonic atomization of the existing ultrasonic electronic cigarette atomizer, because the supply speed of e-liquid is slow, the ultrasonic atomizing sheet is easily dry-burnt. In addition, because the air pipe is directly communicated with the atomization cavity, the e-liquid splashed on the ultrasonic atomizing sheet enters the breather pipe connected with the suction nozzle during the atomization. Hence, the e-liquid is easily inhaled.
The technical problem to be solved by the present invention is to overcome the shortcomings of the prior art, and provide an electronic cigarette atomizing core that supplies e-liquid quickly to prevent dry burning of an ultrasonic atomizing sheet, and an atomizer.
In order to solve the above technical problems, the present invention provides an electronic cigarette atomizing core, including an outer sleeve and an inner sleeve which are sleeved on each other, wherein the side wall of the outer sleeve is provided with a first e-liquid passing port communicated with an e-liquid tank, two ends of e-liquid guide cotton are sandwiched between the outer sleeve and the inner sleeve, the bottom of the inner sleeve is provided with an atomization cavity, the side wall of the inner sleeve is provided with a plurality of air inlet grooves communicating with the atomization cavity along the axial direction as that of e-liquid flowing into the atomization cavity, and at least one air inlet groove is communicated with the first e-liquid passing port by means of the e-liquid guide cotton.
In the present invention, at least one air inlet groove is communicated with the surface of the e-liquid guide cotton, and the airflow direction in the air inlet groove is consistent with the flow direction of the e-liquid entering the atomization cavity. As such, during smoking, due to the air flow in the air inlet groove, the power of the air flow enables the e-liquid to overcome the adhesion of the e-liquid guide cotton, so that the flow speed of the e-liquid in the e-liquid guide cotton is increased. Meanwhile, the air pressure in the air inlet groove changes with the air flow, so that air pressure in the e-liquid tank is not balanced with air pressure in the air inlet groove. While the e-liquid passes through the first e-liquid passing port and is absorbed by the e-liquid guide cotton, a part of the intake air flow directly passes through the e-liquid guide cotton and then passes through the first e-liquid passing port into the sealed e-liquid tank to realize the replacement of e-liquid (just as bubbles appear in the e-liquid tank when smoking), which increases the air pressure in the e-liquid tank, and then increases the speed of the e-liquid from the e-liquid tank to the e-liquid guide cotton, so that sufficient e-liquid is supplied for the ultrasonic atomization of the ultrasonic atomizing sheet to ensure smoke, the time for replacing the e-liquid in the e-liquid tank is shortened, the e-liquid in the e-liquid tank is absorbed by the e-liquid guide cotton more quickly, the continuity of delivery of the e-liquid by the e-liquid guide cotton is better, and dry burning of the ultrasonic atomizing sheet is prevented.
Preferably, e-liquid guide cotton mounting grooves for mounting the e-liquid guide cotton are symmetrically formed on the outer wall of the inner sleeve, the e-liquid guide cotton mounting groove is provided with a clamping segment at the upper part for clamping the e-liquid guide cotton and a loosening segment at the lower part, the depth of the e-liquid guide cotton mounting groove at the clamping segment is less than that of the e-liquid guide cotton mounting groove at the loosening segment, and at least one air inlet groove penetrates the loosening segment, so that the e-liquid guide cotton and the inner sleeve form a whole.
Preferably, four air inlet grooves penetrating axially are evenly distributed on the side wall of the inner sleeve, and at least two symmetrical air inlet grooves penetrate the loosening segments of the e-liquid guide cotton mounting grooves. Since at least two air inlet grooves are arranged symmetrically and penetrate the loosening segments, and the shunt intake air flow in the two air inlet grooves are the same, the intake air flows have the same influence on the speed of delivery of e-liquid by the e-liquid guide cotton, which prevents the atomization effect of the ultrasonic atomizing sheet from being affected by different quantities of e-liquid delivered on the left and right sides of the e-liquid guide cotton, and also enables the smoke in the atomization cavity at the bottom of the air inlet grooves from being taken away more thoroughly.
Preferably, a first upward rib is disposed on the clamping segment, for against a part of the e-liquid guide cotton in the outer sleeve, to reduce large friction produced by large-area extrusion contact between the e-liquid guide cotton and the outer sleeve, and to prevent the e-liquid guide cotton from staying in the outer sleeve when the inner sleeve is pulled out in order to replace the e-liquid guide cotton; a second upward rib is disposed on the loosening segment, for setting the e-liquid guide cotton such that the loosened e-liquid guide cotton is wave-shaped, which enhances the adhesion of e-liquid in this shape, thereby reducing the flow rate of the e-liquid there when the user is not smoking, and preventing the ultrasonic atomizing sheet from being soaked by the e-liquid. In addition, because the air inlet grooves are communicated with the loosening segments, the air flow force overcomes the adhesion of the e-liquid to the wave-shaped e-liquid guide cotton when smoking, the e-liquid flows faster, and the reduction of smoke due to insufficient e-liquid supply and the dry burning and cracking of the ultrasonic atomizing sheet are prevented.
Preferably, the middle part of the inner cavity of the inner sleeve is provided with a boss for sealing and clamping a breather pipe, and an air outlet cavity is formed at the lower part of the inner cavity of the inner sleeve under the boss, so that the e-liquid splashed during ultrasonic atomization is condensed in the air outlet cavity, and the user hardly inhales the e-liquid.
Preferably, the upper part of the inner cavity of the outer sleeve is sleeved with the inner sleeve, and a spring is disposed between the bottom of the inner sleeve and the e-liquid guide cotton; an ultrasonic atomizing sheet, an elastic insulating seat and an electrode assembly are sequentially disposed at the lower part of the inner cavity of the outer sleeve from top down, and the atomization cavity is formed between the bottom of the inner sleeve and the ultrasonic atomizing sheet; a first electrode is disposed on the upper surface of the ultrasonic atomizing sheet, and a second electrode is disposed on the lower surface of the ultrasonic atomizing sheet; the electrode assembly includes a first electrical connection terminal and a second electrical connection terminal separated by an insulating ring, the inner wall of the outer sleeve is directly electrically connected to the first electrode of the ultrasonic atomizing sheet and the second electrical connection terminal of the electrode assembly, and the second electrode of the ultrasonic atomizing sheet is electrically connected to the first electrical connection terminal of the electrode assembly.
Preferably, the upper part of the inner wall of the outer sleeve is provided with a support portion, the top of the outer wall of the inner sleeve is provided with a step, and the step is clamped and fixed on the support portion to fixedly connect the inner sleeve with the outer sleeve.
Preferably, the lower part of the inner wall of the outer sleeve is provided with a resisting portion for resisting the first electrode of the ultrasonic atomizing sheet to form an electrical connection, and a yielding portion for preventing the side wall of the ultrasonic atomizing sheet from being broken due to extrusion surrounds the periphery of the resisting portion, so that the assembled ultrasonic atomizing sheet is only subject to the resisting force of the resisting portion.
In order to solve the above technical problems, the present invention further provides an electronic cigarette atomizer, including an e-liquid tank device and a suction nozzle device which are connected to each other and are rotatable relatively, wherein an e-liquid tank is disposed inside the e-liquid tank device, the suction nozzle device is provided with a second air inlet channel and a suction nozzle, the above-mentioned electronic cigarette atomizing core is disposed in the e-liquid tank device, a breather pipe is disposed between the suction nozzle and the boss of the inner sleeve, a third air inlet channel is formed between the outer wall of the breather pipe and the suction nozzle device and between the outer wall of the breather pipe and the e-liquid tank device, and the second air inlet channel is communicated with the air inlet grooves through the third air inlet channel.
Compared with the prior art, the beneficial effects of the present invention are:
1. With the help of the airflow power during smoking, the flow rate of e-liquid on the e-liquid guide cotton is increased, and the replacement of the air and the e-liquid in the sealed e-liquid tank is accelerated, thereby preventing insufficient e-liquid supply when smoking;
2. An e-liquid obstruction structure (lower e-liquid rib) is disposed at a position corresponding to an e-liquid guide segment that effectively guides e-liquid together with the e-liquid guide cotton, which prevents the ultrasonic atomizing sheet from being soaked by excessive e-liquid guided thereto when the user is not smoking to affect the first puff of smoke during smoking.
The present invention will be further described below with reference to specific preferred embodiments, but the scope of protection of the present invention is not limited thereby.
For ease of description, the relative positional relationships (e.g., upper, lower, left, right, etc.) of components are described according to the layout direction of the accompanying drawings in the specification, and do not limit the structure of this patent.
As shown in
The side wall of the outer sleeve 1 is provided with a first e-liquid passing port 11 communicated with an e-liquid outlet of an e-liquid tank, the top of the outer sleeve 1 is provided with an insertion port 12 for placing in the inner sleeve 2, the upper part of the inner wall of the outer sleeve 1 is provided with a support portion 13 for supporting the inner sleeve 2, the lower part of the inner wall of the outer sleeve 1 is provided with a resisting portion 14 for resisting the first electrode of the ultrasonic atomizing sheet 6, and a yielding portion 15 for preventing the side wall of the ultrasonic atomizing sheet 6 from being broken due to extrusion surrounds the periphery of the resisting portion 14. After the atomizing core is assembled, the ultrasonic atomizing sheet 6 is only subject to the axial resisting force of the resisting portion 14, which prevents the ultrasonic atomizing sheet 6 from being damaged by a radial force.
The top of the outer wall of the inner sleeve 2 is provided with a step 21. Four air inlet grooves 22 penetrating axially and communicated with the atomization cavity 3 are evenly distributed on the side wall of the inner sleeve 2, and the air inlet grooves 22 are located inside the first e-liquid passing port 11. E-liquid guide cotton mounting grooves 23 are symmetrically formed on the outer wall of the inner sleeve 2, the e-liquid guide cotton mounting groove 23 is provided with a clamping segment 231 at the upper part for clamping the e-liquid guide cotton and a loosening segment 232 at the lower part that has a depth greater than that of the clamping segment 231, and two air inlet grooves 22 are arranged opposite to the e-liquid guide cotton mounting grooves 23 and penetrate the loosening segments 232. A first upward rib 2311 is disposed on the clamping segment 231, for holding a part of the e-liquid guide cotton 4 in the outer sleeve 1, to reduce large friction produced by large-area extrusion contact between the e-liquid guide cotton 4 and the outer sleeve 1, and to prevent the e-liquid guide cotton 4 from staying in the outer sleeve 1 when the inner sleeve 2 is pulled out to replace the e-liquid guide cotton 4; a second upward rib 2321 is disposed on the loosening segment 232, for setting the e-liquid guide cotton 4 such that the loosened e-liquid guide cotton 4 is wave-shaped, which enhances the adhesion of e-liquid in the wave-shaped e-liquid guide cotton 4, thereby reducing the flow rate of the e-liquid there when the user is not smoking, and preventing the ultrasonic atomizing sheet 6 from being soaked by the e-liquid. In addition, because a part of the air inlet groove 22 is located in the loosening segment 232 and communicated with the loosening segment 232, the flow rate of the e-liquid on the e-liquid guide cotton 4 can be increased by means of intake air flow when smoking; and a part of the air flow can enter the e-liquid tank through the first e-liquid passing port 11 to replace the e-liquid in the sealed oil tank, so that the e-liquid outlet speed of the e-liquid tank is faster, which prevents the reduction of smoke due to insufficient e-liquid when smoking and the dry burning and cracking of the ultrasonic atomizing sheet. The middle part of the inner cavity of the inner sleeve 2 is provided with a boss 24 for sealing and clamping a breather pipe 9, and the inner cavity of the inner sleeve 2 under the boss 24 is configured as an air outlet cavity 25, so that the e-liquid splashed during the ultrasonic atomization of the ultrasonic atomizing sheet 6 is condensed in the air outlet cavity 25, and the user hardly inhales the e-liquid.
Since the atomization cavity 3 is formed between the ultrasonic atomizing sheet 6 and the bottom of the inner sleeve 2, when the breather pipe 9 is inserted into the boss 24 of the inner sleeve 2 and the outer wall of the breather pipe 9 is clamped and sealed by the boss 24, the intake air flow can only enter the atomization cavity 3 from the four air inlet grooves 22, then passes through the atomization surface of the ultrasonic atomizing sheet 6 to take away smoke, and exits through the air outlet cavity 25 and the breather pipe 9. Since the four air inlet grooves 22 are evenly distributed, and the intake air flow in the four air inlet grooves is the same, equal air flow enters from four directions of the atomization cavity to take away the smoke, so that the smoke in the atomization cavity 3 is taken away more thoroughly.
When the atomizing core is assembled, the e-liquid guide cotton 4 placed with the spring 5 at the middle part is inserted from the bottom of the inner sleeve 2 upwards into the e-liquid guide cotton mounting grooves 23, the two ends of the e-liquid guide cotton 4 are respectively sleeved in the e-liquid guide cotton mounting grooves 23 on two sides of the inner sleeve 2, and the e-liquid guide cotton 4 and the inner sleeve 2 form a whole; then the inner sleeve 2 mounted with the e-liquid guide cotton 4 is inserted into the outer sleeve 1 through the insertion port 12 and clamped with the inner wall of the outer sleeve 1 tightly, the e-liquid guide cotton 4 is fixed more stably, the step 21 is caught and fixed on the support portion 13 to fixedly connect the inner sleeve 2 with the outer sleeve 1, and the loosening segment 232 is aligned with the e-liquid passing port 11 so that the e-liquid guide cotton 4 can fully store and guide e-liquid; finally, the ultrasonic atomizing sheet 6, the elastic insulating seat 7 and the electrode assembly 8 are sequentially placed on the bottom of the e-liquid guide cotton 4, the resisting portion 14 on the inner wall of the outer sleeve 1 presses against the first electrode of the ultrasonic atomizing sheet 6, the bottom of the inner wall of the outer sleeve 1 is connected to the second electrical connection terminal 83 of the electrode assembly 8 through threads, and the second electrode of the ultrasonic atomizing sheet 6 is electrically connected to the first electrical connection terminal 81 of the electrode assembly 8.
The above assembly method is only an option. Obviously, the ultrasonic atomizing sheet 6, the elastic insulating seat 7 and the electrode assembly 8 may also be first mounted at the lower part of the inner cavity of the outer sleeve 1, and then the inner sleeve 2 mounted with the e-liquid guide cotton 4 is inserted into the outer sleeve 1 and clamped with the inner wall of the outer sleeve 1 tightly.
As shown in
The forgoing descriptions are only preferred embodiments of the present application, and do not limit the present application in any form. Although the present application is disclosed above with the preferred embodiments, the present application is not limited thereto. Some variations or modifications made by any skilled person familiar with the art using the disclosed technical contents without departing from the scope of the technical solution of the present application are equivalent to the embodiments, and all fall within the scope of the technical solution.
Number | Date | Country | Kind |
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201910196623.3 | Mar 2019 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2020/079123 | 3/13/2020 | WO | 00 |