RU2830053C2 - Heating spraying core, heating spraying mechanism, heating sprayer and electronic sprayer - Google Patents

Abstract

FIELD: liquid atomisation or spraying devices.

SUBSTANCE: heating spraying core comprises a spraying core casing, a liquid transfer unit, a heating element and a fixing element, note here that said heating element is secured to fluid transfer unit inner wall while spraying core case side wall has fluid transfer hole. Liquid transfer web comprises at least two layers of liquid transfer web with vertical veins or at least two layers of liquid transfer web with horizontal veins, or at least one liquid transfer web with vertical veins and at least one liquid transfer web with horizontal veins. Veins on the liquid transfer web with vertical veins form microgrooves, which are located vertically. Veins on the liquid transfer web with horizontal veins form microgrooves, which are located horizontally.

EFFECT: more uniform flow of liquid into the liquid transfer unit and increased efficiency of liquid transfer and spraying effect.

17 cl, 21 dwg

Description

AREA OF TECHNOLOGY

[0001] The present invention relates to the field of atomization technology, and in particular relates to a heating atomization core, a heating atomization mechanism, a heating atomizer, and an electronic atomization device.

LEVEL OF TECHNOLOGY

[0002] In the prior art, a heating atomizing core usually comprises a liquid transfer unit and a heating element, the liquid in the liquid chamber enters the liquid transfer unit and is then transferred to the heating element. The heating element generates heat to atomize the cigarette liquid in the form of steam. Existing liquid transfer units cannot ensure uniform flow of liquid or uniform transfer of liquid therein, and cannot ensure that a sufficient amount of liquid is supplied to the heating element. When the heating element is continuously operated, the liquid transfer unit cannot provide a sufficient amount of cigarette liquid to the heating element, which makes the atomization effect unsatisfactory and seriously impairs the inhalation experience of users.

DISCLOSURE OF THE ESSENCE OF THE INVENTION

[0003] The technical problem to be solved by the present invention is to eliminate the disadvantages of uneven liquid inflow and transfer, low liquid transfer rate and poor atomization effect in the prior art by providing a heating atomization core, a heating atomization mechanism, a heating atomizer and an electronic atomization device having a good atomization effect and a high liquid transfer rate.

[0004] The technical solution used in the present invention to solve the technical problems is to develop a heating atomizing core that includes a housing of the atomizing core. A cylindrical liquid transfer unit is located in the housing of the atomizing core, and a heating element is attached to the inner wall of the liquid transfer unit and is connected to an electrode.

[0005] A liquid transfer hole is formed in the side wall of the spray core housing for transferring liquid to the liquid transfer unit.

[0006] The liquid transfer unit is a cylindrical structure formed by rolling up a plurality of layers of liquid transfer web with their placement on top of each other. The plurality of layers of liquid transfer web comprise at least one layer of liquid transfer web with vertical veins and/or at least one layer of liquid transfer web with horizontal veins, wherein the liquid transfer web with vertical veins has microgrooves and/or microribs formed by veins that are arranged generally vertically, and the liquid transfer web with horizontal veins has microgrooves and/or microribs formed by veins that are arranged generally horizontally.

[0007] A fixing member for fixing the electrode is located in the housing of the spray core below the liquid transfer unit, and an air inlet is formed in the fixing member.

[0008] Preferably, 1-6 layers of the liquid transfer web with vertical veins are provided, and at least a portion of the veins in each of the layers of the liquid transfer web with vertical veins correspond to each other in the radial direction such that the heating circuit of the heating element is at least partially inserted into the microgrooves or between adjacent microribs formed by the veins.

[0009] Preferably, the veins on the liquid transfer web with vertical veins and the liquid transfer web with horizontal veins are straight veins, curved veins, or veins formed by at least one of straight veins and curved veins.

[0010] Preferably, at least a portion of the veins on the liquid transfer web with vertical veins extend from top to bottom, and at least a portion of the veins on the liquid transfer web with horizontal veins extend from one edge to the other edge.

[0011] Preferably, the veins on the liquid transfer web with vertical veins correspond in shape to at least a portion of the heating element.

[0012] Preferably, 1-6 layers of the liquid transfer web with horizontal veins are provided, and at least a portion of the veins in each of the layers of the liquid transfer web with horizontal veins correspond to each other in the radial direction; or at least a portion of the veins on adjacent layers of the liquid transfer web with horizontal veins are arranged in a staggered manner in the radial direction.

[0013] Preferably, the veins on the web for transferring liquid with horizontal veins are arranged radially from the center in the form of an opening for transferring liquid to two sides; or

the density of veins on the liquid transfer web with horizontal veins near the liquid transfer opening is greater than the density of veins in other positions, or the veins on the liquid transfer web with horizontal veins are arranged horizontally and uniformly.

[0014] Preferably, the spray core housing is a cylindrical structure.

[0015] Preferably, a vertical groove is formed in the side wall of the spray core housing, and two horizontal edges of the plurality of layers of liquid transfer web are clamped in the vertical groove for fixation.

[0016] Preferably, at least two vertical grooves are formed in the side wall of the spray core housing,

wherein at least one of the two horizontal edges of the plurality of layers of the liquid transfer web is clamped in one said vertical groove; or

a plurality of layers of the liquid transfer web have a plurality of segments, and the edges of each two adjacent said segments are clamped in one said vertical groove for fixation.

[0017] Preferably, the spray core housing is a cylindrical structure, and two horizontal edges of each of the plurality of layers of the liquid transfer web are connected in such a way that a plurality of stacked cylindrical structures are formed; or two horizontal edges of the plurality of layers of the liquid transfer web are connected to form a single cylindrical structure.

[0018] Preferably, the vertically veined liquid transfer web is woven from flax and cotton fibers, and the horizontally veined liquid transfer web is woven from spunlace nonwoven fibers.

[0019] Preferably, the lower part of the electrode is bent for being attached to the inner wall of the spray core housing, the fixing member corresponds to the spray core housing in shape, and the electrode is pressed and fixed by the fixing member, or the fixing member is an elastic member, and the electrode is pressed and fixed in the spray core housing by the fixing member.

[0020] Preferably, a groove is formed in the outer wall of the fixing element and the electrode is clamped in the groove and fixed in the housing of the spray core by the fixing element; or

a fixing hole is formed in the fixing member, and the electrode passes through the fixing hole for fixation.

[0021] The heating atomizing mechanism comprises an atomizer housing. The above-described heating atomizing core is disposed in the atomizer housing, the upper and lower portions of the atomizer housing are sealed by an upper sealing member and a lower sealing member, respectively, a liquid chamber is formed between the heating atomizing core and the atomizer housing, and a liquid storage cotton for storing electronic cigarette liquid is disposed in the liquid chamber.

[0022] The heating atomizer comprises a heating atomizing mechanism described above. A guide tube is located in the center of the heating atomizing mechanism, wherein the guide tube has an end connected to the heating element of the heating atomizing core, and the other end connected to the mouthpiece in such a way that the mist atomized by the heating element is directed to the mouthpiece from the guide tube.

[0023] The electronic atomizing device comprises the above-described heating atomizer located in the upper part, a power supply device located in the middle part, and a control device located in the lower part. The power supply device is electrically connected to the heating atomizer and the control device.

[0024] The present invention has the following advantages: according to the heating spray core, the heating spray mechanism, the heating spray and the electronic spray device, the liquid transfer web with vertical veins is disposed on the inner side in contact with the heating element of the liquid transfer unit, the liquid transfer web with horizontal veins is disposed on the outer side in contact with the liquid transfer hole of the liquid transfer unit, wherein the veins on the liquid transfer web with vertical veins form microgrooves and/or microribs that are arranged generally vertically, the veins on the liquid transfer web with horizontal veins form microgrooves and/or microribs that are arranged generally horizontally, wherein both the microgrooves and/or microribs formed by the vertical veins correspond to the circuit structure of the heating element to enable the heating element to be inserted into the liquid transfer web to a small extent, so that the spray area is increased; The horizontal veins form horizontal microgrooves and/or microribs so that capillary gaps are formed in the liquid transfer sheet, the liquid transfer velocity along the microgrooves and/or microribs is higher than the liquid transfer velocity in other directions, and the liquid entering the liquid transfer hole can be better transferred circumferentially and can be transferred uniformly, which increases the liquid transfer efficiency and the atomization effect, and improves the inhalation experience of users.

BRIEF DESCRIPTION OF DRAWINGS

[0025] The present invention will be further described below in conjunction with the accompanying drawings and embodiments. In the drawings:

[0026] Fig. 1 is an exploded structural view of a first embodiment of a spray core in Embodiment 1 of the present invention;

[0027] Fig. 2 is an exploded structural view of a second embodiment of the spray core in Embodiment 1 of the present invention;

[0028] Fig. 3 is an exploded structural view of a third embodiment of the spray core in Embodiment 1 of the present invention;

[0029] Fig. 4 is an exploded structural view of a fourth embodiment of the spray core according to embodiment 1 of the present invention;

[0030] Fig. 5 is a sectional view of a spray core according to embodiment 1 of the present invention;

[0031] Fig. 6 is a three-dimensional structural view of a spray core according to embodiment 1 of the present invention;

[0032] Fig. 7 is a three-dimensional structural view of the spray core in Embodiment 1 of the present invention;

[0033] Fig. 8 - Fig. 14 - a view of a web for transferring liquid with horizontal veins in an unfolded form according to embodiments of the invention;

[0034] Fig. 15 - Fig. 18 - a view of a web for transferring liquid with vertical veins in an unfolded form according to an embodiment of the invention;

[0035] Fig. 19 is an exploded view of a heating spray mechanism according to embodiment 2 of the present invention;

[0036] Fig. 20 is a sectional view of a heating sprayer according to embodiment 3 of the invention; and

[0037] Fig. 21 is a sectional view of an electronic spray device according to embodiment 4 of the present invention.

IMPLEMENTATION OF THE INVENTION

[0038] For a better understanding of the technical features, objectives and effects of the present invention, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

[0039] When one element is referred to as being "attached" to or "disposed upon" another element, it may be directly or indirectly disposed upon said other element. When one element is referred to as being "connected" to another element, it is directly or indirectly connected to said other element.

[0040] Terms such as "upper", "lower", "left", "right", "front", "rear", "vertical", "horizontal", "top", "bottom", "inner" and "outer" are used to indicate directions or positions based on the accompanying drawings solely for the purpose of description and should not be construed as limiting the technical solutions of the present invention. Terms such as "first" and "second" are used solely for the purpose of facilitating the description and should not be construed as indicating or implying relative importance or as implicitly indicating the number of technical features mentioned. Unless otherwise expressly and specifically stated, the term "multiple" refers to two or more.

[0041] Embodiment 1: As shown in Fig. 1 to Fig. 7, the heating spray core comprises a spray core housing 30 in which a cylindrical liquid transfer unit 33 is disposed. A heating element 31 is attached to an inner wall of the liquid transfer unit 33 and is connected to an electrode 32. One or more liquid transfer holes 301 for transferring liquid to the liquid transfer unit 33 are formed in a side wall of the spray core housing 30, and the number of liquid transfer holes 301 is not limited. The liquid transfer block 33 is a cylindrical structure formed by rolling up a plurality of layers of liquid transfer web with their placement on top of each other, wherein the plurality of layers of liquid transfer web comprise at least two layers of liquid transfer web 332 with vertical veins or comprise at least two layers of liquid transfer web 331 with horizontal veins, or comprise at least one layer of liquid transfer web 332 with vertical veins and at least one layer of liquid transfer web 331 with horizontal veins. The present invention does not limit the position of laying the liquid transfer web 331 with horizontal veins and the liquid transfer web 332 with vertical veins on each other, wherein one of the liquid transfer web 331 with horizontal veins and the liquid transfer web 332 with vertical veins may be located on the innermost side for tight contact with the heating element 31, or may be located in the middle, or may be located on the outermost side for contact with the liquid transfer hole 301. Each of the plurality of layers of the liquid transfer web may be the liquid transfer web 331 with horizontal veins, or each of the plurality of layers of the liquid transfer web may be the liquid transfer web with vertical veins, or the plurality of layers of the liquid transfer web comprises both the liquid transfer web 331 with horizontal veins and the liquid transfer web 332 with vertical veins. Preferably, the web 332 for transferring liquid with vertical veins is arranged on the inner side for attachment to the heating element 31 and contact with it, and the web 331 for transferring liquid with horizontal veins is arranged on the outer side for contact with the opening 301 for transferring liquid. The web 332 for transferring liquid with vertical veins has microgrooves and/or microribs formed by veins that are arranged generally vertically, the web 331 for transferring liquid with horizontal veins has microgrooves and/or microribs formed by veins that are arranged generally horizontally; and a fixing member 34 for fixing the electrode 32 is located in the casing 30 of the atomizing core under the liquid transfer unit 33, and an air inlet 341 is formed in the fixing member 34. When using the heating atomizing core, the liquid enters the liquid transfer unit 33 through the liquid transfer hole 301 in the side wall of the casing 30 of the atomizing core, flows into the liquid transfer web 331 with horizontal veins on the outer side of the liquid transfer unit 33, and then flows circumferentially along the horizontal micro-ribs and/or micro-grooves and penetrates into the liquid transfer web 332 with vertical veins on the inner side. The heating element 31 is inserted into the micro-grooves and/or between the micro-ribs on the liquid transfer web 332 with vertical veins. The electrode 32 supplies power to the heating element 31 so that the heating element 31 generates heat to atomize the cigarette liquid in the liquid transfer unit 33 in the form of steam, and at this time, the steam is transferred to the air flow path by the air flowing through the air inlet 341, and is finally inhaled by the users.

[0042] As shown in Fig. 15 - Fig. 18, the veins of the web 332 for transferring liquid with vertical veins are arranged generally vertically, which means that the veins of the web 332 for transferring liquid with vertical veins extend generally from top to bottom, but this does not require that each of the veins extend from top to bottom; the web 332 for transferring liquid with vertical veins may also have branched veins extending outward from the vertical veins, or the vertical veins and horizontal veins may be arranged in a staggered manner. Microgrooves and/or microribs formed by veins, which are arranged generally vertically, of the web 332 for transferring liquid with vertical veins can be used as vertical mounting channels, into which the vertical segments of the heating circuit of the heating element 31 can be slightly inserted in such a way that the contact area between the heating element 31 and the liquid transfer unit 33 is increased. As shown in Fig. 8 - Fig. 14, the veins of the web 331 for transferring liquid with horizontal veins are arranged generally horizontally, which means that the veins of the web 331 for transferring liquid with horizontal veins extend generally from left to right, but this does not require that each of the veins extend from left to right; the web 331 for transferring liquid with horizontal veins can also have branched veins extending outward from the horizontal veins, or the vertical veins and the horizontal veins can be arranged in a staggered manner. Microgrooves and/or microribs formed by veins that are arranged generally horizontally, the web 331 for transporting liquid with horizontal veins form capillary gaps used as horizontal channels for transporting liquid, and the liquid transport speed along the microgrooves and/or microribs is higher than the liquid transport speed in other directions, so that the liquid can be better transported in various directions and can be transported more uniformly, which improves the liquid transport efficiency and the spray effect, and improves the inhalation experience of users.

[0043] The heating element 31 may be a heating part made of metal, which is rolled into a cylinder for attachment to the inner wall of the liquid transfer unit. Typically, the heating element 31 is made of an alloy with a high specific electrical resistance, such as a stainless steel alloy, a nickel-chromium alloy, an iron-chromium-aluminum alloy or an iron-nickel alloy. The thickness of the heating element 31 may be 0.03-0.2 mm, and in this aspect, the present invention is not limited. The heating circuit and the electrode 32 may be formed by a cutting or corrosion process, and the terminal of the electrode 32 is configured to contact the outer electrode 32. The end of the terminal of the electrode 32 extending outside is preferably wrapped with an insulating sheath, and the terminal may be made of pure nickel or be a copper wire with a silver-plated surface. In addition, the fixing element 34 is configured to fix the terminal of the electrode 32 in such a way as to avoid weak contact between the heating element 31 and the liquid transfer unit 33 caused by movements of the heating element 31 when the terminal extending outward is under voltage.

[0044] 1-6 layers of the web 332 for transferring liquid with vertical veins are arranged, wherein the specific number of layers of the web 332 for transferring liquid with vertical veins is not limited. The plurality of layers of the web 332 for transferring liquid with vertical veins are stacked on top of each other in the following manner: at least a part of the veins in the plurality of layers of the web 332 for transferring liquid with vertical veins correspond to each other in the radial direction, which means that the vertical veins in the plurality of layers of the web 332 for transferring liquid with vertical veins correspond to each other in shape and position and are identical or substantially identical in size such that the heating circuit of the heating element 31 is at least partially inserted into the microgrooves or between adjacent microribs formed by the veins. The term "corresponds" used herein should be understood to mean partially or completely corresponding, which can increase the contact area between the heating element 31 and the liquid transfer web 332 with vertical veins (spray area of the spray surface) so that the cigarette liquid in the liquid transfer unit 33 can be sprayed to a greater extent, which improves the spray effect.

[0045] In some embodiments, there are multiple embodiments of the arrangement of veins on the liquid transfer web 332 with vertical veins and on the liquid transfer web 331 with horizontal veins. As shown in Fig. 8 - Fig. 19, the veins on the liquid transfer web 332 with vertical veins and on the liquid transfer web 331 with horizontal veins are straight veins, curved veins, or veins formed by at least one of straight veins and curved veins. The veins on the liquid transfer web 332 with vertical veins and the liquid transfer web 331 with horizontal veins can be straight veins that are arranged at regular intervals and evenly, as shown in Fig. 10 and Fig. 17, or irregular branched veins formed by straight lines, as shown in Fig. 12, or zigzag veins formed by straight lines, as shown in Fig. 9 and Fig. 16. The veins are not absolutely straight veins and may be wavy veins formed by curved lines, as shown in Fig. 11, or veins formed by straight lines and curved lines, as shown in Fig. 13. The veins are not absolutely continuous veins and may be stripe-like veins distributed at intervals, as shown in Fig. 8 and Fig. 18, crossed curved veins, as shown in Fig. 14, or crossed straight veins. Compared with straight veins, zigzag veins and curved veins can provide more storage space for liquid to ensure sufficient supply of liquid during continuous inhalation by users. In actual use, the shape and arrangement of the veins are not particularly limited as long as the direction of the veins satisfies the design principle that the veins on the liquid transfer web in contact with the heating element 31 are generally vertical and the veins on the liquid transfer web in contact with the liquid transfer hole 301 are generally horizontal.

[0046] There are many embodiments of the arrangement of veins on the web 332 for transferring liquid with vertical veins and on the web 331 for transferring liquid with horizontal veins. At least a part of the veins on the web 332 for transferring liquid with vertical veins extend from top to bottom, and at least a part of the veins on the web 331 for transferring liquid with horizontal veins extend from one edge to the other edge. The vertical veins are formed on the web 332 for transferring liquid with vertical veins in such a way that microgrooves or microribs can be formed that are in close contact with the vertical segments of the heating circuit of the heating element 31, thereby increasing the contact area between the heating element 31 and the web 332 for transferring liquid with vertical veins. At least a portion of the veins on the web 332 for transferring liquid with vertical veins extend from top to bottom, and other veins on the web 332 for transferring liquid with vertical veins may be horizontal or inclined, or all of the veins on the web 332 for transferring liquid with vertical veins extend from top to bottom.

[0047] In some embodiments, the veins on the vertically veined liquid transfer web 332 are identical in shape to at least a portion of the heating element 31, that is, at least a portion of the heating element 31 is inserted into microgrooves or between adjacent microribs formed by the veins such that the spray area between the heating element 31 and the vertically veined liquid transfer web 332 is increased.

[0048] In some embodiments, 1-6 layers of the web 331 for transporting liquid with horizontal veins are provided, which are stacked on top of each other in the following manner: at least a portion of the veins in the plurality of layers of the web 331 for transporting liquid with horizontal veins correspond to each other in the radial direction, which means that the horizontal veins in the plurality of layers of the web 331 for transporting liquid with horizontal veins correspond to each other in shape and position and are identical or substantially identical in size. The term "corresponds" as used herein should be understood as meaning a partial or complete correspondence. In other embodiments, at least a portion of the veins on adjacent layers of the web 331 for transferring liquid with horizontal veins are arranged in a staggered manner in the radial direction, which means that the microgrooves or microribs formed by the horizontal veins on adjacent layers of the web 331 for transferring liquid with horizontal veins are arranged in a staggered manner, i.e. the microribs or projections of the horizontal veins forming the microgrooves of the horizontal fibers on one layer of the web 331 for transferring liquid with horizontal veins enter with engagement into the recesses formed by the microribs of the horizontal fibers, or into the microgrooves of the horizontal fibers on an adjacent layer of the web 331 for transferring liquid with horizontal veins in such a way that the speed of transfer of liquid increases, wherein the veins can be partially or completely arranged in a staggered manner.

[0049] In some embodiments, the horizontal veins on the liquid transfer web 331 with horizontal veins and the vertical veins on the liquid transfer web 332 with vertical veins should be understood as micro-ribs or micro-grooves on the surface of the liquid transfer web. The width of the micro-grooves or micro-ribs on each layer of the liquid transfer web is less than 0.5 mm, and the depth of the micro-grooves or micro-ribs on each layer of the liquid transfer web is less than 0.1 mm. By adjusting the height and the distance between the micro-ribs or micro-grooves to control the amount of stored liquid, the liquid transfer unit 33 will be saturated after some absorption of liquid and will not be oversaturated, which will prevent the liquid from flowing out of the liquid transfer unit 33, which otherwise may disrupt the spray effect.

[0050] In some embodiments, the veins on the liquid transfer web 331 with horizontal veins are arranged radially from the center as the liquid transfer opening 301 to two sides, so that the liquid entering the liquid transfer opening 301 can be quickly transferred circumferentially along two sides after entering the liquid transfer web; or the density of the veins on the liquid transfer web 331 with horizontal veins near the liquid transfer opening 301 is greater than the density of the veins at other positions, so that the liquid entering the liquid transfer opening 301 can be transferred around the liquid transfer opening 301 as a center point; or the veins on the liquid transfer web 331 with horizontal veins are arranged horizontally and uniformly.

[0051] The spray core housing 30 is a cylindrical structure. Since the liquid transfer unit 33 is cylindrical, the spray core housing 30 is formed as a cylindrical housing to match the liquid transfer unit 33 in order to better secure the liquid transfer unit 33 formed by rolling up a plurality of layers of liquid transfer web, which can be fixedly installed in the spray core housing 30. In some specific embodiments, in order to save costs, the spray core housing 30 is formed by cutting a metal tube and is a tubular structure, and the liquid transfer hole 301 allowing the liquid to enter is formed in the side wall of the spray core housing 30.

[0052] In some embodiments, the spray core housing 30 may be a tubular metal structure with at least one slot formed in the side wall so that the liquid transfer unit 33 and the heating element 31 can be easily installed in the spray core housing 30. Preferably, a vertical slot 302 is formed in the side wall of the spray core housing 30, as shown in Fig. 2, the open end of the heating element 31 faces the junction of two horizontal edges of the plurality of layers of the laid and rolled up liquid transfer web, and the junction of the two horizontal edges of the plurality of layers of the liquid transfer web is completely clamped in the vertical groove 302 for fixation, so that the heating circuit of the heating element 31 can better correspond to the liquid transfer unit 33, which improves the spray effect and solves the problem that the junction of the two horizontal edges of the plurality of layers of the rolled up liquid transfer web cannot completely correspond to the heating element 31. Or, as shown in Fig. 1 and Fig. 7, no groove is formed in the side wall of the spray core housing 30, and the plurality of layers of the laid and rolled up liquid transfer web are fixed in the cavity of the atomizer.

[0053] In some embodiments, as shown in Fig. 3 and Fig. 6, at least two vertical grooves 302 are formed in the side wall of the housing 30 of the spray core, and two horizontal edges of the plurality of layers of the laid and rolled up liquid transfer web are clamped in one vertical groove 302 for fixation; or, as shown in Fig. 4, the plurality of layers of the liquid transfer web have a plurality of segments, and the edges located in the same direction as each of two adjacent segments of the plurality of layers of the liquid transfer web are clamped in one vertical groove 302 for fixation.

[0054] In some embodiments, the spray core housing 30 is cylindrical, and two horizontal edges of each of the plurality of layers of the liquid transfer web are connected in such a way that a plurality of stacked cylindrical structures are formed; or two horizontal edges of the plurality of layers of the liquid transfer web are connected to form a single cylindrical structure; that is, the cylindrical liquid transfer block 33 is fixed in the cavity of the cylindrical spray core housing 30.

[0055] In some embodiments, the web 332 for transferring liquid with vertical veins is woven from flax and cotton fibers, and the web 331 for transferring liquid with horizontal veins is woven from spunlace nonwoven fibers. The web 332 for transferring liquid with vertical veins woven from flax and cotton fibers can withstand high temperature, the probability of its charring upon contact with the heating element 31 is relatively small and the web has a longer service life, and the vertical veins corresponding to the heating circuit of the heating element 31 ensure that the heating element 31 is inserted to a small extent into the web 332 for transferring liquid with vertical veins, so that the contact area between the heating element 31 and the web 332 for transferring liquid with vertical veins is increased. Since the non-woven fibers have good liquid transfer properties, the horizontal vein liquid transfer web 331 woven from the non-woven fibers can transfer the liquid to the heating element 31 from the inner side faster when arranged on the outer side, and the horizontal veins form horizontal microgrooves or microribs, which in turn form large capillary gaps on the horizontal vein liquid transfer web 331, and the liquid transfer speed along the microgrooves is higher than the liquid transfer speed in other directions, so that the liquid entering the liquid transfer hole 301 can be better transferred circumferentially, and the liquid can uniformly flow into the cylindrical liquid transfer block 33.

[0056] In some embodiments, the lower part of the electrode 32 is bent to be attached to the inner wall of the housing 30 of the atomizing core, the locking element 34 corresponds to the housing 30 of the atomizing core in shape, and the electrode 32 is pressed and fixed by the locking element 34; or the locking element 34 is an elastic element, and the electrode 32 is pressed and fixed in the housing 30 of the atomizing core by means of the locking element 34.

[0057] In some embodiments, a groove is formed in the outer wall of the locking element 34, the electrode 32 is clamped in the groove, and the locking element 34 is fixed in the housing 30 of the spray core; or a locking hole is formed in the locking element 34, and the electrode 32 penetrates through the locking hole for fixation.

[0058] Embodiment 2: In some embodiments, as shown in Fig. 19, the heating spray mechanism comprises an atomizer housing 20, wherein the heating spray core in Embodiment 1 is disposed in the atomizer housing 20, the upper and lower portions of the atomizer housing 20 are sealed by an upper sealing member 21 and a lower sealing member 23, respectively, a liquid chamber is formed between the heating spray core and the atomizer housing 20, and a cotton 22 for storing cigarette liquid is disposed in the liquid chamber; the upper sealing member 21 and the lower sealing member 23 disposed on the atomizer housing 20 can prevent the cigarette liquid in the liquid chamber from leaking; and when the heating spray mechanism is used, the cigarette liquid in the liquid chamber flows to the liquid transfer holes 301 in the atomizer housing 20 and is transferred to the heating spray core to be heated and atomized in the form of steam. Other designs of the heating spray mechanism are prior art and will not be discussed in this document.

[0059] Embodiment 3: As shown in Fig. 20, the heating atomizer comprises the heating atomizer mechanism of Embodiment 2, wherein a guide tube 11 is disposed in the center of the heating atomizer mechanism, one end of which is connected to the heating element 31 of the heating atomizer core, the other end of the guide tube 11 is connected to the mouthpiece 10, and the mist atomized by the heating element 31 is guided to the mouthpiece 10 from the guide tube 11; and when using the heating atomizer, the liquid for the cigarette is heated by the heating element 31 to be atomized in the form of steam, which flows to the mouthpiece 10 through the guide tube 11 and is finally inhaled by users. Other structures of the heating atomizer belong to the prior art and will not be discussed herein.

[0060] Embodiment 4: As shown in Fig. 21, the electronic atomizing device comprises a heating atomizer according to Embodiment 3 at an upper portion, a power supply device 4 at a middle portion, and a control device 5 at a lower portion, wherein the power supply device 4 is electrically connected to the heating atomizer and the control device 5; when using the electronic atomizing device, the control device 5 is controlled to start the power supply device 4 that supplies power to the heating atomizer, which atomizes the cigarette liquid in the form of vapor, and the vapor is finally inhaled by users. Other structures of the heating atomizing device belong to the prior art and will not be discussed herein.

Claims (40)

1. A heating atomizing core comprising a housing (30) of the atomizing core, wherein a cylindrical block (33) for transferring liquid is located in the housing (30) of the atomizing core, and a heating element (31) is attached to the inner wall of the block (33) for transferring liquid and is connected to an electrode (32); in the side wall of the casing (30) of the spray core, a liquid transfer hole (301) is formed for transferring liquid to the liquid transfer unit (33); the liquid transfer block (33) is a cylindrical structure formed by rolling up a plurality of layers of liquid transfer web with their placement on top of each other, wherein the plurality of layers of liquid transfer web comprise at least two layers of liquid transfer web (332) with vertical veins or comprise at least two layers of liquid transfer web (331) with horizontal veins, or comprise at least one layer of liquid transfer web (332) with vertical veins and at least one layer of liquid transfer web (331) with horizontal veins, wherein, when using the web (332) for transferring liquid with vertical veins, the web (332) for transferring liquid with vertical veins provides microgrooves and microribs formed by veins that are located generally vertically, and when using the web (331) for transferring liquid with horizontal veins, the web (331) for transferring liquid with horizontal veins provides microgrooves and microribs formed by veins that are located generally horizontally; a fixing element (34) for fixing the electrode (32) is located in the casing (30) of the spray core below the block (33) for transferring the liquid, and an inlet opening (341) for air is made in the fixing element (34). 2. A heating spray core according to item 1, in which 1-6 layers of web (332) for transferring liquid with vertical veins are placed, and at least a portion of the veins on each of the layers of the web (332) for transferring liquid with vertical veins correspond to each other in shape, position and size in the radial direction in such a way that the heating circuit of the heating element (31) is at least partially inserted into the microgrooves. 3. The heating spray core according to claim 1, wherein when using a web (332) for transferring liquid with vertical veins, the veins on the web (332) for transferring liquid with vertical veins are straight veins, curved veins or veins formed by straight veins and curved veins, and when using the horizontal-veined liquid transfer fabric (331), the veins on the horizontal-veined liquid transfer fabric (331) are straight veins, curved veins, or veins formed by straight veins and curved veins. 4. The heating spray core according to claim 1, wherein when using a web (332) for transferring liquid with vertical veins, at least part of the veins on the web (332) for transferring liquid with vertical veins extends from top to bottom, and when using a web (331) for transferring liquid with horizontal veins, at least a portion of the veins on the web (331) for transferring liquid with horizontal veins extend from one edge to the other edge. 5. The heating spray core according to claim 1, in which the veins on the web (332) for transferring liquid with vertical veins correspond in shape, position and size to at least part of the heating element (31). 6. A heating spray core according to item 1, in which 1-6 layers of web (331) for transferring liquid with horizontal veins are placed, and at least a portion of the veins on each of the layers of the web (331) for transporting liquid with horizontal veins correspond to each other in shape, position and size in the radial direction; or at least some of the veins on adjacent layers of the web (331) for transferring liquid with horizontal veins are arranged in a staggered manner in the radial direction. 7. The heating spray core according to claim 1, in which the veins on the web (331) for transferring liquid with horizontal veins are arranged radially from the center in the form of an opening (301) for transferring liquid to two sides; or the density of veins on the web (331) for transferring liquid with horizontal veins near the opening (301) for transferring liquid is greater than the density of veins located in other positions on the web (331) for transferring liquid with horizontal veins; or The veins on the web (331) for transferring liquid with horizontal veins are arranged horizontally and evenly. 8. The heating spray core according to claim 1, wherein the casing (30) of the spray core is a cylindrical structure. 9. The heating spray core according to claim 1, wherein a vertical groove (302) is formed in the side wall of the casing (30) of the spray core, and two horizontal edges of the plurality of layers of the web for transferring liquid are clamped in the vertical groove (302) for fixation. 10. The heating spray core according to claim 1, wherein at least two vertical grooves (302) are formed in the side wall of the casing (30) of the spray core, wherein the plurality of layers of the liquid transfer web are taken together and folded and rolled into a cylinder, and at least one of the two horizontal edges of the plurality of layers of the liquid transfer web is clamped in one said vertical groove (302); or a plurality of layers of the liquid transfer web have a plurality of segments, and the edges that are in the same direction as each of the two adjacent said segments are clamped in one said vertical groove (302) for fixation. 11. The heating spray core according to claim 1, wherein the casing (30) of the spray core is a cylindrical structure, and two horizontal edges of each of the plurality of layers of the liquid transfer web are connected in such a way that a plurality of stacked cylindrical structures are formed; or two horizontal edges of multiple layers of liquid transfer fabric are connected to form a single cylindrical structure. 12. The heating spray core according to claim 1, wherein the web (332) for transferring liquid with vertical veins is woven from flax and cotton fibers, and the web (331) for transferring liquid with horizontal veins is woven from spunlace nonwoven fibers. 13. The heating atomizing core according to claim 1, in which the lower part of the electrode (32) is bent for attachment to the inner wall of the casing (30) of the atomizing core, the fixing element (34) corresponds to the casing (30) of the atomizing core in shape, position and size, and the electrode (32) is pressed and secured by the fixing element (34); or the fixing element (34) is an elastic element, and the electrode (32) is pressed and secured in the casing (30) of the spray core by means of the fixing element (34). 14. The heating atomizing core according to claim 1, in which a groove is formed in the outer wall of the fixing element (34), and the electrode (32) is clamped in the groove and fixed in the casing (30) of the atomizing core by the fixing element (34); or a fixing hole is formed in the fixing member (34), and the electrode (32) passes through the fixing hole for fixation. 15. A heating spray mechanism comprising a spray housing (20), wherein the heating spray core according to any one of paragraphs 1-14 is located in the casing (20) of the sprayer, the upper and lower parts of the casing (20) of the sprayer are sealed using an upper sealing element (21) and a lower sealing element (23), respectively, a chamber for liquid is formed between the heating atomizing core and the casing (20) of the atomizer, and In the liquid chamber, there is a cotton (22) for storing liquid for storing liquid for an electronic cigarette. 16. A heating sprayer comprising a heating spray mechanism according to claim 15, wherein the guide tube (11) is located in the center of the heating spray mechanism, wherein the guide tube (11) has an end connected to the heating element (31) of the heating atomizing core, and the other end connected to the mouthpiece (10) in such a way that the mist atomized by the heating element (31) is directed into the mouthpiece (10) from the guide tube (11). 17. An electronic atomizing device comprising a heating atomizer according to claim 16, located in the upper part of the electronic atomizing device, a power supply device (4) located in the middle part of the electronic atomizing device, and a control device (5) located in the lower part of the electronic atomizing device, wherein the power supply device (4) has an electrical connection with the heating atomizer and the control device (5).