RU2805522C1 - Electronic evaporator unit and electronic evaporation device - Google Patents

Abstract

FIELD: evaporation devices.

SUBSTANCE: electronic evaporator unit contains a cartridge, a heating housing forming the first groove, and a heating base forming the second groove. The side wall of the first groove forms a receiving groove. A protruding element is located on the side wall of the second groove. The first groove and the second groove form an evaporation chamber. The protruding element is placed in the receiving groove and interacts with the receiving groove to implement a seal between the cartridge and the evaporation chamber. A through hole is formed in the bottom wall of the first groove, and a plurality of protrusions are formed in the side wall of the through hole, and a plurality of third grooves are formed. The claimed electronic evaporation unit is used in an electronic evaporation device containing the electronic evaporation unit and the power unit.

EFFECT: prevention of formation of a liquid film in the through hole after accumulation of condensate during use of the evaporator and prevention of leakage, as well as improved performance of the evaporator.

14 cl, 9 dwg

Description

FIELD OF TECHNOLOGY TO WHICH THE INVENTION RELATES

[001] The present invention relates to the field of vaporizers, and in particular to an electronic vaporizer assembly and an electronic vaporizer device.

PREREQUISITES FOR CREATION OF THE INVENTION

[002] In existing electronic vaporizer devices, leakage of e-liquid when the user inhales the aerosol is a common problem in the industry. One of the main causes of leakage is insufficient sealing of the evaporation chamber. This causes the e-liquid in the cartridge to penetrate into the vapor chamber during suction, and the e-liquid is drawn into the central tube, causing the leakage phenomenon. Another cause of leakage is the formation of an oil film in the central tube by condensed cigarette gas. The oil film is difficult to destroy and is easily absorbed into the user's mouth during suction.

SUMMARY OF THE INVENTION

[003] The present invention provides an electronic vaporizer unit and an electronic vaporizer device to solve the problem of e-liquid leakage when a user inhales the aerosol in existing technology.

[004] According to an aspect of the present invention, an electronic vaporizer assembly is provided. This unit contains: a cartridge, a heating jacket and a heating base. The heating mantle defines the first groove, and the side wall of the first groove defines the receiving groove. The heating base forms a second groove, and the first groove and the second groove form an evaporation chamber. The side wall of the second groove is provided with a protruding element, and this protruding element is located in the receiving groove. The protruding member and the receiving groove are used together to realize a seal between the cartridge and the evaporation chamber.

[005] In some embodiments, the groove direction of the receiving groove is the same as the groove direction of the first slot, and the height direction of the projecting member is the same as the groove direction of the second slot.

[006] In some embodiments, the side walls of the first slot include a first side wall, a second side wall, a third side wall, and a fourth side wall. The first side wall is located opposite the third side wall, and the second side wall is located opposite the fourth side wall. A first receiving groove is formed in the second side wall, and a second receiving groove is formed in the fourth side wall. The side walls of the second groove include a fifth side wall, a sixth side wall, a seventh side wall and an eighth side wall. The fifth side wall is located opposite the seventh side wall, and the sixth side wall is located opposite the eighth side wall. The sixth side wall is provided with a first protruding element, and the eighth side wall is provided with a second protruding element.

[007] In some embodiments, a first recess is formed in the first side wall and a second recess is formed in the third side wall. One end of the first receiving groove extends to the first side wall and is adjacent to the first recess, and the other end of the first receiving groove extends to the third side wall and is adjacent to the second recess. One end of the second receiving groove extends to the first side wall and is adjacent to the first recess, and the other end of the second receiving groove extends to the third side wall and is adjacent to the second recess. A third recess is formed in the fifth side wall, and a fourth recess is formed in the seventh side wall. One end of the first protruding member extends to the fifth side wall and is adjacent to the third recess, and the other end of the first protruding member extends to the seventh side wall and is adjacent to the fourth recess. One end of the second protruding member extends to the fifth side wall and is adjacent to the third recess, and the other end of the second protruding member extends to the seventh side wall and is adjacent to the fourth recess.

[008] In some embodiments, recesses are formed in the inner side wall of the receiving slots, and the side wall of the protruding elements is provided with protruding portions, the protruding portions being arranged in cooperation with the recesses.

[009] In some embodiments, the heating mantle material is plastic and the heating base material is silica gel.

[0010] In some embodiments, a through hole is formed in the bottom wall of the first slot, and a side wall of the through hole is provided with a convex or a third slot is formed therein.

[0011] In some embodiments, a plurality of protuberances or a plurality of third slots at intervals are located on the side wall of the through hole in a circumferential direction.

[0012] In some embodiments, the cross-section of the boss or third slot is square, triangular, or arcuate.

[0013] In some embodiments, the electronic vaporizer assembly further includes a suction tube, and the through hole communicates with the suction tube such that the vapor chamber communicates with the suction tube.

[0014] According to yet another aspect of the present invention, there is provided an electronic vaporizer device comprising an electronic vaporizer assembly and a power supply assembly. The electronic vaporizer assembly is the electronic vaporizer assembly described in any of the above embodiments.

[0015] In the present invention, the seal between the cartridge and the evaporation chamber is realized by placing a receiving groove on the heating jacket and a protruding element on the heating base. By preventing the e-liquid in the cartridge from entering the vaporization chamber, the performance of the vaporizer is improved, while preventing the user from sucking in the e-liquid to be vaporized, thereby affecting the user experience.

BRIEF DESCRIPTION OF GRAPHIC MATERIALS

[0016] To more clearly illustrate the technical solutions in the embodiments of the present application or in the prior art, a brief description is provided of the accompanying drawings used in the embodiments or in the prior art. Of course, the graphics in the following description correspond only to some embodiments of the present invention, and other graphics can be derived from these graphics without creative effort by one skilled in the art.

[0017] In FIG. 1 is a cross-sectional view along the A-A direction of the electronic evaporator unit.

[0018] In FIG. 2 is a cross-sectional view along the B-B direction of the electronic evaporator unit.

[0019] In FIG. 3 is a block diagram of a heating shell of an electronic evaporator unit according to the first embodiment of the present invention.

[0020] In FIG. 4 is a block diagram of a heating base of an electronic evaporator unit according to the first embodiment of the present invention.

[0021] In FIG. Figure 5 shows a block diagram of the configuration of the heating jacket and heating base of the electronic evaporator unit.

[0022] In FIG. Figure 6 shows a block diagram of the through hole of the heating casing of the electronic evaporator unit.

[0023] In FIG. 7 is a block diagram of a through hole of a heating jacket of an electronic evaporator unit according to another embodiment of the present invention.

[0024] In FIG. 8 is a cross-sectional view of the configuration of the receiving groove on the heating mantle and the protruding elements on the heating base of the electronic evaporator unit.

[0025] In FIG. Figure 9 shows a block diagram of an electronic evaporation device.

DETAILED DESCRIPTION

[001] The technical solutions in the embodiments of the present invention will be clearly and fully described with reference to the accompanying drawings in the embodiments of the present invention. Of course, the described embodiments do not represent all, but only a portion of the embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by those skilled in the art without creative work are within the scope of the present invention.

[002] The terms “first,” “second,” and “third” in embodiments of the present invention are used for descriptive purposes only and should not be interpreted as indicating or implying the relative importance of said technical features or as implicitly indicating the number of technical features. Therefore, a feature defined by the terms “first,” “second,” or “third” may explicitly or implicitly include at least one such feature. As used herein, “many” means at least two, such as two, three, etc., unless otherwise expressly and specifically limited. In addition, the terms “includes” and “has” and any variations thereof are intended to cover non-exclusive inclusion. For example, a process, method, system, product or device comprising a number of operations or blocks is not limited to the listed operations or blocks, but optionally also includes operations or blocks that are not listed, or optionally also includes other operations or blocks inherent in the process, method , product or device.

[003] References to “embodiments” mean that the particular feature, structure or characteristic described by reference to the embodiment may be included in at least one embodiment of the present invention. The presence of a term in different sections of the description does not necessarily mean the same embodiment, nor does it mean that it is a separate or alternative embodiment that is mutually exclusive with other embodiments. One skilled in the art will appreciate, either explicitly or implicitly, that the embodiments described herein may be combined with other embodiments.

[004] The present invention provides an electronic vaporizer assembly shown in FIG. 1 and fig. 2. In FIG. 1 is a cross-sectional view in direction A-A of the electronic vaporizer unit, and FIG. 2 is a cross-sectional view in direction B-B. Direction A-A is perpendicular to direction B-B.

[005] The electronic vaporizer assembly may include a cartridge 10, a heating mantle 20, a heating base 30, a heating coil 40, a suction tube 50, and a mouthpiece 60.

[006] The cartridge 10 may be mounted on the heating mantle 20 and is configured to store e-liquid. That is, the heating mantle 20 is located in the cartridge 10. The cartridge 10 may be plastic and may also be made of metal, such as aluminum and stainless steel. Cartridge 10 should only be capable of storing e-liquid without deteriorating. The shape and size of the cartridge 10 are not limited and can be designed according to requirements.

[007] The heating mantle 20 and the heating base 30 form a flash chamber 70. A heating coil 40 may be located between the heating mantle 20 and the heating base 30. A heating coil 40 may be located at least partially within the flash chamber 70. The heating mantle 20 may cooperate with a heating coil base 30 with the implementation of a seal between the cartridge 10 and the evaporation chamber 70. The material of the heating casing 20 is plastic, for example PCTG plastic (polyethylene terephthalate-1, 4-cyclohexanedimethanol). The material of the heating base 30 may be silica gel, such as 70 degree silica gel. The shape and size of the heating mantle 20 and the heating base 30 are not limited and can be designed according to requirements.

[008] The suction tube 50 penetrates the cartridge 10, one end of the suction tube 50 may be connected to the mouthpiece 60, and the other end of the suction tube may be connected to the heating jacket 20. The suction tube 50 may be in communication with the vaporization chamber 70 via the heating jacket 20. Due to this, the evaporated gas in the evaporation chamber 70 can be inhaled by the user through the suction tube 50.

[009] The seal between the cartridge 10 and the vapor chamber 70 can prevent e-cigarette liquid to be vaporized from leaking from the cartridge 10 into the vapor chamber 70 . Since the evaporation chamber 70 communicates with the suction tube 50, preventing e-liquid to be evaporated from leaking from the cartridge 10 into the evaporation chamber 70 prevents e-liquid from leaking into the suction tube 50. Therefore, the phenomenon of e-liquid leakage when the user inhales the aerosol.

[0010] In FIG. 3 is a block diagram of a heating shell of an electronic evaporator unit according to the first embodiment of the present invention, and FIG. 4 is a block diagram of a heating base of an electronic evaporator unit according to the first embodiment of the present invention.

[0011] As shown in FIG. 3, in the first embodiment, the heating mantle 20 may define the first groove 21, and the first groove 21 may form the top of the evaporation chamber 70. The side wall of the first groove 21 may define the receiving groove 211, and the groove direction of the receiving groove 211 may be the same. as the groove execution direction of the first groove 21. In other words, the depth direction of the receiving groove 211 is the same as the depth direction of the first groove 21.

[0012] The side walls of the first slot 21 may include a first side wall 212, a second side wall 213, a third side wall 214, and a fourth side wall 215. The first side wall 212 is located opposite the third side wall 214, and the second side wall 213 is located opposite the fourth side wall walls 215. A first recess 2121 is formed in the first side wall 212, and a second recess 2141 is formed in the third side wall 214. The first recess 2121 and the second recess 2141 have the same shape and size. The first recess 2121 and the second recess 2141 are bottom openings for venting liquid of the electronic vaporizer assembly 1. The receiving slot 211 may define the first receiving slot 2111 and the second receiving slot 2112. The second side wall 213 may define the first receiving slot 2111, and the fourth side wall 215 may define a second receiving groove 2112. One end of the first receiving groove 2111 located on the second side wall 213 extends to a portion of the first side wall 212 and is adjacent to the first recess 2121. The other end of the first receiving groove 2111 extends to a portion of the third side wall 214 and is located next to the second notch 2141.

[0013] In a particular embodiment, only the receiving groove 211 is located on the second side wall 213, or only the receiving groove 211 is located on the fourth side wall 215. In some embodiments, the first receiving groove 2111 is located on the second side wall 213, and the second receiving groove 2112 located on the fourth side wall 215. The first receiving groove 2111 and the second receiving groove 2112 may be continuous or discontinuous. In some embodiments, the first receiving slot 2111 and the second receiving slot 2112 are both continuous.

[0014] The ends of the first receiving slot 2111 and the second receiving slot 2112 adjacent the first recess 2121 or the second recess 2141 may be closed ends and may not communicate with the first recess 2121 or the second recess 2141. In other words, the ends of the first receiving slot 2111 and the second receiving slot 2112, adjacent to the first recess 2121 or the second recess 2141, are blocked by the side walls of the first recess 2121 or the second recess 2141. The heights of the two opposite side walls of the first receiving groove 2111 may be the same or different, and the heights of the two opposite side walls of the second receiving groove 2112 may be the same or different. In one embodiment, the side walls of the first receiving slot 2111 and the second receiving slot 2112 proximal to the flash chamber 70 are lower than the side walls of the first receiving slot 2111 and the second receiving slot 2112 away from the flash chamber 70. In other words, the inner side walls the first receiving groove 2111 and the second receiving groove 2112 are lower than the outer side walls, which can facilitate installation of the heating base 30 on the protruding element 311 and allow more space for the evaporation chamber 70. The cross sections of the first receiving groove 2111 and the second receiving groove 2112 are trapezoidal shape, where the upper part is wide and the lower part is narrow, and the edges and corners are mounted on arcuate surfaces, which can facilitate the assembly of the receiving groove 211 and the protruding member 311 and the formation of a good seal. The upper part refers to the upper part of the first receiving groove 2111 or the second receiving groove 2112, and the lower part refers to the lower part of the first receiving groove 2111 or the second receiving groove 2112, the upper part of the first receiving groove 2111 is wider than the lower part of the first receiving groove 2111; the top of the second receiving slot 2112 is wider than the bottom of the second receiving slot 2112. The depths of the first receiving slot 2111 and the second receiving slot 2112, the heights of the two opposing side walls, and the cross-sectional shape can be designed as required in case the structure may interact with the protruding element 311, implementing a seal between the evaporation chamber 70 and the cartridge 10.

[0015] In the first embodiment, as shown in FIG. 4, the heating base 30 may form a second groove 31. The second groove 31 may form a lower portion of the evaporation chamber 70 and be connected to the first groove 21 to form the evaporation chamber 70. The protruding member 311 is located on the side walls of the second groove 31, and the height direction of the protrusion 311 is in the shape of the strip is the same as the direction along the length of the side wall of the second groove 31.

[0016] The side walls of the second slot 31 may include a fifth side wall 312, a sixth side wall 313, a seventh side wall 314, and an eighth side wall 315. The fifth side wall 312 is located opposite the seventh side wall 314, and the sixth side wall 313 is located opposite the eighth side wall wall 315. A third recess 3121 is formed in the fifth side wall 312, and a fourth recess 3141 is formed in the seventh side wall 314. The third recess 3121 and the fourth recess 3141 have the same shape and size. One end of the heating coil 40 is retained in the third recess 3121 of the heating base 30, and the other end of the heating coil is retained in the fourth recess 3141, so that the middle portion of the heating coil 40 is suspended in the evaporation chamber 70. The projection element 311 includes a first projection element 3111 and a second projection element 3112. A first projection 3111 is located on a sixth side wall 313 and a second projection 3112 is located on an eighth side wall 315. One end of a projection 3111 located on a sixth side wall 313 extends to a portion of a fifth side wall 312 and is adjacent to a third notch 3121; the other end of the protruding member extends to a portion of the seventh side wall 314 and is adjacent to the fourth recess 3141. One end of the second protruding member 3112 located on the eighth side wall 315 extends to a portion of the fifth side wall 312 and is adjacent to the third recess 3121; the other end of the second protruding member extends toward a portion of the seventh side wall 314 and is adjacent to the fourth recess 3141 .

[0017] In a particular embodiment, the protruding element 311 may be located only on the sixth side wall 313, or only the protruding element 311 may be located on the eighth side wall 315. In some embodiments, the first protruding element 3111 is located on the sixth side wall 313, and a second projection element 3112 is located on the eighth side wall 315. The first projection element 3111 and the second projection element 3112 may be continuous or discontinuous. In some embodiments, both the first protruding element 3111 and the second protruding element 3112 are continuous.

[0018] The end faces of the first protruding element 3111, located adjacent to the third recess 3121 or the fourth recess 3141, are in the same plane with the side surfaces of the third recess 3121 or the fourth recess 3141 and are inclined towards the first protruding element 3111. The end faces of the second protruding element 3112, located adjacent to the third recess 3121 or the fourth recess 3141 are in the same plane with the side surfaces of the third recess 3121 or the fourth recess 3141 and are inclined towards the second protruding element 3112. The cross sections of the first protruding element 3111 and the second protruding element 3112 are trapezoidal in shape, with the upper the part is narrow and the bottom part is wide, and the edges and corners are mounted on arcuate surfaces, which can facilitate the assembly of the receiving groove 211 and the protruding member 311 and the formation of a good seal. The lower portion refers to a portion of the first protruding member 3111 adjacent to the sixth side wall 313 and a portion of the second protruding member 3112 adjacent to the eighth side wall 315; the top portion refers to a portion of the first protruding member 3111 remote from the sixth side wall 313 and a portion of the second protruding member 3112 remote from the eighth side wall 315; a portion of the first projection member 3111 adjacent to the sixth side wall 313 is wider than a portion of the first projection member 3111 located away from the sixth side wall 313; the portion of the second projection 3112 proximate the eighth side wall 315 is wider than the portion of the second projection 3112 remote from the eighth side wall 315. The height and cross-sectional shape of the first projection 3111 and the second projection 3112 may be designed according to requirements if the seal between the evaporation chamber 70 and the cartridge 10 can be achieved through the interaction between the protruding element 311 and the receiving groove 211.

[0019] In FIG. 5 is a block diagram of the configuration of a heating mantle and a heating base of an electronic evaporator unit in accordance with the present invention.

[0020] After the heating mantle 20 and the heating base 30 are assembled together, the first recess 2121 on the heating mantle 20 corresponds to the third recess 3121 on the heating base 30, the second recess 2141 on the heating mantle 20 corresponds to the fourth recess 3141 on the heating base 30. The structural size of the protruding element 311 formed on the side wall of the second groove 31 corresponds to the structural size of the receiving groove 211 formed on the side wall of the first groove 21 to ensure good sealing.

[0021] In a specific embodiment, the first receiving slot 2111 is continuous. The second receiving slot 2112 is intermittent. In other words, the second receiving slot 2112 contains a plurality of slave receiving slots. The size of the slave receiving slots may be the same or different, and in some embodiments, the size of the slave receiving slots is the same. The depth of the second receiving groove 2112 is greater than the depth of the first receiving groove 2111. In this situation, the first projection element 3111 is continuous and the second projection element 3112 is discontinuous. That is, the second projection element 3112 contains a plurality of subordinate projection elements. The structural dimensions of the plurality of subordinate projecting members 311 may be the same or different. In some embodiments, the structural dimensions of the subordinate projecting elements are the same. The height of the second projection element 3112 is greater than the height of the first projection element 3111. The structure and size of the receiving groove 211 and the projection element 311 are the same, and the number of subordinate receiving slots and the number of subordinate projection elements are the same. If the receiving groove 211 and the projection member 311 are arranged in multiple sections, the depth of the receiving groove 211 can be correspondingly increased, and the height of the projection member 311 can be correspondingly increased to achieve a better sealing effect. In some embodiments, the receiving groove 211 and the protruding member 311 are continuous. Compared with multiple subordinate receiving grooves and multiple subordinate projection members 311, a better sealing effect can be achieved, and leakage of the cartridge 10 into the evaporation chamber 70 can be prevented to the greatest extent.

[0022] In other embodiments, the side wall of the first groove 21 of the heating mantle 20 is provided with a protruding member 311, and the height direction of the protruding member 311 is opposite to the depth direction of the first slot 21. The side wall of the second groove 31 of the heating base 30 defines a receiving slot 211, and the depth direction the receiving groove 211 is the same as the depth direction of the second groove 31. The structural dimensions of the receiving groove 211 and the protruding member 311 are the same.

[0023] In FIG. Figure 6 shows a block diagram of the through hole of the heating casing of the electronic evaporator unit.

[0024] The lower wall of the first groove 21 defines a through hole 216, and the suction tube 50 communicates with the evaporation chamber 70 through the through hole 216 so that the user can inhale the gas evaporated in the evaporation chamber 70 through the suction tube 50. On the side wall of the through hole 216 is located a plurality of projections 2161, wherein the thickness of the projections 2161 and the depth of the through hole 216 may be the same or different, in some embodiments they are the same. When the thickness of the projections 2161 is less than the depth of the through hole 216, one surface of the projections 2161 and one end surface of the bottom wall around the through hole 216 are in the same plane, or the projection 2161 is located at the middle position of the side wall of the through hole 216.

[0025] The plurality of protuberances 2161 are spaced at intervals in the circumferential direction of the side wall of the through hole 216, and the spacing between the plurality of protrusions 2161 may be equal or unequal, in some embodiments it is equal. The protuberances 2161 may be located around the entire circumference of the side wall of the through hole 216 or may be located on a specific section of the side wall of the through hole 216. The cross section of the protrusion 2161 may be square, triangular, arcuate, or other shape, all that is required is to make the side wall of the through hole 216 uneven. The cross-sectional shape and size of the plurality of protuberances 2161 may be the same or different, with only the side wall of the through hole 216 being uneven. A particular section of the side wall of the through hole 216 is provided with a plurality of protuberances 2161, or the cross-sectional shape and size of the plurality of protuberances 2161 are different, so that the through hole 216 forms an asymmetric structure that facilitates the destruction of the liquid film, and in some embodiments is an asymmetric structure.

[0026] By arranging a plurality of protuberances 2161 on the side wall of the through hole 216, the side wall of the through hole 216 is uneven, thereby preventing the formation of a liquid film in the through hole 216 after condensation accumulates during use of the evaporator, preventing the phenomenon of leakage, and improving performance evaporator.

[0027] In FIG. 7 is a block diagram of a through hole of a heating jacket of an electronic evaporator unit according to another embodiment of the present invention.

[0028] In another embodiment, the side wall of the through hole 216 defines a plurality of slots 2162. At opposite ends of the slot 2162 in the depth direction of the through hole 216, one of the slots 2162 may be an open end and the other may be a closed end, or both may be open end or closed end, in some embodiments both ends of the slot 2162 are open.

[0029] A plurality of slots 2162 are spaced at intervals in the circumferential direction of the side wall of the through hole 216, and the spacing between the plurality of slots 2162 may be equal or unequal, in some embodiments it is equal. The groove 2162 may be formed around the entire circumference of the side wall of the through hole 216 or may be formed on a specific section of the side wall of the through hole 216. The cross section of the groove 2162 may be square, triangular, arcuate, or other shape, only requiring the side wall of the through hole to be formed 216 uneven. The cross-sectional shape and size of the plurality of slots 2162 may be the same or different as long as the side wall of the through hole 216 is uneven. A certain section of the side wall of the through hole 216 forms a plurality of grooves 2162, or the shape and cross-sectional size of the plurality of grooves 2162 are different, so that the through hole 216 forms an asymmetric structure that facilitates tearing of the liquid film. In some embodiments, the plurality of slots 2162 form an asymmetrical pattern in the circumferential direction of the side wall of the through hole 216.

[0030] By providing a plurality of grooves 2162 on the side wall of the through hole 216, the side wall of the through hole 216 is uneven, thereby preventing the formation of a liquid film in the through hole 216 after condensation accumulates during use of the evaporator, preventing the phenomenon of leakage, and improving performance evaporator.

[0031] In FIG. 8 is a cross-sectional view of the configuration of the receiving groove on the heating mantle and the protruding elements on the heating base of the electronic evaporator unit.

[0032] Compared with the first embodiment of the second embodiment of the electronic evaporator unit 1, the structure of the electronic evaporator unit 1 is basically the same, but the difference lies in the design of the receiving groove 211 on the heating shell 20 and the design of the protruding element 311 on the heating base 30.

[0033] In the second embodiment, a first groove 21 is formed in the heating casing 20, and the first groove 21 functions as an upper part of the evaporation chamber 70. The side wall of the first groove 21 defines a receiving groove 211, and the groove direction of the receiving groove 211 is the same as the groove execution direction of the first groove 21. That is, the depth direction of the receiving groove 211 is the same as the depth direction of the first groove 211. The depth directions of the grooves 21 are the same. The inner side wall of the receiving groove 211 defines a recess 2113. The receiving groove 211 includes two opposing inner side walls in a direction perpendicular to the direction of passage. Both opposing inner side walls may define recess 2113, or only one of the inner side walls may define recess 2113. In some embodiments, both two opposing inner side walls of the receiving slot 211 define the recess 2113. The depth direction of the recess 2113 is perpendicular to the depth direction of the receiving slot 211.

[0034] The side walls of the first slot 21 may include a first side wall 212, a second side wall 213, a third side wall 214, and a fourth side wall 215. The first side wall 212 is located opposite the third side wall 214, and the second side wall 213 is located opposite the fourth side wall walls 215. A first recess 2121 is formed on the first side wall 212, a second recess 2141 is formed on the third side wall 214, the shape and size of the first recess 2121 and the second recess 2141 being the same. The first recess 2121 and the second recess 2141 are bottom holes for venting liquid of the electronic vaporizer unit 1. A first receiving groove 2111 is formed on the second side wall 213, and a second receiving groove 2112 is formed on the fourth side wall 215. One end of the first receiving groove 2111 is formed on the second side wall 213 extends to a portion of the first side wall 212 and is adjacent to the first recess 2121. The other end of the first receiving groove 2111 extends to a portion of the third side wall 214 and is adjacent to the second recess 2141. One end of the second receiving groove 2112 formed on the fourth side wall 215 extends to a portion of the first side wall 212 and is adjacent to the first recess 2121. The other end of the second receiving groove 2112 extends to a portion of the third side wall 214 and is adjacent to the second recess 2141.

[0035] The first receiving slot 2111 and the second receiving slot 2112, adjacent to the first recess 2121 or the second recess 2141, are closed at the ends and do not communicate with the first recess 2121 or the second recess 2141. The heights of the two opposite side walls of the first receiving slot 2111 and the second receiving groove 2112 may be the same or different.

[0036] In particular, recesses 2113 may be formed on only the first receiving slot 2111, or recesses 2113 may be formed only on the second receiving slot 2112, or recess 2113 may be formed on both the first receiving slot 2111 and the second receiving slot 2112. In some embodiments, recesses 2113 are formed on the first receiving slot 2111 and the second receiving slot 2112. The running direction of the recesses 2113 is the same as the running direction of the first receiving slot 2111 or the second receiving slot 2112, and the depth direction of the recesses 2113 is perpendicular to the depth direction. a first receiving slot 2111 or a second receiving slot 2112. The recesses 2113 may be continuous or discontinuous, in some embodiments the recesses 2113 are continuous. In this case, the first receiving groove 2111 or the second receiving groove 2112 is continuous, the recesses 2113 formed on the first receiving groove 2111 and on the second receiving groove 2112 can be continuous or intermittent. The first receiving groove 2111 or the second receiving groove 2112 is discontinuous, and the recesses 2113 formed on each section of the receiving groove 211 are continuous.

[0037] In some embodiments, a first receiving slot 2111 is formed on the second side wall 213 of the first slot 21, and a second receiving slot 2112 is formed on the fourth side wall 215, wherein the first receiving slot 2111 and the second receiving slot 2112 are continuous. In both of the two opposite inner side walls of each of the first receiving groove 2111 and the second receiving groove 2112, recesses 2113 are formed, the recesses 2113 being continuous.

[0038] The depth of the first receiving groove 2111 and the second receiving groove 2112, the height of the two opposing side walls and the cross-sectional shape are designed according to the requirements, which is only necessary to interact with the protruding member 311 to realize the seal between the evaporation chamber 70 and the cartridge 10.

[0039] In the second embodiment, a second groove 31 is formed in the heating base 30. The second groove 31 functions as the lower part of the evaporation chamber 70 and cooperates with the first groove 21 to form the evaporation chamber 70. The side wall of the second groove 31 is provided with a protruding member 311, and the direction the height of the protruding element 311 is the same as the running direction of the side wall of the second groove 31. The side wall of the protruding element 311 is provided with a protruding part 3113, and the height direction of the protruding part 3113 is perpendicular to the height direction of the protruding element 311. The protruding element 311 includes two surfaces of opposite side walls in the direction , perpendicular to its direction of passage. Two surfaces of the opposing side walls may be formed with a protruding portion 3113, or only one of the side wall surfaces may be formed with a protruding portion 3113.

[0040] The side walls of the second slot 31 may include a fifth side wall 312, a sixth side wall 313, a seventh side wall 314, and an eighth side wall 315. The fifth side wall 312 is located opposite the seventh side wall 314, and the sixth side wall 313 is located opposite the eighth side wall wall 315. A third recess 3121 is formed in the fifth side wall 312, and a fourth recess 3141 is formed in the seventh side wall 314. The third recess 3121 and the fourth recess 3141 have the same shape and size. One end of the heating coil 40 is held in the third recess 3121 of the heating base 30, and the other end of the heating coil is supported in the fourth recess 3141, so that the middle part of the heating coil 40 is suspended in the evaporation chamber 70. The sixth side wall 313 is provided with the first protruding member 3111, and the eighth side wall side wall 315 is provided with a second projection 3112. One end of the first projection 3111 formed on the sixth side wall 313 extends to a portion of the fifth side wall 312 and is adjacent to the third recess 3121. The other end of the first projection 3111 extends to a portion of the seventh side wall 314 and is adjacent to the fourth recess 3141. One end of the second protruding member 3112 formed on the eighth side wall 315 extends to a portion of the fifth side wall 312 and is adjacent to the third recess 3121. The other end extends to and is adjacent to a portion of the seventh side wall 314 with a fourth recess 3141. The first protruding member 3111 and the second protruding member 3112 adjacent the third recess 3121 or the fourth recess 3141 have closed ends and are not connected to the third recess 3121 or the fourth recess 3141.

[0041] In particular, projection 3113 may be formed on only the first projection 3111, or projection 3113 may be formed on only the second projection 3112, or in some embodiments, both the first projection 3111 and the second projection element 3112 is formed by a protruding portion 3113. The extending direction of the protruding portion 3113 is the same as the extending direction of the first protruding member 3111 or the second protruding member 3112, and the height direction of the protruding portion 3113 is perpendicular to the height direction of the first protruding member 3111 or the second protruding member 3112. The protruding portion 3113 may be continuous or discontinuous, and in some embodiments, the protruding portion 3113 is continuous. The first protruding element 3111 or the second protruding element 3112 is continuous, the first protruding element 3111 is provided with protruding parts 3113, and the protruding element 3112 may be continuous or discontinuous. The first projection element 3111 or the second projection element 3112 is discontinuous, and the projection portion 3113 formed on each section of the receiving groove 211 is continuous.

[0042] In a specific embodiment, the sixth side wall 313 of the second slot 31 is provided with a first projection 3111, the eighth side wall 315 is provided with a second projection 3112, wherein the first projection 3111 and the second projection 3112 are solid. Two opposing surfaces of the side walls of the first protruding member 3111 form a protruding portion 3113, wherein the second protruding member 3112 and the protruding portions 3113 are continuous.

[0043] The height and cross-sectional shape of the first projection element 3111 and the second projection element 3112 can be designed as required, and the seal between the vaporization chamber 70 and the cartridge 10 can be achieved by interacting with the receiving groove 211.

[0044] As shown in FIG. 5, after setting the configuration of the heating mantle 20 and the heating base, the first recess 2121 on the heating mantle corresponds to the third recess 3121 on the heating base 30, and the second recess 2141 on the heating mantle 20 corresponds to the fourth recess 3141 on the heating base 30. The protruding portion 3113 formed on the side wall of the protruding element 311, and the recess 2113 formed on the inner side wall of the receiving groove 211 is selected to match the structural dimensions, and the structural dimensions of the protruding element 311 correspond to the structural dimensions of the receiving groove 211 to ensure a good seal.

[0045] In other embodiments, the side wall of the first groove 21 of the heating mantle 20 is provided with a protruding member 311, and the height direction of the protruding member 311 is in the opposite direction to the depth direction of the first slot 21. The side wall of the second slot 31 of the heating base 30 defines a receiving slot 211, and the depth direction of the receiving groove 211 is the same as the depth direction of the second groove 31, and the inner side wall of the receiving groove 211 is provided with a protruding portion 3113. The structural dimensions of the recess 2113 and the protruding portion 3113 are the same, and the structural dimensions of the receiving groove 211 and the protruding member 311 are the same.

[0046] In FIG. Figure 9 shows a block diagram of an electronic evaporation device.

[0047] The electronic vaporizer device 8 includes an electronic vaporizer unit 1 and a power supply unit 2. The power supply unit 2 supplies energy to the electronic evaporator unit 1 so that the electronic evaporator unit 1 operates. The electronic vaporizer unit 1 is any electronic vaporizer unit 1 in the above embodiments.

[0048] In the present invention, the seal between the cartridge and the atomization chamber is realized by forming a receiving groove on the heating mantle and a projection element on the heating base, and by defining a configuration of the receiving groove and the projection element. At the same time, a plurality of protuberances or depressions are formed on the side wall of the through hole connecting the vapor chamber and the cartridge, which avoids the situation where condensation accumulates in the through hole to form a liquid film during use of the electronic vaporizer device, so as to improve the performance of the electronic vaporizer. vaporizer device, and at the same time prevent the user from inhaling the e-liquid during inhalation, thereby affecting the user experience.

[0049] The above are only examples of the present invention, and they are not intended to limit the scope of the present invention. Any equivalent construction or any equivalent transformation of the method, based on the description and accompanying drawings of the present invention, directly or indirectly applied to other related fields of technology, is intended to be included within the scope of the present invention.

Claims (26)

1. Electronic evaporator unit (1), characterized in that it contains: cartridge (10); a heating mantle (20) defining a first groove (21), wherein a side wall of the first groove (21) defines a receiving groove (211); And a heating base (30) defining a second groove (31), with a protruding element (311) located on the side wall of the second groove (31); the first groove (21) and the second groove (31) form an evaporation chamber (70); the protruding element (311) is placed in the receiving groove (211) and cooperates with the receiving groove (211) to realize a seal between the cartridge (10) and the evaporation chamber (70); wherein a through hole (216) is formed in the lower wall of the first groove (21), and a plurality of protuberances (2161) are formed in the side wall of the through hole (216) and a plurality of third grooves (2162) are formed. 2. The electronic evaporator unit (1) according to claim 1, characterized in that the groove direction of the receiving groove (211) is the same as the groove direction of the first groove (21), and the height direction of the protruding element (311) is the same , as the groove making direction of the second groove (31). 3. Electronic evaporator unit (1) according to claim 2, characterized in that the side wall of the first groove (21) comprises a first side wall (212), a second side wall (213), a third side wall (214) and a fourth side wall ( 215); the first side wall (212) is located opposite the third side wall (214), and the second side wall (213) is located opposite the fourth side wall (215); the receiving slot (211) includes a first receiving slot (2111) and a second receiving slot (2112), a second side wall (213) defines a first receiving slot (2111), and a fourth side wall (215) defines a second receiving slot (2112); the side wall of the second groove (31) includes a fifth side wall (312), a sixth side wall (313), a seventh side wall (314) and an eighth side wall (315); a fifth side wall (312) is located opposite the seventh side wall (314), and a sixth side wall (313) is located opposite the eighth side wall (315); the protruding element (311) includes a first protruding element (3111) and a second protruding element (3112), a sixth side wall (313) is provided with a first protruding element (3111), and an eighth side wall (315) is provided with a second protruding element (3112). 4. Electronic evaporator unit (1) according to claim 3, characterized in that a first recess (2121) is formed in the first side wall (212), and a second recess (2141) is formed in the third side wall (214); one end of the first receiving groove (2111) extends to the first side wall (212) and is adjacent to the first recess (2121), and the other end of the first receiving groove (2111) extends to the third side wall (214) and is adjacent to the second recess ( 2141); one end of the second receiving groove (2112) extends to the first side wall (212) and is adjacent to the first recess (2121), and the other end of the second receiving groove (2112) extends to the third side wall (214) and is adjacent to the second recess ( 2141); And a third recess (3121) is formed in the fifth side wall (312), and a fourth recess (3141) is formed in the seventh side wall (314); one end of the first extension (3111) extends to the fifth side wall (312) and is adjacent to the third recess (3121), and the other end of the first extension (3111) extends to the seventh side wall (314) and is adjacent to the fourth recess ( 3141); one end of the second extension (3112) extends to the fifth side wall (312) and is adjacent to the third recess (3121), and the other end of the second extension (3112) extends to the seventh side wall (314) and is adjacent to the fourth recess ( 3141). 5. Electronic evaporator unit (1) according to claim 3, characterized in that both the first receiving groove (2111) and the second receiving groove (2112) are continuous or intermittent; And both the first protruding element (3111) and the second protruding element (3112) are continuous or intermittent. 6. Electronic evaporator unit (1) according to claim 3, characterized in that the first receiving groove (2111) is continuous and the second receiving groove (2112) is discontinuous; the second receiving slot includes a plurality of subordinate receiving slots; the first protruding element is continuous and the second protruding element is discontinuous; the second projection element contains a plurality of subordinate projection elements. 7. Electronic evaporator unit (1) according to claim 3, characterized in that the upper part of the first receiving groove (2111) is wider than the lower part of the first receiving groove (2111); the upper part of the second receiving groove (2112) is wider than the lower part of the second receiving groove (2112); And a portion of the first projection member (3111) adjacent to the sixth side wall (313) is wider than a portion of the first projection member (3111) located away from the sixth side wall (313); a portion of the second projection member (3112) adjacent to the eighth side wall (315) is wider than a portion of the second projection member (3112) located away from the eighth side wall (315). 8. The electronic evaporator unit (1) according to claim 2, characterized in that a recess (2113) is formed in the inner side wall of the receiving groove (211), and the side wall of the protruding element (311) is provided with a protruding part (3113), and the protruding part (3113) is located in cooperation with the recess (2113). 9. Electronic evaporator unit (1) according to claim 8, characterized in that the depth direction of the recess (2113) is perpendicular to the depth direction of the receiving groove (211); And the height direction of the protruding part (3113) is perpendicular to the height direction of the protruding element (311). 10. Electronic evaporator unit (1) according to any one of paragraphs. 1-9, characterized in that the material of the heating casing (20) is plastic, and the material of the heating base (30) is silica gel. 11. Electronic evaporation unit (1) according to claim 1, characterized in that a plurality of protrusions (2161) and a plurality of third grooves (2162) located at intervals are located on the side wall of the through hole (216) in the circumferential direction. 12. The electronic evaporator assembly (1) according to claim 11, characterized in that the cross-section of each of the plurality of protuberances (2161) or each of the plurality of third grooves (2162) is square, triangular or arcuate. 13. Electronic evaporator unit (1) according to any one of paragraphs. 11, 12, characterized in that it additionally contains a suction tube (50), wherein the through hole (216) communicates with the suction tube (50), and the spray chamber (70) communicates with the suction tube (50). 14. Electronic vaporizer device (8), characterized in that the electronic vaporizer device (8) contains an electronic vaporizer unit (1) and a power supply unit (2), while the electronic vaporizer unit (1) is an electronic vaporizer unit (1) according to any of paragraphs. 1–13.