RU2783142C1 - Evaporator and electronic device for evaporation - Google Patents

Abstract

FIELD: electronic technology.

SUBSTANCE: invention relates to the field of electronic evaporation technologies, and in particular to an evaporator and an electronic evaporation device containing an evaporator. An evaporator is disclosed containing: a housing equipped with a liquid storage chamber for liquid storage and a liquid outlet communicating with a liquid storage chamber; an evaporative component mounted on the housing, and the liquid storage chamber is capable of supplying liquid to the evaporative component through a liquid outlet; and the on-off component connected to the housing and having the first position and the second position. When the on-off component is in the first position, the on-off component blocks the liquid outlet; and when the on-off component is in the second position, the on-off component opens the liquid outlet. The housing contains the main part and the insulating part connected to each other, the insulating part and the main part form the first chamber and the second chamber, the evaporative component is partially placed in the first chamber, and the remaining part of the first chamber, except for the space for accommodating the evaporative component, forms a liquid storage chamber; and the on-off component is located in the second camera. In this case, the on-off component engages with the second camera with the ability to move. The second chamber is a cylindrical chamber, and the on-off component contains a cylindrical guide rod.

EFFECT: invention is aimed at ensuring the prevention of leakage from the evaporator.

21 cl, 11 dwg

Description

FIELD OF TECHNOLOGY

[0001] This application relates to the field of electronic vaporization technologies, and in particular to a vaporizer and an electronic vaporizer device containing a vaporizer.

BACKGROUND OF THE INVENTION

[0002] The electronic vaping device can vaporize a liquid such as an aerosol-generating agent, and the smoke generated after evaporating the aerosol-generating agent does not contain harmful ingredients such as tar and suspended particles, so that the electronic vaping device can be used as an alternative to cigarettes. As for the conventional electronic evaporator, the electronic evaporator leaks oil when the suction stops.

SUMMARY OF THE INVENTION

[0003] One technical problem solved in this application is how to prevent leakage from the evaporator.

[0004] The evaporator of the electronic evaporator comprises:

[0005] a housing provided with a liquid storage chamber for storing liquid and a liquid outlet in communication with the liquid storage chamber;

[0006] an evaporative component mounted on the housing, wherein the liquid storage chamber is capable of supplying liquid to the evaporative component through a liquid outlet; and

[0007] an on-off component connected to the housing and having a first position and a second position;

[0008] when the on-off component is in the first position, the on-off component blocks the liquid outlet; and when the on/off member is in the second position, the on/off member opens the fluid outlet.

[0009] The electronic vaping device comprises a battery component, a sensing component, and a vaporizer according to any of the foregoing, with the battery component connected to the vaporizer.

BRIEF DESCRIPTION OF THE DRAWINGS

[001] To better describe and illustrate the embodiments and/or examples of the inventions disclosed herein, reference may be made to one or more of the accompanying drawings. Additional information or examples used to describe the accompanying drawings should not be construed as limiting the scope of any disclosed inventions, herein described embodiments and/or examples, and herein understood the best versions of these inventions.

[002] In FIG. 1 is a schematic representation of the general assembly structure of an electronic evaporator according to an embodiment;

[003] in FIG. 2 is a schematic representation of the general structure of the assembly shown in FIG. 1, in another perspective;

[004] in FIG. 3 is a schematic representation of the general structure of the evaporator assembly shown in FIG. one;

[005] in FIG. 4 is a schematic sectional view of a three-dimensional structure when the on-off component shown in FIG. 3 is in the first position;

[006] in FIG. 5 is a schematic sectional view of a planar structure when the on-off component shown in FIG. 3 is in the first position;

[007] in FIG. 6 is a schematic sectional view of the planar structure when the on-off component shown in FIG. 3 is in the second position;

[008] in FIG. 7 is a schematic view of the three-dimensional structure in section of the housing shown in FIG. 3;

[009] in FIG. 8 is a schematic sectional view of the planar structure of the housing shown in FIG. 3;

[0010] in FIG. 9 is a schematic representation of the overall structure of the assembly after removal of the housing shown in FIG. 3;

[0011] in FIG. 10 is a schematic representation of the exploded structure shown in FIG. 9; and

[0012] in FIG. 11 is a three-dimensional view of the on-off component shown in FIG. 9.

DETAILED DESCRIPTION OF EMBODIMENTS

[0013] To facilitate understanding of the present application, a more complete description of the present application is provided below with reference to the accompanying drawings. Preferred embodiments of the present application are presented in the accompanying drawings. However, the present application may be implemented in many different forms and is not limited to the embodiments described herein. On the contrary, these implementation options are provided for a deeper and more comprehensive understanding of the disclosed content of the present application.

[0014] It should be noted that when one element is referred to as "attached to" another element, the element may be located directly on the other element, or an intermediate element may be present. When one element is referred to as "connected to" another element, the element may be connected directly to the other element, or an intermediate element may be present at the same time. The terms "inner", "outer", "left", "right" and similar expressions used in this document are for illustrative purposes only and do not represent unique implementations.

[0015] As shown in FIG. 1-6 and figs. 9, the electronic vaporizer 10 according to an embodiment of the present application may be configured to vaporize a liquid represented by an aerosol-forming agent. The electronic evaporation device 10 comprises an evaporator 20, a battery component 30, and a sensing component 500. The evaporator 20 and the battery component 30 may be implemented with a detachable connection. The evaporator 20 includes an evaporator mechanism 21 and an on/off component 300. The evaporation mechanism 21 includes a housing 100 and an evaporation component 200. The electronic evaporation device 10 includes a liquid suction chamber 104 and a liquid storage chamber 103. The liquid storage chamber 103 is configured to store liquid. The body 100 is provided with a liquid outlet 106 in communication with the liquid storage chamber 103 . The liquid storage chamber 103 may inject liquid into the liquid suction chamber 104 through the liquid outlet port 106 . The evaporative component 200 is configured to vaporize the liquid in the liquid suction chamber 104 . The on-off component 300 is connected to the housing 100 and has a first position 11 and a second position 12. When the on-off component 300 is in the first position 11, the on-off component 300 blocks the liquid outlet 106, the liquid storage chamber 103, and the chamber 104 to suck liquid are isolated from each other, the liquid storage chamber 103 stops supplying liquid to the liquid suction chamber 104, and the sensing component 500 stops instructing the battery component 30 of the evaporative component 200 to vaporize liquid in the liquid suction chamber 104, so that the user cannot suck from the electronic vaporizer 10 . When the on-off component 300 is in the second position 12, the on-off component 300 opens the liquid outlet port 106, the liquid storage chamber 103 and the liquid suction chamber 104 communicate with each other, the liquid storage chamber 103 can supply liquid to the liquid storage chamber 104 for suction, and the sensing component 500 instructs the battery-shaped component 30 to heat the evaporation component 200 to vaporize the liquid in the liquid suction chamber 104, so that the user can suck from the electronic vaporization device 10.

[0016] Of course, in other embodiments, the liquid suction chamber 104 may not be provided, and the liquid in the liquid storage chamber 103 may be supplied directly to the evaporator component 200 through the liquid outlet 106. That is, the evaporative component 200 sucks liquid directly from the end hole of the liquid outlet port 106 by capillary action and vaporizes the liquid.

[0017] As shown in FIG. 3 and FIG. 4, fig. 7 and FIG. 8, in some embodiments, the housing 100 includes a main body 110, an insulating part 120, and a nozzle part 130. The main body 110 forms a large containment chamber. The main body 110 is approximately cuboid with a hole. The insulating part 120 is connected to the main part 110 and is located in the containing chamber. The insulating part 120 and the main part 110 form the first chamber 101 and the second chamber 102. That is, the insulating part 120 divides the containing chamber into the first chamber 101 and the second chamber 102. The nozzle portion 130 is substantially in the form of a tube. The nozzle portion 130 is connected to the main body 110. A portion of the nozzle portion 130 protrudes a predetermined length from the outer surface of the main portion 110. The portion of the nozzle portion 130 protruding from the outer surface of the main portion 110 forms a nozzle 131 for suction by the user. The other part of the nozzle part 130 is located in the first chamber 101. The part of the nozzle part 130 located in the first chamber 101 can be inserted into the evaporation component 200.

[0018] As shown in FIG. 3 and FIG. 4, fig. 6, fig. 9 and FIG. 10, the evaporative component 200 includes an evaporative core 210, a base 220, a top casing 230, and a sealing sleeve 240. A cavity is provided in the top casing 230. Part of the base 220 is inserted into the cavity, and the other part of the base 220 is located outside the cavity and can cover the opening of the cavity. In this case, another part of the base 220 can also close the opening of the containment chamber enclosed in the main body 110. The evaporative core 210 is located entirely in the cavity of the upper casing 230 and is placed between the upper casing 230 and the base 220. The evaporative core 210 and the upper casing 230 together form chamber 104 for suction of liquid. That is, the evaporation center 210 may form a partial boundary of the liquid suction chamber 104. For example, a first stepped surface 221 is provided in the base 220, a second stepped surface 231 is provided in the upper casing 230 opposite the first stepped surface 221, and the evaporator core 210 is sandwiched between the first stepped surface 221 and the second stepped surface 231. the central portion 210 may be elevated by the limiting influence of the first stepped surface 221 and the second stepped surface 231 on the evaporative central portion 210.

[0019] The top case 230 is housed in the first chamber 101. The remainder of the first chamber 101, except for the space to accommodate the top case 230, forms the liquid storage chamber 103. That is, the upper case 230, the insulating portion 120, and the main portion 110 together form the liquid storage chamber 103. The evaporator 20 further comprises a plug 400. The main body 110 is provided with a liquid injection port 113 at a location close to the nozzle portion 130. The liquid injection port 113 can communicate with the outside environment with the liquid storage chamber 103. When the amount of liquid stored in the liquid storage chamber 103 is lower than the set value, the liquid may be injected into the liquid storage chamber 103 through the liquid injection hole 113 to replenish the oil volumes in the liquid storage chamber 103. The plug 400 is installed on the main body 110. After oil injection is completed, the plug 400 also engages with the liquid injection port 113 to block the liquid injection port 113 to prevent leakage of liquid from the liquid injection port 113, as well as to prevent dust and other contaminants from entering. into the liquid in the liquid storage chamber 103 through the liquid injection hole 113 .

[0020] As shown in FIG. 6, a first air flow path 201 is provided on the top case 230 and the base 220, and a nozzle portion 130 of the housing 100 is provided with a second air flow path 132. For example, the nozzle portion 130 is inserted into the opening of the first air flow path 201 in the upper casing 230 to realize mutual communication between the first air flow path 201 and the second air flow path 132. The main body 110 is provided with an air inlet 111 to communicate with the environment to the second chamber 102. The insulating portion 120 is provided with a vent 123 to communicate the first air flow path 201 with the second chamber 102. The air inlet 111, the second chamber 102, the vent hole 123, the first air flow path 201, and the second air flow path 132 together form a suction passage 105 for air circulation. When the user sucks from the nozzle, the external air flow sequentially passes through the air inlet 111, the second chamber 102, the vent 123, the first air flow passage 201, and the second air flow passage 132 for suction by the user (dashed arrows in Fig. 6 indicate the direction of air flow).

[0021] As shown in FIG. 5, fig. 6 and FIG. 10, the evaporation center 210 may be made of a porous ceramic material, and the evaporation center 210 is connected to the battery component 30 via an electrode. The evaporator core 210 has a evaporator surface 211. The first air flow path 201 passes through the evaporator core 211. Through the capillary effect of the evaporator core 210, the liquid in the liquid suction chamber 104 is sucked into the evaporator surface 211, the battery component 30 heats the evaporator surface 211 through the electrode, and the liquid evaporates on the evaporation surface 211 to form smoke. When the user sucks from the nozzle, the air drawn from the air inlet 111, the second chamber 102 and the vent 123 into the first air flow path 201 carries smoke and is sucked in by the user through the second air flow path 132.

[0022] The sealing sleeve 240 may be a silicone gel sleeve or the like. That is, the sealing sleeve 240 is made of a silicone gel material. The evaporator center portion 210 is sealed with a silicone gel sleeve, and the silicone gel sleeve abuts between the first stepped surface 221 and the second stepped surface 231. The silicone gel sleeve can prevent liquid leakage in the liquid suction chamber 104 from gaps between the evaporation center portion 210 and the upper housing 230 and between the evaporative center 210 and the base 220. With this, the silicon gel sleeve can protect the evaporative center 210 and insulate heat, prevent heat transfer from the evaporator center 210 to the main body 110 of the body 100 to improve the energy efficiency and at the same time prevent inconvenience to the user due to heat transfer of the body 110.

[0023] In some embodiments, the evaporator core 210 defines a boundary surface of the liquid suction chamber 104, which must be recessed towards the evaporator surface 211 to form a buffer chamber 212. The buffer chamber 212 communicates with the liquid suction chamber 104. The buffer chamber 212 may be configured to buffer liquid in the liquid suction chamber 104. Due to the location of the buffer chamber 212, the bottom wall of the buffer chamber 212 is relatively closer to the evaporation surface 211 so that the liquid can be moved to the evaporation surface 211 more quickly to ensure that the evaporation surface 211 contains enough liquid and to prevent dry combustion due to insufficient suction. liquids. The cross-sectional size of the buffer chamber 212 decreases along the direction of the liquid suction chamber 104 pointing to the first air flow passage 201, i.e., from top to bottom, which can play a role in intelligently balancing liquid suction so that the evaporative surface 211 can suck in an appropriate amount of liquid. , and prevent leakage caused by too much liquid and dry burning caused by insufficient liquid on the evaporation surface 211.

[0024] As shown in FIG. 4-8, in some embodiments, the first through hole 121 and the second through hole 122 are spaced apart on the insulating portion 120. The first through hole 121 and the second through hole 122 together form a fluid outlet 106. The first through hole 121 communicates the liquid storage chamber 103 with the second chamber 102. The second through hole 122 communicates the liquid suction chamber 104 with the second chamber 102. The second chamber 102 may be a cylindrical chamber. The on-off component 300 includes a guide rod 310, a sealing member 330, and a handle 320. The guide rod 310 is slidably disposed in the second chamber 102. The outer surface of the guide rod 310 has a radial recess to form a connecting chamber 311. When the guide rod 310 is moved into the first position 11, the outer surface of the guide rod 310 can effectively block the first through hole 121 on the insulating part 120 to block the entire liquid outlet port 106 and prevent the liquid in the liquid storage chamber 103 from leaking out from the first through hole 121. When the liquid cannot flow out from the first through holes 121, the liquid in the liquid storage chamber 103 cannot enter the liquid suction chamber 104. When the guide rod 310 moves upward from the first position 11 to the second position 12, since the connection chamber 311 is formed by a recess on the outer surface of the guide rod 310, the guide rod 310 cannot block the first through hole 121, and the first through hole 121 and the connection chamber 311 communicate together. In this case, the second through hole 122 also communicates with the connection chamber 311. In this case, the liquid in the liquid storage chamber 103 can enter the liquid suction chamber 104 sequentially through the first through hole 121, the cavity of the connection chamber 311 and the second through hole 122 (solid arrows on Fig. 6 indicate the direction of fluid flow).

[0025] The sealing element 330 may be an O-ring or the like. The sealing member 330 is embedded in the guide bar 310 and is able to fit between the guide bar 310 and the inner wall of the second chamber 102 to prevent liquid and air from leaking from the gap between the guide bar 310 and the inner wall of the second chamber 102. The handle 320 is connected to the guide bar 310. The user can apply force to the handle 320 to cause the guide rod 310 to move up and down in the second chamber 102. The handle 320 passes through the air inlet 111. The air inlet 111 provides a bypass space for movement of the handle 320. When the guide bar 310 is in the first position 11, the guide bar 310 can block the air inlet 111 completely. When the user sucks from the nozzle, outside air cannot enter through the air inlet 111, so that the suction passage 105 cannot suck in air from the outside. In another embodiment, the on-off component 300 may be provided in other forms, and the on-off component 300 is rotatably located in the second chamber 102. The handle 320 may also be omitted. The guide rod 310 is pushed by the automatic control mechanism to move in the second chamber 102.

[0026] The main body 110 is further provided with an air outlet 112. The air outlet 112 corresponds to the end portion of the second chamber 102. The air outlet 112 and the second chamber 102 communicate with each other. During the upward movement of the guide rod 310 from the first position 11 to the second position 12, the volume of the upper part of the second chamber 102 is reduced, and the air in the upper space of the second chamber 102 can be expelled from the air outlet 112 to prevent air pressure interference. , to move the guide bar 310 and allow the guide bar 310 to be pushed smoothly.

[0027] When the guide rod 310 is in the first position 11, the guide rod 310 prevents the sensing component 500 from detecting a negative pressure in the suction passage 105 to command the stack component 30 of the evaporative center 210 to stop heating, thereby preventing the liquid from evaporating. When the guide pin 310 is in the second position 12, the guide pin 310 enables the sensing component 500 to detect a negative pressure in the suction passage 105 to command the stack component 30 of the evaporation center 210 to heat, thereby starting the evaporation of the liquid.

[0028] As shown in FIG. 5, fig. 6, fig. 9 and FIG. 10, in some embodiments, the sensing component 500 includes an airflow sensor 510. The air flow sensor 510 may be located directly on the battery component 30 or located directly on the evaporative component 200. The evaporative component 200 is provided with a sensing passage 513. The sensing passage 513 may be in communication with the suction passage 105. Negative pressure generated by suction in the suction passage 105 can be detected by the sensing component 500 via the sensing port 513. When the guide rod 310 is in the first position 11, the guiding rod 310 closes the sensing port 513 to prevent the sensing port 513 from communicating with the suction port 105. When the guide rod 310 is in the second position 12, the guide rod 310 no longer covers the sensing passage 513 to allow the sensing passage 513 to communicate with the suction passage 105. For example, the guide rod 310 is provided with a connector 312. The connector 312 may represent is a cylindrical hole. The base 200 of the evaporative component 200 is provided with an insertion part 511. A sensing channel 513 is provided on the insertion part 511. The insertion part 511 conforms to the shape of the connector 312, so that the insertion part 511 can be inserted into the connector 312. On the surface of the upper end of the insertion part 511, a connection port 513a is formed. , communicating with the sensitive channel 513 and the suction channel 105.

[0029] When the guide rod 310 is in the first position 11, the insertion portion 511 is inserted into the connector 312, and the bottom wall of the connector 312 blocks the connection port 513a to block communication between the sensing passage 513 and the suction passage 105. When the user sucks from the nozzle, even if a negative pressure is present in the suction passage 105, the air flow sensor 510 cannot detect the negative pressure through the sensing passage 513, whereby the air flow sensor 510 cannot command the coil component 30 of the evaporative core 210 to vaporize the liquid, and the electronic the evaporator 10 cannot be turned on. As a result, the user cannot perform suction. It should be noted that since the guide rod 310 can completely block the air inlet 111 at the first position 11, the external airflow cannot enter the suction port 105, which can also prevent the user from performing suction. When the guide rod 310 is in the second position 12, the insertion part 511 can be completely separated from the connector 312, the guide rod 310 unlocks the connection port 513a and the air inlet 111, and the sensing passage 513 communicates with the suction passage 105. When the user sucks from the nozzle 131, the air flow sensor 510 detects the negative pressure in the suction passage 105 through the sensing passage 513 to command the coil component 30 of the evaporative core 210 to be heated to vaporize the liquid. The smoke resulting from the vaporization of the liquid along with the air flow in the suction passage 105 may be sucked by the user, and the vaporization electronic device 10 may be turned on to realize the suction function.

[0030] In this way, the air flow sensor 510 detects the negative pressure in the suction passage 105 to command the turn on of the electronic evaporator 10, which enables rapid suction from the electronic evaporator 10 and improves the turn on sensitivity of the electronic evaporator 10.

[0031] As shown in FIG. 9-11, the guide rod 310 may be further provided with a guide slot 313. The guide slot 313 extends for a predetermined length along the axial direction of the guide rod 310. The guide slot 313 may communicate with the connector 312 and the suction port 105. The insertion portion 511 is provided with a guide 512. The guide 512 is essentially rectangular in shape. The guide 512 engages with the guide slot 313. As the guide bar 310 moves down from the second position 12 to the first position 11, the insertion portion 511 can smoothly engage with the connector 312 according to the direction of the guide 512. Here, when the guide bar 310 comes out of first position 11, the bottom wall of the connector 312 brings out the connection port 513a from the closed position, so that the air flow sensor 510 can quickly and accurately detect the negative pressure in the suction passage 105 through the sensing passage 513 and the guide groove 313, which further improves the sensitivity of the electronic device 10 for evaporation to the reaction to suction and allows the electronic device 10 to be quickly turned on for evaporation.

[0032] In some embodiments, the battery component 30 is provided with an interface 31 for charging. The charging interface 31 is located on the end portion of the battery component 30 remote from the evaporator 20, that is, the bottom of the battery component 30. The location of the charging interface 31 allows the battery component 30 to be charged at any time.

[0033] When the electronic evaporator 10 is to be turned on for suction, the handle 320 is first pressed to cause the guide rod 310 to move to the second position 12. In this case, the liquid in the liquid storage chamber 103 enters the liquid suction chamber 104 sequentially through the first the through hole 121, the connecting chamber 311, and the second through hole 122. Moreover, the insertion part 511 is separated from the connector 312 in the guide rod 310, and the sensing passage 513 communicates with the suction passage 105. channel 105 creates a negative pressure. The air flow sensor 510 detects the negative pressure through the sensing channel 513 and instructs the coil component 30 of the evaporative core 210 to be heated to vaporize the suction liquid.

[0034] When the electronic evaporator 10 is stopped, the handle 320 can be pressed to move the guide rod 310 to the first position 11. In this case, the guide rod 310 blocks the first through hole 121, and the liquid in the liquid storage chamber 103 cannot flow out from the first through hole 121, so that the liquid in the liquid storage chamber 103 cannot enter the liquid suction chamber 104. Here, the insertion part 511 is inserted into the slot 312 in the guide rod 310, and the guide rod 310 blocks the connection port 513a on the insertion part 511 to prevent the sensing passage 513 from communicating with the suction passage 105. When the user sucks from the nozzle 131, even if the negative pressure is present in the suction passage 105, the airflow sensor 510 cannot detect negative pressure through the sensing passage 513 to command the coil component 30 of the evaporative core 210 to be heated, so that liquid cannot be vaporized for suction. Of course, the guide rod 310 can also completely block the air inlet 111, further preventing the user from being sucked.

[0035] Therefore, when the electronic evaporator 10 is in a standby state in which the user does not perform suction, the guide rod 310 can be located at the first position 11, whereby the liquid storage chamber 103 and the liquid suction chamber 104 are isolated from each other. , and the liquid suction chamber 104 may be empty of a large amount of liquid to effectively prevent liquid leakage in the liquid suction chamber 104 from the evaporator center portion 210. In this case, the air flow sensor 510 detects a negative pressure in the suction passage 105 to command a quick turn on of the electronic evaporator 10, which improves the turn-on sensitivity of the electronic evaporator 10.

[0036] The technical features in the above embodiments may be combined in any order. For brevity of description, not all possible combinations of technical features are described in the above embodiments. However, all combinations of technical features should be considered as included in the scope presented in this description, provided that they do not contradict each other.

[0037] The above embodiments describe only a few embodiments of the present application, and their description is specific and detailed, but it therefore cannot be understood as limiting the scope of the patent for the invention. It should be noted that further changes and improvements may be made by those skilled in the art without departing from the concept of the present application, and all of them fall within the protection scope of the present application. Therefore, the scope of patent protection of the present application shall be determined by the appended claims.

Claims (29)

1. An evaporator of an electronic evaporator device, comprising: a body provided with a liquid storage chamber for storing liquid and a liquid outlet port in communication with the liquid storage chamber; an evaporative component mounted on the housing, wherein the liquid storage chamber is capable of supplying liquid to the evaporative component through a liquid outlet; and an on-off component connected to the body and having a first position and a second position; when the on-off component is in the first position, the on-off component blocks the liquid outlet; and when the on-off component is in the second position, the on-off component opens the liquid outlet; characterized in that the housing comprises a main part and an insulating part connected to each other, the insulating part and the main part form the first chamber and the second chamber, the evaporative component is partially located in the first chamber, and the remaining part of the first chamber, except for the space for accommodating the evaporative component , forms a liquid storage chamber; and the on-off component is located in the second chamber; wherein the on-off component is movably engaged with the second chamber; wherein the second chamber is a cylindrical chamber and the on-off component comprises a cylindrical guide rod. 2. The evaporator according to claim. 1, characterized in that the outlet channel for the liquid contains the first through hole and the second through hole spaced from each other on the insulating part, the first through hole provides communication of the liquid storage chamber with the second chamber, and the second through hole communicates with a second chamber and configured to supply liquid to the evaporation component; the connection chamber is formed by a recess on the surface of the on-off component; when the on-off component is in the first position, the on-off component blocks the first through hole, whereby the first through hole and the second through hole are isolated from each other; and when the on-off component is in the second position, the first through hole, the connecting chamber and the second through hole communicate with each other. 3. The evaporator according to claim 1, characterized in that the on-off component further comprises a sealing element, wherein the sealing element is integrated into the guide rod and is able to fit between the guide rod and the inner wall of the second chamber. 4. The evaporator according to claim. 3, characterized in that the sealing element is a sealing ring. 5. The evaporator according to claim 1, characterized in that the on-off component further comprises a handle, the handle is connected to the guide rod and is designed in such a way as to cause the guide rod to move, the main part is provided with an air inlet that provides communication of the second chamber with the external medium and the handle passes through the air inlet. 6. An evaporator according to claim 5, characterized in that when the on-off component is in the first position, the guide rod blocks the air inlet. 7. The evaporator according to claim. 1, characterized in that the main part is provided with an air outlet that provides communication of the second chamber with the external environment, and during the movement of the on-off component from the first position to the second position, the air in the second chamber is removed from the outlet for air. 8. An evaporator according to claim 1, characterized in that the evaporator component is provided with a liquid suction chamber in communication with the liquid outlet, and the evaporator component is capable of vaporizing liquid in the liquid suction chamber. 9. The evaporator according to claim 8, characterized in that the evaporative component comprises an evaporative center part and is provided with a first air flow channel, the evaporative center part forms a partial boundary of the liquid suction chamber and has an evaporative surface capable of evaporating liquid, the first air flow channel passes through the evaporation surface, and the evaporation center forms a boundary surface of the liquid suction chamber, which must be recessed towards the evaporation surface to form a buffer chamber in communication with the liquid suction chamber. 10. The evaporator according to claim 9, characterized in that the size of the cross section of the buffer chamber decreases along the direction of the liquid suction chamber, pointing to the first air flow channel. 11. The evaporator according to claim 8, characterized in that the evaporative component further comprises a base and an upper casing connected to each other, the evaporative central part and the upper casing form a liquid suction chamber, the first stepped surface is provided in the base, the second is provided in the upper casing a stepped surface opposite the first stepped surface, and the evaporative core is sandwiched between the first stepped surface and the second stepped surface. 12. An evaporator according to claim 11, characterized in that the evaporative component further comprises a silicone gel sleeve, the evaporation center is sealed with a silicone gel sleeve, and the silicone gel sleeve abuts between the first stepped surface and the second stepped surface. 13. The evaporator according to claim. 1, characterized in that the housing contains a nozzle part, the evaporator component is provided with a first air flow channel, the nozzle part is partially located in the liquid storage chamber and is provided with a second air flow channel communicating with the external environment, and the nozzle part inserted into the evaporative component and provides communication of the second air flow channel with the first air flow channel. 14. The evaporator according to claim. 1, characterized in that it further comprises a plug mounted on the housing, and the housing is additionally provided with a liquid injection hole that provides communication between the liquid storage chamber and the external environment, and the plug is able to hermetically close the liquid injection hole. 15. The evaporator according to claim. 1, characterized in that the electronic device for evaporation contains a sensitive component, each of the housing and the evaporative component is provided with a suction channel in communication with the external environment, the evaporator component is provided with a sensitive channel capable of communicating with the suction channel, and a negative pressure in the suction channel is detected by the sensing component through the sensing channel; and when the on-off component is in the first position, the on-off component closes the sensing port to isolate the suction port from the sensing port, and the sensing component stops detecting negative pressure in the suction port; and when the on-off component is in the second position, the sensing port is in communication with the suction port, and the sensing component is capable of detecting a negative pressure in the suction port. 16. The evaporator according to claim 15, characterized in that the on-off component is provided with a connector, the evaporator component is provided with an insertion part, and the connecting port of the sensing channel and the suction channel is located on the insertion part; when the on-off component is in the first position, the insertion part enters the connector, and the bottom wall of the connector blocks the connection port; and when the on-off component is in the second position, the bottom wall of the connector no longer blocks the connection port. 17. The evaporator according to claim 16, characterized in that the on-off component is additionally provided with a guide groove for communicating the connector with the suction channel, and the inserted part is further provided with a guide capable of engaging with the guide groove. 18. The evaporator according to claim 15, characterized in that the sensing component is located at the location of the evaporative component next to the sensing channel. 19. An electronic device for evaporation, containing a component in the form of a battery, a sensitive component and a vaporizer according to any one of paragraphs. 1-17 with the battery component connected to the evaporator. 20. An electronic evaporative device according to claim 19, characterized in that the sensing component comprises an air flow sensor, the air flow sensor being located on the battery or evaporator component. 21. An electronic evaporator device according to claim 19, characterized in that the end portion of the battery-like component remote from the evaporator is provided with a charging interface.

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