CN215958332U - Electronic atomization device and atomizer and electrode connecting device thereof - Google Patents
Electronic atomization device and atomizer and electrode connecting device thereof Download PDFInfo
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- CN215958332U CN215958332U CN202121668787.0U CN202121668787U CN215958332U CN 215958332 U CN215958332 U CN 215958332U CN 202121668787 U CN202121668787 U CN 202121668787U CN 215958332 U CN215958332 U CN 215958332U
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Abstract
The utility model discloses an electronic atomization device, an atomizer thereof and an electrode connecting device, wherein the electrode connecting device is used for bearing an atomization component in the electronic atomization device and electrically connecting the atomization component with a power supply device, and comprises a first conductive piece, a second conductive piece which can be arranged close to or far away from the first conductive piece and an elastic piece which is arranged between the first conductive piece and the second conductive piece, and the elastic piece provides elastic tension between the first conductive piece and the second conductive piece. According to the utility model, the atomization assembly is borne by the elastically telescopic electrode connecting device, and the atomization assembly is electrically connected with the power supply device, so that the structural complexity of the atomizer is obviously reduced, the assembly difficulty is reduced, the assembly efficiency is improved, and the automatic assembly of an assembly production line is facilitated.
Description
Technical Field
The utility model relates to the field of atomization, in particular to an electronic atomization device, an atomizer of the electronic atomization device and an electrode connecting device of the electronic atomization device.
Background
Electronic atomisation devices for inhalation aerosols of the related art typically employ a porous ceramic atomising core for the heated atomisation of a liquid aerosol-generating substrate, the leads of such a porous ceramic atomising core typically having to pass through the porous ceramic, causing the internal structure of the porous ceramic to change and cracking to occur. In addition, when the lead electrodes are electrified and wired, the circuit wiring is long, and the manufacturing difficulty and the production cost of the electronic atomization device are increased.
SUMMERY OF THE UTILITY MODEL
Aiming at the defects in the prior art, the utility model provides an improved electronic atomization device, an atomizer and an electrode connecting device thereof.
In order to achieve the above object, the present invention provides an electrode connecting device for carrying an atomizing assembly in an electronic atomizing device and electrically connecting the atomizing assembly with a power supply device, the electrode connecting device comprising a first conductive member, a second conductive member disposed close to and away from the first conductive member, and an elastic member disposed between the first conductive member and the second conductive member, the elastic member providing an elastic tension between the first conductive member and the second conductive member, the second conductive member including a gas inlet channel through which gas flows.
In some embodiments, the first and second electrically-conductive members are axially movably nested together back and forth and are electrically connected by contact with each other.
In some embodiments, the first conductive member and the second conductive member are electrically connected via the elastic member.
In some embodiments, the first conductive member is cup-shaped and includes a bottom wall and a cylindrical sidewall standing on the periphery of the bottom wall, and one end of the elastic member is disposed in the cylindrical sidewall and supported on the bottom wall; the opening end of the side wall is turned inwards to form a neck.
In some embodiments, the first and/or second electrically conductive members include gas inlet channels through which gas flows.
In some embodiments, the second conductive member includes a cylindrical sidewall and a partition wall disposed in the sidewall near the lower opening; the partition wall divides the central through hole of the second conductive piece into an upper hole part, the upper hole part is communicated with the upper end opening of the side wall, the side wall is provided with an air inlet which is used for communicating the upper hole part with the outer side, and the air inlet, the upper hole part and the upper end opening form the air inlet channel together.
In some embodiments, the partition wall further divides the central through hole into a lower hole portion independent from the upper hole portion, the lower hole portion communicates with the lower end opening, and the other end of the elastic member is embedded in the lower hole portion and abuts against the partition wall.
In some embodiments, a flange extends radially from a lower end edge of the outer surface of the side wall, the flange extends into the first conductive member, and the first conductive member includes a neck portion for preventing the flange from falling off.
The atomizer comprises an atomization main body, wherein the atomization main body comprises a conductive base, a conductive main pipeline and an atomization assembly, the conductive main pipeline is arranged on the base, and the atomization assembly is arranged between the base and the main pipeline; the atomizing main part still including install in with electric insulation electrode connecting device in the base, atomizing subassembly elastic connection in electrode connecting device with between the trunk line, and respectively with electrode connecting device with trunk line electric connection.
In some embodiments, the electrode connecting device comprises a gas inlet channel for gas to flow through, the gas inlet channel being in communication with the atomizing assembly.
In some embodiments, the electrode connecting device is elastically supported below the atomizing assembly and electrically connected to the atomizing assembly.
In some embodiments, the atomizing assembly is cylindrical, and the electrode connecting device comprises an upper end portion supported at the lower end of the atomizing assembly, and the outer diameter of the upper end portion is equivalent to that of the atomizing assembly.
In some embodiments, the electrode connecting device includes a first conductive member installed in the base, a second conductive member that is disposed close to and away from the first conductive member, and an elastic member disposed between the first conductive member and the second conductive member, the elastic member providing an elastic tension between the first conductive member and the second conductive member, the first conductive member and the second conductive member being electrically connected; the second conductive member is carried below the atomization assembly.
In some embodiments, the first conductive member and the second conductive member are axially movably nested together and electrically connected to each other.
In some embodiments, the first conductive member and the second conductive member are electrically connected via the elastic member.
In some embodiments, the first conductive member is cup-shaped and includes a bottom wall and a cylindrical sidewall standing on the periphery of the bottom wall, and one end of the elastic member is disposed in the cylindrical sidewall and supported on the bottom wall; the opening side of the side wall is turned inwards to form a neck.
In some embodiments, the second conductive member includes a cylindrical sidewall and a partition wall disposed in the sidewall near the lower opening; the partition wall divides the central through hole of the second conductive piece into an upper hole part, the upper hole part is communicated with the upper end opening of the side wall, the side wall is provided with an air inlet which is used for communicating the upper hole part with the outer side, and the air inlet, the upper hole part and the upper end opening form an air inlet channel together.
In some embodiments, the partition wall further divides the central through hole into a lower hole portion independent from the upper hole portion, the lower hole portion communicates with the lower end opening, and the other end of the elastic member is embedded in the lower hole portion and abuts against the partition wall.
In some embodiments, a flange extends radially from a lower end edge of the outer surface of the sidewall, the flange extending into the first conductive member, and the first conductive member includes a neck portion that prevents the flange from being separated from the first conductive member.
In some embodiments, the main pipe includes a first pipe section combined on the base and a second pipe section axially detachably connected to an upper end of the first pipe section and electrically connected to the first pipe section, and the atomizing assembly is elastically connected between the electrode connecting device and the second pipe section and electrically connected to the second pipe section.
In some embodiments, the first pipe section comprises a middle pipe section, a side wall of the middle pipe section defines a containing cavity for containing the atomization assembly, and at least one liquid inlet hole for communicating the containing cavity with the outside is further formed in the side wall of the middle pipe section.
In some embodiments, the atomising body further comprises an insulating support disposed on top of the base and closely surrounding the electrode connection means; the insulating support is positioned at the lower side of the at least one liquid inlet hole.
In some embodiments, the first pipe section comprises a lower pipe section sleeved at the upper end of the base, and a step pressed against the insulating support is formed between the lower pipe section and the middle pipe section.
In some embodiments, the first pipe section comprises an upper pipe section connected to the upper end of the middle pipe section, and the outer side wall surface of the upper pipe section is formed with an external thread structure for screwing the second pipe section.
In some embodiments, the second pipe section comprises a cover body part, the cover body part comprises a top wall, and the middle part of the top wall is provided with a vent hole which penetrates up and down; the lower surface of the top wall is also provided with a contact ring, the contact ring surrounds the vent hole and extends into the first pipe section to be electrically connected with the upper end of the atomization assembly in an abutting mode.
In some embodiments, the second duct section includes an air guide coupled to the top surface of the top wall and communicating with the vent hole, the air guide including a non-circular air guide hole.
In some embodiments, the cover body portion includes a cylindrical side wall, an inner wall surface of which is formed with an internal thread structure that matches the external thread structure of the first pipe section, and an outer wall surface of which may be formed with an anti-slip thread structure.
In some embodiments, the atomizing assembly includes a cylindrical atomizing core disposed longitudinally, the atomizing core includes a cylindrical porous body, a heating element disposed on an inner wall surface of the porous body, a first electrode portion disposed on an upper end surface of the porous body and electrically connected to an upper end of the heating element, and a second electrode portion disposed on a lower end surface of the porous body and electrically connected to a lower end of the heating element, the first electrode portion is in electrical contact with the main pipe, and the second electrode portion is in electrical contact with the electrode connecting device.
In some embodiments, the atomizing assembly includes a longitudinally disposed cylindrical atomizing core, and the electrode connecting means includes a cylindrical second conductive member supported at a lower end of the atomizing core, the second conductive member including a cylindrical upper end having an inner diameter and an outer diameter respectively corresponding to the inner diameter and the outer diameter of the lower end of the atomizing core.
An electronic atomizer is also provided, comprising the atomizer and the power supply device.
The utility model has the beneficial effects that: but adopt the flexible electrode connecting device to bear atomizing component to with atomizing component and power supply unit electric connection, showing reduction the structure complexity of atomizer, reduced the equipment degree of difficulty, promoted the packaging efficiency, and do benefit to the automatic equipment realization of assembly line.
Drawings
Fig. 1 is a schematic perspective view of an electronic atomization device according to some embodiments of the present disclosure.
Fig. 2 is a schematic perspective exploded view of the electronic atomizer shown in fig. 1.
Fig. 3 is a schematic longitudinal sectional view of an atomizer of the electronic atomization device shown in fig. 2.
Fig. 4 is a schematic perspective exploded view of the atomizer shown in fig. 2.
Fig. 5 is a schematic longitudinal sectional view of the atomizer shown in fig. 2 in an exploded state.
Fig. 6 is a schematic perspective exploded view of the atomizing body shown in fig. 4.
Fig. 7 is a schematic longitudinal sectional view of the atomizing body shown in fig. 4 in an exploded state.
Fig. 8 is a schematic perspective exploded view of the atomizing core shown in fig. 6.
FIG. 9 is a schematic partial perspective view of an atomizing body in accordance with further embodiments of the present invention;
fig. 10 is a schematic longitudinal sectional view of the atomizing body shown in fig. 9.
Fig. 11 is a schematic longitudinal sectional view of the atomizing body shown in fig. 9 in an exploded state.
Fig. 12 is a schematic perspective view of an atomizing body according to still other embodiments of the present invention.
Figure 13 is a schematic longitudinal cross-sectional view of the atomizing body of figure 12.
Fig. 14 is a schematic perspective exploded view of the atomizing body shown in fig. 12.
Fig. 15 is a schematic longitudinal sectional view of the atomizing body shown in fig. 12 in an exploded state.
Fig. 16 is a perspective exploded view of the electrode connecting device shown in fig. 14.
Fig. 17 is a schematic longitudinal sectional view of the electrode connecting device shown in fig. 14 in an exploded state.
Fig. 18 is a schematic perspective exploded view of the atomizing assembly of fig. 14.
Detailed Description
In order to more clearly describe the present invention, the present invention will be further described with reference to the accompanying drawings.
Fig. 1 and 2 show an electronic atomizer according to some embodiments of the present invention, which can be used for a user to inhale an aerosol in a way of holding the mouth with a hand, and which can be in a cylindrical shape and includes a cylindrical atomizer 1 and a cylindrical power supply device 2 cooperating with the atomizer 1. The nebulizer 1 may be used for storing and heat nebulizing a liquid aerosol-generating substrate, such as a liquid medicament, and for conducting the aerosol out. The power supply means 2 may be used to power the atomiser 1. It is to be understood that the electronic atomizer is not limited to the shape of a column, and may have other shapes such as a square box shape and an irregular shape.
In some embodiments, the atomizer 1 and the power supply device 2 may each have a cylindrical shape, and both are mechanically and electrically connected together in the axial direction. In some embodiments, the atomizer 1 and the power supply device 2 are detachably connected together by means of a screw connection. It will be appreciated that the atomiser 1 and the power supply means 2 are not limited to being threadably connected but may be removably connected together by magnetic attraction. It will be understood that the atomizer 1 and the power supply device 2 are not limited to the cylindrical shape, but may be cylindrical shapes having an oval, racetrack, or irregular shape in cross section. The power supply device 2 may comprise a disposable battery or a rechargeable battery in some embodiments.
As shown in fig. 3 to 5, the atomizer 1 may in some embodiments comprise a lower cylindrical atomizing body 10 for storing and heating an atomized liquid aerosol-generating substrate, and a nozzle assembly 20 axially connected to an upper end of the atomizing body 10 for plugging and guiding the liquid aerosol-generating substrate in the atomizing body 10. In some embodiments, the nozzle assembly 20 is inserted into the upper end of the atomising body 10 with a tight fit to facilitate the injection of the liquid aerosol-generating substrate into the atomising body 10. The nozzle assembly 20 may be removably connected to the upper end of the atomising body 10, in which case the liquid aerosol-generating substrate may be added repeatedly, increasing the lifetime of the atomiser 1. For some single-use atomizers 1, the nozzle assembly 20 and the atomizing body 10 may also be non-detachable, i.e., they are locked once connected and cannot be separated without destroying the existing structure.
Referring to fig. 6 and 7 together, the atomizing body 10 may include a base 11, a main pipe 12, a housing 13, an atomizing assembly 14, an electrode connecting device 15, an insulating seal ring 16, a first electrode jaw 17, and a second electrode jaw 18, which are coaxially assembled together in some embodiments.
The base 11 may be cylindrical in some embodiments and may be electrically conductive. The main pipe 12, which may also be electrically conductive in some embodiments, is embedded in the upper portion of the base 11 along the longitudinal direction and is electrically connected with the base 11; the main conduit 12 defines a cylindrical receiving chamber 120 for receiving the atomizing assembly 14. The housing 13 may be cylindrical in some embodiments, and is sleeved on the upper portion of the base 11 along the longitudinal direction and surrounds the main pipe 12; an annular reservoir 130 is defined between the inner wall surface of the housing 13 and the outer wall surface of the main conduit 12. The main pipe 12 may further have a liquid inlet hole 122 formed therein for communicating the liquid storage chamber 130 with the receiving chamber 120. The atomizing assembly 14 may be cylindrical in some embodiments and is disposed in the receiving cavity 120 along the longitudinal direction; the atomizing assembly 14 may define a longitudinally extending air flow passage 140 at a central portion thereof. The electrode connecting device 15 is longitudinally arranged at the lower part of the base 11 in a penetrating way and is electrically insulated from the base 11; specifically, an insulating sealing ring 16 is longitudinally arranged at the lower part of the base 11, and the electrode connecting device 15 is further arranged in the insulating sealing ring 16 in a penetrating way, so that the insulating sealing connection with the base 11 is realized. One end of the first electrode claw 17 is fixed on the inner wall of the main pipe 12 and electrically connected to the main pipe 12, and the other end of the first electrode claw is in elastic contact with the upper end of the atomizing assembly 14, so as to electrically connect the upper end of the atomizing assembly 14 to the main pipe 12. One end of the second electrode claw 18 is fixed on the electrode connecting device 15 and electrically connected with the electrode connecting device 15, and the other end is in elastic contact with the lower end of the atomizing assembly 14 to electrically connect the lower end of the atomizing assembly 14 with the electrode connecting device 15.
In some embodiments, the electrode connecting device 15 is used to electrically connect with the positive electrode of the power supply device 2, and the base 11 is used to electrically connect with the negative electrode of the power supply device 2, thereby forming an electrical circuit. Let the electric current can come out via power supply unit 2's positive pole after, pass through electrode connecting device 15 and second electrode claw 18 in proper order, reach atomization component 14 lower extreme, run through atomization component 14 and let atomization component 14 generate heat the back, reach atomization component 14 upper end, flow back to power supply unit 2's negative pole after first electrode claw 17, trunk line 12 and base 11 in proper order again. It is understood that in some embodiments, the electrode connecting device 15 and the base 11 can be electrically connected to the negative electrode and the positive electrode of the power supply device 2, respectively, and the current direction is opposite to the above direction.
As shown in fig. 6 and 7, the base 11 may be integrally formed by a metal material in some embodiments, and may include a circular base 111, a first mounting tube 112 longitudinally disposed on the upper surface of the base 111, and a second mounting tube 113 longitudinally disposed on the bottom surface of the base 111, wherein a through hole 1110 longitudinally penetrating is disposed in the middle of the base 111, and the through hole 1110 communicates the first mounting tube 112 and the second mounting tube 113. The outer wall surface of the second mounting tube 113 is formed with a screw structure 1131 for screwing the upper end of the power supply device 2, and the inner wall surface is formed with a mounting ring 1132 fitted to the insulating seal ring 16.
The housing 13 may be made of a transparent material in some embodiments, and has an inner diameter matched with the outer diameter of the first mounting cylinder 112, so that the housing 13 can be sleeved on the first mounting cylinder 112 at the lower end in the axial direction and tightly fit with the first mounting cylinder 112. The upper surface of the housing 13 may be slightly lower than the upper surface of the second tube segment 123 to better mate with the nozzle assembly 20. The inner wall surface of the housing 13 and the inner wall surfaces of the first tube segment 121 and the second tube segment 123 define the liquid storage chamber 130 therebetween, and an annular liquid injection port 132 is formed between the upper end of the housing 13 and the upper end of the second tube segment 123.
The atomizing assembly 14 may include a cylindrical atomizing core 141 disposed longitudinally, a first sealing ring 142 sleeved on an upper end of the atomizing core 141, and a second sealing ring 143 sleeved on a lower end of the atomizing core 141.
The first sealing ring 142 may have an L-shaped cross-section for sealing a gap between the upper end of the atomizing core 141 and the upper end of the first pipe segment 121. In some embodiments, the first sealing ring 142 may include a cylindrical first sealing part 1421 and a circular second sealing part 1423 connected to an upper end edge of the first sealing part 1421, the first sealing part 1421 is sleeved on an outer wall surface of an upper end of the atomizing core 141, and the second sealing part 1423 covers an upper end surface of the atomizing core 141. The inner diameter of the second sealing part 1423 is preferably larger than the bore diameter of the atomizing core 141 so that the first electrode claw 17 is not blocked by the second sealing part 1423 when it is engaged with the atomizing core 141.
The second sealing ring 143 may also have an L-shaped cross-section for sealing a gap between the lower end of the atomizing core 141 and the third pipe segment 125. In some embodiments, the second sealing ring 143 may include a cylindrical third sealing portion 1431 and a circular fourth sealing portion 1433 connected to a lower end edge of the third sealing portion 1431, the third sealing portion 1431 is sleeved on an outer wall surface of the lower end of the atomizing core 141, and the fourth sealing portion 1433 covers a lower end surface of the atomizing core 141. The middle part of the outer wall surface of the atomizing core 141 can be opposite to the liquid inlet hole 122. The atomizing core 141 has a central through hole 1410 formed in the middle thereof and extending longitudinally therethrough. The fourth sealing part 1433 is preferably larger in inner diameter than the aperture of the atomizing core 141 so that the second electrode claw 18 is not blocked by the fourth sealing part 1433 when being engaged with the atomizing core 141.
In some embodiments, the inner wall surface of the first seal ring 142 is formed with a first ventilation groove 1420 in a labyrinth shape, and the first ventilation groove 1420 penetrates the inner wall surfaces of the first and second sealing parts 1421 and 1423. The first ventilation slot 1420 may be designed to be small enough to have a capillary force in a use state for conducting the liquid storage cavity 130 with the airflow channel in the main pipe 12 when the liquid storage cavity 130 is under a large negative pressure, so as to realize gas-liquid balance and prevent dry burning. In some embodiments, the second seal ring 143 may have a second ventilation groove 1430 formed in a labyrinth shape on an inner wall surface thereof, and the second ventilation groove 1430 may penetrate the inner wall surfaces of the third seal part 1431 and the fourth seal part 1433 to have the same function as the first ventilation groove 1420. In some embodiments, the first sealing ring 142 and the second sealing ring 143 have the same structure, and can be used in common, so that the automatic installation can be facilitated, and the mold opening cost of the sealing rings can be saved.
It should be understood that the first sealing ring 142 and the second sealing ring 143 may alternatively be provided with a ventilation structure, and both have advantages and disadvantages. When only the first sealing ring 142 has the ventilation structure, if liquid leaks from the first ventilation channel 1420 of the first sealing ring 142, some of the leaked liquid flows downward from the upper end of the atomizing core 141, and is absorbed by the atomizing core 141 and atomized again. When only the second gasket 143 has the ventilation structure, although possible leakage easily flows into the base 11, since the direction of the air flow in the air flow channel is from bottom to top, the air is supplied more smoothly through the second gasket 143. In some embodiments, the silica gel for sealing the second sealing ring 143 at the lower end is thicker, that is, the distance from the surface of the second sealing ring 143 contacting the atomizing core 141 to the surface contacting the main pipe 12 can better seal the lower end of the atomizing core 141 by interference fit, so as to avoid liquid leakage. When comparing the two, the thickness of the corresponding portion of the first seal ring 142 is compared.
Referring to fig. 8, the atomizing core 141 may include a cylindrical porous body 1411, a heating element 1412 disposed on an inner wall surface of the porous body 1411, a first electrode 1413 disposed on an upper end of the inner wall surface of the porous body 1411 and electrically connected to an upper end of the heating element 1412, and a second electrode 1414 disposed on a lower end of the inner wall surface of the porous body 1411 and electrically connected to a lower end of the heating element 1412. The porous body 1411 may be a porous ceramic in some embodiments, and may be a small size porous body 1411, such small size porous body 1411 may have a length of 0.8-1.2cm in some embodiments, and an inner diameter of 0.18-0.22 cm.
The heating element 1412, which may be made of a material such as a nickel-chromium alloy, an iron-chromium-aluminum alloy, a silver-palladium alloy, etc. in some embodiments, is printed and sprayed on the inner surface of the blank of the porous body 1411, and is formed on the inner wall surface of the porous body 1411 by sintering, and may include two flat and long rectangular heating lines B arranged in parallel in the axial direction of the porous body 1411 and a connecting line C connecting the two heating lines in series, wherein the two heating lines B extend along the inner wall surface of the porous body 1411 in the circumferential direction so as to be C-shaped as a whole. The heating body 1412 may further include an upper end wire D and a lower end wire a connected to the upper and lower ends, respectively, to be electrically connected to the first and second electrodes 1413 and 1414, respectively.
The first electrode 1413 and/or the second electrode 1414 may be made of silver, copper, or other materials, and may be formed on an inner wall surface of the cylindrical porous body 1411 by coating/printing with silver paste or copper paste and sintering, and at least a part of the first electrode is connected to the heating element 1412. The first electrode 1413 and/or the second electrode 1414 may be C-shaped in some embodiments, which is typically first printed with a paste for the heating element 1412 onto a green body of the porous body 1411, followed by printing or coating with an electrode paste, and then sintered together. In some embodiments, the width of the gap of the first electrode 1413 may be smaller than the width of the conductive portion 173, so as to electrically contact all the conductive portions 173 of the first electrode claw 17; the width of the gap of the second electrode 1414 may be smaller than the width of the conductive portions 183 so as to electrically connect with all the conductive portions 183 of the second electrode tab 18. It is understood that the heating element 1412 may be made of a metal heating sheet in some embodiments, and the porous body 1411 is also limited to a porous ceramic material, and other suitable porous body materials may also be used. It is to be understood that the first electrode 1413 and/or the second electrode 1414 are not limited to the C-shaped distribution at the end of the inner wall surface of the porous body 1411, but may be distributed over the entire circumference of the end of the inner wall surface of the porous body 1411, i.e., in a ring shape.
The first electrode 1413 and/or the second electrode 1414 are/is disposed without perforating and threading the porous body 1411, so that the internal structure of the porous body 1411 is more complete, controllable and reliable, and the consistency of the product is well ensured. In addition, a lead can be avoided, and the manufacturing difficulty and the production cost are reduced. This is more obvious for application to the miniaturized porous body 1411.
In some embodiments, it is also beneficial to dispose the first electrode 1413 and the second electrode 1414 on two ends of the inner wall surface of the small-sized porous body 1411, because the inner wall area of the small-sized porous body 1411 is small, and if two electrodes are disposed on one end, the area of the two electrodes is too small to facilitate stable electrical connection with the electrode connecting member, and short circuit is also easily caused, and by disposing the first electrode 1413 and the second electrode 1414 on two ends, the first electrode 1413 and the second electrode 1414 can be disposed conveniently, and the area of the first electrode 1413 and the second electrode 1414 can be made larger to facilitate stable electrical connection with the electrode connecting member.
As further shown in fig. 6 and 7, the electrode connecting means 15 includes, in some embodiments, a central hole 150 extending upward from a lower end, an air outlet hole 152 formed on a top side wall, and a catching groove 154 formed on a side wall surface, the air outlet hole 152 communicating with the central hole 150 for air intake. The locking groove 154 is used to engage with the insulating seal ring 16. The outer wall surface of the insulating seal ring 16 forms a locking groove 160 for engaging with the mounting ring 1132 of the base 11.
The first electrode tab 17 may be made of phosphor copper or 316 stainless steel, and the surface thereof may be plated with gold. The first electrode tab 17 is preferably made of a phosphor-copper material, which has a relatively small resistance. The first electrode tab 17 may include a mounting portion 171 embedded in an inner wall surface of the second tube 123, three extending portions 172 connected to the mounting portion 171, and three conductive portions 173 connected to the three extending portions 172, respectively. Each extension portion 172 and the corresponding conductive portion 173 form an elastic conductive arm of the first electrode tab 17. It is understood that the number of the elastic conductive arms of the first electrode claw 17 is not limited to three, one or more elastic conductive arms may be provided, and the electric connection may be more reliable and the assembly may be more convenient due to the plurality of elastic conductive arms.
The mounting portion 171 may be cylindrical in some embodiments, and has a longitudinal break 1710 extending through both lateral edges, the break 1710 being configured to deform during installation to ensure that the mounting portion 171 is better secured to the inner wall of the second tube segment 123. Specifically, a trumpet-shaped guide surface 1210 is arranged at the joint of the second pipe section 123 and the first pipe section 121, and when the first electrode claw 17 is plugged into the second pipe section 123 along the axial direction, the guide surface 1210 applies a component force inward in the radial direction to the mounting part 171 of the first electrode claw 17, so that the fracture 1710 of the mounting part 171 is closed, the outer diameter is reduced, and the mounting part can be plugged into the second pipe section 123; when mounted in place, mounting portion 171 provides a reactive force against the inner wall of second tube section 123, thereby securely fastening second tube section 123. It will be appreciated that the mounting portion 171 may also be integrally formed with the second tubular segment 123 in some embodiments. In some embodiments, the mounting portion 171 may be axially inserted into the upper end of the central through hole 1410 of the atomizing core 141 and elastically fixed in abutment with the first electrode 1413, so that the elastic conductive arm may be extended to elastically contact the main pipe 12.
The extending portion 172 may be a bar shape in some embodiments and has good elasticity, and after it is bent and extended from the mounting portion 171 toward the central axis of the mounting portion 171 for a certain distance, it is extended along the central axis parallel to the mounting portion 171 toward a direction away from the mounting portion 171, so as to provide a space for the conductive portion 173 to be bent toward the central axis away from the mounting portion 171 and provide good elasticity characteristics. The extension 172 preferably has two or more to ensure more reliable electrical connection; when the number of the extending portions 171 is plural, it is preferable that the extending portions are uniformly distributed on the lower edge of the mounting portion 171 and extend downward. Specifically, the extension portion 172 extends from the mounting portion 171 toward the central axis of the mounting portion 171 at an angle and then extends in a direction away from the mounting portion 171 along the central axis. The end of each extending portion 172 is provided with a conductive portion 173 for elastically contacting the first electrode 1413 of the atomizing core 141. The conductive portion 173 may be in the shape of a scoop in some embodiments, and specifically, the conductive portion 173 extends obliquely away from the central axis of the mounting portion 171, and then bends to extend obliquely toward the central axis. The slope of the spoon-like structure slopes inward to provide a guiding function, and the bottom of the spoon-like structure is in arc transition to better contact with the first electrode 1413 of the atomizing core 141, and will not scratch the first electrode 1413 during assembly. The vertical distance from the bottom of the conductive portion 173 to the central axis is slightly greater than the radius of the central through hole 1410 of the atomizing core 141 at the position of the first electrode 1413, so that when the conductive portion 173 is axially inserted into the central through hole 1410, since the conductive portion 173 has an inclined surface inclined toward the inner side, the atomizing core 141 exerts a force on the conductive portion 173, and a component force toward the central axis direction is exerted, so that the extending portion 171 is elastically deformed toward the central axis direction, and the conductive portion 173 can be inserted. After the conductive portion 173 is inserted into the central through hole 1410, the elastic force of the extension portion 171 causes the conductive portion 173 to be tightly contacted with the first electrode 1413.
The second electrode tab 18 may be made of phosphor copper or 316 stainless steel in some embodiments, and the surface thereof may be plated with gold. The second electrode tab 18 is preferably made of a phosphor-copper material, which is relatively low resistance. The second electrode tab 18 may include a mounting portion 181 coupled to an upper portion of the electrode connecting device 15, an extending portion 182 coupled to the mounting portion 181, and a conductive portion 183 coupled to the extending portion 182. The mounting portion 181 may in some embodiments be cylindrical and have a longitudinal break 1810 through both lateral edges, the presence of the break 1810 allowing deformation during mounting to ensure that the mounting portion 181 is better secured to the upper portion of the electrode connecting means 15, it being understood that the mounting portion 181 may in some embodiments also be integral with the electrode connecting means 15. The extension part 182 may be a bar shape in some embodiments and has good elasticity, and the extension part 182 preferably has two or more to ensure more reliable electrical connection; when there are a plurality of extending portions 181, it is preferable that the extending portions are uniformly distributed on the lower edge of the mounting portion 181 and extend downward. The end of each extending portion 182 is provided with a conductive portion 183 for elastically contacting the second electrode 1414 of the atomizing core 141. The conductive portion 183 may be in the form of a scoop, the slope of which is inclined inward to provide a guiding function, and the bottom of the scoop is rounded to better contact the second electrode 1414 of the atomizing core 141 and to prevent the second electrode 1414 from being scratched during assembly. In some embodiments, the second electrode tab 18 may be identical in structure to the first electrode tab 17, and may be common to both, which may reduce assembly difficulty and cost.
When the atomizing body 10 is assembled, the following steps may be employed:
(1) providing a base 11, an electrode connecting device 15, an insulating sealing ring 16 and a second electrode claw 18, installing the electrode connecting device 15 into a second installation cylinder 113 of the base 11 through the insulating sealing ring 16, and sleeving the second electrode claw 18 on the top of the electrode connecting device 15 to form a base assembly; at this time, the conductive portion 183 of the second electrode tab 18 projects upward;
(2) providing main pipe 12 and first electrode claw 17 as shown in the figure, and embedding first electrode claw 17 into second pipe 123 of main pipe 12, conductive part 173 of first electrode claw 17 is extended downward;
(3) providing an atomizing core 141, a first sealing ring 142 and a second sealing ring 143, and respectively sleeving the first sealing ring 142 and the second sealing ring 143 on the upper end and the lower end of the atomizing core 141 to form an atomizing assembly 14;
(4) the atomization assembly 14 is plugged into the main pipe 12 from bottom to top, and the first electrode 1413 of the atomization core 141 is in conductive contact with the conductive part 173 of the first electrode claw 17, so that the first electrode 1413 of the atomization core 141 is electrically connected with the main pipe 12, and a main pipe assembly is formed;
(5) the main pipe assembly is inserted into the first mounting cylinder 112 at the top of the base assembly to realize the tight fit and the electrical connection between the main pipe 12 and the base 11, and in addition, the conductive part 183 of the second electrode claw 18 is in contact conduction with the second electrode 1414 of the atomizing core 141;
(6) providing the housing 13, and sleeving the housing 13 outside the first mounting tube 112 to assemble the atomizing main body 10.
In the above assembling step of the atomizing main body 10, the first electrode claw 17 and the second electrode claw 18 realize quick electrical contact conduction between elements, and compared with the mode of wire welding and the like in the related art, the operation is more convenient and quick, and the automatic assembly of the product is easier to realize. It is to be understood that the above-mentioned sequence numbers before the steps are merely for convenience of description, and do not indicate the order of the respective steps. For example, in the case of assembly, the main pipe assembly may be constructed first, and then the base assembly may be constructed.
As further shown in fig. 4 and 5, the nozzle assembly 20 may include an annular blocking portion 21 and a flat nozzle portion 22 connected to the annular blocking portion 21, wherein the annular blocking portion 21 is adapted to be inserted into an annular liquid injection port 132 at the upper end of the atomizing body 10. The mouthpiece section 22 has a longitudinal air-guide hole 220 in the middle, which air-guide hole 220 is adapted to communicate with the upper end of the second pipe section 123 of the main pipe 12 for guiding out the mixture of aerosol and air.
In the assembled nebulizer 1, the liquid aerosol-generating substrate is first injected into the liquid storage chamber 130 of the nebulizer body 10 through the injection port 132, and after the liquid storage chamber 130 is filled with the aerosol-generating substrate, the nozzle assembly 20 is inserted into the injection port 132 to close the liquid storage chamber 130, and the air vent 220 of the nozzle assembly 20 is communicated with the main pipe 12. At this time, the liquid aerosol-generating substrate reaches around the atomizing wick 144 via the liquid inlet hole 122, and the porous body 1411 of the atomizing wick 141 sucks the liquid aerosol-generating substrate to the inner surface to contact the heat-generating body 1412 by capillary force. When the atomizing assembly 1 is mounted on the power supply device 2 in use, when a user inhales through the mouthpiece 22, the external air enters through the central hole 150 of the electrode connecting device 15, passes through the through hole 1110 of the base 11, enters the central through hole 1410 of the atomizing core 141, and is then discharged through the air guide hole 220 of the nozzle assembly 20, as indicated by the arrow X in fig. 3. At the same time, an air switch (not shown) in the power supply device 2 is turned on, and the power supply device 2 is driven to supply power to the atomizer 1. The heating element 1412 of the atomizing core 141 is energized to generate heat, and heats and atomizes the liquid aerosol-generating substrate on the inner surface of the porous body 1411 to form aerosol, and the aerosol is entrained by the air flow after being mixed with the air flowing through the central through hole 1410.
Fig. 9 to 11 show an atomising body 10a in some embodiments of the utility model, the illustration omitting the housing, which atomising body 10a may be an alternative to the atomising body 10 described above. As shown, the atomizing body 10a may include a base 11a, a main conduit 12a, an atomizing assembly 14a, an electrode connecting device 15a, an insulating seal ring 16a, a first electrode jaw 17a, and a second electrode jaw 18a, which are coaxially assembled together in some embodiments. The base 11a may be cylindrical in some embodiments and may be electrically conductive. The main pipe 12a, which may also be electrically conductive in some embodiments, is disposed longitudinally above the base 11a and is electrically connected to the base 11 a; the main conduit 12a defines a cylindrical receiving chamber 120a for receiving the atomizing assembly 14 a. The main pipe 12a may further have a liquid inlet hole 122a formed therein for communicating the reservoir chamber with the receiving chamber 120 a. The atomizing assembly 14a may have a cylindrical shape in some embodiments, and is disposed in the receiving cavity 120a along the longitudinal direction; the atomizing assembly 14a may define a longitudinally extending air flow passage 140a at a central portion thereof. The electrode connecting device 15a is longitudinally arranged on the lower part of the base 11a in a penetrating way and is electrically insulated from the base 11 a; specifically, an insulating sealing ring 16a is longitudinally arranged at the lower part of the base 11a, and the electrode connecting device 15a is further arranged in the insulating sealing ring 16a in a penetrating way, so that the insulating sealing connection with the base 11a is realized. One end of the first electrode claw 17a is fixed on the inner wall of the main pipe 12a and electrically connected with the main pipe 12a, and the other end of the first electrode claw is in elastic contact with the upper end of the atomizing assembly 14a, so that the upper end of the atomizing assembly 14a is electrically connected with the main pipe 12 a. One end of the second electrode claw 18a is embedded on the electrode connecting device 15a and electrically connected with the electrode connecting device 15a, and the other end is in elastic contact with the lower end of the atomizing assembly 14a, so as to electrically connect the lower end of the atomizing assembly 14a with the electrode connecting device 15 a.
In some embodiments, the electrode connecting device 15a is used for electrically connecting with the positive electrode of the power supply device 2, and the base 11a is used for electrically connecting with the negative electrode of the power supply device 2, thereby forming an electric circuit. After the current can come out from the positive electrode of the power supply device 2, the current sequentially passes through the electrode connecting device 15a and the second electrode claw 18a, reaches the lower end of the atomizing assembly 14a, penetrates through the atomizing assembly 14a, and after the atomizing assembly 14a generates heat, reaches the upper end of the atomizing assembly 14a, and then sequentially flows back to the negative electrode of the power supply device 2 after passing through the first electrode claw 17a, the main pipeline 12a and the base 11 a. It is understood that in some embodiments, the electrode connecting device 15a and the base 11a may also be electrically connected to the negative electrode and the positive electrode of the power supply device 2, respectively, and the current direction is opposite to the above direction.
The base 11a may be integrally formed of a metal material in some embodiments, and may include a circular base 111a and a second mounting tube 113a longitudinally disposed on a bottom surface of the base 111a, wherein a through hole 1110a is formed in a middle portion of the base 111a, and the through hole 1110a connects the first tube segment 121a of the main tube 12a with the second mounting tube 113 a. An attachment ring 1132a fitted to the insulating seal ring 16a is formed on the inner wall surface of the second attachment tube 113 a. An air intake hole 1130a is also formed in the sidewall of the second mounting cylinder 113 a.
The main conduit 12a may include, in some embodiments, a first pipe segment 121a integrally formed with the base 11a and a second pipe segment 123a axially embedded in an upper end of the first pipe segment 121a and electrically connected to the first pipe segment 121 a. The first pipe segment 121a defines the accommodating cavity 120a, and the liquid inlet holes 122a may be a plurality of and are uniformly formed on the circumferential direction of the sidewall of the first pipe segment 121 a. The inner wall surface of the second tube segment 123a may be provided with a retaining ring 1231a adjacent to the first tube segment 123 for providing an axial retaining force to the first electrode claw 17 a.
The atomizing assembly 14a may include a cylindrical atomizing core 141a disposed longitudinally, a first sealing ring 142a sleeved on an upper end of the atomizing core 141a, and a second sealing ring 143a sleeved on a lower end of the atomizing core 141 a. The first sealing ring 142a may have an L-shaped cross-section for sealing a gap between the upper end of the atomizing core 141a and the first and second pipe sections 121a and 123 a. The second sealing ring 143a may also have an L-shaped cross-section for sealing a gap between the lower end of the atomizing core 141a and the base 11 a. The middle part of the outer wall surface of the atomizing core 141a can be directly opposite to the liquid inlet hole 122 a. In some embodiments, the first and second seal rings 142a, 143a may be of the same construction.
In some embodiments, the inner wall surface of the first sealing ring 142a is formed with a first ventilation groove 1420a in a labyrinth shape, and the first ventilation groove 1420a may be designed to have a small enough size to have a capillary force in a use state, so as to conduct the liquid storage cavity and the air flow channel in the main pipe 12a when the liquid storage cavity is at a large negative pressure, so as to achieve a gas-liquid balance and prevent dry burning. In some embodiments, the second seal ring 143a may have a second ventilation groove 1430a in a labyrinth shape on an inner wall surface, and may have the same function as the first ventilation groove 1420 a. It is to be understood that a purge groove may be alternatively provided in the first seal ring 142a and the second seal ring 143 a. In some embodiments, the first sealing ring 142a and the second sealing ring 143a may have the same structure, and may be common to each other.
As further shown in fig. 11, the atomizing core 141a may include, in some embodiments, a cylindrical porous body 1411a, a heating element 1412a disposed on an inner wall surface of the porous body 1411a, a first electrode 1413a disposed on an upper end of the inner wall surface of the porous body 1411a and electrically connected to an upper end of the heating element 1412a, and a second electrode 1414a disposed on a lower end of the inner wall surface of the porous body 1411a and electrically connected to a lower end of the heating element 1412 a. In some embodiments, the atomizing core 141a may have the same structure as the atomizing core 141 described above, and both may be used in common.
The electrode connection means 15a in some embodiments comprises a central bore 150a extending downwardly from an upper end face. The electrode connecting means 15a may in some embodiments comprise a bottom wall 155a to close off the central hole 150a, so that the central hole 150a can accommodate leakage, preventing leakage to the outside. In some embodiments, the upper end of the inner wall surface of the central hole 150a is further provided with a stop ring 156a to stop the second electrode claw 18 a. The outer wall surface of the insulating seal ring 16a forms a groove 160a for engaging with the mounting ring 1132a of the base 11 a.
The first electrode tab 17a may be made of an elastic metal material in some embodiments, and may include a mounting portion 171a embedded in an inner wall surface of the second tube segment 123a, an extending portion 172a connected to the mounting portion 171a, and a conductive portion 173a connected to the extending portion 172 a. The mounting portion 171a may be cylindrical in some embodiments, and has a longitudinal break 1710a penetrating the upper and lower side edges, and the presence of the break 1710a may make the mounting portion 171a adapt to the error of the inner diameter of the second pipe section 123a, thereby increasing the applicability. The extension 172a may be bar-shaped in some embodiments, and preferably has three or more; the three or more extending portions 171a are uniformly connected to the lower edge of the mounting portion 171a and extend downward. The end of each extending portion 172a is provided with a conductive portion 173a for elastically contacting the first electrode 1413a of the atomizing core 141a to achieve conductivity, thereby improving the assembly efficiency. In some embodiments, the first electrode claw 17a may have the same structure as the first connecting member 17 described above, and may be common to both.
The second electrode tab 18a may have the same structure as the first electrode tab 17a in some embodiments, and may also be made of an elastic metal material, and includes a mounting portion 181a embedded in the central hole 150a of the electrode connecting device 15a, an extending portion 182a connected to the mounting portion 181a, and a conductive portion 183a connected to the extending portion 182 a. The mounting portion 181a may be cylindrical in some embodiments, and has a longitudinal cut 1810a through the upper and lower side edges, and the cut 1810a allows the mounting portion 181a to fit within the tolerance of the size of the central hole 150a of the electrode connecting device 15a, thereby increasing the applicability. The extension 182a may be bar-shaped in some embodiments, and preferably has three or more; the three or more extending portions 181a are uniformly connected to the lower edge of the mounting portion 181a and extend downward. The end of each extending portion 182a is provided with a conductive portion 183a for elastically contacting the second electrode 1414a of the atomizing core 141a to achieve conductivity, thereby improving the assembly efficiency. In some embodiments, the second electrode tab 18a may have the same structure as the second connector 18 described above, and may be common to both.
When the atomizing body 10a is assembled, the following steps may be employed:
(1) providing a base 11a with a first pipe section 121a of a main pipe 12a, an electrode connecting device 15a, an insulating sealing ring 16a and a second electrode claw 18a, installing the electrode connecting device 15a into a second installation cylinder 113a of the base 11a through the insulating sealing ring 16a, and embedding the second electrode claw 18a on the top of the electrode connecting device 15a to form a base assembly; at this time, the conductive portion 183a of the second electrode tab 18a projects upward;
(2) providing an atomizing core 141a, a first sealing ring 142a and a second sealing ring 143a, and respectively sleeving the first sealing ring 142a and the second sealing ring 143a on the upper end and the lower end of the atomizing core 141a to form an atomizing assembly 14 a;
(3) the atomization assembly 14a is plugged into the first pipe section 121a of the main pipe 12a from top to bottom, and the conductive part 183 of the second electrode claw 18 is in contact and conduction with the second electrode 1414 of the atomization core 141, so that the second electrode 1414 of the atomization core 141 is electrically connected with the electrode connecting device 15 a;
(4) providing a second pipe section 123a of the main pipe 12a and the first electrode claw 17a, and embedding the first electrode claw 17a into the second pipe section 123a of the main pipe 12a, wherein the conductive part 173a of the first electrode claw 17a extends downwards to form a second pipe section assembly;
(5) the second tube segment assembly is inserted into the top of the first tube segment 121a, and the first electrode 1413a of the atomizing core 141a is in conductive contact with the conductive portion 173a of the first electrode claw 17a, so that the first electrode 1413 of the atomizing core 141 is electrically connected with the main tube 12.
In the above assembling step of the atomizing body 10a, the first electrode claw 17a and the second electrode claw 18a realize electrical contact conduction between elements, and compared with the method of wire welding and the like in the related art, the method is more convenient and faster to operate, and is easy to realize automatic assembly of products.
Fig. 12 to 15 show an atomizing body 10b in some embodiments of the present invention, which is not shown to omit other structures such as a housing, and the atomizing body 10b may be used as an alternative to the atomizing body 10 a. As shown, the atomising body 10b may in some embodiments comprise a base 11b, a main conduit 12b, an atomising assembly 14b, an electrode connection 15b, an insulating sealing ring 16b and an insulating support 19b assembled together coaxially. The atomizing element 14b may in some embodiments be supported entirely on the electrode connecting means 15b, so that the electrode connecting means 15b, while functioning as an electrode connection, also serves the primary supporting function of the atomizing element 14 b. Thus, a supporting structure of the atomizing assembly 14b on the base 11b is not required, the structural design of the base 11b is greatly simplified, the manufacturing difficulty and cost of the base 10b are reduced, and convenience is provided for the rapid assembly of the whole atomizing main body 10 b.
The base 11b, which may be cylindrical in some embodiments and electrically conductive, has a central through hole 110b running up and down through it. The base 11b may be integrally formed of a metal material in some embodiments, and may include an air intake hole 114b and a boss 115 b. An air intake hole 114b is transversely formed through a sidewall of the base 11b and communicates with the central through hole 110b so that air outside the base 11b can enter the central through hole 110 b. A boss 115b is formed on the inner wall surface of the base 11b and is located at the lower side of the air intake hole 114b, so that the insulating seal ring 16b is embedded therein.
The main pipe 12b, which may also be electrically conductive in some embodiments, is sleeved on the upper end of the base 11b and is electrically connected with the base 11 b; the main conduit 12b defines a receiving cavity 120b for receiving the atomizing assembly 14 b; the sidewall of the main pipe 12b is provided with a liquid inlet hole 1210b for communicating the accommodating chamber 120b with an outside liquid storage chamber (not shown).
Referring to fig. 14 and 15, the main conduit 12b may include a first pipe segment 121b located at a lower portion and a second pipe segment 123b axially detachably connected to an upper end of the first pipe segment 121b and electrically connected to the first pipe segment 121 b.
The first tube segment 121b may have a stepped shaft shape in some embodiments, and includes a lower tube segment 1211b, a middle tube segment 1212b, and an upper tube segment 1213b, which are sequentially connected in an axial direction and have a decreasing outer diameter. The lower pipe 1211b may be sleeved on the upper end of the base 11b in an interference fit manner to tightly couple the first pipe segment 121b to the base 11 b. The middle tube segment 1212b defines a receiving cavity 120b, and the liquid inlet 1210b may be a plurality of liquid inlets, and is uniformly distributed on the circumference of the side wall of the middle tube segment 1212 b. The outer wall surface of the upper pipe section 1213b may be formed with an external thread structure 1214b for the second pipe section 123b to be screwed thereon. The inner diameter of the lower tube 1211b may be larger than that of the middle tube 1212b, and a step 1215b is formed between the inner walls of the two to press against the insulating support 19 b. The inner diameter of the middle tube segment 1212b corresponds to the inner diameter of the base 11 b.
The second pipe segment 123b may include a cover 1231b and an air guide 1232b disposed on a top surface of the cover 1231b, in some embodiments, the cover 1231b includes a cylindrical sidewall 1233b and a top wall 1234b coupled to a top of the cylindrical sidewall 1233b, and a through hole 1230b is formed in a middle portion of the top wall 1234 b. The inner wall surface of the cylindrical sidewall 1233b is formed with an internal thread structure 1235b matching with the external thread structure of the first pipe segment 121b, and the outer wall surface of the cylindrical sidewall 1233b is formed with an anti-slip thread structure 1237b, so that a user can screw the second pipe segment 123b to the first pipe segment 121b by hand. The lower surface of the annular top wall 1234b is further provided with a contact ring 1236b, the contact ring 1236b surrounds the vent 1230b, and is adapted to extend into the first pipe segment 121b to abut against the upper end of the atomizing assembly 14b and electrically connect with the upper end of the atomizing assembly 14 b. The air guide 1232b is coupled to the top surface of the top wall 1234b and communicates with the air vent 1230 b. The air guide 1232b has a polygonal air guide hole 1238b so that the second pipe section 123b can be screwed to the first pipe section 121b using a polygonal wrench. It is understood that the air holes 1238b are not limited to the polygonal shape, and may have other non-circular shapes such as oval, irregular shape, etc.
The electrode connecting means 15b is longitudinally perforated in the lower portion of the base 11b and electrically insulated from the base 11 b. Specifically, an insulating sealing ring 16b is longitudinally arranged at the lower part of the base 11b, and the electrode connecting device 15b is arranged in the insulating sealing ring 16b in a penetrating way, so that the insulating sealing connection with the base 11b is realized. The electrode connecting means 15b is elastically and axially retractable in some embodiments to provide an elastic supporting force for the lower end of the atomizing assembly 14b, and to maintain the lower end of the atomizing assembly 14b in good electrical connection with the electrode connecting member 15b and also to maintain the upper end of the atomizing assembly 14b in good electrical connection with the second tubular segment 123b of the main conduit 12 b.
In some embodiments, the bottom wall 1511b of the electrode connecting device 15b is exposed on the lower surface of the base 11b for electrically connecting with the positive electrode of the power supply device 2, and the base 11b is for electrically connecting with the negative electrode of the power supply device 2, thereby forming an electrical circuit. After the current can come out from the positive electrode of the power supply device 2, the current reaches the lower end of the atomizing assembly 14b through the electrode connecting device 15b, penetrates through the atomizing assembly 14b, and after the atomizing assembly 14b is electrified and generates heat, the current reaches the upper end of the atomizing assembly 14b, and then flows back to the negative electrode of the power supply device 2 along the second pipe section 123b, the first pipe section 121b and the base 11b of the main pipe 12b in sequence. It is understood that in some embodiments, the electrode connecting device 15b and the base 11b may also be electrically connected to the negative electrode and the positive electrode of the power supply device 2, respectively, and the current direction is opposite to the above direction. The electrode connection device 15b may be cylindrical in some embodiments and is axially and electrically insulated through the central bore 110 of the base 11b by an insulating seal ring 16 b.
Referring to fig. 16 and 17 together, the electrode connecting device 15b may be configured in an elastic thimble type configuration in some embodiments, which may include a first conductive member 151b, a second conductive member 152b that may be disposed close to and apart from the first conductive member 151b, and an elastic member 153b disposed between the first conductive member 151b and the second conductive member 152b, the elastic member 153b providing an elastic tension between the first conductive member 151b and the second conductive member 152 b. In some embodiments, the first conductive member 151b and the second conductive member 152b are axially movably nested together and are electrically connected to each other. It is understood that, in some embodiments, the first conductive member 151b and the second conductive member 152b may be separately designed and electrically connected to each other through the elastic member 153 b. The elastic member 153b may include a cylindrical spring that may be electrically conductive in some embodiments. It can be understood that, since the electrode connecting device 15b can elastically expand and contract in the axial direction, it is possible to significantly increase the tolerance of the atomizing assembly 14b during the assembly process while maintaining a reliable electrical connection, thereby further simplifying the design difficulty of the atomizing body 10 b. It will be appreciated that in some embodiments, an elastic contact structure may also be provided between the upper end of the atomizing assembly 14b and the main conduit 12b, while the electrode connection means 15b is provided in a non-elastic telescopic structure. Of course, the elastic contact structure may be provided at both the upper and lower ends of the atomizing assembly 14 b.
Referring to fig. 16 and 17, the first conductive member 151b may have a circular cup shape in some embodiments, and includes a circular bottom wall 1511b, a cylindrical sidewall 1512b standing on the periphery of the bottom wall 1511b, and a rim 1513b formed on the outer wall of the sidewall 1512b and protruding radially outward. The bottom wall 1511b is used for electrically connecting to the positive electrode of the power supply unit 2 on the one hand and for supporting the elastic member 153b on the other hand. The open side of the sidewall 1512b is also folded inwardly in some embodiments to form a neck 1514b having a smaller aperture. The outside diameter of the side wall 1512b is matched to the inside diameter of the insulating seal ring 16b so that the side wall 1512b can be tightly fitted into the insulating seal ring 16 b. It is to be understood that the first conductive member 151b is not limited to a circular cup shape, but may be other shapes such as a square cup shape, an oval cup shape, and the like. In some embodiments, the ratio of the outer diameter of the first conductive member 151b to the outer diameter of the base 10b is greater than one-half, or even greater than two-thirds, that is, the cross-sectional area of the first conductive member 151b occupies most of the cross-sectional area of the base 10b, so that the conductive contact area of the first conductive member 151b is greatly increased.
In some embodiments, the second conductive member 152b may include a cylindrical sidewall 1521b and a partition wall 1522b disposed inside the sidewall 1521 near the lower opening. The outer diameter of the sidewall 1521b is matched with the aperture of the neck portion 1514b of the first conductive member 151b, so that the sidewall 1521b can be tightly inserted into the neck portion 1514b to move axially and be electrically connected. The partition wall 1522b is configured to press against the upper end of the elastic member 153b, and divides the central through hole 1520b of the second conductive member 152b into an upper hole portion and a lower hole portion, which are independent of each other, where the upper hole portion of the central through hole 1520b is communicated with the upper end opening, and the lower hole portion is communicated with the lower end opening. The lower hole portion of the central through hole 1520b is for the upper end of the elastic member 153b to be inserted. The sidewall 1521b is further provided with a plurality of air inlets 1523b, the air inlets 1523b are uniformly distributed on the circumferential direction of the sidewall 1521, and the upper hole part of the central through hole 1520d is communicated with the outer side. Here, an air inlet channel is formed on the second conductive member 152b, wherein the air inlet 1523 is used as an air inlet, the upper hole portion is used as an air flow channel, and the upper end opening is used as an air outlet, so that air entering the base 11b from the outside can enter the atomizing assembly 14. It is to be understood that the air inlet passage is not limited to be provided on the second conductive member 152b, and may be provided on the first conductive member 151b in some embodiments. It is to be understood that the air inlet passage may be formed in both the first conductive member 151b and the second conductive member 152 b.
In some embodiments, a flange 1524b extends radially from a lower end edge of the outer surface of the sidewall 1521b of the second conductive member 152b, and the outer diameter of the flange 1524b is larger than the bore diameter of the neck 1514 and is matched with the inner diameter of the sidewall 1512b of the first conductive member 151b, so that the lower end of the second conductive member 152b is inseparably mounted in the first conductive member 151 b. The inner diameter and the outer diameter of the upper end of the sidewall 1521b of the second conductive member 152b are matched with the inner diameter and the outer diameter of the lower end of the atomizing assembly 14b, respectively, and the second conductive member 152b can better support the atomizing assembly 14b and maintain good electrical connection with the lower end of the atomizing assembly 14 b.
The insulating support 19b, which in some embodiments is in the form of a ring, is mounted on top of the base 11b and closely surrounds the electrode connection means 15b to electrically and insulatively fix the electrode connection means 15b in a horizontal position; in addition, an insulating support 19b is disposed at a lower side of the liquid inlet hole 1210b to prevent liquid from leaking downward. The insulating support 19 may include a cylindrical body 191b and a flange 192b radially outwardly extending from a middle portion of an outer wall surface of the body 191 b. The outer diameter of the body 191b is matched with the inner diameter of the middle tube section 1212b of the first tube section 121b and the inner diameter of the upper end of the base 11b, so that the upper and lower ends of the body 191b can be respectively and tightly embedded in the base 11b of the middle tube section 1212 b. The outer diameter of the flange 192b is larger than the inner diameter of the upper end of the base 11b so that the flange 192 can be lapped over the upper end surface of the upper end of the base 11 b. The flange 192b also has an outer diameter greater than the inner diameter of the middle tube section 1212b of the first tube section 121b and is adapted to the inner diameter of the lower tube section 1211b so that the flange 192b can be tightly pressed against the step 1215b of the first tube section 121 b.
The atomizing element 14b is axially disposed in the receiving cavity 120, and has a lower end coaxially disposed on the electrode connecting device 15b and electrically connected to the electrode connecting device 15b, and an upper end abutting against and electrically connected to the first tubular section 121b of the main conduit 12 b. The atomizing assembly 14b may be cylindrical in some embodiments and is disposed in the receiving cavity 120b along the longitudinal direction; the atomizing assembly 14b may define a longitudinally extending air flow passage 140b at a central portion thereof. The lower end of the atomizing assembly 14b abuts against the upper end of the electrode connecting device 15b, and the two are electrically connected. In some embodiments, the outer diameter of the upper end of the electrode connecting device 15b is equivalent to the outer diameter of the atomizing assembly 14b, and the atomizing assembly 14b can be completely carried by the electrode connecting device 15b without providing an additional supporting structure for the atomizing assembly 14b on the base 11 b. Therefore, the structural design of the base 11b is simplified, the installation difficulty of the atomizing assembly 14b is reduced, and the assembly efficiency of the whole atomizer is improved.
The atomizing assembly 14b may, in some embodiments, include a longitudinally disposed cylindrical atomizing core 141 b. The middle part of the outer wall surface of the atomizing core 141b can be opposite to the liquid inlet hole 1210 b. As further shown in fig. 18, the atomizing core 141b may include, in some embodiments, a cylindrical porous body 1411b, a heating element 1412b disposed on an inner wall surface of the porous body 1411b, a first electrode 1413b disposed on an upper end of the inner wall surface of the porous body 1411b and electrically connected to an upper end of the heating element 1412b, and a second electrode 1414b disposed on a lower end of the inner wall surface of the porous body 1411b and electrically connected to a lower end of the heating element 1412 b. The heating element 1412b may be formed on the inner wall surface of the porous body 1411b by silk-screening, printing or spraying a heating film slurry on the inner surface of the green body of the porous body 1411b, and then sintering the green body to form a heating circuit, which may be spirally distributed on the inner wall surface of the porous body 1411b along the longitudinal direction of the porous body 1411b in some embodiments.
In some embodiments, the first electrode 1413b and/or the second electrode 1414b may be formed on the surface of the cylindrical porous body 1411b by silver paste coating and sintering, and at least partially connected to the heating element 1412 b. In some embodiments, the first electrode 1413b includes a cylindrical first electrode portion M and a circular ring-shaped second electrode portion N connected to an upper edge of the first electrode portion M. The first electrode portion M is formed on the upper end of the inner wall surface of the porous body 1411b, and is connected to the upper end of the heating element 1412 b. The second electrode portion N is formed on the upper end surface of the heating element 1412b for contact with the contact ring 1236b, and the shape and size of the contact ring 1236b are adapted to the second electrode portion N. In some embodiments, the second electrode 1414b includes a cylindrical third electrode portion P and an annular fourth electrode portion Q connected to a lower edge of the third electrode portion P. The third electrode portion P is formed at the lower end of the inner wall surface of the porous body 1411b, and is connected to the lower end of the heating element 1412 b. The fourth electrode portion Q is formed on the lower end surface of the heating element 1412b and abuts against the upper end surface of the second conductive member 152 b.
When the atomizing body 10b is assembled, the following steps may be employed:
(1) providing a base 11b, a main conduit 12b, an atomizing assembly 14b, an electrode connecting device 15b, an insulating seal ring 16b and an insulating support 19 b;
(2) installing the insulating seal ring 16b in the base 11 b;
(3) the electrode connecting device 15b is installed in the insulating seal ring 16 b;
(4) mounting an insulating support member 19b to the upper end opening of the base 11b between the upper end opening of the base 11b and the electrode connecting means 15 b;
(5) sleeving a first pipe section 121b of the main pipeline 12b on the upper end of the base 11 b;
(6) placing the atomization assembly 14b into the first pipe section 121b from the upper end opening of the first pipe section 121b along the axial direction, and supporting the lower end of the atomization assembly 14b on the upper end of the electrode connecting device 15 b;
(7) the second pipe section 123b of the main pipe 12b is screwed on the upper end of the first pipe section 121b, and the contact ring 1236b of the second pipe section 123b is tightly abutted to the upper end of the atomizing assembly 14b, so that the assembly is completed, the assembly is very convenient and fast, and the automatic assembly is very suitable for automatic assembly.
Before the assembly of the atomizing body 10b, an assembly step of the electrode connecting device 15b may be further included, and the assembly step of the electrode connecting device 15b may include:
(1) providing a first conductive member 151b, a second conductive member 152b, and an elastic member 153b in which a neck portion 1514b has not been formed;
(2) placing the elastic member 153b into the first conductive member 151b in the axial direction;
(3) inserting the lower end of the second conductive member 152b into the open end of the first conductive member 151b, and applying a certain pressure to the elastic member 153 b;
(4) the open end of first conductive member 151b is spun radially inward to form neck 1514, which bonds second conductive member 152b to first conductive member 151 b.
In the use process of the atomizing main body 10b, as shown by arrows in fig. 13, the air flow firstly enters the base 11b from the air inlet hole 114b of the base 11b, then enters the electrode connecting device 15b through the air inlet 1523b of the electrode connecting device 15b, then is transmitted to the central through hole of the atomizing assembly 14b, carries the mist in the atomizing assembly 14, and then is guided out through the air guide hole 1238 b.
It should be noted that, for a person skilled in the art, the above technical features can be freely combined, and several variations and modifications can be made without departing from the concept of the present invention, which all fall into the protection scope of the present invention.
Claims (30)
1. An electrode connecting device is characterized in that the electrode connecting device is used for bearing an atomizing component in an electronic atomizing device and electrically connecting the atomizing component with a power supply device, and comprises a first conductive piece, a second conductive piece and an elastic piece, wherein the second conductive piece can be arranged close to or far away from the first conductive piece, the elastic piece is arranged between the first conductive piece and the second conductive piece, and the elastic piece provides elastic tension between the first conductive piece and the second conductive piece.
2. The electrode connecting device according to claim 1, wherein the first and second electrically conductive members are axially movably nested together back and forth and are electrically connected by contact with each other.
3. The electrode connecting device according to claim 1, wherein the first conductive member and the second conductive member are electrically connected via the elastic member.
4. The electrode connecting device according to any one of claims 1 to 3, wherein the first conductive member is cup-shaped and includes a bottom wall and a cylindrical side wall standing on a periphery of the bottom wall, and one end of the elastic member is disposed in the cylindrical side wall and supported on the bottom wall; the opening end of the side wall is turned inwards to form a neck.
5. The electrode connecting device according to any one of claims 1 to 3, wherein the first conductive member and/or the second conductive member includes a gas inlet passage through which gas flows.
6. The electrode connecting device according to claim 5, wherein the second conductive member includes a cylindrical side wall and a partition wall provided in the side wall near the lower end opening; the partition wall divides the central through hole of the second conductive piece into an upper hole part, the upper hole part is communicated with the upper end opening of the side wall, the side wall is provided with an air inlet which is used for communicating the upper hole part with the outer side, and the air inlet, the upper hole part and the upper end opening form the air inlet channel together.
7. The electrode-connecting device according to claim 6, wherein the partition wall further partitions the central through-hole into a lower hole portion independent from the upper hole portion, the lower hole portion communicating with the lower end opening, and the other end of the elastic member is inserted into the lower hole portion and abuts against the partition wall.
8. The electrode connecting device according to claim 6, wherein a flange is further extended radially from a lower end edge of the outer surface of the side wall, the flange is extended into the first conductive member, and the first conductive member includes a neck portion for preventing the flange from falling off.
9. An atomizer comprises an atomizing main body, wherein the atomizing main body comprises a conductive base, a conductive main pipeline arranged on the base and an atomizing component arranged between the base and the main pipeline; the atomization device is characterized in that the atomization main body further comprises an electrode connecting device arranged in the base in an electrically insulated mode, and the atomization component is elastically connected between the electrode connecting device and the main pipeline and respectively electrically connected with the electrode connecting device and the main pipeline.
10. A nebulizer as claimed in claim 9, wherein the electrode connecting means comprises a gas inlet passage through which gas flows, the gas inlet passage communicating with the nebulizing assembly.
11. The atomizer of claim 9, wherein said electrode connecting means is resiliently supported below said atomizing assembly and is in electrical contact with said atomizing assembly.
12. The atomizer of claim 11, wherein said atomizing assembly is cylindrical and said electrode connecting means comprises an upper end portion supported at a lower end of said atomizing assembly, said upper end portion having an outer diameter corresponding to an outer diameter of said atomizing assembly.
13. The atomizer of any one of claims 9 to 12, wherein said electrode connecting means comprises a first electrically conductive member mounted in said base, a second electrically conductive member disposed adjacent and remote from said first electrically conductive member, and an elastic member disposed between said first and second electrically conductive members, said elastic member providing an elastic tension between said first and second electrically conductive members, said first and second electrically conductive members being electrically connected; the second conductive member is carried below the atomization assembly.
14. The nebulizer of claim 13, wherein the first electrically conductive member and the second electrically conductive member are axially movably nested together back and forth and are in electrical contact with each other.
15. The nebulizer of claim 13, wherein the first conductive member and the second conductive member are electrically connected via the elastic member.
16. The atomizer according to claim 13, wherein said first conductive member is cup-shaped and includes a bottom wall and a cylindrical side wall standing on a periphery of said bottom wall, one end of said elastic member being disposed in said cylindrical side wall and carried on said bottom wall; the opening side of the side wall is turned inwards to form a neck.
17. The nebulizer of claim 13, wherein the second conductive member comprises a cylindrical sidewall and a partition wall disposed within the sidewall proximate the lower end opening; the partition wall divides the central through hole of the second conductive piece into an upper hole part, the upper hole part is communicated with the upper end opening of the side wall, the side wall is provided with an air inlet which is used for communicating the upper hole part with the outer side, and the air inlet, the upper hole part and the upper end opening form an air inlet channel together.
18. The nebulizer of claim 17, wherein the partition wall further partitions the central through hole into a lower hole portion separate from the upper hole portion, the lower hole portion communicating with the lower end opening, and the other end of the elastic member is inserted into the lower hole portion and abuts against the partition wall.
19. The nebulizer of claim 17, wherein the outer surface of the sidewall further comprises a radially extending flange at a lower end edge thereof, the flange extending into the first electrically conductive member, the first electrically conductive member comprising a neck portion preventing the flange from disengaging from the first electrically conductive member.
20. The atomizer according to claim 9, wherein said main pipe comprises a first pipe section coupled to said base and a second pipe section axially detachably connected to an upper end of said first pipe section and electrically connected to said first pipe section, and said atomizing assembly is elastically connected between said electrode connecting means and said second pipe section and electrically connected to said second pipe section.
21. The atomizer of claim 20, wherein the first tube segment comprises a middle tube segment, wherein a sidewall of the middle tube segment defines a receiving chamber for receiving the atomizing assembly, and wherein at least one fluid inlet hole is formed in the sidewall of the middle tube segment to communicate the receiving chamber with an outside.
22. The nebulizer of claim 21, wherein the nebulizing body further comprises an insulating support disposed on top of the base and closely surrounding the electrode connecting device; the insulating support is positioned at the lower side of the at least one liquid inlet hole.
23. The atomizer of claim 22, wherein said first tube segment comprises a lower tube segment sleeved on an upper end of said base, and a step pressed against said insulating support member is formed between said lower tube segment and said middle tube segment.
24. The atomizer of claim 22, wherein said first tube section includes an upper tube section connected to an upper end of said middle tube section, an outer side wall surface of said upper tube section being formed with an external thread structure for threaded engagement of said second tube section.
25. The nebulizer of claim 20, wherein the second tube segment comprises a cap portion, the cap portion comprising a top wall, a central portion of the top wall defining an up-and-down vent; the lower surface of the top wall is also provided with a contact ring, the contact ring surrounds the vent hole and extends into the first pipe section to be electrically connected with the upper end of the atomization assembly in an abutting mode.
26. The atomizer of claim 25, wherein said second tube segment includes an air guide coupled to a top surface of said top wall and in communication with said vent aperture, said air guide including a non-circular air guide aperture.
27. The nebulizer of claim 25, wherein the cap portion comprises a cylindrical sidewall having an inner wall surface formed with an internal thread structure that mates with the external thread structure of the first tube segment, and an outer wall surface formed with an anti-slip thread structure.
28. The atomizer of claim 9, wherein the atomizing assembly comprises a longitudinally disposed cylindrical atomizing core, the atomizing core comprises a cylindrical porous body, a heating element disposed on an inner wall surface of the porous body, a first electrode portion disposed on an upper end surface of the porous body and electrically connected to an upper end of the heating element, and a second electrode portion disposed on a lower end surface of the porous body and electrically connected to a lower end of the heating element, the first electrode portion is in electrical contact with the main pipe, and the second electrode portion is in electrical contact with the electrode connecting device.
29. The atomizer of claim 9, wherein said atomizing assembly comprises a longitudinally disposed cylindrical atomizing core, said electrode connecting means comprising a second electrically conductive member supported at a lower end of said atomizing core, said second electrically conductive member including a cylindrical upper end having an inner diameter and an outer diameter adapted to the inner diameter and outer diameter, respectively, of the lower end of said atomizing core.
30. An electronic atomisation device comprising an atomiser as claimed in any one of claims 9 to 29 and a power supply means.
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