CN218635309U - Atomizer - Google Patents

Abstract

An atomizer is disclosed. The atomizer includes a housing, an atomizing assembly, and a battery assembly. The atomization component part is arranged in the shell and comprises a main body and a contact part, the contact part is arranged at one end of the main body, and two electrodes are arranged in the contact part in a penetrating mode. The battery pack is arranged in the shell and comprises a body and ejector pins, the body and the contact part are arranged oppositely, and at least three ejector pins are arranged on one side, close to the contact part, of the body. One of the two electrodes is arranged corresponding to at least one thimble, and the other of the two electrodes is arranged corresponding to the rest thimbles. The electrodes are respectively abutted with the corresponding thimbles so as to electrically connect the atomization assembly with the battery assembly. Through the mode, the fault tolerance rate of atomizer assembly can be increased.

Description

Atomizer

Technical Field

The application relates to the technical field of atomization devices, in particular to an atomizer.

Background

With the continuous acceleration of life rhythm and the upgrading of consumption. The disposable nebulizer gradually comes into the field of view of the consumer. The disposable atomizer is more convenient to use. However, after the disposable atomizer is used, there are still resources such as batteries that can be reused. To reduce waste of resources, disposable atomizers are usually recyclable. The disposable atomizer is at the in-process of assembly, and when battery pack's thimble and atomization component's electrode were connected, problems such as contact dislocation or contact unstability might take place, and the fault-tolerant rate of assembly is lower.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides an atomizer, can increase the fault-tolerant rate of atomizer assembly.

The embodiment of the application provides an atomizer. The atomizer includes shell, atomization component and battery pack. The atomization component part is arranged in the shell and comprises a main body and a contact part, the contact part is arranged at one end of the main body, and two electrodes are arranged in the contact part in a penetrating mode. The battery pack is arranged in the shell and comprises a body and ejector pins, the body and the contact part are arranged oppositely, and at least three ejector pins are arranged on one side, close to the contact part, of the body. One of the two electrodes is arranged corresponding to at least one thimble, and the other of the two electrodes is arranged corresponding to the rest thimbles. The electrodes are respectively abutted with the corresponding thimbles so as to electrically connect the atomizing assembly and the battery assembly.

The beneficial effect of this application is: unlike the prior art, the atomizing assembly can store an atomizing substrate and can atomize the atomizing substrate into an aerosol. The battery pack can store electric energy, and after the battery pack is electrically connected with the atomizing assembly, the battery pack can provide energy required by functions such as atomization for the atomizing assembly. The housing is capable of mounting the atomizing assembly and the battery assembly. The electrode that the contact site of atomization component wore to establish is used for the thimble butt that sets up with the battery pack casing to be connected battery pack and atomization component electricity. The battery pack is provided with at least three ejector pins, so that at least one electrode can be arranged corresponding to at least two ejector pins, the butting of the electrode and the ejector pins can be realized through more than one ejector pin, the fault tolerance rate of the electric connection of the electrode and the ejector pins during assembly can be increased, and the fault tolerance rate of the assembly of the atomizer can be increased.

Drawings

FIG. 1 is a schematic diagram of an embodiment of an atomizer according to the present application;

FIG. 2 is a schematic disassembled view of an embodiment of the atomizer shown in FIG. 1;

FIG. 3 is a schematic cross-sectional view of the atomizer shown in FIG. 1;

FIG. 4 is a schematic structural view of the atomization assembly of FIG. 2;

FIG. 5 is a schematic view of the structure of the battery pack of FIG. 2;

FIG. 6 is a schematic cross-sectional view of the battery assembly shown in FIG. 5;

fig. 7 is an exploded view of the battery module shown in fig. 5.

FIG. 8 is a schematic diagram of the structure of the electrode of FIG. 4;

FIG. 9 is a schematic structural view of the thimble shown in FIG. 6.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

In the research process, the inventor of the present application finds that the consumption demand of the user for the disposable electronic cigarette gradually increases. The disposability of the disposable nebulizer, however, primarily resides in the disposability of the nebulized matrix, the internal components of which, such as the battery, are not disposable components. Therefore, after the atomizer is used, in order to reduce resource waste and save cost, manufacturers can recycle the internal elements of the disposable atomizer. Therefore, the disposable atomizer has a demand for, for example, detachability or mounting stability during the structural design and manufacture.

In contrast to the prior art, the present application may provide the following embodiments regarding the atomizer 1. Based on the above technical background, the atomizer 1 in the embodiment of the atomizer 1 of the present application is a disposable atomizer 1, and the detachable scheme described in the embodiment mainly aims at the scheme design detached when a manufacturer recovers, and generally does not suggest nor require a user to detach the atomizer 1 by himself.

Referring to fig. 1 and 2, an exemplary structure of the atomizer 1 is described in the embodiment of the atomizer 1 of the present application. The atomizer 1 includes a housing 30, an atomizing assembly 20, and a battery assembly 10. Housing 30 is configured to receive atomization assembly 20 and battery assembly 10, and housing 30 may also be held by a user.

Referring to fig. 3 and 4, atomization assembly 20 is partially disposed within a housing 30. The atomizing assembly 20 is capable of storing an atomizing substrate and atomizing the atomizing substrate into an aerosol for use by a user. The atomizing assembly 20 includes a main body 21 and a contact portion 22. The main body 21 includes a cylindrical inner channel member 212 and an outer channel member 211 sleeved outside the inner channel member 212. The inner channel member 212 and the outer channel member 211 are provided with a liquid storage space at an interval. The reservoir space may store the nebulized substrate, or the reservoir space may be used to mount a liquid cotton 214, and the liquid cotton 214 may store the nebulized substrate. The inner and outer channel members 212 and 211 are provided at opposite ends thereof with seals 215, respectively, the seals 215 being at least partially disposed between the inner and outer channel members 212 and 211 to seal the liquid storage space.

The inner passage member 212 has an air passage 213, and the inner passage member 212 is provided with a through hole communicating the liquid storage space and the air passage 213. A heating assembly 24 is disposed in the air passage 213, the heating assembly 24 is disposed at the through hole, and the aerosol substrate in the reservoir space can flow through the through hole to the heating assembly 24. The heating assembly 24 is capable of heating the nebulized substrate to nebulize it into an aerosol that is capable of flowing within the airway 213. Specifically, the heating assembly 24 includes a liquid-conductive cotton 241, a heater 242, and a pin 243. The liquid guide cotton 241 is arranged at the through hole of the inner channel piece 212 to seal the through hole and reduce liquid leakage. The heater 242 is disposed inside the liquid guide cotton 241, the liquid guide cotton 241 can guide the atomized substrate to the heater 242, and the heater 242 can heat and atomize the atomized substrate into aerosol. The pin 243 is electrically connected to the heater 242. Pins 243 may be connected to the electrodes to power the heater 242.

The same end of the inner channel piece 212 and the outer channel piece 211 is provided with a suction nozzle 25, the suction nozzle 25 is provided with an air outlet channel 251 communicated with the air channel 213, and aerosol in the air channel 213 can be discharged through the air outlet channel 251 for users to use. Optionally, a side of the sealing member 215 near one end of the suction nozzle 25 facing the suction nozzle 25 is embedded with a liquid absorbent cotton 216. Since there may be incomplete atomization of the aerosolized substrate and condensation of the aerosol may also occur during flow, there may be liquid residue when the aerosol is discharged from the outlet channel 251. The setting of oil absorption cotton can be with liquid absorption to reduce the residue of liquid at gas outlet 251, in order to promote user experience.

Referring further to fig. 4, the contact portion 22 is disposed at one end of the main body 21, and the contact portion 22 is disposed at a side of the inner channel member 212 and the outer channel member 211 away from the suction nozzle 25 and at a side of the sealing member 215 away from the suction nozzle 25. The contact portion 22 is provided with an electrode 23, and the electrode 23 can be electrically connected to the lead 243 of the heating element 24. Alternatively, the contact portion 22 may also function as a seal, or the contact portion 22 may be the same piece as the seal 215 adjacent thereto.

Referring to fig. 5 and 6, the battery assembly 10 includes a body 100 and a thimble 120, the body 100 is disposed opposite to the contact portion 22, and the thimble 120 is disposed on a side of the body 100 close to the contact portion 22. The body 100 includes a case 110 and a battery 160, the battery 160 is detachably mounted to the case 110, and the case 110 is detachably mounted to the outer case 30. The thimble 120 is disposed through the housing 110 near the contact portion 22, and is electrically connected to the battery 160. Optionally, with reference to fig. 2 and fig. 3, the body 100 and the contact portion 22 are disposed at an interval, and an accommodating gap 40 is provided therebetween, and a part of the thimble 120 is embedded in the body 100, and another part of the thimble is accommodated in the accommodating gap 40. Spike 120 is electrically connected to battery 160 and is capable of electrically connecting to electrode 23 to provide power to atomization assembly 20 when atomization assembly 20 and battery assembly 10 are in place within housing 30. Housing 110 is spaced from contact 22 so that battery assembly 10 and atomization assembly 20 may be manufactured and recycled relatively independently. And the thimble 120 is partially accommodated in the accommodating gap 40, which is beneficial to the contact between the electrode 23 and the thimble 120, reduces the possibility of virtual connection between the electrode 23 and the thimble 120, and increases the stability of connection between the two.

In some embodiments, a magnet is embedded in a side of the housing 110 near the contact portion 22. The material of the electrode 23 may be ferromagnetic, in other words, the electrode 23 can generate an interaction force with the magnet. When the battery assembly 10 and the atomizing assembly 20 are mounted in place in the housing 30, the projection of the electrode 23 on the housing 110 covers the thimble 120 and the magnet. The projection of the electrode 23 covering the thimble 120 enables the electrode 23 to abut against and electrically conduct with the thimble 120. The projection of the electrode 23 covers the magnet, so that a stable and strong magnetic attraction force is generated between the magnet and the electrode 23. Alternatively, the magnet may be a shaped magnet to increase the area of the magnet corresponding to the electrode 23 by changing the shape, thereby increasing the magnetic attraction force of the two. By providing magnets corresponding to electrodes 23 on housing 110, battery assembly 10 and atomizing assembly 20 can have a tendency to move closer to each other when battery assembly 10 and atomizing assembly 20 are mounted in place within housing 30, thereby making the mounting of the two more stable. In addition, the arrangement can increase the pressure when the electrode 23 and the thimble 120 are abutted, thereby increasing the stability of the electrical connection between the electrode 23 and the thimble 120. The structure of the battery assembly 10 and the atomizing assembly 20 can be simplified by increasing the mounting stability through magnetic attraction, and the use of a fixing structure is reduced. This allows the battery pack 10 to be easily removed against the magnetic attraction between the magnet and the electrode 23 when the nebulizer 1 is removed.

Referring to fig. 4 and 5, the contact portion 22 is penetrated by two electrodes 23. The body 100 is disposed opposite to the contact portion 22, and at least three pins 120 are disposed on a side of the body 100 close to the contact portion 22. One of the two electrodes 23 is disposed corresponding to at least one of the needles 120, and the other of the two electrodes 23 is disposed corresponding to the remaining needles 120. The electrodes 23 abut against the corresponding ejector pins 120, respectively, to electrically connect the atomizing assembly 20 and the battery assembly 10. The thimble 120 can be connected to the positive electrode or the negative electrode of the battery 160.

The arrangement is such that at least one electrode 23 can be arranged corresponding to at least two ejector pins 120, and when the battery assembly 10 and the atomizing assembly 20 are both assembled to the housing 110, the electrode 23 can be electrically connected with more than one ejector pins 120. Any one thimble 120 of the at least two thimbles 120 is abutted against the corresponding electrode 23, so that the at least two thimbles can be electrically conducted, and the fault tolerance of the electrical conduction of the electrode 23 and the thimble 120 is increased.

In an embodiment, referring to fig. 4 and 5, the number of the pins 120 is three, and one electrode 23 of each pin corresponds to one pin 120 of the pins. In this way, the electrode 23 and the thimble 120 can be electrically conducted by normal contact therebetween. The other electrode 23 is disposed corresponding to the other two pins 120. Thus, the electrode 23 can correspond to the two pins 120, and the electrode 23 and the pins 120 can be electrically conducted by contacting either of the two pins 120 with the electrode 23. Therefore, the fault tolerance rate of the abutting of the electrode 23 and the thimble 120 can be increased, so that the stability of the electrical connection between the electrode and the thimble is increased, and the working stability of the atomizer 1 is further increased. In addition, in the embodiment, the number of the electrodes 23 and the ejector pins 120 is set, so that the space of the battery assembly 10 and the atomization assembly 20 is reasonably utilized, and the purpose of improving the working stability of the atomizer 1 by using a smaller space is achieved.

Among them, referring to fig. 8, the electrodes 23 corresponding to the two ejector pins 120 may include a connecting portion 231 and a flange portion 232 connected to each other. The connection portion 231 is inserted into the contact portion 22, and the connection portion 231 can be brought into contact with the lead 243 of the heating unit 24 to electrically conduct the two. The flange portion 232 is fitted to the contact portion 22 on the side closer to the battery pack 10. The flange portion 232 is provided corresponding to the thimble 120. The flange portion 232 can increase the area of the electrode 23 projected onto the battery module 10, and can facilitate the contact between the thimble 120 and the electrode 23. The flange portion 232 of at least one electrode 23 includes an abutting portion 232a connected to the connecting portion 231 and an extending portion 232b extending from the abutting portion 232 a. The extending portion 232b is disposed corresponding to the at least one needle 120, and the abutting portion 232a is disposed corresponding to the at least one needle 120. The extended portion 232b and the contact portion 232a are provided so that the thimble 120 can be brought into contact with the electrode 23 even at a relatively long interval. And the thimble 120 can abut on different positions of the electrode 23. That is, even if a partial region of the electrode 23 fails, another partial region can conduct electricity, so that the fault tolerance of the electrical connection between the electrode 23 and the thimble 120 can be further increased.

In an embodiment, referring to fig. 6, the body 100 further includes a first circuit board 131 disposed between one end of the battery 160 close to the atomizing assembly 20 and the housing 110, and a second circuit board 132 disposed between the other end of the battery 160 and the housing 110, wherein the first circuit board 131 and the second circuit board 132 are electrically connected.

Referring to fig. 6 and 7, the specific structure of the housing 110 can be seen in the following exemplary description. The housing 110 includes a receiving portion 113 and a first end portion 111 and a second end portion 112 respectively disposed at both ends of the receiving portion 113. The accommodating portion 113 and the first and second end portions 111 and 112 enclose an accommodating cavity 113a, and the battery 160 is detachably disposed in the accommodating cavity 113 a. The first end portion 111 is disposed at one end of the accommodating portion 113 close to the contact portion 22, the second end portion 112 is disposed at the other end of the accommodating portion 113, and the thimble 120 penetrates through the first end portion 111 and is electrically connected to the battery 160. This arrangement allows the battery pack 10 to be assembled into a single unit so as to be easily attached to and detached from the housing 30. And the battery 160 and the housing 110 of the battery assembly 10 can be conveniently disassembled, so that the atomizer 1 can be conveniently disassembled from the battery assembly 10 in the recycling process.

The first end portion 111 and the second end portion 112 are sleeved with a sealing ring 140, when the battery assembly 10 is installed in the outer shell 30, the sealing ring 140 is located in a gap between the casing 110 and the outer shell 30, and the sealing ring 140 is in interference fit with the gap. By the arrangement, the battery assembly 10 can be stably installed in the shell 30, axial movement of the shell 30 is reduced, and installation stability is improved.

Further, the outer side surface of the accommodating portion 113 is provided with a plurality of abutting pads 113b at intervals in the longitudinal direction of the accommodating portion 113 so as to abut against the inner wall of the housing 30. With this arrangement, the case 110 can be stably abutted against the case 30, so that the vibration after the battery assembly 10 is mounted can be reduced, and the mounting stability can be further increased.

The second end portion 112 is provided with an air inlet channel 112a, the air inlet channel 112a communicates with the accommodating cavity 113a and the outside, the first end portion 111 is provided with an air outlet channel 111a (see fig. 3), and the air outlet channel 111a communicates with the accommodating cavity 113a and the accommodating gap 40. The second end portion 112 is partially disposed beyond the housing 30 so that the intake passage 112a can communicate with the outside. When the battery assembly 10 is mounted in the housing 30, the receiving cavity 113a and the housing 30 can form a channel, and the air inlet channel 112a and the air outlet channel 111a can communicate with the channel. With this arrangement, the external gas can sequentially enter the accommodating gap 40 through the inlet passage 112a, the accommodating cavity 113a and the outlet passage 111 a.

Further, the contact portion 22 is pierced with an air flow passage. The air flow passage communicates the accommodation gap 40 with the air passage 213 of the main body 21. Thus, external air can flow into the atomizing assembly 20 through the battery assembly 10, and the aerosol atomized by the atomizing assembly 20 is discharged from the outlet channel 251.

In one embodiment, referring to fig. 3, the side of the contact portion 22 near the first end portion 111 has an air inlet hole 221 communicating with the air flow channel. The side surface of the first end portion 111 close to the contact portion 22 is provided with an air outlet hole 111b communicated with the air outlet channel 111a, and the air inlet hole 221 and the air outlet hole 111b are arranged in a staggered manner. With such an arrangement, the air outlet hole 111b and the air inlet hole 221 are indirectly communicated through the accommodating gap 40 rather than directly aligned, so that the liquid generated due to incomplete atomization and condensation of the atomized matrix cannot directly flow from the air flow channel to the air outlet channel 111a, and the problem of failure caused by wetting of the liquid on the electronic components in the battery assembly 10 is reduced.

Further, a liquid containing groove 111c is concavely arranged on the side surface of the first end portion 111 close to the contact portion 22 towards the direction far away from the contact portion 22. The liquid containing groove 111c can store a certain amount of liquid, thereby further reducing the possibility of liquid entering into the battery assembly 10. For the disposable atomizer 1, the amount of the liquid generated is not excessive, and the liquid containing groove 111c does not need to be cleaned specially when the user uses the atomizer. Thus, the liquid containing groove 111c can conveniently and effectively reduce the influence of the condensate on the atomizer 1 in the disposable service cycle. The structure in the present embodiment can also facilitate cleaning and recycling when recycling the atomizer 1.

Referring to fig. 7, the first circuit board 131 is disposed between the first end portion 111 and the battery 160, and the second circuit board 132 is disposed between the second end portion 112 and the battery 160. The first circuit board 131 is provided with a first communication hole 131a for communicating the air outlet channel 111a with the accommodating chamber 113a, and the second circuit board 132 is provided with a second communication hole 132a for communicating the air inlet channel 112a with the accommodating chamber 113 a. The first circuit board 131 and the second circuit board 132 are electrically connected to the positive electrode or the negative electrode of the battery 160, respectively, the first circuit board 131 and the second circuit board 132 are electrically connected, and one end of the thimble 120 close to the battery 160 is electrically connected to the first circuit board 131. The first circuit board 131 and the second circuit board 132 are disposed to electrically connect two poles of the battery 160 to the same circuit board, so that the thimble 120 can be indirectly connected to the positive and negative poles of the battery 160 by being connected to the first circuit board 131. Alternatively, the battery 160 in the battery assembly 10 is a rechargeable battery 160, and the first circuit board 131 and the second circuit board 132 may be provided with rechargeable units thereon. When the atomizer 1 is recycled by a manufacturer, the battery pack 10 can be effectively reused by detaching the battery pack 10 and then charging the battery pack, and complicated recycling processes such as the detachment of the battery pack 10 can be reduced.

Referring to fig. 9, an exemplary structure of the thimble 120 is described based on the above description. The thimble 120 includes a mounting portion 123, a terminal portion 121, and a plugging portion 122. The mounting portion 123 is disposed through the housing 110, the terminal portion 121 is located at one end of the mounting portion 123 close to the contact portion 22, and the inserting portion 122 is located at one end of the mounting portion 123 close to the battery 160 and electrically connected to the first circuit board 131.

Further, the mounting portion 123 includes a through portion 123b and an embedding portion 123a connected to each other, and the embedding portion 123a is embedded in a side of the housing 110 close to the contact portion 22 and connected to the terminal portion 121. The insertion portion 123b is inserted into the housing 110 and connected to the insertion portion 122. By such arrangement, the mounting stability of the thimble 120 can be increased, and the axial movement of the thimble can be reduced. Alternatively, the terminal portion 121 may be movably disposed at the mounting portion 123. The terminal portion 121 may be movably disposed on the mounting portion 123 by an elastic member, so that a pressure when the electrode 23 and the thimble 120 abut against each other can be increased to increase stability of electrical connection.

In summary, the atomizing assembly 20 can store an atomizing substrate and can atomize the atomizing substrate into an aerosol. Battery assembly 10 is capable of storing electrical energy and, when electrically connected to atomizing assembly 20, is capable of providing atomizing assembly 20 with the energy necessary for such functions as atomization. Housing 30 can accommodate attachment of atomization assembly 20 and battery assembly 10. The electrode 23 through which the contact portion 22 of the atomizing assembly 20 is inserted is adapted to abut against the thimble 120 provided in the case 110 of the battery assembly 10, so as to electrically connect the battery assembly 10 and the atomizing assembly 20. The battery assembly 10 is provided with at least three ejector pins 120, so that at least one electrode 23 can be arranged corresponding to at least two ejector pins 120, the electrode 23 can be abutted against the ejector pins 120 through more than one ejector pin 120, the fault tolerance rate of the electric connection of the electrode 23 and the ejector pin 120 during assembly can be increased, the connection stability of the electrode 23 and the ejector pin 120 can be increased, and the working stability of the atomizer 1 can be further increased.

The above embodiments are merely examples, and not intended to limit the scope of the present application, and all modifications, equivalents, and flow charts using the contents of the specification and drawings of the present application, or those directly or indirectly applied to other related arts, are included in the scope of the present application.

Claims (10)

1. An atomizer, comprising:

a housing;

the atomization assembly is partially arranged in the shell and comprises a main body and a contact part, the contact part is arranged at one end of the main body, and two electrodes are arranged on the contact part in a penetrating manner;

the battery component is arranged in the shell and comprises a body and ejector pins, the body is arranged opposite to the contact part, and at least three ejector pins are arranged on one side of the body close to the contact part; one of the two electrodes is arranged corresponding to at least one thimble, the other of the two electrodes is arranged corresponding to the rest of the thimbles, and the electrodes are respectively abutted against the corresponding thimbles so as to electrically connect the atomization assembly and the battery assembly.

2. The nebulizer of claim 1, wherein:

the body and the contact part are arranged at intervals, an accommodating gap is formed between the body and the contact part, one part of the thimble is embedded in the body, and the other part of the thimble is accommodated in the accommodating gap.

3. A nebulizer as claimed in claim 1, wherein:

the electrode comprises a connecting part and a flange part which are connected with each other, the connecting part is arranged on the contact part in a penetrating way, and the flange part is embedded on one side of the contact part close to the battery component; the flange part is arranged corresponding to the ejector pin, the flange part of at least one electrode comprises a butting part connected with the connecting part and an extending part extending from the butting part, the extending part is arranged corresponding to at least one ejector pin, and the butting part is arranged corresponding to at least one ejector pin.

4. The nebulizer of claim 1, wherein:

the number of the thimbles is three, one of the electrodes is arranged corresponding to one of the thimbles, and the other electrode is arranged corresponding to the other two thimbles.

5. The nebulizer of claim 1, wherein:

the body includes casing and battery, battery detachably install in the casing, casing detachably install in the shell, the thimble wears to locate the casing is close to one side of contact site, and with the battery electricity is connected.

6. The nebulizer of claim 5, wherein:

the side face of the shell close to the contact part is provided with a liquid containing groove in a concave mode towards the direction far away from the contact part.

7. The nebulizer of claim 5, wherein:

the body still including set up in the battery is close to the one end of atomization component with first circuit board between the casing, and set up in the other end of battery with second circuit board between the casing, first circuit board with the second circuit board electricity is connected.

8. The nebulizer of claim 7, wherein:

the thimble includes installation department, terminal part and grafting portion, the installation department wears to establish the casing setting, the terminal part is located the installation department is close to the one end of contact site, grafting portion is located the installation department is close to the one end of battery, and with first circuit board electricity is connected.

9. The nebulizer of claim 8, wherein:

the installation department includes the portion of establishing of wearing to establish and inlays the portion of establishing that connects each other, inlay the portion of establishing and inlay and locate the casing is close to one side of contact site, and with the terminal part is connected, wear to establish the portion and wear to locate the casing, and with grafting portion connects.

10. The nebulizer of claim 8, wherein:

the terminal portion is movably disposed at the mounting portion.

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