CN220675165U - Atomizing device and atomizing equipment - Google Patents

Abstract

In one aspect of the utility model, an atomization device is disclosed, a effusion cavity for receiving condensate and an air suction channel communicated with an external space are formed in the atomization device, an auxiliary atomization assembly is arranged in the effusion cavity, the auxiliary atomization assembly is used for atomizing condensate in the effusion cavity, and the effusion cavity is communicated with the air suction channel. Another aspect of the utility model discloses an atomizing apparatus employing the above atomizing device. In the working process of the atomization device, the primary tobacco juice is heated through the main atomization component, and the condensate in the liquid accumulation cavity is heated through the auxiliary atomization component, so that when the atomization device is adopted by a user, the smoke converted from the primary tobacco juice can be absorbed, the smoke converted from the condensate can be absorbed, and the tobacco juice utilization rate of the atomization device is improved.

Description

Atomizing device and atomizing equipment

Technical Field

The utility model relates to the technical field of atomization equipment, in particular to an atomization device and atomization equipment for improving the utilization rate of smoke liquid.

Background

The atomizing device generally comprises an atomizing device and a power supply device for supplying electric energy to the atomizing device, wherein an air flow channel and a negative pressure channel which are communicated with an air suction channel of the atomizing device are formed in the power supply device, the other end of the air flow channel is communicated with the outside, and the other end of the negative pressure channel is communicated with a containing cavity provided with a microphone. When a user inhales through the inhalation channel of the atomization device, the negative pressure channel and air in the accommodating cavity communicated with the negative pressure channel are pumped away, and the interior of the accommodating cavity is in a negative pressure state, so that a microphone can be triggered. When the microphone is triggered, the power supply of the power supply device and the heating piece of the atomizing device are conducted, so that smoke liquid in the atomizing device is heated to generate smoke, and the smoke flows into the air suction channel of the atomizing device. At the same time, when the user inhales, external air is continuously sucked through the air flow channel, so that an air flow is formed in the air flow channel, and the air flow can carry smoke, so that the smoke is inhaled by the user.

A part of the mist is liquefied by a decrease in temperature, and condensate is generated. The related art atomizer has a liquid accumulation chamber for receiving condensate, but the collected condensate still cannot be used, which reduces the usage rate of smoke liquid.

Disclosure of Invention

The utility model mainly aims to provide an atomization device and atomization equipment, which are used for solving the problem of low smoke liquid utilization rate of the atomization device in the related art.

To achieve the above object, an aspect of the present utility model provides an atomization device, in which a liquid accumulation chamber for receiving condensate and an air suction channel communicating with an external space are formed, an auxiliary atomization assembly is disposed in the liquid accumulation chamber, the auxiliary atomization assembly is used for atomizing condensate in the liquid accumulation chamber, and the liquid accumulation chamber is communicated with the air suction channel.

In some embodiments, the auxiliary atomizing assembly comprises: the auxiliary power connection pin is connected with an electrode of the atomizing device; the auxiliary heating piece is connected with the auxiliary power connection pin; and the auxiliary liquid guide cotton is in contact with the auxiliary heating piece and is made of a heat-resistant material.

In some embodiments, the atomizing chamber of the atomizing device is in communication with the effusion chamber, and a main atomizing assembly is disposed within the atomizing chamber, the main atomizing assembly comprising: one end of the main power connection pin extends to the effusion cavity and is connected with the auxiliary power connection pin; the main heating piece is connected with the power connection pin; the leading liquid cotton is contacted with the heating piece.

In some embodiments, an atomization device comprises: a shell, wherein an air suction pipe for forming an air suction channel is arranged in the shell; the base is connected with the shell in a nested way, and the effusion cavity is formed in the base; the inner tube is used for forming an atomization cavity, one end of the inner tube is connected with the base and communicated with the effusion cavity, and the other end of the inner tube is connected with the air suction pipe in a nested mode.

In some embodiments, the power pins and the auxiliary power pins are constructed as an integrally formed structure.

In some embodiments, a smoke liquid cavity for containing smoke liquid is formed by enclosing an inner wall of the shell, an outer wall of the base, an outer wall of the inner tube and an outer wall of the air suction tube.

Another aspect of the utility model proposes an atomising device comprising an atomising means as described above.

Compared with the prior art, the auxiliary atomizing assembly is additionally arranged in the effusion cavity of the atomizing device. Therefore, in the working process of the atomization device, not only the original smoke liquid is heated through the main atomization component, but also the condensate in the effusion cavity is heated through the auxiliary atomization component, so that when the atomization device is adopted by a user, the smoke converted from the original smoke liquid can be absorbed, the smoke converted from the condensate can be absorbed, and the smoke liquid utilization rate of the atomization device is improved.

Drawings

FIG. 1 is a schematic view of an atomizing apparatus according to an embodiment of the present disclosure;

FIG. 2 is an exploded view of an atomizing apparatus according to an embodiment of the present disclosure;

FIG. 3 is an exploded view of an atomizer device according to an embodiment of the utility model;

fig. 4 is a cross-sectional view of the atomizing device at A-A in fig. 2.

Reference numerals illustrate:

an atomizing device 100; a effusion cell 101; a suction passage 102; an atomizing chamber 103; a smoke liquid chamber 104; a housing 110; an air suction pipe 111; a base 120; an electrode 121; an inner tube 130; a through hole 131; an auxiliary power pin 141; an auxiliary heating member 142; auxiliary liquid-guiding cotton 143; a main power pin 151; a main heating member 152; dominant liquid cotton 153; and a power supply device 200.

Detailed Description

The following description of the embodiments of the present utility model will be made more clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In view of the technical drawbacks existing in the related art, as shown in fig. 1 and 2, the present embodiment provides an atomizing apparatus. The atomizing apparatus includes an atomizing device 100 and a power supply device 200, and the power supply device 200 is used to supply power to the atomizing device 100 and can control the opening and closing of the atomizing device 100, thereby causing the atomizing device 100 to generate smoke to be supplied to a user for suction.

As shown in fig. 4, in the atomizing apparatus according to the present embodiment, a smoke liquid chamber 104, an atomizing chamber 103, and an air intake passage 102 are formed in an atomizing device 100. The smoke liquid cavity 104 is filled with smoke liquid, and the atomization cavity 103 is respectively communicated with the air suction channel 102 and the smoke liquid cavity 104. A main atomization component for atomizing the tobacco liquid is arranged in the atomization cavity 103, and specifically comprises a main power-on pin 151, a main heating element 152 and a main liquid cotton 153. The main electrical pin 151 is electrically connected to the electrode 121 of the atomizing device 100, and the main electrical pin 151 may be directly electrically connected to the electrode 121 or may be electrically connected to the electrode 121 through an additional wire, which is not illustrated herein. The smoke liquid in the smoke liquid chamber 104 flows to the main heating member 152 through the main liquid cotton 153. The primary heating element 152 is operated such that the smoke liquid in contact with the primary heating element 152 is heated and atomized to form smoke, which is sucked by the user through the suction channel 102.

As shown in fig. 4, the atomizing device 100 of the present embodiment further includes a liquid accumulation chamber 101 for receiving condensate. The liquid accumulation chamber 101 may receive condensate through various means, such as a specially provided condensing passage (not shown), or sequentially through the suction passage 102 and the atomizing chamber 103 to the liquid accumulation chamber 101.

The effusion chamber 101 communicates with an air intake passage 102 communicating with the external space. Wherein, be provided with auxiliary atomization subassembly in hydrops chamber 101 of this embodiment, auxiliary atomization subassembly is used for atomizing the condensate in the hydrops chamber 101, makes the condensate heat atomizing, forms smog. In this embodiment, the auxiliary atomizing assembly operates in the same manner as the main atomizing assembly, i.e., the auxiliary atomizing assembly is electrically connected to the electrode 121 of the atomizer device 100, thereby obtaining electrical energy from the power supply 200 for atomizing condensate.

Since the effusion chamber 101 communicates with the inhalation passage 102, the smoke atomized from the condensate can also be sucked by the user through the inhalation passage 102. The beneficial effects of this are that when the atomizing device 100 of this embodiment is adopted by the user, not only the smog converted from the original tobacco juice can be absorbed, but also the smog converted from the condensate can be absorbed, so that the tobacco juice utilization rate of the atomizing device 100 is improved.

With continued reference to fig. 3 and 4, in this embodiment, the auxiliary atomizing assembly includes an auxiliary power pin 141, an auxiliary heating element 142, and an auxiliary liquid-guiding cotton 143. The auxiliary power connection pin 141 is connected to the electrode 121 of the atomizing device 100, the auxiliary heating element 142 is connected to the auxiliary power connection pin 141, and the auxiliary liquid-guiding cotton 143 is in contact with the auxiliary heating element 142. The auxiliary power receiving pin 141 and the auxiliary heating member 142 are each made of a metal material, but the resistivity is different between the auxiliary power receiving pin 141 and the auxiliary heating member 142. Since the auxiliary heating member 142 is used to generate heat by energization to heat the condensate, the resistivity of the auxiliary heating member 142 should be high, and the auxiliary power-receiving pin 141 is used to conduct current to the auxiliary heating member 142, and thus the resistivity of the auxiliary power-receiving pin 141 should be low. In some alternative examples, the auxiliary heating member 142 is made of an iron-chromium-aluminum alloy material, and the auxiliary power receiving pins 141 are made of pure nickel or pure silver material, but is not limited thereto. It should be noted that, the working properties of the main atomizing assembly and the auxiliary atomizing assembly are substantially the same, so the materials of the main power pin 151 and the main heating element 152 of the main atomizing assembly are selected to be the same as those of the auxiliary atomizing assembly, and the description thereof will not be repeated here.

Further, since the condensate in the atomizing device 100 itself is formed by liquefying a part of the smoke after the original smoke liquid is converted into the smoke, the amount of condensate is small relative to the original smoke liquid. Therefore, the condensate is completely atomized by the auxiliary atomizing assembly, or the auxiliary heating member 142 directly heats the auxiliary liquid guiding cotton 143 when the user uses the atomizing device 100 before the condensate is generated. Here, in order to prevent the auxiliary liquid-guiding cotton 143 from being gelatinized by heating, the auxiliary liquid-guiding cotton 143 of the present embodiment is made of a heat-resistant material, such as glass wool, etc., but is not limited thereto.

In this embodiment, the main atomizing assembly and the auxiliary atomizing assembly may be electrically connected to the electrode 121 of the atomizing device 100 through different conductive paths, or may be electrically connected to the electrode 121 of the atomizing device 100 through the same conductive paths, that is, the main power connection pin 151 and the auxiliary power connection pin 141 may be connected to the electrode 121, or may be constructed as an integrally formed structure and connected to the electrode 121.

As shown in fig. 3 and 4, in some embodiments, the atomizing chamber 103 of the atomizing device 100 is in communication with the effusion chamber 101, and one end of the main power pin 151 extends to the effusion chamber 101 and is connected to the auxiliary power pin 141, so that the main power pin 151 is connected to the electrode 121 through the auxiliary power pin 141, and thus conducts electricity to the main heating member 152.

With continued reference to fig. 3 and 4, in some embodiments, the atomizing device 100 includes an outer housing 110, a base 120, and an inner tube 130. Wherein, the housing 110 is used for forming the whole framework of the atomizing device 100, and the air suction pipe 111 for forming the air suction channel 102 is arranged in the housing 110. The suction pipe 111 may be a separately formed member or may be integrally formed with the housing 110 (as shown in fig. 4). The base 120 is nested with the housing 110, and the effusion cell 101 is formed within the base 120. The electrode 121 is disposed on a side of the base 120 facing away from the housing 110, and the auxiliary power connection pin 141 passes through the base 120 to be connected with the electrode 121. The inner tube 130 is used for forming the atomizing chamber 103, one end of the inner tube 130 is connected with the base 120 and communicated with the effusion chamber 101, and the other end is connected with the air suction pipe 111 in a nested manner, so that the effusion chamber 101 and the air suction channel 102 are communicated with each other.

Further, in order to improve the internal compactness of the atomizing device 100, as shown in fig. 3 and 4, a smoke chamber 104 containing smoke is formed by enclosing the inner wall of the housing 110, the outer wall of the base 120, the outer wall of the inner tube 130, and the outer wall of the suction tube 111. The inner tube 130 is provided with a through hole 131 for the smoke liquid to flow to the atomizing chamber 103 through the through hole 131 and be absorbed by the main liquid cotton 153.

The above description of the preferred embodiments of the present utility model should not be taken as limiting the scope of the utility model, but rather should be understood to cover all modifications, variations and adaptations of the present utility model using its general principles and the following detailed description and the accompanying drawings, or the direct/indirect application of the present utility model to other relevant arts and technologies.

Claims (4)

1. An atomization device, wherein a effusion cavity (101) for receiving condensate and an air suction channel (102) communicated with an external space are formed in the atomization device, and the atomization device is characterized in that an auxiliary atomization assembly is arranged in the effusion cavity (101) and is used for atomizing the condensate in the effusion cavity (101), and the effusion cavity (101) is communicated with the air suction channel (102);

the auxiliary atomizing assembly includes:

an auxiliary power connection pin (141) connected with an electrode (121) of the atomizing device;

an auxiliary heating element (142) connected to the auxiliary power connection pin (141);

an auxiliary liquid-guiding cotton (143) in contact with the auxiliary heating member (142), the auxiliary liquid-guiding cotton (143) being made of a heat-resistant material;

atomizing cavity (103) of atomizing device with hydrops chamber (101) intercommunication, be provided with main atomizing subassembly in atomizing cavity (103), main atomizing subassembly includes:

a main power connection pin (151) with one end extending to the effusion cavity (101) and connected with the auxiliary power connection pin (141);

a main heating element (152) connected to the main power pin (151);

a main liquid cotton (153) in contact with the main heating member (152);

the main power pin (151) and the auxiliary power pin (141) are constructed as an integrally molded structure.

2. An atomising device according to claim 1 characterised in that the atomising device comprises:

a housing (110), wherein an air suction pipe (111) for forming the air suction channel (102) is arranged in the housing (110);

a base (120) in nested connection with the housing (110), the liquid accumulation cavity (101) being formed in the base (120);

and the inner tube (130) is used for forming the atomizing cavity (103), one end of the inner tube (130) is connected with the base (120) and communicated with the effusion cavity (101), and the other end of the inner tube is connected with the air suction tube (111) in a nested manner.

3. An atomizer device according to claim 2, characterized in that a smoke liquid chamber (104) for holding smoke liquid is enclosed between the inner wall of the housing (110), the outer wall of the base (120), the outer wall of the inner tube (130) and the outer wall of the suction tube (111).

4. An atomizing apparatus comprising an atomizing device according to any one of claims 1 to 3.