CN210054636U - Fiber type gas mist generating device - Google Patents

Abstract

The utility model provides a fibrous type aerial fog generating device, including high temperature resistant non-insulating fiber and high temperature resistant insulating fiber, high temperature resistant non-insulating fiber and high temperature resistant insulating fiber are stratiform or cross distribution. The fiber type aerosol generating device has the characteristics of oil guiding and heating atomized tobacco tar, namely the saturated adsorption capacity and the liquid adsorption/precipitation rate of liquid can be adjusted, the resistivity of the fiber type aerosol generating device can be adjusted, and the resistivity of the fiber type aerosol generating device can be adjusted to be matched with a power control device in a more optimized mode).

Description

Fiber type gas mist generating device

Technical Field

The utility model relates to a fibrous type aerial fog generates device.

Background

At present, an electronic cigarette, also called an aerosol production device, is used, which comprises an atomizer, an oil bin, a battery, a control assembly, wherein the control assembly is connected with the battery, the control assembly is also connected with the atomizer and controls the working mode of the atomizer, the oil bin provides a source for the atomizer to continuously atomize the tobacco tar, the atomizer comprises an oil guide cotton and a heating wire, the oil guide cotton adsorbs the tobacco tar in the oil bin, the heating wire atomizes the tobacco tar adsorbed by the oil guide cotton for human suction, the division design of the heating wire and the oil guide cotton is that the oil guide cotton is responsible for guiding the oil, and the heating wire is responsible for heating and atomizing the tobacco tar, because the oil guide cotton can guide the oil in a certain amount, when the heating wire has too high power, the oil guide cotton has insufficient oil guide, the heating wire burns dry heating, so that some harmful substances are easily volatilized, or the oil guide cotton burns, if the power of the heating wire is too low, the oil frying phenomenon easily occurs, and along with the change of temperature, the resistance value of the heating wire is changed at any moment, so that the impedance of the heating wire is difficult to control.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome prior art's defect, provide a fibre type aerial fog generating device, it has can lead oil, can generate heat again, high temperature uses the requirement that accords with health, and nontoxic harmless characteristic during the use.

The utility model discloses a realize like this: a fibrous aerosol-generating device comprising:

the high-temperature-resistant non-insulating fibers and the high-temperature-resistant insulating fibers are distributed in a layered or crossed manner.

Further, the high-temperature-resistant non-insulating fibers comprise high-temperature-resistant conductor fibers and/or high-temperature-resistant semiconductor fibers, the high-temperature-resistant conductor fibers form a high-temperature-resistant conductor fiber layer, the high-temperature-resistant semiconductor fibers form a high-temperature-resistant semiconductor fiber layer, the high-temperature-resistant insulating fibers form a high-temperature-resistant insulating fiber layer, and at least two layers of the high-temperature-resistant conductor fiber layer, the high-temperature-resistant semiconductor fiber layer and the high-temperature-resistant insulating fiber layer are arranged adjacently and distributed in a layered manner.

Furthermore, at least two layers of the high-temperature-resistant conductor fiber layer, the high-temperature-resistant semiconductor fiber layer and the high-temperature-resistant insulating fiber layer are distributed in a layered manner by hot pressing or physical mixing.

Further, the high-temperature-resistant non-insulating fibers comprise high-temperature-resistant conductor fibers and/or high-temperature-resistant semiconductor fibers, and at least two of the high-temperature-resistant conductor fibers, the high-temperature-resistant semiconductor fibers and the high-temperature-resistant insulating fibers are blended in a crossed mode to form the fiber type aerosol generating device.

A fibrous aerosol-generating device comprising:

the high-temperature resistant metal material is made into high-temperature resistant metal fibers, and the high-temperature resistant non-metal material is made into high-temperature resistant non-metal fibers; the high-temperature resistant metal fibers and the high-temperature resistant nonmetal fibers are mixed and distributed in a layered or crossed manner.

Further, when the high-temperature-resistant metal fibers and the high-temperature-resistant nonmetal fibers are distributed in a layered manner, the high-temperature-resistant metal fibers form a high-temperature-resistant metal fiber layer, the high-temperature-resistant nonmetal fibers form a high-temperature-resistant nonmetal fiber layer, and the high-temperature-resistant metal fiber layer and the high-temperature-resistant nonmetal fiber layer are arranged adjacently.

Further, when the high-temperature resistant metal fibers and the high-temperature resistant non-metal fibers are in cross distribution, the high-temperature resistant metal fibers and the high-temperature resistant non-metal fibers are in cross blending distribution.

The utility model provides a fiber type aerial fog generating device, which comprises at least two layers of high temperature resistant conductor fiber layer, high temperature resistant semiconductor fiber layer and high temperature resistant insulating fiber layer which are adjacently arranged and distributed in a layered way; or the fiber type aerosol generating device comprises at least two cross blending of high temperature resistant conductor fiber, high temperature resistant semiconductor fiber and high temperature resistant insulating fiber. The fiber type aerosol generating device has the characteristics of oil guiding and heating atomized tobacco tar (the high-temperature resistant conductor fiber, the high-temperature resistant semiconductor fiber and/or the high-temperature resistant insulating fiber are doped (laminated or cross-blended (uniform doping/disordered mixing)) in different proportions (mass ratio/volume ratio)), namely the saturated adsorption quantity and the liquid adsorption/precipitation rate of liquid can be adjusted, the resistivity of the fiber type aerosol generating device is adjusted to be matched with the power control device more optimally), and the fiber type aerosol generating device is nontoxic and harmless, can not volatilize harmful substances under the high-temperature condition, and meets the requirement of human health.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

FIG. 1 is a process flow diagram provided by the present invention;

fig. 2 is a schematic view of the fiber-type aerosol-generating device according to the present invention in a layered distribution;

fig. 3 is an enlarged schematic view of the inside of fig. 2 provided by the present invention;

fig. 4 is a schematic view of the fiber type aerosol generating device provided by the present invention in a three-layered distribution;

fig. 5 is a schematic view of the fiber type aerosol generating device according to the present invention in a two-layer distribution;

FIG. 6 is a schematic view of another embodiment of the fiber type aerosol-generating device according to the present invention

FIG. 7 is a schematic illustration of the first internal configuration of FIG. 6 provided by the present invention;

fig. 8 is a schematic view of the second internal configuration of fig. 6 provided by the present invention;

fig. 9 is a schematic diagram of a third internal configuration of fig. 6 according to the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

As shown in fig. 1 to 9, an embodiment of the present invention provides a fiber type gas mist generating device and a manufacturing method thereof, and a manufacturing method of the fiber type gas mist generating device, which includes the following steps:

a. providing a high-temperature-resistant insulating material and a high-temperature-resistant non-insulating material;

b. preparing a high-temperature-resistant insulating material into high-temperature-resistant insulating fibers, and preparing a high-temperature-resistant non-insulating material into high-temperature-resistant non-insulating fibers;

c. mixing the high-temperature-resistant insulating fiber and the high-temperature-resistant non-insulating fiber and molding by a mold.

High-temperature-resistant insulating materials such as: glass fiber made of glass, ceramic fiber made of ceramic, mineral fiber and the like.

High temperature resistant non-insulating materials such as: such as metal fibers, stainless steel fibers, alloy fibers, titanium fibers, and the like.

The high-temperature resistant insulating fiber and the high-temperature resistant non-insulating fiber are mixed by a doping or blending method. For example, the blended fabric (also referred to as a blending process) is a textile product made by blending two or more different types of fibers as raw materials for forming the fabric into a yarn, and the chemical fibers such as polyester-viscose, polyester-nitrile, and polyester-cotton are blended with other natural fibers such as cotton wool, silk, hemp, and the like to spin the yarn. For example: polyester cotton cloth and polyester wool gabardine. Blended fabrics are also distinguished from blended and interwoven fabrics: the blended fabric is made of the raw materials of the fabric by combining single yarns of two fibers into a folded yarn, wherein the low-elasticity polyester filament yarns are blended with medium-length polyester filaments, and the polyester staple fibers and the low-elasticity polyester filament yarns are blended into the folded yarn. The interwoven fabric is made of raw materials forming two direction systems of the fabric, wherein the raw materials respectively adopt different fiber yarns, and the interwoven fabric comprises Guxiangsatin interwoven with silk and rayon, Nifu woven interwoven with nylon and rayon and the like.

Another way to dope is to mix various fibers, adjust the proportion and quantity of the fibers as required, and control the speed of the fibers, for example, it is simply understood that lines of different colors are doped together.

The high-temperature-resistant non-insulating fibers comprise high-temperature-resistant conductor fibers and high-temperature-resistant semiconductor fibers, and the high-temperature-resistant conductor fibers are exemplified by: such as metal fibers, stainless steel fibers, alloy fibers, titanium fibers, and the like.

The high-temperature resistant conductor fiber is a metal fiber formed by metal or alloy in a high-temperature and oxygen-free environment. High temperature resistant semiconductor fibers are exemplified by: carbon fibers, cotton and hemp fibers, bamboo fibers and the like. The high-temperature-resistant semiconductor fiber is formed by a semiconductor material under a high-temperature and oxygen-free environment.

A fibrous aerosol generating device comprises high-temperature-resistant non-insulating fibers including high-temperature-resistant conductor fibers 11 and/or high-temperature-resistant semiconductor fibers 12, wherein the high-temperature-resistant conductor fibers 11 form a high-temperature-resistant conductor fiber layer 111, the high-temperature-resistant semiconductor fibers 12 form a high-temperature-resistant semiconductor fiber layer 121, the high-temperature-resistant insulating fibers 13 form a high-temperature-resistant insulating fiber layer 131, and at least two of the high-temperature-resistant conductor fiber layer 111, the high-temperature-resistant semiconductor fiber layer 121 and the high-temperature-resistant insulating fiber layer 131 are arranged adjacently and distributed in a layered manner.

At least two of the high temperature resistant conductor fiber layer 111, the high temperature resistant semiconductor fiber layer 121 and the high temperature resistant insulating fiber layer 131 are distributed in a layered manner by hot pressing or physical mixing.

The high-temperature-resistant non-insulating fiber comprises a high-temperature-resistant conductor fiber 11 and/or a high-temperature-resistant semiconductor fiber 12, and at least two of the high-temperature-resistant conductor fiber 11, the high-temperature-resistant semiconductor fiber 12 and the high-temperature-resistant insulating fiber 13 are blended in a crossed mode to form the fiber type aerosol generating device.

A method of making a fibrous aerosol-generating device, comprising the steps of:

a. providing a high-temperature resistant metal material and a high-temperature resistant non-metal material;

b. the high-temperature resistant metal material is made into high-temperature resistant metal fibers, and the high-temperature resistant non-metal material is made into high-temperature resistant non-metal fibers;

c. mixing the high-temperature resistant metal fiber and the high-temperature resistant nonmetal fiber and molding by a mold. (mixing includes homogeneous/disordered mixing, as desired)

A fiber type aerosol generating device is characterized in that high-temperature resistant metal fibers and high-temperature resistant nonmetal fibers are mixed and distributed in a layered or crossed manner, when the high-temperature resistant metal fibers and the high-temperature resistant nonmetal fibers are distributed in a layered manner, the high-temperature resistant metal fibers form a high-temperature resistant metal fiber layer, the high-temperature resistant nonmetal fibers form a high-temperature resistant nonmetal fiber layer, and the high-temperature resistant metal fiber layer and the high-temperature resistant nonmetal fiber layer are adjacently arranged; when the high-temperature resistant metal fibers and the high-temperature resistant nonmetal fibers are in cross distribution, the high-temperature resistant metal fibers and the high-temperature resistant nonmetal fibers are mutually cross blended.

The high temperature resistant metal fiber can be composed of one or two of stainless steel, carbon steel, cast iron, copper, aluminum, nickel, iron-chromium-aluminum alloy, high temperature alloy, aluminum oxide, titanium, lead and other metals, or a mixture of more than two of the metals, and is not limited to the materials. The shape may be long fibers, short fibers, thick fibers, thin fibers, steel wool, profiled fibers, etc., and is not limited thereto. Preferably, the high temperature resistant metal fiber is stainless steel, or the inner core is stainless steel and the outer layer is copper. The metal fiber is produced by one or more of the methods of wire drawing and cutting, fusion drawing, cluster drawing, scraping, cutting thin steel wire, cold rolling strip shearing, steel ingot milling or molten steel rapid condensation, acid leaching and the like, and is not limited thereto.

Examples of high temperature resistant non-metallic materials are refractory materials, asbestos, vermiculite, alumina, refractory fibers.

Non-metallic materials can be divided into two broad categories, inorganic and organic. There are many varieties that are more commonly used in mechanical engineering.

① the inorganic material includes refractory material, ceramic, abrasive, carbon and graphite material, asbestos, etc.;

② belongs to organic materials such as wood, leather, adhesive, and polymer synthetic materials-synthetic rubber, synthetic resin, synthetic fiber, etc.;

③ A composite material made of non-metal fiber reinforced resin matrix.

The diameter of the artificial inorganic fiber is 0.1-100 μm, and the product contains continuous long fiber and short fiber. The continuous long fibers mainly include glass fibers, boron fibers, carbon fibers (graphite fibers), silicon carbide fibers, silicon oxide fibers, aluminum oxide fibers, and silicon nitride fibers. The short fiber mainly refers to various whiskers and cotton-like fibers (such as glass cotton and alumina cotton). The production method includes melt spinning, centrifugation, melt-blowing, spun-bonding, solution spinning, vortex spinning, carrier spinning, extrusion, impregnation, precursor conversion, vapor-liquid-solid phase method, chemical vapor deposition, single crystal drawing, etc., and the fiber is formed and then subjected to several high-temperature treatments.

The molding of the mold includes thermal pressing, physical mixing, etc., for example, thermoplastic, heating the synthetic fiber or product to a temperature above Tg, applying a certain external force to force the synthetic fiber or product to deform/shape, cooling and removing the external force/stress, the deformation can be fixed, and the shape of the fiber or product will not change greatly when T < Tg later. Heat setting, i.e. a process in which the thermoplastic properties of synthetic fibers are used to heat-treat the fabric under tension to fix it in a new state, such as steaming, ironing.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. A fibrous aerosol-generating device comprising:

the high-temperature-resistant non-insulating fibers and the high-temperature-resistant insulating fibers are distributed in a layered or crossed manner.

2. The fibrous aerosol-generating device of claim 1, wherein the refractory non-insulating fibers comprise refractory conductive fibers and/or refractory semiconductor fibers, the refractory conductive fibers form a refractory conductive fiber layer, the refractory semiconductor fibers form a refractory semiconductor fiber layer, the refractory insulating fibers form a refractory insulating fiber layer, and at least two of the refractory conductive fiber layer, the refractory semiconductor fiber layer, and the refractory insulating fiber layer are disposed adjacent to each other and distributed in a layer.

3. A fibrous aerosol-generating device according to claim 2, wherein at least two of the refractory conductive fibre layer, the refractory semiconductor fibre layer and the refractory insulating fibre layer are arranged in layers by hot pressing or physical mixing.

4. The fiber type aerosol generating device according to claim 1, wherein the high temperature resistant non-insulating fibers comprise high temperature resistant conductive fibers and/or high temperature resistant semiconductor fibers, and at least two of the high temperature resistant conductive fibers, the high temperature resistant semiconductor fibers and the high temperature resistant insulating fibers are blended to form the fiber type aerosol generating device.

5. A fibrous aerosol-generating device comprising:

the high-temperature resistant metal material is made into high-temperature resistant metal fibers, and the high-temperature resistant non-metal material is made into high-temperature resistant non-metal fibers; the high-temperature resistant metal fibers and the high-temperature resistant nonmetal fibers are mixed and distributed in a layered or crossed manner.

6. A fibrous aerosol-generating device according to claim 5, wherein the refractory metal fibers form a refractory metal fiber layer and the refractory non-metal fibers form a refractory non-metal fiber layer when the refractory metal fibers and the refractory non-metal fibers are distributed in a layered manner, the refractory metal fibers and the refractory non-metal fiber layer being disposed adjacent to each other.

7. A fibrous aerosol-generating device according to claim 5, wherein the refractory metal fibers and the refractory non-metallic fibers are arranged in a cross-blending manner when the refractory metal fibers and the refractory non-metallic fibers are arranged in a cross-blending manner.

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