Patent Description:
The present disclosure relates to the technical field of aerosol generation, and in particular to an aerosol generation device.

Heating nonburning tobacco device generally transmits the flavor of the tobacco to consumers through a "heating not burning" method. The appearance and consumption mode are similar to traditional cigarettes too, and thus to certain extent can adapt to and meet the physiological needs and psychological needs of consumers. Such a "heating not burning" method enables the tobacco to be heated only at a low temperature (generally lower than <NUM>); compared with the traditional method of the cigarette tobacco being burned to release smoke, when a heating nonburning tobacco device is employed for smoking, the tobacco is heated at a temperature that is much lower than the temperature of burning the traditional cigarette tobacco, thus greatly reducing the generation of harmful substances in the smoke, preventing the generation of tar and a large number of harmful compounds due to the high-temperature burning of the tobacco; in addition, since there is no side-stream smoke, no second hand smoke will be generated to impact the public environment.

Existing heating nonburning tobacco devices generally include a resistor heating element, which is inserted into the heating nonburning tobacco or sleeved on the outer circumferential surface of the heating nonburning tobacco during usage; during working, the heating circuit on the resistor heating element is electrified to generate heat so as to heat rather than burn the heating nonburning tobacco, so that the heating nonburning tobacco forms an aerosol. However, existing heating nonburning tobacco devices, when heating the heating nonburning tobacco, either heat the heating nonburning tobacco gradually from inside to outside through the resistor heating element, or heat the heating nonburning tobacco gradually from outside to inside through the resistor heating element, thus the speed of aerosol formation is slow. <CIT> relates to a heating combustion-free type electronic cigarette atomizer and an electronic cigarette.

In order to solve the problems in existing technologies, the present disclosure provides an aerosol generation device which can increase the speed of aerosol formation. Specifically the present invention provides an aerosol generation device according to independent claim <NUM> while various improvements to the device are defined in the dependent claims.

In a first aspect, the present disclosure provides an aerosol generation device, including a heating element, wherein the heating element includes a base body, an infrared radiation layer, and at least one light convergence mechanism; the base body has a chamber for accommodating an aerosol substrate material; the infrared radiation layer is disposed on a surface of the base body, and is configured to generate infrared radiation to heat the aerosol substrate material disposed in the chamber; the at least one light convergence mechanism is bonded onto the base body and is configured to converge the infrared radiation into the chamber to heat at least a portion of the aerosol substrate material.

Preferably, the light convergence mechanism includes a light convergent lens located between the infrared radiation layer and the chamber, and the infrared radiation layer is located on a surface of one side of the base body away from the chamber.

Preferably, the light convergent lens is located at a bottom of the chamber, and the infrared radiation layer is located, at least partially, at a lower end surface of an outer surface of the base body.

Preferably, the light convergent lens includes a convex lens or/and a Fresnel Lens.

Preferably, the base body includes an inner surface close to the chamber and an outer surface disposed opposite to the inner surface, and the light convergent lens is formed between the inner surface and the outer surface.

Preferably, the inner surface or outer surface includes a cambered surface convex toward the inside of the chamber or concave away from the chamber.

Preferably, the outer surface includes a cambered surface convex toward the inside of the chamber or concave away from the chamber, and the first infrared radiation layer is disposed on the cambered surface.

Preferably, the base body is in the shape of a tube and forms one chamber extending along a longitudinal direction, the light convergent lens includes a strip-shaped convex or concave cambered surface which is formed on the inner surface of the base body and is disposed to extend along the longitudinal direction of the chamber.

Preferably, there are a plurality of the strip-shaped cambered surfaces, the plurality of the strip-shaped cambered surfaces are disposed equidistantly along the circumference of the chamber, and the infrared radiation layer is disposed, at least partially, surrounding an outer circumferential surface of the base body.

Preferably, the base body is in the shape of a circular tube, the strip-shaped cambered surface is disposed to be convex and extend along the longitudinal direction of the chamber, and a center of a circle to which the cambered surface belongs is located on the outer circumferential surface of the base body.

Preferably, the strip-shaped cambered surface has an arc height of <NUM> to <NUM>.

Preferably, the light convergence mechanism and the base body are of an integrated structure, or the light convergence mechanism and the base body are in interference fit connection.

Preferably, the light convergence mechanism includes a first light reflection concave surface located in the chamber.

Preferably, the base body is in the shape of a tube, the first light reflection concave surface is located at a bottom wall of the chamber, and the infrared radiation layer is located at a lateral surface of the base body.

Preferably, the infrared radiation layer is disposed surrounding the outer circumferential surface of the base body.

Preferably, the aerosol generation device further includes a heat insulation tube, the heat insulation tube is sleeved on the base body, the heat insulation tube includes a second light reflection concave surface facing the chamber, and the second light reflection concave surface is configured to converge infrared rays generated by the infrared radiation layer to the aerosol substrate material.

Preferably, the base body is in the shape of a tube, an upper end of the base body is an open end, and a lower end of the base body is a closed end; the infrared radiation layer further includes a first infrared radiation layer and a second infrared radiation layer, the first infrared radiation layer is located at the lower end surface of the outer surface of the base body, and the second infrared radiation layer is located at the lateral surface of the base body.

Preferably, the second infrared radiation layer is disposed surrounding a side wall of the base body, and the second light reflection concave surface is disposed surrounding the outer circumferential surface of the base body.

Preferably, the base body is in the shape of a tube, an upper end of the base body is an open end, and a lower end of the base body is a closed end; the infrared radiation layer is located, at least partially, at a bottom surface of the base body; the aerosol generation device further includes a first electrode and a second electrode, the first electrode is disposed surrounding an outer circumferential edge of the infrared radiation layer and is electrically connected to the infrared radiation layer, and the second electrode elastically abuts against a roughly central area of the infrared radiation layer at the bottom surface of the base body.

Preferably, the aerosol generation device further includes a support element detachably connected to the base body, the support element extends at least partially into the chamber and is spaced from the light convergence mechanism by a preset distance, and the support element defines thereon a placement groove configured to place the aerosol substrate material.

The present disclosure has the following beneficial effects. First, the infrared radiation layer is disposed on the base body to heat the cigarette in an infrared radiation manner, the infrared rays have a good material penetrating power and can heat both inside and outside of the cigarette at the same time, thus enabling a quick speed of aerosol formation; second, since the heating element further includes the light convergence mechanism located on the base body, and the light convergence mechanism is configured to converge the infrared rays to the aerosol substrate material, the energy can be better accumulated to the aerosol substrate material, not only improving the utilization of energy, but also increasing the speed of aerosol formation.

One or more embodiments are illustrated through the image(s) in corresponding drawing(s). These illustrations do not form restrictions to the embodiments. Elements in the drawings with a same reference number are expressed as similar elements, and the images in the drawings do not form proportional restrictions unless otherwise stated.

The present disclosure will become better understood from a detailed description of the present disclosure below taken in conjunction with drawings and particular embodiments.

Referring to <FIG>, the present disclosure provides an aerosol generation device, including a housing assembly <NUM>, a holder <NUM>, a battery <NUM>, a heating element <NUM>, a support element <NUM>, a first electrode <NUM>, a second electrode <NUM> and a third electrode <NUM>; the housing assembly <NUM> includes a housing sleeve <NUM> and an end cover <NUM>, the end cover <NUM> is arranged to cover an end surface of one end of the housing sleeve <NUM>, and the end cover <NUM> defines a smoke outlet <NUM>, such that a user may inhale the aerosol through the smoke outlet <NUM> during usage. The holder <NUM> is housed within the housing sleeve <NUM> and is connected to the housing sleeve <NUM>, the battery <NUM> is located within the housing sleeve <NUM> and is installed on the holder <NUM>.

In one embodiment, the end cover <NUM> and the holder <NUM> are both detachably connected to the housing sleeve <NUM>. In certain embodiment, the end cover <NUM> may be not provided, the holder <NUM> and the housing sleeve <NUM> are of an integrated structure. Therefore, no concrete limitation is made to the structures of the housing assembly <NUM> and the holder <NUM> here. In addition, during usage, the end cover <NUM> may also be used as a mouthpiece for inhaling the aerosol. It is understandable that an extra mouthpiece may be used to fit with the end cover <NUM> to inhale the aerosol, and no concrete limitation is made here.

The heating element <NUM> is installed on the holder <NUM>, and includes a base body <NUM>, an infrared radiation layer <NUM>, and at least one light convergence mechanism <NUM>; the base body <NUM> is in the shape of a tube, an upper end of the base body <NUM> is an open end, and a lower end of the base body <NUM> is a closed end. A chamber <NUM> is formed inside the base body <NUM> and the chamber <NUM> is configured for accommodating an aerosol substrate material. The aerosol substrate material may be cut tobacco, cigarette cream or a cigarette, etc., as long as it can form an aerosol at a preset temperature after being heated. It is understandable that the aerosol substrate material may be placed directly against the inner wall of the chamber <NUM>, also may be disposed spaced from the inner wall of the chamber <NUM>, and no concrete limitation is made here.

The infrared radiation layer <NUM> is disposed on a surface of the base body <NUM>, and is configured to generate infrared radiation to heat the aerosol substrate material disposed in the chamber <NUM>. It is understandable that the infrared radiation layer <NUM> may be electrified itself to generate heat to hereby generate infrared rays, also may be excited to generate infrared rays through the heat conduction of other heating devices, and no concrete limitation is made here. In the present embodiment, the infrared radiation layer <NUM> is configured to receive an electric power to generate heat to hereby generate infrared rays, and transfer the energy of the infrared rays to the aerosol substrate material at least in a manner of radiation. Specifically, the infrared radiation layer <NUM> is disposed, at least partially, at a lower end surface of an outer surface of the base body <NUM>, that is, the infrared radiation layer <NUM> is located, at least partially, at a bottom surface of the base body <NUM>; the infrared radiation layer may be an infrared radiation coating applied on the lower end surface of the outer surface of the base body <NUM>, also may be an infrared radiation film attached to the lower end surface of the outer surface of the base body <NUM>.

The infrared radiation layer <NUM> when electrified is capable of generating heat, thereby generating infrared rays of certain wavelength, for example, far infrared rays of <NUM> to <NUM>. When the wavelength of the infrared rays is matched with the wavelength absorbed by the aerosol substrate material, the energy of the infrared rays is easy to be absorbed by the aerosol substrate material. In the embodiments of the present disclosure, no limitation is made to the wavelength of the infrared rays, the infrared rays may be infrared rays of <NUM> to <NUM>, preferably far infrared rays of <NUM> to <NUM>.

The infrared radiation layer <NUM> preferably is a mixture of far-infrared electrothermal ink, ceramic powder and inorganic adhesive that is fully stirred and then coated on the surface of the base body <NUM> and finally is dried and cured for certain time, and the infrared radiation layer <NUM> has a thickness of <NUM>-<NUM>. Of course, the infrared radiation layer <NUM> can also be a mixture of tin tetrachloride, tin oxide, antimony trichloride, titanium tetrachloride and anhydrous copper sulfate in certain proportion that is stirred and then coated on the outer surface of the base body <NUM>; or the infrared radiation layer <NUM> is one of silicon carbide ceramic layer, carbon fiber composite layer, zirconium titanium oxide ceramic layer, zirconium titanium nitride ceramic layer, zirconium titanium boride ceramic layer, zirconium titanium carbide ceramic layer, iron oxide ceramic layer, iron nitride ceramic layer, iron boride ceramic layer, iron carbide ceramic layer, rare earth oxide ceramic layer, rare earth nitride ceramic layer, rare earth boride ceramic layer, rare earth carbide ceramic layer, nickel cobalt oxide ceramic layer, nickel cobalt nitride ceramic layer, nickel cobalt boride ceramic layer, nickel cobalt carbide ceramic layer or high silicon molecular sieve ceramic layer; the infrared radiation layer <NUM> can also be other existing material coatings.

The light convergence mechanism <NUM> is bonded onto the base body <NUM> and is configured to converge the infrared radiation into the chamber <NUM> to heat at least a portion of the aerosol substrate material. The light convergence mechanism <NUM> includes a light convergent lens located between the infrared radiation layer <NUM> and the chamber <NUM>, and the infrared radiation layer <NUM> is located on a surface of one side of the base body <NUM> away from the chamber <NUM>. The structure is simple and compact and is convenient to produce.

Specifically, the base body <NUM> includes an inner surface close to the chamber <NUM> and an outer surface disposed opposite to the inner surface, and the light convergent lens is formed between the inner surface and the outer surface and is located at the bottom of the chamber <NUM>; an upper surface of a bottom wall of the base body <NUM> is the inner surface, a lower surface of the bottom wall of the base body <NUM> is the outer surface, that is to say, the light convergence mechanism <NUM> and the base body <NUM> are of an integrated structure, that is, the light convergent lens and the base body <NUM> are of an integrated structure; therefore, the light convergent lens is directly shaped when the base body <NUM> is being manufactured, without fixing the light convergent lens through other fixing mechanisms, the production is convenient and the reliability is high, the infrared rays are ensured to be better converged to a preset position. In the present embodiment, the light convergent lens is a convex lens, specifically, a plano-convex lens.

In order to better align the infrared rays to the aerosol substrate material and to conveniently clean the chamber <NUM>, a support element <NUM> is employed to support the aerosol substrate material to a preset position in the chamber <NUM>. An upper end of the support element <NUM> is in buckling connection with the base body <NUM> to achieve a detachable connection, the support element <NUM> extends at least partially into the chamber <NUM> and is spaced from the light convergence mechanism <NUM> by a preset distance, so that more infrared rays may be converged. The support element <NUM> defines thereon a placement groove <NUM> configured to place the aerosol substrate material, a depth of the placement groove <NUM> may be set as needed, and no concrete limitation is made here. In the present embodiment, the support element <NUM> is a metal mesh. It is understandable that in some embodiment, the support element <NUM> also may be not provided, or the support element <NUM> is fixedly connected to the heating element <NUM>.

The first electrode <NUM> is disposed surrounding an outer circumferential edge of the infrared radiation layer <NUM> and is electrically connected to the infrared radiation layer <NUM>, specifically, the infrared radiation layer <NUM> is in the shape of a disc, the first electrode <NUM> is in the shape of a circular ring, an inner circumferential surface of the first electrode <NUM> comes into contact with an outer circumferential surface of the infrared radiation layer <NUM>, to achieve electrical connection. The second electrode <NUM> elastically abuts against a roughly central area of the infrared radiation layer <NUM> at the bottom surface of the base body <NUM>, that is, the second electrode <NUM> may abut against the center of the infrared radiation layer <NUM>, also may be slightly deviated from the center of the infrared radiation layer <NUM>. The third electrode <NUM> is in the shape of a ring and sleeved on the upper end of the base body <NUM>, and is electrically connected to the first electrode <NUM> through a conductive line <NUM> disposed on a lateral surface of the base body <NUM>. The second electrode <NUM> is a pogo pin fixed on the holder <NUM>, and the second electrode <NUM> is electrically connected to the battery <NUM> to supply power to the infrared radiation layer <NUM>.

It is understandable that the aerosol generation device further includes a switch (not shown in figures) that is electrically connected to the third electrode <NUM> and the battery <NUM> and is configured to control the battery <NUM> to supply power to the infrared radiation layer <NUM>. When a user needs to inhale aerosol, turn on the switch, then the battery <NUM> supplies power to the infrared radiation layer <NUM>, so that the infrared radiation layer <NUM> emits infrared rays to atomize the aerosol substrate material into an aerosol. In one kind of embodiments, the first electrode <NUM>, the second electrode <NUM> and the third electrode <NUM> may be not provided, and the infrared radiation layer <NUM> is electrically connected to the battery <NUM> through a conductive line.

Referring to <FIG>, provided is a sectional view of a partial structure of another embodiment of an aerosol generation device according to the present disclosure. In this embodiment, the light convergent lens is a convex lens, the convex lens is located in the chamber <NUM> of the base body <NUM> and is in interference fit connection with the base body <NUM>, a surface of the convex lens facing the infrared radiation layer <NUM> is a flat surface and a surface of the convex lens away from the infrared radiation layer <NUM> is a spherical surface, that is, the convex lens is a plano-convex lens, thereby being capable of tightly fitting with the interior of the base body <NUM>.

Referring to <FIG>, provided is a sectional view of a partial structure of another embodiment of an aerosol generation device according to the present disclosure. In this embodiment, the light convergent lens is a convex lens, the convex lens is located in the chamber <NUM> of the base body <NUM> and is in interference fit connection with the base body <NUM>, a surface of the convex lens facing the infrared radiation layer <NUM> is a concave surface and a surface of the convex lens away from the infrared radiation layer <NUM> is a spherical surface, that is, the convex lens is a meniscus lens.

Referring to <FIG>, provided is a sectional view of a partial structure of another embodiment of an aerosol generation device according to the present disclosure. In this embodiment, the light convergent lens is a convex lens, the convex lens is located in the chamber <NUM> of the base body <NUM> and is in interference fit connection with the base body <NUM>, both of the surfaces of the convex lens facing the infrared radiation layer <NUM> and away from the infrared radiation layer <NUM> are a spherical surface, that is, the convex lens is a biconvex lens, thereby being capable of better converging infrared rays.

Referring to <FIG>, provided is a sectional view of a partial structure of another embodiment of an aerosol generation device according to the present disclosure. In this embodiment, the light convergent lens is a Fresnel lens, the Fresnel lens is located in the chamber <NUM> of the base body <NUM> and is in interference fit connection with the base body <NUM>, a surface of the Fresnel lens facing the infrared radiation layer <NUM> is a flat surface and a surface of the Fresnel lens away from the infrared radiation layer <NUM> includes a plurality of circular grooves that are disposed coaxially.

Referring to <FIG>, provided is a sectional view of a partial structure of another embodiment of an aerosol generation device according to the present disclosure. In this embodiment, the light convergent lens is a Fresnel lens, the Fresnel lens is located at a bottom wall of the chamber <NUM> and is integrated with the base body <NUM>, thus the structure is compact. During production, it is not needed to assemble the Fresnel lens separately, the efficiency of production is high.

Referring to <FIG> is a perspective view of a partial structure of another embodiment of an aerosol generation device according to the present disclosure. In this embodiment, the base body <NUM> is in the shape of a tube and forms one chamber <NUM> extending along a longitudinal direction, the light convergent lens includes a strip-shaped convex cambered surface which is formed on the inner surface of the base body <NUM> and is disposed to extend along the longitudinal direction of the chamber <NUM>, that is, the strip-shaped cambered surface is disposed to be convex and extend along the longitudinal direction of the chamber, that is to say, the light convergent lens is integrated with the base body <NUM> and is disposed in the chamber <NUM> in a protruding manner. It is understandable that the number of the strip-shaped cambered surface and the radian may be set as needed. During actual application, since the cigarette <NUM> generally is strip shaped, when the cigarette <NUM> is heated the strip-shaped cambered surface is fitting with the cigarette <NUM>, and most areas on the outer surface of the cigarette <NUM> can acquire converged infrared rays, enabling a quick speed of aerosol formation.

In the present embodiment, the aerosol generation device further includes a fourth electrode <NUM>, the base body <NUM> is in the shape of a tube with two open ends, there are a plurality of the strip-shaped cambered surfaces, the plurality of the strip-shaped cambered surfaces are disposed equidistantly along the circumference of the chamber <NUM>, both of the third electrode <NUM> and the fourth electrode <NUM> are in the shape of a ring and are sleeved on two opposite ends of the base body <NUM> respectively, the infrared radiation layer <NUM> is disposed, at least partially, surrounding an outer circumferential surface of the base body <NUM> and is electrically connected to the third electrode <NUM> and the fourth electrode <NUM>, so that as many infrared rays may be converged to the cigarette <NUM> as possible. A center of a circle to which the strip-shaped cambered surface belongs is located on the outer circumferential surface of the base body <NUM>, the strip-shaped cambered surface has an arc height of <NUM> to <NUM>, thus the strip-shaped cambered surface can abut against the outer circumferential surface of the cigarette <NUM>, so that the cigarette does not shake arbitrarily in the chamber <NUM>. Preferably, the strip-shaped cambered surface has an arc height of <NUM> to <NUM>.

Since the strip-shaped cambered surfaces are disposed equidistantly along the circumference of the chamber <NUM>, a space is formed between the strip-shaped cambered surfaces, which may serve as a deformation space of the cigarette, not only facilitating the insertion and removal of the cigarette, but also adapting to cigarettes <NUM> of different diameters to increase compatibility. It is understandable that in one kind of embodiments, the light convergent lens includes a strip-shaped concave cambered surface which is formed on the inner surface of the base body <NUM> and is disposed to extend along the longitudinal direction of the chamber <NUM>.

From <FIG>, when infrared rays emitted by Points A, B and C penetrate through an inner wall of the base body <NUM>, due to the function of the light convergent lens, the infrared rays emitted by Points B and C generate refraction at the inner wall of the base body <NUM>. The base body <NUM> is an optically denser medium, thus the angle of emergence of the infrared rays emitted from the inner wall of the base body <NUM> is greater than the angle of incidence, the infrared rays are converged.

Compared with case of not arranging the light convergent lens, through the convergence function of the light convergent lens on the inner wall of the base body <NUM>, the infrared rays in the same area between the Points B and C on the base body <NUM> has the scope of irradiation onto the outer wall of the cigarette <NUM> changed from <NUM> degrees to <NUM> degrees, namely, the same infrared rays are converged to a smaller scope. That is to say, the same energy is concentrated in a smaller scope, then this local temperature will change more quickly, achieving the function of rapid rise of temperature; as the temperature rises rapidly, the aerosol substrate material corresponding to this part has a quicker speed of aerosol formation, which increases the speed of aerosol formation on the whole.

Referring to <FIG>, provided is a sectional view of a partial structure of another embodiment of an aerosol generation device according to the present disclosure. In this embodiment, the light convergence mechanism <NUM> is a first light reflection concave surface located in the chamber <NUM>. Specifically, the base body <NUM> of this embodiment is in the shape of a tube, the infrared radiation layer <NUM> is located at the lateral surface of the base body <NUM> and is disposed surrounding the outer circumferential surface of the base body <NUM>. The first light reflection concave surface is located at the bottom wall of the chamber <NUM> and is configured to converge the light emitted by the infrared radiation layer <NUM> to the aerosol substrate material. In the present embodiment, an inner surface of the bottom wall of the chamber <NUM> is plated with a first light reflection layer <NUM>, the first light reflection layer <NUM> may be made of materials such as silver, aluminum or alloy, etc., and no concrete limitation is made here. It is understandable that the bottom wall of the chamber <NUM> may also be made of a light reflecting material. Preferably, the first light reflection concave surface is a spherical surface.

Referring to <FIG>, provided is a sectional view of a partial structure of another embodiment of an aerosol generation device according to the present disclosure. In this embodiment, the aerosol generation device further includes a heat insulation tube <NUM>, the heat insulation tube <NUM> is sleeved on the base body <NUM>, the heat insulation tube <NUM> includes a second light reflection concave surface <NUM> facing the chamber <NUM>, the second light reflection concave surface <NUM> is disposed surrounding the outer circumferential surface of the base body <NUM>, and the second light reflection concave surface <NUM> is configured to converge infrared rays generated by the infrared radiation layer <NUM> to the aerosol substrate material. In the present embodiment, an inner surface of the heat insulation tube <NUM> is plated with a second light reflection layer <NUM>, which may be made of materials such as silver, aluminum or alloy, etc., and no concrete limitation is made here. It is understandable that the heat insulation tube <NUM> may also be made of a light reflection material. Preferably, the second light reflection concave surface <NUM> is a spherical surface.

In this embodiment, the base body <NUM> is in the shape of a tube, an upper end of the base body <NUM> is an open end, and a lower end of the base body <NUM> is a closed end. Two ends of the base body <NUM> are sleeved with a third electrode <NUM> and a fourth electrode <NUM>, a second electrode <NUM> is disposed below the base body <NUM>; the second electrode <NUM>, the third electrode <NUM> and the fourth electrode <NUM> are electrically connected to the battery <NUM> through a conductive line. Both of the third electrode <NUM> and the fourth electrode <NUM> are located between the base body <NUM> and the heat insulation tube <NUM>. The infrared radiation layer <NUM> includes a first infrared radiation layer <NUM> and a second infrared radiation layer <NUM>, wherein the first infrared radiation layer <NUM> is located at the lower end surface of the outer surface of the base body <NUM> and is electrically connected to the second electrode <NUM> and the fourth electrode <NUM>. The second infrared radiation layer <NUM> is located at the lateral surface of the base body <NUM> and is electrically connected to the third electrode <NUM> and the fourth electrode <NUM>, and the second infrared radiation layer <NUM> is disposed surrounding the side wall of the base body <NUM>. The light convergent lens is integrated with the base body <NUM> and is located at the bottom of the chamber <NUM>.

Referring to <FIG>, provided is a sectional view of a partial structure of another embodiment of an aerosol generation device according to the present disclosure. This embodiment has the similar structure to the above one embodiment. The base body <NUM> includes an inner surface close to the chamber <NUM> and an outer surface disposed opposite to the inner surface, and the light convergent lens is formed between the inner surface and the outer surface, wherein the outer surface includes the lower end surface of the base body <NUM>, the difference lies in that: the lower end surface of the base body <NUM> of this embodiment is a cambered surface convex toward the inside of the chamber <NUM>, and the first infrared radiation layer <NUM> is disposed on the cambered surface. Specifically, the bottom wall of the base body <NUM> is a meniscus lens.

Referring to <FIG>, provided is a sectional view of a partial structure of another embodiment of an aerosol generation device according to the present disclosure. This embodiment has the similar structure to the above one embodiment, the difference lies in that: the lower end surface of the base body <NUM> of this embodiment is a cambered surface concave away from the inside of the chamber <NUM>, and the first infrared radiation layer <NUM> is disposed on the cambered surface. Specifically, the bottom wall of the base body <NUM> is a biconvex lens.

Referring to <FIG>, provided is a sectional view of a partial structure of another embodiment of an aerosol generation device according to the present disclosure. This embodiment has the similar structure to the above one embodiment, the difference lies in that: the lower end surface of the base body <NUM> of this embodiment is a flat surface, and the bottom wall of the base body <NUM> is a Fresnel lens.

Referring to <FIG>, provided is a sectional view of a partial structure of another embodiment of an aerosol generation device according to the present disclosure. This embodiment has the similar structure to the above one embodiment, the difference lies in that: the light convergence mechanism <NUM> of this embodiment includes a first light reflection concave surface located in the chamber <NUM>. Specifically, the base body <NUM> of this embodiment is in the shape of a tube, the first light reflection concave surface is located at the bottom wall of the chamber <NUM>, the infrared radiation layer <NUM> is located at the lateral surface of the base body <NUM> and is disposed surrounding the outer circumferential surface of the base body. In this embodiment, an inner surface of the bottom wall of the chamber <NUM> is plated with a third light reflection layer <NUM>, which may be made of materials such as silver, aluminum or alloy, etc., and no concrete limitation is made here. It is understandable that the bottom wall of the chamber <NUM> may also be made of a light reflecting material.

To sum up, first, the infrared radiation layer <NUM> is disposed on the base body <NUM> to heat the cigarette in an infrared radiation manner, the infrared rays have a good material penetrating power and can heat both inside and outside of the cigarette at the same time, thus enabling a quick speed of aerosol formation; second, since the heating element <NUM> further includes the light convergence mechanism <NUM> located on the base body <NUM>, and the light convergence mechanism <NUM> is configured to converge the infrared rays to the aerosol substrate material, the energy can be better accumulated to the aerosol substrate material, not only improving the utilization of energy, but also increasing the speed of aerosol formation.

Claim 1:
An aerosol generation device, comprising a heating element (<NUM>), wherein the heating element (<NUM>) comprises a base body (<NUM>), an infrared radiation layer (<NUM>), and characterized in that the aerosol generation device further comprises at least one light convergence mechanism (<NUM>); wherein the base body (<NUM>) has a chamber (<NUM>) for accommodating an aerosol substrate material; the infrared radiation layer (<NUM>) is disposed on a surface of the base body (<NUM>), and is configured to generate infrared radiation to heat the aerosol substrate material disposed in the chamber (<NUM>); and wherein the at least one light convergence mechanism (<NUM>) is bonded onto the base body (<NUM>) and is configured to converge the infrared radiation into the chamber (<NUM>) to heat at least a portion of the aerosol substrate material.