JP2024024584A - Aerosol inhalation cartridge - Google Patents

Abstract

To provide an aerosol inhalation cartridge usable for any heating device of a blade heating type and an induction heating type.SOLUTION: An aerosol inhalation cartridge used for an induction heating device and having a columnar shape as a whole includes an induction heating member 14 disposed inside a filler of an aerosol forming base material 11 that is formed of the filler for generating aerosol. The aerosol inhalation cartridge is characterized in that the induction heating member 14 has a non-linear shape symmetrical to a direction parallel to a diameter of a bottom surface when viewed from the bottom surface side of the columnar shape, while it is disposed inside the filler.SELECTED DRAWING: Figure 1

Description

The present invention relates to an aerosol suction cartridge that is used by being attached to a blade heating type or induction heating device.

In recent years, tobacco products have become widely known that heat a cigarette cartridge containing tobacco components without using a flame and inhale the vaporized tobacco components. Furthermore, due to the diversification of tastes, aerosol inhalation cartridges using cartridge products that allow people to enjoy the aroma and taste of plants that do not contain tobacco components without using a flame are becoming popular.

Such an aerosol suction cartridge generates an aerosol by heating an aerosol-forming base material on which a filler is accumulated. As a heating method for the aerosol forming substrate, (1) a method in which an aerosol suction cartridge is inserted into a heating blade installed inside the heating device and the filling material is heated by electrically heating the heating blade (blade (2) An induction heating member, which is a component whose main component is a ferromagnetic material, is provided in advance inside the aerosol forming base material, and an alternating magnetic field generated by an induction heating device is used to heat the aerosol. A method (induction heating method) is known in which a filling is heated by generating hysteresis loss and Joule heat inside an induction heating member (induction heating) (for example, see Patent Document 2).

Here, blade heating type aerosol suction cartridges cannot be used with induction heating type heating devices, and induction heating type aerosol suction cartridges cannot be used with blade heating type heating devices, so they cannot be used. There has been a problem in that individuals are not necessarily able to select an aerosol suction cartridge that suits their preferences.

In addition, since conventional induction heating members have an elongated flat plate structure, they cannot reach a wide range inside the cylindrical aerosol forming base material, so they cannot effectively cover a wide range inside the aerosol forming base material. It was difficult to heat.

Furthermore, if a flat plate-shaped induction heating member is arranged along the longitudinal direction of the aerosol forming substrate, the component perpendicular to the alternating magnetic field will be determined by the thickness of the flat plate. However, since eddy currents are difficult to generate, there is a problem in that induction heating using Joule heat cannot be performed effectively.

On the other hand, if an induction heating member made of a ferromagnetic material is simply increased in size, depending on its magnetic transition temperature (Curie temperature), there may be problems such as overheating, which may cause the heating device to stop or malfunction, resulting in unstable heating. Ta.

Special Publication No. 2015-519915 JP 2021-175399 Publication

In view of the above circumstances, the present invention provides an aerosol suction cartridge that can be used with either a blade heating type heating device or an induction heating type heating device.

Another object of the present invention is to provide an aerosol suction cartridge that can more efficiently perform heating using Joule heat in induction heating.

Another object of the present invention is to provide an aerosol suction cartridge that can suppress excessive heating during induction heating to stabilize heating, and can effectively heat a wide range inside an aerosol-forming substrate.

In order to solve the above problem, the invention according to claim 1 provides an aerosol suction cartridge which is used in an induction heating device and has a cylindrical shape as a whole, and which includes an aerosol-forming group made of a filler that generates an aerosol. a mouthpiece disposed at one end of the cylindrical shape for inhaling the aerosol, an exterior member packaging the aerosol-forming base material and the mouthpiece, and a filler for the aerosol-forming base material. an induction heating member disposed inside the filling, the induction heating member being parallel to the diameter axis of the bottom surface when viewed from the side of the bottom surface of the cylindrical shape while being disposed inside the filling. An aerosol suction cartridge characterized by having a non-linear shape that is symmetrical in a direction.
In the invention according to claim 2, the induction heating member has at least one of a set of sides that are symmetrical with respect to a direction parallel to the diameter axis of the bottom surface, among the sides forming the non-linear shape. The aerosol suction cartridge according to claim 1, wherein the length of one or more pairs of sides is longer than the radius of the cylindrical circle.
The invention according to claim 3 is characterized in that the non-linear shape is any one of a V-shape, a U-shape, a U-shape, or a combination thereof. The aerosol suction cartridge according to any one of the items.
According to a fourth aspect of the invention, the induction heating member has a cut along the longitudinal direction in a part of the induction heating member in a direction substantially perpendicular to the longitudinal direction thereof. 3. The aerosol suction cartridge according to claim 1, wherein one or more aerosol suction cartridges are arranged.
The invention according to claim 5 is characterized in that the induction heating member has a non-penetrating cut formed in the deformed portion forming the non-linear shape. The aerosol suction cartridge according to item (1).
The invention according to claim 6 provides an aerosol suction cartridge having a generally cylindrical shape for use in an induction heating device, the aerosol forming base being made of a filler that generates an aerosol; , a mouthpiece for inhaling the aerosol disposed at one end thereof and located on the opposite side of the aerosol-forming base material, an exterior member for packaging the aerosol-forming base material and the mouthpiece, and the aerosol-forming base material. an induction heating member disposed inside a filling of material, the induction heating member, when viewed from the side of the cylindrical shape while being disposed inside the filling, An aerosol suction cartridge characterized by having a non-linear shape having a cylindrical radially extending component.
The invention according to claim 7 provides an aerosol suction cartridge which is used in an induction heating device and has a cylindrical shape as a whole, the aerosol forming base material comprising a filler that generates an aerosol, and the cylindrical shape. , a mouthpiece disposed at one end thereof for inhaling the aerosol, an exterior member packaging the aerosol-forming base material and the mouthpiece, and induction heating disposed inside the filling of the aerosol-forming base material. The induction heating member has a length longer than the sum of the longitudinal direction and the diameter of the aerosol forming base, and has a bent part bent at an angle of 90° or more in a part of the longitudinal direction. An aerosol suction cartridge, characterized in that the cartridge is arranged along the longitudinal direction of an aerosol-forming substrate.
The invention according to claim 8 is characterized in that the induction heating member is partially formed of a non-magnetic material or a paramagnetic material. The aerosol suction cartridge according to item 1.
The invention according to claim 9 is characterized in that one or both of the ends of the induction heating member are formed at an acute angle with respect to the longitudinal direction thereof. 7. The aerosol suction cartridge according to any one of 7.

According to this invention, the induction heating member has a non-linear shape that is symmetrical with respect to the direction parallel to the diameter axis of the bottom surface when viewed from the bottom surface side of the aerosol-forming base material. Since the induction heating member is not located near the radial center of the material, there is a space for the heating blade to pass through, making it possible to use either a blade heating type heating device or an induction heating type heating device.

In addition, among the sides forming the non-linear shape of the induction heating member, the length of at least one set of sides located in a symmetrical position with respect to the direction parallel to the diameter axis of the bottom surface is such that Since the radius is longer than the radius of the cylindrical circle of the aerosol formation substrate, the induction heating member is not located near the radial center of the aerosol formation substrate, creating a space for the heating blade to pass through. Any type of heating device can be used. Furthermore, since the induction heating member covers a wide range inside the aerosol forming substrate, it becomes possible to effectively heat a wide range.

In addition, since the induction heating member has a non-linear shape with a component extending in the radial direction of the cylinder when viewed from the side of the cylinder while disposed inside the filling, aerosol formation Since the induction heating member is not located near the radial center of the base material, a space is created through which the heating blade is inserted, and it is possible to use either a blade heating type heating device or an induction heating type heating device. In addition, in induction heating, due to the geometric configuration of the induction heating member, the component in the direction perpendicular to the alternating magnetic field becomes large, making it easier to generate eddy currents, making it difficult to perform heating using Joule heat more efficiently. It becomes possible.

In addition, the non-magnetic material that makes up a part of the induction heating member contributes less to heat generation than magnetic materials and functions as a heat conductor, so in induction heating, it suppresses excessive heating and stabilizes heating. , it becomes possible to effectively heat a wide range of the aerosol-forming substrate.

1 is a schematic side sectional view of an aerosol suction cartridge according to Embodiment 1 of the present invention. 1 is a schematic cross-sectional view (X-X) of an aerosol suction cartridge according to Embodiment 1 of the present invention. 1 is a schematic perspective view of an induction heating member according to Embodiment 1 of the present invention. FIG. FIG. 3 is a schematic side sectional view of an aerosol suction cartridge according to Embodiment 2 of the present invention. FIG. 2 is a schematic cross-sectional view (YY) of an aerosol suction cartridge according to Embodiment 2 of the present invention. It is a side view (a) and a perspective view (b) of an outline of an induction heating member based on Embodiment 2 of the present invention. FIG. 7 is a schematic front view of an induction heating member according to another embodiment of the present invention. FIG. 7 is a schematic front view of an induction heating member according to another embodiment of the present invention. FIG. 3 is a schematic perspective view of an induction heating member according to another embodiment of the present invention. FIG. 7 is a schematic front view of an induction heating member according to another embodiment of the present invention. FIG. 3 is a schematic perspective view of an induction heating member according to another embodiment of the present invention. FIG. 6 is a schematic front view (a) and a plan view (b) of an induction heating member according to another embodiment of the present invention. FIG. 3 is a schematic side sectional view of an aerosol suction cartridge according to another embodiment of the present invention. FIG. 7 is a schematic perspective view of an induction heating member according to another embodiment of the present invention. FIG. 7 is a schematic perspective view of an induction heating member according to another embodiment of the present invention. FIG. 7 is a schematic side view of an induction heating member according to another embodiment of the present invention.

Embodiments of the present invention will be described with reference to the accompanying drawings. In addition, in the drawings, the size, spacing, number, and other details of each part are greatly simplified or exaggerated compared to the actual thing to aid in visual recognition and understanding.

Embodiment 1
FIG. 1 is a schematic cross-sectional view of an aerosol suction cartridge 1 used in an induction heating apparatus according to the first embodiment, and FIG. 2 is a schematic cross-sectional view of the aerosol suction cartridge 1 (X- X). As shown in this figure, the aerosol suction cartridge 1 has an elongated cylindrical shape as a whole, and includes an aerosol forming base material 11 which is a substantially cylindrical accumulation of fillers filled with a large number of fillers, a support member 15 through which airflow from the forming substrate 11 can pass; a mouthpiece 16 disposed at one end of the cylinder and having a mouthpiece at one end; and a sealing member 17 disposed at the opposite end of the mouthpiece 16. are arranged along the longitudinal direction, and are integrally formed by being wound with a sheet-like exterior member 13. The exterior member 13 can be made of paper or the like. Here, in this patent, "slender" means that the length is larger than its width, thickness, or diameter.

Here, the aerosol forming base material 11 is integrated by wrapping the filler in a substantially cylindrical shape with an interior member 12, and an induction heating member 14 is included inside the aerosol forming base material 11.

The filling is made by mixing dried and crushed tobacco or non-tobacco plants with an aerosol former that generates an aerosol, microcrystalline cellulose, flavor additives, preservatives, adhesives, or thickeners, etc. It is formed by forming it into a sheet and then cutting it to have a predetermined width and length.

When the filling is long, the cross section perpendicular to the central axis is approximately rectangular, and the ratio of the long side to the short side of the cross section is, for example, in the range of 1:1 to 30:1. is preferred. The length of the long side is preferably in the range of 0.1 mm to 7.5 mm, more preferably in the range of 0.1 mm to 3.0 mm. The length of the short side is preferably in the range of 0.1 mm to 1.0 mm, more preferably in the range of 0.1 mm to 0.5 mm. Further, it is preferable that the length of the filler is approximately the same as the length of the aerosol forming base material 11. The length of the filler is preferably in the range of 10 mm to 25 mm, more preferably in the range of 10 mm to 20 mm. An example of the dimensions of such a filling is that the long side is 1.5 mm, the short side is 0.3 mm, and the length is 12 mm.

Next, specific examples of raw materials used as fillers will be explained. The filling is composed of any one or more combinations of the raw materials listed below.

The filling is sourced from tobacco or non-tobacco plants. Examples of tobacco plants include tobacco leaves, tobacco stems, expanded tobacco, homogenized tobacco, and the like. Non-tobacco plants include plants other than tobacco plants. Preferred parts of non-tobacco plants include leaves, pulp, seeds, roots (scaly roots, tuberous roots, etc.), stems, tubers, skin (stem bark, bark, etc.), flowers (petals, stamens, pistils, etc.), trunks, and branches. etc.

In addition, "plant" as used herein refers to a group of animals, and includes not only living organisms that have roots and live in a fixed location, such as grass and trees, but also microalgae, seaweed, etc. It also includes algae such as , fungi such as mushrooms, etc.

The filling is made by, for example, mixing dried and crushed non-tobacco plants with an aerosol former that generates an aerosol, microcrystalline cellulose, flavor additives that add flavor, preservatives, binders, thickeners, etc. It is crushed or classified into powder or granules, or formed into a paste. The filler is formed into a sheet and then cut into strips or rods having a predetermined width and length.

For example, tea leaves can be used if the raw material is a non-tobacco plant. Not only do tea leaves come from different plants, but even the same plant can be made into different tea leaves depending on the processing method. Specifically, examples include Japanese tea, black tea, oolong tea, and the like.

As the aerosol former, for example, glycerin, propylene glycol, etc. are preferably used.

Next, microcrystalline cellulose is obtained, for example, by partially depolymerizing α-cellulose obtained from the pulp of fibrous plants with acid. It is a crystallized part.

Microcrystalline cellulose may be used as a powder, or may be dispersed in a solvent such as water to form a suspension liquid. In this case, a high-speed stirrer, a high-pressure homogenizer, or the like can be used for dispersion in a solvent.

Furthermore, flavor additives that add flavor may also be used as raw materials for the filling, if desired. Flavor additives include mint, cocoa, coffee, black tea extracts, catechin powder from tea extracts, and the like. Preferably, the preservatives are those used in foods, such as sorbic acid, potassium sorbate, benzoic acid, and sodium benzoate.

Binders or thickeners include gums such as guar gum, cellulose binders such as hydroxypropylcellulose, polysaccharides such as conjugated base salts of organic acids such as starch, and combinations thereof.

Next, the aerosol suction cartridge 1 according to the first embodiment is formed to have a diameter of 4.0 mm to 7.5 mm, more preferably 5.0 mm to 7.0 mm, and a length of 40 mm to 80 mm. If the outer diameter of the aerosol suction cartridge 1 is set in the range of 6.5 to 7.5 mm, the aerosol suction cartridge 1 will fit with an appropriate force into the insertion part of the aerosol generator, into which the aerosol suction cartridge 1 is inserted. The aerosol suction cartridge 1 can be easily attached and detached while allowing the aerosol generation device to suitably hold the suction cartridge 1. If the length of the aerosol suction cartridge 1 is set in the range of 40 to 80 mm, it will be longer than the length of the insertion part that receives the aerosol suction cartridge 1 provided in the aerosol generator, so the aerosol suction cartridge 1 can be used as an aerosol suction cartridge. Even when inserted into the generator, the mouthpiece can be exposed from the aerosol generator, making it possible to ensure the length necessary for the user to inhale the aerosol.

The support member 15 suppresses movement of the aerosol-forming base material 11 toward the support member 15 side, and allows airflow containing the aerosol generated in the aerosol-forming base material 11 to flow toward the mouthpiece 16 side. The support member 15 is provided, for example, in a cylindrical and solid shape, and is disposed between the aerosol forming base material 11 and the mouthpiece 16 so that its axial direction is along the central axis. The support member 15 is formed, for example, to have an outer diameter of 4.0 mm to 7.5 mm and a length along the central axis of 50 mm or less. Note that the support member 15 may have dimensions different from those described above depending on the function and configuration as appropriate.

In the first embodiment, the support member 15 has a support member main body 15-1 made of a resin material, and an insertion hole 15-2, which serves as an air flow path, is formed in the support member main body 15-1. Examples of the resin material forming the support member 15 include polypropylene, polylactic acid, and silicone.

The mouthpiece 16 is formed into a cylindrical shape, and has a diameter of, for example, 4.0 mm to 7.5 mm, and a length along the central axis of 50 mm or more. The mouthpiece 16 is formed using paper or the like, for example. Further, the mouthpiece 16 may be provided in a cylindrical shape by winding a sheet-like member made of paper, for example, or may include a cellulose acetate filter for removing fine particles. The mouthpiece 16 is a white filter that has the function of filtering water vapor generated by the aerosol-forming substrate 11 and part of the fine particles in the aerosol. Note that if the filling is made from a non-tobacco plant, it is not necessarily necessary to provide the mouthpiece 16 with a filtration function; for example, the inside of the exterior member 13 may be used as is, or a hollow tube may be used. (ie, the area where the mouthpiece 16 is placed is used as a cavity).

The aerosol forming base material 11 is formed into a substantially cylindrical shape by forming a long filler into a bundle along the length direction and wrapping it around a sheet-like interior member 12 . The filling is formed from tobacco or non-tobacco plants. The aerosol-forming substrate 11 has a length of 10 to 25 mm. Note that the filler is not limited to a long shape, and may have other shapes such as a strip, a rod, a sheet, a granule, a dust, a paste, and a porous shape. Further, the aerosol suction cartridge 1 may have dimensions different from those described above, depending on the shape of the aerosol generator.

The outer diameter of the aerosol forming base material 11 is equal to the outer diameter of the support member 15 and the mouthpiece 16, and has a generally constant value along the central axis. The size of this outer diameter is preferably in the range of 4.0 mm to 7.5 mm, and more preferably in the range of 5.0 mm to 7.0 mm.

The induction heating member 14 is provided inside the aerosol forming base material 11 as described above. In the first embodiment, the induction heating member 14 is a processed flat material. Here, the material of the induction heating member 14 is formed of a metal material containing a ferromagnetic material. A ferromagnetic material is a material that becomes strongly magnetic in the same direction as the external magnetic field when an external magnetic field is applied, and has the property of being particularly attracted to a magnet.For example, ferromagnetic materials such as iron, ferrite iron, ferrite powder, Examples include ferrite particles, ferritic stainless steel (for example, SUS430), nickel, nickel-iron alloy (for example, 42 alloy, 36 invar), and cobalt. The relative magnetic permeability of ferromagnetic materials is extremely larger than 1, for example, iron is about 5000, nickel is about 600, cobalt is about 250, and ferritic stainless steel is about 250. It is about 1000 to 1800.

Among magnetic materials, paramagnetic materials are materials that are weakly magnetized in the same direction as the external magnetic field when an external magnetic field is applied, and cease to be magnetic when the external magnetic field is reduced to zero, such as aluminum, platinum, and manganese. . The relative magnetic permeability of paramagnetic materials is slightly larger than 1, for example, aluminum is about 1.000021, platinum is about 1.000265, and manganese is about 1.000830.

Among magnetic materials, diamagnetic materials are materials that become magnetic in the opposite direction to the external magnetic field when an external magnetic field is applied, and cease to be magnetic when the external magnetic field is reduced to zero, such as copper, graphite, bismuth, etc. . The relative magnetic permeability of diamagnetic materials is slightly smaller than 1, for example, copper is about 0.999990, graphite is about 0.99980, and bismuth is about 0.999834. .

When a ferromagnetic material is placed inside a magnetic field (alternating magnetic field) whose direction and size change over time, it not only generates Joule heat due to eddy current flowing due to electromagnetic induction, but also changes the direction of magnetization inside the ferromagnetic material. Since heat is generated due to energy loss (hysteresis loss) that occurs when changing, induction heating can be performed more easily than with paramagnetic materials or diamagnetic materials, and the aerosol forming substrate 11 can be sufficiently heated.

Further, the Curie temperature, which is the temperature at which a ferromagnetic material loses its magnetic order and transforms into a paramagnetic material, is, for example, about 358° C. in the case of nickel. Therefore, even when the aerosol suction cartridge 1 is heated to a high temperature of, for example, 200° C., the heating temperature does not reach the Curie temperature, and the properties as a ferromagnetic material can be maintained, and the aerosol forming substrate 11 can be stably heated. Can be heated.

The material of the induction heating member 14 is a ferromagnetic material such as iron, ferrite iron, ferrite powder, ferrite particles, ferritic stainless steel, ferromagnetic steel, stainless steel, nickel, cobalt, or a combination of these metal materials. May be adopted. For example, it may be a combination of ferritic stainless steel and nickel, and more preferably an alloy that is a combination of iron, chromium, and aluminum (iron-chromium aluminum alloy).

Here, the relationship between temperature and magnetism of iron and chromium will be explained. Iron has a Curie temperature of about 770°C, and chromium has a Neel temperature of about 35°C, which is the temperature at which it changes from antiferromagnetic to paramagnetic.

Further, the induction heating member 14 may be made of a metal material containing a ferromagnetic material as a main component, for example, a ferromagnetic alloy that is an alloy containing preferably 60% or more, more preferably 80% or more of a ferromagnetic material. may be adopted. For example, a nickel alloy or a nickel-iron alloy may be used. Even in this case, the aerosol forming base material 11 can be sufficiently heated by induction heating the ferromagnetic material. Note that a metal material containing a paramagnetic material and a diamagnetic material may be used instead of a ferromagnetic material. Even in this case, induction heating itself is possible. However, from the viewpoint of shortening heating time and reducing power consumption, it is preferable to use a metal material containing a ferromagnetic material.

Next, the shape and arrangement of the induction heating member 14 according to the first embodiment of the present invention will be explained. 2 is a sectional view taken along line XX in FIG. 1, and FIG. 3 is a schematic perspective view of the induction heating member 14.

As shown in FIGS. 2 and 3, the induction heating member 14 is made by bending a flat plate-like material as a whole, and when viewed from the bottom side of the cylindrical shape when placed inside the filling. , has a non-linear shape that is symmetrical in a direction parallel to the diameter axis of the bottom surface. In the first embodiment, it is V-shaped. Here, in the first embodiment, "symmetrical with respect to the direction parallel to the diameter axis of the bottom surface" means that when the diameter of the circle constituted by the bottom surface of the aerosol forming substrate 11 is taken as the axis, the axis and the It means symmetrical in a parallel direction. The same applies to the following embodiments. Moreover, when viewed from the side of the cylinder, as shown in FIG. 3, it has an elongated shape. Here, the induction heating member 14 is V-shaped and has a non-linear shape that is symmetrical with respect to a direction parallel to the diameter direction of the bottom surface (dotted chain line in the figure). Moreover, it is preferable that the length of at least one or more of the pairs of sides located at symmetrical positions is longer than the radius of the cylindrical circle of the aerosol-forming substrate 11. In the first embodiment, the lengths of the left and right sides of the V-shape are longer than the radius of the cylindrical circle of the aerosol-forming substrate 11.

The flat plate that is the material of the induction heating member 14 has a thickness of 0.05 to 0.5 mm, preferably a thickness of 0.1 to 0.3 mm, and a length that is approximately the same as the length of the aerosol forming base material 11. However, it may be different from this. The width is set to such a size that when forming the V-shape as described above, the lengths of the left and right sides are larger than the radius of the cylindrical circle of the aerosol forming substrate 11.

Note that since the flat plate constituting the induction heating member 14 has a thickness, strictly speaking, the length of the side is not determined like a linear figure, but in the first embodiment, the length of the side is not determined as shown in the enlarged view of FIG. The length of the side is defined based on the line passing through the midpoints (a), (b), and (c) in the thickness direction (dotted line in the enlarged view of FIG. 2). The same applies to the following embodiments.

Further, the bending angle of the V-shape of the induction heating member 14 is determined by considering the diameter of the aerosol forming base material 11 and the width of the flat plate that is the material, so that a part of the induction heating member 14 forms a cylindrical shape forming the aerosol forming base material 11. Set at an appropriate angle so that there is enough space for the heating blade of the heating device to pass through without the center induction heating member being placed. In the V-shape of the first embodiment, it is preferable that the inner angle is, for example, 20° or more. In the first embodiment, the angle is set to 30°±10°.

The induction heating member 14 is arranged inside the aerosol forming base material 11 with its longitudinal direction substantially matching the direction of the central axis of the cylinder forming the aerosol forming base material 11. With such a configuration and arrangement, the induction heating member 14 is not located near the radial center of the aerosol forming substrate 11.

Next, the sealing member 17 is formed into a cylindrical shape, and has a diameter of, for example, 4.0 mm to 7.5 mm, and a length along the central axis of 30 to 70 mm. Like the mouthpiece 16, the sealing member 17 may be provided in a cylindrical shape by winding a sheet-like member made of paper, for example. The sealing member 17 has a function of allowing air to pass from the outside of the cartridge toward the aerosol forming base material 11 . Furthermore, the sealing member 17 can absorb residual liquid that remains on the aerosol-forming base material 11 and liquefies among the water vapor and aerosol generated on the aerosol-forming base material 11 . By making the sealing member 17 a different color from the mouthpiece 16 (for example, black), it is possible to easily determine the upstream side and the downstream side of the aerosol suction cartridge 1. Further, one or more through holes for ventilation may be provided in the height direction of the cylinder, or the cylinder may be formed of a porous material having air permeability.

Next, the manufacturing process of the aerosol suction cartridge 1 according to the first embodiment will be explained. The manufacturing process is roughly divided into a filling material manufacturing process, an aerosol forming base material 11 manufacturing process, and an assembly process, which are performed in this order.

<Filling material manufacturing process>
First, the manufacturing process of the filling material will be explained. The manufacturing process for the filling further includes a drying/pulverizing process in which the main raw material, tobacco plants or non-tobacco plants, is dried, crushed, weighed, etc., and other raw materials are pretreated, weighed, etc. The method includes a preparation step, a mixing step of mixing raw materials to form a composition, and a filling molding step of molding the composition.

In the drying and pulverizing process, the parts of tobacco plants or non-tobacco plants that serve as the main raw materials (for example, leaves, seeds, dried fruits, stems, bark, roots, etc.) are processed into a specified pulverized product in order to create a composition. . At that time, it is preferable to adjust the amount of water to a level convenient for absorbing or supporting the aerosol former, water, and other components added later. In drying, the temperature is preferably 60°C or higher and 80°C or lower. By setting it within this range, it is easy to reach the desired moisture content while avoiding the dissipation of the necessary flavor components. Furthermore, the drying/pulverizing step may include a sieving step for sieving the pulverized material, so that the particle size can be adjusted to a desired size and then fed into the mixing step.

In the preparation step, raw materials necessary for producing the filling can be prepared. The aforementioned microcrystalline cellulose is weighed in the preparation step and introduced into the mixing step.

In the mixing step, a conventional mixer can be used. For example, a configuration is preferably used in which the raw materials in the mixing tank are mixed using a stirring blade while applying shearing force.

In the filler forming step, a composition in which various raw materials are mixed is formed into a thin sheet and then cut to form a strip-shaped or rod-shaped filler. In this embodiment, a plurality of roll mills are prepared to make a thin sheet. When using a multi-roll mill, it is possible to form a sheet of the desired thickness using a doctor blade while performing kneading and dispersion through compression by being pushed between narrow rolls and shearing due to the difference in roll speed. ,preferable. Moreover, it can also be produced using a press roller or a press machine.

Further, in order to obtain a powdery or granular filler, it is preferable to appropriately crush or classify the above composition. The average particle diameter of the powdery or granular filler is preferably, for example, 0.1 to 3.0 mm, more preferably 0.5 mm or less. The average particle diameter is determined, for example, by the sieving method described in JIS K 0069:1992. In other words, this average particle diameter is the diameter corresponding to 50% of the mass obtained by integrating the mass of the test results using a plurality of sieves starting from the one with the largest opening. Alternatively, the particle size at an integrated value of 50% in the particle size distribution determined by a laser diffraction/scattering method may be taken as the average particle size.

In the filling molding step, other means may be used, such as molding the composition by passing it through an orifice under pressure. In addition, in the filling forming process, non-tobacco plants, aerosol formers, binders or thickeners, flavor additives, preservatives, etc. may be further added, or water may be added. Also good.

The thickness of the sheet obtained in the filling molding step is preferably in the range of 0.1 mm to 1.0 mm, more preferably in the range of 0.1 mm to 0.5 mm. The obtained sheet is cut into a predetermined width using a cutter, a rotary cutter with a rotating blade, or the like.

Here, when imparting tackiness to the surface of the filler, there is no particular limitation as long as it is a means capable of imparting tackiness, but the above-mentioned binder may be attached to at least a portion thereof. By imparting tackiness, when combining strip-shaped or rod-shaped fillings with powder, granular or paste-like fillings, powder, granular or paste-like fillings can be applied to the surface of strip-shaped or rod-shaped fillings. Can hold objects stably.

<Formation process of aerosol forming base material>
Next, the manufacturing process of the aerosol forming base material 11 will be explained. The manufacturing process of the aerosol forming base material 11 includes the above-described filler forming process, convergence process, inclusion process, and cutting process as internal processes.

In the converging step, the extended filler after the filler forming step described above is converged to match the diameter of the aerosol forming base material 11. In this convergence step, the extended induction heating member 14 is positioned so that the metal plate that is its material is disposed at a predetermined position, and the extended induction heating member 14 is extended along the induction heating member 14. While disposing the filling material, the induction heating member 14 is covered and converged with the filling material.

Note that the metal plate that is the material of the induction heating member 14 is prepared separately in advance by processing a long ribbon-shaped metal flat plate into a predetermined shape such as a V-shape. The processing was a bending process, and was performed by pressing using a mold.

In the enclosing step, the filling material converged in the convergence step is wrapped by the elongated interior member 12 to form the elongated aerosol forming base material 11.
In the cutting process, the extended aerosol forming base material 11 created in the inclusion process is cut into a predetermined length (10 to 25 mm) using, for example, a roller cutter (not shown). form.

Therefore, by setting the thickness of the induction heating member 14 to 0.1 to 0.5 mm, preferably 0.1 to 0.3 mm, the heat storage property and the heating property by the induced magnetic field can be improved, and the extension during the cutting process can be improved. It is possible to reduce the force required to cut the aerosol-forming base material 11 formed by cutting, and to reduce wear and tear on the roller cutter.

<Assembly process>
Next, the assembly process will be explained. In the assembly process, the aerosol suction cartridge 1 is completed by arranging the sealing member 16, the aerosol forming base material 11, the supporting member 15, and the mouthpiece 16 in a line in this order and wrapping them with the exterior member 13. .

According to this invention, when the induction heating member 14 is viewed from the bottom surface of the aerosol-forming base material 11, it has a non-linear shape that is symmetrical with respect to the direction parallel to the diameter axis of the bottom surface, so that the aerosol-forming base material Since the induction heating member 14 is not located near the radial center of the material 11, there is a space through which a heating blade can be inserted, making it possible to use either a blade heating type or an induction heating type heating device.

In addition, the induction heating member 14 has a length of at least one set of sides that are symmetrical with respect to a direction parallel to the diameter axis of the bottom surface among the sides forming the non-linear shape. Since the radius is longer than the radius of the cylindrical circle of the aerosol forming base material 11, the induction heating member 14 is not located near the radial center of the aerosol forming base material 11, creating a space through which the heating blade is inserted. It becomes possible to use either a heating type or an induction heating type heating device. Furthermore, since the induction heating member 14 covers a wide range inside the aerosol forming base material 11, it becomes possible to effectively heat a wide range.

Embodiment 2
Based on FIGS. 4 to 6, the aerosol suction cartridge 2 according to the second embodiment will be described. Here, illustrations and descriptions of configurations and functions common to those of the first embodiment will be omitted.

As shown in FIG. 4, the induction heating member 24 is a component that extends in the radial direction of the cylindrical shape when viewed from the side surface of the cylindrical shape while being disposed inside the filling of the aerosol forming base material 21. It has a non-linear shape. In this second embodiment, as shown in FIGS. 5 and 6, a component parallel to the direction of the central axis of the cylinder forming the aerosol forming base material 21 (parallel component 24-1) and a component perpendicular to it (vertical component 24-2), so to speak, it has a shape of three connected inverted T-shapes.

Like the induction heating member 14, the induction heating member 24 is made by cutting and bending a long ribbon-shaped metal flat plate. Similarly, regarding the size and arrangement of the vertical component 24-2 when folding, the induction heating member is placed at the center of the cylinder constituting the aerosol forming base 211, taking into account the diameter of the aerosol forming base 21 and the width of the flat plate that is the material. The dimensions and angle are set so that there is sufficient space for the heating blade to pass through without the heating blade 24 being placed. In the second embodiment, the vertical component 24-2 is set to be longer than the radius of the aerosol forming base material 11 in the longitudinal direction (vertical direction in FIG. 5) and shorter than the radius in the transverse direction (horizontal direction). There is. Specifically, it has a substantially rectangular shape with a longitudinal side of 5 mm and a short side of 2 mm. With such a configuration and arrangement, the induction heating member 24 is not located near the radial center of the aerosol forming base material 21.

According to this invention, the induction heating member 24 has a non-linear shape having a component extending in the radial direction of the cylinder when viewed from the side of the cylinder while being disposed inside the filling. Since the induction heating member 24 is not located near the radial center of the aerosol forming base material 21, there is a space through which the heating blade is inserted, which allows it to be used with either a blade heating type or an induction heating type heating device. It becomes possible to do so. In addition, in the geometric configuration of the induction heating member 24, the component in the direction perpendicular to the alternating magnetic field becomes large, so eddy currents are more likely to occur during induction heating, making heating using Joule heat more efficient. becomes possible.

Although the embodiments of the present invention have been described above, the scope of the present invention is not limited to the above embodiments, but also extends to other embodiments that can be regarded as the same.

For example, in the first embodiment, the induction heating member 14 has a V-shape when viewed from the cylindrical bottom side when placed inside the filling, but the invention is not limited to this. Any other shape may be used as long as it has a non-linear shape that is symmetrical with respect to the direction parallel to the diameter axis of the bottom surface. For example, it may be U-shaped as shown in FIG. 7(a), W-shaped as shown in FIG. 7(b), or U-shaped, or a combination thereof. But that's fine. Here, in the case of a curved shape that does not have clear corners, such as a U-shape, the length of the sides is determined based on the imaginary center line (dotted chain line in the figure), which is the standard for determining symmetry. , as described above, is determined based on the length to the intersection of the line passing through the center in the thickness direction and the imaginary line. In this case, a portion of the induction heating member 14 is located at the center of the cylinder that constitutes the aerosol forming base material 11.The induction heating member is not placed, and the dimensions are such that there is enough space for the heating blade of the heating device to be inserted. and set the angle. In this case, the length of at least one of the pairs of sides located symmetrically with respect to the direction parallel to the diameter axis of the circle is greater than the radius of the cylindrical circle of the aerosol forming substrate 11. By setting such dimensions, it becomes easy to prevent a portion of the induction heating member 14 from being located at the center of the cylinder. For example, in the case of the W-shape shown in (b), the lengths of two sets of sides (two sides at both ends and two sides at the center) are set to be longer than the radius.

Further, as shown in FIG. 8, the induction heating member 14 may be made of a material containing ferromagnetism, and may have a plurality of heat generating parts 54 that perform induction heating and heat conducting parts 55. Here, the heat conduction part 55 is made of a material (for example, SUS304, aluminum) that does not generate heat due to hysteresis loss like a nonmagnetic material or a paramagnetic material, and has a smaller contribution to induction heating than a ferromagnetic material. use. In FIG. 8A, both the heat generating part 54 and the heat conducting part 55 are V-shaped, and the heat conducting part 55 is formed larger than the heat generating part 54. In FIG. Here, the heat generating part 54 is placed inside the V-shape of the heat conducting part 55 while ensuring thermal contact. The heat generated by the heat generating part 54 during induction heating is transmitted to a wide range of the aerosol forming base material 11 via the heat conducting part 55, and it becomes possible to effectively heat a wide range of the aerosol forming base material, thereby making it possible to heat the aerosol forming base material more effectively. It becomes possible to efficiently generate aerosol. Furthermore, since there is no heat generation due to hysteresis loss in the heat conduction section 55, stable heating can be performed without excessive heat generation. On the other hand, in (b), the heat generating portion 64 is used in a flat plate shape without any particular bending process, but it is possible to obtain the same effect even with such a shape.

Further, the induction heating member 24 in the second embodiment is made by cutting and bending a ribbon-shaped long metal flat plate as a material, but as shown in FIG. 9(a), the vertical component 74-2 The corners may be rounded. Further, when performing the cutting process, the vertical component 84-2 may be formed by simply performing a bending process as shown in FIG. 9(b). In this case, an opening 84-3 having a size corresponding to the length and width of the heating blade is formed in the vertical component 84-2 so as not to interfere with the heating blade during use.

Furthermore, in the first embodiment, the induction heating member 14 may have a rectangular shape as shown in FIG. 10, or may have a polygonal or circular shape as long as it has a non-linear shape. Further, when forming a polygonal or circular shape, the shape may be partially open, such as a C-shape, instead of being a closed shape.

Further, the U-shaped induction heating member 34 in FIG. 11(a) has a cut 34-1 in a part in a direction substantially perpendicular to its longitudinal direction, which has a depth that penetrates the induction heating member 34 in the thickness direction. are arranged one or more along the longitudinal direction. Furthermore, the cut 34-1 is formed within a range that does not completely divide the induction heating member 34. Here, it is formed in a direction substantially perpendicular to the longitudinal direction so that its both ends (corresponding to the longitudinal sides of the induction heating member 34) are not separated. By doing so, in the above cutting process, when the induction heating member 34 is cut, it is possible to minimize deformation due to the pressure of the roller cutter. Further, since the notch 34-1 is penetrating, it becomes a ventilation hole, and it becomes possible to improve the ventilation of the generated aerosol. Moreover, this may be a V-shaped induction heating member 14 as shown in FIG. 11(b), or may be of other shapes such as a U-shape.

Further, as in the induction heating member 14 of FIG. 12, a non-penetrating cut 14-2 may be formed. By doing so, when forming a non-linear shape using the notch 14-2 as a deformation part, it becomes possible to easily deform the cut 14-2. In FIG. 12, the cut 14-2 is a straight line, and this is a V-shaped case, but the invention is not limited to this, and by adjusting the number and spacing of the cuts 14-2, a W-shape, It can form a variety of shapes, such as a U-shape.

Further, as shown in FIG. 13, the induction heating member 104 has an elongated shape as a whole, and its entire length (total length) is longer than the sum of the longitudinal direction and the diameter of the aerosol forming base material 11. It may have a bent portion bent at 90 degrees or more in a part of the direction, and may be arranged along the longitudinal direction of the aerosol forming base material 11 . For example, as shown in FIG. 14(a), the induction heating member 104a may be U-shaped and have a bent portion 104a1 bent at approximately 180 degrees, or as shown in FIG. 14(b) The induction heating member 104b may be V-shaped and have a bent portion 104b1 bent at 90° to 180°. Further, other shapes such as a W-shape, a U-shape, a combination thereof, etc. may be used.

When the induction heating member 104 has such a shape, its position within the filling is stabilized, and it is possible to prevent the position from shifting inside the aerosol forming base material 11 or falling off. Since it is longer than the sum of the longitudinal direction and the diameter of the forming base material 11, the contact area with the filler increases, so the heating range can be widened and the amount of aerosol generated can be increased.

Moreover, unlike the above manufacturing process, when the induction heating member 114 is inserted into the filling of the aerosol forming base material 11 later, the induction heating member 114 is Preferably, 114 is elongated and one or both of its ends are formed at an acute angle with respect to its longitudinal direction. In FIG. 15(a), the induction heating member 114a is U-shaped, and in FIG. 15(b), the induction heating member 114b is V-shaped. Further, other shapes such as a W-shape, a U-shape, a combination thereof, etc. may be used. Alternatively, an acute angle may be formed in a simple shape such as a flat plate.

Here, the acute angle means the smaller of the internal angles θ formed between the longitudinal direction and the end of the induction heating member 114 when viewed from the side, as shown in FIG. 16, and θ is less than 90°. This is called an acute angle. Specifically, the angle is preferably 30 to 70°, and more preferably 40 to 60°. If it is smaller than this, the tip will become too thin and structurally weak, and if it is too large, it will not be able to be smoothly inserted into the filling. Also, acute angles may be formed at both ends.

According to this, unlike the above-mentioned manufacturing process, when the induction heating member 114 is inserted into the filling material of the aerosol forming base material 11 later, the sharp tip allows the induction heating member 114 to stab smoothly into the filling material. This makes it possible to increase productivity, which is effective in improving productivity. In addition, when the induction heating member 114 has a flat plate shape as described above, if it is possible to use either the blade heating type or the induction heating type, the induction heating member 114 when viewed from the bottom side of the cylindrical shape. Preferably, the member 114 is offset from the center of the bottom surface (ie, offset from the diametrical axis passing through the center).

In addition to the tea leaves listed in the embodiment, all commonly used tea leaves can be used as the raw material for the filling. Further, for these tea leaves, used tea leaves may be used after drinking. By using used tea leaves, you can reuse and effectively utilize expensive tea leaves.

In addition, extracts of non-tobacco plants such as those exemplified above, so-called extracts and processed products can also be used. Examples of the form of the extract include liquid, syrup, powder, granules, and solution.

In addition to the materials listed in the embodiment, aerosol formers used as raw materials for fillings include sorbitol, triethylene glycol, lactic acid, diacetin (glycerine diacetate), triacetin (glycerine triacetate), and triethylene glycol diacetate. Cetate, triethyl citrate, isopropyl myristate, methyl stearate, dimethyl dodecanedioate, dimethyl tetradecanesanedionate, and the like can also be used.

Additionally, menthol and a water-insoluble crosslinked polymer (preferably polyvinylpolypyrrolidone) may be included as flavor additives. By combining menthol with a water-insoluble crosslinked polymer, sublimation of menthol can be effectively suppressed and the flavor of menthol can be maintained for a long period of time. Here, menthol is not limited to those obtained from natural products, and may be synthetic products. Additionally, peppermint, mint, peppermint oil, and other substances containing menthol may be used.

Further, the flavor additive is provided in the mouthpiece 16 by impregnating the wall of the mouthpiece 16, for example. The mode in which the flavor additive is provided in the mouthpiece 16 is not limited to this mode. For example, by embedding a capsule containing the flavor additive in the wall of the mouthpiece 16, the flavor additive can be provided in the mouthpiece 16. 16 may be provided with a flavor additive. Alternatively, a capsule containing a flavor additive may be placed between the mouthpiece 16 and the aerosol-forming substrate 11. When the flavor additive is encapsulated in a capsule, the user can destroy the capsule by pressing the capsule with his/her finger, allowing the aromatic components of the flavor additive to volatilize at the desired timing. Become.

Further, when the flavor additive is encapsulated in microcapsules, for example, the encapsulated microcapsules may be provided on the aerosol forming base material 11. Of course, the microcapsules may be provided on the support member 15.

In addition to the binders or thickeners used as raw materials for the filling, in addition to those listed in the embodiments, examples include rubbers such as xanthan gum, gum arabic, and locust bean gum, such as carboxymethyl cellulose, hydroxyethyl cellulose, methyl cellulose, and ethyl cellulose. or polysaccharides such as conjugated base salts of organic acids such as alginic acid, sodium alginate, sodium carboxymethyl cellulose, calanagin, agar and pectin, and combinations thereof.

Furthermore, when using a raw material that does not contain nicotine, such as a non-tobacco plant, a substance that provides a feeling similar to nicotine, a so-called kick feeling, may be added. For example, plants belonging to the genus Piper of the family Piperaceae (Piper spp., Piper spp., Piper spp., Piper spp., etc.), black pepper, white pepper, piperine, lobeline, kavicin, capsaicin, dihydrocapsaicin, glucosinolate, allyl isothiocyanate, and the like are preferred.

Further, the support member 15 may be formed of a resin material other than those mentioned in the embodiment, or a material other than the resin material, such as wood or metal (aluminum, etc.) that increases the cooling effect. Furthermore, the support member 15 is not necessarily necessary if the aerosol forming base material 11 is configured to not easily move toward the mouthpiece 16 (e.g., the aerosol forming base material 11 is fixed to the exterior member 13). .

Similarly, the induction heating member 14 may be a combination of ferromagnetic, paramagnetic or diamagnetic materials. For example, a flat plate made of nickel, which is a ferromagnetic material, and a flat plate made of iron, which is a ferromagnetic material, are physically brought into close contact, or a flat plate of ferromagnetic material and a flat plate made of paramagnetic material are bonded together. Examples of such methods include physically adhering a flat plate made of aluminum, and coating the outer surface of a ferromagnetic material with a paramagnetic material.

Further, the induction heating member 14 does not necessarily need to be formed only from a metal material, and may be made of a composite material of metal and non-metal, etc., as long as it has magnetism as a whole.

Further, the filler may be formed into powder or granule form, or may be formed into paste form.

Furthermore, in the manufacturing method, the induction heating member 14 may be inserted after the aerosol forming base material 11 is formed by including the filler in the interior member 12 in advance. In this case, wear and tear on the roller cutter during the cutting process can be further reduced.

Moreover, the support member 15 is not necessarily required if a means is taken to ensure the shape and position of the filler in the aerosol forming base material 11. In this case, it becomes possible to improve air permeability and to reduce costs by reducing the number of parts. In this case, the means include, for example, molding the filler into a paste form, or providing a partition wall such as a sealing member 17 on the mouthpiece 16 side as well.

Further, a cooling member may be provided between the support member 15 and the mouthpiece 16 to cool the aerosol. This effectively cools the heat of the aerosol, allowing the user to inhale it without any trouble. Here, the cooling member is preferably formed of a material that has a large surface area, such as a porous material or a crimped material, such as paper, resin, or metal.

1, 2, 3 Cartridge for aerosol suction 11, 21 Aerosol forming base material 12 Interior member 13 Exterior member 14, 24, 34, 44, 54, 64, 74, 84, 94, 104, 114 Induction heating member 15 Support member 16 Mouthpiece 17 Seal member

Claims (9)

An aerosol suction cartridge having an overall cylindrical shape and used in an induction heating device,
an aerosol-forming base material comprising a filler that generates an aerosol;
a mouthpiece disposed at one end of the cylindrical shape for inhaling the aerosol;
an exterior member for packaging the aerosol forming base material and the mouthpiece;
an induction heating member disposed inside the filling of the aerosol forming base material,
The induction heating member has a non-linear shape that is symmetrical with respect to a direction parallel to a diametrical axis of the bottom surface when viewed from the side of the cylindrical bottom surface while disposed inside the filling. There is,
An aerosol suction cartridge characterized by: The induction heating member has a length of at least one set of sides that are symmetrical with respect to a direction parallel to the diameter axis of the bottom surface, among the sides constituting the non-linear shape. longer than the radius of the cylindrical circle;
The aerosol suction cartridge according to claim 1, characterized in that: The non-linear shape is V-shaped, U-shaped, U-shaped, or a combination thereof.
The aerosol suction cartridge according to claim 1 or 2, characterized in that: The induction heating member has one or more notches arranged along the longitudinal direction in a part of the induction heating member in a direction substantially perpendicular to the longitudinal direction thereof, each having a depth that penetrates the induction heating member in the thickness direction. ing,
The aerosol suction cartridge according to claim 1 or 2, characterized in that: The induction heating member has a non-penetrating cut formed in the deformed portion forming the non-linear shape.
The aerosol suction cartridge according to claim 1 or 2, characterized in that: An aerosol suction cartridge having an overall cylindrical shape and used in an induction heating device,
an aerosol-forming base material comprising a filler that generates an aerosol;
a mouthpiece for inhaling the aerosol, disposed at one end of the cylindrical shape and located on the opposite side of the aerosol-forming substrate;
an exterior member for packaging the aerosol forming base material and the mouthpiece;
an induction heating member disposed inside the filling of the aerosol forming base material,
The induction heating member has a non-linear shape having a component extending in the radial direction of the columnar shape when viewed from the side surface of the columnar shape while disposed inside the filling.
An aerosol suction cartridge characterized by: An aerosol suction cartridge having an overall cylindrical shape and used in an induction heating device,
an aerosol-forming base material comprising a filler that generates an aerosol;
a mouthpiece disposed at one end of the cylindrical shape for inhaling the aerosol;
an exterior member for packaging the aerosol forming base material and the mouthpiece;
an induction heating member disposed inside the filling of the aerosol forming base material,
The induction heating member has a length longer than the sum of the length of the longitudinal direction and the diameter of the aerosol forming substrate, and has a bent part bent at 90 degrees or more in a part of the longitudinal direction, arranged along the longitudinal direction of
An aerosol suction cartridge characterized by: A part of the induction heating member is formed of a non-magnetic material or a paramagnetic material.
The aerosol suction cartridge according to any one of claims 1, 2, 6, or 7, characterized in that: The induction heating member has one or both ends formed at an acute angle with respect to its longitudinal direction.
The aerosol suction cartridge according to any one of claims 1, 2, 6, or 7, characterized in that:

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