KR20200041339A - Heating unit for HNB-tobacco goods and method for manufacturing heating unit - Google Patents

Abstract

The present invention relates to a heating unit (13) for an HNB-tobacco article (10) comprising a tobacco-containing material (26) and an electrical resistance-heating element (18) for heating the tobacco-containing material (26) without combustion. It is about. The resistance-heating element 18 is made of a conductive suspension.

Description

Heating unit for HNB-tobacco goods and method for manufacturing heating unit

The present invention relates to a heating unit for an HNB-tobacco article comprising a tobacco-containing material and an electrical resistance-heating element for heating the tobacco-containing material without combustion. The present invention also relates to a method of manufacturing a heating unit for HNB-tobacco products.

Heat-Not-Burn (HNB) -goods that have been produced without the burning of the flavoring agent by heating the tobacco or tobacco-containing substances, and therefore without the generation of smoking gases, have been known for a long time, for example, European Patent Publication EP 0 430 The 559 B1 is one of them. Here, for example, a flavoring medium containing tobacco surrounds the heating element in the form of a cylinder in the form of a cylinder. At this time, the heating element is a resistance coil provided in the heat insulating tube.

Another alternative structure of HNB-tobacco goods is disclosed in PCT International Patent Publication No. WO 2013/131764 A1. Here, a combustible material, such as a tobacco mixture, is filled in the chamber, and the heater is arranged in a cylindrical shape to surround the chamber. For example, a ceramic heater, an infrared heater or a resistance heater is proposed.

In the two inventions mentioned above, the tobacco material in contact with the heater is heated directly, but the material far from the heater is heated indirectly and with delay. The non-uniform temperature distribution caused thereby inhibits the desirable divergence of the active substance and the flavoring agent, and has a disadvantage of impairing the reduction of hazardous substances.

An object of the present invention is to provide a heating unit that enables uniform heating of the tobacco-containing substance and a method of manufacturing the heating unit.

The present invention is to solve the above problems with the technical characteristics described in the independent claims. Since the resistance-heating element is made of a conductive suspension, at the point of manufacture, where the suspension is in a well-coated or fluid state, at any desired position in direct contact of the heating element with the tobacco-containing material. It becomes possible to deploy. Due to the direct contact over a wide range of these heating elements and tobacco-containing substances, uniform, direct, and delay-free heating of the tobacco-containing substances is possible, which results in the desired release and hazard of the active and flavoring agents. Reduces divergence.

It is preferred that the resistance-heating element is made of a conductive ointment. In this impractical, non-flowing embodiment, the suspension can be more easily machined, but the present invention utilizes a fluid to fluid suspension as the material of the heating element as well.

According to another preferred embodiment of the invention, the conductive suspension comprises graphite. Instead of graphite, other conductive materials can also be used for metallic or other bases.

According to another preferred embodiment of the present invention, a conductive suspension is applied to the carrier member. The carrier member may preferably be partially ceramic or comprise a ceramic layer. Other suitable carrier members are possible. When ceramic is combined with graphite as a carrier member, a manufacturing technique used to generate carbon film resistance can be advantageously applied.

According to another preferred embodiment of the present invention, the conductive layer forming the heating element is inserted into a multi-layered carrier member, for example between ceramic layers. According to an embodiment, a layer system is proposed in which layers of ceramic, conductive layer, ceramic, and tobacco are layered in order. Depending on the manufacturing process, complex geometric structures can also be considered. For example, the carrier member may have a three-dimensional carrier structure, for example a tubular structure at least partially filled with a conductive material. Such a structure requires a significantly larger surface area than conventional heaters.

According to another preferred embodiment of the present invention, a conductive suspension is applied to the carrier member.

Applying the conductive suspension to the carrier member or directly to the tobacco-containing material is very effective in the printing process, especially in the process using a screen printing method. In this case, two variations can be considered. It is contemplated that the resistance-heating element is printed on the carrier member as a (heated) specimen (sample printing), while alternatively, the same shape or homogeneous layer is applied to the carrier member, especially through a printing or spraying process. The same or homogeneous layer is then transferred to the final (heat-) structure through a separation process in a subsequent second working process. This is done, for example, through laser engraving. Thus, a very precise and complex heating structure can be realized simultaneously for a very thin heating element, which leads to optimum heat dissipation.

The heating element is electrically individual controllable, for example to produce various temperatures, preferably comprising a number of sections. Alternatively, the sections can be heated, for example, also sequentially, to ensure persistence in use, for example. If one section corresponds to the experience of smoking and consuming one cigarette, the production of multi-tobacco-goods can also be realized in this way.

The tobacco-containing material may be, for example, a tobacco mixture, and may also include other components, such as those based on fiber. Also included are foil tobacco and / or reconstituted tobacco material (so-called reconstituted material).

The present invention also proposes a method of manufacturing a heating unit for an HNB-tobacco article, characterized in that the resistance-heating element consists of a conductive suspension.

The present invention will be described in detail below based on preferred embodiments while referring to the accompanying drawings.

1 is a cross-sectional view of an HNB-smoking article.
2 shows an embodiment of a heating unit for an HNB-smoking article according to the present invention.
3 shows another embodiment of a heating unit for an HNB-smoking article according to the present invention.
4 shows a layer system for a heating unit according to the invention.
5 shows a tubular layer structure for a heating unit according to the invention.
6 shows another layer system of a heating unit according to the invention.
7 shows an alternative layer system of a heating unit according to the invention.
8 shows another tubular layer structure of the heating unit according to the invention.

The inhaler 10 shown in FIG. 1 includes an electric energy source 12, a heating unit 13, and a rod-shaped housing 11 in which the electric control material 14 is provided. The electrical energy source 12 can be, for example, a battery or a rechargeable battery. The housing 11 includes a mouthpiece 15 that can be sucked by a user to create an air stream. Furthermore, the housing 11, when a user generates a low pressure in the housing 11 by sucking the mouthpiece 15, one or a plurality of air through which the surrounding air may be introduced into the housing 11 It includes an inlet 16. In this way a regulated air flow 17 within the housing 11 is possible.

The heating unit 13 is arranged in the heating section 19 formed in the axial direction inside the housing 11. The heating unit 13 can be a replaceable cartridge or can be part of such a cartridge. The body of the inhaler 10 is reusable. In this embodiment, the inhaler 10 may consist of a reusable body and a disposable-cartridge.

The air flow 17 passes through the heating section 19 in order to receive the functional substances and / or flavoring agents emitted from the tobacco-containing substance 26 due to the heating element 18, wherein the heating unit ( 13) or proceed directly along the surface of the heating unit 13. This process is described in detail below.

One preferred embodiment of the heating unit 13 according to the invention is shown in FIG. 2. The heating unit 13 comprises a heating element 18 mounted on a non-conductive carrier member 20, suitable for this embodiment. The carrier member 20 may include, for example, a ceramic or ceramic layer or ceramic coating. A number of other materials suitable for the carrier member 20 can also be considered, such as synthetic foils such as polyimide. The carrier member 20 supporting the heating element 18 may be elastic or vice versa. The carrier member 20 should not thermally react within the working range of the inhaler, ie within the controlled heating range.

When manufacturing the heating unit 13, the heating element 18 is provided in a suspension state in which conductive particles are mixed in the liquid, that is, as a solid-liquid-mixture. In the suspension, the ointment is preferably considered, that is, since the proportion of the conductive particles in the suspension is high, the suspension is no longer fluid and has a firmness that can be applied. The conductive particles may preferably be graphite. As a suspension metal particles and particles suitable for a large number of different conductions can be considered. Therefore, in the case of graphite, the heating element 18 is essentially a graphite ointment.

The suspension or ointment is applied to the carrier member 20 in a form corresponding to the heating element 18 when the heating unit 13 is manufactured. It is effective that the process of applying the suspension or ointment agent to the carrier member 20 is performed through a printing process, in particular a screen printing process, or other suitable process. The heating element 18 is then made by drying the suspension or ointment by exposure to air.

Then, the tobacco component-containing material 26 is applied to the carrier member 20 having the heating element 18. The tobacco-containing material 26 may be a tobacco mixture in particular. The tobacco-containing material 26 is in direct contact with the heating element 18, and thereby can be uniformly heated.

When the electronic control material 14 recognizes that the sip is inhaled by the user in an appropriate manner, the electronic control material is a heating element 18 of the heating unit 13 in order to heat the tobacco-containing material 26 to an appropriate temperature. To apply electricity. In this way, the flavoring agent of the cigarette is not burned, and is emitted without the release of harmful smoking gas and carried on the air stream 17. The key in this embodiment is the so-called HNB (Heat Not Burn) -tobacco article 10.

The method of arranging the conductive layer forming the heating element 18 in the carrier member 20 can be implemented by variously modified geometrically. It is preferable that the heating elements 18 are composed of a plurality of heating conductors 22 arranged in parallel to each other in this embodiment. An electrical connection 24 is provided at one connection end 23 of the heating conductor structure 18. A heating conductor loop 21 made of two heating conductors 22 each in this manner is formed by binding the heating conductors 22 to other connection ends of the heating conductor structures 18 facing them so that they can be conducted to each other, for example. ) Is made. Heating voltages are applied to the two connecting portions 24, respectively, so that the heating conductor loops 21 traveling between the connecting portions 24 are individually heated.

Therefore, in order to generate various temperatures, it is preferable that the heating conductor loops 21 are formed of sections 21 of a plurality of heating elements 18, which are electrically individually controlled. Alternatively, it is also possible that the sections 21 are sequentially heated, for example to ensure continuity in the process of smoking. If one section 21 corresponds, for example, to one cigarette smoking (habit), multi-tobacco-articles can also be realized in this way.

Preferably, the tobacco component-containing material 26 is disposed on the heating element 18 as flatly and uniformly as possible, since the maximum overlap occurs between the tobacco-containing substance 26 and the flat type heating element 18. This is because the heating performance of the heating element can directly and uniformly affect the entire tobacco component-containing material 26. If the tobacco component-containing material 26 is made of fiber, it is preferable that the heating conductor 22 is arranged in a direction transverse to the direction in which the long conductor 22 extends.

In the embodiment shown in Fig. 3, the tobacco component-containing material 26 simultaneously forms the carrier member 20. When this is effective, the tobacco-containing substance 26 is sufficiently strong enough to exert a supporting function in the heating unit 13. The tobacco-containing material 26 may include, for example, fibrous raw materials, such as paper, into which crushed, finely crushed or powdered tobacco is carried.

Here, the heating element 18, which is similarly proposed as a conductive suspension or ointment, is directly applied to the tobacco component-containing material 26, and is printed, for example, through a screen printing process. In this embodiment, the step of applying the tobacco component-containing material 26 to the carrier member 20 having the heating element 18 is omitted. It is likewise ensured that the maximum overlap between the tobacco component-containing material 26 and the heating element 18 is achieved, and it becomes impossible for the tobacco material to escape from the carrier member 20.

One variant of the embodiment according to FIG. 2 is shown in FIG. 4. Here, the heating unit 13 is composed of two, eg, ceramic carrier layers 20A, 20B, through which a conductive layer 18, eg, a graphite layer, is inserted. Tobacco component-containing material 26 is applied over the ceramic layer 20A.

An alternative layer system for the heating unit 13 is shown in FIG. 6. Here, a two-layer system comprising a carrier member 20, a heating element 18, and a tobacco component-containing material 26 is disclosed. As shown, the tobacco component-containing material 26 includes a heating element 18 and It may be disposed in relation to it, or alternatively it may be arranged in a manner that lies outside.

Another multilayer system for the heating unit 13 is disclosed in FIG. 7. On the outside is an insulating layer 27, which can be for example part of the housing 11 or part of the cartridge-housing. Between the insulating layers 27, two containing the tobacco component-containing material 26, the carrier member 20, the heating element 18, the carrier member 20, and the tobacco component-containing material 26, respectively, in the order listed below, respectively. A four layer system is provided. An air channel 28 for the air flow 17 is provided between these two layer systems and between the individual layer systems and the insulating layer 27.

The layer structure shown in FIGS. 4, 6 or 7 is used to implement a complex geometric evaporator structure.

For example, FIG. 5 shows a tubular structure comprising a tobacco component-containing material 26, which structure partially or entirely forms a coating film on a tubular carrier 20 that is to be filled with a conductive material 18. Show.

8, the insulating layer 27, the air channel 28, the tobacco component-containing material 26, the carrier member 20, the heating element 18, the carrier member 20, the tobacco component-containing material 26, air An alternative to the layered structure of the cylinder shape is proposed in which the channels 28 are stacked in order from the outside to the inside. A nucleus 29 exerting an insulating function may be disposed inside the heating element 18.

Claims (14)

-Tobacco-containing substance (26); And
-A heating unit 13 for an HNB-tobacco article 10 comprising an electrical resistance-heating element 18 for heating the tobacco-containing material 26 without burning it,
The electrical resistance-heating element 18 is a heating unit for HNB-tobacco article, characterized in that it is made of a conductive suspension. The method according to claim 1,
The electrical resistance-heating element 18 is a heating unit for HNB-tobacco article, characterized in that it is made of a conductive ointment. The method according to claim 1 or claim 2,
The heating unit for HNB-tobacco article, wherein the conductive suspension comprises graphite. The method according to any one of claims 1 to 3,
The heating unit for HNB-tobacco article, characterized in that the conductive suspension is applied to the carrier member (20). The method according to claim 4,
The carrier member 20 is at least partially ceramic or a heating unit for HNB-tobacco article, characterized in that it comprises a ceramic layer. The method according to claim 4 or claim 5,
The heating unit for HNB-tobacco article, characterized in that the conductive layer forming the electrical resistance-heating element 18 is inserted into a multi-layer carrier member 20. The method according to any one of claims 4 to 6,
The HNB-tobacco article 10 is a heating system for a HNB-tobacco article, characterized in that the ceramic, conductive layer 18, ceramic, and tobacco component-containing material 26 are layered in order. The method according to any one of claims 4 to 7,
The carrier member 20 is a heating unit for a HNB-tobacco article, characterized in that it consists of a three-dimensional carrier structure, for example a tubular structure at least partially filled with a conductive material 18. The method according to any one of claims 4 to 8,
The heating unit 13 is made of a tubular, at least partially filled with a conductive material, characterized in that the heating unit for HNB-tobacco products. The method according to any one of claims 1 to 9,
Heating unit for HNB-tobacco article, characterized in that the conductive suspension is applied to the tobacco-containing material (26). The method according to any one of claims 1 to 10,
The conductive suspension is heating unit for HNB-tobacco article, characterized in that it is printed on the carrier member 20 or the tobacco-containing material 26, in particular through a screen printing method. The method according to any one of claims 1 to 11,
The heating element 18 is a heating unit for HNB-tobacco article, characterized in that it comprises a plurality of sections 21 that can be individually electrically controlled. The HNB-tobacco article 10 according to any one of claims 1 to 12,
The HNB-tobacco article 10 comprises a heating unit 13 according to any one of claims 1 to 12, HNB-tobacco article. Manufacturing of a heating unit 13 for an HNB-tobacco article 10 comprising a tobacco-containing material 26 and an electrical resistance-heating element 18 for heating the tobacco-containing material 26 without burning. As a method,
The electrical resistance-heating element 18 is a method of manufacturing a heating unit for HNB-tobacco article 10 characterized in that it is applied to the carrier member 20 or the tobacco-containing material 26 in the form of a conductive suspension. .

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