JP2015051015A - Smoking - Google Patents

Abstract

[PROBLEMS] A new type of smoking that is simple in structure and handling, and that quickly reaches a temperature at which a heat source optimally volatilizes a tobacco leaf without adding liquid or water separately or using a chamber therefor. Offer things.
SOLUTION: A tobacco leaf 3, a suction resistor 4 and a chemical heat source 2 acting on the tobacco leaf are provided. The heat source is constituted by a heat chamber, and is activated by an external stimulus to generate heat.
[Selection] Figure 1

Description

  The present invention relates to a smoking article as defined in the preamble of claim 1 and a method for producing a smoking article as defined in the preambles of claims 16 and 21.

  Because of the dependence of nicotine in tobacco, it is very difficult for smokers to stop smoking. An accepted alternative was to take nicotine in other forms or other ways instead of smoking.

  Known tobacco substitutes and / or articles that aid smoking cessation include chewing gum, salves, spray nasal drops or medicinal candy supplemented with nicotine.

  The problem with these alternatives is that their use does not involve a smoking experience. Smokers want an actual smoking experience and thereby want to taste, for example, the taste of cigarettes and smoke.

  U.S. Pat. No. 7,290,549 discloses a smokeless smoking article. This smoking article has a tobacco leaf and a non-smoke chemical heat source that heats it and volatilizes the aroma or tobacco-containing aerosol. The heat source heat chamber comprises an exothermic cartridge containing an exothermic compound (such as magnesium and iron) and an activating solution (such as a solution of potassium chloride and potassium nitrate) separated by a partition that is easily crushed. It is. In this smoking article, an exothermic reaction is provided by combining the exothermic cartridge and the activation solution by crushing the partition walls.

  The problem with smokeless smoke is that the temperature rises slowly to the optimum volatilization temperature range of tobacco leaves, which is about 125 ° C to 150 ° C. In addition, in order to initiate an exothermic reaction, the smoking article needs to combine two separate chambers.

  EP 0371285 discloses a smoking article comprising a tobacco leaf, a filter element and a heat source. This heat source contains substances (for example, metal oxides and anhydrous metal sulfates) that cause an exothermic reaction when contacted with water. Contact between water and this heat source component generates heat that warms and leaves the tobacco leaves to volatilize. The water required for this reaction may be injected into a heat source, incorporated into a separate friable capsule, or impregnated with a solid salt or hydrated salt.

  U.S. Pat. No. 5,285,798 discloses a smoking article comprising tobacco leaves, a filter element, and a heat source. The chemical substance serving as a heat source comprises at least two metal materials and reacts electrochemically when it comes into contact with an electrolyte solution, for example, water. This electrochemical reaction produces heat that warms and volatilizes the tobacco leaves.

  The problem with the smoking article is that the water that provides the exothermic reaction must be separated from the compounds that react together in the smoking article. These smoking articles always require a separate water capsule, water injection or water release from the hydrated salt to cause an exothermic reaction.

[Object of invention]
The object of the present invention is a new structure free of smoke, which is simple in structure and handling, quickly reaches the temperature at which the heat source will optimally volatilize the tobacco leaf without the need for additional liquid or water and the use of a chamber for it. To provide a type of smoking article. A further object of the smoking article of the present invention is to smoke the smoker without burning tobacco leaves or other components, without smoking outside, and without producing any combustion products such as carbon monoxide. It is to provide a bodily experience. One particular object of the present invention is to alleviate the above mentioned problems.

  Another object of the present invention is to disclose a method for producing this smoking article.

  The smoking article according to the invention is characterized by what is stated in claim 1.

  The method for producing a smoking article according to the present invention is characterized by the matters described in claims 16 and 21.

  The smoking article according to the present invention includes a tobacco leaf, a suction resistor, and a chemical heat source that acts on the tobacco leaf. The chemical heat source comprises a heat chamber formed in a continuous quantity and is activated by external heat and / or oxygen excitation. This chemical heat source is based on an exothermic reaction.

  The heat chamber may be closed.

  The heat generated in the heat chamber quickly reaches and maintains the temperature within the range of 125 ° C. to 150 ° C., which is the desired temperature at which the tobacco leaves volatilize. This heat volatilizes the aroma and nicotine from the tobacco leaves. Aroma from tobacco leaves and other active substances such as nicotine can be optimally released in the desired volatilization temperature range without burning or generating smoke.

The heat chamber contains a compound capable of generating heat. This compound usually contains one or more metals and / or a strongly acidic oxidant. This metal is a metal belonging to a transition metal, alkali metal, alkaline earth and / or other group. Typical examples of applicable metals are iron (Fe), aluminum (Al), magnesium (Mg), lithium (Li), cobalt (Co), platinum (Pt), palladium (Pd), copper (Cu). , Silicon (Si), and iron is particularly preferable. Strongly acidic oxidants are metal oxides, metal peroxides and / or metal oxide salts, such as potassium permanganate, manganese dioxide, lead 3-tetraoxide, barium peroxide, bromate, chlorine It may be an acid salt or the like. The strongly acidic oxidant is preferably potassium permanganate (KMnO ₄ ) or oxygen.

  The compound is selected so that a safe reaction occurs, and the heat generated by the reaction rises rapidly to a maximum temperature that is not too high, and purification of the heat during the reaction lasts for a long time.

  In a preferred embodiment of the invention, this compound is an anhydrous compound.

  The heat chamber may contain a reaction catalyst such as carbon.

  An inert filler can be added to the heat chamber along with a chemical initiator. The inert filler material may include common additives such as a binder capable of storing heat.

  The heat chamber is made of a material that maintains the temperature, typically about 220 ° C., produced by the heat chamber. Polymer-based, paper-based, natural fiber-based, ceramic-based, or glass-based and / or metal-based materials that are resistant to the temperatures and pressures generated during the reaction and the compounds formed during the reaction are used in the manufacture of the heat chamber. Can be used. The polymer base material can include polypropylene, polyethylene, other polyolefins, polyesters and / or other equivalent polymeric materials and / or mixtures thereof. Paper-based materials can include paper and / or coated paper and / or other materials based on natural fibers.

  The material of the heat chamber is oxygen impermeable when oxygen is used as the oxidant.

  The heat chamber may include a heat insulating layer and / or a heat storage layer. When the heat chamber is made of a heat conductive material such as aluminum, it is preferable to provide a heat insulating layer. This thermal insulation layer can be made of a natural or synthetic polymer material such as textiles, paperboard or polystyrene, or a ceramic, glass or metal based material. The thermal storage layer ensures optimal heat that is stable and lasts for a long time. The heat storage layer can be made of, for example, wax.

  The external excitation that activates the heat source is heat and / or oxygen. This heat is provided by, for example, a fire using a match or lighter, or an electric power using, for example, a heating wire, or an excitation that provides an ignition agent and / or other ignition heat. The applied oxygen is usually the oxygen contained in the air in contact with the heat source, for example covered with an oxygen-impermeable protective film or package by breaking the walls of an oxygen-impermeable airtight heat chamber For smoking articles, it is provided by removing the protective film or package and / or by exposing the oxygen impermeable heat chamber to air in a similar manner.

  In a preferred embodiment of the present invention, the heat source contains iron and potassium permanganate as compounds. The reaction between the initiators is initiated by heating the mixture with a match, lighter, igniter and / or heating wire. Oxygen is not required at the start of the reaction.

  The reaction rate and the heat generated during the reaction can be adjusted by the weight ratio of the compounds. This weight ratio shall be selected according to the thermal conductivity of the coating material of the heat chamber.

  In a preferred embodiment of the invention, the weight ratio of potassium permanganate to iron is between 5:95 and 95: 5, preferably between 25:75 and 50:50, more preferably between 30:70. .

In a further preferred embodiment of the invention, the heat chamber contains iron, sodium sulfide, and carbon and contacts each other in the presence of oxygen or air according to the following reaction equation:
Na ₂ S × H ₂ O + C + Fe + CaO + O ₂ →
_{Na 2 SO 4 + CaCO 3 +} Fe n O m ( iron oxide)

  Due to the catalytic effect of carbon, iron generates heat and the heat generated by this reaction further increases. Sodium sulfide may be hydrated or anhydrous. Calcium oxide reacts with the water of crystallization of sodium sulfide, and the temperature generated by the reaction rises more rapidly. The material of the heat chamber is oxygen impermeable.

  Tobacco leaves are a single type of tobacco leaf and / or a mixed tobacco leaf, which may have been processed by raw leaf processing methods known in the tobacco industry. Tobacco leaves and / or mixed tobacco leaves were subjected to the same processing used in finely chopped tobacco, twisted tobacco, flaked tobacco, powdered tobacco, processed tobacco, extruded tobacco, tobacco extract and tobacco industry Tobacco leaves treated in various ways, including shaped tobacco leaves. Tobacco extracts include, for example, tobacco essence, tobacco leaf perfume, spray-dried or freeze-dried tobacco extracts, and corresponding tobacco extracts used for the preparation of tobacco raw materials.

  In addition to flavor components such as menthol, vanilla, cocoa, licorice, cinnamic aldehyde, etc., tobacco fragrance modifiers and other modifiers, additives and fillers used in tobacco production processes, and nicotine can also be added to tobacco leaves.

  The amount of nicotine contained in the tobacco leaf of this smoking article is usually 0.1 mg to 1.0 mg.

  The suction resistance of the smoking article is resistance when the cigarette is smoked, and the smoker can thus utilize the suction rhythm for controlling his / her smoking rhythm. The suction resistance is preferably arranged at one end of the smoking article.

  In a preferred embodiment of the present invention, the suction resistance is a filter that prevents the tobacco leaf from coming into contact with the smoker, and / or a filter that filters harmful components generated when the tobacco leaf volatilizes, such as tar. is there.

  The smoking article further comprises a heat supply element coupled to the heat source that activates the heat source. This heat supply element may be an igniter, for example by folding a smoking article or by a resistance wire such as tungsten that heats strongly when current flows through the wire, fuse and / or ignition tape. Is activated.

  The smoking article further includes a cooling unit that cools the smoke generated by the evaporation of the tobacco leaves by being sucked and breathed by the user. The cooling section can also adjust the amount of smoke emitted from the finely chopped tobacco leaves. The flow path of the cooling part is equal to or substantially smaller than the flow path of the smoking article. By adjusting the cross section of the cooling portion to be smaller than the cross section of the smoking article, the amount of smoke sucked is reduced, and the use time of the smoking article is extended. The cooling unit is preferably arranged between the suction resistor and the tobacco leaf.

  The material of the cooling part is a material having some heat insulation and heat resistance, preferably a heat resistant resin.

  In an embodiment of the invention, the heat chamber is surrounded by tobacco leaves in the smoking article. The heat chamber has a structure that is folded into a rod shape or a spiral shape, an accordion shape, a corrugated shape, or some other shape. By making the structure of the heat chamber as described above, a longer heat chamber can be accommodated in the smoking article. Longer heat chambers provide more stable and longer lasting optimal heat and longer smoking use.

  In a further embodiment of the invention, the tobacco leaf is surrounded by a heat chamber in the smoking article. This heat chamber is hollow.

  Smoking articles may be covered with cigarette paper and / or other materials similar to cigarette paper.

  The surface of the cigarette paper may be treated with a colorant such as a thermochrome pigment that changes color under the influence of heat. This makes it appear as if the cigarette is burning.

  The smoking article is substantially cylindrical and / or rod-shaped with a substantially circular cross section. The cross section may be rectangular or flat. The smoking article should be in the form of a traditional cigarette.

Smoking is
Combining the compounds to form a heat chamber, enclosing the compounds in the heat chamber,
Bringing the tobacco leaf layer into contact with the heat chamber;
Place a suction resistor on one end of the smoking article,
Coating the heat chamber in contact with the tobacco leaf layer,
To manufacture.

  The heat chamber has a rod shape or a spiral shape, an accordion shape, a corrugated shape, a structure folded in some other shape, or a tubular structure.

  The tobacco leaf layer can be wrapped around a heat chamber that is substantially rod-shaped, spiral-shaped, accordion-shaped, corrugated or otherwise folded, or placed in a generally cylindrical heat chamber.

  If necessary, a heat insulating layer and / or a heat storage layer are disposed between the heat chamber and the tobacco leaf.

  If necessary, a thermal insulation layer may be placed on the tobacco leaf layer or heat chamber prior to or with the coating. Smoking is usually covered with cigarette paper.

  If desired, a cooling section is placed at one end of the smoking article. It is desirable to arrange the cooling unit between the suction resistor and the tobacco leaf.

  In the smoking article according to the present invention, the tobacco leaf is surrounded by a heat chamber, and the compound which is a reaction initiating substance is bonded or fixed to a plate-like structure rolled up into a cylindrical structure. Can also be manufactured. The protective film, the heat insulating layer and / or the heat storage layer may be disposed on the reaction starting material, for example, by laminating. The tobacco leaf is disposed inside or outside the hollow structure. The flat structure can be formed by a cigarette paper, a heat insulating layer and / or a heat storage layer.

  In the production of a heat source, when oxygen is used as a means for exciting the heat source from the outside, a substantially oxygen-free atmosphere containing, for example, nitrogen, carbon dioxide, or argon gas is required. This production is performed as a batch process. In this case, the compound is mixed, and the heat chamber is closed in an oxygen-free space that is completely closed and filled with nitrogen gas or argon gas. Airtightness must be maintained from the manufacturing stage to the user. Smoking is packaged in individual packages under hermetic conditions.

  The smoking article according to the present invention can be used immediately when a smoker activates an exothermic heat chamber by heating or by oxygen. The temperature of the heat chamber quickly rises to the volatilization temperature of the tobacco leaf, volatilizing the nicotine and aroma of the tobacco leaf and / or the flavor components added to the tobacco leaf. Smokers can feel the nicotine and aroma of the volatile tobacco leaves, and if they smoke through the filter, they can experience a smoking experience without smoke. The heat chamber generates heat sufficiently and quickly enough to volatilize the tobacco leaf components and maintain the desired volatility temperature range for several minutes. The smoking article and its heat chamber are simple to construct and operate. In producing energy in the heat chamber, for example, it is not necessary to inject water into the heat chamber to combine the compound and water, to crush the separated liquid capsule, or to use a hydrated salt. When handled, the smoking article feels the same as a real smoking article such as a cigarette or cigar, and has the same visual appearance. In addition, the smoking article is excellent in storability. The reaction products of smoking articles are not toxic and can be safely disposed of with normal household waste.

FIG. 1 is a side view of a smoking article according to the present invention. FIG. 2 is a side view of a second smoking article according to the present invention. FIG. 3 is a side view of a third smoking article according to the present invention. FIG. 4 is a cross-sectional view of a smoking article according to the present invention. FIG. 5 is a graph showing the effect of a compound in the heat chamber, its weight ratio on heating rate, maximum temperature, and time variation of temperature. FIG. 6 is a side view of the fourth smoking article according to the present invention. FIG. 7 is a side view of the fifth smoking article according to the present invention. FIG. 8 is a side view of a sixth smoking article according to the present invention.

  The smoking article (1) according to FIG. 1 is formed by smoking a cigarette. This smoking article comprises a substantially rod-like heat source (2), which is a closed heat chamber surrounded by a tobacco leaf layer (3). A suction resistance (4) is provided at one end of the smoking article, which is usually a filter. The heat source (2) contains a compound that reacts exothermically, preferably iron metal oxide and potassium permanganate, which is a strong acidic oxidant. This compound in the heat chamber is present in the inert packing. The smoking article (1) is covered with a cigarette paper (7).

  In the smoking article (1) according to FIG. 2, the tobacco leaf (3) is surrounded by a rod-shaped closed heat source (2). Other points are the same as those of the smoking article.

  In the smoking article (1) shown in FIG. 3 and FIG. 4, the heat storage layer (5) is provided between the heat source (2) and the tobacco leaf (3), so that heat can be radiated more stably and the tobacco leaf is desired. The volatile temperature range is maintained for a longer time. The heat storage layer (5) is a layer containing a metal such as aluminum. Further, the tobacco leaf (3) layer is covered with a heat insulating layer (6) having a low thermal conductivity, such as a polystyrene-based material, and the cigarette does not feel very hot even when held in the hand.

  If the material of the heat chamber is thermally conductive and / or the reaction of the heat chamber generates heat higher than the volatilization temperature of the tobacco leaf, instead of the heat storage layer (5), this heat storage layer will be Or you may arrange | position a heat insulation layer (6) with this layer.

  Alternatively, in the smoking article shown in FIGS. 3 and 4, the heat source (2) may be arranged at the position of the tobacco leaf (3) and the tobacco leaf (3) may be arranged at the position of the heat source (2). In this case, the tobacco leaf is surrounded by a heat source, and the heat storage layer (5) is disposed therebetween. Furthermore, the heat source is covered by a heat insulating layer (6).

  In the smoking article (1) shown in FIG. 6, a rod-shaped heat source (2) is bent in a spiral shape, and this heat source is surrounded by tobacco leaves (3). The longer the heat chamber, the longer the temperature in the desired volatilization region is maintained.

  In the smoking article (1) shown in FIG. 7, the rod-shaped heat source (2) is bent in an accordion shape and surrounded by tobacco leaves (3). A cooling part (8) is arranged between the suction resistance (4) at one end of the smoking article and the part forming the tobacco leaf (3) and the heat source (2). Is smaller than a smoking article and cools the smoke passing through it while volatilizing from the tobacco leaf, reducing the amount of smoke sucked in, thereby extending the use time of the smoking article. The cooling part (8) is usually made of a heat resistant resin. The section (9) surrounding the cooling part (8) usually contains air.

  The cross section of the cooling part (8) may be the same as the cross section of the smoking article, in which case the cooling part simply cools the smoke evaporating from the tobacco leaves to suit the user.

  In the smoking article (1) according to FIG. 8, the heat chamber (3) is formed by combining three rod-shaped heat chambers. The longer the heat chamber, the longer the usage time.

  The effect of the initiator, a heat chamber compound, in the exothermic reaction was tested experimentally. Various weight ratios of reaction initiators were used in the test to verify the effects of heating rate, maximum temperature, and temperature change over time. The heating test was performed using potassium permanganate and iron in weight ratios of 30:70 and 70:30. A mixture of 1.0 g of initiator was used for the test. In this reaction, a reaction starting material was put in an aluminum or glass tube and reacted by an electric ignition device. The temperature was tracked by a thermal element attached to the tube.

  A tube was loaded into a chopped leaf of a standard size cigarette so that a space for the chopped leaf remained. The inner diameter, the outer diameter, and the wall thickness of the aluminum or glass tube are 4.75 mm, 4.05 mm, and 0.35 mm in the case of aluminum, and 5.06 mm and 3.5 mm in the case of glass, respectively. They were 06 mm and 1 mm. The tube length is 55 mm, which is compatible with a hoist for filter cigarettes.

  The results of the heating test performed are shown in FIG.

  The test results showed that in all tests the temperature rose to the optimal volatilization area of the tobacco leaf in less than 20 seconds.

  A weight ratio of 70:30 potassium permanganate / iron produces too high a temperature, especially when paper is used as a wrapper. At this weight ratio, it is necessary to use a heat insulating layer.

  A 30:70 weight ratio of potassium permanganate / iron was compared using glass tubes, aluminum tubes, and insulated glass tubes. According to this result, the glass tube kept heat longer than the aluminum tube, and the maximum temperature rose to about 50 ° C. or more.

  The glass tube was insulated with an aluminum foil covered with a thin cloth to delay the time to reach maximum temperature by tens of seconds. Reaching the volatilization zone was delayed by about 10 seconds, but the temperature lasted 2.5 times on this zone compared to a non-insulated tube, about 2 minutes.

  The functionality of this smokeless smoking article was tested by experiment. An insulated glass tube was used as the heat chamber structure. This structure is the same as that of the first embodiment. The thickness of the heat insulation layer formed of aluminum foil and cloth was 0.56 mm.

  1.0 g of a mixture of potassium permanganate and iron (30:70) was introduced into the heat chamber.

  A heat chamber was placed on a hoisting machine on which a paper roll and a filter and fine leaves were set, and the smoking article was wound up to make a smoking article.

  Heat was introduced into the smoking article to initiate the reaction by a resistance wire that was heated by passing an electric current through the wire.

  After the test, the smoked product was visually inspected, and it was observed that tar separated from the tobacco leaf onto the surface of the paper wrapper. It was seen from the filter that the reaction of the heat chamber separated the tobacco component from the chopped leaves. When the test was opened after the test, no burning marks or darkening of the finely chopped leaves were observed in the cigarette.

  This test proved that the aroma and nicotine of cigarettes can be volatilized from tobacco leaves in smoking articles by devising the components and structure of the heat chamber.

  In this test, smokeless smoking articles according to the present invention, ordinary cigarettes, and commercially available smokeless cigarettes were compared for the luminescent components nicotine, carbon monoxide, and tar. The smoking article of Example 2 was used as an unlicensed smoking article, and Marlboro's “Gold” from Philip Morris was used as a normal cigarette. Woodleaf Corporation brand “Aeros” smoking material was used as smokeless tobacco. It is based on a plastic tube closed at both ends and includes a base material impregnated with nicotine and tobacco aroma. When the smoker cuts off both ends of the plastic tube and draws air from the tube, the scent of nicotine and tobacco enters the smoker's mouth and organs.

Nicotine and tar components were measured using a GC-MS apparatus, and carbon dioxide was measured using a GC-TDC apparatus. Two analyzes of cigarettes were performed in parallel. The results for the smoking article (SAI) of the present invention were converted to the amount of fine cigarette chopped leaves. The results are shown in Table 1.

The present invention is not limited to the exemplary embodiments described above, and many variations are possible within the scope of the inventive idea defined by the claims.

Claims (20)

Tobacco leaves and
With suction resistance,
In a smoking article comprising a chemical heat source connected to the tobacco leaf,
The heat source comprises a heat chamber formed by a continuous space and having an exothermic compound, the heat source being activated by external heat and / or oxygen excitation;
The compound in the heat chamber contains iron and potassium permanganate, and the reaction is excited by heat. The smoking article according to claim 1,
A smoking article wherein the weight ratio of potassium permanganate to iron is in the range of 5:95 to 95: 5, preferably in the range of 25:75 to 50:50, more preferably 30:70. Tobacco leaves and
With suction resistance,
In a smoking article comprising a chemical heat source connected to the tobacco leaf,
The heat source comprises a heat chamber formed by a continuous space and having an exothermic compound, the heat source being activated by external heat and / or oxygen excitation;
A smoking article, wherein the compound in the heat chamber contains iron, sodium sulfide, carbon, calcium oxide, and these reactions are excited by oxygen. In the smoking article according to any one of claims 1 to 3,
A smoking article, wherein the heat chamber is a sealed type. In the smoking article according to any one of claims 1 to 4,
A smoking article, wherein the heat chamber material is a polymer-based, paper-based, natural fiber-based, ceramic-based, glass-based, and / or metal-based material. In the smoking article according to any one of claims 1 to 5,
A smoking article, wherein the heat chamber includes a heat insulating layer and / or a heat storage layer. In the smoking article according to any one of claims 1 to 6,
A smoking article, wherein the suction resistance is a filter. In the smoking article according to any one of claims 1 to 7,
The smoking article further comprises a heat supply element for initiating the reaction. The smoking article according to claim 8,
A smoking article, wherein the heat supply element for initiating the reaction is an ignition agent, a heating wire, a heating wire, and / or an ignition tape. In the smoking article according to any one of claims 1 to 9,
The smoking article further comprises a cooling part. In the smoking article according to any one of claims 1 to 10,
A smoking tool, wherein the heat chamber is surrounded by tobacco leaves. In the smoking article according to any one of claims 1 to 11,
A smoking tool, wherein the tobacco leaf is surrounded by the heat chamber. In the manufacturing method of the smoking article of Claim 1 or 3,
Combining the compounds and placing the compounds in a heat chamber to form a heat chamber;
Contacting a tobacco leaf layer with the heat chamber;
Placing a suction resistance at one end of the smoking article;
Covering a heat chamber in contact with the tobacco leaf layer;
A method characterized by comprising. The method of claim 13, wherein
A method comprising providing a heat insulating layer and / or a heat storage layer between the heat chamber and a tobacco leaf. 15. A method according to claim 13 or 14,
A method of providing the heat insulating layer on the tobacco leaf or on the heat chamber before or when covering the heat chamber. The method according to any one of claims 13 to 15, wherein
A method of disposing a cooling part at one end of the smoking article before or when covering the heat chamber. The method of claim 16, wherein
A method of disposing a cooling part between a suction resistance and a tobacco leaf. In the manufacturing method of the smoking article of Claim 1 or 3,
Fixing the compound on the plate structure;
Winding the structure to form a hollow structure;
Placing tobacco leaves inside or outside the hollow structure;
A method characterized by comprising. The method of claim 18, wherein
The method according to claim 1, wherein the flat structure comprises a cigarette paper, a heat insulating layer and / or a heat storage layer. The method according to claim 18 or 19, wherein
A method characterized in that a protective film, a heat insulating layer and / or a heat storage layer are preferably laminated and placed on the compound.

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