NL8100092A - THERMOGENIC COMPOSITION. - Google Patents

Description

ί ^ * * VO 1363

Subject: Thermogenic composition.

The invention relates to a thermogenic composition which will generate a large amount of heat only through contact with air or oxygen.

To date, thermogenic compositions "are known which are capable of generating heat chemically," e.g. / (X) a composition containing as main component an inorganic oxide, such as calcium oxide, which will generate heat by reaction with or dissolution in water supplied from outside; (2) a composition containing metal powder, such as iron powder or aluminum powder, as well as an inorganic metal salt, such as iron sulfate, copper sulfate, iron chloride or sodium chloride, which will generate heat through contact with externally supplied water and air (or oxygen); and (3) a composition containing at least one member selected from the group 15 of alkali metal sulfides, polysulfides and hydrates thereof, and carbonaceous material * which will generate heat through contact with air or oxygen.

The known thermogenic compositions (1) and (2) have the drawback that they can produce an insufficient amount of heat, when using externally supplied water for their generation of heat, they must comprise thermogenic material and water separated therefrom, as well as an organ to mix the two during use, and that they are very limited in terms of packaging, method of use, application and the like.

The known thermogenic composition (3) has the advantage that it will only generate heat by introducing air or oxygen therein. In addition, it is excellent in packaging, method of use, application and the like in comparison to the known compositions (1) and (2). However, when the known composition (3) contains the hydrate of alkali metal sulfides, it has more "satisfactory thermogenic properties than the known compositions (1) and (2), but insufficient thermogenic properties for applications requiring high temperatures, at which will give a lower temperature than required when the known composition 35 (3) contains the anhydride of alkali metal sulfides, it will use 8100092 - ► -a * '«* __ ^ _,., .....

4 4. -2- generate a greater amount of heat, so that a higher temperature will be obtained; however, processes for the technical preparation of such anhydrides are complicated and such anhydrides are generally not prepared at the use of technical applications, raising problems with the technical preparation of such anhydrides-containing thermogenic compositions.

The thermogenic compositions according to the invention do not have the disadvantages of the known thermogenic compositions and have the following properties: 10 (1) They do not require externally supplied water for the generation of heat, but only contact with air or oxygen for the generation of heat at a high temperature. They can be controlled to achieve any desired temperature by adjusting the degree of contact with air or oxygen, and the like. Furthermore, they can provide greater amounts of heat and higher temperatures than the known thermogenic compositions.

(2) They will not emit noxious gases and will not give dangerous reaction products during their reaction when used, therefore, after being used up, they can be disposed of very safely.

(3) They do not require water supplied from the outside and do not generate steam (which would likely cause burns) due to their heat generation.

(U) They can be compact in size because they are capable of generating a large amount of heat even when used in a small amount, making it possible to use them on a larger scale.

The thermogenic composition according to the invention comprises as main constituents (A) at least one member from the group of alkali metal sulfide® polysulfides and hydrates thereof (B) at least one from the group of carbonaceous materials, and (c) at least one member from the group of metal nitrates, and may further comprise as optional components (D) calcium oxide and (E) at least one member from the group of powdered iron, aluminum, magnesium, and alloys containing at least one of these metals as the major constituent.

8100092 <133> 13th Alkali metal sulfides and polysulfides and their hydrates, which are used as component A in the thermogenic compositions of the invention, include sulfides and polysulfides in powder form of alkali metals such as lithium, sodium, potassium, rubi 5 dium and cesium and erarats also the powdered hydrates of the sulfides and polysulfides. These alkali metal compounds can be used as component (A) alone or in combination. Of the alkaline languages present in these alkali metal compounds, sodium and potassium are preferred. Components (A) and (B) are each in the form of 10 particles, preferably a particle size of k mm or less.

Typical examples of the sodium compounds as component (A) are Ife2S, Ha2S. 1/2 ^ 0, Ha2S.3H20, IfegS ^ HgO, HagS. ^ O, ISa ^ S ^ E ^,

BagSg.e ^ O, JTa ^ .eHgO, HagS ^ .HgO, NagS ^ -9 ^ 0, Ha ^ S ^ .llHgO and ffegSg.éHgO. Many mixtures of various such hydrates are available. The sodium compounds consisting essentially of the commercially readily available Ka2S.3H2 O are preferred. These sodium hydrogen bonds will not generate heat in the air, but will generate heat in the air when mixed with the carbonaceous material as component (B) which exerts a hatalytic effect on component (A). The catalytically active carbonaceous material (B) includes activated carbon, charcoal, carbon black or carbon black, of which carbon black is preferred for generating heat at a high temperature.

The metal nitrates (C) which can be used in the thermogenic composition according to the invention include HaiO2, LiO2O, EbHO2, LiHO3, 3,20, and BaClO2, with KHO2 being preferred. They are powdered with a particle size of preferably no more than 0.8k mm and may have been surface treated as required.

The mechanism of heat generation of the thermogenic composition of the invention is believed to be that component (A) reacts with oxygen using the catalytic influence of component (B) to produce heat, component (C) generated by it heat develops oxygen and the thermogenic effect between the components (A) and (B) is thereby promoted to obtain 8100092

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of a rapid temperature rise. In addition to the metal nitrates, peroxides such as Na 2 O 2 and BaOg are contemplated gene scans as oxygen generating components; however, thermogenic compositions containing these oxygen-generating components can only generate a relatively small amount of heat and are unstable in storage, making it impossible to use them in practice.

As mentioned, the thermogenic composition according to the invention comprises the components (A),) and (C) as essential components and the composition can further comprise (D) calcium oxide and / or (E) powdered iron, aluminum, magnesium and / or contain one or more of these metals as the main constituent alloy, if desired.

The component (E) is in the form of. particles with a size of 0.8U mm or smaller.

Component (D) is particularly useful in a case where component (A) is used in the hydrate form. In this case, the water released from component (A) in hydrate form will react with component (D), taking part in the generation of heat and thus preventing any unnecessary loss of energy caused by evaporation of the water. . Component (D) may be commercially available lime and preferably has a particle size of 0.8mm or less.

Component (E) is particularly useful in the case where a high temperature is desired. It includes reduced iron powder, nitrated iron powder, iron (XI) oxide powder, aluminum powder, magnesium-2? powder or alloy powder containing iron, aluminum or magnesium as the main constituent. These metal powders may also have been surface treated with organic matter or the like to stabilize the surface. These metallic compound and metal powders, which can be used as component (E), are believed to be reactive to oxygen by being activated in some way with heat generated by the combined use of the components ( A), (B), (c) and in some cases (D).

The thermogenic compositions according to the invention can be used with inorganic fillers, such as silicon oxide and aluminum oxide, with 8100092 * 1.

-5- satisfactory heat resistance are combined. It is of course possible to add organic fillers to the compositions.

The thermogenic compositions combined with such fillers are generally used to generate heat at lower temperatures.

Thermogenic compositions of the invention, capable of generating heat at any desired temperature, can also be obtained by varying the constitution of the composition. The component (A) 10 present in the thermogenic compositions is present in an amount of preferably 5-50% by weight of the composition. A content of more than 50% by weight will lead to a delay in the generation of heat, ie a longer time is required to obtain a desired temperature, which can be a great disadvantage from the point of view of practical application of the composition, While a content of less than 5% by weight will lead to heat generation in insufficient quantities, thereby reducing the value of the composition for its practical use.

Component (B) is preferably used in the thermogenic composition in an amount of 5-50 g & r%. The use of component (B) 20 in an amount of more than 50 parts will lead to the formation of a thermogenic composition which gives a lower maximum temperature in use, while the use of component (B) in an amount of less than 5% by weight will lead to the formation of a composition with slow heat generation, which is disadvantageous.

Component (C) is preferably used in the composition in an amount of 1-50% by weight. The use of component (C) in an amount of less than 1 gsw.% Is not very effective, and unsuitable for practical application.

Component (D) is mainly used when the hydrate of an alkali metal sulfide or the hydrate of a polysulfide is used as component (A) and in this case its use is advantageous in that it accelerates the initial rise in temperature. It is not always necessary to use component (D) in a case where such an accelerated rise in temperature is not required.

Component (D) may preferably be present in the thermogenic composition in an amount of 5-70 wt.%. The use of component (D) in an amount of more than 70% has the drawback that it reduces the thermogenic efficiency of the composition, while the use of in an amount of less than 5% by weight is not very effective in view of an acceleration of the initial temperature rise.

Component (E) may preferably be in an amount up to 70% by weight. The use thereof in an amount of more than 70% by weight has the drawback that it makes the thermogenic composition difficult to react with oxygen.

The thermogenic composition according to the invention can generate heat in such a way that a temperature of 1000 ° C or even higher is reached.

The thermogenic composition according to the invention can be prepared by the components (A), (B) and (C) and, if desired, at least one of them.

mixing the components (D) and (E) in the atmosphere of an inert gas, such as nitrogen or argon. The thermogenic composition thus prepared is enclosed in a container which is permeable to oxygen, but does not allow the thermogenic composition to leak out, after which the thus enclosed composition is further enclosed in a bag-type container 20 or a molded container, which is impermeable to oxygen. The thermogenic composition can also be prepared by mixing component (A) with a pre-prepared mixture of components (B) and (C) as well as in certain cases components (D) and (E) (it is not always necessary to components (B), (C), (D) and. (E) to be mixed together in the atmosphere of an inert gas) in the atmosphere of an inert gas the thermogenic composition thus prepared is enclosed in an oxygen-permeable container and the thus-enclosed composition is further enclosed in an oxygen impermeable bag-type container or molded container. The components (A) - (E), whether essential. 2q or optional, can be in any. be mixed in sequence.

When the thermogenic composition is first enclosed in a container that is partially oxygen-permeable while the remainder is oxygen-impermeable, the thus-enclosed composition can be prevented from contacting air by sealing or covering the oxygen-permeable portion with an oxygen-permeable portion. impermeable lid.

8100092 -7- m

The thermogenic composition thus double-sealed can be contacted with air (oxygen) to generate heat by removing the bag-type, impermeable bag-type container, molded container or lid. The oxygen permeable container can be a bag or a molded container made of paper, organic fibers, woven or non-woven cloth, formed from inorganic fibers such as glass or mineral fibers, or perforated plastic films. These materials can be used alone or in combination (as composite products). The bag-type, impermeable bag-type container, molded container or lid may be made of a plastic film, metal sheet or foil, or other inorganic material. The thermogenic composition according to the invention can produce heat such that a high temperature is obtained; preferably, a heat-resistant container, such as a metal container, is used as a container for a thermogenic composition capable of producing such a high temperature. The metal container can be made of an aluminum plate, steel plate and the like, preferably with a thickness of about 0.1-0.5 mm.

The use of metal plates of too small thickness is dangerous because the plates can cause breakage, perforation or other problems.

On the other hand, using plates of too great a thickness will cause an increase in weight and cost. The temperature obtained by the heat generation of the theimogenic composition and the duration of the heat generation can be adjusted or controlled depending on the manner in which the composition is packaged, in particular by controlling the contact surface with air (oxygen) etc. The shape of the container and the size and shape of the surface for contact with air (oxygen) may be selected depending on the purpose for which the thermogenic composition is used, if desired.

In addition, heat generation will be caused only by contact with oxygen, usually air, as noted above.

Various methods can be used for this purpose, e.g. a method of lifting the oxygen impermeable container with something such as a needle, a method of subtracting a cover film covering one or more pre-applied perforations of the oxygen impermeable container, and a method of securing the container foreseeable 8100092 * w. o -8- of a so-called "easy-to-open" member, such as a pull-on tab or a screw-type perforating tool.

The thermogenic compositions of the invention are suitable for applications that are high. require temperatures, e.g. thermal diffusion (smoking, smoking, etc.) of insecticides, fungicides, anti-fungal agents, rodent control agents, worm agents, perfumes, etc., heating of foodstuffs such as canned food, and thawing of frozen food. In addition, they can also be used as a replacement for portable fuel and as. heat source for welding plastic materials and metals.

The invention is further illustrated by the examples. These should not be construed as limiting. When talking about parts, we mean parts by weight, unless stated otherwise.

15 Example I:

It was thoroughly mixed together in a nitrogen atmosphere to obtain a thermogenic composition: U parts of crystalline sodium sulfide hydrate containing about b% by weight of water of crystallization, which hydrate passed through a sieve with meshes of 0 »8U mm, k parts of carbon black, 20 available from Mitsubishi Kasei Co., Ltd. under the designation "Carbon Black Ho. 2300", and 2 parts of powdered saltpetre passed through a sieve of 0 8k mm mesh. 40 of the thermogenic composition thus obtained was enclosed in a jug with a diameter of 10 cm, a height of 3 cm and a thickness of 0.2 mm, after which the thermogenic composition thus generated for generating heat with air comes into contact was brought. The temperatures obtained in the center on the outside of the bottom of the jug by heat generation were measured. As a result, the maximum temperature was found to be 500 ° C. In addition, the amount of heat developed by the composition was 3.53 KJ / g.

Example II;

It was mixed thoroughly in a nitrogen atmosphere to obtain a theimogenic composition: 2 parts of the same sodium sulfide hydrate as used in Example I, 2 parts of carbon-35 black (Carbon Black Ho. 900 from Mitsubishi Kasei Co., Ltd.), 1 part «8100092 * -9- η _» saltpetre passing through a 0.25 mm mesh sieve, 2 parts calcium oxide passing through a 0.8 ^ mm mesh sieve and 3 parts reduced iron powder (supplied by Hippon Teppun Co., Ltd. under the designation OC-6). h5 g of the thermogenic composition thus obtained was placed in a steel container with a diameter of 10 cm, a height of 2 cm and a thickness of 0.2 mm. A glass fiber fabricated filter with good air permeability was placed on the thus applied composition to prevent it from leaking out, after which the composition was contacted with air and measured in the same manner as in Example 1 to determine the composition 10 to determine the maximum temperature and amount of heat obtained. The results were that the maximum temperature was 350 ° C, the duration of temperatures was 300 ° C for 15 minutes, and the amount of heat generated was h} 22 KJ / g.

EXAMPLES III-VI: 15 · Thermogenic compositions with the compositions shown in Table A yield heat in the same manner as in Example I. The maximum temperature and amount of heat generated were measured. The results are also shown in Table A.

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Comparative ideas 1-3:

For comparison, the thermogenic compositions with the compositions shown in Table B (without component (C)) were allowed to generate heat and the maximum temperatures and the amount of heat obtained were measured. Heat generation and measurements were performed in the same manner as in Example I.

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Retaliate Examples k-6: elkα each of these comparative examples, a thermogenic composition was prepared for comparison, comprising 8 parts of the component (A), 8 parts of the component (B), 1¾ parts of the component (D), 35 parts 5 of the component (E) and the peroxide shown in Table C.

The thermogenic compositions thus prepared for comparison were measured in the same manner as in Example 1 to determine their maximum temperature and the amount of heat obtained. The results are also shown in Table C.

Table C

comparative peroxide max. temp. amount (° C) of heat generated (KJ / g) hïfe202 225 1.5 5 EaB03 200 1.3 6 BaOg 23k 1.6 8100092

Claims (1)

A thermogenic composition comprising (A) at least one member from the group of alkali metal sulfides, poly sulfides and hydrates thereof, (B) at least one member from the group of carbonaceous materials, and (C) at least one member. the group of metal nitrates. 5 2. ' Thermogenic composition according to claim 1, characterized in that it further comprises (D) calcium aaxyde. Thermogenic composition according to claim 1 or 2, characterized in that it further comprises (E) at least one member from the group of powdered iron, aluminum, magnesium, and alloys containing at least one of these metals as the main component. b. Thermogenic composition according to one or more of claims 1 to 3, characterized in that the metal nitrate is an alkali metal nitrate. 8100092 e