SE525519C2 - Process for producing heat-generating countermeasures, as well as packaging with heat-generating countermeasures - Google Patents

Abstract

The invention relates to a process for producing heat-generating counter-measures which are intended to be dispensed from sea-based, land-based or air based systems, with heat being generated when an iron compound reacts with oxygen thereby forming iron oxide. The invention also relates to a pack (1) containing heat-generating counter-measures (8) which pack comprises a container (2) and a lid (3), accommodates heat-generating counter-measures and is intended to be dispensed from sea-based, land-based or air-based systems, with heat being generated when the pack (1) is opened, during the dispensing, such that the content of the pack in the form of an iron compound makes contact, and is allowed to react, with oxygen thereby forming iron oxide and heat. According to the invention, the iron compound which is to react with oxygen consists of iron sulphide. The invention provides a less complicated process for producing heat-generating counter-measures, which process does not require the use of vacuum chambers or special spaces containing a protective atmosphere and which, at the same time, makes it possible to produce reliable packs which have an effective action.

Description

0000 O I I 0000 000 O O I IIOI CCI 'ÜÜÜ II IIIÛ II I! .CIO OI IC I O I I O O I I C I U O O O O O I I O O I I I O I O I -OI II OO II OI l0 15 20 25 30 525 519 2 and arm potential leakage from the cartridge. Many of the pyrophoric liquids are compounds based on methyl, propyl, hexyl, ethyl or butyl which are all associated with 11105 major safety hazards.

The group of pyrophoric solids includes the families of materials that spontaneously ignite in contact with O 2, and pyrophoric solids which oxidize rapidly and then emit heat. For pre-emptive purposes, solids that oxidize rapidly have proven to be particularly interesting.

The solids oxidize and emit heat of a suitable temperature so that a target seeker locks on the platform we are trying to protect and thus prevents a missile from being fired.

Examples of known technologies for the manufacture of pyrophoric antidotes are described, inter alia, in U.S. Patent 5,501,751.

However, known technologies for the production of pyrophoric antidotes are generally relatively complicated and may require, among other things, vacuum sensors and / or spaces with a protective gas atmosphere. Furthermore, heating is required during carefully controlled temperature and time courses. The object of the present invention is to provide a less complicated process for producing heat-generating countermeasures which do not require the use of vacuum chambers or special spaces with shielding gas atmospheres and which at the same time allow reliable and protective-efficient packages with heat-generating counterpart to be produced.

The object of the invention is achieved by a process characterized in that the comparison which is to react with oxygen consists of iron fi d, and a package characterized in that the contents of the package reacting with oxygen mainly consist of iron fi d. The ferrous sulphide can be built up inside the package and reacts after the opening of the package in an attractive manner with the oxygen in the air, forming heat with a suitable IR signature. ii According to an advantageous further development of the process according to the invention, the reaction between the iron solution and the oxygen is controlled to at least partially follow any of 0000 III OIOI III O III IC OIOI IC II 20 25k 30 525 519 I 0 I 0 0 00 00 0 0 I 000 U 0 0 I 0 000000 n 0000 0 0000 000000 0 I n 000000 the reactions below or a combination of these: 4FeS + 302 -> 2Fe2O; + 4S + heat 4FeS + 702 -è 2Fe2O3 + 4802 + heat.

According to another advantageous further development of the process j- iron sol fi is prepared from some form of iron oxide of the form FexOy or FexOy (O, H ,.). Advantageously, the iron sulphide can then be formed according to the formula: Fe 2 O 3 + 3H 2 S -> 2 FeS + 3H; O + S.

Alternatively, the ferrous sulfide can be formed according to the formula: FeO (OH) + 3H 2 S -> 2FeS + 4H 2 O + S.

According to another advantageous further development of the process according to the invention, iron oxide is enclosed in a package with container and lid, hydrogen salt is added to an inlet on the package whereby iron salt is formed in the container, residual products are removed via an outlet and the inlets and outlets are closed. The process is relatively easy to apply and a finished package with heat-generating moiiiiedei »is obtained in principle directly.

In order to remove residual products, an inert gas can be supplied to the inlet and which is allowed to pass inside the package and then, together with residual products, leave the package via its outlet. Another way to remove residual products is to boil them off.

According to a further advantageous further development of the method according to the invention, the surface layer of sulfur is added to the surface of the iron as a mask in order to limit the oxygen of the air to come into contact with the entire surface of the iron sulphide at once. In this way, the oxidation process and thus the heat development can be controlled in a more controlled manner.

Suitably, the preparation of the heat generating antidotes is carried out under room atmospheric pressure.

According to an advantageous embodiment of the package according to the invention with heat-generating countermeasures, the package comprises at least one closable inlet and at least one closable outlet. Advantageously, a first outlet can then be arranged II diametrically opposite a first inlet. The arrangement of inlets and outlets creates conditions for the construction of iron ore.

The package, which consists of a container and a lid, can be hermetically sealed in any known flexible manner, for example by welding the container and lid together.

The invention will be described in more detail below with reference to the accompanying drawings, in which: Figure 1 in top view and Figure 2 in sectional side view according to A-A in Figure 1 show an exemplary embodiment of a package according to the invention with heat-generating countermeasures. The package 1 consists of a container 2 and a lid 3. The end of the container towards the lid is formed with a circumferential ns end 4. When closing, the container fl 4 of the container is joined to the peripheral parts of the lid by a suitable sealing method, such as welding. The welding is indicated in Figure 1 with dashed lines 5a-5d. Adjacent to two of the corners of the lid 3 is a gas inlet 6 and a gas outlet 7 marked with dashed lines. The gas inlet and the gas outlet are arranged to be easily dryable. The container contains a heat-generating counterpart 8. In preparing a package of the type described in the preceding paragraph with heat-generating countermeasures, iron oxide is first placed on the substrate or in loose powder form in the container 2 under a tube atmosphere. Then the lid 3 and the container 2 are closed herentically as if on a small opening 6 for gas inlet and a small opening 7 for gas outlet. In this case, hydrogen sulphide is supplied to the gas inlet 6 of the package.

The following two formulas illustrate examples of transformations that can occur: FC2Û3 + 3H2S -) 2 FGS + 3H2O + S F6Û (ÛH) + 3H2S _) ZFCS + 4H2Û + S OOIO IOOOI IOOO CIO OOO Û IIOIOII .I OI I. OI II II After the formation of an iron sulphide and the elimination of any residual products, for example using an inert gas and / or by charring, the inlet and outlet are closed.

Package 1 is thus ready for use.

The degree of pyrophoric activity, ie total energy and rise time to maximum temperature, can be controlled by controlling the supply / flow of hydrogen sulphide, temperature and exposure time at which the conversion from iron oxide to iron sulphide takes place. Further control can take place by storing the finished product as the remaining sulfur to some extent subsequently reacts and further increases the degree of pyrophoric action of the material.

Packages as above constitute ammunition for trapping systems. These felling sisters can be fl ygbuma, fixed or movably placed on land or fixed or movably placed at sea. When the folding system folds a package, the package is opened and the lu's oxygen has access to the inside of the package. Thereby a reaction takes place between the solids and the oxygen in the air during the formation of heat. The following two formulas show examples of reactions that can occur: 4FeS + 302 _) 2FC2Û3 + 4S + Väfmß 4FeS + 702 -> 2Fe2O3 + 4802 + heat.

The heat generated by the packaging provides such an IR signature that threats in the form of target-seeking missiles or the like are prevented from locking on to the target to be protected. In this case, the countermeasure acts as a pre-emptive counterpart that is folded in preventive sewing to prevent a target seeker from locking on the target we are trying to protect and thus preventing missile firing.

To control the oxidation process and limit the heat generation initially, sulfur can be used as a mask. This prevents the lu fi oxygen from coming into contact with the entire iron sole surface at once. The sulfur is then added to the package 1 before the final closing of the inlet and outlet of the package.

The invention is not limited to the embodiments shown above as examples, but may be subject to modifications within the scope of the appended claims.

Claims (1)

1. 00 OO OI OIOI IQ O! A process for the preparation of heat-generating antidotes intended to be precipitated from sea-, ground- or fl-based systems, heat being generated when a comparison reacts with oxygen to form iron oxide, characterized by that the comparison which is to react with oxygen consists of iron salt fi d. Process according to Claim 1, characterized in that the reaction between the solids and the oxygen is controlled to at least partially follow any of the reactions below or a combination of these: 4FeS + 302 -> 2FezO 3 + 4S + heat 4FeS + 702 -> 2Fe 2 O 3 + 4802 + heat. Process according to one of the preceding claims, characterized in that iron sulphide is produced from any form of iron oxide of the form FexOy or alternatively FexOy (OzH2). Process according to Claim 3, characterized in that iron sol fi it is formed according to the following formula: F62Û3 + 3H2S _) 2 FCS + 3H2Û + S. Process according to Claim 3, characterized in that iron sol fi it is formed according to the following formula: in FeO (OH) + 3H2S -> 2FeS + 4H 2 O + S. Process according to any one of the preceding claims, characterized in that iron oxide is enclosed in a package with container and lid, that hydrogen sulphide is supplied to an inlet on the package whereby iron salt is formed in the container, that residual products are removed via an outlet and outlet the outlets are closed. Method according to claim 6, characterized in that residual products are removed by feeding the inlet an inert gas which is allowed to pass the interior of the package and then, together with residual products, leaving the package via its outlet. IIOI I 0000 000 c IOI O 0 ICO I 0 0 0 C 0000 0 co 0900 on oo 0000 oo 00 0 I o 0 0 0 n 0 1 ua 0 0 0 0 II o 0 U c 0 0 Oo oc cc nu 0 10 Process according to Claim 6 or 7, characterized in that residual products are boiled off. Process according to one of the preceding claims, characterized in that sulfur is added to the surface layer of the iron sulphide as a mask in order to limit the oxygen in the lumen to come into contact with the entire surface of the iron sulphide at once. Method according to one of the preceding claims, characterized in that the adjustment of the heat-generating countermeasures is carried out under room atmosphere pressure. Packaging with heat-generating antidote comprising a container with a lid containing heat-generating antidote and intended to be precipitated from sea-, ground- or g-based systems, heat being generated when the packaging is opened during precipitation so that the contents of the packaging in the form of an iron compound are contacted and allowed to react with oxygen during the formation of iron oxide and heat, characterized in that the oxygen - reactive contents of the package consist mainly of iron salt fi d. Packaging according to claim 11, characterized in that the packaging comprises at least one closable inlet and at least one closable outlet. Packaging according to claim 12, characterized in that a first outlet is arranged diametrically opposite a first inlet. Packaging according to one of the preceding claims 11-13, characterized in that the lid is welded together with the container for hermetic sealing.