PL181960B1 - Igniting elements suitable for precise adjustment of cap composition - Google Patents

Abstract

The ignition element, consisting of a combination of 2 detonators, comprises a first detonator (hot wire detonator) contg. initiator(s), heat dissipating additive(s), oxidant(s) and a binder, and a second detonator (output detonator) contg. constituent(s) producing hot reaction particles, an oxidant and a binder. Also claimed are a 2-component ignition element in which the first detonator contains a heat-dissipating initiator and opt. a heat dissipating additive; and the first and second detonator per se.

Description

The subject of the invention is an igniter which is a combination of two ignition masses.

The operation of igniters and igniters is essentially determined by two factors. Firstly, the reaction products should contain as many particles as possible and the particles should be as hot as possible, and secondly, a transport gas must be available for these particles so that the particles can penetrate the propellant as much as possible. Also, the transport gas should be hot enough to maintain the temperature of the molecules. In general, these requirements are met by igniters and igniters that contain a pyrotechnic fuel based on B / KNO ₃ or Ti / Ba (NO ₃ ) ₂ or TiHx / Ba (NO ₃ ) ₂ , where x <1 or also Zr / Ba ( NO ₃ ) ₂ or nitrocellulose, or also flammers and flammers which contain zirconium and potassium perchlorate.

In addition to the essential usability requirements, other properties relating to the sensitivity and safety of such igniters and incendiary elements are also decisive for the quality and applicability of such igniters. These so-called electrical parameters are the igniting sensitivity (Aze), the igniting insensitivity (Azu) and the ignition delay (Azvz) of the individual masses. At the same time, the ignition insensitivity indicates safety, and the ignition sensitivity or ignition delay - the ignition sensitivity of the ignition masses.

So far, ignition masses with sufficiently high ignition sensitivity, but with too high values for the ignition sensitivity or ignition delay, i.e. with too low ignition sensitivity, or ignition masses with sufficiently low ignition sensitivity and ignition delay, but with insufficient insensitivity, are known. incendiary.

The object of the invention is to provide igniters which, in addition to having sufficient power, depending on the purpose of their application, exhibit precisely adjustable values for the igniting sensitivity and the igniting insensitivity without significantly adversely affecting the ignition retardation.

This object is solved according to the invention by providing an igniter consisting of a combination of ignition masses, characterized in that the first ignition mass, constituting the mass of the filament filament, comprises at least one initiating explosive, at least one heat removing additive, at least one oxidizing agent, and one binder and the other energy mass ignition mass comprises at least one hot reaction molecule generating component, an oxidizing agent and a binder.

Preferably, in the igniter according to the invention, the initiating explosive of the filament mass is lead azide, diazodinitrophenol, silver azide, picrate or tricinate, especially lead picrate.

The heat dissipation additives are inorganic or organic heat sinks, preferably metals, metal compounds or organometallic compounds, and particularly preferably the heat dissipation additive is zirconium, aluminum, titanium, ferrotitate, compounds

181,960 metals, in particular zirconium boride or zirconium hydride, or a mixture of these heat dissipation additives.

In the igniter according to the invention, the component that produces hot reactive particles in the energetic mass is zirconium in various crystal modifications, titanium or mixtures thereof.

The oxidizing agent is KC1O ₃ and / or KC1O ₄ .

The binder in the bulk of the igniter is polyvinyl acetate, polysulfone or polyethersulfone, preferably polyvinyl acetate.

The filament mass of the igniter according to the invention consists of 20 to 80 parts of picrate, 80 to 20 parts of a mixture consisting of a heat-removing additive in the form of inorganic or organic heat absorbing substances, preferably metals, metal compounds or organometallic compounds, and an oxidizing agent in the form of KC1O ₃ and / or KClO ₄ and 1 to 6 parts of a binder, preferably 4 parts of a polyvinyl acetate, polysulfone or polyethersulfone binder.

The mixture, consisting of heat sink additive and oxidizing agent, contains 60 to 90 parts heat removal additive and 10 to 40 parts KC1O ₄ .

A variant of the igniter, consisting of a combination of two ignition masses, according to the invention is characterized in that the first ignition mass, constituting the mass of the filament filament, comprises a heat-dissipating explosive or heat-dissipating initiating explosive with a heat-removing additive and a binder, and the second mass, The energy mass ignition element includes at least one component that generates hot reactive molecules, an oxidizing agent, and a binder.

In a variant of the incendiary element according to the invention, the heat removing initiating explosive is silver azide.

The heat dissipation additives are inorganic or organic heat sinks, preferably metals, metal compounds or organometallic compounds, and particularly preferably the heat sink additive is zirconium, aluminum, titanium, ferrotitane, metal compounds, preferably zirconium boride or zirconium hydride or a mixture of these heat dissipation additives .

The component generating hot reaction molecules in the energetic mass is zirconium in various crystal modifications, titanium or mixtures thereof.

The oxidizing agent is KC1O ₃ and / or KC1O ₄ .

The binder is polyvinyl acetate, polysulfone or polyethersulfone, preferably polyvinyl acetate.

The mass of the filament in a variant according to the invention consists of 100 parts of a heat sinking initiating explosive, preferably silver azide, and 1 to 6 parts, preferably 4 parts, of a binder.

The first ignition mass, the so-called filament mass, is responsible for the electrical parameters, while the second ignition mass, the so-called energy mass, is responsible for the power. It has surprisingly been found that, in order to increase the insensitivity of the igniting mass of the filament filament without adversely affecting the ignition retardation, it is of particular importance to provide a large heat dissipation in the filament mass. This is achieved according to the invention thanks to an additive that is able to dissipate heat. This heat-dissipating additive was chosen from substances which are capable of absorbing heat in a known manner and therefore of extracting it from the environment. Examples of such substances are substances of inorganic or organic origin, such as metals, metal compounds or organometallic compounds.

In a first embodiment, the filament masses are metals or metal compounds according to the invention as heat dissipation components. The metals used are, in particular, zirconium, aluminum, titanium and / or ferrotitane. Zirconium is especially preferred. As relationships

181,960 metals, for example, borides and hydrides of the metals mentioned can be used. Zirconium boride and zirconium hydride are particularly preferred. In addition to these heat-dissipating metal additives, the filament masses of the incendiary elements according to the invention contain at least one initiating explosive, for example lead azide, diazodinitrophenol, silver azide, tricinate or picrate, for example lead picrate, as well as one oxidizing agent, for example nitrates. , chlorates, perchlorates of alkali metals or alkaline earth metals, for example KC1O ₃ and / or ₄ KC1O, particularly preferably KC1O ₄ and a binder. The binder is responsible not only for the combination of the individual agents, but also for the thermal resistance of the igniters; they should have a temperature resistance> 85 ° C. Therefore, suitable binders according to the invention are polyvinyl acetate, polysulfone or polyethersulfone. Preferably polyvinyl acetate is used. The heat dissipation additive should increase the incendiary insensitivity, while the primary explosive used is responsible for providing the necessary incendiary sensitivity.

In a second embodiment, the heat dissipation component according to the invention is provided as heat dissipation component as a heat dissipating initiator explosive, preferably silver azide, optionally in combination with further heat dissipation components such as metals, metal compounds or organometallic compounds. As metals, in this embodiment, zirconium, aluminum, titanium and / or ferrotitanium can also be used, as metal compounds, borides and hydrides, preferably zirconium boride and zirconium hydride. A particular advantage of using silver azide is that it simultaneously functions as a heat-removing additive and by its properties as an initiating explosive, it improves the ignition sensitivity. If, according to the invention, only silver azide is used, the weight of the filamentous filament consists of 100 parts silver azide and 1 to 6, preferably 4 parts, a binder. Polyvinyl acetate is preferably used as the binder with the same functions as in the first embodiment.

The energy mass of the igniter according to the invention consists of the component which produces the hot reactive particles and the above-mentioned; an oxidizing agent and a binder. Zirconium in its various crystal modifications, titanium or mixtures thereof are used as the component which produces the hot reaction molecules. As oxidizing agent, for example, KC1O ₃ and / or KC1O ₄ , preferably KC1O ₄ , can be used. The binders used are preferably the same substances as in the filament mass. According to the invention, suitable energy masses of the igniter consist of 30 to 80 parts of zircon, titanium or mixtures thereof, 20 to 70 parts of oxidizing agent, preferably KClO ₄ , and 1 to 6 parts of a binder. Preferably, a mixture of 60 parts zirconium, 40 parts KClO ₄ and 4 parts polyvinyl acetate is used.

The ignition masses can be used in various ways, alone or in combinations. If the filament mass of the ignition element according to the invention is combined with the energy mass of the ignition element according to the invention, ignition elements which can be finely adjusted are produced.

The igniters according to the invention are manufactured as set out above.

The filament mass and energy mass components are screened and suspended in a binder dissolved in a suitable solvent. If polyvinyl acetate is used as the binder, butyl acetate is a suitable solvent. This suspension is made submersible, i.e. the viscosity is adjusted accordingly. It is of particular importance here that the ingredients do not deposit during dipping. To ensure this, for example, the slurry of the ignition mass is homogenized by careful stirring, in compliance with safety regulations. The incendiary elements are generally manufactured in the form of ignition charges. An ignition charge normally used consists, for example, of two electrically conductive, longitudinal polarity carriers (plates) which are connected

181 960 by means of an insulating rib and a filament bridge polarity connecting the carriers. This primary ignition charge body is immersed in the ignition mass sludge many times in such a way that the first ignition mass surrounds the glow bridge. The dipping process is repeated until a sufficient amount of the filament mass mixture is applied for the respective application purpose. For the first ignition mass, amounts of 6 to 10 mg have proven successful. There is a risk of solvent volatilization between the individual dipping processes. After the mass of the filament, the energetic mass is applied in the same manner as a sheath around the filament. With this mass, too, the dipping process is repeated until a sufficient amount of the energy-mass mixture is applied for each application purpose. Values of 50 to 100, preferably 65 to 85 mg, have proven to be the weight of the ignition mass for the entire ignition charge. After the ignition charge has been dried for 24 hours, it is coated with 20% more varnish from the binder in question and then dried for 48 hours.

The ignition masses of the element according to the invention, depending on the binder used, can be used in ignition elements resistant to high temperatures. If, for example, polysulfone or polyethersulfone is used as binder, ignition compounds of the element according to the invention can be used at temperatures of up to 250 ° C. The incendiary elements according to the invention are particularly suitable for the ignition of rocket charges, which require long exposure times to the hot flame, and also for insensitive propellants in which hot metallic particles are required.

The ignition mass mixtures given in Table 1 illustrate the invention in greater detail without restricting it.

The following are used as incandescent fibers:

incandescent I: Cr / Ni 2938 Ohm / m bl. 0.5 mm incl. II: Cr / Ni 2823 Ohm / m bl. 0.5 mm incl. III: Cr / Ni 2827 Ohm / m bl. 0.5 mm on heat IV: Cr / Ni 2631 Ohm / m bl. 0.7 mm incandescent V: Cr / Ni 2649 Ohm / m bl. 0.7 mm incandescent VI: Cr / Ni 2649 Ohm / m bl. 0.5 mm.

Table 1

Example 1 2 3 4 5 6 Picrate (parts) 50 50 40 40 40 - Mixture (parts) 50 50 60 60 60 100 (consisting of: drain off, additive heat 60 60 60 60 60 100 (parts) and KCIO4 (parts) and KCIO4 (parts) 40 40 40 40 40 - Mowilith (parts) 4 4 4 4 4 4 Incandescent fiber AND IV AND II IV IV Azu (mA) 233 245 263 272 280 308 Aze (mA) 546 640 550 587 678 605 Azvz (ms) 1.04 1.27 1.10 1.09 1.27 0.69

181 960

Table 1 - continued

Example 7 8 9 10 11 12 Picrate (parts) 50 50 50 40 40 thirty Mixture (parts) 50 50 50 60 60 70 (consisting of: drain off, additive heat 80 80 80 80 80 80 (parts) and KCIO4 (parts) twenty twenty twenty twenty twenty twenty Mowilith (parts) 4 4 4 4 4 4 Incandescent fiber II IV III III V VI Azu (mA) 234 236 238 260 256 304 Aze (mA) 513 550 499 513 538 579 Azvz (ms) 0.80 0.84 0.73 0.76 0.77 1.02

181 960

Publishing Department of the Polish Patent Office. Circulation of 60 copies

Price PLN 2.00.

Claims (17)

Patent claims 1. Ignition element consisting of a combination of two ignition masses, characterized in that the first ignition mass, constituting the mass of the filament filament, comprises at least one initiating explosive, at least one heat removing additive, at least one oxidizing agent and one binder, and the second ignition mass, the energy mass, comprises at least one component that generates hot reaction molecules, an oxidizing agent, and a binder. 2. The lighting element according to claim 1 The method of claim 1, wherein the initial explosive of the filament mass is lead azide, diazodinitrophenol, silver azide, picrate or tricinate, preferably lead picrate. 3. The igniting element according to claim 1. A process as claimed in claim 1, characterized in that the heat dissipation additives are inorganic or organic heat sinks, preferably metals, metal compounds or organometallic compounds. 4. The lighting element according to claim 1 The process of claim 1 or 3, characterized in that the heat dissipation additive is zirconium, aluminum, titanium, ferrotitane, metal compounds, preferably zirconium boride or zirconium hydride, or a mixture of these heat dissipation additives. 5. The igniting element according to claim 1. The process of claim 1, wherein the component that produces hot reactive particles in the energetic mass is zirconium in various crystal modifications, titanium or mixtures thereof. 6. The igniting element according to claim 1 The process of claim 1, wherein the oxidizing agent is KC1O ₃ and / or KC1O ₄ . 7. The igniting element according to claim 1 The process of claim 1, wherein the binder is polyvinyl acetate, polysulfone or polyethersulfone, preferably polyvinyl acetate. 8. The lighting element according to claim 1, The method of claim 1, characterized in that the mass of the filament fiber consists of 20 to 80 parts of picrate, 80 to 20 parts of a mixture consisting of a heat removing additive in the form of inorganic or organic heat absorbing substances, preferably metals, metal compounds or organometallic compounds, and an oxidizing agent in the form of KC1O form ₃ and / or ₄ KC1O Ido and 6 parts of binding agent is preferably 4 parts of binding agent in the form of polyvinyl acetate, polysulfone or polyethersulfone. 9. The igniting element according to claim 1 The process of claim 8, characterized in that the mixture consisting of the heat sink additive and the oxidizing agent comprises 60 to 90 parts heat removal additive and 10 to 40 parts KClO ₄ . 10. Ignition element consisting of a combination of two ignition masses, characterized in that the first ignition mass, constituting the mass of the filament filament, comprises an initiating explosive heat dissipating or heat dissipating explosive initiating material with a heat-removing additive and a binder, and the second ignition mass, the energy mass includes at least one component that produces hot reactive molecules, an oxidizing agent, and a binder. 11. The lighting element according to claim 1. The explosive of claim 10, wherein the initiating explosive to remove heat is silver azide. 12. The ignition element according to claim 1, The process of claim 10, characterized in that the heat dissipation additives are inorganic or organic heat absorbers, preferably metals, metal compounds or organometallic compounds. 13. The lighting element according to claim 1, A process as claimed in claim 10 or 12, characterized in that the heat dissipation additive is zirconium, aluminum, titanium, ferrotitane, metal compounds, preferably zirconium boride or zirconium hydride, or a mixture of these heat dissipation additives. 181 960 14. The lighting element according to claim 1. The method of claim 10, characterized in that the component generating hot reaction molecules in the energetic mass is zirconium in various crystal modifications, titanium or mixtures thereof. 15. The igniting element according to claim 1, The process of claim 10, characterized in that the oxidizing agent is KC1O ₃ and / or KC1O ₄ . 16. The lighting element according to claim 1, The process of claim 10, characterized in that the binder is polyvinyl acetate, polysulfone or polyethersulfone, preferably polyvinyl acetate. 17. The igniter according to claim 1, The method of claim 10, characterized in that the mass of the filament consists of 100 parts of a heat sinking initiating explosive, preferably silver azide, and 1 to 6 parts, preferably 4 parts, of a binder. ♦ * *