EP0847972A1 - Pyrotechnic delay element, method of manufacture and its use - Google Patents

Abstract

A pyrotechnic retarding device (1) consists of aggregates (3,4,5) pressed one on top of the other and arranged in a metal casing (2). The transition zones between each two adjacent aggregates are formed by solid phases (34,45) containing components of both aggregates compressed and interleaved with one another. Also claimed are (i) a method of manufacturing such a delay device by first packing the triggering aggregate into the case, secondly packing a divided portion of the delay aggregate and thirdly pressing both layers together with a pressure ram. In a fourth step further divided portions are packed into the case each divided portion being pressed with the pressure ram before the next. In a fifth step the last divided portion of the delay aggregate is pressed with the following propagation aggregate and (ii) the use of such elements in ignition devices with predetermined time delays in a Nebel rocket launcher.

Description

The invention relates to a pyrotechnic delay element, consisting of pressed sentences, which in a metallic sleeve are arranged, and a method for its manufacture and its use.

From EP-A1-0 304 973 one is particularly suitable for ignition suitable pyrotechnic delay element by means of a firing pin known. This contains in the cheering and delay set toxic heavy metal compounds, which today in manufacturing and in their use because of their emissions and residues are undesirable.

This delay element also has the disadvantage that it requires a relatively high ignition energy.

It is therefore an object of the invention to be a low-emission pyrotechnic Creating a delay element which is environmentally friendly is, only a low ignition energy is required, both is ignitable both electrically and pyrotechnically. The delay times should be predeterminable and reproducible in the range of seconds be. The delay element should in particular also suitable for firing smoke ammunition and only have small dimensions.

The above task is solved in that the transitions one between each other between two adjacent sentences toothed and compressed solid phase from parts of the two Build sentences.

Black powder is predominantly used in the individual sets, too Flour powder called, used as fuel.

The manufacturing process is that in one first step of the firing set in the sleeve is filled in that in a second step a portion of the delay rate is filled in that in a third step the two layers with a press stamp are pressed, that in a fourth step further Portions of the delay set filled into the sleeve be, each portion before filling the next portion is pressed with the ram, and that in a fifth step the last portion of the delay rate with the one filled in below Transfer set is pressed.

In dependent claims, preferred developments of the Claimed subject of the invention.

The predetermination of the burning time of the delay element after Claim 2 is easily realized between 1 to 13 seconds.

The burn time is primarily a function of the length of the delay set and thus predeterminable in a simple manner. Thereby the reproducibility is high, which makes the Security of the pyrotechnic element is guaranteed.

A lighting set according to claim has proven particularly useful 3 a composition of 99% black powder and 1% binder having.

The burning time of the delay set can additionally according to claim 4 can be varied by in a very wide range usable proportion of the fuel black powder, as well of silicon or ferric oxide, the two the latter components act as slag formers.

A delay set without black powder according to claim 5, has manganese dioxide-zirconium as fuel; it has Also proven in the delay element according to the invention.

The transfer rate is expediently energetically adjusted the delay rate.

Therefore, a delay rate with the composition according to claim 4 with a transfer sentence according to claim 6, added.

According to claim 6, the energy required to form a Flame beam in the transfer set, by adding Zirconium - as a reducing agent for black powder.

The transmission rate according to claim 7 has proven itself as a supplement to the delay rate according to claim 5. Here the increased burning energy is achieved by adding magnesium.

The composition of the black powder according to claim 8 proved to be beneficial.

By eating two sentence types together according to the process claim 9, will have excellent interlocking between two adjacent sentences ensures what a special reliable ignition chain results.

The pressing method according to claim 10 is preferably carried out with a pressure of approximately 31 kN / cm ² .

Based on practically implemented exemplary embodiments, the Subject of the invention explained in more detail.

Fig. 1

einen Längsschnitt durch ein vereinfacht dargestelltes Verzögerungselement mit seinen verzahnten Sätzen

Fig. 2

die Brennzeit in Abhängigkeit der Säulenlänge für ein bestimmtes Verzögerungselement

Show it:

Fig. 1

a longitudinal section through a delay element shown in simplified form with its toothed sets

Fig. 2

the burning time depending on the column length for a specific delay element

The entire delay element is denoted by 1 in FIG. 1. It consists of an elongated, cylindrical sleeve 2 which is filled at one end with the firing kit 3, at the other end with the transfer rate 5. The delay rate 4, fills the average volume of the sleeve 2. Next is the toothed transition 34 of the firing set 3 to the delay set 4 and the transition 45 from the delay set 4 to Transfer rate 5 can be seen.

A front thread 6 is used for the releasable coupling a fog sentence 7; in a back thread become notorious known detonators (electric or with detonators) coupled.

The production of a delay element 1, for example with an inner diameter of 3.5 mm takes place directly in it Sleeve 2. In a first step, 50 mg of the lighting set 3 dosed into the sleeve. Then a small subset of the delay rate 4. This can be between 20 and 50 mg vary. Both sets are pressed, which is a typical Teeth 34 caused at the interface of the two sets. in the next step is another serving of 50 to 100 mg the delay set 4 filled in the sleeve 2 and pressed. This step is made according to the total amount to be dosed Delay set 4 repeated several times until the predetermined amount, or the desired length of the Delay rate 4 is reached. Before the last serving delay set 4 is pressed, 30 to 100 mg of the transmission set 5 dosed into the sleeve and then pressed. This in turn creates a toothed transition 45 between the delay and transmission rate 4 or 5.

Brass sleeves with an inner diameter of 3.5 mm have proven particularly useful. The length of the sleeves varies from 15 to 30 mm depending on the desired delay time or the number of sets to be pressed. Planned stamps as well as stamps with a corrugated pattern are used as press stamps. The pressing is preferably carried out at a pressure of 31 kN / cm ² ; the holding time of each press stage is 4 to 6 s.

It has been shown that the dosage in portions towards the inside diameter of the sleeve 1. Here the set column generated by this is to be used for each pressing process do not exceed the dimension of the inner diameter of the sleeve.

A column height which is in each case 70 to 80% of the Inner diameter is.

1. Anfeuerungssatz: 99% Mehlpulver der Zusammensetzung 77,5% KNO₃, 13,5% C und 9% S und 1,0% Binder14. Binder14 ist eine handelsübliche Polymer Verbindung aus Styrol-Copolymer und modifiziertem Kolophonium in Toluol/Xylol (Hersteller PROGA, CH-2540 Grenchen, Schweiz).

2. Der Verzögerungssatz auf Basis Mehlpulver weist folgende mögliche Zusammensetzungen, Mengen und entsprechende Längen auf, welche seine Brennzeit ändern und bestimmen:

2.1 Mehlpulver 49%, Si 0%, Fe₂O₃ 50%, Binder14 1%, in Mengen vom 620 mg, ergibt in einer Hülsenlänge von 30 mm, eine Verzögerungssatz-Säule von 29,3 mm, welche eine mittlere Brennzeit von 12,6 s aufweist.

2.2 Mehlpulver 39%, Si 60%, Fe₂O₃ 0%, Binder14 1%, in Mengen vom 275 mg, ergibt in einer Hülsenlänge von 19 mm, eine Verzögerungssatz-Säule von 17,8 mm, welche eine mittlere Brennzeit von 2,22 s aufweist.

2.3 Mehlpulver 43%, Si 45%, Fe₂O₃ 11%, Binder14 1%, in Mengen vom 247 mg, ergibt in einer Hülsenlänge von 15,9 mm, eine Verzögerungssatz-Säule von 15,8 mm, welche eine mittlere Brennzeit von 2,87 s aufweist.

2.4 Mehlpulver 69%, Si 0%, Fe₂O₃ 30%, Binder14 1%, in Mengen vom 295 mg, ergibt in einer Hülsenlänge von 19 mm, eine Verzögerungssatz-Säule von 17,4 mm, welche eine mittlere Brennzeit von 3,63 s aufweist.

3. Der Verzögerungssatz auf Basis Zirconium und Mangandioxid weist folgende mögliche Zusammensetzungen, Mengen und entsprechende Längen auf, welche seine Brennzeit ändern und bestimmen:

3.1 Zr 20%, MnO₂ 79%, Si 0%, Fe₂O₃ 0%, Binder14 1%, in Mengen vom 475 mg, ergibt in einer Hülsenlänge von 19 mm, eine Verzögerungssatz-Säule von 17,1 mm, welche eine mittlere Brennzeit von 2,53 s aufweist.

3.2 Zr 30%, MnO₂ 30%, Si 39%, Fe₂O₃ 0%, Binder14 1%, in Mengen vom 365 mg, ergibt in einer Hülsenlänge von 19 mm, eine Verzögerungssatz-Säule von 17,9 mm, welche eine mittlere Brennzeit von 1,34 s aufweist.

3.3 Zr 30%, MnO₂ 30%, Si 0%, Fe₂O₃ 39%, Binder14 1%, in Mengen vom 470 mg, ergibt in einer Hülsenlänge von 19 mm, eine Verzögerungssatz-Säule von 17,8 mm, welche eine mittlere Brennzeit von 1,52 s aufweist.

3.4 Zr 20%, MnO₂ 5%, Si 25%, Fe₂O₃ 49%, Binder14 1%, in Mengen vom 410 mg, ergibt in einer Hülsenlänge von 19 mm, eine Verzögerungssatz-Säule von 17,4 mm, welche eine mittlere Brennzeit von 2,94 s aufweist.

4. Die Zusammensetzung des Übertragungssatzes wurde gemäss den folgenden Beispielen variiert und entsprechend den Charakteristiken der verwendeten Verzögerungssätzen eingesetzt, in Mengen von 30 bis 50 mg:

4.1 Mehlpulver 79%, Zr 20%, Binder14 1%.

4.2 Mehlpulver 94,5%, Zr 5%, Binder14 1%.

4.3 Mehlpulver 59%, Zr 40%, Binder14 1%.

4.4 Zr 60%, MnO₂ 39%, Si 0%, Mg 0%, Binder14 1%.

4.5 Zr 20%, MnO₂ 59%, Si 0%, Mg 20%, Binder14 1%.

4.6 Zr 50%, MnO₂ 34%, Si 15%, Mg 0%, Binder14 1%.

The following describes the compositions of some tried and tested sentences:

1st firing set: 99% flour powder with the composition 77.5% KNO ₃ , 13.5% C and 9% S and 1.0% binder14. Binder14 is a commercially available polymer compound made of styrene copolymer and modified rosin in toluene / xylene (manufacturer PROGA, CH-2540 Grenchen, Switzerland).

2. The time delay set based on flour powder has the following possible compositions, amounts and corresponding lengths, which change and determine its firing time:

2.1 Flour powder 49%, Si 0%, Fe ₂ O ₃ 50%, Binder14 1%, in amounts of 620 mg, results in a tube length of 30 mm, a delay kit column of 29.3 mm, which has an average firing time of 12 , 6 s.

2.2 Flour powder 39%, Si 60%, Fe ₂ O ₃ 0%, Binder14 1%, in amounts of 275 mg, results in a sleeve length of 19 mm, a delay kit column of 17.8 mm, which has an average firing time of 2 , 22 s.

2.3 Flour powder 43%, Si 45%, Fe ₂ O ₃ 11%, Binder14 1%, in quantities of 247 mg, results in a sleeve length of 15.9 mm, a delay kit column of 15.8 mm, which has an average firing time of 2.87 s.

2.4 Flour powder 69%, Si 0%, Fe ₂ O ₃ 30%, Binder14 1%, in amounts of 295 mg, results in a sleeve length of 19 mm, a delay kit column of 17.4 mm, which has an average firing time of 3 , 63 s.

3. The delay rate based on zirconium and manganese dioxide has the following possible compositions, amounts and corresponding lengths, which change and determine its burning time:

3.1 Zr 20%, MnO ₂ 79%, Si 0%, Fe ₂ O ₃ 0%, Binder14 1%, in quantities of 475 mg, gives in a sleeve length of 19 mm, a delay kit column of 17.1 mm, which has an average burning time of 2.53 s.

3.2 Zr 30%, MnO ₂ 30%, Si 39%, Fe ₂ O ₃ 0%, Binder14 1%, in amounts of 365 mg, gives in a sleeve length of 19 mm, a delay kit column of 17.9 mm, which has an average burning time of 1.34 s.

3.3 Zr 30%, MnO ₂ 30%, Si 0%, Fe ₂ O ₃ 39%, Binder14 1%, in quantities of 470 mg, gives in a sleeve length of 19 mm, a delay kit column of 17.8 mm, which has an average burning time of 1.52 s.

3.4 Zr 20%, MnO ₂ 5%, Si 25%, Fe ₂ O ₃ 49%, Binder14 1%, in amounts of 410 mg, results in a sleeve length of 19 mm, a delay kit column of 17.4 mm, which has an average burning time of 2.94 s.

4. The composition of the transfer set was varied according to the following examples and used in accordance with the characteristics of the delay sets used, in amounts of 30 to 50 mg:

4.1 Flour powder 79%, Zr 20%, Binder14 1%.

4.2 Flour powder 94.5%, Zr 5%, Binder14 1%.

4.3 Flour powder 59%, Zr 40%, Binder14 1%.

4.4 Zr 60%, MnO ₂ 39%, Si 0%, Mg 0%, Binder14 1%.

4.5 Zr 20%, MnO ₂ 59%, Si 0%, Mg 20%, Binder14 1%.

4.6 Zr 50%, MnO ₂ 34%, Si 15%, Mg 0%, Binder14 1%.

Of course, other binders can also be used, not exclusively Binder14. Cellulose derivatives and polymers such as polyvinyl pyrrolidone (PVP) were also used and tested. However, it is evident that different binders, different firing times of the retardation set. For a composition of the retardation rate of 43% black powder, 46% Si and 11% Fe ₂ O ₃ , a burning time of 3.1 s was achieved with 0.5% binder14; with 6% binder14 a burn time of 4.1 s; with 1% PVP 3.0 s and with 1% collodion E21 a time of 2.4 s.

The zirconium used was of commercial quality FA Powder, from DEGUSSA AG; also the iron dioxide and silicon were in commercial grit. Magnesium of quality "Standard" from Mimeta SA, CH-1000 Lausanne; Manganese dioxide "Practical" quality from FLUKA; PVP - polyvinyl pyrrolidone K-30 from the company GAF AG CH-6300 Zug; Collodion wool E21 was from Plüss-Staufer delivered in CH-Oftringen.

In Fig. 2, with a sleeve 2, with a bore of 3.5 mm in diameter, the burn time t in seconds as a function of length l is graphically represented in mm. This series of experiments relates to a constant deceleration rate of the composition flour powder 43%, Fe ₂ O ₃ 11%, Si 45% and binder Binder14 1%. The quantities and compositions of the firing set and the transmission set were also kept constant and the measured delay elements were produced under the same pressing pressure. The measured burning times have a linear dependency on the length of the column of the delay set, as the regression line shows; the extrapolated areas of the straight line are drawn.

The linear relationship enables particularly simple predetermination the burning time of the subject of the invention; she can be extrapolated in the dash-dotted area.

The subject of the invention is excellently suitable for lighting of smoke projectors of the type according to EP -B1- 0 322 951 and EP -B1- 0 362 523 and others in particular on battle tanks installed fog-throwing systems.

The low environmental impact of the delay element is particularly favorable, so that it also lends itself to practice ammunition.

Claims (11)

Pyrotechnic delay element (1) consisting of sentences pressed together (3, 4, 5), which in one metallic sleeve (2) are arranged, characterized in that that the transitions between two neighboring ones Sets an interlocking and compacted solid Form phase (34, 45) from parts of the two sentences. Pyrotechnic delay element (1) according to claim 1, characterized in that a lighting set (3), a deceleration rate determining the burn time (4) and a Transfer set (5) are provided, the burning time of the element (1) by choosing the length of the pressed Delay rate (4) is predetermined. Delay element (1) according to claim 2, characterized in that the firing rate (3) from 97 to 99.5% Black powder and 3 to 0.5% binder. Delay element (1) according to claim 2, characterized in that the delay rate (4) from 30-70% Black powder, 0-60% silicon, 0-50% ferric oxide and 0.5-6% binder exists. Delay element (1) according to claim 2, characterized in that the delay set (4) made of 18-30% zirconium, 5-80% manganese dioxide, 0-40% silicon, 0-50% ferric oxide and 0.5-6% binder. Delay element (1) according to claim 2, characterized in that the transfer rate (5) from 57-94% Black powder, 5-40% zirconium and 1-3% binder. Delay element (1) according to claim 2, characterized in that the transfer set (5) made of 20-60% zirconium, 40-60% manganese dioxide, 0-15% silicon, 0-20% magnesium and 1-3% binder. Delay element (1) according to one of Claims 3, 4 or 6 characterized in that the black powder a mixture of 77.5% potassium nitrate, 13.5% coal and 9% Is sulfur and has a grain size smaller than 250 µm. Method of making a delay element according to one of claims 2 to 8, characterized in that that in the first procedural step the firing rate is filled into the sleeve that in one second step a portion of the delay block is filled in that in a third step the two Layers are pressed with a press stamp, that in a fourth step further partial portions of the delay set filled into the sleeve be, each portion before filling the next portion is pressed with the press stamp, and that in a fifth step the last Partial portion of the delay block with the following filled transfer set is pressed. A method for producing a delay element according to claim 8, characterized in that the pressing of the sets in the sleeve with a pressure of at least 25 kN / cm ² takes place for 4 to 6 s and that the press stamp is a flat stamp or a stamp with a corrugated pattern. Use of a delay element (1) according to one of the previous claims to initiate an ignition process with a predetermined delay time in a smoke missile.

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