CH685699A5 - Pyrochemical priming in a gas generator. - Google Patents

Description

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CH 685 699 A5

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description

The present invention relates to a pyrochemical ignition chain in a gas generator with an organometallic initial explosive and an encapsulated detonator containing an electrical ignition means, which is at least partially embedded in a transfer charge of the gas generator.

Gas generators for impact protection systems (air bags) according to the generic term are known (including DE-C1 4 102 275). It is also known from US Pat. No. 5,109,772 that boron potassium nitrate = (BKNO3) is a rapid igniter for pyrotechnic fuel and is used as such for the spread of the ignition of gas-generating material, for the inflation of airbags. In order to achieve the desired effect, BKNO3 is applied over a large area along the entire gas generator; In addition, disks that form similarly coated chambers are provided. This is achieved by immersing the corresponding mechanical parts in an aqueous BKN03 solution followed by a drying process. This type of gas generator is ignited by a conventional thermo-electric igniter. This construction is relatively complex and voluminous and only brings about an improved flame distribution of an already ignited gas generator.

In the course of the technical development of airbags and pyrotechnic belt tensioners, it has been shown that the known systems cause pressure impulses during ignition, which have a negative effect on the spread of gas and interfere with a desired gentle inflation of the airbag or cause mechanical overloading. The same happens with pyrotechnic belt tensioners, where the pressure piston is applied too quickly.

It is accordingly an object of the invention to provide a device which, based on arrangements known per se, causes a gentle pressure increase in the gas generator and also ensures absolutely reliable ignition.

This object is achieved in that at least two initial explosives are provided in the primer, the second having a lower explosiveness than the first initial explosive, that the first initial explosive surrounds the primer and is an organometallic explosive, that the second initial explosive is an inorganic mixture and that both initial explosives are pressed in layer form and encapsulated in a pressure-tight manner.

The inventive solution is based on an adaptation of the ignition chain to the detonation speed which is favorable in terms of system technology in the area of the initial ignition; As a second and possibly further initial explosive layers, explosives are therefore also suitable which are not per se considered to be initial explosives.

In practice, the use of two initial explosives in the detonator primarily results in reliable ignition of the first initial explosive layer and then spreading of the ignition, with reduced ignition speed in the second, less explosive layer.

Compressing the two layers of explosives together surprisingly results in the desired initial ignition effect even with less explosive explosives.

The installation of the transfer charge or at least components of the transfer charge, as provided in the gas generator, has proven effective, according to claim 2.

BKNO3, as a second initial explosive, according to claim 3, has proven particularly useful in compressed form.

Lead ricinate, according to claim 4, gives the 15 necessary ignition security, also in combination with less explosive other explosives.

It makes sense to choose the ratios of the two layers of explosives according to the information in claim 5, since on the one hand the necessary pressure build-up is guaranteed and on the other hand pressure surges are avoided.

In addition, the mixing ratio of BKNO3 can be adapted and optimized to the desired pressure profile according to the information in claim 6.

Preferred grain sizes of the lead ricinate according to claim 7 result in improved functional reliability.

The targeted selection of the grain sizes or crystals of the BKN03 mixture also serves to increase the quality of the ignition process.

The explosive layers are preferably pressed in a plastic cap, and encapsulated, which makes sense for chemical-chemical and corrosion-related reasons.

The use of a glow wire, according to claim 10, has proven itself very well in connection with the use of two initial explosive layers; it can also be produced very economically. Exemplary embodiments of the subject matter of the invention are described in more detail below with reference to drawings.

Show it:

45 Fig. 1 A gas generator with an ignition chain according to the invention,

Fig. 2 is an enlarged sectional view of the gas generator Fig. 1, with details of the structure of the igniter and 50 Fig. 3 shows the characteristic pressure curve resulting from an inventive igniter at different temperatures.

In Fig. 1, a pot-shaped gas generator is designated 55 100. It essentially consists of a combustion chamber housing 101, with chambers, baffles and filter elements (not shown here in more detail) and has a cylindrical central tube 102 in the center, in which a transmission charge 103 made of BKNO3 is located. Passages 104, in the form of bores, ensure gas passage after ignition into the combustion chamber 106, which is filled with known pyrotechnic sentences 107, so-called pellets. 65 The ignition signal is transmitted via an electrical

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CH 685 699 A5

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ker 108 and a 2-pin ignition cable 109 connected via sensors and generated in a known manner supplied to the arrangement.

The igniter 1 is centered axially symmetrically by a carrier flange 105 and by means of a clamp flange 105b. A locking collar 105a prevents axial displacement, a locking bush 110 also serves for locking. 2 shows details of the structure of the igniter 1 in the transfer charge 103; in addition, the plug fuse 9 is designated here.

The housing 2, a metal capsule produced by flanging, contains notches 3 on the end face, which represent predetermined breaking points and ensure targeted gas transfer into the transfer charge 103. In the capsule 2 formed in this way there is a charge cap 4 made of plastic, in which a first initial explosive 5 and a second initial explosive 6 are pressed under pressure. In the first explosive 5 there is a filament 7, which forms a resistance bridge between the two contact pins 8 and acts as an electrical ignition means.

The contact pins 8 are cast into an insulator 10 made of glass which is flat on its end faces.

2, the transfer charge 103 and the second initial explosive are made of the same material, i.e. from a mixture of boron-potassium nitrate = BKNO3. The first initial explosive layer 5 is composed of lead trinitroresorcinate, also called tricinate.

As can be seen from FIG. 3, in a test capsule (test bomb) with a volume of 3 cm 3, a pressure of approximately 90 bar is established within approximately 1 ms, which pressure decreases only very slowly over a further interval of 10 ms. At an ambient temperature of 85 ° C, a maximum pressure of 97 bar is built up within 1 ms to 2 ms, which drops to 80 bar after 0.5 ms and is still 60 bar after approx. 10 ms. At 20 ° C the maximum pressure will drop to 90 bar, after a further 0.5 ms approx. 80 bar and after 7 ms to approx. 70 bar.

The pressure ranges which are not permissible for technical reasons in the system are shown hatched in the diagram according to FIG. 3.

The subject of the invention fulfills the requirements even at very low temperatures. At -35 ° C, a pressure of about 70 bar is built up within less than 2.0 ms, which is maintained for more than 10 ms.

This pressure curve in the gas generator with the igniter according to the invention is essential for the reliable functioning of the impact protection system.

Explosive layers have proven to be optimal with a mass of pressed 1st initial explosive of 30 mg tricinate and also pressed 75 mg boron potassium nitrate as 2nd initial explosive. The ratio of boron to potassium nitrate is 40% by weight B and 60% by weight KNO3.

Grain sizes of boron in the range of 50 (in.

By varying the amounts in the

Claims (10)

The limits mentioned in the claims, the initial gas development in the ignition chain can be controlled in such a way that it can largely be adapted to the physical properties of an airbag or its mechanical strength. The pressure curve for belt tensioners can also be adapted to the kinetic conditions of the pressure piston and the winding mechanism together with the other system parameters of the gas generator. In order to achieve an initial ignition effect of the two explosive layers, it is necessary to compress them in the capsule 2; Press pressures of up to 10,000 N / cm2 have proven to be useful. Surprisingly, no events occurred even at considerably higher pressures. Of course, there may also be more than two layers of explosives in the primer if the primer chain is to be adapted to a system-related, gentle build-up of pressure. Likewise, conventional initial explosives can also be used to adapt to the desired pressure profile, the ignition chain generally starting with the more explosive explosive and being transferred to the less explosive explosives. List of names 1 igniter (glow wire) 2 housing (capsule) 3 notches (predetermined breaking point) 4 charge cap (plastic) 5 1. Initial explosives 6 2. Initial explosives 7 glow wire 8 contact pins 9 plug fuse 10 insulator (glass) G gas (filtered) 100 gas generator (pot-shaped) 101 combustion chamber housing 102 central tube 103 transfer charge 104 passages (bores) 105 support flange 105a safety collar 105b clamp flange 106 combustion chamber 107 Pyrotechnic phrases (pellets) 108 Electrical plug 109 ignition cable (2-pin) 110 fuse socket Claims 1. Pyrochemical ignition chain in a gas generator with an organometallic initial explosive and an encapsulated detonator containing an electrical ignition means, which is at least partially embedded in a transfer charge of the gas generator, characterized in that in the ignition capsule at least two initial explosives 5 10. Pyrochemical ignition chain according to claim 1, characterized in that the ignition means (7) is a filament. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 4th 10th 15 20th 25th 30th 35 40 45 50 55 60 65 3rd 5 CH 685 699 A5 fe (5, 6) are provided, the second (6) being less explosive than the first initial explosive (5), the first initial explosive (5) surrounding the ignition means (7) and an organometallic explosive being the second initial explosive (6) is an inorganic mixture and that both initial explosives (5, 6) are pressed in layer form and encapsulated in a pressure-tight manner. 2. Pyrochemical ignition chain according to claim 1, characterized in that the second initial explosive (6) consists of at least two reactive components and that the same components are provided in the transfer charge (103) of the gas generator (100). 3. Pyrochemical ignition chain according to claim 2, characterized in that the reactive components of the second initial explosive (6) are boron and potassium nitrate. 4. Pyrochemical ignition chain according to claim 1, characterized in that the first initial explosive (5) is lead trinitroresorcinate. 5. Pyrochemical ignition chain according to claim 1, characterized in that the weight ratio of the first (5) to the second (6) initial explosive layer is 1: 2 to 1: 5. 6. Pyrochemical ignition chain according to claim 3, characterized in that the ratio of boron to potassium nitrate is 10 to 70 wt .-% B and 30 to 90 wt .-% KNO3. 7. Pyrochemical ignition chain according to claim 4, characterized in that the lead trinitroresorcinate has a grain size of 80 µm to 120 µm. 8. Pyrochemical ignition chain according to claim 6, characterized in that the boron-potassium nitrate has an average grain size of 40 firn to 70 µm. 9. Pyrochemical ignition chain according to claims 1 to 8, characterized in that the two initial explosives (5, 6) are encapsulated in a molded form in a plastic cap (4).