DE1132475B - Electric spark igniter - Google Patents

Description

GERMAN

PATENT OFFICE

H39335VIb / 78e

REGISTRATION DATE: MAY 4, 1960

NOTICE THE REGISTRATION ANDOUTPUTE EDITORIAL: JUNE 28, 1962

Electric spark igniter

The invention relates to an electric spark igniter which is used to ignite an explosive charge, especially in mines, during exploration work and in storeys. Such detonators are known to contain two electrodes connected to a source of electrical power and through a dielectric are separated.

Various types of spark igniters are known. Used for high voltage operation one generally thinks of the electrical dielectric as a dielectric Electricity non-conductive explosives. The explosives are made by the spark that goes between the two Electrode flashes over, ignited. Such a detonator, however, requires a powerful generator, the voltage of z. B. can give 20,000 volts, so that this detonator is practically only in mines and quarries and the like can be used.

To such a detonator m a projectile to be used where the generator must have a very much gerimgere terminal voltage due to the very small space available, it is granted a certain conductivity dielectric by graphite or metal powder is mixed in finely divided it. The space between the two electrodes filled with this mixture thus forms a series of numerous small gaps, as a result of which the explosive mixture allows the formation of a sparkover at a low voltage of about 500 volts. However, this arrangement has several disadvantages. On the one hand, the composition of the mixture of the explosive and the metal powder used, which serves as an electrical resistance between the two electrodes, is very critical, because its conduction properties must be precisely adjusted to the available electrical voltage, and on the other hand, the detonator must be very sensitive Ignition explosives are provided, since only a low-capacity power generator can be accommodated in one floor. As a result, the safety of the projectile versefaen with this fuse is significantly impaired.

The invention aims to avoid these disadvantages. It concerns an improved spark igniter, which is easy to produce with simple means and is good has reproducible electrical properties, which is a particularly great advantage for mass production represents such a detonator.

As is known, the spark igniter according to the invention contains two electrodes separated by a dielectric and is characterized in that one of the electrodes is made of an explosive that contains the Conducts electricity.

Applicant:
Hotchkiss-Brandt, Paris

Representative: Dipl.-Ing. R. Ohmstede

and Dipl.-Ing. B. Schmid, patent attorneys,

Stuttgart S, Falbenhennenstr. 17th

Claimed priority:
France of May 4, 1959 (No. 793 891)

According to one embodiment, the dielectric consists of an insulating element on which Place where the spark should jump, a hole with a smaller cross-section than the grain size of conductive explosives.

According to another embodiment, the dielectric consists of a layer of a crystalline semiconductor, for example the oxide or carbide of the metal from which the other electrode is made. This crystalline semiconductor allows current to pass from one electrode to the other with interposition one or more emission centers of the electrons. This well-known discharge contract always takes place in the form of sparks when the flashover voltage is reached.

The conductivity of the explosive serving as an electrode can be obtained by a known method be, for example by mixing the explosive with a conductive substance, e.g. B. graphite or metal powder. While the properties of the mixture are extremely critical if As with the known detonators, it is a matter of producing a layer of certain electrical energy Resistance is made of such a mixture, in the case of the electrode consisting of a conductive explosive, the mixing ratios in quite large limits vary, with the percentage of the conductive portion for example between 10 and 20 can be without affecting the operation of the Detonator is adversely affected by this.

Further details of the invention emerge from the description of some exemplary embodiments Hand drawing. Show in it

209 617/147

3 4

Fig. 1 to 5 are schematic sections through sanding means for overshoot voltages between 50 and

dene igniter according to the invention. 300 volts can be produced.

In the example shown in Fig. 1, the For smaller voltages, z. B. in the size igniter A ¹ a metal sleeve 1, whose with a hole 2 voltage of 20 to 50 volts, you can use an electrode 4 provided bottom for centering an insulating ring 3 5 made of aluminum, the surface of which is made of plastic, ceramic or. Like. Serves. This is coated with an insulating layer of oxide 5 α. This generating ring 3 is used to hold a first elec- OxydschicMhat a pronounced crystalline struktrode 4, which consists of metal. door, and the passage of current already happens for a This electrode is with a dielectric! Layer 5 low flashover voltage by means of the emission centers, which are well known from the half-covered, consisting of a thin disk, preferably io conductor technology. Those made of plastic or made of; Paper or the like. Discharge takes place in spite of the low voltage with the disk 5 has a very narrow spark formation in its center. If one wants to reach higher flashover voltages 0.01 mm, which forms a very short channel, with this simple hole 6 with a diameter of the order of magnitude, all that is needed is the chemical oxidation that the ignition spark has to pass through. This channel 6 15 produced layer with an insulating lacquer can preferably be produced in that to be drawn. Instead of an oxide layer, the disk S can also be made of a carbide layer, which is perforated by means of a high-voltage spark, before it is introduced into the igniter. Such semiconducting oxide or carbide layers. Above the disk 5 there is a second chemical, electrolytic or electrode? Which consists of a layer of an ignition detonation thermal path on other metals or alloying substances. As stated above, it is rung e.g. are produced on iron, copper od. like. rendered conductive, that it with a conductive constituents Fig. 3 shows a further embodiment of a part A ^s, z. B. graphite or metal powder is mixed. As a detonator according to the invention, although above explosive, lead azide or lead trinitro- the disks provided with a hole 12, a resorcmat or a mixture of both can advantageously serve. The metal 25 metal capsd 13 is provided with a central hole 14, the powder can be made of aluminum, copper or the like. The only condition is that it does not reduce the amount of conductive explosive 7 used. In this the explosive is chemically attacked. Case does the discharge from the electrode 4 run above the second electrode? is there a dielectric layer 5α to the electrode? and the non-conductive detonating explosive 8, which, for example, flows from the capsule 13 to the sleeve 1. consists of lead azide, and finally a secondary detonator A ⁱ , in the case of the explosive 9, which is made, for example, of tetryl, pentrite, two insulated conductive wires IS and 16 as electro-hexogen, trinitrotoluene or the like. which serve, where the conductive explosives? In this case, the parts located in the sleeve 1 are used as an intermediate electrode. The two for example by a clamping edge 10 at the end of the 35 wires 15 and 16 are namely held on a certain sleeve. Length from their end twisted together, where-If the sleeve 1 and the electrode 4 are subjected to an electrical at least one of the ends previously with a ddtric voltage U , which was coated with the electrical layer 5b . Preferably via dotted contacts, it is an oxide layer that is fed to the electrodes 4 and 7 40 electrolytically or chemically generated, on both sides of the dielectric 5 under voltage and the two twisted wires are then jumped into it a spark between them through the ka- one body? embedded in plastic, which looks nal6 over. As a result, the conductive in turn is located at the bottom of the sleeve 1 so that the explosive 7 existing electrode is brought to explode ends of the wires somewhat below the surface 18 of the. This ignites the non-conductive initial explosive body 17, but the dielectric material (s) 8, and this in turn ignites the explosive layer (s) protruding slightly from this area, or the charge 9 protrudes. These layers are then Fig. 2 shows a fuse ^ L ² , the electrode 4 ground down to the level of this surface, so that the surface is covered with a dielectric layer 5 α over the at least one end of the wires and be covered with an insulating washer - 50 electrical layer 5b as a result of the grinding "is covered with the one that has a central hole 12. This surface 18 terminates.

Hole is the conductive serving as the second electrode above this or these dielectric layer (s))

Explosive 7 in contact with the dielectric 5 b , the explosive 7 is attached, which creates an intermediate

ShiftSat. In this case, the electrical removal electrode is located between the two electrodes 15

charge through the dielectric layer 5 a through 55 and 16, and above the explosive 7 loading

instead of forming a spark on that stele, the initial explosive 8 and the

where the electrical resistance is lowest, d. H. secondary explosive charge 9.

at the point between the two electrodes 4 With this solution, the ignition of the explosive

and 7 the insulating washer 11 because of the hole 12 is not fabric layer 7 achieved by a spark between

is available. 60 see the layer 7 and at least one of the wires

The electrode 4 can be made of aluminum 15 or 16, for example.

consist, in which case the dielectric layer 5 α consists of If a single dielectric layer 5 b is provided

Consists of aluminum oxide, which is duroh anodic oxide, the arrangement has only two electrodes,

tion was obtained. Such an oxide layer shows one of which consists of the wire 15 or 16, the

no actual crystalline structure, but is actually carried by this layer while the other electrode

borrowed from channels of very small cross-section through the explosive 7 is formed,

that allow a certain amount of current to pass through. If, on the other hand, according to the configuration shown in FIG.

Such an anode layer can with a simple guide form both wires 15 and 16 each with one

dielectric layer 5b are covered, the arrangement forms two detonators connected in series from parts 15, 15b and 7, or 7, 5b and 16. The explosive? which forms the bridge between the two layers 5b , plays then the role of an electrode common to the two detonators lying in series.

The same applies to the igniter A ⁵ according to FIG. 5, in which the ends of the conductors 15 and 16 serving as electrodes end at the bottom of a cavity 19 which is incorporated in the insulating support 17. As before, at least one of the wire ends is covered with a dielectric layer 5b on which the conductive explosive layer 7 is located, which serves as an intermediate electrode.

This unit of parts 15, 16, 17, Sb and 7 can in this case be independent of the rest of the detonator, which consists of a commercially available; Primer with initial charge 70 and main charge 21 can exist.

The main advantage of the invention apparently lies in the possibility of using extremely simple means a dielectric layer 5, 5 a or Sb between the electrodes, ie between the electrode 4 and the explosive electrode? 1, 2 and 3 or between the electrodes 15 and 16 and the explosive layer? 4 and 5, with great regularity being able to be achieved by selecting the thickness of the insulating disk 5 or the dielectric layer 5α or 5b for a given electrical operating voltage by means of a simple rollover test.

The electrode made of explosives? always receives the available electrical energy in form of a spark.

As already mentioned, the conductivity of the explosive, which in the case of the known electrical Detonators, where this explosive acts as an electrical resistance, have a very precisely defined value must vary within wide limits in the arrangement according to the invention, without the work of the Detonator is disturbed by it. This makes it easy to mass-produce the arrangement.

With the known detonators, if the conductivity of the explosive is too high, the current does not generate sparks over, while if the conductivity is too low, the resistance is so high that none at all Electricity flows and therefore no spark can flash over. These disadvantages are after the detonator the invention is completely omitted.

Of course, the invention is not limited to the illustrated and described exemplary embodiments limited.

Claims (7)

PATENT CLAIMS: 1. Electrical spark igniter with at least two electrodes which are separated from one another by a dielectric, characterized in that one electrode (7) consists of an explosive that conducts electricity, while the dielectric (5, Sa, 5 b) is not an explosive. 2. igniter according to claim 1, characterized in that the dielectric consists of an insulating Element (5) consists of a very small one at the point where the spark should jump over Has hole (6) z. B. produced by electrical arcing at high voltage became. 3. The igniter according to claim 1, characterized in that the dielectric (5 ä) consists of a crystalline semiconductor, for example an oxide or carbide layer, which coats a metal electrode (4) in a manner known per se. 4. Detonator according to one of the preceding claims, characterized in that between the conductive explosive (7) and the dielectric (5, 5 a) an insulating element (11) with a central hole (12) is arranged which limits the area of spark formation . 5. igniter according to claim 4, characterized in that behind the insulating element (11) a metal element (13) with a central hole (14) is arranged and that the amount of the an electrode forming conductive explosive (7) approximately on the filling of the two Holes (12,14) required dimension is limited. 6. igniter according to one of claims 1 to 3, characterized in that two lead wires (15, 16) are embedded in an insulating carrier (17) and that the end of at least one wire with the dielectric (5 b) is covered with the surface of the carrier (17) and over which the conductive explosive (7) is located. 7. igniter according spoke 6, characterized in that the surface (18) of the carrier (17) at which the lead wires end, is at the bottom of a cavity (19) in the carrier and that the conductive explosive (7) the cavity (19) fills so that it forms a unit with the carrier (17), the lead wires (15, 16) and the dielectric (5 b) , which can be assembled with a primer (20, 21). Considered publications:
German Auslegeschrift No. 1 036 138,
434, 1084183;
German Patent No. 957 735;
British Patent No. 578,300. 1 sheet of drawings © 209 617/147 6.