PT1903298E - Ignition impuls distributer - Google Patents

Abstract

The device for distributing a non electric ignition pulse of a strand-like ignition means (6) on two other strand-like ignition means (8), comprises a flask-like closed housing (2, 3) with a normal interior, an inlet (5) for the reception of the ignition means (6), and two outlets (7) for the admission of two other ignition means (8). The inner surfaces of the housing are coated with octogen and an initial ignition agent is arranged in the outlet. The coating is introduced in a quantity of 4-7 g/m 2> on the interior surface of the housing. The initial ignition agent is pressed into the inlet. The device for distributing a non electric ignition pulse of a strand-like ignition means (6) on two other strand-like ignition means (8), comprises a flask-like closed housing (2, 3) with a normal interior, an inlet (5) for the reception of the ignition means (6), and two outlets (7) for the admission of two other ignition means (8). The inner surfaces of the housing are coated with octogen and an initial ignition agent is arranged in the outlet. The coating is introduced in a quantity of 4-7 g/m 2> on the interior surface of the housing. The initial ignition agent is pressed into the inlet. The initial ignition agent of 10-20 mg is used per outlet. The outlets are closed individually and are formed for tubular nozzle protruding into the housings. The tubular nozzle has an external thread, on which a cover is screwed for locking the respective outlets. The housing is detachable for recoating the inner surface and is divided along a longitudinal section into two housing halves, which are pressed together by a clamping device (4). The device is arranged in modular manner and has an input module, a final module and central modules arranged between the input module and the final module.

Description

ΕΡ 1 903 298 / ΡΤ DESCRIPTION " Ignition Distributor " The present invention relates to a device for delivering a non-electric ignition pulse of lanyard-type ignition means to at least two other cord-type ignition means.

In explosions explosive charge detonation is usually activated by the transmission of an ignition pulse to a detonator, which, in turn, detonates the explosive charge. In this case, it can be differentiated between a transmission of electrical and non-electric ignition pulses. In the non-electric transmission of ignition pulses, rope-type ignition means are generally used, which may be indicated, for example, a detonating cord or a detonation start cord or a safety fuse.

If it is necessary to simultaneously detonate several consecutive and separate explosive charges or in a predetermined sequence, then the activation ignition pulse has to be distributed to all explosive charges to be detonated. This is necessary, for example, in the evacuation of combat means, where unplanned projectiles or collapsed mines often have to be detonated simultaneously.

In the transmission of non-electric ignition pulses, the detonating cords of the various explosive charges may be conveyed together to a common ignition device, so that upon activation of the ignition device, the ignition pulse is transmitted to all detonating cords. Owing to the fact that the ignition device is often far enough away from the explosive charges, a number of long detonating cords have to be laid down which is costly, costly and susceptible to malfunction.

Alternatively it is also possible to series-connect the explosive charges by means of a continuous detonating cord. In this case, the individual explosive charges, depending on the detonating cord used, are detonated in more or less long time intervals. If, in this case, a defect is detected in the detonating cord and according to the defect, one or more of the explosive charges subsequently located will not detonate.

A further possibility of the distribution of the ignition pulses is the joining of the various detonating cords relatively close to the explosive charges. These are then suitably joined with a detonation charge which, by means of a detonating cord of its own, is detonated and transmits an ignition pulse to the detonating strands previously attached.

A corresponding dispensing device is described in WO 03/023316 AI. In this case, a detonator charge is introduced into a housing which, at one end, has a clamping device, with which several safety wires can be retained. The detonator charge is oriented within the housing so that the main detonation pulse is directed toward the tight safety wires, so that they transmit an ignition pulse to the explosive charges attached thereto.

In DE 4 73819 C, on which the preamble of independent claim 1 is based, there is described connecting body for the instantaneous detonating strands serving for the distribution of an ignition pulse. The connecting body is formed by a cylindrical compressed core of explosive material which is surrounded by a metal nozzle and terminating by a metal cap. In the caps and in the compressed core are holes, into which a detonator can be inserted which ignites the connecting body and the detonating strands conducting the ignition pulses.

In the dispensing device described above an additional detonator (the detonator charge) is required to construct an explosion system. Due to the fact that the construction of an explosion system, in addition to true explosive charges, the detonators are the most significant cost factor, the costs for the explosion system increase due to such a construction. In addition, the use of a detonator charge carries with it additional risks with regard to safety at work. The use of octogen for driving an ignition pulse through a detonating cord is described, for example, in US-A-5,010,821. The described connection allows for transmission of energy in two different ways. To this end, a fine steel wire (for electrical signal conduction) or a glass fiber (for optical signal transmission) is applied to a known safety fuse, which usually has a hollow space. PETN, RDX or HMX (octogen) materials are referred to as materials for coating the inner surface of the safety fuse.

Based on this assumption, the invention aims to provide a dispensing device which enables a safe delivery of an ignition pulse to various cord-type ignition means, such as safety wires or detonating cords at low costs but high working safety.

This object will be achieved by means of a non-electric ignition impulse delivery device having the features indicated in claim 1. The device according to the invention for delivering a non-electric ignition pulse from cord-type ignition means for at least two other cord-type ignition means comprises the following components: a closed housing with an unbranched interior space, an inlet opening, which opens into the interior space, for receiving the cord-type ignition means, at least , two outlet openings which open into the interior space for receiving respectively one of at least two other cord-type ignition means, in which the inner surfaces of the shell are coated with an initial ignition material is arranged in the outlet openings.

By means of the ignition pulse transmitted from bead-type ignition means to the device, the octagonal coating of the inner surfaces of the shell is detonated, which, in turn, detonates the initial ignition material provided at the outlet apertures. Through this, the ignition pulse is transmitted to the other cord-type ignition means, connected to the outlet apertures.

Due to the fact that the initial ignition material is arranged directly in the front portions of the bead-type ignition means receiving the ignition pulse, substantially less initial ignition material is required than in the prior art described for transmission of the ignition pulse. ignition. Because of this, costs can be reduced and, nevertheless, work safety can be increased.

To keep costs as low as possible and to achieve easy use of the device, it should be as small as possible. For example, in one of the ignition distributors of approximately 4 cm, the length may be from 5 to 10 cm and the thickness from 0.8 to 1.0 cm. If a distribution is required for relatively many cord-type ignition means, the selected measurements may be of correspondingly larger dimensions.

As material for the dispensing device according to the invention, any suitable material which can be coated with octogen may be used. Examples of synthetic materials are polyethylene, polypropylene, polycarbonate and polyamide.

Preferably, the octagene coating contains a mixture of aluminum, whereby very finely powdered aluminum is generally used. The aluminum raises the temperature during ignition of the coating and, thereby, improves the ignition efficiency of the initial ignition material in the outlets of the εΡ 90 903 298 / ΡΤ outlet. To this end 9% by weight of aluminum is used in the coating mixture. In order to improve ignition of the coating, microballoys may be added to the coating mixture in addition to or instead of the aluminum. These microballoons are small glass beads (microspheres) which act as initial cores during ignition of the coating.

For coating the inner walls of the wrapper, the coating mixture is applied to the inner walls, preferably in an amount of 4.0 to 7.0 g / m 2. Depending on the surface quality (roughness) of the inner walls, the amount to be applied in the coating mixture may have different values, so that, overall, they are coated between 15% and 100% of the total surface of the shell.

As the initial ignition material, the initial ignition materials normally used in the explosion technique may be applied. Examples are, in this case, so-called fulminants.

Preferably, the initial ignition material is compressed in the outlet apertures in a sufficient amount. 10 to 20 mg of the initial ignition material may be used at each outlet aperture.

The outlet openings of the dispensing device according to the invention are preferably equipped so that they can be individually closed. If the dispensing device according to the invention has more outlet openings than are required in the exploding system under construction, the dispensing device can be adapted to these circumstances, the unnecessary outlet openings being closed.

The outlet openings are preferably formed, respectively, in a protruding nozzle of the housing, having an outer thread, in which a cover is screwed which closes the respective outlet opening, so that during the distribution of the ignition pulse, it is only transmitted to the cord-type ignition means connected to the outlets and thus flammable materials which may exist outside the ignition distributor, such as gases or powders, are not supplied. may be inflamed.

In order to repack the dispensing device according to the invention after use, it is advantageous if it is constructed so that it can be dismantled. For example, if the shell is in the form of a bottle, which is divided into two shell halves along its longitudinal cutting plane, one half of the upper shell and one lower half, which are pressed against each other by means of of a clamping device.

Further advantages and features of the present invention result from the description of an exemplary embodiment, as well as, with the aid of the drawings.

The drawings show: in Fig. 1 a schematic cross-section of an embodiment of the device for dispensing a non-electric ignition pulse in accordance with the present invention; 2a shows a schematic cross-section of a nozzle of an outlet opening of the device for dispensing a non-electric ignition pulse of Fig. 1; 2b shows the nozzle of Fig. 2a in a simplified perspective view; Fig. and in Fig. 3 a schematic cross-sectional view of another embodiment of the device for dispensing a non-electric ignition pulse in accordance with the present invention, which is characterized in that it has a modular construction.

In Fig. 1 there is shown a dispensing device 1, which has the shape of a bottle along a plane of the longitudinal section, and is formed by an upper bottle half 2 and a lower bottle half 3. Both halves of the housing are tightened together in a sealed manner by means of suitable clamping elements 4, here in the form of two bolts with nuts, which penetrate the bottle halves 2, 3. Alternatively both of the wrap halves 2, 3 may be tightened together, for example by means of a clip wrapping the two housing halves, in the form of a tubular clamp, or by any other suitable tightening device.

On the left-hand side of the dispensing device 1 there is provided an inlet opening 5, in an extension of the casing, in the form of a bottle neck, into which the cord-type ignition means 6, such as a safety filler , for the transmission of an ignition pulse to the dispensing device and which maintains a seal against an unintended subsequent release. To this end, as shown in Fig. 1, the bottle-shaped extension may be provided with an outer thread, in which a cover nut 14, which surrounds the cord-type ignition means, is screwed and the cord-type ignition means 6 has a ring-shaped flange 15, which is pressed by means of the cover nut 14 against the front surface of the casing extension, in the form of a bottle neck, and thus, if necessary, also radially inwardly against the cord-type ignition means. As an alternative to this, the cover nut 14 may press a hollow cone (not shown) movably disposed in the cord-like ignition means 6, in a ring-shaped slot between the cord-like ignition means 6 and the inner peripheral portion of the bottle-neck extension in the direction of the casing, so as to securely fasten the rope-like ignition means 6 in the inlet port 5 and to secure it against slipping. In another alternative, the bottle neck-like extension of the bottle neck may have tightening ends in a so-called radially inwardly pressing olive shape, which engages the cord-type ignition means in the outer peripheral portion. The tightening ends of this type are schematically shown at the outlet openings 7. 8 ΕΡ 1 903 298 / ΡΤ

In the upper half of the housing 2 there are formed three openings 7 with tubular shaped nozzles 13 branching from the housing for receiving, respectively, lanyard-type ignition means 8, for which the ignition pulse is to be transmitted. In Fig. 1 two of these lanyard-type ignition means 8 are inserted, such as, for example, two safety wires.

The nozzles 13 of the outlet openings have, on their outer peripheral surface, an outer thread 9, into which a protective cap 10 can be screwed. In the dispensing device 1 shown in Fig. 1, for example, the outlet opening 7 is closed by means of a protective cap 10.

The inner surfaces of both housing halves 2, 3 of the dispensing device 1 are coated with an octagonal layer 11. In both of the outlet apertures 7, upon which the ignition pulse is to be transmitted to the ignition means 8, a sufficient amount of the initial ignition material 12 is compressed, as shown in Fig. 1. The type ignition means bead 8 are inserted into the respective outlet aperture to the abutment in the respective initial ignition material 12. Like the ignition means 6, the ignition means 8 are also held in the outlet openings 7 secured against a separation, e.g., by non-positive binding. Thus, it is ensured that during the operation of the ignition distributor, ie during the distribution of the ignition pulses to the lantern-type ignition means 8, connected to the outlet apertures, they can not be separated from the ignition distributor and thus , flammable materials, e.g. ex. gases or powders can not be ignited. This is particularly important, among others, in mine work, where ignition of methane gas (= grit) has to be avoided.

Instead of the cover nut 14 shown in Fig. 1 which, by means of a hollow cone or an annular flange, develops a clamping force acting radially inwardly on the cord-type ignition means, the free end sections of the tube shaped nozzles 18 have, as shown in FIG. 2b, longitudinal grooves axially spaced in a peripheral direction, through which the flexible nozzle portions 16 are formed in the peripheral direction, as shown in FIG. In the nozzles 13, exemplarily shown in Fig. 2b, four flexible nozzle portions 16 are spaced apart from each other by an angle of approximately 90ø.

As schematically shown in Fig. 1 and in detail in Fig. 2a, these flexible portions 16 respectively have a clamping end 17 in the inner peripheral part, which engages in the outer peripheral part the cord-like ignition means 8, introduced into the opening about to leave. In the simplest case and with a suitable correspondence of the inner diameter, the longitudinal grooves (length and width of the grooves) and the wall thickness of the nozzles 13 with the outer diameter of the lanyard means 8, the clamping force of the portions of nozzle 16 is sufficient to safely retain inserted means 8 of ignition. Furthermore, the cover nut 18 may, however, as shown in Fig. 2a, the respective lantern-type ignition means 8 be screwed onto the tube-shaped nozzle 13 by means of which a force acting radially inwardly which complements or maintains only the clamping force of the nozzle portions 16. In any case, the nozzle portions 16 act in conjunction with the clamping ends 17 inwardly against the cord-like ignition means 8 and ensure a secure seating of the ignition means 8 even during the operation of the ignition distributor according to the invention.

If an ignition pulse is now transmitted from the safety filler 6 to the delivery device 1, it causes ignition of the octagonal inner liner and transmits the ignition pulse to both the pressed pieces of initial ignition material 12 in the apertures 7. In order for these pressed pieces of initial ignition material 12 to be ignited, they transmit the ignition pulse to the safety catch 8 inserted in the outlet openings 7. 10 ΕΡ 1 903 298 / ΡΤ

After use, the dispensing device 1 may be opened, by releasing both clamping elements 4 and being again coated with octagene.

An alternative embodiment of the ignition distributor is shown in Fig. 3. This is characterized by a module construction which allows the ignition distributor to be constructed in accordance with the requirements of the quantity of the lanyard-type ignition means 8, in order to which the ignition pulse must be distributed.

This is achieved through three types of modules, i.e. an input module A, optionally one or more central modules B and a terminal module C which, as shown in Fig. 3 are arranged in this sequence. Modules are improved in their end sectors to be joined so that a fixed connection of the modules to each other during operation is ensured, although these, after use, can be separated so that they can be again coated with octogen. Thus, the modules are reused as often as desired.

A connection of this type can be provided, for example, by a coupling joint without interference of shape, for example in the form of a male and female connection, as schematically shown in Fig. 3. In addition, the modules already connected may be, by means of one or several suitable clamping devices (not shown in Fig. 3), tightened together in the longitudinal direction of the ignition distributor, to ensure even more improved fastening during operation.

If each of the modules A, B and C has an outlet opening 7, depending on whether a central module B is used and, if so, how many central modules B are required, there may be composed of two or more outlet 7. Thus, ignition distributors with 30 or more central modules B are possible. Modules A, B and C may, however, also have a number of outlet openings 7 located side by side. If, for example, three output openings 7 are respectively available for one module, the total number of output openings 7 for each additional central module B is also increased by 11 ΕΡ 1 903 298 / ΡΤ three. The advantage of such a construction by modules of the ignition distributor according to the invention is based on the fact that the ignition distributors intended by the user according to the plane of explosions are of various sizes and are easily formed, in this way, without the need for expensive management of the storage of different sizes of ignition distributors.

Lisbon, 2010-09-01

Claims (11)

A device for distributing a non-electric ignition pulse from the cord-type ignition means (6) to at least two other cord-type ignition means (8), in particular that the device comprises the following: a closed envelope (2, 3) with: - an unbonded inner space, - an inlet opening (5) for receiving the cord-type ignition means (6), at least two openings of (7) for receiving each of at least one of two other cord-type ignition means (8), characterized in that the inner surfaces of the shell (2, 3) are octagonal coated and disposed in the outlet apertures (7) an initial ignition material (12). A device according to claim 1, characterized in that the octagonal coating (11) contains a mixture of aluminum. Device according to claim 2, characterized in that the coating (11) contains at most 9% by weight of aluminum. Device according to one of the preceding claims, characterized in that the coating (11) is applied to the inner surface of the shell (2, 3) in an amount of 4.0 to 7.0 g / m 2. Device according to one of the preceding claims, characterized in that the initial ignition material (12) is compressed in the outlet openings (7). Device according to one of the preceding claims, characterized in that 10 to 20 mg of the initial ignition material is used in each outlet opening (7). ΕΡ 1 903 298 / ΡΤ 2/2 Device according to one of the preceding claims, characterized in that the mackerel openings (7) can be closed individually. A device according to claim 7, characterized in that the outlet openings (7) are respectively formed in the projecting nozzles (13) of the housing (2, 3), each nozzle having an outer thread, in which a thread (10), which closes the respective outlet opening (7). Device according to one of the preceding claims, characterized in that the housing (2, 3) is removable, so that the inner surface can be re-coated after use. A device according to claim 9, characterized in that a collar (2, 3) is divided into two halves of the casing (2, 3), along a longitudinal cutting plane, the halves of which are pressed against each other by means of a clamping device (4). Device according to claim 9, characterized in that the device is formed of modules and is composed of an input module, an end module and optionally one or more central modules arranged between the input module and the terminal module . Lisbon, 2010-09-01