NO333107B1 - Plastic explosive mixture, especially for a flavor-calibrated initial ignition for tunnel buildings, manufacture thereof and a booster for its use - Google Patents

Abstract

In using a plastic explosive composition (PEC), the ignitor, in spite of initially closed stoppers (12), can be inserted very easily and precisely in the PEC. When the PEC is combined with a booster, safe and central placing of the ignitor in the sleeve (11) is ensured, and the PEC, because of the stoppers on both sides, can be safely and densely packed. The PEC contains (wt.%): pentaerythritol tetranitrate and/or hexogen and/or octogen as high explosive material (50-80), dibutyl phthalate and/or diamyl phthalate as plastifying agent (15-30), nitrocellulose (0.5-3), inorganic nitrates, e.g. sodium (Na) and/or potassium (K) nitrate (up to 10), and small amounts of impurities, colorants and inert materials. Independent claims are also included for the following: (1) a process for preparation of the PEC having the above properties involving making a mixture containing (wt.%) dibutyl phthalate and/or diamyl phthalate as plasticizer (15-30) and nitrocellulose (0.5-3) to form a gelatin, to which are added pentaerythritol tetranitrate (nitropenta) and/or hexogen and/or octogen as high explosive materials (50-80), inorganic nitrates (up to 10) and small amounts of colorant and inert materials, until a homogeneous composition is obtained; (2) a booster for the explosive material, especially for the borehole loading tube, a small caliber priming, and a boosting charge for tunnel construction, with a tubular sleeve (11) with plastics stoppers (12) at both end sections, of which at least one can be penetrated by the ignitor for the explosive in the sleeve (11), where the sleeve stoppers (12) are strongly and tightly closed, and at least one stopper has a central opening (19) for an ignitor, so that the ignitor is enclosed centrally, and can be arrested.

Description

The present invention relates to a plastic explosive mixture, in particular for a small-caliber initial ignition for tunnel construction, with substances that are not toxic, that have good handling safety and detonation ability, with at least one high-explosive explosive and a plasticizer; a method for its manufacture with the features of the introductory part of the sole method claim; as well as a booster for such a plastic explosive mixture, especially for charging hoses for boreholes and a small-calibre initial ignition, i.e. booster charge for tunnel construction, with a tubular sleeve with plastic plugs down both ends where at least one is permeable to an igniter for the explosive in the sleeve.

Today's global trend towards larger blasting facilities for raw material extraction has led to the mechanization of charging operations. Explosive-free explosives such as ANFO (ammonium nitrate fuel oil) explosives and emulsion explosives are produced on the mixed loader vehicle and are filled or pumped directly into the boreholes using suitable devices. These kinds of explosives have good blasting technical parameters, but are in most cases not cap sensitive and need a strong initiation. Often, a so-called impact cartridge is used for this, which can be initiated safely with a conventional, explosive detonator. In recent years, the use of boosters or ignition amplifiers has increased at the expense of the use of percussion cartridges. Such boosters mostly consist of high-explosive explosives such as pentaerythritol trinitrate (nitropenta) and/or trinite-rotoluene (TNT). When used in open pits, the diameter of such boosters is mostly 65 mm.

Loose explosives such as powders or emulsions are now also used to a greater extent in underground areas and above all in tunnel construction. However, the borehole diameter for tunnel construction is significantly smaller than for blasting work today in order to be able to carry out targeted blasting. For the most part, they are in the range of 36 to 50 mm. The loose explosives are pumped or blown into the boreholes using a charging hose. Of course, the charging hose has a smaller diameter than the borehole so that when it is inserted into the borehole it should not get tangled or blocked. For the most part, the outer diameter of the charging hose is between 25 and 27 mm and the inner diameter 19 mm. With the charging technology in connection with tunnel construction, the booster, equipped with an explosive igniter, is inserted into the charging hose and in this way brought into the borehole together with the charging hose. The diameter of the booster must therefore be smaller than the inner diameter of the charging hose.

The booster must cause a small-calibre initial ignition, i.e. be a small-calibre booster charge.

Known boosters consist of a tubular sleeve whose ends are closed with plugs whereby one of the plugs exhibits openings, for example a slot for easier introduction of the explosive and an igniter. From these openings, components of the explosive can seep out, and liquid can seep in, whereby the explosive can also reach the inner walls of the packaging, i.e. the inner walls of bags or cartons for boosters, which can lead to problems from a safety and occupational hygiene point of view. The slot also serves for the introduction of the igniter into the explosive mass in the booster, but which only loosely, or at least without further fixing or positioning, protrudes into the explosive mixture. In the case of a solid explosive mixture, there is usually even a pre-formed cavity for incorporating the igniter into the explosive mixture, which, however, entails the risk of the igniter sitting too loosely in the cavity or of jamming when the igniter is inserted into the cavity in the booster. When the igniter is inserted, the explosive mixture also swells beyond the booster, which also leads to unwanted soiling. The booster prepared in this way can also only be equipped with a detonator from one side and this results in more complicated handling which also entails the risk of loss of detonators and/or explosive mixture. An accurate and thus efficient, centered arrangement of the igniter, which depending on the manufacturer has a slightly varying diameter, is only possible by careful handling and alignment during the introduction of the igniter, all in an individual way. This means that a person entitled to blast can only do this by hand.

Several compositions for such boosters are known in the literature. As early as 1929, Stettbacher (T. Urbanski in "Chemie und Technologie der Explosivstoffe", VEB Deutscher Verlag fur Grundstoffindustrie, Leipzig, 1964, volume III, page 239) described explosives consisting only of nitropenta and nitroglycerol and which he designated as pentrinite. Depending on the quality of this nitropenta (crystal size) and its composition, a plastic mixture can be obtained, otherwise nitroglycerol will flow out of the mixture after a few days. A loss of nitroglycerol from the explosive mixture always constitutes a serious quality and safety deficiency, as nitroglycerol exhibits an impact energy of 0.2 J. According to, for example, the current German and also European transport regulations, such an explosive material can only be transported when the impact energy is greater than 2 J and the frictional energy is greater than 80 N.

Stettbacher also proposed a substitute for dynamite that consisted only of nitroglycerol, nitrocellulose and nitropenta. Investigations have shown that, on the one hand, this explosive is distinguished by a very high detonation speed (>8000 m/s), on the other hand, the impact energy required to trigger the explosion amounts to only 7.5 J (with the addition of potassium nitrate even 5 J) and the required frictional energy only 180 N.

Gelatinous ammonium nitrate explosives with a high nitroglycerol and/or nitroglycol content can also be used for boosters. As the critical diameter for gelatinous ammonium nitrate explosives, depending on the composition, is between 15 and 16 mm (without inclusion), gelatinous ammonium nitrate explosives for such applications are additionally equipped with high explosive explosives to achieve the required cap sensitivity. These explosive mixtures are also very sensitive to impact. The impact sensitivity required for detonation release amounts to 7.5 J. A further shortcoming of these explosive mixtures is the effect of "ageing". With longer storage, the fine air bubbles introduced during the manufacturing process disappear. The inner surface of the explosive mixtures is reduced and thereby also the sensitivity (see Ullman's "Enzyklopådie der technischen Chemie", Verlag Chemie GmbH, Weinheim, volume 21).

Also cast or pressed explosive mixtures of TNT or nitropenta or mixtures of these have been used for boosters.

Newer plastic explosives contain hexogen/octogen Mtropenta mixtures and a plasticizer (for example, styrene-butadiene copolymer).

Several of the listed explosive mixtures contain nitroglycerol and/or nitroglycol as components. These substances are classified according to the current hazard regulations as "highly toxic". The component TNT is also listed as "toxic". The use of these substances, above all underground, is considered problematic. The known explosive mixtures are therefore not very suitable for satisfactorily solving the task of the present invention.

As already mentioned, the known boosters are not tight and they are complicated to handle and are strongly influenced by the physical properties of the explosive mixtures, with the result that the cavities for the igniter are exposed to difficult-to-calculate changes when the explosive mixtures are changed. As a result, the known boosters are not particularly suitable for solving the task of the present invention either.

The present invention has the task of providing a plastic explosive mixture, in particular for a small-caliber initial primer, i.e. a booster charge in tunnel construction, which does not contain toxic substances, which exhibits a small critical diameter and which nevertheless exhibits an improved handling safety (more impact and friction energy ) than the hitherto known explosive mixtures, and to specify a method for their production.

Furthermore, a task for the invention is to provide a booster for a plastic explosive mixture, in particular for charging hoses for boreholes and a small-caliber initial igniter or primer, i.e. booster charge in tunnel construction, which does not exhibit any of the aforementioned defects of the known technique, as in the context of the plastic explosive mixture according to the invention is safe to transport and use and also easy to use, and which ensures optimal and safe positioning of the igniter in the booster.

The task with regard to the plastic explosive mixture is solved according to the invention by the mixture consisting of - 50 - 80% by weight pentaerythritol trinitrate and/or hexogen and/or octogen as a high explosive explosive,

15-30% by weight dibutyl phthalate and/or diamyl phthalate as plasticizer,

- 0.5 - 3% by weight nitrocellulose,

up to 10% by weight inorganic nitrates such as sodium and/or potassium nitrate, and

- small amounts of coloring and inert substances,

whereby the components dibutyl phthalate and/or diamyl phthalate when mixed form a gelatin with nitrocellulose which together with nitropenta and/or hexogen and/or octogen and sodium nitrate and/or potassium nitrate and coloring or inert substances form a plastic homogeneous mass;

and, with regard to the method for its production, the task is solved by the characterizing features in the method requirement.

According to the invention, the problem with regard to the booster is solved by the characterizing features in the independent claim relating to the booster.

Advantageous embodiments of the invention appear from the subclaims.

According to the invention, the mixture consists of 50 to 80 parts by weight of high explosive explosive such as pentaerythritol trinitrate and/or hexogen and/or octogen, 15 to 30 parts by weight of a plasticizer such as dibutyl phthalate and/or diamyl phthalate, nitrocellulose in the order of 0.5 to 3%, inorganic nitrates such as sodium and/or potassium nitrate in an amount of up to 10% as well as small amounts of coloring and inert substances.

The explosive mixture is primarily intended as a small-calibre initial charge (diameter 15 mm), also called an ignition amplifier or booster, for safe ignition of explosives in bulk, also in the form of powders or emulsions.

Dibutyl phthalate and diamyl phthalate are used in the field of explosives above all in the production of smokeless gunpowder that softens (see Ullmann's "Enzyklopådie der technischen Chemie", Verlag Chemie GmbH, Weinheim, volume 20, page 102). These substances therefore contribute surprisingly to a significant extent to the mixture of the invention.

The detonating ability of an explosive depends mainly on its ignitability and ability to redirect the detonation.

Ignitability is defined according to DIN 20163 "sprengtechnik, Ausgabe November 1994" as a comparison value for the sensitivity to ignition of an explosive which includes the required cap strength or explosive quantity for an ignition booster. The "critical diameter" is according to DIN 20163 "Sprengtechnik", the diameter of a charging column below which the detonation is no longer reliably transmitted. An explosive with a high detonation capacity therefore generally requires a low cap strength and has a small critical diameter. For testing, the procedure is generally as follows: A feng cap or an electric lighter contains 0.6 g of nitropenta as a secondary charge. In accordance with the current (including the German) regulations, the testing of an explosive with regard to cap sensitivity is carried out with a test detonator which has a lower secondary charge. Such sample lighters contain 0.375 g or only 0.250 g of nitropenta. Test lighters with 0.450 g of nitropenta are also used internationally.

According to the invention, dibutyl phthalate and diamyl phthalate are used as excellent substitutes for nitroglycerol/nitroglycol, in order to overcome the already mentioned shortcomings - toxicological (highly toxic) and safety technical properties. Both substances are, in accordance with the current law for hazardous materials, admittedly designated as "harmful to health", but not as "highly toxic" or "poisonous". The dibutyl phthalate used according to the invention, but not indicated as "very toxic" or "toxic", is also referred to as diisobutyl phthalate and is, in accordance with the provisions on dangerous substances, classified as only "hazardous to the environment".

According to the invention, it is advantageously proposed that in order to achieve a desired high detonation speed of at least 6260 m/s, an impact energy of at least 15 J and a friction energy of at least 360 N as well as a critical diameter of at least 15 mm and for charging hoses smaller than their internal diameter , the following recipes according to the table below are mixed together to form a gelatin:

Dibutyl phthalate and diamyl phthalate have, as already mentioned, a phlegmatizing effect on the explosive mixture. Handling safety is clearly improved with the above-mentioned recipes according to the invention and the recipe of the invention. The impact and rubbing energy is higher than with the known explosive mixtures. In addition, the explosive mixture exhibits a smaller critical diameter, which is desired for so-called boosters.

Advantageously, it is further aimed that the components dibutyl phthalate and/or diamyl phthalate form a gelatin with nitrocellulose by mixing which then, together with nitropenta and/or hexogen and or octogen and sodium nitrate and/or potassium nitrate and the coloring and inert substances, form a plastic, homogeneous mass. The explosive mixture is therefore particularly easy to handle and can easily be filled in very thin plastic sleeves which are easily movable in a thin charging hose of perhaps only 19 mm internal diameter. The explosive mixture is mainly filled in rigid, cylindrical plastic sleeves which are closed on both sides with plastic plugs. These plastic plugs have a star-shaped break line, whereby the introduction of lighters can take place in a simple and easy way.

Advantageously, it is further aimed that the explosive mixture has a consistency with a plasticity which enables easy insertion into two-sided closable plastic sleeves at the same time as the introduction of the detonator into this ignition amplifier is facilitated, and the retention of the detonator is ensured. The explosive mixture thereby exhibits a plastic consistency through which introduction of the detonator is facilitated. The retention of the igniter in the plastic sleeve (booster) is also significantly better with a plastic explosive mixture than with molded or pressed explosive mixtures (TNT/nitropenta).

Method according to the invention, according to which

15-30% by weight dibutyl phthalate and/or diamyl phthalate as plasticiser, and

- 0.5 - 3% by weight nitrocellulose,

mixed until a gelatin is formed and where this gelatin is then added

- 50 - 80% by weight pentaerythritol tetranitrate (nitropenta) and/or hexogen and/or octogen as a high explosive explosive, and

- up to 10% by weight inorganic nitrates, such as sodium and/or potassium nitrate, and

- small amounts of coloring and inert substances

until a plastic, homogeneous mass is formed by mixing, particularly supports the mechanization of charging work on site, ensures a high safety standard and leads to a long-term stable explosive mixture in addition to the advantages already described in connection with the mixture itself.

The task with regard to the booster with the plastic explosive mixture according to the invention is solved according to the invention by the plugs closing the sleeve firmly and tightly and by at least one plug having a central passage opening which can be opened individually, for an igniter, the opening keeping the igniter centered and sealing.

Surprisingly, it has been shown that the detonator can be introduced very easily and accurately into a plastic explosive mass, despite the initially closed plug. A combination of the plastic explosive mass with the booster according to the invention ensures, so to speak, automatically the safe and centered insertion of the detonator into the sleeve by, so to speak, complete tightness even with inserted teeth. This means that the plastic explosive mass is packed securely and tightly in the sleeve with the plugs on both sides so that neither explosives nor explosive components can escape or humidity can enter. As already described, known plugs have openings, for example slits for easier insertion of the lighter, and where explosives and/or liquid can escape, or enter respectively, and where the environment can possibly be soiled. This also leads to technical safety problems.

Advantageously, it is aimed that the explosive mixture does not completely fill the inner volume of the closed sleeve. In this way, a swelling of plastic explosive mass is excluded in a simple way when the second plug is inserted and when the igniter is brought into place.

Furthermore, it is intended that the free volume in the closed sleeve at least corresponds to the volume of the lighter to be inserted and a plug. In this way, various effects can be prevented. It has been shown that you can thereby prevent an expression of the second plug when inserting one plug and you can likewise prevent it when the lighter is inserted through one plug. Based on experience, it is sufficient to have only a few percent of the filling volume as free space.

According to the invention, it is further aimed that the sleeve is rigid and circular-cylindrical and that the plugs protrude tightly and firmly into the sleeve with a part and also have an external remaining flange whose outer diameter corresponds to that of the sleeve. This makes safe and predictable handling of the plugs possible, even with robust on-site handling. Because of the flange, each plug can thus only be pressed into the sleeve to a predetermined depth. The plugs are either easy to press in or similar and/or equipped with an adhesive or similar and thereby automatically seal the sleeve, so to speak. As the flange has the same outer diameter as the sleeve, the booster's mobility in the charging hose is not restricted either.

According to the invention, it is further aimed that each plug is elastic and circularly symmetrical and that the outer flange, together with a central part projecting into the sleeve, has a design similar to a thimble with a bottom projecting into the sleeve, which forms the passage opening for the igniter. With this simple precaution, manageability, especially when inserting a toothpick, is greatly facilitated. The thimble forms, so to speak, a target funnel for the igniter that guides the igniter safely towards the passage opening.

Furthermore, it is aimed that the bottom of the plug is orthogonal to the longitudinal extent of the sleeve and has a lower wall thickness with a breaking point radiating from the middle. The in and of itself closed access opening can thereby be broken open, but always from the centre, without the need for any special dexterity or use of force.

According to the invention, it is further aimed that one or both surfaces of the bottom are radially equipped with straight lines of reduced cross-section which form one or more fracture lines or the like, in a pattern reminiscent of a sliced round cake. In this way, the production technical effort can be kept low, since the breaking points themselves are formed from radially extending lines with a lower cross-section and since already three cake-like parts are sufficient to form a star-shaped passage opening and whereby all advantages according to the invention can be achieved.

According to the invention, it is further aimed that the "pieces of cake" belonging to the star-shaped passage opening hold the inserted igniter firmly due to their inherent elasticity in a centered manner and thereby also seal the sleeve. In this way, the inserted teeth are always pushed into the center of the sleeve and at the same time secured against extraction by means of the formed "receiver". The star-shaped passage opening is also only broken open as much as necessary, i.e. corresponding to the diameter of the lighter. The formed "receivers" lie close to the igniter. According to the application, the sleeve is tightly closed with and without teeth. However, an unintentionally pushed in tooth can be further pulled out as the elasticity of the "receptions" allows this and these will be relieved after pulling out the tooth and seal the opening again.

Furthermore, it is intended that the sleeve and plugs consist of polyethylene or polypropylene. Hereby, materials can be used which are easy to process, which ensure interaction between themselves and which optimally fulfill the sliding requirements in the charging hose at an outer diameter corresponding to the critical diameter and necessarily smaller than the inner charging hose diameter.

Furthermore, it is aimed that the sleeve satisfies the requirements of an extrusion method and the plugs the requirements of an injection molding method. Hereby, it is possible to produce the booster according to the invention in an economically attractive manner.

Example 1

At the intended 100 parts by weight, 28.3% dibutyl phthalate and 1.7% nitrocellulose are mixed to form a gelatin. 65% nitropenta, 5% potassium nitrate and small amounts of color and inert substances are then added until a homogeneous, plastic mass is formed.

Explosive technical parameters:

Example 2

At the intended 100 parts by weight, 25% dibutyl phthalate and 1% nitrocellulose are mixed until a gelatin is formed. 65% nitropenta, 9% potassium nitrate and small amounts of color and inert substances are then added until a homogeneous, plastic mass is formed.

Explosive technical parameters:

Example 3

At the intended 100 parts by weight, 20% dibutyl phthalate and 1% nitrocellulose are mixed until a gelatin is formed. 75% nitropenta, 4% potassium nitrate and small amounts of color and inert substances are then added until a homogeneous, plastic mass is formed.

Explosive technical parameters:

Example 4

At the intended 100 parts by weight, 20% dibutyl phthalate and 1% nitrocellulose are mixed until a gelatin is formed. Then 79% nitropenta, 0% potassium nitrate and small amounts of color and inert substances are added until a homogeneous, plastic mass is formed.

Explosive technical parameters:

Example 5

At the intended 100 parts by weight, 21% dibutyl phthalate and 1.5% nitrocellulose are mixed until a gelatin is formed. 68.5% nitropenta, 9% potassium nitrate and small amounts of color and inert substances are then added until a homogeneous, plastic mass is formed.

Explosive technical parameters:

Example 6

At the intended 100 parts by weight, 21% dibutyl phthalate and 1.0% nitrocellulose are mixed until a gelatin is formed. 70.0% nitropenta, 8% potassium nitrate and small amounts of color and inert substances are then added until a homogeneous, plastic mass is formed.

Explosive technical parameters:

The receptors are distinguished by explosive technical properties similar to those obtained with toxic substances, by an extremely high impact energy and the additional advantages already mentioned.

One embodiment according to the invention regarding the booster for a plastic explosive composition, in particular for charging hoses for boreholes and a small caliber initial ignition for tunnel construction shall be explained in more detail with reference to the figures where:

Figure 1 is an elevation, partially in section, of a booster according to the invention,

Figure 2 is a top view of the booster according to Figure 1 along the line A-A,

Figure 3 is a schematic sketch in side view of a plug in the booster, and

Figure 4 is a booster according to Figure 1 seen from above along the line B-B broken away

opening

Figure 1 shows a partial section view of a booster 10 according to the invention with a plastic sleeve 11 and two plugs 12, also made of plastic. The plugs 12 have an outer flange 13 with an outer diameter corresponding to that of the sleeve 11. The sleeve 11 and the plugs 12 have a circular cylindrical basic shape and are firmly and tightly connected to each other. This connection takes place via a circular-cylindrical section 14 which is connected in one piece with the flange 13 to the stopper 12 and, for example, projects a few millimeters into the sleeve 11 and is in firm and tight engagement with the inner wall 15 of the sleeve 11. This connection can take place under its own power and/or with the help of adhesive or heat. Although these are the preferred connections, it is of course also possible to use other connections such as ice screws or other connections such as snap and snap-in connections. With regard to the plug 12 shown in section at the bottom in Figure 1, the flange 13 has a centrally arranged and protruding into the sleeve 11 thimble-shaped (cylindrical) part 16 with a bottom 17 and a beam-shaped breaking device 18 indicated in Figure 1. The flange 13 is open in the area for the thimble-shaped part 16 so that a tooth shown only as a cross-sectional surface in Figure 4 can be pressed with its front end against the bottom 17 and thus against the breaking point 18 and break through this in an intentional manner. The igniter can also fill the entire star-shaped through-opening 19, i.e. the base 17. The break point or break points 18 are formed by radially or radially extending lines with cross-sectional reduction from the center, which are provided on one of the surfaces, for example the outer surface of the base 17. In addition to this, the flange 13 prevents the plug 12 from being pushed in when the opening 19 is broken through. Figure 2 shows a sleeve with a plug seen from above, corresponding to the line A-A in Figure 1. You can see the circularly symmetrical shape of the plug 12 and the flange 13 as well as also the bottom 17 with radially extending fracture lines 18, two of which are shown. Together, these form six cake-like sections, also called laskers or "receivers" 20. The thus formed, star-shaped through openings 19 are arranged deep in the thimble-like part 16 and thereby facilitate, in the form of a funnel, the introduction of the igniter 21. For otherwise, reference is made to the description in figure 1. Figure 3 schematically shows a side view of a plug 12 with flange 13, the cylindrical section 14 for fixing the plug 12 in the sleeve 11 and the thimble-like part 16 shown in dashed lines. In order to be able to put this the stopper 12 with still closed opening 19 into the sleeve 11 without the second stopper 12 pressed in at the other end of the sleeve 11 being pushed out again, according to the invention it is aimed that the sleeve 11 is not completely filled with plastic explosive. According to the invention, the sleeve 11 is only filled with plastic explosive to the extent that an expansion of the explosive during insertion of the igniter 21 is avoided. Tests have shown that with normal lighters, the free volume should correspond to around 1 cm for a booster 10 with a diameter of, for example, around 15 mm, or correspondingly approximately a filling of around 90 to 95% of the booster 10.

Figure 4 shows a section along the line B-B in Figure 1. The figure corresponds to Figure 2, however, in addition, the opening 19 is broken open and therefore shown star-shaped with an internal cross-section which may correspond to that of the igniter 21. The igniter 21 may have a larger or smaller cross-section. The radially formed lines for the breaking points 18 form elastic tabs 20, also called "receiver", which with their angular tips determine the available free diameter of the opening 19 and, due to their elastic material tension, keep the igniter 21 centered and secured against extraction. With a suitable choice of materials, the fracture lines will not be torn up appreciably more than absolutely necessary and the flaps 20 will join closely to the igniter 21 so that the opening 19 when inserted teeth 21 is, so to speak, tightly closed.

As a summary, it can be determined that the star-shaped break points 18 for the plug 12 are made in such a way that on the one hand tightness is achieved and thereby an exit of explosives or components thereof is prevented, and on the other hand is thin

and has a special construction that enables easy introduction of the igniter 21. When introducing the igniter 21, the fracture lines 18 are broken up to form the flaps 20. The igniter 21 can be easily introduced into the plastic explosive mass according to the invention and thereby attached by the combination of elastic explosive mass and the plastic tabs 20 and are thereby kept centered in the sleeve 11. Because of these tabs 20, it is further difficult for the igniter 21 to slip. As the plug 12 is the same on both sides, the igniter 21 can be guided

into the sleeve from both sides. The booster 10 must therefore not be held in any particular direction in order to be able to introduce the transmitter 21.

The advantage of a plastic explosive mass in such a booster 12 compared to a cast, solid explosive mixture, further consists in the fact that there must not be any previously created cavity in the explosive to be able to insert the igniter 21. A previously created cavity results in there is always a risk that the igniter is too loose or that problems arise when inserting the igniter 21. The volume of the sleeve 11 is only filled 90 to 95% with plastic explosive mass (on one side of the sleeve 11 there remains approximately 10 millimeters of empty space at a diameter for sleeve 11 in the centimeter range). This cavity is also sufficient for inserting the lighter 21 without the plug 12 inserted on the other side of the sleeve 11 being pressed out of the sleeve 11. The sleeve 11 and the plug 12 are made of plastic, such as polyethylene or polypropylene. The sleeve 11 is preferably produced by extrusion and the plugs 12 by injection molding, which leads to good economy.

The features of the invention described in the description above as well as in Figures 1 to 4 and in the claims can, both individually and in combination, be of importance to the execution of the invention in the various embodiments.

Claims (19)

1. Plastic explosive mixture, especially for a small-caliber initial ignition for tunnel construction, with substances that are not toxic, that have good handling safety and detonation ability, with at least one high explosive explosive and a plasticizer, characterized in that the mixture consists of - 50 - 80% by weight pentaerythritol trinitrate and/or hexogen and/or octogen as high-explosive explosive, 15-30% by weight dibutyl phthalate and/or diamyl phthalate as plasticiser, - 0.5 - 3% by weight nitrocellulose, - up to 10% by weight inorganic nitrates such as sodium and/or potassium nitrate and - small amounts of coloring and inert substances, whereby the components dibutyl phthalate and/or diamyl phthalate when mixed form a gelatin with nitrocellulose which together with nitropenta and/or hexogen and/or octogen and sodium nitrate and/or potassium nitrate and coloring or inert substances form a plastic, homogeneous mass. 2. Mixture according to claim 1, characterized by a critical diameter of at least 15 mm, a detonation speed of at least 6260 m/s, an impact energy of at least 15 J and a rubbing energy of at least 360 N. 3. Mixture according to claim 2, characterized by - 65% by weight nitropenta and/or hexogen and/or octogen, - 28.3% by weight dibutyl phthalate and/or diamyl phthalate, 1.7% by weight nitrocellulose, - 5% by weight sodium and/or potassium nitrate and - small amounts of coloring and inert substances. 4. Mixture according to claim 2, characterized by - 65% by weight nitropenta and/or hexogen and/or octogen, - 25% by weight dibutyl phthalate and/or diamyl phthalate, 1.0% by weight nitrocellulose, 9% by weight sodium and/or potassium nitrate and small amounts of coloring and inert substances. 5. Mixture according to claim 2, characterized by - 75% by weight nitropenta and/or hexogen and/or octogen, - 20% by weight dibutyl phthalate and/or diamyl phthalate, 1.0% by weight nitrocellulose, - 4% by weight sodium and/or or potassium nitrate and - small amounts of coloring and inert substances. 6. Mixture according to claim 2, characterized by - 68.5% by weight nitropenta and/or hexogen and/or octogen, - 21% by weight dibutyl phthalate and/or diamyl phthalate, - 1.5% by weight nitrocellulose, - 9% by weight sodium - and/or potassium nitrate and small amounts of coloring and inert substances. 7. Mixture according to claim 2, characterized by - 70% by weight nitropenta and/or hexogen and/or octogen, - 21% by weight dibutyl phthalate and/or diamyl phthalate, 1.0% by weight nitrocellulose, 8% by weight sodium and/or potassium nitrate and - small amounts of coloring and inert substances. 8. Mixture according to one or more of the preceding claims, characterized by a wood consistency with a plasticity that enables easy insertion into double-sided closable plastic sleeves and also facilitates the insertion of an igniter into this ignition amplifier and ensures retention of the igniter therein. 9. Process for producing the plastic explosive mixture according to claim 1, in particular for a small-caliber initial ignition for tunnel construction, with substances that are not toxic, have good handling safety and detonation ability, with at least one high explosive explosive and a plasticizer, characterized by a mixture of 15-30 weight -% dibutyl phthalate and/or diamyl phthalate which softens, and - 0.5 - 3% by weight nitrocellulose, is mixed until a gelatin is formed and that this gelatin is then added 50 - 80% by weight pentaerythritol trinitrate (nitropenta) and/or hexogen and/or octogen as a high explosive explosive, - up to 10% by weight inorganic nitrates such as sodium and/or calcium nitrate and - small amounts of coloring and inert substances until a plastic, homogeneous mass is formed by mixing. 10. Booster for a plastic explosive mixture according to claim 1, in particular for charging hoses for boreholes and a small caliber initial ignition, i.e. booster charge for tunnel construction, with a tubular sleeve (11) with plastic plugs (12) at both ends where at least one is permeable for an igniter ( 21) for the explosive in the sleeve (11), characterized in that the stoppers (12) close the sleeve (11) tightly and tightly and at least one stopper (11) has a central passage opening (19) which can be opened individually, for an igniter (21), as the opening maintains the igniter (21) centered and sealing. 11. Booster according to claim 10, characterized in that the explosive mixture only partially fills the inner volume of the closed sleeve (11) with a diameter corresponding to the critical diameter. 12. Booster according to claim 11, characterized in that the free volume in the closed sleeve (11) at least corresponds to the volume of the lighter (21) to be inserted and one of the plugs (12). 13. Booster according to claim 12, characterized in that the sleeve (11) is rigid and circular-cylindrical and that the plugs (12) protrude tightly and firmly into the interior of the sleeve (11) with a section (14) and have an external remaining flange (13) if outer diameter corresponds to that of the sleeve (11). 14. Booster according to claim 13, characterized in that each plug (12) is elastic and circularly symmetrical and that the outer flange (13) together with a central part (16) projecting into the sleeve (11) has a design similar to a thimble, with an in in the sleeve (11) projecting bottom (17) which forms the passage opening (19) for the igniter (21). 15. Booster according to claim 14, characterized in that the bottom (17) of the plug (12) is aligned orthogonally to the longitudinal course of the sleeve (11) and has fracture lines (18) with thinner wall thickness extending from the center in a radial fashion. 16. Booster according to claim 15, characterized in that one or both surfaces of the bases (17) are equipped with beam-shaped, straight lines with a reduced cross-section which form the fracture lines (18) by forming cake-like flaps (20). 17. Booster according to claim 16, characterized in that the flaps (20) in the star-shaped opening (19) center and hold the inserted teeth (21) due to their given elasticity and at the same time seal the sleeve (11). 18. Booster according to any one of claims 10 to 17, characterized in that the sleeve (11) and the plugs (12) are made of polyethylene or polypropylene. 19. Booster according to one or more of claims 10 to 17, characterized in that the sleeve (11) can be produced by extrusion and the plugs (12) by an injection molding process.