EP0142717A1 - Blasting device for precision blasting - Google Patents

Abstract

1. Blasting device for non-recurrent use for precision blasting, on which an explosive (5) is able to be applied, characterized in that the blasting device consists of a hollow body (1 ; 8) which is closed on all sides, and which is provided to receive a non-combustible fluid as tamping substance (2), that the hollow body (1) is provided with a contact surface (3) serving for the application of the blasting device on a surface of the object which is to be blasted, that the hollow body (1) partially surrounds the explosive (5) externally, whereby for this within the extent of the contact surface (3 ; 10) and partially delimited thereby at least one associated depression (4, 4') which is open toward the exterior is provided in the wall of the hollow body to receive the explosive (5), and that the hollow body (1) is thin-walled but at the same time inherently stable such that there is a defined association of the explosive (5) to the blasting device and to the object which is to be blasted.

Description

The invention relates to a blasting tool for precision blasting.

For a number of applications, for example in disaster relief, there is a need to carry out explosions in rooms and in the immediate vicinity of people, for example to create a passage through a building wall. It is important to measure the explosive charge so that the material is loosened or penetrated to the desired extent, but that neither by damaging the explosive charge nor the parts detached from the material to be loosened or penetrated, for example, by the explosive charge persons in the room to be opened by the explosion are injured. The decisive factor here is the dimensioning of the amount of explosives in relation to the material to be loosened or penetrated and the dimensioning of the dam in relation to the selected amount of explosives. In the event of a disaster, it is often necessary to carry out an explosion in a very short time was not feasible with the previously known methods.

The invention is based on the object of creating an explosive tool with the aid of which the above-mentioned requirements can be met.

This object is achieved according to the invention by a damper with an abutment surface and at least one open recess lying in the abutment surface and at least partially delimited by it for receiving explosives. Such an explosive tool makes it possible to combine the explosive and the dam in one element, so that not only is the handling considerably simplified but also the explosive tool can be attached regardless of the position of the surface to be penetrated. If, according to an embodiment of the invention, fastening means are arranged in the area of the contact surfaces, it is possible to attach such an explosive tool not only to inclined or vertical surfaces, but also overhead and to carry out corresponding explosions in such constrained positions. The particular advantage of such an explosive tool is also that prefabricated dam members of different sizes can be kept on standby in order to be able to cover different explosive quantity ranges in the manner of a "map", in order in each case to provide easy-to-handle dam for the explosive quantity specified by the explosive task To have available. The explosives can either be introduced into the recess on site or can already be connected to the damper at the factory. If several recesses are provided, it is also possible to provide the damper body with a basic charge in the factory, which can be reinforced according to local requirements by the subsequent introduction of further amounts of explosives into a still open recess.

Explosives which are easily separable and easily portionable, such as plastic explosives or detonating cords, are preferably used.

In a preferred embodiment, the insulation body is designed as an elongated strip. This makes it possible to produce blasting tools of different lengths, it also being possible here to provide a certain “division grid”, so that certain contours, for example openings in walls of any desired size, can be blown up by assembling a plurality of insulating bodies. The strip-shaped insulation bodies can be straight or curved. Furthermore, it is possible to provide contours that are already predetermined for standard cases, for example by a frame-shaped design of the explosive tool.

In a preferred embodiment of the invention, the depression is designed as a continuous groove. This not only leads to a simplification in the manufacture of the displacer, since this can then be produced as a strand, but also allows variation options in the selection of the explosive to be used, since the continuous groove in any case offers the possibility of using detonating cords, but at the same time also other explosives, for example plastic explosives, can be introduced in a simple manner, it not being necessary to fill the groove in full length with explosives for a given dam. This increases the availability of the blasting tool according to the invention.

In a preferred embodiment, the fastening means arranged in the area of the contact surfaces are formed by an adhesive layer applied to the contact surface.

Silicon-based adhesives are preferably used here, which have the advantage of adhering even to rough walls, so that it is possible to attach the blasting tool to an inclined or vertical building wall or else overhead to a part of the building. The high adhesiveness of such silicone adhesives also allows the explosive tool to be attached to the surface in question with little effort. The adhesive layer does not need to be applied continuously over the contact surface, but can also be applied in zones or at points on the contact surfaces on both sides of the depression.

In the case of explosive tools which are already provided with explosives in the factory, this is fastened in the depression by means of adhesive or the like. In a preferred embodiment, however, it is provided that the depression is provided with holding means for the explosive. This makes it possible to fix the explosive in the recess, the holding means being able to be adapted to the packaging of the explosive used in each case. This holding means ensures that the entire explosive tool, ie. H. the detonating body with inserted explosives can be safely brought to the place of use even in difficult situations and can be attached to the explosive site without the risk of the explosive detaching from the detonating body. Depending on the packaging of the explosives used, various holding devices can be considered. For example, it is possible to fix an explosive cord in the recess using adhesive, for example silicone adhesive. This can be done both at the factory completion of the entire blasting tool and when the detonating cord is inserted on site.

In a preferred embodiment of the invention it is provided that the holding means are formed by fastening claws which protrude into the recess. Such preferably resiliently designed fastening claws simplify the handling of the explosive tool in such a way that the connection between the dam and explosive, in particular explosive in the form of an explosive cord in front of a wire, can be made very quickly without additional aids, since the detonating cord only needs to be pressed into the recess and then held in place by the mounting claws. Even when plastic explosives are pressed into the recess, fastening claws of this type ensure that the explosive is securely fastened in the recess.

In a particularly advantageous preferred embodiment of the invention, it is provided that the insulation body is thin-walled, hollow and is filled with an insulation material. This has the advantage that there is a wide variation possible for the manufacture and use of such blasting tools, in such a way that different cross-sectional shapes are available for a given insulation material, particularly in the case of strip-shaped insulation bodies, or different displacement materials are used in each case for a specific, optimal cross-sectional shape can be. Another advantage is that the manufacturing process and warehousing are simplified and so inexpensive materials can be used. Extrusion processes or the like can preferably be used for the production of the hollow profile, so that soft and / or hard plastics, rubber-like materials or even metals can be used as materials for the hollow profile. Plastics, for example PVC, offer the advantage that when the detonation is detonated, the wall of the hollow profile is broken down into such small pieces that there is no risk of injury to persons who must be in the immediate vicinity of the charge when detonating. The wall thickness only needs to be dimensioned in such a way that the landing of the hollow profile does not occur for handling, ie storage, transport and attachment can bump or burst under bending stress. Depending on the type of insulation used, it may not be necessary for the material for the walls of the hollow profile to be dimensionally stable. For example, in the case of pictorial insulation materials which enable the desired shaping for the blasting tool, the walls of the hollow profile can also be made from foils or the like.

In a preferred embodiment, a non-flammable liquid is used as the insulation material. Water is particularly suitable for this because it has significant advantages both in terms of its density and its chemical safety. If, for example, water is enclosed as a insulation material in a PVC hollow profile, the amount of water enclosed by the hollow profile is atomized during the blasting, in which the hollow profile is broken down into fine particles. Health damage to people who are at the blasting site cannot occur, so that the blasting tool can also be used in closed rooms. Instead of water, other non-flammable liquids, but also liquid mixtures, can be used. In a preferred embodiment, to increase the availability of the blasting tool according to the invention, it is provided that the liquid has a freezing point below the freezing point. When using water as a insulation material, this can be done, for example, by adding appropriate antifreeze.

Instead of a liquid as a damming agent, it is also possible to use finely divided solids or mixtures of solids, in order to avoid any risk of injury, such solids should be as dusty as possible and should be chemically inert at least for the area of use given here. That means that the solids or a mixture of solids must be neither flammable nor flammable. Furthermore, the solid used must not be chemically reactive insofar as it can come into contact with the human body, ie with tear fluid, saliva, mucous membrane, open wounds or the like. In an expedient embodiment of the invention, the finely divided solid is bound by a liquid. In this way it is avoided that, in the event of blasting by the sealing body, there is an additional dust development which obstructs the view. A further advantage is that the additional liquid, for example water, also fills the pore volume of the filling material and thus better insulation is achieved. Clay, for example, can be used as a finely divided, liquid-bound solid. This makes it possible to use a insulation material with a higher density than water, nevertheless ignite the explosive tool in closed rooms without causing additional dust formation or causing injuries to persons in the room, it being possible to assume that those attaching the explosive tool and igniting persons must maintain a certain safety distance and a certain cover and, as handling personnel, are generally provided with appropriate protective clothing.

For so-called single loads, in which the damper body is approximately pot-shaped, it is provided in an embodiment of the invention that the recess has a cross section widening into the damper body. This makes it possible to use the explosive tool in the manner of a so-called cutting charge, the use of the damper body according to the invention in conjunction with the conical shape that narrows towards the mouth of the depression causes the explosive effect to be concentrated on the penetration point. Against Using conventional loads, there is the possibility of using a smaller amount of explosives, depending on the application, instead of commercial explosives. highly explosive explosives can also be used. With a blasting tool of this type, it is possible, for example, to blast openings in the case of catastrophe operations in reinforced concrete ceilings, which then make it possible to make contact with spilled persons and, if necessary, to introduce supply lines into the cavity.

Another embodiment of the invention provides for the explosive tool to be used as a cutting charge in the true sense. Here, according to the invention, the depression is conical, the cone tip pointing into the displacement body, and that the explosive consists, in a manner known per se, of a shaped body which is designed as a hollow cone. This results in the possibility of carrying out explosions with such cutting charges with much smaller amounts of highly explosive explosive, since instead of being blocked by the ambient air, the block is now blocked by the block. The load on the environment due to the detonation shock is considerably reduced, so that such a cutting charge, which could previously only be used in the military, can now also be used in the civilian sector, for example in the event of a disaster.

In an embodiment of the blasting tool for separating rod-shaped objects, in particular steel cables by means of blasting technology, the invention provides that the contact surfaces are formed by a slot-like recess, that the recess containing the explosives in the bottom region of the slot opens into the latter and that the recess extends from one side of the slot Ver Insulation body-enclosed mouth expanded into the insulation body. Such an explosive device represents a single charge, which can be placed like a rider on the rod-shaped object to be separated, in particular a steel cable, which is then almost punctured after the explosive is detonated. For such applications, a highly explosive explosive is expediently used with a transfer speed of over 7,000 m / s, so that the rope to be separated is already destroyed by the detonation impact.

In an expedient embodiment of the invention, for blasting tools designed as a single charge, it is provided that the damper body is provided with an ignition channel leading from the recess to the outside. This allows the damper to lie tightly on the mating surface at the explosive site and the energy of the explosive is almost fully available at the penetration point. It is also advantageous here if the ignition channel opens into the depression in the region of the mouth. This has the advantage that the ignition initially in the mouth area, ie. H. takes place in the immediate vicinity of the penetration point and so the amount of explosives is ignited from the mouth into the depression, so that the blasting energy is always present in the area of the mouth, which leads to an increase in the penetration rate even with highly explosive explosives.

One embodiment is based on the task of designing an explosive tool of the type mentioned at the outset in such a way that factory production based on simple series parts is possible as far as possible, so that the insulation body can be stored as a pre-fabricated empty body and, in the event of use, only with explosives, detonators and insulation material is to be provided.

This object is achieved in that a closure piece is arranged at least one end of the damper body, which is provided with at least one closable filler opening for the damper material and which is connected to the groove-like recess and is sealed off from the interior of the damper body, preferably transversely has bore extending to the body axis. Such a closure piece allows the insulation body to be produced, for example, from an extruded hollow plastic profile in such a way that sections cut to length from a profile strand, for example according to a predetermined grid size, are used, the free ends of which are closed with closure pieces of the aforementioned type, for example by gluing, welding or the like. Liquid-tight connection. The filling opening can be closed by a simple, preferably elastic stopper. The transverse to the axis of the damper body and extending into the groove-like recess allows either to lead out an explosive cord guided in the groove-like recess of the damper body, which can then be connected to an ignition device, or through this hole the ignition agent into the Introduce the area of the groove-like depression filled with explosives, both in the form of a simple detonating cord and in the form of a detonator, which is inserted into the bore and acts on the explosive when detonated.

In a preferred embodiment of the invention, it is further provided that the closure piece has in its edge region a recess which is flush with the groove-like depression of the insulation body. This configuration has the advantage that when used as an extension or corner Connector through this recess of the explosives, for example an explosive cord can be passed over the entire length of the explosive tool without interruption. If such a closure piece is used as an end piece, it is possible either to lead the explosive axially out of the damper body or to introduce the ignition means, for example an ignition cord or detonator capsule, into the groove-like depression in the axial direction.

worden ist. Hält nun die Bedienungsperson die Verlängerung in der Hand und begibt sich in Sicherheit, so wird der Zünddraht vom Wikkel abgezogen und die Sprengung kann durch Betätigung des Zündschalters ausgelöst werden, sobald die Bedienungsperson einen entsprechenden Sicherheitsabstand erreicht hat.In a preferred embodiment of the invention it is provided that an axially removable, hollow extension is arranged on the closure piece of one end of the damper body, which is provided with a removable ignition wire coil, which is connected at one end to a detonator fastened in the groove-like recess of the closure piece is and that an ignition switch and an insertable ignition battery are arranged inside the extension. This configuration is preferably provided for police applications in which the attachment of the explosive tool and the ignition must follow one another within a very short time. As a rule, there is no time here to arm the explosive-filled and explosive-equipped explosive tool by inserting the ignition means and connecting it to the ignition device. Due to the special shape of the closure piece, it is possible to prepare such an explosive tool complete with a filler, an explosive and an ignition means, the ignition means, here the detonator capsule, already being connected to an ignition switch via the ignition wire. The explosive tool is armed in the present case by inserting the ignition battery. The blasting tool, which is provided on its contact surface with an adhesive, for example a self-adhesive layer, can now be attached to the blasting point at the blasting point.

has been. Lasts now the operator has the extension in hand and goes to safety, the ignition wire is pulled from the winding and the detonation can be triggered by actuating the ignition switch as soon as the operator has reached an appropriate safety distance.

In an advantageous embodiment of the invention it is provided that the ignition switch is arranged in the interior of the extension so that it is only accessible through an opening that becomes free after the extension has been removed. This ensures that even after the blasting tool has been armed by inserting the ignition battery, the blasting tool cannot be triggered accidentally, which is of particular importance in police use.

In an embodiment of the invention, the ignition wire winding is arranged on part of the outer surface of the extension. This also allows the ignition wire to be checked immediately before use, so that proper removal is ensured after the blasting tool has been attached.

In another embodiment of the invention, it is provided that the ignition wire winding is held on a preferably conical winding mandrel which is arranged in the interior in the pulling direction of the extension. All that is required here is a slight taper of the winding mandrel, which ensures that the ignition wire is pulled off the winding properly. The arrangement of the ignition wire winding in the interior of the extension has the advantage that any damage to the ignition wire due to transport and / or storage is excluded. It is expedient if, in a further embodiment of the invention, a releasable release agent, for example a paper sleeve or the like, is arranged between the ignition wire winding and the outer surface of the winding support.

• Fig. 1 perspektivisch ein leistenförmiges Sprengwerkzeug;
• Fig. 2 einen Querschnitt durch ein als Einzelladung ausgebildetes Sprengwerkzeug;
• Fig. 3 einen Querschnitt durch ein als Schneidladung ausgebildetes Sprengwerkzeug;
• Fig. 4 einen Querschnitt und
• Fi^g. 5 einen Längsschnitt durch ein Sprengwerkzeug zum Durchschlagen stabförmiger Gegenstände;
• Fig. 6 eine Aufsicht auf ein in das leistenförmige Sprengwerkzeug einschiebbares Verschlußstück;
• Fig. 7 einen Querschnitt durch das Verschlußstück entsprechend der Linie III-III in Fig. 2;
• Fig. 8 einen Längsschnitt gemäß der Linie IV-IV in Fig. 2;
• Fig. 9 einen Längsschnitt gemäß der Linie V-V in Fig. 2;
• Fig. 10 ein Hohlprofil im Schnitt mit Befestigungsmitteln für eine Sprengstoffschnur;
• Fig. 11 ein Sprengwerkzeug mit Verschlußstück und Verlängerung mit Zündeinrichtung in abgezogenem Zustand.

The invention is explained in more detail with reference to schematic drawings of exemplary embodiments:

• 1 shows a strip-shaped blasting tool in perspective;
• 2 shows a cross section through an explosive tool designed as a single charge;
• 3 shows a cross section through an explosive tool designed as a cutting charge;
• Fig. 4 shows a cross section and
• Fi ^g. 5 shows a longitudinal section through an explosive tool for penetrating rod-shaped objects;
• 6 shows a plan view of a closure piece which can be inserted into the strip-shaped explosive tool;
• 7 shows a cross section through the closure piece along the line III-III in Fig. 2.
• Fig. 8 is a longitudinal section along the line IV-IV in Fig. 2;
• 9 shows a longitudinal section along the line VV in FIG. 2;
• 10 shows a hollow profile in section with fastening means for an explosive cord;
• Fig. 11 is an explosive tool with a closure piece and extension with ignition device in the removed state.

The embodiment shown in Fig. 1 of a strip-shaped explosive tool consists of a thin-walled hollow profile 1, the cavity 2 on all sides, ie. H. is also closed on the end faces and filled with a insulation material. The hollow profile is made for example from a plastic such as PVC or the like.

As can be seen from the end face shown as a section, the insulating body defined by the hollow profile 1 in its shape has a preferably flat contact surface 3 which delimits an open recess 4 designed as a groove on both sides. An explosive, for example an explosive cord 5, is introduced into this groove 4 and is formed by holding means 6 in the form of adhesive dots, staples or, as shown here, projecting fastening claws. In the end region of the recess 4, the detonating cord 5 is provided with a conventional connecting means (not shown here) for connection to the ignition means.

A blasting tool designed in this way can be brought ready for use to the place of use, connected there with the ignition means and ignited, the blasting tool being placed with the open side of the groove-shaped recess 4 on the medium to be penetrated. In the case of horizontal or only slightly inclined surfaces, it is sufficient to place the explosive tool on the surface. In the case of strongly inclined or vertical surfaces or when installing overhead, for example under a building ceiling, it is necessary to provide the explosive tool with appropriate fastening means. In its simplest form, this is possible in such a way that an adhesive, preferably a silicone-based adhesive, is applied to the contact surface 3 in zones or in a continuous layer 7, which also applies the explosive tool holds vertical surfaces in the specified position after pressing. The use of silicone-based adhesives with the appropriate layer thickness makes it possible to achieve sufficient adhesion even on flat or dusty surfaces. Like the explosives, the adhesive layer can only be connected to the damper at the place of use.

Instead of the arcuate cross-sectional shape shown, a rectangular or trapezoidal cross-sectional shape can also be specified for the hollow profile. Furthermore, it is possible to arrange two or more depressions next to one another instead of just a groove-shaped depression, in order to be able to use an explosive tool for different charge strengths by filling one or more depressions with explosive according to the desired charge strength.

As stated at the beginning, several strip-like explosive tools, as shown in the figure, can be combined with one another for use, for example four such explosive tools in the form of a frame being attached to the wall in order to create an opening in a building wall. If certain shapes have to be used repeatedly, it is also possible to prefabricate complete frames on the basis of such strip-shaped blasting tools, which only have to have an interruption at least at one point for the supply of the ignition means.

The blasting tool for a single load shown in cross section in FIG. 2 consists of a cup-shaped, thin-walled hollow insulation body 8, for example made of a plastic with a circular or a square outline. The insulation body is in turn with a insulation material 9, in particular one non-flammable liquid such as water or the like filled. The insulation body has a preferably flat contact surface 10, which surrounds an opening 11 of the depression 4 on all sides for receiving the explosive. In the exemplary embodiment, the depression is designed in such a way that it has a cross section which widens into the damper body, starting from the mouth, so that the blasting energy is concentrated on the penetration point. The insulation body 8 is provided with a laterally outwardly directed ignition channel 12, which is sealed off from the cavity and through which the ignition means, for example an explosive capsule which can be ignited electrically or by means of a detonating cord, can be introduced into the depression 4 and brought into connection with the explosive . The ignition channel 12 expediently opens out in the vicinity of the mouth 11 of the depression 4, so that the explosive is ignited in the immediate vicinity of the penetration point specified by the mouth 11. If such an individual charge is placed, for example, on a reinforced reinforced concrete ceiling 13, then it is possible to blow up an opening 14 which widens accordingly in a funnel shape.

Fig. 3 shows another embodiment of the explosive tool for a so-called cutting charge. The insulation body 8 is again thin-walled hollow and filled with a liquid, for example water as insulation material. The recess 4 'is again approximately conical, but in contrast to the embodiment according to FIG. 2 such that the conical tip 15 of the recess 4' points into the dam body. The explosive is formed by a shaped body 16 which forms a hollow cone in a manner known per se. Compared to the previously known cutting loads, this system offers the same effect with less use of explosives because of the more effective insulation.

4 and 5, an explosive tool is shown, as it is used in particular for the detonation of rod-shaped objects, for example steel cables. Here too, an insulation body 8 is provided, which is preferably thin-walled hollow and is filled with a liquid, for example water, as insulation material. As can be seen from the two cuts at 90 ° to one another according to FIGS. 4 and 5, the recess 4 is conically conical towards the mouth 11 and is filled with explosives, preferably highly explosive explosives. In contrast to the other embodiments, the contact surface 3 'is formed by a slot-like recess in the insulation body, the mouth 11 of the recess 4 being in the bottom region of this slot. The damper body also has an ignition channel 12 which is guided laterally from the outside into the recess 4 and through which the ignition means, for example an ignition capsule 17, can again be connected to the explosive.

When in use, the blasting tool is placed like a rider on a steel cable 18 to be penetrated, as can be seen from the two sectional views.

Auf der Innenseite des Steges 22 sind zwei Einfüllkanäle 24 angeordnete die die dünnwandige Platte 21 durchstoßen. Diese Einfüllkanäle bilden bei der Verwendung als Verschlußstück zugleich die Einfüllöffnungen, die dann durch einen nicht näher dargestellten Verschlußstopfen, vorzugsweise aus einem elastischen Werkstoff, nach dem Füllen mit dem Verdämmungsstoff verschlossen werden können.6 shows a top view of a closure piece with which the free ends of the hollow profile 1 shown in FIG. 1 can be closed. The exemplary embodiment shown shows a closure piece which, at the same time, as an extension piece permits the connection of several individual hollow profile pieces. The closure piece 20 consists essentially of a thin-walled plate 21, on the plate level of which a circumferential web 22 is arranged on both sides, the outer contour 23 (FIG. 7) of which corresponds to the inner contour of the cross section of the hollow profile 1, so that the connecting piece into the Hollow profile inserted and with this

On the inside of the web 22 are two filling channels 24 arranged which penetrate the thin-walled plate 21. When used as a closure piece, these filling channels also form the filling openings, which can then be closed by a sealing plug, not shown, preferably made of an elastic material, after filling with the insulating material.

In the area of the thin-walled plate 21 there is a bore 25 which runs transversely to the longitudinal extent of the closure piece and opens into the groove-like recess 4, which is also present on the closure piece in accordance with the cross section of the hollow profile. This bore 25 has no connection with the interior of the hollow profile.

As can be seen from the top view according to FIG. 6, circumferential projections 26 can be arranged at a distance from the plate 21 on the outer surface 23 of the webs on both sides of the bore 25, which serve as stops when inserted into the hollow profile 1.

9 and 10 show the longitudinal sections indicated in FIG. 6, which illustrate the arrangement of the plate 21 on the one hand and the bore 25 on the other hand. In the longitudinal section according to FIG. 8, the closure piece is also shown pushed into a hollow profile 1, the one visible filler channel being closed with a closure plug 27. As can be deduced from the longitudinal section according to FIG. 8, a detonator inserted into the bore 25 from above protrudes with its tip into the groove filled with explosive 4 (in use), so that when the detonator is detonated, the detonator capsules directly onto it Explosives. A detonator can in the illustrated embodiment of a closure piece, which can also serve as an extension piece, not only in the end area of the blasting tool, but also at any joint of a strip-shaped blasting tool composed of several parts.

In Fig. 1, a hollow profile of the explosive tool is shown, the groove 4 is provided with bracket-shaped fastening elements. In Fig. 10, an embodiment is shown in a cross section, which according to the embodiment. Fig. 1 has manufacturing advantages. In this embodiment, an extruded plastic hollow profile is used, the groove-shaped recess 4 is dimensioned so that the largest detonating cord for the given profile can be inserted. The simplification of the construction is that there is no need for additional fastening claws or gluing the detonating cord 5 into the groove 4. The attachment of the detonating cord, which can also have a smaller diameter than the maximum permissible cord thickness, is held in the groove 4 in the exemplary embodiment shown in FIG. 10 in that a self-adhesive adhesive tape 28 is applied to the contact surface 3 on both sides of the groove 4 is provided on its outer surface with a removable protective cover 29 made of paper or the like. The adhesive strips applied to both sides of the groove 4 are now dimensioned in width so that they cover the groove 4 from both sides and only leave a narrow slot above the groove 4. The slot allows a thin detonating cord to be inserted into the groove 4, which is then held in the groove by the edges of the adhesive strip 28 covering the groove 4. Correspondingly thicker detonating cords can, as in the embodiment according to. Fig. 9 are pressed into the groove 4 so that they are held there positively.

11 shows an embodiment in which a closure piece 20 corresponding to the design shown in FIG. 6 is firmly connected to a hollow profile 1 by gluing or welding. The hollow profile 1 is tightly closed at its other end, for example by a corresponding closure piece and filled with an insulating material, for example water. Explosives, for example an explosive cord 5, the free end 30 of which is fixed in the bore 25, are introduced into the groove-like depression.

On the side of the closure piece 20 facing away from the hollow profile 1, a detonator capsule 31, the ignition wire ends 32 of which are attached to the inside of the web 22, is arranged in the corresponding groove-like depression in the web. On the inside of the web 22, the free end 33 of an ignition wire coil 34 is also fastened and connected to the ignition wire ends 32 of the detonator capsule 31.

In the example shown here, the ignition wire winding 34 is fastened on a winding mandrel 35 inside an extension 36, which has a cross-sectional profile corresponding to the web 22 and can be pushed onto this. The ignition wire coil 34 is wound here in such a way that the ignition wire 33 can be pulled off the explosive tool in the direction of arrow 37 from the winding mandrel 35 when the extension 36 is pulled off, so that the operator can remove himself from the explosive site after attaching the explosive tool. Instead of an internal winding mandrel, the ignition wire winding 34 can also be applied to the outside of the extension 36, preferably at the end facing the closure piece 20. The other end of the extension 36 is expediently provided with a handle or finger grip or a grip loop (not shown here).

dessen Schaltgriff 39 durch eine Ausnehmung 4o in der Wandung der Verlängerung 36 mit dem Finger

Die Zuordnung des Schaltergriffes 39 zur

40 ist hierbei so vorgesehen, daß bei aufge-

Zustand der Schaltergriff 39 durch den entspre-

des Stages 22 abgedeckt ist, so daß der

39 erst freigegeben wird, wenn die Verlängerung 36 vom Sprengwerkzeug abgezogen wird. Der Zünddrahtwickel 34. der entweder aus einem zweiadrigen Draht oder durch zwei parallel laufende Drähte gebildet wird, ist mit seinem in der Verlängerung 36 liegenden Ende an den Zündschalter 38 angeschlossen, der Zündschalter 38 ist ferner mit zwei außenliegenden Kontakten 41 für eine Zündbatterie 42 versehen. Für die Zündbatterie 42 ist zweckmäßigerweise im Innenraum der Verlängerung 36 eine hier nicht näher dargestellte Halterung vorgesehen, die es erlaubt, die Zündbatterie zum Scharfmachen des Sprengwerkzeuges erst im Einsatzfall durch eine Öffnung 43 in der Rückwand 44 der Verlängerung 36 einzuschieben. Federnde Rasten oder dgl., die auch aus Kunststoff in die Halterung eingeformt sein können, sorgen in üblicher Weise dafür, daß die Zündbatterie 42 kontaktsicher gegen die Anschlußkontakte 41 des Zündschalters 38 angedrückt wird.In the interior of the extension 36, an ignition switch is also

whose switching handle 39 through a recess 4o in the wall of the extension 36 with the finger

The assignment of the switch handle 39 to

40 is provided here so that when the

State of the switch handle 39 by the corresponding

of stage 22 is covered, so that the

39 is only released when the extension 36 is removed from the blasting tool. The ignition wire coil 34, which is formed either from a two-wire wire or from two parallel wires, is connected to the ignition switch 38 with its end located in the extension 36, and the ignition switch 38 is also provided with two external contacts 41 for an ignition battery 42. For the ignition battery 42, a holder, not shown here, is expediently provided in the interior of the extension 36, which allows the ignition battery to be activated to arm the explosive tool only when it is in use through an opening 43 in the rear wall 44 of the extension 36. Resilient catches or the like, which can also be molded into the holder from plastic, ensure in a conventional manner that the ignition battery 42 is pressed securely against the connection contacts 41 of the ignition switch 38.

die Öffnung vergrößernde Wirkung haben.To blow up a wall breakthrough, especially in emergencies, in which it is rarely possible to determine the thickness of the wall to be blasted with sufficient certainty, it is particularly expedient if the strip-shaped insulation bodies are assembled in an X-shape. This has the advantage over a blasting tool assembled in the form of a frame that, in the area of the crossing point, the damper body has a higher amount of explosive available relative to the area covered by the blasting tool. When igniting, the main effect that opens the masonry therefore occurs in the intersection area, while the amounts of explosives to the end area the dam body towards one.

the opening enlarging effect.

Ausnehmung aufweist, die in die nutenar-

angeschlossenen Verdämmungskörper

und die mit der zentralen Bohrung in Verbin-

Dies ermöglicht es bei der Verwendung von

Sprengschnüre in das Sprengwerkzeug

bogenförmig in zwei Stücken einzulegen, wobei die beiden Schnurstücke sich im Bereich der Ausmündung der

für den Zünder berühren.The strip-shaped insulation bodies can be attached to the wall from individual pieces in X or cross shape. However, it is particularly expedient if an X-shaped connecting piece is provided, on the free ends of which the strip-shaped insulating bodies are fastened. This results in a much simpler handling, especially for emergencies, and here too the X-shaped arrangement has the advantage that the blasting tool can be held at the point of intersection with one hand and attached to the blasting point while, for example, the explosive wire is retightened or but the ignitor can be kept on standby. It is particularly expedient here if the respective transition region between the free ends of the X-shaped connecting piece and the insulation body connected therewith is designed to be slightly flexible in the plane of the contact surface of the explosive tool, so that unevenness of the masonry is easily compensated for when the explosive tool is attached, and so one perfect adhesion between masonry and the pressure sensitive adhesive arranged on the contact surface is guaranteed. As a result, not only is the explosive tool securely attached to the wall, but also reliable insulation of the explosive located in the groove-like depression is provided. The X-shaped connecting piece can be designed approximately in the form of the closure piece according to FIG. 6. In this case, however, the through-channels for the liquid damper can be dispensed with, which is particularly advantageous if the individual arms of the blasting tool are flexible with the connection perpendicular to the plane of the contact surface.

Has recess that in the groove

connected insulation body

and connected to the central hole

This makes it possible when using

Detonating cords in the detonating tool

to be arched in two pieces, the two pieces of cord being in the area of the mouth of the

touch for the detonator.

Claims (26)

1. Blasting tool for precision blasting, characterized by a damming body (1) with a contact surface (3) and at least one open recess (4) lying in the contact surface (3) and at least partially delimited by this for receiving explosives (5) . 2. explosive tool according to claim 1, characterized in that the dam member (1) is formed by an elongated strip. 3. explosive tool according to claim 2, characterized in that the recess (4) is designed as a groove. 4. explosive tool according to claims 1 to 3, characterized in that fastening means are arranged in the region of the contact surfaces (3).

9. explosive tool according to claim 7, characterized in that the holding means (6) is formed by an adhesive layer which is arranged at least in zones in the recess (4). 10. explosive tool according to one of claims 1 to 9, characterized in that the damper body (1) is thin-walled hollow and is filled with a damper. 11. explosive tool according to claim 10, characterized in that the insulating material is a non-flammable liquid. 12. explosive tool according to claim 11, characterized in that the liquid has a freezing point below the freezing point. 13. explosive tool according to one of claims 1 to 10, characterized in that the insulating material is formed by a finely divided solid. 14. explosive tool according to one of claims 1 to 13, characterized in that the finely divided solid is bound by a liquid. 15. Explosive tool according to one of claims 1 to 14, characterized in that the recess (4) has a cross-section which widens into the damper body (8). 16. explosive tool according to one of claims 1 to 14, characterized in that the recess (4 ') is conical, the conical tip (15) pointing into the damper and that the explosive in a conventional manner from a molded body (16) exists, which is designed as a hollow cone. 17. explosive tool for detonating rod-shaped objects, in particular steel cables according to claims 1 to 15, characterized in that the contact surfaces (3 ') are formed by a slot-like recess, that the recess (4) containing the explosives in the bottom region of the slot in this opens out and that the recess (4) widens from a mouth (11) enclosed on all sides by the damper body into the damper body. 18. Explosive tool according to one of claims 1 to 17, characterized in that the damper body is provided with an ignition channel (12) leading outwards from the depression (4). 19. explosive tool according to claim 18, characterized in

(12) opens into the recess in the area of the mouth (11). 20. explosive tool according to claims 1 to 19, characterized in
that at least one end of the damper body (1) has a closure piece (20) which is provided with at least one closable filler opening (24) for the damper sooff and which is connected to the groove-like recess (4) in relation to the interior of the Isolation body (1) has closed, preferably transverse to the body axis bore (2.5). 21. Explosive tool according to claim 2 ₀ , characterized in that the closure piece (20) in its edge region has a recess aligned with the groove-like recess (4) of the damper body (1). 22. Explosive tool according to one of claims 20 to 21, characterized in that an axially removable, hollow extension (36) is arranged on the closure piece (20) of one end of the damper body, which is provided with a removable ignition wire coil (34) which with a End is connected to a detonator (31) fastened in the groove-like recess (4) of the closure piece (20), and that an ignition switch (38) and an insertable ignition battery (42) are arranged in the interior of the extension (36). 23. Explosive tool according to claim 22, characterized in that the ignition switch (38) in the interior of the extension (36) is arranged such that it is accessible only through an opening (40) which becomes free after the extension (36) has been pulled off. 24 explosive tool according to claim 22 or 23, characterized in that the ignition wire coil (34) is arranged on part of the outer surface of the extension (36). 25. Blasting tool according to one of claims 22 or 23, characterized in that the ignition wire winding (34) is held on a preferably conical winding mandrel (35) arranged in the pull-out direction of the extension in the interior. 26. Explosive tool according to one of claims 2,2 to 25, characterized in that a releasable release agent is arranged between the ignition wire winding (34) and the outer surface of the winding support (outer surface of the extension or outer surface of the winding mandrel). 27. explosive tool according to claims 1 to 26, thereby; indicates that the strip-shaped insulation bodies are composed of an X-shape. 28. Explosive tool according to claim 27, characterized by an X-shaped connecting piece, strip-shaped insulating bodies are fastened to the free ends. 29) explosive tool according to claim 28, characterized in that the connecting piece has a central bore for receiving a detonator and on the side of the contact surface has a recess which opens into the groove-like depression of the connected damper and which is connected to the central bore.

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