DE3843884A1 - Device for annular detonation of a shaped charge - Google Patents

Abstract

A disturbance in the annular detonation of a main charge (2) from the underneath is avoided according to the invention by coating an inert body (8), which is known as a barrier, only partially with a relatively small amount of explosive, preferably an explosive film. The form and stability of the inert body (8) can be designed exclusively such that it is the best for the shape of the explosive coating (7). This also results in a considerable simplification in production. Using such an inert body, in addition, the influence of various parameters on the detonation behaviour of a shaped charge can be investigated systematically. <IMAGE>

Description

The invention is directed to a shaped charge, one axially orderly detonator, a rotationally symmetrical, as thin as possible Transfer charge in connection with an inert body as De tonation wave guide and a rotationally symmetrical main la showing manure.

It is known that the ignition of the rotationally symmetrical Main charge of a shaped charge as evenly as possible ring-like from the outside on the side of the main charge facing the igniter, which is also called the bottom of the main cargo in the following, must be done.

The ring-like ignition is achieved with a rotation symmetry trical transfer charge, in which an igniter is used axially is. Often the transfer charge has an approximate shape a truncated cone or a spherical section. The two between the igniter and main charge is formed by a Inert body, the so-called barrier, filled. The inert body causes detonation wave guidance from the detonator to the desired ignition area of the main charge, and it should avoid that direct detonation waves from the detonator to the middle Hit the area of the main charge and ignite there too early trigger. DE-A 34 48 865 describes that a de Toning wave-guiding and damping barrier also as an evacu ized, for example cylindrical hollow body can be.

The previously observed fluctuations in Hohl's performance charges are usually explained by the fact that the rotation sym metry of the transition area from the transfer charge to the main cargo is not sufficiently perfectly formed.

This difficulty has been tried in various ways to meet. The transfer charge often consists of the  same explosive as the main charge and will be like this formed by pressing or casting. This alone is over For reasons of strength, a wall thickness of several millimeters conducive.

It has also been pointed out that one is too thick Transfer charge (US-A 31 00 445, DE-A 19 48 058) the bar between detonator and main charge function as detona tional wave guide can not meet and the middle range of Main charge is ignited too early. Known to the which embodiments are the results in terms Performance uniformity unsatisfactory.

Gluing a preformed, thin-walled, detonating shaped body on an inert body still has the after part that Luftbla between the molded body and the inert body sen can be included, which in turn is the uniform Can detonation adversely affect. It can even do so a lead of swaths occur, the unwanted ignitions cause.

The invention has for its object the above parts to eliminate, so that fluctuations in performance at Hohlladun gene can be avoided.

The object is achieved in that instead of the transmission charge a rotation sym based on the inert body Metric explosives coverage is provided and only a part area of the upper inert body not facing the main charge surface is covered with explosives.

With this concept one has freed oneself from the idea that the inert body must form a barrier, i.e. that it is his The task is to form the igniter directly to the main charge To dampen ignition impulses. By reducing the explosives quantity for the ignition impulse transmission you gain a high degree freedom of design for the inert body, because it is only as Carrier or support body must serve. The lower explosives  quantity reduces loads and damage to the inert body pers. In particular, there are also manufacturing technology Advantages. Gluing the barrier to the main and over Carrying charge is no longer required.

The inert body preferably has a cylinder-like (straight Circular cylinder) or truncated cone-like shape, taking the side facing away from the detonator, in the following also the bottom side is called, with the bottom of the main cargo in Kon is tact. The axes of the inert body and the rotational symmetry trical shaped charge collapse. It has been shown that it is particularly favorable if at least the area around the Igniter arranged on the inert body with rotationally symmetrical explosive strip. You can use the Cylinder or cone surface up to the bottom line of the Inert body and then there direct contact with the Un side of the main cargo. But it is also straightforward possible to split the explosives assignment and / or under to train differently. The cylindrical surface of the inert body can be completely covered with explosives (at for example in the form of a slipped hose).

However, it has been shown that the transitional area of the transfer charge on the main charge is not necessarily as a continuous charge ring surface must be formed. On the bottom the explosive ring can be on the side facing the main charge the bottom of the inert body also in or out be interrupted several times in a rotationally symmetrical manner.

A very special advantage with the Ausge invention staltung a shaped charge is that it is inexpensive Have test series carried out, for example, the on flow of the position of the annular ignition point on the underside the main charge to examine the effect of the shaped charge. The inert body is easy to manufacture and can easily be changed be changed. This means that test series can be carried out for the first time lead where the location is the width, the slope, the thickness the occupancy and also the type of explosives on the effect  the shaped charge can be changed systematically. Leave it thus the previously difficult to change transfer charges test for yourself in every detail.

In the inventive device for ring-like lighting you let yourself be guided by a shaped charge, as little as possible Explosives for the transfer charge and the smallest possible Chen detonator to use. The amount of explosives is in the case of foils for example less than a tenth of that for a ge pressed transfer charge required amount.

Since the inert body is only designed for this purpose must be reali such a thin explosive coverage different usable designs are possible. No ben the preferred assignment of the inert body with a detonation The explosive covering can also be painted on printed or glued or directly by a chemi cal reaction on the surface of the inert body produced the. In terms of process technology, it is particularly advantageous if the Explosives are occupied by extrusion. The inert body is in a corresponding form on its bottom side connected the extruder; by an appropriately designed The surface of the inert body (or the counterform) can Partial areas of the coating on the main charge facing inert body surface from an occupancy will. In addition, the smallest possible fuse should always be are used with which the explosive assignment is ignited can still be done sufficiently safely.

So far, the uniformity and symmetry of the verbin transfer charge with the main charge very large Added value. Main and transfer charges were usually glued to the barrier. The goodness of such a connection was hardly controllable. It seems that minor So far asymmetries have been given too much importance has been. If it comes to the described ring-shaped lighting of the Main charge comes without the in an uncontrolled manner Main load already in the middle area on the bottom or  performance is even fluctuated off-center hardly any longer with shaped charges. It is even by the edge sharp ignition initiation observed an increase in performance. A check of the rotational symmetry to the shaped charge is ever currently possible.

Another advantage of the device according to the invention is to be seen in that the inert body covered with explosives easily supported and protected from the outside can, by placing a case over the explosives, more common made of plastic or light metal. A Flow or compression or detachment of the explosive coating even at high accelerations, it can be used in a simple manner be avoided without reducing reliability.

Further stabilization is achieved when the inner, the Explosion assignment facing side of the housing - in particular those in the area parallel to the axis - corrugated, compressed or ge is shaped.

As an explosive for the partial covering of the inert body explosives and explosive mixtures are particularly suitable, which have a detonation speed of at least 2000 m / s, preferably over 6000 m / s, e.g. Tetryl, nitropenta Lead and silver azide, the explosive heavy metal salts from Trinitrophenols and those described in DE-C 28 06 599 Metal salts of mono- or dinitrodihydroxidiazobenzenes. Also Polynitropolyphenylenes are suitable.

A thin layer of explosives on the inert body can also done by forming a detonation transferring coating from a detonatable metal salt necessary reaction on the surface of the inert body ablau leaves. One of the reaction components can react to the Surface of the inert body by means of a method known per se applied and then with a second reak tion component to form the desired metal salt Implementation. The first reaction component or  their preliminary product can be vapor-deposited on the surface or on be galvanized. The surface is then covered by Be act with an acid or halogens while doing the top or all of the metal layer in a reactive salt transferred. The metal activated in this way is on it with an alkali azide solution or gaseous nitrogen Hydrogen acid converted to the desired heavy metal azide. Heavy metal picrate covers can be produced in a similar way the. A reaction component can also disper in a paint be greedy. This layer is then covered with a protection layer, which can consist of wax or lacquer and At the same time, the explosives are phlegmatized.

The invention is shown in the drawing and in the following further described by way of example. Show it:

Fig. 1 section through a shaped charge with a cylinder-like inert body;

Fig. 2 is means for lighting a ring-like shaped charge having a frusto-like inert solids;

Fig. 3 variants of the handling of an explosive foil for covering the jacket area of a cylinder-like inert body ,;

Fig. 4 variants of the assignment of an annular area on the bottom surface of an inert body in cross section;

Fig. 5 partial section through a cylinder-like inert body with toothed explosives.

A shaped charge consists according to FIG. 1 of a cylindrical housing 1 , with a rotationally symmetrical main charge 2 , de ren cone is lined with a metal layer 3 , from which a spike or a projectile is formed in a known manner. The ignition of the main charge 2 is based on an axially arranged igniter 4 . The transmission of the ignition pulse to a ring-like area 5 on the underside of the main charge 2 takes place via an explosive foil 7 , which is attached to an inert body by 8 , here a one-sided closed cylindrical injection molding. To protect the explosive assignment 7 , it is covered with a thin plastic housing 12 . It is not absolutely necessary for the rotationally symmetrical inert body 8 to be solid. A direct ignition to the main charge 2 , that is, an early ignition of the central region 10 of the main charge 2 is avoided in that the explosive coating 7 , in particular in the area around the detonator 4 , is not oversized and only partially covers the inert body. On the side facing away from the main charge 2 11 of the Inertkörpers 8 Sprengstoffolie 7 is strip-shaped be applied, the cylindrical casing region of the Inertkör whereas pers 8 here with an explosive hose is completely covered. In the case of a multi-piece explosive assignment 7 , the transition areas must of course be given special attention. However, it has been shown that a very uniform ring-shaped lighting is also possible in this way. The person skilled in the art will of course also note that, for example, all explosive strips are cut from a film in the same way in order not to introduce any differences in the system caused by a possible rolling texture. The cavity 9 of the inert body 8 is not required to dampen the detonation waves, but only serves to save weight. One can easily see from the basic drawing how unproblematic the manufacture and installation of this device for ring-shaped ignition of the main charge 2 are. Experiments show that a perfect, uniform ring-shaped ignition of the main charge is possible without premature ignitions occurring in the central region 10 .

Another form of a rotationally symmetrical inert body 8 is shown in FIG. 2. The explosive coating 7 äh nelt more of the known pressed transfer charge, where here again only a portion of the inert body is covered with explosive strips. In the area 13 around the detonator (not shown), the explosive film 7 is star-shaped, strip-shaped and sufficiently thin. This inert body 8 can also be produced inexpensively as an injection molded part.

In these examples, the inert body is covered with an explosive foil which is characterized by the following property values: It consists of 75% by weight of pentaerythritol tetranitrate with 25% by weight of binder and plasticizer; the density is 1.5 g / cm ³ ; the film can be up to about 3 mm thick; it can be bent through 180 ° without tearing; it is adhesive at temperatures from -10 ° to 50 ° and can be cut into any dimension with a cutting tool and also processed plastically; it can be ignited safely with a test igniter PETN 0.25 g; the detonation speed is 7000 m / s. It has been shown that even with a 1.5 mm thick film, a uniform ing-like ignition of the shaped charge takes place.

Variants of covering the inert body with explosive foil are shown in FIG. 3. They show the processing of the cut foil. The partial picture a shows a one-piece basic shape with four strip-shaped tracks 14 , which are guided on the side of the bottom surface of the inert body facing away from the main charge to the centrally attached detonator, and a continuous, annular region 15 , which covers the wall area of the cylindrical inert body, and where the edge 16 directly forms the annular ignition area of the shaped charge.

However, it has also been shown that a continuous ring area on the inert body is not required to ignite the main charge, but point-by-point ignition can be sufficient as long as these points are rotationally symmetrical and the ignition pulse is transmitted evenly. The ring-like punctiform ignition of the hollow charge can preferably with explosives strip 17 according to the sub-picture b implement 3, which strips are disposed rotationally symmetrically from the igniter to the inert solids to the main charge.

Another possible variant is shown in drawing c . Here he follows due to the increasing width of a triangle-like explosive assignment, a steady transition from the punctiform detonator via two transmission paths to the ring-like introduction into the main charge.

The partial images d to h according to FIG. 4 show the cross-section of the assignment for the annular region in the bottom side of the inert body. This makes it clear that when determining the explosive occupancy only the size, shape and location of the ignition points must be observed without having to take other conditions such as component strength into account, making optimization much easier.

An increase in the reliability of highly accelerated Hohlladun conditions is achieved if the explosives 7 ( Fig. 5) is supported by a profile 18 on the inside of a divisible plastic housing 12 . As a result, compression or displacement of the film 7 in the axial direction is easily prevented. A similar effect can of course also be achieved if the cylindrical surface of the inert body 8 is profiled accordingly.

Claims (12)

1. Hollow charge an axially arranged detonator ( 4 ), a ro tationssymmetrische, as thin as possible transfer charge in conjunction with an inert body ( 9 ) lenlenker as Detonationswel and a rotationally symmetrical main charge ( 2 ), characterized in that instead of the transfer charge on the Inert body ( 8 ) supporting rotationally symmetrical explosive covering ( 7 ) is provided and only a partial area of the inert body surface not facing the main loading ( 2 ) is covered with explosive ( 7 ). 2. Hollow charge according to claim 1, characterized in that the explosive covering is an explosive foil ( 7 ). 3. Hollow charge according to claim 1 or 2, characterized in that the explosive coating on the inert body ( 8 ) is painted on, printed on or brought on by extrusion, or is generated by a chemical reaction. 4. shaped charge according to claim 1, 2 or 3, characterized in that the inert body ( 8 ) is an injection molded cylinder or truncated cone-like part, preferably made of plastic or light metal. 5. shaped charge according to one of claims 1 to 4, characterized in that at least the area around the detonator ( 4 ) on the inert body ( 7 ) with strips ( 14 , 17 ) of explosive material is occupied. 6. shaped charge according to one of claims 1 to 5, characterized in that the explosive assignment ( 15 ) on the Zy cylinder or truncated cone surface forms a substantially closed surface. 7. Hollow charge according to one of claims 1 to 5, characterized in that the explosive assignment on the Zy cylinder or truncated cone surface area, preferably strip-shaped ( 17 ), is divided. 8. shaped charge according to one of claims 1 to 7, characterized in that on the main charge ( 2 ) facing side of the inert body ( 8 ) a continuous explosive ring ( 5 , 16 ) is attached. 9. shaped charge according to one of claims 1 to 7, characterized in that on the shaped charge ( 2 ) facing side of the inert body ( 8 ) a circumferentially one or more times rotationally symmetrically interrupted explosive ring is applied. 10. shaped charge according to one of claims 1 to 9, characterized ge indicates that the surface covered with explosives of the inert body - especially in the axially parallel area - is curled, compressed or embossed. 11. Hollow charge according to one of claims 1 to 10, characterized in that the explosive coating ( 7 ) on the inert body ( 8 ) with a preferably plastic or light metal injection molded housing ( 12 ) is surrounded. 12. Hollow charge according to claim 11, characterized in that the inner surface of the housing ( 12 ) - in particular in the axially parallel area - is corrugated, compressed or embossed.