FI20215629A1 - Blasting cap and method for installation of a blasting cap in connection with an explosive - Google Patents

Abstract

The present invention relates to a detonator holder (1) and a method, where this detonator holder is used for installing the detonator (7). Said detonator comprises a truncated conformal piece with a cap (3) and a bottom (4) which are opposite and essentially parallel. The piece is pierced in the direction of its entire longitudinal axis (5) by a channel (6) to receive the detonator (8). The piece has at least one wedge-shaped slot (15) from the lid towards the bottom. When the piece is pressed into the cavity (10) in connection with the hard shell explosive, an outer jacket (2) is created and cooperates with the inner wall (17) of the cavity, which leads to the channel (6) being unfastened towards the longitudinal axis (5). The channel thus reduced to its diameter (D) is pressed against the outer surface (20) of the explosive cap (8) which has been guided into the channel.

Description

BADDLE HOLDER AND METHOD FOR INSTALLING A BALLET TO AN EXPLOSIVE CONNECTION Background of the invention The present invention relates to a ball holder according to the preamble of claim 1, with which the ball is especially attached to a plastic or metal hard-shell explosive. The subject of the invention is also a method according to the preamble of patent claim 11 for installing a teddy bear in an explosive. The purpose of the teddy bear holder and the method that utilizes it is to form a waterproof structure that protects the explosive, prevents the teddy bear from moving due to external forces, and centers the teddy bear on the explosive so that the detonating force of the teddy bears on the explosive.

The explosives designed to be safe are so insensitive that you always need a teddy bear to detonate them. Most commonly, the teddy bear is pressed into its explosive mass or into an empty hole built for it. However, the teddy bear staying in place in such a conventional installation method is uncertain due to the vibration or movement applied to it during installation. As a result, an air gap easily forms between the teddy bear and the explosive. When the teddy moves in a borehole containing water, water gets under the bottom of the teddy, which can result in the explosive's complete inactivity or partial lack of power.

Today, the explosive often consists of a viscous mass into which a teddy bear is planted. When the explosive mass is cold, it is difficult to put the teddy bear in place, and the cold stiff mass does not necessarily form a proper adhesion, so the teddy bear can move or even come off. A similar problem arises with warm explosive mass, in which the teddy bear is easy to place, but the viscosity of which decreases when warm, and may no longer stick to the teddy bear properly, in which case the teddy bear may move or even detach. When attached to the mass, the teddy bear can also be oriented at an angle, which can be a consequence of the transverse pull of the impulse hose or electric wires connected to the teddy bear. In that <Q case, the worst result may be the complete inoperability of the explosive.

E 30 The charge, i.e. the teddy bear and the explosive, can also have to be disassembled for some reason. Mechanical teddy bear locking mechanisms can have such a weakness that once the O teddy bear is fixed in place, it is impossible or difficult to remove it without N tools. Using force to remove the teddy bear is always a safety risk.

N Attempts have been made to correct the present problems, for example, in the manner shown in patents EP 3 612 786, US 6 112 666 and US 9 115963 by locking the teddy bear with mechanical claws. However, exact grip on the bottom of the teddy bear nest is only achieved with teddy bears of a certain length, even though, for example, teddy bears containing different retarders can be of different lengths. The structures presented in the patents are also not waterproof.

The worst consequence of the problems described above, for example in the mining industry, is that the blasting of a borehole full of explosives fails partially or completely. As a result of failure, the download must be unloaded, for example mechanically. Regardless of the demolition method, this kind of work always poses a huge safety risk to the construction site.

Brief description of the invention The goal of the invention is to create a teddy bear holder with which the problems mentioned above can be largely avoided.

This goal is achieved in such a way that the teddy bear holder and the method for installing the teddy bear have the characteristics defined in the patent claims according to this invention. To be more precise, the main characteristic of this pacifier holder according to the invention is what is presented in the distinguishing part of patent claim 1. In turn, the method according to the invention for installing a teddy bear is mainly characterized by what is presented in the characterizing part of claim 1. Advantageous embodiments of the invention are the subject of non-independent patent claims.

The invention is based on the fact that the teddy bear holder must fit firmly in place, while at the same time centering the teddy bear watertightly in the surrounding cavity when exploding.

With the help of the invention, considerable advantages are achieved. Therefore, the design of the teddy bear holder is very simple and it can be made of polymer at a low cost, for example by injection molding or 3D printing as mass production.

S The invention makes it possible to attach the teddy bear to the liquid in a simple way. Attaching a teddy bear to, for example, a powdery explosive mass is E 30 otherwise almost impossible without aids that require additional work, such as, for example, attaching the teddy bear to the explosive by taping, etc.

O Thanks to its flexible structure, the teddy bear holder according to the invention stays N in place regardless of vibration, pull or other external force, even if the load is many times compared to the weight of the product. Despite this, the teddy bear holder or the teddy bear holder with the teddy bears arranged in it can be removed and reattached safely without special tools.

The presented teddy bear holder also forms a waterproof plug in the explosive cavity when placed in place, both without a teddy bear and with a teddy bear arranged in it.

The presented teddy bear holder also always centers the teddy bear arranged in it so that the detonating force of the teddy bear is aimed at the explosive and not, for example, towards the protective shell in the explosive.

Other advantages brought by the invention are presented below, when specific embodiments of the invention are described in more detail. Brief description of the drawings In the following, some advantageous embodiments of the invention are explained in more detail by referring to the accompanying drawing, where Figure 1 shows a schematic axonometric image of the teddy bear holder viewed obliquely from the back, Figure 2 shows a longitudinal section of the teddy bear holder according to Figure 1 from point A-A installed in the explosive, Figure 3 shows another advantageous view of the teddy bear holder schematic axonometric view of the embodiment shown obliquely from the back, figure 4 shows a longitudinal section of the ball holder according to figure 3 from point B-B installed in the explosive, figure 5 shows the ball holder according to figure 3 looking towards the cover, figure 6 shows the ball holder according to figure 3 from the side facing the cap sotto, N figure 7 shows a side view of a third embodiment of the pacifier holder, S figure 8 shows the use of the pacifier holder according to figure 3 when installing the pacifier N, viewed from the side and the explosive partially cut open una, E 30 in Fig. 9 shows the installation according to Fig. 6 completed, and o Fig. 10 shows a detail C according to Fig. 9 of the operation of the pacifier holder O with the pacifier locked in place. O Detailed description of the preferred embodiments In the present drawings, the teddy bear holder is not shown to scale, but the figures are schematic, expressing the principle of the preferred embodiments.

list structure and function. In this case, the structural parts indicated with reference numbers in the attached figures correspond to the structural parts marked with reference numbers in this explanation. It is very important that the teddy bear used in blasting work is placed in the connection with the explosive, because the most commonly used explosives are rather insensitive and require direct contact of the teddy bear with the explosive or a very small air gap between the teddy bear and the explosive to work. If water gets into the air gap between the teddy bear and the explosive, the worst possible consequence is that, for example, the detonation of a borehole full of explosives will fail. In general, a completely or partially non-functioning product in blasting poses an immediate safety risk, and just finding out the cause can be time-consuming and bring considerable costs. It is therefore important that the teddy bear can be reliably locked in place in connection with the explosive.

Figures 1 and 2 thus show a first advantageous embodiment of the teddy bear holder 1, which in this case comprises an outer shell 2 — an essentially rotationally symmetrical, preferably circular cylinder-shaped, piece with opposite and essentially parallel cover 3 and base 4. Of course, the teddy bear holder can comprise any a truncated cone-shaped body, in which case it has a cross-sectional shape that is polygonal, for example square or triangular, or oval.

The teddy bear holder 1 is essentially pierced by the channel 6 in the direction of its entire longitudinal axis 5, however, in such a way that the base 4 is provided with a thin, easily permeable protective film 7 that closes the cylindrical channel. Preferably, this permeability is implemented in such a way that the film has one or more thinning to ease the passage of the pacifier 8 installed in the pacifier holder.

Figure 2 shows the installation of the lollipop holder in the cavity 10 in the explosive 9, whereby it cooperates in this case with the conical mouth opening of the cavity. For this purpose, the outer shell 2 N of the teddy bear holder extends essentially over the entire cross-section of the cavity, both in terms of the cross-sectional shape of the bear holder 2 and its outer diameter, which can be 10 mm up to N 30 50 mm. E In Figures 3-7, in turn, another advantageous o embodiment of the teddy bear holder 1 is shown, which also comprises a substantially rotationally asymmetrical, preferably circular cylinder-shaped body with an opposite and substantially parallel cover 3 and base 4 on the outer shell 2. The teddy bear holder is in the manner described above in N 35, in the direction of its longitudinal axis 5 essentially pierced by a cylindrical channel 6, however, in such a way that a thin cylindrical

an easily permeable protective membrane 7 that closes the male channel. Preferably, the permeability of the membrane is implemented in such a way that the membrane has one or more thinnings to ease the penetration of the pacifier 8 installed in the pacifier holder.

The inner diameter 5 and (D) of the channel 6 of this teddy bear holder according to Figures 3-7 is typically 0.5 mm larger than the diameter of the teddy bear 8 installed in it, and, for example, for the most common teddy bears with a diameter of 7.5 mm in use, the inner diameter as a channel is therefore 8, 0 mm. The diameter of the pacifier holder's channel is also generally standard, but in another embodiment, the pacifier holder's cylindrical channel is adapted to include a compression strip 11 that expands conically towards the cover at its end, compare the area marked with a dashed line in Fig. 4.

The outer shell 2 of the teddy bear holder 1 has at least two consecutive zones in the direction of the longitudinal axis 5. Figure 7 shows the truncated cone part 12 tapering from the cover 3 towards the bottom 4 and the cylinder part 13, which is still related to this and ends at the bottom. The embodiment according to Figure 6 shows a functionally more advantageous embodiment, in which the outer shell 2 is also adapted to the part bordering the bottom 4 to comprise a conically tapering installation part 14, whereby guiding the pacifier holder into place in the cavity 10 of the explosive 9 becomes easier mechanically, for example.

The body formed by the teddy bear holder 1 still has at least one wedge-shaped slit 15 extending from the cover 3 towards the bottom 4 and parallel to the longitudinal axis 5 of the body. There are preferably 2-6 pieces of these slits such that they are arranged essentially symmetrically to the one in the outer shell 2 and surrounding the channel 6 for the circumference 16. An advantageous embodiment is obtained when there are two slits according to the presented figures 1-7 on the opposite sides of the circumference of the outer shell. The slits are preferably dimensioned so that from their widest point N they reach at least from the point 2 of the outer surface on the circumference 16 into the hollow of the ballpoint holder 8, which is pressed closed. In this way, the teddy bear holder, together with the 2 stuffed teddy bears inserted into it, forms a tight plug in the mouth opening of the explosive cavity. In turn, the aim is to extend the length of the slit N 30 — as far as possible towards the bottom 4 in the direction of the longitudinal axis 5. In this way, a teddy bear holder is created, which allows greater tolerances while still being as light as possible to use even with harder O manufacturing materials. It has been found that the suitable length of the gap is 50-95% of the length L of the nal-N lipid. The preferred length is about 85% of the length. N 35 The presented teddy bear holder 1 is therefore intended to be used when installing a known teddy bear 8 in an explosive 9. Such an explosive can be formed, for example,

biscuit pipe charge, so-called used in connection with other explosives a booster or military explosive whose shell is made of hard material. Figures 8 and 9 show an example of a pipe charge/booster. The teddy bear can be a well-known electric teddy bear, an electron teddy bear, an impulse hose teddy bear or a time fire wire teddy bear.

In this case, the purpose of the teddy bear holder 1 is to form a bond with which the teddy bear 8 is reliably and tightly attached to the explosive 9. For this purpose, the material of the teddy bear holder must be such that it is slightly flexible, so that on the one hand it can be more easily guided into the cavity 10 in the explosive and on the other hand this slightly when the teddy bear is pressed into channel 6. The teddy bear holder can be made of, for example, a flexible polymer, elastomer or a flexible composite containing polymer or elastomer. The outer shell 2 of the teddy bear holder can also preferably be equipped with fin-like devices (not shown in the figures) projecting perpendicularly to the longitudinal axis 5, which increase the friction between the outer shell 2 and the inner wall 17 in the cavity 10. Part of the cone and/or cylinder part of the teddy bear holder can also be thinned longitudinally and replaced with fin-like devices to save material, but without compromising tightness.

It is also advantageous to shape the teddy bear holder 1 with a flange 18 protruding directly from the outer shell 2 and connected to the cover 3, such that it prevents the teddy bear holder from sliding completely into the cavity 10.

The present teddy bear holder 1 is thus obtained by forming, for example, by injection molding or 3D printing a piece, into which the opposite and essentially parallel cover 3 and base 4 are shaped.

The teddy bear holder 1 is manufactured in its preferred embodiment according to Figures 3-7 to comprise an essentially rotationally symmetrical circular cylinder shape. The channel 6 of this teddy bear holder is shaped essentially cylindrical with a substantially constant diameter (D) and is equipped with a thin channel-closing membrane 7 in the part that borders the bottom. 2 In this embodiment, at least two consecutive zones are formed in the outer shell 2 N 30 of the object to be manufactured in the direction of the longitudinal axis 5. E The first zone is a truncated cone section 12 tapering from the cover 3 towards the base 4. The second zone is a cylindrical section 13 ending at the bottom. In addition to these, at least one wedge-shaped section extending from the cover towards the bottom and tapering towards the bottom in the direction of the longitudinal axis 6 of the section N is formed in the section O. slit 15 and the flange 18 protruding from the outer casing, which goes around the N 35 cover.

When using the teddy bear holder 1, it is first guided according to the lower part of figure 8 to the cone section 12 on the outer surface 2 and into the cavity 10 connected to the explosive 9. Installation can be made easier by forming a conically tapering installation section 14 bordering the bottom of the outer jacket.

The ball-point holder thus closes the cavity and the membrane 7 closing the channel 6 ensures tightness, whereby the explosive mass 19 in the explosive 9 is invisible and protected from the effects of the environment. The explosive is now ready to be stored and/or transported to its destination. Alternatively, the teddy bear holder can be delivered separately and installed in place only when in use.

At the point of use, the teddy bear 8 is first guided according to figure 8 into the channel 6 of the teddy bear holder 1, whereupon it simultaneously pierces the membrane 7 at the bottom of the channel. The teddy bear can now be pressed into the explosive 9 in its explosive mass 19. When it has been ensured that the teddy bear is in sufficient contact with its explosive mass, the teddy bear holder is pressed into the cavity 10 This is done in such a way that the cone part 12 is compressed towards the longitudinal axis 5, as a result of which the wedge-shaped slits 15 are at least partially closed and also the diameter of the cylinder part 13 of the teddy bear holder is reduced over a long distance. Compare figure 10. In this way, the teddy bear holder is easier to move in the cavity of the explosive 10. When pushing the teddy bear holder into the cavity, the cone section stops the movement depending on the force applied to the holder, however, at the latest, when the teddy bear holder has been pushed into the cavity as far as its flange 18. At the same time, the wedge-shaped slits 15 of the teddy bear holder at the mouth opening in the cavity are mostly closed and the attachment forms a tight waterproof entity. In the installation method described above, as a result of the cooperation of the cone section 12 obtained during compression and the inner wall 17 in the cavity 10, the teddy bear holder 1 locks into the cavity and the channel 6 piercing the body reaches towards the longitudinal axis 5 of the body. lin 8 against outer surface 20. The teddy bear holder ensures tightness and keeps the teddy bear in place 2 while also ensuring that a possible lateral pull on the impulse coil N 30 or electrical conductors 21 leaving the teddy bear does not move the teddy bear too much.

o The cone part 12 is preferably dimensioned so that when the teddy bear holder 1 is pressed into the cavity 10, the wedge-shaped slits 15 are still slightly N open from their end on the cover 3 side. Thanks to such dimensioning, it is possible to safely remove the teddy bear holder inserted into the cavity N 35, because the end of the teddy bear holder protruding from the cavity is still pressed together, so that the teddy bear

The tight grip formed by the dike with the cavity becomes lighter and the teddy bear with the teddy bear holder can be removed. Detaching can be further facilitated by forming a cylindrical channel 6 of the teddy bear holder at its end of the cover to expand conically towards the cover for the transmission of the compression strip 11. Such a compression strip creates a small room for movement at the outer end of the teddy bear holder, which makes it easier to press the end of the teddy bear holder together, in order to lighten the pressure on the teddy bear.

The operation of the teddy bear holder 1 was tested in practice using the embodiment of the teddy bear holder according to figure 3, to which a purpose-made measuring stick of the size of a teddy bear (7.6 mm) in diameter was adapted. A Sauter FK50 force meter was used in the measurements. The tests were performed at room temperature.

The comparison subjects were two previously known explosive tubes of different manufacturers.

In the first comparison site, five pieces of explosive tubes were selected, which contained visible plastic explosives. These had a hole made in the explosive almost to the bottom of the detonator tube to attach the teddy bear. In the experiment, a measuring stick simulating a teddy bear was pressed into place in a hole in the explosive, after which it was pulled out with the force meter connected and — the necessary pulling resistance was measured. The tensile strength was 11 N on average.

In the second comparison site, five pieces of detonator tubes were chosen in the same way, whose explosive was protected by a permeable plastic end plug. In the experiment, a measuring stick simulating a teddy bear was pushed into the explosive, after which it was pulled out with the force meter connected and the necessary pulling resistance was measured.

The tensile strength was 5 N on average.

Five pieces of plastic pipe with a diameter of 15 mm and a length of 150 N mm were used when testing the present embodiment of the teddy bear holder 1 according to Figure 1. In the experiment, the measuring stick simulating a teddy bear was fixed in place with the present teddy bear holder 2. After that, the N 30 measuring stick connected to the force meter was pulled from the pipe. The pull was continued until the measuring stick E came off the ball holder or the ball holder came off the tube. The obtained measurement reading o simulates the force needed to dislodge the teddy bear. Before detachment, the tensile strength was 43 N on average.

N It could therefore be stated that, using the present solution, N 35 times the pulling force is required to detach the pacifier from the detonator tube compared to the available state of the art.

The function of the presented teddy bear holder 1 was also tested for its water tightness. The test was performed indirectly by filling the detonator tube with table salt (NaCl). After that, the impulse hose ball, which is known per se, was attached to the detonator tube with the shown ball holder according to Figure 1. The detonator tube with teddy bears was immersed in tap water to a depth of 200 mm and its instantaneous electrical conductivity was measured. The detonator tube with teddy bears was left in the water, after which the electrical conductivity measurement was repeated a week later. The electrical conductivity was 10 mS/m in the first measurement, and the measurement result did not change in the comparison measurement performed 7 days later. It could therefore be concluded that nothing — salt had dissolved from the explosive tube, which would have increased the conductivity of electricity. The joint formed by the teddy bear holder had remained waterproof.

It is obvious to a professional in the field that as technology develops, the basic idea of the invention can be implemented in many different ways. The invention and its embodiments are therefore not limited to the examples described above, but may vary within the scope of the patent requirements.

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Claims (16)

Patent Claims 1. Teddy bear holder (1), characterized by the fact that the teddy bear holder comprises a truncated cone-shaped body with an outer shell (2), with an opposite and essentially parallel cover (3) and base (4), which body is substantially cylindrical in the direction of its entire longitudinal axis (5) shaped channel (6) and that the piece has a wedge-shaped crack (15) extending from one to six covers (3) towards the bottom (4) and parallel to the longitudinal axis (5) of the piece. 2. The teddy bear holder (1) according to claim 1, characterized in that the teddy bear holder comprises an essentially straight circular cone-shaped body on its outer shell (2). 3. The teddy bear holder (1) according to claim 1, characterized in that the teddy bear holder comprises a rotationally symmetrical body on its outer shell (2), whereby the outer shell (2) of the body comprises at least two consecutive zones in the direction of the longitudinal axis (5), from the cover (3) to the base (4) towards the truncated cone part (12) and the cylinder part (13) that follows it and ends at the bottom. 4. The teddy bear holder (1) according to claim 3, characterized in that the teddy bear holder (1) is pierced by an essentially cylindrical channel (6) along its entire length axis (5) so that the channel (6) has an essentially constant diameter (D) . N 5. The teddy bear holder (1) according to one of the preceding claims, N characterized in that there are two slits (15) on opposite sides of the outer shell (2) circle (16). N E 30 6. Teddy bear holder (1) according to one of the preceding claims, o characterized in that the outer sheath (2) is adapted to taper conically in its part bordering the bottom (4). S N 7. The teddy bear holder (1) according to one of the preceding claims, characterized in that the channel (6) is arranged so that the cover (3) expands conically towards it at its end. 8. Teddy bear holder (1) according to one of the preceding claims, characterized in that a thin membrane (7) closing the channel (6) and easily permeable is provided in the base (3). 9. Teddy bear holder (1) according to one of the preceding claims, characterized in that a flange (18) protrudes from the outer shell (2) in connection with the cover (3). 10. Teddy bear holder (1) according to one of the preceding claims, characterized in that the teddy bear holder (1) is made of flexible polymer, elastomer or flexible composite containing polymer or elastomer. 11. A method for installing a teddy bear (8) in an explosive (9), known for the fact that the method comprises the following steps: a truncated cone-shaped piece with opposite and substantially parallel covers (3) and bases (4) is formed from the outer shell (2), which delineate a channel (6) parallel to the longitudinal axis (5) of the outer shell (2) between them, and a wedge-shaped slit (15) is formed in the outer shell from one to six covers (3) extending towards the bottom (4) and parallel to the longitudinal axis (5) of the piece, whereby when the piece is pressed into the cavity (10) connected to the explosive (9), a cooperation is achieved with the outer jacket (2) and the inner wall (17) in the cavity, as a result of which the channel (6) piercing the piece N stretches towards the longitudinal axis (5) of the piece, thus , that the channel reduced in diameter (D) N 30 is pressed against the outer surface (20) of the teddy bear (8) guided into the channel E of the body. Q O 12. The method according to claim 11, characterized in that a body having the shape of an essentially straight circular cone is formed from the outer shell (2). 13. The method according to claim 11, characterized in that an essentially rotationally symmetric piece is formed from the outer shell (2), whereby at least two consecutive zones are formed in the outer shell in the direction of the longitudinal axis (5), a truncated cone part ( 12) and the cylinder part (13) that follows this and ends at the bottom. 14. The method according to one of claims 11--13, characterized in that the channel (6) is formed in an essentially cylindrical shape so that it has an essentially constant diameter (D). 15. The method according to one of claims 11--14, characterized by the fact that the outer jacket (2) is shaped to taper conically in its part bordering the base (4). 16. The method according to one of claims 11--15, characterized in that the channel (6) is shaped so that the cover (3) expands conically towards it at its end. OF O OF LÖ I co OF I a a O N © LO OF O OF