RU2498064C2 - Gas generator for destruction or cracking of natural and artificial objects, and method of destruction or cracking of natural and artificial objects - Google Patents

Abstract

FIELD: blasting operations.

SUBSTANCE: gas generator (3) is used for breaking or cracking of natural and artificial structures, being inserted into the drilled boreholes and ignited to start the combustion reaction in the deflagration or non-detonating mode. The gas generator consists of a first part (11) with the first main cavity (12) and a second part (13) with the second main cavity (14). The first part contains the oxidant and the fuse composition. The second part contains liquid, such as water which serves for distribution of pressure generated by the gases formed in the combustion reaction. The first and second main cavities are separated from each other by bottom of the first part (21), which for example can be mounted according to the size of the first cavity and the volume of oxidant in it. The present gas generating device in particular is well adapted for use in horizontally drilled holes. The first part can consist of a composition that uses as a part of the fuse composition the bearing structure of the polymer material and aluminium or similar material added to it, which reduces the burning time and increases the energetic capacity of the composition. Any special igniting device (27) can be used.

EFFECT: gas generator is easy to use, safe in operation, has a lower noise level, enables to carry out more precise separation of objects.

12 cl, 9 dwg

Description

RELATED TO THE INVENTION OF THE APPLICATION

This document claims priority and effect from Swedish patent applications numbered 080178-6, filed August 11, 2008, 090002-5, filed in January 2009, and 0900044-9, filed in January 2009, the full contents of which are set forth below.

FIELD OF TECHNOLOGY

The present invention relates to a gas generator for use in drilled holes for cracking rocks or block stone, and in particular for destroying objects in a gentle manner, for example for use in the field of tunneling, as well as in the mining industry and quarrying. The invention also relates to an ignition device for igniting charges with slowly burning compositions. Further, the invention relates to a composition based on alkali metal chlorates and perchlorates and organic compounds, intended for use in gas generators of the aforementioned kind.

PRELIMINARY INFORMATION

To destroy or crack hard objects such as block stone or rock blocks in a gentle manner in order to avoid the disadvantages associated with the use of conventional explosives, a deflagration reaction, that is, rapid combustion of a specially selected fuel, can be used. The rate of combustion in a deflagration reaction is lower than that of an explosive, with the explosive participating in the detonation reaction with a burning rate greater than the speed of sound. One way to use deflagration to destroy an object is to drill holes along the line of the planned separation, with the addition of liquid and solid reagents selected in such a way that they participate in the planned non-detonation combustion reaction, then jamming the holes and, finally, igniting the charges to start non-knock reaction. Charges may consist of solid fuel in the form of tubes or films with longitudinal directions parallel to the direction of propagation of the fire and bore holes. Fine powder or a granular mixture of an oxidizing agent such as NaClO ₃ and other fuels, liquid, and possibly some suitable metal, is placed inside and between the tubes or between the films.

Russian patent No. 2211923 describes a gas generator (GG) with a housing made of a combustible substance and channels containing an oxidizing agent. Channels may be formed as parallel channels, for example, within a plurality of parallel tubes. The gas generator is adapted to operate in a gentle, non-knock mode and to produce a sufficient volume of gases for the destruction of stone and similar materials.

A gas generator similar to the one described above is described in Swedish patent 020192-7 with publication number 523163 and it additionally contains a certain amount of liquid fuel, namely hydrocarbon, with which the interiors of the tubes or casing made of solid hydrocarbon polymer material are filled after they are filled with an oxidizing agent.

These previously known gas generators have the following advantages:

1. The stability and uniformity of the composition of the oxidizing agent along and across each channel and in the gas generator.

2. The minimum compositional variability between different gas generators and various tubes making up the gas generator.

3. The cross section of the tube constituting the gasifier can be in the form of a round or hexagonal ring or any other shape that provides the most dense packing of channels oriented along the axis of the gasifier.

However, these previously known gas generators have several disadvantages, especially for working with horizontal holes. When using such a gas generator to work with long holes, a pressure transfer means such as sand can be used. Sand is loaded into the end of the holes, for example, using paper tubes filled with sand, for example, 0.25 m long. The number of tubes used is determined by the length of the hole. For a hole 1.5 m long, approximately eight such tubes are required. The loading process of such tubes is thus difficult to automate, especially in the case of long horizontal holes.

An ignitor shall be used in the gas generator to ignite the appropriate charge. Such an ignitor for igniting charges containing slowly burning compositions must be resistant to mechanical stress so that there is no risk of damaging the incendiary composition contained in it. Also incendiary "tablet" -fused and incendiary composition should be easily and safely loaded into igniters.

In gas generators of the type described above and the like, a mixture is used which, when ignited, burns more or less quickly, producing large volumes of gases. Such mixtures are usually used for field cracking or destruction of materials. So widely used explosives based on ammonium nitrates, see Dubnov LV, Bakharevich Kh.S., Romanov AI, "Industrial explosives", Nedra, 1973, p.320. Most of them have suitable properties. Explosives based on potassium chlorate and / or perchlorate together with explosives based on ammonium perchlorate were used during the First World War in France, Great Britain and Germany as charges for shells and bombs, see D. Ligotsky. Loss of granite during mining and processing. - Problems of the theory of quarry design. Interuniversity. Sat scientific tr., 1995, St. Petersburg. P.75, 76 and Kotov L.R., Kutsenko G.P., Kulakevich Ya.S. Hose charges for cracking granite blocks. Moscow, September 7-11, 1999. However, when using the aforementioned compositions for breaking block stone into smaller parts, intended for use in the quarry industry for the production of, for example, building stone, the yield may not exceed 20%, see the cited work of Ligotsky, due to the large explosion force. In order to reduce the risks associated with explosions produced by conventional explosives, a more sparing mode of the explosion process can be used. Various methods and methods have been invented for conducting sparing explosions, for example, the use of charges with a low explosive content, or the use of soft charges containing, in addition to the explosive, an inert filler such as water or air, suitably sealed, as described in the quoted work of Kotov and others. Recently, in the extraction of block stone, attempts have been made to use materials that produce pressure in holes in the deflagration mode, and not in the commonly used detonation mode of ordinary explosives, or in the low-speed detonation mode. However, the use of explosive mixtures having a reduced detonation velocity, for example Granilen-1,2,3, Forsyth, Gurit, only partially solves the problem, since the cost of their production is higher, environmental problems, etc. can occur.

Black powder is still used in some mines, but its danger is well known. However, the use of black powder, as well as the aforementioned compositions for the production of block stone from rock, can be somewhat understandable if we take into account the dynamic parameters of these compositions, in particular, a short reaction time, which can vary from a few microseconds to several milliseconds.

Currently, of particular interest due to their low cost and the ability to automate both delivery and charge equipment are compositions based on sodium chlorate (NaClO ₃ ) and hydrocarbons (C _x H _y ), in solid or liquid form, for example, polymers such as polyethylene, poliropylene, mineral oils such as diesel fuel. Also, such compositions can finally be produced directly in the field, directly at the place of their use, which increases labor safety. According to preliminary thermodynamic calculations, the operability (RT, product of the gas constant by temperature) of the explosion products for the main component in a composition based on a stoichiometric mixture of NaClO ₃ and C _x H _y (in a mixture of this kind, the number of oxygen atoms is exactly equal to the number of carbon atoms and hydrogen in the reactions 2O + C → CO ₂ and O + 2H → H ₂ O) is approximately 720 kJ / kg. Even larger RTs can be achieved using compositions that also include aluminum and are based on perchlorates instead of chlorates, more preferably ammonium perchlorate. However, the further use of such compositions is not widespread, mainly due to the high cost, in particular compositions using ammonium, see the cited work of Dubnov and others. Currently, such compositions have some use only in Japan (Karlites) and partially in France (Sevronites). Chlorate-based formulations have a lower cost and are safer to use.

Another advantage of compositions based on perchlorates and chlorates is their higher initial density in comparison with compositions based on ammonium nitrate. So, the density of ammonium nitrate is 1730 kg per cubic meter, while the density of sodium chlorate is 2490 kg per cubic meter, see S. Schreiber. "The production of bertolletova salt and other chlorates", GONTI NKTP, 1938, s.367.

Explosive compositions for use in boreholes described in the patent of the Russian Federation No. 2152376 and in the cited Swedish patent 0201972-7 contain 7-11% liquid hydrocarbons and 17.3-20.9% solid hydrocarbon polymer material, the remainder is sodium chlorate. Such a composition allows to obtain explosives having both detonation and deflagration, non-detonation type of combustion. A deflagration type of combustion of the composition can be obtained if the solid material, that is, the solid hydrocarbon polymer, has a suitable shape in which other components of the composition will be enclosed or which will support, for example, a plurality of tubes, honeycomb structure, corrugated cardboard or plates. The disadvantage of the composition described in the patent of the Russian Federation No. 2152376 and in the above-cited Swedish patent when used in a gentle mode, i.e. in a deflagration mode of combustion, and especially when used without a liquid component in holes drilled in high-strength materials, as well as in cracked rock, is that it can have a low burning rate due to the too low energy of the process, leading to an insufficient rate of increase in pressure created in the hole the basics. This can in some cases be compensated by using a larger mass composition, which, however, causes a rise in the cost of the composition used per hole. Also, the pressure can be so low that it will not split the rock in which the hole is drilled.

SUMMARY OF THE INVENTION

The aim of the invention is to provide a gas generator for the split or destruction of materials in which the aforementioned disadvantages of previous versions of the gas generator are eliminated, and the advantages are preserved.

The aim of the invention is to provide a gas generator with a composition having a sufficient burning rate and sufficient energy and which can be directly used without the addition of additional components in the field to crack or destroy materials, while maintaining the main advantages of the composition described in the above-cited Swedish patent 0201972-7.

Summarizing, it seems a gas generator for cracking rock formations, block stone and similar objects in a sparing mode and in general for the destruction of natural and artificial objects.

In general, a gas generator consists of two main cavities or spaces, or two parts, separated from each other. The first part may be executed in accordance with the cited Russian patent 2211923 and / or the first cavity may be filled with material as described in Russian patent 2153069 or in Russian patent 2152376 or as described below. The first part can also be produced as described in Swedish patent 0201972-7. The second cavity in the second part is filled with a substantially incompressible liquid, for example water. The liquid is separated from the body of the first cavity by at least the bottom of the first part and the first cavity.

The gas generator may have advantages, such as reducing the time used to load the horizontal hole, since most of the hole is occupied by that part of the gas generator that is filled with liquid. A smaller volume of explosive or combustible material may also be used due to the effect of pressure distribution in the part filled with liquid. For example, for holes longer than 2.5 m, it was previously proposed to use two gas generators weighing 120 and 90 grams, while for the gas generator described here 150 grams of the composition located in the fuel part are sufficient. Obviously, using a slower burning process compared to conventional explosives can have such advantages as a “softer” effect, that is, lower noise level, lower deviation of the resulting crack from the planned one, etc.

Another aspect of the gas generator is an ignition device, which is generally designed or adapted to ignite the charges of slowly burning substances, in particular to ignite the charges in the gas generator, and adapted to crack rock, block stone and similar objects in a gentle manner, that is, generally to destroy natural and artificial objects. The igniter consists of an igniter, which includes a cavity containing an igniter composition. The fuse is surrounded on the sides by a free buffer space located inside the outer thermowell. The buffer space protects the igniter and the igniter composition contained therein during storage and operation with the igniter device, such as installing it in a charge or in a gas generator.

The igniter device may include a cup-shaped housing, a cap is then included in the housing, from which an external thermowell exits. The housing may then include a supporting structure inside the outer sleeve, such as an inner sleeve for fixing the igniter. Then, between the outer sleeve and the frame of the inner sleeve, a free buffer space is formed. In the inner sleeve then there may be an inner space into which the fuse is inserted. The shapes of the inner space and the fuse can be adapted to each other so that the fuse will hold firmly in the inner space. Also the shapes of the inner space and the fuse can be adapted to each other so that the fuse can be easily inserted into the inner space. The fuse, thus, can be a device separate from the housing, but easily connected to it. It can also be separated from the housing for, for example, checking the ignition composition. This allows you to store fuses separately and attach them to the ignition device immediately before use, such as when the gas generator must be loaded into the drilled hole, providing an easy and reliable way to work with the part containing the igniter composition.

Further, the fuse may have a bottom that limits the cavity and is directed toward the charge when the igniter is prepared for ignition of the charge, as well as side walls that define the cavity and are connected to the bottom and extend beyond the surface of the charge. The side walls can be significantly thicker than the bottom, so that when the igniter is activated and the igniter is ignited, a torch of burning material appears, directed from the cavity containing the igniter, piercing the bottom of the cavity and directed to the surface of the charge. This torch is formed in free space at the inner end of the fuse and is relatively well localized and narrow. Thus, the torch affects only a relatively small portion of the surface of the flammable charge. The heating power of the igniter composition is thus very concentrated and high-energy, which also makes it possible to ignite charges that are relatively safe or "slow", i.e. not easily set on fire.

This design of the igniter device can provide a high degree of safety when working with it. The device can be equipped very easily, work with it does not require, in particular, welding operations.

Another aspect of the gas generator is a composition used for cracking rock, block stone and similar objects in a gentle manner, that is, in general for the destruction of natural and artificial objects, consisting of a solid oxidizing agent, for example, based on chlorate or perchlorate, such as one or several of the following substances: sodium chlorate, potassium chlorate, sodium perchlorate and potassium perchlorate - and material of solid walls, mainly of hydrocarbon polymer material, and solid walls are presented in the approach dyaschey form, in particular in the form of tubes, structures "cells" or corrugated plates or a plurality of containers, which contain the other components of the composition. The composition is suitably placed in a gas generator.

In the second embodiment of the "gas generator" object, the solid material includes a material that increases the burning rate, in particular aluminum or a similar metal. The material that increases the burning rate may have a concentration of 1.0-15% of the mass. of the total weight of the composition, the concentration of solid hydrocarbon material together with a material that increases the burning rate can be 5-21% of the mass. of the total weight of the composition, and the remainder of the mass can be mainly sodium chlorate.

The solid hydrocarbon polymer may, for example, be one or more of the following: polyethylene, polypropylene, polystyrene and the like.

This kind of composition can be used in the above gas generators, but this is not limited to its use. The composition can be used wherever fast or slow burning material is required, such as for cracking or destructive materials.

BRIEF DESCRIPTION OF THE DRAWINGS

Now the invention will be described using exemplary (not limiting other possible implementations) implementations with reference to the attached drawings, in which:

- Figure 1 contains a cross section of a gas generator,

- Figure 2 shows an alternative embodiment of a gas generator,

- Fig.3 and 4 are similar to Fig.1, but they depict gas generators consisting of two shared parts,

- Figure 5 depicts schematically a hole drilled in a split object, in a hole there are gas generators of two separate parts,

- Fig.6 schematically depicts a split object,

- Fig.7. schematically depicts a cross section of an igniter device,

- Fig. 8 is similar to Fig. 7, the ignition device is slightly modified,

- Figure 9 contains a cross section of a simple gas generator.

DETAILED DESCRIPTION

When cracking rocks, for example, when building tunnels, holes 1 can break through as indicated in Fig.6. A gas generator 3 is inserted into the bore holes to a certain depth 3. The pressure of the gases generated when the gas generator is ignited is distributed to the walls of the drilled hole 1 using a fluid 5 located in the hole between the gas generator and the bottom of the hole, and the outer end of the hole is blocked by clogging 7. As a liquid, Use a substantially incompressible fluid such as water. If the remainder of the hole intended for clogging has a sufficient length, for example, about 1.5 m for a hole with a diameter of 32 mm (one and a quarter of an inch), the clog can be made, for example, of ordinary sand with a grain diameter of 0.5-2 mm tightly clogged at the outer edge of the hole. If the borehole is not long enough, a wooden plug not shown in the figure may be used.

When loading the fluid 5 into the drilled holes 1, problems can arise, in particular when the holes are substantially horizontal or directed upward from the corresponding external holes. Moreover, in some cases, such substantially horizontal or upward bore holes can have a considerable length, for example 3-5 m, which makes loading the liquid even more difficult.

One way to solve this problem is to include the liquid 5 in the composition of the gas generator 3. Then the gas generator "increases" and includes two parts: the first part 11 containing the first main chamber or cavity 12 and the second part 13 containing the second main chamber or cavity 14 , see figures 1 and 2.

In the first part 11 or in the first main cavity 12, material for combustion is placed, for example in a gentle mode. The first part can be configured substantially as described in the Russian patent 2211923 cited above or in the Swedish cited patent 0201972-7 cited above and / or the first cavity can be constructed and / or filled with material as described in Russian patents 2153069 or 2152376 or it can be built as described below. As can be seen from the figures, the first part may contain many parallel channels 15, which together form the first cavity 12 and which are filled with a suitable composition. The filler may, for example, include a suitable oxidizing agent such as one or more alkali and / or alkaline earth metal chlorates and / or perchlorates, for example sodium chlorate NaClO ₃ , and any combustible material such as a hydrocarbon compound and / or a suitable polymer, for example, hydrocarbon a polymer such as polyethylene, polypropylene and / or polystyrene. Also, the walls 17, 19 of the channels 15 can, if necessary, be made of combustible material. The channels are closed by a bottom 21 - at the lower end of the first main cavity 12, and a lid 23 - at the upper end of the first main cavity. At the top cover, for example in the space 25, closed by the top cap 27, may be an igniter 29.

The channels 15 can be formed by a variety of tubes located next to each other, for example, having a circular cross section. The channels may also have a polygonal shape, a square rectangular section formed by straight dividing walls perpendicular to each other, or the shape of a honeycomb, or the shape of an accordion or corrugated foil inserted inside the outer wall 17, as described in the above-cited Swedish patent 0201972-7.

The second cavity 14 in the second part 13 is filled with a liquid 5, that is, a liquid which, as indicated above, can be a substantially incompressible liquid, for example, water. Thus, the second part is a container for liquid 5 and can be called the container part, while the first part 11 is actually the gas generating part. The walls 30 of the second part can be made of any suitable material that is impervious to the fluid used and has sufficient mechanical strength to allow work with the second part, in particular, loading it into the hole. In the second part, for example, at least partially impregnated paper, a polymeric material such as polyethylene or rubber, or a metal such as aluminum can be used. The second cavity is separated from the first cavity 13 by the bottom 21 of the first cavity 12.

As shown in figure 1, the outer walls of the first and second cavities 12,14 can be formed by a common tube 17, which, thus, can be made of one piece and / or of only one material. This tube has a bottom 18, which also forms the bottom or lower end of the second cavity. In another embodiment, the outer walls may be formed by a tubular structure formed by the first tubular part 17 ', overlapping the first cavity 12 and the second tubular part 17 ", which is an essential part of the outer wall of the second cavity 14. These two tubular parts can be made of different materials, such, for example, that the walls of the second tubular part are thinner than the walls of the first tubular part. Thus, the second tubular part 17 "can be folded or twisted so that it can be stored without liquid in or a false twist.

The dimensions of the cavities 12, 14 are determined by the depth of the hole 1 and the strength of the material being destroyed. For example, the size of the cavity 12 for granite can be set so that it contained 90 g of fuel per 1.5 m of the length of the hole 1 behind the bottom hole 7 with a diameter of 32 mm.

The material of the bottom 21 should provide long-term contact with the oxidizing agent used; for example, polyethylene, polypropylene, polystyrene, and the like can be used.

Accordingly, such polymers can be used in a foamy form, that is, polyethylene foam, expanded polystyrene or expanded polystyrene, in particular, to reduce the weight of the gas generator 3. The bottom must hermetically separate the first and second cavities, in particular there should be no risk of liquid from the second cavity 14 into the first cavity 12.

The first part 11 of the gas generator 3 can be equipped as follows:

1. The bottom 21 is located at a height required by the volume of the composition, which is filled with the first cavity 12.

2. Tubes, honeycombs or corrugations of the required length are loaded, the walls of which are shown as 19.

3. The channels 15 are loaded with the amount of oxidizer required in accordance with the calculations, as well as, if required, a combustible mixture.

4. The top cover 23 closes the tube, honeycomb, etc.

5. Install a simple plug 27.

When the final consumer prepares to use the gas generator 3, he can remove the simple plug 27 and install another plug instead of it containing an igniter 29 or possibly a separate igniter device and then reinstall the simple plug. Then, the complete assembly containing two parts 11 and 13, while the cavity 14 is filled with liquid, is inserted, for example, using a wooden pole, not shown in the figures, into the drilled hole 1, until the bottom or the inside of the second part contacts the bottom of the hole while holding electrical wires taut. If the stemming uses sand as a filler, then the total length of the gas generator, including the part filled with liquid, should be determined in such a way that at least 1.5 m of free space should remain from the top of the gas generator 3 to the rock surface. Finally, sand is drilled into the free space in accordance with the proven technology for jamming the bore hole 1. Paper tubes, not shown in the figures, filled with 0.25 m sand, for example, can be used. The first paper tube is inserted so that it comes into contact with an already installed one gas generator 3, but without the use of force. Subsequent paper tubes are inserted with force using, for example, a wooden pole, pressing the sand tightly until the paper packaging is torn to form tight contact with the walls of the hole 1. If the free space to the open end of the hole 1 is shorter, sand can also be used, but the hole must then be securely closed with, for example, a wooden plug.

It is also possible that the gas generator is supplied to the end user without the liquid 5 filling the second part 13. Then the end user, before activating the gas generator (installing the igniter 29), in a suitable way fills the second cavity 14 with liquid, for example water.

The two parts 11 and 13 of the gas generator can be rigidly connected to each other, as shown in figures 1 and 2, or they can be separate parts, which in one implementation of the gas generator can be docked and undocked, as can be seen in figure 3 and 4, and in another implementation are completely separate parts. As can be seen in FIGS. 3 and 4, the second part 13 can, in particular, have a protruding part 33, which can be detachably connected to the bottom of the first part 11, The protruding part can be inserted into the receiving recess, which can be formed due to the fact that the bottom 21 of the first part is spaced from the lower edge of the outer walls 17 of the first part, see FIG. 3. In another embodiment, the second part 13 may have its own upper cap 31, including the protruding part 33, see figure 4. The receiving recess may also be formed due to the fact that instead of a bottom 21, a bottom cover 21 'is used in the shape of an inverted bowl, see also FIG. 4. The protruding part 33 may, if required or if necessary, be attached to the receiving recess in any suitable way, for example, by using mating protrusions and recesses connecting the two parts by snapping-in, or on a thread; fasteners are schematically indicated by bold lines 35.

The thickness of the upper plate-shaped part 37 of the protruding part, which, when the two parts 11 and 13 are connected to each other, is in contact with the bottom 21 or the plate-shaped part 39 of the lower cover 21 'can be chosen so that it is not too strong or thick, so that it can be easily broken by the pressure generated when the fuel in the first part is ignited. For example, it may have a thickness between 0.2 and 1.0 mm, in particular from 0.2 to 0.5 mm.

The gas generator 3 may also include two separate parts without any special means for their connection with each other. Thus, as illustrated in figure 5, where the large diameter of the hole 1, one or more gas generators can be inserted into the hole. Then, the second part 13 of the gas generator is first inserted, having the structure of a closed piece of hose filled with, for example, water. The walls of the 17 '”hose are made of a suitable material having sufficient mechanical strength so that the second part can be inserted without damage. The wall material should also, of course, be capable of hermetically containing liquid 5. Suitable materials are, as mentioned above, solid hydrocarbons, for example polymers such as polyethylene and rubber. The wall thickness can be, for example, from 150 to 200 microns. The diameter of the hose is selected taking into account the diameter of the hole, for example, slightly smaller than the diameter of the hole for which it is intended. As above, the second part 13 can be “collapsible”, so that it can be stored, without liquid, in rolled or twisted form.

After the second part 13 of the first gas generator 3 is inserted into the hole 1, so that it is relatively tightly supported against the bottom of the hole, the first part 11 of the same gas generator is inserted, so that it in turn abuts relatively tightly against the outer end of the second part. This end and the bottom of the first part, thus, abut against each other. In the case where the hole is relatively long or deep, it may be useful to use one or more additional gas generators. In this case, the second part 13 of the second gas generator is inserted into the hole so that its bottom abuts or is in relatively reliable contact with the upper end of the first part of the first generator. After that, the second part of the same second gasifier is inserted. If necessary, one or more gas generators 3 can be inserted into the hole in the same way. Finally, the upper end of the hole 1 is clogged with sand. Sand blockage 7 may be clogged with a wooden plug 41.

The length of the sand block 7 should be at least about 1.5 m if a wooden plug is not used, as mentioned above. The length of each of the second parts 13 may, accordingly, be longer than the sandstone.

To ignite the gas generating devices 3, for example, electric wires not shown in the figure can be used, coming from the igniters located in the first parts of the gas generator to some external control device not shown in the figure.

It is also possible to exclude a separate interior with liquid; this option is not shown in the illustrations. In this case, the first part 11 of the gas generator is inserted into the hole, then the second part 13 of the second gas generator, the first part of the second gas generator, etc. Thus, between the first two parts 11 there is always a liquid-filled part 13.

Figure 7 schematically shows a section of the igniter 51, shown as the top cap 27 of Figure 1-4, and which can be used as such. The igniter device consists of a housing 53 including a cover 55, which can be substantially flat and also form the outer surface of the gas generating device 3 shown in FIGS. 1-4. Two cylindrical sleeves protrude from the bottom surface of the cover 55, the outer sleeve 57 and the inner sleeve 59. These two sleeves can, for example, be arranged concentrically with respect to each other. The outer surface of the outer sleeve may be cylindrical, in particular in the form of a regular cylinder. Its inner surface can also be cylindrical, it can be, as shown, slightly beveled, for example, in the form of a truncated cone, so that the outer sleeve can have a width near its inner open end slightly less than the width at the place where the outer sleeve connected to the lid 55, that is, the outer sleeve may have a shape that tapers toward its open end. The inner sleeve, which generally can be considered a holding device or a supporting structure, limits its interior surface to the space into which the sleeve or fuse 61, corresponding to the detonator for activating an ordinary explosive, is inserted. This space may be cylindrical, for example, in the form of a regular cylinder, relatively mating with the igniter, the outer surface of which is configured accordingly so that the igniter 61 can be inserted into the inner space and securely fixed there. Alternatively, or in conjunction with the foregoing, the inner space of the inner sleeve 59 may be configured to hold the igniter fuse due to its shape by snapping in, using a suitably designed rim or flange not shown in the figures interacting with the annular recess on the surface of the igniter . The inner sleeve 59 may also taper towards its open end, while the outer surface of the inner sleeve will, for example, be in the form of a truncated cone, so that the inner sleeve will already be at its open inner end than in the area of connection with the cover 55.

The igniter device 51 can be designed so that the outer sleeve 57 protrudes a certain distance from the cover 55, greater than the distance from the cover 51, which is located on the end or lower surface of the fuse 61. Thus, the inside or end surface of the outer sleeve is located in a plane perpendicular to the axis of the igniter, which is 1 distance from a parallel plane passing through the free, internal terminal surface of the igniter 61. When ignited An integral device 51 is positioned near a flammable charge 63, such as for example on a charge limiting plate 65, a distance 1 is formed between the surface between the wall surface or the top cover 65 and the surface of the lower end of the igniter 61. Therefore, the internal free end of the igniter 61 has free space as well there is a space between the outer sleeve 57 and the fuse, and in particular between the outer and inner sleeves 57 and 59. These free spaces form buffer spaces protecting the fuse 61.

In the ignition 61, in turn, there is an internal space or cavity filled with igniter composition 69. The ignition, as shown in the illustration, can have relatively thick walls 71 surrounding the igniter composition and a relatively thin bottom 73 at the open inner end of the igniter. The cavity 67 may have a relatively elongated shape and thus has a longitudinal direction. The ratio of the length of the cavity to its width or diameter may be at least 1.5: 1. The value of the ratio of length to width or diameter of the fuse 61 is not (so) critical, but may be, for example, at least 1: 1.

When the igniter device is activated and the igniter composition 69 starts to burn, a torch (jet) 75 of burning material is formed very quickly, while the burning material is ejected from the inner, free end of the ignition by destroying the thin bottom of the ignition 61. This allows the use of safe explosives in the ignited charge 63 or other combustible material due to the high concentration of physico-chemical energy in the discarded flare. This can, in particular, provide advantages in the mining and construction industries, since the diameters of the parts where the charges are to be ignited do not exceed 75 mm. The fact that a jet of burning material is actually formed is caused by the fact that the igniter composition 69 is located in a chamber whose wall thickness is significantly greater than the thickness of the bottom. The gap between the outer sleeve 57 and the inner sleeve 69 protects the inner shell and the fuse 61 from mechanical stress when working with the ignition device 61.

In the implementation (gas generator) shown in Fig. 7, the ignition device may, as shown, be mounted on the gas generator with walls 77 extending into the outer sleeve 57 with a tight fit to secure the ignition device. The ends of the walls of the gas generator may be in contact with the inner surface of the lid 55. Alternatively, the walls of the gas generator may be located on the outer side of the outer sleeve 57, as shown in Fig. 8 and Figs. 1-4. The inner end or space at the end of the outer sleeve 57 may then be in contact with the wall or plate 65 limiting the charge. The plate 65, limiting the charge 63, then corresponds to the plate 23 of figure 1-4.

The upper surface of the igniter 61, i.e. intended to be in contact with the lid 55, can, as shown, be formed so as to allow easy insertion of the igniter into the interior of the supporting structure, i.e. the inner sleeve 59.

In one example, the bottom 73 of the igniter 61 may have a thickness of 0.3 to 0.7 mm, and the wall thickness may be at least 3, for example 3 to 5 mm. The diameter and height or length of the fuse may be approximately 15 mm. The distance l may be at least, for example, from 1 to 2 mm. The igniter material 61 should be selected so that it can withstand prolonged contact with the igniter 69, and may, for example, include a polymer such as polyethylene, polypropylene and polystyrene, in particular a high density polymer such as high pressure polyethylene (HP-DE).

An electric wire, not shown in the figure, as well as a NONEL® ignition cord, or any other starting system that has the required characteristics to activate the igniter 69 by heating, can pass through the hole 79 in the cover 53.

Cavities 67 of a plurality of fuses 61 can be filled simultaneously with an ignition mixture 69 by placing empty fuses in the openings on a vibrating stand (not shown) and applying a certain amount of ignition mixture to the surface of the stand using, for example, a special spatula using vibration. This ensures uniform and equal filling of the cavities of the fuses.

Combustible material or charge in the first part 11, that is, in the gas generating part of the gas generating device 3 shown in FIGS. 1-4 may include a special composition, as will be described below. This composition can also be used in gas generators of other types and generally used for cracking and / or destruction of materials and objects.

Thus, the composition for cracking and / or destruction of materials and objects, for example, in a sparing mode is used in the gas generator 81, see Fig.9. The composition consists, as described above, of an oxidizing agent, usually solid, based on one or more chlorates and / or perchlorates of alkali and / or alkaline earth metals, for example sodium chlorate, and a solid hydrocarbon polymer material. This solid material is at least partially included in the material of the walls 83, 85 having an acceptable shape for placement in the cavities 87 of the other components of the composition, such a shape can be, for example, many tubes, a honeycomb structure with polygonal cells, corrugated ribbons or sheets or other similar forms. In addition, the material of the solid walls contains, in addition to the hydrocarbon polymer material, an energy component such as aluminum or metal with similar combustion characteristics, for example, magnesium. The solid oxidizing agent can be present in a more or less granular form and can, in particular, be a powder, for example, with a grain size of 10 to 100 μm as described in the cited Swedish patent 0201972-7 and mix in the cavities 87 formed by the material of the solid walls 83 and 85. These cavities are of appropriate size. The wall thickness 83 and 85 is selected in accordance with the density of the oxidizing agent. The diameter of the sleeves 57 may, for example, be chosen equal to from 10 to 20 times the wall thickness. The internal diameter of the cavities, if the solid wall material is based on polyethylene, can be, for example, in the range from 2.5 to 7 mm, if the wall thickness is in the range from 0.05 to 0.7 mm.

It turns out that, on the contrary, adding aluminum powder to the composition, for example, mixed with a granular oxidizing agent such as sodium chlorate, can in the same way increase the energy of the composition, as described in the Swedish patent cited above, but it can also increase the likelihood of deflagration conversion mode of composition in detonation, associated with its inherent disadvantages, see, for example, a discussion in the cited Swedish patent 0201972-7. Such disadvantages may include a decrease in the volume of suitable block stone due to an increase in the content of cracks and splits in the resulting blocks, an increase in the volume of small fragments and an increase in the separation distance of such fragments during an explosion, which reduces the safety of operations and increases the seismic load on the environment environment, which is the inevitable result of the detonation regime. On the contrary, aluminum or a similar material is introduced into the composition of the solid material, for example, the composition of the material of the solid walls, for example, the solid hydrocarbon polymer or polymers, which can be produced at the stage of production of the solid wall material. Aluminum can thus be included in the composition of the wall material 83, 85 tubes, “honeycombs”, corrugation or plates or similar capacitive structures or can be applied to them in one or more layers inside and / or on the surface of the walls. The added material will still increase the burning rate and, accordingly, the rate of pressure formation and energy composition in proportion to its share in it.

An experiment using a constant-volume bomb showed that the linear burning rate under normal conditions of a composition containing 1.5% weight. aluminum included in the wall material of a solid hydrocarbon material in structures supporting other components of the composition increased by 3.5-5 times compared with the composition described in the above patent of the Russian Federation No. 2152376 without a liquid component. Energy growth was approximately 10-15%. This led to a reduction in the total burning time of the composition from 0.3 s to 0.1 s. Other experiments have shown that aluminum should be included in a concentration of at least 1.0% by weight. from the total mass of the composition.

Further, higher energy leads to the fact that the mass of the composition to perform a given work can be reduced. The choice of a specific composition, that is, the percentage of the material that accelerates combustion, such as aluminum, added to the composition, can be made if we take into account the data obtained by measuring the burning rates under normal conditions, as well as in a manometric bomb simulating natural conditions, since this described in the cited patent of the Russian Federation No. 2152376.

The experiments showed that to obtain a noticeable effect, the material that accelerates combustion should be used in a concentration of at least 1.0% by weight. of the total weight of the composition. In addition, increasing the concentration of the material that accelerates combustion to more than 15% weight. of the total mass of the composition does not produce an effect, because, despite the increase in the temperature of the reaction products, the pressure created by the combustion of the composition can then decrease, since the volume of the condensed phase resulting from the combustion reaction increases, and the volume of the gaseous phase, respectively, decreases.

The experiments also showed that the concentration of solid hydrocarbon polymer material, including a material that accelerates combustion, is in the range from 4 to 21% by weight. and even better in the range of 7 to 14% weight. of the total weight of the composition, in the case of using sodium chlorate, when the solid oxidizing agent was the bulk of the composition.

Since all components of the composition are widely available, its manufacture is very easy. All compositions presented were tested in vivo.

Claims (12)

1. A gas generator for the destruction or splitting of natural and artificial objects, which, when placed in a hole and ignited to start a combustion reaction in it in a deflagration or non-detonation mode, produces gas and creates the appropriate pressure and contains an oxidizing agent and a combustible composition or material, characterized in that
- the gas generator consists of a first part containing a first main cavity and a second part containing a second main cavity,
- the oxidizing agent and the combustible composition or material are contained in the first part and at least partially in the first main cavity,
- a liquid, such as water, is contained in the second main cavity, and
- the first and second main cavities are separated from each other by the bottom of the first part, which is the bottom of the first main cavity. 2. The gas generator according to claim 1, characterized in that the first main cavity comprises a plurality of parallel channels formed, in particular, by a plurality of parallel tubes, or having regular polygons in cross section, and forming in particular a square or rectangular or honeycomb structure, or formed corrugated foil inserted into the first main cavity. 3. The gas generator according to claim 1, characterized in that the oxidizing agent is one or more chlorates and / or perchlorates of alkali and alkaline earth metals, in particular sodium chlorate NaClO ₃ . 4. The gas generator according to claim 1, characterized in that the combustible composition or material is a hydrocarbon compound and / or polymers, such as a hydrocarbon polymer, in particular polyethylene, polypropylene and / or polystyrene. 5. The gas generator according to claim 2, characterized in that the outer walls of the first and second main cavities are formed by the walls of the same tube covering the entire first and second parts. 6. The gas generator according to claim 2, characterized in that the bottom has the shape of an inverted bowl at least partially inserted into the housing of the first part, while the inner part of the bowl is adapted to include the upper part of the second part. 7. The gas generator according to claim 2, characterized in that the first and second parts are detachably connected to each other. 8. A gas generator according to any one of claims 1 to 4, characterized in that the combustible composition or material is at least partially contained in the first main cavity. 9. A gas generator according to any one of claims 1 to 4, characterized in that the combustible composition or material is at least partially included in the material of the walls of the first main cavity. 10. A method of destroying or splitting natural and artificial objects, comprising the following steps:
- placing at least one part of the gas generator in the hole and
- ignition of at least one of the aforementioned parts of the gas generator, comprising an oxidizing agent and a combustible composition or material in order to initiate a combustion reaction in the gas generator in a deflagration or non-detonation mode, accompanied by gas evolution and the creation of the corresponding pressure,
characterized by the presence of an additional step in which at least one container with an incompressible liquid, for example water, is inserted into the hole, so that the hole is completely filled, with the exception of the mouth of the hole, at least one of the aforementioned parts of the gas generator and at least one of the aforementioned containers. 11. The method according to claim 10, characterized in that at least two gas generators are introduced and a container is placed between the gas generators. 12. The method according to claim 10, characterized in that with the introduction of the aforementioned at least one gas generator and at least one container, one container and one gas generator are introduced into the borehole as a whole.

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