SE534177C2 - Gas generator for cleavage and decomposition of materials - Google Patents

Description

534 'iïí However, these aforementioned / above mentioned gas generators can have fl your disadvantages, especially when working with horizontal holes. When using such a gas generator in deep boreholes, a pressure reducing agent such as sand may be used. Sand is placed on the bottom of the boreholes, this can be done by using paper tubes filled with sand and which are e.g. about 0.25 m long.

The number of paper tubes required is determined by the DJ up of the boreholes. For 1.5 m deep holes, about eight such pipes are needed. It can be difficult to automate such a packing process especially of deep horizontal holes as a large number of sand pipes are required.

Disclosure of the invention / Summary It is an object of the invention to provide a gas generator in which the above-mentioned disadvantages are reduced while the advantages are maintained.

Consequently, in general, a gas generator for a gentle cleavage of rocks, boulders and similar objects is produced, thus generally for the decomposition of natural and art objects.

Generally, a gas generator is designed to have two separate main cavities or spaces or generally two parts. In the first part or the first main equipment there is a material for combustion in a gentle mode. The first part can Lex. designed according to the cited Russian patent 2211923 and / or the first cavity may be filled with a material described in the Russian patent 2153069 or in the Russian patent 21523 76. The first part may also be designed to a large extent as described in the cited Swedish patent 0201972-7.

The second cavity in the second part is filled with a liquid which is mainly non-compressible liquid, e.g. water. The liquid is shielded from the body of the first cavity with the bottom plate of the first part and the first cavity.

The gas generator can have advantages such as reduced time used for charging horizontal holes because the main part of the bore is filled with the part of the gas generator which is filled with liquid. In addition, due to the pressure dissipating effect from the part filled with water, a smaller amount of detonator can be used. For example, for boreholes longer than 2.5 m, it has previously been proposed that two gas generators weighing 120 and 90 g be used, while with the gas generator described here a composition weighing 150 g placed in the gas generator fuel area is sufficient. Of course, the use of a slower combustion process compared to the conventional explosives may have advantages such as generally "softer" operation, i.e. lower sound level, less deviation of the actually created crack from the planned cracking jig.

Brief Description of the Drawings The invention will now be described by way of non-limiting design with reference to the accompanying drawings, in which: - Figure 1 is a cross-sectional drawing of the gas generator, - Figure 2 is a view similar to Figure 1 but with an alternative design of the gas generator. , Figures 3 and 4 are similar to Figure 1 but with gas generators made of two removable parts 534 '177 - Figure 5 is a schematic drawing of an object to be split Detailed description When splitting rock as in tunnel construction, the holes (1) can be drilled as it is drawn in Figure 5.

The gas generator (3) is inserted into the holes to be placed at some depth in the holes. The gas pressure generated when the gas generator is ignited to burn is distributed to the walls of the boreholes (1) by a surface means (5) located in the space between the gas generator and the bottom / tip of the borehole and the mouth of the hole is plugged with a plug device (7) . The surfactant may be substantially a non-compressible liquid such as water. If the area of the hole left for a plug device has a significant length, e.g. about 1.5 m for a hole with a diameter of 32 mm (1 W), the plug device can be made of e.g. ordinary sand that can have a particle size in the groove area 0.5-2 mm and is packed up to the mouth of the hole.

It can be problematic to supply the fl surface means (5) into the boreholes, especially when they are substantially horizontal or directed upwards, seen from their orifices or openings.

In addition, in some cases, such substantially horizontal holes and the upwardly directed holes may have a significant length, e.g. 3-5 m which makes the addition of the liquid more difficult.

One way to solve this problem is to incorporate the fl surfactant (5) into the gas generator (3). Accordingly, the gas generator is extended to include both the first portion (1 l) containing the first headspace or cavity (12) and the second portion (13) including the second headspace or cavity (14), see Figures 1 and 2.

In the first part (11) of the first main space (12), materials for combustion in a gentle mode are provided. The first part can e.g. is mainly conformed as described in the cited Russian patent 2211923 or in the cited Swedish patent 0201972-7 and / or the first cavity can be filled with material described in Russian patent 2153069 or 2152376. As can be seen in the pictures, the first part consist of a number of parallel channels (15) which together form the first cavity (12) and which are filled with a suitable composition. The filling can e.g. include a suitable oxidizing agent such as one or more chlorates and / or perchlorates of alkaline metals and earth metals, e.g. sodium chlorate NaClO 3, and some combustible materials such as hydrocarbon mixture and / or a suitable polymer, e.g. hydrocarbon polymer such as polyethylene, polypropylene and / or polystyrene. In addition, if desired or suitable, the walls (17), (19) of the channels (15) can be made of a combustible material.

The channels in the bottom of the first main cavity (12) are closed with a bottom plate (21) and the upper part of the first main cavity is closed with a top plate (23). In the top plate, e.g. in the space (25) closed with a top plug (27), a lighter can be arranged.

The channels fl 5) can be formed by a fl number of pipes placed side by side with each other, e.g. pipes having a circular cross-section. Alternatively, the channels may have a polygonal shape, as a square or generally rectangular cross-section formed by straight partitions perpendicularly intersecting each other or a honeycomb structure / cells or shaped as an accordion-like structure or conjugated bands / membrane arranged inside the outer wall (17). 5351 TT? The second cavity (14) in the second part (13) is filled with liquid, e.g. water. The walls (30) of the second part may be made of any leather material which is impermeable to the liquid used. For example. impregnated paper, polymeric material or metal such as aluminum can be used at least partially in the second part. The second cavity is delimited from the first cavity (13) by the bottom plate (21) of the first cavity.

As shown in Figure 1, the outer walls of the first and second cavities (12), (14) can be formed by an integral common tube (17) which can thus be made as a piece and / or of only one material. The tube has a bottom (18) which simultaneously forms the bottom or inner end of the second cavity. An alternative variant is that the outer walls can be formed as a tubular structure formed by the first pipe part (17 ') extending over the first cavity (12) and the second pipe part (17 ") which is an essential part of the outer wall of the second cavity (14) .The two pipe sections can be made of different materials, eg so that the second pipe section has walls that are thinner than the walls of the first pipe section. Consequently, the second pipe section (17 ") can e.g. be collapsible so that it can be stored, when it does not contain any liquid, in a folded or rolled-up state.

The size of the cavities (12, 14) is determined by the depth of the hole and the strength of the material to be broken. For example, the size of the cavity (12) for granite could be determined to contain 90 g of the fuel for a 1.5 meter deep hole (1) located behind the plug (7), at hole diameters of 32 mm.

The material of the base plate (21) should be selected to allow long-term contact with the oxidizing agent; polyethylene, polypropylene, polystyrene etc. can be used. Suitably, such polymers may be used in their expanded or foamed state, such as polyethylene, polypropylene, polystyrene, etc. foams to reduce the weight of the gas generator (3). The bottom plate must insulate the first and second cavities tightly for years, especially so that there is no risk of the liquid found in the second cavity penetrating into the first cavity.

The first part (11) of the gas generator (3) can be charged in the following way: 1. The bottom plate (21) is placed at the height determined by the amount of the composition to be filled in the first cavity (12). 2. Charge the pipes, hive structure or corrugated tape / foil, the walls of which are visible on (19), of a suitable length. Charge with a required amount of the oxidant according to calculations into the ducts (15) and, if necessary, with a combustible agent / material. 4. The top plate (23) is mounted on top of the pipes, the hive structure etc. 5. Install a simple top plug (27).

When the gas generator is to be used by the end user, he can disassemble the simple top plug and instead install an amran top plug that is integrated with a lighter (29) or possibly a lighter made as a separate unit and then reassemble the simple top plug.

The lighter is fitted with electrical cables, not shown, for activation. Then, the oily assembly, consisting of the two parts (1 l), (13), the cavity (14) of the other part filled LT! 34 1? 7 with the liquid, is introduced by means of e.g. a wooden stick, not shown, into a drilled hole (1) until it is stopped by the contact between the inner side or bottom of the other part and the bottom / tip of the holes, the electrical cables must be tapped throughout the operation. If a plugging device made of sand filling is used, the total length of the gas generator including the part filled with liquid shall be calculated in such a way that a length of at least 1.5 meters of fi- in space from the top and rock surface of the gas generator (3) an of the rock. Finally, sand is applied to pack the hole in the thumb space in the mouth of the hole according to the proven technology. For example, paper tubes, not shown, filled with sand and 0.25m long can be used. The first paper tube is inserted to come into contact with already inserted gas generator (3) but without using high compressive force. The following paper tubes are inserted with a higher pressure force fi, by means of e.g. a wooden stick that strongly compresses the sand to break paper blows and to get a firm grip in the borehole (1). If there is a shorter free space at the opening of the borehole (1), sand can also be used, but the hole must certainly be closed directly at the mouth by pressing in e.g. a wooden plug.

It is also possible for the gas generator to be delivered to the end user without the liquid filled in the second part (13). Then, before the operation of putting the gas generator in the activated state by mounting a lighter (29), the end user fills the second cavity (14) with the liquid, e.g. water, in an appropriate manner.

The two parts (11, 13) of the gas generator may be fixedly / rigidly assembled with each other as seen in Figure 1 or they may be separate parts which are removable from each other as seen in Figure 3 and Figure 4. The other part (13) can e.g. have a protruding part (33) which can be removably mounted to the bottom of the first part (1 1). The projecting part can be inserted into the receiving recess which can be formed by the bottom plate (21) of the first part being retracted from the lower edge of the outer walls (17) of the first part, see Fig. 3.

Alternatively, the second part (13) may have its own top plug which includes the projecting part (33), see Figure 4. The receiving recess can also be formed by using instead of the bottom plate (21) a bottom sealing structure (2l ') designed as an upside down cup, see also Figure 4. The protruding part (33) can, if necessary or required, be secured in the receiving recess in a suitable manner, e.g. by using mating projections and depressions which attach the two parts to each other with a snap function or by providing cooperating lines, securing means schematically indicated by the thick lines (35).

The thickness of the barrel-shaped top portion / part (37) of the projecting part which, when the two parts (11, 13) have been fitted into each other, comes into contact with the bottom plate (21) or barrel-shaped top part (39) of the bottom-closing structure (2l ') can be designed not to be too firm or thick so that it can be easily broken with the pressure that occurs when the fuel in the first part is ignited. For example, it may have a thickness between 0.2 and 1.0 mm, specifically in the range between 0.2 and 0.5 mm.

Claims (10)

1. 534 17? Claims 1. A gas generator device for cleavage or decomposition of natural and artificial objects inserted into a borehole and ignited to start a combustion reaction in a de-aggregation or non-detonation mode in the device, the combustion reaction is accompanied by the gas evolution and corresponding pressure, a gas generator of an oxidizing agent and a combustible mixture or material, characterized in that the gas generator (3) consists of a first part (11) containing a first main cavity (12) and a second part (13) containing a second main cavity (14), that the oxidizing agent and the combustible mixture are contained in the first part and at least partially in the first main cavity, that a liquid (S), in particular water, is contained by the second main cavity (14), and that the first and the second main cavities (12, 14) are separated fi from each other by a bottom plate (21) of the first part (11), when the bottom plate (21) forms the bottom of the first main cavity (12). A gas generator device according to claim 1, characterized in that the first main cavity (12) includes a number of parallel channels (15), which in particular are formed by a number of parallel tubes or which have a cross section of substantially regular polygonal shape, for to form in particular a square or bar pattern or a honeycomb structure, or formed by a corrugated band / membrane inserted into the first main cavity (12). A gas generator device according to any one of claims 1-2, characterized in that the outer walls (17) of the first and the second main cavities (12, 14) are formed by a uniform tube which extends over the seams throughout the first and second the main cavities (1 l, 13). A gas generator device according to any one of claims 1-2, characterized in that the first and the second parts (11, 13) are detachably mounted to each other. A gas generator and device according to any one of claims 4, characterized in that! in that the bottom plate (21) has the shape of an upside-down cup which is at least partially inserted into the body of the first part (1 l), the inner space of the cup design is adapted to receive the top portion (33) of the second part ( 13). A gas generator device according to any one of claims 1-5, characterized in that the walls (30) of the second main cavity (14) are made of materials which are impermeable to the liquid (5) contained therein, the walls (30) in particular at least partly made of impregnated paper, a polymeric material or metal such as aluminum. A gas generator device according to any one of claims 1-6, characterized in! because the oxidizing agent consists of one or more chlorates and / or perchlorates of alkaline metals and earth metals, in particular sodium chlorate NaClO3. A gas generator device according to any one of claims 1-7, characterized in that the combustible mixture or material contains a hydrocarbon mixture and / or a polymer such as a hydrocarbon polymer, in particular polyethylene, polypropylene and / or polystyrene. 535! “FTF A gas generator device according to any one of claims 1-8, characterized in that the combustible mixture or material is at least partially contained (?) In the first main cavity (12). A gas generator device according to any one of claims 1-9, characterized in that the combustible mixture or material is at least partially included in the material of the walls (1, 7, 19) of the first main cavity (12).