RU2174110C2 - Explosive charge and method for blastings - Google Patents

Abstract

FIELD: manufacture of explosives and blastings. SUBSTANCE: the explosive charge has a hermetically sealed casing, explosive device and a double-component liquid explosive. The components are positioned in different containers separated by a hermetic partition. The explosive device is positioned in the container with combustible, and the partition is made of thin polymeric film in the form of a double hermetic sleeve turned inside out and filled with combustible or of fragile material and filled with combustible, it accommodates a special device for its destruction, for a special device for its destruction, for instance, a thin exposable metal wire. The explosive device is made in the form of a thin exposable metal wire or film applied on a dielectric support. The method for blasting consists in placement of the given charge and explosive device on the object, wiring of the electroblasting network, connection of the explosive device to it, and blasting of the given charge. EFFECT: enhanced safety in manufacture and use of the explosive charges. 5 cl, 3 dwg _

Description

 The invention relates to the field of blasting, in particular, it can be used to separate or destroy objects with an explosion, for example, when cutting bulky metal structures from used surface and submarines, tanks, aircraft, etc.), for crushing rocks, metal processing pressure, etc.

 Known elongated cumulative charge containing placed in a cylindrical tubular, for example polymer, shell with a cumulative recess liquid explosive (LHE), which is a mixture of an oxidizing agent, for example nitrogen tetroxide, and hydrocarbon fuel, for example kerosene or diesel fuel (Patent RU 2094741, cl. 6 F 42 B 1/02, 1995).

 A known method of manufacturing an elongated cumulative explosive charge, which consists in preliminary preparation of the shell and filling it with explosives (Patent RU 2035028, CL 6 F 42 B 1/036, 1992).

 The disadvantages of this charge and the method of its manufacture include a high degree of danger in its manufacture, transportation and use.

 Known explosive charge containing a housing, a liquid explosive (a mixture of nitrogen tetroxide and hydrocarbon fuel) and an explosive device bonded to the housing, made in the form of an exploding wire or bridge (Patent RU 2084806, CL 6 F 42 V 1/02, F 42 D 3/00, 1995).

 A known method of blasting, including the placement of the charge and the means of blasting at the facility, the installation of an electric blast network within the danger zone and the connection of blasting devices to it, carried out before filling the housing of the explosive charge (Patent RU 2084806, class 6 F 42 V 1/02, F 42 D 3/00, 1995).

 The disadvantages of these solutions are the high degree of fire hazard of the manufacture and use of explosives in place, the difficulties of its use in the separation of complex objects. Nitrogen tetroxide, other oxidizing agents used and unitary explosive substances are generally highly toxic volatile substances. Filling of live rocket charges directly at the place of work requires great care and a long time, especially when pouring a lot of charges on an extended or complex object. Due to the high volatility of the oxidizing agent, the possibilities of working with live air in the summer at a high ambient temperature are sharply limited. Therefore, this method of blasting is time-consuming and represents a great fire and toxicological hazard for a person (an explosive) when performing the operation of filling the housing of the explosive charge. Restricting the ability to work with life-threatening substances in the summer. The presence of an explosive device made in the form of an exploding wire or bridge in a medium containing an active oxidizing agent sharply reduces the reliability of the initiation system due to corrosion of the wire.

 A known explosive charge containing a sealed enclosure, an explosive and a two-component liquid explosive made in the form of a binary charge, for which the components of a liquid explosive are an oxidizing agent, for example nitrogen tetroxide, and fuel, for example hydrocarbon fuel, placed in different volumes separated by a sealed septum. (Patent RU 2135439, CL 6 C 06 V 47/00, F 42 B 3/087, F 42 D 1/00, 08/27/1999).

 A known method of conducting blasting operations, comprising placing a charge of a two-component liquid explosive substance in the form of a binary charge, for which the components of the liquid explosive substance are an oxidizing agent, for example nitrogen tetroxide, and fuel, for example hydrocarbon fuel, are placed in different volumes separated by a sealed partition containing sealed enclosure, blasting equipment at the facility, installation of an electric blast network, connection of blasting devices to it and charge detonation (Patent RU 2135439, class 6 C 06 V 47/00, F 42 B 3/087, F 4 2 D 1/00, 08.27.1999).

 These solutions (according to patent RU 2135439) are the closest analogues of the claimed inventions.

 The disadvantages of these solutions are the high degree of fire hazard and high toxicity, the difficulties of its use in the separation of complex objects, the limitation of the possibility of working with live explosives in the summer. The presence of an explosive device made in the form of an exploding wire or bridge in a medium containing an active oxidizing agent sharply reduces the reliability of the initiation system due to corrosion of the wire.

 The objective of the invention is the creation of such a charge of live rocket explosives and a method of blasting that would reduce fire and toxicological hazards in the preparation and use of the charge, simplify the installation (placement) of it at various sites, the ability to work at high ambient temperatures, increase the reliability of the initiation system, the duration of storage and transportation safety, reducing the cost and complexity of blasting.

 The solution to this problem is achieved by an explosive charge containing a sealed enclosure, an explosive and a two-component liquid explosive made in the form of a binary charge, for which the components of the liquid explosive are an oxidizing agent, for example nitrogen tetroxide, and fuel, for example hydrocarbon fuel, are placed in different volumes separated by a sealed partition. The blasting medium is placed in a volume with fuel, and the partition is made of a thin polymer film in the form of a double sealed sleeve turned inward and filled with fuel, the bend of which is worn on a cylindrical plug and compressed by an elastic sealing device on one side of the charge housing, and the cutting end of the outer part of the sleeve with of the opposite side of the charge housing is sealed on the cylindrical sleeve of the charge housing, and the cutting end of the inner part of the sleeve is hermetically sealed and brought out through the crimp assembly three cylindrical bushings or a partition is made of brittle material, for example glass and filled with fuel, and a special device for its destruction is placed inside it, for example, a thin exploding metal wire.

 The blasting means can be made in the form of a thin exploding metal wire.

 The blasting means can be made in the form of a thin exploding metal film deposited on a dielectric substrate.

 One or more explosive devices with different electrical resistances differing by at least 10% from each other can be placed in the volume with fuel, and all explosive devices are connected in parallel.

 The solution to this problem is also achieved by the method of blasting, including the placement of a charge of a two-component liquid explosive, made in the form of a binary charge, for which the components of a liquid explosive - an oxidizing agent, such as nitrogen tetroxide, and fuel, such as hydrocarbon fuel, are placed in different volumes, separated a sealed partition containing a sealed enclosure, an explosive device at an object, installation of an electric blast network, connection of an undermining device to it and undermining of a charge poison. The blasting medium is placed in a volume with fuel, and the partition is made of a thin polymer film in the form of a double sealed sleeve turned inward and filled with fuel, the bend of which is worn on a cylindrical plug and compressed by an elastic sealing device on one side of the charge case. The cut-off end of the outer part of the sleeve on the opposite side of the charge housing is hermetically put on the cylindrical sleeve of the charge case, and the cut-off end of the inner part of the sleeve is hermetically sealed and brought out through the crimp assembly inside the cylindrical sleeve, or the partition is made of brittle material, for example glass and filled with fuel, and inside it there is a special device for its destruction, for example, a thin exploding metal wire, and the formation of liquid explosives is carried out m removal of the septum between the oxidizer and the fuel after installing the electric explosion network and connecting to it a means of detonation.

 The proposed charge and method have been developed on the basis of detailed experimental studies of the parameters of the structure of the explosive charge and the parameters of a special device for the destruction of the glass shell. The ratio of the volumes of the oxidizer and fuel in the charge casing was chosen from the condition of ensuring the stoichiometric composition of the liquid substances after mixing the components. The charge can be made elongated, in particular cumulative, with one or more cumulative recesses or concentrated (axisymmetric) cumulative. To date, such binary explosive charges and the method of blasting have not been used, and it was impossible to foresee the possibility of practical implementation of the idea.

 The principal result of the tests carried out is the establishment of the possibility of organizing fast, efficient and safe mixing of components in a sealed charge housing after removal of the shell (septum) between the oxidizer and fuel. Experiments with tinted components showed that in a cylindrical charge with a diameter of 40 mm and a length of 250 mm, having a cumulative recess and a separation shell of a thin polymer film, the mixing time of the components did not exceed 10 s, which was facilitated by the strong turbulence of the liquids when the polymer sleeve was pulled out of the charge case. A similar result was obtained for a charge with a separation shell made of glass, destroyed by a shock wave during the electric explosion of a thin metal wire inside a volume with fuel. The fragments of the glass shell moving with high speed in the liquid inside the charge casing lead to fast and efficient mixing of the components.

 It was found that the blasting device and a special device for breaking the shell of brittle material can be connected in parallel if the electrical resistance of the blasting device exceeds the electrical resistance of a special device for breaking the shell. In this case, the sequential initiation of a special device for the destruction of the shell and the initiation of explosive means can be carried out by two consecutive pulses of electric current from the means of detonation along the same electric circuit. The electric current of the first pulse flows mainly through a conductor with a minimum resistance, i.e. through a special device for the destruction of the shell, causing it to electric explosion. The blasting means is stored and initiated by a second pulse of electric current. Reliable initiation of charge is ensured if the electrical resistance of the explosive is more than 10 times greater than the electrical resistance of a special device for breaking the shell.

 It has been established that to increase the reliability of initiation of a charge in a volume with fuel, two or more explosive devices connected in parallel can be placed. When applying an electric current impulse to initiate the resulting explosive attack due to the nonlinearity of the electrical process, an electric explosion of an explosive means occurs with a minimum electrical resistance. If, for any reason, this means of blasting turns out to be faulty, then an electric explosion of the next means of blasting with minimal electrical resistance occurs. The certainty in the sequence of initiation of explosive devices, which can be placed in various regions of the fuel volume, is achieved by the fact that their electrical resistances are selected differing from each other by no less than 10%.

 The proposed hermetic design of the binary charge allows long-term and safe storage and transportation, quick and safe bringing it into working condition at the place of blasting, which greatly simplifies its installation (placement) at various facilities and overcomes the difficulties of its use in the separation of complex objects.

 Equipping a charge with a highly toxic and volatile oxidizer in a specialized organization reduces the cost and complexity of blasting, does not violate the environmental situation at the facility. The charge equipment with hydrocarbon fuels, such as diesel fuel, can also be carried out in a specialized organization or on site.

The tightness of the charge allows you to work in conditions of elevated ambient temperature (up to 40-50 ^o C) even when using such volatile oxidizing agents as nitrogen tetroxide. Placing the blasting means and the device for breaking the brittle shell, made, for example, in the form of thin metal wires or a bridge, in a hydrocarbon fuel medium ensures their long-term safety and trouble-free operation.

The drawing shows an explosive charge containing the housing 1 and the blasting means 2. The charge housing 1 is sealed, and the liquid oxidizer 3 and the liquid fuel 4 are placed in different volumes separated by a sealed shell 5 (a) or 12 (b). The blasting device 2 is placed in the volume with fuel 4. The charge housing may have a cumulative recess 11. In this case:
a) the separation shell 5 of a thin polymer film is made in the form of a double sealed sleeve turned inward and filled with fuel, the bend of which is worn on a cylindrical plug 6 and compressed by an elastic sealing device 7 on one side of the charge housing, and the cutting end of the outer part of the sleeve on the opposite side of the housing the charge is sealed on the cylindrical sleeve 8 of the charge housing, and the cutting end of the inner part of the sleeve 9 is hermetically sealed and brought out through the crimp assembly 10 inside the cylindrical sleeve 8;
b) the hermetic shell 12 is made of brittle material, for example glass, and is filled with fuel 4, and a special device 13 is placed inside it for its destruction, for example, a thin metal wire exploding from an electric current pulse;
C) the profile of the housing 1 charge can be axisymmetric or have, as shown in the drawing (a, b), a cumulative recess 11.

 In the charged state, the charge is not dangerous, since the oxidizing agent and fuel are placed in different volumes isolated from each other, and individually neither the oxidizing agent nor the fuel are detonating explosives.

When carrying out blasting operations according to the proposed method, curb charges are installed in the required places, the electric blast network is installed within the danger zone of the upcoming explosion with the blasting equipment connected to it, and then each charge is brought into operation by organizing the mixing of these charge components. This is as follows:
a) when pulling the inner part of the sleeve 9 from the cylindrical sleeve 8 through the crimping assembly 10, the inner part of the sleeve 5 slides from the sleeve 6 from under the elastic sealing device 7, as a result of which the fuel flows from the volume of the inner part of the sleeve 4 into the volume with oxidizing agent 3 and mixes with him, forming a living arm. The crimp assembly 10 inside the sleeve 8 provides complete emptying of the inverted sleeve from the fuel;
b) when a preliminary pulse of electric current is applied to a special device 13, for example, to a thin metal wire, an electric explosion occurs, leading to the destruction of the hermetic shell 12 from brittle material, as a result of which the fuel flows from volume 4 into the volume with oxidizing agent 3 and mixes with him, forming ZHVV.

 After bringing the charges into working condition, an initiating impulse of electric current from the means of detonation is fed into the electric explosion network to the means of detonation of the charge and they are detonated.

 The use of the claimed invention will allow to reduce fire and toxicological hazards in the preparation and use of the charge, simplify the installation (placement) of it at various facilities, provide the ability to work at high ambient temperatures, increase the reliability of the initiation system, ensure storage time and transportation safety, reduce costs and the complexity of blasting.

Claims (5)

 1. An explosive charge containing a sealed enclosure, an explosive and a two-component liquid explosive made in the form of a binary charge, for which the components of the liquid explosive are an oxidizing agent, for example nitrogen tetroxide, and fuel, for example, hydrocarbon fuel, are placed in different volumes, separated by an airtight partition, characterized in that the explosive is placed in a volume with fuel, and the partition is made of a thin polymer film in the form of a double turned inward and filled fuel of a sealed sleeve, the bend of which is worn on a cylindrical plug and squeezed by an elastic sealing device on one side of the charge housing, and the cut-off end of the outer part of the sleeve on the opposite side of the charge housing is sealed on the cylindrical sleeve of the charge housing, and the cutting end of the inner part of the sleeve is hermetically sealed and withdrawn outward through a crimp assembly inside a cylindrical sleeve, or the partition is made of brittle material, such as glass, and is filled with fuel, and a special device is placed inside it roystvo for its destruction, such as exploding a thin metal wire.  2. The charge according to claim 1, characterized in that the means of blasting is made in the form of a thin exploding metal wire.  3. The charge according to claim 1, characterized in that the blasting device is made in the form of a thin exploding metal film deposited on a dielectric substrate.  4. The charge according to any one of claims 1 to 3, characterized in that in the volume with the fuel there is additionally one or more explosive devices with different electrical resistances that differ from each other by at least 10%, and all explosive devices are connected in parallel.  5. A method of blasting, which includes placing a two-component liquid explosive material in the form of a binary charge on the object, for which the components of the liquid explosive — an oxidizing agent, such as nitrogen tetroxide, and fuel, such as hydrocarbon fuel, are placed in different volumes separated by a sealed a partition containing a sealed enclosure and explosive means, installation of an electric explosion network, connection of detonating means and charge detonation to it, characterized in that the explosive means p is housed in a volume with fuel, and the partition is made of a thin polymer film in the form of a double sealed sleeve turned inward and filled with fuel, the bend of which is worn on a cylindrical plug and compressed by an elastic sealing device on one side of the charge housing, and the cutting end of the outer part of the sleeve on the opposite side the charge housing is sealed on the cylindrical sleeve of the charge housing, and the cutting end of the inner part of the sleeve is hermetically sealed and brought out through the crimp assembly inside the cylindrical the shells or the partition is made of brittle material, such as glass, and is filled with fuel, and a special device for its destruction is placed inside it, for example, a thin exploding metal wire, and the formation of liquid explosive is carried out by removing the partition between the oxidizer and fuel after installing the electric explosion network and connecting detonating means to it.