RU2084806C1 - "quasar-charge" explosive charge and method of "quasar-method" blasting operations - Google Patents

Abstract

FIELD: separation or destruction of objects by blast. SUBSTANCE: liquid explosive charge 1 is placed in case 2. Blaster 3 is made as a casing element. Liquid explosive 1 is a mixture of tetroxide nitrogen and hydrocarbon-type combustible at a volume relation of (0.9 to 9.0):1. Liquid explosive with the casing and blaster is positioned on the object. Wiring of electroblasting network and blasting are accomplished. Electroblasting network within the dangerous zone is laid and the blaster is connected to it before the charge casing is filled with liquid explosive. EFFECT: enhanced safety. 14 cl, 9 dwg

Description

 The invention relates to the field of blasting, in particular, can be used for separation or destruction of objects by explosion, for example, when cutting bulky metal structures (used surface and submarines, tanks, aircraft, etc.), for crushing rocks, processing pressure metals, etc.

 A known charge containing a housing, an explosive (BB) placed therein and an explosive (initiation) means [1] An explosive of a solid state of aggregation was used as an explosive.

The disadvantages of this charge include:
complexity (multioperational) of manufacturing technology;
a high degree of danger in the manufacture, transportation and use;
the difficulty of placing the charge along the desired circuit on the barrier.

 Known charge containing a housing, explosive and explosive means, which used liquid explosive, which eliminates a number of disadvantages inherent in charges with a solid explosive [2] This charge is the closest analogue of the claimed invention.

 The disadvantage of such a charge is a rather high risk of manufacture and use, the difficulty of using a charge in the separation of complex objects.

A known method of blasting, which consists in placing the charge at the place of blasting, installing the means of blasting, installing an electric blast network and undermining the charge [3]
The disadvantage of this method is the high degree of danger of blasting, caused by the need for the presence of a person (fuse) when installing the blasting equipment and installing an electric blast network within the danger zone, produced after filling the charge body with explosive.

 The aim of the invention is to reduce the danger in the manufacture and use of charge, simplifying the installation (placement) of it at various sites, reducing the cost of blasting.

This goal is achieved in that in a device containing a housing, a liquid explosive and an explosive, as a liquid explosive, a mixture of nitrogen tetroxide N ₂ O ₄ and carbon fuel is used at a volume ratio of (0.9 9.0) 1, and the means blasting bonded to the body.

 The blasting means can be made in the form of several sites of initiation.

 The blasting means may be in the form of an exploding wire or a bridge.

 The housing can be made detachable with detachable end elements, and the explosive is located in the end elements.

 The housing can be made of several separate sections.

 The charge can be made elongated, in particular, cumulative with one or more cumulative recesses, or concentrated (axisymmetric) cumulative.

 The charge case can be made of a polymeric material, for example, polyethylene or polyvinyl chloride, and also used packaging or packaging, for example, polymer, glass or metal, can be used as a case. As the latter can be used packages from under dairy products and other drinks, bottles, cans, and other vessels from under liquid or bulk products, etc.

 In the manufacture of a cumulative charge housing from a polymeric material, metal inserts can be installed without a gap in all or some cumulative recesses to enhance the cumulative effect. When used under water, cumulative recesses (all or some) can be filled with an inert material, for example, polystyrene foam to protect the cavity of the recess from water ingress before the charge is triggered.

 As hydrocarbon fuel, oil refining products (oil cracking), for example, kerosene or diesel fuels of various grades, can be used. An explosive is prepared at the place of use by mixing an oxidizing agent and a fuel.

 This goal is achieved by the fact that in the method of blasting, which includes placing the charge and means of detonating at the facility, installing an electric blast network and detonating the charge, charge is used with the body and means of blasting bonded to the body and liquid explosive, and installation an electric explosion network within the danger zone and the connection of the explosive means to it is carried out until the charge casing is filled with liquid explosive.

 When carrying out drilling and blasting operations, several elongated cumulative charges are used, each of which is placed in a borehole or well so that the bisectors of the angles of the solutions of the cumulative notches of charges coincide with the directions of separation (destruction) of the object or intersect in the separation (destruction) sections of the object.

 The following circumstances served as the basis for the choice of an explosive called "Quasar-BB". Firstly, for the production of both the oxidizing agent and the hot, there is a huge raw material and extensive production base. Secondly, of the known combustible components, the proposed ones are the most widespread, relatively cheap and least toxic. Thirdly, the components of explosives are separately explosion-proof, which allows them to be transported to the place of use and stored without the specific difficulties that are inherent to such operations with explosive materials.

 Of particular danger are the operation of installing blasting equipment at the place of blasting and installing an electric blast network in a hazardous area. Therefore, the implementation of the explosive means, bonded to the body and without the presence of any explosive substance or sensitive composition in it, eliminates the appearance of a person (detonator) in the danger zone of the upcoming explosion to install the explosive means and connect it to the electric explosion network after the formation of the charge.

 The execution of the case in the form of several separate sections allows you to install a distributed charge on the object, placing the sections so that the detonation of explosives in sections containing explosive means (initiation units) is transmitted through the influence to the explosives in all other sections.

 The implementation of the housing of a polymer elastic material in conjunction with a liquid explosive allows you to give the charge any desired shape, which greatly simplifies the installation of charge on objects of various configurations and diversifies the ability to perform tasks.

 The use of used containers or packaging as a case reduces the cost and simplifies the technology of manufacturing charges.

 The use of several elongated cumulative charges located in a specific way, that is, placed in separate boreholes or wells so that the bisectors of the angles of the solutions of the cumulative recesses of charges coincide with the planned directions of destruction (separation) of the object or intersect in the planned sections of the destruction (separation) of the object, improves the efficiency blasting, for example, during the destruction of rocks, by concentrating the action of the explosion of all charges in the intended directions at circulating the total mass of the explosive used.

 During blasting, a case with an explosive means is installed, an electric blast network is installed within the danger zone of the upcoming explosion with the blasting equipment connected to it, and then the case is filled with liquid explosive. After connecting an explosive device (machine) to the mounted network by applying voltage, this charge is undermined.

 The invention is subject to drawings representing embodiments of a charge and placement of charges on objects.

 Figure 1 shows the charge of a liquid explosive 1, an element of the casing 2 of which is a blasting device 3, attached by a clamp 4.

 In FIG. 2 shows the charge of a liquid explosive 1, the element of the casing 2 of which is an explosive 3, attached with a binder 5.

 In FIG. 3 shows a charge consisting of several separate sections, one of which contains explosive means.

 In FIG. 4 shows a concentrated cumulative charge, the casing of which consists of a shell 6, a funnel 7 and an end element of the upper cover 8 with explosive means 3 having an opening 9 for filling BB1.

 In FIG. 5 shows an elongated charge, the housing of which consists of a shell 10 with an opening 9 for pouring explosives 1, two end elements — end sleeves 11, and explosive devices, including two initiation units 12.

 In FIG. 6 shows an elongated cumulative charge with liners 13 located in the recesses of the polymer shell 10.

 In FIG. 7 shows a charge with a cumulative recess filled with inert material 14.

 In FIG. 8 shows a charge, the housing of which consists of an elastic shell 15 and an end element of the upper sleeve 16 with blasting means 3 and an opening 9 for pouring a liquid explosive 1; in the place of contact with the destructible object 15, the shape of the charge housing corresponds to the surface configuration of the object.

 In FIG. Figure 9 shows the layout of five elongated cumulative charges with one and three cumulative recesses (the free surface of the shared array is outlined above and to the right).

 The claimed method of work was used in the destruction of the lining of the melting furnace in the workshop of AMO ZIL and when cutting decommissioned vessels at the Ship Separation Base of the Northern Fleet for scrap, the declared explosive charges were used, both concentrated and elongated, including cumulative.

Claims (14)

 1. An explosive charge containing a casing, a liquid explosive and an explosive, characterized in that a mixture of nitrogen tetroxide and hydrocarbon fuel is used as a liquid explosive with a volume ratio (0.9 to 9.0): l, and the explosive is bonded with housing.  2. The charge according to claim 1, characterized in that the means of blasting is made in the form of several sites of initiation.  3. The charge according to claim 1, characterized in that the means of blasting is made in the form of an exploding wire or bridge.  4. The charge according to claim 1, characterized in that the housing is made of several separate sections.  5. The charge according to claim 1, characterized in that the housing is detachable with one or more detachable end elements, and the blasting means is located in the end elements.  6. The charge according to claim 1, characterized in that it is made concentrated cumulative.  7. The charge according to claim 1, characterized in that it is made elongated.  8. The charge according to claim 7, characterized in that it is made cumulative with one or more cumulative recesses.  9. The charge according to claim 1, characterized in that the housing is made of a polymeric material, such as polyethylene or polyvinyl chloride.  10. The charge according to claims 8 and 9, characterized in that it is equipped with metal inserts installed without a gap in all or some cumulative recesses.  11. The charge according to claim 8, characterized in that the recesses are filled with an inert material, such as foam.  12. The charge according to claim 1, characterized in that the body is used second-hand containers or packaging, for example polymer, glass or metal.  13. The method of blasting, including the placement of the charge and the means of blasting at the facility, the installation of an electric blast network and the detonation of the charge, characterized in that the charge used is a charge with the body and blasting means bonded to the body and liquid explosive, and the installation of electric explosive the network within the danger zone and the connection of the explosive means to it is carried out until the charge casing is filled with liquid explosive.  14. The method according to p. 13, characterized in that several elongated cumulative charges are used, each placed in a separate borehole or well so that the bisectors of the angles of the solutions of the cumulative recesses coincide with the separation directions or intersect in the object’s separation cross sections.

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