RU2089828C1 - Detonating device based on blasting agent - Google Patents

Abstract

FIELD: blasting operations, explosive devices used in blasting operations in mining and petroleum- gas industries and in civil engineering. SUBSTANCE: detonating device case 1 accommodates ignition element 2, intermediate shell 4, initiating (7) and initiated (10) charges. Initiating charge 7 is placed in additional shell 6, partially or completely placed inside intermediate shell 4 and having hole 5 on the side of ignition element 2. Additional shell 6 on the side of initiating charge 10 is thinner than its rest part, or has an open end. A partition may be installed between initiating (7) and initiated (10) charges, the partition is partially or completely placed inside additional shell 6. The partition cross-section area equals the cross-section area of initiating charge 7. The partition may be made in the form of cup 9, whose bottom faces initiated charge 10. Retarding and/or ignition compound may be placed between ignition element 2 and initiation charge 7. EFFECT: enhanced safety. 7 cl, 2 dwg

Description

 The invention relates to the field of blasting, in particular to means of blasting, and can be used in initiators of detonation of explosive charges (BB) during blasting in the mining and oil and gas industries and construction.

 The main requirements for the means of initiation are safety in circulation and high reliability of operation. Various paths are used to meet these requirements. The most radical way to increase the safety of initiation tools is to exclude initiating explosives from their composition.

 Known detonating device [1] electric detonator (ED), which is a housing in which there is an igniter element (electric igniter), a protective sleeve, an intermediate shell containing incendiary, slowing and igniter compositions, initiated charge blasting explosive, consisting of two parts: low-density and high density. The principle of operation of this ED is based on the transition of combustion into detonation of the charge of a blasting explosive in a strong shell.

 The disadvantage of this design is the low reliability of operation, due to the strong dependence of the probability of the transition of combustion into detonation on the strength of the body and the density of the low-density part of the initiated charge. The disadvantages should also include the toxicity of decomposition products due to the content of lead salts in the igniter composition, as well as the complexity of the manufacturing technology associated with the preparation of a sensitive mixed igniter composition and the need to manufacture an initiating charge, consisting of two parts with different pressing densities.

 Known detonating device on a blasting explosive [2] containing a hollow body in which an igniter element (electric igniter) is arranged in series, initiating a blasting explosive charge, a partition (membrane) rigidly fixed in the housing blocking the guide channel, and a high-density blasting explosive charge located at the end of the guide channel. The principle of operation of this detonating device is that when the igniter is activated, ignition of the initiating charge of the blasting explosive leads to an increase in pressure sufficient to cut down part of the partition, its acceleration in the guiding channel of the body and impact on the charge of the dense blasting explosive, which initiates detonation in the latter.

 The disadvantage of this design is the low reliability of the ED operation due to the unpredictability of the nature of the collision of the partition with an initiated explosive charge. The disadvantages are the danger of equipment and manufacture of an electric detonator, the complexity of its design.

 Closest to the claimed is a detonating device (detonator without initiating explosive), containing a hollow body with a closed bottom, in which the igniter element is sequentially placed, an intermediate shell containing an initiating charge of a blasting explosive and a partition in the form of a cup, and an initiated charge of a blasting explosive, consisting of two parts: the intermediate, the density of which is less than the density of the initiating charge of the explosive, and the main high-density part of the charge [3] When the igniter is activated, it lights up initiating charge, gas pressure increases with the formation of a weak shock wave in the intermediate shell which encountering partition becomes strong enough to provide a rapid transition from combustion to detonation charge initiated by an intermediate portion, and then the main part of the detonation charge triggered.

 The disadvantage of this design is the complexity of the detonator manufacturing technology, due to the need to prepare a fine-crystalline blasting explosive, to manufacture and install a complex shaped partition in the intermediate shell, to form an initiated charge by pressing in at least two steps to ensure the density of the intermediate part of the initiated charge specified in strict limits.

 The present invention solves the problem of creating detonating devices that are safe to use, reliable in operation and easy to manufacture.

 The technical result of the invention is to simplify the manufacturing technology of a detonating device based on blasting explosives and increase the reliability of its operation.

 This result is achieved by the fact that in the proposed detonating device comprising a housing with a closed bottom, in which the igniter element and the intermediate shell are placed in series with an initiating charge and an initiated charge located in it partially or completely, the initiating charge is placed in an additional shell. The additional shell is partially or completely placed inside the intermediate shell and is made with a hole on the side of the igniter element.

 The thickness of the additional shell on the side of the initiated charge may be less than the thickness of the rest of the shell.

 The additional shell can be made with an open end on the side of the initiated charge. In this case, a partition can be established between the initiating and initiated charges, partially or completely placed inside the additional shell. The cross-sectional area of the septum is equal to the cross-sectional area of the initiating charge.

 The septum can be made in the form of a cup facing the bottom to the initiated charge.

 Between the igniter element and the initiating charge, slowing or igniting compositions can be installed, or both compositions together, while the igniting composition is located between the initiating charge and the slowing composition. The retardant and / or igniter composition is preferably placed in an additional shell.

 An incendiary composition may be located between the igniter and the retardant composition.

 Placing the initiating charge in an additional shell provides the necessary conditions for an accelerated transition of combustion to detonation at pressurization densities of the initiating and initiated charges, which vary over a wide range.

 For an accelerated transition, it is necessary to provide a breakthrough under a sufficiently high pressure of the gaseous products of combustion of the initiating charge into the low-density part of the initiated charge. The value of the gas breakthrough pressure is determined by the strength of the walls of the additional shell. Since the additional shell is located inside the intermediate shell, when pressing the initiated charge partially or completely into the intermediate shell due to the friction of the explosive on the inner surface of the shell, the minimum density of the initiated charge is realized on the interface with the additional shell.

 This allows you to refuse to install partitions of complex shape in the detonating device and to press the initiated charge in one step, i.e. to simplify manufacturing technology while maintaining the reliability of the detonating device.

 The implementation of the additional shell of different thickness (the thickness from the side of the initiated charge is smaller than the thickness of the rest) allows to provide more stable conditions for the breakthrough of gases into the initiated charge and the transition of combustion of the initiated charge to detonation.

 The implementation of the additional shell with an open end on the side of the initiated charge simplifies the manufacturing technology of the additional shell. In this case, the reliability of the initiation of detonation of the initiated charge is maintained, since the pressure of the breakthrough of the gaseous products of combustion of the initiating charge remains at a high level and the breakthrough occurs in the low-density region of the initiated charge. In this case, under the influence of the pressure of the combustion products, the unreacted part of the initiating charge is pushed out under conditions of increasing resistance from the side of the compressible initiated charge. The breakthrough pressure is determined not only by the parameters of the additional shell and the magnitude of the friction of the initiating charge on the side surface of the additional shell, but also by the pressure of pressing the initiated charge, the lengths of the initiating and initiated charges. Since the cross-sectional area of the initiating charge placed in the additional shell is smaller than the cross-sectional area of the initiated charge, gas breakthrough occurs in that region of the initiated charge that did not experience compression when pushing out the unreacted part of the initiating charge and has an initial low density.

 The placement between the initiating and initiated charges of the partition with a cross-sectional area equal to the cross-sectional area of the initiating charge, partially or completely placed inside the additional shell, allows you to increase the pressure of gas breakthrough into the initiated charge. In this case, the mass and thickness of the septum will affect the pressure of the breakthrough of gases into the initiated charge.

 The execution of the partition in the form of a cup facing the bottom to the initiated charge simplifies the technology of fastening the partition in an additional shell.

 The retarding composition placed between the igniter and the initiating charge provides the necessary response time of the detonating device and increases the burst pressure of the combustion products of the initiating charge into the initiated charge, preventing the outflow of gases from the opening of the additional shell.

 The igniter composition located in front of the initiating charge increases the reliability of ignition of the initiating charge from the igniter element or retarding composition and stabilizes the response time of the detonating device.

 Incendiary composition located between the igniter and the retardant composition, increases the reliability of ignition of the retardant composition from the initiating pulse.

 In FIG. 1 is a longitudinal sectional view of an instantaneous detonating device; in FIG. 2 slow motion.

 The drawings indicate: 1 body, 2 igniter, 3 - hole in the end of the intermediate shell on the side of the igniter, 4 intermediate shell, 5 hole in the end of the additional shell on the side of the igniter, 6 additional shell, 7 initiating charge, 8 end of the additional shell from the side of the initiated charge, 9 cup, 10 initiated charge, 11 retarding composition, 12 igniter composition.

One embodiment of a particular embodiment of the detonating device is shown in FIG. 1. The body of the detonating device with a diameter of 7 mm, a length of 60 mm and a wall thickness of 0.3-0.8 mm was a bimetallic sleeve. As an initiating element, a standard electric igniter with rigid bridge fastening was used. The intermediate shell was a steel cap with an external diameter of 6.4 mm, a length of 15 mm and a wall thickness of 0.6 mm, made with a hole with a diameter of 4 mm from the igniter element and an open end from the side of the initiated charge. An additional shell made of steel with a diameter of 5.2 mm and a length of 6 mm was made with a hole with a diameter of 1.7 mm in the end from the igniter element and an open end from the side of the initiated charge. The thickness of the additional shell was equal to 2.5 mm in the end from the igniter element and 0.8 mm in the remaining parts of the shell. A cup with a wall thickness of 0.1 mm with a diameter of 3.6 mm and a height of 3 mm was made of nickel. The initiating charge was made from a mixture of bistrinitroethylethylenedinitramine (substance “H”) and aluminum powder. The initiating charge was made of pentaerythritetranitrate (Ten substance). The density of the initiating and initiated charges varied in the range of 0.9-1.6 g / cm ³ . The mass of the initiating charge was in the range of 40-70 mg, and the initiated charge was 0.4-1.7 g.

Another embodiment of a particular detonating device is shown in FIG. 2. Its distinguishing features from the previous version are as follows. Between the igniter element (a segment of the initiating waveguide of the Nonel type) and the initiating charge of the placement, a retardant composition pressed into the hole of the additional shell with a diameter of 1 mm. An additional shell with a length of 10 mm and a wall thickness at the end of the ignition element of 6.5 mm was made of aluminum with an open end from the side of the initiated charge and fixed in the intermediate shell. The initiating charge weighing 50 mg was made from a mixture of PETN with aluminum powder, the charge density was 1.5-1.6 g / cm ³ . An igniter composition weighing 30 mg was made from a mixture of zirconium with lead minium, and a retardant composition weighing 10 mg from a mixture of silicon and lead minum.

 The detonating device shown in FIG. 1 works as follows. When the igniter element 2 is triggered, the resulting gaseous and solid actuation products through the openings 3 in the end face of the intermediate shell 4 ignite the initiating charge 7, the combustion of which occurs with increasing gas pressure in the additional shell 6. Energy losses due to gas outflow through the hole 5 in the end of the additional shell 6 and deformations of the additional shell 6 are blocked by an increase in the burning rate (energy release) of the initiating charge 7. When reaching the additional shell 6, pressure sufficient to shift the cup 9, the cup 9 together with the unreacted part of the initiating charge 7 is pushed through the open end 8 of the additional shell 6 into the initiated charge 10. Additional energy losses due to pushing the cup 9 with the unreacted part of the initiating charge 7 are blocked by an increase in the burning rate of the initiating charge 7, which provides a further increase in gas pressure in the additional shell 6. At a gas pressure in the additional shell 6 sufficient to break the lateral the surface of the cup 9, a gas breakthrough occurs, with a partial extrusion of the unreacted part of the initiating charge 7 through the cracks in the side surface of the cup 9 into the region of the minimum density of the initiated charge 10 located between the intermediate shell 4 and the side surface of the cup 9, which has invaded the initiated charge 10. In this region favorable conditions are created for the “accelerated” transition of combustion to the detonation of the initiated charge 10 over its small length.

 The principle of operation of the second variant of the device is similar. Igniter 2 ignites a retardant composition 11, which after a predetermined time ignites the igniter composition 12. Combustion extends to the initiating charge 7, the breakthrough of the combustion products through the unreacted part of the initiating charge 7 leads to the initiation of detonation in the initiated charge 10.

 Other detonating device variants are possible, differing in the type of blasting explosives and igniter used. As an ignition element, a flame-retardant cord and a detonating cord with small lateral action can be used. With the appropriate selection of the geometric dimensions of the intermediate and additional shells in the detonating device, other blasting explosives can be used.

Claims (7)

 1. A detonating device based on a blasting explosive, comprising a housing with an ignition element and an intermediate shell placed in it, in which initiating and initiated charges are located, characterized in that the initiating charge is placed in an additional shell, partially or completely placed in the intermediate shell and made with hole on the igniter side.  2. The device according to claim 1, characterized in that the additional shell is made of different thickness and the thickness of the shell from the side of the initiated charge is less than in the rest of the shell.  3. The device according to claim 1 or 2, characterized in that the additional shell on the side of the initiated charge is made with an open end.  4. The device according to any one of claims 1 to 3, characterized in that a partition is installed between the initiating and initiated charges, partially or completely placed in the additional shell and having a cross-sectional area equal to the cross-sectional area of the initiating charge.  5. The device according to claim 4, characterized in that the partition is made in the form of a cup facing the bottom to the initiated charge.  6. The device according to claim 1, characterized in that between the igniter element and the initiating charge placed igniter composition and / or retarding composition.  7. The device according to claim 6, characterized in that between the ignition element and the retarding composition is placed incendiary composition.

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