RU2192609C2 - Directional action charge - Google Patents

Abstract

FIELD: design of directional action charges. SUBSTANCE: directional action charge includes explosive charge positioned in hollow body comprising outer shell, cone-shaped hollow depression with central hole in vertex, lid with cylindrical bushing with through hole and initiator. Outer shell and cone-shaped hollow depression are made as single unit. Cone-shaped hollow depression is made of conjugate longitudinal members oriented with vertexes towards central hole in depression and is fitted with tubular member with axial duct. Lower part of tubular member is conjugate to cone-shaped hollow depression with the aid of longitudinal members and axial duct communicates with central hole and has variable section. Lower part bordering on central hole is conical and upper part is cylindrical. Tubular member protrudes beyond lid. EFFECT: enhanced efficiency of destruction of objects, expanded application field. 1 cl, 3 dwg

Description

 The invention relates to blasting, in particular to structures of charges of directional action, and can be used for crushing rocks, metal structures, as well as as a structural member and initiator of a borehole charge.

 Known charge directional (AS 1459385, F 42 V 1/02, F 42 D 3/04), including a cylindrical body with an explosive inside and an end cumulative funnel, a site for initiating a charge, the opposite cumulative funnel, a tubular insert mesh insert coaxially mounted inside the case.

 The disadvantage of this charge is the complexity of the prefabricated design and the unreliability of mounting the initiation unit, the high cost of manufacturing the charge.

 Closest to the proposed technical solution is a directional charge (US Pat. UK 1243647, F 42 D 7/00), including a charge of explosives placed in a hollow housing consisting of an outer shell, a cone-shaped cumulative recess with a central hole in the apex, covers with cylindrical sleeve with through hole and initiator.

 In a known charge of directional action, the cone-shaped cumulative recess during the explosion of the charge does not allow the full use of the energy characteristics of the explosive. In addition, this device consists of a complex prefabricated design, which leads to a decrease in manufacturability and an increase in the cost of charge. Ultimately, all this leads to a decrease in the efficiency of using a known charge of directional action, limiting the scope.

 The only technical result of the proposed technical solution is to expand the field of charge use, giving it manufacturability and increasing the destruction efficiency by increasing the energy of the cumulative jets.

 The specified technical result is achieved in that in a known charge of directional action, including an explosive charge, placed in a hollow body consisting of an outer shell, a cone-shaped cumulative recess with a central hole in the top of the lid with a cylindrical sleeve with a through hole and initiator, the outer shell and cone-shaped the cumulative recess is made inseparable, the cone-shaped cumulative recess is made of conjugated longitudinal elements oriented by the vertices to the central hole of the recess, and provided with a tubular element with an axial channel, the lower part of the tubular element is associated with a cumulative recess through longitudinal elements, and the axial channel with a central hole and made with a variable cross section, the lower part adjacent to the Central hole of the recess is made conical, and the upper - cylindrical, and the tubular element is made with a part protruding above the lid, in addition, the through hole of the lid sleeve is made in the form of truncated s.

 The implementation of the outer shell and cumulative excavation one-piece (at the same time) reduces the complexity of manufacturing, simplifies the design.

 In addition, this implementation of the charge contributes to the expansion of its scope by using it as an element of the borehole charge.

 The interaction of the charge body with the walls of the well (shock, friction) when delivering it to deep wells, as well as the effect of the weight of the overlying column of explosives when the charge is suspended in the well as a result of using it as an active jamming (blocking charge) or to create air gaps to the destruction of the body of the charge and its separation into fragments even with partial deformation of the body.

 One-piece charge shell made of durable polymer materials prevents the expansion of explosion products, helps to maintain pressure for a long time. An experimentally established increase in energy yield up to 10% when using identical charges made inseparable from polyethylene grade ND in comparison with the prefabricated structure.

 Performing a cone-shaped cumulative recess from the conjugated longitudinal elements oriented with their vertices to the central opening of the recess, makes it possible to create a shaped profile in the longitudinal direction of the cumulative recess, which allows to increase the mass of explosives in comparison with the prototype. In this case, the end part of the charge in contact with the destructible surface is significantly reduced, and consequently, the energy losses of the explosive of the end part of the charge are reduced.

 The tubular element with an axial channel is a functional part of the charge structure, which, depending on the conditions of use and the purpose of the charge, carries the functions of the initiator fastener or is used as a link for transforming the energy of explosive transformation.

 The execution of the tubular element with a part protruding above the lid ensures that the lid of the tubular element with the initiator is fixed outside the charge cavity, as a result of which the contact of the explosive with the part of the tubular element in which the initiator is placed is increased.

 The through hole of the sleeve in the form of truncated cones opposite the vertices allows the initiator to be “rigidly” fixed in the tubular element over a short section of the axial channel, which makes it possible to realize the effect of axial cylindrical cumulation.

 So, the presence of the axial channel of the tubular element allows you to create a detonation front directed towards the axial channel with the subsequent formation of a longitudinal cumulative jet of the axial channel. It is known that a channel wave includes a leading detonation wave, a stream of gaseous detonation products (cumulative jet) and an air shock wave (see K. Yuhanson, P. Person. Detonation of explosives. M .: Mir, 1973, p. 89-90, Fig. 51; Salganik V.A. et al. Method for increasing the useful work of an explosion at mining enterprises // Mining Journal, 1977, 2, pp. 54-57).

 In general, the presence of an axial channel ensures the passage of a powerful initiating pulse and creates conditions for increasing the cumulative effect due to the occurrence of two cumulative jets that form in the cavity of the axial channel and in a cone-shaped cumulative recess.

 The work of the charge is based on the principle of the interaction of detonation products and the regulated redistribution of energy of gas flows (cumulative jets) from additional cumulating planes of profiled recesses. The conjugation of the lower part of the tubular element with a cumulative recess through the longitudinal elements and the communication of the axial channel with the central hole ensures the manufacturability of the charge when equipped with explosive devices (detonating cord, detonator capsule), operational safety. The equipment of the charge with explosive means is made after filling the case with explosive, and the explosive means themselves are introduced into the axial channel and fixed there, that is, they are protected from external influences.

 When using charge as a structural element of a borehole charge with a through axial channel in the tubular element, the initiator (detonating cord) is placed in the conical part of the axial channel, ensuring the reliability of fastening, eliminating the possibility of failure due to its breakage.

 The invention is illustrated by drawings, where in Fig.1 shows a General view of the design of the charge of directional action, in Fig.2 a longitudinal section is a variant of the overhead charge, in Fig.3 is a longitudinal section of a variant of the charge with a concentrated initiator. The directional charge includes an explosive charge 1 placed in a hollow body 2, consisting of an outer shell 3 and a cone-shaped cumulative recess 4 with a central hole 5. The cumulative recess 4 consists of longitudinal elements 6 conjugated to each other, oriented with their vertices toward the central hole 5 recesses 4, in the upper part of recess 4 there is fixed a tubular element 7 with an axial channel 8. The lower part of the tubular element 7 is mated to a cumulative recess 4 by means of longitudinal elements 6, and the axial channel 8 It communicates with the central hole 5 of the recess 4 and is made with a variable cross section. The lower part 9 of the tubular element 7 adjacent to the Central hole 5 of the recess 4 is made conical, and the upper 10 is cylindrical.

 The charge is provided with a cover 11 with a cylindrical sleeve 12 with a through hole 13, through the through hole 13 of the cover 11 the cylindrical portion 10 of the tubular element 7 protruding above the cover is passed, in the axial channel 8 of which the initiator 14 is fixed (Fig. 1).

 A design variant of the charge is provided in which the hole 13 of the cylindrical sleeve 12 is made in the form of truncated cones opposite to the tops (FIG. 2).

 The directional charge is applied as follows. The charge housing 2 is filled with explosive 1. Then, when using the charge as an overhead (external) charge of the explosive, a cover 11 is placed on the housing 1, while a section of the protruding cylindrical part 10 of the tubular element 7 reaches the mating point of the truncated cones of the through hole 13 of the sleeve 12 (figure 2).

 An initiator 14 (for example, a detonating cord) is inserted into the axial channel 8 of the tubular element 7 to a depth of 3-4 cm from a section of the protruding part of the tubular element 7. The cover 11 is forcefully sent to the charge body 2, while the protruding cylindrical part 10 of the tubular element 7 is passed through the through hole 13 of the sleeve 12. The walls of the cylindrical part 10 of the axial channel 8 of the protruding part of the tubular element 7 are crimped by the narrowest part of the through hole 13 (the place of mating of the truncated cones), while rigidly fixing the end of the detonating pin pa 14. The diameter of the through hole 13 at the junction of oppositely directed truncated cones is performed less than the diameter of the projecting cylindrical portion 10 of the tubular element 7 and at least equal to the diameter of the detonating cord 14.

 The walls of the tubular element 7 have a thickness of 0.5-0.8 mm and are made of a deformable polymer material. Due to the deformation of the walls of the cylindrical part 10 of the tubular element 7, the detonating cord 14 is rigidly fixed in the axial channel 8. In this case, as a result of fixing the cover 11 in the charge housing 2, the upper layer of explosive 1 is sealed against the surface of the cover 11 and fills the volume of the lower truncated the cone of the through hole 13, increasing the contact area of the explosive 1 with the upper part of the tubular element 7, in the axial channel 8 of which the initiator is fixed - detonating cord 14.

 When the oversized pieces of rock or metal structures are destroyed, a directional charge is placed on the surface of the object being destroyed.

 The directional charge works as follows.

 When the explosive 1 is initiated by initiator 14, a detonation wave propagates, in the axial channel 8 of the tubular element 7, a shock wave arises with a leading steep front, followed by a shock-compressed gas, and the effect of axial cylindrical channel cumulation with the channel of the channel along the charge axis to destructible object.

 When the detonation wave reaches the vertices of the longitudinal elements 6 and its further movement in each of the longitudinal elements 6, cumulative jets are formed, which ensure the formation of a central cumulative jet due to the directed movement of the detonation products from the longitudinal elements to the charge axis.

 The total impact on the object of two cumulative jets of the axial direction of the channel and central provides the maximum destructive effect.

 In the part of the longitudinal elements 6 adjacent to the end part of the charge, "flat" cumulative jets of radial direction are formed. The interaction of a powerful axial and radial load on the object significantly increases the effect of the explosion and creates the conditions for the development of radial and concentric crack formation.

 The implementation of the charge involves its use as a structural element of the borehole charge (figure 1).

 The area of charge use as an element of a borehole charge: initiator of a borehole charge; revitalizer charge (passive initiator); active stemming ("locking" charge); a garland of explosive charges; auxiliary charge (elimination of pressing-in, shooting holes), etc.

 The use of the proposed directional charge in downhole wells provides for reliable and technological fastening of the detonating cord, which is carried out as follows: after filling the housing 2 with explosive 1, sealing the housing 2 with the cover 11, the detonating cord 14 is passed through the cylindrical part 10 of the axial channel 8 of the tubular element 7 and make a node at the end of the detonating cord 14, placing the node in the conical part 9 of the axial channel 8, after which the detonating cord 14 is wedged in a conical part 9 by tensioning and finally fixed in a cylindrical sleeve 12.

 When initiating a borehole variant of a directional charge with a detonating cord 14 located along the entire length of the axial channel 8, the explosive 1 operates in a linear initiation mode, which is characterized by an increase in the detonation velocity of the main explosive to the initiator detonation speed (a.s. 1369461, F 42 V 3/10. Downhole charges with air gaps / Under the direction of B.P. Ryabchenko. Novosibirsk: Nauka, 1974, p. 32).

 When the detonation velocity of the explosive charge 1 (ammonite 6Ж) equal to 4800 m / s, the explosive column equal to the length of the tubular element 7 without a protruding part detonates at a speed close to the initiator detonation velocity of 6800 m / s. Consequently, a detonation wave with parameters exceeding the parameters characteristic of a given type of explosive comes to the tops of the longitudinal elements 6, due to which the maximum amount of detonating explosive energy 1 is transformed into the region of the cumulative recess 4 adjacent to the tubular element 7. of elements 6, detonation waves emerge with parameters corresponding to the nominal detonation velocity of 6GW ammonite. Due to the axial “feeding” of the central cumulative stream from the region of the cumulative recess 4 adjacent to the tubular element 7, the loading dynamics of the fracture object increases, which improves the quality of crushing of the object.

 In FIG. 3 shows a variant of a directional charge with a concentrated initiator. A “directional” flat charge is used as an initiator of axial action or as a “bottom” charge placed in the bottom of the well, and is characterized by the presence of a shortened tubular element 7 and an increased diameter of the axial channel 8. The focused initiator 14 is formed by bending the detonating cord and placing it in the axial channel 8 of the tubular element 7 loop 15 in the conical part 9 of the axial channel 8. In the opening of the loop 15 is placed a fragment of inert material 16 (paper, polyethylene) and by tension discharge of the branches of the detonating cord 14, the loop 15 propped in a conical portion of the axial channel 8 of the tubular element 7.

 The concentrated initiator has a high initiating impulse, which increases the reliability of the initiation of a directional charge.

 Thus, the proposed design of the charge allows you to significantly expand the scope of its use, increase manufacturability and destruction efficiency, which determines its use in blasting technology to control the effects of the explosion.

Claims (2)

 1. A directional charge, including an explosive charge, placed in a hollow housing consisting of an outer shell, a cone-shaped cumulative recess with a central hole in the apex, a cap with a cylindrical sleeve with a through hole and an initiator, characterized in that the outer shell and the cone-shaped cumulative recess made one-piece, the cone-shaped cumulative recess is made of conjugated longitudinal elements oriented with vertices to the central opening of the recess, and provided a tubular element with an axial channel, the lower part of the tubular element is associated with a cone-shaped cumulative recess through longitudinal elements, and the axial channel is in communication with the Central hole and made with a variable cross section, the lower part adjacent to the Central hole is made conical, and the upper is cylindrical, and tubular the element is made with a part protruding above the lid.  2. The charge according to claim 1, characterized in that the through hole of the cylindrical sleeve of the cover is made in the form of truncated cones opposite to the tops.

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