RU2106472C1 - Firing-blasting device - Google Patents

Abstract

FIELD: oil and gas production industry. SUBSTANCE: this is used for secondary opening of bed. Effective performance of device is ensured at cutting out lengthy section of piping in well. Device has body with shaped charges located in different levels along its axis. Charges are kept in contact with detonation transmitting system. This system is arranged along axis of device. Shaped charges are positioned over spiral lines. Number of spiral lines corresponds to number of shaped charges in each level. Installed between shaped charges in each level are inserts made of explosive material which are detonation-connected to them. Charges and inserts are arranged uniformly over circumference in each level. In addition, circular charges are installed along axis of device between levels. Circular charges are detonation-connected with shaped charges of adjacent levels. Shaped charges are enclosed in modules made of inert material. EFFECT: higher efficiency. 2 cl, 4 dwg

Description

 The invention relates to the oil and gas industry and can be used in the development of perforating and explosive equipment, for example, devices for cutting pipe sections in wells.

 Known explosive cutting device [1], containing a cylindrical body in which a number of explosive drafts of explosives (BB) and a system for their initiation are located. This system includes three detonators mounted along the axis of the device and interconnected by detonation cords. Two of the three detonators are installed at opposite ends of the body, and the third is on the end surface of one of the pieces.

 The disadvantage of this device is its low efficiency and low reliability.

 A device for cutting pipes [2], containing two disk cumulative charge (CI) with an initiation system located on the axis of the device, and a high-explosive disk charge located between the cumulative charges symmetrically with respect to the axis of the device. The impact of cumulative jets, and then products of a high-explosive charge explosion, leads to the complete destruction of the pipe walls with the ejection of metal outside it.

 This device can be used to break pipes when replacing them, but it does not allow cutting long sections in the casing when opening productive oil reservoirs in order to switch from a vertical wellbore to an inclined or horizontal wellbore.

 Known closest in technical essence to the claimed invention perforating explosive device for perforating wells [3], containing a housing in which cumulative charges in contact with the detonation transmission system — axially located detonating cord — are laid out in tiers along its axis.

 The disadvantage of the prototype is low efficiency due to incomplete destruction of the walls of the pipe of the well in an extended area.

 The objective of the invention is to reduce labor costs and time when cutting long sections of the pipe in the well.

 The technical result of the proposed solution is to increase the efficiency of the device when cutting an extended section of the casing of the well.

 The technical result is achieved by the fact that in a perforated explosive device including a housing in which cumulative charges in contact with the detonation transmission system are distributed in tiers along its axis, the cumulative charges are located along helical lines, the number of which is equal to the number of short-circuit in each tier. Moreover, between the cumulative charges in each tier there are installed explosive inserts connected detonationly with short-circuit, and the charges and explosive inserts are located uniformly around the circumference in each tier.

 The location of the cumulative charges uniformly around the circumference in each tier provides a uniform along the circumference of the impact of sharply directed cumulative jets on the walls of the casing of the well, punching holes in it.

 The location of the cumulative charges along helical lines along the axis of the device, together with the uniform location of the short circuit in each tier, is necessary for breaking holes in the casing at the “points” evenly spaced along the length of the pipe and the circumference of the pipe, and creating stress concentrators on the punched holes and thereby weakening the strength of the casing.

 Inserts of explosives installed between the short circuit in each tier are necessary for the high-explosive impact of the explosion products on the pipe walls, and at the same time provide powerful pressure in the central part of each mesh cell formed from the punched short holes. This increases the efficiency of the device. After breaking the pipe into small fragments, the latter are poured down the well. Thus, a positive effect is achieved.

 Depending on the strength of the material of the casing and the thickness of its walls in the proposed device to increase the impact on the inner surface of the casing between the cumulative charges of adjacent layers, explosive charges are made in the form of rings, detonation associated with the short circuit of neighboring layers.

 To simplify the assembly of the device during its operation, cumulative charges can be installed in modules of inert material, which are, for example, elongated cylinders or prisms, the basis of which are regular polygons.

 In addition, to increase the high-explosive effect of cumulative charges, the latter, containing explosives with cumulative facings, are installed in modules made of an inert material, such as wood. This ensures penetration of a larger area in the casing and thereby reduces the size of each mesh cell formed from holes punched in the pipe. This increases the efficiency of the device without increasing the mass of the explosive.

 In addition, by combining the charge groups into a single module housing, the cost of manufacturing a short circuit is reduced (since it is not necessary to manufacture a housing for each cumulative charge), the assembly technology of the device is simplified.

 Figure 1 shows a General view of the proposed device; figure 2 is a section aa in figure 1; figure 3 - charging module, in which between the short-circuit tiers installed ring charges of high explosive action; figure 4 is a section aa in figure 3.

 The proposed device (figures 1 and 2 consists of a housing 1, which is an elongated hollow cylinder with an outer diameter of 115 mm and a thickness of 10 mm, made of an aluminum alloy of type D16. Inside the housing 1, charging modules 2 are installed adjacent to each other, made in the form a cylinder of an inert material, such as wood, 317 mm long and 92 mm in diameter.

 In the case of each module along its axis, cumulative charges 3 are distributed in tiers with a pitch of 35 mm, which are arranged along five helical lines (according to the number of cumulative charges in each tier) and are in contact with the detonation transmission system 4, which runs along the axis of each module and is installed in the central channel of each explosive rod module with a diameter of 13 mm, connected to cumulative charges by wiring from explosives.

 From the ends of each module, this explosive rod is lined with metal, for example, aluminum alloy, and the surface of the lining is recessed relative to the end surface of the charging module so that there is a guaranteed gap between the lining and the end of the module, which is necessary to disperse the lining under the influence of the explosion products of the detonation transmission system.

Cumulative charges 3 are installed in the module casing in each tier uniformly around the circumference (the angle between the axes of adjacent short-circuit in the tier is 36 ^o ). Between the cumulative charges of each tier, inserts of explosive 5 are installed, made in the form of pieces with a diameter of 12 mm and a height of 9 mm. In this case, explosive inserts are detonation-related to cumulative charges in the layer. Each cumulative charge 3 with an explosive mass of 31 g has a cumulative lining with a solution angle of 70 ^° , made, for example, of copper and glued into the cumulative recess of the explosive. (To increase the high-explosive action, short-circuiting devices were made without their own enclosure and include explosive and cumulative linings.) Short-circuit dimensions: diameter - 34 mm, height - 34 mm. Cumulative charges and explosive inserts are installed in the module housing with glue.

 To ensure the location of KZ 3 along helical lines along the entire length of the housing 1, in the housing of each charging module from one of its supporting end surfaces there are centering elements, for example pins, on the opposite side there are corresponding holes for installing the centering pins of the subsequent module.

 At the ends of the housing of the device 1 are mounted on a thread; on the one hand, there is a cable head 6, which serves to connect with a load-bearing geophysical cable and place the initiator 8 in it, on the other hand, a tip 7. To seal the joints in the grooves of the cable head and the tip, rubber rings 9 are installed.

 Cumulative charges 3 are designed to influence the products of the explosion and the cumulative linings of high-speed jets formed upon collapse on the walls of the casing and punching holes in it.

 A uniform short circuit arrangement in each tier is necessary for uniformly penetrating holes in the pipe along the circumference, and their arrangement along helical lines ensures uniform penetration of holes in the casing along its length in a "checkerboard pattern" and increasing the number of punched holes per unit length of the device. This increases the efficiency of his work.

 Inserts from BB 5 located between the short circuit in each tier and connected detonation with them are necessary to create pressure on the pipe walls in the central parts of the mesh cells formed by punched holes.

 The detonation transmission system is designed to transfer detonation to cumulative charges sequentially from tier to tier.

 Its location along the axis of the device and each charging module is necessary for the simultaneous transmission of detonation to cumulative charges located uniformly around the circumference in each tier.

 The use of ring charges 3 (FIGS. 3 and 4) located in modules between adjacent short-circuit tiers is intended to increase the area of impact of the products of the explosion of ring charges 10 on the walls of the casing, facilitating its breaking into small fragments.

 The location of the ring charges 3 along the axis of the device is necessary for a uniform effect of the products of their explosion on the walls of the casing.

 The device operates as follows. An initiator 8 is triggered from an external pulse (see Figs. 1 and 2), which initiates detonation in the detonation transmission system 4. The detonation passes modulo sequentially along the tiers, initiating cumulative charges 3 and from them - explosive inserts 5. Under the action of the explosion products the lining of the explosive rod of the detonation transmission system is accelerated in the gap between the modules to a speed sufficient to cause detonation in the subsequent module. The detonation reception and its further transmission is facilitated by the broadening of the central channels in the modules.

 Similarly, through the knock transmission system, detonation is transmitted from module to module, causing the cumulative charges 3 and the BB 5 inserts to be sequentially tiered.

 During the explosion of cumulative charges 3, metal short conical shells collapse and form high-speed jets, which, together with the products of the explosive short-circuit explosive, exert high pressure on the barrier (device body 1 and casing), leading to penetration of holes in the casing, creating a kind of mesh from the punched holes and weakening the strength of the pipe.

 With a further explosion of inserts BB 5, the products of their explosion act on the central parts of the cells of such a grid, break the casing into small fragments that crumble down the wells.

Claims (3)

 1. Shotgun-explosive device containing a housing in which cumulative charges in contact with a detonation transmission system located along the device axis are spread in tiers along its axis, characterized in that the cumulative charges are arranged along helical lines, the number of which is equal to the number of cumulative charges in each tier, and between the cumulative charges in each tier detonation-related inserts of explosives are installed, while the cumulative charges and inserts of explosive are located s uniformly around the circumference in each tier.  2. The device according to p. 1, characterized in that on the axis of the device between the tiers are installed ring charges detonation associated with the cumulative charges of adjacent tiers.  3. The device according to paragraphs. 1 and 2, characterized in that the cumulative charges are installed in modules of inert material.

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