RU2091697C1 - Method of blast cutting of metalworks and line shaped charge for its realization - Google Patents

Abstract

FIELD: cutting of plate metal and members of various metalworks. SUBSTANCE: metal facing is installed on metalwork 1. Then profiled rod 2 of elastic explosive is attached close to the facing. The charge is blasted. The line shaped charge uses elastic profiled rod 1 of explosive, which in cross-section represents a trapezoid with height and layer base B, smaller base - 0.3 B. The shaped recess is a cone with height 0.45-0.55B and base B. Shaped recess facing is made of heavy plastic material. EFFECT: enhanced efficiency. 3 cl, 4 dwg

Description

 The invention relates to the field of blasting, in particular, new technologies that use explosive energy to cut sheet metal and elements of various metal structures using linear or elongated cumulative charges (LKZ or UKZ).

 The method and charge are intended for use in the nuclear, chemical industry, in the oil production complex and other industries for explosive cutting of large structures and structures, including under water.

 There is a method of explosive cutting using detonating cords [1] which consists in the fact that the detonating cord is installed on a metal structure under water and undermine it.

 The detonating cord is an easily deformed metal profile with longitudinal channels. The first channel is filled with explosive (BB), the second channel, hermetically sealed at the ends, is filled with gaseous material. The partition creating a cumulative effect separates the two channels.

 The detonating cord acting under water serves to cut the steel hulls of ships.

 There is also a method of explosive cutting using elastic LKZ or UKZ [2,3] consisting in the fact that LKZ, made in the form of elastic cords or rods with a longitudinal cumulative recess, impose on the surface of the cut structure, reproducing its contours, and fix on the desired contour cut using the simplest means (twine, tape with a sticky layer, etc.), and then undermine. Of the known elastic charges that are openly used in industry, the most widely used are the charge of the ShKZ type (cord shaped charges) produced by the NPO Crystal (Dzerzhinsk, Nizhny Novgorod Region).

 ShKZ charges are elastic cords or rods with a longitudinal cumulative recess lined with metal. A metal plastic used for facing a polymer-based substance containing a significant (≈ 85%) amount of powdered iron or copper, as well as explosives, which has the property of elasticity.

, при этом H ≈ B) с параболической кумулятивной выемкой. Высота заряда в сечении - H, которую можно принять за калибр, изменяется от 9 мм для ШКЗ-1 до 32 мм для ШКЗ-6.ShKZ charges have several standardized sizes (from ShKZ-1 to ShKZ-6), which differ in caliber (the largest cross-sectional size). In the cross section, they have a profile close to semi-elliptical (taking charge height H for the major half-axis and a small half-width for

, with H ≈ B) with a parabolic cumulative notch. The charge height in the section - H, which can be taken as a caliber, varies from 9 mm for ShKZ-1 to 32 mm for ShKZ-6.

The maximum thickness of a steel sheet cut by a charge of the largest caliber is ≈ 25 mm. ShKZ charges and cutting method with their help are taken as a prototype of the proposed method and charge. They have the following technical disadvantages:
1) the method and charge does not allow cutting under water;
2) the method does not allow cutting large-sized thick-walled structures (with a wall thickness t ≃ 40-100 mm);
3) the method and charge are mainly focused on cutting structures for scrap and do not allow cutting with a high quality of the cutting surface, for subsequent installation and welding.

 These disadvantages are eliminated in the claimed method and charge.

 The technical task to be solved is the development of an explosive cutting method using a new type of LKZ, which provides the possibility of explosive cutting of structures made of high-strength materials having, in general, indirect contours and wall thicknesses of 40-100 mm, on an open surface and under water, with high accuracy and the quality of the cut surface, with a greater safety of work compared with the prototype. Such tasks arise during the repair and dismantling of chemical and nuclear installations, offshore drilling platforms, nuclear submarines and surface ships of the Navy, etc.

The technical problem is solved by the fact that the proposed method of explosive cutting, which consists in placing on the surface of the cut structure of a linear cumulative charge and undermining it, in which, according to the invention, pre-produce laying along the cut contour of the metal lining, which is pre-shaped (curvature) corresponding to the contours structures, reliably fix the cladding, and then close to it fix the charge of an elastic explosive. When cutting under water, the cavity between the lining and the structure is preliminarily isolated from water by placing a waterproof insert made of a low-density substance (for example, foam, ρ ≅ 0.1 g / cm ³ ) or an airtight shell into which compressed gas is supplied before undermining.

 The inventive method is implemented using LKZ, consisting of an explosive charge, in the form of an elastic profiled rod with a longitudinal cumulative recess, and a cumulative recess lining, in which, according to the invention, the charge cross section is a symmetrical trapezoid with a large base B, height HB, smaller base b 0.3 V, and the cumulative recess is made from the side of the larger base and represents a triangle in cross section with a height of h 0.45-0.55 H and the base C ≃ B, the cumulative lining is made of heavy plastic metal and with a profile in the zone of contact with the charge corresponding to the profile of the cumulative recess reproducing the contours of the structure, while the lining and the explosive charge form a contour corresponding to the cut contour.

 Distinctive features of the proposed method are pre-laying and securing along the cut contour of the metal lining of the cumulative recess, which is given a shape corresponding to the contours of the structure, and the subsequent fastening of the elastic explosive charge to it. When cutting under water, in addition, the placement in the cavity between the structure and the liner liner of a low-density substance or a sealed shell into which compressed gas is supplied before undermining.

 The indicated differences achieve the removal of restrictions on the charge gauge arising from non-linear contours of the structure, due to the fact that the larger the charge gauge, the more difficult it is to change its original shape. Most of the known LKZ, including the prototype, provide a maximum cutting depth not exceeding 20-25 mm for steel, with charge calibers 25-35 mm. There are no fundamental restrictions on increasing the LKZ caliber to at least 100 mm; there is also a practical need for charges of such a caliber.

 The limitation of the use of large-caliber charges is associated with the difficulties of their use in indirect cuts. The achieved gauge values (25-35 mm) for most types of LKZs are the practical limit at which the possibility of changing the shape of the charge to the required samples during its use remains. This applies to both charges in the form of deformable metal profiles and elastic charges. You can try to give the desired shape to a large-caliber elastic charge (with an elastic lining), but at the same time, due to large deformations of the charge in the region of the cumulative recess, the initial shape of the lining is lost and the efficiency of the cumulative charge is significantly reduced. Charge efficiency with a metal lining is lower than with a solid plastic metal lining. Thus, the charge efficiency with a metal lining, which is preliminarily given a shape corresponding to the contours of the structure, and having a calculated profile is much higher than a similar explosive charge, which is required to be given the required shape.

 Giving a large-caliber charge (H ≥ 35 mm), assembled with a metal cladding, of a forced shape significantly different from a straight one at the place of work, is unrealistic, due to the required significant efforts and mainly due to the deformations and ruptures of the cladding, delamination it from a charge, etc. defects, the presence of which is unacceptable. Preliminary execution of the facing of the desired profile and shape and fitting its shape to the design at the place of work with the subsequent charge assembly does not present significant difficulties and allows you to remove the caliber restriction for non-linear cut contours. It should be noted that in most cases, non-linear cuts have a circular shape: a cut of cylindrical or other surfaces of revolution or circular cuts in a plane. This facilitates the implementation of the metal cladding of the required curvature and profile.

 To perform cuts under water, the cavity of the cumulative recess in the inventive method is filled with a low-density substance or gas. (The latter is more preferred). To perform this operation, it is necessary to ensure reliable fastening of the charge to the structure, eliminating the ingress of water into the cavity in an uncontrolled manner, or the discharge of the charge from the structure under the influence of a liner or shell with compressed gas. Securing a large-caliber charge is generally a difficult task, especially under water. Separation of charge and cladding fastening operations in the claimed method allows preparatory operations (in the absence of VMs at the place of work) to ensure reliable cladding fastening with a liner and structures using the usual arsenal of tools and devices used in such works, including perforated welding, pneumatic shock equipment, the use of which, if there is an explosive at the place of work, is excluded or difficult. This increases the safety of work compared to the prototype. The subsequent fastening of the explosives to the lining can be carried out in advance by preparatory simple means: brackets, clamps, wire binding, etc.

Distinctive features of the proposed LKZ are:
1) charge profile in cross section (shape);
2) quantitative ratios characterizing the proportions that ensure the greatest efficiency of the charge: BH, b 0.3H, h = 0.45-0.55 H, C ≃ B;
3) facing material;
4) the shape of the cladding (in cross section and along the contour).

 The claimed profile of the charge in the cross section ensures its high efficiency when satisfying relations 2) and, in addition, is the most technological in comparison with the profiles formed by smooth curves (semi-elliptic, parabolic, etc.). This is important both in the manufacture of charges from an elastic explosive and metal cladding.

 The specified ratio of the parameters together provides a high gas-dynamic charge efficiency. In combination with a metal lining, the charge efficiency with such a profile, measured by the depth of cut, is two times higher than that of the prototype. This has been proven by numerous experiments. For one particular case, comparison with the prototype is carried out below. Deviation from ratios 2) in the range of 5-10% does not lead to a significant deterioration in the work of the charge, and with large deviations, the charge efficiency decreases sharply.

 As the cladding material in the claimed LKZ, mild plastic steel (iron) or copper (in special cases, other similar metals) is used. The mild steel cladding provides the required parameters of the cumulative jet and can be made by known technological methods. The fastening of such a cladding can be carried out by welding, soldering, as well as using powerful permanent magnets.

 The shape of the cladding in cross section provides the desired shape (profile) of the cumulative recess, as well as the location of the charge in the required manner relative to the surface of the structure, i.e. at the required angle and at the required (focal) distance of the top of the cumulative recess from the surface. The shape of the lining along the contour allows cutting structures with non-linear contours. The circular shape of the cladding along the contour can be achieved using simple bending devices.

 Figure 1 shows the inventive LKZ; figure 2 installation LKZ on the cut design.

 The inventive LKZ is as follows.

An elastic explosive (detonation velocity D 7.5 • 10 ³ m / s, density ρ 1.66 g / cm ³ ) is made of bar 1 with the claimed profile of the required caliber. The technology for manufacturing charges of 10 to 100 mm caliber has been developed. Charges are made by pressing on high-performance equipment. A parametric series of calibers is provided in the range of 10-100 mm, providing the need for practice. The cost of manufacturing charges is estimated to be 20-30% lower than that of the prototype. The metal cladding 2 in the form of a corner profile is made of soft sheet steel, for small calibers - of galvanized sheet iron. The thickness of the sheet depends on the caliber and varies from 0.5 to 1.5 mm. To ensure the required focal length - from the top of the cumulative recess to the structure 4 and the required inclination of the axis of the charge when cutting at an angle other than normal, there are fasteners 3, the design of which can be different depending on the conditions and nature of the work. LKZ assembly is carried out after fitting the lining curvature along the cut contour at the work site. Charges to the place of work can be delivered in bays (for small calibers), and for large calibers (H ≥ 60 mm) in the form of rods with a length of l 1-1.4 m in the corresponding container.

 The charge with the lining is fastened with brackets, tape, etc.

 The inventive method is implemented as follows.

 According to the data on the object of work, the required charge gauge and lining parameters are selected. For large calibers, the cladding is manufactured in the factory using stamping and bending equipment. The bending of small-caliber profiles can be carried out at the place of work using the simplest devices. At the place of work, fitting and fixing of the cladding is carried out. This technological operation can be carried out long before the delivery of explosives to the place of work. The lining can be fastened using welding, shooting equipment, etc. When carrying out unique work, for example, under water, permanent magnets or electromagnets can be used for fastening.

 When working under water in the cavity between the lining and the structure is placed liner 3 (figure 2) or a sealed shell into which compressed gas is supplied before undermining.

 The elastic charge is attached to the lining after all preparatory operations are carried out by explosive specialists who carry out the blasting.

 Thus, the technology provides for the separation of work with and without VM, which significantly reduces the cost and increases the safety of work. This became possible as a result of a successful combination of elastic charge and lining in the form of an angular metal profile, found and realized in the claimed invention, and charge assembly at the place of work.

, шириной

;
облицовка металлопласт на основе меди δ ≃ 1 мм.The technical feasibility and effectiveness of the claimed charge is proved experimentally. Efficiency (penetration depth) and cut quality of the experimental charge, made according to the claimed formula in the center, the ShKZ-6 prototype (on the right) and the semi-cylindrical profile charge used in the industry (on the left) were compared. The explosive characteristics of explosives, of which the charges are made, are approximately the same:
detonation velocity D (7.5-7.6) • 10 ³ km / s;
density r 1.64-1.66 g / cm ³ ;
the profile of the experimental charge is made in accordance with the formula (caliber height in cross section H 32 mm);
galvanized iron cladding d 0.8 mm;
ShKZ-6 standard charge profile is close to semi-elliptical (caliber H 32 mm);
cumulative notch parabolic with relative depth

width

;
Copper based metal lining δ δ 1 mm.

 The linear weights of explosive charges, experimental and prototype, are almost the same. The linear weight of the semi-cylindrical charge is much larger. All charges are mounted on a massive plate of steel St.3.

The following results were obtained:
The depth of cut of the prototype charge was S ≃ 20 mm. This corresponds to the passport data. (The maximum thickness of the cut plate is always greater than the cut depth in a thick plate, due to the dolom). The depth of cut of the experimental charge was S ≃ 40 mm, which is twice as much as that of the prototype. The cut quality of the claimed charge is higher. The cut is more even and narrow.

 The efficiency of a semi-cylindrical charge is much lower, the cut is wide, ragged. In a similar formulation, experiments were carried out with a sample plate made of titanium alloy used in the design of submarines.

 The notch depth from the ShKZ-6 charge was 18 mm, from the claimed charge ≃ 35 mm.

 Thus, it is shown that the effectiveness of the claimed charge is two times higher than that of the prototype.

 The feasibility and effectiveness of the proposed method is proved in various experiments on cutting vessels with water, pipes and other objects.

 Thus, the claimed method, using the inventive device solves the problem of cutting large-sized thick-walled structures, inaccessible to other methods.

Claims (3)

 1. The method of explosive cutting of structures, which consists in placing a linear cumulative charge on the cut structure and detonating the explosive charge, characterized in that the metal cladding is preliminarily laid along the cut contour on the structure, after which a profiled elastic explosive rod is fixed close to it.  2. The method according to claim 1, characterized in that the cavity of the cumulative recess between the cladding and the structure is filled with a low-density waterproof substance or compressed gas in an airtight shell.  3. Linear cumulative charge for explosive cutting of structures, consisting of an explosive charge in the form of an elastic shaped rod with a longitudinal cumulative recess and a cumulative recess lining, characterized in that the cross section of the charge is a symmetrical trapezoid with a large base B, height HB, smaller base b 0.3B, and the cumulative recess is made from the side of the larger base and represents a triangle in cross section with a height of h 0.45 0.55H and the base C ≈ B, the lining of the cumulative recess is made of heavy plastic material with a profile corresponding to the profile of the cumulative recess.

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