RU198026U1 - CUMULATORY CHARGE HOUSING - Google Patents

Abstract

The utility model relates to the manufacture of cumulative charges for perforation systems used to enhance oil recovery, specifically, to the design of the shells of cumulative charges. The objective of creating a utility model is to increase the penetration depth of a surface with a charge while simplifying its manufacture. Technical result of the claimed solution: increase the penetration depth of a surface. This problem was achieved in the case of a cumulative charge made in a curved shape with a cylindrical section at the outlet, characterized in that it is made by stamping from a sheet, and the height of the cylindrical part is made from the ratio h = (0.3 ... 0.35) N, where h- the height of the cylindrical part; H is the total height of the body. After stamping, mechanical refinement of precise surfaces, for example, with their turning groove, can be performed. 1 s.p. f-ly, 3 ill.

Description

The utility model relates to the manufacture of cumulative charges for perforation systems used to enhance oil recovery, specifically to the design of the shells of cumulative charges.

Known housing the cumulative charge according to the patent of the Russian Federation for the invention No. 2351878, IPC F42B 1/028, publ. 04/10/2009

This body is machined in a conical shape with a transition to the cylindrical part at the outlet. The height of the cylindrical part is not indicated.

Disadvantages: manufacturing complexity and shallow penetration depth.

Known housing the cumulative charge according to the patent of the Russian Federation for the invention No. 2442948, IPC F42B 1/032, publ. 02/20/2012

This body is machined in a conical shape with a transition to the cylindrical part at the outlet. The height of the cylindrical part is not indicated.

Disadvantages: manufacturing complexity and shallow depth of penetration.

Known housing the cumulative charge according to the patent of the Russian Federation for the invention No. 2638066, IPC F42B 1/02, publ. 12/11/2017 prototype.

This case is made by machining, shaped, with a transition to the cylindrical part at the exit. The height of the cylindrical part is not indicated.

Disadvantages: manufacturing complexity and shallow penetration depth.

The task of creating a useful model: increasing the depth of penetration by a surface charge while simplifying its manufacture.

Effect: increase the depth of penetration of the surface.

The solution of this problem was achieved in the case of a cumulative charge, made in a curved shape with a cylindrical section at the output, characterized in that it is made by stamping from a sheet, and the height of the cylindrical part is made from the ratio

h _c = (0.3 ... 0.35) N _total ,

where h _c - the height of the cylindrical part,

N _total - the total height of the hull.

After stamping, mechanical refinement of precise surfaces can be performed, for example, with their turning groove.

The invention is illustrated by drawings of FIG. 1 ... 3, where:

in FIG. 1 shows the design of the housing,

in FIG. 2 shows a view A, chamfered holes,

in FIG. Figure 3 shows the results of a test for breaking through steel plates with a charge obtained by stamping.

The housing 1 (Fig. 1) is made of three parts: radial 2, conjugated with radii R ₁ and R ₂ , with cylindrical 3 from the exit side of the cumulative jet and the upper one as part of a sphere 4 of height h _k (Fig. 1). At the top of the sphere 4, a hole 5 is made with a chamfer 6 from the inside. Bevel angle α = 100-110 °. The fillet is made with radii R _ext and R _nar .

The body is made by stamping. This made it possible to increase the penetration depth by the charge of the steel wall, which is confirmed in Table. 1 and in FIG. 3.

After stamping, mechanical refinement of precise surfaces, for example, a cylindrical surface 7, with its turning groove, can be performed.

As a result of comparative tests of cumulative charges with turned and stamped bodies, the following results on the penetration depth of the table are obtained. 1.

From the table. 1 it follows that the use of a stamped body increased the penetration depth by 7 ... 8% compared with the chiseled one.

The penetration depth, as shown by the tests shown in FIG. 3, their results are shown in table. 2, it turned out maximum in the following ratio of the dimensions of the cylindrical part and the total height of the housing.

The depth of penetration of the jet is a function of the density of the shell material, the ductility of the material under conditions of high-speed deformation and the volumetric speed of sound in the body material. The volumetric speed of sound in a stamped material is 20% higher than in a machined material, which increases the depth of penetration of the cumulative jet into the material being pierced. Also, the penetration ability favorably contributes to the optimum ratio of the dimensions of the cylindrical part of the shell.

Requirements for other sizes:

d = (6% ... 7%) D ₀ , where:

d is the diameter of the hole

D ₀ - inner diameter of the base

bevel angle 5:

α = 100 ° ... 110 °

The wall thickness of the body is made constant:

δ _article = R ₁ -R ₂ = (8% ... 10%) D _about ,

where: δ _st - wall thickness,

R ₁ is the outer radius

R ₂ is the inner radius.

The work of the cumulative charge with the proposed housing

When detonating an explosive (the charge in FIGS. 1 and 2 is not shown) from a detonating pulse received through hole 5 and chamfer 6, where in an expanding channel it accelerates to supersonic speeds (FIGS. 1 and 2), a supersonic jet having a very high temperature burns out the lining (not shown) and pierces the surface (Fig. 3). With the indicated ratios of the case dimensions, the penetration depth is maximal.

A large experimental batch of cases was manufactured and bench tests were carried out.

Application of the utility model allowed:

- increase the penetration depth of the material,

- simplify the technology,

- accelerate the production of cases,

- expand the range of charges for perforation systems designed for oil and gas production.

Claims (5)

1. The body of the cumulative charge, made in a curved shape with a cylindrical section at the output, characterized in that it is made by stamping from a sheet, and the height of the cylindrical part is made from the ratio h _c = (0.3 ... 0.35) N _total , where h _c - the height of the cylindrical part; H _total - total height of the body. 2. The case of the cumulative charge according to claim 1, characterized in that after stamping, mechanical refinement of the exact surfaces is performed, for example, by their turning groove.

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