HU183623B - Effect increasing lining material particularly for perforating pipes of producer hydrocarbon wells - Google Patents

Abstract

The liner of a hollow charge that is to be used for perforating pipes of hydrocarbon-producing wells consists of elementary bismuth, an alloy thereof, or a metal mixture thereof. Preferred are eutectic alloys consisting of: 55.5% Bi and 44.5% Pb; 58% Bi and 42% Sn; 60% Bi and 40% Cd; 28.5% Pb, 14.5% Sn, 9% Sb, 48% Bi, or Bi/Co alloy containing 0.7% Bi.

Description

BACKGROUND OF THE INVENTION The present invention relates to a high-performance hollow explosive charge fitted with a residual liner cone, particularly for perforating pipes in hydrocarbon producing wells.

In shallow-bore wells, the layers to be put into production are opened by installing a surface-mounted filter and forming a frame made of gravel of a certain mesh size. At deeper wells, such as hydrocarbon wells, filtering equipment is generally not possible. In such cases, the layer to be put into production or tested is opened by perforating the cemented pipe.

The purpose of perforation is to establish a hydraulic connection between the permeable layers drilled through the drill and the space inside the pipe, or to put the layer into production, possibly by applying fluid treatment materials, or by displacing water, gas, etc. in tertiary production. to allow its injection.

Hydrocarbon wells have been extensively used for perforating pipes from hollow explosives. The hollow explosive charge is the most commonly used type of directional explosive charge, in which the perforating effect of the perforation results from the concentration of the explosion energy in the direction of the rotationally symmetrical, generally conical, hollow axis. The efficiency of energy transfer multiplies when the cavity formed in the explosive charge is lined with metal. Cavity explosive seals are generally initiated at their opposite end to the axis of rotation, i.e. properly induced to explode, so that the wavefront of the explosion is perpendicular to the axis and, when introduced into the lining material, accelerates strongly toward the interior of the cavity. At the intersection of the liner material with the collision wall, a pressure of tens of thousands of MPa is created, which extracts part of the liner material at an axial velocity higher than the explosion rate. The hydrodynamic theory developed for the mathematical description of the phenomenon treats the metal-lining material as an ideal fluid because of its high pressure.

Lining materials used for hollow explosive charges may be made of steel, aluminum, copper (J. Applied Physics, 1948, 563-582), as well as lead, nickel, silver, magnesium, cobalt, tin, zinc or cadmium (Explosivstoffe, 1959, 155-167). Lining materials of iron-containing glass, high ferro-silicon-containing ceramic materials and high graphite cast iron are also known (German Patent No. 1,139,418).

No. 1 076543. U.S. Patent No. 4,600,600 describes the use of tin-coated copper balls as a lining material. No. 146,290. According to Hungarian Patent Specification, sintered and pressed iron, copper or titanium powder is used as a lining material, while U.S. Pat. According to the Hungarian patent application titanium or a mixture of aluminum and iron oxide is used for this purpose.

Special alloys have also been described as the lining material for hollow explosive charges, such as antimony and nickel powder blended in a sectic alloy of lead, antimony, tin and zinc (U.S. Pat. No. 3,112,700).

Mixtures of rare earth metals for lining materials have also been described (German Patent No. 1,182,567).

A common disadvantage of most of the known blast fillers with known lining material is that only a small proportion of the lining material is accelerated to a very high speed of 500010000 m / s and forms a cumulative radius that actually punctures. Most of the liner material is a metal rod shorter than the cumulative beam but with a larger diameter, which follows the cumulative beam at a 50-70% lower rate. This metal mass, which is relatively slow but has a large diameter relative to the diameter of the hole, will in many cases obstruct the cavity punched into the well. As a result, the perforation of the cemented pipes in the hydrocarbon wells will not be satisfactory due to the presence of a metal plug in the wells.

Known lining materials made of metal powders do not form a plug, but the depth of the punched hole is less than the depth of the holes formed with massive metal-lined charges.

It is an object of the present invention to provide a hollow explosive charge in which the well is perforated with high efficiency, i.e. a large diameter hole is formed without the metal plug being formed in the hole.

It has been found that the above object is achieved by using a bismuth alloy and / or a bismuth metal alloy and / or elemental bismuth as a potentiating agent for hollow explosive charges used for perforating hydrocarbon wells.

The present invention is based on the discovery that the known enhancement liners, despite high pressures, do not behave as ideal fluids during cumulation, since deformation and shear forces occur within the liner and the energy used to overcome them reduces the cumulative radius of motion. energy. On the other hand, during the flight of a high velocity metal beam, due to the velocity gradient that occurs during accumulation, it is stretched, fragmented, and the unrelated cumulative ray penetrates only a short distance into the target. Surprisingly, our studies have shown that lining materials made from bismuth alloys and elemental bismuth itself have low work losses, high kinetic energy, and act as an almost ideal fluid for cumulative beam formation. So far, no bismuth or bismuth alloys have been used for this purpose.

The lining material of the high performance hollow explosive filler according to the invention contains 0.5-100% bismuth and is known in the art for rotationally symmetrical, generally cone, double cone, truncated cone, etc. can be shaped.

A preferred embodiment of the hollow explosive charge according to the invention consists of linings of bismuth-containing eutectic alloys, such as those containing 55.5% bismuth and 44.5% lead (m.p. 124 ° C), 58% bismuth and 42% tin. (op. 140 ° C), alloys containing 60% bismuth and 40% cadmium (op. 140 ° C) or alloys containing 48% bismuth, 28% lead, 14.5% tin and 9% antimony (op. 226 ° C) They are.

These cone-shaped liners made from 48 to 60% bismuth containing eutectic alloys, while not creating any plugs in the punched hole, also significantly increase the permeability of the blank explosive charge. With a 60-tapered conical liner, the same hollow explosive charge is 50-70% larger

183,623 can efficiently accelerate the use of the above bismuth containing eutectic, either alone or in admixture with copper / bronze powder, as a suppository material instead of the known copper. The reduction in energy used to crush the cone-shaped liner and the coherence that remains at high radius increases the penetration depth by 20-60%, without creating a massive metal plug.

Another preferred embodiment of the hollow explosive filler lining material of the present invention is lining materials made of relatively low bismuth bismuth copper alloys. These alloys are extremely brittle at very low levels, such as 0.7% bismuth, and break down into a dynamic force such as a detonation shock wave, resulting in an ideal perforation.

A further preferred embodiment of the high-performance, non-lining hollow explosive charge of the present invention consists of only bismuth lining materials. These provide extremely high penetration depths without plug formation.

a comparison was made between the hollow explosive charges of the present invention and the known copper lining material. The hollow explosive charge, which is otherwise identical, is provided with an aluminum block with two types of liner material. We performed 20 to 20 shots and determined the minimum and maximum penetration depths as well as the mean and examined for possible plug formation. The results are shown in the table.

Comparison of an embodiment of the invention with the known hollow filling:

Hollow explosive charge

Bismuth containing Copper lining with lining material

It can be seen from the table that the minimum penetration depth for the hollow fill according to the invention is the same as the maximum penetration depth for the filler of known lining material. The average penetration depth of the filler according to the invention is 44% longer than that of the reference filler of known lining material.

It is also clear from the table that no plug formation occurs in the fill of the invention.

The hollow explosive charge according to the invention provides various technical and economic advantages.

In hydrocarbon wells, the deeper and unobstructed penetration channels into the cemented pipes improve the hydraulic connection between the storage layers behind the cemented pipes and the space inside the pipe. As a result, for example, more hydrocarbon can be extracted from the wells.

Given that the length of the penetration channel increases during the perforation and the channel does not contain a plug, the specific number of shots per unit well can be reduced to achieve the same flow result.

Claims (2)

CLAIMS 1. A high-performance hollow explosive charge filled with a lining cone, characterized in that the lining cone material consists of a bismuth alloy and / or a bismuth metal alloy and / or elemental bismuth for perforating the pipes of hydrocarbon producing wells. An embodiment of a high-performance hollow explosive charge fitted with a residual lining cone according to claim 1, characterized in that the material of the lining cone is: 35 bismuth containing alloys of eutectic composition. Penetration depth, mm minimum 165 102 maximum 225 166 average 189 131 Plugging or. lining- residual occurrence frequency,% 0 55