RU2384695C2 - Implosator - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention relates to oil-and-gas production field, and it is used in wells during intensification of hydrocarbon raw material extraction producing formation. Implosator includes shaped-charge perforator, shaped charge of which is fixed opposite to implemented in its casing muffled radial openings, connected to casing shaped-charge perforator one or several hollow pipes, forming implosion chambers, cable head with hoist cable. Implosator is implemented as multistage and consists of set interlaced in different amount imgagozion chamber, changing working volume of implosator. Additionally between mentioned chambers it is located at least one casing shaped-charge perforator, in which with specified sequence there are installed cumulative charges with coating or without it, able to cover radial openings in casing shaped-charge perforator with formation of cumulative jet or without it. Additionally different sets of implosion chambers are implemented with ability of interlace with different sets of shaped-charge perforator depending on well conditions.

EFFECT: effectiveness increasing of implosator operation.

3 dwg

Description

The invention relates to the oil and gas industry. It is used in wells for the intensification of hydrocarbon production from the reservoir.

It can also be used to increase the production rate of artesian wells.

The main physical principle of the device is implosion (explosion inside).

Known devices operating on the principle of implosion. The device (see AS USSR No. 369247, class E21B 43/18, 1967) contains a cylindrical metal hollow body with bleed holes, a replaceable fitting, a glass plug, which is destroyed by an electric detonator.

The disadvantage of this device is that the absorption of the borehole fluid into the imploser occurs from the lower end through the neck, which is closed by a plug, which is destroyed by the electric detonator. This reduces the efficiency of the imploser.

The intensity of depression on the formation depends on the opening speed of the neck, its area and the working volume of the implosion chamber of the imploser. The faster and over a larger area the working chamber of the imploser opens, the more efficient its operation.

In this case, the borehole fluid cannot be immediately absorbed into the entire working volume of the imploser due to the limited capacity of the neck. In this regard, the "explosion inward" is stretched in time, reducing the effectiveness of the impact on the reservoir.

A device is known for increasing formation productivity by the implosion method (see US Pat. RF No. 2039221, C ₁ 6 E21B 43/18, 43/25, 1992).

The device contains a hollow tube, which is a hollow body of an imploser with an opening in the lower part, which is closed by a cover that is destroyed by an electric detonator. The full body of the imploser, made of a pipe, is equipped with a damper dividing the cavity of the body into separate chambers, which eliminates the water hammer that occurs when the well fluid collapses.

The disadvantage of this device is that the intensity of the depression on the formation is limited by the diameter of the suction hole, the diameter of which, at best, is equal to the diameter of the borehole imploser itself.

Due to the limitation of the intensity of depression, the effect of “explosion inward” grows in time and the implosion impulse does not provide “shooting” of the mud and sludge from the pores of the formation through channels and perforations in the casing inside the well. This reduces the efficiency of the device.

Closest to the proposed invention in technical essence is a device (US Pat. RF No. 2072421, ЕВВ 43/117, 43/18, 43/25, 01/27/1997) - a prototype containing a hollow body with plugged holes, cumulative charges placed in it, detonating cord and explosion cartridge, implosion chamber, the internal cavity of which is connected to the internal cavity of the housing. The device is equipped with an additional implosion chamber, with one of the implosion chambers placed on top and the other below the body. The cavity of the implosion chamber can be separated from the membrane body.

The disadvantage of this device is the presence of only 2 implosion chambers, and even equipped with membranes that carry out the selection of well fluid in steps.

This reduces the efficiency of the device.

The technical result of the invention is to increase the efficiency of the imploser.

This is achieved by the fact that the imploser is multi-tiered and consists of a set of implosion chambers alternating in different numbers that change the working volume of the imploser, while at least one case shaped cumulative perforator is installed between these cameras, in which cumulative charges are installed with or without facing capable of opening radial holes in the body of a cumulative punch with the formation of cumulative jets or without them, while various sets of implosive Amer are arranged to interlace with different sets of cumulative perforating depending on well conditions. This allows you to increase the flow rate of the well and to process several intervals of perforation of the casing string of the well in one round trip of the imploser, that is, it will increase the efficiency of the imploser.

The large opening area of the imploser and the lack of stepiness in its work allows depression on the formation to instantly reach its maximum value. In this case, the intensity of depression is also maximum. The leading edge of the depression pulse approaches the vertical one, which ensures the explosive nature of the “ejection” of the mud and sludge from the reservoir and perforation channels into the well.

Distinctive features of the claimed invention are the following.

1. The imploser is multi-tiered and consists of a set of implosion chambers alternating in different numbers, changing the working volume of the imploser. Between the chambers is placed at least one case shaped-type punch.

2. For the operation of the imploser, cumulative charges are used that can open individual holes in the body of a cumulative perforator with the formation of cumulative jets or without them.

3. The working volume of the imploser is included in the work immediately and all. This allows you to generate a depression impulse with a vertical leading edge, providing a "shooting" of mud and sludge, cleaning the reservoir and perforation channels, which increases the flow rate of the well.

4. The imploser allows the suction radial holes of the perforator to be stacked, specifically against perforation intervals along the depth of the well, in any combination alternating tiers.

5. The imploser allows you to make additional cumulative perforation before the start of the implosion, if necessary for geological and geophysical indications, and allows you to ensure the stability of the casing string for cracking.

Comparison of the claimed technical solution with the prototype allowed us to establish the following common features.

1. The presence of a corpuscular cumulative perforator in the imploser.

2. The presence of implosion chambers.

The proposed technical solution meets the criterion of "novelty."

In the study of other well-known technical solutions in this field on the basis of the relative position of the elements, the emergence of new relationships between elements and devices revealed "significant differences". The proposed imploser also expands the arsenal of technical equipment for a similar purpose.

In more detail, the invention will be described below.

Figure 1 presents a schematic drawing of the proposed imploser; figure 2 - hole 11 in magnification; figure 3 - group cumulative charge.

The imploser has a cable head 1 with a logging cable 2, connected to the first implosion chamber of the imploser 3, made of a hollow pipe, inside of which an electric core of cable 4 passes.

A case-shaped cumulative perforator 5 with a cumulative charge 6, 7 and 8, with a detonating cord 9 and an electric detonator 10 connected to an electric core cable 4 is screwed to the implosion chamber 3.

Cumulative charges are fixed against the radial holes 11 of the perforator 5, closed by a disk 12 and a rubber stopper 13.

Next, the next implosion chamber of the imploser 14, identical to chamber 3 and also made of a hollow tube closed from below by a tip 15, is attached to the body of the perforator 5.

1 also shows a casing 16, a perforation channel 17, a pest 18, a borehole fluid 19, a cement ring 20, a producing formation 21.

Figure 2 - enlarged hole 11, the casing 16, the borehole fluid 19, the cement ring 20, the reservoir 21 and the perforation channel 17.

Figure 3 shows the group cumulative charge 8, which immediately opens 4 holes in the housing of the cumulative perforator 5.

The imploser works as follows.

The imploser is lowered into the well to a predetermined depth, for example, 2 km, where it is necessary to actuate it and clean the perforation channels in the casing, cement ring and in the reservoir, in order to intensify the flow rate of the well. For example, well fluid we take water with a specific gravity of Y = 1 g / cm ³ . Inside the imploser, the pressure is atmospheric. The imploser is sealed. Inside it, standard cumulative charges are installed in the standard housing of the case shaped-charge perforator, for example, PK-103. If there is a lining charge in the cumulative funnel, the cumulative charge forms a cumulative stream during the explosion, which punches the disk 12, the plug 13, opening the radial holes 11, then the jet pierces the casing 16, cement ring 20 and the productive formation 21, forming the so-called perforation channel 17. The lining is made of copper, mild steel or alloys. The cumulative jet has a significant velocity gradient. So, if the speed of the head of the jet is 8 km / s and it contains 6: 10% of the mass of the liner, then the tail of the jet, with the rest of the mass, constantly lagging behind the head and stretching the jet, moves in the form of pest 18 at a speed of 6 km / s, without possessing breakdown force, and in the form of a deformed piece of metal gets stuck in the perforation hole of the casing (see figure 1, pos. 18). This reduces perforation efficiency.

The increased density of the perforation leads to a violation of the integrity of the casing string and the failure of the well. The optimal density of the perforation should provide a compromise between the resistance of the casing to fracture and the hydrodynamic perfection of opening the reservoir, so the charges in the perforator are selected so that only part of them has a metal lining, and the other part does not. The "shot" of the formation, with a thickening density of perforation, is determined by the geophysicist. In this case, all the radial holes 11 of the punch must be open. To open the holes 11 without breaking the casing string 16, cumulative charges are used without facing the cumulative charge funnel.

If the charge without facing or has paper facing, or if the cumulative funnel is simply covered with paint or varnish, then such a charge with its cumulative stream will only open hole 11, but will not penetrate holes in the casing and the column will maintain its integrity. Detonation products, with a temperature of ~ + 4000 ° С, will be lined inside the borehole, warm the borehole fluid and the internal cavity of the old perforation channels to a temperature exceeding the temperature at this depth. (Geothermal gradient + 33 ° C per 1 km of well depth). Further, the process will develop as follows.

Known process parameters are as follows.

- The volume of gaseous detonation products. For TNT - RDX charges, this volume is 1000 l / kg.

- The weight of the cumulative charge along with an additional detonator for PK-103 is 21.5 g.

- If we consider a 10-charging PK-103, then the total weight of the explosive, taking into account the electric detonator and the detonating cord, will be approximately 250 g.

- The amount of gas produced will be 400 liters.

- Given the hydrostatic pressure of the water column in the well, this volume will be 2 liters.

If we take into account that part of the gases ejected from the PK-103 into the well through the holes 11, then there will be even less gases inside the imploser.

We take the total volume of the imploser 25 l, then the free volume, net of gaseous detonation products, will be 23 l. Due to the fact that the radial holes of the perforator open all at once and instantly, and the chambers of hollow steel pipes are located above and below the perforator, the suction of the well fluid inside the imploser will go over a large area. The reservoir will feel an “explosive” discharge from the hydrostatic pressure of the liquid column. A sharp drop in pressure will lead to swelling of the surface of the perforation channels and reservoir pressure from them will "shoot" all the sludge and mud in the well and into the imploser. Pestles will also be shot “inward explosion” and fall into the sump of the well. There will be a deep explosive cleaning of all perforation channels of the formation through which the fluid enters. The permeability of the reservoir is restored.

Further, the hydrostatic column of the borehole fluid, collapsing, creates a cavitational hydraulic shock, which, in the cleaned channels and the formation, will create cracks that increase the area of the fluid recovery of the formation into the well. If there are places free of cumulative charges in the PC-103 case, the openings 11 located opposite them remain covered by disks 12 and plug 13. The disks are installed taking into account hydrostatic pressure at the depth of immersion of the imploser. They are made of different thicknesses and from different metals. As a rule, it is aluminum or steel. In our case, the hole 11 will be covered by an aluminum disk.

After the imploser is triggered, those disks that were not knocked out of the holes by the gas pressure from the explosion will be destroyed and driven or punched into the imploser by a hydraulic shock of a water column in the well, which also increases the opening area of the implosion chamber. Water hammer, as a pressure impulse, will repeatedly propagate up and down the wellbore in the water, changing the polarity on the surface and bottom of the well with attenuation. The positive and negative polarities of the pulse, swinging the reservoir, also increase the effect of implosion.

In addition, a pressure impulse, like a seismic signal, will propagate through the reservoir, creating seismic vibrations in it, restoring the permeability of the reservoir, which also works to achieve a technical result.

After the imploser is triggered, it is raised with a logging hoist to the day surface and, if necessary, is equipped again and lowered into the same or another perforation interval.

The imploser can be assembled in many tiers, alternating different volumes of perforators and different volumes of hollow pipes and grouping them in different ways. At the same time, the widest selection is possible by matching them into groups. In addition, it is possible to vary charges with and without cladding. All this works to increase the efficiency of the imploser and, ultimately, to increase the flow rate of the well. Thus, a technical result is achieved.

In the imploser, it is possible to use disposable perforators such as PKO. The imploser is technically applicable, since it uses known and proven devices in field geophysics. So, for example, the chamber of an imploser from hollow pipes can be made of tubing (N.K.T.) of the corresponding diameter and wall thickness.

Claims (1)

An imploser, including a cumulative perforator, the cumulative charges of which are fixed opposite the muffled radial holes made in its body, one or more hollow pipes forming implosion chambers connected to the body of the cumulative perforator, a cable head with a wireline cable, characterized in that the imploser is multilevel and consists of a set of implosion chambers alternating in different numbers, changing the working volume of the imploser, while at least between these cameras at least one case-shaped cumulative perforator, in which cumulative charges with or without cladding are installed with a certain sequence, capable of opening radial holes in the body of the cumulative perforator with the formation of cumulative jets or without them, while different sets of implosion chambers are made with the possibility of alternating with different sets cumulative perforators depending on downhole conditions.

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