RU2241823C2 - Method for directing cumulative charges (variants), directed shooting perforator (variants), method for placing well components (variants), rigid centering holder, device for measuring direction - Google Patents

Abstract

FIELD: perforation technologies.

SUBSTANCE: method includes increasing weight of one or more components of perforators column, while in one or more component material is partially removed for changing gravity center. Directed shooting perforator has one or more cumulative charge having cover, charge body and charge pipe. One or more component of perforator is eccentrically increased in weight, and other one or more components have some material removed eccentrically. Method for placement well components includes lowering one or more focused detectors. One or more well components is detected. Their position is displayed by gyroscope. Rigid centering holder contains transfer sleeve, waist ring, spring stopping ring and stopping ring. Device for measuring direction of cumulative charges has detonating wire and checking device made with possible activation by detonation of detonating wire. Checking device is made with possible use on both ends of perforators column.

EFFECT: higher efficiency.

18 cl, 43 dwg

Description

BACKGROUND OF THE INVENTION

This application is based on provisional application US No. 60/286907, filed April 27, 2001, provisional US application No. 60/306938 filed July 20, 2001, provisional US application No. 60/307086, filed July 20, 2001, provisional US application No. 60/307087, filed July 20, 2001, US provisional application No. 60/310970, filed August 8, 2001, US provisional application No. 60/314200, filed August 22, 2001 and US provisional application No. 60 / ... filed January 23, 2002

FIELD OF THE INVENTION

The present invention relates to the field of perforation. More specifically, the invention relates to devices and methods for both orienting perforating devices and verifying their orientation.

The rocks traversed by a well, especially horizontal or highly inclined wells, are examined to determine the most useful perforation orientation. The desired orientation can be selected based on the possibility of sand production, the existence of strong reservoir pressure and / or shear stress, or the location of control lines and / or other downhole equipment and tools.

State of the art

A known method of orientation of cumulative charges, in which eccentrically weight one or more components of the drill string (US patent 5964294 from 12.10.1999).

US Pat. No. 5,964,294 discloses an orientated firing punch attached to a punch string and comprising: one or more portions of a punch string containing: one or more cumulative charges having a charge shell, a charge housing, and a charge tube, with at least one or more component parts of the drill string are eccentrically weighted to orient the cumulative charges in the desired direction.

A rigid centering holder for orienting perforating devices is known from US Pat. No. 5,964,294.

US patent 5964294, which is the closest analogue for the group of inventions of this application: the method of orientation of the cumulative charges, oriented firing punch and rigid centering holder, does not provide significant orientational torque and orientation in the preferred manner, which are necessary under the above conditions. From the patent SU 224708 of 08/12/1968, a method is known for placing one or more downhole components and displaying from a position at a single descent into a well, in which the detected material is used in one or more downhole components, one or more focused detectors are lowered and one or more downhole components are detected by one or more focused detectors. This patent can be considered the closest analogue to the placement method claimed in this application, but the solution proposed in this patent does not give the desired results in wells with a slight inclination. From publication RU 95119863 from 10.27.1997, a device for measuring the orientation of cumulative charges in an explosion is known, comprising a test device that is kept stationary relative to the orientation of the cumulative charges, a detonating cord that is capable of exploding cumulative charges. In the patent RU 2179235 of 02/10/2002 it is said that a detonation cord is made with the possibility of activating an additional device and a device with such a detonation cord. But the solutions presented in these publications do not allow after the completion of the perforation operation to obtain the actual orientation of the perforation in the well and to verify the orientation of the perforations during the explosion.

Therefore, there is a need for devices and methods for orienting firing rotary hammers and for verifying that the correct orientation has been achieved.

SUMMARY OF THE INVENTION

The tasks are solved due to the fact that the proposed method of orientation of the cumulative charges, in which eccentrically weight one or more components of the drill string to orient the cumulative charges in the desired direction, in which according to the invention one or more components of the drill string are eccentrically weighted by removing material for changes in the center of gravity.

It is desirable that one or more of the components of the drill string is selected from the cumulative charges, charge tubes and drill cases.

It is desirable that a rotary charge tube be used as one or more components of the drill string.

The problem is solved in that in the method of orientation of the cumulative charges, in which one or more components of the drill string are eccentrically weighted to orient the cumulative charges in the desired direction, according to the invention, an articulated articulated charging tube is used as one or more components of the drill string having many segments interlocked with each other so that the individual segments are able to bend, and there is no disengagement.

The problem is solved in that in a method in which one or more components of the punch string are eccentrically weighted to orient the cumulative charges in the desired direction in which according to the invention the bending moment is uneven in one or more of the components of the punch string and compensate for the bending moment .

It is desirable that the unevenness of the bending moment is determined by bending one or more components of the drill string at an angle of deviation of the wellbore and measuring the amount of torque required to rotate one or more components of the drill string to the desired orientation when the angle of deviation is located.

The problem is solved in that in an oriented firing punch attached to the punch string and containing one or more components of the punch string containing one or more cumulative charges having a charge shell, a charge body, and at least one charge tube or a larger number of components of the drill string are eccentrically weighted to orient the cumulative charges in the desired direction, moreover, according to the invention, the shape of the shell of one or more emulative charges altered to displace its center of gravity.

The problem is solved in that in an oriented firing punch attached to the punch string and containing one or more parts of the punch string, comprising one or more cumulative charges containing a charge housing, a perforator housing, a charging tube, according to the invention, at least one or more the component of the firing punch is eccentrically weighted to orient the cumulative charges in the desired direction, the material being removed from the punch body.

Preferably, due to material removal, recesses are formed on the surface of the perforator body.

The problem is solved in that in an oriented firing punch attached to the punch string containing one or more parts of the punch string, comprising one or more cumulative charges having a charge casing, a punch casing and a charging tube, according to the invention, at least one or more the components of the firing punch are eccentrically weighted to orient the cumulative charges in the correct orientation, while material is removed from the charging tube.

The problem is solved in that in an oriented firing punch attached to the punch string containing one or more parts of the punch string containing one or more cumulative charges having a charge casing, a punch casing and a charging tube, according to the invention, the charging tube is rotationally eccentrically weighted the charging tube and the punch body is oriented relative to the rotary charging tube with one or more loads, with one or more loads a punch disposed outside the housing.

It is desirable that one or more loads be provided with rounded ends configured to direct the firing hammer drill through the curvature of the well.

The problem is solved in that in an oriented firing punch attached to the punch string and containing one or more parts of the punch string including one or more cumulative charges having a charge casing, a punch casing and a charging tube, at least one or more firing components perforators are eccentrically weighted to orient the cumulative charges in the desired direction, moreover, according to the invention, the charging tube is made in the form of an articulated charging tube a plug having a plurality of segments interlocked with each other so that the individual segments are able to bend without being disengaged.

The problem is solved in that in an oriented firing punch attached to the punch string containing one or more parts of the punch string, including one or more cumulative charges having a charge casing, a punch casing and a charging tube, one or more parts of the punch string is eccentric weighted to orient the cumulative charges in the desired direction, moreover, according to the invention, the perforator body furthermore comprises an articulated weighted puncture a plate attached to the drill string and having a plurality of segments interlocked with each other so that the individual segments are able to bend without being disengaged.

The problem is solved in that in an oriented firing punch attached to the punch string containing a plurality of firing punch attached to each other with a rigid centering holder, each punch has one or more parts of the punch string, including one or more cumulative charges, having a shell, a shell of a perforator and a charging tube, at least one or more parts of the column of perforators are eccentrically weighted to orient the cumules tive charge in a desired direction, thus according to the invention a hard centering holder is configured to eliminate misalignment resulting from processing tolerances and clearances that exist in a plurality of perforating guns.

The problem is solved in that in the method of placing one or more downhole components and displaying their position during a single descent into the well, in which the detected material is used in one or more downhole components, one or more focused detectors are lowered in conjunction with with a gyroscope, one or more downhole components are detected by one or more focused detectors, and according to the invention, the position relative to stationary position in the casing with one or more downhole components detected, the display is carried out by a gyroscope, and one or more downhole components are control lines.

The problem is solved in that in the method of placing one or more downhole components and displaying their position with a single descent into the well, in which the detected material is used in one or more downhole components, one or more focused detectors are lowered and detected by one or a large number of focused detectors one or more downhole components using one or more focused detectors and according to the invention the position relative to the stationary position in the casing with one or more borehole components detected is displayed, the display is carried out by means of a gyroscope, the detected material being coolant used to pump fluid through one or more borehole components, and one or more focused detectors are devices for thermal detection.

The problem is solved in that in the method of placing one or more downhole components and displaying their position with a single descent, in which the detected material is used in one or more downhole components, one or more focused detectors are lowered in conjunction with a gyroscope, determine one or more downhole components and according to the invention display the position relative to a stationary position in the casing with one or a large number of downhole component parts, the display is carried out using a gyroscope, and the detected material is a smart card type converter used in one or more downhole component parts.

The problem is solved in that in the method of placing one or more downhole components and displaying their position in a single run, in which the detected material is used in one or more downhole components, one or more focused detectors are lowered in conjunction with a gyroscope, detecting one or more downhole components with one or more focused detectors using one or more focused detectors, and agree According to the invention, the position relative to the stationary position in the casing with one or more downhole components detected is displayed, the display is performed by a gyroscope, and the detected material is an electronic tag used in one or more downhole components.

The problem is solved in that in the method of placing one or more downhole components and displaying their position in a single run, in which the detected material is used in one or more downhole components, one or more focused detectors are lowered in conjunction with a gyroscope, detect one or more downhole components with one or more focused detectors using one or more focused detectors and agree invention display position relative to a stationary position in the casing with the detected one or more downhole components, mapping is performed gyroscope, wherein the magnetic material is a detectable label that is used in one or more downhole components and a large number of detectors are focused magnetrons.

The problem is solved in that in the method of placing one or more downhole components and displaying their position in a single run, in which the detected material is used in one or more downhole components, one or more focused detectors are lowered in conjunction with a gyroscope, detect one or more downhole components with one or more focused detectors using one or more focused detectors and agree of the invention, the position relative to the stationary position in the casing with one or more downhole components detected is displayed, the display is performed by a gyroscope, and one or more focused detectors are instruments for recording the reflected ultrasonic signal, which detect changes in acoustic resistance around one or more downhole components. The problem is solved in that the rigid centering holder according to the invention comprises: an adapter sleeve having a belt with thread turns and holes for set screws, a waist ring that is screwed onto the thread of the belt and fixed with set screws, a spring thrust ring that is mounted on the coupling near the waist rings, and a retaining ring having a plurality of protruding locking tabs for rigid connection with downhole components and keyways for rigid connection with narrowing Misia keyed collar.

It is desirable that a rigid connection between the tapered keys and the keyways eliminate manufacturing tolerances.

It is desirable that the rigid connection between the legs and the downhole components eliminate manufacturing tolerances.

Preferably, the rigid centering holder comprises a snap ring for fastening the retaining ring to the adapter sleeve in a rigid connection. It is desirable that the plurality of downhole components be firing hammer drills. It is desirable that a plurality of downhole components be selected from downhole tools and downhole equipment.

It is desirable that the downhole components be selected from firing perforators, downhole tools and downhole equipment.

The problem is solved in that in the device for measuring the orientation of the cumulative charges in the explosion, according to the invention, the test device is driven by detonation of the detonating cord, the test device can be used at both ends of the stationary column of perforators and remains stationary relative to the orientation of the cumulative charges.

It is desirable that the test device contains: an auxiliary charge rigidly fixed in the test device with respect to the orientation of the cumulative charges, and a test plate eccentrically weighted to maintain the test plate at an angle relative to the orientation of the cumulative charges and configured to sense the release of the auxiliary charge.

It is desirable that the test device contains: an auxiliary charge located in the rotary support, a counterweight to bias the rotary support in the direction relative to the orientation of the cumulative charges, and an outer casing configured to sense the release of the auxiliary charge.

It is desirable that the test device comprises: an outer casing, a shaft in the outer casing for receiving a detonating cord through itself, one or more guides to support the shaft in the center of the outer casing and to allow free rotation of the shaft and a counterweight to bias the shaft in a direction relative to the orientation of the cumulative charge, so that when detonating the detonating cord, the pressure inside the shaft increases to fix it inside one or more guides to maintain the shaft in a biased direction Avlenie.

It is desirable that the test device contains: an outer case, a rotary and test load, eccentrically weighted in the direction relative to the orientation of the cumulative charges, containing a hardened peak and having a central hole for receiving the detonating cord, and a hardened peak placed in the test load and made with the possibility firing into the outer casing with increasing pressure in the central hole caused by detonation of the detonating cord.

It is desirable that the test device comprises: a housing configured to receive a detonating cord through itself, and one or more balls rotating in the housing, displaced in the direction relative to the orientation of the cumulative charges and configured to extrude a recess on the housing with increasing pressure in the housing, caused by detonation of the detonating cord.

It is desirable that the test device comprises: a supporting support configured to receive a detonating cord through itself and having at least one radial channel extending through it, an eccentric load mounted on the supporting support in such a way that the load is displaced in a direction relative to the orientation cumulative charges, and shrapnel, which passes through at least one radial channel and hits an eccentric load when the detonating cord is detonated.

It is desirable that the test device comprises: a supporting support configured to receive a detonating cord through itself and having at least one radial channel extending through it, an eccentric load having one or more radial channels and mounted on the supporting support in this way that the load is displaced in the direction relative to the orientation of the cumulative charges, and one or more radial channels are flush with at least one radial channel in the bearing support, and with detonation and detonating cord eccentric weight is fixed at the orientation with a bearing support.

List of figures

figure 1 is a view in section of a conventional firing punch according to the prior art,

figure 2 is a sectional view of one embodiment of the present invention having a modified shape of a cumulative charge,

figure 3 is a sectional view of another embodiment of the present invention having a modified shape of a cumulative charge,

FIG. 4 is a sectional view of another embodiment of the present invention having a modified charge tube,

5 is a sectional view of another embodiment of the present invention having a modified charge tube,

6 is a sectional view of another embodiment of the present invention having a modified perforator body,

FIG. 7 is a sectional view of another embodiment of the present invention having modified perforator bodies and a charge tube,

FIG. 8 is a cross-sectional view of another embodiment of the present invention having modified cumulative charge and a charge tube,

9 illustrates an embodiment of the present invention having a weighted rotatable charge tube,

10 illustrates an embodiment of the present invention having a rotatable charge tube and lower weights,

11 illustrates an embodiment of the present invention, in which a charging tube is weighted around the cumulative charges,

12 is a sectional view of an embodiment of the invention shown in FIG. 11,

Fig.13 is a perspective view of the orienting load in Fig.11 and 12,

FIG. 14 is a perspective view of an embodiment of an articulated weighted liner according to the present invention, FIG.

15 is a top view of an embodiment of an articulated weighted gasket according to the present invention,

FIG. 16 is a side view of an embodiment of an articulated weighted gasket according to the present invention, FIG.

17 is a perspective view of an embodiment of a cover of an articulated weighted gasket,

figa-18C is a top view, side view and from the end of an embodiment of a shaped load of articulated jointed weighted linings,

Fig is a top view of an embodiment of the articulated charging tube according to the present invention,

Fig.20 is a top view of an embodiment of an articulated charging tube according to the present invention,

21 is a perspective view of an embodiment of an articulated charging tube according to the present invention,

Fig is a perspective view of a device for measuring "torque characteristics in the presence of bending",

Fig is a graph of the relationship between torque and angle of rotation,

24 is a perspective view of an embodiment of a rigid centering holder according to the present invention,

25 is a perspective view of an embodiment of a transition sleeve of a rigid centering holder,

26 is a perspective view of an embodiment of a waist ring of a rigid centering holder,

Fig.27 is a side view of an embodiment of a waist ring of a rigid centering holder,

28 is a perspective view of an embodiment of a spring ring of a rigid centering holder,

Fig.29 is a side view of an alternative embodiment of a spring ring of a rigid centering holder,

30 is a top view of an alternative embodiment of a spring ring of a rigid centering holder,

Fig is a perspective view with a cut of an alternative embodiment of the spring ring,

32 is a perspective view of an embodiment of a retaining ring of a rigid centering holder,

Fig is a schematic top view of a typical relative positioning of the casing and the control line, showing the relative support and the direction of perforation,

Fig. 34 is a side view of an embodiment of a test device according to the present invention,

Fig. 35 is an enlarged side view of the testing device shown in Fig. 34,

Fig. 36 is a sectional view of the testing device shown in Fig. 34,

Fig. 37 illustrates another embodiment of a test device according to the present invention,

Fig. 38 illustrates another embodiment of a test device according to the present invention,

Fig. 39 illustrates another embodiment of a test device according to the present invention,

40 illustrates another embodiment of a test device according to the present invention,

Fig. 41 illustrates another embodiment of a test device according to the present invention,

Fig. 42 illustrates another embodiment of a test device according to the present invention,

Fig. 43 illustrates another embodiment of a test device according to the present invention.

However, it should be noted that the accompanying drawings illustrate only typical embodiments of this invention and, therefore, should not be construed as limiting its limits, and other, equally effective variants of its implementation may relate to the invention.

Information confirming the possibility of carrying out the invention

Figure 1 shows a conventional firing punch. A conventional firing punch, generally designated 1, contains a cumulative charge 10, a charging tube 12, a punch body 14 and a detonating cord 16. The punch 1 shown also contains a recess 18 cut out on the punch body 14 and flush with the cumulative charge 10 Although the conventional firing hammer drill 1 shown is a recessed hammer drill 1, it is important to note that the present invention is equally applicable to smooth wall punchers.

Figure 2 shows one embodiment of the present invention in which the configuration of the shell with a cumulative charge 10 is changed so that the weight distribution provides sufficient torque to orient the perforator 1. As shown in figure 2, the shell with a cumulative charge 10 contains additional material 10a located on the rear side or bottom of the shell with a cumulative charge 10 and providing the formation of an eccentric load that biases the center of gravity from the axis of the perforator. This embodiment causes the charge 10 to be oriented for sweeping in the upper direction. It should be noted that the additional material / load 10a can be made in one piece with the cumulative charge 10 or added to it as a separate component, for example, screwing the load to the cumulative charge 10.

Figure 3 shows another embodiment of the present invention, in which the configuration of the shell with a cumulative charge 10 is changed. In the example in Figure 3, additional material 10a is located in front or at the expanded part of the shell with a charge of 10. This embodiment causes the charge 10 to be oriented in the lower direction . As discussed with reference to FIG. 2, the additional material / load 10a can be made integrally with the cumulative charge 10 or added to it as a separate component.

It should be noted that in alternative embodiments of the invention, the shell with a charge of 10 can be additionally installed so that the center of gravity is even more distant from the axis of rotation.

Modifying the plurality of charges 10 in the manner described with reference to FIGS. 2 or 3 increases the eccentricity effect, which can provide significant orientational torque. For example, changing the configuration of the back side of the PJ2906 charge shell manufactured by Schlumberger Technology Corporation, you can add 48 grams of additional material to each charge. A 200-foot punch produces an additional 68-pound of torque. This illustrative torque value corresponds to a 40% increase over a 7-foot weighted gasket in a similar punch if steel is used as the material of the load. In addition, a perforator that uses the modified cumulative charge 10 according to the present invention, provides better use of space and its economy.

Figure 4 shows another embodiment of the present invention, in which the charging tube 12 is modified to provide the required torque. For example, the charging tube 12 may have more material on one side than the other. As shown in FIG. 4, the charging tube 12 has more material 12a on the lower side (i.e., the side that is intended to be low during shooting). Accordingly, the charging tube 12 has an eccentric mass balancing at which the center of gravity is offset from the axis of rotation. Thus, gravity will cause rotation of the charging tube 12 and its orientation in a preferred manner.

In the embodiment of the invention shown in FIG. 5, material 12b is removed from the charging tube 12 on one side of the cumulative charge 10 to provide a different orientation than in the embodiment of FIG. 4. In the embodiment of FIG. 5, the center of gravity of the charging tube 12 is offset from the axis of rotation, which leads to the orientation of the cumulative charges 10 in the horizontal direction.

FIG. 6 shows an embodiment of the present invention, where the punch body 14 is modified in a similar manner. On one side of the punch body 14, recesses or thinned parts 18 can be formed so that the body 14 itself will provide some degree of preferred orientation. 6, the punch body 14 has numerous recesses 18 at its upper part. Thus, the body has a center of gravity that is offset from the axis of rotation, and gravity will cause the punch body 14 to rotate and orient in a preferred manner.

The design features described with reference to FIGS. 2-6 can be combined to improve orientation or applied individually. For example, as shown in FIG. 7, a modified punch case 14 and a modified charging tube 12 with conventional charges 10 can be used in the punch 1. In another example shown in FIG. 8, the modified charges 10 are combined with the modified charging tube 12 and a conventional housing 14 punchers. The above examples are intended to be illustrative and non-restrictive with respect to possible combinations within the scope of the present invention.

The hammer drill 1 according to the present invention may contain charges 10, of which some are modified, while others are not modified or are ordinary. According to one of many possible examples, the charges 10 of the punch 1, oriented in the first direction, are eccentric and modified type (i.e., having a center of gravity that is offset from the axis of rotation), while charges oriented in the other direction are charges of the usual type . In another embodiment, perforator 1 uses charges 10 oriented with a phase offset of 0-180 °.

According to another embodiment of the present invention shown in FIG. 9, there is provided a firing punch 1 with cumulative charges 10 mounted in a charging tube 12 that pivots inside the punch body 14. In addition to the cumulative charges 10, the charging tube 12 carries a load 20, which causes the rotation of the rotary charging tube 12 to the desired orientation (down in FIG. 9).

In the above example, the used cargo 20 is a semicircular cargo. However, other embodiments are within the scope of the present invention. In addition, the load 20 may be of any number of types and configurations, for example, in the form of cargo such as a hollow vessel filled with a high-density substance, or in the form of semi-solid metal rods.

In the case of using perforating guns with smooth walls, no additional alignment is required, since the perforator body 14 has a uniform thickness around its circumference. Similarly, in the case of the use of a firing punch 1 having machined grooves extending around the circumference of the punch body 14 and located at each interval with a cumulative charge, no additional alignment of the punch 1 is required.

In the case of using firing punchers 1 with recesses shown in FIG. 9, the punch body 14 needs to be oriented for alignment with cumulative charges 10 so that the cumulative charges 10 shoot through recesses 18. In the embodiment of the present invention shown in FIG. 10, orientation of the body 14 of the punch. As shown, the punch body 14 is lowered into the bore 22 on the working string of the rods 24. A swivel 26 is fixed between the punch body 14 and the working string of the rods 24 so that the casing 14 can be rotated if necessary. One or more weights are attached to the underside of the housing 14, causing the housing 14 to rotate so that the recesses 18 are turned downward.

In the embodiment of the invention shown in FIG. 10, an average load 28 and a lower load 30 are used. The average load 28 has a thread at the upper end and a thread at the bottom to receive additional loads. The lower load 30 has a rounded lower end 30a to facilitate the direction of the rod string 24 to the top of the pipe string and around the corner in highly deflected or horizontal wells. Since the average weights 28 and the lower weights 30 are in the well conditions, they can be made of heat-treated steel to withstand the descent into the well and the rise from it.

It should be noted that the embodiment shown in FIG. 10 serves as one example of the numerous cargo combinations that can be used with the present invention. For example, depending on the weight required for orientation, a plurality of medium weights 28 may be used. In addition, depending on the application, no medium weights 28 may be required.

11 shows another embodiment of the present invention, in which the charge tube 12 is weighted around the cumulative charges 10. The firing drill 1 is a smooth-wall drill 1 containing a rotatable charging tube 12. However, this option can also be used with a stationary charging tube 12, when the entire firing hammer drill 1 is rotated. By surrounding part of the cumulative charge 12 with the orienting weight 32, the need for an additional length added to the column is eliminated.

12 and 13 show an embodiment of the firing drill 1 with a charging tube 12 weighted around the cumulative charges 10. FIG. 12 shows a sectional view of the firing gun 1, and FIG. 13 is a perspective view of the orienting load 32. As shown, the orienting load 32 is shaped and arranged so that the charging tube 12 and the cumulative charge 10 are oriented in the horizontal plane. The cutouts 32a in the orienting load 32 correspond to the arrangement of the cumulative charges 10, so that the orienting load 32 does not interfere with the charges 10 or the detonating cord 16.

Although the above example illustrates the use of the orienting weight 32 when punching in the horizontal plane, it should be borne in mind that the orienting weight 32 can be made to provide orientation in any desired plane.

In another embodiment of the invention shown in FIGS. 14-18, a pivotally weighted gasket 40 is used to ensure the correct orientation of the firing hammer drill along the winding path of the wellbore. As shown, the articulated weighted gasket 40 comprises a semicircular gasket tube 42 that is deployed in a hollow hammer body 14 (shown by dashed lines in FIG. 1). However, in alternative embodiments, the articulated weight pad 40 may take any number of forms.

The spacer tube 42 comprises a plurality of zigzag, puzzle-like cuts 44 arranged at intervals along its length. The cuts 44 extend around the circumference of the tube 42 so that they cut the cushioning tube 42 into separate segments 46 without the possibility of separating them from each other. Sections 44 allow the gasket tube 42 to bend slightly at the location of each section 44 without causing the gasket tube 42 to lose its structural properties and main purpose (i.e., orienting the drill string in the right direction). The segments 46 at each end of the gasket tube 42 are attached to the centering plates 48, which are used to connect the articulated, weighted gasket 40 to the punch body 14 or to the drill string.

Each section 46 has a correspondingly profiled load 50 (best shown in FIGS. 18A-18C). The weights 50 orient the spacer 40 and thus the drill string in the desired direction. In the shown embodiment, in which the cushion tube 42 has a semicircular shape, the load 50 can also have a semicircular shape, which makes it possible to fit it tightly into each section 46. However, any number of forms and types of cargo are within the scope of the invention. In addition, each segment 46 may at each of its ends have an end plate 56 to prevent axial movement of the loads 50 in the gasket tube 42.

As shown in FIGS. 14, 15 and 17, a cover 52 is attached to each segment 46 to cover and secure the load 50 therein. The cover can be connected to its corresponding segment 46, using, for example, tabs 54 that snap into engagement with segment 46. In addition, each cover 52 has partially cut petals 58 that can be bent from the cover 52. Each petal 58 has a through hole 60 with a size that allows you to accept a detonating cord (not shown). When the drill string is assembled, the petals 58 can be folded so that they protrude from the cover 52 and a detonating cord is passed through each hole 60 to secure the detonating cord in the gasket 40.

The articulated weighted pad 40 does not have a directionally preferred bending stiffness. It has the same stiffness, or bending resistance, or bending moment of inertia in all directions. Although gravity corrective torque will still be applied to the drill string when the drill string is not oriented in the desired direction, the articulated weight pad 40 will not rotate the drills from the intended, gravitationally preferred direction, when the liner is bent in an indirect wellbore ( i.e. when the bend is not in the plane of 6 or 12 hours).

Thus, due to the manufacture of the cushioning tube 42 in this way, the segments 46 remain rigid, while the entire cushioning tube 42 is capable of bending in any direction without resistance. The number and length of the segments 46 and the width of the cuts 44 can be selected to provide a suitable bending radius. Thus, the punch can be passed through a curved borehole without fear that the cushion pipe 42 will tend to mis-orient the drill string.

On Fig-21 shows an embodiment of the articulated charging tube 70, which embodies the main features of the above-described articulated articulated gasket 40. Articulated charging tube 70, which is deployed in the hollow body 14 of the drill (shown by dashed lines in FIG. .19), contains a lot of zigzag-like, puzzle-like cuts 72 arranged at intervals along its length. The cuts 72 extend around the circumference of the charging tube 70 in such a way that they cut the charging tube 70 into separate segments 74 without the possibility of separation from each other. The cuts 72 allow the charging tube 70 to bend slightly at the location of each cut 72 without causing the charging tube 70 to lose its structural properties and main purpose (i.e., to keep the cumulative charges in their correct position inside the punch case 14). The segments 74 at each end of the charging tube 70 are attached to the end plates 76, which are used to connect the articulated charging tube 70 to the drill string.

Each segment 74 may include multiple openings 78 for receiving cumulative charges (not shown). In addition, there may be petals 80 that help to consolidate the cumulative charges in place. Opposite each opening 78 may also be an opposite opening 82 for receiving the rear end of the corresponding cumulative charge.

By manufacturing the charging tube 70 in this way, the individual segments 74 remain rigid, while the entire charging tube 70 is capable of bending in any direction without resistance. The number and length of sections 74 and the width of sections 72 can be selected to provide a suitable bending radius. Thus, the punch can be passed through the curved borehole without fear that the charging tube 70 will tend to mis-orient the drill string.

According to another embodiment of the present invention, there is provided a method of compensating for uneven bending moment in the components of a drill string (i.e., in perforator bodies, perforator gaskets and weighted bodies). In this embodiment of the invention, a piece of material of the component of the perforator is bent with a curvature similar to the curvature that can be observed at a bent wellbore. While the material is curved, it is rotated around its longitudinal axis. The amount of torque required to make turns is measured as a function of the angle of rotation between the "zero reference" and 360 °. Such measurements are performed using a device for determining “torque characteristics in the presence of bending” shown in FIG.

On Fig shows a graph of the relationship between the required torque and angle of rotation. This graph shows that the components of the drill string will be affected by the uneven bending moment of inertia. The “static” position or initial position is characterized by the place where the graph of the relationship between the torque and the angle of rotation crosses the value of torque equal to zero. Using this data, an “optimum angular position” is determined. This optimum angular position, called the “zero angle with bending torque”, is the angle at which the component will actively orient along the inner curved surface of the casing of the curved wellbore.

Knowing in advance the borehole trajectory and the "bending angle", you can use the puncher bodies, punch gaskets and weighted gasket bodies that will actively orient the punch string in the desired direction. Puncher bodies, perforator gaskets, and weighted gasket bodies that are known or intended to be placed on a curved portion can be made to have a zero angle of torque when there is a bend that matches the bend angle of the curved borehole.

The magnitude of the provided or available torque in an active orientation can also be determined from the obtained characteristics of the material during testing to establish the characteristics of the torque with a curved material. This value will vary depending on the individual part of the material, the degree of bending and the length of the bent part of the wellbore. The longer the curved portion of the wellbore, the greater the active orienting torque available. The larger the bending angle in the wellbore, the greater the active orienting torque available. Finally, the greater the amount of torque required to rotate a part of the material by one revolution, as it was determined during tests to establish the characteristics of the torque with a curved material, the greater the available orienting torque.

According to another embodiment of the present invention, there is provided a rigid centering holder that eliminates the misalignment in subsequent drill columns that exists due to machining tolerances and clearances. In other words, the rigid centering holder 90 shown in FIGS. 24-32 ensures that the additional punch columns attached to the first oriented punch string maintain the orientation of the first punch string.

Referring to FIG. 24, where the rigid centering holder 90 comprises a adapter sleeve 92, a waist ring 94, a snap ring 96 and a locking ring 98. As shown, the rigid centering holder 90 is connected to both the second rigid centering holder 100 and the downhole tool 102, as, for example, with an additional housing of a perforating gun. The rigid centering holder 90 can be successfully used to connect with any number of components of the well string, tools and parts of the downhole equipment.

25 shows a perspective view of an embodiment of the adapter sleeve 92 of the rigid centering holder 90. In the shown embodiment, both ends 104, 106 of the adapter sleeve 92 can be used to rigidly center the adjacent components. In alternative embodiments, one end of the adapter sleeve 92 may be integral with one of the adjacent components, or may be attached in a standard manner to the adjacent component, for example, by screws.

The adapter sleeve 92 has a girdle 108 provided with turns of thread 110. Near the turns of thread 110 are a plurality of holes 112 for the set screws. These holes 112 are located around the circumference of the adapter sleeve 92. In addition, the adapter surface 114 has a plurality of tapering keys 116 that protrude from the adapter sleeve surface 114. The tapering keys 116 have beveled edges 118. In the illustrated embodiment, the tapering keys 116 have a rectangular shape. However, in alternative embodiments, the tapered keys 116 may take any number of regular and irregular shapes.

Referring to FIGS. 26 and 27, in which the waist ring 94 is shown in perspective and side view. A plurality of keyways 122 are made along the inner diameter of the waist ring 94, which correspond to the tapered keys 116 of the adapter sleeve 92 and are aligned with them. The keyways 122 allow tapering keys 116 to pass the waist ring 94 in any direction without interference. In addition, inside the waist ring 94, there are turns of thread 120 that can mate with turns of thread 110 on the girdle 108 of the adapter sleeve. Around the circumference of the waist ring 94 are a plurality of grooves 124.

Referring to FIG. 28, a perspective view of an embodiment of a spring thrust ring 96 is shown. A spring thrust ring 96 is a conventional spring, such as a wave spring, which has a number of keyways 126 located along its inner diameter and allowing unhindered the passage of the spring 96 over the tapered keys 116 of the adapter sleeve. On Fig.29-31 shows an alternative embodiment of the spring 96.

FIG. 32 is a perspective view of an embodiment of a retaining ring 98. The retaining ring 98 has a plurality of retaining tabs 128 that protrude axially from the retaining ring 98. The locking tabs 128 are limited by the tapered surfaces 130. The locking tabs 128 are dimensioned and shaped to engage with corresponding tapering grooves at the ends of the punch bodies, gaskets, other adapter couplings, and other downhole components. On the inner surface of the locking tabs 128 there are keyways 132 having beveled sides 134. The keyways 132 are dimensioned and shaped so that there is always an interference fit between the tapered keys 116 and the keyways 132 when the snap ring 98 moves along the tapered keys 116. Thus thus, the retaining ring 98 must be deformed to fit on the adapter sleeve 92, thereby eliminating the entire gap between them.

When the device is in operation, the waist ring 94 is first moved along the adapter sleeve 92 in the direction of the threaded girdle 108. The waist ring 94 is adapted to allow the tapered keys 116 to pass by aligning the keyways 132 with the tapered keys 116. After passing the tapered keys 116, the waist ring is screwed onto the turns thread 110 of the belt 108. Then move the snap ring 96 to the adapter sleeve and install it near the waist ring 94.

After locating the snap ring 96 on the adapter sleeve 92, the retaining ring 98 is moved onto the adapter sleeve 92 so that the key recess 132 is engaged with the tapered keys 116. As mentioned above, there is an interference fit between the tapered keys 116 and the key recesses 132, so that the retaining ring 98 must be deformed to fit on the adapter sleeve. Such deformation eliminates any gap between them.

After the snap ring 98 is mounted on the tapered keys 116, the snap ring 98 is held in place by the waist ring 94 and the snap ring 96. The snap ring 94 is screwed from the threads of the thread 116 of the adapter sleeve 108 until the snap ring 96 is act on the circlip 98 with the desired strength. After the desired force has been achieved, the set screws are inserted through the grooves 124 of the waist ring 94 into the holes 112 for the set screws in the adapter sleeve. The set screws retain the position of the waist ring 94, which in turn retains the force exerted by the snap ring 96 on the snap ring 98. The snap ring 96 acts to hold the snap ring 98 in place, and also acts to absorb the forces created by any axial moving the retaining ring 98 towards the waist ring 94. Such axial movement may occur during operations in the well.

Alternatively, the waist ring 94 is screwed off from the threads 116 on the adapter collar 108 until the waist ring 94 is in contact with the snap ring 98. Thus, the snap ring 96 is not required. However, any axial movement or axial forces acting on the snap ring 98 should be supported by set screws and / or threads 110 on the waist ring 94.

Once the retaining ring 98 is secured in place above the tapering keys 116, the mating component (perforator body, gasket, adapter sleeve, etc.) can be attached. As shown in FIG. 24, the mating component (100 or 102) has tapering grooves 136, 138 that engage with locking tabs 128 on the retaining ring 98. Tapering grooves 136, 138 have beveled surfaces that facilitate bonding with beveled surfaces 130 stoppers 128.

The snap ring 98 is rigidly centered and secured both by the interaction between the keyways 132 and the tapered keys 116, and by the action of the waist ring 94. The mating component (perforator body, gasket, adapter sleeve, etc.) is rigidly centered and fixed by engagement with the snap rings tabs 128 on the snap ring 98. Consequently, manufacturing tolerances are eliminated and the connection is rigidly centered. Repeating a compound of this type throughout the assembled column results in the assembled column not having a gradual “misalignment” of alignment.

According to another embodiment of the present invention, there is provided a system and method for detecting control lines (acoustic, electrical, nuclear, thermal, magnetic, etc.) based on the detection of various materials contained therein. As shown in FIG. 33, by detecting the control line 140 by the sensor and simultaneously displaying its position compared to the stationary position in the casing 142 (for example, the relative direction (OH) to the top wall or bottom wall of the well), the information needed to accommodate firing perforators 1 in the desired direction. As shown in the figure, the control line 140 is displayed compared with the relative direction to the upper wall, and the firing hammer 1 is oriented and detonated in a direction (shown by an arrow) that avoids any interference from the side of the control line 140.

It is important to note that the system and method are equally applicable to downhole sensors, control devices, downhole equipment and downhole tools that may be damaged or affected when a cumulative charge is on or near the path. However, to facilitate discussion, the invention will be discussed with reference to control lines.

In one embodiment of a system and method for detecting control lines 140 (and other components), a control line 140 is displayed and a hammer drill 1 is indexed during the same lowering and lifting in the well. In this embodiment, a focused detector (s) is used to determine the position of the control line 140, and in conjunction with the detector (s), a gyroscope is used to display the position of the control line 140 relative to the lower or upper wall of the casing 142. After this is determined, lower into a drill string with an inclinometer / tool for determining the relative direction (wire inclinometer for use in punching) and a gyroscope. This is done to verify that the inclinometer / tool for determining the relative direction is consistent with the gyroscope (necessary for wells with small inclinations). During the shooting step, the perforators 1 and the inclinometer / tool are lowered to determine the relative direction (the gyroscope has been removed) when the hammer 1 is located in the desired shooting direction. An inclinometer / tool is used to determine the relative direction to verify that the punch 1 is located in the desired direction and the perforators 1 are blown. The punchers 1 can be oriented using any of the above methods. In addition, perforators can be set to a predetermined position by any conventional passive means (wire oriented perforating tool: weighted spring positioning device) or active means (downhole motor wire perforating platform).

A focused detector (s) are selected based on the fact that the control lines 140 (or other components) are made of or contained therein. In one embodiment of the method and system, radiation detection is used. In this embodiment, a gamma ray detector is used to detect the control line 140 or any component in the control line 140, which or which contains a radioactive indicator (cobalt-60, cesium, etc.). In the same way, a gamma ray detector can be used to detect a radioactive tag placed on the brackets that secure the control line 140 to the casing / riser. A gamma ray detector can also be used to detect radioactive fluid introduced into control line 140.

In another embodiment of the system and method for detecting control lines 140, a detector (s) is used for acoustic detection. Ultrasonic devices may be used if the control line 140 has a significant difference in acoustic resistance from the environment (cement, mud crust on the walls of the well, rock, gravel packing, etc.).

In yet another embodiment of the system and method for detecting control lines 140, a focused detector (s) are used for thermal detection. In this embodiment, thermal detection devices (production platform, gauge temperature probe) can be used to detect coolant that is pumped into control line 140.

In yet another embodiment of the system and method, electrical detection is used to detect control lines 140. In this embodiment, the control line 140 is detected where the communication on the induced EMF signal on the side of the casing 142 with the control line is different from that on the opposite side. On the other hand, transducers such as smart cards or other electronic tags can be oriented and detected on the casing 142 or control line 140.

In another embodiment of the system and method, magnetic detection is used to detect control lines 140, a magnetometer can be used when a magnetic mark is placed on the control line, brackets for attaching the control line, or casing 142.

In another embodiment of the present invention, a device and method is used to verify that the correct orientation of the firing hammer drill 1 is achieved. As shown in FIGS. 34-36, the testing device 200 is placed in the housing 14 of the hammer drill and attached to the charging tube 12. It should be noted that in alternative embodiments, it is not necessary that the test device 200 is attached to the charging tube 12 while the test device 200 is attached to the drill string at a constant angle with respect to the orientation of the cumulus poisonous charges 10.

Test device 200 is provided with an auxiliary charge (small cumulative charge) 202, which is triggered by the same detonating cord 16 that initiates the main cumulative charges 10. When detonated, the auxiliary charge 202 fires into the test plate 204 to provide evidence of the orientation of the perforator 1 during the explosion. This evidence is provided without punching the punch body 14 and the risk of damage to the well or its components.

In the shown embodiment, the test plate 204 is made in the form of a semicircular plate placed in a well-polished guide 206. The test plate 204 has one or more wheels 204a that allow the plate 204 to rotate in the guide 206 around the central axis of the punch 1. Due to its own a weight test plate 204 will always be on the underside of the well. Auxiliary charge 202 is located for firing straight down relative to the correct orientation of the charging tube 12 and the main charges 10 (at an angle of 0, 90, 180 degrees or at any other deflection angle), when correctly oriented. Thus, if the orientation of the charge tube 12 is correct, then the auxiliary charge 202 will always shoot directly through the center of the test plate 204. If the charges 10 are not correctly oriented, then the degree of displacement can be measured by shot into the test plate 204.

It should be noted that in alternative embodiments, the test plate 204 can be made completely extending around the auxiliary charge 202 and still guided by gravity to record minor and large deviations.

In another embodiment of the test device 200 shown in FIG. 37, the auxiliary charge 202 is located in a rotating support 208 placed in the charging tube 12. The support 208 has a counterweight 210 that biases the support 208 so that the load 210 is oriented towards lower position. In the shown embodiment, the auxiliary charge 202 is opposite to the counterweight 210, so that the auxiliary charge is always oriented in the upper direction (although in other cases it could be oriented in other directions).

The detonating cord 16 is attached to the auxiliary charge 202 with the possibility of actuation, so that detonation of the detonating cord causes an explosion of the auxiliary charge 202. When detonating, the auxiliary charge 202 explodes, forming a mark on the charging tube 12, which can be checked to determine the orientation of the perforations. The orientation is again checked without the need for punching the punch body 14 with an auxiliary charge 202.

On Fig shows another variant of verifying that the correct orientation of the firing hammer drill 1 is achieved. In this embodiment, the test device 200 is attached to the charging tube 12 (not shown), placed in the charging tube 12 or attached to the string of perforators motionless relative to the cumulative charges (not shown). Test device 200 may be located in a space protected from damage by the explosion of cumulative charges (not shown), such as spacers, pressure regulators, swivels, etc.

The test device 200 has an upper centering plate 212 and a lower centering plate 214 fixed to the outer casing 216. The upper centering plate 212 and the lower centering plate 214 are each provided with a centered guide 212a, 214a for receiving the central shaft 218. The guides 212a, 214a allow the central shaft 218 rotate freely at both ends. A counterweight 210 is rigidly attached to the central shaft 218, which is always located at the bottom of the test device 200 by gravity.

The detonating cord 16 passes through the central shaft 218. When detonating the detonating cord 16 to detonate cumulative charges (not shown), the pressure inside the central shaft 218 rapidly increases, which causes the central shaft 218 to expand and lock in the upper and lower guides 212a, 214a. Thus, the central shaft 218 is fixed in the position in which it was during the explosion of the cumulative charges. After removing the drill string, the position of the central shaft 218 in the test device 200 can be checked to determine the orientation of the drill string during the explosion.

It should be noted that only the extension of the central shaft 218 is required to fix it in one of the guides 212a, 214a. For example, the bottom rail may be made of plastic and used only for directional purposes, and not for fixing purposes. In addition, it should be noted that the guides 212a, 214a may contain uneven surfaces in order to mechanically fix the central shaft 218, and not to hold it in a fixed position only by friction.

On Fig shows another embodiment of the test device 200. In this embodiment, the test device 200 is again fixed in the housing 14 of the guns motionless relative to the orientation of the cumulative charges. The outer housing 216 of the test device 200 is again attached to the upper centering plate (not shown). Inside the outer casing 216, a test load 220 is held in place by two roller bearings 222. The test load 220 is provided with a hardened peak 221 and is shaped so that it is preferably gravitated to the bottom of the test device 220 when the peaks 221 are turned into top direction. A detonating cord (not shown) passes through a central drilled hole 224 in the test load 220.

Upon detonation of the detonating cord, the pressure in the drilled hole 224 rises rapidly, causing the peaks 221 to be pushed up. During the explosion, the hardened peak 221 hits the inner surface of the outer casing 216 and makes a depression on it. After the punching operation is completed, the outer casing is removed and checked to determine the actual orientation of the perforation in the well.

FIG. 40 shows another embodiment of the test device 200. The test device 200 is again fixed to the drill string stationary relative to the orientation of the cumulative charges. In this embodiment, the test device 200 comprises two discs 226 with a gap 228 between them. A sleeve 230 is disposed between the disks 226 around the circumference. The disks 226 and the sleeve 230 are fixed relative to the outer casing 216 by means of, for example, screws 231 or studs 232.

The mechanism for action of the pike 234 is equipped with a tube 236, two bearings 238, a sleeve 240, a cylinder 242 and a pike 244. The tube 236 is located in the central holes 246 made through discs 226. Bearings 238 are mounted on the tube 236 on each side of the sleeve 240, while the tube 236 also extends through a central bore 248 in bushing 240. Bearings 238 allow rotation of bushing 240. Cylinder 242 extends from bushing 240 and is in communication with central bore 248. Peak 244 is located in cylinder 242 and may initially be held in place by means of a shear pin 250. The mechanism for operating the peak 234 is weighted, for example, by including a cylinder 242 and peaks 244, so that the cylinder 242 and peak 244 are oriented by gravity to the lower side of the drill string.

The detonating cord 16 (shown by dashed lines) passes through the central holes 246 in the disks 226 and through the internal cavity of the tube 236. Upon detonation of the detonating cord 16, the tube 236 is destroyed and the pin 250 is cut off, causing the peaks 244 to be pushed down and the depression to be pressed on the inner surface of the sleeve 230 After the punching operation, the location of the recess can be used to determine the actual orientation of the perforations.

FIG. 41 shows another embodiment of the test device 200. In this embodiment, the ball (or counterweight) 252 is placed in the housing 254 and can rotate therein so that the ball 252 remains on the underside of the housing 254. The detonating cord 16 extends through the housing 254 so that the ball 252 is located between the detonating cord 16 and the inner wall 256 of the housing 254.

Upon detonation of the detonating cord 16, an increase in pressure in the housing 254 causes a ball 252 to form a depression on the inner wall 256 of the housing 254. The housing 254 is stationary relative to the cumulative charges, so that the depression is used to check the orientation of the perforations during the explosion.

In alternative embodiments, the housing 254 contains numerous balls 252. In addition, it should be noted that using the housing 254 having a rounded shape in the axial direction, it is possible to determine the orientation of the drill string in many axes. In other words, the ball (s) 252 rotate towards the lower side of the housing 254, which makes it possible to determine the angle of the perforators in the longitudinal direction, as well as the angular orientation.

42 shows another embodiment of a test device 200. In this embodiment, the eccentric weight 260 is mounted on a support leg 262 having a supporting surface 264. The eccentric weight 260 is rotated so that the weighted side remains in its lowest position. Carrier support 262 has at least one radial channel 266 extending through it. The detonating cord 16 extends along the central axis of the bearing support 262. A coaxial tube 268 surrounds the detonating cord 16.

When the detonating cord 16 is detonated, the coaxial tube 268 forms shrapnel, which passes through one or more radial channels 266 in the bearing support 262 and hits the inner supporting surface of the eccentric load 260. Knowing the orientation of one or more channels 266 relative to the orientation of the cumulative charges, eccentric load check 260 determine the orientation of the perforations.

In an alternative to that shown in FIG. 42, detonation causes expansion fixation of the relative position of the eccentric load 260 and the bearing support 262. FIG. 43 shows one exemplary embodiment in which the fixation method by expansion is applied. In this embodiment, the eccentric load 260 has one or more radial channels 270 that are flush with one or more radial channels 266 in the support leg 262. When the perforators are fired at the correct orientation and the load 260 engages with the support leg 262, one or more channels 266, 270 are aligned. Orientation can be checked by simply inserting the studs into the coaxial channels 266, 270 or by other means of checking the channels 266, 270.

It should be noted that test devices 200 can be used at both ends of a stationary drill string. In this way, the orientation at both ends of the drill string can be verified. In addition, it should be noted that the above embodiments of the test device 200 are illustrative and are not intended to limit the scope of the present invention. The described features may be combined and modified and remain within the scope of the present invention. As one example, the hardened peak 221 in FIG. 39 can be used to pierce a cylindrical sleeve and thereby fasten the sleeve to the outer casing 216 and fix their relative positions.

Although the foregoing is directed to a preferred embodiment of the present invention, other and further embodiments of the invention may be devised without departing from its basic limits as defined in the following claims. The applicant's explicit intention is not to require the application of section 35, § 112, paragraph 6 of the US Code with respect to any restrictions on any of the claims, except for those where the word “means” is specifically used in the claims together with related function.

Claims (36)

1. The method of orientation of the cumulative charges, in which one or more components of the drill string to orient the cumulative charges in the desired direction are eccentrically weighted, while in one or more components of the drill string partially remove material to change the center of gravity. 2. The method according to claim 1, wherein one or more of the components of the column of perforators is selected from the cumulative charges, charging tubes and bodies of perforators. 3. The method according to claim 1, wherein a rotary charge tube is used as one or more components of the drill string. 4. A method for orienting cumulative charges, in which one or more components of the punch string are eccentrically weighted to orient the cumulative charges in the desired direction, in which an articulated charging tube having a plurality of segments is used as one or more components of the punch string interlocked with each other in such a way that the individual segments are able to bend and there is no disengagement. 5. The method of orientation of the cumulative charges, in which one or more components of the punch string are eccentrically weighted to orient the cumulative charges in the desired direction, in which, moreover, the unevenness of the bending moment in one or more of the components of the punch string is determined and compensate for the uneven bending moment. 6. The method according to claim 5, in which the unevenness of the bending moment is determined by bending one or more components of the drill string at an angle of deviation of the wellbore and measuring the amount of torque required to rotate one or more components of the drill string to the desired orientation when located at an angle of deviation. 7. Oriented firing punch attached to the punch string and containing one or more components of the punch string containing one or more cumulative charges having a charge shell, a charge housing and a charge tube, with at least one or more components the drill columns are eccentrically weighted to orient the cumulative charges in the desired direction, and the shell shape of one or more cumulative charges is changed to shift its center of gravity and. 8. Oriented firing punch attached to the punch string and containing one or more parts of the punch string including one or more cumulative charges containing a charge casing, a punch casing, a charging tube in which at least one or more components of the firing punch are eccentrically weighted to orient the cumulative charges in the desired direction, while the material from the punch body is removed. 9. Oriented firing punch according to claim 8, in which, due to material removal, recesses are formed on the surface of the punch case. 10. Oriented firing punch attached to the punch string and containing one or more parts of the punch string including one or more cumulative charges having a charge casing, a punch casing and a charging tube, at least one or more parts of the punch is eccentrically weighted for orientation of the cumulative charges in the desired direction, while the material is removed from the charging tube. 11. Oriented firing punch attached to the drill string containing one or more parts of the drill string containing one or more cumulative charges having a charge body, a punch body and a charging tube, the charging tube being a rotary eccentrically weighted charging tube, and the punch body oriented relative to the rotary charging tube with one or more loads, and one or more loads are located outside the perforator body. 12. Oriented firing drill according to claim 11, in which one or more loads are provided with rounded ends configured to direct the firing drill through the curvature of the well. 13. Oriented firing punch attached to the punch string and containing one or more parts of the punch string including one or more cumulative charges having a charge casing, a punch casing and a charging tube in which at least one or more parts of the firing punch are eccentrically weighted to orient the cumulative charges in the desired direction, and the charging tube is made in the form of an articulated charging tube having a plurality of segments interlocked with each other so that individual segments are able to bend without disengagement. 14. Oriented firing punch attached to the drill string, containing one or more parts of the drill string, including one or more cumulative charges having a charge housing, a drill case and a charging tube in which one or more parts of the drill string are eccentricly weighted for orientation cumulative charges in the desired direction, and the perforator body, in addition, contains a pivotally weighted gasket attached to the column of perforators and having a plurality of segments interlocked with each other in such a way that individual segments are able to bend without disengagement. 15. Oriented firing punch attached to the drill string, containing a plurality of firing punch attached to each other with a rigid centering holder, each punch has one or more parts of the punch string, including one or more cumulative charges having a shell, a shell of a punch and a charging tube in which at least one or more parts of the drill string are eccentrically weighted to orient the cumulative charges in the desired board, while the rigid centering holder is made with the possibility of eliminating misalignment resulting from processing tolerances and clearances. 16. A method of placing one or more downhole components and displaying their position at a single descent into the well, in which the detected material is used in one or more downhole components, one or more focused detectors are lowered in conjunction with a gyroscope, one or a large number of focused detectors one or more downhole components and display the position relative to a stationary position in the casing with one th or a large number of downhole components, the display is carried out by a gyroscope, and one or more downhole components are control pipes to display their position relative to the stationary position in the casing and to obtain the information necessary to place the perforators in the desired direction. 17. A method of placing one or more downhole components and displaying their position at a single descent into the well, in which the detected material is used in one or more downhole components, one or more focused detectors are lowered and one or more focused detectors are detected one or more downhole components using one or more focused detectors and display a position relative to a stationary position I am in a casing with one or more borehole components detected, the display is carried out by means of a gyroscope, the detected material being coolant used to pump fluid through one or more borehole components, and one or more focused detectors are devices for thermal detection. 18. The method of placing one or more downhole components and displaying their position on a single run, in which the detected material is used in one or more downhole components, one or more focused detectors are lowered in conjunction with a gyroscope, one or more downhole components and display the position relative to a stationary position in the casing with one or more downhole components detected, display carried out using a gyroscope, and the detected material is a smart card type transducer used in one or more downhole components. 19. A method of placing one or more downhole components and displaying their position on a single run, in which the detected material is used in one or more downhole components, one or more focused detectors are lowered in conjunction with a gyroscope, and one or more focused detectors one or more downhole components using one or more focused detectors and display the position relative to the stationary th position in the casing with the detected one or more downhole components, mapping is performed gyro, wherein E is a detectable label material used in one or more of the downhole components. 20. A method of placing one or more downhole components and displaying their position on a single run, in which the detected material is used in one or more downhole components, one or more focused detectors are lowered in conjunction with a gyroscope, and one or more focused detectors one or more downhole components using one or more focused detectors and display the position relative to the stationary th position in the casing with the detected one or more downhole components, mapping is performed gyroscope, wherein the magnetic material is a detectable label that is used in one or more of the downhole components, and one or more detectors are focused magnetometers. 21. A method of placing one or more downhole components and displaying their position on a single run, in which the detected material is used in one or more downhole components, one or more focused detectors are lowered in conjunction with a gyroscope, and one or more focused detectors one or more downhole components using one or more focused detectors and display the position relative to the stationary th position in the casing with the detected one or more downhole components, mapping is performed gyro, wherein one or more focused detectors are devices for recording the reflected ultrasonic signal that detect changes in an acoustic impedance around one or more downhole components. 22. A rigid centering holder comprising an adapter sleeve having a girdle with thread turns and holes for set screws, a waist ring that is screwed onto the thread of the girdle and secured with set screws, a snap ring that is mounted on the sleeve close to the waist ring, and a snap ring, having a plurality of locking tabs for rigid connection with downhole components and keyways for rigid connection with tapering keys of the adapter sleeve. 23. The rigid centering holder of claim 22, wherein the rigid connection between the tapered keys and keyways eliminates manufacturing tolerances. 24. The rigid centering holder of claim 22, wherein the rigid connection between the legs and the downhole components eliminates manufacturing tolerances. 25. The rigid centering holder of claim 22, comprising a snap ring for fastening the retaining ring to the adapter sleeve with a rigid connection. 26. The rigid centering holder of claim 22, wherein the plurality of downhole components are firing punchers. 27. The rigid centering holder of claim 22, wherein the plurality of downhole components are selected from downhole tools and downhole equipment. 28. The rigid centering holder of claim 22, wherein the downhole components are selected from firing punch tools, downhole tools, and downhole equipment. 29. A device for measuring the orientation of cumulative charges in an explosion, containing a detonating cord, a test device configured to detonate a detonating cord, the test device configured to use perforators at both ends of the stationary column and remain stationary relative to the orientation of the cumulative charges. 30. The device according to clause 29, in which the test device contains an auxiliary charge, rigidly fixed in the test device relative to the orientation of the cumulative charges, and a test plate eccentrically weighted to maintain the test plate at an angle relative to the orientation of the cumulative charges and configured to perceive the release of auxiliary charge . 31. The device according to clause 29, in which the test device contains an auxiliary charge located in the rotary support, a counterweight to bias the rotary support in the direction relative to the orientation of the cumulative charges, and an outer casing configured to perceive the release of the auxiliary charge. 32. The device according to clause 29, in which the test device includes an outer casing, a shaft in the outer casing for receiving through the detonating cord, one or more guides to support the shaft in the center of the outer casing and to allow free rotation of the shaft and a counterweight to bias shaft in a direction relative to the orientation of the cumulative charge so that when the detonating cord is detonated, the pressure inside the shaft increases to fix it inside one or more guides to keep the shaft shifted direction. 33. The device according to clause 29, in which the test device contains an outer casing, a rotary and test load, eccentrically weighted in the direction relative to the orientation of the cumulative charges, containing a hardened peak and having a Central hole for receiving a detonating cord, and a hardened peak placed in test load and made with the possibility of firing into the outer case with increasing pressure in the Central hole caused by detonation of the detonating cord. 34. The device according to clause 29, in which the test device includes a housing configured to receive through the detonating cord, and one or more balls made to rotate in the housing, offset in the direction relative to the orientation of the cumulative charges and made with the possibility of extrusion recesses on the housing with increasing pressure in the housing caused by detonation of the detonating cord. 35. The device according to clause 29, in which the test device contains a bearing support, configured to receive through a detonating cord and having at least one radial channel extending through it, an eccentric load mounted on a bearing support so that the load is displaced in the direction relative to the orientation of the cumulative charges, and shrapnel, which passes through at least one radial channel and hits an eccentric load when the detonating cord is detonated. 36. The device according to clause 29, in which the test device contains a bearing support, configured to receive through a detonating cord and having at least one radial channel extending through it, an eccentric load having one or more radial channels and mounted on the bearing support in such a way that the load is offset in the direction relative to the orientation of the cumulative charges, and one or more radial channels are flush with at least one radial channel in the bearing support and when onatsii detonating cord when an eccentric load is fixed orientation with carrier support.

Images