RU2002111637A - Method for orienting cumulative charges, oriented firing punch (options), method for orienting firing punch, method for active orientation of drill string components, method for placing downhole components, rigid centering holder, method for checking the correct orientation, orientation measuring device, punching system and punching method - Google Patents

Claims (64)

1. The method of orientation of the cumulative charges, in which eccentrically weight one or more components of the drill string to orientate the cumulative charges in the desired direction. 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 one or more of the components of the drill string is eccentrically weighted by adding additional material to change the center of gravity. 4. The method according to claim 1, wherein one or more of the components of the drill string is eccentrically weighted by removing material to change the center of gravity. 5. The method according to claim 1, wherein one or more of the components of the drill string is eccentrically weighted by placing one or more of the components of the drill string in the drill string at a place where the center of gravity of one or more components of the drill string is remote from the axis of rotation columns of perforators. 6. The method according to claim 1, wherein a rotary charge tube is used as one or more components of the drill string. 7. The method according to claim 1, in which, as one or more components of the drill string, an articulated charging tube having a plurality of segments interlocked with each other so that the individual segments are able to bend without being disengaged is used. 8. The method according to claim 1, in which, in addition, determine the unevenness of the bending moment in one or more components of the column of perforators, and compensate for the unevenness of the bending moment. 9. The method of claim 8, wherein 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. 10. 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 the number of components of the drill string is eccentrically weighted to orient the cumulative charges in the desired direction. 11. The oriented firing drill according to claim 10, in which the shape of the shell of one or more cumulative charges is changed to shift its center of gravity. 12. Oriented firing punch according to claim 10, in which loads are attached to the shell of one or more cumulative charges. 13. Oriented firing drill according to claim 10, in which one or more cumulative charges are fixed in the charging tube at a place where the center of gravity of one or more cumulative charges is remote from the axis of rotation of the firing hammer. 14. The oriented firing punch of claim 10, wherein additional material is added to the punch body. 15. The oriented firing punch of claim 10, wherein material is removed from the punch body. 16. Oriented firing punch according to clause 15, in which due to the removal of material formed recesses on the surface of the body of the punch. 17. Oriented firing punch according to claim 10, in which additional material is attached to the charging tube. 18. Oriented firing punch according to claim 10, in which the material is removed from the charging tube. 19. Oriented firing punch according to claim 10, in which the charging tube is made in the form of an eccentrically weighted rotary charging tube. 20. Oriented firing punch according to claim 19, in which the rotary charging tube has an attached pendulum load. 21. The oriented firing drill according to claim 19, in which the rotary charging tube has an orienting load that surrounds at least a portion of one or more cumulative charges. 22. Oriented firing punch according to claim 19, in which the body of the punch one or more loads is oriented relative to the rotary charging tube. 23. Oriented firing drill according to claim 22, in which one or more loads are located outside the body of the drill. 24. The oriented firing drill according to claim 23, in which one or more loads are provided with rounded ends configured to guide the firing hammer through the bends of the well. 25. Oriented firing punch according to claim 10, in which the charging tube is made in the form of an articulated charging tube having a plurality of segments interlocked with each other so that the individual segments are able to bend without being disengaged. 26. The oriented firing punch of claim 10, wherein the punch body further comprises a pivotally weighted gasket attached to the drill string and having a plurality of segments interlocked so that the individual segments are able to bend without being disengaged. 27. Oriented firing punch according to claim 10, containing many shooting punch. 28. The oriented firing punch according to claim 27, wherein the plurality of firing punchers are fastened to each other by a rigid centering holder. 29. The oriented firing drill according to claim 28, wherein the rigid centering holder is configured to eliminate misalignment resulting from processing tolerances and gaps that exist in a plurality of firing drills. 30. A method of orienting a firing punch in a curved wellbore, wherein an articulated, weighted pad in a firing punch is used, comprising a plurality of eccentrically weighted segments interlocked so that the individual segments are able to bend without being disconnected from adjacent segments. 31. The method of active orientation of the components of the drill string, which determines the path of the wellbore, which will follow the components of the drill string, bend the material of the drill string with a curvature similar to the path of the well, which will follow the component, measure the amount of torque required to rotate the component of the drill string to the desired orientation angle when bending along the path of the wellbore, select the material of the drill string, which is required r minimum torque for rotating to a desired orientation angle, and use components of the column perforators manufactured with a selected perforating column material. 32. The method according to p, in which the torque is measured by a device for determining the characteristics of the torque in the presence of a bend. 33. 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 minutes or more downhole components, wherein the display is provided by the gyroscope. 34. The method according to p, in which one or more of the downhole components are control lines. 35. The method according to p, in which one or more downhole components is selected from downhole sensors, downhole equipment and downhole tools. 36. The method according to claim 33, wherein the detectable material is radioactive indicators used by applying to one or more downhole components, and one or more focused sensors is a gamma ray detector. 37. The method according to claim 33, wherein the detectable material is one or more radioactive labels used in one or more downhole components, and one or more focused detectors is a gamma ray detector. 38. The method according to p, in which the detected material is a radioactive liquid used to pump fluid into one or more downhole components, and one or more focused detectors is a gamma ray detector. 39. The method according to p, in which the detected material is a coolant used to pump fluid through one or more downhole components, and one or more focused detectors are devices for thermal detection. 40. The method according to claim 33, wherein the detected material is an induced EMF signal having signal changes based on the location of one or more downhole components, and one or more focused detectors are electrical detectors. 41. The method according to claim 33, wherein the detected material is a smart card type transducer used in one or more downhole components. 42. The method according to claim 33, wherein the detectable material is an electronic tag used in one or more of the downhole components. 43. The method according to claim 33, wherein the detectable material is a magnetic mark used in one or more downhole components, and one or more focused detectors are magnetometers. 44. The method of claim 33, wherein the one or more focused detectors are instruments for recording a reflected ultrasound signal that detect changes in acoustic impedance around one or more downhole components. 45. A rigid centering holder for rigidly connecting a plurality of borehole components in a fixed orientation, comprising a adapter sleeve having tapering keys, and a retaining ring having keyways for rigidly connecting with the adapter tapering keys and tabs for rigid connection to the borehole components. 46. The rigid centering holder of claim 45, wherein the rigid connection between the tapered keys and keyways eliminates manufacturing tolerances. 47. The rigid centering holder of claim 45, wherein the rigid connection between the legs and the downhole components eliminates manufacturing tolerances. 48. The rigid centering holder of claim 47, further comprising means for securing the retaining ring to the adapter sleeve with a rigid connection. 49. The rigid centering holder of claim 45, wherein the plurality of downhole components are firing punchers. 50. The rigid centering holder of claim 45, wherein the plurality of downhole components are selected from downhole tools and downhole equipment. 51. The rigid centering holder of claim 45, wherein the downhole components are selected from firing punch tools, downhole tools, and downhole equipment. 52. A method of checking the correct orientation of the cumulative charges in an explosion, in which a test device driven by a detonating cord of cumulative charges is used, the orientation of the test device relative to the orientation of the cumulative charges is maintained, and the detonating cord of cumulative charges is detonated to explode the cumulative charges and actuate the test device . 53. A device for measuring the orientation of cumulative charges in an explosion, comprising a test device that is kept stationary relative to the orientation of the cumulative charges, and a detonating cord, which is configured to both explode the cumulative charges and actuate the test device. 54. The device according to item 53, 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 the auxiliary charge . 55. The device according to item 53, 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 sense the release of the auxiliary charge. 56. The device according to item 53, 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 displacement of the shaft in the 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 Hinnom direction. 57. The device according to item 53, 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 the 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. 58. The device according to item 53, in which the test device comprises a housing configured to receive a detonating cord through itself, and one or more balls rotating in the housing, offset 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. 59. The device according to item 53, in which the test device contains a bearing support made with the possibility of receiving through a detonating cord and having at least one radial channel extending through it, an eccentric load mounted on a bearing support in such a way that the load is offset in the direction relative to the orientation of the cumulative charges, and shrapnel, which passes through at least one radial channel and hits the eccentric load when the detonating cord is detonated. 60. The device according to item 53, 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 a 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 and detonating the detonation cord is fixed at the eccentric weight orientation with carrier support. 61. A punching system comprising means for displaying a desired orientation, means for orienting a perforating system, and means for checking a proper orientation during an explosion. 62. A punching method in which a borehole is displayed to prevent perforation of selected borehole components, the punching system is oriented, and the correct orientation during the explosion is checked. 63. Oriented firing hammer drill containing one or more eccentrically weighted components of the drill string. 64. The oriented firing drill according to claim 63, wherein the component parts of the drill string are selected from cumulative charges, charging tubes and drill cases.