RU2001117069A - Method and system for providing access to an underground deposit from the surface - Google Patents

Claims (88)

1. A method of providing access to the underground zone from the surface, characterized in that it includes the following operations: drilling a plurality of mainly vertical wells from the surface to the underground zone, drilling an articulated well from the surface to the underground zone, wherein the articulated well is horizontally offset from each from mainly vertical wells at the surface and crosses each mainly vertical well at the joint near the underground zone, and drilling through an articulated well mainly cial drainage pattern extending from each of the junctions into the subterranean zone. 2. The method according to claim 1, characterized in that it further includes the following operations: the formation of an expanded cavity in each of the mainly vertical wells near the underground zone, drilling an articulated well to the intersection with the expanded cavity of each of the mainly vertical wells, and drilling through an articulated well of substantially horizontal drainage patterns extending from each of the expanded cavities into the subterranean zone. 3. The method according to claim 1, characterized in that the underground zone is a coal seam. 4. The method according to claim 1, characterized in that the underground zone is an oil layer. 5. The method according to claim 1, characterized in that it additionally provides for the production of fluid from the underground zone through mainly vertical wells. 6. The method according to claim 1, characterized in that it further provides for the installation of a mainly vertical plug-in, sucker rod pump unit in each of the mainly vertical wells, with the pump inlet located in the immediate vicinity of the corresponding joint, and the activation of the mainly vertical an inserted sucker rod pump unit for extracting fluid from the underground zone. 7. The method according to claim 1, characterized in that the underground zone contains a low pressure zone. 8. The method according to claim 1, characterized in that the drilling of mainly horizontal drainage circuits going from each of the joints to the underground zone includes the following operations: drilling of a mainly horizontal well from each of the joints limiting the first end of the area in the underground zone, to the remote end of this area, drilling the first set of mainly horizontal lateral wells having a predetermined spatial position relative to each other, from a mainly horizontal well to the periphery of the region, a first side mainly horizontal well, and drilling a second set of mainly horizontal lateral well bores having a predetermined spatial position relative to one another, of mainly horizontal well towards the periphery of the area on a second opposite side of the main horizontal well. 9. The method according to claim 8, characterized in that each of the side wells departs from the mainly horizontal well at an angle of about 45 °. 10. The method according to claim 8, characterized in that the area of the underground zone is mainly in the shape of a quadrangle. 11. The method according to claim 8, characterized in that the area of the subterranean zone is mainly in the form of a square. 12. The method according to claim 1, characterized in that the drilling of mainly horizontal drainage schemes going from each of the joints to the underground zone includes the following operations: drilling drainage schemes using an articulated drill string passing through an articulated well and joints, supply of drilling fluid down through the articulated drill string and back up through the annular space between the articulated drill string and articulated borehole to remove drill cuttings from drilling drainage circuits soup articulated drill string, the introduction of drilling gas into the substantially vertical well and mixing the drilling gas with the drilling fluid at the junctions to reduce hydrostatic pressure in the subterranean zone during drilling of the drainage patterns. 13. The method according to p. 12, characterized in that the drilling gas contains air. 14. The method of claim 12, wherein the subterranean zone comprises a low pressure reservoir having a pressure below 250 psi. 15. The method according to claim 1, characterized in that the drilling of mainly horizontal drainage schemes going from each of the joints to the underground zone includes the following operations: drilling drainage schemes using an articulated drill string passing through an articulated well and joints, supplying drilling fluid down through an articulated drill string to remove drill cuttings obtained by drilling drainage patterns using an articulated drill string, pumping drilling fluid with drill cuttings up through mainly vertical wells to reduce hydrostatic pressure in the underground zone while drilling drainage schemes. 16. The method of claim 15, wherein the subterranean zone comprises an ultra-low pressure reservoir having a pressure below 150 psi. 17. A system for providing access to an underground zone from a surface, characterized in that it includes a plurality of mainly vertical wells extending from the surface to the underground zone, an articulated borehole extending from the surface to the underground zone, the articulated borehole being horizontally offset from each of the mainly vertical wells at the surface and intersects each mainly vertical well at the joint near the underground zone and mainly the horizontal drainage pattern going from from joints to the underground zone. 18. The system according to 17, characterized in that each of the joints additionally contains an expanded cavity formed in the corresponding mainly vertical well near the underground zone. 19. The system according to 17, characterized in that the underground zone is a coal seam. 20. The system according to 17, characterized in that the underground zone is an oil layer. 21. The system of claim 17, wherein the subterranean zone comprises a low pressure reservoir. 22. The system of claim 17, wherein the subterranean zone comprises an ultra-low pressure reservoir having a pressure below 150 psi. 23. The system according to 17, characterized in that it further comprises a mainly vertical plug-in sucker-rod pump unit installed in at least one of the mainly vertical wells for pumping fluid from the underground zone through a suitable joint to the surface. 24. The system according to item 23, wherein the mainly vertical plug-in sucker rod pump unit contains a suction plug-in sucker rod pump. 25. The system according to 17, characterized in that each of the horizontal drainage schemes includes: a mainly horizontal well extending from the corresponding joint bounding the first end of the region in the underground zone to the remote end of this region, the first set of mainly horizontal lateral wells having a predetermined spatial position relative to each other, coming from a mainly horizontal well to the periphery of the region, on the first side of the mainly horizontal well, and a second set t mainly horizontal lateral well bores having a predetermined spatial position relative to each other, coming from mainly horizontal well towards the periphery of the area on a second opposite side of the main horizontal well. 26. The system according A.25, characterized in that each of the side wells departs from the mainly horizontal wells at an angle of about 45 °. 27. The system according A.25, characterized in that the area of the underground zone has mainly the shape of a quadrangle. 28. The system according A.25, characterized in that the area of the underground zone is mainly in the form of a square. 29. The main horizontal underground drainage scheme to provide access to a given area of the underground zone from the surface, characterized in that it includes: mainly a horizontal well extending from the borehole drilled from the surface of the boundary bounding the first end of the area in the underground zone to the remote the end of this area, the first set of mainly horizontal lateral wells having a predetermined spatial position relative to each other, coming from a mainly horizontal well, on p the first side of the mainly horizontal well, and the second set of mainly horizontal lateral wells having a predetermined spatial position relative to each other and coming from the mainly horizontal well on the second opposite side of the diagonal, the length of the side wells of both the first and second sets gradually decreasing as the distance between each side well and the well drilled from the surface increases. 30. The underground drainage scheme according to clause 29, wherein the lateral wells go to the periphery of a given area of the underground zone. 31. The underground drainage scheme according to clause 29, wherein each of the lateral wells goes at an angle of 40 to 50 ° from a mainly horizontal well. 32. The underground drainage circuit according to clause 29, wherein each of the lateral wells goes at an angle of about 45 ° from the mainly horizontal well. 33. The underground drainage circuit according to clause 29, wherein said region is a quadrangle, and said ends include the remote corners of the quadrangle. 34. The underground drainage circuit according to clause 29, wherein the specified area is a square, and these ends include the opposite corners of the square. 35. The underground drainage scheme according to clause 29, wherein the mainly horizontal and lateral wells provide mainly uniform coverage of the specified area. 36. The underground drainage circuit according to clause 29, wherein the lateral wells in each of the sets are mainly uniformly offset from each other. 37. Structure for providing access to a given area of the underground zone, characterized in that it includes: a first mainly vertical well that borders one end of the first area in the specified area, a second mainly vertical well that borders one end of the second area in the specified area adjacent to said first region, an articulated well that has a first section intersecting the first mainly vertical well at the first joint, and a second section intersecting the second main image then a vertical well at the second joint, the first mainly horizontal diagonal well, going from the first joint along a line with the first section of the articulated well to the remote end of the first region, the second mainly horizontal diagonal well, going from the second joint along the line with the second joint wells to the remote end of the second region, each diagonal well comprising a plurality of substantially horizontal lateral wells extending from the diagonal well to the periphery The series of the area that contains the diagonal well. 38. The structure according to clause 37, wherein the lateral wells extending from each of the diagonal wells include: a first set of lateral wells extending from the diagonal well to the periphery of the region, on the first side of the diagonal well, a second set of lateral wells, going from the diagonal well to the periphery of the area, on the second opposite side of the diagonal well. 39. The structure of claim 38, wherein the lateral wells are substantially evenly spaced from each other. 40. The structure according to § 38, characterized in that the lateral wells gradually become shorter as they move away from the mainly vertical wells in this area. 41. The structure according to clause 37, characterized in that it further includes: a third mainly vertical well, bounding one end of the third region in the specified area, a fourth mainly vertical well, bounding one end of the fourth region in the specified area, articulated well , which has a third section intersecting a third mainly vertical well at a third joint, and a fourth section crossing a fourth mainly vertical well at a fourth joint, third chapters Thus, the horizontal diagonal well, going from the third joint in a line with the third section of the articulated well to the remote end of the third region, and the fourth mainly horizontal diagonal well, going from the fourth joint in one line with the fourth section of the articulated well to the remote end of the fourth region. 42. The method of forming an underground drainage scheme to provide access to a given area of the underground zone from the surface, characterized in that it includes the following operations: drilling through the articulated well of a mainly horizontal well extending from the first end to the second end of the specified area of the underground zone, a change in the inclination of the mainly horizontal well at each of the plurality of lateral points, and after drilling the mainly horizontal well with an articulated drill string, retraction with a stratified drill string into each of the consecutive side points and drilling a plurality of side wells from said side points extending from each side of a mainly horizontal well to the periphery of the region, the length of each of the side wells gradually decreasing as the distance between each side point and the first end increases area. 43. The method according to § 42, characterized in that it further provides, mainly a uniform distribution of the lateral points along a mainly horizontal well. 44. The method according to § 42, characterized in that it further comprises drilling lateral wells from each corresponding lateral point at an angle of 45 ° to the mainly horizontal well. 45. The method according to item 42, wherein the specified region of the underground zone has mainly the shape of a quadrangle. 46. The method according to § 42, wherein the specified area of the underground zone is mainly in the form of a square. 47. The method according to § 42, wherein the first and second ends limit the opposite angles of the area. 48. The method of preparing the underground zone for field development, characterized in that it includes the following operations: drilling a mainly vertical well from the surface to the underground zone, drilling an articulated well from the surface to the underground zone, wherein the articulated well is horizontally offset from the mainly vertical wells at the surface and crosses mainly a vertical well at the joint near the underground zone, drilling through an articulated well of a mainly horizontal drainage circuit we going from the joint to the underground zone, drainage of water from the underground zone through the drainage circuit to the joint, pumping water from the joint to the surface through a mainly vertical well, and gas production from the underground zone through at least one of the mainly vertical and articulated wells . 49. The method according to p, characterized in that at the junction provides an expanded cavity formed in a mainly vertical well. 50. The method according to p, characterized in that the underground zone is a coal seam. 51. The method according to p. 48, characterized in that it further provides for: installing a mainly vertical plug-in sucker rod pump unit in a mainly vertical well, with the pump inlet in the immediate vicinity of the joint, and pumping water from the joint to the surface through mainly vertical push-in sucker rod pump unit. 52. The method according to p, characterized in that the underground zone contains a low pressure zone. 53. The method according to p. 48, characterized in that the drilling of a mainly horizontal drainage circuit going from the junction includes the following operations: drilling a diagonal well from the junction bounding the first end of the area aligned with the underground coal chamber to the opposite end of this areas, drilling a plurality of side wells on each side of the diagonal well leading to one or more coal chambers. 54. The method according to item 53, wherein the drainage circuit contains a feathery structure. 55. The method according to p. 48, characterized in that it further provides for re-hydration of the underground zone after the degassing of the underground zone, by injecting water into the underground zone through the drainage scheme. 56. The method according to p. 55, characterized in that it further provides for the injection of additives into the underground zone through the drainage scheme. 57. The method according to p. 48, characterized in that it further provides for the extraction of gas from the produced space through at least one of the mainly vertical and articulated wells, after completion of field development in the area of the underground zone through which the drainage scheme passes. 58. A cavity submersible pump, characterized in that it comprises: a borehole section having an inlet for discharging the borehole fluid from the underground cavity, and a device for selecting a position in the cavity articulated with the borehole section, the device for selecting a position in the cavity being elongated from the first position to the second position inside the underground cavity, for installing the inlet at a predetermined location within the underground cavity. 59. The cavity submersible pump according to claim 58, characterized in that the device for selecting a position in the cavity is rotatably connected to the well section, the device for selecting the position in the cavity being rotatable from the first position to the second position. 60. The cavity submersible pump according to claim 58, wherein the device for selecting a position in a cavity automatically extends from a first position to a second position when the device for selecting a position in a cavity transitions from a vertical well to an underground cavity. 61. The cavity submersible pump according to claim 60, wherein the device for selecting a position in the cavity is further configured to retract from the second position to the first position, when said device for selecting the position is withdrawn from the cavity. 62. The cavity submersible pump according to claim 58, wherein the device for selecting a position in the cavity has a first end and a second end and is rotatably connected to the borehole portion between its first and second ends, the device for selecting a position in the cavity having at the first end, a section of the counterweight, providing the second end to turn outward into the underground cavity, when the device for selecting a position in the cavity makes a transition from a vertical well to the underground cavity. 63. The cavity submersible pump according to claim 62, characterized in that the counterweight section additionally provides a combination of a device for selecting a position in the cavity with a vertical well to ensure withdrawal from the cavity of the specified device for selecting the position. 64. The cavity submersible pump according to claim 58, characterized in that the device for selecting a position in the cavity has a first end and a second end, which are adapted to extend outward mainly in opposite directions, for installing the device for selecting a position in the cavity in a second position moreover, the device for selecting a position in the cavity is configured to enter into contact with a portion of the underground cavity to install the inlet at a predetermined location. 65. The cavity submersible pump according to claim 58, wherein the device for selecting a position in the cavity in its second position comes into contact with a portion of the underground cavity to prevent the inlet from moving downward into the sump. 66. A method of producing gas from an underground coal seam, characterized in that it includes the following operations: drilling a first mainly vertical well intersecting said coal seam, forming an expanded diameter cavity in said first well at a depth of said coal seam, drilling a second well with horizontal displacement relative to said first well, said second well comprising mainly a horizontal section intersecting said cavity, and drilling a head an otherwise horizontal main drainage well in said coal seam, said drainage well intersecting said cavity, and gas is produced from said coal seam through said drainage well. 67. The method according to p, characterized in that it further includes the operation of gas production from the specified coal seam. 68. The method according to p. 67, characterized in that in the case of excess water in the coal seam, it further includes the operation of installing a pump in the specified cavity, draining water from the coal seam through the specified drainage well and pumping this water upward through the barrel of the specified first well . 69. The method according to p, characterized in that it further comprises drilling a plurality of secondary drainage wells in said coal seam intersecting said main drainage well. 70. The method according to p, characterized in that the specified primary and secondary drainage wells form a feathery pattern. 71. A method of producing gas from an underground coal seam, characterized in that it includes the following operations: drilling a first mainly straight well from a surface intersecting said coal seam, logging said first well to identify the depth of the coal seam, forming an expanded diameter cavity in said first well at a depth of the coal seam, drilling a displaced well from the surface before crossing with a specified cavity, using said displaced well to drill in the main image of the horizontal main drainage well in the specified coal seam crossing the specified cavity, and many secondary drainage wells in the specified coal seam, each of the secondary drainage wells intersecting the main drainage well, the drainage of water from the coal seam through the secondary and main drainage wells into the specified cavity pumping water from the cavity to the surface through said first well, withdrawing gas from the coal seam through secondary and main drainage wells, and supplying gas to surface through said first well. 72. The method according to p, characterized in that the said primary and secondary drainage wells form a feathery pattern. 73. A method of creating drainage wells in an underground coal seam, characterized in that it includes the following operations: creating a first mainly straight well that goes from the surface at least to the depth of the coal seam, logging the first well to identify the depth, which the first well crosses the coal seam, expanding the diameter of the first well at a depth of the coal seam to create a cavity at a depth of the coal seam that communicates with the first well, urination of another well displaced horizontally from said first well, said displaced well having mainly a vertical section extending from the surface to a depth less than the depth of the coal seam, mainly a horizontal section crossing said cavity and a curved section connecting said horizontal and vertical sections, the use of an articulated drill string passed through the specified offset well and the specified cavity for drilling the main drainage wells in the coal seam, supplying the drilling fluid downward through the articulated drill string and back upward through the annular space between the indicated displaced borehole and the articulated drill string to remove drill cuttings from the main drainage well, and mixing the compressed air into the drilling fluid to reduce hydrostatic pressure in said main drainage well, thereby reducing the possibility of rebalancing the drilling conditions in the specified drainage well. 74. The method according to p, characterized in that at least a portion of the compressed air is supplied through an articulated drill string. 75. The method according to p, characterized in that at least a portion of the compressed air is supplied through the specified first well. 76. The method according to p. 73, characterized in that it further includes the following operations: removing the articulated drill string from the drainage well and the displaced well, sealing said displaced well, draining the water and gas flow from the coal seam through said drainage well, supply water to the surface through the specified main well, and the supply of gaseous methane to the surface through the specified main well. 77. A method of producing coal from an underground coal seam, characterized in that it involves preparing the coal seam for mining by removing excess water and hazardous gases from it, before coal mining from the coal seam, the preparation includes the following operations: the creation of the first mainly direct borehole, going from the surface to the specified coal seam, the creation of an extended diameter cavity in the specified borehole approximately at the depth of the coal seam, the main drilling a horizontal drainage well in the coal seam that communicates with the specified cavity, drainage of excess water and the discharge of hazardous gases from the coal seam through the drainage well into the specified cavity, pumping water and the removal of hazardous gases from the cavity to the surface through the specified mainly direct well, and continued operations of water drainage and the removal of hazardous gases from the coal seam into the specified cavity and pumping water and the removal of hazardous gases from the cavity to the surface until it is produced from the coal seam Alain desired amount of water and dangerous gases. 78. The method according to p. 77, characterized in that it further provides for the creation of many secondary drainage wells in the specified coal seam in communication with the specified main drainage well. 79. The method according to p, characterized in that the said primary and secondary drainage wells form a feathery pattern. 80. A method of providing access to the underground zone from the surface, characterized in that it includes the following operations: drilling a mainly vertical well from the surface to the underground zone, drilling an articulated well from the surface to the underground zone, wherein the articulated well is horizontally offset from the main a vertical borehole at the surface, has a radius of at least 100 feet and crosses mainly a vertical borehole at a junction close to the subterranean zone, and drilling through an articulated wellbore the backbone of the horizontal drainage pattern going from the junction to the subterranean zone, and choosing a radius of at least 100 feet from the articulated well reduces friction in it and allows you to increase the distance of the drainage pattern from the junction. 81. The method according to p. 80, characterized in that it further includes the following operations: forming an expanded cavity in a mainly vertical well close to the subterranean zone, drilling an articulated well to an intersection with the extended cavity, and drilling through an articulated well mainly horizontal drainage scheme going from the expanded cavity to the underground zone. 82. The method of claim 81, wherein the formation of the expanded cavity is the formation of an expanded cavity with a radius of about 8 feet. 83. The method of providing access to the underground zone from the surface, characterized in that it includes the following operations: drilling a mainly vertical well from the surface to the underground zone, drilling an articulated well from the surface to the underground zone, wherein the articulated well is horizontally offset from the main a vertical well at the surface and crosses mainly a vertical well at the junction close to the subterranean zone, drilling through an articulated well of a mainly horizontal drainage pattern, and uschey from the junction into the subterranean zone, and extraction of minerals from the subterranean zone through the substantially vertical well bore. 84. The method according to p, characterized in that it further provides for: installing a mainly vertical plug-in sucker rod pump unit in a mainly vertical well, with the pump inlet located in the immediate vicinity of the joint, and activating a mainly vertical plug-in sucker rod pump block for mining from the underground zone. 85. A method of providing access to the underground zone from the surface, characterized in that it includes the following operations: drilling a mainly vertical well from the surface to the underground zone, drilling an articulated well from the surface to the underground zone, wherein the articulated well is horizontally offset from the main a vertical well at the surface and intersects mainly a vertical well at the joint near the subterranean zone, and drilling through an articulated well of a mainly horizontal drainage pattern, going from the junction to the underground zone, and the drainage scheme includes mainly a horizontal well and many side wells extending from each side of the mainly horizontal well. 86. A method of producing gas from an underground coal seam, characterized in that it includes the following operations: drilling a first mainly vertical well intersecting said coal seam, drilling a second well with horizontal displacement relative to the first well, said second well mainly a horizontal section crossing the first well, drilling a mainly horizontal drainage well in a coal seam, said drainage well extending from the intersection of howling and the second well, and gas production from the specified coal seam through the drainage well and the first well. 87. A method of providing access to the underground zone from the surface, characterized in that it includes the following operations: drilling the first well from the surface to the underground zone, drilling a second well that intersects the first well at a joint near the underground zone, said second well having a bend radius of at least 100 feet and drilling a substantially horizontal drainage pattern extending from the joint into the subterranean zone, the selection of a bend radius of at least 100 feet of the second well to reduce friction and It allows one to increase the distance from the junction of the drainage pattern. 88. A method of providing access to the underground zone from the surface, characterized in that it includes the following operations: drilling a mainly vertical well from the surface to the underground zone, drilling an articulated well from the surface to the underground zone, wherein the articulated well is horizontally offset from the main a vertical well at the surface and crosses mainly a vertical well at the junction close to the subterranean zone, drilling through an articulated well of a mainly horizontal drainage pattern, and uschey from the junction into the subterranean zone using an articulated drill string, mud feed down through the articulated drill string and back up through the annulus between articulated drill string and articulated borehole, to remove drill cuttings obtained by drilling a drainage circuit using an articulated drill string, introduce drilling gas into a mainly vertical borehole, and mix the drilling gas with the drilling fluid at the joint to reduce hydrostatic pressure in the underground zone during drilling drainage scheme.