RU2013123039A - ICE SCREEN SUPPORTS FOR SELF-LIFTING DRILLING MARINE BASIS OF ICE CLASS - Google Patents

Abstract

1. Jack-up ice-class drilling rig for drilling for oil and gas in potentially ice conditions on coastal offshore areas, comprising: a floating hull having a relatively smooth deck in its upper part and an ice-curving shape in its lower part, extending downward and inward around the perimeter hulls, where the ice-bending shape extends from the hull zone near the deck level and extends downward near the bottom of the hull; an ice deflector section passing around the perimeter of the hull bottom to direct ice around the hull rather than under the hull; at least three supports installed inside the perimeter the bottom of the floating hull, while the supports are made with the possibility of lifting from the seabed to provide towing of the drilling rig through shallow water, as well as extension to the seabed and additional extension to lift the hull partially or completely out of the water; a self-lifting device connected to each support as for lifting supports from the seabed to jack-up drills The first ice-class rig could float due to the buoyancy of the hull, and pushing the supports down to the seabed and pushing the hull upward with partial exit from the water when floating ice floes threaten the rig, and completely out of the water when there is no ice; support ice screens installed to protect the truss supports from ice. 2. The jack-up rig according to claim 1, further including an anchoring mechanism coupled to the shoe of each leg to create additional resistance to forces that the floating ice may transmit to the rig. Jack-up rig �

Claims (18)

1. Self-elevating ice class drilling rig for drilling for oil and gas in potentially ice conditions on coastal sea areas, containing: a floating hull having a relatively smooth deck in its upper part and an ice-curving shape in its lower part extending downward and inward around the perimeter of the hull, the ice-curving shape extending from the hull area near the deck level and going down near the hull bottom; a section of an ice deflector extending around the perimeter of the bottom of the body to direct ice around the body, and not under the body; at least three supports installed inside the perimeter of the bottom of the floating body, while the supports are made with the possibility of lifting from the seabed to ensure towing of the drilling rig through shallow water, as well as extension to the seabed and additional extension for lifting the body partially or completely out of the water; self-lifting device connected to each support both to raise the support from the seabed so that the ice-class self-lifting drilling rig can float due to the buoyancy of the hull, and pushing the supports down to the seabed and pushing the hull up with partial exit from the water when floating ice floes threaten the drill installation, and completely out of the water when ice is absent; and ice screens of supports installed to protect the supports of the truss structure from ice. 2. The self-elevating drilling rig according to claim 1, further comprising a fastening mechanism connected to the shoe of each support, to create additional resistance to the forces that floating ice can transmit to the drilling rig. 3. Self-elevating drilling rig according to claim 1 or 2, in which the curving ice surface deviates upward and outward from the neckline of a reduced size to a ledge of an increased size. 4. Self-elevating drilling rig according to claim 1 or 2, in which the curving surface of the ice extends vertically at least 8-10 or more meters. 5. Self-elevating drilling rig according to claim 3, in which the curving surface of the ice extends vertically at least 8-10 or more meters. 6. The self-elevating drilling rig according to claim 4, in which the angle of the curving surface of the ice has a value in the range of 30-60 degrees from the vertical. 7. Self-elevating drilling rig according to claim 5, in which the angle of the curving surface of the ice has a value in the range of 30-60 degrees from the vertical. 8. A self-elevating drilling rig according to any one of claims 1, 2 or 5-7, wherein the ice-curving surface comprises a plurality of relatively smooth inclined sections extending around the periphery of the drilling rig. 9. The self-elevating drilling rig according to claim 3, wherein the ice-curving surface comprises a plurality of relatively smooth inclined sections extending around the periphery of the drilling rig. 10. The self-elevating drilling rig according to claim 4, in which the ice-curving surface comprises a plurality of relatively smooth inclined sections extending around the periphery of the drilling rig. 11. Self-elevating drilling rig according to claim 1 or 2, in which the truss supports include long racks connected by transverse elements, and ice screens of supports installed in the span between long racks and protecting the transverse elements of the supports. 12. The self-elevating drilling rig according to claim 1 or 2, in which the ice screens of the supports extend along the supports from a mark below to a mark above the waterline, when the self-lifting drilling rig is installed for drilling, the distance is less than the length of the supports and are designed to cover the span between the long racks and protecting the transverse elements of the supports. 13. A method for exploratory drilling in waters prone to ice, where an exploratory well is drilled to determine the existence and profitability of hydrocarbon reserves in the reservoir under the seabed, in which: create a drilling rig with a floating hull having a relatively smooth deck in its upper part and an ice-bending form in its lower part, the ice-bending form extending from the hull area near the deck level and going down near the bottom of the hull, and an ice deflector section passing around the perimeter the bottom of the body for directing ice around the body and not under the body; create at least three truss supports installed in the perimeter of the bottom of the housing, each support contains many vertical racks connected by transverse elements, and ice screens installed between the racks to protect the transverse elements from ice; lower each support so that the shoes at the bottom of the supports come into contact with the seabed and lift the body up and out of the water when ice does not threaten the rig, when the rig drills a well at the drilling site; and the body is lowered into the ice protection configuration, with the ice bending form passing above and below the sea surface to bend the ice going to the drilling rig, to ensure that the ice is submerged under water and applying bending forces breaking the ice, while the ice bypasses the drilling installation. 14. The method according to item 13, further comprising the step of securing the support on the seabed for additional resistance to the forces of floating ice floes. 15. The method according to item 13 or 14, in which the curving ice surface passes from the ledge to the neckline, and the stage of lowering the body into the water, in particular, includes the lowering of the body into the water so that the neckline is at least 4 meters below the sea surface and the ledge is at least 7 meters above the sea surface. 16. The method according to item 13 or 14, further comprising the step of lifting the hull from the water when the threat from floating ice is reduced. 17. The method according to clause 15, further comprising the step of lifting the hull from the water, when the threat from floating ice is reduced. 18. A method of drilling in waters prone to ice, comprising the use of a drilling rig according to any one of claims 1 to 12.