RU2516315C2 - Support stand-anchor of marine platform - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction of platforms to mount drilling and oil production equipment in the sea. The support stand-anchor of the marine platform comprises joined upper section with the upper support site, ballast cisterns-sections and the lower drilling section, in which there is a hydraulic engine installed, to the shaft of the rotor of which a drill is connected, and a pipeline of water drain and a nozzle of water drain are connected to the stator of the hydraulic engine. At the same time on the marine platform in the control cabin the system of filling-emptying of ballast cisterns-sections additionally comprises a compressor for compressed air, the outlet of which via serially connected first valves and three-way switching valves are connected to pipelines of compressed air supply, hydraulic pumps. Between ballast cisterns-sections there are remote support sections, the upper section is made in the form of two coaxial hollow cylinders arranged relative to each other coaxially. The upper support site by means of hinge parts rigidly connected to it and the marine platform, may rotate around the common axis of the hinged joint, and with it the entire support stand of the anchor with removal of the bolt joints by means of its transition from the vertical working position into the horizontal transport position.

EFFECT: expansion of functional capabilities of a support stand-anchor and reduction of axial load.

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Description

The invention relates to the field of drilling oil and gas wells on the continental shelf, and in particular, to the construction of platforms at sea on which drilling and oil-producing equipment are mounted.

Known pile - the anchor support anchor of the offshore platform, containing the upper section interconnected by flange connections with the support platform, ballast pipe sections - ballast tanks with a system for filling and emptying of water and compressed air and a lower drilling section in which the hydraulic motor is installed, to whose rotor shaft is connected with helical blades and a cone drill bit, and a water discharge line is connected to the stator of the hydraulic motor - a water supply pipe and a water discharge pipe .

The ballast tank filling-emptying system comprises a compressed air supply pipe, a water supply pipe and nozzles with kingston valves for draining water (see the description of the invention to RF patent No. 2071531, IPC E02B 17/00, publication 01/10/1997).

A disadvantage of the known support armature is the lack of functionality.

The objective of the invention is the expansion of functionality, which include:

- reduction of axial load due to hollow lattice remote support sections;

- the use of a drill reverse for multiple use of one stand for its intended purpose and transportation of the drilling platform together with the anchor stand to a new drilling site.

The invention consists in the following.

Anchor support anchor of the offshore platform, containing the upper section interconnected by flange and bolt connections with the upper support platform, ballast tanks-sections with a system for filling and emptying them with water and compressed air, and the lower drilling section, in which the hydraulic motor is installed, to the rotor shaft of which a drill is connected, and a water supply pipe and a water discharge pipe are connected to the stator of the hydraulic motor, the filling system for emptying the ballast tanks-sections contains a supply pipe in odes, water discharge pipes and a compressed air supply pipe for emptying the ballast tanks sections from water, on the offshore platform in the control cabin, the ballast tank filling and emptying system additionally contains a compressor for compressed air, the output of which is through the first connected valves and three-way switching valves valves are connected to compressed air pipelines, which have the ability to discharge air from the ballast sections when they are filled with water through the appropriate the positions of the three-way switching valves and the second valves for releasing air into the atmosphere connected to them, a hydraulic pump, the output of which through the third valve is connected to the pipeline for supplying water to the ballast tank sections; a hydraulic pump, the output of which through the fourth valve is connected to the first pipeline for supplying water to the hydraulic motor, when the rotor is reversed, the output of the hydraulic pump through the fifth valve is connected to the second pipeline for supplying water to the hydraulic motor, remote support sections are located between the ballast tanks, the upper section is made in the form of two coaxial hollow cylinders located coaxially relative to each other, of which the first cylinder is made with two mja fixing diametrically arranged holes and rigidly connected with the upper support plate, a second cylinder is provided with two diametrically disposed spring fingers and a flange rigidly connected to the upper section, thus forming a mechanical latch; the upper supporting platform by means of the hinge parts rigidly connected with it and the sea platform has the ability to rotate around the common axis of the hinge, and with it the entire support armature when removing bolted joints by moving it from a vertical operating position to a horizontal transport position.

The invention is illustrated by drawings, where: in Fig.1. Shows the anchor support of the offshore platform, general view; figure 2 - also, with the offshore platform in transport position.

The anchor support column of the offshore platform contains interconnected flange and bolt joints 1 upper section 2 with upper support platform 3, ballast tanks-sections 4, between which are located remote support sections 5 and the lower drilling section 6, in which the hydraulic motor 7 is installed, to the shaft 8 of the rotor of which the drill 9 is connected, and to the stator of the hydraulic motor 7, a water supply pipe 10 and a water discharge pipe 11 are connected. The filling-emptying system of ballast tank sections 4 includes a water supply pipe 12, a water discharge pipe 13 and a compressed air supply pipe 14 for emptying the ballast tank sections 4 from water.

On the offshore platform in the control cabin, the ballast tank filling and emptying system 4 additionally contains a compressor 15 for compressed air, the output of which is connected through series-connected first valves 16 and three-way switching valves 17 to compressed air supply pipelines 14, which are able to discharge air from ballast tank sections 4 when they are filled with water through the corresponding position of the three-way switching valves 17 and the second air release valves 18 connected to them in a mosferu, a hydraulic pump 19 whose output via a third valve 20 connected to conduit 12 supplying water to the ballast tanks 4-sections.

A hydraulic pump 21, the output of which through the fourth valve 22 is connected to the first pipe 10 for supplying water to the hydraulic motor 7, when the rotor is reversed, the output of the hydraulic pump 21 through the fifth valve 23 is connected to the second pipe 24 for supplying water for the reverse of the hydraulic motor 7. Top section 2 is made in the form of two coaxial hollow cylinders 25 and 26 located coaxially relative to each other, of which the first cylinder 25 is made with two fixing and diametrically located holes and of a tight connected to the upper support plate 3 and the first cylinder 25 is formed with two diametrically located lugs 27 and a second cylinder is provided with two diametrically disposed spring fingers 28 and is rigidly connected with the flange upper rack 2, thus forming a mechanical latch. The upper support platform 3 through the parts of the hinge 30, rigidly connected with it and the sea platform 29, can rotate around the common axis of the hinge 30, and with it the entire support armature when removing the bolt joints 31 by moving it from a vertical operating position to a horizontal transport position .

The support armature works as follows.

The interconnected sections of the anchor support, located in a horizontal transport position (see Fig. 2), together with the offshore platform, are towed out to sea and brought to the point where the platform is supposed to be installed. Using the ability to rotate around the common axis of the hinge 30 of the upper supporting platform 3, and with it a rigidly fixed support armature, translate and fix it in a vertical position using bolted connections 31.

Ballast tanks-sections 4 are filled with water through nozzles (kingstones) 13, by transferring the three-way switching valves 17 to the appropriate position and opening the ventilation valves 18 connected to the pipe 14 to release air into the atmosphere. To accelerate the process of filling the ballast tanks, a hydraulic pump 19 is additionally used, the water leaving from it through a valve 20 connected to the pipeline 12. As a result of filling the ballast tanks, the weight of the anchor support column is increased and its soil is pressed closer together with the marine floating platform 29 by a force equal to γ Vbts (where γ is the density of water t / m ³ , Vbts is the volume of ballast tanks, m ³ ). At the same time, a gradual filling of auxiliary ballast tanks 32 of the offshore platform 29 takes place for landing it on the armature rack and pressing it to the ground. Using a hydraulic pump 21, the output of which through the valve 22 is connected to the pipeline 10, water is supplied to the hydraulic motor 7 and, by rotating the rotor shaft 8 and the drill 9 rigidly fixed on it, the anchor support is deepened into the ground. In the process of deepening the anchor support post into the ground, there is an increase in the landing of the floating platform and more rigid fixation of the floating structure on the ground. To ensure the stability of the floating structure during sea waves, it is necessary that the vectors of the lifting force γ V and the weight P of the floating platform-rack structure are on the same line, and the center of gravity G is between them. This position ensures the stability of the structure during sea waves and its inclinations at angles θ due to the occurrence of a restoring moment M = a sin θ γ V (where a is the distance between the points of application of the lifting force γ V and weight P, m; γ is the density of sea water t / m ³ ; V is the volume of the impermeable submerged part of the platform-rack construction, m ³ ).

The same stability conditions must be observed during transportation of the offshore platform to the installation site and after removal of the anchor post from the ground.

After completion of work on the shelf for excavation of the anchor support post from the ground using a compressor 15, the output of which through series-connected valves 16 and three-way switching valves 17 through the pipe 14, compressed air is supplied to the ballast tanks section 4 to displace the ballast water through the nozzles 13. At the same time with the blowing of the ballast tanks of the rack, the auxiliary tanks 32 of the offshore platform 29 are drained. After the water is displaced from the ballast tanks 4, the anchor support column receives a positive floating st and the hydraulic pump 21 via valve 23 and piping 24 water is supplied to reverse hydraulic motor 7. As a result, the rotor and reverse auger rotation shaft 9 August occurs auger recess 9 from the ground. By removing the bolted joints 31 and turning the parts of the hinge 30 around its common axis with the anchor rigidly connected to it, as well as the positive buoyancy resulting from the flushing of the ballast tanks 4, the rack is transferred to the horizontal transport position. Using guy wires ends (not shown in figure 2.) and eyelets 27, the armature is attached to the sea platform in a horizontal transport position. Remote support sections due to their permeability reduce the dynamic load on the support armature during sea waves and increase its stability. The pipelines of the support armature can be made flexible in the form of high pressure hoses.

The claimed invention allows you to:

- expand the functionality of the support armature;

- reduce axial load due to hollow lattice remote support sections;

- reuse the racks for their intended purpose and transport the drilling platform together with the anchor rack to a new drilling site.

Claims (1)

Anchor support anchor of the offshore platform, containing the upper section interconnected by flange and bolt connections with the upper support platform, ballast tanks-sections with a system for filling and emptying them with water and compressed air, and the lower drilling section, in which the hydraulic motor is installed, to the rotor shaft of which a drill is connected, and a water supply pipe and a water discharge pipe are connected to the stator of the hydraulic motor, the filling-emptying system of the ballast tank sections contains a supply pipe to odes, water discharge pipes and a compressed air supply pipe for emptying the ballast tank sections from water, characterized in that on the offshore platform in the control cabin, the ballast tank filling and emptying system further comprises a compressor for compressed air, the outlets of which are through the first connected in series valves and three-way switching valves are connected to the compressed air supply pipelines, which are able to discharge air from the ballast sections when they are filled with water through the corresponding positions of the three-way switching valves and the second valves for releasing air into the atmosphere connected to them, a hydraulic pump, the output of which through the third valve is connected to the water supply pipe to the ballast tank sections; a hydraulic pump, the output of which through the fourth valve is connected to the first pipeline for supplying water to the hydraulic motor, when the rotor is reversed, the output of the hydraulic pump through the fifth valve is connected to the second pipeline for supplying water to the hydraulic motor, remote support sections are located between the ballast tanks, the upper section is made in the form of two coaxial hollow cylinders located coaxially relative to each other, of which the first cylinder is made with two mja fixing diametrically arranged holes and rigidly connected with the upper support plate, a second cylinder is provided with two diametrically disposed spring fingers and a flange rigidly connected to the upper section, thus forming a mechanical latch; the upper supporting platform by means of the hinge parts rigidly connected with it and the sea platform has the ability to rotate around the common axis of the hinge, and with it the entire support armature when removing bolted joints by moving it from a vertical operating position to a horizontal transport position.

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