RU2719650C1 - Method for transportation of self-lifting floating drilling rig - Google Patents

Abstract

FIELD: soil or rock drilling.

SUBSTANCE: invention relates to floating not self-propelled self-lifting drilling rigs (SPDR) for search and exploration of hydrocarbon deposits at shallow-water marine areas. Method for transportation of self-lifting floating drilling rig includes use of auxiliary equipment for increasing depth margin under floating vehicle, in form of flexible elastic waterproof containers with initially zero buoyancy, which are brought under body of floating craft and fixed on side surface of floating craft, and then filled with compressed air, wherein the pontoon side surfaces of the self-lifting floating drilling rig along its perimeter are additionally equipped with L-shaped crossbars, the horizontal shelf of which is installed at the level of the main (upper) pontoon deck, flat lattice metal structures are laid over horizontal shelves of L-shaped crossbars, and under them flexible waterproof tanks with initially zero buoyancy are introduced, which are then simultaneously filled with compressed air. Pontoon at points of its retrofitting with L-shaped girders and their pre-installation are reinforced by stiffness ribs on inner side surface of pontoon and additional flat plates. L-shaped crossbars, on top of which flat lattice metal structures are laid, are made as detachable after transportation of SPDR over shallow water, installation of platform at the specified drilling point and for period of well construction. Flexible resilient watertight containers are modular and isolated from each other.

EFFECT: reduction of settling of self-lifting floating drilling rig during its transportation over maximum shallow water.

4 cl, 4 dwg

Description

The invention relates to hydraulic devices, in particular to floating non-self-propelled self-propelled floating drilling rigs (SPBU) for the search and exploration of hydrocarbon deposits in extremely shallow marine areas.

A known method of transporting a self-propelled floating drilling rig in shallow water areas with all or part of the side walls of the outside of the hull equipped with buoyancy compartments not reaching the upper deck and supports with a lifting mechanism (RF patent 2478752 from 05.13.2013). The disadvantage of this method is that when transporting a jack-up floating drilling rig in conditions of extreme sea shallow water, the buoyancy compartments on the outer side walls of the hull do not provide the necessary buoyancy and integrity of the bottom of the hull of the floating drilling rig. In addition, the buoyancy compartments mounted on the side walls of the body, in the working position when drilling the well, create an additional load on the support of the offshore platform, which is not taken into account during their design and manufacture, increase the sailness of the platform and the catchment area during precipitation.

A known method of transporting a self-propelled floating drilling rig in shallow water areas, equipping it along all or part of the side walls outside the pontoon (platform) with removable buoyancy compartments having an oval shape in their cross section, not reaching the upper deck, and supports with a lifting mechanism, and the lower surface the buoyancy compartments are buried 0.3 ... 0.5 m below the bottom of a self-elevating drilling rig (RF patent 2589237 dated 05.29.2014). The disadvantages of this method is that the volume of removable buoyancy compartments having an oval shape in their cross section does not provide transportation of a self-elevating floating drilling rig in the conditions of extreme shallow sea.

A known method of guiding a vessel through canals and shallow sections of inland waterways and a device for its implementation (RF patent 2446982 from 04/10/2012). The wiring method consists in the use of auxiliary equipment made in the form of pontoons. Pontoons are the bow and stern buoyancy modules. The increase in the depth reserve under the vessel is carried out by reducing the wave resistance when the vessel moves in shallow water due to the absorption of waves reflected from the hull. Waves are damped by means of buoyancy modules. Pontoons are equipped with fasteners to the hull. The stern and bow modules are made in the form of structures corresponding to the configuration of the bow and stern of the hull. The fastening elements to the hull of the vessel are made in the form of stops-clamps equipped with jacks and cables for tightening the buoyancy modules on the vessel. The disadvantage of this invention is the large metal consumption and the complexity of the manufacture of stern and bow pontoons, which must correspond to the shape and size of a particular type of vessel, the need for them to accurately pair with the bow and stern of the vessel and perform complex installation operations when installing and securing them to the hull of the vessel. All this raises doubts about the reliability of this method of escorting a vessel through shallow areas of a reservoir.

There is a method of piloting a boat in shallow areas of a reservoir by means of auxiliary equipment to increase the depth margin under the boat, which use flexible flexible waterproof containers connected by a mesh cloth, while with initially zero buoyancy, the tanks are brought under the body of the boat and fixed to the boat and then filled with compressed air (RF patent 2648555 from 10.31.2016). However, the fastening of flexible flexible waterproof containers on the side surfaces of the craft does not ensure its passage through extremely shallow water areas. In addition, the use of this method for transporting a jack-up drilling rig is not possible due to the design features of the pontoon of a jack-up drilling rig.

The technical result to which the claimed invention is directed is to reduce the draft of a self-elevating floating drilling rig during its transportation in extreme shallow water.

To achieve the technical result in a method of transporting a self-propelled floating drilling rig using auxiliary technical means to increase the depth reserve under the craft, which use flexible flexible waterproof containers with initially zero buoyancy, which are brought under the body of the craft and fasten them on the side surface of the craft, and then filled with compressed air, according to the invention, the side surfaces of the pontoon self-lifting floating the rig along its perimeter evenly and with an interval is additionally equipped with L-shaped crossbars, the horizontal shelf of which is installed at the level of the main (upper) deck of the pontoon, flat lattice metal structures are laid and fixed over the horizontal shelves of the crossbars, and flexible elastic waterproof containers are placed under them below. with initially zero buoyancy, which are then simultaneously filled with compressed air. In addition, the pontoon in the places of its equipping with L-shaped crossbars and their preliminary installation is reinforced with stiffeners on the inner side surface of the pontoon and with additional flat plates, L-shaped crossbars, on top of which flat lattice metal structures are laid and fixed, are made removable after transportation of SPBU to the limit shallow water, installation of the platform at a given point of drilling and for the period of well construction, and flexible flexible waterproof containers are modular and isolated and apart.

Distinctive features of the proposed method are:

• additional equipment before the transportation of SPBU in extreme shallow water for equipping the side surfaces of the pontoon with a self-elevating floating drilling rig along its outer perimeter evenly and with an interval of L-shaped crossbars, the horizontal shelf of which is installed at the level of the main (upper) deck of the pontoon;

• reinforcement of the pontoon with stiffening ribs and additional flat plates on its inner vertical lateral surface in the places where the pontoon is equipped with L-shaped crossbars and their preliminary installation on the pontoon;

• laying and fastening on top of the horizontal shelves of the L-shaped crossbars of flat lattice metal structures;

• execution of L-shaped crossbars, on top of which flat lattice metal structures are laid and fixed, removable after transportation of SPBU in the shallow water, installation of the platform at a given drilling point and for the period of well construction;

• the implementation of flexible waterproof containers modular and isolated from each other;

• supply of flexible modular elastic waterproof containers with initial zero buoyancy under the L-shaped crossbars, on top of which flat lattice metal structures are placed and fixed;

• simultaneous filling of isolated from each other flexible modular elastic waterproof containers with compressed air;

• retrofitting the pontoon of the SPBU L-shaped crossbars and lattice metal structures stacked on top of horizontal shelves of flexible modular elastic waterproof containers with compressed air of the L-shaped crossbars, supply of flexible modular elastic waterproof containers with initial zero buoyancy under the L-shaped crossbars and their simultaneous filling completion of drilling operations for transportation of SPBU to a new drilling point through the shallow water.

The essence of the invention is as follows.

Transportation of jack-up floating jack-up rigs to a new point is ensured by the presence of an airtight pontoon, which houses drilling, technological and power equipment. According to Archimedes' law, the buoyancy of the SPBU is ensured by the excess of the weight of the displaced water immersed in the water of the SPBU over the weight of the actual marine installation. At the same time, the pontoon of a self-elevating floating drilling rig is partially submerged in water.

If it is necessary to drill wells at extremely shallow depths of the sea, serious problems arise with the transportation of a self-propelled floating drilling rig and its installation at a given drilling point, due to significant settlement of marine self-propelled floating drilling platforms in the region. To enable the use of existing self-elevating floating drilling rigs in water areas with extremely shallow depths, there is a need to reduce their draft, i.e. ensuring a greater excess of the weight of the displaced water immersed in the water of the SPBU over the weight of the offshore platform itself. This can be achieved by increasing the volume of the body (pontoon SPBU), immersed in the sea. To do this, it is proposed that the volume of the SPBU pontoon immersed in the marine environment be supplemented with volumes of modular flexible elastic waterproof containers additionally installed along the side perimeter of the pontoon, which also act as pontoons, which initially lead to zero buoyancy under the horizontal shelves of L-shaped crossbars fixed uniformly and with an interval on the side surfaces of the pontoon SPBU.

To increase the forced immersion in water of modular flexible elastic waterproof containers filled with compressed air, they are installed and fixed under the horizontal shelves of the L-shaped crossbars, on top of which flat lattice metal structures are installed and fixed. In connection with the emergence of new additional loads on the pontoon of the SPBU, caused by the installation of L-shaped crossbars and flexible flexible waterproof containers filled with compressed air, pre-installation of the L-shaped crossbars, the inner vertical side surface of the pontoon is reinforced by installing stiffeners on the inner side surface of the pontoon and additional flat plates in the places of equipping the external lateral vertical surface of the pontoon with L-shaped crossbars. The reinforcement of the pontoon with stiffeners and flat plates is preliminarily equipped with L-shaped crossbars to equip the external vertical side surface of the pontoon.

The method is carried out by the following sequential steps in the order of presentation:

• if it is necessary to transport a self-elevating floating drilling rig through an extremely shallow water area to a given drilling point, reinforce the pontoon by setting stiffeners on the inner side vertical surface of the pontoon and additional flat plates in places of the planned retrofit of the outer side surface of the pontoon along its perimeter uniformly and with an interval of L-shaped crossbars ;

• on the lateral surfaces of the SPBU pontoon reinforced with stiffening ribs and flat plates along its perimeter and at intervals with the use of SPBU full-turn deck cranes and, if necessary, an additional crane, removable L-shaped crossbars are installed, the horizontal shelf of which is installed at the level of the main (upper) deck of the pontoon;

• on the horizontal shelf of the L-shaped crossbars, flat lattice metal structures are installed and fixed from above;

• using full-rotated deck cranes SPBU and, if necessary, an additional crane for horizontal shelves of L-shaped crossbars with flat lattice metal structures placed and fixed on them, modular flexible flexible waterproof containers with initially zero buoyancy are set up, separated by braces of crossbars, forming cells for modular flexible elastic waterproof containers;

• at the same time, compressed air from the compressor of the drilling rig is fed into modular flexible elastic waterproof containers through flexible high-pressure hoses;

• attach modular flexible elastic waterproof containers filled with compressed air to crossbars and flat lattice metal structures;

• attach a self-elevating floating drilling rig with reduced draft to the tugboats for transportation in the shallow water to the point of well drilling;

• install a self-propelled floating drilling rig at a given drilling point in extremely shallow waters;

• release compressed air from modular flexible elastic waterproof containers;

• disconnect modular flexible elastic waterproof containers with zero buoyancy from the L-shaped crossbars and with the use of SPBU full-turn deck cranes and, if necessary, put an additional crane onto the deck of a transport and towing vessel or barge;

• using SPBU full-turn deck cranes and, if necessary, an additional crane, dismantled L-shaped crossbars with flat lattice metal structures are dismantled and loaded onto a barge;

• drill a well in extremely shallow waters;

• after completion of the well’s construction, the pontoons of the SPBU are equipped with removable L-shaped crossbars, on the horizontal shelf of which flat lattice metal structures are mounted and fixed on top, modular flexible flexible waterproof containers with initially zero buoyancy are placed under them, at the same time they are filled with compressed air from the compressor of the drilling rig,

• SPBU is transported by a transport and towing vessel to a new drilling point.

The invention is illustrated by drawings, where in FIG. 1 shows a self-elevating floating drilling rig afloat in the transport position (side view) with L-shaped crossbars and modular flexible flexible waterproof containers along all side walls; in FIG. 2 is a section A-A of a self-elevating floating drilling platform in FIG. 1; in FIG. 3 - section BB in FIG. 2; in FIG. 4 is a view B shown in FIG. 3.

The implementation of the invention.

According to the bathymetric map, the water area of the North Caspian Area licensed area is shallow, heterogeneous. The depth of the sea in the water area of the Offshore West Rakushechnoye field, the structures of the West Rybachy, Severo-Ukatnaya varies from 1 to 3 m, - on the Rybachy, Pribortovaya and Tough structures - from 3 to 4 m with an average level of the Caspian minus 26.8 m .

The Astra self-propelled floating drilling rig is designed for drilling wells up to 4570 m deep with sea depths from 5 to 45 m. It has a hull length of 53.04 m, a hull width of 53.6 m, a hull height of 5.49 m, height of supports - 67.51 m.

The self-elevating floating drilling rig includes a hull in the form of a sealed pontoon, a main (upper) deck, with drilling, technological and power equipment installed on it, a residential complex, a drilling rig and a set of general ship systems and mechanisms.

On the main deck of a self-propelled floating drilling rig, there is a residential complex designed for 74 people at a time, a drilling rig and drilling equipment, a drilling fluid cleaning system, pressurized systems for receiving fuel and chemicals from transport vessels, shipments of spent drilling mud and all the towing vessels types of wastewater, silos for storage of bulk materials, sealed containers for collecting drill cuttings, vibrating screens, equipment for testing wells, cementing equipment equipment, pipe racks and drilling tools, two BLM full-turn deck cranes with a lifting capacity of 20 tons, helicopter landing pad.

A 44.8 m high Pyramid drill rig with a payload capacity of 474 tons is installed at the end of a double longitudinal cantilever beam behind the residential complex.

The settlement draft of the Astra self-elevating floating drilling rig is 3.81 m in the flooded position, the settlement draft when towing afloat by the sea is 3.385 m, which excludes its use for drilling wells in extremely shallow water areas.

The self-elevating floating drilling rig has a body in the form of a sealed pontoon 1 with a bottom 2, an upper deck 3 on which a derrick 4 is installed, two full-slewing cranes 5, drilling equipment and a helipad (not shown), side walls 6 of the pontoon 1, three supports 7 with lifting mechanisms 8, located in the shaft 9. Along the outer perimeter of the side walls 6 of the pontoon 1, with the help of deck cranes 5 SPBU and, if necessary, an additional crane, removable L-shaped crossbars 10 are installed uniformly and with an interval, horizontal floor and 11 are located at the level of the main (upper) deck 3 SFDR. The lower ends of the vertical component of the L-shaped crossbars 10 are installed at the level of the bottom 2 of the pontoon 1. Pontoon 1 pre-installation of the L-shaped crossbars 10 is reinforced by installing stiffeners 15 on the inner vertical side surface and the inner bottom of the pontoon 1, as well as additional flat plates 16 in retrofit of the outer side surface of the pontoon with 1 L-shaped crossbars. On the horizontal shelves 11 of the crossbars 10, flat lattice metal structures 12 are placed and fastened to them, which in width correspond to the horizontal shelves 11 of the crossbars 10. To ensure strength and rigidity, the L-shaped crossbars 10 are provided with braces 13.

Modular flexible elastic waterproof containers 14 with zero buoyancy are brought into cells, formed by the side walls 6 of the pontoon 1, horizontal shelves 11 with flat lattice metal structures 12 and braces 13, and are attached to the crossbars 10 and metal structures 12.

Through flexible hoses (not shown in the drawings) high pressure from the compressor (not shown) of the drilling rig, compressed air is simultaneously supplied to the modular flexible elastic waterproof containers 14.

The implementation of flexible flexible waterproof containers 14 in the form of modules isolated from each other allows you to maintain the buoyancy of a self-elevating drilling rig even in case of integrity loss as a result of damage to one of the modules.

With the length of each side surface 6 of a self-floating floating drilling rig 53 m for a horizontal shelf of 11 L-shaped crossbars, for example, 5 m long, the approximate volume of all modules of flexible flexible waterproof containers mounted on three lateral planes of the pontoon can be more than 6000 m ³ , allowing significantly (up to 50%) to reduce the existing sludge SPBU.

After transportation in extremely shallow water areas and the installation of a self-elevating floating drilling rig at a given drilling point, compressed air is released from modular flexible flexible waterproof containers 14; disconnect modular flexible elastic waterproof containers with zero buoyancy from the L-shaped crossbars 11 and load them onto a barge (not shown in the drawings); dismantle removable L-shaped crossbars with flat lattice steel structures 12 and load them onto a barge.

Thus, the additional equipment of the side surfaces of the pontoon with a self-elevating floating drilling rig along its perimeter is uniform and with an interval of L-shaped crossbars, the horizontal shelves of which are installed at the level of the main (upper) deck of the pontoon, laying flat lattice metal structures on top of the horizontal shelves of the crossbars, placing them under cells of modules of flexible elastic waterproof containers with zero buoyancy and the simultaneous filling of them with compressed air ensures a decrease in precipitation available in hydrochloric SFDR region and its transportation by an extremely shallow area. The execution of the L-shaped crossbars together with horizontal lattice shelves and modules of flexible elastic waterproof containers removable after transportation and installation of a self-propelled floating drilling rig at a given drilling point can reduce the additional load on the supports of the offshore platform, which is not taken into account during their design and manufacture, the sailing of the platform and the area catchment during precipitation.

Claims (4)

1. A method of transporting a self-propelled floating drilling rig, including the use of auxiliary equipment to increase the depth margin under the watercraft, which use flexible flexible waterproof containers with initially zero buoyancy, which are brought under the body of the watercraft and fixed to the side surface of the watercraft, and then filled compressed air, characterized in that the side surfaces of the pontoon of a self-elevating floating drilling rig along its perimeter are uniform but even with an interval, they are additionally equipped with L-shaped crossbars, the horizontal shelf of which is installed at the level of the main upper deck of the pontoon, flat lattice metal structures are laid and fixed over the horizontal shelves of the L-shaped crossbars, and flexible elastic waterproof containers with initially zero buoyancy are brought under them, which are then simultaneously filled with compressed air. 2. The method according to p. 1, characterized in that the pontoon in the places of its equipping with L-shaped crossbars and their preliminary installation is reinforced with stiffeners on the inner side surface of the pontoon and additional flat plates. 3. The method according to p. 1, characterized in that the L-shaped crossbars, on top of which flat lattice metal structures are laid and fastened, are removable after transportation of the self-lifting floating drilling rig in extreme shallow water, installation of the platform at a given drilling point and for the period of well construction. 4. The method according to p. 1, characterized in that the flexible flexible waterproof containers are modular and isolated from each other.

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