RU2481438C2 - Underwater complex for repair of underwater pipelines - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: underwater complex for repair of underwater pipelines comprises a caisson, having a chamber in the form of a box with an open bottom and with two holes of round shape in two opposite side walls for installation on the pipeline and sealing on it at the edges of the specified holes, a mounting frame designed for placement of the caisson on it, connected with facilities of its fixation relative to the soil and having tube grips arranged at both sides of the caisson, and grips are arranged as capable of fixation on the pipeline. The mounting frame is made of four pairwise connected pipes, pairs of pipes are arranged at opposite sides of the caisson along its solid side walls, and pipes of each pair are connected by their ends with tube grips. On two opposite side walls of the caisson chamber there are arc cuts made and folds installed so that whenever folds are closed on each of the specified side walls there is the specified hole of the round shape, edges of each hole in the form of semicircumference is formed by the upper part of the arc cut, and edges of the hole in the form of a quarter of the circumference are arranged on each of the folds, at the same time at edges of each hole there are sealing facilities made as capable of adjacency to the outer surface of the pipeline with formation of a wet bell chamber.

EFFECT: development of a reliable dismountable structure providing for repair of an underwater pipeline by method of replacement of a defect section of a pipeline, safe and comfortable work of divers.

11 cl, 4 dwg

Description

The invention relates to the repair of underwater gas and oil product pipelines at depths of up to 30 m. The use of the repair complex allows the replacement of damaged sections of pipelines, welding of through and through defects, the performance of other welding operations in hyperbaric conditions in an inert gas at underwater crossings of main pipelines.

The method of welding directly in the aquatic environment (“wet method” of welding) has a number of disadvantages - porosity of the weld, the presence of a significant number of slag inclusions, the possibility of cracks in the heat-affected zone, which does not allow it to be used for critical welded joints of hazardous production facilities.

When welding a subsea pipeline in an inert gas environment, a protective gas medium is created around the welding site. This allows you to overcome most of the disadvantages inherent in the "wet method" of welding, and to obtain a quality of the weld equal to "ground".

Closest to the proposed is an underwater caisson for repair of underwater pipelines, containing a caisson having a chamber in the form of a box with an open bottom and an opening in one of the side walls, in two other opposite side walls of which there are segment recesses with an arc radius corresponding to the radius of the pipeline being repaired with enabling the camera to adhere to the outer surface of the pipeline along the generatrices and arcs of circles with the formation of a diving bell, a device for fixing the cam ry on the pipe and means for fixing the camera relative to the ground, connected to the chamber with the possibility of rotation around the pipeline axis. The device for fixing the camera on the pipeline contains guides rigidly connected to the camera with fasteners for fixing on the pipeline and clamping half rings connected to the camera. Means for fixing the camera relative to the ground is made in the form of two rods connected through hinged devices to the ends of the brackets rigidly connected to the camera (RU 2342492 C2, publ. 2008).

The disadvantages of the known device are the inconvenience of repairing extended defective sections and significant damage located on a large surface of the pipeline, and the inability to carry out work associated with the removal of part of the damaged pipeline.

An object of the invention is the creation of a reliable collapsible design that provides repair of the underwater pipeline by replacing a defective section of the pipeline, safe and comfortable work of divers.

The problem is solved in that the underwater caisson for repairing underwater pipelines contains a caisson having a chamber in the form of a box with an open bottom and with two round holes in two opposite side walls for installation on the pipeline and sealing on it along the edges of these holes, an installation frame, designed to place a caisson on it, connected to means of fixing it relative to the ground and having pipe grips located on both sides of the caisson, made with the possibility of fixation on the pipeline.

Preferably, the frame is made of four pairwise connected pipes, pairs of pipes are located on opposite sides of the caisson along its continuous side walls, and the pipes of each pair are connected at their ends with pipe grippers.

Moreover, each of the pipe grippers is made of two parts, with each of which the ends of the corresponding pair of pipe tubes are connected.

In addition, the caisson has in the upper part a support beam with locking elements for installation on the upper of each pair of pipes of the installation frame.

In addition, the means for fixing the camera relative to the ground is made in the form of four pivotally height-adjustable supports pivotally connected to the frame.

In addition, to control the position of the installation frame, the supports are equipped with hydraulic cylinders.

In addition, the pipe grippers are made, each, in the form of a shell, consisting of two parts in the form of half-cylinders connected in the upper part by the axis of the hinge.

In addition, each tube of the installation frame is divided into ballast compartments to increase or decrease the buoyancy of the complex.

In a particular case, on two opposite side walls of the caisson chamber, arch cuts are made and the shutters are installed so that with closed shutters on each of the indicated side walls, the specified round hole is formed, each round hole is formed by the upper part of the arched cut-out in the form of a semicircle, and the edges of the hole in the form of a quarter of a circle are made on each of the wings, with sealing means arranged along the edges of each hole, made to fit to the outer surface the pipeline with the formation of a diving bell chamber.

In addition, in the caisson, each said sealing means is a pneumatic inflatable seal.

In addition, on the edges of the flaps adjacent to the side walls of the chamber of the caisson, there are gaskets made of elastic material.

In addition, a hollow protrusion is made in the upper part of the caisson chamber, in the cavity of which there are diving expiratory reducers, fastening of cargo hoists, cable, TV, communication, lighting cable entry and a ventilation system outlet hose.

The invention is illustrated using the drawings. Figure 1 shows the proposed complex (front view), figure 2 shows the complex (side view), figure 3 shows the complex (top view), figure 4 shows the caisson (inside view).

The underwater complex contains a caisson 1 having a chamber in the form of a box with an open bottom, an installation frame 2, consisting of four pairwise connected pipes 3, at the ends of which pipe grips 4 are installed on both sides of the caisson 1, which are made with the possibility of fixation on the pipeline.

The mounting frame 2 is designed for rigid fixation in the initial position of the emergency section of the main pipeline, as well as to hold the caisson 1 from the ascent when it is completely purged. The hinged-opening design of the installation frame 2 is welded. Frame 2 is made of four pipes 3 with a diameter of 720 mm with a wall thickness of 18.7 mm and a steel grade 10G2FBYu (yield strength 475 MPa). Pipes 3 are welded from pipe segments and connected in pairs. The axis of the extreme parts of each of the pipes 3 are located at an angle to the axis of the middle part. Pipes 3 are arranged in pairs on both sides of the caisson 1 along its continuous side walls. Two pipe grippers 4 are located at the ends of the corresponding pairs of pipes 3 and are precisely aligned with each other. The shells of the grippers 4 consist, each, of two detachable half rings, which in the upper part are connected by the axis of the hinge 5, and in the lower part by flanges 6 for bolt connection. Shells are made with a diameter of 1370 mm with a wall thickness of 25 mm and steel grade 09Г2С (yield strength 343 MPa). Along the edges of each of the grips 4 there are polyurethane gaskets 7 with a thickness of 50 mm, a width of 500 mm and a circumference of the emergency pipeline, which are attached to detachable half rings of the shells with bolts securing them from longitudinal displacement. The gaskets provide a tight fit of the frame 2 on the pipeline during compression of the flanges 6 of the pipe clamps 4, without affecting the reinforcement of the longitudinal welds, and compensate for the permissible bending of the main pipeline, as well as tolerances for the diameter and ovality of the main pipe.

Means for fixing the installation frame 2 relative to the ground are made in the form of four adjustable supports 8 installed along the edges of the frame 2.

The pipes 3 of the mounting frame 2 are divided into ballast compartments, which allow to increase or decrease the buoyancy of the complex. For flooding and purging on the frame 2 installed cranes and purge nipples.

Mounting hydraulic cylinders 9 are installed on the frame 2, connected with pipe clamps 4 and providing their closing-opening.

Height-adjustable movable bearings 8 remove the weight load of the complex on the pipeline and have hydraulic cylinders 24 with manual pumping with a force of 20 tons each and a piston stroke of 360 mm. Supports 8 can be used to center the pipeline in the UP-LOW plane. The maximum pressure of the area of the supports 8 on the soil does not exceed 137 g / cm ² .

The supports 8 are connected to the frame 2 through hinges 10, which have two degrees of freedom, which allows the entire complex to move in a horizontal plane, which is sometimes necessary for centering the pipeline when installing the "coils" of the pipe. To support the temporary vertical position of the supports 8, there are hinged latches installed on the upper pipes 3 of the frame 2.

The caisson 1 contains a metal chamber in the form of an open bottom duct forming a diving bell. The design of the chamber is welded, made of sheet steel St3sp GOST380-71 with a thickness of 20 mm. The camera is made of hermetically interconnected detachable upper part 11 and two lower parts 12 and 13.

On two opposite side walls of the chamber of the caisson 1, arched cutouts 14 are made. The upper part of the arched cutout 14 is formed by a semicircular cutout in the upper part 11 of the caisson 1 with an arc radius corresponding to the radius of the pipeline being repaired.

On each of the two opposite side walls of the chamber between the lower parts 12 and 13 there are gaps that form the lower part of each arched notch 14 and the passage for the pipeline. To ensure tightness at the edges of the gaps, lowering parts 12 and 13 are installed in the lower parts 12 and 13, in which recesses 17 and 18 are arranged opposite each other, each in the form of a quarter circle with an arc radius corresponding to the radius of the pipeline being repaired. At the edges of these recesses 17 and 18, the flaps 15 and 16 are adjacent to the outer surface of the pipeline. When the shutters 15 and 16 are closed, a circular hole for the pipeline is formed in each side wall of the chamber, each round hole is formed by the upper part of the arched notch 14, and the edges of the quarter-shaped hole are made on each of the shutters 15 and 16.

For ease of installation of the caisson 1, the shutters 15 and 16 in the initial position are open inward. In this position, the caisson 1 is installed on the pipeline, which runs between the lower parts 12 and 13 of the chamber. After closing the flaps 15 and 16, the chamber is sealed with the formation of the following tight sections: the section between the edges of the recesses 17 and 18 of the flaps 15 and 16 and the outer surface of the pipeline, the tightness of which is ensured by a pneumatic releasable inflatable seal, the sections between the end surfaces of the flaps 15 and 16 facing each other , the tightness of which is ensured by a gasket of elastic rubber, and sections between the other end surfaces of the flaps 15 and 16 and the edges of the side walls of the chamber, the tightness of which is echivaetsya pad made of porous rubber.

In the upper part of the chamber, a protrusion U-shaped protrusion 19 is made, in the cavity of which there are diving expiration reducers, fastening of cargo hoists, cable TV, communication, lighting cable entry and a ventilation system outlet hose. The inlet hose of the ventilation system, air tool receivers with inlet hoses are also located in the upper part of the box of the caisson.

When welding in confined spaces, rapid smoke occurs, visibility is reduced to zero. To clean the gas environment from smoke, ventilation of the inner space of caisson 1 is provided. Ventilation is carried out along the circuit. Welding smoke from the inner space of the caisson 1 through a ball valve (designed to adjust the gas discharge rate) located inside the upper part of the box, through a discharge hose enters the fine filter with a replaceable filter element, a mixture recirculation reducer and a gas analyzer in the complex and then to the suction the fitting of the low-pressure technical air compressor. The gas purified from the welding gas from the compressor through a dehumidifier with a replaceable silica gel filter through the inlet hose enters a non-return valve located inside the upper part of the duct, and then into a divider located inside the lower part of the duct. Leaks in the system are replenished from transport cylinders with carbon dioxide and (or) argon tied to a compressor. Excess gas is removed through the lower edge of the open bottom of the duct, and with constant adjustment of the ventilation system, the water level will be maintained automatically. A compressor, smoke filter, dehumidifier, gas cylinders are located on the deck of the craft.

The caisson 1 is equipped with means for fixing on the installation frame 2. These tools include support beams 20 fixed in the upper part of the box with locking screws 21, with which the caisson 1 is fixed to the pipes 2 of the installation frame of the complex.

Centralizers 22 are fixed on the side walls of the chamber, fixing the caisson 1 relative to the frame, and folding locking stops 23, which keep the caisson 1 from floating.

Repair work using the invention is carried out as follows.

After determining the boundaries of the defective section of the pipeline and, accordingly, determining the boundaries of the installation of the complex, it is necessary to remove the insulation of the pipeline in the area of 0.5 m in each direction from the boundary of the installation of the complex.

The disassembled complex is delivered to the place of work on a barge with a 32-ton crane. The barge is anchored above the damaged section of the pipeline.

On a flat site, with the help of a crane, one half (a pair of pipes rigidly connected to each other by means of a branch pipe) of the installation frame 2 is centered and joined with the other using the hinge axes 5 of the pipe grippers 4. The frame is mounted on the keel blocks (supports), the supports 8 are inserted and crimped in the clamps of the hinges 10. Mounting hydraulic cylinders 9 are mounted on the frame. A hydraulic system is being assembled (hydraulic station, BRS hoses, etc.). Using a crane, the upper part 11 of the chamber of the caisson 1 is installed on the lower parts 12, 13 of the chamber of the caisson 1, where a sealing cord of circular cross section is preliminarily embedded. Alignment of the flanges is carried out by mounting rails. Using a wrench, all bolts are crimped. The support beams 20, the flip stops 23 are installed, the sealing flaps 15 and 16 are hung, the receivers of the pneumatic tool, the exhalation reducer are mounted (they are connected by corrugated hoses with bayonets for connection to a diver). The communication system, TV, lighting, gas supply and exhaust system are installed and checked. The entire ground support system for the complex is being assembled.

The assembled installation frame 2 is lifted by a crane, and the pipe clamps 4 are bred by the mounting cylinders 9 to the width DU + 200 mm of the emergency pipeline. Descent under water. On pre-established guides installation frame 2 is lowered onto the prepared pipe section (foundation pit, weights, foot rail and insulation, marking with a marked defect). The lowering of the installation frame 2 under water is carried out to a distance of 1 m to the upper generatrix of the pipeline. A working diver must check and ensure the exact location of the installation frame above the marked defective section of the main pipe. Next, the diver checks the absence of foreign bodies between the polyurethane gaskets 7 pipe grippers 4 of the installation frame and the surface of the main pipe. Pipe grips 4 of the installation frame through polyurethane gaskets 7 tightly wrap around the pipeline using mounting cylinders 9 and the weight of the halves of the frame. Reaching the shells is carried out by a removable hydraulic tensioner, the rod of which passes through a special hole in the flanges of the shells. Further, the flanges are fixed with bolts and crimped with a torque wrench. Then the bearings 8 are released until they are fully installed on the ground and fixed in the hinges 10 of the supports with the required bolt tightening torque.

The assembled and tested caisson 1 with open hinged stops 23 and open sashes 15 and 16 is lowered by a tap under water. The descent of the caisson 1 under water is carried out to a distance of 1 m to the upper pipe 2 of the installation frame. A working diver should check and ensure that the caisson is positioned above the installation frame.

The caisson 1 is lowered into the installation frame, moving down the centralizers 22 until the support beams 20 touch the upper tubes 2 of the installation frame. Close and fix the hinged stops 23 of the caisson 1. Close the sealing flaps 15 and 16 and compress them with connecting bolts to each other, and the folding clamping bolts press them to the arch cut in the upper part of the caisson 1. Sealing between the end surfaces of the flaps 15 and 16 and the edges of the cuts in the side walls of the box are provided with elastic rubber gaskets that are glued to the sealing units. Between the edges of the recesses 17 and 18 and the outer surface of the pipeline, a seal is inserted and filled with air or water.

To the caisson 1 down and fix the hoses of the ventilation system. Squeeze the compressor water from the caisson 1, checking the caisson 1 for leaks by blowing it with air (checking for air bubbles on the surface of the water at the installation site of the caisson). If available, eliminate all air leaks.

The caisson 1 is filled with water and the protective gas is supplied into it until the water is displaced (pressure is equal to the immersion depth) - to the lower edge of the caisson. The lifting force is transmitted through the hinged stops 23 and is compensated by the weight of the mounting frame 2. Inside the caisson 1, lighting, television, communications, welding equipment and pneumatic tools are placed, and the welder diver welds the defect. To ensure an emergency-safe environment, the diver’s breathing air is supplied via a hose cable through the lower edge of the caisson 1, and air exhaled by divers is taken from the pulmonary masks in the exhalation reducers (the exhalation hose connects to the outlet fitting of the reducer) located in opposite corners inside the upper parts of the box of the caisson and beyond.

The air and breathing mixture of the welder divers is supplied and discharged through separate hoses, while it is not mixed with the protective gas for welding.

The operation of the pneumatic tool inside the caisson 1 is carried out by connecting hoses through the nozzle to the valves of the receivers located inside the upper part of the caisson 1. The two receivers located outside the upper part of the caisson 1 are fastened with clamps. Air from the compressor to the receivers is supplied through durite hoses and connected to the receivers via quick-release couplings.

Dismantling the caisson is carried out in the reverse order.

The collapsible design of the installation frame 2 and the caisson 1 allows them to be transported in parts by road. Any part of the complex can be transported in the back of a car 12 meters long. This is especially important when working on non-navigable rivers, where the last kilometers have to be overcome on the road.

To work with the complex does not require special lifting equipment, it is enough to use a truck crane with a lifting capacity of 25 tons. The weight of the heaviest part of the complex does not exceed 9 tons.

When working on small rivers, the installation frame can be assembled ashore in a convenient place and then towed afloat to the place of work. The minimum channel depth is 2 meters.

The whole complex is assembled and prepared for work on the surface, then it is lowered along the guide ropes to the pipeline.

The robust installation frame and the hydraulic system of the complex allow you to center pipes with a diameter of 1220 and 1020 mm.

When cutting the pipeline, the installation frame together with the caisson reliably keeps the ends of the pipeline from diverging.

The variable buoyancy of the caisson allows additional efforts to be made to the ends of the pipe alignment pipe.

The availability of mounting units makes it easy to mount and dismantle the complex in cramped conditions and limited visibility

The shape and saturation (gearbox, lighting, TV, alarm system, ventilation and control) of the internal space of the caisson ensures maximum safety and comfort for working divers.

Claims (11)

1. An underwater complex for repair of underwater pipelines, containing a caisson having a chamber in the form of a box with an open bottom and with two round-shaped openings in two opposite side walls for installation on the pipeline and sealing on it along the edges of these openings, an installation frame designed to accommodate there is a caisson on it, connected with means for fixing it relative to the ground and having pipe grips located on both sides of the caisson, made with the possibility of fixation on the pipeline, and the frame is made nene of four pairwise connected pipes, pairs of pipes are located on opposite sides of the caisson along its continuous side walls, and the pipes of each pair are connected at their ends with pipe grippers. 2. The complex according to claim 1, characterized in that each of the pipe grippers is made of two parts, with each of which the ends of the corresponding pair of pipes of the frame are connected. 3. The complex according to claim 1, characterized in that the caisson has in the upper part a support beam with retaining elements for installation on the top of each pair of pipes of the installation frame. 4. The complex according to claim 1, characterized in that the means for fixing the installation frame relative to the ground are made in the form of four pivotally height-adjustable supports. 5. The complex according to claim 4, characterized in that for regulating the position of the installation frame, the supports are equipped with hydraulic cylinders. 6. The complex according to claim 1, characterized in that the pipe clamps are each made in the form of a shell, consisting of two parts in the form of half-cylinders connected in the upper part by the hinge axis. 7. The complex according to claim 1, characterized in that each pipe of the installation frame is divided into ballast compartments to increase or decrease the buoyancy of the complex. 8. The complex according to claim 1, characterized in that on two opposite side walls of the chamber of the caisson, arched cutouts are made and the sashes are installed so that with the closed sashes on each of these side walls, the specified hole is round, each round hole is formed by the upper part an arched notch in the shape of a semicircle, and the edges of the holes in the form of a quarter of a circle are made on each of the wings, with sealing means arranged along the edges of each hole Nia to the outer surface of the conduit to form a chamber diving bell. 9. The complex according to claim 8, characterized in that each said sealing means is a pneumatic inflatable seal. 10. The complex of claim 8, characterized in that on the edges of the flaps adjacent to the side walls of the chamber, there are gaskets made of elastic material. 11. The complex according to claim 8, characterized in that a hollow protrusion is made in the upper part of the chamber, in the cavity of which there are diving expiratory reducers, fastening of cargo hoists, cable TV, communication, lighting cable entry and a ventilation system outlet hose.

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