RU107187U1 - CESSON FOR REPAIR OF UNDERWATER PIPELINES - Google Patents

Abstract

 1. A caisson for repair of underwater pipelines, comprising a chamber including an upper and two lower parts, a means of sealing the chamber on the pipeline, in two opposite end walls of the upper part of the chamber there are arched cutouts in the form of a semicircle, the diameter of which corresponds to the diameter of the pipeline, and the upper part is made with a hole for connecting the shaft, while each of the lower parts of the chamber is pivotally connected on the sides with the upper part of the chamber, and in the opposite end walls of each of their lower parts of the first chamber, cuts are made in the shape of a quarter of a circle for airtight installation on the pipeline when they are closed, the camera is equipped with rotation mechanisms of the lower parts of the camera, an installation frame rigidly fixed to the upper part of the camera with means for installing the camera on the pipeline, and also camera fixation devices on soil fixed to the end walls of the chamber. ! 2. Caisson according to claim 1, characterized in that the rotation mechanisms of the lower parts of the chamber are made in the form of hydraulic cylinders placed on the end walls of the chamber. ! 3. The caisson according to claim 1, characterized in that the means for installing the camera on the pipeline are made in the form of hydraulic grippers placed on both sides of the end walls of the camera and connected to hydraulic cylinders installed at the edges of the installation frame. ! 4. Caisson according to claim 1, characterized in that the sealing means is made in the form of a rubber seal located on the edges of the lower parts of the chamber, and a pneumatic inflatable seal located on the edges of the arched cutouts of the upper and lower parts of the chamber. ! 5. Caisson

Description

The utility model relates to the construction and repair of underwater gas and oil product pipelines at depths of up to 30 m.The use of a caisson allows replacing damaged sections of pipelines, welding through and through defects, performing other repair work, including welding, in the air at underwater crossings of main pipelines.

A known method of welding metal surfaces directly in the aquatic environment, the so-called "wet method" of welding. However, this method has several disadvantages - the 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 an underwater pipeline in a caisson providing an air environment for repair work, a protective gas environment 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 "land".

The closest analogue is a caisson for repair of underwater pipelines, containing a chamber consisting of two detachable parts, an upper and a lower one, an input shaft mounted on the upper part of the chamber, and means for sealing the chamber on the pipeline (RU 2203360 C1, 2002).

However, this design of the caisson has a number of drawbacks, such as the complexity of installing the camera on the pipeline, the necessity of ballasting the camera when installing it, and the difficulty of carrying out repairs inside the caisson by removing the defective section of the pipeline due to the lack of a means of fixing the axial position of the pipeline when cutting it.

The technical task of the utility model is to create a reliable design that provides ease of installation on the pipeline mechanically, as well as fixing the axial position of the pipeline when removing its defective section.

The problem is solved in that the caisson for repair of underwater pipelines contains a chamber including an upper and two lower parts, a means of sealing the chamber on the pipeline, in two opposite end walls of the upper part of the chamber there are arched cutouts in the form of a semicircle, the diameter of which corresponds to the diameter of the pipeline, and the upper the part is made with a hole for connecting the shaft, while each of the lower parts of the chamber is pivotally connected on the sides with the upper part of the chamber, and in opposite ends the out walls of each of the lower parts of the chamber are cut out in the shape of a quarter of a circle for an airtight installation on the pipeline when they are closed, the camera is equipped with mechanisms for turning the lower parts of the camera, an installation frame rigidly fixed to the upper part of the camera with means for installing the camera on the pipeline, and also devices for fixing the camera on the ground, mounted on the end walls of the camera.

Moreover, the rotation mechanisms of the lower parts of the chamber are made in the form of hydraulic cylinders placed on the end walls of the chamber.

In addition, the means of installing the camera on the pipeline are made in the form of hydraulic grips placed on both sides of the end walls of the camera and connected with hydraulic cylinders installed at the edges of the installation frame.

In addition, the sealing means is made in the form of a rubber seal located on the edges of the lower parts of the chamber, and a pneumatic inflatable seal located on the edges of the arched cutouts of the upper and lower parts of the chamber.

In addition, the device for fixing the camera on the ground is made in the form of hydraulic supports.

The essence of the utility model is illustrated using the drawings. Figure 1 shows a caisson with a mounting frame (perspective view). Figure 2 shows a front view of the caisson.

A caisson containing a chamber 1 is installed on the pipeline using an installation frame 2, which is fixed on the pipeline by two hydraulic pipe clamps 3, connected to the mounting hydraulic cylinders 4, providing closing-opening of the pipe clamps 3, i.e. installation of a caisson on the pipeline. The installation frame 2 is designed to fix the axial position of the pipeline when removing its defective section, i.e. prevents the displacement of parts of the pipeline when it is cut. Hydraulic pipe clamps 3, associated with the hydraulic system, provide a mechanized method of installing the caisson on the pipeline, thereby reducing the complexity and increasing the speed of installation work.

The caisson contains a chamber 1 made in the form of a welded metal box (figure 1) in the form of a parallelepiped. The camera 1 consists of an upper part 5 and two lower parts 6 and 7. Each of the lower parts 6 and 7 is pivotally connected by hinges 8 to the upper part 5 of the box on their sides 9 with the possibility of rotation of the lower parts 6 and 7 of the camera.

The upper part 5 is made with arched cutouts 10 in the form of a semicircle in the end walls 11 of the chamber. The lower parts 6 and 7 are made with cutouts 12 in the form of a quarter of a circle in the end walls 11 of the box. When closing the lower parts 6 and 7, the cut-outs 10 and 12 form a circular hole 13 (Fig. 2) or a circle whose diameter corresponds to the diameter of the pipeline being repaired so that when the two lower parts 6 and 7 are installed on the repairing section and the chamber 1 is fully closed covers the repaired section of the underwater pipeline and forms the internal working space.

In the upper part 5 of the box, a hollow cylindrical protrusion 14 with a flange 15 is made, for the possibility of mounting the shaft, providing a connection of the inner working space of the chamber 1 with the air, as well as the transportation of equipment and welders.

The mounting frame 2 is welded along the upper part of the chamber 1, the length of the frame is equal to the length of the chamber 1 of the caisson plus 2.050 m from each of its end walls, i.e. the length of the mounting frame 2 provides installation on it on both sides of the end walls 11 of the chamber of the hydraulic grippers 3.

Each of the lower parts 6, 7 of the chamber is equipped with two hydraulic cylinders 16, which ensure their opening and closing.

On each of the end sides 11, two hydraulic height-adjustable supports 17 are fixed, providing additional support on the ground and stability of the caisson.

The tightness of the installation of the caisson 1 on the surface of the pipeline is ensured by a sealed cord (rubber sealant) located around the perimeter of the segment cutouts of the chamber adjacent to the outer surface of the pipeline, and along the perimeter of the lower parts 6 and 7 of the chamber 1. The tightness of the caisson around the pipeline is ensured by a pneumatic split inflatable seal. The tightness of the caisson should be controlled by monitoring the presence of air bubbles on the surface of the water at the place of its installation on the pipeline.

The welds of the chamber 1 of the box must ensure the tightness of the inner space of the box when it is installed on the outer surface of the pipeline to a depth of 30 m

The design of the caisson with the welded installation frame 2 provides the possibility of rigid fixation in the initial position of the pipeline during the cutting of the defective section and the possibility of carrying out repairs, including welding, in a dry air environment.

The assembly and operation of the caisson is as follows.

Preparing the caisson for installation.

Assembly and preparation of the caisson for installation on the repaired section of the pipeline is carried out on a flat site using a crane. The upper part 5 of the chamber 1 is installed on its lower parts 6 and 7 with the help of hinges 8, which provide opening-closing (rotation) of the lower parts 6 and 7, around the perimeter of which a sealing cord of circular cross section is glued - a rubber sealant.

The hydraulic supports 17 of the caisson are inserted and crimped in the hinge clamps.

The hydraulic cylinders 4 (hydraulic tensioners) are mounted on the frame 2, the hydraulic system is mounted and checked.

Installation of the caisson on the repaired pipeline section is as follows.

The assembled design of the caisson is lifted by a crane, using the hydraulic system including hydraulic cylinders 16, two lower parts 6 and 7 of chamber 1 are bred.

The pipe clamps 3 of the mounting frame 2 are opened using hydraulic cylinders 4 to the width of the pipe diameter plus 200 mm, the caisson is centered over the markers of the defective section and lowered along the guides to the pipeline.

Using the distributor of the hydraulic system by means of hinges 8, the lower parts 6 and 7 of the chamber 1 of the caisson are closed, the caisson covers the repaired section of the pipeline.

Then the hydraulic system, including hydraulic cylinders 4, provides compression of the pipe grippers 3 of the mounting frame 2, which through polyurethane gaskets cover the surface of the pipeline, are fixed with bolts and crimped by divers.

Lower the hydraulic supports 17 of the caisson until they touch the ground and are fixed, after which the crane slings are removed.

Mount the pneumatic seal pipe-housing and fill it with air.

Mount sections of the shaft 18 to the flange 15 of the cylindrical protrusion 14 of the upper part 5 of the chamber 1 of the box to the level of the water surface.

The compressor pumps out water from the inner space of the caisson, checks its tightness, and eliminates air leaks.

With the help of the mine 18, the personnel, the required equipment and tools are transported to the inner working space of the caisson, in which repairs, including welding, are carried out on the defective section of the pipeline using technologies used in ground conditions.

When carrying out repairs in the caisson, life support systems are used: ventilation, lighting, video surveillance and communications, which are transported and mounted also using the mine 18.

The operation of the pneumatic tool inside the caisson is carried out by connecting hoses through the nozzle to the valves of the receivers located inside the upper part of the caisson. The fastening of two receivers located outside the upper part of the caisson is carried out by 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. When cutting the pipeline, the proposed caisson together with the installation frame reliably keeps the ends of the pipeline from diverging. The availability of mounting units makes it easy to mount and dismount the caisson 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 (5)

1. A caisson for repair of underwater pipelines, comprising a chamber including an upper and two lower parts, a means of sealing the chamber on the pipeline, in two opposite end walls of the upper part of the chamber there are arched cutouts in the form of a semicircle, the diameter of which corresponds to the diameter of the pipeline, and the upper part is made with a hole for connecting the shaft, while each of the lower parts of the chamber is pivotally connected on the sides with the upper part of the chamber, and in the opposite end walls of each of their lower parts of the first chamber, cuts are made in the shape of a quarter of a circle for airtight installation on the pipeline when they are closed, the camera is equipped with rotation mechanisms of the lower parts of the camera, an installation frame rigidly fixed to the upper part of the camera with means for installing the camera on the pipeline, and also camera fixation devices on soil fixed to the end walls of the chamber. 2. Caisson according to claim 1, characterized in that the rotation mechanisms of the lower parts of the chamber are made in the form of hydraulic cylinders placed on the end walls of the chamber. 3. The caisson according to claim 1, characterized in that the means for installing the camera on the pipeline are made in the form of hydraulic grippers placed on both sides of the end walls of the camera and connected to hydraulic cylinders installed at the edges of the installation frame. 4. Caisson according to claim 1, characterized in that the sealing means is made in the form of a rubber seal located on the edges of the lower parts of the chamber, and a pneumatic inflatable seal located on the edges of the arched cutouts of the upper and lower parts of the chamber. 5. Caisson according to claim 1, characterized in that the device for fixing the camera on the ground is made in the form of hydraulic supports.