RU2235243C1 - Method and device for laying pipelines - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: pipeline provided with pontoon-heavers filled with a loose material for control its buoyancy is submerged by filling the pontoons-heavers with fluid. The pontoons-heavers are made of soft containers provided with two soft pressure-tight vessels connected with the pipeline and filled with soil. Each vessel is provided with a soft filling hose, means for its shutting off, and valves for filling the vessels with fluid and discharging air. The longitudinal axes of the pressure-tight vessels are parallel to the longitudinal axis of the pipeline. The soft vessels are additionally interconnected.

EFFECT: simplified design.

2 cl, 2 dwg

Description

The invention relates to the construction and can be used when laying trunk pipelines by the alloy method.

It is known that gas pipelines laid in floodplain areas, in swamps or along the bottom of a reservoir are loaded both during their laying and to ensure their stable position in future operation. Testing of underwater oil and oil products pipelines with gas or air without preliminary checking their buoyancy and ballasting is unacceptable because of the danger of pipelines floating to the surface and their damage. The loading or fastening of these oil product pipelines is necessary when at least a short-term emptying of the pipeline from the transported product is possible. As the diameter of the pipeline increases, its stability in watered soils, in swamps, or at the bottom of a reservoir decreases.

According to the requirements of clause 8.30 * SNiP 2.05.06.-85 * the stability of the position (against ascent) of pipelines laid on flooded sections of the route should be checked for individual (depending on construction conditions) sections under the condition

Q _act ≤ (Q _pac ) / k _nv ,

where Q _act is the total calculated load on the pipeline acting upwards, including elastic resistance when laying by a free bend, N;

Q _Pac - total calculated load acting down (including mass - _dead weight), N;

k _nv - the coefficient of reliability of the stability of the position of the pipeline against the ascent, for sections of the transition through swamps, floodplains, water bodies in the absence of flow, flooded and flooded areas within the GVV of 1% coverage - 1.05.

In the construction of pipelines in deep marshes and in reservoirs, detachable ring weights are used, fixed to the pipeline with tie bolts, as well as continuous weighting coatings, such as concrete coating.

The design of cast-iron ring loads and reinforced concrete weighting materials ensures their strong connection to the pipeline, but these devices also have significant drawbacks. So, the movement of pipelines equipped with ring loads along the roller trigger when laying in an irrigated or underwater trench is very difficult and involves damage to the insulation. The installation of these goods in the process of pulling the pipeline directly behind the last roller support near the water edge is very laborious, and it takes a lot of time to assemble goods and fasten the bolts.

Setting and securing ring loads under water requires considerable work by a diver in conditions of limited visibility, and sometimes even in its complete absence.

A continuous weighting coating, such as concrete coating of a pipeline, is free from the disadvantages inherent in single loads, but it is laborious, expensive, in addition, with an increase in the coating thickness, the total rigidity of the pipeline increases, the deflection of which will be less than the deflection of a steel pipeline without coating, which creates certain difficulties at the exit sections pipeline to the shore (see Levin S.I. "Submarine pipelines". - M .: Nedra, 1970, pp. 132-136). In addition, concrete coating has another significant drawback, which is that it complicates the search for leaks of a pumped product, such as gas, under a concrete coating, as well as the difficulty of underwater repair due to the need to remove the concrete coating (with a reinforcing mesh). The concrete pipe laid in a trench in a deep swamp during operational pulsations of the pumped product easily destroys the base under the pipeline and moves from the design position, because due to its geometric cross section it is easily, without significant resistance, flowed around with soil.

When constructing an oil pipeline in conditions of extended deep bogs with an uneven thickness of flooded peat with low bearing capacity, overloading of a concrete pipe also occurs non-uniformly, which can lead to a local excess of permissible bending moments along the length of a concrete pipe, the flexibility of which is much less than the flexibility of a steel pipeline without heavier coating . From the practice of building pipelines, there are known cases when a concrete pipeline laid in deep bogs shifted from the design position down and to the side by 8-10 meters.

Known pontoon-weighting pipe containing a pair of sealed containers and their connection, covering the pipeline with a gap. The tanks are interconnected by contour connection tubes. Devices are exposed in the cross section of the transition, the pipeline is dragged afloat with its placement under the bonds of individual weight pontoons. The pipeline is immersed by pouring water into the cavity of one of the tanks, from where the water enters the cavity of the other tank through loop pipes (see SU 1427142 A1, 09/30/1988, F 16 L 1/24). The specified solution is closest to the claimed device as an object of the invention.

A disadvantage of the known solution is its lack of reliability, the possibility of displacement of the pontoons-weights in the process of filling them with water, as well as when immersing the pipeline.

There is a method of constructing an underwater pipeline, which consists in placing it afloat in the cross section with preliminary equipment with ballasting devices, the buoyancy of which is regulated by the partial filling of their volume with ballast - bulk material. The pipeline is immersed by filling the devices with water. Auxiliary pipes of smaller diameters are used as ballasting devices parallel to the pipeline and connected with it by flexible rods, and concrete is used as bulk material (see SU 1781497 A1, 12/15/1992, F 16 L 1/18). The known method is closest to the claimed method as an object of the invention.

The known solution allows you to abandon the costly, supporting the pipeline afloat pontoons, to exclude from the process of laying the pipeline the time-consuming operation of removing the pontoons from the pipeline, which increases the productivity of the work. However, this method has significant disadvantages. So, the pipeline must be equipped with bundles of auxiliary metal pipes 12 meters long, after filling the auxiliary pipes with concrete, it is necessary to seal their ends with welded plugs. The mounting system of auxiliary pipes is complex and requires lining of the pipeline to protect its insulation from damage by mounting cables. In addition, a corrosion protection system is also required for metal auxiliary pipes. Finally, in a pipeline equipped with a system of long auxiliary pipes, weight pontoons, the total rigidity of the pipeline increases, the deflection of which will be less than the deflection of the steel pipeline.

Thus, there is the task of creating a method and device for constructing a pipeline in water bodies, in swamps, in flooded soils, aimed at simplifying the process of equipping the pipeline, laying it in the design position, and also preventing the pipeline from shifting from design marks during its operation. At the same time, it is desirable to have devices that do not require the consumption of expensive pipes, do not require special measures for corrosion protection, and at the same time the service life of which would be at least the service life of the main pipeline as pontoons.

The claimed group of inventions is aimed at solving this problem and ensures its solution by the fact that when constructing the pipeline in swamps, in flooded soils and ponds, it is equipped with pontoons-weights that control the buoyancy of the pipeline filled with loose material, place the latter afloat in the cross section and immerse the pipeline subsequent filling with liquid medium pontoons weighting. Soft containers are used as the latter, each of which contains two soft, sealed containers filled with a bond imposed on the pipeline and filled with soil. Each of them is equipped with an end loading sleeve, means for closing it and valves for filling the liquid medium into the tank and discharging air from the tank. When applying the specified connection to the pipeline, the longitudinal axes of the soft sealed containers are parallel to the longitudinal axis of the pipeline. Soft containers are connected by an additional flexible connection covering the pipeline from below. Before filling the containers with liquid medium, the buoyancy of the pontoon-weighting systems is a positive pipeline, close to zero, and after immersion of the pipeline, it is negative with a given coefficient of stability in the design position. In addition, in the pontoon-weighting agent for the main pipeline constructed in swamps, in irrigated soils and reservoirs, which contain hermetic containers located symmetrically relative to the longitudinal axis of the pipeline and sealed with a connection with it, made in the form of a soft container containing two soft containers filled with soil, each of which has an end loading sleeve and means for closing it. To increase its carrying capacity and strength from a single waterproof panel in the container, by fastening its transverse edges to a limited length, a primary shell is created by a preliminary connecting seam, each end of which is formed of a waterproof panel previously bonded with its curved edges to the main shell, and soft containers are obtained by eversion of the central part of the ends of the main shell inside it with the subsequent closure of its diametrically opposite bands until the jumper and fastening the jumper strips with power seams with the formation of a bond imposed on the pipeline, and the longitudinal axis of the soft containers are parallel to the longitudinal axis of the pipeline when the specified connection is applied to it, while the pontoon-weighting device is equipped with an additional flexible connection covering the pipeline from below, and each the soft container is equipped with valves to fill it with liquid medium and to release air from it.

The invention is illustrated in graphic material, in which Fig. 1 shows an equipped pipeline located afloat in the cross section; figure 2 is the same, a section aa in figure 1.

Weighting pontoons 2 filled with granular porous material 3 are placed and fixed on the pipeline 1 with a calculated step. Hermetic soft containers are used as weighting pontoons; each of them contains two soft, sealed waterproof containers filled with a bond 4 and filled with granular material 3 5, each of which has an end loading sleeve 6 and valves 7, 8, respectively, for filling containers 5 with liquid medium and for releasing air from them, and the longitudinal axis of the soft containers are located agayutsya parallel to the longitudinal axis of the conduit 1 at the application of a specified communication, and more soft tank connected link 9 embracing the conduit 1 below. The task is to equip the buoyant pipeline with the estimated number of weight pontoons filled with bulk material, the linear weight of which in the tank volume is less than the total buoyant force acting in the liquid medium on the pontoon-weighting system - pipeline, and when filling the tanks with liquid medium - the total linear weight of bulk material and liquid medium in the tanks exceeds the specific buoyancy of the specified system and provides a predetermined coefficient of stability of the pipeline after it is loaded tions in the design position.

Each sealed textile container contains two containers 5 located on the pipeline 1 filled with bulk material 3, connected by a bond 4 imposed on the pipeline and an additional flexible connection 9, covering the pipeline from below. The longitudinal axis of the tanks 5 are parallel to the longitudinal axis of the pipeline 1 when pontoons-weights are fixed on it. Each container 5 is equipped with an end loading sleeve 6 and load loops 10 arranged symmetrically with respect to the longitudinal axis of the containers. The lower end 11 of the containers 5 is formed by a single waterproof panel, the edges 12 of which are pre-bent and connected to a single shell 13 forming the container 5. After connecting the edges 12 of the panel with the casing 13, the diametrical part of the panel is turned inside the casing 13, flattened in the plane of the connection 4 imposed on the pipeline 1 and connected to it, as a result of which an end face 11 is formed s 5.

This embodiment of the end of the containers allows you to increase the length and number of connecting seams of the bottom with the shells of the tanks, eliminates the work of the connecting seams on the raster, which improves the strength of the connection and the container as a whole. Each sleeve 6 is equipped with a means for closing it, which can be performed according to well-known recommendations, for example, see SU 1738706 A1, 06/07/1992, B 65 D 33/00.

The method is as follows. Tanks of pontoons-weights are filled with bulk material, such as sandy soil, slag, local soil. They equip the pipeline, for which the pontoons-weights in the vertical position are brought through the traverse to the longitudinal axis of the pipeline and lowered until the connection 4 on the outer surface of the pipeline with a symmetrical arrangement of sealed soft containers relative to the longitudinal axis of the pipe, and the longitudinal axis of the soft containers are parallel to the longitudinal axis of the pipeline and they attach pontoons-weights to the pipeline by means of additional connections covering the pipeline from below. The equipped pipeline is brought to the target of the transition to the place of immersion of the pipeline, while the buoyancy of the pontoon-weighting systems is a positive pipeline, close to zero. Depressurization of containers of pontoon weights is carried out, that is, through valves 7, liquid is supplied to sealed soft containers, and air is released from containers through valves 8. Due to the porosity of the bulk material, the liquid enters the containers and fills these pores, while the weight of the pontoons is weighting compounds increases by the value of the weight of the liquid medium entering the pontoon tank, buoyancy of the pontoon-weighting systems - the pipeline becomes negative and the equipped pipeline is immersed in design position. The volume of containers of pontoons-weighting materials and bulk material filling them is calculated based on the need to obtain positive buoyancy of the system close to zero, and when filling containers with liquid medium - negative buoyancy, regulated by the requirements of clause 8.30 * SNiP 2.05.06.-85 * to stability (against ascent) laid in the design position of the pipeline. For example, a pipeline with a diameter of 1420 mm with a linear buoyancy of 1.1 t / m is equipped with weight pontoons with a total volume of soft sealed containers equal to 1.25 m ^{3 /} pog.m. As the filling material used sandy soil with a bulk density in the air of 1.6 t / m ³ . With a water density of 1.0 t / m ³ , the linear buoyancy of the equipped pipeline is positive and is plus 0.35 t / m. When filling the containers of pontoons-weights with liquid medium - water, the linear buoyancy of the equipped pipeline becomes negative and equal to minus 0.15 t / m, which corresponds to the reliability coefficient of stability of the position of the pipeline against ascent for sections of the underwater passage, adopted in accordance with clause 8.30 * SNiP 2.05 .06.-85 *.

Thus, the invention provides the manufacturability of laying the pipeline in flooded soils, swamps, while the pontoons, after filling them with liquid medium, perform the function of weighting materials, the service life of which is not less than the service life of the pipeline. The implementation of pontoons-weights of soft material allows you to evenly distribute their weight on a large surface of the pipeline, which eliminates the occurrence of local contact stresses in the wall of the pipeline while maintaining its constant flexibility.

Claims (2)

1. The method of laying pipelines by the alloy method in ponds, swamps, in floodplain areas, which consists in equipping the pipeline with pontoons-weighting materials filled with bulk material, regulating the buoyancy of the pipeline, placing the latter afloat in the gauge and immersing the pipeline with the subsequent filling of weighting pontoons with weighting liquid the fact that the latter use soft containers, each of which contains two connected by a bond imposed on the pipeline and filled with soil m soft sealed containers, each of which has an end loading sleeve, means for closing it and valves for filling the containers with liquid medium and venting air from them, the longitudinal axes of the soft sealed containers being parallel to the longitudinal axis of the pipeline when this connection is applied to it, and the soft containers are connected additional connection, covering the pipeline from below, while before filling the tanks with liquid medium, the buoyancy of the pontoon-weighting systems is a positive pipeline, close to zero, and after immersion of the pipeline - with given negative resistance coefficient. 2. The pontoon-weighting agent for the main pipeline, laid by the alloy method in reservoirs, swamps, in floodplain areas, containing hermetic containers arranged symmetrically with respect to the longitudinal axis of the pipeline and sealed with it with a connection, which can be filled with a liquid medium for regulating buoyancy, characterized in that the sealed containers are made in the form of a soft container containing two soft containers filled with soil, each of which has an end loading sleeve and its means closure, while in the container to increase its carrying capacity and strength from a single waterproof panel by bonding its transverse edges to a limited length, a primary shell is created by a preliminary connecting seam, each end of which is formed of a waterproof panel previously bonded with its curved edges to the main shell, and soft containers are obtained by inverting the central part of the ends of the main shell inside it, followed by closing diametrically opposite e strips until a jumper is formed and the jumper strips are fastened with power seams with the formation of a bond imposed on the pipeline, the longitudinal axis of the soft containers being parallel to the longitudinal axis of the pipeline when the specified connection is applied to it, while the pontoon-weighting device is provided with an additional flexible connection covering the pipeline from below, and each soft container is equipped with valves to fill it with liquid medium and to release air from the containers.

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