RU192586U1 - DEVICE FOR COMPOSITE PIPELINE BASIS ON WATERS AND WATERFLATED AREAS - Google Patents

Abstract

The utility model relates to the development of technologies for the construction of trunk pipelines in special environmental conditions, is intended for the construction and further repair of oil and gas pipelines in swamps and flooded areas. and stability of the structure to loads and impacts arising during operation t of the water supply system and during its possible repair. The solution to this problem lies in the fact that in the construction of a composite pipeline base on swamps and flooded areas, including composite elements in the form of central and lateral pontoons having a metal power frame of I-section and a shell made of basalt-carbon-plastic, tightened with high-strength composite load-holding cables, according to a utility model, the components of the pipeline base are interconnected and into the track in the form of a spike-groove. Cylindrical rods made of basalt-carbon-plastic are stretched through holes in the thorn-groove connection. The components of the pipeline base are staggered. On the track from the central pontoons installed supporting devices under the pipeline. Along the perimeter of the pipeline base, high-strength composite load-bearing cables are stretched.

Description

The utility model relates to the field of development of technologies for the construction of trunk pipelines in special natural conditions, intended for the construction and further repair of gas and oil pipelines in swamps and flooded areas.

Pipelines laid in Siberia, in the north of the European part of Russia and the Far East, cross bogs and wetlands for a considerable length. In swamps and wetlands, as a rule, they provide for the underground laying of the pipeline and, as an exception, with appropriate justification, laying of pipelines on the surface of the swamp in the body of the embankment (ground laying) or on supports (overhead laying).

However, there is a limitation in the construction of pipelines in the time of year, since it is advisable to lay the pipeline only in the winter, and the remaining seasons make significant changes to the technology.

Design, construction and overhaul of main pipelines in the conditions of bogs in the northern climatic zone are of increased complexity due to the specific features of organic soils.

Nevertheless, the reliability and safety of underground and surface pipelines at the same passage through a swamp in an uninhabited area are almost the same, and the economic indicators of the construction of the latter are much higher. In this regard, the methods of laying and calculation of land pipelines in the swamps require their development and improvement.

Closest to the proposed utility model is the construction of a composite pipeline base on swamps and flooded areas, including components in the form of central and lateral pontoons having a metal I-beam power frame and a sheath made of basalt-carbon-plastic, pulled together by high-strength composite cargo-fixing cables (Russian Federation Patent No. 26303939 IPC E01C 3/04: Arrangement of a composite pontoon under the base of the pipeline route in swamps and permafrost / AF Zakuraev , V.A. Ivanov, A.V. Ryabkov, S.A. Plotnikov. No. 2016116360; claimed April 26, 2016; publ. September 14, 2017. Bull. No. 26).

This device has a number of significant disadvantages.

One of them is the “father-mother” type lock connection of the composite elements of the composite pipeline base to each other and to the track, in which excessive stresses can occur due to the uneven distribution of loads from the movement of construction equipment, which in turn will lead to its failure .

Ropes require ongoing monitoring and maintenance. If the cable is damaged or broken, to restore it, it is necessary to disassemble the entire structure, which is unacceptable without stopping the pumping of the product through the pipeline.

The collapsible design of the side and central pontoons is also impractical, due to the complexity of installation and its metal consumption.

The absence of supports for the pipeline on the pipeline base will not allow for the correct distribution of the loads acting on the pipeline and their transfer to the pontoons, and can also lead to unpredictable behavior of the pipeline during its movement during operation.

The objective of the utility model is to improve the design of the composite pipeline base in swamps and waterlogged areas with the achievement of the following technical result: increasing the strength and stability of the structure to the loads and impacts that arise during operation of the pipeline and during its possible repair.

The solution to this problem lies in the fact that in the device of a composite pipeline base on swamps and flooded areas, including components in the form of central and lateral pontoons having a metal power frame of I-section and a sheath of basalt-carbon-plastic, tightened with high-strength composite cargo-fixing cables, according to the utility model, the components of the pipeline base are interconnected and into the track in the form of a thorn groove. Through the holes in the thorn-groove connection, cylindrical rods made of basalt-carbon-plastic are stretched. The components of the pipeline base are staggered. On the track from the central pontoons mounted supporting devices under the pipeline. Along the perimeter of the pipeline base, high-strength composite load-bearing cables are stretched.

The advantages of the thorn-groove connection over the castle are as follows:

- the absence of gaps after mounting the components in a prefabricated structure;

- the absence of abrasion and loosening of joints during operation;

- lack of stress concentration at the joints. The location of the constituent elements of the pipeline base in

the checkerboard pattern gives strength and resistance to deformation at the joints at unevenly distributed load on the pipeline base, which in turn increases the service life of not only the pipeline base, but also the pipeline itself.

The supports installed on the track from the central pontoons at an estimated distance from each other will ensure the correct distribution of the loads acting on the pipeline and their transfer to the pontoons, as well as maintain the design position of the pipeline during its operation.

The tension on the reinforced concrete pyramidal anchors installed on the day surface of high-strength composite load-bearing cables located around the perimeter of the composite pipeline base will ensure the stability of the entire structure as a whole under the most unfavorable combination of loads and impacts.

The parameters of the constituent elements of the pipeline base are selected depending on the characteristics of the pipeline and the construction conditions. The width of the central pontoon B _c is 2 meters or more, and the width of the side pontoon B _b is 4 meters or more. The lengths of the central L _c and lateral L _b pontoons are up to 12 meters. Supporting devices are selected for each pipeline in accordance with GOSTs and placed at a distance calculated for a particular pipeline.

In FIG. 1 shows the construction of a component of the pipeline base in the form of a central pontoon; in FIG. 2 shows the construction of a component of the pipeline base in the form of a side pontoon; in FIG. 3 shows the “tongue-and-groove” connection of the components of the pipeline base to the track and to each other; in FIG. 4 shows a composite pipe base with a pipe laid on it.

The composite pipeline base consists of a bunch of central pontoons 1, side pontoons 2, connected to each other and into the track by a thorn-groove connection 3-4 by passing longitudinal and transverse fixing rods of basalt-carbon-plastic into the holes 5, stretched onto reinforced concrete pyramidal anchors with high-strength composite cargo-fixing cables 6, located around the perimeter of the prefabricated pipeline base in the eyes 7, as well as the pipeline 8, laid on the supporting device 9, secured by a bolt connection 1 0 on a composite basis.

The construction of a composite pipeline base in swamps and flooded areas is as follows.

Arrange a fixed launch pad with shelter from the weather. Reinforced concrete pyramidal anchors are installed around the perimeter of the composite pipeline base on the day surface of the earth. Pull high-strength composite load-bearing cables 6 from the anchor to the launch pad. The load-fixing cables 6 are fixed on the central 1 and side 2 pontoons using eyelets 7. The central 1 and side 2 pontoons are joined together by a thorn-groove 3-4 connection, passing longitudinal fixing rods of basalt-carbon-plastic into holes 5. Successively build up the pipeline base into the track, fastening the sections to each other with transverse fixing rods using holes for the transverse fixing rods 5. Operations are sequentially performed using the installation and laying complex. At the same time, channels are mounted on the pipeline base with shelves upwards to provide passage on this track of the required equipment, while the assembly and laying complex, which carries support devices in the abdominal part for pipeline 9 and pipeline sections 8 for providing the possibility of sequential building up of the onshore pipeline under construction by the “on itself” method.

The proposed construction of a composite pipeline base will allow the construction of trunk pipelines in swamps of all types, in irrigated areas at any time of the year without disturbing the ecological balance in nature.

Claims (5)

1. The device of the composite pipeline base on swamps and flooded areas, including components in the form of central and lateral pontoons having a metal power frame of I-section and a sheath of basalt-carbon-plastic, tightened with high-strength composite load-fixing cables, characterized in that the components of the pipeline base are interconnected and into the track like a thorn groove. 2. The device of the composite pipeline base in swamps and flooded areas according to claim 1, characterized in that basalt-carbon-plastic rods are cylindrically shaped through holes in the thorn-groove connection. 3. The device of the composite pipeline base in swamps and flooded areas according to claim 1, characterized in that the components of the pipeline base are staggered. 4. The device of the composite pipeline base in swamps and flooded areas according to claim 1, characterized in that on the track from the central pontoons supporting devices are installed under the pipeline. 5. The device of the composite pipeline base in swamps and flooded areas according to claim 1, characterized in that high-strength composite load-bearing cables are stretched along the perimeter of the pipeline base.

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