RU117557U1 - PIPELINE BREAK LIMITER IN ITS MOBILE FIXATION PLACES - Google Patents

Abstract

A pipeline rupture limiter in the places of its fixed fixation on a fixed support, containing elements of its installation on the pipeline, placed on both sides of the "postulated" rupture section and connected by hairpin connections containing elements having axial elasticity, characterized in that the elements of the breakdown limiter installation on pipeline are made in the form of two main support flanges, spaced from the section of the "postulated" rupture by a distance not less than half of the pipeline diameter, and assembled from semi-flanges connected by bolted joints, while one of the support flanges is fixed by thrust plates welded to the pipeline surface, and between the main support flanges in the immediate vicinity of the section of the "postulated" rupture, an additional support flange of two half-flanges is installed, while the additional support flange is spaced from the thrust plates by the brackets attached to it, It is equipped with through holes for studs connecting the two main supporting flanges, and on the surface of the studs between the additional supporting flange and one of the main supporting flanges, above the section of the "postulated" rupture, metal rings welded from half rings, welded to the outer surface, are evenly spaced along the specified area brackets, and the elements of the stud connection, which have axial elasticity, are made in the form of disc springs.

Description

The design of a pipeline rupture limiter as a utility model relates to devices used to prevent the consequences of ruptures of energy pipelines in places of their fixed fixation, in particular: on fixed supports, in areas of welds when connecting pipelines with elements of penetrations through walls and partitions, etc. e. in the places where the pipeline elements are fixed, where so-called “postulated” ruptures are theoretically possible, the consequences of which on the pipelines of the first and second circuit of nuclear power plants can be “whiplash” movements of the ends of the pipeline, the effect of a jet stream on the surrounding structures and equipment, the increase in pressure in the rooms power plants.

A device for pipe hardening is known, comprising a reinforcing sleeve welded to a hardened pipe above the welded joint, characterized in that the latter is made in the form of a thin-walled shell with a shape of one and a half ', and increased pressure is created in the cavity of the reinforcing sleeve. (Description to the patent of the Russian Federation No. 2067717 according to the application No. 93016381/06, Mcl. From 03.31.1993; published on 10.10.1996).

A disadvantage of the known device is the lack of access to the weld after installing the device on the pipe, which is unacceptable for pipelines of energy systems operating at high pressures and temperatures of the coolant, because it becomes impossible to control welded joints during the operation of the pipeline.

There is also a known limiter for rupture of a pipeline installation seam used as part of a sealing unit for pipeline penetration through protective shells (Description to the patent of the Russian Federation No. 2338949, M. Cl. F16L 5/00 according to the application No. 2007111444/06 of 03/28/2007, published: 20.11.2008 g.). The gap limiter is made in the form of a sleeve with a flange and an annular end face. By means of a flange, a gap limiter is mounted on the end surface of the transitional flange, closes the pipeline installation seam and abuts against the installation element mounted on the pipeline and made in the form of a ring or in the form of radial ribs mounted on the pipeline. At least one hole for overpressure relief in the event of a partial violation of the integrity of the mounting seam of the penetration pipe is made in the wall of the burst limiter.

The main disadvantage of the known limiter of pipeline ruptures is the possibility of mounting it only on elements of a tight penetration with an existing structure for connecting the sleeve, which narrows the scope of its use. It is impossible to use the specified limiter to protect the welds of critical pipelines at the points of connection of the pipeline, for example, to the passage of the pipeline through protective structures. In addition, the implementation of holes in the sleeve for bleeding excess pressure in the case of a partial violation of the integrity of the installation weld of the pipeline can lead to the formation of secondary jet jets.

The closest in purpose, technical essence and the achieved result to the pipeline break limiter, which is declared as a utility model, is a device for limiting leakage during pipeline rupture, containing two fastening elements - tightening clamps installed on the pipeline respectively on both sides of the protected section of the pipeline and connected directly to each other with another using connecting means, including elements with axial elasticity, providing freedom bottom axial expansion of the pipe, with each clamp containing means of axial fastening on the pipeline, for example, hooks in the form of a shoulder on the surface of the pipe and a shoulder on the surface of one of the clamps, or in the form of toroidal rods laid in annular grooves on the surface of the pipe and clamp and consists of two half-clamps connected together and having a section of mutual socket connection, providing alignment that prevents the displacement of the pipeline along the axis in case of rupture of the specified section, and yney least one of the two clamps has a vent channels. (Description to the patent of the Russian Federation No. 2050499 according to class F16L 55/18 according to the application No. 5001550/29 of September 12, 1991, published on December 20, 1995).

The disadvantage of this device is the need to mount the clamps on the pipeline by means of elements requiring refinement of the pipeline design and the inability to install it in places of fixed fixation of the pipeline. The manufacture of collars for the installation of hooks of clamps or grooves for laying bars is not technologically feasible on existing pipelines, and is not permissible on pipelines of energy systems, because may lead to additional loosening of the pipeline. In addition, the implementation of the centering elements in the form of a mutual socket connection, preventing the pipeline from moving along the axis in the event of a gap in the protected welded joint, does not provide sufficient reliability of the design on high pressure pipelines, and the presence of ventilation ducts in the clamps weakens their construction and can serve as channels for the formation of secondary jet streams when a pipeline ruptures.

The technical problem solved by the claimed limiter of pipeline ruptures is to simplify the technology of its installation on existing and under construction pipelines in the places of “postulated” ruptures, to minimize the consequences of ruptures while increasing the reliability of the structure and expand the scope.

The technical result of using this utility model is to simplify the installation technology of the device on the surfaces of pipelines in places of fixed fixation and increase the reliability of elements providing axial and radial fixation of the pipeline in the section area of a “postulated” rupture, for example, a weld, by simplifying structural elements.

The specified technical result is ensured by the fact that in the limiter of pipeline ruptures containing installation elements of it on the pipeline, placed on both sides of the protected section of the “postulated” rupture, and connected longitudinally by means of hairpin joints, including elements with axial elasticity, according to the utility model, installation elements of a gap limiter on a pipeline are made in the form of two main supporting flanges, spaced spatially from the section of the “postulated” gap the distance not less than half the diameter of the pipeline, and assembled from half flanges connected by bolt connections, while one of the support flanges is fixed by stop plates welded to the surface of the pipeline, and between the main support flanges in close proximity to the section of the “postulated” gap, an additional reference a flange of two half flanges, while the additional support flange is spaced from the thrust plates by brackets attached to it, made with through holes for I have studs connecting the two main support flanges, and on the surface of the studs between the additional support flange and one of the main support flanges, metal rings welded from half rings evenly spaced over the indicated section are mounted over the cross section of the “postulated” gap, and the elements are attached to the outer surface of the brackets hairpin connections with axial elasticity are made in the form of Belleville springs.

The implementation of the pipeline rupture limiter, in which the elements of the installation of the rupture limiter on the pipeline - two main supporting flanges, spaced at a distance not less than half the diameter of the pipeline, provides an increase in the volume of the pipeline included in the zone of operation of the rupture limiter, which increases the reliability of fixing the zone of the pipeline with a cross section postulated "rupture and minimizes the consequences of rupture of the pipeline.

Implementation of a gap limiter with an intermediate flange remote from brackets fixed to the pipeline of the support plates, providing additional fixation of the gap limiter on the pipeline or its auxiliary elements, for example, on a fixed support of the pipeline or on the elements of the pipe fittings, which allows to increase the level of protection of the section of the “postulated” pipeline rupture .

An increase in the rigidity of the longitudinal and lateral fixation provided by additional metal rings mounted on the surface of the studs, tightening the two main supporting flanges of the gap limiter and attached to the plate brackets, increases the reliability of the structure, relieves the stress of the pipeline and eliminates the threat of a “postulated” gap. At the same time, the use of disk springs in hairpin joints as elements with axial elasticity makes it possible to take into account the temperature stresses of the pipeline and provides damping properties to the hairpin joints.

In addition, the implementation of all elements of the pipeline movement limiter in the form of simple parts that do not require special technical means to adapt the surface of the pipeline to the fastening of the support elements of the gap limiter simplifies the technology of their assembly on the surface of existing and under construction pipelines.

Distinctive features of the claimed gap limiter provide a simplification of the technology of its installation on existing and under construction pipelines at the junction with auxiliary pipeline elements and minimize the consequences of ruptures, increase the reliability of the structure and expand the scope.

An example of the implementation of the pipeline break limiter is illustrated by drawings.

Figure 1 shows a section of a pipe break limiter mounted on a weld of a pipeline and a tight penetration.

Figure 2 shows the pipeline break limiter mounted on a fixed pipeline support.

The pipeline rupture limiter comprises support flanges 2 and 3 mounted on the surface of the pipeline 1, made of half flanges 2a and 2b, and 3a, 3b, respectively, fastened with threaded joints 2b and 3b, for example, bolted ones. The supporting flanges 2 and 3 are spaced from the zone of the weld 4, which connects the sections of the pipeline and is the section of the “postulated” gap, to a distance of not less than half the diameter of the pipeline. One of the main support flanges, for example, the main support flange 2, is fixed by welding to the end face A of the support plates 5 welded to the surface of the pipeline or to its auxiliary elements, and an additional support flange 7 is attached to the ends B of the support plates 5 by means of brackets 6 mounted on the other the sectional side of the “postulated” gap relative to the flange 2. The flange 7 is also made of two half rings 7a and 7b, interconnected by bolted joints 8. The main supporting flanges 2 and 3 through the holes in them 9 and 10 and open Article 11 in the additional support flange 7 is tightened with studs 12 with nuts 13, 14, 15, 16 screwed on the outer ends of the studs, and with Belleville springs 17 mounted on the surface of the half flanges 2a and 3b. The studs 12 are passed through holes 11 in the additional support flange 7 free. On the outer surface of the studs 12 between the main support flange 2 and the additional support flange 7 installed on the other side of the section of the “postulated” gap, metal rings 18 are welded from two half rings 18a and 18b, the inner surface of the brackets 6 welded to the outer surface.

Installation of the pipeline break limiter is carried out in the following sequence.

On the surface of the pipeline 1 or on the auxiliary elements fixing the portion of the pipeline (not shown in the drawing), at a distance from the protected weld 3 (cross section of the “postulated” gap) at least a quarter of the diameter of the pipeline, thrust plates 5 are installed and fixed. End to end A thrust plate 5 on the surface of the pipeline 1 is installed, the main supporting flange 2, assembled from half rings 2A and 2B, fastened with bolted joints 2B. On the other side of the weld 4 at a distance of not less than a quarter of the diameter of the pipeline, a second main support flange 3 is assembled on the surface of the latter, assembled from half flanges 3a and 3b, connected by bolt joints 3b, and on the same side relative to the weld 4 in close proximity to it an additional supporting flange 7 is installed, the half rings of which 7a and 7b are fixed by brackets 6 to the end face B of the thrust plates 5. Through holes 9 and 10 in the main supporting flanges 2 and 3 and the hole 11 in the additional supporting flange 7, studs 12 are passed, fixed at the ends with nuts 13, 14 and 15, 16 with disc springs 17 installed in them, which have axial elasticity. Outside, the studs 12 are reinforced by rings 18 welded from two half rings 18a and 18b, which are welded to the outer surface of the brackets 6.

The use of a pipeline break limiter will improve the safety of existing and under construction pipeline systems of power facilities. The installation of a pipeline rupture limiter on existing and under construction pipelines at energy facilities will provide reinforcement of welds in the places of their connection with the nozzles of power equipment or with the elements of penetrations through walls and partitions, at the places of connection with shaped pipe elements, such as elbows, tees, and in places fixing it on the fixed supports of pipelines. Thus, the use of rupture limiters will make it possible to strengthen the pipelines of energy facilities in places of theoretically possible ruptures, the consequences of which can be "whiplash" movements of the ends of the pipeline, the impact of a jet stream on the surrounding structures and equipment.

Claims (1)

The limiter of pipeline ruptures in the places of its fixed fixation on the fixed support, containing elements of its installation on the pipeline, placed on both sides of the section of the “postulated” rupture and connected by hairpin connections containing elements with axial elasticity, characterized in that the elements of installation of the gap limiter on the pipeline is made in the form of two main supporting flanges, spaced spatially from the section of the “postulated” gap by a distance of not less than half the diameter piping, and assembled from half flanges connected by bolt connections, one of the supporting flanges being fixed by stop plates welded to the surface of the pipeline, and between the main supporting flanges in close proximity to the section of the “postulated” gap, an additional supporting flange of two half flanges is installed, wherein the additional support flange is spaced from the thrust plates by brackets attached to it, made with through holes for studs connecting the two main flanges, and on the surface of the studs between the additional support flange and one of the main support flanges, over the cross section of the “postulated” gap, metal rings welded from half rings evenly spaced over the indicated section are attached to the outer surface of the brackets, and the elements of the hairpin connection with axial elasticity are made in the form of disk springs.