SK284886B6 - Safety device for damping or preventing the movements of a broken section of a piping system - Google Patents

Abstract

A safety device is disclosed for damping or preventing the movements of a broken section of a piping system (1). In a first embodiment, at least two stiff or deformable traction bars (5) bridge a possible breaking point (2) so as to prevent it from breaking. In another embodiment, a part of the piping system (1) is supported by a buttress (7) at a branch (6) or fitting housing so as to prevent it from breaking. The branch (6) is further joined to the buttress (7) by at least two deformable traction bars (5), in particular a deformable hoop (11).

Description

Technical field

BACKGROUND OF THE INVENTION The present invention relates to a pivotable fuse for damping or preventing movement of a fractured portion of a conduit comprising a connecting element for bridging a predicted possible fracture point.

BACKGROUND OF THE INVENTION

In industrial plants, for example also in power plants, pipelines are used through which the medium flows under high pressure. In the event that such a pipe would burst, both parts of the pipe could be thrown at a correspondingly high velocity apart at high velocity ejection due to the backflow of the medium. It would then not be possible that parts of the pipeline would be damaged by impact on other pipelines and components.

One pivotable fuse of the type in which two bushings connected by a connecting element for bridging the potential breakage location, which are connected to the pipe on both sides of the potential breakage, is known from WO 94/15138.

SUMMARY OF THE INVENTION

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a pivotable safety device which, upon rupture of a pipe, prevents parts of the pipe from impacting and damaging parts of the apparatus at high speed.

This object is achieved by a pivotable fuse for damping or preventing the movement of a broken pipe section comprising a connecting element for bridging a predicted possible fracture point, according to a first embodiment of the invention, by providing at least two rods which are articulated on both sides of the possible fracture point with pipes.

This has the advantage that after the pipe rupture, the pipe parts are held firmly by the drawers and / or the kinetic energy of the pipe part is removed by deformation of the drawers and thus the force in the drawers is limited. The dynamic load factor is clearly less than 2. The pipeline parts move only slightly from the break point.

As a rule, it is sufficient if such pivoting fuses are located on known particularly endangered pipe sections. For example, the rods may be attached to parts that are welded to the pipe on both sides of a possible breaking point.

According to a particularly preferred example, the rods are articulated to the pipe. This has the advantage that forces that do not act axially on the pipe section can also be damped. The pipeline parts can be stabilized in the axial position.

For example, the rods are connected to at least one side of a possible breaking point with at least one rocker (e.g. articulated) that is movably mounted on an eccentric, for example a circular eccentric, and is rotatable about it. The eccentric is firmly connected to the pipe. For example, it can be subsequently welded. The rocker arm is also mounted on the eccentric always in balance after deflection or even after a pipe break. It also compensates for unequal elongation of engaging drawbars.

In particular, the linkage is connected to a pair of rocker arms, the rocker arms of which are mounted on the pipeline with respect to each other on separate eccentrics. The linkage may be articulated to one or both of the linkage. They can also be placed on both sides of a possible breaking point.

According to a third embodiment of the invention, the object is solved by providing at least two rods which are connected to the duct on the one hand and with a support on the other hand which supports the duct in the direction of the possible breaking point on the distributor member. Such an arrangement is only possible if such a distribution member exists in the vicinity of the predicted breaking point.

According to a third embodiment of the invention, this object is achieved by providing at least two rods which are connected to the pipe on the one hand and with a support on the other hand which supports the pipe in the direction of the possible breaking point on the distributor member.

In this way, only two adjacent break points cannot be braked or even tightly restrained. A second equal fuse is required for the adjacent break point.

For example, the rods are disposed obliquely on the axis of the pipe sections extending from the manifold member or from the valve body. They can also be placed at an angle to the axis of the valve body. The advantage is achieved that the rods are damped force components in the direction of the axis of all these pipe sections and the valve body. The consequences of pipeline rupture in each section are also managed.

For example, the part that is expected to break is surrounded by a fixed or deformable yoke in the region of the manifold member or body of the armature, the arms of which form both arms. By this measure, no fastening means is required on this part of the pipe.

Distortible flexible tubes may be placed between the support and the pipe. These elastic tubes, as deformable rods, preferably absorb kinetic energy. The flexible tubes may be parts of the sliding bearing used anyway.

In addition, articulated struts can be placed between the support and the building structure. In this way, the effect of forces on the structure of the building is optimally arranged.

In particular, the pivoting fuse according to the invention achieves the advantage that the broken pieces remain in their original position after the pipe rupture. They cannot fly off due to kickback and cause further damage.

BRIEF DESCRIPTION OF THE DRAWINGS

Three variations of the pivoting lock according to the invention are explained in more detail below with reference to the drawings, in which: FIG. 1 shows a pivot lock according to the invention in which the breaking point can be bridged; FIG. 2 shows a pivoting safety device according to the invention, in which the breaking point can be bridged and part of the pipe is supported on the support, and FIG. 3 shows a pivotable fuse according to the invention in which a portion of the pipe is surrounded by a deformable yoke and supported on a support.

DETAILED DESCRIPTION OF THE INVENTION

Fig. 1 shows a pipe 1 with a breaking point 2. If the medium is contained in line 1 under high pressure and when the line 1 is broken, then at the break point 2 the medium is ejected at high speed. This would cause a stroke of part of the pipe 1 to be kicked back, whereby this could be plucked from its holders. In a device that includes a pipe 1, further damages may result from the burst of pipe 1.

If there is a known location on the duct 1 where it is likely to break, it is advantageous to place the pivoting safety device shown in FIG. 1. Such a place may be, for example, a weld seam.

The rocker shown in FIG. 1 consists, inter alia, of an eccentric 3, for example a circular eccentric, which is welded to the pipe 1 above the breaking point and below the breaking point 2. In addition to each eccentric 3 shown there are two other eccentric cams (not shown) 3. A rocker arm 4 is attached to each eccentric 3. For this purpose, the eccentric 3 engages in a bore in the rocker arm 4. A total of four rocker arms 4 are arranged, only two of which are visible. A pair of rocker arms 4 located on one side of the break point 2 is connected to the pair of rocker arms 4 on the other side of the break point 2 by means of two deformable rods 5. The two deformable rods 5 are opposed to one another with respect to the duct 1 and can be articulated to the pair of rocker arms 4.

Should the pipe 1 break between the two pairs of rocker arms 4, although the medium will be ejected from the pipe 1, the resulting kickback will have no consequential damage. Indeed, the kinetic energy of the portion of the pipe 1 which is converted into a kickback causes plastic deformation of the deformable rods 5 while holding the portions of the pipe 1 in their original position, while at the same time limiting the forces in the rods 5.

Fig. 2 shows a manifold member 6 of a pipe 1 from which a portion of the pipe extends upwards in the drawing and two parts of a pipe 1 extend perpendicular to the drawing. On the upwardly directed portions of the pipe 1, they are corresponding to the upper part of FIG. 1, two eccentrics 3, two rocker arms 4 and two deformable rods 5 are located. The rods 5 are in this case articulated to the rocker arms 4 so that non-axial movements of the pipe 1 can also be damped. At the end of the rods 5 opposite the rocker arms the support 7. The support 7 is arranged below the distributor member 6 and supports the distributor member 6 and the remaining pipe 1.

Upon rupture of pipe 1 at the break point 2, the top of pipe 1, as in the embodiment of FIG. 1, held by deformable rods 5. The lower part of the pipe 1 with the splitting member 6 is prevented by the support 7 from flying back due to the kickback. Between the support 7 and the manifold member 6 of the conduit 1, according to FIG. These flexible tubes 8 may be part of the plain bearing. The role of the flexible tube 8 in relation to the pivoting fuse is that after the rupture of the pipe 1 the kinetic energy of the lower part of the pipe 1 compresses the flexible pipe 8 so that no greater movement of the bottom part is possible. Between the support 7 and the structure of the building 10, articulated struts 9 or fixed building elements or a combination of both can be placed on the structure of the building to absorb external forces.

The embodiment of the pivoting lock according to FIG. 2 is applicable in the region of the distributor member 6.

The opposing forces acting upon the interruption of the pipe 1 on both its parts are transmitted both via the rods 5 and the flexible tubes 8 to one and the same support 7. The forces are limited by the plastic deformations of the rods 5 and the flexible tubes 8. , the forces transmitted from the support 7 to the structure of the building 10 are relatively small.

Fig. 3 shows another embodiment of the pivoting fuse according to the invention, which can be mounted on the distributor members but also on the valve bodies. Here, as shown in FIG. 2, the manifold member 6 or the valve body is supported on the support 7. A flexible tube 8 is provided between the support 7 and the manifold member 6 or the valve body 6. In addition, articulated struts 9 are disposed between the structure of the building 10 and the support 1. the deformable yoke 11 is disposed, the arm extending approximately in the direction of the axis of the angle, which are clamped relative to each other on the axes of the two portions of the pipe 1 coming from the separating member 6. The deformable yoke 11 corresponds to deformable rods. indirectly connected to the building structure 10, for example by means of a support 7.

By means of the deformable yoke 11, the force components push the distributor member 6 or the valve body against the flexible tube 8 and thus against the support 7. Other force components prevent the distributor member 6 or the valve body from moving too far along the path in the drawing to the left. In this way the breaks up and to the right of the manifold member 6 or the valve body are managed. In order to be able to handle breaks in the pipe 1 to the left of the manifold member 6 or the valve body, a second deformable yoke (not shown) would need to be arranged mirror-symmetrically to the yoke shown 11, the plane of symmetry extending perpendicular to the drawing along the axis of the pipe 1 pointing up.

By means of the pivoting fuse according to the invention, the broken portions of the pressure line can be reliably locked in their original position.

Rigid rods 5 may also be used instead of deformable rods 5.

Claims (10)

PATENT CLAIMS A pivotable fuse for damping or preventing movement of a fractured part of a pipe (1), comprising a connecting element for bridging a predicted possible breaking point (2), characterized in that at least two drawbars (5) are provided as connecting element, at the sides of the possible breaking point (2) articulated to the pipe (1). Pivotable fuse for damping or preventing movement of a fractured part of a pipe (1), comprising a connecting element for bridging a predicted possible breaking point (2), characterized in that at least two drawbars (5) are provided as a connecting element on one on the other side with the pipe (1) and on the other side with a support (7) which supports the pipe (1) in the direction of the possible breaking point (2) on the distributor member (6). Pivotable fuse according to claim 2, characterized in that the rods (5) are articulated to the pipe (1). Pivotable fuse according to one of Claims 1 to 3, characterized in that the rods (5) are connected to at least one rocker (4) which is movably mounted on an eccentric (3) which is fixedly connected to the pipe (1). . A pivotable fuse for damping or preventing movement of a fractured part of a duct (1), comprising a connecting element for bridging a predicted possible breaking point (2), characterized in that the portion of the duct (1) expected to break is at its splitting point a member (6) or on the body of its fitting supported by a support (7) and connected to it by at least two rods (5). Pivotable fuse according to claim 5, characterized in that the rods (5) are arranged obliquely on the axis of the pipe sections (1) coming from the manifold member (6) or from the valve body. Pivotable fuse according to one of Claims 5 or 6, characterized in that the part of the pipe (1) that is expected to break is surrounded by a yoke (11) in the region of the manifold (6) or the valve body, the arms of which form both arms (5). Pivotable fuse according to one of claims 2 to 7, characterized in that deformable flexible tubes (8) are arranged between the support (7) and the pipe (1). Pivotable fuse according to claim 8, characterized in that the flexible tubes (8) are parts of the plain bearing. Pivotable fuse according to one of claims 2 to 9, characterized in that articulated struts (9) are arranged between the support (7) and the building (10).