UA57048C2 - safety device for damping or preventing displacement of the ends of broken pipeline - Google Patents

Abstract

A safety device for damping or preventing the movements of a broken section of a piping system (1). has at least two stiff or deformable traction bars (5)that bridge a possible breaking point (2) or a part of the piping system (1) is supported by a buttress (7) so as to prevent it from breaking.

Description

Description of the invention

The invention relates to a safety device for damping or preventing displacement of the detached part 2 of the pipe.

In industrial installations, for example, in power plants, pipes (pipelines) are used, through which a substance under high pressure flows. In the event of a rupture of such a pipe, both of its parts can move relative to each other at a correspondingly high speed due to the recoil of the substance escaping at high speed. At the same time, it is not excluded that parts of the pipe in case of collision with other pipes and 70 structural elements may damage them.

Therefore, the invention is based on the task of developing a safety device that, in the event of a pipe rupture, prevents parts of the pipe from hitting the structural elements of the installation at high speed and damaging them.

According to the first form of implementation of the invention, the problem is solved by the fact that, covering the possible place of pipe rupture, at least two rigid or deformable screeds are installed, fixed on both 79 sides of the possible place of pipe rupture.

Thanks to this, after the pipe breaks, its parts are held by the ties and/or the kinetic energy of the pipe parts is extinguished due to the deformation of the ties and at the same time the force is limited in the ties. At the same time, the dynamic load coefficient is much smaller than 2. As a result, the parts of the pipe are displaced at a small distance from the place of rupture.

As a rule, it is sufficient to install such safety devices on known, especially prone to rupture, sections of the pipeline. Ties can be fixed, for example, on parts welded to the pipe on both sides of the possible place of rupture.

According to a particularly advantageous embodiment of the invention, the screeds are connected to the pipe by a universal joint.

Due to this, the forces acting on parts of the pipe not along the axis can also be damped. In this way, the axial position of the pipe parts is stabilized. Gee)

For example, screeds on at least one side of a possible place of rupture are connected to a rocker (for example, a cardan joint), which is movable, with the possibility of rotation around it, installed on a stop, for example, a round stop. The stop is immovably connected to the pipe. It can be, for example, additionally welded. The rocker arm always hangs on the stop in balance, even after the pipe breaks. It evens out perhaps not exactly the same degree of tension of the screeds. "AND

In particular, the screeds are connected to a pair of rockers mounted on stops placed on the pipe opposite each other. Ties can be connected by a cardan connection to one or both rockers. Such a pair of rocker arms can be installed on both sides of a possible break point. uh-

According to another example of implementation, the tie rods are connected to a counterpoise, which supports the pipe in the direction 39 of a possible place of rupture in the manifold. Such a design is possible only when such a splitter is installed near the probable place of the rupture.

According to the second form of implementation of the invention, the task is solved by the fact that opposite the part of the pipe, the rupture of which is expected, under the manifold or the armature body, a counter-support is installed, to which the specified part of the pipe is connected with rigid or deformable ties. C 50 Thus, not both adjacent broken parts of the pipe, but only one part is inhibited or even c held in place. A second similar safety device is required for the adjacent detached part of the pipe.

From" Ties are placed, for example, diagonally to the axes of the pipeline sections coming out of the distributor or from the valve body. They can also be placed diagonally to the axis of the armature body. Due to this, such screeds achieve damping of force components in the directions of the axes of all sections of the pipeline and the valve body. In this way, the consequences of pipeline breaks in each section are averted. For example, a part of the pipeline, which is expected to break, in the region of the distributor or the body of the armature is covered by a rigid or deformable bracket, the shoulders of which are formed by rigid or deformable tie rods. Thanks to this, there is no need for fasteners on this part of the pipeline. o Deformable flattened pipes can be placed between the counterpoise and the pipeline. These "rides" 20 flattened pipes, as well as capable of deforming screeds, absorb the kinetic energy of the detached parts of the pipeline. Flattened pipes can be a component of an already existing slide bearing. co In addition, hinged spacers can be installed between the buttress and the building element. Thanks to this, the transfer of forces to the building element can be carried out in an optimal way.

The benefit of using the safety device according to the invention is that after the rupture of the pipeline 29, the detached parts largely remain in their original place. They can't

GF) fly away under the action of recoil and cause secondary damage.

Three variants of the safety device according to the invention are explained in more detail with the help of drawings. They show: Fig. 1 safety device according to the invention, in which the place of possible rupture is covered; 60 fig. 2 a safety device according to the invention, in which the place of a possible rupture is blocked and a part of the pipe is pressed against a support; Fig. 3 safety device according to the invention, in which a part of the pipe is covered with a deformable clamp and is pressed against a resistance.

Fig. 1 shows the pipeline 1 with the place 2 of the break. If there is a substance under high pressure in the pipeline, after the rupture of the pipeline 1, it could exit at a high speed at the place of the rupture 2. This could cause a recoil force applied to the parts of the pipeline 1, as a result of which they could move out of their places and damage the installation of which the pipeline 1 is a component.

Since, as a rule, the location of the pipeline 1 is known, in which a rupture may occur with an average statistical probability, it is advisable to install the safety device shown in Fig. 1 in such a location. Such a place can be, for example, a weld.

The safety device depicted in Fig. 1 contains a stop 3, for example, a round stop welded to the pipeline 1 below and above the place 2 of the break. Two more stops 3, not visible in Fig. 1, are placed opposite each stop Z shown. A rocker arm 4 is installed on each of these stops C. For this, stop C is inserted into a hole in 7/0 Rocker arm 4. A total of four rockers 4 are installed, of which only two are visible in the drawing. A pair of rockers 4, installed on one side from the place 2 of the break, is connected by deformable ties 5 to a pair of rockers 4, installed on the other side of the place 2 of the break. Both deformable screeds 5 relative to the pipeline 1 are placed opposite each other and can be connected to pairs of rocker arms 4 by a cardan connection.

In the event of a rupture of pipeline 1 between both pairs of rocker arms 4, although the substance flows out of pipeline 1, the resulting recoil does not cause damage. The kinetic energy of the pipeline parts caused by the recoil causes plastic deformation of the deformable ties 5, which at the same time largely hold the pipeline parts in their original place, and at the same time the forces are limited in the ties.

Figure 2 shows the manifold 6 of the pipeline 1, from which one part of the pipeline is oriented upwards in the plane of the drawing, and two parts of the pipeline are oriented perpendicular to the plane of the drawing. On the upwardly oriented part of the pipeline, two stops corresponding to those depicted on the upper part of Fig. 1 are installed

C, two rocker arms 4 and two deformable tie rods 5. At the same time, the tie rods 5 are connected to the rocker arms 4 by a completely cardanic connection, thanks to which non-axial displacements of the pipeline 1 can also be damped. are connected to the counter-support 7. This counter-support 7 is placed under the manifold 6 and supports it and the pipeline 1.

After the rupture of the pipeline 1 at the point 2 of the rupture, the upper part of the pipeline 1, as in the example of implementation i) according to Fig. 1, is held by deformable tie rods 5. The lower part of the pipeline 1 together with the branch b is kept by the counterporous 7 from flying away under the action of recoil. According to Fig. 2, flattened pipes 8 are installed between the counterspring 7 and the distributor b. These flattened pipes 8 can be a part of the slide bearing. However, the problem of the flattened pipes 8 from the point of view of the safety device is that after the rupture of the pipeline 1, the kinetic energy of the lower part of the pipeline 1 - compresses the flattened pipes 8, due to which significant movement of the lower part of the pipeline is impossible. Hinged spacers 9 or rigid structural elements or a combination of both technical solutions can be installed between the counter-support 7 and the building element 10 in order to remove the effect of external forces on the building element. yu

The form of execution of the safety device according to fig. 2 can be applied in the zone of placement of splitters 6.

Oppositely directed forces acting on both parts of the pipeline after its rupture, on the one hand through the ties 5, and on the other hand through the flattened pipes 8, are applied to the same counterpoise 7. In this case, the forces are limited due to the plastic deformation of the ties 5 and the flattened pipes pipes 8. Since the forces from c are directed oppositely, the forces applied to the element 10 of the building are relatively insignificant. . Fig. 3 shows another form of implementation of the safety device according to the invention, which can be applied both for splitters and for armature housings. At the same time, as shown in Fig. 2, the splitter 6 or the armature body rests on the counter strut 7. Between the counter strut 7 and the splitter 6 or

Expandable pipes 8 are placed in the body of the armature. In addition, hinged spacers 9 are installed between the element 10 of the building and the buttress 7s.

The inner bend of the distributor b or the armature body is surrounded by a deformable bracket 11, the shoulders of which are oriented approximately in the direction of the median of the angle formed by the axes of the pipeline parts coming out of the distributor 6. According to its properties, the deformable bracket 11 corresponds to the deformable tie rods 5. It is connected to the element 10 of the building directly or indirectly, for example, through the counter-support 7. c Through the deformable bracket 11, one component of the force presses the distributor 6 or the valve body to the flattened pipes 8 and, thereby, to the counter-support 7. Another component of the force prevents displacement of the splitter 6 or the armature body a considerable distance to the left in the drawing plane. In this way, gaps in the plane of the drawing above and to the right of the distributor 6 or the armature body are eliminated. To eliminate the rupture of the pipeline to the left of the distributor 6 or the valve body, a friend, not shown in the drawing, would be needed

Ф) the bracket 11 is capable of deforming, which must be installed mirror-symmetrically to the bracket 11, and the plane of symmetry is oriented perpendicular to the plane of the drawing along the axis of the upwardly oriented part of the pipeline. With the safety device according to the invention, the detached parts of the high-pressure pipelines are largely kept in their original places.

Instead of deformable screeds 5, rigid screeds can also be used.

Claims (9)

Formula of the invention b5 (21) 99063012 1. A safety device for damping or preventing the displacement of a detached part of a pipe (1), which includes a connecting element that is installed to cover a possible place (2) of a pipe break, which is characterized by the fact that the connecting element is at least two rigid or capable the ties (5) connected to the pipe (1) on both sides of the possible place (2) of the break by means of a cardan joint are deformed. 2. A safety device for damping or preventing the displacement of a detached part of the pipe (1), which 7/0 Contains a connecting element that is installed to cover a possible place (2) of a pipe break, which is characterized in that the connecting element is at least two stiff or deformable ties (5), as well as the fact that the ties (5) are connected on one side to the pipe (1) and on the other side to the counterpoise (7) placed under the manifold (6) in the direction of possible places (2) of rupture. C. Safety device according to claim 2, which is characterized by the fact that the ties (5) are connected to the pipe (1) by a cardan connection. 4. Safety device according to claim 1 or 2, which is characterized by the fact that the ties (5) are connected to at least one rocker arm (4), movably mounted on a stop (3), immovably connected to the pipe (1). 5. The safety device according to claim 5, which is characterized by the fact that the ties are installed at an angle to the axes of the pipe segments coming out of the distributor (6) or the valve body. 6. Safety device according to claim 4 or 5, which is characterized by the fact that the part of the pipe, which is supposed to be torn off, in the area of the distributor or the armature body is covered by a rigid or deformable clamp (11), the shoulders of which are formed by two rigid or deformable ties (5) . 7. Safety device according to one of claims 2 - b, which is characterized by the fact that flattened pipes (8) are placed between the counterpoise (7) and the pipe (1). high school 8. Safety device according to claim 7, characterized in that the flattened tubes (8) are components of the sliding bearing. and) 9. Safety device according to one of claims 2 - 8, which is characterized by the fact that hinged spacers (9) are installed between the buttress (7) and the element (10) of the building. that co Head of Department K.V. Zhdanenko Performer T.M. Basova " "c) i- IS c) - with . and? 1 -I («c) sh» IC e) F) ime) 60 b5