RU2647284C1 - Method of marking the main pipeline - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to the construction and operation of main pipelines. Technical result is achieved by the fact that in a method for marking a main pipeline, consisting of the fact, that installing markers along the length of the pipeline, in the form of plates that are found on the defectograms of the pipeline, diagnosed with the help of an in-tube flaw detector, as identification signs. These signs are pre-recorded in the technical documentation of the main pipeline. As markers, plates with through holes are used, the combination of which corresponds to a specific number. In this case, the plates are fixed in the near-weld zone before carrying out the isolation operation of the assembly seam. Plates can be with a combination of holes in the form of numbers or with slots made on their peripheral part, the number of which corresponds to the number of the pipeline section.

EFFECT: technical result of the present invention is to provide a high accuracy of marking all the assembly seams, cost reduction of marking up the pipeline, increasing the speed and accuracy of searching for the necessary (damaged) pipe.

3 cl, 3 dwg

Description

The invention relates to the construction and operation of trunk pipelines and can be used to accurately determine the location of a particular pipe. It is most applicable for pipelines located in inaccessible places and environments (seabed, wetlands, etc.), where work on pipeline ruptures is difficult and errors when replacing pipes are unacceptable, and repeated in-pipe inspection is problematic.

All critical main pipelines are periodically monitored by passing an in-line magnetic or acoustic flaw detector through them. Such flaw detectors are moved with the help of the transported product (oil, gas). As a result of such diagnostics, defectograms to be decrypted are obtained. Inhomogeneities, thickenings and other deviations from the norm of a certain pipe, found on the defectogram, must be found on the track, studied and eliminated. The pipeline in a certain (according to the defectogram) place is dug up or rises from the aquatic environment to identify the zone of interest on the pipeline. The part of the pipeline that interests is exempted from isolation. Further, using manual flaw detectors, thickness gauges, they try to find a defective place. Most often this place is impossible to find due to the fact that they cleaned the wrong pipe. Usually, all pipes are depersonalized, do not have numbers and are sought in calculating the distance from a certain reference point, which is on the track and is visualized on a defectogram. Therefore, the probability of making a mistake is very high. This problem becomes especially acute when there are many defective places and there is no possibility of re-skipping an in-tube flaw detector. So you can bandage, cut and replace the whole pipe or pipe is not with the most dangerous defect.

To obtain complete information about the technical condition of the pipeline and ensure its safe operation, a reliable pipeline marking system is required, obtaining and processing information about the state of the pipeline, identifying defective zones, the presence of which led (or can lead) to emergency situations. Therefore, many methods for marking pipe lines based on the use of markers, benchmarks, etc., have now been developed.

In A.S. No. 1214984 (IPC ⁸ : F17D 3/00, publ. 02/28/86, Bull. No. 8) gives an example of the use of a large number of marker (indicator) plates in the form of overlays - the so-called passive markers. Various combinations of these plates determine the number of this pipe. These plates create a thickening on the body of the pipe, which is visible on the defectogram. The plates are installed along the pipeline with an offset relative to each other both in its diameter and in the axis. They are fixed by welding, which in itself is already a negative factor, since the place of welding is a stress concentrator in the pipe body and can provoke cracking, which is unacceptable. In addition, such an indication has limited information capabilities.

As marker plates, pads are also used, the fastening of which is performed without welding to the pipe, but they also have their drawbacks. So, in the patent of the Russian Federation No. 2511787 (IPC ⁹ : F17D 5/02, publ. 04/10/2014) overlays with a corrosion-resistant composite plastic material with magnetic properties are presented, which are superimposed on the upper part of the insulated pipeline and held thereon due to the magnetic force the attraction of permanent magnets mounted on them. It should be noted that this method of marking also has low informative capabilities. The magnetic properties of the composite material are lower than steel. In addition, thick-walled pipe insulation, which moves it away from the ferromagnetic mass of the pipe, will interfere with the recognition of a low-magnetic composite reference.

Closest to the claimed technical solution there is a method of marking the main pipeline, which consists in the fact that along the length of the pipeline markers are installed in the form of plates, which are detected on the defectograms of the pipeline diagnosed with an in-line flaw detector, as identification signs that are pre-recorded in the technical documentation of the main the pipeline (Systems for determining the location of defects in the pipeline. A.N. Kovalenko. Journal of Control and Diagnostics, No. 2, 2016, p. 28-20).

According to this decision, the marking is carried out using patch marker plates, regularly placed along the pipeline on the base pipes. Any pipe can be defective, most often not the base one. In order to find a defective pipe, you need to count the distance from the base pipe with a marker plate, which is visible on the defectogram. To facilitate the determination of the location of base pipes with marker plates, special marks (benchmarks) are installed on the ground at the place of their laying with a record of their distance and the number of such a marker. From this reference point, according to the defectogram data, the distance to the defective zone of the pipeline is measured.

But such a markup technique is inaccurate, complex and inconvenient in execution. This is due primarily to the fact that surface marks, as well as inscriptions on them, are not a reliable enough informative tool, because due to many factors - both natural and human, they can be destroyed, damaged or simply removed. In addition, the installation of labels and measurements from them can become problematic due to the complexity of the surface landscape. Obviously, under such conditions, finding the right pipe by counting the distance from the base is quite difficult. And errors in determining the excavation site lead to high costs.

The basis of the invention is the task of increasing the accuracy and informativeness of the method of marking the main pipeline by using plates with a combination of through holes as markers, which corresponds to a specific number, which ensures high accuracy of the designation of all mounting joints, reduces the cost of the process of marking the pipeline, increases the speed and accuracy of the search necessary ( affected) pipe.

The problem is achieved due to the fact that in the method of marking the main pipeline, which consists in the fact that along the length of the pipeline markers are installed in the form of plates, which are detected on the defectogram of the pipeline diagnosed by means of an in-line flaw detector, as identification signs that are pre-recorded in the technical documentation the main pipeline, according to the invention, as markers, plates with through holes are used, the combination of which corresponds to the definition ELENITE number, the plates secured in the weld zone prior to the mounting operation the joint insulation. Along the length of the pipeline can be installed plate with a combination of holes in the form of numbers. In addition, plates can be installed with slots made on their peripheral part, the number of which corresponds to the number of the pipeline section.

The method proposed in this technical solution provides a new piping marking system using plates suitable for numbering an almost unlimited number of mounting joints. The plates have several rows of through holes covered by removable plugs, each of which is assigned a number, and to indicate a specific mounting seam or a specific section of the pipe, it is only necessary to free the corresponding holes of the plate from the plugs, the numbering and combination of combinations of which are indicated in advance in the technical documentation.

The use of such plates does not require the installation of surface benchmarks, since the technical documentation indicates the distance of each mounting seam from the reference point. This greatly simplifies and reduces the cost of finding the right pipe to be repaired or replaced.

The most simplified identification features may consist of at least one hole, which opens from the set of all holes made on the plate. In this case, the number of designated mounting joints (provided that one hole is used) corresponds to the number of holes on the plate. If you open two, three or more holes and create a certain combination of them (positioning vertically and horizontally), then the number of identification signs (and, therefore, designated places) increases by tens, or even hundreds of times.

If necessary, lateral slots can be made on the plates, the number of which corresponds to the number of the pipeline section. This is an additional informative feature, but even in the absence of variations, the combination of holes will be more than enough for designations.

Based on the above information, it can be stated that by manipulating various combinations of holes and the number of slots of the plate, you can create the most simplified and quite effective marking system. And the larger the number of identification signs located along the pipeline, the more accurately the results of defectogram decryption will be transferred to the real pipeline.

Using the holes in the plates, numbers can also be displayed. It can be both Arabic numerals (1, 2, 3, ... 9, 10, etc.), and Roman (I, II, III ... IX, X, etc.).

The developed method of marking using marker plates with holes can be successfully applied in various situations that arise on trunk pipelines during the entire period of their operation.

There can be many options for using identification features based on holes, and the specifics depend on the individual conditions of the pipeline design, its construction, purpose, location, etc. For example, in some cases, identification features may be assigned on a separate part of the pipe or not on all mounting joints. Since each mounting seam is associated with two pipes located to the right and left of it, marking through one mounting seam is possible. The technical documentation should indicate the method of marking the pipeline, where and how these identification signs are located.

The technology described in the prototype provides for fixing the plates to the base pipe over its insulation, which makes it difficult to identify the marker plate due to the insulation layer, which is the cause of the dispersion of magnetic (or acoustic) fields. The difference of the proposed technical solution is that marker plates are fixed before performing the operation of isolation of the installation joint. Such a sequence of actions significantly increases the detectability of the plate and the holes corresponding to it during in-line diagnostics, because in this case conditions are created for the unhindered passage of the magnetic field (or acoustic radiation) emanating from the moving in-line flaw detector.

The drawings presented schematically show some of the possible uses of holes for marking installation joints:

- in FIG. 1 is an example of a marker plate with 30 indicator holes;

- in FIG. 2 is an example of a marker plate with 15 possible positions for two holes;

- in FIG. 3 is an example of the image of numbers using holes that indicate the seam under No. 957.

Depicted in FIG. 1 plate has thirty through holes (six vertically and five horizontally) with numbered plugs (No. 1-30). This plate is able to provide 30 numbers by opening one hole. In FIG. 1, the cap at number 10 is removed, which indicates that this plate is used to mark the mounting seam at number 10. Three side slots are made on the plate, which indicates that it belongs to the third section of the pipe line.

The wide possibilities of the proposed marking method are demonstrated by the example of the plate shown in FIG. 2, which is designed for 15 holes. Only with two open holes on this plate can you create 105 marking combinations that can mark 105 mounting joints. In this case, the technical documentation contains a table with plate numbers that correspond to the location of the holes. Five lateral slots are made on this plate, indicating that it designates the fifth section of the highway.

The marking process can be simplified as much as possible if, focusing on the number of the mounting seam recorded in the technical documentation, open the holes in an arbitrary order, while observing an indispensable condition - their number should correspond to the figure indicated in the technical documentation. With this type of marking, there is no need for strict adherence to one or another combination of holes, because You can open the latter in any order. This layout is very convenient, its capabilities are limited only by the area of the plate.

It should be noted that the simplest and most obvious is the combination of holes in the form of numbers, as shown in FIG. 3. Here, as an example, 45 holes of the plate are grouped with the formation of the number 957, which corresponds to the number of the mounting seam - No. 957. In the same way, you can mark any mounting seam, creating the corresponding numerical designations on the plate. This plate is able to provide 999 numbers.

Identification plates are tightly attached to the surface of the pipe and through holes are easily detected on the defectograms of both magnetic and acoustic in-line flaw detectors. The thickness of the identification plate must be not less than the thickness of the reinforcement of the welds, which are well identified on defectograms. The thicker the plate, the easier it is determined on the defectogram. The diameters of the through holes and the openings between them must also be of sufficient size for recognition.

Implementation of the proposed method:

Pipes of a certain length coated with insulation are supplied for the construction of highways. The ends of such pipes (about 30 cm) are free from insulation - this is necessary for the convenience of assembly joints. After welding in the zone of intersection of the annular assembly weld and the longitudinal factory weld, a certain identification plate with holes with the identification signs reflected in the technical documentation is attached (glued). Thus, the location of the plate is strictly determined (the intersection of the mounting and longitudinal seams) and is easily located on the defectogram. In this case, before installing on the plate, open the plugs, form numbers or the desired combination of holes.

Subsequently, the heat-affected zone together with the plate is isolated, covered with bitumen, etc.

To determine the numbers of the plugs, special stencils can be used that repeat the geometry of the plate and help to properly open the required holes in accordance with the requirements of the technical documentation.

The possibilities of this method for marking a pipeline can be considered using an example of a plate having 30 holes, as shown in FIG. 1. Removing only one plug, such a plate can mark 30 mounting joints. Additionally, attracting slots (and there are 3), you can get 30 × 3 = 90 designations. To increase this number, each subsequent series of designations can be offset relative to the longitudinal factory seam of the pipeline, for example, by 30 °, 60 °, 90 °, 120 °, which will give, for example, 210 × (360/30) = 2520 numbers.

Thus, using such a simple scheme, using only one hole, we can designate 2520 assembly joints, and, therefore, cover a sufficiently large gap in the length of the pipe line. And taking into account that the pipes are delivered, as a rule, with a length of 12 m, then with this simple method for designating each mounting seam, this gap will be 2520 × 12 = 30240 m. If you use not one hole, but a combination of several, this length may be an order of magnitude higher.

Claims (3)

1. The method of marking the main pipeline, which consists in the fact that along the length of the pipeline markers are installed in the form of plates, which are detected on the defectograms of the pipeline diagnosed with an in-line flaw detector, as identification signs that are pre-recorded in the technical documentation of the main pipeline, characterized in that as markers, plates with through holes are used, the combination of which corresponds to a specific number, while the plates are fixed in oloshovnoy zone before carrying out the operation of mounting the joint insulation. 2. The method according to p. 1, characterized in that the plate is installed with a combination of holes in the form of numbers. 3. The method according to p. 1 or 2, characterized in that the plate is installed with slots made on their peripheral part, the number of which corresponds to the number of the pipeline section.

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