RU2118741C1 - Method of sanitation of pipe lines - Google Patents

Abstract

FIELD: protection of pipe lines against corrosion in erection and repair. SUBSTANCE: pipe line open at both ends is dried with heated air, its inner surface is cleaned with abrasive material, after which pipe line is heated and rarefaction is created in it. Then coating material is introduced in pipe line which, gets deposit to wall of pipe line and is hardened. EFFECT: easy application of coat; avoidance of toxic effect on environment. 21 cl

Description

 The invention relates to a method for sanitizing pipelines, wherein the pipeline open at least from two ends is dried with preheated air, the internal deposits are removed by passing an abrasive agent through it, the pipeline is heated, if necessary, with heated air, and finally, the inside is covered with viscous, curable coating material.

 It should be noted that pipelines subject to rehabilitation are already laid pipelines through which gas, steam or liquid can pass. It may be, for example, inlet and / or outlet pipelines for water or gas in residential, industrial and communal buildings, and pipelines for discharging domestic and industrial wastewater also fall under them. All these pipelines are prone to the formation of deposits, caused primarily by deposits of lime from water, the formation of rust on the inner wall of the pipeline, precipitation from the medium, reaction products between the flowing medium and related substances, as well as the material of the pipeline, etc. as well as the combined effects they cause. The above phenomena lead to leaks or a very significant decrease in the marching cross-section of the pipes, which impairs the transportation of the medium that passes through, if at all does not make it possible.

 The described method of sanitation of pipelines avoids complex updating of the pipeline, which is especially preferred in relation to integrated embedded sanitizing devices. In particular, here, after the removal of the reinforcement, the pipelines become more or less freely available, so that the claimed method of cleaning and coating can be used. In any case, it is important that there is access to the pipeline from at least two open sides in such a way that individual process operations can be carried out. The claimed method does not exclude at least partial conventional repair of pipelines, due to which the integrated network of pipelines can also be partially updated and partially sanitized in accordance with the claimed method.

 Methods of the type described are known for a long time from practice. By way of example only, reference can be made to European Patent Description 0 299 134. From this European Patent Description there is known a method that has been taken into account in the restrictive part of the claims, moreover, drying the pipeline, removing deposits from the inner wall of the pipeline, heating the pipeline and finally coating the inner wall of the pipeline is carried out using compressed air. In other words, according to the known method, compressed air is blown through the pipeline as such, or as a carrier. But in practice, the use of compressed air creates problems associated with the fact that compressed air easily destroys the processed pipeline just in the area of bends or arcs. If the pipeline already has leaks, the use of compressed air leads to leaks of compressed air in the places of damage and, thereby, to leaks of the medium supplied by compressed air. In addition, the use of compressed air in the case of significant deposits on the inner wall leads to blockages in the pipeline and, therefore, to significant costs for the elimination of blockages. Flat particles captured by compressed air tend to accumulate in the bend area of the pipeline, which as a result leads to complex blockage of the pipeline. In this case, a pulsating supply of compressed air or a supply of compressed air from the other side of the pipeline becomes necessary, which significantly increases the cost of hardware design and time and, therefore, costs.

 In addition, the known method has another significant drawback, namely that when using the method or during the supply of compressed air it is impossible to detect or it is difficult to detect leaks. Therefore, there is a danger that, despite the leaks, coating is applied to the inner side of the pipe, and leak closure is virtually eliminated. As a result, due to coating in the pipeline, a “big” leak or a hole that cannot be effectively sealed is "obtained".

 And finally, the known method leads to a significant problem from the point of view of environmental protection, since particles captured by compressed air are ejected from the open end of the pipeline into the surrounding space. And, therefore, in addition to the means for supplying compressed air used on the inlet side, a special collecting means is necessary for collecting particles entrained in the compressed air. In any case, compressed air leaving the free end cannot be uncontrolledly released into the environment, which also significantly increases the cost of hardware design.

 The basis of the invention is the creation of a method of sanitation of pipelines, with the help of which simple technical means and while eliminating the harmful effects on the environment, achieve such a quality of pipelines that is comparable with new pipelines.

 The problem is solved by the signs contained in paragraph 1 of the claims. According to this paragraph, a method of sanitizing pipelines of the aforementioned type is performed in such a way that air, abrasive material and coating material are sucked into the piping from one end or sucked through the piping so that there is always a vacuum in the piping.

 According to the invention, it should first be noted that the compressed air used according to the prior art, on the one hand, can lead to damage to the sanitized pipeline or cause clogging of the pipeline, and on the other hand, without special measures leads to harmful effects on the environment, since compressed air being blown into a pipeline with high pressure can exit from the exhaust side with harmful substances - with very high pressure - into the surrounding area. It is necessary to have special trapping or filtering devices independently or from the other side of the compressed air inlet from the inlet side, because of which the additional costs for hardware design and, consequently, costs increase significantly. Additional devices in addition to creating a vacuum in accordance with the method according to the invention are no longer needed, because in accordance with the method according to the invention, the suction is carried out exclusively on one side and the sucked air together with particles or the like captured or collected in a device in front of the suction device. A further, particular advantage is added to this, that the method according to the invention can be carried out at least to a large extent on one side of the pipeline, namely on the suction side. At the free end, only a viscous coating material should be supplied, and this can be done before suction, so that a single operator from the suction side can activate and process during coating.

 And finally, the claimed method according to the invention has another, very significant advantage, consisting in the fact that the vacuum created from the suction side decreases towards the open end of the pipeline. Therefore, the detached particles are more strongly trapped with decreasing distance from the outlet side or the end from the rarefaction side, thereby effectively blocking when pressure drops towards the outlet side, since they separate or trap more intensively as the distance to the end from the outlet side decreases. And finally, in the method according to the invention, it is possible to detect leaks due to the fact that in the case of a leak at the end, less depression is established at the outlet side. If such a decrease in rarefaction occurs pulse-like - this indicates an unexpected hole in the pipeline.

 The method according to the invention creates an advantage associated with particularly effective environmental protection if the heated air used to dry the pipe is not simply sucked out, but sucked or sucked through the pipe through a filter device. The filtering device can be installed directly in front of the compressor serving for this, so special devices are not required.

Particles of any type carried by a stream of air, which, however, must be harder than the removed deposits, can serve as an abrasive agent for removing deposits from the inner wall. It is necessary, especially in the case of sanitation of water pipes, so that the particles have a grain size in the range from 0.3 to 6 mm. The specific gravity should preferably not exceed 3.0 g / cm ³ , in which case air is used as the carrier medium. As abrasive particles, we are talking specifically about corundum or quartz sand. Abrasive particles can also be obtained from metal particles, in particular from ferromagnetic particles. With the use of such particles, subsequent magnetic separation of the abrasive particles from the separated material of the internal deposits, consisting of, as previously mentioned, rust and / or lime, is possible.

The application of the coating agent and, on the one hand, good wetting of the inner wall of the pipeline, and on the other hand, the quick subsequent curing is especially improved due to the fact that the pipeline, after removing internal deposits, is heated to a temperature above ambient. In this case, a temperature of 40 ^° C is especially recommended. Heating of the pipeline can also be carried out by sucking in heated air until the desired temperature is reached at the end from the outlet side. It can also be determined by the temperature drop between the end of the pipeline from the input side and its end from the output side. In any case, it is essential that the heating of the pipeline occurs by suctioning heated air, and not by injecting compressed air. And finally, the heated air used to heat the pipeline can also be sucked through a filter device, and this filter device can be connected directly in front of the compressor used for suction.

 In addition, the heating of the pipeline, in a particularly preferred manner, can be carried out exclusively or additionally by means of a heating device that is sucked into the pipeline after cleaning and before coating the inner wall. A suction of heated air may not be required if the capacity of the heating device sucked into the pipeline is sufficient. In any case, the heating device, especially with particularly long pipelines, can prevent cooling of the air drawn in from one side, which greatly accelerates the heating process. The heating device used for this is preferably made of a heating wire. Such a self-regulating heating wire can be made in the form of a resistance heater with ceramic insulation of the heating element. In principle, it is possible to use any devices introduced or sucked into the pipeline.

 In terms of effective heating of the pipeline, a particular advantage is obtained if the heating wire is passed mainly along the entire length of the pipeline. This ensures uniform heating of the pipeline.

 With respect to the introduction of the heating wire, it is particularly preferred if it is sucked into the pipeline by a towing system. As a towing system, a parachute or the like can be used, which passes through a pipeline with a stream of air created by vacuum, and draws a heating wire along with it.

 After sufficient heating of the pipeline, the heating wire is preferably pulled out of the pipeline again before coating the inside. In this case, the heating wire can be pulled both from the end from the input side and from the output side, i.e. end from the rarefaction side, and in the latter case, the current connections should be disconnected from the input side.

 After that, coating material is introduced into the heated pipeline, and a vacuum is also created here from the outlet side. Based on this vacuum, the coating material is sucked into the pipeline along with the surrounding air, and, due to the different viscosity between the air and the coating material, the viscous coating material is pressed against the pipe wall and wets it. In the case of using resin or artificial resin or artificial material as a coating material, a seamless coating of the inner wall of the pipeline is obtained, and the pressure drop necessary to tighten the coating material is created exclusively due to the vacuum from the outlet side.

 In the case of significant leaks, the coating material may have fibers laid in its base, in particular artificial fibers, with glass fibers being particularly preferred in this case. These glass fibers, due to irregularly made outlet openings, intersect or catch, and thereby create sufficient adhesion of the viscous coating material to seal leaks. Thus, it is possible to seal at least small holes and eliminate leaks.

 In addition, you can get a very special advantage, especially in order to exclude further environmental burden and the need to remove waste, if the coating material supplied from the free end of the pipeline is supplied in such a quantity that, although it is enough for coating the inner wall pipeline, but from the exit side of the pipeline does not leave a significant amount of coating material. In other words, knowing the thickness of the coating, calculated in the usual way, and the length of the pipe to be coated, at least approximately the amount of coating material that is necessary is set and the exit of a certain amount of material from the suction side and the corresponding waste treatment are prevented.

 In addition, in the method according to the invention, upon suction from the end side, the free end of the pipe is at least temporarily closed, and places due to gradual underpressure can reveal possible leaks. As soon as a vacuum is reached, significant leaks are detected in the pipeline to be sanitized.

 If it is desirable to investigate the condition of a pipeline being cleaned or already cleaned, for example, a pipeline that has already been cleaned before the coating itself, or if it is desirable to check the quality of the coating measures taken after coating, the optical device is sucked into the pipeline to check the pipeline or control the quality of the coating material. And here a towing system can be used as an aid. In the simplest case, a fiberglass conductor can be used as an optical device, which, on the one hand, introduces light into the pipeline, and, on the other hand, can output reflected light rays from the pipeline. Fiber bundles or various fiberglass conductors can be used with various tasks. In the case of particularly high performance requirements, the optical device may include a device in the form of an endoscopy device, i.e., in the form of a miniature chamber sucked into the pipeline with appropriate lighting and even with a miniature remotely controlled hand-held sampling instrument, etc.

 In conclusion, it should be emphasized that the claimed method can cover other preferred operations of the method, without going beyond the solution described in paragraph 1 of the claims.

Claims (21)

 1. A method of sanitizing pipelines, wherein the pipeline open at least from two ends is dried with preheated air, the internal deposits are removed by passing an abrasive agent through it, the pipeline is heated, if necessary, with heated air, and finally it is coated from the inside viscous, curable coating material by suctioning the coating material, characterized in that the heated air and particles are sucked together with the carrier air from one end into the sludge pipe sucked through the conduit so that the conduit is formed exclusively underpressure, wherein the coating material introduced from the free end of the pipe is introduced in such an amount that, while the pipeline inner wall and covered entirely, but the suction side of the conduit does not extend an appreciable amount of the coating material.  2. The method according to claim 1, characterized in that the heated air for drying the pipeline is sucked through a filtering device.  3. The method according to claim 1 or 2, characterized in that the particles have a grain size in the range of 0.3 to 6 mm 4. The method according to claim 1 or 3, characterized in that the particles have a specific gravity of more than 3 g / cm ³ .  5. The method according to one of claims 1 to 4, characterized in that corundum or quartz sand is used as particles.  6. The method according to one of claims 1 to 4, characterized in that metal particles, in particular ferromagnetic particles, are used as particles. 7. The method according to one of claims 1 to 6, characterized in that the pipeline is heated to approximately 40 ^o C. after removal of internal deposits.  8. The method according to one of claims 1 to 7, characterized in that the heating of the pipeline is carried out by suction of heated air.  9. The method according to claim 8, characterized in that the heated air used to heat the pipeline is sucked out through a filtering device.  10. The method according to one of claims 1 to 7, or 8, or 9, characterized in that the heating of the pipeline is carried out exclusively or additionally using a heating device, sucked into the pipeline after cleaning and before coating the inner wall.  11. The method according to claim 10, characterized in that the heating device is made in the form of a heating wire.  12. The method according to claim 11, characterized in that the heating wire is self-regulating.  13. The method according to claim 11 or 12, characterized in that the heating wire passes mainly through the pipeline along its entire length.  14. The method according to one of paragraphs.11 to 13, characterized in that the heating wire is sucked into the pipeline using a towing system.  15. The method according to one of claims 11 to 14, characterized in that the heating wire is again pulled from the pipeline before applying the inner coating.  16. The method according to one of claims 1 to 15, characterized in that the coating material is sucked into the pipeline together with air.  17. The method according to clause 16, wherein the coating material is a resin, preferably artificial resin or artificial material.  18. The method according to 17, characterized in that the coating material has in its structure fibers, preferably glass fibers.  19. The method according to one of claims 1 to 18, characterized in that the coating material introduced at the free end of the pipeline is calculated by the amount so that the inner wall of the pipeline is coated without significant exit of the coating material from the pipeline from the suction side.  20. The method according to one of claims 1 to 19, characterized in that upon suction from the side of the end, the free end of the pipeline is closed for at least some time and the possible presence of leaks is judged by a varying vacuum.  21. The method according to claim 20, characterized in that the optical means is introduced, at least in a broad sense, in the form of an endoscopy device.