WO1998058768A1 - Method for cleaning pipes using dry ice - Google Patents

Abstract

The invention relates to a method for cleaning pipes, wherein said pipe has at least two open ends and the inner liners are removed by means of abrasives flowing through the pipe as a result of negative and positive pressure. The inside of the cleaned pipe is coated with a viscous hardening coating material. In order to avoid the presence of contaminated abrasives and to guarantee a sufficient abrasive effect, the method uses granular-shaped dry ice as an abrasive.

Description

 METHOD FOR RENOVATING PIPELINES BY DRY ICE

The invention relates to a method for the rehabilitation of pipelines, the pipeline being open at at least two ends, the inner linings being removed by abrasives flowing through the pipeline by means of negative pressure or excess pressure, and the cleaned pipeline being internally coated with a viscous, hardening coating material.

Basically, it should be noted at this point that the pipes to be renovated are already installed pipes that can carry different flow media. For example, there may be inlet and / or outlet pipes for water or gas in residential, industrial and municipal systems, which also include household and industrial waste water pipes. All of these lines tend to incrust, mainly due to lime deposits from the water or wastewater, to rust formation on the inner wall of the line, to excretions from the flow medium, to reaction products between the flow medium and entrained substances and the line material, etc. and from them combined effects are attributable. The aforementioned phenomena lead to cross-sectional tapering and often also to leaks, as a result of which the transport of the flow medium is disturbed, if not made impossible.

The method claimed here for the rehabilitation of pipelines helps to avoid a complete renewal of the pipeline, which has proven to be particularly advantageous in particular with regard to completely installed sanitary facilities, sewage systems, air conditioning systems, etc. Here, namely, the pipes are more or less freely accessible after removing the fittings, so that the claimed cleaning and coating process can be used. In any case, it is essential that a pipeline must be made accessible at at least two open ends, so that the individual process steps can be carried out. The claimed method does not preclude a conventional repair of the pipelines, at least in some areas, so that complete pipeline networks can also be partially renewed and partially renovated according to the claimed method.

Methods of the type in question have been known in practice for some time. By way of example only, reference is made here to European patent specification 0 299 134 and to international publication WO 95/09320. The disclosure content is hereby expressly assumed to be known and complements the introduction to the description within the framework of the prior art.

A generic method is known from European Patent 0 299 134, in which the drying of the pipeline, the removal of the inner linings in the pipeline, the preheating of the pipeline and finally the internal coating of the pipeline are carried out using compressed air. In other words, according to the known method, compressed air is pressed through the pipeline as a carrier medium.

The method known from the European patent specification 0 299 134 has the very considerable disadvantage that leaks during the application of the method or during the pressurization of compressed air cannot be or are virtually impossible to determine. As a result, there is a risk here that the interior coating will be carried out despite enormous leaks, with the leaks being virtually impossible to close. In this respect, a large leak or a hole in the pipeline is virtually "refined" by coating and can no longer be effectively closed.

The method known from WO 95/09320 is also concerned with the renovation of fresh water pipes with a small cross-section, the drying of the pipe as well as the sandblasting of the inner coverings and the subsequent coating being carried out exclusively by means of negative pressure. In any case, here too, a pressure difference between the inlet-side and outlet-side end of the pipeline accelerates the air and thus the abrasive particles and also the coating material. The previously known methods for the rehabilitation of pipelines use conventional abrasives as abrasives, for example sand suitable for sandblasting. However, the use of such abrasives is problematic insofar as there is first of all the risk that the abrasive particles damage the inner wall of the pipeline or even cause leaks at corroded locations. Conventional abrasives have the further problem that they contaminate due to the abrasive cleaning process and have to be disposed of on the outlet side of the pipeline. In any case, reuse of the abrasive particles is no longer possible due to the contamination or only after labor-intensive preparation. In any case, the disposal and, if necessary, the preparation of contaminated abrasive particles entail considerable costs.

The present invention is therefore based on the object of designing and developing a method for the rehabilitation of pipelines of the generic type in such a way that the formation of contaminated abrasive particles is at least largely avoided. A sufficient abrasive effect should be ensured with careful handling of the pipeline.

The method according to the invention achieves the above object by the features of claim 1. Thereafter, the method for the rehabilitation of pipelines of the type mentioned at the outset is designed in such a way that granular dryness is used as the abrasive.

According to the invention, it was first recognized here which problems are associated with the use of conventional abrasives or abrasives. Above all, it has been recognized here that the inner wall of the pipeline wears out heavily as a result of conventional abrasives. In addition, the amounts of contaminated abrasive that occur when cleaning the pipeline represent very considerable problems, particularly with regard to disposal or reprocessing.

In a further step according to the invention, it was recognized that the amount of “used” abrasive is not only reduced, but overall can be avoided by using dry ice as the abrasive - in the form of the invention - in granular form.

Ultimately, granular dry ice is a kind of cryogenic snow that never becomes liquid. In concrete terms, dry ice is the solid form of carbon dioxide (CO2). If CO2 is expanded, fine powder CO2 snow is created. This deep-cold snow is pressed through matrices and thus compressed into dry ice.

Dry ice has a density of approx.1,300 kg / m ³ . The bulk density of the granular dry ice is approximately 1,100 kg / m ³ . It looks similar to conventional water ice, but has completely different properties that can be used particularly well for the pipeline rehabilitation process in question here.

The temperature of the industrial dry ice is constantly at -78 ^° C. When energy is supplied, for example by means of heat or when the dry ice particles hit the inner wall of the pipeline, the dry ice does not become liquid, but rather changes directly to the gaseous state. As a result, there are no liquid residues in the interior of the pipeline, in particular on the inner wall of the pipeline, which have to be suctioned off at the end or even disposed of. Rather, the dry ice becomes gas and can be extracted outside the pipeline.

Dry ice granules are produced in so-called pelletizers and can be transported in special deep-freeze containers, regardless of where they are produced, so that one is independent of the equipment required for producing the dry ice at the place of use.

If the granular dry ice is now used as an abrasive, the dry ice particles - as well as conventional abrasive or blasting agent - hit the inner wall or any impurities, limescale deposits or rust spots in the pipeline. When the dry ice particles strike, three physical effects that occur simultaneously lead to cleaning of the inner surface of the pipeline. The -78 ^° C cold dry ice particles suddenly cool the inner surface of the pipeline when it hits it. Contaminants, lime or rust adhering there become brittle and lose their elasticity that may still exist. Due to different expansion coefficients of the contaminants, the lime, the rusty incrustations, etc. on the one hand and the material of the pipeline on the other hand, mechanical stresses occur in the interface which negatively influence the adhesion. Finally, the kinetic energy of the dry ice particles leads to an immediate and residue-free transition of the solid state of aggregation of the dry ice particles into the gas phase upon impact with the inner wall of the pipeline or with the impurities, limescale deposits or incrustations. This transition to the gas phase is associated with an abrupt volume increase, which means that impurities, limescale deposits, etc. are detached from the inner wall of the pipeline without residue and removed by the air flow, especially since the impurities, limescale residues, etc. are already loosened by thermal stresses. Ultimately, when the dry ice particles hit the already at least partially dissolved impurities, lime deposits, etc., there is an explosion by sublimation of the dry ice into the gas phase, whereby the components to be detached from the inner surface of the pipeline are literally blown away.

The use of granular dry ice as an abrasive has considerable advantages over conventional abrasives, which can be summarized as follows.

On the inner wall of the pipeline, there is at most an extremely small amount of removal from the original material there. Rather, only brittle contaminant particles are initially embrittled there and literally blasted off the inner wall of the pipeline. A disposal or reprocessing problem with abrasives is effectively avoided. On the outlet side of the pipeline, only the loosened impurities have to be collected and - compared to conventional procedures - disposed of in significantly reduced amounts due to the absence of "used" abrasives. When using granular dry ice as an abrasive for the rehabilitation of pipelines, it is particularly important that the granular dry ice weakens the bond between the pipeline and the contaminants due to its low temperature by cooling the pipeline, namely by thermal stresses between the pipeline material and the contaminants. This is due to different expansion coefficients between the contaminants and the piping material. The explosion-like expansion of the gas that occurs when the dry ice is sublimated literally blows the already loosened impurities away from the surface of the pipeline.

The granular dry ice used in the manner according to the invention as an abrasive has a further advantage in that it is also possible to improve already internally coated pipelines, since the dry ice is particularly suitable for cleaning or even removing already applied inner coatings. Smooth inner coatings are extremely difficult to remove with conventional abrasives. However, the use of the granular dry ice leads to such considerable thermal tensions between the piping material and the applied smooth inner coating that thermal tensions caused by extremely different coefficients of expansion cause the coating to become detached. In accordance with the above explanations, inner coatings can thus be effectively removed, so that a new inner coating or repair is effortlessly possible for the first time as part of repair work.

The dry ice is produced in a particularly advantageous manner in conventional pelletizers and can be brought to the construction site in thermally insulated containers. These thermally extremely well insulated containers also serve to store the granular dry ice. On site, i.e. at the construction site, the granular dry ice can be removed directly from the thermally insulated containers or can be poured into a special storage container and - directly from the thermally insulated containers or from the storage containers - fed to the pipeline to be cleaned abrasively. In the context of a first variant of the method according to the invention, the dry ice could be metered into a compressed air flow and carried by the compressed air flow into the pipeline and conveyed through the pipeline. The pressure difference between the pipeline inlet and the pipeline outlet required to convey the granular dry ice is thus created by means of compressed air.

It is also possible in the context of a second variant of the method according to the invention that the dry ice is sucked in from the pipeline either from the thermally insulated container or from the special storage container and - initially metered - by the air flow occurring in the pipeline due to the negative pressure on the outlet side, first into Pipeline is fed in and finally through the pipeline. In this case, the pressure difference required for air flow within the pipeline results from a negative pressure prevailing on the outlet side, pressure differences of up to 0.9 bar compared to ambient pressure being able to be realized here without further notice.

In the context of a third variant of the method according to the invention, it is possible for the dry ice to be metered into a compressed air flow and conveyed into the pipeline by the compressed air flow. There, the dry ice could be conveyed through the pipeline by an air flow created by the compressed air and by simultaneous negative pressure on the outlet side. Ultimately, this is a combination of the two variants discussed above, namely in that the granular dry ice is introduced into the pipeline on the one hand by means of compressed air and on the other hand is extracted on the outlet side, the extraction referring to the sublimed gas which is directly released into the environment can be delivered.

The granular dry ice could, for example, be in the form of round particles. Specifically, these particles could have a diameter in the range between 2 mm and 6 mm.

It is also conceivable to design the granular dry ice in the form of elongated particles, as a result of which the particles rotate with a corresponding rotation very special abrasive effect. Such particles could have a length in the range between 4 mm and 10 mm and a thickness in the range between 2 mm and 4 mm.

Furthermore, it should be noted here that the granular dry ice can also be transported into the pipeline by means of compressed air via a probe or a hose or the like. The dry ice at the open end of the pipeline could escape the hose into the pipeline unhindered. However, it would also be conceivable for a nozzle to be arranged at the free end of the hose through which the granular dry ice is blown into the pipeline. Of course, significantly higher speeds of the dry ice particles can be achieved than by simply sucking them into the pipeline.

In concrete terms, the hose could be gradually pulled out of the pipeline from the connection end at a predeterminable speed, so that the nozzle moves through the pipeline. Depending on the speed that can be achieved here, there may be greater abrasion on the inner wall of the pipeline.

The nozzle could be designed in such a way that it radiates on all sides towards the inner wall of the pipeline, so that the nozzle and at least partially the hose within the pipeline virtually center itself. Ultimately, contacting the nozzle with the inner wall of the pipeline would be largely avoided and the nozzle would "float" almost centrally in the pipeline.

It would also be conceivable if the nozzle head were designed as an endlessly rotating component and rotated when blasting, a swirling spray mist consisting of dry ice particles being generated. A homogeneous abrasion would be guaranteed.

With a special configuration of the nozzle, a further advantage could be achieved in that the hose or the nozzle has its own drive through the pipeline, namely due to an air jet or jet of dry ice particles directed obliquely against the inner wall of the pipeline. keln. Ultimately, the hose would push or push through the pipeline on its own, with a receptacle for the hose being required at the connection-side end.

As a further active measure, one could center the outlet-side end of the hose or the nozzle within the pipeline by a type of chassis. In this respect it would be ensured that the end of the hose or the nozzle on the outlet side in any case avoids contact with the inner wall of the pipeline. For this purpose, at least three elastic or resilient undercarriage arms - for example equipped with rollers - could be provided, which support the hose or nozzle on the inner wall of the pipeline, approximately centered.

Finally, it is also conceivable, especially in the case of very stubborn soiling, to combine it with the conventional methods in such a way that conventional abrasives, preferably sand or the like, are metered into the pipeline to the dry ice, such addition being carried out at periodic intervals or once can take place for a certain period of time. Endoscopic monitoring of the pipeline can be used to monitor the addition of conventional abrasives and their effects.

Finally, it should be particularly emphasized that the claimed process - use of granular dry ice as an abrasive - can be used in any pipeline for cleaning, decalcifying or even rust removal of the inner wall, regardless of the purpose of the pipeline.

Claims

Patent claims 1. A method for the rehabilitation of pipelines, the pipeline being open at at least two ends, the inner linings being removed by abrasives flowing through the pipeline by means of negative pressure or excess pressure, and the cleaned pipeline being internally coated with a viscous, hardening coating material, characterized in that the abrasive is used granular dry ice is used. 2. The method according to claim 1, characterized in that the dry ice is produced in pelletizers, stored in thermally insulated containers and possibly transported, possibly poured into a storage container at the construction site and fed to the pipeline. 3. The method according to claim 1 or 2, characterized in that the dry ice is metered into a compressed air flow and carried by the compressed air flow into the pipeline and conveyed through the pipeline. 4. The method according to claim 1 or 2, characterized in that the dry ice is sucked in from the pipeline and is preferably metered into the pipeline and through the pipeline through the air flow occurring within the pipeline due to outlet-side negative pressure. 5. The method according to claim 1 or 2, characterized in that the dry ice is metered into a compressed air stream and carried by the compressed air stream into the pipeline and that the dry ice is conveyed through an air flow through the pipeline resulting from the compressed air and from the outlet-side vacuum becomes. 6. The method according to any one of claims 1 to 5, characterized in that approximately round particles are used as granular dry ice. 7. The method according to claim 6, characterized in that the particles have a diameter in the range between 2 mm and 6 mm. 8. The method according to any one of claims 1 to 5, characterized in that approximately elongated particles are used as granular dry ice. 9. The method according to claim 8, characterized in that the particles have a length in the range between 4 mm and 10 mm and a thickness in the range between 2 mm and 4 mm. 10. The method according to any one of claims 1 to 9, characterized in that conventional abrasive, preferably sand or the like, is metered into the pipeline to the dry ice.