DE102013203156A1 - Method for removing biofilms from installations for the provision and distribution of drinking and service water - Google Patents

Abstract

Process for removing deposits of microbial origin from plants for supplying and supplying drinking water and process water, in particular for removing biofilms formed on the surfaces in contact with water from water-carrying pipeline networks, pipelines and partial sections thereof, and from flow-through containers, in which one - the Water is removed from the system to be cleaned or from sections of the system to be cleaned, - an air and / or gas flow leads past the coverings in order to dry them to a large extent and thus make them removable, and - the at least partially dried coverings are then removed a rinsing liquid from the treated system.

Description

The invention relates to a process for the removal of deposits, which consist predominantly of biomass of microbial origin and water and are referred to in this application for short as "biofilms" of facilities for the provision and distribution of drinking and industrial water, in particular from piping systems, and the Application of this method as part of the cleaning of such systems or piping systems.

Drinking water is the most important food for humans. It is crucial for the health of the population that drinking water has a perfect condition. This means that the content of chemical ingredients and the microbiological properties of the drinking water must be such that people can not be affected by their health or even fall ill. Furthermore, it is important that drinking water keeps its perfect condition on the way from its extraction and, if necessary, treatment to the customer's faucet. Drinking water is not germ-free by nature. In order to prevent uncontrolled and unacceptable germ multiplication on the way from the preparation to the consumer, the recognized rules of technology for the construction and general operation of drinking water systems, pipelines and networks must be adhered to.

When dealing with drinking water, it should be borne in mind that the conditions under which the quality of the water must be preserved can be very different. For example, in residential complexes and also in commercial consumers, the residence time of the water in a pipeline network depends on the current, possibly time-varying water consumption, and the temperature and oxygen content of the water from the climatic conditions and the technical quality of the pipe network. This can lead to water of identical initial quality in different plants varying in tendency to tend to contact the parts of the plant in contact with water, e.g. Pipe walls, form pads.

In the case of service water pipes, the microbiological purity is less critical than with drinking water. Since deposits in the form of biofilms but can also be present in service water pipes and affect the functioning of the conduit system, a removal of biofilms is desirable in such lines usually.

In practice, it has been found that certain microorganisms occurring in drinking water are able to accumulate on the surfaces of the water-contacting parts of the plant and on inner walls of the pipes. They can survive and multiply there. Over time, the already mentioned "biofilms" are formed. They consist of microorganisms, the extracellular polymer substance (EPS), which is formed by the microorganisms, mineral particles such as sediments, corrosion products, lime and the like. and a lot of water.

The composition of EPS can vary widely. However, it usually has a gel-like or mucous-like consistency and in practice represents a heterogeneous mixture of various macromolecular constituents. In addition to various slime-forming polysaccharides, it also contains proteins, for example. in the form of active extracellular enzymes, as well as smaller amounts of lipids (glycolipids). It is usually assumed that the EPS usually constitutes 70-95% by weight of the dry matter of a biofilm, and that the water content of typical biofilms or the hydrated EPS is in the range of 70-97% by weight, in particular 90 -97% by weight of the wet weight of the total biofilm.

The EPS performs several functions that are essential for the cohesion of the biofilm and the vital functions of the microorganisms that are present in it and that regenerate or regenerate it. Among the important functions of the EPS is the mediation of the adhesion of the biofilm to surfaces, the aggregation of cells of microorganisms and the immobilization of heterogeneous bacterial populations, the protection of the microorganisms of the biofilm against various chemical and physical agents, so that in the biofilm against numerous biocides such as disinfectants and antibiotics are protected, and finally the water retention or hydration, which protects the biofilm and the microorganisms contained therein from drying out. The EPS also absorbs various substances from the water and can contain enzymes that make EPS a bioactive medium.

The biofilms are usually thin and irregular coatings of mostly soft consistency on the surfaces in contact with drinking water. The biofilm adheres firmly to the surfaces and is normally not removed by the flow in pipelines. It adjusts its consistency of flow velocity near the surface. This means that the stronger the flow, the denser and thinner the biofilm. At low flow, however, a softer, voluminous biofilm grows.

In a biofilm also pathogenic microorganisms, such as For example, Pseudomonas aeruginosa, where they survive and multiply in the protection of the EPS formed by them. Biofilms also provide the basis for the growth of amoebae, which in turn may be contaminated with Legionella. A health hazard of many other organisms, which could be detected in biofilms (eg certain mycobacteria), is at least discussed.

Occasionally, smaller or larger parts of the biofilm may peel off so that they can be washed away and re-attached downstream elsewhere, resulting in further colonization of the aquifer system. Organisms from the biofilm are therefore often detectable in planktonic form in the water and can optionally be absorbed by humans in this form. However, the determination of such planktonic organisms does not provide a reliable picture of the microbiological burden of a water-bearing system, as the detectable mobile organisms do not reflect the extent of colonization of a silty microfilm-bound microorganism water-bearing system.

It is therefore desirable to reliably remove biofilms from the water-bearing systems and to prevent or at least delay their regeneration as far as possible.

A measure to be considered in principle for the removal of biofilms consists in the destruction of the microorganisms in the biofilm with biocidal agents and thus in its destruction, i. in a disinfection of the plants and plant parts, in which biofilms can find or train. Furthermore, it is conceivable to completely or at least partially remove biofilms mechanically, if necessary in combination with a disinfection.

Prophylactic chemical disinfection of fresh drinking water, e.g. With chlorine or ozone, with which the Keimentwicklung and thus also the formation of deposits of microbial origin can be controlled to a certain degree, is not desired in Germany.

Drinking water can be disinfected in various ways. For example, a disinfection using chemical disinfectants is customary. Disinfection is the reduction of the number of germs to a level from which infection is no longer possible. In the past, the disinfecting effectiveness of agents has been determined primarily by their effect on (planktonic) microorganisms dispersed in an aqueous medium. The fact that the microorganisms in biofilms are protected by the EPS was not sufficiently taken into account, so that in practice the disinfecting effect often did not meet the expectations. In general, there are significant gaps in the understanding of biofilm removal, especially among practitioners.

As approved for water treatment disinfectants with depot effect, which have been tested on planktonic, ie not in biofilms sedentary microorganisms, to call chlorine, chlorine compounds such as sodium or calcium hypochlorite and chlorine dioxide. For special cases, also chlorine-releasing agents, e.g. Di- or trichloroisocyanuric acid allowed. Finally, the disinfecting effect of these agents is due to the oxidizing properties of the hypochlorous acid. However, all active ingredients used are hazardous substances, some of which must be labeled "toxic" or "very toxic". Comprehensive health and safety, transport and storage regulations must be observed when handling these substances. Special dosing techniques with the corresponding safety devices for these substances are needed. Maximum addition levels and limit values in drinking water are defined by the authorities. The limit values must be adhered to, which requires a correspondingly complex chemical-analytical monitoring of the drinking water treated in this way.

Nevertheless, the use of chlorine or chlorine compounds can not prevent the formation of biofilms. The effective destruction and removal of biofilms through the use of chlorine requires extremely high dosages (e.g., sixty times the limit of the Drinking Water Ordinance) and very often does not produce the desired result, since the bacteria in the biofilms are very well protected by matrix effects. The removal of this firmly adhering organic matrix is thus a central problem.

Mineral inorganic deposits and incrustations of oxidic and / or carbonate nature, the substances of microbial origin usually contain as inclusions and / or as superficial mucus films (EPS layers) and which are built in particular from cold fresh water, can be chemically acidic, acidic and simultaneously oxidizing or reducing agents (see for example DE 32 44 443 A1 and DE 44 28 027 A1 ) as well as with alkaline cleaning solutions. Such mineral deposits usually form thick, massive and dense layers, and the chemical means for removing such layers must be able to dissolve the inorganic, mineral crusts in the first place. The funds required are often hazardous substances and dangerous goods. Therefore, they are only used if one Flooring resolution by other means is not possible. The use of these detergents requires special attention in terms of transport and storage, dosing and flushing technology, occupational safety and training in the application and the proper disposal of rinsing waters. After use, it must be checked and ensured that any residues of cleaning agent have been completely removed from a treated drinking water system so that consumers are not affected by residues of the cleaning agents.

Attempts are also being made to hydrolyze deposits and biofilms in water-bearing systems by means of a combined air-water rinse and to rinse them off. In such methods, which are described in various apparatus design, for example, in the German utility models G 85 02 327.2 or DE 202 01 782 U1 or in the published German patent applications according to DE 196 41 629 A1 and DE 10 2008 056 522 A1 , it is always only to increase the effect of flowing water in order to better turbulence and increase the impact and shear forces acting on the coverings to be removed. For this purpose, compressed air and water are forced through the pipeline to be treated at alternating short time intervals. Due to the very strong turbulence and cavitation phenomena and the high flow velocities at the interfaces between air and water, loose deposits and biofilms are torn off the drinking water-touched surfaces. Since air and water act in swirling form or in the form of alternating, line-filling gas bubbles or gas blocks on the coverings, the gas remains saturated with moisture and the pads always moisturized, so there may be no drying effects.

Such methods only marginally consider the effects of cleaning on microbiology. Scientific evidence of a complete discharge of coverings, especially of biofilms, are not known. In any case, therefore, in such hydromechanical processes, a downstream disinfection step by means of chemical disinfection is required in order to completely kill or at least immobilize remaining microorganisms or biofilm residues. For the above-mentioned hydromechanical technology, a comparatively complex equipment park and special knowledge in use is necessary. The compressed air must e.g. be very clean and oil-free, as oil residues for microorganisms are recoverable and can lead to strong germ multiplication after treatment. Loose mineral deposits such as the frequently occurring brown colored iron hydroxide-containing particles or limescale deposits are also entrained during use.

The sustainable removal of biofilms is thus problematic in terms of the complete and sustainable removal of the biofilms and the contamination of the water occurring as a result of the cleaning measures. The approaches currently available in the market do not have sufficient efficacy in eliminating biofilms to neutralize and remove unwanted microorganisms from the treated plants, particularly those for the provision and distribution of drinking and utility water, e.g. from piping systems and pipe networks.

It is an object of the present invention to provide a novel method that takes particular account of the microbiology in such systems and with the biofilms and with them also any stored pathogenic microorganisms from drinking water systems, pipes and pipe networks with high efficiency and sustainable removal can.

This object is achieved by a method whose basic features are described in the set of claims in claim 1.

Advantageous embodiments of such a method will become apparent to those skilled in the art from the dependent claims 2 to 9 and the study of the following description of currently particularly contemplated embodiments of a method according to the invention.

The following will be explained to a 1 Reference is made, which shows the technological scheme of a possible embodiment of a method according to the invention.

The present invention is based on the fact known per se that biofilms and also the microorganisms contained therein consist for the most part of water and that a biofilm can only fulfill its various functions if it has a sufficient water content. The microorganisms contained therein are not viable without a high water content.

According to the invention, the water is withdrawn from the biofilm by a purposeful intensive drying of the drinking water-contacted surfaces. As a result, the biofilm shrinks and loses hold on its wearer surface. The dried or at least partially dehydrated biofilm is then easily detached from the surface and can be rinsed out of the conduit system. The initially cohesive and intact biofilm forms fine thin particles, flakes and loose plaques due to loss of water and shrinkage processes. which can be flushed out of the system after completion of the drying step with drinking water and / or a suitable rinsing solution.

The drying according to the invention is preferably carried out with air capable of absorbing a lot of moisture, i. with heated air and / or predried air or other heated and / or pre-dried gas and / or gas / air mixture.

 According to the invention, in order to increase the antimicrobial effectiveness of the treatment, a microbiologically active gas such as nitric oxide, chlorine, chlorine dioxide, ozone and / or another biocidal or bioactive gas may also be added to the air stream in order to control the germicidal and biofilm-removing effect of the per se. increase chemistry-free "drying process. In addition to such gases can in individual cases, if special demands are placed on the sterility and if the technical requirements, for. given a sufficient tightness of the piping system, also another sterilizing acting gas such. the ethylene oxide used in medicine or formaldehyde gas may be added.

After drying, the at least substantially dried line is thoroughly rinsed, usually with an aqueous rinse solution. Such a rinsing solution used after the drying step is also part of the cleaning system or method according to the invention. In order to make the effect of the rinse solution as efficient as possible, apparatus and / or chemical aids may be used which allow the most complete removal of the dry residue and which may also develop an additional cleaning effect against lime and other deposits. The rinsing is preferably carried out under conditions in which the largest possible flow forces act on the dried coverings (biofilms). Such conditions are most easily reached in pipelines. It is also possible, for example, to add to the rinsing solution abrasive granules or other particles which are suspended in the rinsing solution or float therein and are transported by the latter via the linings.

For large-scale walls, as they occur in water tanks or basins, the inventive method is less suitable, once because of the difficulty to dry such walls effectively with dry gas streams, as well as because of a flushing, as used in pipelines is not possible without further ado. The method is particularly suitable structures or cavity sections that can be hermetically sealed.

The rinse solution may also contain disinfectants that destroy remnants of biofilms. It may also be a preferred embodiment of the method to use the rinse solution optionally in a closed loop, multiple times and at high rinse rates. The process of drying and rinsing may optionally also be applied several times in succession to achieve a more thorough cleaning and disinfecting effect.

The invention will be explained in more detail with reference to an embodiment or calculation example for carrying out the method according to the invention.

Embodiment:

A drinking water pipe made of 100 m long steel and 2.54 cm (1 inch) in diameter has a volume of approximately 58 l and an internal surface area of approximately 8.5 m ² . If one assumes for a model calculation that the line is evenly lined with a biofilm with an average thickness of 1 mm, the volume of the biofilm is approx. 8.5 l. Neglecting the solid constituents of the biofilm, one can assume that about 8.5 kg of water must be removed for an estimate of the required process conditions so that the biofilm is completely dried.

Air of 20 ° C with 50% relative humidity contains 7.7 g of water in 1 kg of air. It can absorb an additional 7.8 g / l of water and is then saturated with 100% relative humidity (Mollier-hx diagram). When air at around room temperature is used, the heat of evaporation must be applied by the environment. It is calculated that the evaporation of 8.5 kg of water requires 980 m ^{3 of} air.

However, the heat of evaporation can be at least partially fed by heating before the supply of drying air to the piping system. An outlet air of 20 ° C with 50% relative humidity, for example, heated to 41 ° C, whereby the relative humidity is additionally lowered, and then passed through the pipe. It absorbs the water from the biofilm and finally leaves the tube at a temperature of 20 ° C and 100% relative humidity. In such a case, in the above example, an amount of energy of 21800 kJ or about 6 kWh heat energy is needed.

This calculation applies to the above boundary conditions where 1 mm thick continuous occupancy is assumed. In the real case, however, the occupancy should be significantly lower and more likely to be 0.1 mm. On the other hand, other moisture residues must be removed from the system in addition to the water bound in the biofilm, so that the total amount of energy to be expended in this form can be regarded as a realistic estimate. However, this does not take into account additional technical heat losses, which must always be expected in practice.

Since piping systems can be designed very diverse, e.g. Due to their geometry, branching and the consequent different flow conditions, and also the kinetic conditions in the drying in the pipes can not theoretically predict certain, some practical testing for the empirical determination of each optimal process conditions in most cases part of the implementation of the inventive method.

A possible embodiment of a method according to the invention is described below with reference to the scheme of 1 described in more detail:
For carrying out an embodiment of the method according to the invention, first the water is removed from the plant to be treated, eg a pipe network, a pipeline or a section of a pipeline from which biofilms are to be removed, eg by draining and / or expelling with compressed air. This can already lead to a superficial predrying.

Filtered air 1 It is designed in accordance with the technical characteristics of the pipeline to be treated compressor 2 compressed. The air is optionally pre-dried before use. If necessary, traces of oil from the air can also be eliminated. For the said predrying, any desired methods which ensure the achievement of the desired degree of drying can be used, for example chemical processes (use of desiccants in the form of flow-through particle beds) or physical processes (condensation, compression and relaxation).

The air is then optionally in a heating device 3 , which is suitably operated with electrical or combustion energy, heated and in the emptied drinking water pipe 5 initiated. If necessary, pre-drying of the pipeline with unheated but dried air has already taken place, in which free water and liquid films have been removed from moist surfaces.

About a metering device 4 between the heating device 3 and the drinking water line to be treated 5 , which no liquid column or no stagnant or running water contains, is arranged, optionally a microbiologically active gas can be metered.

After leaving the drinking water line, the air and / or air / gas mixture is analyzed by passing the gas stream through an analytical station 6 to a gas outlet 7 is directed. In the analytical station, the relative humidity of the exiting gas flow is measured continuously or intermittently. The endpoint of the treatment is displayed when a previously set limit value for the relative humidity of the gas flow is exceeded. Furthermore, the concentrations of the microbiologically active gases can also be measured here.

After drying, the system is rinsed over the same accesses over which the drying took place. For this purpose, the inlet and outlet of the system is possibly closed briefly, and the rinse solution is preferably pumped for sustained action in a circle. As a parameter for the fact that the rinsing process can be stopped, it can serve to establish that the turbidity of the rinsing solution does not rise any further or a fresh solution for rinsing no longer becomes cloudy

The above based on the technological scheme of 1 The explained procedure can be modified in many ways. Thus, the flow direction of the air and / or gas stream and / or the rinse solution can be varied in various ways in adaptation to the special conditions of the treated system. It may correspond to the direction of the normal flow direction of the water in the plant, or be chosen counter to this direction of flow, or it may be varied or pulsed during the drying and / or rinsing step. The rinse solution may be recycled and a rinse solution containing disinfecting and / or delaminating additives may also be used. The drying and / or rinsing steps can be carried out several times.

The flow rate of the air and gas streams can be varied to achieve optimal drying. Since the process is carried out on anhydrous pipes, the gas does not have to be forced into a water column, i. the promotion of the air and / or gas flow does not have to be carried out as compressed air delivery, but the air and / or gas flow can also be conveyed by suction through the system, e.g. by suction on the outlet side of an air and / or gas stream, which was sucked at its inlet side into the pipeline system by a heater and thereby heated.

If the anhydrous plant, such as a pipeline, connected to a suction pump, this can also be used so that, for example, for predrying a pipe in this a more or less strong negative pressure is generated, which enhances the drying effect.

If a disinfecting gas is added to the air and / or gas stream, e.g. in a final stage of treatment, after extensive drying has already been achieved, the effect of the disinfecting gas additive on the biofilms or biofilm residues can be prolonged and intensified by slowing down the delivery of the air and gas streams or by intermittently stopping them and the disinfecting gas in a static atmosphere.

The method according to the invention can be used particularly advantageously for cleaning and disinfecting piping systems in larger buildings in which many people have to be supplied with water, e.g. in hospitals, housing estates, old people's pensions, hotels and other accommodation facilities and rental complexes. For example, the treatment may be overnight if the water requirement is low. In addition, since a significant amount of air cleaning can be done, it reduces the risk of unwanted human exposure to the treated object with irritant or harmful substances. In such large objects, the treatment can be advantageously carried out in stages by successively treating different sections of a pipeline system, for example certain pipeline sections or floors of an object. Of course, it is also not excluded, the inventive method also on a smaller scale, e.g. in the rehabilitation of the pipeline network of a single-family dwelling.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 3244443 A1 [0017]
• DE 4428027 A1 [0017]
• DE 8502327 U [0018]
• DE 20201782 U1 [0018]
• DE 19641629 A1 [0018]
• DE 102008056522 A1 [0018]

Claims (9)

 Process for the removal of deposits of microbial origin from installations for the provision and supply of drinking water and process water, in particular for the removal of contact surfaces of water-bearing networks, pipelines and subsections thereof and biofilms formed by flow-through containers, in which one The water is removed from the plant to be cleaned, or from sections of this plant to be cleaned, - Passing an air or gas flow past the pads to dry them too much to make them removable, and - The at least partially dried pads then rinsed with a rinsing fluid from the treated system. Method according to one of claims 1, wherein a preheated air and / or gas stream is supplied. Method according to one of claims 1 or 2, wherein one or more disinfecting, water-binding or sterilizing acting gases can be added to the air and / or gas stream prior to its introduction into the plant to be treated. Method according to one of claims 1 to 3, wherein the moisture content and / or the content of metered gases in the emerging from the treating plant air and / or gas flow is analytically monitored. Method according to one of claims 1 to 4, wherein after drying with the air and / or gas stream, the dried deposits are rinsed with drinking water or a suitable rinse solution from the treated plant. Method according to one of claims 1 to 5, wherein the flow direction of the gas and / or air flow and / or the rinsing solution in the direction of the normal flow direction of the water in the plant or against this direction of flow is selected or varies during the drying and / or rinsing step becomes. Method according to one of claims 1 to 6, wherein the rinsing solution is recycled. Method according to one of claims 1 to 7, wherein a rinsing solution is used which contains disinfecting and / or delamination-releasing additives. Method according to one of claims 1 to 8, wherein the drying and / or rinsing steps are performed several times.

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