DE102021131879A1 - Concentrate for a cleaning solution e.g. - Google Patents

Abstract

The invention relates i.a. a concentrate (10) for a cleaning liquid (11) circulating in a cleaning system (18, 31) for the removal, in particular for the residue-free removal, of dirt containing oil or lubricants on the surfaces of workpieces (33a, 33b, 33c), wherein the concentrate comprises two different, self-separating phases (12, 13), the first phase (12) comprising a solution with bacterial spores, and the second phase (13) comprising a mixture comprising at least the following components: i) non-ionic surfactants ii) hydrotropes (clarifiers) iii) complexing agents iv) preservatives, the first phase (12) and/or the second phase (13) having at least one membrane lipid, in particular a glycolipid.

Description

The invention initially relates to a concentrate for a cleaning solution.

The concentrate is used to provide a cleaning solution. The cleaning solution provides a means of emulsifying, degreasing and removing oil and/or grease on surfaces. In particular, the invention relates to concentrates, cleaning solutions and methods for producing these cleaning solutions which can remove soiling in the form of oily or lubricant-containing substances and surfaces of materials without residue or essentially without residue. This essentially residue-free removal is carried out using oil-degrading bacteria.

According to an essential aspect of the invention, the concentrate according to the invention is produced as a 2-phase concentrate and used on the basis of bacterial spores and glycolipids in wash basins in a ratio with water, in particular between 1:3 and 1:6.

The concentrate according to the invention contains in particular, inter alia, glycolipids and a mixture of several surfactants in or with a spore solution.

The concentrate and/or the finished cleaning solution can also contain ethoxylates, mixtures of spore solutions, glycolipids and in particular also supramolecular complexes consisting of rhamnolipids, alginates, pyoverdine and water.

State of the art:

Due to the manufacturing process, there are often greases and oils, drilling solutions and other pigment-like dirt on the surface of workpieces. The surfaces must be cleaned, e.g. B. to generate better adhesive properties during further processing.

For this purpose, it is known to provide washbasins in which organic and inorganic solvents are used. Some of these washbasins are operated with oil separators or with oil-degrading bacteria in order to increase the service life of the washing solutions used.

Various synthetic surfactants are added to the washstands. Surfactants contain a hydrophilic (polar) and a hydrophobic (non-polar) part. As a result of this amphiphilic character, they are surface-active in various solvents, especially water. This means they accumulate in the interfaces of the aqueous phase. The surfactant molecules used form monomolecular films at the interfaces, which can have a lasting effect on the properties of the systems.

• • Reduktion der Grenzflächenspannung zwischen Wasser und der angrenzenden Phase
• • Veränderung der Benetzungseigenschaften zwischen Wasser und Feststoffen
• • Ausbildung elektrischer Doppelschichten an den Grenzflächen.

The interfacial adsorption leads to the following effects:

• • Reduction of the interfacial tension between water and the adjacent phase
• • Change in wetting properties between water and solids
• • Formation of electrical double layers at the interfaces.

Washstands, for example, are known in the prior art for cleaning workpieces, such as those offered by the company Biocircle in Gütersloh, among others. In these washbasins, the fats and oils that are brought in are emulsified with surfactants, among other things, or dissolved and washed off with solvents.

Once the workpiece has been cleaned or lifted out, the organic compounds can lead to regreasing from a certain concentration. This is comparable to crockery that is removed from an already heavily soiled dishwashing water and is still covered by a film of grease. After a certain time, the grease absorption capacity of the washing bath is exhausted and a greasy film forms on the water surface. In order to achieve high degreasing quality, it is important to avoid regreasing and re-contamination of the workpiece. This can be remedied by connecting a grease separator to the system or by adding grease and oil-decomposing microorganisms to the washing solution in the washbasin.

A large number of microorganisms are capable of decomposing the washed-off impurities. These include, for example, gram-positive species such as Arthrobacter, Bacillus, Nocardia, gram-negative species such as Flavobacterium, Enterobacter, Escherichia, Pseudomonas and other genera.

Fats and oils (lipids) are broken down in several steps. Hydrocarbon breakdown occurs in the cell. Water-soluble hydrocarbons are absorbed directly through the cell membrane, while water-insoluble ones are attached to the fat-loving cell wall. Surfactants, which are synthesized by the microorganisms, can emulsify the lipid-water mixture. As a result, the phase interface is enlarged and thus the degradation efficiency is increased. The actual breakdown of lipids takes place intracellularly.

The majority of organisms incorporate molecular oxygen into fats and oils via an enzymatically catalyzed oxidation reaction in order to be able to introduce them into their metabolism. For this reason, the decomposition of aliphatic hydrocarbons such as paraffins and aromatic hydrocarbon compounds occurs most effectively in the presence of oxygen. For this reason, these systems are continuously supplied with oxygen. The microorganisms are supplied with oxygen by blowing in air.

The washbasins used in this way work on the principle of a bioreactor. These are operated at a process temperature of > 42 °C to prevent the proliferation of pathogenic germs. In addition, higher temperatures lead to a reduction in the viscosity of oils and fats, accelerate chemical reactions and thus intensify the process.

The washing solution can, for example, be adjusted to a pH of 8.5 that is tolerable for the microorganisms using a phosphoric acid solution. The set pH value also prevents an increase in pathogens in the cleaning bath. At the same time, the phosphoric acid serves as an additional source of phosphorus for the microorganisms used.

The washing or cleaning solution in the prior art must not exceed a specified service life and is then replaced. For this purpose, the solution is brought from the factory of a cleaning solution manufacturer to the washbasin that is usually installed at the place of work. The cleaning liquid contained in the washbasin is disposed of after a predetermined service life has been reached, and the washbasin is filled with a new and fresh cleaning solution.

Object of the invention:

Proceeding from the prior art described, the object of the invention is to specify a way of improving the method used in the prior art.

The invention initially solves this problem with claim 1.

A concentrate for a cleaning solution is proposed. The concentrate consists of two phases.

A first phase comprises a spore solution, where the spore solutions are bacterial spores. A second phase comprises at least one surfactant. The two phases are self-mixing from one another.

In one embodiment of the invention, the two different phases have different PH values. The PH values can be between 6.5 and 9.5.

According to the invention, the concentrate can be bottled at the manufacturer's plant and shipped as a concentrate to the point of use. Only there is it diluted with water and mixed with water to form a cleaning solution.

After dilution with water, the phases are mixed together and can no longer separate from each other.

According to the invention, the concentrate can be diluted with water. The concentrate according to the invention can be diluted with tap water or with demineralized water. Since water can be provided practically anywhere in the world, the invention allows only the concentrate to go to the point of use has to be transported and available water supplies can be used at the place of use, for example at the installation site of the washbasin. Due to the transport as a concentrate, transport costs and transport volume can be reduced compared to the prior art.

The concentrate according to the invention comprises two phases which can be separated from one another. As a result, all components required for the provision of a cleaning solution - with the exception of water - can be safely stored and also transported over long periods of time.

Due to the special ingredients of the concentrate according to the invention or the cleaning solution produced later, dirt can be better removed from the surfaces in the workpiece. Residues can also be better dissolved. Finally, the service life of a cleaning solution or washing solution in a washbasin in a cleaning system is significantly increased with the concentrate according to the invention.

An advantage of the concentrate according to the invention is that the product designed as a 2-phase concentrate remains inactive until the bacteria used, which are present as spores in the high concentrate, are activated. The activation takes place by diluting the concentrate with tap water or with demineralized water, under the influence of temperature, in particular at a temperature of more than 40 degrees Celsius, and with the supply of oxygen. Manufacturing the product as a 2-phase concentrate brings economic and ecological advantages, such as the reduction of storage, transport and handling costs.

Used as a 2-phase concentrate in connection with glycolipids in a closed system, significantly better results are achieved when using a cleaning solution compared to the prior art. This is reflected in an increase in service life, an improvement in cleaning performance and better solubilization of natural and synthetic fats and oils. The improved solubilization leads to better metabolism for the bacteria used, resulting in better results.

Another advantage of the invention is that by adding water to the specially composed nutrient solution, consisting of glycolipids and the inactive spore solution, the metabolism of the bacterial cells can be optimized in such a way that only very little biomass accumulates in the washbasin. The organic waste can be discharged together with the introduced inorganic solids via an integrated filter in the system.

The biomass can, for example, also be sedimented via a separator, in particular a lamella separator, drawn off and dewatered from time to time in a chamber filter press. The filter cake is then disposed of.

The concentrate according to the invention serves in particular to provide a cleaning solution for the essentially residue-free removal of oil- or lubricant-containing contaminants. The formulation residue-free or essentially residue-free allows for the purposes of the invention that solids such. As metal chips, but also flocculated biomass, namely z. B. dead bacteria, accrue, which are separated and disposed of.

The concentrate according to the invention offers considerable advantages with regard to reducing the greasy films in the washing solution and on the workpieces. This is primarily due to the additional increased degreasing performance of the spore solution activated after dilution in combination with the glycolipids. Oily films are avoided in the washbasin itself. The quality of the washing water is maintained over a long period of up to several months. Of course, this requires regular filter maintenance and addition of the washing water lost during washing and regular refilling of the concentrate according to the invention.

The concentrate according to the invention can, for example, comprise rhamnolipids or sophorolipids or a mixture thereof. The two substances mentioned are so-called biosurfactants.

• Definition Sophorolipide:
  • Sophorolipide sind mikrobielle Biotenside der Glykolipidklasse, die aus einem hydrophoben Fettsäureschwanz mit 16 oder 18 Kohlenstoffatomen und einem hydrophilen Kohlenhydratkopf, Sophorose bestehen.
• Definition Rhamnolipide:
  • Rhamnolipide sind Biotenside, die zur Gruppe der Glykolipide gehören und hauptsächlich von Pseudomonas aeruginosa produziert werden (Abdel-Mawgoud et Einleitung 11 al., 2011). Sie setzen sich aus ein (Mono-Rhamnolipide) bis zwei (Di-Rhamnolipide) Rhamnose-Einheiten und ein bis drei β-Hydroxyfettsäuren zusammen. Die βHydroxyfettsäuren können gesättigt oder ungesättigt sein und eine Kettenlänge von 8 bis 16 Kohlenstoffatomen aufweisen.

These are defined in the usual way and specifically as follows:

• Definition of sophorolipids:
  • Sophorolipids are microbial biosurfactants of the glycolipid class consisting of a hydrophobic fatty acid tail with 16 or 18 carbon atoms and a hydrophilic carbohydrate head, sophorose.
• Definition of rhamnolipids:
  • Rhamnolipids are biosurfactants belonging to the glycolipid group and mainly produced by Pseudomonas aeruginosa (Abdel-Mawgoud et Introduction 11 al., 2011). They are composed of one (mono-rhamnolipids) to two (di-rhamnolipids) rhamnose units and one to three β-hydroxy fatty acids. The β-hydroxy fatty acids can be saturated or unsaturated and have a chain length of 8 to 16 carbon atoms.

It is particularly advantageous to add rhamnolipids of the P. aeruginosa JRV-L strain to the products, the cell-free culture fluid of which is able to emulsify various hydrocarbon active substances with an emulsification index E24 in the range of 60-80%. Another distinctive feature of this compound is its ability to emulsify hydrocarbons at different pH values. In this way, different products can be manufactured to suit different types of soiling.

It is particularly advantageous to use the natural polymer alginate contained in the rhamnolipid with a molecular weight of 400-600 kDa, since it has a high emulsifying activity. This allows the natural amphiphilic substances to develop their hydrophilic and hydrophobic properties, which allow them to bind to the interfaces between the liquid phases with different degrees of polarity. This results in optimal emulsification of the fats and oils and/or water and the adhering impurities.

Phospholipids belong to the family of membrane lipids. These are phosphorus-containing lipids. A distinction is made between phosphoglycerides and sphingoglycolipids.

Alternatively or in addition to phospholipids, glycolipids can also be used as membrane lipids. These are phosphorus-free structural lipids.

The glycolipids mentioned as special membrane lipids according to claim 1 include the already mentioned rhamnolipids and sophorolipids and additionally, for example, rhamnoselipids, threhaloselipids and glycosyl diglycerides.

The glycolipids also include sodium surfactin, i.e. the salt of surfactin. This can be obtained commercially, for example, under the trade name Kaneka Surfactin from Kaneka Corporation based in Osaka, Japan.

It is sufficient according to the invention to add these membrane lipids in very small amounts. Even extremely small components of sometimes only 0.01% in the concentrate mean that a significant reduction in surface tension can be achieved.

If various membrane lipids are mentioned in the present patent application and proposed as a component of the concentrate according to the invention, such as phospholipids or glycolipids, in particular rhamnolipids, the invention also includes if a mixture of several of these different membrane lipids is provided as a component in the concentrate.

The concentrate according to the invention comprises a solution with bacterial spores. For this purpose, for example, NobleBio B.V. Bacterial solution commercially available in Oldenzaal in the Netherlands under the item designation UB2 Cultuur number 1200.

The biosurfactant commercially available under the CAS number 2568-33-4 under the registered trademark SOPHOCLEAN® from Impag Import GmbH in Offenbach is mentioned as an example of a sophorolipid which can be used according to the invention.

Alternatively, the substance available under the name SOPHOGREEN under the CAS number 7732-18-5 from the same source, which also belongs to the group of glycolipids, can also be used.

Finally, sodium surfactin (CAS number 302933-83-1/24730-31-2) commercially available under the name KANEKA from Kaneka in Japan can also be used.

Suitable rhamnolipids are also biosurfactants belonging to the group of glycolipids. These can be obtained commercially, for example, under the CAS number 4348-76-9.

It is particularly advantageous to use microbial biosurfactants as cosurfactants, such as glycolipids, for example.

The concentrate according to the invention forms two phases, of which the lower phase makes up the bacterial spore solution and the upper phase forms a surfactant solution.

According to an advantageous embodiment of the invention, the concentrate contains rhamnolipids.

According to an alternative advantageous embodiment of the invention, the concentrate according to the invention comprises sodium surfactin.

According to an alternative advantageous embodiment of the invention, the concentrate according to the invention comprises sophorolipoids.

According to an alternative advantageous embodiment of the invention, the concentrate according to the invention comprises a foam blocker.

Glycolipids, also known as glycolipoids or glycolipids, are phosphorus-free structural lipids or membrane lipids (components of cell membranes) in which one or more mono- or oligosaccharides are glycosidically bound to a lipid molecule. The lipid consists of fatty acids linked to glycerol by ester bonds or to sphingosine by amide bonds. Glycolipids are found in all tissues, but only on the outside of the lipid bilayer.

Anionic surfactants are surfactants that have a negatively charged functional group. Like all surfactants, anionic surfactants are made up of a polar and a non-polar part. An alkyl radical serves as the non-polar part. The polar functional group is -COO ^- (carboxylate), -SO ₃ ^- (sulfonate) or -SO ₄ ^2- (sulfate).

Nonionic surfactants or nonionic surfactants are surfactants that do not contain any dissociable functional groups and therefore do not separate into ions in water. Like any surfactant, nonionic surfactants are made up of a non-polar and a polar part. A fatty alcohol (C ₁₂ -C ₁₈ ) or octyl or nonyl phenols are usually used as the non-polar part. The polar groups here are the hydroxy group and the ether group. These groups are contained in polyethylene glycol or monosaccharides.

Surfactants form association colloids in the form of micelles with the poorly soluble substances. Other substances such as urea or N-methylacetamide break the structure of the water at the hydrophobic sites of the substance to be dissolved. A third possibility is the formation of mixed crystals.

According to claim 1, the concentrate according to the invention also includes hydrotropes. Hydrotropes are agents with which the water solubility of poorly soluble organic compounds can be increased. It is therefore a solubilizer.

Hydrotropes within the meaning of the patent application are also referred to as so-called clarifiers. It is therefore a matter that can remove cloudiness.

The concentrate according to the invention also comprises at least one complexing agent.

Complexing agents are Lewis bases, i. H. chemical compounds or simple anions with lone pairs of electrons that form coordination compounds with metal ions or metal atoms as Lewis acids. For example, they lead to a masking of (undesirable) chemical properties of metal ions.

The concentrate according to claim 1 also comprises one or more defoamers.

Defoamers or antifoam agents are chemical formulations with pronounced surface activity that are suitable for suppressing unwanted foam formation (e.g. in waste water treatment, paper manufacture, during the washing process in washing machines, in painting, in fermentation processes) or to destroy foam that has already formed. A distinction is sometimes made between defoamers (prevent the formation of foam or dissolve foam) and deaerators (bring the air bubbles to the surface more quickly). The similar term anti-foam refers almost exclusively to the field of food technology and basically describes substances or mixtures that have the same effect. For example, mono- and diglycerides of fatty acids and dimethylpolysiloxane can be used.

According to the invention of claim 1, the invention relates to a concentrate for a cleaning liquid.

However, the invention also relates to a cleaning liquid according to claim 4.

Again, based on the prior art described at the outset, the object of the invention is to specify a cleaning liquid which can improve the cleaning method according to the prior art.

The invention solves this problem with the features of claim 4.

To avoid repetition, reference is made to the previous explanations for an understanding of these features and the advantages.

The cleaning liquid according to the invention comprises a concentrate and water. The amount of water is approximately one to ten times the amount of concentrate.

According to a further aspect, the invention relates to a method according to claim 9.

Proceeding from the prior art described at the outset, the object of the invention is to specify a method which is improved over the prior art method.

The invention solves this problem with the features of claim 9.

According to step b), the method according to claim 9 enables the cleaning solution to be produced by diluting the concentrate with water only immediately before it is introduced or when it is introduced (or equally shortly after it is introduced) of the concentrate into a cleaning system, i.e. into a receiving basin for the cleaning liquid the cleaning system. As a result, transport volumes of water components can be avoided. It is sufficient to transport the concentrate to the application site of the cleaning liquid.

To avoid repetition, reference is made to the previous statements.

According to a further aspect, the invention relates to a method according to claim 10. The invention is again based on the object of improving the method from the prior art.

The invention solves this problem with the features of claim 10.

The method according to claim 10 differs from the method according to claim 9 in that the cleaning solution is not achieved by diluting a concentrate with water, but that the two different phases of the concentrate according to the invention according to claim 1 are present separately from one another, housed in separate containers. transported separately to the place of dilution or mixing in the vicinity of the cleaning plant, and only there diluted with water to produce a cleaning solution.

According to a further aspect, the invention relates to a method according to claim 15.

Again, the object of the invention is to improve the prior art method.

The invention solves this problem with the features of claim 15.

To avoid repetition, reference is made to the previous statements.

The invention further relates to a container according to claim 16.

To avoid repetition, reference is made to the previous statements.

Finally, the invention relates to the use of a concentrate according to claim 17.

To avoid repetition, reference is made to the previous statements.

Further advantages of the invention result from the non-cited subclaims and from the following description of the exemplary embodiments illustrated in the drawings and the exemplary embodiments described in the following text.

• 1 in einer teilgeschnittenen schematischen Ansicht ein erstes Ausführungsbeispiel eines Gebindes befüllt mit einem ersten Ausführungsbeispiel eines Konzentrats gemäß der Erfindung, das zwei Phasen aufweist,
• 2 ein Ausführungsbeispiel einer erfindungsgemäßen Reinigungslösung in einem von einem Waschtisch bereitgestellten Becken, und
• 3 ein Ausführungsbeispiel einer zu dem Waschtisch der 2 alternativen Reinigungsanlage.

In the drawings show:

• 1 in a partially sectional schematic view a first embodiment of a container filled with a first embodiment of a concentrate according to the invention, which has two phases,
• 2 an exemplary embodiment of a cleaning solution according to the invention in a basin provided by a washbasin, and
• 3 an embodiment to the vanity of 2 alternative cleaning system.

Exemplary embodiments of the invention are described by way of example in the following description of the figures, also with reference to the drawings. For the sake of clarity - even if different exemplary embodiments are concerned - the same or comparable parts or elements or areas are denoted by the same reference symbols, sometimes with the addition of lowercase letters.

Features that are only described in relation to one exemplary embodiment can also be provided in any other exemplary embodiment of the invention within the scope of the invention. Such modified exemplary embodiments are included in the invention, even if they are not shown in the drawings.

All disclosed features are essential to the invention. The disclosure of the application also includes the content of the disclosure of the associated priority documents (copy of the previous application) as well as the publications cited and the devices of the prior art described, also for the purpose of combining individual or several features of these documents into one or more Claims of the present application to include.

An embodiment of a concentrate according to the invention is in 1 denoted by the reference numeral 10. The concentrate is intended to be diluted with water, in a ratio of 1 to 10, advantageously in a ratio of 1 to 6 to 1 to 3, to form a cleaning liquid 11, as in 2 is shown.

The starting point is the concentrate 10 according to 1 , which has two separate phases 12 and 13. The first phase 12 is separated from the second phase 13 by a separating layer 14 .

The first phase 12, the bottom floating phase, comprises a bacterial spore solution. The upper phase 13 comprises a mixture of surfactants. A thin separating layer 14 can form in the course of the self-separation of the two phases 12, 13 from one another.

1 shows an embodiment of a container according to the invention in the form of a canister 15. An outlet 16 via a conventional canister, which can be closed by a cover 37, is indicated. Advantageously, the canister 15 is not completely full, but a certain gap of air 36 remains after filling.

The concentrate 10 according to the invention can be used in a vanity 18 according to 2 are used, and are placed there in a basin 17 for receiving a cleaning solution 11. Cleaning solution 11 includes water and concentrate 10.

The vanity 18 comprises a pump 19, indicated only schematically, e.g. B. a circulation pump that can ensure circulation of the cleaning liquid. The circulation pump 19 comprises a suction side 20 and a pump outlet 21.

A filter element 28 is advantageously arranged on the suction side 20 .

The pump outlet has a section through which the cleaning liquid flows out again into the basin 17 so that circulation is achieved.

The pump 19 can supply the cleaning liquid to a hand basin 25 via a further line section 22 . A feed 23 and additionally or alternatively a brush feed 24 are indicated for this purpose.

Only schematically indicates the 2 a kind of Y-switch on the output side of the pump 19. Of course, other arrangements can also be made in order, on the one hand, to achieve a circulation of the cleaning liquid 11 in the basin 17 and, on the other hand, to convey cleaning liquid to the hand basin 25 .

The vanity 18 according to 2 has a hand basin 25, in which to be cleaned workpieces 33 with oily soiling on the surface can be introduced. Cleaning liquid 11, indicated by the drops 27c and 27d, can be supplied to the workpiece 33 manually with the aid of the supply 23 or brush supply 24. The cleaning liquid can wash the surface of the workpiece or remove dirt. The dirt is fed to an outlet 39 of the hand basin 25 and passes through a solids filter 26 for coarse particles, e.g. B. for metal chips. The cleaning liquid, indicated by the drops 27a, 27b, can drip back into the basin 17 from the filter 26.

The cleaning system 18 according to 2 also includes a heating element 29 to temper the cleaning liquid 11, preferably to a temperature above 42 °. On the one hand, this keeps the bacteria in an activated state. On the other hand, unwanted germs are eliminated.

Finally, an air supply 30 is indicated, which supplies the cleaning liquid 11 within the basin 17 with oxygen.

On the line 22, a valve 38 is indicated, the z. B. can be actuated manually or automatically.

An alternative of a cleaning system 31 is in 3 shown: There the basin 17, in which the cleaning liquid 11 is located, is traversed by a transport device 34. The transport device 34 can include a receiving device 32 in which a large number of workpieces 33a, 33b, 33c can be accommodated. The loading of the transport device 34 with workpieces 33a, 33b, 33c can take place, for example, at a loading station 41 that is only indicated. The transport device 34 can then move through the basin 17, with the workpieces 33a, 33b, 33c being wetted with cleaning liquid. The receiving device 32 can be designed, for example, as a lattice box in order to allow the cleaning liquid to pass through.

After the basin 17 with the cleaning liquid 11 has passed through, the receiving device 32 can be unloaded from the cleaned workpieces in the region of an unloading station 42 . The transport device 34 can be moved along a transport path 43 .

The cleaning system 31 according to 3 has a heater 29, a pump 19 and an air supply 30.

Examples:

• a) Die Sporenlösung wird unter Rühren, max. 30 Umdrehungen pro Minute, einem Rührwerkskessel zugeben. Während des gesamten Herstellungsprozess werden unter ständigem Rühren die folgenden Zuschlagstoffe zugegeben.
• b) Das Glycolipid (Rhamnolipid; und/oder Surfactin; und/oder Sophorolipoide) wird zugegeben.
• c) Ein erstes Tensid Alkohol - Ethoxylat C10 4 EO wird zugegeben.
• d) Ein zweites Tensid Alkohol - Ethoxylat C10 5,5 EO wird zugeben.
• e) Ein Hydrotrop Alkyl Amide thoxylat C12 - C14 wird zugegeben.
• f) Der Komplexbildner bestehend aus Glutaminsäure, N,N-Diessigsäure, Tetranatriumsalz wird zugegeben.
• g) Das Konservierungsmittel, 2-Phenoxyethanol, „-n-Butylbenzo[d]isothiazol-3-on, N-(3Aminopropyl)-N-dodecylpropan-1,3-diamin wird zugegeben.
• h) Der PH-Wert wird mit Citronensäure oder Phosphorsäure auf einen PH-Wert zwischen 8-8,5 eingestellt.
• i) Nach Einstellung des PH-Werts wird ca. 20 Minuten weiter gerührt.
• j) Unter ständigem Rühren wird das Konzentrat in die entsprechenden Gebinde, zum Beispiel in ein 20 Liter-Gebinde, abgefüllt.
• k) Innerhalb von ca. 30 Minuten haben sich die 2 Phasen gebildet.
• l) Das so erhaltene Konzentrat wird - um eine Reinigungslösung zu erhalten - im Verhältnis 1:4; 1:5; oder je nach Verschmutzung zwischen 1:3 - 1:6 mit Wasser verdünnt.

The following is an exemplary method for producing an embodiment of a stable two-phase concentrate according to the invention:

• a) The spore solution is added to a stirred tank with stirring at a maximum of 30 revolutions per minute. During the entire manufacturing process, the following additives are added with constant stirring.
• b) The glycolipid (rhamnolipid; and/or surfactin; and/or sophorolipids) is added.
• c) A first surfactant alcohol - ethoxylate C10 4 EO is added.
• d) A second surfactant alcohol - ethoxylate C10 5.5 EO is added.
• e) A hydrotrope alkyl amide ethoxylate C12 - C14 is added.
• f) The complexing agent consisting of glutamic acid, N,N-diacetic acid, tetrasodium salt is added.
• g) The preservative, 2-phenoxyethanol, N-butylbenzo[d]isothiazol-3-one, N-(3aminopropyl)-N-dodecylpropane-1,3-diamine is added.
• h) The pH is adjusted to a pH between 8-8.5 with citric acid or phosphoric acid.
• i) After the pH has been adjusted, stirring is continued for about 20 minutes.
• j) The concentrate is filled into the appropriate container, for example a 20 liter container, while stirring constantly.
• k) The 2 phases have formed within approx. 30 minutes.
• l) The concentrate thus obtained is - to obtain a cleaning solution - in the ratio 1:4; 1:5; or diluted with water between 1:3 - 1:6, depending on how dirty it is.

According to a variant, the preparation process is carried out at room temperature.

• Ein erster Bestandteil kann von einem Rhamnolipid, oder von Surfactin, oder von Sophorolipid bereitgestellt werden.
  1. 1. Alternative:
• Rhamnolipide können die Oberflächenspannung von Wasser von 72 mN/m auf Werte unter 30 und die Grenzflächenspannung von Wasser/Ol-Systemen von 43 mN/m auf Werte < 1 mN/m reduzieren. Rhamnolipide können in dem erfindungsgemäßen Konzentrat in einer Konzentration von < 1% eingesetzt werden.
  • 2. Alternative:
• Surfactin ist ein cyclisches Lipopeptid, bestehend aus sieben Aminosäuren und verschiedenen B-Hydroxysauren (C13-CI5; Hauptkomponente: 3-Hydroxy-13- methyl-rnyristinsäure). Surfactin erniedrigt bei einem Wert von 25 mg/l die Oberflächenspannung von Wasser von 72 mN/m auf 27 mN/m und die Grenzflächenspannung im System von Wasser/n-Hexadeean von 43 mN/m auf unter < 1 mN/m. Bei einer Ausführungsform der Erfindung kann das Surfactin mit einer Konzentration von < 1 % in dem Konzentrat zum Einsatz kommen.

• 3. Alternative:
  • Sophorolipoide sind Gärungsprodukte von Glucose und Rapsöl-Fettsäuremethylester mit Hefe.

In the first exemplary embodiment of a method according to the invention, described below, for the production of an exemplary embodiment of a concentrate according to the invention, the concentrate according to the invention comprises at least eight components:

• A first component can be provided by a rhamnolipid, or by surfactin, or by sophorolipid.
  1. 1st alternative:
• Rhamnolipids can reduce the surface tension of water from 72 mN/m to values below 30 and the interfacial tension of water/oil systems from 43 mN/m to values < 1 mN/m. Rhamnolipids can be used in the concentrate according to the invention in a concentration of <1%.
  • 2nd alternative:
• Surfactin is a cyclic lipopeptide consisting of seven amino acids and various B-hydroxy acids (C13-CI5; main component: 3-hydroxy-13-methyl-myristic acid). At a value of 25 mg/l, surfactin reduces the surface tension of water from 72 mN/m to 27 mN/m and the interfacial tension in the water/n-hexadecane system from 43 mN/m to below < 1 mN/m. In one embodiment of the invention, the surfactin can be used with a concentration of <1% in the concentrate.

• 3rd alternative:
  • Sophorolipoids are fermentation products of glucose and rapeseed oil fatty acid methyl ester with yeast.

The second component can be provided by a surfactant alcohol - ethoxylate C10 4 EO in a concentration of> 5%.

The third component includes a surfactant alcohol - ethoxylate C10 4.5 EO in a concentration> 10.0%.

The fourth component comprises a hydrotrope alkyl amide ethoxylate C12 - C14 in a concentration of >5%.

The fifth component includes a complexing agent consisting of glutamic acid, N,N-diacetic acid, tetrasodium salt in a concentration> 20%.

The sixth ingredient includes a preservative, 2-phenoxyethanol, "-n-butyl-benzo[d]isothiazol-3-one, N-(3aminopropyl)-N-dodecylpropane-1,3-diamine at a concentration of <5%.

The seventh component comprises a pH regulating agent such as phosphoric acid, citric acid in a concentration of >2%.

The eighth component comprises a spore solution in a concentration > 40%.

In addition, if foam formation in the washbasin is not desired, it can be provided according to the invention that the concentrate also includes a defoamer, for example based on silicone, in particular in a concentration of less than <1%.

A few further examples of formulations for the production of a concentrate according to the invention are given below as an example: First example of a formulation: UB2 culture number 1200 40.87% Dissolvine GL 47 S 25.28% Berol 360 7.50% Berol 366 12.50% Berol Surfboost AD15 7.50% Parmetol BPX 3.50% Sophoclean 0.05% citric acid 2.80% 100.00% Second embodiment of a recipe: UB2 culture number 1200 40.00% Dissolvine GL 47 S 25.00% Berol 360 7.50% Berol 366 12.50% Berol Surfboost AD15 7.50% Parmetol BPX 3.50% Sophoclean pH regulating agent 1.20% citric acid, lactic acid; phosphoric acid 2.80% 100.00% Third embodiment of a recipe: UB2 culture number 1200 40.87% Dissolvine GL 47 S 25.28% Berol 360 7.50% Berol 366 12.50% Berol Surfboost AD15 7.50% Parmetol BPX 3.50% rhamnolipid 0.05% citric acid 2.80% 100.00% Fourth embodiment of a recipe: UB2 culture number 1200 40.00% Dissolvine GL 47 S 25.00% Berol 360 7.50% Berol 366 12.50% Berol Surfboost AD15 7.50% Parmetol BPX 3.50% sodium surfactin 1.20% citric acid 2.80% 100.00% Fifth exemplary embodiment of a recipe: UB2 culture number 1200 40.00% Dissolvine GL 47 S 25.00% Berol 360 7.50% Berol 366 13.30% Berol Surfboost AD15 7.50% Parmetol BPX 3.50% Sophoclean 0.40% citric acid 2.80% 100.00% Sixth exemplary embodiment of a recipe: UB2 culture number 1200 40.87% Dissolvine GL 47 S 25.28% Berol 360 7.50% Berol 366 12.50% Berol Surfboost AD15 7.50% Parmetol BPX 3.50% Sophoclean 0.05% citric acid 2.80% 100.00% Seventh embodiment of a recipe: UB2 culture number 1200 40.87% Dissolvine GL 47 S 25.28% Berol 360 7.50% Berol 366 12.50% Berol Surfboost AD15 7.50% Parmetol BPX 3.50% Surfactin Sodium 0.05% citric acid 2.80% 100.00% Eighth exemplary embodiment of a recipe: UB2 culture number 1200 40.87% Dissolvine GL 47 S 25.28% Berol 360 5.50% Berol 366 14.50% Berol Surfboost AD15 7.50% Parmetol BPX 3.50% Sophoclean 0.05% citric acid 2.80% 100.00% Ninth exemplary embodiment of a recipe: UB2 culture number 1200 35.87% Dissolvine GL 47 S 30.28% Berol 360 7.50% Berol 366 12.50% Berol Surfboost AD15 7.50% Parmetol BPX 3.50% Sophoclean 0.05% citric acid 2.80% 100.00% Tenth exemplary embodiment of a recipe: UB2 culture number 1200 37.00% Dissolvine GL 47 S 25.00% Berol 360 7.50% Berol 366 15.50% Berol Surfboost AD15 7.50% Parmetol BPX 3.50% Sophoclean pH regulating agent 1.20% citric acid, lactic acid; phosphoric acid 2.80% 100.00% Eleventh exemplary embodiment of a recipe: UB2 culture number 1200 44.87% Dissolvine GL 47 S 23.28% Berol 360 5.50% Berol 366 12.50% Berol Surfboost AD15 7.50% Parmetol BPX 3.50% rhamnolipid 0.05% citric acid 2.80% 100.00% Twelfth exemplary embodiment of a recipe: UB2 culture number 1200 40.00% Dissolvine GL 47 S 25.00% Berol 360 5.50% Berol 366 14.50% Berol Surfboost AD15 7.50% Parmetol BPX 3.50% sodium surfactin 1.20% citric acid 2.80% 100.00% Thirteenth exemplary embodiment of a recipe: UB2 culture number 1200 40.00% Dissolvine GL 47 S 25.00% Berol 360 7.50% Berol 366 15.30% Berol Surfboost AD15 5.50% Parmetol BPX 3.50% Sophoclean 0.40% citric acid 2.80% 100.00% Fourteenth exemplary embodiment of a recipe: UB2 culture number 1200 40.87% Dissolvine GL 47 S 25.28% Berol 360 5.50% Berol 366 16.50% Berol Surfboost AD15 5.50% Parmetol BPX 3.50% rhamnolopids 0.05% citric acid 2.80% 100.00% Fifteenth exemplary embodiment of a recipe: UB2 culture number 1200 40.87% Dissolvine GL 47 S 25.23% Berol 360 7.50% Berol 366 12.50% Berol Surfboost AD15 7.50% Parmetol BPX 3.50% Surfactin Sodium 0.05% Sophoclean 0.05% citric acid 2.80% 100.00% Sixteenth exemplary embodiment of a recipe: UB2 culture number 1200 40.87% Dissolvine GL 47 S 25.28% Berol 360 4.50% Berol 366 14.50% Berol Surfboost AD15 7.50% Parmetol BPX 3.50% Sophoclean 1.05% citric acid 2.80% 100.00%

In the exemplary embodiments given above, the designations Berol 360, Berol 366 and Berol Surfboost AD15 refer to exemplary embodiments for various surfactants.

For this purpose, the following CAS data are given: Berol 360: CAS: 26183-52-8 Alcohol, C10, ethoxylated (≥2.5 - ≤4 EO) Berol 366: CAS: 26183-52-8 Alcohol C10, ethoxylated (>5 - ≤10 EO) Berol Surfoost AD15: Mixture of wetting agents C12-C14 amide ethoxylate

In the above embodiments, the agent Dissolvine is given as an example of a complexing agent.

• Dissolvine GL 47: CAS No: 51981-21-6 L-Glutamic acid, N,N-diacetic acid tetrasodium salt

For this purpose, the following CAS data are given:

• Dissolvine GL 47: CAS No: 51981-21-6 L-Glutamic acid, N,N-diacetic acid tetrasodium salt

• Parmetol BPX: PHENOXYETHANOL, 2-n-Butylbenzo[d]isothiazol-3-on, N-(3-Aminopropyl)-N-dodecylpropan-1,3-diamin

In the above exemplary embodiments, the ingredient Parmetol is also given as an example of a preservative. For this we refer to the following material information:

• Parmetol BPX: PHENOXYETHANOL, 2-n-butylbenzo[d]isothiazol-3-one, N-(3-aminopropyl)-N-dodecylpropane-1,3-diamine

Claims (17)

Concentrate (10) for a cleaning liquid (11) circulating in a cleaning system (18, 31) for removing, in particular for removing without residue, dirt containing oil or lubricants on surfaces of workpieces (33a, 33b, 33c), the concentrate comprises two different, self-separating phases (12, 13), the first phase (12) comprising a solution with bacterial spores, and the second phase (13) comprising a mixture comprising at least the following components: i) nonionic surfactants ii) hydrotropes (clarifiers) iii) complexing agents iv) preservatives, wherein the first phase (12) and/or the second phase (13) has at least one membrane lipid, in particular a glycolipid. concentrate after claim 1 , characterized in that the first phase (12) comprises anionic surfactants. concentrate after claim 1 or 2 , characterized in that the membrane lipid is a glycolipid which comes from the group of the following substances: a) rhamnoselipids or rhamnolipids b) sophorolipids or sophorolipids c) trehalose and other mycolic acid-containing glycolipids d) cellobiose and mannosylerythritol lipids. Cleaning liquid (11) for use in a closed circuit in a cleaning system (18, 31), comprising a concentrate (10), in particular a concentrate according to one of the preceding claims, which contains at least two different phases (12, 13 ) comprises, wherein the first phase (12) comprises a solution with bacterial spores, and further comprising water for diluting the concentrate, wherein the cleaning liquid (11) comprises 1-10 times the amount of water based on the amount of concentrate. cleaning liquid claim 4 , characterized in that the concentrate (10) has at least one membrane lipid, in particular a glycolipid. cleaning liquid claim 5 , characterized in that the concentrate (10) comprises at least the following components: i) nonionic surfactants ii) hydrotropes (clarifiers) iii) complexing agents iv) preservatives. cleaning liquid claim 5 or 6 , characterized in that the concentrate (10) comprises anionic surfactants. Cleaning fluid according to one of Claims 5 until 7 , characterized in that the membrane lipid is a glycolipid which comes from the group of the following substances: a) rhamnoselipids or rhamnolipids b) sophorolipids or sophorolipids c) trehalose and other mycolic acid-containing glycolipids d) cellobiose and mannosylerythritol lipids. Method for providing a cleaning liquid (11) that circulates in a cleaning system (18, 31) for workpieces (33a, 33b, 33c), comprising the following steps: a) providing a concentrate (10) of a cleaning solution (11) which comprises at least two different phases (12, 13) which separate from one another, the first phase (12) comprising a solution with bacterial spores, b) diluting the concentrate (10) with water to form a cleaning solution (11), step b) being carried out immediately before or when the concentrate (10) is introduced into a cleaning system (18, 31). Method for providing a cleaning liquid (11) circulating in a cleaning system (18, 31) for workpieces (33), comprising the following steps: a) providing a cleaning solution (11) from at least two different phases (12, 13) which are separated are housed in separate containers from one another, the first phase comprising a solution containing bacterial spores, and the second phase comprising at least one surfactant, b) diluting the cleaning solution (11) with water, step b) immediately before introducing or when introducing the Concentrate (10) is carried out in a cleaning system (18, 31). procedure after claim 9 or 10 , characterized in that the cleaning solution (11) has at least one membrane lipid, in particular a glycolipid. procedure after claim 10 , characterized in that the membrane lipid is a glycolipid which comes from the group of the following substances: a) rhamnoselipids or rhamnolipids b) sophorolipids or sophorolipids c) trehalose and other mycolic acid-containing glycolipids d) cellobiose and mannosylerythritol lipids. Procedure according to one of claims 9 until 12 , characterized in that the concentrate (10) or the cleaning solution (11) comprises at least the following components: i) nonionic surfactants ii) hydrotropes (clarifiers) iii) complexing agents iv) preservatives. Procedure according to one of claims 9 until 12 , characterized in that the concentrate (10) or the cleaning solution (11) comprises anionic surfactants. Method for cleaning, in particular for residue-free cleaning, of workpieces (33) whose surfaces are afflicted with dirt containing oil or lubricants, comprising the following steps: a) providing a cleaning solution (11) which comprises a solution with bacterial spores and which has at least one membrane lipid, in particular a glycolipid, b) circulating the cleaning solution, c) heating the cleaning solution, d) supplying air and/or oxygen to the cleaning solution. Container (15) with a concentrate (10) of a cleaning liquid (11), in particular a concentrate according to one of Claims 1 until 3 , for removing, in particular for removing without leaving any residue, dirt containing oil or lubricants on the surfaces of workpieces (33), the concentrate comprising two different phases (12, 13) which are self-separating, the first phase (12 ) comprises a solution with bacterial spores, and wherein the second phase (13) comprises a mixture comprising at least the following components: i) nonionic surfactants ii) hydrotropes (clarifiers) iii) complexing agents iv) preservatives. wherein the first phase and/or the second phase has at least one membrane lipid, in particular a glycolipid. Use of a concentrate (10), in particular a concentrate (10) according to one of Claims 1 until 3 , wherein the concentrate comprises two different, self-separating phases (12, 13), wherein the first phase (12) comprises a solution with bacterial spores, and wherein the second phase (13) comprises a mixture containing at least the following components includes: i) nonionic surfactants ii) hydrotropes (clarifiers) iii) complexing agents iv) preservatives. wherein the first phase (12) and / or the second phase (13) at least one membrane lipid, in particular Has glycolipid, as a circulating cleaning liquid for removing, in particular, residue-free dirt containing oil or lubricants on surfaces of workpieces (33).

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