DE102020116036B4 - Coating composition and use of the same - Google Patents

Abstract

A paint composition comprising:between 1 and 3% by weight glass particles doped with silver ions, the silver content of the glass particles being 0.1 to 10% by weight and the glass particles being composed of borosilicate glass;between 7 and 80% by weight of a binder , wherein the binder contains at least one aliphatic polyurethane or a polyurethane dispersion based on a renewable raw material;between 0.1 and 0.4% by weight of a defoaming agent;and the remainder a solvent,wherein the glass particles have an average particle size of 1 µm to 8 have microns.

Description

The present application is concerned with an improved coating which can be applied to various types of surfaces in the form of a paint and which can reduce the germ load, i.e. the load from bacteria and viruses, on a surface treated with this paint. The aim is therefore to reduce or combat and prevent the germ load on surfaces caused by bacteria, viruses, fungi and yeasts.

Especially in times when the new type of corona virus (CoVid-19) poses a threat to the health of many people, compliance with strict hygiene regulations is essential in order to contain the spread of this virus. This includes wearing a face mask and disinfecting your hands with a disinfectant, such as an isopropanol-based disinfectant.

However, viruses (and other germs such as bacteria and fungi) can accumulate and continue to multiply on surfaces such as doorknobs, window handles, floors, etc., despite hand disinfection. The germ load on these surfaces can only be reduced by disinfecting processes that are repeated at short intervals, for example spraying with a disinfectant containing isopropanol.

It would therefore be advantageous if such components themselves had germ-reducing surfaces that could stop or at least reduce the proliferation of germs and effectively kill germs there - without having to repeatedly disinfect them manually.

The novel coronairus (SARS-CoVi-2) can be detected in particular on steel and plastic surfaces for up to 72 hours, as can be seen in the article "Aersosol and Surface Stability of SARS-CoV-2 as Compared with SARS-CoV-1" (N Engl J Med, 382;16).

In the state of the art the article "Synergistic Antimicrobial Effects of Silver/Transition - metal Combinatorial Treatments" (Nature Scientific reports, 7: 903) is known, which describes a study on the germicidal effect of silver and copper ions. In this study, the minimum concentrations of silver and other transition metal ions used to inhibit gram-positive and gram-negative bacteria were determined. In the case of the bacterium E. coli, for example, these are 0.0024 mg/l for silver ions and 64.1 mg/l for zinc ions. According to the study, in combination with silver and zinc, this application concentration can be drastically reduced again.

Such ions can be used at concentrations that exhibit antibacterial effects at non-toxic concentrations for human keratinocyte cells.

However, with non-metallic surfaces there is a problem of permanently fixing silver ions or zinc ions on the surface - because even if a solution containing silver ions or zinc ions is applied, these could be caused by mechanical friction or contact be removed with moisture. patent document DE 10 2016 003 868 A1 discloses a color-stable, antimicrobial glass powder obtained by partial ion exchange at a temperature of 300 to 350°C and an exchange time of 1 to 120 minutes. It consists of a mixture of: porous glass particles with micropores and macropores made of borosilicate glass continuously foamed by extrusion with an Fe ₂ O ₃ content of less than 0.2% by weight, the glass foam obtained then being dry-milled to an average particle size of 1, 0 to 8.0 microns, and color stabilizers containing 0.1% to 0.2% ammonium ions, and antimicrobial metal ions from dissolved metal salts, where the metal ions can be silver and / or zinc and / or copper ions.

The mode of action of the porous glass particles, which are doped with silver, among other things, is characterized by a rapid release of the antimicrobial silver ions from the open pores of the glass particle surface for the short-term effect and a diffusive release of the silver ions from the glass matrix or from deeper pores of the glass particles for the antimicrobial long-term effect.

This document also discloses the use of the colour-stable, porous antimicrobial glass powder in polymer molding compounds, silicone sealants, plasters, paints or cosmetics at 0.1 to 20% by weight in order to achieve antimicrobial products.

This document also discloses that an antimicrobial effect can be achieved by adding the colour-stable, antimicrobial glass powder to diffusion-open plasters, such as mineral plasters based on lime, gypsum or cement, silicate or silicone resin plasters - also in paints such as silicone resin paints , silicate emulsion paints, pure acrylate paints, acrylate emulsion paints and silicate emulsion paints, as well as interior wall paints such as silicate paints, casein paints or latex paints.

However, using the patent document DE 10 2016 003 868 A1 compositions described only a limited number of surfaces can be treated. Further state of the art is U.S. 8,569,396 B1 , WO 02/087339 A1 , the company publication of BASF SE: Technical Information – Irgaguard® B 5000. Edition 11/2011, the company publication SPRANGER, J. ; SCHILDE, W: Antibacterial spunbonded nonwovens - production and properties. In: 25. Hofer Vliesstofftage, November 2010, the corporate publication of CIBA Corporation: Irgaguard® B6000 Technical Bulletin. Washington, May 2011 and European Chemicals Agency: Substance Infocard - silver zinc zeolite (CAS 130328-20-0).

It is therefore an object of the present invention to expand the field of application of the color-stable antimicrobial glass powder and to enable the application of dimensionally stable antimicrobial glass particles to many different surfaces in order to achieve a long-lasting and consistent antimicrobial effect. For example, antibacterial protective wall paints for surgeries, clinics, waiting rooms, department stores, schools, offices, meeting places and other public and private rooms, etc., antibacterial protective paint for door handles, doors, fittings, etc., antibacterial textile protection for clothing, upholstery, car seats etc. as well as antibacterial protection for plastic surfaces.

This object is achieved by a paint composition as claimed in claim 1 and a use as claimed in claim 7. Further advantageous configurations of the present invention are the subject matter of the dependent claims.

• zwischen 1 und 3 Gewichts-% Glaspartikel, welche mit Silberionen dotiert sind, wobei der Silbergehalt der Glaspartikel 0,1 bis 10 Gewichts-% beträgt und die Glaspartikel aus Borosilicatglas bestehen; zwischen 7 und 80 Gewichts-% eines Bindemittels, wobei das Bindemittel mindestens ein aliphatisches Polyurethan oder eine Polyurethandispersion auf Basis eines nachwachsenden Rohstoffs enthält;
• zwischen 0,1 und 0,4 Gewichts-% eines entschäumenden Agens;
• sowie als Rest ein Lösungsmittel,
• wobei die Glaspartikel eine mittlere Partikelgröße von 1 µm bis 8 µm aufweisen.

A coating composition according to the invention includes:

• between 1 and 3% by weight glass particles which are doped with silver ions, the silver content of the glass particles being 0.1 to 10% by weight and the glass particles consisting of borosilicate glass; between 7 and 80% by weight of a binder, the binder containing at least one aliphatic polyurethane or a polyurethane dispersion based on a renewable raw material;
• between 0.1 and 0.4% by weight of a defoaming agent;
• and the remainder a solvent,
• the glass particles having an average particle size of 1 μm to 8 μm.

As the glass particles, those as described in the patent document are used DE 10 2016 003 868 A1 are described.

The paint contains at least 1% by weight of glass particles, which are doped with silver ions, since a reliable germ-reducing effect can be achieved from this value.

The paint contains a maximum of 3% by weight of glass particles, which are doped with silver ions, since the paint layer would appear milky or cloudy at higher concentrations, which is not desirable or tolerable for all applications. Thus, a discoloration or turbidity of the paint is avoided.

The binder distributes the glass particles homogeneously and provides a matrix for application to surfaces. In addition, the binder ensures that the glass particles adhere to the corresponding surface.
When the surface of the dried paint is exposed to moisture, the silver ions dissolve and develop their germ-inhibiting effect.

The defoaming agent enables the paint to be applied evenly, prevents blistering and ensures adequate wetting of the surface to be treated with the paint. A more homogeneous paint application is thus achieved.

The ions attack the multiple constituents of bacterial cells, including oxygen, sulfur and nitrogen. Due to the multiple influence of silver ions on the different components of bacterial cells, the development of resistance can be reduced to a minimum effects are not to be expected. This creates a broad, reliable and biocidal mode of action. Released silver ions attack the different areas of the bacterium simultaneously (eg proteins, cell wall, cell membrane and DNA/RNA).

Furthermore, the bacterial (and also virological lifespan) is limited as follows: Silver ions penetrate into the interior of the microorganism cells, where they accumulate on the enzymes and prevent their vital transport function. The structural strength of the microorganism cell is impaired by the ions, and the cell membrane is also attacked by the ions, leading to an ionic imbalance and cell death. The resistance and functionality of the bacteria and viruses is severely impaired because the ions change the protective layer of the cell membrane from the bacterial cell wall. The result is the loss of essential cell components, which leads to cell death of the pathogen. The cell division and proliferation of bacteria is also disturbed by the interaction of silver with the DNA/RNA of the microorganisms.

According to the invention, the silver ion content of the glass particles is 0.1-10% by weight, preferably 0.5-5% by weight. This is not toxic, but still sufficient for a germ-inhibiting effect.

The glass particles are preferably additionally doped with zinc ions and/or copper ions. These also have a germ-inhibiting effect.

According to the invention, the glass particles consist of borosilicate glass. This is inexpensive.

The binder comprises an aliphatic polyurethane or a polyurethane dispersion based on a renewable raw material. These are particularly suitable for the applications mentioned above and bind the glass particles with sufficient stability so that they are embedded in a matrix after application.

Preferably, the defoaming agent comprises liquid hydrocarbons, modified fatty compounds, nonionic emulsifiers and hydrophobic silica. This enables a smooth, homogeneous application of the paint, which cannot be disturbed by foam bubbles, etc.

The solvent is preferably water or an organic solvent.

Depending on the application, the paint composition also has one or more of the following groups of substances: biocide, wetting agent, additive influencing the rheological properties, corrosion inhibitor, pigments, fillers, matting agent, pH-modifying agent, stabilizer.

The use of glass particles doped with silver ions in germ-inhibiting protective coatings for metal surfaces, plastic surfaces, wooden surfaces, textiles and/or wall paints has advantages, since these can release biocidal silver ions in a controlled and long-lasting manner. A coat of paint has a biocidal effect of approx. 12 months.

The coating composition can exhibit its effect particularly advantageously when it is applied to a workpiece or to a substrate and forms a firmly adherent layer which is used as a covering or protection.

The formulation of the paint composition was selected in such a way that it contains a system made up of several phases: the glass particles doped with silver ions as an ion depot, additives such as a defoaming agent, and binder particles in the appropriate dispersion medium.

The laws of colloid chemistry apply to the particle components, with the different particles influencing each other and being activated especially with moisture

Stability and effectiveness are achieved when the sum of the surface charge, the electrostatic repulsion energy caused on the particles, and the attraction energy is significantly greater than the thermal energy of the particles.

Otherwise the system can become ineffective or coagulate, ie the particles settle after particle enlargement and the dispersion medium is present as serum above the particles

Especially in polar media (such as water), these particles have a surface charge in the disperse state. In a corresponding composition, this charge is created by dissociation of groups on the surface.

A lacquer composition as described above is preferably used in germ-inhibiting protective lacquers for metal surfaces, plastic surfaces, wooden surfaces, textiles and/or wall paints.

Preferred embodiments of the present invention are described in more detail below.

The first embodiment is a paint composition, particularly for the treatment of plastics. This composition is colorless and transparent. Table 1 shows the composition of a paint composition according to the first embodiment of the present invention: material weight % water 16:92-18:92 Agitan® 232 0.18 POROcide® FCM 616 0.3 Tegowet® KL 245 1.1 Trovoguard® B-K2-04 03 71 1 -3 Borchi Gel® L 75 N 0.5 Alberdingk® U5201 76 Dowanol® DPnB 2

Agitan® 232 from MÜNZING CHEMIE GmbH is a defoamer for aqueous systems and is a combination of liquid hydrocarbons, modified fatty substances, non-ionic emulsifiers and hydrophobic silicic acid.

POROcide® FCM 616 from PORO Additive GmbH is a biocide and a combination of the active ingredients MIT (2-methylisothiazolinone) and CIT (5-chloro-2-methylisothiazolinone) with a special formaldehyde donor system based on TMAD ( tetramethylolacetylenediurea).

Tegowet® KL 245 from Evonik Resource Efficiency GmbH is a siloxane-based substrate wetting additive. This should improve the adhesion of the paint on plastics by reducing the surface tension of the paint and thus improving wetting.

Trovoguard® B-K2-04 03 71 from Trovotech GmbH is a porous, amorphous glass powder doped with silver ions. This glass powder is the actual active ingredient.

Borchi Gel® L 75 N from OMG Borchers GmbH is a rheology additive for aqueous paint systems. This improves the rheological properties and thus the spreadability of the paint.

Alberdingk® U5201 from Alberdingk Boley GmbH is a binder based on an aliphatic polyurethane.

Dowanol® DPnB from Dow Chemical Company is a solvent made from dipropylene glycol n-butyl ether. This solvent shows a high affinity for plastics and resins.

Such a composition is produced, for example, using a disk stirrer (dissolver).

Water is initially taken as the solvent, and Agitan® 232, POROcide® FCM 616 and Tegowet® KL 245 are then added (at a stirrer speed of 10 m/s peripheral speed). This mixture is stirred for 5 minutes.

The following substances are then added with a stirrer, and the mixture is stirred for a further 15 minutes at a stirrer speed of 10 m/s peripheral speed: Borchi Gel® L 75 N, Alberdingk® U5201, Dowanol® DPnB

Then Trovoguard® B-K2-04 03 71 is added and the mixture is stirred slowly for a further 10 minutes.

The dissolver is used in the dispersion or in the manufacture of the products.

The toothed agitator disc can also agitate at a peripheral speed of 10 - 20 m/s.

The higher the peripheral speed, the greater the shear forces, but the temperature rises accordingly. This breaks up the agglomerates into smaller primary particles.

The solids are usually pre-dispersed in an existing solution using a dissolver. During the subsequent dispersion, the accumulations of solids (agglomerate) are broken down.

In this process, the raw materials, which are insoluble, slightly granular solids, must be evenly distributed and completely wetted in the liquid medium of water.

The product is dispersed in the grinding batch.

The manufacturing process is divided into several steps.

When the ingredients are wetted, the air is displaced from the surface by the liquid in the mill base. This process is difficult because the polarity of the fillers and the paint are not similar, e.g. B. in hydrophobic organic

pigments in solvent-based paints, or hydrophilic solids in water-based paints.

Therefore, in the case of the ingredients used in the composition with a polar and non-polar surface, wetting can be supported by additional wetting agents in order later to achieve a sufficiently long storage stability and a long-lasting effect of reducing germs.

In order to completely break down the ingredients, energy must be introduced in the form of shearing forces. This happens during production with the dissolver, whereby the transfer of shearing energy to the particles is influenced by the addition of additives, in this case the defoaming agent. It is very important here that the newly created surfaces are quickly wetted in order to prevent the formation of agglomerates and to have a lasting effect against bacteria and viruses.

In order to stabilize the achieved state of distribution of the dispersed solids, the reagglomeration must be prevented in the long term. By anchoring the dispersing additives to be dosed on the surface of the solids, attractive forces between the uncoated solid surfaces are avoided.

The concentration of ions in the paint is 20 to 100 times lower than the water hazard limit, depending on the concentration of glass particles selected.

This manufacturing method was described in detail for the first embodiment—but it can just as well be used analogously for all other embodiments.

The second embodiment is a paint composition, particularly for the treatment of metal surfaces. This composition is also colorless and transparent.

Table 2 shows the composition of a paint composition according to the second embodiment of the present invention: material weight % water 14:8-16:8 Agitan® 232 0.4 POROcide® FCM 616 0.3 Tegowet® KL 245 1 Trovoguard® B-K2-04 03 71 1-3 Borchi Gel® L 75 N 0.5 Alberdingk® AC 2403 76 Dowanol® DPnB 2 Ascotran® HPB 2

Agitan® 232 from MÜNZING CHEMIE GmbH is a defoamer for aqueous systems and is a combination of liquid hydrocarbons, modified fatty substances, non-ionic emulsifiers and hydrophobic silicic acid.

POROcide® FCM 616 from PORO Additive GmbH is a biocide and a combination of the active ingredients MIT (2-methylisothiazolinone) and CIT (5-chloro-2-methylisothiazolinone) with a special formaldehyde donor system based on TMAD ( tetramethylolacetylenediurea).

Tegowet® KL 245 from Evonik Resource Efficiency GmbH is a siloxane-based substrate wetting additive. This should improve the adhesion of the paint on plastics by reducing the surface tension of the paint and thus improving wetting.

Trovoguard® B-K2-04 03 71 from Trovotech GmbH is a porous, amorphous glass powder doped with silver ions. This glass powder is the actual active ingredient.

Borchi Gel® L 75 N from OMG Borchers GmbH is a rheology additive for aqueous paint systems. This improves the rheological properties and thus the spreadability of the paint.

Alberdingk® AC 2403 from Alberdingk GmbH is a binder based on an aliphatic polyurethane.

Dowanol® DPnB from Dow Chemical Company is a solvent made from dipropylene glycol n-butyl ether. This solvent shows a high affinity for plastics and resins.

Ascotran® HPB from ASCOTEC is a water-soluble corrosion inhibitor for ferrous metals.

The comparative example of the third paint composition is a paint composition particularly suitable for interior paints. This paint composition is particularly abrasion-resistant (according to DIN EN ISO 11998). In addition, this composition has a high hiding power.

Table 3 shows a comparative example of a third paint composition: material weight % water 27:4-29:4 Agitan® 232 0.4 POROcide® FCM 616 0.3 Walocel® XM 30,000 PV 0.2 Borchi® Gel L 75 N 0.3 Borchi® Gel NA 40 1.2 Tronox® CR 826 19 Talc ST30 3.2 Omyacarb® 2 GU 13 Omyacarb® 5 GU 13 Trovoguard® B-K2-04 03 71 1-3 Mowilith® LDM 1871 19

Agitan® 232 from MÜNZING CHEMIE GmbH is a defoamer for aqueous systems and is a combination of liquid hydrocarbons, modified fatty substances, non-ionic emulsifiers and hydrophobic silicic acid.

POROcide® FCM 616 from PORO Additive GmbH is a biocide and a combination of the active ingredients MIT (2-methylisothiazolinone) and CIT (5-chloro-2-methylisothiazolinone) with a special formaldehyde donor system based on TMAD ( tetramethylolacetylenediurea).

Trovoguard® B-K2-04 03 71 from Trovotech GmbH is a porous, amorphous glass powder doped with silver ions. This glass powder is the actual active ingredient.

Walocel® XM 30,000 PV from the Dow Chemical Company is a cellulose ether-based thickener. Thus, a paintable color can be obtained.

Borchi Gel® L75 from OMG Borchers GmbH is a rheology additive for aqueous paint systems. This improves the rheological properties and thus the spreadability of the paint.

Borchi Gel® NA 40 from OMG Borchers GmbH is a wetting and dispersing agent.

Tronox® CR 826 from Tronox is a rutile titanium dioxide pigment. This has a good covering effect, which is important for interior paints.

Talcum ST30 from LUZENAC is a talcum powder (sheet silicate with the chemical composition Mg ₃ [(OH) ₂ | Si ₄ O ₁₀ ].

Omyacarb® 2 GU and Omyacarb® 5 GU from Omya International AG are each calcium carbonate as a fine powder.
Mowilith® LDM 1871 from Celanese Emulsions is a binder.

The fourth embodiment is a coating composition based on renewable raw materials, in particular for the treatment of textiles (upholstery, protective masks, carpets, seats, etc.). This composition is also colorless and transparent and is sprayable (e.g. via a nozzle).

Such a paint is water-dilutable, highly flexible and biodegradable. The fourth embodiment is a sustainable and resource-saving recipe, among other things through the use of plant-based, renewable raw materials based on soy.

There is no change in the character of the fabric on textiles (discoloration, sticking, etc.).

Table 4 shows the composition of a paint composition according to the fourth embodiment of the present invention: material weight % water 81.5-83.5 Agitan® 232 0.4 POROcide® FCM 616 0.3 Salmiak 25% 0.2 Kelzan® AR 1.3 Trovoguard® B-K2-04 03 71 1-3 Alberdingk® CUR 77 13.3

Agitan® 232 from MÜNZING CHEMIE GmbH is a defoamer for aqueous systems and is a combination of liquid hydrocarbons, modified fatty substances, non-ionic emulsifiers and hydrophobic silicic acid. POROcide® FCM 616 from PORO Additive GmbH is a biocide and a combination of the active ingredients MIT (2-methylisothiazolinone) and CIT (5-chloro-2-methylisothiazolinone) with a special formaldehyde donor system based on TMAD ( tetramethylolacetylenediurea).

Salmiak is an ammonia solution in water and is used to adjust the pH value of the paint composition.

Kelzan® AR from Kelco U.S. (Xanthan Gum) is a polysaccharide and is mainly used to thicken and stabilize the paint composition.

Trovoguard® B-K2-04 03 71 from Trovotech GmbH is a porous, amorphous glass powder doped with silver ions. This glass powder is the actual active ingredient.

Alberdingk® CUR 77 from Alberdingk Boley GmbH is a polyurethane dispersion based on renewable raw materials and serves as a binder in the present coating composition.

The fifth embodiment is a lacquer composition, in particular for the treatment of wood surfaces, and is colorless and transparent. The paint has a matt appearance on wood.
Table 5 shows the composition of a paint composition according to the fifth embodiment of the present invention: material weight % Alberdingk® AC 3630 73:1-75:1 Agitan® 232 0.4 Dowanol® DPnB 3 Drewplus® T-4201 0.8 Aquacer® 513 3 Acematt® TS 100 1.5 Tego Wet® KL 245 0.3 Byk® 346 0.3 Tego Glide® 410 0.3 Byk® E 420 0.1 Aquaflow® XLS 530 0.9 Trovoguard® B-K2-04 03 71 1-3 Alberdingk® CUR 77 13.3

Alberdingk® AC 3630 from Alberdingk Boley GmbH is an acrylate copolymer dispersion and serves as a binder.

Agitan® 232 from MÜNZING CHEMIE GmbH is a defoamer for aqueous systems and is a combination of liquid hydrocarbons, modified fatty substances, non-ionic emulsifiers and hydrophobic silicic acid.

Dowanol® DPnB from Dow Chemical Company is a solvent made from dipropylene glycol n-butyl ether. This solvent shows a high affinity for plastics and resins.

Drewplus® T-4201 from Ashland is a defoamer and consists of silicic acid derivatives, mineral oil and esters.

Aquacer® 513 from Byk is a VOC-free wax emulsion based on HDPE to improve surface protection in water-based coatings and printing inks as well as in water-based care products and polishes.

Acematt® TS 100 from Evonik Resource Efficiency GmbH is a matting agent. Tegowet® KL 245 from Evonik Resource Efficiency GmbH is a siloxane-based substrate wetting additive. This should improve the adhesion of the paint on plastics by reducing the surface tension of the paint and thus improving wetting.

Byk® 346 from Byk is a silicone surfactant for aqueous paints with a strong reduction in surface tension.

Tego Glide® 410 from Evonik Resource Efficiency GmbH is a slip and flow additive and contains a polyethersiloxane copolymer.

Byk® E 420 is a liquid rheology additive for aqueous and water-dilutable paint systems to improve anti-sag and anti-settling properties. This is particularly useful for a homogeneous paint finish on a wooden surface.

Ashland's Aquaflow® XLS 530 is a nonionic synthetic rheology modifier.

Trovoguard® B-K2-04 03 71 from Trovotech GmbH is a porous, amorphous glass powder doped with silver ions. This glass powder is the actual active ingredient.

Alberdingk® CUR 77 from Alberdingk Boley GmbH is a polyurethane dispersion based on renewable raw materials and serves as a binder in the present coating composition.

The present invention is not limited to the embodiments described. Rather, a variety of pigments, dyes or other ingredients can be added to modify the properties of the germ-inhibiting paint accordingly.

Claims (7)

Varnish composition, which includes: between 1 and 3% by weight glass particles which are doped with silver ions, the silver content of the glass particles being 0.1 to 10% by weight and the glass particles consisting of borosilicate glass; between 7 and 80% by weight of a binder, the binder containing at least one aliphatic polyurethane or a polyurethane dispersion based on a renewable raw material; between 0.1 and 0.4% by weight of a defoaming agent; and the remainder a solvent, the glass particles having an average particle size of 1 μm to 8 μm. Paint composition according to claim 1 , the silver content of the glass particles being 0.5 - 5% by weight. Paint composition according to claim 1 , wherein the glass particles are additionally doped with zinc ions and/or copper ions. A paint composition according to any one of the preceding claims wherein the defoaming agent comprises liquid hydrocarbons, modified fatty compounds, nonionic emulsifiers and hydrophobic silica. A paint composition as claimed in any one of the preceding claims wherein the solvent is water or an organic solvent. Paint composition according to one of the preceding claims, further comprising one or more of the following groups of substances: biocide, wetting agent, the rheological properties influencing additive, corrosion inhibitor, pigments, fillers, matting agent, pH-modifying agent, stabilizer. Use of glass particles doped with silver ions in a composition according to one of Claims 1 until 6 in germ-inhibiting protective coatings for metal surfaces, plastic surfaces, wooden surfaces, textiles and/or wall paints.