DE2714593A1 - Wear and corrosion resistant coating, esp. for industrial walkways - having abrasive grains or powder embedded in synthetic resin - Google Patents

Abstract

Coating surfaces for protection against wear and corrosion involves applying a synthetic resin coating and then, before this has hardened, abrasive grains or powder, so that a firm bond is obtd. Another synthetic resin coating is applied after the first has hardened and pref. after removing excess abrasive particles. The process can be used for coating all types of surface, esp. industrial walkways, e.g. of wood, stone, steel, bricks, flags, clinker or plastics, and improves the resistance to corrosion by oils, water, cleaning compsns., sunlight and mechanical wear. The abrasive material pref. is SiC and/or alumina and the resin a liquid polyester based on bisphenol or o-phthalic acid and styrene, a liquid epoxy resin or a urethane alkyd resin.

Description

-powders is applied to the resin layer as long as it is

this is still in a soft state. After complete hardening The layer after a few hours is another layer of lacquer on the abrasive applied and immediately after that another layer of abrasive grains is applied or powder applied. This process is repeated several times until one Coating of the desired thickness depending on the requirements for the surface Abrasion, erosion, corrosion resistance, traffic safety, etc., have been achieved is.

Economy and perfection in the coating of industrial floors are some of the salient features of the process according to the invention. Another advantage is the short time required for maintenance and servicing of floor coatings.

The method according to the invention is based on the principle of combination different layers of originally liquid resin mixtures with solids from abrasive grains made of aluminum oxide and silicon carbide as well as powders Abrasives and hard fillers such as natural abrasives. For the same Purpose can be used all kinds of abrasive waste, such as incurred in factories for the production of grinding wheels. Grains are preferred or powder of substances with a hardness on the Mohs scale of more than 8.5, in particular with a hardness between 8.5 and 9.5.

The first layer of synthetic resin (hereinafter also referred to as "lacquer") is applied to the surface to be coated after the same by brushing or spray (cold spray) has been cleaned. Depending on the grain size of the abrasive grains the thickness of the layer is determined by the viscosity of the paint. After applying of the abrasive grains, some of these grains protrude from the first Paint layer out. After the paint layer has completely hardened, the excess Grains are removed by compressed air or brushing, and then another layer of varnish is applied followed by the application of additional abrasive grits. After the complete Hardening will remove the excess grains in turn and then another Paint layer applied. The process is finally carried out by applying a Finished last coat of varnish to protect the layer of abrasive grains. Paint layers and abrasive grain layers are fixed to one another without breaking the continuity connected, whereby an overall layer with a predetermined thickness is formed. Another important point is that a certain grain is halfway from the lower layer of varnish and half is held by the lacquer layer above. Besides that the second and / or the third layer of grains can have a finer grain size so that they fill the gaps between the first applied grains fills out better.

It should be noted that this application method for coating the surface has the advantage over known methods that when the second layer of lacquer and grains is applied, the first layer is already applied is cured.

Another important point is that according to the invention Method obtained layer (about 3 mm thick) no migration and no settling the grain shows at the bottom of the layer. All the layers of varnish and grains are very well welded together. The final layer has a high mechanical resistance and there is a guarantee that continuous porosity will not occur.

These properties are particularly important for floors in commercial establishments and factories in which the floors are subject to severe abrasion and exposure to various Kinds of harsh chemicals are subject to. They must also be used industrially Floors must be resistant to corrosion from cleaning agents that can be used daily after work or on weekends. Quite a number industrial residues must be removed with solvents, thereby removing the flooring material is attacked if the protective layer has pores or is not resistant to it Chemicals is.

The method and means according to the invention fulfill both of the above Conditions, namely those of high chemical resistance and those of absence any porosity. Because the different layers of paint have been applied one after the other are, there are layers of grains connected to one another by layers of lacquer; there is no sedimentation of the grains, and there is a firm connection with practically all types of flooring materials; the application is extraordinary fast and easy.

Preferred embodiments are given below by way of examples the invention explained in more detail. All details in "parts" and "percent" are - if applicable not otherwise stated -Weight information.

Example 1 parts 1) polyester resin (liquid, unsaturated, based on bisphenol)) 8000 2) polyester resin (liquid, based on o-phthalic acid) 1) 1100 parts 3) monomeric styrene 250 4) cellosolve acetate 155 5) paraffin ( 2% solution in styrene) 10 2) 6) Diacetyl peroxide 112 7) Silicon carbide or aluminum oxide powder (grain size smaller than 0.074 mm) 2000 8) Abrasive grains or powder (waste from the manufacture of grinding wheels; grain size from 0.42 to 0, 71 mm, 0.177 to 0.35 mm or smaller than 0.177 mm) 4) 4500 9) Diethylenetriamine (DTA; amine accelerator) 75 1) Liquid polyester resins with a low molecular weight (1000 to 3000) can be used which are produced by esterification of diacids ( saturated or unsaturated) with glycol. They have approximately the following structure: The raw material used can be o-phthalic acid as the dicarboxylic acid and ethylene glycol as the alcohol. Other starting materials, ie, other dicarboxylic acids and glycols, can also be used. The result is o-phthalic acid or bisphenol polyester resins with different chemical properties. It is also possible to use liquid polyester resins which have a viscosity of 400 to 600 cP; these have a varying styrene content (from 28 to 40), they polymerize when heat is supplied or when additives develop molecular heat (heat between molecules as the starting point for the polymerization reaction).

2) Diacetyl peroxide (butanedione, biacetyl), product of Poliquima Ind. Com. S / A, Brazil 3) Products that arise in dust collectors and a grain size less than 0.074 mm.

4) It can contain all kinds of abrasive waste generated in processing of grinding wheels or when cleaning abrasive and dust collectors incurred, used; the waste should be suitably sieved, in order to obtain the specified grain size ranges; a magnetic deposition of iron parts is recommended in cases in which the coatings have a higher Should have corrosion resistance.

Example 2 parts S) 1) Liquid epoxy resin) 135 2) Abrasive powder (from waste; grain size less than 0.074 mm) 233 3) aluminum oxide grains or -powder (waste from the manufacture of grinding wheels; grain size from 0.42 to 0.71 mm, 0.177 to 0.35 mm or smaller than 0.177 mm) 4) 140 -1 Parts 4) Isopropanol 210 5) Butyl Glycol 196 6) Hydroxypropyl Cellulose 10 7) Chromium Oxide Green 37 8) Polyamide 6) (amine value 130 to 160) 148 9) Water 247 10) Additional water (Addition at the moment of application) 450 5) The one used in this example liquid epoxy resin is a condensation polymer made from bisphenol and epichlorohydrin.

The structure of the epoxy resin can be roughly explained by the following structural formula: wherein R is -C6H4-C (CH3) 2-C6H4-O-CH2-CHOH-C112-O- and n is 0 or an integer.

4) See note on example 1 6) The ones used in this example Polyamides are derived from amides of the general structural formula R-CO-NH2 and have viscosities in the range of 600 to 800 cP; they are in this mix with everyone solvents used compatible.

Example 3 parts 1) Linseed oil 64 2) Glycerin 5 3) Pentaerythritol 5 4) Toluylene diisocyanate TDI 26 5) White spirit 25 6) Iron oxide pigment 12 To the To prepare the urethane alkyd resin of this example, the ingredients except the toluene diisocyanate and the solvent in a suitable reaction vessel mixed together and heated to 225 to 0 235 C for 1 to 2 hours to complete To effect alcoholysis. Then be careful at a temperature of 50 to 600C the toluene diisocyanate is added and the mixture is kept at this temperature, until complete implementation has taken place.

At this point, the required amount of solvent is used added, and the product is immediately cooled to room temperature. The product obtained is a urethane alkyd resin which cure at room temperature can. Its structural formula is made up of recurring units of the formula -NH-CO-O- marked.

This urethane alkyd resin varnish can be used immediately before application 260 parts of abrasive grains or powders from waste from the manufacture of grinding wheels mixed and then applied with brushes. But this can also be done that the urethane alkyd resin paint is applied and that immediately over the freshly applied paint the abrasive grains (grain size 0.25 to 0.6 mm or 0.15 to 0.18 mm). The mixture of the present example is particularly suitable for coating ship decks, with only one Layer of abrasive grains is applied between two coats of paint is stored.

Claims (13)

Method for coating surfaces for protection against abrasion and corrosion, characterized in that on the to be protected Surfaces a synthetic resin layer is applied and that then before Curing the layer abrasive grains or powder applied to the layer so that they bond firmly to this layer, and that after hardening a further synthetic resin layer is applied to the first synthetic resin layer. 2. The method according to claim 1, characterized in that before removing excess abrasive grains after applying the further synthetic resin layer will. 3. The method according to claim 1, characterized in that the Abrasive grains or powder have a hardness on the Mohs scale of more than 8.5, preferably from 8.5 to 9.5. 4. The method according to claim 1, characterized in that the Abrasive grains or powder consist of silicon carbide and / or aluminum oxide, which preferably have a grain size of less than 0.074 mm. 5. The method according to claim 1, characterized in that on the Freshly applied varnish layer of abrasive grains or powder as a mixture of different Grain sizes are applied, preferably a mixture of a powder with a grain size of less than 0.074 with powders with a grain size of less applied as 0.177 mm, 0.177 to 0.35 mm or 0.42 to 0.71 mm. 6. The method according to claim 1, characterized in that the Varnish is applied by hand with rollers or brushes. 7. The method according to claim 1, characterized in that the Application of a layer of lacquer and the application of abrasive grains or powders is repeated after the previously applied layer has hardened until the desired total thickness of the coating is obtained. 8. Means for performing the method according to claim 1, characterized characterized in that it is a liquid polyester resin based on bisphenol and / or a liquid polyester resin based on o-phthalic acid and monomeres Contains styrene, cellosolve acetate and a 2 ring solution of paraffin in styrene. 9. Means for performing the method according to claim 1, characterized characterized in that it is a liquid epoxy resin, isopropanol, butyl glycol, hydroxypropyl cellulose, Contains chromium oxide green, polyamide and water. 10. Means for performing the method according to claim 1, characterized characterized as containing a urethane alkyd resin. 11. Means for performing the method according to claim 3, characterized marked that the abrasive grains or Powder a hardness on the Mohs scale of more than 8.5, preferably from 8.5 to 9.5. 12. Means for performing the method according to claim 4, characterized characterized by the fact that it contains abrasive grains or -powder of silicon carbide and / or aluminum oxide, which is preferably have a grain size of less than 0.074 mm. 13. Means for performing the method according to claim 5, characterized characterized by the fact that it contains abrasive grains or - contains powder mixtures of different grain sizes, preferably one Mixture of a powder with a grain size of less than 0.074 mm with a powder with a grain size of less than 0.177 mm, 0.177 to 0.35 mm or 0.42 to 0.71 mm.