BE1020819A3 - COATING WITH HIGH MICROBIAL CONTENT. - Google Patents

Description

COATING WITH HIGH MICRO-PEEL CONTENT Object of the invention

The present invention relates to a method for incorporating a high microparticle content in an organic coating so as to form a composite coating on a moving substrate. In particular, the method involves continuously applying the composite coating to metal strips.

These microparticles may be: generally spherical (microbeads) but may have edges and angular aspects; composed of glass, carbides, nitrides, silicates, and more generally are of non-organic or metallic nature.

In the following description, when we use the term microbeads, it can be generalized to microparticles may deviate somewhat from the spherical shape.

The invention also relates to the product obtained by the process.

State of the art

[0005] Two types of composite coatings are mainly known.

On the one hand, there are coatings in which a second, insoluble phase has been introduced which brings particular properties to the coating. This is for example the case of paintings rich in zinc. These are organic paints in which zinc powders have been introduced which give them a very good resistance to corrosion. This is also the case when we introduce aluminum particles in some paints to give them a metallic appearance. These paints can be applied as conventional paints even in continuous processes.

On the other hand, there are coatings reinforced with glass fibers. A typical case is illustrated by polyester coatings reinforced with glass fibers. The glass fibers are present in large quantities, in the form of woven or non-woven assembly. This second type of coating is characterized by outstanding mechanical properties. On the other hand, these composite coatings are built on substrates in successive layers, which makes them incompatible with continuous deposits.

The incorporation of microbeads in coatings such as paints and varnishes exists for different applications.

A first application consists of coating architectural panels. JP07292849 protects a decorative paint for architectural applications which comprises a layer enriched with glass beads coated with a transparent color layer.

A second application relates to automotive application paints (bodywork, headlights, wheels). Document KR20030082108 describes a car paint composition with metallic shiny appearance. The aluminum and mica particles commonly used to obtain the glossy appearance are replaced by glass beads. The content of beads in the paint does not exceed 5%.

A third application is to increase the abrasion resistance for coatings, especially for floor coverings. EP 296976 discloses a decorative and resistant coating for floors and panels consisting of iridescent epoxy varnish and a load of glass microbeads.

A fourth application relates to surfaces for which the friction is controlled. The glass beads placed on the surface give these surfaces increased friction. JP2003-213896 proposes a bathroom floor paint. The final layer is doped with microbeads.

A fifth application is to give special properties to a substrate, for example increased water resistance, photochromism, resistance to external voltages, porcelain appearance, high thickness, etc. CN101709193 proposes a water-based acrylic paint doped with hollow glass beads to increase its thermal insulation or its watertightness.

In addition to these different applications, the incorporation of glass microbeads improves the general properties of a paint. US3904560 protects a high performance paint containing a mixture of solid and hollow glass beads.

In addition to the fact that the incorporation of glass beads improves the performance of paints and varnishes, it can significantly reduce their production costs because the glass beads, in particular, and non-organic particles and metal, in general, are cheaper than most resins.

The incorporation of microbeads in coatings is described in the literature according to two methods.

The first method consists in mixing glass beads with a resin, a solvent and other additives. This is the most widely used method for architectural and automotive applications. It is also the technique proposed for the application of a coating on metal strips according to the process called "coil coating".

The document WO9716754 of the company 3M describes a manufactured product covered with a surface layer of glass beads and a process for the preparation of this product.

The second method is to project beads into a paint before drying. In some cases, the beads are mixed with the paint and are processed to emerge on the top side of the coating. This is the technique of choice when the balls must produce a surface effect, such as reflectivity, an anti-fouling effect, non-stick, controlled friction. The ultimate goal is to modify an extreme surface property. Thus, the balls are not projected inside the paint layer but only on the surface. This is the so-called "dusting" technique used for road marking.

The document KR1Ó1012876 describes a road marking method of depositing balls by dusting the paint just applied, so as to keep the balls on the surface and thus obtain a high gloss.

In these various processes, the contents of beads in the paint are limited to 5-10% because for higher levels, application difficulties are encountered. In addition, these microbead-doped paints are generally more expensive than non-microbead paints because of the use of additives and additional treatments.

Deposition of the beads in a continuous process increases the reproducibility of the deposit with respect to a discontinuous process. EP1144773 describes a technique for continuously depositing particles in a resin deposited on a metal substrate. Incorporation is by pressure from a roll or carpet. The content of particles in the resin is limited to 3%.

Goals of 11 invention

The invention aims to provide a method for an application not yet described in the state of the art and does not have the disadvantages thereof.

In particular, the invention aims to provide a method for obtaining a composite coating on a substrate, said coating having properties of mechanical strength but also formability, durability, robustness, corrosion resistance, sealing gas, visual appearance, cost, chemical resistance, etc. greatly improved.

Main features of invention

A first aspect of the present invention relates to a method of coating a moving substrate, for example in continuous scrolling, comprising successively: a deposition at least partially continuous of a liquid organic coating on the substrate; an at least partially continuous projection of inorganic or metallic microparticles, in particular microbeads or microparticles of cubic form, with incorporation into the bulk of the organic coating still in the liquid phase, the content of microparticles in the coating being greater than 25% by volume and the size of the microparticles being between 1 to 100 μm.

According to preferred embodiments, the method according to the invention is limited by one or a suitable combination of the following characteristics: the substrate is composed of a metallic material, synthetic material, paper, of mineral origin, or vegetable origin; the microparticles have a generally spherical shape while being able to present edges and angular aspects; the microparticles are composed of glass, carbides, nitrides, silicates, zeolites, ceramics, silica, alumina, talc, graphite, polystyrene, metal or an appropriate mixture of these components; the microparticles have a size of between 5 and 50 μm; the microparticles have a size of between 5 and 15 μm; the microparticles have undergone a preliminary surface treatment giving them high wettability in the liquid phase or preventing the formation of agglomerates of particles and improving their fluidity; the microparticles are surface-treated, before use, by functionalization, to improve their incorporation into the organic coating; the projection is carried out pneumatically, by use of a turbine, electrostatically or mechanically; - In the case where the moving substrate is in a horizontal configuration, the projection is carried out by creating a curtain of particles falling by gravity, the microparticles being introduced into the liquid organic phase and incorporated therein either by sedimentation or by effect of surface tension or wetting; before the deposition of the organic coating on the substrate, the substrate undergoes a cleaning and / or pretreatment phase; after the projection of microparticles, an additional step of drying and / or baking of the coating is carried out.

[0027] A second aspect of the invention relates to the product obtained by the process, namely a coated substrate having an organic coating with inorganic microparticles, such as glass beads, incorporated into the coating mass, characterized in that the content of microparticles in the coating is greater than 25% by volume and in that the size of the microparticles is between 1 to 100 μπι.

A third aspect of the invention relates to the use of the substrate coated as described above, in the form of coated or painted metal sheet in the fields of construction, household appliances and the automotive industry or under form of flooring with high durability.

The inventors have unexpectedly discovered that the process of massive incorporation and continuous microbeads in organic coatings gives them properties superior to those of products of the state of the art.

Among these properties, note a better mechanical strength. The method of the invention makes it possible to obtain a very good resistance of the product to scratching and abrasive wear. The presence of hard microbeads like glass particles added to a softer matrix like a paint is the basis of this property.

The method of the invention also provides a more marked barrier effect of the organic layer due to the presence of microbeads which are gas-tight. This property promotes corrosion resistance.

The product obtained by this process also has a better fire resistance and temperature variations. This is the case when. inert / incombustible particles (in the form of microbeads) are added in large quantities to a combustible organic matrix (paint, varnish, etc.). In addition, if glass beads are used, the glass does not pose a problem of heating and has a coefficient of thermal expansion almost 10 times lower than that of organic compounds. This property decreases internal stresses during process heating cycles, resulting in improved corrosion resistance.

The product of the invention also has a better resistance to chipping. This is the case when softer particles added to a more brittle matrix absorb micro-deformations and reduce the internal stresses responsible for scaling.

The product of the invention may have electrical or thermal conductivity properties in the case where the microbeads are composed of a conductive material such as for example graphite particles or metal in an insulating matrix.

The implementation of the process can significantly reduce the cost of production, the microbeads are much cheaper than the resins.

The replacement of a large portion of the organic coating to be dried and polymerized by a high load of microbeads reduces energy consumption by allowing a fast drying time.

Finally, the ecological footprint is reduced: the glass microbead is a recycling product that partially replaces organic materials from petroleum, the durability of the painted product is improved (advantage in terms of LCA or Life Cycle assessment), the incorporation of a high content of microbeads in the coating reduces the use of solvent and thus directly emissions of volatile organic compounds (VOCs).

Definitions

The substrate

The substrate is preferably metal of the steel or aluminum type. It can also be composed of a synthetic material such as a plastic film, paper such as resin-coated paper forming the resistance layer of laminated floor plates, mineral-originated plate (tiles) or vegetable origin ( agglomerated particles).

The substrate may be of planar shape, such as a strip or a plate. It can also be elongated like a wire or bar.

The coating

Organic coatings include paints and varnishes. The coating material may be synthetic or metallic. The paints include, for example, thermosetting paints such as polyamide epoxies, polyesters, polyurethanes, polyesters and polyurethanes. It is also possible to use thermoplastic paints such as PVC plastisol or PVDF, acrylic resins, generally water-based and epoxy coatings.

The thickness of these coatings is typically 20 to 200 μm.

The coatings regularly comprise several layers (primer, intermediate layer, top coat, etc.) · The method of the invention can be applied to each of these layers or to the entire coating. It can be applied to one or both sides of a generally flat substrate.

The coatings in their use are in the solid state on the substrate but not all are deposited solids. Some coatings are deposited in the solid state, this is the case of electrolytic deposits or from the vapor phase ( PVD for Physical Vapor Deposition). Others are in the liquid state at the time of deposition and are solidified. This is the case of solvent-based or water-based paints. This is also the case for tempered metal coatings such as galvanization. Finally, some coatings are in the solid state and are melted before finally being re-solidified. This is the case of enamels, powder coatings or metal coatings remelted as tin.

The present invention relates to coatings which are in the liquid or pasty state at the time of their deposition on the substrate and before subsequent solidification.

Microbeads

The microspheres or microparticles constituting the solid phase projected in the liquid phase are advantageously composed of glass, ceramic, silica, alumina, carbides, nitrides, silicates, talc, graphite, polystyrene, metal, etc. or an appropriate mixture of these components.

The microbeads have a size of between 1 to 100 μm, preferably 5 to 50 μm, more preferably 5 to 15 μm.

The microbeads may be solid or hollow.

The particle size of the glass microbeads determines the shape and the measurement of the dimensions of the microbeads in a compound. The microbeads advantageously have a distribution such that the ratio standard deviation / average is between 0.3 and 1.

The shape of the balls is generally spherical, while being angular. In the case of UV-curable resins, transparent microbeads will be used.

The ratio between the size of the larger microbeads and the thickness of the liquid coating before the incorporation of the microbeads is advantageously between 0.1 and 1.0.

Advantageously, the microbeads can undergo a surface treatment conferring a high wettability by the liquid phase or a transformation reaction.

Advantageously also, the particles undergo a surface treatment which prevents the formation of agglomerates of particles and improves their fluidity. This treatment, sometimes combined with the insertion of fine particles, is all the more useful when the particles are small.

Description of preferred embodiments of the invention

The process of the invention consists in creating a composite coating comprising at least two phases in a volume ratio ratio close to 1 and homogeneous throughout the coating. This is achieved by injecting a solid second phase in a first phase when the latter is in the liquid state and then causing solidification of the composite liquid phase. The injection is carried out so that the microbeads of the second phase are fully immersed in the first phase.

The performance of the composite coating strongly depends on the rate of composition, that is to say the percentage of second phase present in the composite. We will in most cases want to achieve a strong improvement in the desired performance and we will aim for a high rate of composition.

It is therefore a question of producing a mixture of two phases and of producing this mixture in situ, on a substrate in motion and in a definitive manner. Unlike road marking for example, it is not the deposit system that moves according to the invention but the application target.

To treat the surface of the substrate in an effective and controlled manner, it is most often used lines / continuous chains in which the substrates scroll and undergo the successive steps of known surface treatment. This is the case of paint lines for continuous metal strips, which is commonly called "coil coating" or processing lines for plates. These continuous or semi-continuous equipments offer the reproducible conditions which are required for the application of the invention. Their common feature is that the substrate to be coated is moving relative to fixed application systems.

According to a preferred embodiment, before the step of depositing an organic coating on the substrate, the latter undergoes a cleaning phase and / or pretreatment.

In particular, the massive incorporation of glass beads by mixing in the organic coatings is not obvious to obtain. Indeed, beyond a certain percentage of beads, the viscosity of the bi-phasic liquid increases drastically and makes the coating deposition very difficult to control.

Still according to a preferred embodiment, the incorporation of the glass beads is by the projection technique which does not have the above limitations.

The projection technique applied can be achieved by several means, the purpose being to provide enough energy to the balls so that they penetrate entirely into the organic coating.

The projection system must be able to give the microbeads a speed preferably at least equal to 10 m / s at the output of the projection system, so that, thanks to their kinetic energy, the particles are well fully immersed in the liquid phase. This property also depends on the particle size of the balls and other projection conditions (impact direction, position after the paint station, horizontal or vertical substrate, etc.).

Another projection technique applies to the case where, just after the deposition of the liquid phase, the moving substrate is in a horizontal configuration. In this case, it is possible to create a curtain of particles which fall by gravity, are introduced into the organic phase surface and are incorporated therein either by gravity (sedimentation) or by surface tension effect (wetting by the liquid phase). In this case, the particles are advantageously: of density higher than that of the organic phase; - strongly wetted by the organic phase (after surface treatment of the particles if required).

The projection can also be performed pneumatically, that is to say by transport by means of a gas flow such as air for example, by use of turbine, electrostatically or mechanically, by example via a roller or a blade that carries and presses the microbeads in the liquid organic coating but is not wet by it.

The projection system is chosen according to the shape of the substrate. For a substrate in planar form, such as a moving band, several projection systems operate in parallel and are located in a plane slightly inclined with respect to the direction of movement of the strip at the location of the impact. A particular case is that of a large number of injection systems each projecting a limited band width so as to ensure a high homogeneity of distribution of the microbeads in the liquid phase. For a substrate in elongated form, several projection systems operate in parallel and surround the substrate to be covered.

The incorporation of the microbeads in the organic coating is massive, the content of microbeads in the coating is preferably greater than 25% by volume.

Advantageously, the bead content in the organic coating is preferably between 25 and 50%.

It is known that glass is an inert material, property of the most interesting compared to chemical attacks. On the other hand, this property represents a limitation for their integral insertion into an organic matrix such as paints.

Also, according to a preferred embodiment of the invention, the glass microbeads are surface treated, before use, by functionalization to ensure a more efficient incorporation into the organic coating. The surface treatments include functionalization methods ensuring on one side a strong bond with the glass and terminated on the other side by a radical which strongly binds to the organic matrix. The use of silanes or TiO 2 for functionalization are advantageous options. This solution allows the microspheres to become one with the organic matrix and thereby to reinforce its mechanical properties.

According to another preferred embodiment, after the projection of microbeads, an additional step of drying and / or baking of the coating is carried out.

The coatings thus produced are preferably used in the form of metal sheet coated or painted in the fields of construction (roofing, cladding), household appliances (refrigerator bodies, furnace, etc.) and the industry. automobile.

Also, according to a preferred embodiment of the invention, the coatings are used in the form of flooring with high durability.

EXAMPLE

Projection of glass microbeads in coatings deposited on a moving metal substrate (coil coatinq)

The metal strip moves on rollers through the successive stages of painting: cleaning and surface preparation, deposition and baking of the primer and deposition of the final layer on one or both sides (top coat). The metal strip coated continuously in the final layer of paint still liquid, thickness 30 μπι, microbeads of glass size between 5 and 15 pm, or from 0.15 to 0.5 times the thickness of the paint layer. Once the paint is dried, these microbeads are not visible. The content of glass beads in the coating is of the order of 30-50%. Unreacted microbeads are harvested and recycled. Thus, for example, particles that have not been introduced into the coating are extracted from the working area by suction. They are then separated from the carrier gas by a known filtration technique (cyclone, regeneration filter, etc.). It is thus possible to recycle them and ensure a clean atmosphere in the vicinity of the projection area.

Claims (15)

A method of coating a moving substrate successively comprising: at least partially continuous deposition of a liquid organic coating on the substrate; an at least partially continuous projection of inorganic or metallic microparticles with incorporation into the bulk of the organic coating still in the liquid phase, the content of microparticles in the coating being greater than 25% by volume and the size of the microparticles being between 1 and 100; pm. 2. Method according to claim 1, characterized in that the substrate is composed of a metallic material, synthetic, paper, mineral or vegetable origin. 3. Method according to claim 1, characterized in that the microparticles have a generally spherical shape while being able to present edges and angular aspects. 4. Method according to claim 1, characterized in that the microparticles are composed of glass, carbides, nitrides, silicates, ceramics, silica, alumina, talc, graphite, polystyrene, metal or an appropriate mixture of these components. 5. Process according to claim 1, characterized in that the microparticles have a size of between 5 and 50 μm. 6. Process according to claim 5, characterized in that the microparticles have a size of between 5 and 15 μm. 7. Method according to claim 1, characterized in that the microparticles have undergone a preliminary surface treatment conferring high wettability in the liquid phase or preventing the formation of particle agglomerates and improving their fluidity. 8. Process according to claim 1, characterized in that the microparticles are surface treated before use, by functionalization, to improve their incorporation into the organic coating. 9. The method of claim 1, characterized in that the projection is carried out pneumatically, by use of turbine, electrostatically or mechanically. 10. Method according to claim 1, characterized in that the moving substrate is in a horizontal configuration and the projection is carried out by creating a curtain of particles falling by gravity, the microparticles being introduced into the liquid organic phase and incorporating therein. either by sedimentation or by surface tension or wetting. 11. The method of claim 1, characterized in that, before the deposition of the organic coating on the substrate, the substrate undergoes a cleaning phase and / or pretreatment. 12. The method of claim 1, characterized in that, after the projection of microparticles, an additional step of drying and / or baking of the coating is performed. Coated substrate having an organic coating with inorganic microparticles incorporated in the bulk of the coating, characterized in that the microparticle content in the coating is greater than 25% by volume and in that the size of the microparticles is between 1 to 100 pm. 14. Use of the coated substrate according to claim 13 in the form of coated or painted metal sheet in the fields of construction, household appliances and the automotive industry. 15. Use of the coated substrate according to claim 13 in the form of a floor covering of high durability.