FR2688524A1 - NON-SLIP COATING AND PROCESS FOR OBTAINING SAME. - Google Patents

Abstract

The invention relates to an anti-slip coating having spherically shaped asperities (4) on its surface. These asperities may in particular consist of balls, made of glass for example, fixed to the surface of the coating. Application: non-slip floor coverings for pedestrians.

Description

ANTI-SLIP COATING AND
ITS PROCESS FOR OBTAINING
The present invention relates to a non-slip coating and its production process.

 It applies in particular to floor coverings to which it is necessary to ensure a non-slip power for pedestrians, resistant to wear, without altering their colors, their brightness, their shades or other characteristic properties for - reasons of safety, hygiene or economy as in the case for example of signs on the ground or luminescent coatings intended to be seen in the event of darkness.

 The non-slip coatings already known are generally obtained by powdering quartz, silica or corundum. These materials, of milky yellow or black tint alter the colors, the luminosity and the nuances of these coatings, seriously jeopardize, in certain cases, the safety brought in particular by coatings of signaling on the ground or luminescent coatings.

 Furthermore, these angular and protruding materials add two other disadvantages to these coatings. On the one hand, they easily catch all kinds of impurities or dust and as a result, the coatings get dirty very quickly while being very difficult to clean or decontaminate. On the other hand, they deteriorate the elements which pass in contact with them, shoe soles for example, they can even in certain cases cause injuries.

Fouling also contributes to altering the colors and the luminosity of the coating and prevents more diverse applications requiring given hygienic qualities. Likewise, the risk of injury from these coatings limits their use.

 Finally, the maintenance of a minimum of qualities of these coatings is very expensive and therefore cannot be ensured on any occasion, in particular in the case for example where the coating surfaces become large.

 The object of the invention is to overcome the aforementioned drawbacks.

 To this end, the subject of the invention is a non-slip coating, characterized in that it has roughness having a spherical shape on its surface.

 The invention also relates to a process for obtaining the above-mentioned coating.

 The main advantages of the invention are that it makes it possible to obtain non-slip coatings, easy to clean and decontaminate, therefore offering very good hygienic conditions, not taking moisture, not injuring and not deteriorating. not the shoe soles, which it allows, in one embodiment with glass, to obtain non-slip wear-resistant coatings, the colors or brightness of which do not deteriorate, finally that is economical and easy to implement.

Other characteristics and advantages of the invention will become apparent from the following description given with reference to the appended drawings which represent:
- Figure 1a, a non-slip coating according to the prior art;
- Figure 1b, a possible example of a non-slip coating according to the invention;
- Figures 2a and 2b, an example of the use of non-slip coating;
- Figures 3a and 3b, possible concentrations of beads attached to coatings according to the invention;
- Figures 4a, 4b, 4c and 4d, a possible method of obtaining a coating according to the invention;
- Figures 5a, 5b and 5c, a variant of the above method.

 Figure la shows a non-slip coating 1 disposed on a support 2 produced according to the prior art. On its surface, angular and projecting asperities 3, elements of quartz, silica or corundum for example, are polymerized with the binder of the coating, so as to remain fixed to its surface. These sharp edges 3, hook the sole of a shoe for example and thus prevent people from slipping and falling in particular. These elements 3 are effective in achieving this result, but provide the coating with all of the aforementioned drawbacks.

 Figure I b shows an example of a non-slip coating according to the invention. The coating 1, deposited on the support 2, is covered with asperities 4 having a spherical shape. These asperities can consist, for example, of balls fixed to the coating.

These balls can for example be made of glass. Generally, balls, in particular in glass, are placed on coatings to enhance the luminosity of the latter. In the case of highway signaling coatings on the ground, for example, the glass balls reflect the light rays from the headlights of the vehicles, thereby enhancing the visibility, at night, of these signals. However, the quantity of these balls is limited, their rate being less than approximately 5% of the surface, because far from preventing the skidding of the vehicles, they favor it.

 Contrary to what these results suggest, the depositor has carried out experiments and calculations showing that glass beads1 in particular, fixed in large quantities to a floor covering, provide this coating with very good anti-slip power, particularly for pedestrians. The performances obtained are as good, or even better than those allowed by a non-slip coating of the type of that of FIG.

 Through his experiments and his calculations, the applicant has confirmed that the results obtained can be different depending on whether a dynamic or static coefficient of friction is involved.

 In the case of a pedestrian moving, even when running, as illustrated in FIG. 2a, the coefficient of friction in play between the sole 5 of his shoe 6 and the covering 1 is the coefficient of static friction. When the coating 1 is a non-slip coating according to the invention, covered for example with glass beads, the coefficient of static friction between them and the sole 5 is very much higher than a dynamic coefficient of friction which would be in play for example between these and the tires of a motor car launched at high speed, and therefore provides very good anti-skid performance.

 FIG. 2b illustrates an additional effect of the asperities 4 in the form of a ball of the coating 1 according to the invention. This effect reinforces the anti-slip power of the coating 1. These roughnesses 4, if they consist in particular of glass beads, become embedded in the sole 5 less hard than the roughness 4, without, however, that these deteriorate the sole 5. The numerous asperities embedded in the sole 5 make sliding between the latter and the covering 1 even more difficult.

 The example of FIG. 2a shows a shoe sole in contact with the non-slip coating 1. However, this sole 5 can be replaced by any other element, the results obtained in terms of the anti-slip power being a function of the coefficient of static friction of this element with the contact surface of the asperities 4 in the form of a ball.

 FIG. 3a specifies a possible form for these asperities 4.

This figure constitutes a sectional view and an enlargement at the surface of the non-slip coating 1 according to the invention. Balls 4, made of glass for example, are fixed on the coating 1. For this, the coating 1 consisting of a binder and a filler, the balls 4 can be covered with a film promoting their fixing to the binder, the film being a bridging agent for example, then placed on the binder before polymerization thereof. The phenomenon of capillarity 7 softens the angles between the balls 4 and the binder of the coating 1. The density of the balls 4 must be sufficient to allow good anti-slip power to be obtained. The surface of the coating 1 can for example be completely saturated with balls 4 as shown in FIG. 3b.

 These balls 4 can be made of glass, translucent or transparent. In these latter cases, not only is the coating 1 non-slip, but its colors, its luminosity, its nuances are not altered. It is also very easy to clean or decontaminate it because the glass beads do not catch dirt or microbes, it is also very resistant to wear.

 Figures 4a, 4b, 4c and 4d show a process for obtaining the coating according to the invention.

 Figures 4a, 4b and 4c illustrate the first step of the above process.

 FIG. 4a shows a binder 41, containing at least one base and one hardener, before polymerization, deposited on a support 2.

Balls 4, made of glass for example, are poured onto the binder 41 in refusal.

The effect of the refusal payment, known to those skilled in the art, is illustrated in FIGS. 4b and 4c. Figure 4b shows the balls 4 saturating the binder 41 to the point of overflowing. Figure 4c, enlarging the interior of the circle 42 of Figure 4b shows the arrangement of the balls 4 inside the binder and outside, those outside being said to refuse.

 Once the balls 4 poured in refusal into the binder 41 and once the latter has polymerized, the second step of the process for obtaining, illustrated by FIG. 4d, consists in sweeping the balls 4 said to be refusal. It therefore only remains, on the surface of the coating, that the balls 4 fixed to the binder. These balls, according to the invention, provide the anti-slip power of the coating.

 Figures 5a, 5b and 5c illustrate a variant of the method described above. In this case, the binder contains a filler.

 FIG. 5a shows the pouring of balls 4 into the binder 41 which here already contains a filler 51. This filler 51 can for example be accompanied by pigments, in particular luminescent.

 FIG. 5b illustrates the refusal payment of the balls 4.

 FIG. 5c, enlarging the interior of the circle 52 of FIG. 5b, shows a sectional view of the coating after polymerization of the binder 51 and scanning of the rejection beads. The beads that did not attach to the binder disappeared with this scan. If the balls 4 are in particular translucent or transparent glass, the coating retains its colors, its nuances or other characteristic properties provided by the load 51, such as photo luminescence for example.

 The support 2 on which the binder is deposited, loaded or not, can be a mold intended for the manufacture of tiles, for floor coverings in particular.

 The binder may contain a hardener and a base composed for example of polyurethane, methacrylate or an epoxy resin. The filler can itself consist of glass beads, colored or not, of crushed glass quartz or of silica. All types of pigments can be mixed with the binder and the filler. Additive agents intended to promote the attachment of the elements of the mixture to each other are generally added.

 It is possible to modulate the anti-slip power of the coating by varying the concentration of the balls or spherical roughness on its surface as well as their particle size. The balls may possibly be made of organic material, however in this case it risks making the non-slip power of the coating less resistant to wear.

 Finally, there may be other means of creating spherical asperities on the surface of the coating. Thus, before polymerization, a self-leveling resin can for example be poured into a mold, the bottom of which contains a multitude of small spherical cavities which will create spherical asperities on the surface of the resin after demolding.

Claims (9)

 1 - Non-slip coating, characterized in that it has roughness (4) on its surface having a spherical shape.  2 - Coating according to claim 1, characterized in that the asperities (4) consist of balls fixed to the surface of the coating (1).  3 - Coating according to claim 2 characterized in that the balls (4) are translucent.  4 - Coating according to any one of claims 2 or 3, characterized in that the balls (4) are made of glass.  5 - Coating according to any one of claims 2 to 4, characterized in that it comprises at least one binder (41), the balls (4) being fixed to the binder (41) on the surface of the coating (1).  6 - Coating according to any one of claims 2 to 5, characterized in that its surface is saturated with balls (4).  7 - Coating according to any one of the preceding claims, characterized in that it contains luminescent pigments.  8 - A method for obtaining the coating according to any one of the preceding claims, characterized in that it consists in a first step to refuse pouring balls (4) in a binder (41) containing at least one base and a hardener, before polymerization, and in that it consists in a second step in sweeping from the surface of the binder (41) the balls (4) not fixed to the binder (41) after its polymerization.  9 - Method according to claim 8, characterized in that the binder (41) contains a filler (51).