JP2023141152A - transparent anti-slip sheet - Google Patents

Abstract

To provide a transparent anti-slip sheet capable of exhibiting appropriate frictional resistance over a long period of time.SOLUTION: The transparent anti-slip sheet consists of transparent plastic films that allow the applied surface to be seen through in order to be anti-slip effective when the sheet is laid on the application surface, and has a base sheet comprising convex parts with convex surfaces and concave parts with concave surfaces, and an anti-slip material layer fixed to the surface of the base sheet, the anti-slip material layer is composed of a mixture of glass particles with different particle sizes ranging from 100 to 800 μm, the glass particles consist of machining dust, which are waste generated when glass products are processed, and the anti-slip material layer is arranged on the convex parts and concave parts.SELECTED DRAWING: Figure 2

Description

The present invention relates to a transparent anti-slip sheet that exhibits an anti-slip effect when laid on a construction surface.

Currently, such as sidewalks and walking spaces in urban areas, for example, places where the frictional resistance changes suddenly, such as between concourses at stations, asphalt or concrete on road pavements, and ceramic tiles on sidewalks, or near pools and fountains. In areas that are prone to getting wet, it is necessary to take measures because the danger of slippery conditions changes significantly when wet.

In such a case, the inventor of the present application discloses a transparent anti-slip sheet that is laid on the construction surface to exhibit an anti-slip effect, and is made of a plastic film having transparency that allows the construction surface to be seen through. It comprises a base sheet and an anti-slip material layer made of pulverized glass particles and fixed to the surface of the base sheet, the anti-slip material layer being made of glass having different particle sizes ranging from 100 to 800 μm. It is composed of a mixture of particles, and the surface of the anti-slip material layer has an uneven structure due to the difference in particle size of the glass particles. A transparent anti-slip sheet characterized by being made of powder. ' has been disclosed.

The transparent anti-slip sheet has an anti-slip material layer made of crushed glass particles, and the anti-slip material layer is made of a mixture of glass particles having different particle sizes ranging from 100 to 800 μm, preferably from 300 to 400 μm. and its surface has an uneven structure based on the different particle sizes of the glass particles, so it is possible to provide a transparent anti-slip sheet that provides a sense of security to pedestrians due to moderate frictional resistance. In particular, according to the above invention, even in places where the frictional resistance suddenly changes such as the boundary between outdoors and indoors, asphalt of road pavement, concrete and ceramic tile sidewalks, or places that easily get wet with water, slipping can occur due to moisture. It does not increase the ease of use, and has the effect of being self-cleaning so that organic matter is decomposed and dirt does not accumulate.

Although the transparent anti-slip sheet described above has been well received by the market, there is a demand for a longer service life.

Patent No. 5647800

The present invention has been made with attention to the above points, and its object is to provide a transparent anti-slip sheet that can exhibit appropriate frictional resistance over a long period of time.

In order to solve the above problem, the transparent anti-slip sheet of the first aspect is made of plastic films having transparency that allows the construction surface to be seen through, in order to exhibit an anti-slip effect when laid on the construction surface, The surface includes a convex portion having a convex shape and a concave portion having a concave shape, a base sheet including a base sheet, and an anti-slip material layer fixed to the surface of the base sheet, the anti-slip material layer having a size of 100 to 800 μm. It is composed of a mixture of glass particles with different particle sizes in a range, and the glass particles consist of chips, which are waste products produced when processing glass products, and the anti-slip material layer has convex convex parts and concave parts. It is placed in a recess.

Moreover, in the transparent anti-slip sheet of the second aspect, in the first aspect, the anti-slip material layer further has a surface layer having a self-cleaning property that decomposes organic matter.

Moreover, the transparent anti-slip sheet of the third aspect covers the surface of the anti-slip material layer as an inorganic coating layer in the first aspect, and has a self-cleaning surface layer on the inorganic coating layer.

Since the present invention is configured and operates as described above, it is possible to provide a transparent anti-slip sheet that can exhibit appropriate frictional resistance over a long period of time.

FIG. 3 is a plan view of a transparent anti-slip sheet pasted on the construction surface. FIG. 2 is a cross-sectional view of the transparent anti-slip sheet of the first embodiment attached to the construction surface. It is a cross-sectional view of a state in which a transparent anti-slip sheet of a second example is pasted on a construction surface.

A first example will be described below with reference to the illustrated embodiment. The transparent anti-slip sheet 10 of the first embodiment is pasted onto a construction surface 100, which is a floor surface of a concourse such as a station or a floor surface such as asphalt or concrete for road pavement. Note that the construction surface 100 is preferably a flooring material such as ceramic tiles or plastic.

The transparent anti-slip sheet 10 of the first embodiment includes a base sheet 20 and an anti-slip layer 30 disposed on the surface 21 of the base sheet 20. The base sheet 20 is preferably transparent so that the printing sheet 80 attached to the construction surface 100 can be seen through, and transparent plastic films are preferable.

Furthermore, the base sheet 20 is installed on the concrete construction surface 100, but since it will be stepped on by pedestrians' shoes, it is preferable that it has sufficient strength as well as the above-mentioned transparency in consideration of durability. . Such plastic films are preferably made of polyethylene, vinyl chloride, polycarbonate, polypropylene, etc., but are not limited to these. Note that all materials that have the above-mentioned transparency and strength are eligible. Further, the base sheet 20 is preferably made of polyethylene and has a thickness of 500 μm to 1100 μm.

Further, the surface 21 of the base sheet 20 has a convex portion 25 having a convex shape and a concave portion 26 having a concave shape in a cross-sectional view. For example, processing is performed to form unevenness on the surface 21 of the base sheet 20 so that the surface 21 of the base sheet 20 has a convex portion 25 having a convex shape and a concave portion 26 having a concave shape when viewed in cross section. , embossing, extrusion, printing, embossing, and molding are preferred, but are not limited to these.

An anti-slip material layer 30 is arranged on the surface 21. The anti-slip material layer 30 is arranged so as to be applied to the convex portions 25 having a convex shape and the concave portions 26 having a concave shape in a cross-sectional view of the surface 21 . As a result, the anti-slip material layer 30 enters into the recessed portion 26 having a concave shape, and even if the anti-slip material layer 30 disposed on the convex portion 25 peels off due to use, the area between the convex portions 25 is The anti-slip material layer 30 that has entered the concave portion 26 remains and retains its anti-slip function. In particular, since the convex portions 25 having a convex shape and the concave portions 26 having a concave shape in this embodiment are configured to be continuous with each other, the anti-slip material layer 30 may not enter into the concave portions 26 having a concave shape. Therefore, the above-mentioned anti-slip function can be maintained. That is, it can be said that the concave portion 26 having a concave shape is for inserting the anti-slip material layer 30.

The anti-slip material layer 30 can be constituted by a mixture 35 of glass particles having different sizes, that is, particle sizes, in the range of 100 to 800 μm, more preferably in the range of 300 to 500 μm, and a fixing part 40 that fixes the mixture 35. . If the thickness is less than 100 μm, it will not have sufficient anti-slip effect against standard footwear with soles made of synthetic resin or leather, and if it is larger than 800 μm, it will cause non-negligible abrasions on the body of the person who falls. This is because problems such as the occurrence of problems may arise, and within the above range, there is little risk of such problems. Furthermore, although there is a common belief that glass fragments are sharp and dangerous, this danger disappears when the particle size is 800 μm or less, and the advantage of not getting caught in the soles of shoes is maintained when the particle size is 100 μm or more. The most preferred is a mixture of glass particles with different particle sizes in the range of 300 to 500 μm, since glass particles in this range can provide a suitable amount of friction and cause only minor chafing. It is. Further, the glass particle mixture 35 is made of chips that are waste products produced when glass products are processed, and those having the size within the above-mentioned range can be selected and used. In addition, the mixture 35 mainly includes three types of glass particles: soda-lime glass, alkali-free glass, and borosilicate glass, and these can be used. Among the glass particles, those having the maximum diameter d1 are shown as 35a, and the glass particles having the minimum diameter d2 are shown as 35b in FIGS. 2 and 3. Thus, it is preferable that d1 = 500 μm and d2 = 300 μm, and that particles in this range are fixed in a dispersed manner in the fixing part 40 at an appropriate density. Further, there is no particular restriction on the type of glass that can be used as the glass particles, and all types of glass used in window glass, glassware, and other glass products can be used.

The fixing part 40 that fixes the mixture 35 of glass particles with different particle sizes to the surface 21 uses a two-component urethane adhesive, in which the glass particles 35 are mixed in one of the two components, and an application roller is used. The glass particles 35 are coated on the surface of the base sheet 20 by a coating method. The fixing portion 40 is set to have a thickness of approximately 100 to 200 μm so that the glass particles 35b having the minimum diameter d2 are exposed and the glass particles 35a having the maximum diameter d1 can be sufficiently fixed. Note that instead of using a two-component adhesive made of polyurethane or epoxy resin, it is also possible to use, for example, an α-cyanoacrylate adhesive or the like.

Further, the transparent anti-slip sheet 10 of the first embodiment preferably has a printed sheet 80 printed on the back surface 22 of the base sheet 20. Since the transparent anti-slip sheet 10 of the first embodiment having the printed sheet 80 is protected by the base sheet 20, the possibility that the printed portion of the printed sheet 80 will peel off is reduced. Further, an adhesive 90 can be applied to the back surface of the printing sheet 80. This is for pasting on the construction surface 100. Note that it is also possible to apply a luminescent paint to the printed portions of the printing sheet 80. It can also be printed with luminescent ink.

In addition, the transparent anti-slip sheet 12 of the second embodiment further includes a surface layer 60 having a self-cleaning property that decomposes organic matter that falls on it, covering the surface of the anti-slip material layer 30 of the transparent anti-slip sheet 10 of the first embodiment. It is also preferable to have a configuration having the following. Note that the same components as those in the first embodiment are given the same reference numerals, and the explanation thereof may be omitted.

In the transparent anti-slip sheet 12 of the second embodiment, a self-cleaning surface layer 60 can be directly formed on the surface of the anti-slip material layer 30. The self-cleaning surface layer 60 can be formed, for example, by applying a titanium dioxide solution that decomposes organic matter through a photocatalytic reaction.

In addition, since the transparent anti-slip sheet 12 of the second embodiment uses an adhesive containing the above-mentioned synthetic resin as the fixing part 40, the anti-slip material layer is used to prevent the adhesive from being decomposed as an organic substance. 30 may be covered with an inorganic coating layer 70. As the inorganic coating layer 70, for example, one that forms a thin film of 1 μm or less of silica glass (SiO2) by a chemical reaction between perhydropolysiloxane and water, commonly known as glass coating, etc. can be used. . Therefore, the surface of the anti-slip material layer 30 can be further covered with an inorganic coating layer 70, and a surface layer 60 having self-cleaning properties can be provided thereon.

When the transparent anti-slip sheet 10 of the first embodiment is laid on a construction surface such as a floor or road surface and is actually used, all kinds of organic matter from pedestrians will fall on its surface. Therefore, if this is left as it is, the surface of the anti-slip material layer will be covered with them and left to become dirty. Therefore, by using the transparent anti-slip sheet 20 provided with the surface layer 21 having self-cleaning properties, the organic matter will be decomposed into water and carbon dioxide, and the problem of staining will also be solved.

Furthermore, in the transparent anti-slip sheet 10, when the surface 21 of the base sheet 20 is viewed in cross section, an anti-slip material layer 30 is disposed on the convex portions 25 having a convex shape and the concave portions 26 having a concave shape. However, if the transparent anti-slip sheet 10 is continued to be used, the anti-slip material layer 30 disposed on the convex portions 25 will wear out, but the anti-slip material layer 30 that has entered the concave portions 26 will continue to remain, resulting in moderate friction. It can exert resistance over a long period of time.

Further, since the transparent anti-slip sheet 12 has the surface layer 60, it can exhibit appropriate frictional resistance for a longer period of time. In addition, in the case where the transparent anti-slip sheet 12 further covers the surface of the anti-slip material layer 30 as an inorganic coating layer 70 and has a self-cleaning surface layer 60 thereon, the appropriate frictional resistance can be maintained for a long period of time. able to demonstrate.

10 Transparent anti-slip sheet of the first embodiment 12 Transparent anti-slip sheet of the second embodiment 20 Base sheet 21 Surface 25 Convex portions 26 Recesses 30 Anti-slip material layer 35 Mixture 40 Fixed portion 60 Surface layer 70 Inorganic coating layer 80 Printed sheet 90 Adhesive 100 Construction surface

Claims (3)

In order to exhibit an anti-slip effect when laid on a construction surface, it is made of a transparent plastic film that allows the construction surface to be seen through, and has a convex surface and a concave recess, and a base material sheet. ,
an anti-slip material layer fixed to the surface of the base sheet,
The anti-slip material layer is composed of a mixture of glass particles having different particle sizes ranging from 100 to 800 μm, and the glass particles are composed of chips, which are waste products produced when processing glass products, and The anti-slip material layer is a transparent anti-slip sheet placed in the convex portion and the concave portion. The transparent anti-slip sheet according to claim 1, wherein the anti-slip material layer further includes a surface layer having self-cleaning properties that decomposes organic matter. The transparent anti-slip sheet according to claim 1, wherein the surface of the anti-slip material layer is covered with an inorganic coating layer, and a surface layer having self-cleaning properties is provided on the inorganic coating layer.

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