JP2007284953A - Paving body and construction material - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a paving body and a construction material superior in light resistance and intelligent in a change in a color corresponding to a temperature change, and to further provide the paving body and the construction material for improving scenic properties and design. <P>SOLUTION: This paving body 10 is constituted so that a backing layer 20 including a white or the other colored pigment or dye is formed on a paved road surface 50, and a temperature indicating material layer 30 including a heat reversible temperature indicating material is formed on the backing layer 20, and a heat resistant layer 40 including a heat resistant material is formed on the temperature indicating material layer 30. The paving body 10 is characterized in that the backing layer 20 includes a heat conductivity adjusting material in at least a part. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a pavement and a construction material.

  Conventionally, there is known a temperature indicating material that develops a color when the temperature falls below a predetermined temperature and disappears when the temperature exceeds a predetermined temperature. This temperature indicating material is obtained by mixing a temperature indicating pigment or a temperature indicating dye whose color changes reversibly with a temperature change into a base resin. This temperature indicating material is used for decoration of toys, tableware, seals and the like because the color changes depending on the temperature.

  However, the temperature indicating material is not only decomposed by ultraviolet rays, but also has a low durability against visible light of a predetermined wavelength and an accompanying oxidation resistance, so that it is used outdoors, especially in blocks, tiles, Currently, there is almost no application to construction materials and paved surfaces exposed to the external environment such as bricks, panels and boards.

  As a conventional technique for using a temperature indicating material outdoors, for example, Patent Document 1 discloses a welding application type road marking material and a road marking sheet for the purpose of calling attention to freezing using the temperature indicating material. Yes. However, the technique of Patent Document 1 does not take any measures for enhancing the light resistance to ultraviolet rays and visible light, and it is doubtful whether it can withstand outdoor use.

  Patent Document 2 discloses a road marking work using a temperature indicating material as a paint. In this road marking work, it is stated that a light resistance improver such as an ultraviolet absorber may be added as a measure for improving the light resistance, but the service life when applied to the road surface on the site is only a little. It is 3 months and it is hard to say that the light resistance is sufficient.

  On the other hand, in Patent Document 3 and Patent Document 4, as a measure for enhancing the light resistance of the temperature indicating material, a light-resistant protective layer containing a light resistance improving agent is provided outside the temperature indicating material layer containing the temperature indicating material. Is described. According to this method, the light resistance of the temperature indicating material can be further improved as compared with the method of adding a light resistance improving agent to the temperature indicating material. In particular, as described in Patent Document 4, when α iron oxide fine particles are used as the light resistance improver, the light resistance can be further improved.

  However, according to such a method, since it becomes the structure which laminated | stacked several layers for light resistance improvement, the transmission of the heat to a temperature-indicating material layer becomes slow. As a result, the color change of the temperature indicating material layer with respect to the temperature change becomes slow. In particular, if this method is applied to construction materials such as blocks and road surfaces, measures to improve the durability of vehicles and pedestrians must be taken at the same time, increasing the thickness of the protective layer covering the temperature indicating material layer. It is necessary to let As a result, the heat transfer to the temperature indicating material layer becomes increasingly slower, and the color change of the temperature indicating material with respect to the temperature change becomes slower. Therefore, when trying to call attention to freezing due to a change in color due to a decrease in road surface temperature, the change in color of the temperature indicating material with respect to the decrease in temperature is slow, so that the function of calling attention cannot be performed sufficiently. is there.

JP 2003-171914 A JP 2003-193440 A Japanese Patent Publication No. 4-18543 Japanese Patent Laid-Open No. 2005-220201

  This invention is made | formed in view of said background art, and makes it a subject to provide the pavement and construction material which are excellent in light resistance, and whose color change with respect to a temperature change is agile. It is another object of the present invention to provide a technique capable of improving the design of road pavement and construction materials by utilizing a color change mode caused by a temperature change.

Means for solving the above problems are the following inventions (1) to (14).
(1) An underlayer containing a white or other colored pigment or dye is formed on the paved road surface, and a temperature indicating material layer containing a thermoreversible temperature indicating material is formed on the underlayer. A pavement in which a light-resistant layer including a light-resistant material is formed on the temperature indicating material layer, wherein the base layer includes a thermal conductivity adjusting material at least in part. .
(2) The pavement according to (1), wherein the thermal conductivity adjusting material is a high thermal conductivity material.
(3) The pavement according to (1) or (2) above, wherein the base layer is coated with a paint containing a white or other colored pigment or dye and a thermal conductivity adjusting material. The pavement is formed, wherein the temperature indicating material layer is formed by applying a paint containing the temperature indicating material, and the light resistant layer is formed by applying a paint containing the light resistant material.
(4) An underlayer containing a white or other colored pigment or dye, a temperature indicating material layer containing a thermoreversible temperature indicating material laminated on the underlayer, and laminated on the temperature indicating material layer A resin plate integrated with a light-resistant layer containing a light-resistant material, wherein the base layer includes a thermal conductivity adjusting material at least partially.
(5) A pavement formed by sticking the resin plate described in (4) above on a pavement road surface.
(6) The pavement according to the above (5), wherein the resin plate is stuck on a pavement road surface with an adhesive containing a high heat conductive material.
(7) An underlayer containing a white or other colored pigment or dye is formed on at least a part of the surface, and a temperature indicating material layer containing a thermoreversible temperature indicating material is formed on the underlayer. And a light-resistant layer including a light-resistant material is formed on the temperature indicating material layer, wherein the foundation layer includes a thermal conductivity adjusting material at least in part. Construction material characterized by that.
(8) The construction material according to (7), wherein the thermal conductivity adjusting material is a high thermal conductivity material.
(9) The construction material according to (7) or (8) above, wherein the base layer is coated with a paint containing a white or other colored pigment or dye and a thermal conductivity adjusting material. A construction material, wherein the temperature indicating material layer is formed by applying a paint containing the temperature indicating material, and the light resistant layer is formed by applying a paint containing the light resistant material.
(10) A construction material in which the resin plate according to (4) is attached to at least a part of the surface.
(11) The construction material according to (10), wherein the resin plate is attached with an adhesive containing a high thermal conductivity material.
(12) An underlayer containing a white or other colored pigment or dye is formed on the paved road surface, and a temperature indicating material layer containing a thermoreversible temperature indicating material is formed on the underlayer. A pavement in which a light-resistant layer containing a light-resistant material is formed on the temperature-indicating material layer, wherein the base layer has a thermal conductivity different from that of other surrounding areas in at least a part of the area. A pavement characterized in that it is formed.
(13) A base layer containing a white or other colored pigment or dye is formed on at least a part of the surface, and a temperature indicating material layer containing a thermoreversible temperature indicating material is formed on the base layer. A light-resistant layer containing a light-resistant material is formed on the temperature-indicating material layer, and the base layer has a thermal conductivity that is at least partially in other areas and surrounding. Construction material characterized by being formed differently.
(14) An underlayer containing a white or other colored pigment or dye, a temperature indicating material layer containing a thermoreversible temperature indicating material laminated on the underlayer, and laminated on the temperature indicating material layer A resin plate integrated with a light-resistant layer containing a light-resistant material, wherein the base layer is formed such that at least a part of the region has a thermal conductivity different from that of other surrounding regions. Characteristic resin plate.

  According to the present invention, it is possible to provide a pavement and a construction material that are excellent in light resistance and have a color change sensitive to a temperature change. Moreover, the pavement body and construction material excellent in scenery property and designability can be provided by making the change speed of the color of a certain area | region of a surface differ from each other area | region, respectively.

In the pavement 10 of the present invention, as shown in FIG. 1, a base layer 20 containing a white or other colored pigment or dye is formed on a pavement road surface 50, and the reversible layer is thermally reversible. A temperature indicating material layer 30 including a characteristic temperature indicating material is formed, and the light-resistant layer 40 including a light resistant material is formed on the temperature indicating material layer 30. In addition, the foundation layer 20 is the pavement 10 characterized in that at least a part thereof includes a thermal conductivity adjusting material.
In the present invention, the paved road surface 50 is, for example, a road surface that is laid and solidified on the surface of a road, a plaza, a staircase, etc., and is a road surface that is paved with a pavement material such as asphalt or concrete.

As shown in FIG. 3, the construction material 60 of the present invention has a base layer 70 containing a white or other colored pigment or dye formed on at least a part of the surface, and on the base layer 70, A construction material 60 in which a temperature indicating material layer 80 including a thermoreversible temperature indicating material is formed, and a light-resistant layer 90 including a light-resistant material is formed on the temperature indicating material layer 80, is the base layer. Reference numeral 70 denotes a construction material 60 characterized in that at least a part thereof includes a thermal conductivity adjusting material.
In the present invention, the construction material 60 is a material used to construct a road surface, a wall surface of a building, and the like. Specifically, for example, blocks, tiles, bricks, panels, boards, etc. included.

  Hereinafter, each of the (1) temperature indicating material layer, (2) light-resistant layer, and (3) base layer constituting the pavement 10 or the construction material 60 of the present invention will be described in detail.

(1) Temperature indicating material layer The temperature indicating material layer is a layer containing a temperature indicating material. The temperature indicating material is a material in which a temperature indicating pigment or a temperature dye that develops a color when the temperature is lower than a predetermined temperature and disappears when the temperature exceeds a predetermined temperature is mixed with a base resin. Since the temperature indicating material contains a temperature indicating pigment or a temperature indicating dye, it is possible to reversibly repeat color development and decoloration in response to a change in ambient temperature. As will be described later, the temperature indicating material may be applied to the pavement road surface or the surface of the construction material in a state of being prepared as a paint, or may be paved in a state of being formed in advance on a resin plate having a predetermined thickness. You may affix on the surface of a road surface or construction material. The temperature indicating material layer may be formed so as to cover the entire surface of the paved road surface or the construction material, or may be formed so as to cover only a part of the surface of the paved road surface or the construction material.

  As the temperature indicating pigment or temperature indicating dye, for example, a microencapsulated mixture of an electron-donating colored organic compound, an electron-accepting compound, and a color-change temperature adjusting agent can be used.

  As the electron donating colored organic compound, a leuco dye can be preferably used. These leuco dyes can be used alone or in combination of two or more, so that the color at the time of color development can be any color such as yellow, orange, red, peach, magenta, purple, blue, green, brown, black, etc. can do. Any leuco dye may be used as long as it is conventionally known. For example, those disclosed in JP-A-7-40660 and JP-A-2003-313453 can be used.

  The electron-accepting compound is a compound that develops a color reaction with the electron-donating colored organic compound and develops a color. For example, triazole-based, phenol-based, bisphenol-based, aromatic carboxylic acids, aliphatic carboxylic acids, thiols Ureas, phosphoric acids, or esters thereof, ethers, metal salts and the like known for pressure-sensitive and heat-sensitive copying papers can be used. Any electron-accepting compound may be used as long as it is conventionally known. For example, those disclosed in JP-A-7-40660 and JP-A-2003-313453 may be used. it can.

  The color-change temperature adjusting agent is a component for controlling the reaction temperature between the electron-donating colored organic compound and the electron-accepting compound. By using this color change temperature adjusting agent, the color change temperature of the temperature indicating material can be freely controlled. As the color temperature adjusting agent, any conventionally known color temperature adjusting agent can be used. For example, alcohols, esters, ethers, ketones, amides, azomethines, fatty acids, hydrocarbons and the like can be used. Can be used.

Any resin can be used as the base of the temperature indicating material as long as it is generally used as this type of resin. For example, acrylic resin, methyl methacrylate resin (MMA resin), urethane resin, polypropylene resin, ABS resin, polystyrene resin, vinyl chloride resin, polyethylene resin, polyester resin, polycarbonate resin, polyamide resin, epoxy resin, phenol resin, fluorine resin, Alkyd resins, petroleum resins, etc. can be used. In addition, water-based emulsions such as acrylic emulsions, fluorine emulsions, and vinyl acetate emulsions can also be used. In addition, rubber-based materials such as natural rubber, chloroprene rubber, styrene-butadiene copolymer rubber, or water-based emulsions thereof can be used. These resins can also be used as a base resin for a light-resistant layer and an underlayer described later.
When preparing the temperature indicating material, not only the temperature indicating pigment (or temperature indicating dye) described above but also a light fastness improving agent described later may be mixed in the base resin. Further, in order to adjust the color, a pigment similar to the pigment used in the below-described underlayer may be mixed as appropriate.

  In order to form the above-mentioned temperature indicating material layer on the underlayer, a paint containing the above-mentioned temperature indicating material may be applied to the surface of the underlayer, or a solid resin plate containing the above-mentioned temperature indicating material is formed. You may affix on the surface of a base layer. For the sticking, the resin plate containing the above-mentioned temperature indicating material may be bonded with an adhesive or the like, or the resin plate containing the above-mentioned temperature indicating material is heated and welded or pressed and bonded by pressure bonding or the like. May be.

(2) Light-resistant layer A light-resistant layer containing a light-resistant material is formed on the temperature indicating material layer described above.
The light-resistant material is obtained by mixing a light resistance improver into a base resin. The “light resistance improver” is a substance that enhances durability against decomposition by ultraviolet light or visible light and accompanying oxidation. For example, ultraviolet absorbers such as benzotriazole and benzophenone, hindered amine light stabilizers (HALS), Phenol-based, amine-based, lactone-based, phosphorus-based, or a combination thereof, ferric oxide (α-Fe ₂ O ₃ ), iron oxyhydroxide (FeOOH), titanium oxide (TiO ₂ ), oxidation In addition to inorganic light fastness improvers that are fine powders such as zinc (ZnO), any other material that improves the durability against decomposition by light (ultraviolet light, visible light) and accompanying oxidation is applicable. Can also be used.
The light-resistant layer can be formed by applying a light-resistant material in the form of a paint and applying it on the temperature indicating material layer. Alternatively, the light-resistant material can be formed in the form of a solid resin plate, and the resin plate can be formed on the temperature indicating material layer by sticking, pressure bonding, welding, or the like.

(3) Underlayer Since the temperature indicating material has a slightly lower surface concealability, when the temperature indicating material layer is formed on the pavement surface or the surface of the construction material, the color of the underlayer may be transparent. Therefore, in the present invention, an underlayer containing a white or other colored pigment or dye is formed under the temperature indicating material layer.

  The underlayer can be formed by applying a paint in which a white or other colored pigment or dye and a base resin are mixed. Or it can form by sticking the solid resin board which mixed white or other colored pigment or dye, and resin used as a base. Alternatively, it can be formed by applying or transferring a pasty material in which a white or other colored pigment or dye and a base cement-based material (cement, mortar, concrete, etc.) are mixed. When the base layer is white, the base layer may be formed by applying or transferring a cement-based material using white cement without using a pigment. In this specification, the material for forming these underlayers may be referred to as “underlying material”.

  Any pigment may be used for the underlayer as long as it is a conventionally known pigment. For example, the white pigment is preferably zinc oxide or titanium oxide. The titanium oxide is preferably rutile type titanium oxide. Other colored organic pigments include azo, quinacridone, alizarin, perylene (red), anthraquinone, isoindoline, benzimidazolone, phthalocyanine, halogenated phthalocyanine, indanthrone, A pigment such as magenta or dioxazine can be used. As other colored inorganic pigments, pigments such as iron oxide, yellow ocher, chromium oxide, and cobalt can be used. As the white or other colored dye, any known dye can be used.

By forming the base layer under the temperature indicating material layer, it is possible to prevent the pavement road surface or the surface of the construction material from being seen through.
The use of a white pigment for the underlayer is preferable because the color of the temperature indicating material layer becomes clear. In this case, when the temperature exceeds a predetermined temperature, the color of the temperature indicating material disappears to become a white surface. When a colored pigment other than white is used, when the temperature exceeds a predetermined temperature, the color of the temperature indicating material disappears and changes to the color of the underlayer. That is, the color of the surface changes reversibly according to the temperature change of the external environment.
For example, when such a pavement is formed on a pavement surface of a road, it is possible to change the color and pattern of the road, the mode of a sign for alerting, or the like. Moreover, when the wall surface of a building is constructed using such construction materials, the pattern of the wall surface changes variously according to changes in the outside air temperature. Therefore, it is possible to change the pattern and color of the wall surface of the building according to changes in the time of day and the season.

The underlayer can contain a thermal conductivity adjusting material at least partially. The thermal conductivity adjusting material is a material that, when mixed in the base material, improves or decreases the thermal conductivity as compared to the base layer made of only the base material.
In the present invention, a thermal conductivity adjusting material that improves the thermal conductivity is distinguished from a “high thermal conductive material”, and a thermal conductivity adjusting material that is lowered is distinguished from a “low thermal conductive material”. Only one kind of heat conductivity adjusting material may be mixed, or a plurality of heat conductivity adjusting materials may be mixed and mixed. The thermal conductivity of the underlayer can be adjusted by changing the type and mixing amount of the thermal conductivity adjusting material. In addition, when the thermal conductivity adjusting material is contained in the underlayer, the underlayer is divided into two or more layers, and at least one of them is mixed with the thermal conductivity adjusting material to adjust the thermal conductivity of the underlayer. it can. For example, the base layer may be divided into two or more layers, and the thermal conductivity adjusting material may be mixed only in a layer in contact with the paved road surface or the surface of the construction material.

  The paved road surface and construction materials may need to be thickened to ensure physical durability in order to prevent wear and damage when a car or pedestrian passes. In order to increase the thickness, it is necessary to increase the thickness of the temperature indicating material layer, the light-resistant layer, or the base layer. However, as the thickness of these layers increases, the transfer of heat to the temperature indicating material layer becomes slower. Therefore, in order to quickly transmit the temperature change of the pavement road surface or the surface of the construction material to the temperature indicating material, it is preferable that the base layer contains a high heat conductive material. As a result, the thermal conductivity of the underlayer increases, so that heat transfer to the temperature indicating material layer is accelerated.

  Specific examples of high thermal conductive materials include metal powders such as aluminum and iron, powders of oxide crystals with high thermal conductivity such as aluminum oxide and silicon oxide (quartz), and heat such as silicon carbide, silicon nitride, and aluminum nitride. An inorganic compound powder or the like having high conductivity can be used.

A raw material containing a large amount of the high heat conductive material may be crushed to a predetermined particle size or less and kneaded with a base resin to form a mortar, which may be used as a base material.
Iron ore, quartzite, garnet, or the like can be used as a rough ore containing a large amount of high heat conductive material. In addition, an artificial aggregate mainly composed of aluminum oxide or mullite can be used. When using these as a high heat conductive material, it is preferable to use them after crushing them into granular materials having a maximum dimension of 2 mm or less.

  Moreover, as a high heat conductive material, an aluminum plate, an iron plate, etc. can also be inserted in a base layer instead of mixing powder and a granular material with high heat conductivity.

  In addition, as a low heat conductive material, porous resin products, such as hollow particles, such as a ceramic balloon, a glass balloon, a fly ash balloon, or foaming urethane, etc. can be used.

  By including the high thermal conductive material in the underlayer, the heat transfer rate in the underlayer is increased. That is, the foundation layer can quickly transfer the heat generated from the paved road surface or the surface of the construction material to the temperature indicating material layer. As a result, the temperature indicating material layer is rapidly colored or decolored with the temperature change of the pavement surface or the surface of the construction material. By using this phenomenon, it is possible to make pedestrians and drivers recognize the temperature change on the road surface more quickly.

  The underlayer may be formed such that at least a part of the region has a thermal conductivity different from that of other surrounding regions. That is, by using two or more types of base materials having different thermal conductivities, the base layer may be formed so that a specific region has a different thermal conductivity from other neighboring regions. By making the thermal conductivity of the underlayer different from each other in a plurality of regions, it is possible to change the color change rate of the temperature indicating material layer in each region. As a result, the following effects are exhibited.

FIG. 2 is a cross-sectional view of the pavement 12 in the present invention.
The pavement 12 includes a base layer 22 formed on the paved road surface 50, a temperature indicating material layer 32 formed on the base layer 22, and a light-resistant layer 42 formed on the temperature indicating material layer 32.
The underlayer 22 includes a first region 22a and a second region 22b adjacent to the periphery of the first region 22a. The first region 22a is formed of a base material containing a high heat conductive material. On the other hand, the second region 22b is formed of a base material that does not include a thermal conductivity adjusting material or a base material that includes a low thermal conductivity material.
As a result, heat generated from the surface of the paved road surface 50 is quickly transferred to the temperature indicating material layer 32 in the first region 22a containing the high thermal conductivity material. On the other hand, in the second region 22b that does not include the thermal conductivity adjusting material (or includes the low thermal conductivity material), heat generated from the surface of the pavement surface 50 is gently transferred to the temperature indicating material layer 32.

  In the portion of the temperature indicating material layer 32 that is in contact with the upper surface of the first region 22a, the color of the temperature indicating material layer 32 changes rapidly because the heat transfer rate is fast. On the other hand, in the portion of the temperature indicating material layer 32 that is in contact with the upper surface of the second region 22b, the color of the temperature indicating material layer 32 changes gradually because the heat transfer rate is slow. Thereby, it is possible to make the timings at which the colors change in a specific region and other regions in the temperature indicating material layer 32 different from each other.

  As another example, the base layer 22 is formed using a base material containing a low thermal conductive material in the first region 22a, and the base material or the high thermal conductive material does not contain a thermal conductivity adjusting material in the second region 22b. It is also possible to form the base layer 22 using a base material containing. In this case, the first region 22a has a lower heat transfer rate than the second region 22b. Therefore, the temperature of the temperature indicating material layer 32 changes in color at a portion in contact with the upper surface of the first region 22a later than a portion in contact with the upper surface of the second region 22b.

The same applies to construction materials. Hereinafter, the case of construction materials will be specifically described with reference to FIG.
FIG. 4 is a cross-sectional view of the construction material 62 in the present invention.
As shown in FIG. 4, a base layer 72 containing a white or other colored pigment or dye is formed on the surface of the construction material 62, and a thermoreversible temperature indicating material is placed on the base layer 72. A temperature indicating material layer 82 is formed, and a light resistant layer 92 including a light resistant material is formed on the temperature indicating material layer 82.
The underlayer 72 includes a first region 72a and a second region 72b adjacent to the periphery of the first region 72a. The first region 72a is formed of a base material containing a high heat conductive material. On the other hand, the second region 72b is formed of a base material that does not include a thermal conductivity adjusting material or a base material that includes a low thermal conductivity material.
As a result, heat generated from the surface of the construction material 62 is quickly transferred to the temperature indicating material layer 82 in the first region 72a containing the high thermal conductivity material. On the other hand, in the second region 72b not including the thermal conductivity adjusting material (or including the low thermal conductivity material), heat generated from the surface of the construction material 62 is gently transferred to the temperature indicating material layer 82.

  In the portion of the temperature indicating material layer 82 that is in contact with the upper surface of the first region 72a, the color of the temperature indicating material layer 82 changes rapidly because the heat transfer rate is high. On the other hand, in the portion of the temperature indicating material layer 82 that is in contact with the upper surface of the second region 72b, the color of the temperature indicating material layer 82 changes gradually because the heat transfer rate is slow. Thereby, the timing at which the color changes in a specific region and other regions in the temperature indicating material layer 82 can be made different from each other.

  As another example, the base layer 72 is formed using a base material containing a low thermal conductive material in the first region 72a, and the base material or the high thermal conductive material does not contain a thermal conductivity adjusting material in the second region 72b. It is also possible to form the base layer 72 by using a base material containing. In this case, the heat transfer rate of the first region 72a is slower than that of the second region 72b. Therefore, in the temperature indicating material layer 82, the color of the portion in contact with the upper surface of the first region 72a changes later than the portion in contact with the upper surface of the second region 72b.

  As described above, according to the pavement or construction material of the present invention, the color changes by forming at least a part of the base layer so that the thermal conductivity is different from the other surrounding areas. The start timing can be varied. As a result, it is possible to make an arbitrary pattern appear temporarily as the surface temperature changes. Thereby, the designability of a paving body and construction material can be improved.

  In addition, by combining a plurality of construction materials on which an underlayer is formed so as to have different thermal conductivities, it is possible to make an arbitrary pattern appear temporarily on, for example, a paved road surface or a wall surface of a building.

Each of the temperature indicating material layer, the light-resistant layer, and the base layer may be formed by applying a liquid paint or may be formed by sticking a solid resin plate.
The method for forming each layer on the paved road surface or the surface of the construction material will be specifically described below.

A method for forming each layer using a paint-like material will be described.
First, a base material prepared in a paint form is applied to a paved road surface or the surface of a construction material. The number of times of application may be one time, but if the surface of the paved road surface is dark or the surface unevenness is relatively large (in the case of a rough surface), the number of times of application of the base material should be twice. Is preferred. Three or more overcoats may be applied. The amount of coating applied once to form the underlayer varies depending on the type of resin as the base, the thermal conductivity adjusting material contained, the type of pigment, etc., but is 0.1 kg / m ² or more and 1 It is preferable to apply so as to be 0.0 kg / m ² or less. At this time, if a plurality of types of base materials formed so as to have different thermal conductivities are used, the base layer can be formed so that at least a part of the base layer has a different thermal conductivity from other surrounding regions. it can. In addition, it is possible to draw an arbitrary pattern, character, or the like by using a plurality of base layers formed so as to have different thermal conductivities.

After the base layer is cured, a temperature indicating material is applied thereon to form a temperature indicating material layer. The temperature indicating material may be applied one time or two or more times. It is also possible to draw arbitrary patterns, characters, etc. on the temperature indicating material layer using a mold or masking tape. The coating amount for forming the temperature indicating material layer is preferably 0.1 kg / m ² or more and 1.0 kg / m ² or less, as in the case of the base layer.

After the temperature indicating material layer is cured, a light resistant material is applied to form a light resistant layer. As described above, when a pattern or character is drawn with the temperature indicating material layer, a light-resistant layer may be formed only on the pattern or character, or a light-resistant layer including a portion other than the pattern or character may be formed. It may be formed. The number of times of application of the light-resistant material for forming the light-resistant layer is usually once, and may be performed twice or more. The application amount of the light-resistant material at one time is preferably 0.1 kg / m ² or more and 1.0 kg / m ² or less, similarly to the temperature indicating material layer and the base layer described above.

Next, a method for forming each of the temperature indicating material layer, the light-resistant layer, and the base layer using a resin plate will be described.
In order to form each layer, a base layer, a temperature indicating material layer, and a light-resistant layer may be formed from a resin plate, and these layers may be laminated and integrated. As a method for integrating the layers, a resin plate constituting each layer may be separately molded, and a plurality of resin plates may be integrated by hot pressing or the like. Or you may integrate each layer at the time of shaping | molding of a resin board by techniques, such as multilayer extrusion molding. When forming the underlayer, the underlayers having different thermal conductivities may be arranged so as to be adjacent to each other, and these underlayers may be welded together on the side surface by hot pressing or the like to be integrated.

The resin plate thus molded is stuck on the paved road surface or the surface of the construction material. For sticking, an adhesive or a technique such as welding may be used. As the adhesive, a known adhesive such as an epoxy resin, an acrylic resin, or a urethane resin may be used. In this case, in order to quickly transmit the temperature of the paved road surface or the surface of the construction material to the resin plate, it is preferable to mix a high heat conductive material in the adhesive.
In particular, in the case of a thick resin plate, it is preferable that the thickness of the resin plate is scraped off from the paved road surface or the surface of the construction material and bonded so as to embed the resin plate.

  If the construction material is a cement concrete block, a resin plate is pasted on the inner surface of the mold in advance, and the cement concrete is poured into the mold to integrate the resin plate and the block. You may use the technique to make.

  In the present invention, the “resin plate” for forming the temperature indicating material layer, the light-resistant layer, or the base layer is formed to have any thickness as long as it can be attached to the paved road surface or the surface of the construction material. Things may be used. For example, what was shape | molded into the thin film-like resin sheet about 0.1 mm thick may be used, and what was shape | molded in the thick plate shape whose thickness is 1 cm or more may be used. Of course, the thickness may be 0.1 mm or more and 1 cm or less.

  Moreover, the anti-slip | skid effect can be provided to the pavement and construction material of this invention as needed. For example, by providing an anti-slip material on the light-resistant layer, between the light-resistant layer and the temperature indicating material layer, or between the temperature indicating material layer and the underlayer, an anti-slip effect can be imparted.

  As described above, according to the present invention, it is possible to realize a pavement and a construction material excellent in design and landscape, in which the color changes reversibly according to a change in ambient temperature. Furthermore, the functionality can be remarkably improved by including a thermal conductivity adjusting material in the underlayer.

  For example, a pavement in which a high thermal conductive material is mixed in the foundation layer can be used as a road marking material that alerts the road surface to freezing. In this case, since the temperature of the road surface is reflected in the color of the temperature indicating material layer more quickly, it is possible to more effectively exhibit the warning indication function.

In addition, when a part of the base layer is formed so as to have higher thermal conductivity than the other part, the discoloration speed of the temperature indicating material is increased only in that part, so that it temporarily differs from the surroundings. Color can be developed. As a result, the appearance changes over time, so that it is possible to construct a landscape pavement or the like with improved design.
Furthermore, it is also possible to make an arbitrary pattern appear temporarily by combining a plurality of construction materials having different thermal conductivity of the underlayer. By utilizing this, it is possible to construct an outer wall or the like of a building in which the appearance changes with time and a pattern or a character appears.

In this embodiment, as shown in FIG. 5A, the base layer 120, the temperature indicating material layer 130, and the light-resistant layer 140 are formed using a paint, and the layers are laminated and integrated. A specimen 110 was created. And the change of the color tone accompanying the temperature change of the specimen 110 was measured.
The underlayer 120 was formed using a paint mixed with a high heat conductive material or a low heat conductive material. In addition, as a comparative example, the base layer 120 was formed using a paint that did not contain the thermal conductivity adjusting material.
The temperature indicating material layer 130 and the light-resistant layer 140 were also formed using a paint. Table 1 shows an outline of the temperature indicating material used for the temperature indicating material layer 130 and the light resistant material used for the light resistant layer 140.

  Table 2 shows the composition (composition) of the base material used to form the base layer 120. Table 3 shows an outline of the materials used for preparing the base material. The base materials were all prepared using MMA resin as the base resin and blending the white pigment and the thermal conductivity adjusting material in the proportions shown in Table 2. The base material 1 contains only a white pigment, the base materials 2 to 5 are mixed with a high heat conductive material, and the base material 6 is mixed with a low heat conductive material. In Table 2, (inner) indicates that the base resin is mixed in the inner portion, and (outer) indicates that the base resin is mixed in the outer portion. For example, “white pigment 5% (inner) + aluminum nitride 10% (outer)” substitutes white pigment for 5% by mass with respect to the base resin, and 10% of the mass of the mixture of the base resin and the white pigment. It shows that the base material was prepared by adding aluminum nitride corresponding to%. Moreover, the thermal conductivity in Table 2 uses a separately prepared specimen of 160 mm × 80 mm × 10 mm, and uses a rapid thermal conductivity meter Chemtherm QTM-03 (manufactured by Kyoto Electronics Co., Ltd.) in an atmosphere of 20 ° C. Measured.

  A specimen having the configuration shown in Table 4 was prepared using the materials described above. In Examples 3, 4, 7 and 8, as shown in FIG. 5B, the light-resistant layer 142 and the temperature indicating material layer 132 constituting the specimen 112 are single layers, but the base layer 122 is the upper layer. The upper and lower layers 122a and 122b were divided into two upper and lower layers, which were formed using different base materials. The color tone of each created specimen was measured by the method described later, and the degree of change in color tone at the time of each measurement relative to the initial color tone was calculated.

[Color tone measurement method 1]
In an atmosphere of 20 ° C., as shown in FIG. 6A, hot water 158 was put into a container 152 and heated by a throwing heater 156 to keep the hot water 158 at 40 ° C. An iron plate 154 was installed in the vicinity of the water surface, and the specimen 110 (112) was placed thereon so that the ground layer 120 (122) was in contact with the iron plate 154. The measurement part of the color difference meter 170 was applied to the light-resistant layer 140 (142) of the specimen 110 (112), and the color tone of the specimen 110 (112) was measured. The color tone is measured at intervals of 5 seconds from 0 to 60 seconds and at intervals of 10 seconds from 60 to 180 seconds, and a Lab color system using a color difference meter (CR-410 manufactured by Konica Minolta Celsing Co., Ltd.). Measured with

[Color tone measurement method 2]
In an atmosphere of 20 ° C., ice 164 at −5 ° C. was placed in the container 162 as shown in FIG. The specimen 110 (112) was placed on the ice 164 so that the ground layer 120 (122) was in contact with the ice 164, and the color tone of the specimen 110 (112) was measured in the same manner as the color tone measuring method 1.

[Calculation of degree of change in color tone at each measurement with respect to initial color tone]
The degree of change in color tone at the time of each measurement relative to the initial color tone was calculated from the following equation (1).

^{_{E n = ((L n -L}} 0) 2 + (a n -a 0) 2 + (b n -b 0) 2) 1/2 ··· Equation (1)
E _n : degree of change in color tone at the time of measurement after n seconds with respect to the initial color tone L _n , a _n , b _n : values L ₀ , a ₀ , b at the time of measurement after n seconds L ₀ , a ₀ , b ₀ : L, a, b values at the time of initial measurement (before test)

Furthermore, for each specimen, the value of _{E n} of 180 seconds each _{(E 180)} as a final change value, this as 100%, a value representing the ratio of _{E n} and _{E 180} at each measurement time as a percentage (E _n / E ₁₈₀ ratio) was calculated by the following equation (2), and the relationship between elapsed time and E _n / E ₁₈₀ ratio was determined.

E _n / E ₁₈₀ ratio (%) = (E _n ÷ E ₁₈₀ ) × 100 (2)
E _n : degree of change in color tone during measurement after n seconds with respect to the initial color tone E ₁₈₀ : degree of change in color tone during measurement after 180 seconds with respect to the initial color tone

First, Examples 1 to 4 were investigated. In Examples 1 to 4, a high thermal conductive material is mixed in the underlayer. Of these, Examples 3 and 4 are obtained by dividing the underlayer into two layers and mixing the high thermal conductive material only in the lower layer. Comparative Example 1 in which the thermal conductivity adjusting material was not mixed in the underlayer was used as a control. Each of the temperature indicating material layers constituting them is composed of the temperature indicating material 1 which changes color at 27 ° C. (green below 27 ° C., and decolored when exceeding 27 ° C.). The color tone of these specimens was measured by the above color tone measuring method 1. At this time, in each specimen, the temperature indicating material is colored at 20 ° C. at room temperature in the initial measurement, and the heat of the iron plate is transmitted to the temperature indicating material through the underlayer, and the temperature of the temperature indicating material gradually rises and exceeds 27 ° C. The color of the temperature indicating material disappeared (hereinafter referred to as a test for erasing at high temperature). The degree of change in color tone at the time of each measurement relative to the initial color tone was calculated, and the relationship between elapsed time and E _n / E ₁₈₀ ratio was determined. The result is shown in FIG.

Subsequently, Examples 5 to 7 were investigated. In Examples 5 to 7, a high thermal conductive material is mixed in the underlayer, and in this example, the underlayer is divided into two layers, and the high thermal conductive material is mixed only in the lower layer. Comparative Example 2 in which the thermal conductivity adjusting material was not mixed in the underlayer was used as a control. Each of the temperature indicating material layers constituting these is composed of the temperature indicating material 2 which changes color at 5 ° C. (red below 5 ° C. or decolored after exceeding 5 ° C.). The color tone of these specimens was measured by the above color tone measuring method 2. At this time, in each specimen, the temperature indicating material is 20 ° C. at room temperature and the color disappears, and the temperature of ice is transmitted to the temperature indicating material through the base layer, and the temperature of the temperature indicating material gradually decreases to 5 ° C. or less. As a result, the temperature indicating material develops color (hereinafter referred to as a test that develops color at a low temperature). The degree of change in color tone at the time of each measurement relative to the initial color tone was calculated, and the relationship between the elapsed time and the E _n / E ₁₈₀ ratio was determined. The result is shown in FIG.

From the results shown in FIG. 7 and FIG. 8, it can be seen that the color tone quickly changes in both cases when the underlayer mixed with the high thermal conductivity material is used.
Specifically E _{n /} E ₁₈₀ ratio Comparing at the point of 90%, the results of the decolored tested at elevated temperatures shown in FIG. 7, the Examples 1 to 4 were mixed with a high thermal conductivity material in the underlying layer It can be seen that the color tone changes about 10 to 30 seconds faster than the comparative example 1 in which the thermal conductivity adjusting material is not mixed in the underlayer. Moreover, in the result of the test which develops color at a low temperature by the color tone measuring method 2 shown in FIG. 8, Examples 5 to 7 in which the base material is mixed with the high thermal conductivity material are comparative examples 2 in which the base material is not mixed with the thermal conductivity adjusting material. It can be seen that the color tone is changing about 10 to 80 seconds faster than the above. In addition, in the result of FIG. 7 or FIG. 8, when the change in color tone of Examples 3, 4 or Example 7 in which the base layer is divided into two layers and the high thermal conductive material is mixed only in the lower layer, the entire base layer is observed. The change is slightly slower than that in which the high thermal conductivity material is mixed (Examples 1 and 2 or Examples 5 and 6), but compared to the material in which the thermal conductivity adjusting material is not mixed in the underlayer (Comparative Example 1 or Comparative Example 2). I found it fast. In addition, since this test was performed by rapidly changing the temperature, and the temperature change in the actual pavement and construction materials is more gradual than in this example, the time difference of discoloration is expected to be larger. .

  From these results, it was found that the color change occurred quickly in response to the temperature change of the external environment by containing a high thermal conductive material in at least a part of the underlayer. Therefore, if this is applied to a pavement (road marking material) that indicates warnings when the road surface freezes, etc., it is possible to more accurately indicate the temperature condition of the road surface, and the warning function is more effective. It has been found that it is possible to achieve this.

Next, Examples 8 and 9 were investigated. In Examples 8 and 9, the base layer is mixed with a low thermal conductive material. Of these, Example 9 is a base layer divided into two layers, and the low thermal conductive material is mixed only in the lower layer. Comparative Example 1 in which the thermal conductivity adjusting material was not mixed in the underlayer was used as a control. Each of the temperature indicating material layers constituting these is composed of the temperature indicating material 1 which changes color at 27 ° C. The color tone of these specimens is measured by a test for erasing at a high temperature according to the color tone measurement method 1 described above, the degree of change in color tone at each measurement relative to the initial color tone is calculated, and the elapsed time and E _n / E ₁₈₀ ratio Sought the relationship. The result is shown in FIG.

Subsequently, Example 10 was investigated. In Example 10, a low thermal conductive material was mixed in the underlayer. Comparative example 2 in which the thermal conductivity adjusting material was not mixed in the underlayer was used. The temperature indicating material layer constituting them is composed of the temperature indicating material 2 which changes color at 5 ° C. The color tone of these specimens is measured by a test for color development at a low temperature by the above color tone measurement method 2, and the degree of change in color tone at the time of each measurement relative to the initial color tone is calculated. The elapsed time and the ratio of _En / E ₁₈₀ Sought a relationship. The result is shown in FIG.

From the results shown in FIG. 9 and FIG. 10, it can be seen that when the underlayer mixed with the low thermal conductivity material is used, the color tone slowly changes. Specifically, when the ratio E _n / E ₁₈₀ is 90%, the results of the test for decoloring at high temperature shown in FIG. 9 shows that the color tone changes about 10 seconds later than in Comparative Example 1 in which the thermal conductivity adjusting material is not mixed in the base material. From the result of the color development test at a low temperature shown in FIG. 10, Example 10 in which the low thermal conductivity material was mixed into the base material was delayed by about 10 seconds compared with Comparative Example 2 in which the thermal conductivity adjusting material was not mixed into the base material. It can be seen that changes. In addition, in the result of FIG. 9, regarding the change in color tone of Example 9 in which the base layer was divided into two layers and the low heat conductive material was mixed only in the lower layer, the low heat conductive material was mixed in the entire base layer (implementation) Although the change was faster than Example 8), it was found that the change was slower than that in which the low thermal conductivity material was not mixed in the underlayer (Comparative Example 1). In addition, this test is a rapid change in temperature, and the temperature change in actual pavement and construction materials is gentler than in this example. It is expected that the time difference in discoloration from the case of not doing will be larger.

  From these results, it can be seen that when the low thermal conductivity material is mixed in the base material, the color change of the temperature indicating material occurs slowly. Here, it has been found that when the high thermal conductivity material is mixed in one of the adjacent underlayers and the low thermal conductivity material is mixed in the other, the time difference in which the adjacent portions are discolored becomes larger. It is also clear that using this result, it is possible to make an arbitrary pattern appear temporarily at the time of color change by combining the underlayer with a different thermal conductivity in an arbitrary form. It became.

It is sectional drawing of a pavement. It is sectional drawing of the pavement currently formed so that the one part area | region of a base layer may differ from other surrounding area | regions in thermal conductivity. It is sectional drawing of construction material. It is sectional drawing of the construction material currently formed so that the one part area | region of a base layer may differ from the surrounding other area | region. (A) is sectional drawing of the specimen of an Example, (b) is sectional drawing of the specimen in which a base layer is divided into two layers among the specimens of an Example. (A) is a front view of the apparatus used for the color tone measuring method 1, and (b) is a front view of the apparatus used for the color tone measuring method 2. Is a graph showing the relationship between the elapsed time and the _E n _{/ E 180} ratio according to Examples 1 to 4 and Comparative Example 1. It is a graph showing a relationship between elapsed time and _E n _{/ E 180} ratio according to Example 5-7 and Comparative Example 2. It is a graph showing the relationship between the elapsed time and the _E n _{/ E 180} ratio according to Example 8 and 9 and Comparative Example 1. It is a graph showing the relationship between the elapsed time and the _E n _{/ E 180} ratio according to Example 10 and Comparative Example 2.

Explanation of symbols

10, 12, Pavement 20, 22, 70, 72, 120, 122 Underlayer 30, 32, 80, 82, 130, 132 Temperature indicating material layer 40, 42, 90, 92, 140, 142 Light-resistant layer 50 Pavement surface 60, 62 Construction materials

Claims (14)

An underlayer containing a white or other colored pigment or dye is formed on the paved road surface, and a temperature indicating material layer containing a thermoreversible temperature indicating material is formed on the underlayer. A pavement in which a light-resistant layer containing a light-resistant material is formed on a material layer,
The pavement is characterized in that the base layer includes a thermal conductivity adjusting material at least in part. The pavement according to claim 1,
The pavement characterized in that the thermal conductivity adjusting material is a high thermal conductive material. The pavement according to claim 1 or 2,
The underlayer is formed by applying a paint containing a white or other colored pigment or dye and a thermal conductivity adjusting material,
The temperature indicating material layer is formed by applying a paint containing the temperature indicating material,
The light-resistant layer is a pavement formed by applying a paint containing a light-resistant material. An underlayer containing a white or other colored pigment or dye, a temperature indicating material layer containing a thermoreversible temperature indicating material laminated on the underlayer, and a light-resistant material laminated on the temperature indicating material layer A resin plate integrated with a light-resistant layer containing,
The resin layer, wherein the underlayer includes a thermal conductivity adjusting material at least in part.   The pavement formed by sticking the resin board of Claim 4 on a pavement road surface. The pavement according to claim 5,
The resin plate is a pavement adhered on a pavement road surface with an adhesive containing a high thermal conductive material. An underlayer containing a white or other colored pigment or dye is formed on at least a part of the surface, and a temperature indicating material layer containing a thermoreversible temperature indicating material is formed on the underlayer, A construction material in which a light-resistant layer containing a light-resistant material is formed on the temperature indicating material layer,
The foundation material includes a thermal conductivity adjusting material at least in part. The construction material according to claim 7,
The construction material, wherein the thermal conductivity adjusting material is a high thermal conductivity material. The construction material according to claim 7 or claim 8,
The underlayer is formed by applying a paint containing a white or other colored pigment or dye and a thermal conductivity adjusting material,
The temperature indicating material layer is formed by applying a paint containing the temperature indicating material,
The light resistant layer is a construction material formed by applying a paint containing a light resistant material.   Construction material in which the resin plate according to claim 4 is adhered to at least a part of the surface. The construction material according to claim 10,
The resin plate is a construction material that is adhered by an adhesive containing a high thermal conductive material. An underlayer containing a white or other colored pigment or dye is formed on the paved road surface, and a temperature indicating material layer containing a thermoreversible temperature indicating material is formed on the underlayer. A pavement in which a light-resistant layer containing a light-resistant material is formed on a material layer,
The pavement is characterized in that the foundation layer is formed so that at least a part of the region is different in thermal conductivity from other surrounding regions. An underlayer containing a white or other colored pigment or dye is formed on at least a part of the surface, and a temperature indicating material layer containing a thermoreversible temperature indicating material is formed on the underlayer, A construction material in which a light-resistant layer containing a light-resistant material is formed on the temperature indicating material layer,
The construction material, wherein the underlayer is formed so that at least a part of the region has a thermal conductivity different from that of other surrounding regions. An underlayer containing a white or other colored pigment or dye, a temperature indicating material layer containing a thermoreversible temperature indicating material laminated on the underlayer, and a light-resistant material laminated on the temperature indicating material layer A resin plate integrated with a light-resistant layer containing,
The resin layer, wherein the base layer is formed such that at least a part of the region has a thermal conductivity different from that of other surrounding regions.

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