JP4623015B2 - Functional materials - Google Patents

Description

  The present invention relates to a functional material, and more particularly, to a functional material that has been given a functionality by subjecting a surface portion of a building material to a surface treatment.

Conventionally, as a building material used indoors and outdoors, many functional materials imparted with antibacterial property, antifungal property, antifouling property and the like have been used.
Such functional materials can be molded by mixing functional agents such as antibacterial agents and fungicides with resin materials, etc., or by surface treatment on various base materials and building materials. As described above, functionality was imparted by painting a paint containing a functional agent.
As in the former, in the process of mixing the functional agent with the material itself, only a part of the functional agent is exposed on the surface, and the performance of the functional agent mixed in the material is not exerted. There was a problem of wastefulness and high costs.
In the surface treatment that paints the surface containing the functional agent on the surface of the latter base material or building material, since it is applied directly to the surface of the building material, the performance of the contained functional agent is fully demonstrated. Even if you want to add functionality to only a part of the surface of the building material, it is necessary to paint the entire surface of the building material because the color tone of the surface of the building material will be lost and the design will be poor. There was a problem of high costs.

Moreover, in patent document 1, the decorative sheet used in order to provide antibacterial performance to various base materials is proposed.
This is a thermoplastic resin sheet, printing layer, adhesive layer, ethylene-vinyl alcohol copolymer (EVOH) film laminated in this order, embossed on the surface of the EVOH film that becomes the surface layer The embossed pattern is filled with ink added with an antibacterial agent by a wiping process to impart antibacterial properties to the decorative sheet.
Japanese Patent Laid-Open No. 10-119197 (see FIG. 2)

The decorative sheet described in Patent Document 1 can impart antibacterial performance to various substrates by sticking the decorative sheet to the surfaces of various substrates. However, since the ink to which the antibacterial agent is added is filled in the recesses of the embossed pattern by wiping, the ink is applied in addition to the recesses, and a wiping operation is required. For this reason, ink is wasted and a wiping work process is required.
Furthermore, even when there is no need to attach a paint or decorative sheet to the surface of the base material, it is necessary to apply a paint containing a functional agent or a decorative sheet mixed with a functional agent, resulting in high costs. There was a problem.

  The present invention has been proposed in order to solve the above-mentioned problems. The purpose of the present invention is to provide functionality at a low cost to a desired part of the surface portion of a building material and to demonstrate the functionality for a long time. It is to provide a functional material that can be sustained.

  In order to achieve the above object, the functional material according to claim 1 forms a plurality of fine holes in the surface portion of the building material by the dissolving agent discharged from the dissolving agent discharging device, The surface treatment is performed by filling the functional agent-containing solution with an ink jet coating jetting apparatus.

  In Claim 2, in Claim 1, the said solubilizer is an acidic or alkaline solution, It is characterized by the above-mentioned.

  In Claim 3, in Claim 1 or 2, the functional agent contained in the functional agent-containing solution is at least one of an antiseptic, an antibacterial agent, a deodorant, an insect repellent, a water repellent, a hydrophilic agent, and a photocatalyst. It is characterized by being one.

  A fourth aspect of the present invention is characterized in that in any one of the first to third aspects, a colorant is added to the functional agent-containing solution.

According to the first to fourth aspects of the present invention, the functional material is formed by dissolving the surface portion of the building material with the dissolving agent discharged from the dissolving agent discharging device to form a plurality of fine holes. Since the surface treatment is carried out by filling the fine holes with a functional agent-containing solution using an inkjet paint spraying device, the functional agent is mixed with the material itself or the paint containing the functional agent is applied to the entire surface of the substrate. Compared with the conventional thing which apply | coated or mixed the functional agent with the decorative sheet, and stuck on the base material, functionality is provided easily.
In addition, the functional material of the present invention is a surface treatment by filling the formed fine holes with a functional agent-containing solution with an inkjet coating jetting apparatus, so that the functional agent is also mixed inside the substrate. Compared to those imparted with functionality by wiping or the like, the functional agent-containing solution is not wasted and costs are reduced.
Furthermore, since it is set as the structure which ejects a functional agent containing solution with an inkjet coating injection apparatus, control is easy and functionality can be provided to the desired site | part of a building material. That is, since a fine hole can be formed in a site where functionality is desired and the functional agent-containing solution can be filled in the fine hole, functionality is limited to only the location where functionality needs to be imparted. It can be given and is low cost.
Furthermore, since it is set as the structure filled with the functional agent containing solution in the micropore formed in the surface part of a building material, each performance which various functional agents have can be maintained over a long period of time.

  According to the second aspect, since the dissolving agent is an acidic or alkaline solution, it is possible to easily adjust the size of the fine hole by adjusting the concentration and the discharge amount of the solution. For this reason, adjustment of the quantity of the functional agent with which the fine hole is filled can also be performed easily.

In claim 3, the functional agent contained in the functional agent-containing solution is at least one of preservatives, antibacterial agents, deodorants, insect repellents, water repellents, hydrophilic agents, and photocatalysts. By selectively containing a functional agent according to the construction site where the material is used, a functional material with high marketability is obtained.
In particular, as described above, since the surface treatment is performed by filling the functional agent-containing solution with the ink jet coating jetting apparatus, the filling position of the functional agent-containing solution can be finely controlled. For example, it is also possible to alternately fill a functional agent-containing solution containing functional agents having different performances into a plurality of formed fine holes, and a functional material having a plurality of functionalities depending on the construction location It can also be.

In Claim 4, since the coloring agent is added to the said functional agent containing solution, functionality can be provided to the surface part of a building material, and coloring is also attained.
In particular, as described above, the surface treatment is performed by filling the functional agent-containing solution with the ink jet coating spraying apparatus. For example, it is possible to print complicated and fine patterns by forming fine holes densely. It becomes possible.
Further, if the colorant is the same color as the surface portion of the building material, the appearance is not impaired even when the functional agent-containing solution is filled in the fine holes.

Embodiments of the present invention will be described below with reference to the drawings.
FIGS. 1 to 3 show an example of an embodiment of a functional material according to the present invention, and FIG. 1A is a schematic cross-sectional view showing one step of a process of forming a functional material according to the embodiment. b) is a schematic cross-sectional view showing an example of a functional material, FIG. 2 is a schematic plan view for explaining a functional material forming process according to the embodiment, and FIGS. (c) is a schematic sectional drawing which shows the other process of the formation process of the functional material which concerns on the embodiment, respectively.

As shown in FIG. 1B, the functional material 10 of the present embodiment is a functional agent as described later in a plurality of fine holes 11b formed in the surface portion 11a of the building material 11 formed in a plate shape. The containing portion 14b is formed.
As the building material 11, in this embodiment, a decorative board 11 in which a resinous decorative sheet layer 13 is attached to a wooden base material 12 such as a laminated board, a plywood, a particle board, and a wooden fiber board is used. The sheath type is not particularly limited, and the present embodiment can be applied to other woody materials, resin materials, and the like that have been widely used as interior building materials and exterior building materials of buildings.
As other woody materials, at least the surface layer may be woody and can be applied to solid wood, laminated wood, plywood, particleboard, wood fiberboard, and the like. Alternatively, these can be applied to a base material or a resin base material to which a decorative layer such as a wood veneer is attached.
Further, as the resin material, it is sufficient that at least the surface layer is resin-based, and it can be applied to a synthetic resin such as plastic.
Furthermore, the shape is not limited to a plate-like shape as shown in the figure, and the present invention can be applied to various shapes of building materials such as a prismatic shape, a cylindrical shape, and a conical shape.
Moreover, as construction sites where the functional material 10 is used, it can be used for interior and exterior, for example, doors, floors, stairs, fences, pillars, handrails, shelves, kitchen panels, ceilings, various furniture cabinets, Suitable for top plate, inner wall, etc.

FIG. 2 schematically shows various apparatuses for forming the functional material 10, 20 is a base on which the building material 11 is placed, 21 is a dissolving agent discharge apparatus, 31 is a drying apparatus, and 25 is Inkjet paint injection device 30 is a control device for controlling operation of each device, and 29 is a signal line connecting each device and control device 30.
The base 20 is formed in accordance with the shape and size of the building material 11 and forms a part of the transport line. When the functional material 10 is formed as will be described later, the base 20 is transported by, for example, a belt conveyor. The functional material 10 is transported toward the next process by means (not shown).

The dissolving agent discharge device 21 includes a device main body 21a disposed adjacent to the base 20, and a discharge nozzle head guide rod 22 that is connected to the device main body 21a and guides the discharge nozzle head 23. Is configured to be movable in the white arrow Y direction (longitudinal direction of the building material 11) with respect to the building material 11 placed on the base 20.
The discharge nozzle head guide rod 22 is supported by the device main body 21a and a guide rod support portion 24 disposed to face the device main body 21a with the base 20 interposed therebetween.
The discharge nozzle head 23 is configured to be movable in the direction of the white arrow X (the width direction of the building material 11) along the discharge nozzle head guide rod 22, and an acidic or alkaline solution 35 is used as a dissolving agent on the back surface. A plurality of discharge nozzles 23a (see FIG. 3B).
In the present embodiment, the discharge nozzle head 23 has four discharge nozzles 23a arranged in a line along the direction of the white arrow X.

The acidic or alkaline solution 35 discharged from the discharge nozzle 23a toward the surface portion 11a of the building material 11 can be appropriately selected according to the physical properties of the surface portion 11a of the building material 11, but the acidic or alkaline solution 35 It is preferable to use a strong acid or strong alkaline solution capable of forming the fine hole 11b having a diameter of about 20 μm to 2 mm when the surface portion 11a is dissolved by discharge. For example, hydrochloric acid, sulfuric acid, sodium hydroxide or the like is used as a solvent such as water. The solution diluted with is mentioned.
Further, the dissolving agent is not limited to the acidic or alkaline solution 35, but the surface portion 11a of the building material 11 such as acidic or alkaline powder is dissolved to form the fine hole 11b having a diameter of about 20 μm to 2 mm. Anything can be obtained.
As an aspect in which the acidic or alkaline solution 35 is discharged from the discharge nozzle 23a, an inkjet nozzle driving method is used, as in the case of the discharge nozzle 27a described later. As a result, as will be described later, fine control can be easily performed, and a desired fine hole 11b can be easily formed.
The diameter of the discharge port of the discharge nozzle 23a will be described later.

The drying apparatus 31 includes an apparatus main body 32 disposed adjacent to the base 20, a support portion 33 disposed to face the apparatus main body 32 with the base 20 interposed therebetween, and the apparatus main body 32 and the support portion 33. The entire apparatus is configured to be movable in the direction of the white arrow Y with respect to the building material 11 placed on the base 20.
The drying unit 34 has a hot air outlet 34a that is formed in an elongated shape along the white arrow Y direction on the back surface thereof and opens downward.

The ink jet coating / injecting apparatus 25 includes an apparatus main body 25a disposed adjacent to the base 20, and a nozzle head guide rod 26 that is connected to the apparatus main body 25a and guides the nozzle head 27. The building material 11 placed on the table 20 is configured to be movable in the white arrow Y direction.
The nozzle head guide rod 26 is supported by a guide rod support portion 28 disposed opposite to the apparatus main body 25a with the base 20 interposed therebetween, and the apparatus main body 25a.
The nozzle head 27 is configured to be movable in the direction of the white arrow X along the nozzle head guide rod 26, and a plurality of ejection nozzles 27a (FIG. 1) for ejecting a functional agent-containing solution 14a to be described later are formed on the back surface. (See (a)).
In this embodiment, as shown in FIG. 1A, the nozzle head 27 has four ejection nozzles 27a arranged in a line along the direction of the white arrow X, that is, the plurality of ejection nozzles. The number of ejection nozzles 27a is the same as the number of ejection nozzles 27a, and the number of ejection nozzles 27a is the same as that of the plurality of ejection nozzles 23a.

The diameter of the ejection port of the ejection nozzle 23a and the diameter of the ejection port of the ejection nozzle 27a can be appropriately selected according to the diameter of the fine hole 11b to be formed, but is preferably about 5 μm to 500 μm or acidic. Alternatively, it is preferable to set the diameter so that the dot diameter is about 10 μm to 1 mm when the alkaline solution 35 is discharged and the functional agent-containing solution 14a described later is ejected and landed.
The inkjet nozzle driving method for ejecting the functional agent-containing solution 14a described later from the ejection nozzle 27a is not particularly limited, and the diameter of the fine holes 11b, the physical properties of the surface layer 11a of the building material 11, and the functional agent described later. A publicly known one can be appropriately selected according to the physical properties and the like of the contained solution 14a, and an arbitrary one such as a drop-on-demand piezo method, a drop-on-demand valve method, or a continuous charging deflection method can be applied.

The functional agent-containing solution 14a is a solution in which, for example, a resin, a solvent, a curing agent, an additive, or the like is mixed with a functional agent described later, and a known inkjet ink, for example, methyl ethyl ketone, ethanol, acetone, or the like is used as a solvent. Quick-drying inks, oil-based oil-based inks, UV curable inks that are cured by irradiating ultraviolet rays, water-based inks, and the like are applicable, but are configured so as not to impair the performance of the functional agents contained, and at least weather resistance and water resistance It is preferable to have it.
In addition, it is preferable that the functional agent-containing solution 14a is appropriately selected according to the above-described inkjet nozzle driving method and the physical properties of the surface portion 11a of the building material 11, for example, permeability, etc. The hole 11b is preferably impregnated with the fine hole 11b when it is dried and solidified without impregnation, and preferably contains an acrylic, methacrylic, urethane, or fluorine resin. .

  Examples of the functional agent contained in the functional agent-containing solution 14a include preservatives, antibacterial agents, deodorants, insect repellents, water repellents, hydrophilic agents, and photocatalysts. Moreover, it is good also as what contained 2 or more types. Examples of preservatives include parabens and sorbic acid. Examples of the antibacterial agent and deodorant include silver. Examples of insect repellents include paradichlorobenzene and naphthalene. Examples of the water repellent include a fluorine-based filler and silicone, and examples of the hydrophilic agent include silica sol. Examples of the photocatalyst include titanium oxide, zinc oxide, strontium titanate, tungsten trioxide, ferric oxide, bismuth trioxide, and tin oxide.

Such a functional agent may be dissolved in the above-described solvent to become a liquid or particles dispersed in the solvent depending on the physical properties. Moreover, although the compounding quantity changes with functional agents, what is necessary is just to be 0.1 weight%-20 weight%.
In addition, when dispersing particles in a solvent, those having a particle diameter of several nm to several μm are preferable as the particles to be used, and it is preferable to appropriately mix a known dispersion medium so that precipitation or the like does not occur.
In addition, the mixing ratio of each constituent material of the functional agent-containing solution 14a can be appropriately selected according to the physical properties of the building material 11, the construction location, the resin, the solvent, and the physical properties of the functional agent.
Furthermore, it is good also as a structure which adds colorants, such as dye and a pigment, to the functional agent containing solution 14a. According to this, while being able to provide functionality to the surface part 11a of the building material 11, coloring is also possible. In particular, since the surface treatment is performed by filling the functional agent-containing solution 14a with the ink jet paint injection device 25, for example, by forming the fine holes 11b densely, a complicated and fine pattern or the like is formed on the surface of the building material 11. Can be printed.
Moreover, when adding a coloring agent to the functional agent containing solution 14a, you may add the coloring agent matched with the color of the surface part 11a of the building material 11. FIG. According to this, the functional agent-containing portion 14b formed by the functional agent-containing solution 14a filled in the fine holes 11b becomes inconspicuous, and thus the appearance of the functional material 10 is not impaired and the design property is excellent. Become.

Next, the process for forming the functional material 10 will be described.
First, the building material 11 is placed on the base 20 (see FIG. 3A), the dissolving agent discharge device 21 is driven, the discharge nozzle head 23 is moved XY, and the above-described acidic or alkaline solution. 35 is discharged from the discharge nozzle 23a toward a desired portion of the surface portion 11a of the building material 11, that is, a portion where the fine hole 11b is to be formed (see FIG. 3B).
The surface portion 11a of the building material 11 is dissolved by the discharged acidic or alkaline solution 35 to form the fine hole 11b.
At this time, fine holes 11b may be formed on the entire surface of the building material 11 at regular intervals, but depending on the construction location of the functional material 10, the fine holes are formed only in a desired portion where functionality is desired. It is good also as a structure which forms 11b.
At this time, the dissolution agent discharge device 21 may be controlled based on a program stored in advance in a memory or the like of the control device 30, or the control device 30 may be operated to place a plurality of micro holes 11b in a desired part. The fine hole formation data may be stored in a memory or the like.

Further, the concentration and the number of droplets of the acidic or alkaline solution 35 discharged from the discharge nozzle 23a are preferably set as appropriate so that the diameter of the fine hole 11b is about 20 μm to 2 mm as described above.
Furthermore, it is preferable that the diameter of the fine hole 11b is, for example, about 20 μm to 500 μm. By setting the thickness to 20 μm or more, the filled functional agent is fixed, and the performance can be exhibited for a long time. Moreover, even if the functional agent-containing solution 14a is not filled, the surface of the building material 11 is not changed and the appearance is hardly harmed by being 500 μm or less.

Moreover, it is preferable to wash the surface of the building material 11 with water or the like after discharging the acidic or alkaline solution 35 to dissolve the surface portion 11b and forming the fine holes 11b. Or it is good also as an aspect which neutralizes by discharging and spraying a neutralizer, and also wash | cleans.
As described above, when cleaning is performed after the formation of the fine holes 11b, it is preferable to drive the above-described drying device 31 to dry the surface of the building material 11 after cleaning, as shown in FIG.
In addition, as a neutralizing agent, it can select suitably according to the discharged acidic or alkaline solution 35, for example, when discharging the acidic solution and forming the fine hole 11b, a weak alkaline baking soda is sprayed. Alternatively, when the microhole 11b is formed by discharging an alkaline solution, a weakly acidic acetic acid solution may be discharged.

After the fine holes 11b are formed in the surface portion 11a of the building material 11 as described above, the ink jet coating injection device 25 is driven, and the nozzle head 27 is positioned so that each of the injection nozzles 27a is located above the plurality of fine holes 11b. Is moved XY, the functional agent-containing solution 14a is ejected, and the functional agent-containing solution 14a is filled in the plurality of micro holes 11b (see FIG. 1A).
The movement control of the nozzle head 27 may be controlled based on a program stored in advance in a memory or the like of the control device 30, or stored in the control device 30 when the fine hole 11b is formed as described above. It is good also as a structure controlled based on the formed fine hole formation data. Furthermore, it is good also as a structure which detects the micro hole 11b formed by the distance sensor, the optical sensor, etc., and controls the movement of the nozzle head 27.

As described above, the functional agent-containing solution 14a filled in the fine holes 11b is dried and solidified to form the functional agent-containing portion 14b on the surface portion 11a of the building material 11, as shown in FIG. A functional material 10 is formed.
The number of droplets of the functional agent-containing solution 14a ejected from the ejection nozzle 27a is preferably set as appropriate according to the size of the fine holes 11b and the size of the droplets, and the droplets are dried and solidified to function. When the agent-containing portion 14b is formed, it is preferable to set the amount so that the fine hole 11b is substantially closed and smoothed with the other surface where the fine hole 11b of the building material 11 is not formed.

Moreover, when forming the functional agent containing part 14b as mentioned above, it is preferable to apply the functional agent containing solution 14a according to the construction location of the functional material 10, for example, water such as a kitchen or a bathroom vanity. When applied around, it is preferable to contain an antibacterial agent and a water repellent.
Further, when a plurality of functionalities are desired to be imparted to the surface portion 11a of the building material 11, the formed fine holes 11b are alternately filled with the functional agent-containing solution 14a containing functional agents having different performances. It is good also as composition to do.
Furthermore, it is good also as a structure which forms the functional agent containing part 14b only in the site | part which wants to provide functionality, for example, an insect repellent only to the outer periphery vicinity part of a front door, the skirt part near the floor surface of a kitchen cabinet or a pillar, etc. It is good also as a structure which forms the functional agent containing part 14b in which was contained.
In particular, in the present embodiment, since the functional agent-containing solution 14a is ejected by the ink jet coating / injecting device 25, control is easy, and functionality can be imparted to a desired portion of the building material 11. That is, since the fine hole 11b can be formed in the part where functionality is desired and the functional agent-containing solution 14a can be filled in the fine hole 11b, the function is limited to only the part where functionality needs to be imparted. Property can be imparted and the cost is low.

As described above, in the present embodiment, the functional material 10 is filled with the functional agent-containing solution 14a in the fine holes 11b formed in the surface portion 11a of the building material 11 by the ink jet coating spray device 25, and is subjected to surface treatment. Conventionally, functional agents are mixed into the material itself, paints containing functional agents are applied to the entire surface of the base material, and functional agents are applied to and mixed with a decorative sheet and pasted onto the base material. Functionality is easily imparted compared to the above.
In addition, since the functional material 10 is surface-treated by filling the formed fine holes 11b with the functional agent-containing solution 14a by the inkjet coating injection device 25, the functional agent is also mixed inside the base material. Compared with a thing provided with functionality by things, wiping processing, etc., waste does not arise in functional agent content solution 12a, and it becomes low cost.

Furthermore, since it is set as the structure filled with the functional agent containing solution 14a in the fine hole 11b formed in the surface part 11a of the building material 11, each performance which various functional agents have can be maintained over a long period of time. .
Furthermore, functionality can be imparted by applying a surface treatment to the surface of a building material that does not require the application of a paint or decorative sheet to the surface as described above.
In the present embodiment, since the acidic or alkaline solution 35 is used as the dissolving agent, the size of the fine hole 11b can be easily adjusted by adjusting the concentration and discharge amount of the solution. . For this reason, adjustment of the quantity of the functional agent with which the micro hole 11b is filled can also be performed easily.
Further, as described above, the discharge nozzles 23a of the dissolving agent discharge device 21 and the discharge nozzles 27a of the ink jet coating injection device 25 have the same number, and the arrangement intervals are also the same. The functional agent-containing solution 14a can be ejected toward the fine holes 11b that are easily formed by simple control.

  In the present embodiment, as the building material 11, a decorative board 11 in which a resin decorative sheet layer 13 is attached to a wooden base material 12, that is, a surface layer of a resin base is used. In addition, the surface layer may be made of wood. With conventional products that add functionality by applying decorative sheets made of paint or synthetic resin, the texture, texture, fragrance, etc. peculiar to solid wood are impaired. If this invention is applied, it will become the functional material 10 which provided the functionality to the surface part 11a, without impairing the texture peculiar to solid wood.

In the present embodiment, the discharge nozzle head 23 of the dissolving agent discharge device 21 and the nozzle head 27 of the inkjet coating injection device 25 are configured to move XY relative to the building material 11. -Y may be configured to move, or the building material 11 may be configured to be movable in the Y direction, and the discharge nozzle head 23 and the nozzle head 27 may be configured to be movable in the X direction with respect to the building material 11. Good.
Further, the number and shape of the discharge nozzles 23a of the discharge nozzle head 23 and the ejection nozzles 27a of the nozzle head 27 are not limited to those shown in the drawings, and may be appropriately determined according to the configuration of each device, the shape and size of the fine holes, and the like. Selectable.
Furthermore, in this embodiment, the fine holes 11b are formed and dried, and the functional agent-containing portion 14b is formed on one base 20, but each process is carried over a plurality of bases. Needless to say, this may be done in any other manner.

Alternatively, an adhesive layer for easily fixing the functional agent to the fine hole 11b may be formed after the fine hole 11b is formed and before the functional agent-containing solution 14a is filled.
Furthermore, as long as the functionality of the functional agent-containing portion 14b is not hindered, for example, a breathable decorative sheet may be further adhered to the surface after the functional agent-containing portion 14b is formed on the surface portion 11a. .
Furthermore, when the fine hole 11b is formed relatively large and the dried and solidified functional agent-containing portion 14b protrudes from the surface, the surface may be smoothed with a scraper or the like.

An example of embodiment of the functional material which concerns on this invention is shown, (a) is a schematic sectional drawing which shows 1 process of the formation process of a functional material, (b) is a schematic sectional drawing which shows an example of a functional material It is. It is a schematic plan view for demonstrating the formation process of the functional material which concerns on the same embodiment. (A), (b), (c) is a schematic sectional drawing which shows each other process of the formation process of the functional material which concerns on the embodiment.

Explanation of symbols

10 Functional materials 11 Decorative panels (building materials)
11a Surface (building material)
11b Fine hole 12 Wood base material (building material)
13 Resin decorative sheet layer (building material)
14a Functional agent-containing solution 21 Dissolving agent discharge device 25 Inkjet coating spray device 35 Acidic or alkaline solution (dissolving agent)

Claims (4)

  A plurality of fine holes are formed on the surface portion of the building material by the dissolving agent discharged from the dissolving agent discharge device, and the fine agent is filled with the functional agent-containing solution by an inkjet coating spray device and surface-treated. A functional material characterized by In claim 1,
The functional material, wherein the solubilizer is an acidic or alkaline solution. In claim 1 or 2,
The functional material contained in the functional agent-containing solution is at least one of an antiseptic, an antibacterial agent, a deodorant, an insect repellent, a water repellent, a hydrophilic agent, and a photocatalyst. . In any one of Claims 1 thru | or 3,
A functional material, wherein a colorant is added to the functional agent-containing solution.

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