JP2024069099A - Color changing planter - Google Patents

Abstract

[Problem] To provide a highly convenient color-changing planter that allows the amount of moisture in the culture medium to be visually confirmed and allows watering at an appropriate time, even for home plant cultivation where industrial management is not possible. [Solution] A planter 2 for cultivating plants made of nonwoven fabric, with a porous layer 3 on at least a part of the outer surface, in which a low refractive index pigment is fixed in a dispersed state in a binder resin, and which has different transparency between a liquid-absorbing state and a liquid-non-absorbing state, and a color-changing planter 1 in which watering a plant 5 causes moisture to leak from the inner surface of the planter to the outer surface through the culture medium 4, causing the porous layer 3 to change appearance. [Selected Figure] Figure 1

Description

The present invention relates to a color-changing planter. More specifically, the present invention relates to a color-changing planter that allows the presence or absence of moisture in the soil to be visually confirmed from the outer surface.

Traditionally, pottery or plastic planters have been widely used as planter (flowerpot) for cultivating plants, but in recent years there has been an increasing demand for cloth planters made of nonwoven fabrics and the like because they are lightweight, durable, and have excellent breathability and moisture retention properties.
Fabric planters are used not only for home cultivation but also in industrial garden systems because they allow outside air to easily enter the culture medium, such as soil or nonwoven fabric, through the walls when plants are being grown, which helps plants to take root better and speeds up growth (see, for example, Patent Documents 1 and 2).

JP 2017-169550 A JP 2011-130757 A

When cultivated industrially using a garden system such as that in Patent Document 1, multiple planters are managed systematically under the same conditions, so that environmental addition and watering can be performed under uniformly determined conditions. Therefore, fabric planters can be used without worrying about the timing of watering. However, in the case of home planters such as those in Patent Document 2, depending on the location, the medium is more likely to dry out in places exposed to sunlight or wind from an air conditioner, and the moisture in the medium is less likely to evaporate in places in the shade, so it has the disadvantage that it is difficult to check the moisture content. In order to check the moisture content, it is necessary to touch the surface of the planter to check the wetness, so when installed under conditions where the wetness varies depending on the place touched, it is difficult to check the appropriate moisture content and to time watering.

The present invention solves the above-mentioned problems by providing a highly convenient color-changing planter that allows the moisture content of the medium to be visually confirmed and allows watering at the appropriate time, even in home plant cultivation where industrial management is not possible.

The present invention is a planter for growing plants made of nonwoven fabric, which has a porous layer on at least a part of its outer surface, in which a low refractive index pigment is fixed in a dispersed state in a binder resin, and which has different transparency between a liquid-absorbing state and a liquid-non-absorbing state, and which is a color-changing planter in which the appearance of the porous layer changes as water leaks from the inner surface of the planter through the culture medium when plants are watered.
A further requirement is that a colored layer be provided between the porous layer and the outer surface of the planter.
Furthermore, it is a requirement that the back surface of the color-changing nonwoven fabric on which the porous layer is provided on the surface of the substrate is integrated with the outer surface of the planter by a needle punching method while in contact with the outer surface of the planter, and that a colored layer is provided between the porous layer and the substrate.
Furthermore, it is a requirement that the surface of the color-changing nonwoven fabric, in which the porous layer and the colored layer are laminated in this order on the surface of the substrate, is integrated with the outer surface of the planter by a needle punching method while in contact with the surface.
Further requirements are that the basis weight of the nonwoven fabric constituting the planter is greater than the basis weight of the base material of the color-changing nonwoven fabric, that the basis weight of the base material of the color-changing nonwoven fabric is in the range of 30 to 100 g/ ^m2 , and that the basis weight of the nonwoven fabric constituting the planter is in the range of 101 to 1000 g/ ^m2 .

The present invention makes it easy to visually check the moisture content of the medium during plant cultivation, providing a highly convenient color-changing planter that allows watering at the right time without excess or deficiency.

FIG. 1 is an explanatory diagram of one embodiment of a color-changing planter of the present invention. FIG. 2 is a cross-sectional view illustrating a main portion of FIG. 1 . FIG. 2 is an explanatory cross-sectional view of a main portion of another embodiment of a color-changing planter of the present invention. FIG. 13 is an explanatory cross-sectional view of a main portion of another embodiment of a color-changing planter of the present invention. FIG. 2 is an explanatory cross-sectional view of a main portion of another embodiment of a color-changing planter of the present invention. FIG. 13 is an explanatory cross-sectional view of a main portion of another embodiment of a color-changing planter of the present invention.

The color-changing planter of the present invention is a container that contains a medium for growing plants together with plants, and is made of nonwoven fabric. At least a portion of the outer surface (part exposed to the outside air) of the planter (container) is provided with a porous layer. With this configuration, water poured into the plant when watering leaks through the medium from the inner surface (space containing the medium) of the planter to the outer surface (part exposed to the outside air), causing the porous layer to change appearance, making it possible to visually confirm the presence or absence of water.

Nonwoven fabrics that make up planters (containers) can be divided into several types depending on the method used to bond the fibers from a web of accumulated fibers. Methods for bonding the fibers of a web include the chemical bonding method, in which the intersections of fibers are bonded with a resin adhesive, the thermal bonding method, in which a thermoplastic resin is mixed and the fibers are fused together by thermocompression bonding, the needle punch method, in which the fibers are pierced repeatedly with a needle to entangle them, and the hydroentanglement method, in which the fibers are entangled by spraying a high-pressure water stream.
When using a color-changing nonwoven fabric with a porous layer to form a porous layer on a planter in the present invention, a needle can be pierced while the nonwoven fabric is superimposed on the color-changing nonwoven fabric, causing some of the fibers of the nonwoven fabric to be pulled out and pass through the meshes of the color-changing nonwoven fabric while also becoming entangled with the threads of the color-changing nonwoven fabric. Therefore, a nonwoven fabric whose fibers have been entangled by a needle punch method or a water flow entanglement method is preferable in that the fibers are easily pulled out when pierced with a needle.

The raw material of the fibers that make up the nonwoven fabric is not particularly limited, and can be natural fibers such as cotton, hemp, and wool, synthetic fibers, semi-synthetic fibers, regenerated fibers, or a mixture of two or more of these. Note that the JIS standard does not include felt made by entangling animal hair by wet heat treatment, but does include felt made by entangling 100% synthetic fibers or fibers mixed with synthetic fibers using a needle punch method, but in the present invention, any felt is defined as being included in the nonwoven fabric.

The nonwoven fabric is one that retains its shape without deformation when containing a culture medium such as soil, and has a liquid absorption and retention capacity after watering. The weight per unit area is 101 to 1000 g/m ² , preferably 120 to 500 g/m ² , and more preferably 150 to 420 g/m ² . If the weight per unit area is less than 101 g/m ² , the strength of the planter may be weakened, and the water retention performance may also be reduced. If the weight per unit area is more than 1000 g/m ² , the product weight may be large, or the weight at the time of water supply may be large, which may reduce the ease of handling.

The outer surface of the planter (container) is provided with a porous layer in which a low refractive index pigment is dispersed and fixed in a binder resin, and which has different transparency in a liquid-absorbent state and a liquid-non-absorbent state. In particular, it is preferable to provide the layer at a location (height) where a culture medium such as soil is to be stored, rather than near the opening.
Examples of the low refractive index pigment include silicic acid and/or silicate salts, baryte powder, barium sulfate, barium carbonate, calcium carbonate, gypsum, clay, talc, alumina white, magnesium carbonate, and the like, which have a refractive index in the range of 1.4 to 1.8 and exhibit good transparency when absorbing a liquid.
Examples of the silicate include aluminum silicate, potassium aluminum silicate, sodium aluminum silicate, calcium aluminum silicate, potassium silicate, calcium silicate, sodium calcium silicate, sodium silicate, magnesium silicate, and potassium magnesium silicate.
The particle size of the low refractive index pigment is not particularly limited, but a particle size of 0.03 to 10.0 μm is preferably used.
Two or more of the low refractive index pigments can be used in combination.
An example of a low refractive index pigment that is preferably used is silicic acid.
The silicic acid may be silicic acid produced by a dry method (hereinafter referred to as dry method silicic acid), but silicic acid produced by a wet method (hereinafter referred to as wet method silicic acid) is preferred.
This point will be explained below.
Silica is produced as non-crystalline amorphous silicic acid, and depending on the production method, it can be roughly divided into dry methods using a gas phase reaction such as thermal decomposition of silicon halides such as silicon tetrachloride, and wet methods using a liquid phase reaction such as decomposition with an acid such as sodium silicate.
Dry process silicic acid and wet process silicic acid have different structures. Dry process silicic acid has a structure in which silicic acid is densely bonded, whereas wet process silicic acid has a structural portion in which silicic acid is condensed to form a long molecular arrangement.
Therefore, since the molecular structure of wet-process silicic acid is coarser than that of dry-process silicic acid, it is presumed that when wet-process silicic acid is applied, it has superior diffuse reflection of light in a dry state and has greater hiding power than a system using dry-process silicic acid.
In addition, since the porous layer absorbs water, wet-process silicic acid has more hydroxyl groups present as silanol groups on the particle surface than dry-process silicic acid and has a higher degree of hydrophilicity, and is therefore preferably used.

Examples of the binder resin include urethane resins, nylon resins, vinyl acetate resins, acrylic ester resins, acrylic ester copolymer resins, acrylic polyol resins, vinyl chloride-vinyl acetate copolymer resins, maleic acid resins, polyester resins, styrene resins, styrene copolymer resins, polyethylene resins, polycarbonate resins, epoxy resins, styrene-butadiene copolymer resins, acrylonitrile-butadiene copolymer resins, methyl methacrylate-butadiene copolymer resins, butadiene resins, chloroprene resins, melamine resins, and emulsions of each of the above resins, casein, starch, cellulose derivatives, polyvinyl alcohol, urea resins, and phenol resins.
The mixing ratio of the low refractive index pigment and the binder resin depends on the type and properties of the low refractive index pigment, but is preferably 0.5 to 2 parts by mass, more preferably 0.8 to 1.5 parts by mass, of the binder resin solid content per part by mass of the low refractive index pigment. If the binder resin solid content is less than 0.5 parts by mass per part by mass of the low refractive index pigment, it tends to be difficult to obtain a practical film strength of the formed porous layer, and if it exceeds 2 parts by mass, there is a risk that the permeability of water into the inside of the porous layer will deteriorate.
The porous layer has a smaller mixing ratio of binder resin to colorant than a general coating film, so it is difficult to obtain sufficient film strength. Therefore, it is preferable to use nylon resin or urethane resin among the binder resins to increase the abrasion resistance.
The urethane resin may be a polyester urethane resin, a polycarbonate urethane resin, a polyether urethane resin, etc., and two or more of them may be used in combination. In addition, a urethane emulsion resin in which the resin is emulsified and dispersed in water, or a colloidal dispersion type (ionomer type) urethane resin in which the urethane resin having ionic properties (urethane ionomer) is self-emulsified without the need for an emulsifier due to the ionic group of the resin itself, and dissolved or dispersed in water, may be used.
The urethane resin may be either an aqueous urethane resin or an oil-based urethane resin, but an aqueous urethane resin, particularly an urethane emulsion resin or a colloidal dispersion type urethane resin, is preferably used.
The urethane-based resin can be used alone, but can also be used in combination with other binder resins depending on the type of container and the performance required for the film. When a binder resin other than the urethane-based resin is used in combination, in order to obtain a practical film strength, it is preferable that the binder resin of the porous layer contains the urethane-based resin in a solid content ratio of 30 mass% or more.
In the above-mentioned binder resin, if it is crosslinkable, the strength of the film can be further improved by adding an arbitrary crosslinking agent to crosslink the binder resin.
The binder resin has a large or small affinity with water, and by combining these, it is possible to adjust the time for penetration into the porous layer, the degree of penetration, and the drying speed after penetration. Furthermore, the above adjustment can be controlled by adding a dispersant as appropriate.
The porous layer may also contain a colorant.

The porous layer can be formed directly on the outer surface of the planter by known means, such as printing means such as screen printing, offset printing, gravure printing, coater, pad printing, transfer printing, brush painting, spray painting, electrostatic painting, electrocoating, flow painting, roller painting, dip painting, etc.
Furthermore, a method can be applied in which a separate nonwoven fabric or other fabric is used as a substrate, a porous layer is disposed on the substrate by the above-mentioned method to form a color-changing nonwoven fabric, and then the fabric is integrated with the outer surface of the planter. Although adhesion, pressure bonding, etc. are possible as a means of integration, it is preferable to use the needle punch method, since the nonwoven fabric has the characteristic of intertwining and fixing the fibers to each other, the outer surface of the planter and the color-changing nonwoven fabric can be firmly attached, and multiple fine holes through which moisture can flow to the porous layer side can be formed. The color-changing nonwoven fabric can be integrated by contacting the back surface (the surface without the porous layer) with the outer surface of the planter, or by contacting the front surface (the surface with the porous layer) with the outer surface of the planter depending on the thickness, transmittance, and basis weight of the substrate.
The production using the above-mentioned color-changing nonwoven fabric is particularly preferable because it is easy to form a porous layer with a uniform thickness and the production efficiency is high.

A coloring agent may be contained in the porous layer, or a water-permeable coloring layer containing a coloring agent may be provided between the outer surface of the planter and the porous layer. Furthermore, when a color-changing nonwoven fabric is used, a coloring layer may be provided between the substrate and the porous layer, on the surface of the porous layer, or on the back surface of the substrate (on the surface where the porous layer is not provided). The coloring layer may be formed in the form of a design or pattern (image), which can further increase added value.
By making the colored layer contain a colored colorant of a different hue from the outer surface of the planter and the base material of the color-changing nonwoven fabric, the hue of the colored layer, which is different from the hue of the planter and the base material, can be visually recognized when the porous layer has absorbed liquid, making it possible to more clearly visually determine whether there is moisture inside the planter.

The porous layer may also be provided with a water-repellent resin layer.
The water-repellent resin layer is a layer that is present within and coexists with the porous layer obtained by applying a water-repellent treatment liquid containing a water-repellent resin selected from silicone-based, paraffin-based, polyethylene-based, alkylethylene urea-based, fluorine-based, and other water-repellent resins to a porous layer so as to form an image of an appropriate shape, and then penetrating and drying the liquid.
Since the water-repellent resin layer is present within a part of the porous layer and is arranged in a coexisting state, the porous layer in the coexisting portion of the water-repellent resin layer does not absorb water due to the water-repellent effect, and the opaque state is maintained.
Therefore, the water-repellent resin layer and the porous layer, which are difficult to distinguish in a dry state, can be distinguished by the absorption of liquid into the porous layer in the portion where the water-repellent resin layer is not provided.
Here, the water-repellent resin layer that is arranged in a coexisting state with the porous layer may be in a state where the water-repellent resin layer coexists from the upper layer of the porous layer to the lower layer of the porous layer located on the outer surface of the container, in addition to a state where the water-repellent resin layer coexists from the upper layer of the porous layer to the middle of the porous layer, a state where the water-repellent resin layer coexists in the middle of the porous layer, and a state where the water-repellent resin layer coexists from the middle of the porous layer to the lower layer of the porous layer.

Furthermore, by incorporating a transparent metallic pigment in which a transparent core material is coated with a metal oxide or a transparent metallic pigment with color flop properties into the porous layer, a color-changing planter can be obtained in which the color of the low refractive index pigment is visible in the dry state, and the metallic luster color of the transparent metallic pigment is visible in the liquid-absorbing state.
Examples of transparent metallic luster pigments include pigments having a core material of natural mica, synthetic mica, glass, or alumina, the surface of which is coated with an oxide of a metal such as titanium, zirconium, chromium, vanadium, or iron.
Examples of transparent metallic luster pigments having color flop properties include cholesteric liquid crystal type transparent metallic luster pigments and transparent metallic luster pigments in which silicon oxide is coated with one or more types of metal oxides.
In order to visually recognize a clear metallic luster color in the liquid-absorbed state, it is preferable that the colored layer contains a metallic luster pigment.

Furthermore, by incorporating a reversible thermochromic material or photochromic material into the porous layer, or by providing a layer containing a reversible thermochromic material or photochromic material between the outer surface of the planter and the porous layer, it is possible to impart a variety of color changes in response to temperature changes or exposure to light.

The substrate constituting the color-changing nonwoven fabric is a nonwoven fabric for forming a porous layer or a colored layer on the surface, so one with a low basis weight and small surface irregularities is used. The basis weight is in the range of 30 to 100 g/m ² , preferably 40 to 80 g/m ^2. If the basis weight is less than 30 g/m ² , the ink for printing and coating tends to penetrate to the back side when forming the porous layer or colored layer by printing and coating, making it difficult to form a layer of sufficient thickness. If it is more than 100 g/m ² , the unevenness of the nonwoven fabric surface becomes large, making it difficult to form a porous layer of uniform thickness.
Furthermore, at the above-mentioned basis weight, the nonwoven fabric itself becomes permeable when it absorbs liquid, making the underlying layer visible. Therefore, even if the substrate is configured as the outermost surface (i.e., the porous layer side laminated on the substrate is in contact with the outer surface of the planter), the surface of the porous layer can be protected without interfering with the visibility of the hue change when liquid is absorbed, and the texture when touched is pleasant.

Examples are shown below, but the present invention is not limited to these examples.
In the examples, "parts" refers to parts by weight.
Example 1 (see Figures 1 and 2)
A blue water-based screen printing ink was used to print a solid pattern on the surface of a grey nonwoven fabric (made of polyester, basis weight 330 g/ ^m2 ) in a cross shape (consisting of five square panels with each side measuring 10 cm) that would become a planter (container) 2, in a 3 cm wide band spanning three of the panels, to form a coloured layer 32. After that, a white screen printing ink containing silica fine powder and an acrylic resin emulsion was used to print a solid pattern on the coloured layer 32, which was then dried and hardened to form a white porous layer 3.
The four faces of the cross-shaped square panel were set up perpendicular to the bottom panel so that the porous layer 3 was the inner surface, and the contacting edges were sewn to form a container shape, and then the panel was folded back so that the porous layer side was the outer surface, thereby obtaining a color-changing planter 1.

The obtained color-changing planter 1 can accommodate a culture medium 4 such as soil or nonwoven fabric inside the planter (container) 2, and a plant 5 such as a seed or seedling can be planted in the culture medium 4 and cultivated by watering it.
In the cultivation form, water penetrates into the medium 4 when the plant 5 is watered, and when the medium 4 has accumulated a sufficient amount of water, the water is exposed from the inner surface of the planter 2 to the outer surface. At that time, the area where the porous layer 3 was provided was visible as a white belt-like decoration before watering, but as the water is exposed, water seeps out to the outer surface of the container, so the porous layer 3 provided on the outer surface of the planter absorbs water and becomes transparent, and the absorbed part is visible as the blue color of the lower layer (colored layer 32), so it is easy to visually determine whether there is sufficient water in the planter. The blue state can be permanently seen as long as water exists, and as the water in the medium 4 decreases and the outer surface of the planter dries, the part that turned blue returns to its original white color. This change in appearance could be repeated.

Example 2 (see FIG. 3)
A color-changing planter 1 was obtained in the same manner as in Example 1, except that the colored layer 32 used in Example 1 was removed and a pink pigment was added to the screen printing ink for forming the porous layer 3.

The obtained color-changing planter 1 can accommodate a culture medium 4 such as soil or nonwoven fabric inside the planter (container) 2, and a plant 5 such as a seed or seedling can be planted in the culture medium 4 and cultivated by watering it.
In the cultivation form, water penetrates into the medium 4 when the plant 5 is watered, and when the medium 4 has accumulated a sufficient amount of water, the water is exposed from the inner surface of the planter 2 to the outer surface. At that time, the part where the porous layer 3 was provided was visually recognized as a pale pink belt-like decoration before watering, but as the water is exposed, water seeps out to the outer surface of the container, so that the porous layer 3 provided on the outer surface of the planter absorbs water, and the absorbed part is visually recognized as reddish brown, which is a mixture of the gray of the planter and the pink of the porous layer 3, so that it is possible to easily determine by visual inspection whether there is sufficient water in the planter. The reddish brown state can be permanently seen as long as water exists, and as the water in the medium 4 decreases and the outer surface of the planter dries, the part that has turned pale pink returns to its original pale pink color. This change in appearance can be repeated.

Example 3 (see FIG. 4)
A nonwoven fabric made of 90% polyethylene terephthalate and 10% rayon with a basis weight of 60 g/ ^m2 was used as the substrate 31. A strip-shaped floral pattern was printed on the surface of the substrate 31 using a red water-based screen printing ink to form a colored layer 32. A white screen printing ink containing silica fine powder and a urethane resin emulsion was then solid-printed on the red colored layer 32 in a strip shape having a width of 3 cm, and the resulting ink was dried and cured to form a white porous layer 3, thereby obtaining a color-changing nonwoven fabric 6 in which the floral pattern 32 was concealed by the porous layer 3.

The back side of the previously obtained color-changing nonwoven fabric 6 was laminated onto the front surface (one of the panels that would become the side walls) of a cross-shaped gray nonwoven fabric (made of polyester, with a basis weight of 180 g/ ^m2 ) (consisting of five square panels with sides of 13 cm) that would become a planter (container) 2, and the two types of nonwoven fabrics were integrated using the needle punch method to obtain a color-changing laminate.
The four faces of the cross-shaped square panel were set perpendicular to the bottom panel so that the porous layer 3 of the obtained laminate was the inner surface, and the contacting edges were sewn to form a container shape, and then the panel was folded back so that the porous layer side was the outer surface, thereby obtaining a color-changing planter 1.

The obtained color-changing planter 1 can accommodate a culture medium 4 such as soil or nonwoven fabric inside the planter (container) 2, and a plant 5 such as a seed or seedling can be planted in the culture medium 4 and cultivated by watering it.
In the cultivation form, water penetrates into the medium 4 when the plant 5 is watered, and when the medium 4 has accumulated a sufficient amount of water, the water is exposed from the inner surface of the planter 2 to the outer surface. At that time, the area where the porous layer 3 was provided was visible as a white belt-like decoration before watering, but as the water is exposed, water seeps out to the outer surface of the container, so the porous layer 3 provided on the outer surface of the planter absorbs water and becomes transparent, and the red floral pattern of the lower layer (colored layer 32) is visible in the part that absorbed the water, so it is easy to visually determine whether there is sufficient water in the planter. The display state of the floral pattern can be permanently seen as long as water exists, and when the moisture in the medium decreases and the outer surface of the planter dries, the floral pattern display part returns to its original white color. This change in appearance could be repeated.

Example 4 (see FIG. 5)
A nonwoven fabric consisting of 60% rayon and 40% polyethylene terephthalate and having a basis weight of 50 g/ ^m2 was used as the substrate 31. A white screen printing ink containing silica fine powder and a urethane resin emulsion was solidly printed on the surface of the substrate 31, and the ink was dried and cured to form a white porous layer 3.
Next, multiple smile marks were printed at equal intervals all over the porous layer using blue water-based screen printing ink to form a colored layer 32, thereby obtaining a color-changing nonwoven fabric 6 having multiple smile marks on the porous layer.

The obtained color-changing nonwoven fabric 6 was entirely covered on the surface of a large-sized gray polyester nonwoven fabric (350 g/ ^m2 basis weight) so that the colored layer 32 was in contact (i.e., the surface side of the color-changing nonwoven fabric was placed in contact), and the two types of nonwoven fabrics were integrated by a needle punch method to obtain a color-changing laminate. Further, a cross shape consisting of five square panels with each side being 13 cm was punched out to obtain a nonwoven fabric laminate that would become a planter (container) 2, and the four faces of the cross-shaped square panels were set perpendicular to the bottom panel so that the color-changing nonwoven fabric side was the inner surface, and the contacting edges were sewn to form a container shape, and the fabric was then folded back so that the porous layer side was the outer surface, obtaining a color-changing planter 1.

The obtained color-changing planter 1 can accommodate a culture medium 4 such as soil or nonwoven fabric inside the planter (container) 2, and a plant 5 such as a seed or seedling can be planted in the culture medium 4 and cultivated by watering it.
In the cultivation form, water penetrates into the medium 4 when the plant 5 is watered, and when the medium 4 has accumulated a sufficient amount of water, the water is exposed from the inner surface to the outer surface of the planter 2. At that time, before watering, the entire surface is visible as the white nonwoven fabric of the base material 31, but as the water is exposed, the water seeps out to the outer surface of the container, so the porous layer 3 provided on the color-changing nonwoven fabric 6 absorbs water and becomes transparent, and the absorbed part is visible through the base material as a blue smiley face mark of the lower layer (colored layer 32), making it easy to visually determine whether there is sufficient water in the planter. The display state of the smiley face can be permanently seen as long as water is present, and when the water in the medium 4 decreases and the outer surface of the planter dries, the display part of the smiley face returns to its original white color. This change in appearance could be repeated.
In this configuration, the colored layer 32 and the porous layer 3 laminated on the substrate 31 as the color-changing nonwoven fabric 6 are not exposed to the outside but are covered by the substrate 31, so that peeling and deterioration due to long-term use can be suppressed.

Example 5 (see FIG. 6)
A pink-colored nonwoven fabric made of 100% polyethylene terephthalate with a basis weight of 80 g/ ^m2 was used as the substrate 31, and a white screen printing ink containing silica fine powder and an acrylic resin emulsion was solid-printed on the surface of the substrate 31, followed by drying and curing to form a white porous layer 3, thereby obtaining a color-changing nonwoven fabric 6.

The back side of the previously obtained color-changing nonwoven fabric 6 was laminated onto the front surface (four panels that would become the side walls) of a cross-shaped gray nonwoven fabric (made of polyester, with a basis weight of 400 g/ ^m2 ) that would become a planter (container) 2 (consisting of five square panels with each side measuring 10 cm), and the two types of nonwoven fabrics were integrated using the needle punch method to obtain a color-changing laminate.
The four faces of the cross-shaped square panel were set perpendicular to the bottom panel so that the porous layer 3 of the obtained laminate was the inner surface, and the contacting edges were sewn to form a container shape, and then the panel was folded back so that the porous layer side was the outer surface, thereby obtaining a color-changing planter 1.

The obtained color-changing planter 1 can accommodate a culture medium 4 such as soil or nonwoven fabric inside the planter (container) 2, and a plant 5 such as a seed or seedling can be planted in the culture medium 4 and cultivated by watering it.
In the cultivation form, water penetrates into the medium 4 when the plant 5 is watered, and when the medium has accumulated a sufficient amount of water, the water is exposed from the inner surface of the planter 2 to the outer surface. At that time, the white color of the porous layer 3 was visible before watering, but as the water is exposed, the water seeps out to the outer surface of the container, so the porous layer 3 provided on the outer surface of the planter (substrate surface) absorbs water and becomes transparent, and the absorbed part is visible as pink color of the substrate 31, so it is easy to visually determine whether there is sufficient water in the planter. The pink state can be permanently seen as long as water exists, and when the water in the medium 4 decreases and the outer surface of the planter dries, the pink visible part returns to its original white color. This change in appearance could be repeated.

1. Color changing planter 2. Planter (container)
3 Porous layer 31 Substrate 32 Colored layer 4 Culture medium 5 Plant 6 Color-changing nonwoven fabric

Claims (8)

A planter for growing plants made of a nonwoven fabric, comprising a porous layer on at least a part of an outer surface thereof, the porous layer having a different transparency between a liquid-absorbed state and a liquid-non-absorbed state, the porous layer comprising a low refractive index pigment fixed in a dispersed state in a binder resin,
A color-changing planter in which the porous layer changes appearance as water leaks from the inside to the outside of the planter through the medium when plants are watered. The color-changing planter according to claim 1, which has a colored layer between the porous layer and the outer surface of the planter. The color-changing planter according to claim 1, in which the back surface of the color-changing nonwoven fabric on which the porous layer is provided on the substrate surface is in contact with the outer surface of the planter and is integrated therewith by a needle punch method. The color-changing planter according to claim 3, which has a colored layer between the porous layer and the substrate. The color-changing planter according to claim 1, in which the surface of the color-changing nonwoven fabric, in which the porous layer and the colored layer are laminated in order on the surface of the substrate, is integrated with the outer surface of the planter by a needle punching method while in contact with the surface. A color-changing planter according to any one of claims 3 to 5, characterized in that the weight of the nonwoven fabric constituting the planter is greater than the weight of the base material of the color-changing nonwoven fabric. The color-changing planter according to any one of claims 3 to 6, wherein the weight of the base material of the color-changing nonwoven fabric is in the range of 30 to 100 g/ ^m2 . The color-changing planter according to any one of claims 1 to 7, wherein the nonwoven fabric constituting the planter has a basis weight in the range of 101 to 1000 g/ ^m2 .

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