JP2023114478A - Plant cultivation material, production method thereof, and plant cultivation molded body - Google Patents

Abstract

To provide a plant cultivation material, a production method thereof, and a plant cultivation molded body, in which the plant cultivation material and the plant cultivation molded body use a polyurethane foam as a base material, yet have good water absorption and water retention, are free from early release of a held fertilizer, and have continuous fertilizer release.SOLUTION: A plant cultivation material 1 using a polyurethane foam as a base material includes a polyurethane foam base material 2 having a large number of open cells 21, and diatomaceous earth powder 4 held on the inner walls of the open cells 21 of the polyurethane foam base material 2. Alginate 5 is attached to surfaces of the diatomaceous earth powder 4, the diatomaceous earth powder 4 and/or the alginate contain fertilizer for plant cultivation, and the plant cultivation material 1 has water absorbency.SELECTED DRAWING: Figure 1

Description

TECHNICAL FIELD The present invention relates to a plant cultivation material, a method for producing the same, and a molded body for plant cultivation.

Cultivation beds for horticulture and substrates for planting, which are mainly composed of materials other than soil and culture soil, have been developed.
As such a cultivation bed, there is, for example, Japanese Patent Application Laid-Open No. 2005-176756 (Patent Document 1). The one disclosed in Patent Document 1 is made of polyurethane foam containing aggregate, and the polyurethane foam further contains fertilizer.
In Patent Document 1, when the polyurethane foam contains the fertilizer, the fertilizer and the aggregate may be contained separately, or the aggregate containing the fertilizer may be added to add the fertilizer. It may be contained, or both may be used in combination. The form of fertilizer may be either solid or liquid.

JP 2005-176756

In Patent Document 1, as methods for adding fertilizer to polyurethane foam, there are a method of adding fertilizer to raw materials of polyurethane resin separately from aggregate, and a method of spraying liquid fertilizer on polyurethane foam containing aggregate. are listed.
However, when aggregate containing fertilizer is added to contain the fertilizer, there is a high possibility that the fertilizer will not be released satisfactorily. In addition, when a polyurethane foam containing aggregates is sprayed with a liquid fertilizer, the fertilizer tends to come off and is not sustainable. In addition, since urethane foam has a certain degree of water repellency, its water absorbency is not sufficient.

An object of the present invention is to provide a material for cultivating plants and a molding for cultivating plants using polyurethane foam as a base material, which have good water absorption and water retention properties, do not early release fertilizers, and are sustainable. An object of the present invention is to provide a material for cultivating plants having a fertilizer-releasing property, a method for producing the same, and a compact for cultivating plants.

What achieves the above objectives is the following.
(1) A plant cultivation material based on polyurethane foam,
The plant cultivation material comprises a polyurethane foam base material having a large number of open cells, and diatomaceous earth powder held on the inner walls of the open cells of the polyurethane foam base material, and the surface of the diatomaceous earth powder is coated with alginate. and the diatomaceous earth powder and/or the alginate contain fertilizer for plant cultivation, and the material for plant cultivation has water absorbency.

(2) The plant according to (1) above, wherein the diatomaceous earth powder is held on the inner walls of the open cells formed in the polyurethane foam substrate by the solidified alginate adhering to the surface of the diatomaceous earth powder. Cultivation material.
(3) The plant cultivation material according to (2) above, wherein the solidified alginate is a water-soluble solidified material.
(4) The plant cultivation material according to any one of (1) to (3) above, wherein the diatomaceous earth powder is coated with the solidified alginate.
(5) The plant cultivation material according to any one of (1) to (4) above, wherein the polyurethane foam substrate is a flexible polyurethane foam substrate that can be compressed by pressing and recovered by releasing pressure.
(6) The plant cultivation material according to any one of (1) to (5) above, wherein the polyurethane foam substrate contains a plant cultivation fertilizer.
(7) The plant cultivation material according to any one of (1) to (6) above, wherein the alginate is a water-soluble salt composed of alginic acid and a monovalent cation.
(8) A molded body for plant cultivation molded into a predetermined shape from the plant cultivation material according to any one of (1) to (7) above.
(9) The molded body for plant cultivation according to (8) above, wherein the molded body for plant cultivation has a slit extending inwardly from the upper surface.
(10) The molded body for plant cultivation according to (9) above, wherein the slit is a cross slit.
(11) The molded body for plant cultivation according to (9) or (10), wherein the slit does not reach the lower surface of the molded body for plant cultivation.

Moreover, what achieves the above purpose is as follows.
(12) A bottomed container, and the plant cultivation material according to any one of the above (1) to (7) stored in the bottomed container, or the plant cultivation material according to any one of the above (8) to (11) A plant cultivation floor comprising:

Moreover, what achieves the above purpose is as follows.
(13) A method for producing a plant cultivation material using polyurethane foam as a base material, comprising:
The method for producing the plant cultivation material comprises:
providing a polyurethane foam substrate having a large number of open cells;
preparing a diatomaceous earth solution consisting of alginate, plant fertilizer, diatomaceous earth powder and water;
A diatomaceous earth solution impregnation step of putting the polyurethane foam base material into the diatomaceous earth solution, pressing the polyurethane foam base material, and impregnating the polyurethane foam base material with the diatomaceous earth solution;
A first drying step of drying the polyurethane foam substrate impregnated with the diatomaceous earth solution;
a step of applying plant fertilizer-containing water to the polyurethane foam substrate dried in the first drying step;
and a second drying step of drying the polyurethane foam substrate to which the plant fertilizer-containing water has been applied.

The polyurethane foam-based plant cultivation material of the present invention comprises a polyurethane foam base material having a large number of open cells, and diatomaceous earth powder held on the inner walls of the open cells of the polyurethane foam base material. Alginate is adhered to the surface, and the diatomaceous earth powder and/or alginate holds a plant-cultivating fertilizer, and the plant-cultivating material is water absorbent.
This plant-cultivating material has water absorption and water-holding properties by containing diatomaceous earth powder, and further contains diatomaceous earth powder and/or alginate as a plant-cultivating fertilizer, and on the surface of diatomaceous earth powder Since the alginate is adhered, the diatomaceous earth powder containing the fertilizer is less likely to be released from the polyurethane foam base material, and a sustained release of the fertilizer can be expected, resulting in good plant growth.

FIG. 1 is an explanatory diagram for explaining the internal structure of the plant cultivation material using the polyurethane foam of the present invention as a base material. FIG. 2 is a cross-sectional view of a plant cultivation bed using a polyurethane foam-based plant cultivation material according to an embodiment of the present invention. FIG. 3 is a front view of a plant cultivating bed using a plant cultivating compact molded into a predetermined shape from the plant cultivating material of the present invention. 4 is a plan view of the plant cultivation bed shown in FIG. 3. FIG. 5 is a longitudinal sectional view of the plant cultivation bed shown in FIG. 3. FIG.

The material for cultivating plants using the polyurethane foam of the present invention as a base material will be described with reference to the examples shown in the drawings.
The polyurethane foam-based plant cultivation material 1 of the present invention comprises a polyurethane foam substrate 2 having a large number of open cells 21 and diatomaceous earth powder 4 retained on the inner walls of the open cells 21 of the polyurethane foam substrate 2. Alginate is attached to the surface of the diatomaceous earth powder 4, the diatomaceous earth powder 4 and/or the alginate 5 holds plant cultivation fertilizer, and the plant cultivation material 1 is water absorbent It has

As shown in FIG. 1, which is an explanatory diagram for explaining the internal structure of the plant cultivation material using the polyurethane foam of the present invention as a base material, the plant cultivation material of the present invention is a polyurethane foam having a large number of open cells 21. It comprises a foam base material 2 and diatomaceous earth powder 4 retained on the inner walls of open cells 21 of the base material 2. - 特許庁In this embodiment, the diatomaceous earth powder 4 is held on the inner walls of the open cells 21 formed in the polyurethane foam substrate 2 by solidified alginate adhering to the surface of the diatomaceous earth powder 4 . Furthermore, the diatomaceous earth powder 4 holds the fertilizer for plant cultivation.

The fertilizer for plant cultivation is held by the diatomaceous earth powder 4 by being held directly by the diatomaceous earth powder 4 or by being held by the solidified alginate 5 adhering to the diatomaceous earth powder 4. Furthermore, the plant-cultivating fertilizer may contain both the material directly contained in the diatomite powder 4 and the material contained in the solidified alginate 5 adhering to the diatomaceous earth powder 4 .
The form of the fertilizer for plant cultivation is preferably a dried fertilizer for plant cultivation. The dried fertilizer for plant cultivation is not completely dried, but may be one from which a certain amount of water has been removed (specifically, one that has undergone a drying process).
The form of the solidified alginate may be a dry solidified alginate, a viscous solidified alginate, or a viscous and water-containing solidified alginate.

In the one shown in FIG. 1, the polyurethane foam substrate 2 has a number of open cells 21, in other words, a plurality of cells (voids) connected to each other, and has a communication path that communicates from the upper surface to the lower surface of the polyurethane foam substrate 2. are doing. The diatomaceous earth powder 4 is coated with a solidified alginate 5 . The coating may be either complete coating or partial coating, but complete coating is preferred.
The diatomaceous earth powder 4 is held on the inner walls of the open cells (communication passages) 21 formed in the polyurethane foam base 2 via the solidified alginate adhering to the surface of the diatomaceous earth powder 4 .
The polyurethane foam substrate 2 having a large number of open cells 21 is preferably a flexible polyurethane foam substrate 2 that can be compressed by pressing and recovered by releasing the pressure.

The flexible polyurethane foam is generally used as a flexible polyurethane foam molded by mixing and stirring polyol, isocyanate, water, catalyst (amine catalyst, metal catalyst, etc.), foam stabilizer, etc. There are no particular restrictions on the component composition or raw materials used. A molded article molded from a normal flexible polyurethane foam is preferred. It should be noted that offcuts produced when the molded product is cut out can also be used.

The flexible polyurethane foam substrate preferably has a density (JIS K 7222) of 10 to 60 kg/m ³ . If it is 10 kg/m ³ or more, it has a mechanical strength suitable as a material for plant cultivation. In addition, if it is 60 kg/m ³ or less, diatomaceous earth powder to which a sufficient amount of solidified alginate is adhered can be supported.

The number of cells (JIS K 6400) of the flexible polyurethane foam substrate is preferably 20 to 70/25 mm. If the number of cells is 20 cells/25 mm or more, diatomaceous earth powder to which a sufficient amount of solidified alginate is adhered can be supported. Moreover, if the number of cells is 70 cells/25 mm or less, it has mechanical strength suitable as a material for plant cultivation. The number of cells can be adjusted by adjusting the amount of foaming agent, the amount and type of foam stabilizer, and the like.

Both water-repellent and hydrophilic flexible polyurethane foam substrates can be used. The diatomaceous earth powder 4 retained on the inner walls of the open cells 21 of the polyurethane foam substrate 2 makes the plant cultivation material 1 having the polyurethane foam as the substrate of the present invention have water absorbability and water retention. there is

As the diatomaceous earth powder used in the present invention, so-called diatomaceous earth powder and siliceous shale powder are used. Diatomaceous earth is a sedimentary rock composed mainly of silicic acid after algae have been deposited on the bottom of the sea or lake for many years, and the protoplasm inside the body has decomposed. Siliceous shale is a shale-like rock formed by geological changes due to the influence of ground pressure and geothermal heat from diatomaceous earth, which is formed by depositing the remains of diatom plankton. Diatomaceous earth powder has a porous structure. The diatomaceous earth powder preferably has a moisture content of 5 to 40% by mass. The average particle size of the diatomaceous earth powder is preferably about 10 to 100 μm. In particular, it is preferably 30 to 80 μm.
The content of the diatomaceous earth powder 4 in the plant cultivation material 1 using the polyurethane foam as a base material of the present invention is considered to be about 0.01 to 0.15 g/cm ³ . In particular, 0.015 to 0.06 g/cm ³ is considered suitable.

A water-soluble alginate is used as the alginate used in the present invention. Specifically, water-soluble salts of alginic acid and monovalent cations, such as sodium alginate, potassium alginate, and ammonium alginate, are used. Sodium alginate is particularly preferred. The alginate solidified material attached to the diatomaceous earth powder is preferably a water-soluble solidified material. In other words, the alginic acid or alginate attached to the attached diatomaceous earth powder is not an insoluble salt combined with polyvalent cations. Therefore, it does not hinder the water absorption of the diatomaceous earth powder.

Water-soluble alginates have been produced by extraction from seaweed (brown algae). A water-soluble alginate is a water-soluble salt composed of alginic acid and a monovalent cation, and is a neutral salt in which the carboxyl group of alginic acid is combined with a monovalent cation such as Na ion or potassium ion. Water-soluble alginate dissolves well in cold and hot water to form a viscous aqueous solution.
A water-soluble alginate, such as sodium alginate, dissolves in cold or warm water to form a viscous colloidal solution. The viscosity, which is the stickiness of an aqueous solution, changes according to the molecular weight of sodium alginate, that is, the degree of polymerization of the uronic acid molecules that make up alginic acid. Become.

As the alginate used in the present invention, one that does not have a very high viscosity is preferable in consideration of the manufacturing process. The alginate used in the present invention is considered to have a low to medium molecular weight, specifically, a weight average molecular weight of 10,000 to 5,000,000, preferably 20,000 to 2,000,000 by GPC measurement.

As the fertilizer used in the present invention, water-soluble chemical fertilizers and chemical fertilizers are preferably used. Further, as water-soluble fertilizers, granular fertilizers, powdered fertilizers dissolved in water, and water-based fertilizers as they are or diluted are used. In addition, in the plant cultivation material 1 of the present invention, the diatomaceous earth powder is contained in the dried water-soluble fertilizer.
Furthermore, in the plant cultivation material 1 of the present invention, the polyurethane foam base material 2 may also directly contain a plant cultivation fertilizer. The plant cultivation fertilizer directly held by the polyurethane foam substrate 2 is released from the plant cultivation material 1 at the beginning when water is administered to the plant cultivation material 1, so the initial application of the fertilizer to the plant is good. will be carried out on

Fertilizers used in the present invention include nitrogenous fertilizers, phosphate fertilizers, potassium fertilizers, and if necessary, essential plant elements such as calcium, magnesium, sulfur, iron, trace elements such as manganese and boron, and silicon. Containing chemical fertilizers and chemical fertilizers are preferred. Specifically, the product name Univazole (high-purity powder liquid fertilizer, Hyponex Japan Co., Ltd.) can be preferably used.
As for the shape of the plant cultivation material 1 of the present invention, as shown in FIG. 2, when a large number of plant cultivation materials 1 are put in a container and used, an appropriate shape such as a spherical shape, a cylindrical shape, It is formed in a polygonal medium shape, an irregular shape, and the like. It is considered that the size is preferably 5 mm ³ or more. In particular, it is considered that 10 mm ³ or more is preferable.

Next, a method for producing a plant cultivation material using the polyurethane foam of the present invention as a base material will be described.
In the method for producing a plant cultivation material of the present invention, a step of preparing a polyurethane foam base material having a large number of open cells, a step of preparing a diatomaceous earth solution comprising an alginate, a plant fertilizer, diatomaceous earth powder and water, and a diatomaceous earth solution A diatomaceous earth solution impregnation step in which a polyurethane foam base material is introduced into the polyurethane foam base material, and the polyurethane foam base material is further pressed to impregnate the diatomaceous earth solution into the polyurethane foam base material, and the polyurethane foam base material impregnated with the diatomaceous earth solution is dried. A first drying step, a step of applying plant fertilizer-containing water to the polyurethane foam substrate dried in the first drying step, and a second drying step of drying the polyurethane foam substrate to which the plant fertilizer-containing water has been applied. Carry out the process.

The step of preparing a polyurethane foam base material having a large number of open cells is carried out by purchasing a polyurethane foam base material suitable for a plant cultivation material using polyurethane foam as a base material, or by making one yourself. As the flexible polyurethane foam substrate to be prepared, it is preferable to prepare one having the density and the number of cells described above.

The step of preparing a diatomaceous earth solution comprising alginate, plant fertilizer, diatomaceous earth powder, and water includes mixing and stirring alginate, water-soluble plant fertilizer, and diatomaceous earth powder in water to obtain a diatomaceous earth solution in which the diatomaceous earth powder is almost evenly dispersed. It is done by preparing As the alginate, water-soluble plant fertilizer, and diatomaceous earth powder, those mentioned above are preferably used.

Next, a diatomaceous earth solution impregnation step is performed in which the polyurethane foam base material is put into the diatomaceous earth solution prepared as described above, and the polyurethane foam base material is further pressed to impregnate the polyurethane foam base material with the diatomaceous earth solution. will be This process is carried out by putting a polyurethane foam base into a diatomaceous earth solution tank filled with a diatomaceous earth solution, pressing the upper surface of the polyurethane foam base, and repeating compression and release of the compression of the polyurethane foam base. This process creates a polyurethane foam substrate impregnated with a diatomaceous earth solution.

Next, a first drying step is performed to dry the polyurethane foam substrate impregnated with the diatomaceous earth solution. This step is carried out by placing the polyurethane foam substrate impregnated with the diatomaceous earth solution in a dryer and heating and drying it.
Furthermore, in the present invention, a step of applying plant fertilizer-containing water to the polyurethane foam substrate dried in the first drying step is performed. The application of the plant fertilizer-containing water is preferably carried out by spreading or spraying the plant fertilizer-containing water from the upper surface of the dried polyurethane foam substrate.
Subsequently, a second drying step is performed to dry the polyurethane foam base material to which the plant fertilizer-containing water has been applied. This drying step is carried out by air drying or drying by heating with a dryer.

Next, a plant cultivation bed using a plant cultivation material having a polyurethane foam as a base material according to an embodiment of the present invention, shown in FIG. 2, will be described.
The plant cultivation bed (plant cultivation pod) 20 of this embodiment comprises, as shown in FIG. is provided as a base material for plant cultivation 1. As the plant cultivation material 1, those mentioned above are preferably used.
The bottomed container 7 has a cylindrical side portion 71 , a bottom portion 73 , an internal storage portion 72 , and a flange 74 formed at the upper end of the cylindrical side portion 71 . The bottomed container 7 is made of synthetic resin, paper, ceramic sintered material, or the like. A bottom portion 73 of the bottomed container 7 is provided with an opening 75 to allow drainage.
there is

Next, a plant cultivation bed using a plant cultivation material having a polyurethane foam as a base material according to an embodiment of the present invention, shown in FIG. 3, will be described.
As shown in FIG. 3, the plant cultivation floor (plant cultivation pod) 30 of this embodiment comprises a bottomed container 7 with an upper opening and a plant cultivation compact 10 housed in the bottomed container 7. I have. The molded body for plant cultivation 10 is obtained by molding the plant cultivation material 1 having the polyurethane foam of the present invention as a base material into a predetermined shape, and the configuration thereof is preferably the same as that of the plant cultivation material 1 described above. Used.

The bottomed container 7 has a cylindrical side portion 71 , a bottom portion 73 , an internal storage portion 72 , and a flange 74 formed at the upper end of the cylindrical side portion 71 similarly to the one shown in FIG. 2 . The bottomed container 7 is made of synthetic resin, paper, ceramic sintered material, or the like. A bottom portion 73 of the bottomed container 7 is provided with an opening 75 to allow drainage.

In addition, the molded body for plant cultivation 10 has slits 12 as shown in FIGS. 4 and 5 . The slit 12 has a length shorter than the diameter of the upper surface of the molded article and passes through substantially the center of the upper surface of the molded article. It has a second slit 12b which has a shape and intersects with the first slit 12a. The first slit 12a and the second slit 12b are substantially orthogonal. In this embodiment, the slit 12 is a cross-shaped slit.
5, the first slit 12a and the second slit 12b do not reach the lower surface of the molded body for plant cultivation 10. As shown in FIG. In other words, the first slit 12a and the second slit 12b terminate at positions above the lower surface of the molded body for plant cultivation 10, as shown in FIG.

1 plant cultivation material 2 polyurethane foam substrate 4 diatomaceous earth powder 7 bottomed container 10 plant cultivation moldings 20, 30 plant cultivation floor

Claims (13)

A plant cultivation material based on polyurethane foam,
The plant cultivation material comprises a polyurethane foam base material having a large number of open cells, and diatomaceous earth powder held on the inner walls of the open cells of the polyurethane foam base material, and the surface of the diatomaceous earth powder is coated with alginate. is attached, and the diatomaceous earth powder and / or the alginate contains a fertilizer for plant cultivation, and the plant cultivation material is water absorbent. material. The plant cultivation material according to claim 1, wherein the diatomaceous earth powder is held on the inner walls of the open cells formed in the polyurethane foam base material by a solidified alginate attached to the surface of the diatomaceous earth powder. 3. The material for plant cultivation according to claim 2, wherein the solidified alginate is a water-soluble solidified material. The plant cultivation material according to any one of claims 1 to 3, wherein the diatomaceous earth powder is coated with the solidified alginate. The plant cultivation material according to any one of claims 1 to 4, wherein the polyurethane foam substrate is a flexible polyurethane foam substrate that can be compressed by pressing and recovered by releasing pressure. 6. The material for cultivating plants according to any one of claims 1 to 5, wherein the polyurethane foam substrate contains a fertilizer for cultivating plants. 7. The material for plant cultivation according to any one of claims 1 to 6, wherein the alginate is a water-soluble salt composed of alginic acid and a monovalent cation. A molded body for plant cultivation molded into a predetermined shape from the plant cultivation material according to any one of claims 1 to 7. 9. The molded body for plant cultivation according to claim 8, wherein said molded body for plant cultivation has a slit extending inwardly from the upper surface thereof. The molded body for plant cultivation according to claim 9, wherein the slit is a cross slit. The molded body for plant cultivation according to claim 9 or 10, wherein the slit does not reach the lower surface of the molded body for plant cultivation. A bottomed container, and the plant cultivating material according to any one of claims 1 to 7 or the plant cultivating compact according to any one of claims 8 to 11 housed in the bottomed container. Plant cultivation floor. A method for producing a plant cultivation material based on polyurethane foam, comprising:
The method for producing the plant cultivation material comprises:
providing a polyurethane foam substrate having a large number of open cells;
preparing a diatomaceous earth solution consisting of alginate, plant fertilizer, diatomaceous earth powder and water;
A diatomaceous earth solution impregnation step of putting the polyurethane foam base material into the diatomaceous earth solution, pressing the polyurethane foam base material, and impregnating the polyurethane foam base material with the diatomaceous earth solution;
A first drying step of drying the polyurethane foam substrate impregnated with the diatomaceous earth solution;
a step of applying plant fertilizer-containing water to the polyurethane foam substrate dried in the first drying step;
and a second drying step of drying the polyurethane foam substrate to which the plant fertilizer-containing water has been applied.

Images