JP2002103510A - Gypsum board having antibacterial properties and gas adsorbability, and method for manufacturing the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a gypsum board having antibacterial properties and gas adsorbability by reutilizing waste containing a silicic acid component and/or an aluminum component. SOLUTION: An artificial zeolite composition is synthesized from waste containing a silicic acid component and/or an aluminum component to be substituted with polyvalent cations, and antibacterial cations are further supported on this composition. The resulting composition is mixed with a baked gypsum slurry and/or raw material to provide a gypsum board having antibacterial properties and gas adsorbability.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to an artificial zeolite composition obtained by reusing a waste rich in a silicate component and an aluminum component and heating or pressurizing it under alkaline conditions to obtain iron ions, calcium ions or magnesium ions. Purified gypsum slurry obtained by substituting with ions and adsorbing and supporting antibacterial cations was added to calcined gypsum, and the calcined gypsum slurry obtained by mixing with water was integrally joined with the base paper and molded. Gypsum board) which is excellent in humidity control.

[0002]

2. Description of the Related Art Gypsum boats conventionally used as building materials have been known to have humidity control properties and deodorization properties. Japanese Patent Application Laid-Open No. 2000-45450 discloses an inorganic fine powder and a water-soluble powder. The use of a molecule or carbide as a humidity control or deodorizing material is disclosed.

[0003]

However, in the conventional gypsum board, it is necessary to mix admixtures of different materials having different applications and mix them into the calcined gypsum slurry, and in view of strength, performance and manufacturing cost. There was also a problem.

[0004]

SUMMARY OF THE INVENTION The present invention has been made to achieve the above object.
The gypsum gypsum slurry is supplied from the main mixer onto the base paper for the gypsum board of the base paper, and the base paper for the gypsum board of the top paper is arranged on the slurry, and then the gypsum board formed through a molding machine is used. And an artificial zeolite composition exchanged with iron ions or calcium ions or magnesium ions for adsorbing and supporting antibacterial cations and water, and then forming a slurry together with the base paper, and molding. Gypsum board with antibacterial properties and gas adsorption properties.

[0005] A second aspect of the present invention is a gypsum board base paper in which at least one of an upper paper and a lower paper has an antibacterial cation adsorbed and carried on an artificial zeolite composition substituted with iron ions, calcium ions or magnesium ions. The gypsum board with antibacterial property and gas adsorption property according to claim 1, which is mixed with 5 to 50%.

The antibacterial cation to be adsorbed and carried on the artificial zeolite composition substituted with iron ions or calcium ions or magnesium ions is a silver ion, copper ion, zinc ion, tin ion, cadmium ion or nickel ion. 3. A method according to claim 1, wherein
A gypsum board having the described antibacterial properties and gas adsorption properties.

According to a fourth aspect of the present invention, the artificial zeolite composition is obtained by hydrothermally synthesizing a waste containing a silicic acid component and / or an aluminum component. Gypsum board with gender.

[0008] A fifth aspect of the present invention is to mix an artificial zeolite composition substituted with iron ions or calcium ions or magnesium ions with antibacterial cations adsorbed thereon and mixed with calcined gypsum and water. The calcined gypsum slurry is supplied from the main mixer onto the base paper for the gypsum board of the base paper, and the base paper for the gypsum board of the top paper is arranged on the calcined gypsum slurry, and then integrally joined with the base paper through a molding machine. And a method for producing a gypsum board having antibacterial properties and gas adsorbing properties.

[0009] A sixth aspect of the present invention is a gypsum board base paper in which at least one of an upper paper and a lower paper has an artificial zeolite composition substituted with iron ions, calcium ions or magnesium ions and adsorbed and carried an antibacterial cation. The method for producing a gypsum board having antibacterial property and gas adsorbing property according to claim 5, wherein 5 to 50% is mixed.

[0010]

Embodiments of the present invention will be described below. The gypsum board according to the present invention is prepared by adsorbing and supporting an antibacterial cation on an artificial zeolite composition obtained by substituting calcined gypsum as a main raw material with iron ions or calcium ions or magnesium ions in a weight percentage of 5 to 50%.
After mixing and adding water to make a slurry, it is supplied from the main mixer onto the base paper for gypsum board of the base paper, and the base paper for the gypsum board of the top paper is placed on top of this and cured through the molding machine. , Dried and integrally joined with the base paper. The content of the artificial zeolite composition is 5 to 50% by weight.
The lower limit at which the antibacterial and gas adsorption effects appear by mixing the artificial zeolite composition is 5%.
The upper limit at which the slurry mixed with the artificial zeolite composition is compatible with the base paper is set to 50%.

[0011] The artificial zeolite composition according to the present invention refers to a reaction obtained by adjusting the silicate ratio of a waste containing a silicic acid component and / or an aluminum component, followed by heating or pressurizing under alkaline conditions. Product. The alkaline condition means that an alkaline aqueous solution when the artificial zeolite is mixed is a hydroxide of an alkali metal and is soluble in water, for example, sodium hydroxide, potassium hydroxide, calcium hydroxide, water. An aqueous solution of barium oxide, lithium hydroxide, or the like is used.
This means that the operation is performed in the range of 5 to 4.5N. As the heating conditions during the reaction, an artificial zeolite composition can be synthesized by heating to 80 to 230 ° C. or by heating using a saturated vapor pressure to generate heat.

The main component of the zeolite composition is the ratio of the raw material to sulphate, that is, (ratio of the weight composition of SiO ₂ and Al ₂ O ₃ ) ×
Depending on 1.7, what is produced as a main component is hydroxysodalite, phillipsite, faujasite and the like. In addition, as a component other than the main component, a small amount of zeolite A or the like may be contained, and as a non-zeolite component, an activated carbon-like substance derived from unburned carbon, iron, other impurities, and intermediate products up to zeolite, etc. They coexist.

The above-mentioned artificial zeolite composition substituted with iron ions, calcium ions or magnesium ions is obtained by immersing the artificial zeolite composition in an aqueous solution of each of the above-mentioned cations. Also, the adsorptivity to an anionic gas increases. This increase in adsorption capacity is due to a crosslinking effect of polyvalent cations and a chelating effect, and is more preferable than using monovalent cations.

The artificial zeolite composition substituted with iron ions, calcium ions or magnesium ions according to the present invention, which is adsorbed and supported with an antibacterial cation, is defined as the artificial zeolite in the above-mentioned aqueous solution containing each metal cation. After being immersed in and replaced with, an antibacterial cation is further adsorbed and carried. Examples of antibacterial cations include silver ions, copper ions, zinc ions, tin ions, cadmium ions, and nickel ions. Considering the effects on the environment and the human body (toxicity), silver ions, copper ions, Preference is given to using zinc ions.

[0015] The base paper for gypsum board according to the present invention refers to an artificial zeolite composition obtained by substituting at least iron ions, calcium ions or magnesium ions for paper fibers in the production process of gypsum board base paper, with an antibacterial cation. It is the one adsorbed and carried and 5-50% by weight. Gypsum board of the present invention, calcined gypsum, iron ions, or an artificial zeolite composition replaced with calcium ions or magnesium ions further adsorbed and carried antibacterial cations, water and mixed together, slurry and The raw material is supplied from the main mixer onto the base paper for the gypsum board of the base paper, and then the base paper for the gypsum board of the top paper is arranged thereon, and then the gypsum board is formed through a molding machine to form the gypsum plaster. It is manufactured by removing excess moisture in a drying step after curing.

The method for producing a gypsum board having antibacterial and gas-adsorbing properties according to the present invention comprises the steps of: supplying a calcined gypsum slurry from a main mixer onto a base paper for a gypsum board as a base paper; In gypsum board formed through the forming machine after disposing gypsum board base paper, antibacterial cation is adsorbed and carried on calcined gypsum and artificial zeolite composition replaced with iron ion or calcium ion or magnesium ion In this method, a slurry obtained by mixing the mixture and water is integrally joined together with the base paper and molded.
Further, as the gypsum board base paper, at least the paper fibers in the base paper manufacturing process, iron ion or artificial zeolite composition substituted with calcium ions or magnesium ions, adsorbed and carried an antibacterial cation, weight, % Is preferably used. Next, an example in which the gypsum board of the present invention is used for a wall surface of a food storage room will be described, but the gypsum board of the present invention is not limited to this example. Further, a diatom board can be manufactured by mixing the artificial zeolite with diatomaceous earth and performing the same treatment as the above-mentioned gypsum board.

[0017]

EXAMPLE An ultrasonic transmitter (Molybdenum DEL US-600T, manufactured by Nippon Seiki Seisaku-Sho, Ltd.) was installed in a 1-liter autoclave with a stirrer (manufactured by Toyo Koatsu Co., Ltd.), and amorphous silica was added to the reaction vessel. 1 kg of fly ash having an aluminum content of 95% and an aluminium ratio of about 2.5 (obtained from Matsuura Power Station Co., Ltd., fly ash association) was placed in a pressure-resistant reaction vessel, and 4 kg of the top was placed thereon.
After 10 liters of an aqueous solution of N sodium hydroxide was put in, and the lid was closed, the mixture was pressurized with saturated steam while oscillating 25 kHz ultrasonic waves at 600 W, and heated until the internal temperature reached 120 ° C. After maintaining this state for 3 hours, the steam was released to return to atmospheric pressure, and the artificial zeolite composition was taken out.

The reaction product was washed with water, air-dried, and then subjected to X-ray diffraction. As a result, an artificial zeolite composition mainly composed of phillipsite was formed, and the cation exchange capacity of the composition was 350 cmol. (+) Kg ⁻¹ . Next, an aqueous solution of calcium chloride having a concentration of 0.5 mol was added to the produced artificial zeolite composition, and the mixture was stirred for 2 hours using a reciprocating shaker. Repeat this process 5 times,
After removing excess salt by washing with water by centrifugation, 150 ° C.
To prepare a calcium-substituted artificial zeolite composition. Next, the above-mentioned calcium-substituted artificial zeolite composition was immersed in an aqueous solution of copper sulfate having a concentration of 0.2 N for 1 hour, dried at 105 ° C., and loaded with copper ions in the calcium-substituted artificial zeolite composition. Was prepared.

A gypsum board is prepared by mixing a calcium-substituted artificial zeolite composition containing 5% by weight of calcined gypsum with copper ions supported thereon, and adding water to form a slurry from the main mixer. Base paper (a mixture of 5% calcium-substituted artificial zeolite based on the weight of the base paper fibers and copper ions carried therein), and a base paper for gypsum board is placed on the slurry. After that, a gypsum board was prepared by passing through a molding machine.

A food storage room (volume: 1 m ³ ) in which the above-mentioned gypsum board is installed on the inner wall surface and a gypsum board not using the above-mentioned zeolite composition are prepared. Was stored for 1 week at a room temperature of 25 ° C., and the change with time of the ethylene gas concentration affecting the freshness of the banana is shown in Table 1.

[0021]

[Table 1] As shown in Table 1, the concentration of ethylene gas in the food storage room has increased sharply from the time when two days have elapsed, but the ethylene gas concentration in the storage room of the gypsum board using the artificial zeolite composition is as follows. , Lower than when no artificial zeolite was used.

The average pulp hardness of the banana is 2.00 kg immediately after storage, and after one week, the pulp hardness of the banana in the storage room of the gypsum board using the artificial zeolite composition is 1. On the other hand, in the case of a banana in a gypsum board storage room not using an artificial zeolite composition, the weight is 0.55 kg, and the artificial zeolite composition in the gypsum board absorbs ethylene gas, thereby increasing the freshness of the banana. Retention was allowed. Also,
No mold generation was observed on the inner wall of the storage room using the gypsum board of the present invention, but mold was generated at several places on the inner wall of the storage room using the gypsum board without the artificial zeolite composition. However, it was confirmed that the gypsum board of the present invention was also effective against mold.

[0023]

As described above, if the gypsum board of the present invention is used as an interior material or the like, no mold is generated on the interior wall surface, and odors and harmful gases generated indoors can be removed. Furthermore, it will provide a new technology for effective use of waste generated from industry and nature.

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) E04C 2/04 E04C 2/04 FF term (Reference) 2E001 DB00 DH00 FA06 GA12 HA03 HC07 HE10 2E162 CA16 4F100 AC04B AC04H AE06B BA03 BA06 BA10C CA12B CA12H DG10A DG10C GB08 JC00 JD02B JD14 JD14B 4G066 AA02B AA47A AA47C AA62B AA78A BA02 CA02 CA51 DA03 FA03 FA28 FA38

Claims (6)

[Claims] 1. A gypsum formed by feeding a calcined gypsum slurry from a main mixer onto a base paper for a gypsum board, and disposing a base paper for a gypsum board on the slurry, and then passing through a molding machine. On the board, plaster of Paris, an artificial zeolite composition substituted with iron ions, calcium ions, or magnesium ions to which antibacterial cations are adsorbed and supported, and a mixture of water and a slurry are integrally joined together with the base paper. A gypsum board having antibacterial properties and gas adsorption properties, which is characterized by being molded. 2. An artificial zeolite composition in which at least one of an upper paper and a lower paper of a gypsum board base paper is replaced with iron ions or calcium ions or magnesium ions is adsorbed and supported with an antibacterial cation by 5 to 50.
The gypsum board according to claim 1, wherein the gypsum board has an antibacterial property and a gas adsorption property. 3. The antibacterial cation to be adsorbed and carried on an artificial zeolite composition substituted with iron ions or calcium ions or magnesium ions is any one of silver ions, copper ions, zinc ions, tin ions, cadmium ions and nickel ions. A gypsum board having the antibacterial property and the gas adsorbing property according to claim 1 or 2. 4. An artificial zeolite composition comprising a silica component and / or
4. A gypsum board having antibacterial properties and gas adsorption properties according to claim 1, which is obtained by hydrothermal synthesis of waste containing an aluminum component. 5. An artificial zeolite composition substituted with any of iron ions, calcium ions, and magnesium ions, on which an antibacterial cation is adsorbed and supported, mixed with calcined gypsum, and water is mixed. The obtained calcined gypsum slurry is supplied from the main mixer onto the base paper for gypsum board of the base paper, and the base paper for the gypsum board of the top paper is arranged on the calcined gypsum slurry, and then integrated with the base paper through a molding machine. A method for producing a gypsum board having an antibacterial property and a gas adsorbing property, characterized by joining and molding. 6. An artificial zeolite composition substituted with iron ions or calcium ions or magnesium ions on at least one of an upper paper and a lower paper of a gypsum board base paper, and adsorbing and carrying an antibacterial cation on 5 to 50 grit.
%. A method for producing a gypsum board having antibacterial properties and gas adsorbing properties according to claim 5.