JP2019099947A - Novel material using volcanic ashes of active volcano - Google Patents

Abstract

To provide a novel material using volcanic ashes of an active volcano.SOLUTION: A physical and chemical material uses volcanic ashes of an active volcano and is characterized in that the volcanic ashes were erupted from the active volcano, and are within 100 years from when they were erupted.SELECTED DRAWING: Figure 3

Description

The present invention relates to new materials using active volcanic ash, in particular, chemical fibers, foams and structures.

  Japan has a land that contains volcanic ash ejected from dormant volcanoes and active volcanoes. Volcanic ash is a powder mainly composed of inorganic substances, and itself has characteristics such as porosity, catalytic activity, tackiness, adsorption, material exchangeability, detoxification, fixation, filterability, bacteria resistance, insect resistance and the like It has a function. In addition, volcanic ash is used in various applications because it emits far-infrared effects (heat buildup, heat storage properties and heat retention properties), ion generation effects, and magnetic effects. For example, it is used as a concrete composition, glass component, inorganic particle, building material, ceramic component, filter material, catalyst component, filler, abrasive, soil modifier, detergent, cosmetics, glaze and the like.

  Conventionally, as a thing using volcanic ash, the thermal dispersion film formation aqueous dispersion is proposed (patent document 1: Unexamined-Japanese-Patent No. 2017-088809). A resin composition in which volcanic ash is mixed as a filler has been proposed (Patent Document 2: JP-A-2017-008238). A porous ceramic fired body provided with a fired body of weathered volcanic ash has been proposed (Patent Document 3: JP-A-2008-001564). In addition, bedding has been proposed, which is characterized by generating negative ions by using shirasu powder among volcanic ash (Patent Document 4: Japanese Patent Application Laid-Open No. 2007-097752 and Patent Document 5: Japanese Patent Application Laid-Open No. 2007-097753. ).

   However, volcanic ash spouted from active volcanoes is spouted and accumulated in large quantities, and its effective use in the industry is still required.

Unexamined-Japanese-Patent No. 2017-088809 JP, 2017-008238, A JP, 2008-001564, A Japanese Patent Application Publication No. 2007-097752 Japanese Patent Application Publication No. 2007-097753

   The inventors of the present invention conducted a new examination of volcanic ash, and found that recent volcanic ash ejected from an active volcano has extremely superior characteristics than the volcanic ash of a dormant volcano and volcanic ash ejected a long time ago from the active volcano. I found out that. The present invention has been made based on such findings.

[Aspect of the Present Invention]
The present invention can propose the following one aspect.
[1] It is a physical and chemical material provided with volcanic ash of active volcano,
The physical and chemical material, wherein the volcanic ash is ejected from an active volcano and is within 100 years from the time of ejection.
[2] The physical and chemical material according to [1], wherein the volcanic ash is ejected from an active volcano and is within 50 years from the time of ejection.
[3] The physical and chemical material according to [1], wherein the volcanic ash is ejected from an active volcano and is within 5 years from the time of ejection.
[4] The physical chemistry according to any one of [1] to [3], wherein the physical and chemical material is a chemical fiber, a foam, or a structure comprising the volcanic ash of the active volcano. Material.
[5] The physical and chemical material according to [4], wherein the chemical fiber is a purified fiber, a regenerated fiber, a semisynthetic fiber, or a synthetic fiber.
[6] The physical and chemical material according to [4] or [5], wherein the chemical fiber is a filament, a stable, a spinning, a woven fabric, a knitted fabric, or a non-woven fabric.
[7] The foam is a polyurethane foam, polyethylene foam, polystyrene foam, polypropylene foam, rubber foam, silicone foam, melamine sponge, acrylic foam, EVA, or transcool, Physical and chemical materials described in [4].
[8] The physical and chemical raw material according to [4], wherein the structure comprises the volcanic ash of the active volcano and a thermoplastic resin or a thermosetting resin.
[9] Moisture-permeable waterproof material, heat-insulating material, heat-storage / insulating material, hygroscopic heat-generating material, far infrared ray processed fiber, antibacterial / deodorant processed material / bacterium-processed material, abrasive material, deodorized processed material, mite-processed material, antiallergic substance Any one of [1] to [8] which is a measure material, pollen prevention material, charge or charge control material, heat fusion material, flame retardant / disaster prevention material, ultraviolet light shielding material, stretch material, or form stable material [10] The physical and chemical material according to any one of [1] to [8], which is a garment fiber material, a bedding fiber material, or a textile material for household goods.

  According to the present invention, by adopting recent volcanic ash ejected from an active volcano, porosity, catalytic activity, adhesiveness, adsorptivity, substance (alkali, acid) exchangeability, in comparison with conventional volcanic ash It can exhibit excellent special properties such as anti-toxic, fixative, filterability, deodorizing, swelling, viscosity, plasticity, suspension, dispersibility, spreadability, gloss, bacteria resistance, insect repellent, etc. . In addition, volcanic ash that has just been ejected from an active volcano has far-infrared effects (heat buildup and heat retention), ion generation effect, moisture retention, deodorant, deodorant, antifungal properties, etc. compared to conventional volcanic ash. It is possible to achieve the effect in high dimensions.

BRIEF DESCRIPTION OF THE DRAWINGS The following drawings, which are appended to the present specification, illustrate preferred embodiments of the present invention, and serve to provide a further understanding of the inventive concept as well as the detailed description of the invention. It should not be construed that the present invention is limited to the matters described in the drawings.
FIG. 1 is a schematic view of a 45 degree parallel re-emission apparatus. The drawing of Japanese Patent Application Laid-Open No. 09-005170 is cited. FIG. 2 is a schematic view of an apparatus for measuring thermal characteristics. FIG. 3 is a thermographic measurement result of measuring the thermal characteristics.

[Definition]
(volcanic ash)
"Volcanic ash" is one of the volcanic products (volcanic debris), mainly fine fragments produced by magma foaming, with an average particle size of less than 10 mm (usually around 2 to 3 mm) It is made of volcanic glass, mineral crystals, etc. The fine fragments that can be generated by magma include, in addition to volcanic ash, volcanic dust, (volcanic ash), volcanic sand, volcanic gravel, volcanic gravel, lava from the ascending order of average particle size. It is the same as volcanic ash. In the present invention, the volcanic ash also includes volcanic dust and the like, and also includes crushed (crushed) products which have the desired average particle diameter. As volcanic ash is deposited, shirasu (volcano ash) exists, but shirasu is a volcanic ash that was generally ejected from the volcano and accumulated during the old age (30,000 years ago).

(active volcano)
"Active volcano" is generally defined as "the volcano that has erupted within the last 10,000 years and the volcano that is currently active with fumarolic activity" (2003, Volcanic Eruption Liaison Committee). Active volcanoes also include “defensive volcanoes,” which have been defined in the past (the eruption record has been recorded in a verifiable historical age based on the literature and books, but refer to volcanoes that are currently inactive). is there. According to the Japan Meteorological Agency report, there are 111 active volcanoes as of June 2017. In the present invention, volcanic ash ejected from active volcanoes in and outside Japan can be used. Active volcanoes include, for example, those belonging to the Pacific Rim volcanic zone including the Japan volcanic zone, the Indonesian volcanic zone, the Mediterranean volcanic zone and the like. In Japan, in recent years, due to the nature of magma and the results of geophysical studies, it is now divided into two parts, the East Japan Volcanic Zone and the West Japan Volcanic Zone.

  However, in the past, those included in the seven volcanic zones described below are included. Chishima Volcanic Zone (Tokachi-dake, Daisetsuzan, Mt. Okan, Meakan-dake, Raosu-dake, Mt. Mt. Yudake, etc. is exemplified), Nasu Volcanic Zone (Sashiyama, Mt. Mt. Yotei, Mt. Mt. Akita Komagatake, Mt. Kurikoma, Mt. Zao, Mt. Atatsura, Mt. Atatsura, Mt. Nasu, Mt. Mt. Mt. Mt. Mt. Mt. Takahara, Mt. Mt. Mt. Mt. Mt. Mt. Akagi, Mt. Asama, etc., Mt. Mt. Mt. Moriyoshi, Mt. Chokai, Mt. Tsukiyama, Mt. Asakusa, Mt. Mt. Monaga, Mt. Naiba, etc., Fuji volcanic zone (Niigata Yakeyama, Myoko, Mt. Kurohime, Mt. Tateshina, Yatsugatake, Mt. Fuji, Mt. Amagiyama, Izu Oshima, Miyakejima, Hachijojima, Bayonnaise Rock Formation, Iwojima, Fukutoku Nobo, etc.), Norikura Volcanic Zone (Tateyama, Yakedake, Mt. Hakusan, Oyama, Sanbeyama, Tsurumi-dake, Yufudake, Mt. Kusueren, Unzendake etc. are exemplified), Kirishima Yamatai (Aso, Kirishima, Sakurajima, Kaimondake, Iwo Satsuma, Suwanosejima the like).

[Physical chemical materials]
(volcanic ash)
In the present invention, a physical and chemical material is proposed that uses active volcanic ash. In the present invention, the volcanic ash of the active volcano is used, but the one 100 years or more after the eruption of the active volcano is not used. Therefore, Shirasu is not included in the present invention. However, the volcanic ash of an active volcano may be referred to as raw shirasu, which is included in the volcanic ash used in the present invention.

  As the volcanic ash of the active volcano, any material can be used significantly as long as it has spouted from the active foreign volcano, and among them, the active volcano belonging to the Kirishima volcanic zone in Japan, preferably, Mt. Aso, Kirishima It is a mountain, Sakurajima, Kaimondake, Satsuma Iwojima, or Suwanose Island, and more preferably, Sakurajima (Kagoshima City), Satsuma Iwojima (Mishima Village), Suwanose Island (Joshima Village), Kirishimasan (Kagoshima City) Kirishima City), Kuinonaga Rabujima (Yakushima Town), Nakanoshima (Toshishima Village), etc. are exemplified. In the present invention, in particular, volcanic ash ejected from active volcanoes of Sakurajima (Kagoshima City) and Kirishima (Kirishima City) existing in Kagoshima Prefecture is preferably used.

  In the present invention, the volcanic ash is ejected from an active volcano, and within 100 years, preferably within 50 years, more preferably within 10 years, most preferably within 5 years from the time of ejection. The preferred one is characterized by using within 1 year (among which, within 6 months, more preferably after squirting). That is, in the preferred embodiment of the present invention, the volcanic ash is most preferably freshly ejected from an active volcano (within at least one year, within six months, within three months). According to the present inventors, the volcanic ash which has just been erupted is extremely high in its characteristics and functions as compared to the volcanic ash which has passed over the years (for example, Shirasu which forms the Shirasu plateau having passed over 30,000 years). is there.

The average particle diameter (volume average diameter MV) of the volcanic ash is more than 0 mm and 10 mm or less, preferably 1 mm or more and 6 mm or less, and more preferably 2 mm or more and 4 mm or less. The BET specific surface area of volcanic ash is more than 0S (m ² / g) and not more than 100S (m ² / g), preferably not less than 10S (m ² / g) and not more than 60S (m ² / g), more preferably Is 20 S (m ² / g) or more and 50 S (m ² / g) or less. In the BET method, the pressure (P) and the adsorption amount (V) are introduced into the BET calculation formula by a gas adsorption method using nitrogen (N2) gas molecules, and after the monomolecular adsorption amount (Vm) is determined, nitrogen (N2) From the adsorption cross section (Am) of gas molecules, it can be calculated by BET specific surface area = (Vm × N / M) × Am (N is Avoga number and M is molecular weight of gas molecules) .

Volcanic ash spouted from an active volcano has each component composition described in the following [Table 1], and in the present invention, it is most preferable to include these components by the composition content. Volcanic ash spouted from the active volcano is characterized in that the content of silicon oxide and aluminum oxide is small and the content of iron oxide and calcium oxide is large, as compared with weathered volcanic ash and shirasu forming the silas plateau.

(Chemical fiber)
The physical and chemical material includes the above-mentioned volcanic ash, and may be composed of chemicals and the like, for example, may be composed of chemical fibers.
When chemical fiber is used, the content of volcanic ash is more than 0% by mass and 70% by mass or less with respect to the total mass of the chemical fiber, and the lower limit is preferably 10% by mass or more, more preferably 20% by mass or more The upper limit thereof is preferably 50% by mass or less, more preferably 30% by mass or less.

  Examples of the “purified fiber (natural polymer)” include cellulose fibers (Lyocell, Tencel). As an example of the production of purified fiber, a natural polymer in which wood pulp, which is a raw material, is dissolved in a solvent (harmless to the human body) and filtered with a filter or the like without treatment with chemical agents. In addition, volcanic ash, and a mixture prepared by adding an additive if necessary, can be obtained by extruding through a nozzle or through pores (bases) having a plurality of desired diameters.

  As “regenerated fiber (natural polymer)”, cellulose fiber (rayon, viscose rayon, polynozic, cupra, copper ammonia rayon), protein fiber (casein fiber, peanut protein fiber, corn protein fiber, soy protein fiber, Examples thereof include regenerated silk yarns, other fibers (algin fibers, chitin fibers, mannan fibers, rubber fibers) and the like.

  As an example of the production of "regenerated fibers", the production of purified fibers differs only in the treatment with chemical agents. For example, natural cellulose (protein etc.) is treated or dissolved with sodium hydroxide (N-methylmorpholine-N-oxide or copper ammonia solution etc.) using plants such as wood pulp, cotton and rubber as raw materials, and in the case of rayon A cellulose derivative or the like is prepared by reacting with carbon sulfide or the like, and this is dissolved in an alkali solution or the like to make a stock solution, and a solution prepared by adding volcanic ash and additives as necessary to this stock solution is through a nozzle. It can be obtained by extruding into an acid bath from pores (bases) having one or more desired diameters.

  Examples of "semi-synthetic fibers (semi-synthetic polymers)" include cellulose fibers (acetate, triacetate, acetate acetate), protein fibers (promix), natural rubber fibers (chlorinated rubber, hydrochloric acid rubber), etc. .

  An example of the production of "semi-synthetic fibers" is that in regenerated fibers, fibers are obtained through chemical modification or reaction with chemicals, and they are not regenerated into chemicals derived from raw materials. For example, using a plant such as wood pulp, a protein-containing plant or plant as a raw material, cellulose, casein protein, rubber is treated with (anhydrous) acetic acid or the like to modify it, and this is dissolved in a solvent such as acetone, The solution is filtered to make a stock solution, and a solution prepared by adding volcanic ash and, if necessary, additives to this stock solution is discharged through a nozzle or from pores (bases) having a plurality of desired calibers, and the solvent Can be obtained by evaporation.

  As "synthetic fiber (synthetic polymer)", polyamide fiber (nylon, nylon 6, nylon 66, aromatic nylon), aromatic polyamide fiber (aramid), polyvinyl alcohol (vinylon), polyvinylidene chloride ( Polyvinylidene fiber, polyvinyl chloride fiber (polyvinyl chloride), polyester fiber (polyester), polyacrylonitrile fiber (polyacrylonitrile fiber, modacrylic fiber), polyolefin fiber (polyethylene fiber, polypropylene fiber, polystyrene fiber), poly Examples thereof include ether ester fibers (Lexe and Success), polyurethane fibers (polyurethane), polyimide fibers (polyimide), acrylate fibers, ethylene vinyl alcohol fibers, polychlor fibers and the like.

  As an example of the production of “synthetic fiber”, a solution prepared by adding volcanic ash and, if necessary, an additive to a solution obtained by dissolving a chemically synthesized polymer as a raw material in a solvent, through a nozzle Alternatively, it can be obtained by evaporating the solvent by discharging from pores (caps) having a plurality of desired diameters.

  The chemical fiber production method is as described above, but if roughly classified, there are three methods, a melting method (spinning), a wet method (spinning) and a dry method (spinning). The “melting method” is generally a method of melting a polymer exhibiting thermoplasticity such as polyester, nylon, polypropylene, discharging it from a nozzle or a die without dissolving it in a solvent and producing it, which is simple and easy. The manufacturing method is low in manufacturing cost. The "wet method" is a method of producing a fiber in a liquid called a coagulant by dissolving a polymer in a solvent, and a method of producing acrylic, rayon, vinylon and the like. The "dry method" is a method in which a polymer is dissolved in a solvent which is easy to evaporate, and the mixture is heated while being spun in the air to evaporate the solvent. It is a method of producing acetate, polyurethane, acrylic and the like. Other than these, "gel spinning" utilizing stretching, "liquid crystal spinning" utilizing liquid crystal orientation, etc. may be mentioned.

  Chemical fibers may be filaments (long fibers: multifilaments, single fibers: monofilaments), staples (short fibers). In addition, after spinning, it may be subjected to drawing (processing to give a fiber an appropriate strength and elongation). Further, as an operation of twisting, drawing, etc., a drawn yarn (FOY), a semi-drawn yarn (POY), or a drawn yarn (DTY) may be carried out. Furthermore, after spinning, spinning (spun staples into yarns), blending (separating two or more different staples and spinning), twisting (filaments or spinning yarns), crossing A desired fiber (yarn) can be obtained by twisting (twisting while mixing two or more different kinds of yarn). In addition, the cross section of the fiber can also be in various shapes such as a circle, an ellipse, a polygon, a Y shape, a star shape, etc., and touch feeling, feeling, gloss, color and the like can be improved. Moreover, it can be comprised as a hollow fiber which made the inside of a fiber a hollow, and can exhibit desired functions (heat dissipation, moisture retention, heat storage, soundproofing etc.).

  Chemical fibers can be made into textiles and fabrics as “textiles”, “knitted fabrics” and “nonwoven fabrics” after being spun and made into yarns. The fabric or fabric may be colored by dyeing, dyeing, printing or the like. In addition, fabrics and fabrics are shrinkproof, flameproof, waterproof, moisture-permeable, water-repellent, water-repellent, water-repellent, antifouling, flame-retardant, antistatic, insectproof, antifungal, antibacterial and deodorant Processing may be performed according to various uses such as deodorizing processing.

  Chemical fibers are moisture-permeable waterproof materials, heat-insulating materials, heat-storage / warm-up materials, hygroscopic heat-generating materials, far infrared rays processed fibers, antibacterial / deodorant processed materials / bacterium-processed materials, abrasive materials, deodorized processed materials, mite-processed materials, antialleles It can be used for anti-material materials, pollen-preventing materials, electrification or charge control materials, heat fusion materials, flame retardant / disaster prevention materials, ultraviolet shielding materials, stretch materials, form stable materials and the like.

<< Application >>
Chemical fibers are further used as fiber materials for agriculture, forestry and fisheries. For example, clothing, bedding, textile materials for household goods; vehicle textile materials (eg, tire cords, safety belts, airbags, cushions, car body sheets, covers, etc. used for automobiles, airplanes, ships, space aircrafts, etc. Textile materials for civil engineering and rivers (Ground surface treatment materials (for preventing uneven settlement, textile materials for housing land and road construction)); Textile materials for surface protection (lining, textile materials for preventing erosion, textile materials for agriculture Textile materials for agriculture (coverage textile materials for agriculture, for example, insect-repellent net, heat retention sheet, light shielding sheet); textile materials for electricity, chemical industry (for example, V-belts, etc., clothing for clean rooms, heat insulation materials, filters, Insulating materials, packaging materials, etc.) Textile materials for construction (fiber materials for construction of ground, underground work, foundation work, etc.), waterproof layer reinforcement cloth, membrane, tents, asbestos substitute Fiber, concrete reinforcing fiber (FRC), curing sheet, etc .; fiber material for medical use (hospital, hygiene / medical equipment etc.), for example, artificial blood vessel, artificial dialysis module, surgical gown, sanitary goods , Bandages, etc .; Fiber materials used for human protection, safety equipment, etc. (eg, protective clothing, bulletproof clothing, fire protection clothing, camouflage net, safety work clothing etc.), marine textile materials (fishing, marine development, marine leisure) It is a textile material for, for example, fishing nets, ropes, artificial reefs, plastic reinforced fibers (FRP), etc.

  In the present invention, chemical fibers are preferably used in clothes (eg, underwear, jackets, pajamas, athletic clothes, coats, winter clothes, rainwear), bedding (eg, comforters, comforters, pillows, mattresses, etc. Covers, etc.), and textile materials for household goods (eg, cushions, carpets, mats, kotatsu beds, hangings, etc.). However, when it is in the form of chemical fiber, for example, yarn, fabric, etc., it can be used as an outer wrapping cloth and sewing yarn constituting the product. Specifically, as bedding, for example, it can be configured as a blanket, a comforter, a pillow, an outer wrapping constituting a mattress, and can be configured as a sewing thread of a product. As a textile material for household goods, it can be constituted, for example, as a cushion, a carpet mat, an outer wrapping constituting a kotatsu bed, and a hook, and can be constituted as a sewing thread of a product. Heat retention, heat buildup, heat storage, deodorization, flexibility, spreadability, fungicide, insect repellent, catalytic activity, adsorptive, substance (alkali, acid) since it contains volcanic ash spouted from an active volcano It is possible to exert excellent specialities such as exchangeability, detoxification, filterability, etc., and to provide a consumer with a plurality of functional products.

(Foam)
The physical and chemical material includes the above-mentioned volcanic ash and may be composed of chemicals and the like, for example, may be composed as a foam.
When the foam is used, the content of volcanic ash is more than 0% by mass and 70% by mass or less with respect to the total mass of the foam, and the lower limit is preferably 4% by mass or more, more preferably 20% by mass or more The upper limit thereof is preferably 50% by mass or less, more preferably 30% by mass or less.

  Foam (foamed plastic) is also referred to as polymer foam, and gas is finely dispersed in polymer (for example, chemical synthetic resin) which is a raw material, and it is molded into foam (foam) or porous shape. Say what was done. Foams are roughly classified into polyurethanes, polyethylenes, rubbers, and other foams, depending on the raw material. The foam in the present invention is configured as a foam, including the above-mentioned volcanic ash and, if necessary, additives. Hereinafter, although the composition of the foam is described, it is needless to say that the above-mentioned volcanic ash is included.

  Foams (foamed plastic) are low-molecular-weight oligomers, “casting-foaming molding method” in which a polymer is foamed during casting, “melt-foaming molding method” in which foaming is performed in a fluid state by heating, etc. It can be formed by the "solid phase foam molding method" which foams in a solid or similar state.

<< Polyurethane foam >>
The “urethane-based foam” is a foam which is made of a polyol and an isocyanate as main components and is foamed while being mixed with a foaming agent, a foam stabilizer, a catalyst, a colorant and the like to be resinified. Urethane foams are classified into ether urethane foams and ester urethane foams. By changing the composition of the components, it is possible to provide functionality such as high elasticity, low repulsion, specialized sound absorption, and conductivity.

The “soft urethane foam (soft PUF)” is a continuous, soft, recoverable urethane foam with a foam ratio of 10 to 60 and a density of about 16 to 100 kg / m ^3. You Among these, flexible urethane foams having a density of about 20 ± 5 kg / m ³ and a hardness of about 75 to 120 N are referred to as general purpose urethane foams.

  The “soft urethane foam (soft PUF)” is generally manufactured by using a block method of post-processing a foamed product (slab) and a molding method of foam-forming in a mold, among cast foam-forming methods. It is. In the block method, a raw material in which a synthetic resin and volcanic ash are mixed is discharged and free-foamed, and it can be manufactured using a horn-like or clam-like lump-like foam.

"High-quality urethane foam (high-quality PUF)" is a urethane foam characterized by high resilience, quick deformation and return compared to general-purpose urethane foam. The “high-quality urethane foam (high-quality PUF)” is a flexible urethane foam having a density of about 35 ± 5 kg / m ³ and a hardness of about 150 N.

  For "high quality urethane foam (high quality PUF)", various methods of cast foam molding are used. At that time, there is a one-shot method in which all the raw materials are mixed and foamed at one time, and a premix method in which a liquid in which only raw materials except isocyanate is mixed are separately prepared and isocyanates are separately prepared and mixed and foamed. The block method and the molding method conform to the method of producing a flexible PUF foam, but there is no crushing step. In the molding method, a relatively dense skin layer is formed, which enables insert molding of metal parts and the like, and also improves water resistance.

  In addition to the above, “urethane foam” includes low-resilience urethane foam, semi-rigid urethane foam, urethane chip foam, ester urethane foam, conductive antistatic polyurethane foam, sound absorbing urethane foam, water seal urethane foam, Filter urethane foam, microcell urethane foam, heat compression urethane etc. are mentioned.

<< polyethylene-based foam >>
The "polyethylene foam" has low water absorption, and is excellent in flexibility and compressive strength. The “polyethylene foam” is mainly made of polyethylene such as low density polyethylene, high density polyethylene, linear polyethylene and the like, and ethylene-vinyl acetate copolymer (EVA) and ethylene-propylene copolymer are used. The blowing agents are azodicarbonamide and N, N-dinitrosopentamethylenetetramine in the decomposition type organic system, hydrocarbons or halogenated hydrocarbons such as butane and pentane in the volatile state, carbon dioxide and nitrogen in the inert gas Etc. are used. As a crosslinking agent in the crosslinking foaming method, an organic peroxide system such as dicumyl peroxide is used.

  The "polyethylene foam" can be produced by a melt foam molding method. It is a method of mixing a foaming agent and volcanic ash with polyethylene (PE) and heating it again. In addition to the above, PE light, PE light Z, Sampercapef, Softlon, Opcel, rubberlike polyethylene, conductive and antistatic polyethylene, open-celled polyethylene, environment-type polyethylene, etc. may be mentioned as “polyethylene foam”. .

<< Polystyrene foam >>
The "polystyrene foam" is also called "expanded polystyrene". Generally, general purpose polystyrene is used as a main raw material, and hydrocarbons having a boiling point lower than the softening point of PS (propane, butane, pentane, hexane, heptane, cyclohexane, etc.) are used alone or in combination as the foaming agent. Volcanic ash is mixed with this to form bubbles.

  In order to form uniform and fine bubbles in extrusion molding (XPS, PSP), “polystyrene foam” is silica or talc powder in inorganic, combined use of citric acid-sodium bicarbonate in organic, and reaction compound etc. It is used as an agent. As the foaming agent, an evaporation type (low boiling point solvent utilization method) and a decomposition type (chemical reaction gas utilization method) are used. In the decomposition type, gases generated from nitrogen and carbon dioxide easily permeate PS and it is difficult to increase the expansion ratio.

<< Polypropylene-based foam >>
The “polypropylene-based foam” is one using polypropylene (PP) as a raw material, and is relatively high in heat resistance. The “polypropylene-based foam” is produced by mixing a crosslinking agent and volcanic ash with polypropylene (PP) and using a pressure foaming method.

<< Rubber foam >>
The “rubber-based foam” is produced by mixing various materials such as an organic-based foaming agent with synthetic rubber or special rubber and thermally decomposing it, and has a lightweight and strong material. The “rubber-based foam” can be produced by mixing a crosslinking agent, a foaming agent, and volcanic ash with rubber (synthetic) and heating to form bubbles. Examples of the "rubber-based foam" include CR-based rubber sponges, NR-based rubber sponges, NBR-based rubber sponges, EPDM-based rubber sponges, epto-sealers, Lucila, Opsler, rubber tip sponges and the like.

<< Other foams >>
Other foams include silicone foam, melamine sponge, acrylic foam, EVA, Transcool and the like, which are produced by the above-mentioned production method.

<< Application >>
The foam may be identical to the chemical fiber application described above. Especially, since it is a foam (sponge, foam), it can be utilized as an inclusion which constitutes a product. Specifically, as the bedding, for example, it can be configured as a mattress, a comforter, a pillow, and an inclusion constituting a mattress. As a textile material for household goods, it can be constituted, for example, as an inclusion which constitutes a cushion, a carpet, a mat, a kotatsu bed, and a hook. Since the foam according to the present invention contains volcanic ash ejected from an active volcano, it has heat retention property, heat buildup property, heat storage property, deodorizing property, flexibility, spreadability, bacteria resistance, insect repellent property, catalytic activity, adsorption property It is possible to exert excellent special properties such as substance (alkali, acid) exchangeability, detoxification, filterability, etc., and it becomes possible to provide a plurality of functional products to the consumer.

(Structure)
The physical and chemical material includes the above-mentioned volcanic ash, and may be composed of a chemical substance or the like, for example, may be composed as a structure.
In the case of "structure", the content of volcanic ash is more than 0% by mass and 70% by mass or less, and the lower limit is preferably 4% by mass or more, more preferably 20% by mass with respect to the total mass of the foam. %, And the upper limit thereof is preferably 50% by mass or less, more preferably 30% by mass or less.

  The “structure” may be configured to include a chemical substance (polymer compound) and volcanic ash to form a specific shape. In addition, the form of the “structure” may be a polygon, a cylinder, a sphere, a cone, a polygonal pyramid or the like, and may be a sheet, a film or a hollow body.

  The “structure” can be produced by mixing a polymer compound (for example, resin), volcanic ash, a curing agent, a polymerization initiator, and other additives, and heating and pressing. Resins are roughly classified into thermosetting resins and thermoplastic resins. As a thermosetting resin, phenol resin (PF), epoxy resin (EP), melamine resin (MF), urea resin (urea resin, UF), unsaturated polyester resin (UP), alkyd resin, polyurethane (PUR), A thermosetting polyimide (PI) etc. are illustrated.

  Further, as the thermoplastic resin, polyethylene (PE), high density polyethylene (HDPE), medium density polyethylene (MDPE), low density polyethylene (LDPE), polypropylene (PP), polyvinyl chloride (PVC), polyvinylidene chloride, Examples include polystyrene (PS), polyvinyl acetate (PVAc), polyurethane (PUR), Teflon (polytetrafluoroethylene, PTFE), ABS resin (acrylonitrile butadiene styrene resin), AS resin, acrylic resin (PMMA) and the like.

  In the case of using a thermoplastic resin, a raw material mixture is heated and softened, and then pressed into a mold to be cooled and solidified to use injection molding for forming a final product. Due to the characteristics of the thermoplastic resin, the toughness is superior to that of the thermosetting resin, and although the molding temperature is high, since the molding can be performed in a short time, the productivity is excellent.

  When forming as "engineering plastic", as a raw material, polyamide (PA), nylon, polyacetal (POM), polycarbonate (PC), modified polyphenylene ether (m-PPE, modified PPE, PPO), polyester (PEs), Polyethylene terephthalate (PET), glass fiber reinforced polyethylene terephthalate (GF-PET), polybutylene terephthalate (PBT), cyclic polyolefin (COP), etc. are used as a raw material.

  When forming as a "super engineering plastic", polyphenylene sulfide (PPS), polytetrafluoroethylene (PTFE), polysulfone (PSF), polyether sulfone (PES), amorphous polyarylate (PAR) as a raw material Examples thereof include liquid crystal polymers (LCP), polyetheretherketone (PEEK), thermoplastic polyimide (PI), and polyamideimide (PAI).

<< Application >>
The structure may be identical to the chemical fiber and foam applications described above. In particular, since the structure can form various forms, it can be used as an inclusion that constitutes a product. Specifically, as the bedding, for example, it can be configured as a mattress, a comforter, a pillow, and an inclusion constituting a mattress. As a textile material for household goods, it can be constituted, for example, as an inclusion which constitutes a cushion, a carpet, a mat, a kotatsu bed, and a hook. Since the structure according to the present invention contains volcanic ash ejected from an active volcano, it has heat retention property, heat buildup property, heat storage property, deodorizing property, flexibility, spreadability, bacteria resistance, insect repellent property, catalytic activity, adsorption property It is possible to exert excellent special properties such as substance (alkali, acid) exchangeability, detoxification, filterability, etc., and it becomes possible to provide a plurality of functional products to the consumer.

  Although an example of the embodiment of the present invention is explained below, the scope of the present invention is not interpreted as being limited to these examples. In addition, the present invention solves the problems according to the present invention by reading the entire specification and by the following embodiments, and those skilled in the art can easily carry out all the contents of the present invention. It is a thing.

[Volcanic ash / Shirasu]
(Example) As a volcanic ash of an active volcano, the thing of the fine particle which erupted from Sakurajima which is an active volcano of Kagoshima Prefecture, Japan, and which collected within about three months was used.
(Comparative example)
Shirasu used fine particles collected from the Shirasu plateau (approximately 30,000 years ago volcanic ash: dated by C14 dating method) that forms the ground of Kagoshima Prefecture, Japan.
The physical properties such as the average particle diameter of the fine particles were substantially the same in both the example and the comparative example.

[Preparation of physical and chemical materials]
(1) Textile fabric An aromatic isocyanate compound having a urethane bond (-O. CO. NH-) as a polymer raw material in N, N-dimethylformamide solvent, and volcanic ash fine particles of an active volcano according to an example or a comparative example A raw material composition to which 30% by mass each of shirus fine particles is added is wet-spun and knitted to prepare a urethane chemical material (fiber fabric) having a weight per unit area of about 500 g / m 2 and a thickness of about 1 mm. It is referred to as Example 1 and Comparative Example 1.

(2) Hollow beads A raw material composition to which 4 mass% of polyethylene and the fine volcanic ash particles of the active volcano according to the example or the silas fine particles according to the comparative example were respectively added was introduced into a forming device and molded into a hollow shape A polyolefin chemical material (structure: hollow bead) was prepared, which was referred to as Example 2 and Comparative Example 2. The hollow beads had a length × width × thickness of about 2 cm × about 2 cm × about 1.3 cm, a hollow structure, and a bead film thickness of about 0.5 mm.
〔Evaluation test〕

[Evaluation 1: Heat re-emission characteristic evaluation]
[Evaluation method 1]
Example 1 and Comparative Example 2 were evaluated using a 45-degree parallel re-emission method (according to Far Infrared Association (one company) recognition rule).
The 45 degree parallel re-emission method was performed using the apparatus outlined in FIG. This measuring apparatus measures the amount of far infrared rays emitted from the sample stand 4 for placing the sample 3 disposed on the measurement stand 1, the heater 5 for heating the sample 3 placed on the measurement stand frame 2, and the sample The camera comprises a thermography camera 6 and a monitor 7. Sample 3 consists of a measurement sample (Example 1) and a control sample (Comparative Example 2), and the surface temperature of both samples is measured every 15, 30, 60, 120, T ((s / sec) by a thermoviewer. The temperature was measured (n = 5) and the temperature difference (ΔT) was determined. The test was performed twice, with the left and right sides replaced. The measurement results were as shown in [Table 2] below.

[Evaluation result 1]
ΔT = 0.6 ° C. (n = 5) (a significant difference was observed with a confidence limit of 99% (Pr: 0.01)).
Therefore, it was understood that the amount of far infrared radiation in Example 1 is higher than that in Comparative Example 1. That is, compared with the fabric of Comparative Example 1, the fabric of Example 1 has enhanced absorption and re-emission characteristics (far-infrared effect) with respect to far-infrared rays in a wide wavelength range, and improves heat retention in extremely high dimensions ( It was understood that it was achieved.

[Evaluation 2: Thermal property evaluation]
[Evaluation method 2]
Thermal characterization was performed on Example 2 and Comparative Example 2 using the surface temperature measurement device outlined in FIG. In this measurement apparatus, hollow beads of samples (Example 2 and Comparative Example 2) arranged on a sample table were arranged in a row of five in length and six in total of 30 in total. Under the following [Evaluation condition 2], the surface temperature of the sample when the reflex lamp was irradiated was measured over time with a thermo camera. The measurement was performed twice by exchanging the positions (right and left) with the sample (Example 2 and Comparative Example 2), and the measurement data was taken as an average value.

[Evaluation condition 2]
Used lamp: Iwasaki Denki Co., Ltd. eye lamp <spot> PRS 100 V 500 W
Irradiation distance: 50 cm
Irradiation Surface: Front side Irradiation time: 15 minutes Laboratory temperature: 20 ± 2 ° C
Thermo camera: FLIR T430sc (emissivity 0.94) manufactured by FLIR SYSTEMS JAPAN LTD.

[Evaluation result 2]
The results of the surface temperature over time were as described in [Table 3], [Table 4] and [Figure 3] below. [Table 3] and [Table 4] are average temperatures in the thermo image (for example, [Fig. 3]) in the measurement apparatus of [Fig. 2]. The average temperature is calculated in consideration of including the temperature of the sample table.
As described in [Table 3], [Table 4] and [FIG. 3], it was understood that Example 2 had extremely high heat absorbability (thermal characteristics) due to temporal change as compared to Comparative Example 2. .

[Evaluation 3: Moisturizing evaluation]
[Evaluation method 3]
Test pieces of the same standard were prepared from the fabric of Example 1 and Comparative Example 1, and each material was dried with a dryer, and then the respective weights were measured. After moisture absorption at 40 ° C. × 90% RH, the mass of each sample was measured after 1 to 4 hours. Thereafter, after releasing moisture at 20 ° C. × 65% RH, the mass of each sample was measured after 1 to 4 hours.

[Evaluation result 3]
The evaluation results were as shown in the following [Table 5] and [Table 6] (graph). As shown in the results shown in [Table 5] and [Table 6], it was understood that Example 1 had extremely high moisture retention as compared with Comparative Example 1.

[Evaluation 4: Deodorant and deodorant evaluation]
It carried out according to the sensory evaluation test in SEK mark textiles product recognition standard (deodorizing test) in a fiber evaluation technology meeting (one company).
[Evaluation method 4]
1) A mixture of ammonia, acetic acid and isovaleric acid was prepared as a sweat odor.
2) A mixture of ammonia, acetic acid, isovaleric acid and nonenal was prepared as an aged odor.
A sample having a total mass of about 1.0 g is prepared with respect to about 10 g of each of Example 1, Example 2, Comparative Example 1 and Comparative Example 2, and the above 1 ) And 2) were placed in a 500 ml Erlenmeyer flask and sealed. Two hours after sealing, the atmosphere odor in the Erlenmeyer flask is compared with the standard odor (equivalent to odor intensity 2.0), and a panelist (applicant employee 18 to 65 years of five male and 20 females in total) 10 Evaluated by name). Evaluation was performed according to the following [Evaluation Criteria 4].

[Evaluation criteria 4]
The odor after 2 hours was evaluated by the number of persons who correspond to the following criteria in comparison with the standard odor. The results were as described in the following [Table 7].
Evaluation ◎: There was no odor after 2 hours.
Evaluation :: The odor after 2 hours was comparable to the reference odor.
Evaluation :: The odor after 2 hours exceeded the standard odor.

[Evaluation result 4]
In Example 1 and Example 2, it was judged that all 10 persons had no odor. On the other hand, Comparative Example 1 and Comparative Example 2 were judged to be equivalent to the reference odor, or that an odor exceeding the reference odor remained.
Therefore, it was understood that the examples had higher deodorizing properties and deodorizing properties as compared with the comparative examples.

Claims (10)

It is a physical and chemical material equipped with the volcanic ash of the active volcano,
The physical and chemical material, wherein the volcanic ash is ejected from an active volcano and is within 100 years from the time of ejection.    The physical and chemical material according to claim 1, wherein the volcanic ash is ejected from an active volcano and is within 50 years from the time of ejection.    The physical and chemical material according to claim 1, wherein the volcanic ash is ejected from an active volcano and is within 5 years from the time of ejection.    The physical and chemical material according to any one of claims 1 to 3, wherein the physical and chemical material is a chemical fiber, a foam or a structure provided with volcanic ash of the active volcano.   The physical and chemical material according to claim 4, wherein the chemical fiber is a purified fiber, a regenerated fiber, a semi-synthetic fiber, or a synthetic fiber.   The physical and chemical material according to claim 4 or 5, wherein the chemical fiber is a filament, a stable, a spinning, a woven fabric, a knitted fabric or a non-woven fabric.   The foam is a polyurethane foam, a polyethylene foam, a polystyrene foam, a polypropylene foam, a rubber foam, a silicone foam, a melamine sponge, an acrylic foam, EVA, or Transcool. Physical and chemical materials described in.   The physical and chemical raw material according to claim 4, wherein the structure comprises the volcanic ash of the active volcano, and a thermoplastic resin or a thermosetting resin.   Moisture-permeable waterproof material, thermal insulation material, thermal storage and insulation material, hygroscopic heat generation material, far infrared ray processed fiber, antibacterial / deodorant processed material / bacterium-processed material, abrasive material, deodorized processed material, mite-processed material, antiallergenic material, The physical property according to any one of claims 1 to 8, which is a pollen prevention material, a charge or charge control material, a heat fusion material, a flame retardant / disaster prevention material, an ultraviolet light shielding material, a stretch material, or a form stable material. Chemical material The physical and chemical material according to any one of claims 1 to 8, which is a garment fiber material, a bedding fiber material, or a textile material for household goods.