JP2009280575A - Pest-exterminating material - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a pest-exterminating material with microencapsulated organophosphorus agent's new formulation, simple in application method and usable at any site, exhibiting long-term aftereffect and also exhibiting high effectiveness even on pests having resistance and/or repellency to organophosphorus agents, and to provide a method for controlling pests using this material. <P>SOLUTION: The pest-exterminating material is such as to be obtained by incorporating a carrier with a microencapsulated organophosphorus agent obtained by including an organophosphorus agent as core substance as a pest-controlling agent in polyurea-membrane microcapsules formed by an interfacial polymerization process between a polyisocyanate and a polyfunctional amine. A pest-exterminating instrument, and a method for controlling pests using the above pest-exterminating material or pest-exterminating instrument are also provided. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a pest control material for controlling pests, and particularly to a pest control material containing a pest control agent in a solid carrier.

Organophosphorus agents and pyrethroids are used to control pests such as cockroaches, bed bugs, fleas, ants, flies, and mosquitoes. Among these, organophosphorus agents are effective against a wide range of pests and have high safety to mammals, and are widely used as insecticide pest control agents. As an organic phosphorus preparation for pest control, emulsions, oils and powders adsorbed on solid carriers are used. However, organophosphorus agents have problems such as short medicinal sustainability due to rapid degradability and peculiar odor, and have problems in general use for home use and business use.
In order to solve these problems, a microencapsulated organic phosphorus agent in which an organic phosphorus agent is encapsulated in a microcapsule has been developed. This is a preparation that encapsulates the medicinal component and suppresses the decomposition of the medicinal component and its odor to solve the above-mentioned problems and to give higher safety to the sprayer. The microencapsulated organophosphorus agent is marketed mainly as a spray agent for dispersion in water, and a prescription for spraying the entire floor surface is recommended, and an excellent pest control effect is exhibited. Therefore, it is desired to develop a new pesticide using a microencapsulated organophosphorus agent that is easier to handle and maintain while maintaining this pest control effect. Patent Document 1 discloses an insect repellent paper in which a microencapsulated organic phosphorus agent is attached to a mount. According to Non-Patent Document 1, it is disclosed that the capsule membrane material of the diazinon MC suspension (imported product) used in these examples is a polyamide-polyurea membrane. Patent Document 2 discloses a pest killing device in which a microencapsulated organic phosphorous agent is applied to the inside of a cylindrical body having a hole in its side surface. This uses a microencapsulated fenitrothion preparation as an organic phosphorus agent, and a higher pest-killing effect is obtained as compared with a pest-stimulator that treats fenitrothion that is not microencapsulated. Non-Patent Document 2 describes that the microcapsule membrane material of the microencapsulated fenitrothion preparation is a polyurethane membrane.

JP 2001-128608 A JP 10-23851 A

Development of follow-up medicines Vol.18 Development of pesticides I page 105 Yodogawa Shoten Journal of Pesticide Science No. 12, Vol. 23-27, 1987

Most microencapsulated organophosphorus agents are commercially available as spraying agents, but they must be sprayed over the entire floor where insect pests are supposed to come in contact. There is a problem. In addition, many organic phosphorus agents have a problem that drug-resistant insect pests are easily developed by repeated use, and repellency is also observed. Even with existing microencapsulated organophosphorus agents, the problems of drug resistance and drug repellency cannot be improved, and there is a problem that a certain extermination effect cannot be obtained over a long period of time.
In order to solve these problems, the object of the present invention is a micro application that has a simple application method and can be used regardless of scenes, exhibits long-lasting residual effects, and is highly effective against organophosphate-resistant pests. The object is to provide a new pest control material using an encapsulated organophosphorus agent.

The present inventors have found that a pest control material obtained by incorporating a microencapsulated organophosphorus agent having a specific film composition into a carrier exhibits a remarkably excellent effect on the above problems, and have reached the present invention. The contents of the present invention are as follows.
(1) A microencapsulated organic phosphorous agent containing an organic phosphorous agent as a core substance in a polyurea film microcapsule by interfacial polymerization of polyisocyanate and polyfunctional amine is contained in a carrier. Pest control material.
(2) The pest control material according to (1), wherein the organic phosphorus agent is diazinon or propetanephos as a pest control agent.
(3) The pest control according to (1) or (2), wherein the carrier is a carrier formed by combining one or more selected from the group consisting of a fiber carrier, a porous carrier, and a water-absorbing polymer carrier. Wood.
(4) The pest control material according to (3), wherein the fiber carrier is a carrier formed by combining one or more selected from the group consisting of papers and fabrics.
(5) The pest control material according to (3), wherein the porous carrier is a carrier formed by combining one or more selected from the group consisting of silica, clay, vermiculite, pumice, and sponge.
(6) The pest control material according to (3), wherein the water-absorbing polymer carrier is a polyacrylate.
(7) The pest control material according to any one of (1) to (6), wherein the organophosphorus agent contains 5 to 5000 μg / cm ² per surface area of the carrier.
(8) The pest control material according to any one of (1) to (7), wherein the pest is a cockroach, a bed bug, or a mosquito.
(9) A pest control device using the pest control material according to any one of (1) to (8).
(10) A pest control method using the pest control material or pest control device according to any one of (1) to (9).

  The present invention provides a microencapsulated organic phosphorus agent-containing insect pest control material that exhibits long-term residual efficacy and high effectiveness against organophosphate-resistant insect pests. This pesticide is a solid preparation of microencapsulated organophosphorus agent, which is highly safe, easy to handle and can be used regardless of the situation. Moreover, it can be used as a pest control device incorporating this control material as a medicinal component-containing member. The pest control device using this disinfectant has the same insecticidal effect and long-term residual effect as conventional floor spraying with a conventional spraying agent, and is an easy-to-handle dosage form, so it is a general household and commercial pest control device. Can be used as Further, even when installed on the oil film surface, it exhibits a sufficient insecticidal effect and can maintain the effect for a long period of time.

  The microencapsulated organophosphorus agent used in the present invention is desirably a microencapsulated preparation with a moderately controlled release rate of the encapsulated drug. A microcapsule preparation method satisfying this performance is a method of preparing a polyurea film microcapsule by an interfacial polymerization method using a polyvalent isocyanate and a polyfunctional amine, and the polyvalent isocyanate is an aromatic isocyanate and a non-aromatic isocyanate. The aromatic isocyanate can be used alone or mixed with a non-aromatic isocyanate. A specific preparation method may be performed with reference to the method described in JP-A-9-249505, and a microencapsulated organic phosphorus agent suitable for the present invention can be obtained. That is, an organic phosphorous agent which is a core substance and a polyvalent isocyanate are mixed, added to an aqueous solution to which a dispersant is added, and a dispersion in which fine particles are suspended by stirring is prepared. This can be obtained by adding a polyfunctional amine with stirring to form a polyurea capsule film on the surface of the dispersed particles.

  Examples of the organophosphorus agent include dichlorvos, diazinon, fenitrothion, phenanthion, temefos, trichlorphone, chlorpyrifosmethyl, pyridafenthion, propetanephos, and the like. In the present invention, diazinon and propetanephos are preferable. Propetanephos is particularly preferable.

  In the preparation of microcapsules, it may be used as is if the organic phosphorous agent that is the core substance is liquid, and difficult if it is poorly mixed with solid or polyisocyanate, or poorly dispersible in water. A water-soluble or water-insoluble organic solvent may be dissolved in one or a mixture thereof. Examples of poorly water-soluble and water-insoluble organic solvents include hydrocarbons such as hexane, heptane, paraffin and isoparaffin, aromatic hydrocarbons such as toluene, xylene and alkylbenzene, ethers such as butyl ether and ethyl vinyl ether, dichloromethane, Examples include organic chlorines such as trichloroethane, mineral oils such as machine oil, and vegetable oils.

  In the preparation of the microcapsule preparation suitable for the present invention, as the polyvalent isocyanate, a mixture of aromatic isocyanate and non-aromatic isocyanate can be used, or aromatic isocyanate alone can be used. Examples of the aromatic isocyanate include 2,4-toluene diisocyanate, 2,6-toluene diisocyanate, methylene-bis- (4-phenyl isocyanate), polymethylene polyphenyl polyisocyanate, and the like. Examples of non-aromatic isocyanates include tetramethylene diisocyanate, pentamethylene diisocyanate, hexamethylene diisocyanate, trimethylhexamethylene diisocyanate, and isophorone diisocyanate. Polyvalent isocyanates may be used alone or in combination of two or more.

  Examples of the dispersant for dispersing the organic phosphorous agent and the polyvalent isocyanate mixed solution in water include high acrylic polymers, (meth) acrylic acid copolymers, maleic acid copolymers, carboxymethylcellulose, polyvinyl alcohol, and the like. Molecular substances, natural polysaccharides such as xanthan gum, gum arabic, and sodium alginate, polyoxyethylene alkyl ethers, polyoxyethylene alkyl esters, polyoxyethylene alkylphenyl condensates, sorbidan fatty acid esters, etc. alone or in combination Are used in combination. These are added in an amount of 0.1 to 10% by weight, more preferably 0.1 to 5% by weight, based on the entire dispersion.

  Examples of the polyfunctional amine include tetramethylenediamine, pentamethylenediamine, hexamethylenediamine, ethylenediamine, propylene-1,3-diamine, diethylenetriamine, triethylenetriamine, tetraethylenepentamine, 1,3-phenylenediamine, 2, There are 4-toluylenediamine and the like, and these may be used alone or in combination of two or more.

  Furthermore, a thickener, an antifreezing agent, a stabilizer, a synergist, an antifungal agent, a coloring agent, an aromatic, etc. can be added as needed. The obtained microencapsulated organic phosphorous agent is obtained as a suspension in water, and the particle diameter is not particularly limited, but is usually 3 to 50 micrometers, preferably 5 to 40 micrometers.

  The microencapsulated organic phosphorus agent suitable for the present invention obtained by the above preparation method is obtained as a suspension in water, but is a mixed solvent with an appropriate volatile water-soluble organic solvent that does not destroy the microcapsule dispersion system. It can also be used as a dispersion. Suitable organic solvents include methanol, ethanol, 2-propanol, acetone, acetonitrile, tetrahydrofuran, 1,4-dioxane, and the like. These may be used alone or in combination of two or more. The content of the microencapsulated organic phosphorus agent dispersion is not particularly limited.

  The microencapsulated organic phosphorous agent can be used by diluting a commercially available microencapsulated organic phosphorous agent aqueous dispersion with water or a volatile water-soluble organic solvent. Commercially available microencapsulated organophosphorus agents suitable for the present invention are diazinon SL sol (manufactured by Nippon Kayaku Co., Ltd.), diazinon MC suspension (manufactured by Nippon Kayaku Co., Ltd.), saflotin MC (Nippon Kayaku Co., Ltd.). ), Arista Life Science Co., Ltd., Sankyo Agro Co., Ltd.). These are preparations having the above-mentioned specific microcapsule film composition and are preferable. In particular, saflotin MC (manufactured by Nippon Kayaku Co., Ltd., Arista Life Science Co., Ltd., Sankyo Agro Co., Ltd.) is more preferred.

As the carrier used in the present invention, any one of a fiber carrier, a porous carrier, a water-absorbing polymer carrier, or a carrier formed by combining two or more types can be used. As a specific carrier, an aqueous dispersion containing a microencapsulated organic phosphorous agent can be uniformly applied, the organic phosphorous agent can contain ⁵ to 5000 μg / cm ² per surface area of the carrier, and interacts with the microencapsulated organic phosphorous agent. If it is a material which does not show, it will not specifically limit.

The fiber carrier is a carrier formed by combining one or more of papers and fabrics. Examples of paper include high-quality paper, cardboard, Kent paper, kraft paper, filter paper, Japanese paper, cardboard and the like. Thick paper, filter paper, and Japanese paper are preferred. Among cardboard, coated cardboard is rich in water absorption on one side and is inexpensive and easy to process. Also, the surface of the paper carrier is durable by applying varnish, vinyl, press coat, polypropylene film, polyethylene film, polypropylene mat, polyethylene mat, foil stamping, embossing treatment, etc. to protect the formulation from oil, moisture, dirt, etc. It is also possible to improve printing performance or to perform printing that integrates with the installation environment. Cloths include natural fiber materials such as cotton, hemp, silk, and wool, and synthetic fiber materials such as rayon, polyamide fiber, acrylic fiber, polyester, and polyethylene. Can do. Cotton and polyester are preferred as the cloth material. Any fiber material of any shape and thickness can be used.
Examples of the porous carrier include inorganic carriers such as silica, clay, vermiculite and pumice, and foamable resin carriers such as sponges. Examples of sponges include polyurethane foam, rubber sponge, polyolefin foam and the like, and polyurethane foam sponge is more preferable.
Examples of the water-absorbing polymer carrier include polyacrylic acid, alginic acid, carboxymethylcellulose, propylene naglycol and the like, salts thereof, and cross-linked products of these polymers. Polyacrylate is preferred, and sodium polyacrylate is particularly preferred.

The carrier can be used alone or in combination of two or more. Particularly preferred carriers in the present invention are cardboard, non-woven fabric, and cotton fabric. A more preferable carrier is cardboard, and it is particularly suitable to mold the preparation with coated cardboard processed on one side with varnish or polypropylene film.
Moreover, the composite material which affixed this support | carrier on various molded plates, such as hard paper, wood, a metal, glass, a plastic, can also be used.

  The shape of the carrier of the present invention is not particularly limited, but since pests have a habit of favorably entering a narrow and dark space, a fold fold process of about 1 to 2 cm, a cylindrical shape of about 1 to 5 cm in diameter, or about 1 to 5 cm of a piece It can also be processed into a rectangular tube shape or a belt shape. More preferably, it is suitable to form a triangular tube or a rectangular tube having a right angle in cross section so that the length can be set to about 10 to 30 cm so that it can be installed on the floor without creating a gap between the wall and the wall. For flying insects, a sheet-like material that can be processed on the surface of air-permeable materials such as curtains and screen doors, or can be easily suspended or attached to indoor walls or ceilings where insects are likely to anchor. It can be processed into a shape.

In addition to the microencapsulated organic phosphorus agent, the present invention includes organic phosphorus agent, carbamate insecticide, pyrethroid insecticide, neonicotinoid insecticide, pyrrole insecticide, phenylpyrazole insecticide, benzoylphenyl It is also possible to add other insecticidal active ingredients such as urea insecticides and insect growth inhibitors.
Examples of the organic phosphorus agent include dichlorvos, diazinon, fenitrothion, phenanthion, temefos, trichlorfone, chlorpyrifosmethyl, pyridafenthion, propetanephos, and the like. Examples of carbamate insecticides include oxamyl, butkin carboxyme, mesomil, BPMC, MIPC, MPMC, MTMC, NAC, PHC, XMC, pirimicarb, propoxur and the like. Examples of pyrethroid insecticides include permethrin, phenothrin, allethrin, phthalthrin, d-T80-restmethrin, mushroom extract, acrinathrin, bifenthrin and the like, and neonicotinoid insecticides include thiamethoxam, imidacloprid, dinotefuran, clothianidin, and nitenpyram. , Acetamiprid, etc., pyrrole pesticides include chlorfenapyr, phenylpyrazole pesticides include fipronil and etiprole, benzoylphenylurea pesticides include bistrifluron, chlorfluazuron, hexa Fulmuron is exemplified, and examples of the insect growth inhibitor include diflubenzuron, pyriproxyfen, metoprene, chromafenozide and the like.

  In the present invention, if necessary, a binder agent, a pH adjuster, and a fragrance may be added singly or in combination of two or more. Examples of the binder agent include water-soluble polymers such as polyvinyl alcohol, polyethylene glycol, polypropylene glycol, and polyvinyl pyrrolidone. Moreover, the said water-soluble polymer can also be used as a thickener. These contain microencapsulated organophosphorus agents in a carrier and are used for the purpose of efficiently attaching an insecticidal active ingredient. Moreover, you may add food fragrance | flavor as a pest attracting component. Each additive component can be used alone or in combination of two or more.

The pest control material according to the present invention can be prepared by storing an aqueous dispersion of a microencapsulated organic phosphorus agent in a carrier. Examples of the storage method include a method of immersing these carriers in a microencapsulated organic phosphorus agent dispersion, a method of applying the dispersion, and a method of spraying the dispersion. More preferably, a quantitative and uniform spray surface can be obtained by performing spraying into the preparation with a two-fluid nozzle after molding. The coating amount of the organic phosphorous agent is not limited, but it can be contained in the carrier in the range of 5 to 5000 μg / cm ² , and preferably contains 10 to 200 μg / cm ² as the organic phosphorous agent. The carrier containing these drugs can be dried if necessary and used as a pest control material. When adding a binder, pH adjuster, or fragrance to the pest control material as necessary, a solution or suspension of these additives in water and / or a volatile organic solvent is included in the microencapsulated organic phosphorous agent. It can be obtained by overcoating or spraying the dried pest control material and drying it. Alternatively, these additives can be added to a microencapsulated organic phosphorus agent dispersion to prepare a uniform solution or suspension, which is stored in a carrier by the above-described method, and dried if necessary.

  The pest control material of the present invention can be used as a medicinal component supporting member of a pest control device. That is, not only the shape described above but also a part of the internal structure of the pest control device can be used as a medicinal component-containing member. In that case, the shape of the disinfectant can be molded into any shape according to the shape of the disinfectant used.

  The pest control material of the present invention can be applied to control dwarf sanitary pests such as cockroaches, bed bugs, ants and termites, and flying sanitary pests such as mosquitoes and flies. In particular, it is a pest control material suitable for controlling cockroaches, bedbugs and mosquitoes.

The pest control device of the present invention uses coated cardboard processed on one side with varnish or polypropylene film as a more preferable carrier, and is formed into a rectangular tube shape having a right angle in cross section and molded to a length of about 10 to 30 cm. The microcapsules of the organic phosphorus agent are obtained by spraying with a two-fluid nozzle in the range of 10 to 200 μg / cm ² .

EXAMPLES Hereinafter, although an Example and a test example demonstrate this invention further in detail, this invention is not limited to these examples.
Example 1
A dispersion obtained by diluting 80 times of water with a microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) on a plate-like plate formed of 10 cm square of cardboard (0. 25 mL of a liquid containing 25% by weight) was sprayed and air-dried at room temperature for 24 hours to prepare Example 1 using cardboard as a carrier.

Example 2
A dispersion obtained by diluting 80 times of water with a microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) on a plate-like plate molded into a 10 cm square filter paper (0. 5 as propetanephos). 25 mL of a solution containing 25% by weight) was sprayed and air-dried at room temperature for 24 hours to prepare Example 2 using filter paper as a carrier.

Example 3
A non-woven fabric (Tyvek No. 1056D) was cut into a 10 cm square, and a microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) diluted 80 times with water (as propetanephos) 0.25 wt% solution) was sprayed and air-dried at room temperature for 24 hours to prepare Example 3 using a nonwoven fabric as a carrier.

Example 4
A cotton cloth is cut into a 10 cm square, and a microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20 wt% as propetanephos) is diluted 80 times with water (0.25 wt% as propetanephos) (Liquid-containing solution) was sprayed in an amount of 0.5 mL and air-dried at room temperature for 24 hours to prepare Example 4 using cotton cloth as a carrier.

Example 5
A canvas was cut into a 10 cm square, and a microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) diluted 80 times with water (0.25% by weight as propetanephos) (Liquid-containing solution) was sprayed in an amount of 0.5 mL and air-dried at room temperature for 24 hours to prepare Example 5 using canvas as a carrier.

Example 6
On a plate-like plate molded into a 10 cm square urethane foam sponge, a microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) diluted 80 times with water (as propetanephos) 0.25 wt% solution) was sprayed and air-dried at room temperature for 24 hours to prepare Example 6 using urethane foam sponge as a carrier.

Example 7
A dispersion obtained by diluting microcapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., 20% by weight as propetanephos) 40 times with water on a plate-like plate formed of 10 cm square of cardboard (0,5 as propetanephos). 5 mL of 5 wt% solution) was sprayed and air-dried at room temperature for 24 hours to prepare Example 7 using cardboard as a carrier.

Example 8
A microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) diluted 5 times with water on one side of cardboard (4 × 20 cm) (containing 4% by weight as propetanephos) ) 2.5 mL was sprayed and air dried at room temperature for 24 hours. Example 8 was prepared by molding this chemical-treated cardboard into a vertically long rectangular tube with the chemical-treated surface inside.

Example 9
A non-woven fabric (Tyvek No. 1056D) cut to 10 cm square is folded about 1 cm, and microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) on one side with water Example 9 was prepared by spraying 3.0 mL of a 5-fold diluted dispersion (containing 4% by weight as propetanephos), air-drying at room temperature for 24 hours, and folding the nonwoven fabric as a carrier.

Example 10
A dispersion obtained by diluting a microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) 20 times with water (1. 0 ml (containing 0% by weight) was sprayed and air-dried at room temperature for 24 hours to prepare Example 10 using cardboard as a carrier.

Example 11
On a plate-like plate formed of 10 cm square filter paper, a microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) was diluted 20 times with water (propetanephos as 1. 0 ml (containing 0 wt%) was sprayed and air-dried at room temperature for 24 hours to prepare Example 11 using filter paper as a carrier.

Example 12
A dispersion obtained by diluting a microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) 40 times with water on a plate-like plate molded into a 10 cm square filter paper (0. 5 as propetanephos). 5 ml (containing 5% by weight) was sprayed and air-dried at room temperature for 24 hours to prepare Example 12 using filter paper as a carrier.

Example 13
A non-woven fabric (Tyvek No. 1056D) is cut into a 10 cm square, and a microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) diluted 20 times with water (as propetanephos) 1.0 ml of a solution containing 1.0% by weight) was sprayed and air-dried at room temperature for 24 hours to prepare Example 13 using a nonwoven fabric as a carrier.

Example 14
A non-woven fabric (Tyvek No. 1056D) was cut into a 10 cm square, and a microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) diluted 40 times with water (as propetanephos) 0.5 mL of a solution containing 0.5% by weight) was sprayed and air-dried at room temperature for 24 hours to prepare Example 14 using a nonwoven fabric as a carrier.

Example 15
A microcapsulated diazinon aqueous dispersion (diazinone MC suspension, Nippon Kayaku Co., Ltd., containing 23% by weight as diazinon) was diluted 46 times with water (as diazinon) 0.5 mL (containing 0.5 wt% liquid) was sprayed and air-dried at room temperature for 24 hours to prepare Example 15 using cardboard as a carrier.

Example 16
A microcapsulated diazinon aqueous dispersion (Diazinon MC Suspension, Nippon Kayaku Co., Ltd., containing 23% by weight as diazinon) was diluted 46 times with water (propetanephos as propetanephos) on a plate in which filter paper was formed into a 10 cm square. 0.5 mL (containing 0.5 wt% solution) was sprayed and air-dried at room temperature for 24 hours to prepare Example 16 using filter paper as a carrier.

Example 17
A non-woven fabric (Tyvek No. 1056D) was cut into a 10 cm square, and a dispersion obtained by diluting a microencapsulated diazinon aqueous dispersion (Diazinon MC suspension, Nippon Kayaku Co., Ltd., 23% by weight as diazinon) 46 times with water 0.5 mL of a liquid (containing 0.5% by weight as diazinon) was sprayed and air-dried at room temperature for 24 hours to prepare Example 17 using a nonwoven fabric as a carrier.

Example 18
A material obtained by embossing UV varnishing on one side of cardboard (coated ball) is molded into a square cylinder of 1.5 cm square and 30 cm length with the processed surface facing outside. 0.5 mL of a dispersion (containing 2.0% by weight as propetanephos) of microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) diluted 10-fold with water Spraying was carried out using a two-fluid nozzle and air-dried at room temperature for 24 hours to prepare Example 18 using cardboard as a carrier.

Example 19
A material laminated with PP on one side of cardboard (coated ball) is molded into a square cylinder of 1.5 cm square and 30 cm length with the processed surface facing outside. 0.5 mL of a dispersion (containing 2.0% by weight as propetanephos) of microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) diluted 10-fold with water Spraying was carried out using a two-fluid nozzle and air-dried at room temperature for 24 hours to prepare Example 19 using cardboard as a carrier.

Case 20
A material that has been UV varnished on one side of cardboard (coated ball) is molded into a square cylinder of 1.5 cm square and 30 cm long with the processed surface facing outside. 0.5 mL of a dispersion (containing 2.0% by weight as propetanephos) of microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) diluted 10-fold with water The inside was sprayed using a two-fluid nozzle and air-dried at room temperature for 24 hours to prepare Example 20 using cardboard as a carrier.

Example 21
A material obtained by embossing UV varnish processing on one side of cardboard (coated ball) is molded into a right triangle having a cross section of 1.5 × 2.0 × 2.5 cm and a triangular tube having a length of 30 cm, with the processing surface facing outside. 0.5 mL of a dispersion (containing 2.0% by weight as propetanephos) of microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) diluted 10-fold with water It was sprayed using a two-fluid nozzle, and air-dried at room temperature for 24 hours to prepare Example 21 using cardboard as a carrier.

Example 22
A material laminated with PP on one side of cardboard (coated ball) is molded into a right triangle with a cross section of 1.5 × 2.0 × 2.5 cm and a triangular tube with a length of 30 cm with the processing surface facing outside. 0.5 mL of a dispersion (containing 2.0% by weight as propetanephos) of microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) diluted 10-fold with water Spraying was carried out using a two-fluid nozzle and air-dried at room temperature for 24 hours to prepare Example 22 using cardboard as a carrier.

Example 23
A material that has been UV varnished on one side of cardboard (coated ball) is molded into a right triangle with a cross section of 1.5 × 2.0 × 2.5 cm and a triangular tube with a length of 30 cm, with the processing surface facing outside. 0.5 mL of a dispersion (containing 2.0% by weight as propetanephos) of microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) diluted 10-fold with water Spraying was carried out using a two-fluid nozzle, and air-dried at room temperature for 24 hours to prepare Example 23 using cardboard as a carrier.

Example 24
Cardboard (coated balls) is molded into a square cylinder of 1.5 cm square and 30 cm long. 0.5 mL of a dispersion (containing 2.0% by weight as propetanephos) of microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) diluted 10-fold with water Spraying was carried out using a two-fluid nozzle, and air-dried at room temperature for 24 hours to prepare Example 24 using cardboard as a carrier.

Example 25
Cardboard (coated balls) is molded into a triangular cylinder having a cross section of 1.5 × 2.0 × 2.5 cm and a right triangle and a length of 30 cm. 0.5 mL of a dispersion (containing 2.0% by weight as propetanephos) of microencapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) diluted 10-fold with water Spraying was carried out using a two-fluid nozzle and air-dried at room temperature for 24 hours to prepare Example 25 using cardboard as a carrier.

Comparative Example 1
A 10-fold dilution of propetanephos emulsion (Sankyo Saflotin Emulsion, Sankyo Agro Co., Ltd., 3.0% by weight as propetanephos), and 0 (containing 0.30% by weight as propetanephos) on a plate in which cardboard was formed into a 10 cm square 5 mL was sprayed and air-dried at room temperature for 24 hours to prepare Comparative Example 1 using cardboard as a carrier.

Comparative Example 2
0.5 mL of 80 times diluted solution of microencapsulated fenitrothion (Osaka Kasei Co., Ltd., containing 20% by weight as fenitrothion) (containing 0.25% by weight as fenitrothion) is sprayed on a plate formed of cardboard 10cm square And air-dried at room temperature for 24 hours to prepare Comparative Example 2 using cardboard as a carrier.

Comparative Example 3
A non-woven fabric (Tyvek No. 1056D) was cut into a 10 cm square, and a 10-fold diluted solution of propetanephos emulsion (Sankyo Saflotin emulsion, Sankyo Agro Co., Ltd., 3.0% by weight as propetanephos) (containing 0.30% by weight as propetanephos) 0.5 mL of liquid) was sprayed and air-dried at room temperature for 24 hours to prepare Comparative Example 3 using a nonwoven fabric as a carrier.

Comparative Example 4
A non-woven fabric (Tyvek No. 1056D) was cut into a 10 cm square, and an 80-fold diluted solution of microencapsulated fenitrothion (Osaka Kasei Co., Ltd., containing 20 wt% as fenitrothion) (containing 0.25 wt% as fenitrothion) 0.5 mL was sprayed and air-dried at room temperature for 24 hours to prepare Comparative Example 4 using a nonwoven fabric as a carrier.

Comparative Example 5
A 20-fold diluted solution of fenitrothion emulsion (Sumithion emulsion, Dainippon Insect Chrysanthemum Co., Ltd., containing 10% by weight as fenitrothion), (containing 0.50% by weight as fenitrothion) was added to a plate on which cardboard was formed into a 10 cm square. 5 mL was sprayed and air-dried at room temperature for 24 hours to prepare Comparative Example 5 using cardboard as a carrier.

Comparative Example 6
A 10-fold diluted solution of cyphenothrin emulsion (Gokylate emulsion, Sumitomo Chemical Co., Ltd., 5% by weight as cyphenothrin), (containing 0.50% by weight as cyphenothrin) on a plate in which cardboard is molded into a 10 cm square. 0.5 mL was sprayed and air-dried at room temperature for 24 hours to prepare Comparative Example 6 using cardboard as a carrier.

Comparative Example 7
On a plate formed of 10 cm square of cardboard, 0.5 mL of a 50-fold diluted solution of propetanephos emulsion formulation (Nippon Kayaku Co., Ltd., 50% by weight as propetanephos) (containing 1.0% by weight as propetanephos) It sprayed and air-dried at room temperature for 24 hours, and the comparative example 7 which used cardboard as the support | carrier was prepared.

Comparative Example 8
Sprinkle 0.5 ml of a 45-fold diluted solution of pyrimiphosmethyl emulsion (acteric emulsion, Nippon Pesticide Co., Ltd., 45% by weight as pyrimifosmethyl) (containing 1.0% by weight as pyrimiphosmethyl) on a plate with cardboard 10 cm square. Then, it was air-dried at room temperature for 24 hours to prepare Comparative Example 8 using cardboard as a carrier.

Comparative Example 9
A material obtained by embossing UV varnishing on one side of cardboard (coated ball) is molded into a square cylinder of 1.5 cm square and 30 cm length with the processed surface facing outside. 0.5 mL of propetanephos emulsion (Sankyo Saflotin emulsion, Sankyo Agro Co., Ltd., 3.0% by weight as propetanephos) was sprayed into a rectangular tube using a two-fluid nozzle, air-dried at room temperature for 24 hours, and cardboard was used as a carrier Comparative Example 9 was prepared.

Comparative Example 10
A material obtained by embossing UV varnish processing on one side of cardboard (coated ball) is molded into a right triangle having a cross section of 1.5 × 2.0 × 2.5 cm and a triangular tube having a length of 30 cm, with the processing surface facing outside. 0.5 mL of propetanephos emulsion (Sankyo Saflotin emulsion, Sankyo Agro Co., Ltd., 3.0% by weight as propetanephos) was sprayed into a rectangular tube using a two-fluid nozzle, air-dried at room temperature for 24 hours, and cardboard was used as a carrier Comparative Example 10 was prepared.

いずれの実施例においてもゴキブリに対して殺虫率１００％であり、害虫駆除材として十分な殺虫作用を示した。いずれの吸水性素材担体においても殺虫活性成分の薬効は阻害されず、殺虫活性成分担体として使用し得ることが明らかとなった。 Test Example 1: Insecticidal effect test on cockroaches Into a glass cylinder (diameter 9 cm, height 6 cm) coated with butter for preventing escape on the inner wall, the pest control material according to Examples 1 to 6 was placed with the drug residue surface upright, Ten adult German cockroaches were released inside, and the test insects were forced to contact the drug-treated surface for 24 hours, and the mortality after 24 hours was determined. As a control, test insects were released on plates not treated with the drug. The results are shown in Table 1.

In all Examples, the insecticidal rate was 100% against cockroaches, and the insecticidal action was sufficient as a pest control material. It has been clarified that any water-absorbing material carrier does not inhibit the efficacy of the insecticidal active ingredient and can be used as an insecticidal active ingredient carrier.

プロペタンホスＭＣ：マイクロカプセル化プロペタンホス
ダイアジノンＭＣ：マイクロカプセル化ダイアジノン
プロペタンホスＥＣ：プロペタンホス乳剤
フェニトロチオンＭＣ：マイクロカプセル化フェニトロチオン
実施例、比較例のいずれの害虫駆除材においても調製直後は２４時間後死亡率が１００％であったが、駆除材調製後の時間の経過とともに、比較例害虫駆除材は駆除効果の低下が見られた。一方、実施例１、３、１５、及び１７は調製後６ヶ月を経過しても駆除効果は衰えず、初期の殺虫効果を維持した。比較例２、及び４は非特許文献１よりポリウレタン膜によるマイクロカプセル製剤と推定されるが、実施例の特定組成によるポリウレア膜マイクロカプセル製剤と比較して残効性に違いが確認された。このことから本発明による害虫駆除材は害虫駆除処理作業において１度処理を行うことで長期間にわたり駆除効果を維持でき、作業処理回数を大幅に低減できる害虫駆除材となり得ることが示された。 Test Example 2: Residual Effect Test Immediately after the chemical treatment of the pest control material according to Examples 1, 3, 15 and 17 and Comparative Examples 1, 2, 3, and 4, and chemical treatment 1, 3, 6 months with the same pest control material After the elapse, the pest control material is placed in a glass cylinder (diameter 9 cm, height 6 cm) with butter to prevent escape on the inner wall, and 10 male cockroach male adults are released inside and treated with chemicals. The test insect was forced to contact the surface for 24 hours, and the mortality after 24 hours was determined. As a control, test insects were released on plates not treated with the drug. The results are shown in Table 2.

Propetanfos MC: Microencapsulated Propetanfos Diazinon MC: Microencapsulated Diazinon Propetanfos EC: Propetanfos Emulsion Fenitrothion MC: Microencapsulated Fenitrothion In both pest control materials of Examples and Comparative Examples, mortality after 100 hours was 100% after preparation However, with the lapse of time after the preparation of the control material, the comparative insect pest control material showed a decrease in the control effect. On the other hand, Examples 1, 3, 15, and 17 did not lose the extermination effect even after 6 months had passed after preparation, and maintained the initial insecticidal effect. Although the comparative examples 2 and 4 are estimated from the nonpatent literature 1 as the microcapsule formulation by a polyurethane film, the difference in the residual effect was confirmed compared with the polyurea membrane microcapsule formulation by the specific composition of an Example. From this, it was shown that the pest control material according to the present invention can be a pest control material that can maintain the control effect over a long period of time by performing the treatment once in the pest control processing operation and can greatly reduce the number of work processing.

プロペタンホスＭＣ：マイクロカプセル化プロペタンホス
フェニトロチオンＥＣ：フェニトロチオン乳剤
シフェノトリンＥＣ：シフェノトリン乳剤
フェニトロチオン乳剤、及びシフェノトリン乳剤処理駆除材は殺虫剤抵抗性ゴキブリに十分な殺虫効果を示さなかった。実施例７による害虫駆除材は殺虫剤抵抗性ゴキブリに対しても十分な殺虫効果を示すとともに、駆除材調製後６ヶ月を経過してもその殺虫効果を維持した。 Test Example 3: Insecticide effect test and residual effect test against insecticide-resistant cockroaches Pest control material according to Example 7, Comparative Examples 5 and 6 (one day after preparation), and 1, 3 after chemical treatment with the same pest control material After 6 months, pest control material is placed in a glass cylinder (diameter 9 cm, height 6 cm) with butter on the inner wall coated with butter to prevent escape, and the insecticide-resistant adult German cockroach 10 The head was released, and the test insects were forcibly contacted with the drug-treated surface for 24 hours, and the mortality was determined after 24 hours. As a control, test insects were released on plates not treated with the drug. The insecticide-resistant adult German cockroach was a strain collected from Sakae Ward, Nagoya City, which was 15-fold resistant to phenothrin and 6-fold resistant to fenitrothion. The results are shown in Table 3.

Propetanfos MC: Microencapsulated Propetanfos Fenitrothion EC: Fenitrothion Emulsion Cyphenothrin EC: Ciphenothrin Emulsion Fenitrothion emulsion and ciphenothrin emulsion treated disinfectant did not show sufficient insecticidal effect on insecticide resistant cockroaches. The insect-controlling material according to Example 7 showed a sufficient insecticidal effect against insecticide-resistant cockroaches and maintained its insecticidal effect even after 6 months from the preparation of the insecticide.

実施例８、９による害虫駆除材によるゴキブリ駆除効果は、同殺虫活性成分マイクロカプセル剤の散布剤と同等の殺虫効果を示し、更に速やかな薬効発現が確認できた。本発明による害虫駆除材による害虫駆除方法は、部屋の一部に当該害虫駆除材を設置することで、既存のマイクロカプセル化有機リン剤散布剤の床全面散布と同等の殺虫効果を示し、尚且つ迅速な害虫駆除効果を発揮し、簡便で安全な害虫駆除方法となることを示した。 Test example 4: Comparison test with spraying agent Test Zone 1 Water and food in a test frame (100 × 100 × H28 cm), adult German cockroaches (female 50, male 50) are released together with the shelter, and the test insect is in the shelter. After confirming that it entered, the pest control agent of Example 8 was independently installed outside the shelter.
Test Zone 2 Conducted after confirming that the adult cockroach (female 50, male 50) was released together with water, food and shelter in the test frame (100 x 100 x H28cm) and the test insect entered the shelter. The pest control material of Example 9 was installed in a shelter.
Test group 3 After confirming that adult cockroaches (female 50, male 50) were released together with water, food, and shelter in the test frame (100 x 100 x H28 cm), the test insect entered the shelter. 50 mL of an encapsulated propetanephos aqueous dispersion (Saflotin MC, Sankyo Agro Co., Ltd., containing 20% by weight as propetanephos) diluted 80 times with water (containing 0.25% by weight as propetanephos) on the bottom of the test vessel The whole surface was sprayed.
Test group 4 Adult German cockroaches (female 50, male 50) were released together with water, food and shelter in a test frame (100 × 100 × H28 cm).
The number of dead insects was taken out and counted every elapsed day, and the cumulative death rate was calculated. The results are shown in Table 4.

The cockroach control effect by the pest control material in Examples 8 and 9 showed the insecticidal effect equivalent to the spraying agent of the same insecticidal active ingredient microcapsule, and it was confirmed that the drug effect was further rapidly expressed. The pest control method using the pest control material according to the present invention has an insecticidal effect equivalent to that of the existing microencapsulated organophosphate spray applied to the entire floor by installing the pest control material in a part of the room, and It has been shown that it is a simple and safe pest control method that exhibits a rapid pest control effect.

プロペタンホスＭＣ：マイクロカプセル化プロペタンホス
プロペタンホスＥＷ：プロペタンホス水溶剤
ピリミホスメチルＥＣ：ピリミホスメチル乳剤
本願実施例及び比較例はいずれも害虫駆除材調製１日後には高い殺虫効果が確認された。しかしながら比較例７、８は害虫駆除材調製時間の経過とともに殺虫効果の低下が認められたのに対し、実施例７、１０は害虫駆除材調製６ヶ月経過後でも高い殺虫効果を示した。すなわち本発明のマイクロカプセル化有機リン剤を用いた害虫駆除材はナンキンムシにも有効であり、残効性の高い害虫駆除材であった。 Test Example 5: Insecticidal effect test and residual effect test against bed bugs 15 test insects were released on a high-waist petri dish (diameter 9 cm, depth 6 cm) coated with butter for preventing escape on the inner wall. Using the pest control material of Comparative Examples 7 and 8, and the same pest control material, the pest control material after 1, 3 and 6 months of chemical treatment, and covering the waist high petri dish on the chemical treatment surface, the whole is inverted The test insect was forcibly brought into contact with the drug residue surface. The mortality after 24 hours was determined. As a control, test insects were released on plates that had not been treated with the drug. The test was carried out in two consecutive systems. The results are shown in Table 5.

Propetanfos MC: Microencapsulated Propetanfos Propetanfos EW: Propetanfos aqueous solvent Pirimifosmethyl EC: Pirimifosmethyl emulsion In both of the present Examples and Comparative Examples, a high insecticidal effect was confirmed one day after the preparation of the pest control material. However, Comparative Examples 7 and 8 showed a decrease in the insecticidal effect as the pest control material preparation time passed, while Examples 7 and 10 showed a high insecticidal effect even after 6 months of the pest control material preparation. That is, the pest control material using the microencapsulated organophosphorus agent of the present invention was effective against bed bugs and was a pest control material with high residual effect.

プロペタンホスＭＣ：マイクロカプセル化プロペタンホス
ダイアジノンＭＣ：マイクロカプセル化ダイアジノン
実施例２、１１、１２、１６及び実施例３、１３、１４、１７の害虫駆除材はチカイエカにも有効性を示し、尚且つ害虫駆除材調製６ヶ月後においても駆除効果は衰えず、高い残効性を示した。 Test Example 6 Insecticidal effect test and residual effect test against Chikaeka Example 2, 11, 12, 16 and Examples 3, 13, 14, and 17 pest control material, and chemical treatment 1, 3, After 6 months, the pest control material plate was rolled and placed along the glass surface so that the drug-treated surface did not contact the glass on the inner wall surface of a glass cylinder having a diameter of 4.5 cm and a height of 13.5 cm. Fifteen adult Chichieka were released inside the glass cylinder, the top and bottom surfaces of the cylinder were covered with gauze, and 0.5% sugar water was impregnated as food and lightly squeezed cotton was placed on the gauze. The test was carried out in two consecutive systems. The number of dead insects 24 hours after release was counted and the mortality rate was calculated. The results are shown in Table 6.

Propetanephos MC: Microencapsulated Propetanephos Diazinon MC: Microencapsulated Diazinon The pest control materials of Examples 2, 11, 12, 16 and Examples 3, 13, 14, and 17 are also effective against Chikaeka, and pest control Even after 6 months of the preparation of the material, the extermination effect did not fade and showed a high residual effect.

Test Example 7: Comparison with spraying agent and residual effect test test section 1 In a test frame (100 × 100 × H28 cm) coated with sesame oil on the entire bottom surface, adult cockroach (female 20, male 20) together with water and food, shelter The insects were released for 7 days every elapsed day. After confirming that the test insect had entered the shelter, the pest control agent of Example 18 was independently installed outside the shelter.
Test Zone 2 Adult cockroaches (female 20, male 20) were released for 7 days for each elapsed day in a test frame (100 × 100 × H28 cm) coated with sesame oil on the entire bottom surface, together with water, food, and shelter. After confirming that the test insect entered the shelter, the pest control material of Example 19 was installed independently outside the shelter.
Test Group 3 In a test frame (100 × 100 × H28 cm) in which sesame oil was applied to the entire bottom surface, water, bait, and adult cockroach 20 females and male 20) were released for 7 days every elapsed day. After confirming that the test insect entered the shelter, the pest control material of Example 20 was installed independently outside the shelter.
Test Group 4 In a test frame (100 × 100 × H28 cm) in which sesame oil was applied to the entire bottom, water, bait, and adult cockroach 20 and male 20) were released for 7 days every elapsed day. After confirming that the test insect had entered the shelter, the pest control material of Example 21 was independently installed outside the shelter.
Test group 5 In a test frame (100 × 100 × H28 cm) in which sesame oil was applied to the entire bottom surface, water, bait, and adult cockroach adult female 20 and male 20) were released for 7 days every elapsed day. After confirming that the test insect entered the shelter, the pest control material of Example 22 was installed independently outside the shelter.
Test Group 6 In a test frame (100 × 100 × H28 cm) in which sesame oil was applied to the entire bottom surface, water, bait, and adult cockroach adult female 20 and male 20) were released for 7 days every elapsed day. After confirming that the test insect entered the shelter, the pest control material of Example 23 was installed independently outside the shelter.
Test Zone 7 Adult German cockroaches (female 20, male 20) were released for 7 days every elapsed day together with water, food and shelter in a test frame (100 × 100 × H28 cm) coated with sesame oil on the entire bottom surface. After confirming that the test insect entered the shelter, the pest control material of Example 24 was independently installed outside the shelter.
Test Zone 8 Adult cockroaches (female 20, male 20) were released for 7 days for each elapsed day together with water, food and shelter in a test frame (100 × 100 × H28 cm) coated with sesame oil on the entire bottom surface. After confirming that the test insect entered the shelter, the pest control material of Example 25 was installed independently outside the shelter.
Test Zone 9 Adult cockroaches (female 20, male 20) were released for 7 days for each elapsed day together with water, food, and shelter in a test frame (100 × 100 × H28 cm) coated with sesame oil on the entire bottom surface. After confirming the presence of the test insect in the shelter, a microencapsulated propetanephos aqueous dispersion (containing 20% by weight as saflotin MC, Sankyo Agro Co., Ltd., propetanephos) diluted 80 times with water ( 50 mL of a liquid containing 0.25% by weight as propetanephos) was sprayed over the entire surface of the test container.
Test plot 10 Adult German cockroaches (female 20, male 20) together with water, food, and shelter in a test frame (100 × 100 × H28 cm) coated with sesame oil on the entire bottom surface was released for 7 days every elapsed day. After confirming that the test insect entered the shelter, the pest control material of Comparative Example 9 was independently installed outside the shelter.
Test group 11 In a test frame (100 × 100 × H28 cm) in which sesame oil was applied to the entire bottom surface, adult German cockroaches (female 20, male 20) were released together with water, bait, and shelter for 7 days every elapsed day. After confirming that the test insect entered the shelter, the pest control material of Comparative Example 10 was independently installed outside the shelter.
Test Zone 12 Adult German cockroaches (female 20, male 20) were released for 7 days every elapsed day together with water, food, and shelter in a test frame (100 × 100 × H28 cm) coated with sesame oil on the entire bottom surface. After confirming that the test insect entered the shelter, the number of dead insects was taken out and counted every elapsed day, and the cumulative death rate was calculated. The results are shown in Table 7.

プロペタンホスＭＣ：マイクロカプセル化プロペタンホス
プロペタンホスＥＣ：プロペタンホス乳剤
実施例１８，１９，２０，２１，２２，２３，２４，２５による害虫駆除材によるゴキブリ駆除効果は、同一殺虫活性成分マイクロカプセル剤の散布剤の１０分の１以下の薬剤量であるにもかかわらず、飲食店の厨房等でよく見受けられる油膜面上において、３ヶ月もの間安定した高い効果を示し、散布剤や乳剤で作成した比較例９，１０よりもその効果は勝った。

Propetanfos MC: Microencapsulated Propetanfos Propetanfos EC: Propetanfos Emulsion The cockroach control effect by the pest control material according to Examples 18, 19, 20, 21, 22, 23, 24, 25 is the same as the spraying agent of the same insecticidal active ingredient microcapsule. Comparative Example 9 produced with a spraying agent or an emulsion, showing a stable and high effect for 3 months on the oil film surface often found in restaurant kitchens, etc., even though the drug amount is 1/10 or less. , 10 better than the effect.

Claims (10)

Pests made by containing microencapsulated organophosphorus agent containing polyphosphoric acid and polyfunctional amine in a polyurea film microcapsule by interfacial polymerization method and encapsulating organophosphorus agent as a pesticidal core material in the carrier Exterminator. The pest control material according to claim 1, wherein the organic phosphorus agent is diazinon or propetanephos as a pest control agent. The pest control material according to claim 1 or 2, wherein the carrier is a carrier formed by combining one or more selected from the group consisting of a fiber carrier, a porous carrier, and a water-absorbing polymer carrier. The pest control material according to claim 3, wherein the fiber carrier is a carrier formed by combining one or more selected from the group consisting of papers and fabrics. The pest control material according to claim 3, wherein the porous carrier is a carrier formed by combining one or more selected from the group consisting of silica, clay, vermiculite, pumice, and sponge. The pest control material according to claim 3, wherein the water-absorbing polymer carrier is a polyacrylate. The pest control material according to any one of claims 1 to 6, wherein the organophosphorus agent contains 5 to 5000 µg / cm ² per surface area of the carrier. The pest control material according to any one of claims 1 to 7, wherein the pest is a cockroach, a bedbug, or a mosquito. A pest control device using the pest control material according to any one of claims 1 to 8. A pest control method using the pest control material or the pest control device according to any one of claims 1 to 9.