JP2017128530A - Volatile closed space anti-pest - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an anti-pest containing a safe active ingredient and exhibiting a sufficient effect in a closed space such as a room and a storage space.SOLUTION: Provided is a volatile closed space anti-pest comprising monohydric alcohol only made of nine carbon atoms, one oxygen atom and a hydrogen atom(s) and having two or more branched alkyl groups as an active ingredient, used in a closed space and destructing a pest(s). The anti-pest is used in a closed space to destruct a pest(s), and the pest(s) is preferably at least one kind of pest selected from the group consisting of a sanitary pest, a discomfort pest, a clothing pest, a food pest, a cultural property pest, a house pest and a pet pest.SELECTED DRAWING: None

Description

  The present invention relates to a volatile closed space insect repellent that is used in a closed space to control pests.

  Research and development on repelling and extermination of pests such as mites and mosquitoes has been actively conducted, and many types of pest repellents, pesticides or insecticides have been developed so far. However, many of these compounds used as active ingredients such as pest repellents have problems such as poor pest control effects and adverse effects on the human body.

  Many insect pest control agents or biocides containing a pyrethroid compound as an active ingredient have been developed as having high safety and rapid action (Patent Documents 1 and 2). However, in recent years, pests that are resistant to pyrethroid compounds have emerged, which is a problem.

  Patent Document 3 discloses a pest control agent containing essential oil as an active ingredient. Essential oils are aromatic volatile oils obtained from plants, have a good fragrance, and are highly safe. In addition, there is no need to directly contact pests by spraying such as spray, and research and development of pest control agents containing essential oil are being actively promoted, but the problem is that the pest control effect is weak.

Patent Document 4 discloses an insect control agent containing ketones, esters, alcohols and the like as active ingredients. Although some of the active ingredients listed are safe, in the examples of Patent Document 4, it is said that the insects (Drosophila) can be avoided by the vapor of the test compound (active ingredient), that is, by the active ingredient volatilized. can not cut.
Moreover, the effect confirmed in the Example etc. of Patent Document 4 is limited to “repelling of insects”.

Therefore, the development of “volatile agents that can be used in closed spaces and have a pest control effect” that can control pests with the active ingredient vapor does not require direct contact with the pests by spraying. Is desired.
Moreover, it is possible to kill not only repellents but also insects, not only pests belonging to insect class, but also effective against pests belonging to spiders such as mites and tsutsugamushi, and a volatile enclosed space containing safe active ingredients Development of pesticides is desired.

JP 2014-156463 A JP 2013-095744 A Japanese Patent Laid-Open No. 11-060421 JP 2013-177342 A

  This invention is made | formed in view of the said background art, The subject contains the active ingredient which is safe and safe, and provides the insect repellent which exhibits an effect sufficiently in closed spaces, such as indoor and storage space. For the purpose.

  As a result of intensive studies to solve the above problems and problems, the present inventor has found that pests in a closed space can be controlled by containing a specific compound as an active ingredient.

  Furthermore, by mixing and using the specific compound and a compound selected from the specific compound group, the present invention is completed by finding that the compound exhibits a superior pest control effect due to the synergistic action between the compounds. It came to.

  That is, the present invention is a volatilization characterized by containing, as an active ingredient, a monohydric alcohol consisting of only 9 carbon atoms, 1 oxygen atom, and hydrogen atom and having 2 or more branched alkyl groups. It is intended to provide an insecticidal space insecticide.

  The present invention also provides a solid volatile closed space insect repellent composition characterized in that the volatile closed space insect repellent is carried on a carrier.

  In addition, the present invention provides a liquid volatile closed space insect repellent composition, which is obtained by diluting the volatile closed space insect repellent with a liquid.

The present invention also provides the solid volatile closed space insecticide composition or the liquid volatile closed space insecticide composition in a closed space of 1 × 10 ⁻³ m ³ or more and 1 × 10 ³ m ³ or less. The present invention provides a method for exterminating pests characterized by being volatilized at room temperature.

  ADVANTAGE OF THE INVENTION According to this invention, the said subject can be solved and the volatile closed space insecticide containing an active ingredient which is safe and safe can be provided. Moreover, the volatile closed space insecticide of this invention is excellent in sustainability, and can exhibit a long-term effect.

  Moreover, since the volatile enclosed space insect repellent of the present invention exerts the insect repellent effect by the vapor generated by volatilization of the active ingredient, the volatile closed space insect repellent is directly brought into contact with the pest by a spray or the like. There is no need. Further, the volatile closed space insecticide can be used at room temperature and does not need to be heated. In addition, the effect can be accelerated by heating, ultrasonic irradiation, or the like.

  Furthermore, when a spraying device such as a spray agent is used, it is not easy to spread the active ingredient sufficiently to a narrow space in the closed space, but the volatile closed space insecticide of the present invention is a volatilized active ingredient. This vapor can exert a pest control effect to every corner of the closed space and can protect foods, clothes, furniture, houses, etc. existing in the closed space.

Further, the volatile closed space insecticide of the present invention is not limited to repelling insects, but can also kill insects, and is not limited to insect pests belonging to the insect class, for example, ticks, house dust mites, mites, spider mites, mites, etc. It is also effective against harmful insects that cause discomfort to humans such as millipede, centipede, and dandelion.
In addition, the volatile closed space insecticide of the present invention rarely has an adverse effect on the human body even though it has a pest control effect.

In addition, the volatile closed space insect repellent of the present invention is used in combination with “at least one compound selected from the group consisting of a chain monoterpene alcohol, a cyclic monoterpene alcohol and a cyclic monoterpene ketone”. Therefore, various synergistic effects are easily exhibited.
For example, the total volatilization amount (evaporation amount) when used in combination can be smaller than the volatilization amount (evaporation amount) when each is used alone; the volatilization amount (evaporation amount) can be adjusted; An advantageous effect that it is easy to exert a combined effect such as:

In addition, the volatile closed space insecticide of the present invention is supported on a carrier as a “solid volatile closed space insecticide composition” or diluted with a liquid to form a “liquid volatile closed space insecticide”. It is particularly effective when used as a “pesticide composition”.
The solid volatile closed space insect repellent composition or the liquid volatile closed space insect repellent composition of the present invention supports or dissolves the volatile closed space insect repellent agent. A simple step of installing at a location can control the pests at the target location.

  In addition, since the method for exterminating the pest of the present invention exterminates the pest with the vaporized active ingredient, it is possible to exterminate the pest throughout the entire closed space regardless of the size of the space to be used. .

  Hereinafter, the present invention will be described, but the present invention is not limited to the following specific embodiments, and can be arbitrarily modified within the scope of the technical idea.

<Volatile closed space insecticide>
The volatile closed space insecticide of the present invention contains, as an active ingredient, a monohydric alcohol consisting of only 9 carbon atoms, 1 oxygen atom, and hydrogen atom and having 2 or more branched alkyl groups. It is characterized in that it is used in closed spaces to control pests.

  In the volatile closed space insecticide of the present invention, the active ingredient volatilizes at room temperature to become a gas, and the gas exerts the insecticide effect. That is, by directly contacting the volatile closed space pesticide itself with a pest, the pesticide effect is not exerted, but the vapor generated by volatilization of the active ingredient contained in the volatile closed space pesticide ( Pest control effect is exhibited by the action of gas) on pests. Due to such differences in action / principle, application / use method, etc., an effective volatile enclosed space insect repellent differs in chemical structure from an effective contact insect repellent.

  In the present invention, “closed space” refers to “a space that is not opened for a certain period of time”. Specific examples include indoors such as houses and buildings; inside vehicles such as freight cars, ships, airplanes, and trains; storage places such as chests, closets, closets, warehouses, shoe boxes, and containers;

In the present invention, “control” includes the meanings of “repellency, insect repellent and insecticide”. That is, the volatile enclosed space pesticide of the present invention can “repell away from the enclosed space”, “prevent entry into the enclosed space” and / or “kill” the enclosed pest.
Further, in the present invention, the “insect-proof effect” includes the meanings of “effect of repelling pests”, “effect of preventing pests from entering a target place” and / or “effect of killing pests”.

The volatile closed space insecticide of the present invention is used for the purpose of controlling insect pests. The pests include “hygienic pests” defined by the Pharmaceutical Affairs Law and “unpleasant pests” other than hygienic pests. These include not only adults but also larvae.
Examples of sanitary pests include flies, mosquitoes, flyfish, fleas, lice, cockroaches, house dust mites, indoor dust mites and the like.
Examples of unpleasant pests include millipede, dandelion, centipede, spider, bracken, stink bug, and fly.
The volatile closed space insecticide of the present invention is preferably used for controlling unpleasant insects.

The volatile closed space insecticide of the present invention is preferably used for controlling clothes insects, food insects, cultural property insects, house (architectural) insects and / or pet insects.
Examples of clothes (fiber) pests include cutworms, moths, and carp.
Examples of food pests include acarid mites, moths, carp moths, scallops, coconuts, weevil, moths, ticks, cockroaches, cockroaches, tobacco beetles and the like.
Examples of cultural property pests include cutworms, scallops, weevil, slatted beetles, moth beetles, nagashin worms, spots, and leopard worms.
Examples of house (architecture) pests include Giant beetle, millipede, stain, iga, cutlet worm, butterfly and the like.
Examples of pet pests include fleas, ticks, spiders, and mosquitoes.

  The volatile closed space insect repellent of the present invention may be used for the control of cockroaches, flies, ticks, moths, moths, mosquitoes, cigarette beetles, cutworms, beetles, beetles, beetles, beetles, spots, fleas or butterflies. It is particularly preferable to use it for cockroaches, flies, ticks, moths, mosquitoes or tobacco beetles. The target of use includes not only adults but also larvae.

The aliphatic monohydric alcohol which is an active ingredient of the volatile closed space insecticide of the present invention consists of only 9 carbon atoms, 1 oxygen atom and hydrogen atom, and has 2 or more branched alkyl groups. Have. Hereinafter, this may be simply abbreviated as “branched C ₉ aliphatic monohydric alcohol”.

  The “branched C9 aliphatic monohydric alcohol” is preferably a monohydric alcohol having 2 or 3 branched methyl groups, since the effects of the present invention are further exhibited.

Specifically, preferred examples include 3,6-dimethyl-1-heptin-3-ol, 3-ethyl-1-heptin-3-ol, 3,5,5-trimethyl-1-hexanol, 3 , 3,5-trimethylcyclohexanol, 2,6-dimethyl-4-heptanol, 4-isopropylcyclohexanol, 2-isopropylcyclohexanol, 4-propylcyclohexanol and the like.
These can be used alone or in combination of two or more.

  Among them, 3,6-dimethyl-1-heptin-3-ol and 3-ethyl-1-heptin-3 are sufficient in that they exhibit a pest control effect, can be obtained at low cost, and can be easily synthesized. -Ol, 3,5,5-trimethyl-1-hexanol, 3,3,5-trimethyl-1-cyclohexanol or 2,6-dimethyl-4-heptanol is more preferred.

  Furthermore, a monohydric alcohol having 2 or 3 branched methyl groups is particularly preferable. Specifically, from the above points, 3,5,5-trimethyl-1-hexanol, 3,3,5-trimethyl-1-cyclohexanol or 2,6-dimethyl-4-heptanol is particularly preferable.

  Further, the volatile closed space insecticide of the present invention is not limited, but “from (A) chain monoterpene alcohol, (B) cyclic monoterpene alcohol and (C) cyclic monoterpene ketone. It preferably contains at least one compound selected from the group consisting of: Hereinafter, this “” may be abbreviated as “combination compound”.

  Specific examples of the chain monoterpene alcohol (A) include citronellol, geraniol, nerol, linalool, dihydrolinalool, mugor, myrsenol, dihydromyrsenol, osmenol, lavandurol, and the like. It may be used in a mixture of two or more.

  (B) Specific examples of the cyclic monoterpene alcohol include isopulegol, menthol, terpineol, dihydroterpineol, terpineol-4, carveol, dihydrocarbeole, perilla alcohol, myrtenol, nobol, pinocarbeol, fenquil alcohol, borneol , Isoborneol, tweenol and the like, and these may be used alone or in combination of two or more.

  (C) Specific examples of the cyclic monoterpene ketone include carvone, menthone, isomenthone, camphor and the like, and these may be used alone or in combination of two or more. .

In addition, (A), (B), and (C) may be used together (mixed) and used in combination with “branched C ₉ aliphatic monohydric alcohol”.

The volatile closed space insect repellent of the present invention tends to exhibit several synergistic effects specifically by using the branched C ₉ aliphatic monohydric alcohol in combination with the above-mentioned combination compound.
For example, the total volatilization amount / evaporation amount (use amount) when used in combination can be smaller than the volatilization amount / evaporation amount (use amount) when each is used alone; The odor does not become strong; the odor quality can be adjusted by adding a fragrance, etc .; it can be effective against various pests; it can be easily increased by using a compound with a low pest control effect; the odor attached to clothing, etc. There likely (omission likely) taken when placing the garment or the like in ventilation environment; the combined effect of the concomitant compounds such as branched C ₉ aliphatic monohydric alcohol in the present invention described above will be specifically exhibited.

When the above combination compound is used in combination, the content of the above combination compound with respect to the entire volatile closed space insect repellent is not particularly limited and can be appropriately selected depending on the purpose.
The book described above, including the effect of further enhancing the insecticidal effect of the branched C ₉ aliphatic monohydric alcohol, which is an active ingredient contained in the volatile closed space insecticide, and exhibiting the insecticidal effect sufficiently and continuously In order to exhibit the effect of the invention more effectively, when the total amount of the volatile closed space insect repellent is 100 parts by mass, the combined compound is preferably contained in an amount of 2 to 90 parts by mass as the total amount. It is more preferable to contain -80 mass parts, It is still more preferable to contain 10-75 mass parts, It is especially preferable to contain 30-70 mass parts, It is mix | blending by the content of 40-60 mass parts. Most preferred.

The mass ratio of the branched C ₉ aliphatic monohydric alcohol and combination compound is not particularly limited, further enhancing the anti-pest effect of branched C ₉ aliphatic monohydric alcohol, sufficiently and persistently exhibited anti pests effect From the point of doing, 1: 9-9: 1 are preferable, 3: 7-7: 3 are more preferable, and 4: 6-6: 4 are especially preferable.

  The volatile closed space insecticide of the present invention may contain “other components” in addition to the above components. The “other components” are not particularly limited and may be appropriately selected depending on the purpose within a range not impairing the effects of the present invention. For example, solvents, preservatives, retention agents, surfactants, dyes , Deodorants, antioxidants, antibacterial agents, antifungal agents, polymer polymers, gelling agents, organic solvents, inorganic substances, fragrances, essential oils, colorants and the like.

The volatile closed space insecticide of the present invention is, for example, a method of supporting on a support described later; a method of supporting on a porous material; a method of supporting on a fibrous body such as filter paper or non-woven fabric; It can be used by the method of making it;
In addition, the dosage form can be used as a solid dosage form, a liquid dosage form, a paste agent, a gel agent, an aerosol agent, a microcapsule agent or the like according to the purpose of use.
It is preferable to use it in a solid dosage form in that it can be easily installed and installed in a narrow space.

<Solid volatile closed space insecticide composition>
The solid volatile closed space insect repellent composition of the present invention (hereinafter sometimes simply referred to as “solid composition”) carries the volatile closed space insect repellent of the present invention on a carrier. It is characterized by being made.

The carrier is only required to carry a volatile enclosed space insect repellent and vaporize the vaporized volatile enclosed space insect repellent in the enclosed space. Preferred examples of the carrier include silica, talc, and alumina. , Zeolite, calcium silicate, diatomaceous earth, allophane, pearlite, activated carbon, carbohydrate, water-absorbing resin, synthetic resin, nonwoven fabric, fiber and the like.
Silica such as silica gel, zeolite, non-woven fabric, fiber, synthetic resin such as water absorbent resin, mineral, synthetic mineral, diatomaceous earth, activated clay, bentonite, in order to sufficiently exert the effect of the volatile closed space insecticide Black earth, activated carbon, and the like are more preferable, and silica such as silica gel, zeolite, nonwoven fabric, fiber, synthetic resin such as water absorbent resin, activated carbon, and the like are particularly preferable.

By supporting the volatile closed-space insecticide of the present invention on a carrier to form a solid composition, the branched C9 aliphatic monohydric alcohol and / or the combination compound having a relatively high vapor pressure can be sustained- _released. It is effective to suppress the outflow of liquid, make it easy to handle, adjust the insect-control effect and safety, reduce odor, and so on.

  The content of the volatile closed space insect repellent in the solid volatile closed space insect repellent composition of the present invention can be appropriately set depending on the type and use of the carrier used. When the whole solid composition is 100 parts by mass, it is preferably contained in an amount of 0.01 to 70 parts by mass, preferably 0.1 to 60 parts by mass, and more preferably 1 to 50 parts by mass.

The dosage form of the solid composition of the present invention is not particularly limited, and examples thereof include powders, granules, tablets, gels, and capsules.
In addition, the solid composition can be obtained by supporting the volatile closed space insecticide on a support by a known method.

<Liquid volatile closed space insecticide composition>
The liquid volatile closed space insect repellent composition of the present invention (hereinafter sometimes simply referred to as “liquid composition”) dissolves or disperses the above-described volatile closed space insect repellent of the present invention in a liquid. It is characterized by letting it be.

  For example, examples of the liquid include alcohols such as methanol and ethanol; glycols such as propylene glycol; ketones such as acetone; ethers such as diethyl ether; These liquids may be used alone or in combination of two or more.

The liquid composition can contain other solvents, emulsifiers, dispersants, suspending agents and the like in addition to the volatile closed space insect repellent, depending on the purpose of use.
Examples of the emulsifier include nonionic surfactants, cationic surfactants, anionic surfactants, and amphoteric surfactants.

  The content of the volatile closed space insect repellent in the liquid volatile closed space insect repellent composition of the present invention can be appropriately set depending on the intended use. When the entire liquid composition is 100 parts by mass, it is preferably contained in an amount of 0.01 to 70 parts by mass, preferably 0.1 to 60 parts by mass, and more preferably 1 to 50 parts by mass.

Although the dosage form of the liquid composition of this invention is not specifically limited, For example, an oil agent (liquid agent), an emulsion, a wettable powder, a paste agent, a gel agent, a capsule agent etc. are mentioned.
Further, the liquid composition of the present invention can be produced by a known method. Further, the liquid composition may be volatilized as it is, or may be volatilized by soaking in a core rod, filter paper, non-woven cloth, felt or the like.

<How to get rid of pests>
The method for controlling pests of the present invention uses the solid volatile closed space pesticide composition or the liquid volatile closed space pesticide composition in a closed space, and the solid or liquid composition. It is characterized by volatilizing a volatile enclosed space insect repellent in materials at room temperature.

The size of the closed space is not particularly limited, but with respect to the upper limit, the volatile closed space insect repellent of the present invention with respect to the lower limit, in terms of exerting a pest control action throughout the closed space and every corner, 1 × 10 ⁻³ m ³ or more and 1 × 10 ³ m ³ or less are preferable, and 0.1 m ³ or more and 5 × 10 ² m ² or less are more preferable in terms of functioning as a repellent or a pest control agent. , 1 m ³ or more 200 meters ³ or less are particularly preferred, 10 m ³ or more 100 m ³ or less is more preferable.

  The amount of the solid or liquid composition used in the method for controlling pests of the present invention (hereinafter sometimes simply abbreviated as “the method of the present invention”) is not particularly limited, and is appropriately selected according to the purpose. can do.

In addition, the period during which the solid or liquid composition is used in the closed space can be appropriately selected according to the size of the closed space, the degree of the desired effect, etc. It is preferable to use 3 hours to 6 months or more, and it is particularly preferable to use 8 hours to 3 months.
In addition, the method of the present invention may be used for preventing the invasion of pests or may be used for the purpose of killing insects.

  In the method of the present invention, for example, the solid or liquid composition is placed in an air-permeable container as it is or allowed to stand in a closed space to prevent volatile closed space in the solid or liquid composition. What is necessary is just to volatilize a pesticide naturally. If necessary, the volatile enclosed space insect repellent contained in the solid or liquid composition may be volatilized by subjecting the solid or liquid composition to heat treatment, blowing treatment, or the like. Good.

  Hereinafter, the present invention will be described more specifically with reference to examples. However, the present invention is not limited to these examples as long as the gist thereof is not exceeded.

Example 1
Hereinafter, according to Evaluation Examples 1 to 6, a model evaluation was performed on the volatile closed space insecticide of the present invention. In the following evaluation examples, model evaluation is performed in a relatively narrow space, but it has been confirmed by experiments that the effect of the present invention is fully exhibited even when the volume of the space is expanded.

Evaluation Example 1
[Effects on cockroaches]
A polypropylene container of 534 mm × 348 mm × 292 mm (height) was used as a test box. Vaseline was applied to the upper half of the inner wall of the container in order to prevent escape of cockroaches.
In order to facilitate the observation, 90 mmφ × 7 mm (height) transparent polystyrene Petri dish shelters (having 10 mm × 7 mm size entrances / exits) were used.
Two 225 mm × 153 mm × 125 mm (height) translucent polypropylene containers having an inner volume of 4.3 L were prepared and placed in the container. One entrance / exit of 40 mm × 8 mm (height) was provided at the center of the bottom of each container, and connected by a transparent plastic 40 mm × 50 mm × 8 mm (height) passage. Vaseline was applied to the upper third of the inner wall of each container to prevent the escape of cockroaches.

In one container, there are two shelters contaminated with cockroach feces (previously left overnight in a breeding box to make the cockroaches settled), water and food, and the other container has a cockroach. Two new shelters, contaminated with feces, water and food were installed.
Test worms (50 adult males of 50 cockroaches and 50 adult females) are released in a test box (container) and sealed with a transparent plastic plate for easy observation. The test insects were acclimated to the container day and night. After confirming that many cockroaches inhabit the shelter side contaminated with cockroach droppings, gently remove the plastic plate and remove a 20 mmφ filter paper soaked with 20 mg of the test substance to a size of 32 mmφ × 15 mm (height) It was placed in a petri dish and placed near a shelter contaminated with cockroach droppings and covered with a plastic plate again.
Thereafter, the number of test insects hiding in the shelter and test box was observed over time.

Table 1 shows the results when 2,6-dimethyl-4-heptanol was used as a test substance. In Table 1, the extermination rate (%) was calculated using the following formula (1).
Hereinafter, in this evaluation example, a test container in which a test substance is installed is referred to as a “sample container”, and a test container in which no test substance is installed is referred to as a “control container”.
Removal rate (%)
= (Number of insects in control container-number of insects in specimen container) / number of insects in control container × 100 (1)

In Table 1, “immediately before test” means immediately before the test substance is placed in the specimen container, and “immediately after installation” means immediately after the test substance is placed in the specimen container, “3 hours later”, “8 hours later” “After” and “after 24 hours” refer to 3 hours, 8 hours, and 24 hours after the test substance is placed in the specimen container, respectively.
From the results shown in Table 1, it was found that 2,6-dimethyl-4-heptanol had an effect of expelling (exterminating) cockroaches. Further, it was confirmed that all cockroaches were expelled 24 hours after the test substance was installed.

Further, as the test substance, Table 2 shows the results obtained using three kinds of branched C ₉ aliphatic monohydric alcohol. In addition, as a reference example, the results when monoterpene alcohol (citronellol, menthol) and monoterpene ketone (camphor) are used alone are also shown. Moreover, the result when n-nonanol which is a linear alcohol is used as a comparative example is also shown.

  From the results in Table 2, the cockroach expelling (disinfecting) effect of each test substance was observed with time. The time required for extermination was different for each test substance, but it was confirmed that almost all cockroaches were expelled from all the test substances in Table 2 24 hours after the test substance was installed.

The branch _{C 9} aliphatic monohydric alcohol mono terpene alcohols (citronellol, menthol) by combination with or monoterpene ketone (carboxylic), 2,6-dimethyl-4-heptanol, or 3,5,5-trimethyl - Compared with the case of using 1-hexanol alone, the initial eviction (extermination) effect was enhanced. This result, monohydric alcohol of branched C ₉ aliphatic, believed to be due to synergistic effect with the monoterpene alcohol or monoterpene ketones.

Evaluation example 2
[Evaluation of the fly]
As a test box, a container made of plywood having a size of 582 mm × 900 mm × 600 mm (height) was used. Two sides of the container side were covered with wire mesh, and a transparent plastic plate was installed on the upper part for easy observation. Two cans (235 mm x 235 mm x 345 mm (height): volume 19.0 L) were placed in a test box as test containers.
In one test container (specimen container), a container containing the test substance (200 mg of test substance in a 55 mmφ filter paper and then put in a petri dish of 60 mmφ × 16 mm (height)) and an attractant Put the container. Only the container with the attractant was placed in the other test container (control container).
About 10 flies about 10 minutes after placing adhesive paper (98mm x 79mm: 5mmφ holes at 4 locations) on the containers with attractant installed in each test container. (Drosophila) was released in the test box.
About 24 hours after the release, the number of flies captured with adhesive paper and the number of fly flies invading into the test container were examined.

Table 3 shows the results when 2,6-dimethyl-4-heptanol was used as the test substance. In Table 3, the extermination rate (%) was calculated using the following formula (1).
Removal rate (%)
= (Number of insects in control container-number of insects in specimen container) / number of insects in control container × 100 (1)

  As a result of Table 3, 2,6-dimethyl-4-heptanol showed an extermination effect against the fly, and an invasion preventing effect was recognized.

Further, Table 4 shows the results when the test substance, using three kinds of branched C ₉ aliphatic monohydric alcohol. In addition, as a reference example, the results when monoterpene alcohol (citronellol, menthol) and monoterpene ketone (camphor) are used alone are also shown. Moreover, the result when n-nonanol which is a linear alcohol is used as a comparative example is also shown.

  In all of the test substances in Table 4, an invasion preventing effect against the fly was recognized.

The branch C ₉ aliphatic monohydric alcohol mono terpene alcohols (citronellol, menthol) or monoterpene ketone (camphor) in combination with the results, in comparison with the case of the branched C ₉ aliphatic monohydric alcohol alone, intrusion The prevention rate was high.
This result, monohydric alcohol of branched C ₉ aliphatic, believed to be due to synergistic effect with the monoterpene alcohol or monoterpene ketones.

Evaluation Example 3
[Effects against mites]
About 50 g of mite saturated medium (estimated density 50,000 to 60000 individuals / g) was placed on the inner bottom surface of the 162 mm × 112 mm × 85 mm (height) AS resin container and uniformly spread. An untreated black fine paper was gently placed on a mite (condensed mite) medium, and an 8 mmφ filter paper soaked with the test substance was placed in the center of the black fine paper. The filter paper is no. Using 514A, the release paper laminated on the back surface was adhered to prevent the test substance from moving to the black fine paper.
After the test substance was installed, observation was continued for 1 hour over time, and the number of ticks moved on untreated black fine paper was measured to determine the extermination effect. In order to determine the removal distance, concentric circles were drawn with white lines at intervals of 5 mm from the outer edge of the filter paper soaked with the test substance in advance on black fine paper. The test substance was infiltrated into the filter paper using a microsyringe (4 μL / 0.50 cm ² ≈80 g / m ² ). The evaluation test was performed at 25 ° C.

2,6-Dimethyl-4-heptanol and 3,5,5-trimethyl-1-hexanol were used as test substances. Also investigated the spatial control action of monoterpene alcohols (linalol, carbeol) and monoterpene ketone (carvone), respectively, and the commercial control products known as insect repellents and the spatial control action of DEET. It was. Table 5 shows the results of three tests for each test substance. The numerical value in the table represents the average value of 3 wards in one district. Moreover, the result when n-nonanol which is a linear alcohol is used as a comparative example is also shown.
In Table 5, the numbers in parentheses indicate the number of dead ticks.

In Table 5, “after 15 minutes”, “after 30 minutes”, and “after 60 minutes” refer to 15 minutes, 30 minutes, and 60 minutes after the test substance is placed on the black fine paper, respectively. . Moreover, it can be said that a test substance (test substance) has a high intrusion prevention effect, so that the numerical value of a table | surface is small (the number of invading ticks is small).
All of the two test substances in Table 5 showed a disinfecting action against ticks and an intrusion prevention effect was observed. There was no spatial control effect on the commercial product and DEET. In addition, the test substance also showed an acaricidal effect.

Further, there is branched _{C 9} aliphatic monohydric alcohol having two or more branched alkyl groups 2,6-dimethyl-4-heptanol, or 3,5,5-trimethyl-1-hexanol monoterpene alcohol (linalool, carveol ) or by combination with a monoterpene ketone (carboxylic), as compared with the case of the branched C ₉ aliphatic monohydric alcohol alone, high penetration prevention effect was observed. This result, monohydric alcohol of branched C ₉ aliphatic, believed to be due to synergistic effect with the monoterpene alcohol or monoterpene ketones.

Evaluation Example 4
[Effects on Koiga]
A tea strainer (metal ball container: approx. 6 cmφ) with a wool cloth (approx. 3 cm x 3 cm: approx. 0.2 g) is hung so as not to come into contact with the glass container (capacity: 1450 mL). Placed in a container. The test substance was added to the glass container as the test group, and the test substance was not added as the control group. The lethality and inhibition of feeding were determined from the lethality of the moth larvae and the amount of food in the wool cloth 3 weeks after the start of the test. The effect was investigated. The test was performed in duplicate for each group.
In the test area, a non-woven fabric (40 mm × 40 mm) filled with 4 g of silica gel containing 15% test substance was added.

The feeding inhibition rate was calculated using the following formula (2).
Feeding inhibition rate (%) = (feeding amount in control group (g) −feeding amount in test group (g)) / feeding amount in control group (g) × 100 (2)
2,6-Dimethyl-4-heptanol and 3,5,5-trimethyl-1-hexanol were used as test substances. The results are shown in Table 6. Moreover, as a reference example, the results when monoterpene alcohol (nerol, menthol) and monoterpene ketone (camphor) are used alone are also shown. Moreover, the result when n-nonanol which is a linear alcohol is used as a comparative example is also shown.

  As a result of Table 6, all of the two test substances showed an extermination action against carp, and an antifeeding effect was observed. Further, the test substance was found to have a lethal effect on the moth larvae.

Further, there is branched _{C 9} aliphatic monohydric alcohol having two or more branched alkyl groups 2,6-dimethyl-4-heptanol, or 3,5,5-trimethyl-1-hexanol monoterpene alcohol (nerol, menthol ) or monoterpene ketone (camphor) in combination with the results, in comparison with the case of the branched C ₉ aliphatic monohydric alcohol alone, antifeedant rate was higher.
This result, monohydric alcohol of branched C ₉ aliphatic, believed to be due to synergistic effect with the monoterpene alcohol or monoterpene ketones.

Evaluation Example 5
[Effects against mosquitoes]
As a test box, a veneer container made of 850 mm × 1500 mm × 820 mm (height) was used. Two sides of the container side were covered with wire mesh, and a transparent plastic plate was installed on the upper part for easy observation. Two test containers (360 mm × 360 mm × 400 mm (height): volume 51.84 L) made of brown decoupage were placed in the test box. A metal rack of 265 mm × 200 mm × 170 mm (height) was placed at the center of each test container.
A container containing a test substance and an attractant was installed on the rack in one test container. The test substance was immersed in 500 mg of 55 mmφ filter paper and then placed in a petri dish of 60 mmφ × 16 mm (height). Only the container containing the attractant was placed on the rack in the other test container (control container).

Place the adhesive paper (98mm x 79mm: 5mmφ holes in 4 places) for collection on the container with the attractant installed in each test container, and about 10 minutes after placing the adhesive paper, About 100 mosquitoes (Acacia) were released in the test box.
About 16 hours after release, the number of mosquitoes captured on adhesive paper and the number of mosquitoes entering each test container were counted.

Table 7 shows the results when 2,6-dimethyl-4-heptanol was used as a test substance. In order to eliminate the difference depending on the installation location of the test container, the container containing the test substance (specimen container) and the control container were replaced, and the repeated test was performed. The total results are shown in Table 7.
In Table 7, the intrusion prevention rate was calculated using the following formula (3).
Intrusion prevention rate (%) = (Number of intrusions into untreated area−Number of intrusions into treated area) / Number of intrusions into untreated area × 100 (3)

  As a result of Table 7, 2,6-dimethyl-4-heptanol showed an extermination effect against mosquitoes and an invasion preventing effect was recognized.

Further, as the test substance, Table 8 shows the results obtained using three kinds of branched C ₉ aliphatic monohydric alcohol. In addition, as a reference example, the results when monoterpene alcohol (citronellol, perilla alcohol) and monoterpene ketone (menton) are used alone are also shown. Moreover, the result when n-nonanol which is a linear alcohol is used as a comparative example is also shown.

  In all of the test substances in Table 8, an invasion preventing effect against mosquitoes was observed.

The branch C ₉ aliphatic monohydric alcohol mono terpene alcohols (citronellol, perilla alcohol) or monoterpene ketone (Menton) and combination results, as compared with the case of the branched C ₉ aliphatic monohydric alcohol alone, The intrusion prevention rate was high.
This result, monohydric alcohol of branched C ₉ aliphatic, believed to be due to synergistic effect with the monoterpene alcohol or monoterpene ketones.

Evaluation Example 6
[Effects against tobacco beetles]
Prepare two polystyrene cups (11cmφ (bottom is 10cmφ), 6.8cm (height)), and provide a 20mm x 10mm (height) entrance / exit at the center of each bottom. Were connected by a passage of a square pipe (40 mm × 100 mm × 10 mm (height)). A 40 mmφ hole was made in the center of the pipe, and a disposable cup (70 mmφ × 40 mmφ, 68 mm (height)) with the bottom portion cut was attached.
An injection needle was attached to the side surface of the central part of the pipe so that air could be inhaled. In addition, in order to prevent the escape of tobacco beetles, an evaluation test was performed by placing a transparent plastic plate on two cups and a disposable cup so as to be close to a hermetic state.
One cup (specimen container) was provided with 8 mmφ filter paper impregnated with 50 mg of the test substance, and after 1 hour, air was sucked from the suction port at 50 mL / min to release 20 cigarette beetles. The location of the tobacco beetle was examined one hour after releasing the tobacco beetle.

Table 9 shows the results when 3,5,5-trimethyl-1-hexanol was used as a test substance (4 repeated tests were performed).
In Table 9, the intrusion prevention rate was calculated using the following formula (4).
Invasion prevention rate (%) = (number of insects in control container−number of insects in specimen container) / number of insects in control container × 100 (4)

  As a result of Table 9, 3,5,5-trimethyl-1-hexanol showed an extermination effect against tobacco beetle and an invasion preventing effect was recognized.

Further, as the test substance, it is shown in Table 10. The results in the case of using the three kinds of branched C ₉ aliphatic monohydric alcohol. In addition, as a reference example, results obtained when monoterpene alcohol (linalool, menthol) and monoterpene ketone (carvone) are used alone are also shown. Moreover, the result when n-nonanol which is a linear alcohol is used as a comparative example is also shown.

  In all the test substances in Table 10, an invasion preventing effect against tobacco beetle was observed.

The branch C ₉ aliphatic monohydric alcohol monoterpenes alcohol (linalool, menthol) or monoterpene ketone (carboxylic) and the combination result, as compared with the case of the branched C ₉ aliphatic monohydric alcohol alone, intrusion The prevention rate was high.
This result, monohydric alcohol of branched C ₉ aliphatic, believed to be due to synergistic effect with the monoterpene alcohol or monoterpene ketones.

Example 2
According to the following Production Examples 1 to 4 and Evaluation Examples 7 and 8, a volatile closed space insecticide composition was produced and evaluated.
As above-mentioned, Example 1 is evaluation of the pest control effect of the active ingredient of a volatile closed space insecticide. An example in the form actually used is shown in the second embodiment.
Production Example 1
[Preparation of solid volatile closed space insecticide composition]
To 75 parts by mass of silica gel, 25 parts by mass of 2,6-dimethyl-4-heptanol was added, mixed, and supported to obtain a solid volatile closed space insecticide composition.

Production Example 2
[Preparation of solid volatile closed space insecticide composition]
70 parts by mass of activated carbon, 25 parts by mass of 3,5,5-trimethyl-1-hexanol and 5 parts by mass of the following combined compounds are mixed and supported, respectively, and each solid volatile closed space insecticide A composition was obtained.
Concomitant compounds: citronellol, nerol, linalool, carvone, menthone

Production Example 3
[Production of liquid volatile closed space insecticide composition]
95 parts by mass of 2,6-dimethyl-4-heptanol was mixed with 5 parts by mass of 2-octanol to obtain a liquid volatile closed space insect repellent composition.

Production Example 4
[Production of liquid volatile closed space insecticide composition]
95 parts by mass of 3,5,5-trimethyl-1-hexanol was mixed with 4 parts by mass of 2-octanol and 1 part by mass of linalool to obtain a liquid volatile closed space insect repellent composition.

Evaluation Example 7
When the solid volatile closed space insecticide composition obtained in Production Examples 1 and 2 was evaluated in the same manner as in Evaluation Example 5, the same effect as in Evaluation Example 5 was obtained.

Evaluation Example 8
When the liquid volatile closed space insecticide composition obtained in Production Examples 3 and 4 was put in a bottle and evaluated in the same manner as in Evaluation Example 5 using a core-up felt, it was the same as in Evaluation Example 5. The effect was obtained.

Since the volatile enclosed space pesticide of the present invention has an effect of exterminating pests in the enclosed space, the present invention can protect what is present in the enclosed space from pests. It can be widely used in fields such as furniture industry and transportation industry.

Claims (10)

  A volatile enclosed space insect repellent characterized by containing, as an active ingredient, a monohydric alcohol consisting of only nine carbon atoms, one oxygen atom, and hydrogen atom and having two or more branched alkyl groups .   The volatile closed space insecticide of Claim 1 which contains the monohydric alcohol which has 2 or 3 branched methyl groups as an active ingredient.   The volatile closed space insecticide of Claim 1 or Claim 2 which contains the monohydric alcohol whose flash point is 70 degreeC or more as an active ingredient.   Furthermore, one or more combination compounds selected from the group consisting of (A) a chain monoterpene alcohol, (B) a cyclic monoterpene alcohol, and (C) a cyclic monoterpene ketone are contained. The volatile enclosed space insect repellent according to any one of the claims.   The pest is at least one pest selected from the group consisting of sanitary pests, unpleasant pests, clothes pests, food pests, cultural property pests, house pests and pet pests. The volatile enclosed space insect repellent according to claim.   The pest is at least one pest selected from the group consisting of cockroaches, flies, ticks, moths, moths, mosquitoes, tobacco beetles, cutworms, scutellar, weevil, beetles, scallops, spots, fleas and butterflies The volatile closed space insect repellent according to any one of claims 1 to 5.   A solid volatile closed space insect repellent composition comprising the volatile closed space insect repellent according to any one of claims 1 to 6 supported on a carrier. .   The solid according to claim 7, wherein the carrier is a carrier selected from the group consisting of silica, zeolite, nonwoven fabric, fiber, synthetic resin, mineral, synthetic mineral, diatomaceous earth, activated clay, bentonite, black clay, and activated carbon. A volatile enclosed space insect repellent composition.   A liquid volatile closed space insect repellent composition comprising the volatile closed space insect repellent according to any one of claims 1 to 6 diluted with a liquid. The solid volatile closed space insect repellent composition according to claim 7 or 8, or the liquid volatile closed space insect repellent composition according to claim 9 is 1 × 10 ⁻³ m ^3. A method for exterminating pests characterized in that it is volatilized at room temperature in a closed space of 1 × 10 ³ m ³ or less.