JP6774482B2 - Mosquito control aerosol and mosquito control method - Google Patents

Description

In the present invention, an aerosol stock solution containing a pest control component and an organic solvent, a pressure-resistant container provided with a fixed-quantity injection valve filled with a propellant, and an injection provided with an injection port connected to the fixed-quantity injection valve. The present invention relates to a mosquito control aerosol equipped with a button, and a mosquito control method using the same.

As a method of exterminating flying pests, for example, a method of evaporating a chemical from a carrier impregnated with a chemical containing an insecticidal component and volatilizing it in a treatment space, a method of directly spraying the chemical on the flying pest, or a place where flying pests are likely to appear. There is a method of spraying a drug in advance. Regarding these methods, aerosol insecticides containing insecticidal components have been developed as products for exterminating flying pests that invade indoors. Aerosol insecticides are widely used as easy-to-use products because they can easily spray insecticidal components into the treatment space.

Conventionally, there have been some aerosol pesticides that suppress a decrease in the residual rate of the agent in the air indoors (see, for example, Patent Document 1). According to Patent Document 1, after releasing a drug, the drug is retained in the air to suppress a decrease in air concentration, whereby a sufficient extermination effect against mosquitoes lurking in the shadow can be maintained. There is.

In addition, there was an aerosol insecticide in which the particle size when the drug was sprayed indoors was set to be larger than that of Patent Document 1 (see, for example, Patent Document 2). Patent Document 2 is an aerosol insecticide based on the same technical idea as Patent Document 1, and is intended to leave the agent in the air in the room for as long as possible to enhance the insecticidal effect on mosquitoes.

On the other hand, regarding aerosol insecticides, there is a method for exterminating flying pests in a house, which is characterized by adhering to the surface of an indoor structure or equipment (see, for example, Patent Document 3). According to Patent Document 3, since a specific compound attached to an indoor structure or the like evaporates, it does not require repeated spraying or continuous operation of electric appliances or the like, and a flying pest in a house by a simple means. It is said that it can be effectively removed.

Japanese Unexamined Patent Publication No. 2001-17555 Japanese Unexamined Patent Publication No. 2013-99336 Japanese Unexamined Patent Publication No. 2001-328913

The aerosol insecticide of Patent Document 1 has been attempted to prolong the time that the drug remains in the air by adjusting the particle size of the drug that diffuses into the room, and to prolong the duration of the drug. However, the residual rate of the drug particles in the air at 12 hours or more from the start of the treatment is 0.5% or more, and the aerosol pesticide of Patent Document 1 for the purpose of maintaining the residual rate in the air has a limited duration. is there. In Patent Document 2, the residual rate of the drug particles in the air is the same as that in Patent Document 1, and it is not an aerosol insecticide that can be expected to have a long duration.

Here, among the mosquitoes to be controlled (including not only ordinary mosquitoes such as Aedes albopictus and Aedes albopictus, but also chironomids and Aedes albopictus belonging to the suborder Nematocera), especially Aedes albopictus and Aedes albopictus suck blood. Since it is a mosquito that not only protects itself but also transmits infectious diseases, it is necessary to protect itself from these mosquitoes, and it is required to establish an more effective extermination method than before. Since mosquitoes are flying pests that invade indoors day and night, an insecticide that is effective all day long, that is, has an effective duration of 24 hours, is ideal.

However, as described above, the aerosol pesticides disclosed in Patent Document 1 and Patent Document 2 have an effect lasting only about 12 hours. Further, in Patent Document 1 and Patent Document 2, the drug is positively left in the air by adjusting the particle size of the drug, but the fact that the drug particles remain in the air does not mean that the drug particles remain in the air. It means that people and pets in the treatment space are left in the environment where the drug is inhaled for a long time. Therefore, it cannot be said that it is a preferable aerosol insecticide in terms of its effect on the human body and pets.

Even in the extermination method of Patent Document 3, it is unclear whether a stable effect can be maintained for a long period of time. The chemical particles ejected into the air are (A) suspended in the air and remain, (B) adhered to the floor or wall, (C) (B) volatilized again after (B), or (D) decomposed by light or the like. It is thought that it follows either behavior of disappearing. In light of these, the extermination method of Patent Document 3 corresponds to the type (C). However, when the chemicals adhering to the structures in the room volatilize again in the air, they are easily affected by the temperature, air volume, etc. Therefore, the extermination method of Patent Document 3 has a stable effect on the extermination of flying pests. Not always available.

The present invention has been made in view of the above problems, and among flying pests, it is possible to exert an excellent control effect on mosquitoes for a long period of time, and also on the human body and pets. It is an object of the present invention to provide a mosquito control aerosol in which the influence of the above is reduced, and a mosquito control method using the mosquito control aerosol.

The characteristic configuration of the mosquito control aerosol according to the present invention for solving the above problems is
An aerosol stock solution containing a pest control component and an organic solvent, a pressure-resistant container provided with a fixed-quantity injection valve containing a propellant, and a pressure-resistant container.
An injection button provided with an injection port connected to the fixed-quantity injection valve,
It is a mosquito control aerosol equipped with
The injection capacity when the injection button is pressed once is adjusted to 0.1 to 0.4 mL, and the injection force at an injection distance of 20 cm is adjusted to be 0.3 to 10.0 g · f at 25 ° C.
The aerosol stock solution is injected from the injection port as adhesive particles adhering to an exposed portion in the treatment space and floating particles floating in the treatment space.

As described in "Problems to be Solved by the Invention", conventional aerosol pesticides are being developed in the direction of actively diffusing drug particles in the treatment space and prolonging the time remaining in the air as much as possible. Was being done. However, if the residence time of the drug particles floating in the treatment space is long, if a person or pet enters the treatment space, the drug particles may be inhaled, which may affect health. To.
By the way, according to the research by the present inventors, mosquitoes represented by mosquitoes (hereinafter, simply referred to as "mosquitoes" in the present invention) are spent on a wall surface or the like rather than on a flying time. It turned out that it was longer. That is, most of the mosquitoes that have invaded indoors stay on the wall surface or the like, and are looking for an opportunity to suck blood. For this reason, the conventional method of prolonging the floating time of the drug particles in the treatment space can have a certain effect on the control of mosquitoes in flight, but it stays on the wall surface or the like. The effect of the drug cannot be sufficiently exerted on the mosquitoes, and as a result, the control of the mosquitoes may be incomplete. From the above research results, the present inventors have found that enhancing the control effect on mosquitoes perched on a wall surface or the like suppresses the inhalation of chemicals by humans or pets, while invading mosquitoes indoors. I thought that it would lead to the improvement of the control of the whole class.
Therefore, in the mosquito control aerosol according to the present invention, the aerosol stock solution sprayed into the treatment space is applied to the exposed portion in the treatment space (for example, the surface of a structure such as a floor surface, a wall surface, or furniture existing in the treatment space). Etc.), and the floating particles floating in the treatment space are formed as two types of particles. That is, by assigning the roles to the particles of the two types of aerosol stock solutions sprayed into the treatment space, the insect repellent effect can be efficiently exhibited at the optimum location in the treatment space. Therefore, both mosquitoes that are stationary in the exposed part and mosquitoes that are flying in the treatment space can be effectively knocked down or killed, and the control effect of the entire mosquito can be improved. it can. Further, the aerosol stock solution sprayed into the treatment space is formed of either adhesive particles or floating particles. As a result, even if the suspended particles are evenly diffused throughout the treatment space, not all of the aerosol stock solution becomes floating particles and is diffused into the treatment space, so that the concentration of the aerosol stock solution in the treatment space is adhesive. It is reduced by the amount of particles. Therefore, the amount of particles of the aerosol stock solution inhaled by a person or pet in the treatment space becomes extremely small, and the aerosol becomes a safer mosquito control aerosol for the human body or pet.
Further, the mosquito control aerosol according to the present invention has an injection capacity of 0.1 to 0.4 mL when the injection button is pressed once, and an injection force at an injection distance of 20 cm is 0.3 to 10 at 25 ° C. It is adjusted to be 0.0 g · f. By adjusting the injection capacity and the injection force in this way, the injected aerosol stock solution can be formed as adhesive particles and floating particles, and an excellent control effect on mosquitoes can be obtained.

In the mosquito control aerosol according to the present invention
The adhesive particles preferably have a 90% particle diameter of 20 to 80 μm in a volume integrated distribution at 25 ° C. and an injection distance of 15 cm.

According to the mosquito control aerosol of this configuration, by adjusting the adhesive particles to the above optimum range, the mosquitoes that are stuck in the exposed part are surely knocked down or killed by the pest control component of the adhesive particles. Can be made to.

In the mosquito control aerosol according to the present invention
The suspended particles preferably have a 90% particle diameter of less than 20 μm in a volume integrated distribution at 25 ° C. and an injection distance of 15 cm.

According to the mosquito control aerosol of this configuration, by adjusting the floating particles to the above optimum range, the mosquitoes flying in the treatment space are knocked down or killed by the pest control component of the floating particles. Can be done.

In the mosquito control aerosol according to the present invention
The volume ratio (a / b) of the aerosol stock solution (a) and the propellant (b) sealed in the pressure-resistant container is preferably 10/90 to 50/50.

According to the mosquito control aerosol of this configuration, when the volume ratio (a / b) of the aerosol stock solution (a) and the propellant (b) is within the above range, adhesion formed from the sprayed aerosol stock solution. The balance between aerosol and airborne particles is optimal. As a result, the adherent particles can surely reach the exposed portion in the processing space, and the floating particles can float in the processing space in an amount that does not affect the human body or pets. As described above, the adhesive particles and the floating particles are present in the optimum state, and the respective roles can be shared to maximize the effect of the pest control component.

In the mosquito control aerosol according to the present invention
When the aerosol stock solution is sprayed once into the treatment space, the residual rate in the air of the pest control component after 2 hours is preferably 0.05 to 5%.

According to the mosquito control aerosol of this configuration, when the aerosol stock solution is sprayed once into the treatment space, the residual rate of the pest control component in the air (in the treatment space) after 2 hours is 0.05 to 5%. It is adjusted to be. Within such a range, the pest control component of the floating particles can be effectively volatilized in the treatment space. Further, the floating particles will remain in the air even after the lapse of 2 hours, but the floating particles are present in a state where the low concentration is maintained. Therefore, while having the effect of knocking down or killing mosquitoes flying in the treatment space, the risk of affecting the human body and pets is significantly reduced, and the mosquitoes can be used safely.

In the mosquito control aerosol according to the present invention
The organic solvent is preferably at least one selected from the group consisting of higher fatty acid esters and alcohols.

According to the mosquito control aerosol of the present configuration, the organic solvent is at least one selected from the group consisting of higher fatty acid esters and alcohols. By using such an organic solvent, the effect of each component can be efficiently exhibited. Further, when the aerosol stock solution is sprayed, adherent particles and floating particles can be formed in a well-balanced manner, and the control effect on mosquitoes becomes stable.

In the mosquito control aerosol according to the present invention
The pest control component preferably has a vapor pressure of 2 × 10 ^-4 to 1 × 10 ^-2 mmHg at 30 ° C.

According to the mosquito control aerosol of this configuration, the pest control component uses a component having a vapor pressure of 2 × 10 ^-4 to 1 × 10 ^-2 mmHg at 30 ° C. With such a pest control component, when the aerosol stock solution is sprayed, adhesive particles and floating particles can be formed in a well-balanced manner, and each of them exists in an optimum state and shares the roles of each. It can exert the effect of pest control ingredients. Further, when prepared with each component other than the pest control component, the above-mentioned organic solvent, and the propellant, an effective mosquito control aerosol can be realized.

In the mosquito control aerosol according to the present invention
When the aerosol stock solution is sprayed once into the treatment space, the effect duration of the pest control component is preferably 20 hours or more for a space of 33 m ³ or less.

In the method for exterminating mosquitoes with an aerosol insecticide disclosed in Patent Document 1 and Patent Document 2, the duration of the drug is set to 12 hours. However, in the case of the mosquito control aerosol according to the present invention, a pest control effect for 20 hours or more, that is, substantially one day, for a space of 33 m ³ or less by injecting the aerosol stock solution into the treatment space only once. Can be sustained.

In the mosquito control aerosol according to the present invention
The injection port preferably has an injection port diameter of 0.2 to 1.0 mm.

According to the mosquito control aerosol of this configuration, since the nozzle diameter is set in the above optimum range, the particle diameter and jet force of the aerosol stock solution can be adjusted appropriately, and the adhesive particles and Floating particles can be formed in a well-balanced manner. As a result, each particle exists in an optimum state in the treatment space, and each particle can share the role of the pest control component.

The characteristic configuration of the mosquito control method according to the present invention for solving the above problems is
The mosquito control aerosol according to any one of the above is used to inject the aerosol stock solution into the treatment space to knock down or kill the mosquitoes.

Since the mosquito control method of the present configuration is carried out using the mosquito control aerosol of the present invention, it is possible to obtain the same excellent mosquito control effect as the above-mentioned mosquito control aerosol.

In the mosquito control method according to the present invention
It is preferable to inject the aerosol stock solution into the treatment space once every 24 hours.

As described above, the mosquito control aerosol according to the present invention has a pest control component having a duration of 20 hours or more, which is approximately one day. Therefore, using this mosquito control aerosol, the aerosol stock solution can be sprayed into the treatment space once every 24 hours. If such a mosquito control method is carried out, the pest control effect can be maintained over the life time zone by spraying once a day at a fixed time.

FIG. 1 is a model diagram showing the behavior of particles of the aerosol stock solution when the aerosol stock solution is injected into the treatment space.

The mosquito control aerosol of the present invention is a pressure-resistant container provided with an aerosol stock solution containing a pest control component and an organic solvent and a metering agent filled with a propellant, and a jet connected to the metering valve. It is equipped with an injection button provided with a mouth. Hereinafter, the mosquito control aerosol of the present invention will be described. However, the present invention is not intended to be limited to the configurations described in the embodiments and drawings described below.

<Aerosol stock solution>
[Pest control ingredients]
The pest control component, which is one of the main components of the aerosol stock solution, has a vapor pressure of 2 × 10 ^-4 to 1 × 10 ^-2 mmHg at 30 ° C. As such a pest control component, metoflutrin, transfluthrin and the like are preferably selected. These pest control ingredients can be used alone or in a mixed state. Note that metoflutrin and transfluthrin have optical isomers and geometric isomers based on asymmetric carbon, which are also included in the present invention.

The content of the pest control component in the aerosol stock solution is preferably 1.0 to 50% by weight in consideration of being dissolved in an organic solvent and then sprayed into the treatment space. Within such a range, the pest control component is easily dissolved in the organic solvent, and when the aerosol stock solution is sprayed, adhesive particles and floating particles are easily formed (adhesive particles and floating properties). The particles will be described in detail later.) When the content of the pest control component in the aerosol stock solution is less than 1.0% by weight, the pest control component cannot be effectively exerted, and the mosquito control effect becomes insufficient. On the other hand, when the content of the pest control component in the aerosol stock solution exceeds 50% by weight, the concentration of the pest control component becomes high, and it becomes difficult to properly prepare the aerosol stock solution.

As described above, the pest control component contained in the mosquito control aerosol of the present invention has a vapor pressure of 2 × 10 ^-4 to 1 × 10 ⁻² mmHg at 30 ° C. (methofurtrin, transfluthrin, etc.). However, in addition to these components, pyrethroid compounds such as profluthrin and empentrin, phthalthrin, resmethrin, cifluthrin, phenothrin, permethrin, ciphenothrin, cypermethrin, allethrin, prarethrin, flamethrin, imiprothrin, etofenprox and the like It is also possible to contain a pyrethroid compound, a silicon compound such as silafluofen, an organic phosphorus compound such as dichlorvos and phenothrin, and a carbamate compound such as propoxul.

The pest control component is adjusted so that when the aerosol stock solution is sprayed once into the treatment space, the residual rate in the air (in the treatment space) after 2 hours has elapsed is 0.05 to 5%. The air residual ratio is the ratio of the number of particles (Q) existing in the processing space after a predetermined time elapses to the number of particles (P) existing in the processing space immediately after injection, that is, Q / P × 100 (%). However, as will be briefly described in Examples described later, it can be obtained from the theoretical air concentration of the pest control component and the air concentration of the pest control component after a lapse of a predetermined time. The injection amount of the pest control component at this time is adjusted to 5.0 to ³⁰ mg per 4.5 to 8 tatami mats (about 18.5 to 33.0 m ³ ). Within such a range, adherent particles and suspended particles are formed in a well-balanced manner by the aerosol stock solution, each particle exists in an optimum state, and each role is shared to exert a pest control effect. Can be done. Moreover, even if the survival rate is relatively low as described above, mosquitoes can be effectively knocked down or killed. Furthermore, even if a person or pet in the processing space inhales, there is no risk of affecting the human body or pet, and it can be used safely.

[Organic solvent]
The organic solvent, which is another main component of the aerosol stock solution, can dissolve the above pest control components to prepare an aerosol stock solution, and when the prepared aerosol stock solution is sprayed into the treatment space, the optimum particles are produced. What can be formed is used. As the organic solvent, higher fatty acid esters and alcohols are preferable. The higher fatty acid ester preferably has a total number of carbon atoms of 16 to 20, and examples thereof include isopropyl myristate, butyl myristate, hexyl laurate, and isopropyl palmitate. Of these, isopropyl myristate is particularly suitable. As the alcohols, lower alcohols having 2 to 3 carbon atoms are preferable. As the organic solvent, for example, a hydrocarbon solvent such as n-paraffin and isoparaffin, glycol ethers having 3 to 6 carbon atoms, a ketone solvent and the like can be mixed.

[Other ingredients]
In addition to the above components, the mosquito control aerosol of the present invention includes acaricides, fungicides for fungi and fungi, antibacterial agents, fungicides, air fresheners, deodorants, stabilizers, and charges. Inhibitors, antifoaming agents, excipients and the like can also be appropriately added. Examples of the acaricide include 5-chloro-2-trifluoromethanesulfonamide methyl benzoate, phenyl salicylate, 3-iodo-2-propynylbutylcarbamate and the like. Antifungal agents, antibacterial agents, and bactericidal agents include hinokithiol, 2-mercaptobenzothiazole, 2- (4-thiazolinyl) benzimidazole, 5-chloro-2-methyl-4-isothiazolin-3-one, triphorin, 3 -Methyl-4-isopropylphenol, ortho-phenylphenol and the like can be mentioned. Air fresheners include orange oil, lemon oil, lavender oil, peppermint oil, eucalyptus oil, citronella oil, lime oil, yuzu oil, jasmine oil, cypress oil, green tea essential oil, limonene, α-pinene, linalol, geraniol, phenylethyl. Examples include aromatic components such as alcohol, amylcinnamic aldehyde, cumin aldehyde, and benzyl acetate, and fragrance components containing green leaf alcohol and green leaf aldehyde called "green scent".

<Injector>
Examples of the propellant used in the mosquito control aerosol of the present invention include liquefied petroleum gas (LPG), dimethyl ether (DME), nitrogen gas, carbon dioxide gas, nitrous oxide, compressed air and the like. The above propellant can be used alone or in a mixed state, but one containing LPG as a main component is easy to use.

The mosquito control aerosol of the present invention is adjusted so that the volume ratio (a / b) of the aerosol stock solution (a) and the propellant (b) is 10/90 to 50/50. By adjusting to such a range, the balance between the adhesive particles and the floating particles becomes optimum. As a result, the adherent particles can surely reach the exposed portion in the processing space, and the floating particles can float in the processing space in an amount that does not affect the human body or pets. As described above, the adhesive particles and the floating particles are present in the optimum state, and can share the roles of each and maximize the pest control effect. If the ratio of the propellant (b) is increased with respect to the volume ratio (a / b) of 10/90, that is, if the propellant to be sealed in the pressure-resistant container is increased, the amount of the aerosol stock solution to be jetted becomes more than necessary. Adhesive particles are reduced due to miniaturization. As a result, there is a shortage of adhesive particles adhering to the exposed portion in the treatment space, so that it may not be possible to reliably control mosquitoes that have stopped in the exposed portion. On the other hand, when the ratio of the propellant (b) is reduced with respect to the volume ratio (a / b) of 50/50, that is, when the propellant sealed in the pressure-resistant container is reduced, the aerosol stock solution to be jetted is described above. Since it is difficult to form as adhesive particles having a particle size in the optimum range and floating particles, the aerosol stock solution settles immediately after being injected. Therefore, both the adhesive particles adhering to the exposed portion in the treatment space and the floating particles floating in the treatment space are insufficient in quantity, and it becomes difficult to knock down or kill the mosquitoes at an early stage.

<Aerosol for mosquito control>
As described above, an aerosol product is completed by selecting a pest control component, an organic solvent, a propellant, and other components to be blended as necessary and enclosing them in a pressure-resistant container. This aerosol product is the mosquito control aerosol of the present invention, and injects an aerosol stock solution into a treatment space. The aerosol stock solution is mainly composed of a pest control component and an organic solvent, and is strictly different from the propellant. However, the aerosol stock solution is released to the outside of the pressure-resistant container at the same time as the propellant. Therefore, in the following description, the aerosol content containing the aerosol stock solution and the propellant may be treated as the "aerosol stock solution". Here, the injection valve provided in the mosquito control aerosol according to the present invention will be described. The mosquito control aerosol according to the present invention is mainly composed of a pressure-resistant container (aerosol container), a fixed-quantity injection valve, and an injection button. An injection button, which is an operating unit for injecting the aerosol stock solution, is connected to the metering injection valve, and the injection button is provided with an injection port for ejecting the aerosol stock solution from the aerosol container to the outside (processing space). is there.

When the injection button of the mosquito control aerosol is pressed once, the fixed quantity injection valve is activated by the pressure of the propellant, and the aerosol stock solution in the pressure resistant container rises to the injection port and is injected into the treatment space. The injection volume of the aerosol stock solution at this time is adjusted to 0.1 to 0.4 mL, and more preferably 0.2 to 0.4 mL. Within such a range, the adhesive particles and the floating particles are formed in a well-balanced manner so that the control effect can be optimally exerted in the treatment space. If the injection capacity is less than 0.1 mL, the injection capacity is too small and the adherent particles do not sufficiently adhere to the exposed part in the treatment space, knocking down or killing the mosquitoes that are stuck in the exposed part. Becomes difficult. In addition, since the number of floating particles is reduced, it becomes difficult to knock down or kill mosquitoes flying in the treatment space. On the other hand, if it exceeds 0.4 mL, the aerosol stock solution is released into the treatment space more than necessary, which makes it difficult for people and pets to enter the treatment space, and the amount of the aerosol stock solution used becomes excessive, which is economical. It is also disadvantageous.

The mosquito control aerosol is adjusted to have an injection force of 0.3 to 10.0 g · f at a distance of 20 cm from the injection port and an injection force of 25 ° C. Within such a range, the adhesive particles formed from the aerosol stock solution can be smoothly reached to the exposed portion in the treatment space by one injection, and the effect of the pest control component can be exerted. .. Further, the injection port diameter of the injection port is preferably set to 0.2 to 1.0 mm. Within this range, the above particle size and jetting force can be appropriately adjusted, and adhesive particles and floating particles are optimally formed from the aerosol stock solution jetted into the treatment space, and the pest control effect can be obtained. It can be exerted and can reliably knock down or kill mosquitoes in the treatment space.

FIG. 1 is a model diagram showing the behavior of particles of the aerosol stock solution when the aerosol stock solution is injected into the treatment space. FIG. 1A is a model diagram when the mosquito control aerosol according to the conventional product is sprayed into the treatment space, and FIG. 1B is a model diagram when the mosquito control aerosol according to the present invention is sprayed into the treatment space. It is a model diagram in the case of.
As shown in FIG. 1 (a), a conventional aerosol product for mosquito control (simply referred to as “conventional product”) becomes particles M having a particle diameter of less than 20 μm when the aerosol stock solution is sprayed into the treatment space. And diffuse into the processing space. After a while after the injection, the particles M further diffuse throughout the treatment space and volatilize the pest control component. This allows mosquitoes flying in the treatment space to be knocked down or killed. However, as described above, since mosquitoes stay in the exposed part in the treatment space for a longer time than in the flying time, the mosquitoes that stay in the exposed part in the treatment space in the conventional product Cannot be reliably knocked down or killed. Further, when the wind blows in by opening the window of the treatment space or the like, some of the particles M floating in the treatment space are washed away by the wind, and the effect of the pest control component is greatly reduced. Further, if the particles M are suspended in the processing space for a long time, the amount of the particles M inhaled by the person or the pet in the processing space increases, which may adversely affect the human body or the pet.
Therefore, the present inventors have developed an aerosol product for mosquito control that solves these problems after diligent research. Hereinafter, adhesive particles and floating particles, which are characteristic constituents of the mosquito control aerosol product according to the present invention, will be described.

[Adhesive particles]
As shown in FIG. 1 (b), when the aerosol stock solution is sprayed once into the treatment space, adhesive particles X and floating particles Y are formed. In FIG. 1B, the white circles are the adhesive particles X, and the black circles are the floating particles Y. The particle diameters of the two are different, and the adhesive particle X is formed as a particle diameter larger than that of the floating particle Y. The preferable particle size of the adhesive particles X is such that the 90% particle size in the volume integration distribution at 25 ° C. and an injection distance of 15 cm is 20 to 80 μm. Within this range, when the aerosol stock solution is sprayed into the treatment space, it can quickly move to the exposed portion in the treatment space and adhere to it. Therefore, the mosquitoes perched on the exposed portion can be knocked down or killed by the pest control component of the adhesive particles X. In addition, since it has a pest control effect on mosquitoes that have invaded the treatment space and are about to stop in the exposed part, it is possible to expel them out of the treatment space. If the particle size is less than 20 μm, the particle size is too small and it is difficult to reach the exposed part, and as a result, it is difficult to control mosquitoes that have stopped or are about to stop at the exposed part. It becomes. On the other hand, when the particle size exceeds 80 μm, the particle size is too large, so that it becomes difficult to control the behavior of the adherent particles, and it becomes difficult to properly adhere to the exposed portion. A more preferable particle size of the adhesive particle X is 90% particle size of 25 to 70 μm in the volume integration distribution at 25 ° C. and an injection distance of 15 cm.

Also preferred adhesion amount of adhering particles X is 0.01~0.4mg per 1 m ² on the exposed portion of the processing space, preferably, 1 m ² per 0.05～0.2Mg. Within such a range, mosquitoes perched on the exposed portion can be effectively knocked down or killed. If the amount of adhesion is less than 0.01 mg per 1 m ² , it is not possible to exert a sufficient control effect on mosquitoes stuck in the exposed portion, and it becomes difficult to knock down or kill the mosquitoes. On the other hand, even if the adhered amount exceeds 0.4 mg per 1 m ² , the pest control effect is not significantly improved, and the amount of the aerosol stock solution used is excessive, which is economically disadvantageous.

[Floating particles]
The preferred particle size of the suspended particles Y is such that the 90% particle size in the volume integration distribution at 25 ° C. and an injection distance of 15 cm is less than 20 μm. Within such a range, when the aerosol stock solution is sprayed into the treatment space, it can be rapidly diffused and suspended in the treatment space. Therefore, mosquitoes flying in the treatment space can be knocked down or killed by the pest control component of the planktonic particles Y. In addition, since it is effective against mosquitoes trying to invade the treatment space, it is possible to suppress the invasion into the treatment space. When the particle size of the floating particles Y is 20 μm or more, it functions as the adhesive particles X. In this way, by adjusting the particle size to the optimum range as described above with some particles of the aerosol stock solution as planktonic particles Y, the behavior is different from that of the adhesive particles X, and the particles adhere. Together with the plankton X, mosquitoes can be effectively knocked down or killed.

As shown in FIG. 1B, the adhesive particles X and the floating particles Y as described above are exposed in the treatment space immediately after the aerosol stock solution is once injected into the treatment space. Moving quickly towards the part, the suspended particles Y begin to diffuse throughout the processing space. After a while after the injection once, the adherent particles X complete the adhesion to the exposed portion and maintain the adhered state. Then, as described above, the mosquitoes perched on the exposed portion are knocked down or killed by the pest control component. On the other hand, the floating particles Y diffuse evenly throughout the treatment space, and the pest control component gradually volatilizes, knocking down or killing the mosquitoes flying in the treatment space. In addition, it is possible to prevent the invasion of mosquitoes that try to invade the treatment space. Even if the mosquito invades the treatment space, if the mosquito stops at the exposed part in the treatment space or approaches the exposed part, the adhesive particles X adhering to the exposed part Pest control ingredients can reliably knock down or kill. As described above, in the mosquito control aerosol according to the present invention, since the particles formed from the injected aerosol stock solution are two types of particles having different behaviors, each particle exists in an optimum state, and each particle exists. The pest control effect can be maximized by sharing the roles of. Therefore, the adhesive particles X and the floating particles Y exert an excellent control effect on both mosquitoes existing in the treatment space and mosquitoes trying to invade the treatment space, and knock down or die. Can be made to.

Further, when the wind blows into the processing space, the adhesive particles X remain in the exposed portion even if a part of the floating particles Y is blown by the wind. As described above, most of the mosquitoes in the treatment space stay in the exposed part for a longer time, so if the adhesive particles X can exert the desired effect, the amount of the floating particles Y will decrease. However, there is no concern that the control effect on mosquitoes will be inferior. Further, as in the conventional product, some of the particles formed by the aerosol stock solution injected into the treatment space are formed as floating particles Y. Therefore, the concentration of the aerosol stock solution (suspended particles Y) diffused in the treatment space is reduced by the amount of the adhesive particles X, so that the concentration in the treatment space is lower than that of the conventional product. Therefore, the influence of inhalation of the floating particles Y on the human body and pets is reduced, and the product can be provided as a safe product.

When the aerosol stock solution prepared above is sprayed once into the treatment space, the effect duration of the pest control component is 20 hours or more for a space of 33 m ³ or less. The space of 33 m ³ or less includes a living room of 4.5 to 8 tatami mats (ceiling height 2.5 m). Therefore, the mosquito control aerosol according to the present invention can maintain the pest control effect substantially all day in a normal living space such as a general house. Mosquitoes invade indoors day and night, and it is necessary to prevent blood from being sucked during bedtime, but the effect of the pest control component lasts for 20 hours or more in a space of 33 m ³ or less. For example, if it is sprayed once before going to bed at night, the effect will continue until the afternoon of the next day, and you can go to bed with peace of mind.

<Mosquito control method>
The mosquito control method of this configuration is carried out using the above-mentioned mosquito control aerosol. First, in a pressure-resistant container provided with an aerosol stock solution containing a pest control component and an organic solvent and a fixed-quantity injection valve filled with a propellant, an injection button provided with an injection port connected to the fixed-quantity injection valve is pressed. When pressed once, the aerosol stock solution is injected from the injection port into the processing space (injection step). At this time, as shown in FIG. 1B, adherent particles X and floating particles Y are formed from the aerosol stock solution and injected into the processing space. The adhesive particles X adhere to the exposed portion in the processing space, and the floating particles Y float in the processing space. Adhesive particles X are effective against mosquitoes that are stuck on the surface of the wall surface, floor surface, structure, etc. in the treatment space, knock down or kill them, or try to stop at these places. Play and drive out of the processing space. On the other hand, the floating particles Y can knock down or kill mosquitoes flying in the treatment space, and also have an effect on mosquitoes trying to invade the treatment space, and enter the treatment space. Suppress the invasion of. The pest control effect of the adhesive particles X and the floating particles Y as described above lasts for a long time of 20 hours or more in a space of 33 m ³ or less. After the lapse of a predetermined time, the aerosol stock solution can be sprayed into the treatment space again to knock down or kill the mosquitoes.

As described above, the mosquito control aerosol according to the present invention has a duration of the pest control component of 33 m ³ or less for 20 hours or more, which is approximately one day. Therefore, if the mosquito control method is carried out using this mosquito control aerosol, the operation can be completed only by executing the injection step of injecting once a day at a fixed time every day. In this way, anyone can easily inject the aerosol stock solution into the treatment space, and it is possible to prevent the injection timing from being missed.

In order to confirm the mosquito control effect of the mosquito control aerosol of the present invention, a plurality of mosquito control aerosols (Examples 1 to 10) having the characteristic configuration of the present invention were prepared and the mosquito control effect was confirmed. The test was carried out. For comparison, an aerosol for controlling mosquitoes (Comparative Examples 1 and 2) not having the characteristic composition of the present invention was prepared, and a similar mosquito control effect confirmation test was conducted.

As shown in Table 1 as Examples 1 to 10, mosquito control aerosols were prepared according to each example in composition and conditions, and the tests shown below were performed. For Comparative Examples 1 and 2, mosquito control aerosols were prepared according to the compositions and conditions shown in Table 1, and the same tests as in Examples were performed. The test results are shown in Table 2.
(1) 25 m the aerosol mosquitoes control injected once obliquely upward with respect to the central room 25 m ³ was completely closed control effect mosquitoes in ³ rooms, this immediately emit Fifty Culex females After exposure for 2 hours, all test mosquitoes were collected. During that time, the female adults of Akai-eka that fell and turned over with the passage of time were counted, and the KT ₅₀ value was calculated. Then, in the same room, the same operation was performed 10 hours, 14 hours, and 20 hours after the mosquito control aerosol was sprayed once.
(2) Residual rate of suspended particles in air A mosquito control aerosol was sprayed diagonally upward once toward the center of a closed 25 m ³ room. An air collection tube (glass tube filled with silica gel and both ends filled with absorbent cotton) is installed 50 cm behind the center of the room (130 cm from the wall surface) and 120 cm above the floor, and is connected to a vacuum pump for injection processing. After 2 hours had passed, a predetermined amount of air was sucked. The air collection tube was washed with acetone, and the amount of the collected pest control component was analyzed by gas chromatography (manufactured by Shimadzu Corporation, model GC1700). Based on the obtained analytical values, the air concentration of the pest control component was calculated, and the ratio to the theoretical air concentration was determined as the air residual rate.

From the results in Tables 1 and 2, when metoflutrin and / or transfluthrin was used as the pest control component (Examples 1 to 7, 9, 10), the mosquito control aerosol was sprayed once. It was found that the KT ₅₀ value was maintained at a significant value even after 20 hours and showed an excellent control effect. The control effect was also excellent for transfluthrin supplemented with a small amount of profluthrin (Example 8). Further, as an organic solvent to be combined with the pest control component, a higher fatty acid ester having a total number of carbon atoms of 16 to 20 such as isopropyl myristate and a lower alcohol having a carbon number of about 2 to 3 such as ethanol are effective. It turned out. On the other hand, in Comparative Examples 1 and 2, the KT ₅₀ value was inferior to that of Examples 10 hours after the injection of the mosquito control aerosol once, and after 14 hours, the KT ₅₀ value was inferior. It showed even worse results. Then, after 20 hours, it was shown that the control effect on the adult female mosquitoes was almost extinguished in all the comparative examples.

Next, a test was conducted to confirm the mosquito control effect of the mosquito control aerosol of the present invention for mosquitoes different from Examples 1 to 10. This test is referred to as Example 11.
In Example 11, the pest control component metoflutrin was dissolved in the organic solvent isopropyl palmitate to prepare an aerosol stock solution of 36.0% by weight of metoflutrin. 4.0 mL of this aerosol stock solution and 16.0 mL of liquefied petroleum gas as a propellant were pressurized and filled in an aerosol container with a fixed-quantity injection valve to obtain the aerosol for controlling mosquitoes of the present invention. The volume ratio (a / b) of the aerosol stock solution (a) and the propellant (b) was adjusted to be 20/80. Then, in a 6-mat room (about 25 m ³ ) having a ceiling height of 2.5 m in which the above-mentioned mosquito control aerosol was substantially sealed, 0.1 mL of the aerosol stock solution was sprayed slightly diagonally upward. At this time, the spraying force (25 ° C.) of the mosquito control aerosol at a spraying distance of 20 cm was 1.4 g · f. The 90% particle diameter of the adhesive particles formed by the aerosol stock solution in the volume integration distribution at 25 ° C. and an injection distance of 15 cm was 42 μm.

Immediately after injecting the mosquito control aerosol of Example 11, chironomids were released into this room, and the chironomids were immediately knocked down or killed. Moreover, when the residual rate in the air of the pest control component (methoflutrin) was determined by the same method as in Examples 1 to 10, it was 0.93%.

From the test results of Examples 1 to 11, according to the mosquito control aerosol of the present invention and the mosquito control method using the same, it exceeds 20 hours for a space of at least 25 m ³ (equivalent to about 6 tatami mats). It was clarified that it exerts an excellent control effect on mosquitoes for a long time. It was confirmed that the mosquito control aerosol of the present invention exerts a mosquito control effect for 20 hours or more even if the space volume to be treated is expanded to 33 m ³ (equivalent to about 8 tatami mats). In addition, when a similar control effect confirmation test was conducted for flying pests other than mosquitoes, a control effect of 4 hours or more was shown for flies in a space of 33 m ³ or less, which is extremely practical. It turned out to be. Furthermore, a secondary effect of repelling crawling pests such as cockroaches, ants and beetles was also confirmed.

According to the present invention, it is possible to provide an aerosol for controlling mosquitoes having a high control effect on mosquitoes, and a mosquito control method using the aerosol.

X Adhesive particles Y Floating particles

Claims (6)

An aerosol stock solution containing a pest control component and a higher fatty acid ester having a total number of carbon atoms of 16 to 20 as an organic solvent, a pressure-resistant container provided with a fixed-quantity injection valve containing a propellant, and a pressure-resistant container.
An injection button provided with an injection port connected to the fixed-quantity injection valve,
It is a mosquito control aerosol equipped with
The injection capacity when the injection button is pressed once is adjusted to 0.1 to 0.4 mL, and the injection force at an injection distance of 20 cm is adjusted to be 0.3 to 10.0 g · f at 25 ° C.
The aerosol stock solution is ejected from the injection port as adherent particles adhering to the exposed portion in the treatment space, and the adherent particles have a 90% particle diameter of 20 in a volume integration distribution at 25 ° C. and an injection distance of 15 cm. ~ 80 μm,
When the aerosol stock solution is sprayed once into the treatment space, the spray amount of the pest control component is adjusted to 5.0 to 30 mg per 4.5 to 8 tatami mats.
When the aerosol stock solution is sprayed once into the treatment space, the effect duration of the pest control component is 20 hours or more for a space of 33 m ³ or less. The mosquito control according to claim 1 , wherein the volume ratio (a / b) of the aerosol stock solution (a) and the propellant (b) sealed in the pressure-resistant container is 10/90 to 50/50. aerosol. The mosquito control aerosol according to claim 1 or 2 , wherein the pest control component has a vapor pressure of 2 × 10 ^-4 to 1 × 10 ^-2 mmHg at 30 ° C. The mosquito control aerosol according to any one of claims 1 to 3 , wherein the injection port has a injection port diameter of 0.2 to 1.0 mm. A mosquito control method for knocking down or killing mosquitoes by injecting the aerosol stock solution into a treatment space using the mosquito control aerosol according to any one of claims 1 to 4 . The mosquito control method according to claim 5 , wherein the spray of the aerosol stock solution into the treatment space is executed once every 24 hours.

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