JP2009143868A - Method for exterminating crawling pest - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a new method for exterminating crawling pests which exhibits a sufficient exterminating effect to crawling pests with a smaller amount of drugs than when conventional whole amount-spray type aerosol or a smoking agent is used. <P>SOLUTION: The method for exterminating crawling pests comprises exterminating crawling pests by atomizing an insecticide liquid containing an insecticide component and a solvent into spaces such as room spaces and storage spaces. A compound having a specific structure is used for the solvent. The insecticide liquid is transpired over a long time using a piezo type sprayer and keeping the amount of transpiration of the insecticide liquid per a unit of time low so that the fine particles of the insecticide liquid continue to stay floating in the spaces. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a method for controlling insects such as cockroaches and ticks.

In general, insect pests such as cockroaches have low sensitivity to drugs and are not easily exterminated. Therefore, in order to effectively control these pests, it is necessary to select and use an optimal drug from many drugs in consideration of use conditions and the like.
However, many of the drugs that are effective against insect pests have a low vapor pressure, so the transpiration and diffusibility of the drugs in the use space are weak. It has been used as a smoke agent (see Patent Document 2). In the case of such an all-injection aerosol or smoke agent, a method of use is generally employed in which the drug is diffused all at once and the room is ventilated after the space is sealed for a certain period of time.

JP 2002-309242 A JP-A-11-246306

In the case of the above-described all-injection aerosol, since the drug particles diffused into the space are relatively large, many of them fall to the floor surface. For this reason, it acts on pests that wrinkle the floor surface and exerts its effect. On the other hand, when the pests are repelled and lurking in the gap, the drug particles are difficult to reach and tend not to exert the effect. Therefore, it was necessary to use a relatively large amount of the medicine so that the medicine can reach the gap in the indoor space with the all-injection aerosol.
On the other hand, in the case of the smoke agent described above, since the drug particles dissipated in the space are relatively small, most of them will float in the space. Since the drug particles having a small particle diameter and drifting in the space are easy to enter the gap, the smoke agent can be expected to be highly effective against pests lurking in the gap. However, on the other hand, drug particles are unlikely to fall on the floor surface, so they tend to be less effective for pests that rub the floor surface, and some of the drug particles floating in the space are naturally ventilated. In the case of a smoke agent, a relatively large amount of the drug is used in order to surely obtain the extermination effect.
Thus, according to conventional all-injection aerosols and smoke agents, more drugs are used than are thought to actually contribute to the pest control effect. It can be said that there is waste. In addition, it is desired that the amount of medicine used be reduced from the viewpoint of safety to the human body and the like.
Furthermore, all-injection aerosols and smoke agents are used to disperse the drug at once and increase the drug concentration in the indoor space for a predetermined time. There was a risk that fire alarms and gas alarms would malfunction.

  The present invention has been made in view of such a situation, and is a new agent that exerts a sufficient extermination effect against insect pests with a smaller amount of medicine than when a conventional all-injection aerosol or smoke agent is used. It is intended to provide a pest control method.

  As a result of intensive research to solve the above-mentioned problems, the present inventors do not disperse most of the used drug at once, as in the case of using a full-injection aerosol or smoke agent, but rather a piezo element. Using a piezo-type sprayer that atomizes a medicine (liquid) by ultrasonic vibration using, an insecticidal solution containing a compound with a specific structure as a solvent is gradually evaporated over a longer time than usual. Then, the insecticidal liquid particles with a small particle diameter will continue to float in the space, and by maintaining such a state for a long time, the drug is effectively used against pests that hang on the floor surface and pests that lurk in the gaps. The amount of drug used is significantly reduced compared to conventional all-injection aerosols and smoke agents (for example, 1/30 to 1/1 of the amount of drug used in all-injection aerosols) ), It was found to be able to efficiently combat crawling pests. In other words, the present inventors have overturned the conventional method of lethality before a pest escapes by exposing a large amount of drug at once, even if the drug amount is less than the lethal dose per unit time. They discovered a new finding that they can be effectively controlled by long-term exposure to pests. The present invention has been completed based on this finding.

That is, the present invention has the following configuration.
(I) A method of exterminating insect pests by evaporating an insecticidal solution containing an insecticidal component and a solvent into a space such as an indoor space or a storage space, wherein the solvent is represented by the following general formula (1) or (2) Using a compound having a structure such that the insecticidal liquid particles having a small particle size continue to float in the space, the pesticidal sprayer is used to reduce the amount of transpiration per unit time of the insecticidal liquid and reduce the amount of transpiration over the time. A method for controlling insect pests, characterized by evaporating the liquid.
R ¹ (—OCH ₂ CH ₂ ) _n —OR ² (1)
R ¹ (—OCH (CH ₃ ) CH ₂ ) _n —OR ² (2)
(In the formulas (1) and (2), n is an integer of 1 to 3, R ¹ and R ² are any one of H, CH ₃ , C ₂ H ₅ , and C (═O) CH ₃ , They may be the same or different, provided that R ¹ and R ² must not be H at the same time.)
(Ii) The method for controlling worms according to the above (i), wherein the transpiration time is 4 hours or more.
(Iii) The insect pest control method according to (i) or (ii), wherein an average particle diameter (D50) of the insecticidal liquid fine particles floating in the space is 1 to 15 μm.
(Iv) The method for controlling worms according to any one of (i) to (iii), wherein the worms are cockroaches.
In this specification, unless otherwise specified, the release of the insecticide (insecticide component and solvent) is referred to as “transpiration”, and the release of the insecticide component is referred to as “volatilization”.

  According to the present invention, it is possible to obtain a sufficient extermination effect against insect pests with a smaller amount of medicine than when a conventional full-injection aerosol or smoke agent is used. Further, according to the present invention, since the concentration of indoor smoke or fog does not temporarily increase, the problem that a fire alarm or a gas alarm malfunctions can be avoided. In addition, the extermination method of the present invention is a method that fully considers safety to the human body.

The insect pest control method of the present invention is a method for controlling insect pests by evaporating an insecticide containing an insecticide component and a solvent into a space such as an indoor space or a storage space.
The insecticidal component that can be used in the present invention is not particularly limited as long as the desired effect can be achieved, and is selected from various insecticidal components that are effective against cockroaches and mites such as mites. Can be used. For example, ciphenothrin, bifenthrin, transfluthrin, metfurthrin, profluthrin, empentrin, propoxl, methoxadiazone, amidoflumet, dinotefuran, hydroprene, methoprene and the like can be mentioned. Among these, cyphenothrin, propoxur, methoxadiazone, transfluthrin, methfluthrin, and profluthrin have good volatility (transpiration) when applied to a piezo nebulizer, have excellent disinfecting effects, and have solubility in preferred solvents described below. It is preferable because it is good. In addition, as an insecticidal component, only 1 type of the said compound may be used, and 2 or more types may be used together.

The solvent that can be used in the present invention is a compound having a structure represented by the following general formula (1) or (2).
R ¹ (—OCH ₂ CH ₂ ) _n —OR ² (1)
R ¹ (—OCH (CH ₃ ) CH ₂ ) _n —OR ² (2)
(In the formulas (1) and (2), n is an integer of 1 to 3, R ¹ and R ² are any one of H, CH ₃ , C ₂ H ₅ , and C (═O) CH ₃ , They may be the same or different, provided that R ¹ and R ² must not be H at the same time.)
By using the compound having the structure represented by the general formula (1) or (2) as a solvent, an excellent extermination effect can be obtained even with a small amount of drug, and the use efficiency of the drug (insecticidal component) can be improved. Can be increased. In addition, a solvent may use only 1 type and may use 2 or more types together.

  Specific examples of the compound having the structure represented by the general formula (1) or (2) include, for example, propylene glycol diacetate, ethylene glycol diacetate, diethylene glycol dimethyl ether, diethylene glycol diethyl ether, diethylene glycol ethyl methyl ether, and triethylene glycol. Dimethyl ether, propylene glycol monomethyl ether, propylene glycol methyl acetate, dipropylene glycol dimethyl ether, tripropylene glycol methyl acetate, ethylene glycol dimethyl ether, diethylene glycol monomethyl ether, diethylene glycol monoethyl ether, triethylene glycol monomethyl ether, propylene glycol monomethyl ether acetate Over DOO, dipropylene glycol monomethyl ether, and the like.

The insecticide that can be used in the present invention is obtained by dissolving the insecticide component in the solvent so as to have a concentration of 1 to 20% by mass, preferably 2 to 10% by mass.
In addition, the insecticide may contain additives such as a fragrance, a deodorant, a bactericide, a dye, a stabilizer, a volatilization regulator, an antiseptic, and an antioxidant as long as they do not impair the effects of the invention. It can also be contained.

  In the present invention, when the insecticide is evaporated, the insecticide is evaporated using a piezo-type sprayer while keeping the amount of evaporation per unit time of the insecticide small. In this way, instead of releasing the whole amount of the insecticide at a stroke as in the case of using a conventional all-injection type aerosol or smoke agent, the space is kept by evaporating a small amount of the insecticide over a long period of time. As a result, the insecticidal liquid fine particles having a small particle diameter continue to float, and as a result, an excellent insecticidal effect is exhibited, and the amount of medicine (insecticidal component) used can be greatly reduced.

  In the present invention, it is preferable that the amount of transpiration per unit time when the insecticidal solution is evaporated is always kept small, and depending on the concentration of the insecticidal component in the insecticidal solution, for example, transpiration from the start of transpiration. The average transpiration amount obtained by dividing the total transpiration amount until the end by the transpiration time is preferably 200 mg / hour or less, more preferably 8 to 100 mg / hour.

In the present invention, the volatilization amount of the insecticidal component per unit time is preferably 1 to 10 mg / hour, more preferably 2 to 5 mg / hour.
The amount of volatilization of the insecticidal component per unit time is measured, for example, by sucking the insecticidal solution evaporated from a piezo-type sprayer, collecting it with silica gel, and extracting and analyzing the insecticidal component from there. be able to.

  In the present invention, it is important to evaporate the insecticide over time. Specifically, the evaporation time when evaporating the insecticide is preferably 4 hours or more, more preferably It should be 8 hours or longer. The transpiration time is the total time required from the start of transpiration to the end of transpiration. For example, when the piezo-type sprayer is driven intermittently, the time from one spray to the next spray is also related. It shall be handled as the required time.

In the present invention, the average particle diameter (D50) of the insecticidal liquid fine particles floating in the space when the insecticidal liquid is evaporated is preferably 1 to 20 μm, more preferably 1 to 15 μm. If the average particle diameter of the insecticidal liquid fine particles is larger than the above range, it tends to fall on the floor surface, and it is difficult to float in the space for a long time.
In the present invention, the average particle diameter (D50) of the insecticidal liquid fine particles floating in the space means D50 (cumulative 50%) measured by the particle size distribution measuring device and analyzed by the automatic calculation processing device. Specifically, it can measure by the method as described in the Example mentioned later.

The piezoelectric sprayer used in the present invention is not particularly limited as long as the desired effect can be obtained. For example, various conventionally known piezoelectric sprayers can be employed.
When spraying the insecticidal solution using a piezo type sprayer, the insecticidal solution may be filled in a suitable container equipped with a liquid absorbing (liquid absorbing core or the like) and set in the piezo type sprayer. As a result, the insecticide is transmitted to the diaphragm via the liquid absorption, and can be evaporated into the space by the vibration of the diaphragm that has caused resonance with the piezoelectric element.

An example of a piezo-type sprayer that can be used in the present invention is shown in FIG.
A piezo-type sprayer shown in FIG. 1 includes a container 1 containing an insecticidal solution 2, a liquid absorbent core 3 whose upper part protrudes from the upper opening of the container 1 and whose lower part is immersed in the insecticidal liquid 2 in the container 1, and An ultrasonic vibrator 5 in contact with the upper end of the liquid core 3 and an ultrasonic oscillator 7 connected to the vibrator 5 are provided. A joining piece 6 made of metal, ceramic or the like is disposed between the upper end portion of the liquid absorbent core 3 and the vibrator 5, whereby the vibrator 5 is indirectly attached to the liquid absorbent core 3 (via the joint piece 6). ) Touching. Reference numeral 8 denotes a battery as a power source. The liquid absorbent core 3 is supported by a hollow disk type core support 4 fitted in the upper opening of the container 1.

  The liquid absorbent core 3 is made of a material having a large surface tension, such as felt, sponge, cotton, or a porous material (for example, a molded body mainly composed of carbonaceous fine powder and made of a mixture of this and a binder). A core material formed in a rod shape can be used. Of these, a molded body using carbonaceous fine powder is preferable because it exhibits a liquid absorbing function only when ultrasonic waves are applied and functions as a sealed plug when no voltage is applied.

  In the piezo-type sprayer shown in FIG. 1, a signal is sent from the oscillator 7 to the vibrator 5 in a state where the insecticide 2 is sufficiently absorbed to the upper end of the liquid absorbent core 3 as described above, and the vibrator 5 And the joining piece 6 is ultrasonically vibrated. As a result, ultrasonic vibration energy equal to or higher than the surface tension of the insecticidal liquid 2 and higher than the viscosity is applied to the upper end portion of the liquid absorbent core 3, and the insecticidal liquid 2 is fogged into the air as fine droplets from the liquid absorbent core 3. Can be evaporated. In the piezo-type sprayer, the vibrator 5 may be in direct contact with the upper end portion of the liquid absorbent core 3 without arranging the joining piece 6.

The piezo-type sprayer that can be used in the present invention is not limited to the piezo-type sprayer shown in FIG. 1 described above, and a piezo-type sprayer as shown in FIG. 2 can also be used.
A piezo-type sprayer shown in FIG. 2 includes a container 1 containing an insecticidal solution 2, a liquid absorbent core 3 whose upper part protrudes from the upper opening of the container 1 and whose lower part is immersed in the insecticidal liquid 2 in the container 1, and the absorbent core 3. An ultrasonic transducer 10 in contact with the upper end of the liquid core 3, a lid 11 fixed to the transducer 10 and fitted in the upper opening of the container 1, and an ultrasonic oscillator connected to the transducer 10 (not suitable) As shown).

  The liquid absorbent core 3 is supported by a hollow disk-shaped core support body 4 fitted in the upper opening of the container 1, and the vibrator 10 is attached to the lid portion 11 by the claw portion 12 and the fixing member 13 of the lid portion 11. It is fixed. The vibrator 10 has a diameter of 5 to 10 mm at the center. A joining piece 15 is disposed between the upper end portion of the liquid absorbent core 3 and the vibrator 10, whereby the vibrator 10 is in contact with the liquid absorbent core 3 indirectly (via the joint piece 15). As the joining piece 15, an orifice plate having a hole with a diameter of 3 to 20 μm at the center is used.

In the piezo-type sprayer shown in FIG. 2, the spray port 14 is provided in the lid portion 11, and the vibrator is driven from the oscillator in a state where the insecticide 2 is sufficiently absorbed up to the upper end of the liquid absorbent core 3. When a signal is sent to 10 and the vibrator 10 is ultrasonically vibrated, the insecticide 2 can be atomized into the air as fine droplets from the spray port 14 and evaporated. Although the vibrator 10 having a predetermined hole at the center has been described, a vibrator having a large number of holes on the entire surface can be used instead.
In addition, a piezo nebulizer as described in US Pat. No. 6,450,419 may be used.

In addition, the piezo-type sprayer that can be used in the present invention preferably has one or more of the following conditions (1) to (6), more preferably a sprayer that has all. .
(1) Do not use a blower.
(2) The frequency of the ultrasonic oscillator is 50 to 300 kHz.
(3) Intermittent transpiration in which driving for 5 milliseconds to 1 second and stopping for 1 to 180 seconds are alternately performed per time can be performed.
(4) The amount of the chemical solution that is evaporated by one driving is 0.01 to 1 μL.
(5) Power consumption in one driving is 0.3 to 10 W.
(6) Alkaline battery (LR20 (single 1), LR14 (single 2), LR6 (single 3), LR3 (single 4), LR1 (single 5)) or manganese battery (R20P (single 1), R14P (single 2) ), R6P (AA), R3P (AA), R1P (AA)).

  The driving conditions for the piezo-type sprayer are not particularly limited, and may be set as appropriate so that the transpiration time, the average particle diameter of the atomized insecticide fine particles, and the like are within the predetermined ranges described above.

  Examples of the insect pests that can be controlled in the present invention include cockroaches, ticks, fleas, lice, ants, cardworms, and geese, and the control method of the present invention is particularly effective against cockroaches.

EXAMPLES The present invention will be specifically described below with reference to examples, but the present invention is not limited to these examples.
In the following Examples and Comparative Examples, the average particle diameter (D50) of the insecticidal liquid fine particles floating or sprayed into the space was measured as follows.
That is, a laser light scattering particle size distribution measuring apparatus with an automatic arithmetic processing device (“LDSA-1400A” manufactured by East Japan Computer Applications Co., Ltd.) is used as a measuring device, and laser light is emitted at a position 30 mm above the vibrator of the piezo-type sprayer. The height was such that it hits, and the distance from the center of the sprayer to the lens of the detection camera of the measuring device was set to 300 mm, and measurement was performed.

(Example 1)
An insecticidal solution having a composition of 5% by mass of cyphenothrin, 2% by mass of propoxur, and 93% by mass of the solvent shown in Table 1 was prepared.
Each of the obtained insecticides was evaporated for 4 hours under the following driving conditions using a piezo-type sprayer shown in FIG.
At this time, the same transpiration rate was always maintained from the start to the end of transpiration, and the initial weight of the insecticide at the start of transpiration and the remaining weight of the insecticide at the end of transpiration were measured. Then, the difference between the initial weight and the remaining weight was defined as the total transpiration amount, and a value obtained by dividing the total transpiration amount by the transpiration time (average transpiration amount) was obtained as the transpiration amount per unit time.
Further, the volatilization amount (actual volatilization amount) of the insecticidal components (cyphenothrin and propoxle) per unit time was measured by the following method.
These results are shown in Table 1.
In addition, the average particle diameter (D50) of the evaporated insecticidal liquid fine particles was about 3 μm when any solvent was used.

<Driving conditions for piezo sprayer>
・ Frequency of ultrasonic oscillator: 150 kHz
・ Driving conditions: intermittent driving for 10 seconds and stopping for 8 seconds ・ Amount of chemical solution: 0.02 μL of transpiration by one driving
・ Power consumption: 10W during oscillation
・ Battery: One LR6 (AA) (1.5V)

<Method of measuring volatilization amount of insecticidal components (cyphenothrin, propoxur) per unit time>
Volatilized vapor was collected by suction on a silica gel column for 4 hours (4 hours after the start of transpiration and stabilized), this silica gel column was extracted with acetone, concentrated, quantitatively analyzed with a gas chromatograph, and measured for each insecticidal component. The amount of volatilization was determined.

(Example 2)
An insecticidal solution was prepared with a composition of 3% by mass of ciphenothrin, 12% by mass of methoxadiazone, and 85% by mass of the solvent shown in Table 2.
Each of the obtained insecticides was evaporated for 4 hours using the same piezo-type sprayer and driving conditions as in Example 1.
At this time, the same transpiration rate was always maintained from the start to the end of transpiration, and the initial weight of the insecticide at the start of transpiration and the remaining weight of the insecticide at the end of transpiration were measured. And the amount of transpiration per unit time was calculated | required similarly to Example 1. FIG. Further, in the same manner as in Example 1, the measured volatilization amount of the insecticidal components (cyphenothrin and methoxadiazone) per unit time was measured. These results are shown in Table 2.
In addition, the average particle diameter (D50) of the evaporated insecticidal liquid fine particles was about 3 μm when any solvent was used.

(Example 3)
An insecticide was prepared with a composition of 5% by mass of bifenthrin and 95% by mass of the solvent shown in Table 3.
Each of the obtained insecticides was evaporated for 4 hours using the same piezo-type sprayer and driving conditions as in Example 1.
At this time, while maintaining the same transpiration rate from the start to the end of transpiration, the initial weight of the insecticide at the start of transpiration and the remaining weight of the insecticide at the end of transpiration were measured. And the amount of transpiration per unit time was calculated | required similarly to Example 1. FIG. Further, in the same manner as in Example 1, the measured volatilization amount of the insecticidal component (bifenthrin) per unit time was measured.
Further, after the volatilization amount was measured, while the insecticide was continuously evaporated for 15 hours, it was visually observed whether or not crystals were observed in the insecticide. These results are shown in Table 3. In addition, the average particle diameter (D50) of the transpirated insecticide fine particles was about 3 μm when any solvent was used.

Example 4
10 g of a mixture comprising 5% by mass of cyphenothrin and 2% by mass of propoxol as an insecticidal component and 93% by mass of propylene glycol diacetate as a solvent was prepared as an insecticidal solution, of which 85 mg was evaporated in the following test.

A slit box (slit) containing 10 adult black cockroaches (female) in one of the four corners near the maximum position of 4.5 tatami mats or 6 tatami mats from the center of the floor of a 24 tatami test room (without ventilation) Part: width 3 cm × height 10 cm), and a piezo-type sprayer shown in FIG. 2 containing the insecticide obtained above was installed in the center of the floor. Then, the insecticide was continuously evaporated for 8 hours under the following driving conditions (that is, the time (exposure time) for which black cockroaches were exposed to the insecticidal component was 8 hours).
At this time, while maintaining the same transpiration rate from the beginning to the end of transpiration, the initial weight of the insecticide at the start of transpiration and the residual weight of the insecticide at the end of transpiration are measured, and the difference between the initial weight and the remaining weight is the total amount of transpiration It was. Moreover, the amount of the insecticidal component contained in the total amount of transpiration was calculated from the concentration of the insecticidal solution, and this was used as the amount of drug used.

<Driving conditions for piezo sprayer>
・ Frequency of ultrasonic oscillator: 150 kHz
・ Driving conditions: intermittent driving for 10 seconds and stopping for 8 seconds ・ Amount of chemical solution: 0.02 μL of transpiration by one driving
・ Power consumption: 10W during oscillation
・ Battery: One LR6 (AA) (1.5V)

  Immediately after the transpiration, each cockroach was transferred to a clean cup containing absorbent cotton containing water. Then, the lethality of each cockroach after 48 hours was observed to determine the lethality. Table 4 shows the total amount of transpiration, the amount of drug used, and the mortality after 48 hours.

  In Example 4, the average particle size (D50) of the evaporated insecticide microparticles was measured and found to be 2.60 μm (minimum 2.31 μm to maximum 2.99 μm).

(Comparative Example 1)
Ethanol was added to 85 mg of the insecticide used in Example 4 (mixture consisting of 5% by mass of ciphenothrin and 2% by mass of propoxin as an insecticidal component and 93% by mass of propylene glycol diacetate as a solvent) to make 30 mL of insecticide. This insecticide was filled in a full-amount-injecting aerosol device (using “Earth Red Non-Smoke” manufactured by Earth Pharmaceutical Co., Ltd.) together with a propellant (70 mL of dimethyl ether).

A slit box (slit) containing 10 adult black cockroaches (female) in one of the four corners near the maximum position of 4.5 tatami mats or 6 tatami mats from the center of the floor of an 8 tatami test room (without ventilation) Part: width 3 cm × height 10 cm), and the above-mentioned full-injection aerosol apparatus was installed in the center of the floor.
The whole amount of the insecticide of the aerosol apparatus was sprayed in about 60 seconds and then left for 1 hour (that is, the time (exposure time) for which black cockroaches were exposed to the insecticidal component was about 1 hour).
In this case, since the entire amount filled in the aerosol device was jetted, the amount of drug used was 4.25 mg of cyphenothrin and 1.7 mg of propoxle.

  Immediately after being left for 1 hour, each cockroach was transferred to a clean cup containing absorbent cotton containing water. Then, the lethality of each cockroach after 48 hours was observed to determine the lethality. Table 4 shows the total amount of transpiration, the amount of drug used, and the mortality after 48 hours.

  In Comparative Example 1, as in Example 4, the average particle size (D50) of the evaporated fine particles of the insecticide was measured and found to be 20.5 μm (minimum 18.2 μm to maximum 23.2 μm). It was.

(Comparative Example 2)
According to the same operation as in Comparative Example 1, the entire amount of the insecticide was sprayed in a few seconds using a total amount spraying aerosol apparatus, and then left for 8 hours (that is, the time for the black cockroach to be exposed to the insecticidal component (exposure time). ) Was about 8 hours). The amount of drug used at this time is the same as in Comparative Example 1.

  Immediately after standing for 8 hours, each cockroach was transferred to a clean cup containing absorbent cotton containing water. Then, the lethality of each cockroach after 48 hours was observed to determine the lethality. Table 4 shows the total amount of transpiration, the amount of drug used, and the mortality after 48 hours.

From Table 4, Example 4 in which the pesticidal sprayer was used to evaporate the insecticide over a long period of time was less than Comparative Examples 1 and 2 in which the entire amount of the insecticide was sprayed at once using a full-amount spraying aerosol device. It is clear that the amount of drug used exhibits a remarkably excellent extermination effect.
In addition, it is comparative example 1 that when the entire amount of insecticide is sprayed at once using a full-injection type aerosol device, the extinguishing effect can be slightly improved by increasing the standing time (exposure time) after spraying on cockroaches. As can be seen from FIG. 2, even when the exposure time was set to 8 hours, which was the same as in Example 4, it became clear that the same extermination effect as in the example could not be obtained.

It is a schematic sectional drawing which shows an example of the piezo type sprayer which can be used in this invention. It is a schematic sectional drawing which shows another example of the piezoelectric atomizer which can be used in this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Container 2 Insecticide 3 Liquid absorption core 4 Core support body 5, 10 Ultrasonic vibrator 6 Joint piece 7 Ultrasonic oscillator 8 Battery 11 Lid part 12 Claw part 13 Fixing member 14 Spraying port 15 Joint piece

Claims (4)

It is a method for exterminating insect pests by evaporating an insecticide containing an insecticidal component and a solvent into a space such as an indoor space or a storage space,
As the solvent, a compound having a structure represented by the following general formula (1) or (2) is used,
R ¹ (—OCH ₂ CH ₂ ) _n —OR ² (1)
R ¹ (—OCH (CH ₃ ) CH ₂ ) _n —OR ² (2)
(In the formulas (1) and (2), n is an integer of 1 to 3, R ¹ and R ² are any one of H, CH ₃ , C ₂ H ₅ , and C (═O) CH ₃ , They may be the same or different, provided that R ¹ and R ² must not be H at the same time.)
The pesticidal solution is evaporated over time while suppressing the amount of transpiration per unit time of the insecticidal solution using a piezo-type sprayer so that the fine particles of the insecticidal solution having a small particle diameter continue to float in the space. How to control moth pests.   The method for controlling insect pests according to claim 1, wherein the transpiration time is 4 hours or more.   The insect pest control method according to claim 1 or 2, wherein an average particle diameter (D50) of the insecticidal liquid fine particles floating in the space is 1 to 15 µm.   The method according to claim 1, wherein the insect pest is a cockroach.

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