JP6850930B1 - Solution pesticide - Google Patents

Abstract

PROBLEM TO BE SOLVED: To decompose a carcass of a pest left after extermination while exerting an insecticidal effect. SOLUTION: The solution-type insecticide 100 is alkaline with pH 11.5 added to purified water 1, titanium oxide (TiO2) which is a photocatalyst 3, and 5.5% by weight based on the total amount of the insecticide. It contains electrolyzed water 2. The alkaline electrolyzed water 2 exerts an insecticidal action on the pests sprayed with the insecticide. Titanium oxide (photocatalyst 3) exerts a sterilizing and antibacterial action on substances that attract pests and propagate pests when irradiated with ultraviolet rays. The titanium oxide (photocatalyst 3) decomposes dead pests exterminated by alkaline electrolyzed water 2 when irradiated with ultraviolet rays. [Selection diagram] Fig. 1

Description

The present invention relates to a solution pesticide.

In the warm season, various pests such as gypsum flies may gather or spring up in the home due to food residues and their odors.
As a familiar analogy, Drosophila and flies, which are generally called "kobae", are not enough to carry pathogens, but they gather in foods, spawn, and spawn in large numbers at once.
In addition, flies are pests that are considered to be a problem in terms of hygiene because they are also generated from animal excrement.

Pyrethroid compounds are a typical example of substances used as insecticidal components against pests.
For example, in the technique of Patent Document 1 described later, a kerosene sparingly soluble pyrethroid compound is used as an insecticidal component, and the solubilizing agent is an aerosol agent containing N, N-diethyl-m-toluamide, which is an aromatic amide compound. Is used.
However, it is difficult to say that such an insecticidal component is sufficiently safe and sound for humans, and it is generally accepted that it is painful to be in the space actually used.

Further, Patent Document 2 discloses that a combustion chamber provided with a mixed gas injection nozzle for oxygen and hydrogen, an ignition device, and a rod-shaped or linear gold supply device is provided inside a high-pressure water storage tank.
In the technique of the same document 2, gold vapor is generated by igniting a mixed gas injection nozzle of oxygen and hydrogen by an ignition device in this combustion chamber to dissolve and evaporate the raw material gold.
After that, "high-performance water containing gold ultrafine particles" is generated by a manufacturing method using a device having a very unique structure in which ultrafine gold particles generated by contacting the generated gold vapor with high-pressure water are suspended and dispersed in water. To do.
From the configuration of Document 2, it is possible to obtain "high-performance water containing ultrafine gold particles" in which ultrafine gold particles are suspended and dispersed in pure water generated by mixing oxygen and hydrogen.
Patent Document 2 suggests that such high-performance water containing "ultrafine gold particles" also has an effect as a pest repellent (paragraph 7 of the same document 2).
According to Patent Document 2, the only component contained in pure water is ultrafine particles of gold that are suspended and dispersed. Therefore, if the highly functional water of Document 2 is used as a pest repellent component, it is safe for the human body. It is considered to be secured.

Japanese Unexamined Patent Publication No. 2005-306753 Japanese Unexamined Patent Publication No. 2008-214755

When pests are exterminated using pesticides, some of the carcasses may remain where they were exterminated.
Although conventional insecticides such as those exemplified in Patent Documents 1 and 2 have an insecticidal effect, they can be decomposed when a part of the dead body of the pest remains after extermination. Not considered.
It is not only psychologically unpleasant to have carcasses of pests of such a small size that it is difficult for pesticide users to notice, but they are also taken orally by some means, especially in infants. I'm even afraid.
In addition, it may attract new pests that live on those carcasses, which is not preferable.
Furthermore, since bacteria may be attached to the bodies of these pests, it is hard to say that it is a hygienic condition that some of the fine carcasses are left as they are after extermination.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a solution-type insecticide capable of exhibiting an insecticidal effect and decomposing a carcass of a pest left after extermination.

[First invention]
Therefore, in order to solve the above-mentioned problems, the solution-type insecticide according to the first invention of the present application is used.
It is a solution-type insecticide that can exert sterilizing and antibacterial effects while exerting an insecticidal action.
With purified water
Titanium oxide (TiO ₂ ), which is a photocatalyst,
Alkaline electrolyzed water with a pH of 11.5 added in an amount of 5.5% by weight based on the total amount of the pesticide in the form of a solution.
Including,

(1) Alkaline electrolyzed water exerts an insecticidal action on pests sprayed with this insecticide.
(2) Titanium oxide exerts a bactericidal and antibacterial effect on substances that attract pests and propagate pests when irradiated with ultraviolet rays.
(3) The titanium oxide was configured to decompose the carcasses of pests exterminated by alkaline electrolyzed water when irradiated with ultraviolet rays.

According to the first invention, (1) insecticidal action by alkaline electrolyzed water, (2) sterilization / antibacterial action by titanium oxide against substances (food residues, etc.) that attract insects or propagate insects, and (3). ) It also has a decomposing effect on the dead pests that have been exterminated.
Therefore, when the solution of this insecticide is sprayed, (1) the sprayed insects are killed, and (2) the causative substances (food residue and other kitchen waste, etc.) that the insects gather are sterilized. Antibacterial treatment can also be applied at the same time.

Furthermore, when titanium oxide (photocatalyst) is irradiated with ultraviolet rays, holes are generated on the surface of the photocatalyst (titanium oxide), and these holes oxidize the adsorbed water on the surface of the photocatalyst to generate hydroxyl radicals (radical OH). ..
Hydroxy hydroxyl radicals have the highest reactivity and the strongest oxidizing power among active oxygen, so they react with all substances such as sugars, proteins, and lipids.
Therefore, the hydroxyl radical decomposes the organic matter adsorbed on the surface of titanium oxide (photocatalyst) into water and carbon dioxide.

The decomposition action of this hydroxyl radical is extremely strong, and even a carcass of an insect (originally composed of an organic substance) is finally decomposed into carbon dioxide.
Therefore, according to the first invention, (3) even if a part of the carcasses of the pests exterminated by the insecticide remains in the place where the extermination was performed, the effect of titanium oxide (photocatalyst) causes the said. The corpse is disassembled.
Furthermore, although various bacteria are lurking in the carcasses of insects, titanium oxide (photocatalyst) is indistinguishable from the carcasses of insects and can exert a decomposing action on these bacteria as well.

As the photocatalyst mixed in the present solution pesticide, "iron ion or copper ion" may be added together with titanium oxide in order to enhance the catalytic action in the visible light region.

Further, in many general insecticides on the market, an air spray bottle is filled with an insecticidal component together with a gas and sprayed as a gas.
When such a gaseous insecticide is sprayed on the pest to be exterminated, the gas after the spray spray diffuses into the air, and the user is likely to inhale the insecticidal component.
However, according to the first invention, water having a low viscosity (purified water or alkaline electrolyzed water) occupies most of the components, and is a solution-like insecticide.
Therefore, even when the solution-type insecticide of the first invention is sprayed with a spray bottle, the droplets are only sprayed in the form of mist, so that the diffusion range in the air is much larger than that of the gaseous insecticide. It is narrow.
Therefore, when the solution-type insecticide of the first invention is used, the risk of the user inhaling the insecticide of the present application through the nostrils or the oral cavity can be significantly reduced as compared with the gaseous insecticide.
Further, in the solution pesticide of the first invention, "titanium oxide used as a food additive" is adopted as an antibacterial component in addition to a component harmless to the human body such as purified water and alkaline electrolyzed water.
Therefore, even if the user accidentally inhales the insecticide when using the solution-type insecticide, high safety is ensured.

[Second invention]
Further, in order to solve the above-mentioned problems, the solution-type insecticide according to the second invention of the present application is used.
The composition further contained sodium hydrogen carbonate (NaHCO _3).

According to the second invention, the deodorizing effect of sodium hydrogen carbonate on the acidic odor can be expected to have the effect of alleviating these odors when the insecticide is sprayed on food residues and the like.

[Third invention]
Further, in order to solve the above-mentioned problems, the solution-type insecticide according to the third invention of the present application is used.
The composition further contains herbs and other plant-derived aromatic components.

According to the third invention, when the pesticide is sprayed on a causative substance that attracts pests due to herbs and other plant-derived aromatic components, a repellent effect against pests can be expected.
As the aroma component derived from the plant as described above, natural essential oils such as citronella oil, lemon eucalyptus oil, lemongrass oil, orange oil, and cassia oil can be adopted as well as herb oil.
In addition, these plant-derived aromatic components also have the effect of alleviating the odor of kitchen waste such as food residues.

It is a schematic diagram which shows the composition of the solution type insecticide which concerns on embodiment of this invention.

Hereinafter, the solution-type insecticide of the present invention will be described with reference to FIG.
[Embodiment]
Embodiments of the present invention exert an insecticidal action on pests such as Drosophila, and at the same time, exert a sterilizing / antibacterial action on causative substances (food residues, etc.) that attract pests, and a decomposing action on dead pests. This is an example in which a solution-type insecticide 100 is constructed as an object.

FIG. 1 is a schematic view showing the composition of the solution-type insecticide 100 according to the present embodiment.
The solution-type insecticide 100 shown in FIG. 1 contains purified water 1, alkaline electrolyzed water 2, and titanium oxide (TiO2), which is a photocatalyst 3.
In this example, iron ions or copper ions may be added together with titanium oxide in order to further enhance the "catalysis in the visible light region" of the photocatalyst 3.

The present solution-type insecticide 100 is prepared "without containing any special insecticidal component, sterilizing / antibacterial component" other than these components 1 to 3.
Therefore, the method for producing the pesticide 100 is very simple, and it is only necessary to mix these components 1 to 3.
In addition, since the manufacturing process is extremely simple, it is possible to control the manufacturing cost and the selling price in the market.
The crystal structure of titanium oxide 3 is not limited to the most stable rutile type (tetragonal crystal), and may be anatase type (tetragonal crystal) or brookite type (orthorhombic crystal).
When adding titanium oxide 3 to the pesticide 100, titanium oxide 3 processed into powder in advance may be dissolved in a mixture of purified water 1 and alkaline electrolyzed water 2.

Purified water 1 is water produced from normal water by using ion exchange, distillation, reverse osmosis, and ultrafiltration individually or in combination.
The purified water 1 used in the solution-type insecticide 100 of the present invention has no significant effect even if various germs are mixed in with general purified water (used for cleaning solvents for scientific experiments, contact lenses, medical instruments, etc.). Water used for the purpose) is sufficient.
The solution-type insecticide 100 is sprayed on a causative substance (food residue, etc.) at which pests gather in light of its intended use, and the fact that it is purified to high purity means that it is purified with respect to the solvent (purified water 1). This is because it is not required.

Next, the alkaline electrolyzed water 2 will be described.
The alkaline electrolyzed water 2 is electrolyzed water obtained on the negative electrode side when salt is added to tap water and electrolyzed.
Alkaline electrolyzed water 2 is generally used for washing cooking utensils and the like because it has an ability to dissolve proteins and an ability to emulsify fats and oils.

Of the alkaline electrolyzed water, those having a pH (power of hydrogen: hydrogen ion concentration index) value in the range of pH 9 to 10 are considered to be drinkable.
However, in the solution-type insecticide 100 of the present application, the alkaline ^{activity of hydrogen ions (H +} ) (almost equal to the hydrogen ion concentration) is low at "pH 11.5", which is about several tens of times higher than the drinkable range. Electrolyzed water 2 is used.

In Patent Document 2 described above, "high-performance water containing ultrafine gold particles" (water in which ultrafine gold particles are suspended and dispersed in pure water generated by mixing oxygen and hydrogen) can be drunk as it is. It is disclosed that the same functional water can also be used as a pest repellent (see the second and seventh paragraphs of the same document).
In this respect, the present invention is based on a technical viewpoint different from that of Patent Document 2 in that "alkaline electrolyzed water" is used to exert an insecticidal effect.
Further, in the solution-type insecticide 100 of the present application, out of the "alkaline" electrolyzed water, it is out of the drinkable range (pH 9 to 10), and the "alkaline" of pH 11.5 that a remarkable insecticidal effect can be obtained. We are focusing on electrolyzed water.

In the solution-type insecticide 100 of the present invention, alkaline electrolyzed water 2 having a pH of 11.5 is added in an amount equivalent to "5.5% by weight" with respect to the total amount of the liquid insecticide 100.
This alkaline electrolyzed water 2 showing extremely strong alkalinity brings about a very effective insecticidal effect against pests.

The inventor of the present application has repeatedly tried to confirm the insecticidal effect by using purified water 1 containing only 5.5% by weight of alkaline electrolyzed water 2 having a pH of 11.5.
Therefore, in order to spray the pests with "purified water containing 5.5% by weight of alkaline electrolyzed water having a pH of 11.5" (not containing the photocatalyst 3), the above-mentioned predetermined amount (5.5% by weight%) is sprayed. ), Purified water 1 containing alkaline electrolyzed water 2 was filled in a liquid spray bottle.
The liquid spray bottle used in the trial has a discharge rate of 0.14 ml each time the pump is pressed, and the particle size of the droplets discharged from the spray port is about 20 to 30 microns.

According to the above trial, a minimum of 5 sprays (14 at a maximum, 7 times on average), that is, a minimum amount of about 0.7 ml (0.14 ml × 5) in terms of liquid volume, "stink bug" "Lethal effect on" was confirmed.

In addition, according to the above trial, the "lethal effect on Drosophila" was confirmed with an average of two sprays, that is, an amount of about 0.3 ml (0.14 ml x 2) in terms of liquid volume. It was.

As described above, conventionally, alkaline electrolyzed water has attracted attention only for its ability to dissolve proteins and emulsify fats and oils, and its general use has been limited to cleaning cooking utensils and the like.
Therefore, it seems that no attempt has been made in the past to use "alkaline" electrolyzed water for the purpose of killing insects.
Therefore, it is considered that the "invention of use" called "insecticide using alkaline electrolyzed water" was made by the trial to confirm the repellent effect this time.

Next, the photocatalyst 3 will be described.
The photocatalyst 3 used in the solution-type insecticide 100 of the present application is titanium oxide (TiO ₂ ), which exerts a strong redox action and a superhydrophilic action.
Titanium oxide (TiO ₂ ) is inexpensive, has excellent chemical stability, has high photocatalytic activity (organic compound degradability, antibacterial and antiviral properties, etc.), and is harmless to the human body. Widely used.

The principle that the photocatalyst 3 exerts an antibacterial action will be described below.
Titanium oxide (TiO ₂ ) having photocatalytic activity generally absorbs light having energy corresponding to the band gap between the valence band and the conduction band, and the electrons existing in the valence band become the conduction band. Transition to.
The electrons that have transitioned from the valence band to the conduction band have the property of moving to the substance adsorbed on the surface of titanium oxide.
Therefore, the substance adsorbed on the surface of titanium oxide is reduced by the electrons.
Further, the electrons transitioning from the valence band to the conduction band generate superoxide anions (oxygen molecules having one unpaired electron) when oxygen in the air is reduced.

On the other hand, when the electrons existing in the valence band transition to the conduction band, holes are generated in the valence band.
The holes generated in the valence band have the property of taking electrons from the substance adsorbed on the surface of _{titanium oxide (TiO 2).}
Therefore, the substance adsorbed on the surface of titanium oxide is oxidized by being deprived of electrons by holes.
Further, when the holes generated in the valence band oxidize the adsorbed water on the surface of the photocatalyst 3, hydroxyl radicals (radical OH) are generated.

Next, the action of the solution-type insecticide 100 according to the present embodiment will be described.

In the present solution-type insecticide 100, the alkaline electrolyzed water 2 brings about an "insecticidal effect on pests".
This is because the inventor of the present application newly found that alkaline electrolyzed water, which is generally used for cleaning kitchen utensils, "also has an insecticidal effect on pests" based on a two-month trial experiment. It was discovered.
The insecticidal effect of this alkaline electrolyzed water 2 on pests was confirmed with extremely high reproducibility.
As described above, the subjects of the experiment in which the inventor of the present application actually tested the insecticidal effect are Drosophila and stink bugs.

In addition, when titanium oxide (TiO ₂ ), which is a photocatalyst 3, is irradiated with ultraviolet rays, it has an antibacterial effect against substances (food residues, etc.) that attract pests and propagate pests.
The light energy (energy corresponding to the band gap between the valence band and the conduction band) required to excite titanium oxide (TiO _{2) is said to be 3.2 electron volt to 3.3 electron volt.} ..
This energy corresponds to a wavelength of about 380 nm when converted based on the proportional relationship between the energy quantum and the frequency, and is included in the near-ultraviolet region (wavelength 200 to 380 nm).

As described above, when the titanium oxide (photocatalyst 3) is irradiated with ultraviolet rays, holes are generated on the surface of the photocatalyst 3, and these holes oxidize the adsorbed water on the surface of the photocatalyst 3 to produce hydroxyl radicals (radical OH). To generate.
Hydroxy hydroxyl radicals have the highest reactivity and the strongest oxidizing power among active oxygen, so they react with all substances such as sugars, proteins, and lipids.
Therefore, the hydroxyl radical decomposes the organic matter adsorbed on the surface of titanium oxide (photocatalyst 3) into water and carbon dioxide.
That is, when the photocatalyst 3 is irradiated with near-ultraviolet rays, it absorbs the light energy of the near-ultraviolet rays and decomposes organic substances and the like adsorbed on the surface of the photocatalyst 3, so that it has "oxidative decomposition action" and "antibacterial action". Express.
In this example, in order to improve the catalytic performance of the photocatalyst 3 in the visible light region, not only titanium oxide alone is used as the photocatalyst 3, but also iron ions and copper ions are added together with titanium oxide to form the photocatalyst 3. Good.

As described above, according to the solution-type insecticide 100 according to the present embodiment, (1) insecticidal action against pests and (2) sterilization / antibacterial function against causative substances in which pests flock can be compatible and coexist. ..

In particular, when the solution-type insecticide 100 is sprayed on a causative substance that attracts pests such as food residues in order to exterminate (kill) the pests, the photocatalyst 3 is generated by the sunlight containing ultraviolet rays hitting the agent 100. Titanium oxide (TiO2) exerts a sterilizing and antibacterial effect on the causative substance.
As a result, it is possible to simultaneously perform an insecticidal action (function by alkaline electrolyzed water) and a sterilization / antibacterial action (function by photocatalyst) on a causative substance that attracts pests.
It should be noted that, like the solution-type insecticide 100, exerting the insecticidal effect as well as the sterilizing and antibacterial effect on the causative substance by irradiation with sunlight (ultraviolet rays) simultaneously causes a chain of secondary reproduction of pests. It is thought that it will also lead to cutting off.

Further, according to the present embodiment, (3) even if a part of the carcass of the pest exterminated by the insecticide remains in the place where the extermination was performed, the carcass is due to the effect of titanium oxide (photocatalyst 3). The rest of is decomposed to carbon dioxide.
In addition, although various bacteria are lurking in the carcasses of insects, titanium oxide (photocatalyst 3) is indistinguishable from the carcasses of insects and exerts a decomposing effect on these bacteria as well.

Further, in the solution-type insecticide 100 of the present embodiment, water having a low viscosity (purified water or alkaline electrolyzed water) occupies most of the components, and is formed in a solution form.
Therefore, even when the solution-type insecticide 100 is sprayed with a spray bottle, the droplets are only sprayed in the form of mist, and the diffusion range in the air is significantly narrower than that of the gaseous insecticide.
Therefore, when the solution-type insecticide 100 is sprayed, the risk of the user inhaling the agent 100 through the nostrils or the oral cavity can be significantly suppressed.

Further, in the present solution pesticide 100, titanium oxide (photocatalyst 3) used as a food additive is adopted as an antibacterial component in addition to components harmless to the human body such as purified water 1 and alkaline electrolyzed water 2. ..
Therefore, even if the user accidentally inhales the solution-type insecticide 100 through the nostrils / oral cavity, the safety is maintained.

[Modification example: Add sodium hydrogen carbonate (NaHCO ₃ )]
The solution-type insecticide 100 _{may further contain sodium hydrogen carbonate (NaHCO 3} ) (so-called baking soda).
By doing so, the deodorizing effect of sodium hydrogen carbonate on the acidic odor reduces the odor of the causative substance when the insecticide 100 is sprayed on the causative substance (food residue, etc.) where the pests gather. You can expect the effect of
Sodium hydrogen carbonate (NaHCO ₃ ) is in the form of a white powder at room temperature, and the pH of the aqueous solution is slightly alkaline.

[Modification example: Add plant-derived aromatic components]
The solution-type insecticide 100 may further contain herbs and other plant-derived aromatic components.
By doing so, when the pesticide 100 is sprayed on a causative substance that attracts pests due to a plant-derived aromatic component, a repellent effect against pests can be expected.
As the above-mentioned plant-derived aromatic component, natural essential oils such as citronella oil, lemon eucalyptus oil, lemongrass oil, orange oil, and cassia oil can be adopted as well as herb oil.
In addition, these plant-derived aromatic components also have the effect of alleviating the odor of the causative substance in which pests gather.

Although the present invention has been described above with reference to the embodiments, the present invention is not limited to the above embodiments. Various modifications that can be understood by those skilled in the art can be made to the structure and details of the present invention without departing from the gist of the present invention.

1 Purified water 2 Alkaline electrolyzed water 3 Photocatalyst 100 Solution pesticide

Claims (3)

It is a solution-type insecticide that has an insecticidal effect on Drosophila and stink bugs, and also has a bactericidal and antibacterial effect.

With purified water
Titanium oxide (TiO ₂ ), which is a photocatalyst,
Alkaline electrolyzed water with a pH of 11.5 added in an amount of 5.5% by weight based on the total amount of the pesticide in the form of a solution.
Including,

(1) Alkaline electrolyzed water exerts an insecticidal action on Drosophila and stink bugs sprayed with this insecticide.
(2) Titanium oxide attracts Drosophila and stink bugs when irradiated with ultraviolet rays, and exerts a bactericidal and antibacterial effect on the causative substances in which Drosophila and stink bugs propagate.
(3) Titanium oxide is a solution-type insecticide characterized in that it is configured to decompose carcasses of Drosophila and stink bugs that have been exterminated by alkaline electrolyzed water when irradiated with ultraviolet rays.
In the solution-type insecticide according to claim 1,
A solution pesticide characterized by being configured to further contain sodium bicarbonate (NaHCO _3).
In the solution-type insecticide according to claim 1,
Characterized in that it is configured to further include an aromatic herbal ingredients - derived solutions like insecticides.

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