JP2021153561A - Insect proof net - Google Patents

Abstract

To provide an insect proof net which has less impact applied to an environment, and is excellent in an insect pest entry prevention effect.SOLUTION: There is provided an insect proof net obtained by adhering at least one kind of fatty acid ester of glycerin selected from the following group consisting of: at least one kind of fatty acid ester of glycerin including, glycerol caprylate, diglycerol caprylate, glycerol diacetomonocaprylate, glycerol diacetomonocaprate, triglycerol mono-dicaprylate, and triglycerol mono-dicaprylate, the fatty acid ester of glycerin including as a constituent fatty acid, capric acid and/or caprylic acid; at least one kind of fatty acid ester of glycerin including laurate as a constituent fatty acid and being selected from glycerin diacetomonolaurate and diglycerol laurate; and at least one kind of fatty acid ester of glycerin including oleate as a constituent fatty acid, and being selected from glycerol tri-olate, diglycerol mono-diolate, decaglycerol olate and glycerol diacetomonoolate.SELECTED DRAWING: None

Description

The present invention relates to an insect repellent net, and more particularly to an insect repellent net capable of preventing the invasion of an insect repellent net having a size that allows pests to pass through.

A warm climate is often required for the growth of plants such as crops and ornamental plants, and the outbreak of pests due to the warm climate, especially the outbreak of pests that transmit viral diseases, has become a major problem. Therefore, techniques have been developed to prevent pests from invading areas where plants grow, such as in greenhouses.

As the pest invasion prevention technology known so far, there are technologies such as an ultraviolet ray removing film, a light reflecting sheet, and a yellow adhesive sheet for attracting. These techniques have the effect of reducing the invasion of pests by about 30 to 70%. However, the intrusion prevention effect is affected by environmental factors and lacks stability. In addition to the above, a pest invasion prevention technique using an insect repellent net is also known, but there is a problem that it does not effectively act on pests having a size smaller than the mesh size of the insect repellent net.
Insect repellent nets with smaller meshes have been developed to solve this problem, but invasion of very small size pests such as Bemisia tabaci (body length about 1.0 mm, body width 0.4 mm). In order to prevent this, a very fine insect repellent net having a mesh size of less than 0.4 mm is required, and there is a problem that the manufacturing cost increases. In addition, the insect repellent net with such a small mesh has poor air permeability and causes the temperature inside the greenhouse to rise, so it is easy to induce the outbreak of pests, it becomes difficult to control the temperature, and the working environment of the farmer deteriorates. There is also the problem.

Therefore, a method of impregnating an insect repellent net having a mesh size of about 1 mm, which has been conventionally used, with an insecticide such as Etofenprox has been proposed (Patent Documents 1 and 2). However, this method is rarely used because the effect of the drug is low on micropests that have acquired drug resistance, such as Bemisia tabaci.

On the other hand, Non-Patent Document 1 describes that a machine oil emulsion is sprayed on an insect repellent net to prevent the invasion of Bemisia tabaci. Patent Document 3 discloses a winged pest repellent containing glycerin fatty acid ester, sorbitan fatty acid ester, sucrose fatty acid ester and the like as active ingredients. In Patent Document 4, oils and fats such as Sun Crystal (manufactured by Sankei Chemical Co., Ltd.) and Makupika (manufactured by Ishihara Bioscience Co., Ltd.) and / or a surfactant are sprayed on a 0.8 mm insect repellent net. , It is disclosed to prevent the invasion of Konajirami into the insect repellent net.

Japanese Patent Application Laid-Open No. 8-163950 Japanese Patent Application Laid-Open No. 2003-299434 WO2006 / 028170 JP 2011-16737

Prevention of Bemisia tabaci by spraying machine oil emulsion onto an insect repellent net with a mesh size of 1 mm Nine Disease Research Institute Bulletin 59: 64-71 (2013)

However, since the machine oil emulsion used in Non-Patent Document 1 contains mineral oil as the main component, there is a risk of adversely affecting aquatic animals and plants, and its use is restricted because care must be taken not to flow into rivers and ponds. There is a problem that it will be done.

The repellent of Patent Document 3 does not disclose that it is used for an insect repellent net, and its effect is unknown. In addition, the repellent is sprayed directly on the crop, and the purpose is to prevent pests from adhering to or continuing to adhere to the sprayed part, whereas the insect repellent net has a hollow part between the nets. However, since it is not possible to impregnate the cavity with a drug, it is difficult to suppress the invasion of pests smaller than the mesh into the cavity only by the repellent effect. In fact, the present inventor produced an insect repellent net using sorbitan laurate, sucrose fatty acid ester (laurate) and coconut oil, which were taught as compounds exhibiting an excellent repellent effect in Patent Document 3, and exerted an effect of preventing pest invasion. We investigated, but confirmed that the effect was the same as or less than that in the case of no treatment, and that a compound excellent as a repellent did not necessarily exert an excellent effect when used in an insect repellent net. (See Tests 2 and 3 herein).

In the test of Patent Document 4, the collected whiteflies are confined in a narrow glass tube without feeding plants, and the whiteflies are placed in a strong confusion / stress state. Even with such a strongly confused / stressed whitefly, it is difficult to accurately evaluate the effect of the drug on the whitefly in the natural environment. In fact, the present inventor produced an insect repellent net using Sun Crystal Emulsion and Makupika, which were taught in Patent Document 4 to exhibit excellent effects, and suppressed pest invasion in an environment with less confusion / stress for pests. The effect has been tested and it has been confirmed that the effect is not sufficient (see Test 1 herein).

As described above, no insect repellent net has been found that has a small impact on the environment and is excellent in preventing the invasion of pests.
The present invention has been made in view of the above points, and an object of the present invention is to provide an insect repellent net having a small impact on the environment and an excellent effect of preventing the invasion of pests.

As a result of diligent studies to solve the above problems, the present inventors have a small impact on the environment by adhering a specific glycerin fatty acid ester to the net portion (mesh portion) of the insect repellent net, thereby preventing pest invasion. We have found that an insect repellent net with excellent effect can be obtained, and completed the present invention.

That is, the gist of the present invention is as follows.
[1] An insect repellent net to which at least one glycerin fatty acid ester selected from the following group is attached:
Capric acid and / or caprylic acid as constituent fatty acids selected from glycerin caprilate, diglycerin caprilate, glycerin diacet monocaprilate, glycerin diacet monocaplate, triglycerin mono dicaprelate, and triglycerin mono dicaprate. At least one glycerin fatty acid ester, including
At least one glycerin fatty acid ester containing lauric acid as a constituent fatty acid selected from glycerin diacet monolaurate and diglycerin laurate, and glycerin trioleate, diglycerin monogeolate, decaglycerin oleate and glycerin diacetomonoole. At least one glycerin fatty acid ester containing oleic acid as a constituent fatty acid selected from ate.
[2] The insect repellent net according to [1], which has a mesh size of 0.5 to 5 mm.
[3] The glycerin fatty acid ester
At least one glycerin fatty acid ester containing lauric acid as a constituent fatty acid selected from glycerin diacet monolaurate and diglycerin laurate, and glycerin caprilate, diglycerin caprilate, glycerin diacet monocaprelate, glycerin diacet monoca At least one glycerin fatty acid ester, which comprises capric acid and / or capric acid as a constituent fatty acid, selected from plates, triglycerin mono-dicaprylate, and triglycerin mono-dica plates.
The insect repellent net according to [1] or [2], which is at least one selected from the group consisting of.
[4] Any of [1] to [3], wherein the glycerin fatty acid ester is at least one glycerin fatty acid ester containing lauric acid as a constituent fatty acid, which is selected from glycerin diacet monolaurate and diglycerin laurate. Or the insect repellent net described in item 1.
[5] The insect repellent net according to [4], wherein the glycerin fatty acid ester is glycerin diacet monolaurate.
[6] Constituent fatty acids in which the glycerin fatty acid ester is selected from glycerin caprilate, diglycerin caprilate, glycerin diacet monocaprelate, glycerin diacet monocaplate, triglycerin mono / dicaprelate, and triglycerin mono / dicaplate. The insect repellent net according to any one of [1] to [3], which is at least one glycerin fatty acid ester containing capric acid and / or capric acid.
[7] The glycerin fatty acid ester is selected as a constituent fatty acid selected from glycerin monocaprylate, glycerin tricaprylate, diglycerin monocaprylate, diglycerin dicaprylate, glycerin diacet monocaprylate, and glycerin diacet monocaprate. The insect repellent net according to [6], which is at least one glycerin fatty acid ester containing capric acid and / or caprylic acid.
[8] The insect repellent net according to [7], wherein the glycerin fatty acid ester is glycerin monocaprilate.
[9] The insect repellent net according to any one of [1] to [8], to which a polyoxyalkylene-based nonionic surfactant is not attached.
[10] A composition containing at least one glycerin fatty acid ester selected from the group consisting of the following, which is applied to an insect repellent net to protect plants from pests.
Capric acid and / or caprylic acid as constituent fatty acids selected from glycerin caprilate, diglycerin caprilate, glycerin diacet monocaprilate, glycerin diacet monocaplate, triglycerin mono dicaprelate, and triglycerin mono dicaprate. At least one glycerin fatty acid ester, including
At least one glycerin fatty acid ester containing lauric acid as a constituent fatty acid selected from glycerin diacet monolaurate and diglycerin laurate, and glycerin trioleate, diglycerin monogeolate, decaglycerin oleate and glycerin diacetomonoole. At least one glycerin fatty acid ester containing oleic acid as a constituent fatty acid selected from ate.
[11] A method for producing an insect repellent net, which comprises a step of applying a composition containing at least one glycerin fatty acid ester selected from the following group to the net.
Capric acid and / or caprylic acid as constituent fatty acids selected from glycerin caprilate, diglycerin caprilate, glycerin diacet monocaprilate, glycerin diacet monocaplate, triglycerin mono dicaprelate, and triglycerin mono dicaprate. At least one glycerin fatty acid ester, including
At least one glycerin fatty acid ester containing lauric acid as a constituent fatty acid selected from glycerin diacet monolaurate and diglycerin laurate, and glycerin trioleate, diglycerin monogeolate, decaglycerin oleate and glycerin diacetomonoole. At least one glycerin fatty acid ester containing oleic acid as a constituent fatty acid selected from ate.
[12] The production method according to [11], wherein the composition further contains at least one solvent selected from ethanol and water.
[13] The production method according to [11] or [12], wherein the composition does not contain a polyoxyalkylene-based nonionic surfactant.
[14] A method for protecting a plant from harmful insects, which comprises the step of installing the insect repellent net according to any one of [1] to [9] around the plant.
[15] A method for protecting a plant from pests, which comprises applying the composition according to [10] to an insect repellent net.

According to the present invention, it is possible to provide an insect repellent net that has a small impact on the environment and is excellent in the effect of preventing the invasion of pests.

<< Insect repellent net >>
The first aspect of the present invention is an insect repellent net to which at least one glycerin fatty acid ester selected from the following group is attached.
Capric acid and / or caprylic acid as constituent fatty acids selected from glycerin caprilate, diglycerin caprilate, glycerin diacet monocaprilate, glycerin diacet monocaplate, triglycerin mono dicaprelate, and triglycerin mono dicaprate. At least one glycerin fatty acid ester, including
At least one glycerin fatty acid ester containing lauric acid as a constituent fatty acid selected from glycerin diacet monolaurate and diglycerin laurate, and glycerin trioleate, diglycerin monogeolate, decaglycerin oleate and glycerin diacetomonoole. At least one glycerin fatty acid ester containing oleic acid as a constituent fatty acid selected from ate.

(Glycerin fatty acid ester)
At least one glycerin fatty acid ester selected from the group consisting of the following (A) to (C) is attached to the insect repellent net of the present invention.
(A) Caprylic acid and / or as constituent fatty acids selected from glycerin caprilate, diglycerin caprilate, glycerin diacet monocaprilate, glycerin diacet monocaplate, triglycerin mono-dicaprelate, and triglycerin mono-dicaplate. At least one glycerin fatty acid ester containing caprylic acid,
(B) At least one glycerin fatty acid ester containing lauric acid as a constituent fatty acid selected from glycerin diacet monolaurate and diglycerin laurate, and (C) glycerin trioleate, diglycerin mono-dioreate, decaglycerin ole. At least one glycerin fatty acid ester containing oleic acid as a constituent fatty acid, selected from ate and glycerin diacet monooleate.

The glycerin fatty acid ester of the present invention is not a mineral oil (waste oil produced in large quantities after making plastics and other industrial products from petroleum), but a synthetic oil synthesized from plant-derived fatty acids and glycerin. Therefore, the insect repellent net of the present invention has an advantage that the influence on the environment is small.

In the present specification and claims, for example, glycerin caprylate means an ester compound of monoglycerin and monocaprylic acid, dicaprylic acid or tricaprylic acid, or a mixture thereof. Therefore, those containing fatty acids other than caprilate as constituent fatty acids, such as glycerin diacet monocaprelate, are not included in glycerin caprilate. The same applies to diglycerin caprilate, diglycerin laurate, decaglycerin oleate and the like.
In the present specification and claims, for example, the term triglycerin mono-dicaprylate refers to a mixture of triglycerin monocaprelate and triglycerin dicaprelate.

Examples of at least one glycerin fatty acid ester containing capric acid and / or caprylic acid as the constituent fatty acids of (A) include glycerin caprilate, diglycerin caprilate, glycerin diacet monocaprilate, glycerin diacet monocaplate, and triglycerin. Mono-dicaprylate and triglycerin mono-decaplate are preferred, glycerin caprilate, diglycerin caprilate, glycerin diacet monocaprelate, glycerin diacet monocaprate are more preferred, glycerin monocaprilate, glycerin dicaprelate, glycerin tri Caprylate, diglycerin monocaprelate, diglycerin dicaprylate, glycerin diacet monocaprelate, glycerin diacet monocaplate are even more preferred, glycerin monocaprelate, glycerin tricaprylate, diglycerin monocaprelate, diglycerin di Caprylate, glycerin diacet monocaprelate and glycerin diacet monocaprate are even more preferred, glycerin monocaprelate, diglycerin monocaprelate and diglycerin dicaprelate are even more preferred, and glycerin monocaprelate is particularly preferred. Only one type of glycerin fatty acid ester (A) may be used, or two or more types may be used in combination.
As at least one glycerin fatty acid ester containing lauric acid as the constituent fatty acid of the above (B), diglycerin monolaurate, glycerin diacet monolaurate and diglycerin dilaurate are preferable, and glycerin diacet monolaurate is more preferable. Only one type of glycerin fatty acid ester (B) may be used, or two or more types may be used in combination.
As at least one glycerin fatty acid ester containing oleic acid as the constituent fatty acid of the above (C), glycerin trioleate, diglycerin mono-diolate, decaglycerin oleate and glycerin diacet monooleate are preferable, and glycerin trioleate and deca Glycerin oleate is more preferred, and decaglycerin oleate is even more preferred. Only one type of glycerin fatty acid ester (C) may be used, or two or more types may be used in combination.
Further, as the glycerin fatty acid ester, among the above (A) to (C), the above-mentioned glycerin fatty acid ester (A) is preferable.

In the insect repellent net of the present invention, at least one glycerin fatty acid ester selected from the above is preferably 50% by mass or more, preferably 60% by mass or more, of the total glycerin fatty acid ester adhering to the insect repellent net. Is even more preferably 70% by mass or more, even more preferably 80% by mass or more, even more preferably 90% by mass or more, and even more preferably 95% by mass or more. Preferably, one or more glycerin fatty acid esters selected from the above may be 100% by mass of the total glycerin fatty acid esters attached to the insect repellent net.
By attaching the glycerin fatty acid ester to the insect repellent net of the present invention, it is possible to effectively prevent the invasion of pests having a size smaller than the mesh size of the insect repellent net. Therefore, by providing an insect repellent net around the plant, the plant can be protected from pests.

The glycerin fatty acid ester may be attached only to the surface of the net (also referred to as the net portion) constituting the insect repellent net, and may be contained not only on the surface of the net but also inside the net, but at least of the net. It is preferably adhered to the surface, and more preferably contained in the surface and inside of the net.
Further, the glycerin fatty acid ester may be attached to a part of the surface of the net constituting the insect repellent net, or may be attached to the entire surface of the net, but it is preferably attached to the entire surface.
Examples of the method for adhering the glycerin fatty acid ester to the net include a method in which a solution or suspension in which the glycerin fatty acid ester is added to a diluent (solvent) is applied to the net. Examples of the method of applying to the net include spray spraying, coating, and dipping, but spray spraying is preferable from the viewpoint of inexpensive and uniform application. The diluent is not particularly limited as long as it does not cause phytotoxicity to the plant and dissolves without reducing the effect of the active ingredient, but a diluent that can volatilize even at room temperature is preferable. Examples of the diluent include water, ethanol, isopropanol and the like. Of these, water and ethanol are preferable. When water is used, it may not be mixed with the glycerin fatty acid ester, so it is preferable to use a surfactant described later. After spraying on the net, the diluent will volatilize and the glycerin fatty acid ester (and surfactant) will remain on the net surface and / or inside the net.
Alternatively, when the glycerin fatty acid ester is liquid at room temperature, the net may be immersed in the glycerin fatty acid ester without diluting with a diluent. Alternatively, the glycerin fatty acid ester may be heated and melted to make it liquid, and then the net may be immersed in the glycerin fatty acid ester without diluting with a diluent.

^{The amount of glycerin fatty acid ester adhering to the net is not particularly limited, but 1 mg to 2} g per 10 cm 2 of the area of one side of the net (including the area of the mesh portion and the area of the space in the mesh), that is, ^{1 mg to 2} g / 10 cm 2 is preferable, 5 mg to 1 g / 10 cm ² is more preferable, and 20 mg to 0.5 g / 10 cm ² is even more preferable. Within this range, the invasion of pests into crops can be sufficiently prevented.
(Net)
The material of the net constituting the insect repellent net of the present invention is not particularly limited as long as it is a material to which the solution / suspension containing the glycerin fatty acid ester can adhere, but the solution / suspension containing the glycerin fatty acid ester penetrates. Easy ones are preferable. Examples of the net material include polyethylene, polystyrene, polypropylene, cotton, hemp and the like.

(Net mesh)
The mesh size is the size of the mesh of the net constituting the insect repellent net. For example, a net having a mesh of 0.8 mm has a mesh of 0.8 mm × 0.8 mm.
The mesh size of the net constituting the insect repellent net may be determined according to the size of the target pest, but it is preferable to have a mesh size of 0.5 to 5 mm. The mesh size of the net is more preferably 0.5 to 4 mm, even more preferably 0.6 to 3.5 mm, and even more preferably 0.8 to 3 mm. By setting the mesh size of the net within the above range, the pest invasion prevention effect of the present invention can be sufficiently exhibited, and sufficient air permeability can be ensured.
Further, if the effect of preventing the invasion of pests is emphasized, the mesh size of the net is preferably 0.5 to 2.0 mm, more preferably 0.5 to 1.0 mm, and 0.5 to 0. Even more preferably, it is 0.8 mm.

The insect repellent net of the present invention may consist only of a net, or may include components other than the net. Examples of components other than the net include silver tape such as aluminum vapor-deposited tape and auxiliary threads.
The color of the net is not particularly limited, and white, red, blue, etc. can be adopted.

(Other ingredients)
The insect repellent net of the present invention may or may not have components other than the glycerin fatty acid ester attached (to the net constituting the insect repellent net). Examples of other components include surfactants and the like. When a surfactant is used, even when water is used as a diluent, the glycerin fatty acid ester can be uniformly dissolved, suspended, or emulsified in water before being sprayed on the net. Therefore, it becomes easy to uniformly attach the glycerin fatty acid ester to the net. Examples of the surfactant include polyoxyethylene sorbitan fatty acid ester (T-20), polyoxyethylene caster oil (hydrogenated), polyoxyethylene alkyl ether and the like.
The insect repellent net of the present invention tends to prevent the invasion of pests when the surfactant is not attached, as compared with the case where the insect repellent is attached. Therefore, the insect repellent net of the present invention may or may not have a surfactant attached, but it is preferable that the surfactant is not attached. Further, it is preferable that a polyoxyalkylene-based nonionic surfactant (for example, polyoxyethylene (5) monododecyl ether, polyoxyethylene phenyl ether, etc.) is not attached. Further, it is preferable that soybean oil does not adhere to the insect repellent net of the present invention, and it is preferable that mineral oil (machine oil or the like) does not adhere to the insect repellent net.

<< Composition >>
A second aspect of the present invention is a composition containing at least one glycerin fatty acid ester selected from the group consisting of the following, which is applied to an insect repellent net to protect plants from pests.
Capric acid and / or caprylic acid as constituent fatty acids selected from glycerin caprilate, diglycerin caprilate, glycerin diacet monocaprilate, glycerin diacet monocaplate, triglycerin mono dicaprelate, and triglycerin mono dicaprate. At least one glycerin fatty acid ester, including
At least one glycerin fatty acid ester containing lauric acid as a constituent fatty acid selected from glycerin diacet monolaurate and diglycerin laurate, and glycerin trioleate, diglycerin monogeolate, decaglycerin oleate and glycerin diacetomonoole. At least one glycerin fatty acid ester containing oleic acid as a constituent fatty acid selected from ate.

The composition of the present invention can be used to produce the insect repellent net of the first aspect.
As the glycerin fatty acid ester, the mesh of the insect repellent net, and the like, those mentioned in the first aspect can be used, for example. Examples of plants and pests include those described in the third aspect below. Further, as a method of applying the composition to the insect repellent net, the same method as the method of adhering the glycerin fatty acid ester in the first aspect to the net can be mentioned.

In the composition of the present invention, at least one glycerin fatty acid ester selected from the above is preferably 50% by mass or more, preferably 60% by mass or more, of the total glycerin fatty acid ester contained in the composition. It is more preferably 70% by mass or more, further preferably 80% by mass or more, further preferably 90% by mass or more, and even more preferably 95% by mass or more. , One or more kinds of glycerin fatty acid esters selected from the above may be 100% by mass of the total glycerin fatty acid esters contained in the composition.

The composition of the present invention may be composed only of the above-mentioned glycerin fatty acid ester, or may contain a component other than the above-mentioned glycerin fatty acid ester. Examples of components other than the glycerin fatty acid ester include solvents such as water, ethanol, and isopropanol. In addition, those exemplified as other components in the first aspect may be included.
The amount of the glycerin fatty acid ester contained in the composition is not particularly limited, but the mass ratio of the glycerin fatty acid ester: solvent is preferably 100: 0 to 0.0001: 99.99999, and 50:50 to: It is more preferably 0.0001: 99.99999, even more preferably 30:70 to 0.0001: 99.99999, and even more preferably 10:90 to 0.001: 99.9999. preferable.
The mass ratio of the glycerin fatty acid ester: solvent may be 1: 0 to 1: 1000, 1: 1 to 1: 1000, or 1: 1 to 1: 800. , 1: 1 to 1: 500, 1: 1 to 1: 300, 1: 1 to 1: 100, 1: 1 to 1:50. It may be 1: 1 to 1:20, or 1: 1 to 1:10.

In addition, the present invention may be used for applying at least one glycerin fatty acid ester selected from the group consisting of the following to an insect repellent net to protect plants from pests.
Capric acid and / or caprylic acid as constituent fatty acids selected from glycerin caprilate, diglycerin caprilate, glycerin diacet monocaprilate, glycerin diacet monocaplate, triglycerin mono dicaprelate, and triglycerin mono dicaprate. At least one glycerin fatty acid ester, including
At least one glycerin fatty acid ester containing lauric acid as a constituent fatty acid selected from glycerin diacet monolaurate and diglycerin laurate, and glycerin trioleate, diglycerin monogeolate, decaglycerin oleate and glycerin diacetomonoole. At least one glycerin fatty acid ester containing oleic acid as a constituent fatty acid selected from ate.
As the glycerin fatty acid ester, insect repellent net, application method, plant, pest and the like, those described in the first to sixth aspects can be used.

<< Protection method 1 >>
The insect repellent net of the present invention can protect the plant from harmful insects by installing it around the plant. Therefore, a third aspect of the present invention is a method of protecting the plant from pests, which comprises the step of installing the insect repellent net of the first aspect around the plant. According to the method of the present invention, it is possible to prevent pests from passing through the insect repellent net and adhering to plants.

The methods of installing the insect repellent net around the plant are as follows: (i) Cover the plant with the insect repellent net (for example, install an insect repellent net around the plant in a mosquito net shape), and (ii) grow the plant. Install an insect repellent net so as to block the side windows, sky windows, ventilation openings, etc. of the vinyl house, (iii) install an insect repellent net in the shape of a warm or mosquito net at the entrance and exit of the vinyl house, (iv) freshly attached to the furrows Insect repellent nets may be installed in the shape of a curtain or in the shape of a curtain. Among these, it is preferable to cover the perimeter of the plant with an insect repellent net.

(plant)
Examples of plants include crops (vegetables, fruit trees) and ornamental plants. Among these, crops (vegetables, fruit trees) are preferable, and cucumbers, tomatoes, eggplants, and peppers are particularly preferable.

(pest)
The pests that can be prevented from invading by the insect repellent net of the present invention are not particularly limited, but the insect repellent net of the present invention can effectively act on pests of a size that the insect repellent net can pass through and prevent the invasion. .. Target pests include leafhoppers such as tobacco aphids and leafhoppers; leafhoppers such as aphids, aphids, aphids, aphids, aphids, aphids, aphids, aphids, aphids, aphids, aphids, aphids, aphids, aphids, aphids, aphids, aphids, aphids, aphids, aphids, aphids, aphids, aphids, aphids, and aphids. , Aphids such as Nasia bramushi; Aphids such as Tsumaguro yokobai, Inazuma yokobai, Chanomidorihime yokobai, Tobiirounka, Sejirounka, Himetobiunka; Examples include dust mites such as cyclamen dust mites, and aphids such as tomato aphids and aphids. Among these, the insect repellent net of the present invention acts effectively on whiteflies and more effectively on Bemisia tabaci.
Whiteflies, such as Bemisia tabaci, are about 1.0 mm long and 0.4 mm wide and transmit tomato yellow leaf curl disease. Therefore, in order to prevent the invasion of Bemisia tabaci, an insect repellent net with a mesh size of less than 0.4 mm is usually required. However, by containing a specific glycerin fatty acid ester, the insect repellent net of the present invention can remarkably prevent the invasion of Bemisia tabaci even with a mesh size of 0.4 mm or more.

<< Protection method 2 >>
The insect repellent net of the present invention can protect plants from pests by applying the composition of the second aspect to the insect repellent net. Therefore, a fourth aspect of the present invention is a method of protecting the plant from pests, which comprises the step of applying the composition of the second aspect to an insect repellent net.
Examples of plants and pests include those described in the third aspect. Further, as a method of applying the composition to the insect repellent net, the same method as the method of adhering the glycerin fatty acid ester in the first aspect to the net can be mentioned.
The method of the present invention may further include the step of installing an insect repellent net around the plant. The step of installing the insect repellent net around the plant may be performed before applying the composition to the insect repellent net, or may be performed after applying the composition to the insect repellent net.
As a method of installing the insect repellent net around the plant, the method described in the third aspect can be mentioned.
According to the method of the present invention, it is possible to prevent pests from passing through the insect repellent net and adhering to plants.

<< Manufacturing Method 1 >>
The insect repellent net of the present invention can be produced, for example, by the following method.
A fifth aspect of the present invention is a method for producing an insect repellent net, which comprises a step of applying a composition containing at least one glycerin fatty acid ester selected from the group consisting of the following to the net.
Capric acid and / or caprylic acid as constituent fatty acids selected from glycerin caprilate, diglycerin caprilate, glycerin diacet monocaprilate, glycerin diacet monocaplate, triglycerin mono dicaprelate, and triglycerin mono dicaprate. At least one glycerin fatty acid ester, including
At least one glycerin fatty acid ester containing lauric acid as a constituent fatty acid selected from glycerin diacet monolaurate and diglycerin laurate, and glycerin trioleate, diglycerin monogeolate, decaglycerin oleate and glycerin diacetomonoole. At least one glycerin fatty acid ester containing oleic acid as a constituent fatty acid selected from ate.

(Composition containing glycerin fatty acid ester)
Compositions containing glycerin fatty acid esters include glycerin fatty acid esters. As the glycerin fatty acid ester, those mentioned in the first aspect above can be used. The composition may consist only of the glycerin fatty acid ester or may contain components other than the glycerin fatty acid ester, but preferably contains at least one solvent.
Examples of the solvent include ethanol, water, isopropanol and the like. Among these, ethanol and water are preferable, and ethanol is more preferable.

The ratio of the glycerin fatty acid ester to the solvent in the composition is not particularly limited, but the mass ratio of the glycerin fatty acid ester: solvent is preferably 100: 0 to 0.0001: 99.99999, and 50:50 to: 0. It is more preferably .0001: 99.9999, even more preferably 30:70 to 0.0001: 99.99999, and even more preferably 10:90 to 0.001: 99.9999. ..
The mass ratio of the glycerin fatty acid ester: solvent may be 1: 0 to 1: 1000, 1: 1 to 1: 1000, or 1: 1 to 1: 800. , 1: 1 to 1: 500, 1: 1 to 1: 300, 1: 1 to 1: 100, 1: 1 to 1:50. It may be 1: 1 to 1:20, or 1: 1 to 1:10.

No particular limitation on the concentration of a composition comprising a glycerin fatty acid esters sprayed in the net, but it is preferred to spray in an amount of ^{5ml / m 2 ~1L / m 2} , an amount of 20ml / m ² ~500ml / m ² it is more preferable to spray, it is further preferable to spray in an amount of ^{40ml / m 2 ~200ml / m 2} . Incidentally, the net 1 m ^2, the area of the space portion is also included in the network as well as network portion of the net is that 1 m ^2.

The composition containing the glycerin fatty acid ester may or may not contain components other than the above. Examples of other components include surfactants and the like. When a surfactant is contained, even when water is used as a diluent, the glycerin fatty acid ester can be uniformly dissolved, suspended, or emulsified in water before being sprayed on the net. Therefore, it becomes easy to uniformly attach the glycerin fatty acid ester to the net. Examples of the surfactant include polyoxyethylene sorbitan fatty acid ester (T-20), polyoxyethylene caster oil (hydrogenated), polyoxyethylene alkyl ether and the like.
The insect repellent net of the present invention tends to prevent the invasion of pests when the surfactant is not attached, as compared with the case where the insect repellent is attached. Therefore, the composition of the present invention may or may not contain a surfactant, but it is preferable that it does not contain a surfactant. Moreover, it is preferable that it does not contain a polyoxyalkylene-based nonionic surfactant. Further, the composition containing the glycerin fatty acid ester preferably does not contain soybean oil, and preferably does not contain mineral oil (machine oil or the like).

In the production method of the present invention, it is preferable to mix the glycerin fatty acid ester with a solvent to obtain a mixed solution before spraying the composition containing the glycerin fatty acid ester on the net. Examples of the solvent include water, ethanol, isopropanol and the like. Among these, water and ethanol are preferable, and ethanol is more preferable. Further, after mixing the glycerin fatty acid ester with ethanol to obtain a mixed solution, the mixed solution may or may not be diluted with water, but it is preferably diluted with water.

Examples of the method for applying the composition containing the glycerin fatty acid ester to the net of the insect repellent net include the method described in the first aspect above. After applying the composition containing the glycerin fatty acid ester to the net of the insect repellent net, it may have a step of drying the net.

<< Manufacturing Method 2 >>
The insect repellent net of the present invention can be produced, for example, by applying the composition of the second aspect to the insect repellent net. Therefore, the sixth aspect of the present invention is a method for producing an insect repellent net, which comprises a step of applying the above composition to the insect repellent net.
Examples of the method of applying the composition to the insect repellent net include the same method as the method of adhering the glycerin fatty acid ester in the first aspect to the net.

Next, test examples relating to the present invention will be described, but these are not limited to the present invention.

<Test 1>
(Example 1)
Glycerin monocaprilate (trade name: M-100, manufactured by Riken Vitamin Co., Ltd.) and 99% ethanol are mixed at room temperature (about 25 ° C.) so as to have a mass ratio of 2: 8, and Example 1 A treatment agent for insect repellent net was prepared.
(Comparative Examples 1-2)
Sun Crystal Emulsion (manufactured by Sankei Chemical Co., Ltd.) and Makupika (manufactured by Ishihara Bioscience Co., Ltd.) were used as treatment agents for Comparative Examples 1 and 2, respectively. According to the Material Safety Data Sheet of Sun Crystal Emulsion, Sun Crystal Emulsion is a product containing fatty acid glyceride (decanoyl octanoyl glycerol) as an active ingredient. According to Makupika's Safety Data Sheet, Makupika is a product made of polyether-modified silicone oil.

(Test method)
The treatment agent of Example 1, the treatment agent of Comparative Example 1, or the treatment agent of Comparative Example 2 was dissolved in water so as to have a concentration of 1 g / 50 mL, and sprayed onto a white net having a mesh size of 0.8 mm. After leaving it in an air-conditioned greenhouse for one day, a net treated with a treatment agent was put on the window of the breeding box. Put the cucumber seedlings in the breeding box, place the breeding box in the 1.8m x 0.9m x 0.6m ami room, put the cucumber seedlings with whiteflies in the ami room, cut the roots, and gradually It was dried and confined in the sapling chamber. Two days later, the number of whiteflies on the cucumbers in the breeding box was counted.
After the first test, the whitefly attached to the whitefly was removed with a brush, set again, and a total of three penetration tests were performed.
The results are shown in Table 1.

(result)
As a result of Test 1, it was found that the sun crystal emulsion and the insect repellent net to which Makupika was attached, which was taught in Patent Document 4 as exhibiting an excellent effect, did not have a sufficient pest invasion prevention effect. On the other hand, it was found that the insect repellent net of the present invention has a remarkably small number of whiteflies attached to cucumber and exhibits an excellent pest invasion prevention effect.
Regarding the test using Sun Crystal Emulsion and Makupika, although the number of whitefly passing individuals was small in the test of Patent Document 4, the number of passing individuals (the number of cucumber-attached individuals) was large in the test of this test. It is considered that the reason is that in the examples of Patent Document 4, the whitefly was confined in a narrow glass tube, so that the whitefly was confused and the accurate behavior could not be tested. Further, in the example of Patent Document 4, no bait is installed, and the test is a mild test lacking motivation for the whitefly to pass through the insect repellent net. As a result, it is considered that the number of passing individuals was small. On the other hand, in the test method of the present invention, a whitefly bait is installed and has a strong motivation for the whitefly to pass through the insect repellent net. Therefore, it can be said that the test is closer to the actual environment. Moreover, since the whitefly is not confined in a narrow glass tube, confusion is unlikely to occur. As a result, it is considered that the more accurate behavior of whiteflies with respect to the insect repellent net could be tested.
The excellent effect of preventing the invasion of whiteflies by the insect repellent net treated with glycerin monocaprelate of Example 1 with respect to the case of using Sun Crystal Emulsion or Makupika was unpredictable from the disclosure of Patent Document 4.

<Test 2>
Cucumber seedlings are placed in each of the breeding box with a 1 mm mesh insect repellent net immersed in each of the following reagent solutions (original body) and the breeding box with an insect repellent net that has not been treated with chemicals, and the cucumber seedlings are exposed to the outside. It was installed in a large, sealed room to prevent it from escaping. After that, a pot-planted cucumber in which Bemisia tabaci is growing was placed in the room and outside the breeding box. Then, the pot-planted cucumber stalks in which Bemisia tabaci was growing were cut. By gradually drying the cucumber seedlings by cutting the stems, the Bemisia tabaci growing on the cucumber seedlings moves toward the undried cucumber seedlings in the breeding box.
Three days after placing the pot-planted cucumbers in which Bemisia tabaci grows in the room, the number of whiteflies that have settled on the cucumbers in the breeding box is examined, and each implementation is performed when the number of whiteflies in the untreated state is 100. The number of whiteflies in the example was calculated as the invasion rate (fixation rate).
Each test sample was not diluted, and the net was immersed in the undiluted solution. Since OL-100, coconut oil, and M-100 are solid at room temperature, they were heated to 60 ° C. to melt, and then the net before being attached to the breeding box was immersed in these oils. After soaking, excess chemical solution was removed by free fall, then set in a breeding box and used in the experiment.
The results are shown in Table 2.

The actor LO-1 of Example 3 uses high oleic canola oil containing a large amount of oleic acid as a constituent fatty acid as a raw material, and further increases the oleic acid content by changing linoleic acid and linolenic acid contained in the raw material to oleic acid. It is an enhanced synthetic oil (synthetic oil synthesized from plant-derived fatty acids and glycerin) (the total amount of unsaturated fatty acids is about 93%). Since oleic acid occupies most of the constituent fatty acids, it is called glycerin trioleate here.

(result)
As a result of Test 2, among the test samples (bulk ingredients) used in the experiment, when treated with glycerin monocaprilate or glycerin trioleate, whiteflies did not pass through the insect repellent net (Examples 2 and 3). .. On the other hand, in coconut oil and glycerin monooleate, whiteflies passed through the treated insect repellent net (Comparative Examples 3 and 4). From this result, it was found that there are a glycerin fatty acid ester in which whiteflies cannot pass by treating the insect repellent net and a glycerin fatty acid ester in which whiteflies can pass through even if the insect repellent net is treated. This result was also unpredictable from the disclosure of Patent Document 4.
Next, as with glycerin monocaprilate, we searched for glycerin fatty acid esters that could not pass whiteflies by treating them with an insect repellent net.

<Test 3>
(Example 4)
Examples of mixing glycerin monocaprilate (trade name: Poem M-100, manufactured by Riken Vitamin Co., Ltd.) and 99% ethanol at room temperature (about 25 ° C) so as to have a mass ratio of 2: 8. The treatment agent for the insect repellent net of 4 was prepared.
(Examples 5 to 16)
The insect repellent net treatment agents of Examples 5 to 16 were prepared by the same method as in Example 4 except that the glycerin monocaprilate was changed to the following compounds. In the following, an esterification rate of 50% means that the average esterification rate is 50%.
Example 5: Glycerin tricaprylate (trade name: Actor M-2, manufactured by Riken Vitamin Co., Ltd.)
Example 6: Glycerin diacet monocaprilate (trade name: BIOCIZER, manufactured by Riken Vitamin Co., Ltd.)
Example 7: Diglycerin mono-dicaprylate (esterification rate 50%)
Example 8: Glycerin diacet monocaprilate / caplate ^(*) (Product name: Rikemar PL-019, manufactured by Riken Vitamin Co., Ltd.)
^(*) Mixture of glycerin diacet monocaprelate and glycerin diacet monocaplate (former: latter = 50:50 (mass ratio))
Example 9: Glycerin diacetomonoca plate Example 10: Triglycerin mono-dicaprylate (esterification rate 50%) (manufactured by RIKEN Vitamin Co., Ltd.)
Example 11: Triglycerin mono-dica plate (esterification rate 50%) (manufactured by RIKEN Vitamin Co., Ltd.)
Example 12: Glycerin diacetomonolaurate (trade name: Rikemar PL-004, manufactured by Riken Vitamin Co., Ltd.)
Example 13: Diglycerin mono-dilaurate (esterification rate 30%) (trade name: Rikemar L-71-D, manufactured by Riken Vitamin Co., Ltd.)
Example 14: Glycerin trioleate Example 15: Decaglycerin oleate (esterification rate 100%) (trade name: Poem J-0381, manufactured by Riken Vitamin Co., Ltd.)
Example 16: Glycerin diacet monooleate

(Comparative Examples 5 to 11)
The insect repellent net treatment agents of Comparative Examples 5 to 11 were prepared by the same method as in Example 4 except that the glycerin monocaprilate was changed to the following compounds.
Comparative Example 5: Diglycerin tetracaprylate (manufactured by Riken Vitamin Co., Ltd.)
Comparative Example 6: Glycerin Monoca Plate (Product Name: Poem M-200, manufactured by Riken Vitamin Co., Ltd.)
Comparative Example 7: Diglycerin mono-dica plate (esterification rate 50%) (manufactured by Riken Vitamin Co., Ltd.)
Comparative Example 8: Sorbitan Laurate Comparative Example 9: Sucrose fatty acid ester (caprilate)
Comparative Example 10: Sucrose fatty acid ester (laurate)
Comparative Example 11: Sucrose fatty acid ester (caplate)

(Test method)
1 g of each of the treatment agents of Examples 4 to 16 and Comparative Examples 5 to 11 was dissolved in 100 mL of water and sprayed onto an insect repellent net (white, mesh size 0.8 mm). After air-drying, an insect repellent net treated with a treatment agent was put on the window of the breeding box, and cucumber seedlings were put inside. As a control, a breeding box with an untreated insect repellent net was used.
Four breeding boxes were installed in a closed room. After that, pot-planted cucumber seedlings or cabbage seedlings in which Bemisia tabaci was growing were placed in the room and outside the breeding box. In the evening, after dark, the cucumber or cabbage stalks were cut and gradually dried. Due to drying, Bemisia tabaci flew away from the host, passed through the mesh of the insect repellent net, and began to settle on the cucumbers in the breeding box.
The next day, the number of whiteflies that invaded each breeding box (that is, passed through the insect repellent net) in the evening was counted. Compare the number of whiteflies that invaded the breeding box in each example or comparative example with the number of whiteflies that invaded the breeding box in the case of no treatment (control), and calculate the whitefly invasion rate for the control by the following formula. Calculated.

Whitefly invasion rate with respect to control = number of whiteflies invading the breeding box in each example or comparative example / number of whiteflies invading the breeding box in the case of no treatment (control) × 100
The results are shown in Table 3.
For each of the treatment agents of Examples 4 to 16 and Comparative Examples 5 to 11, the same test was performed a plurality of times, and the results of each time were obtained in the first, second, and third times. Described in Part 4 respectively. In the table, "-" means that the test has not been performed.

(result)
As a result of Test 3, the insect repellent net to which sorbitan laurate and sucrose fatty acid ester, which were taught in Patent Document 3 as exhibiting an excellent repellent effect, had the same or worse whitefly invasion as in the untreated case. It showed the rate and was found not to be effective in preventing the invasion of pests. On the other hand, it was found that the insect repellent net of the present invention has a remarkably low whitefly invasion rate as compared with the case of no treatment, and exhibits an excellent pest invasion prevention effect.
Therefore, the excellent effect of the insect repellent net of the present invention on preventing the invasion of whiteflies was unpredictable not only from the disclosure of Patent Document 4 but also from the disclosure of Patent Document 3.

<Test 4>
Next, in order to examine the necessity of an auxiliary agent, a treatment agent containing no auxiliary agent (Example 17) and a treatment agent containing an auxiliary agent (Examples 18 to 19) were prepared as follows, and each treatment agent was prepared. The whitefly invasion rate with respect to the control when was used was compared.

(Example 17)
Glycerin monocaprilate (trade name: M-100, manufactured by Riken Vitamin Co., Ltd.) and 99% ethanol are mixed at room temperature (about 25 ° C.) so as to have a mass ratio of 2: 8, and Example 17 A treatment agent for insect repellent net was prepared.

(Example 18)
Glycerin monocaprelate (trade name: Poem M-100, manufactured by RIKEN Vitamin Co., Ltd.), auxiliary agent A (glycerin monocaprelate: auxiliary agent A = 8: 2 (mass ratio)) and 99% ethanol, glycerin The insect repellent net treatment agent of Example 18 was prepared by mixing at room temperature (about 25 ° C.) so that the total mass ratio of monocaprilate and auxiliary agent A was: ethanol = 2: 8.
Auxiliary agent A: Polyoxyethylene (5) monododecyl ether (trade name: B-205, manufactured by Riken Vitamin Co., Ltd.)

(Example 19)
Glycerin monocaprelate (trade name: Poem M-100, manufactured by RIKEN Vitamin Co., Ltd.), auxiliary agent B (glycerin monocaprelate: auxiliary agent B = 8: 2 (mass ratio)) and 99% ethanol, glycerin The insect repellent net treatment agent of Example 19 was prepared by mixing at room temperature (about 25 ° C.) so that the total mass ratio of monocaprilate and auxiliary agent B was: ethanol = 2: 8.
Auxiliary agent B: Diglycerin monooleate (trade name: DO-100, manufactured by Riken Vitamin Co., Ltd.): Polyoxyethylene phenyl ether + dodecylbenzene sulfonate (trade name: 355H, manufactured by Toho Chemical Industry Co., Ltd.): Mixture of soybean oil = 1: 1: 1 (mass ratio)

(Test method)
0.5 g of each of the treatment agents of Examples 17 to 19 was suspended in 50 mL of distilled water, sprayed on an insect repellent net (0.8 mm or 3 mm mesh), air-dried, and then treated with the insect repellent net without treatment. Insect repellent net (0.8 mm or 3 mm mesh) was put on one side of the breeding box containing the cucumber seedlings. After that, four breeding boxes were installed in a large closed room so that whiteflies would not escape to the outside, and cucumber seedlings with whiteflies were placed in the room and outside the breeding box, and the roots were placed. It was cut and dried to allow whiteflies to fly away. The experiment was conducted in an air-conditioned greenhouse at 25 ° C., and the number of cucumber boxes flying in each breeding box was counted.
Table 4 shows the results when an insect net with a mesh size of 0.8 mm was used, and Table 5 shows the results when an insect screen with a mesh size of 3 mm was used.

(result)
As a result of Test 4, the insect repellent net of the present invention is effective with or without an auxiliary agent, but it is better to contain the auxiliary agent than to include the auxiliary agent. It was found that the whitefly invasion rate can be further reduced. Further, it was found that the insect repellent net of the present invention can significantly prevent the invasion of whiteflies in both the case of the mesh size of 0.8 mm and the case of the mesh size of 3 mm as compared with the case of no treatment.

<Test 5>
Cucumber seedlings are placed in each of the breeding box with a 1 mm mesh insect repellent net immersed in each of the following reagent solutions (original body) and the breeding box with an insect repellent net that has not been treated with chemicals, and the cucumber seedlings are exposed to the outside. It was installed in a large, sealed room to prevent it from escaping. After that, a pot-planted cucumber in which Bemisia tabaci is growing was placed in the room and outside the breeding box. Then, the pot-planted cucumber stalks in which Bemisia tabaci was growing were cut. It was thought that the cucumber seedlings gradually dried due to the cutting of the stems, which caused the Bemisia tabaci to scatter and move toward the cucumber seedlings in the breeding box.
Each test sample was not diluted, and the net was immersed in the test sample as it was. After soaking, excess chemical solution was removed by free fall, then set in a breeding box and used in the experiment.
Three days after placing the pot-planted cucumber in which Bemisia tabaci grows in the room, the number of whiteflies that invaded the breeding box was examined, and the number of whiteflies in the untreated case was set to 100 in each embodiment. The number of whiteflies was calculated as the invasion rate (fixation rate). The results are shown in Table 6.

(result)
As a result of Test 5, it was reconfirmed that the invasion of whiteflies into the net can be prevented when the stock solutions of glycerin diacet monolaurate, glycerin diacet monocaplate, glycerin trioleate, and diglycerin mono dilaurate are used. .. It was also found that treatment with diglycerin monogeolate can also prevent whiteflies from invading the net.

According to the present invention, it is possible to provide an insect repellent net having an excellent effect of preventing the invasion of pests. Therefore, the insect repellent net of the present invention is extremely useful industrially.

Claims (15)

An insect repellent net to which at least one glycerin fatty acid ester selected from the following group is attached:
Capric acid and / or caprylic acid as constituent fatty acids selected from glycerin caprilate, diglycerin caprilate, glycerin diacet monocaprilate, glycerin diacet monocaplate, triglycerin mono dicaprelate, and triglycerin mono dicaprate. At least one glycerin fatty acid ester, including
At least one glycerin fatty acid ester containing lauric acid as a constituent fatty acid selected from glycerin diacet monolaurate and diglycerin laurate, and glycerin trioleate, diglycerin monogeolate, decaglycerin oleate and glycerin diacetomonoole. At least one glycerin fatty acid ester containing oleic acid as a constituent fatty acid selected from ate. The insect repellent net according to claim 1, which has a mesh size of 0.5 to 5 mm. The glycerin fatty acid ester
At least one glycerin fatty acid ester containing lauric acid as a constituent fatty acid selected from glycerin diacet monolaurate and diglycerin laurate, and glycerin caprilate, diglycerin caprilate, glycerin diacet monocaprelate, glycerin diacet monoca At least one glycerin fatty acid ester, which comprises capric acid and / or capric acid as a constituent fatty acid, selected from plates, triglycerin mono-dicaprylate, and triglycerin mono-dica plates.
The insect repellent net according to claim 1 or 2, which is at least one selected from the group consisting of. 13. Insect repellent net. The insect repellent net according to claim 4, wherein the glycerin fatty acid ester is glycerin diacet monolaurate. The glycerin fatty acid ester is selected from glycerin caprilate, diglycerin caprilate, glycerin diacet monocaprelate, glycerin diacet monocaplate, triglycerin mono-dicaprelate, and triglycerin mono-dica plate, and capric acid as a constituent fatty acid. The insect repellent net according to any one of claims 1 to 3, which is at least one glycerin fatty acid ester containing caprylic acid. The glycerin fatty acid ester is selected from glycerin monocaprelate, glycerin tricaprylate, diglycerin monocaprelate, diglycerin dicaprelate, glycerin diacet monocaprelate, and glycerin diacet monocaplate. / Or the insect repellent net according to any one of claim 6, which is at least one glycerin fatty acid ester containing caprylic acid. The insect repellent net according to claim 7, wherein the glycerin fatty acid ester is glycerin monocaprilate. The insect repellent net according to any one of claims 1 to 8, to which a polyoxyalkylene-based nonionic surfactant is not attached. A composition comprising at least one glycerin fatty acid ester selected from the group consisting of the following, which is applied to an insect repellent net to protect plants from pests.
Capric acid and / or caprylic acid as constituent fatty acids selected from glycerin caprilate, diglycerin caprilate, glycerin diacet monocaprilate, glycerin diacet monocaplate, triglycerin mono dicaprelate, and triglycerin mono dicaprate. At least one glycerin fatty acid ester, including
At least one glycerin fatty acid ester containing lauric acid as a constituent fatty acid selected from glycerin diacet monolaurate and diglycerin laurate, and glycerin trioleate, diglycerin monogeolate, decaglycerin oleate and glycerin diacetomonoole. At least one glycerin fatty acid ester containing oleic acid as a constituent fatty acid selected from ate. A method for producing an insect repellent net, which comprises a step of applying a composition containing at least one glycerin fatty acid ester selected from the group consisting of the following to the net.
Capric acid and / or caprylic acid as constituent fatty acids selected from glycerin caprilate, diglycerin caprilate, glycerin diacet monocaprilate, glycerin diacet monocaplate, triglycerin mono dicaprelate, and triglycerin mono dicaprate. At least one glycerin fatty acid ester, including
At least one glycerin fatty acid ester containing lauric acid as a constituent fatty acid selected from glycerin diacet monolaurate and diglycerin laurate, and glycerin trioleate, diglycerin monogeolate, decaglycerin oleate and glycerin diacetomonoole. At least one glycerin fatty acid ester containing oleic acid as a constituent fatty acid selected from ate. The production method according to claim 11, wherein the composition further contains at least one solvent selected from ethanol and water. The production method according to claim 11 or 12, wherein the composition does not contain a polyoxyalkylene-based nonionic surfactant. A method for protecting a plant from harmful insects, which comprises the step of installing the insect repellent net according to any one of claims 1 to 9 around the plant. A method of protecting a plant from pests, which comprises applying the composition of claim 10 to an insect repellent net.