BRPI0903351B1 - STRUCTURAL BODY, STEAM RELEASE DEVICE, STEAM RELEASE METHOD AND METHOD FOR PRODUCTION OF A STRUCTURAL BODY - Google Patents

Abstract

The present invention relates to a structural body which is composed of a fibrous structural body and particles of which at least part is present in the form of an aggregate attached to the fibrous structural body. The structural body can absorb and then vaporize liquid rapidly and stably. The structural body can be used as a vapor release device wick, such as a liquid absorbing type hot vapor release insecticide device.

Description

(54) Title: STRUCTURAL BODY, STEAM RELEASE DEVICE, STEAM RELEASE METHOD AND METHOD FOR PRODUCTION OF A STRUCTURAL BODY (51) Int.CI .: A01M 1/20; A01N 25/18 (52) CPC: A01M 1/2061, A01N 25/18 (30) Unionist Priority: 12/09/2008 JP 2008-235249, 12/09/2008 JP 2008-235250 (73) Holder (s) : SUMITOMO CHEMICAL COMPANY, LIMITED (72) Inventor (s): MITSUKO YAMADA

DESCRIPTION REPORT FOR THE STRUCTURAL BODY, STEAM RELEASE DEVICE, STEAM RELEASE METHOD AND METHOD FOR PRODUCTION OF A STRUCTURAL BODY.

Field of the Invention

The present invention relates to a structural body comprising a fibrous material and particles adhered to the fibrous material, to a method for producing the structural body, to a vapor release device comprising the structural body, to a method of releasing vapor and to a steam release kit.

Prior Art

Insecticidal hot vapor release devices of the liquid absorption type have been conventionally used in order to vaporize insecticides and release them efficiently into the air in an environment for the purpose of mosquito control. Such insecticidal devices generally work in such a way that a chemical liquid that has been absorbed by a wick inserted into a reservoir containing the chemical liquid is vaporized by heating the upper end of the wick. In insecticidal devices for releasing hot vapor of the liquid absorption type, a liquid absorption wick is used, which is porous and has contiguous voids in order to vaporize a chemical liquid stably. The devices are configured so that a chemical liquid can be absorbed and vaporized through such a capillary action that the chemical liquid moves in small empty spaces in the wick.

JP 55-58047 A discloses a wick for insecticidal hot vapor release devices of the liquid absorption type, the wick being a product obtained by fortifying a mixture of mineral powder, such as activated clay, diatomaceous earth and talc, with wood flour or coal powder, with a gluing agent, such as dextrin or starch. JP 5-328884 A and JP 8-205744 A each reveal a wick with a liquid-absorbing layer made of fibers in its center, a layer that is covered with a fiber braid, and also discloses a product where the twisted of

Petition 870170090594, of 11/23/2017, p. 6/13 the aforementioned fiber is still covered with silicone varnish, thus fixing the liquid absorption layer to the braid.

Description of the Invention

Problems to be solved by the invention

However, the wick disclosed in JP 55-58047 A exhibits a low liquid absorption rate and needs several hours to absorb a chemical liquid. In this way, it takes a long time before it absorbs a necessary amount of chemical liquid to become ready for vaporization of the liquid.

The wicks disclosed in JP 5-328884 A or JP 8-205744 A also had a problem that the liquid absorption rate is low and the wastes need a long time until they absorb a necessary amount of chemical liquid to become ready for use. vaporization of the liquid.

The present invention was made in view of these problems, and the objective then is to provide a structural body that can absorb a liquid quickly and stably and that is excellent in vapor release ability, without using a bonding agent or resin.

Means for solving problems

In order to solve the above problems, the structural body of the present invention is characterized by the fact that it contains particles and a fibrous structural body and that at least part of the particles is present in the form of an aggregate attached to the fibrous structural body.

In the structural body of the present invention, it is desirable that the average particle diameter of the particles is 1 to 500 nm.

In the structural body of the present invention, it is desirable for the particles to be inorganic particles.

In the structural body of the present invention, it is desirable for the inorganic particles to be silica.

In the structural body of the present invention, it is desirable that the fibrous structural body be made of paper, woven fabric or nonwoven fabric.

In the fibrous structural body of the present invention, it is desirable that the structure be in a columnar shape.

One of the preferred applications of the structural body of the present invention is a wick, and the use of the structural body of the present invention as a wick is one of the preferred embodiments of the present invention.

The vapor release device of the present invention is characterized by having:

a reservoir containing a vaporizable liquid, and a wick made of the structural body of the present invention, the wick being located in such a way that a part of the wick is immersed within the vaporizable liquid and another part of the wick is exposed to the outside of the reservoir.

It is desirable that the vapor release device of the present invention also has heating devices for heating a portion of the wick, the portion not being immersed in the vaporizable liquid.

In the vapor delivery device of the present invention, it is desirable for the vaporizable liquid to comprise an insecticidal component.

In the vapor delivery device of the present invention, it is desirable that the vaporizable liquid further comprises an organic solvent.

In the vapor delivery device of the present invention, it is desirable that the vaporizable liquid comprises water in addition to the organic solvent and the insecticidal component.

In the vapor release device of the present invention, it is desirable for the insecticidal component to be a pyrethroid compound.

The vapor release method of the present invention is characterized by including the following actions:

immersing a part of the structural body of the present invention within a vaporizing liquid, thereby causing the structural body to absorb the liquid, and releasing, from the surface of the structural body, steam generated from the absorbed vaporizable liquid.

The vapor release kit of the present invention is characterized by comprising the structural body of the present invention.

The method of the present invention for producing a structural body is characterized by including:

an absorption step of bringing at least part of a fibrous structural body in contact with a dispersion liquid where particles are dispersed in a liquid medium, thereby causing the fibrous structural body to absorb the dispersion liquid, and a removal step removal of the liquid medium from the fibrous structural body that absorbed the dispersion liquid.

In the method of the present invention for producing a structural body, it is desirable that in the absorption step, the act of bringing at least part of the fibrous structural body in contact with a dispersion liquid is carried out by immersing the at least part of the fibrous structural body in the dispersion liquid.

In the method of the present invention for producing a structural body, it is desirable that the fibrous structural body be in a columnar shape and that in the absorption step the act of bringing at least part of a fibrous structural body in contact with a dispersion liquid is carried out by immersing a part of the longitudinal end of the fibrous structural body in the dispersion liquid.

In the method of the present invention for producing a structural body, it is desirable that the removal of the liquid medium from the fibrous structural body which has absorbed the dispersion liquid is carried out by drying the fibrous structural body.

In the method of the present invention for producing a structural body, it is desirable that the absorption step and the removal step are repeated until the proportion of particles that were contained in the fibrous structural body is 10 to 95% by weight, provided that the structural body weight is allowed to be 100% by weight.

In the method of the present invention for producing a structural body, it is desirable that the concentration of the particles in the dispersion liquid is 1 to 50% by weight.

In the method of the present invention for producing a structural body, it is desirable that the average particle diameter of the particles is 1 to 500 nm.

In the method of the present invention for producing a structural body, it is desirable that the fibrous structural body be made of paper, woven fabric or non-woven fabric.

In the method of the present invention for producing a structural body, it is desirable for the particles to be inorganic particles.

In the method of the present invention for producing a structural body, it is desirable for the inorganic particles to be silica.

The structural body of the present invention is characterized by being produced using any of the above methods.

Advantages of the invention

The present invention makes it possible to provide a structural body that can absorb and vaporize liquid quickly and stably.

Brief description of the drawings

Figure 1 is a schematic sectional view of an insecticidal hot vapor release device of the liquid absorption type according to an exemplary embodiment of the present invention.

Figure 2 is a diagram showing the results of SiO ₂ mapping by a ΕΡΜΑ (Electron Probe Micro Analyzer) of a cross section of a wick according to an exemplary embodiment of the present invention.

Figure 3 is a diagram showing an electron microscope image of a wick according to an exemplary embodiment of the present invention.

Figure 4 is a diagram showing the results of SiO2 mapping by a ΕΡΜΑ (Electron Probe Micro Analyzer) of a cross section of a wick according to another exemplary embodiment of the present invention.

Figure 5 is a diagram showing the results of mapping SiO ₂ by a ΕΡΜΑ (Electron Probe Micro Analyzer) of a cross section of a wick according to another exemplary embodiment of the present invention.

Figure 6 is a diagram showing an electron microscope image of a wick according to another exemplary embodiment of the present invention.

Figure 7 is a graph showing the vapor release ability of a wick.

Figure 8 is a graph showing the vapor release ability of a wick.

Description of preferred embodiments of the present invention [Structural body]

The structural body of the present invention is characterized by the fact that it contains particles and a fibrous structural body and that at least part of the particles is present in the form of an aggregate attached to the fibrous structural body. The structural body can be used properly, for example, as a wick that absorbs and then vaporizes liquid. The wick of the present invention can be used suitably as a wick 1 of a liquid vapor-absorbing insecticidal hot release device 5 such as that shown in figure 1. In addition, it can also be used properly as a wick of a flavoring device, deodorizing device, etc. The liquid-absorbing hot vapor insecticidal release device 5 shown in figure 1 is described in detail later.

(Fibrous structural body)

The wick of the present invention contains a fibrous structural body as a base material. In this report, a fibrous structural body can also be referred to as a base material. The fibrous structural body is made up of a plurality of thin linear aggregated objects, which are generally called fibers, and the fibrous structural body has empty spaces surrounded by the aggregated fibers. The fibrous structural body preferably contains hydrophilic fibers and more preferably is paper, woven fabric or non-woven fabric which are excellent in liquid absorption ability. Although the fibrous structural body itself has excellent liquid absorption ability, the presence of particles in the form of an aggregate in the fibrous structural body makes the wick excellent in shape stability and able to absorb liquid stably and quickly. If paper is used as the fibrous structural body, the wick is stable and it can maintain its structure even if it is put in an aqueous solvent. As the aqueous solvent, water or a hydrophilic solvent is intended to be used.

The paper to be used as the fibrous structural body is a product obtained by dispersing a fibrous substance (pulp) isolated from plants such as wood in water, spreading the resulting dispersion on a net or canvas so that a thin layer can be formed, pulp entanglement, dehydration and drying. Among papers, a paper that is classified as toilet paper includes tissue paper, toilet paper, paper towels, etc., and these are characterized by their high water absorption. Especially sanitary papers are preferred as the paper for the present invention.

Woven fabrics or non-woven fabrics to be used as a fibrous structural body are made of natural fibers, chemical fibers, synthetic fibers, inorganic fibers, or the like, and any of such fibers can be chosen appropriately depending on the intended application. Natural fibers as referred to here are fibers obtainable from materials existing in nature. Natural plant-derived fibers include cotton, linen, bamboo and pulp. Natural animal-derived fibers include wool and silk.

Chemical fibers are fibers obtained through chemical treatment of materials existing in nature and include rayon and rayon of cuprammonium, which are obtained by dissolving cellulose, such as pulp, in a solvent and then regenerating cellulose, and resulting cellulose acetate (triacetate) chemical treatment of cellulose. Synthetic fibers are chemically synthesized fibers from raw materials such as oil, and there are many examples of them, such as nylon, a polyester, acrylic fiber, polypropylene, polyurethane and vinyl. Inorganic fibers include glass fibers, metal fibers and carbon fibers.

(Particles)

In the wick of the present invention, the particles attached to the fibrous structural body are not particularly restricted with respect to their chemical composition. Although various materials can be used for the particles, inorganic substances, organic substances and their mixtures are used properly. Examples of particles that can be used suitably for the present invention are as follows.

The inorganic substance includes alkali metals, alkaline earth metals, transition metals and non-ferrous metals and specific examples thereof include gold, palladium, platinum, silver, and aluminum, or their oxides, hydroxides, sulfides or salts, such as carbonates and sulfates , and additional examples include oxides, hydroxides, sulfides or salts, such as carbonates and sulfates, of silicon, aluminum, zinc, magnesium, calcium, barium, titanium, zirconium, manganese, iron, cerium, nickel, tin and the like. Among these particles, inorganic particles are preferred, and silica is particularly preferred.

The organic substance includes resins, etc., and examples of resins include polyolefin resins, such as polyethylene, polypropylene and polystyrene; acrylic resins such as polymethyl methacrylate; polyamide resins such as polycondensate hexamethylenediamine-adipic acid; polyester resins such as polyethylene terephthalate and polyacetic acid; polyether resins, such as polyphenylene ether and polypropylene glycol; polycarbonate resins and liquid crystal resins.

Regarding the size and shape of the particles that make up the aggregates attached to the fibrous structural body, any particles can be used that are so small that the particles can be accepted into empty spaces in the fibrous structural body. Particular preferred particles are those that are so small that they can be supplied in the form of a colloidal solution where particles are dispersed in a liquid medium. When the particles are supplied from a colloidal solution, although the particles can be of any size so that they can be dispersed colloidally in a liquid medium, it is preferred to use particles having an average particle diameter of 1 to 500 nm, more preferably 2 nm to 100 nm and most preferably 5 nm to 70 nm because they can be handled easily. The particle diameter can be chosen depending on the intended application. The smaller the empty spaces in the fibrous structural body and the lower the porosity, the slower the liquid absorption speed when used as a wick.

Conventional colloidal solutions can be used as the colloidal solution mentioned above for the present invention. Examples of such colloidal solutions include colloidal metal solutions, colloidal oxide solutions, colloidal hydroxide solutions, colloidal carbonate solutions and colloidal sulfate solutions. Examples of metal elements contained in colloidal metal solutions include gold, palladium, platinum and silver. Examples of elements contained in colloidal oxide solutions, colloidal hydroxide solutions, colloidal carbonate solutions and colloidal sulfate solutions include silicon, aluminum, zinc, magnesium, calcium, barium, titanium, zirconium, manganese, iron, cerium, nickel and tin . In particular, it is preferred to use a colloidal oxide solution or a colloidal hydroxide solution, and especially a colloidal silicon oxide solution is preferred. When a colloidal silicon oxide solution is used, a resulting wick contains silica as particles. Such a wick is preferred because it is excellent in heat resistance.

The wick of the present invention has sufficiently shaped stability because it contains particles and a fibrous structural body and at least part of the particles is present in the form of an aggregate attached to the fibrous structural body. In this way, the wick exhibits stable liquid absorption ability. Particularly when paper is used as the fibrous structural body, the wick exhibits excellent shape stability in aqueous liquid. In this way, even if the wick is induced to absorb and then vaporize an aqueous chemical solution, the wick shape is maintained and stable and rapid absorption and vaporization of liquid can be achieved.

In the present invention, the shape of the wick is determined according to the shape of the fibrous structural body. For example, a wick in a columnar shape such as a cylindrical shape can be obtained using a fibrous structural body that has been formed in a columnar shape. A wick in a plate-like shape or a leaf-like shape can be obtained using a fibrous structural body having been formed in a plate-like shape or a leaf-like shape. Such a configuration that the fibrous structural body extends in a direction where the fibrous structural body absorbs the liquid is preferred because the liquid can flow well. For example, when a cylindrical fibrous structural body is formed, a sheet of paper can be shaped into a cylindrical shape by spiraling it from one side of it. At this point, the direction in which the paper extends matches the longitudinal direction of the cylinder and then suction happens quickly.

The wick of the present invention can be produced without using adhesives, such as varnish. In addition, since the type, particle diameter, etc. of the particles to be used can be changed, the vapor release ability of a wick can be changed by changing these factors and, as a result, vaporization can be controlled. easily.

[Method for producing a structural body]

By using the method of the invention to produce a structural body, a structural body to be used as a wick can be produced. In this exemplary embodiment, a method of the present invention for producing a structural body is described using a method for producing a wick as an example. The method of the present invention for producing a wick is characterized by comprising: an absorption step of bringing at least part of a fibrous structural body in contact with a dispersion liquid where particles are dispersed in a liquid medium, thereby causing the fibrous structural body absorbs the liquid, and a removal step of removing the liquid medium from the fibrous structural body which has absorbed the dispersion liquid. A wick can be produced, for example, by bringing a fibrous structural body made of fibers in contact with a dispersion liquid where particles are dispersed in a liquid medium to make the structural body absorb the dispersion liquid, thereby filling the dispersion liquid. in a fibrous structural body, while simultaneously removing the liquid medium of the absorbed dispersion liquid. Through such procedures, at least part of the particles are captured and bound to the fibers of the fibrous structural body and, as a result, the particles can be filled into the fibrous structural body at a high density.

Here, it is sufficient for the dispersion liquid where particles are dispersed in a liquid medium to be a dispersion liquid where particles are dispersed in the liquid medium without sediment. In order to disperse particles to a greater degree, a surfactant, an emulsifier or the like can be added to the dispersion liquid. Although the liquid medium where particles are dispersed is not particularly restricted, water is preferred from the point of view of simplifying the production facility, the load on the environment, etc. Although the concentration of particles in a dispersion liquid is not particularly limited, it is generally 1 to 50% by weight. In order to quickly fill and aggregate particles at a high density, a higher concentration is preferred and a concentration of 20 to 50% by weight is preferred.

The method for bringing a fibrous structural body into contact with a dispersion liquid can be, for example, a method where at least part of the fibrous structural body is put in the dispersion liquid or a method where the dispersion liquid is applied to the structural body fibrous. When a fibrous structural body is placed in a dispersion liquid, the fibrous structural body can be fully immersed in the dispersion liquid. Alternatively, the fibrous structural body can be partially placed in the dispersion liquid, so that the dispersion liquid is spread over the fibrous structural body through capillary action.

If a fibrous structural body is only partially immersed in a dispersion liquid, then it will absorb the dispersion liquid, this is advantageous because only a necessary amount of liquid is absorbed and then the dispersion liquid is not wasted. In addition, the concentration of particles in the fibrous structural body can be increased by continuing to immerse in the dispersion liquid while removing the solvent or by repeating the removal of the liquid medium and contact with the dispersion liquid.

In particular, it is desirable to repeat the absorption step and the removal step until a desired amount of particles is contained and a desired aggregate is formed. At this time, the absorption step and the removal step can be repeated until the proportion of particles that have been attached to the fibrous structural body is 10 to 95% by weight, as long as the weight of the wick is 100% by weight. When a columnar fibrous structural body is used, liquid absorption can be accomplished by immersing a longitudinal end of the fibrous structural body in a dispersion liquid. When a dispersion liquid is sprayed with a spray or the like or is applied with a brush or similar to a fibrous structural body, it is desirable to cause the dispersion liquid to completely bathe the fibrous structural body.

The method for removing a liquid medium from a fibrous structural body filled with a dispersion liquid can be, for example, drying the fibrous structural body having been made to absorb the dispersion liquid naturally at room temperature or by facilitating vaporization of the liquid medium compulsorily through heating with a dryer. When removing the liquid medium, only particles adhere to the fibers and the particles aggregate to harden, so that rigidity and resistance to liquid that are suitable as a wick are given to the fibrous structural body. At this time, the proportion of particles attached to the fibrous structural body is preferably 10 to 95% by weight, and more preferably 50 to 90% by weight, as long as the weight of the wick is 100%. The fibrous structural body and the dispersion liquid where particles are dispersed can, according to need, contain dyes, pigments, antioxidants, UV absorbers, preservatives, etc.

In the wick produced by the method of the present invention for producing a wick, at least part of the particles is bound to the fibrous structural body and is present in the form of an aggregate and the particles have been filled into the fibrous structural body at a high density. So, the wick has sufficiently high shape stability. In this way, a liquid can be absorbed and vaporized stably and quickly.

[Steam release device and steam release method]

The vapor release device of the present invention is characterized by having a reservoir containing a vaporizable liquid and a wick made of the structural body of the present invention, the wick being located in such a way that a part of the wick is immersed within the vaporizable liquid and another part of the wick is exposed to the outside of the reservoir. The vapor delivery device of the present invention can be used, for example, as an insecticidal device using an insecticidal liquid containing an insecticidal component such as the vaporizable liquid. In this exemplary embodiment, an explanation is made by providing, as an example, a case where the structural body of the present invention is used as a wick and the vapor release device of the present invention is used as an insecticidal device. The insecticidal device of the present invention may be a liquid vapor-absorbing hot vapor insecticidal device further having a heater (heating device) to heat a portion of the wick, the portion being out of the insecticidal liquid.

An exemplary embodiment of an insecticidal hot vapor release device of the liquid absorption type comprising a wick of the present invention is described below with reference to figure 1. Figure 1 is a schematic section view illustrating an insecticidal hot vapor release device liquid absorption type 5 of the present invention. As shown in figure 1, the liquid-absorbing hot-vapor insecticidal device 5 has a cylindrical wick 1, a ring-shaped heater 2 for heating wick 1, a heater support 3 that supports heater 2 and a reservoir 4 which is filled with an insecticidal liquid.

The wick 1 was inserted in a reservoir 4 with a longitudinal end of it projected from the reservoir and with the other end immersed in the insecticidal solution. The heater 2 indirectly heats the tip of the wick 1 projecting from the reservoir 4. The heater 2 is not particularly restricted as long as it is an exothermic body that can heat the fibrous structural body indirectly by about 60 to

150 ° C, and it is typically a normal ring-shaped electric heater that generates heat through the application of electric current. In this case, a heater (not shown) is connected to heater 2 to apply electric current to cause the heater to generate heat.

The distance between heater 2 and the wick is generally within the range of 0.5 mm to 2 mm and it is desirable that, in a safety aspect, the heating temperature of heater 2 is 150 ° C or less. The wick is usually adjusted so that its lower part inserted in the reservoir 4 can be located 0 mm to about 2 mm from the internal bottom of the reservoir 4. In order to absorb the insecticidal liquid in the reservoir 4 without any waste and use it until above, it is desirable to locate the lower end near the bottom of the reservoir as much as possible.

Although the material forming reservoir 4 is not particularly restricted as long as it is a material through which a chemical solution does not leak or escape even after a long period of time, transparent materials through which the residual amount of a chemical liquid remaining in the reservoir can be checked from the outside, as glass and plastics are preferred. In addition, materials having a UV protection property are preferred for the purpose of preventing chemical photo-decomposition agents. The insecticidal device for releasing hot vapor of the liquid absorption type can be equipped with a pilot lamp that indicates whether an electric current is being applied or not.

In the present invention, several conventionally known insecticides can be used as an insecticidal component to be contained in an insecticidal solution and examples thereof include pyrethroid insecticides, carbamate insecticides and organophosphorous insecticides. Pyrethroid insecticides are used appropriately because they are generally of high safety, and examples of them include alethrin, bioallethrin, pralethrin, metoflutrin, proflutrin, transflutrin, phthaltrin, etofenprox, resmetrin, furametrin, permethrin, fenotrin, fenvalerate, sphenopherine, cipermetrine, cipermetrine, cipermetrine, cipermetrine. fempropatrin, fenflutrin, empentrin, teralethrin, d-tetramethrin, cife15 notrina, tralometrina and deltametrina.

Examples of carbamate insecticides include phenobucarb (BPMC), methoxyzazone, alanicarb, oxamyl, carbosulfan, benfuracarb, methomyl, carbaryl (NAC), tiodicarb and ethiofencarb. Examples of organophosphorous insecticides include phenitrothione, acetate, diazinone and malathione.

In addition, the insecticidal liquid may contain a synergist that increases the action of these insecticides, for example, piperonyl butoxide. Noctylbicycloheptenodicarboxamide, N- (2-ethylhexyl) -1-isopropyl-4methylbicyclo [2,2,2] oct-5-ene-2,3-dicarboximide and octachlorodipropyl ether. The content of the synergist is preferably 0.1 to 10 times based on the content of the insecticidal component.

The concentration of an insecticidal component in an insecticidal liquid is preferably from 0.3% by weight to 20% by weight and most preferably a concentration within the range from 0.3% by weight to 5% by weight. Weight. These insecticidal components can be used alone or alternatively they can be used in combination. Aids, such as stabilizers, deodorants and dyes, can, if necessary, be added to the insecticidal liquid in a small amount. On the other hand, in use for the purpose of aromatization, a liquid containing one or more natural or artificial perfumes can be used as the liquid in which the wick is to be immersed. In addition, various agents, such as deodorants, germicides and repellents, can also be used for each purpose. These components can also be used as a solution after being dissolved in an organic solvent or a liquid mixed with an organic solvent and water.

In the insecticidal device of the present invention, the insecticidal liquid can be a solution obtained by dissolving an insecticidal component in an organic solvent or an aqueous liquid mixed with an organic solvent and water. Although the solvent in the insecticidal liquid is not particularly restricted, examples of it include oil-based liquids composed only of solvents and aqueous liquids composed of solvents and water. Solvents to be used for oleaginous liquid generally include organic solvents, and preferably include saturated hydrocarbon solvents (i.e., aliphatic saturated hydrocarbon solvents and saturated alicyclic hydrocarbon solvents) and more preferably include one or two or more selected members of saturated hydrocarbon solvents having a boiling point of 180 ° C to 310 ° C. Specific examples of such saturated hydrocarbon solvents include Solvent H No. 0 (produced by Nippon Oil Corporation), Solvent M No. 0 (produced by Nippon Oil Corporation), Solvent L No. 0 (produced by Nippon Oil Corporation), Normal Paraffin (produced by Nippon Oil Corporation), Solvent IP 2028 (produced by Idemitsu Kosan Co., Ltd.), Norpar 12 (produced by ExxonMobil Chemical), Norpar 13 (produced by ExxonMobil Chemical), Norpar 15 (produced by ExxonMobil Chemical), Isopar M (produced by ExxonMobil Chemical), Isopar L (produced by ExxonMobil Chemical), Isopar V (produced by ExxonMobil Chemical), Exxol D80 (produced by ExxonMobil Chemical), Exxol D110 (produced by ExxonMobil Chemical) and Exxol D130 (produced by ExxonMobil Chemical).

In order to control the vaporization of an insecticidal liquid, a high boiling solvent having a boiling point of 300 ° C or greater, for example, can be added to the insecticidal liquid. Specific examples thereof include esters or derivatives of fatty acid, such as isopropyl laurate, dibutyl phthalate, dibutyl sebacate, tributyl acetyl citrate and medium chain fatty acid triglyceride, higher alcohols such as octyldodecanol and oils and fats, such as like corn oil.

Examples of the solvents to be used for aqueous liquids include a solvent obtained by adding to the water a surfactant that vaporizes at 100 ° C to 180 ° C, which is a heating temperature range with a heater as disclosed in JP 3-7207 A, and a liquid obtained by adding to water a hydrophilic organic solvent which has a relatively low molecular weight and a boiling point within the range of 100 ° C to 300 ° C and which vaporizes at the time of heating as disclosed in JP 7-316002 A. To the mixed liquid of such hydrophilic organic solvent and water, hydrophilic diol compounds, hydrophilic alcohol compound, etc., can be added as a vaporization regulator.

The insecticidal device of the present invention has a wick of the present invention. So, if the wick has to absorb an insecticidal liquid and the absorbed liquid is then heated to be released in the form of vapor from the surface of the wick, the shape of the wick is maintained and the device can stably absorb and vaporize the liquid and quickly.

The vapor release method of the present invention can be carried out, for example, as an insecticidal method using an insecticidal liquid. In this exemplary embodiment, a vapor release method of the present invention is described using an insecticidal method as an example. In the insecticidal method of the present invention, a wick of the present invention is partially immersed in an insecticidal liquid containing an insecticidal component, so that the wick absorbs the liquid, and then the wick releases the absorbed liquid in the form of vapor from its surface. It is desirable, from the point of view of vaporization efficiency, to heat the wick that absorbs the insecticidal liquid. In an exemplary embodiment, a wick is partially immersed in an insecticidal liquid and an immersed portion of the wick is partially heated. The insecticidal method of the present invention can also be carried out using the aforementioned insecticidal method of the present invention. Since the insecticidal method of the present invention uses a wick of the present invention, an insecticidal effect is developed rapidly and the insecticidal effect can last stably.

[Steam release kit]

A vapor release kit of the present invention can be used, for example, as a kit for insecticidal applications. In this exemplary embodiment, a steam release kit of the present invention is described using an insecticide kit as an example. The kit for insecticidal applications is characterized by comprising a structural body of the present invention to be used as a wick. The insecticidal application kit preferably has an insecticidal liquid containing an insecticidal component. The insecticidal component can be one selected from those provided above as examples of the insecticidal component to be contained in the aforementioned insecticidal device. The kit for insecticidal applications of the present invention has at least one wick of the present invention. This makes it possible to improve the stability of the wick shape in liquid while maintaining the wick's liquid absorption ability. As a result, stable and rapid absorption and vaporization of liquid can be achieved.

The present invention will be described in more detail below with reference to the Examples, but the invention is not limited to the Examples. [Examples] [1. Preparation of wick]

A piece of KIMWIPES (trademark WIPER S-200 (100% pulp, 215 mm x 120 mm in size, produced by NIPPON PAPER CRECIA Co., Ltd.) was folded in half on its longest sides and then tightly rolled from an edge of it to a columnar shape. This was cut to a length of 73 mm in accordance with the height of the heating device. Then, base material A was prepared. The base material weighed 0.6 g. a PET film was wrapped around the base material so that the film could cover the base material and the coiled end was fixed with adhesive tape. in a glass tube 50 cm ³ were placed 10 cm ³ of colloidal silica liquid (SNOWTEX 20 produced by Nissan Chemical Industries, Ltd.) having an average particle diameter of 20 nm and a solid concentration of 20% by weight. Base material A was left with its lower end (1 cm long) immersed in the colloidal silica liquid. nutes later, the base material A was taken from the colloidal silica liquid and kept horizontally overnight. Then, the PET film was removed and the base material was allowed to rest until it dried completely. The material then obtained is left to be wick A. Wick A weighed 1.2 g after drying and the amount of bound silica particles was 50% by weight.

Subsequently, wick B was prepared in the same manner as in the preparation of wick A except that a base material was immersed in a colloidal silica liquid (SNOWTEX ZL produced by Nissan Chemi19 cal Industries, Ltd.) having an average particle diameter of 70 nm and a solid concentration of 40% by weight. Wick B weighed 2.3 g after drying and the amount of bound silica particles was 74% by weight.

The analysis results for wick B are shown in figures 2 and

3. Figure 2 is a diagram showing the results of mapping SiO ₂ through a ΕΡΜΑ (Electron Probe Micro Analyzer) of a cross section of the upper portion (that is, the end that has not been immersed in the colloidal silica liquid) of the wick B. In figure 2, an electron image of retrograde diffusion (BSE) is shown on the left and a Si mapping image of the same part is shown on the right. As shown in figure 2, many silica particles are added to the fibers of the wick B base material.

Figure 3 is a diagram showing an electron microscope image of wick B. In figure 3, an image obtained at an acceleration voltage of 10.0 kV and a magnification of x10.0 k is shown on the upper left, an image obtained at an acceleration voltage of 10.0 kV and a magnification of x50.0 k is shown on the upper right, and an image obtained at an acceleration voltage of 10.0 kV and an magnification of x100.0 k is shown on the left bottom. As shown in Figure 3, many particles of silica aggregate and bond to the fibers in the base material so that the fibers of the base material cannot be seen.

Subsequently, wick C was prepared in the same manner as in the preparation of wick A except that a base material was immersed in a colloidal silica liquid (SNOWTEX XS produced by Nissan Chemical Industries, Ltd.) having an average particle diameter of 5 nm and a solid concentration of 20% by weight. Wick C weighed 1.4 g after drying and the amount of bound silica particles was 57% by weight.

The results of analysis of wick C are shown in figures 4 to 6. Figure 4 is a diagram showing the results of mapping SiO ₂ through a ΕΡΜΑ of a cross section of the upper portion (that is, the end that was not immersed in the colloidal silica liquid) from wick C. Figure 5 is a diagram showing the results of mapping SiO ₂ by por of a cross section of the lower portion (that is, the end that has been immersed in the colloidal silica liquid) of the wick C. In figures 4 and 5, an electronic retrograde diffusion (BSE) image is shown on the left and a Si mapping image of the same part is shown on the right. As shown in figures 4 and 5, many silica particles are added in both the upper and lower portions in the fibers of the wick C base material.

Figure 6 is a diagram showing an electron microscope image of wick C. In figure 6, an image obtained at an acceleration voltage of 10.0 kV and an enlargement of x10.0 k is shown on the upper left, an image obtained at an acceleration voltage of 10.0 kV and a magnification of x50.0 k is shown on the upper right and an image obtained at an acceleration voltage of 10.0 kV and an magnification of x100.0 k is shown on the lower left . As shown in figure 6, so many silica particles aggregate and bond to the fibers of the base material that the fibers of the base material cannot be observed.

Subsequently, wick D was prepared in the same manner as in the preparation of wick A except that a base material was immersed in a colloidal silica liquid prepared by mixing a colloidal silica liquid (SNOWTEX 20 produced by Nissan Chemical Industries, Ltd.) having an average particle diameter of 20 nm and a colloidal silica liquid (SNOWTEX SX produced by Nissan Chemical Insdustries, Ltd.) having an average particle diameter of 5 nm in a 1: 1 ratio to adjust the solid concentration to 20 % by weight. Wick D weighed 1.4 g after drying and the amount of bound silica particles was 57% by weight in total.

Wick E was prepared in the same way as in the preparation of wick A except for the use of a cigarette filter (24 mm perimeter, cut to a length of 70 mm, 0.4 g in weight) in place of the base material A The wick E weighed 1.2 g after drying and the amount of bound silica particles was 67% by weight. As a comparative example, a commercially available talc wick (7 mm in diameter and 73 mm in length) was used as F wick.

[2. Preparation of a solvent for insecticidal liquid]

An oleaginous solvent was prepared using a mixed solvent (Norpar 13 / Norpar 15 = 7peso / 3peso) composed of Norpar 13 (produced by ExxonMobil Chemical Co., Ltd.) and Norpar 15 (produced by ExxonMobil Chemical Co., Ltd.), both being commercially available saturated hydrocarbon solvents. An aqueous solvent was prepared using a mixed solvent (2- (2-butoxyethoxy) ethanol / water = 7 weight / 3 weight) composed of 2- (2-butoxyethoxy) commercially available ethanol and water.

[3. Hot steam release device]

Measurement of the vaporization rate of each wick was performed using a hot steam release device such as the one shown in figure 1. Here, the used reservoir 4 was commercially available in a 55 mm high cylindrical shape made of transparent plastic , having a bottom inner diameter of 40 mm, a height for the curvature of the bottle of 35 mm and an inner diameter of 16 mm. As the wick support (not shown) for wick support one was used which was made of a soft plastic material with a lid shape provided with a hole that was 7 mm in diameter in accordance with the outside diameter of the wick 1 and which can seal the chemical solution bottle 4 so that the chemical liquid with which the bottle is filled would not leak or escape.

As a ring-shaped heater 2 to indirectly heat the upper surface of the wick 1 projecting from the reservoir 4, a 15 mm wide piece of metal that had been rounded to form a ring having an internal diameter of 10 mm was used. A heater support 3 to support heater 2 was located at a height of 60 to 75 mm from the bottom of the bottom of the chemical liquid, namely, a position that corresponded to the upper portion of the wick 1. Heater 2 was adjusted to have a temperature of around 130 ° C by applying electric current.

[4. Vaporization rate measurement]

Reservoir 4 was loaded with 30 g of the oleaginous solvent prepared using the procedure described above. Wicks A to F were each adjusted so that their end could be immersed in the oleaginous solvent and would come in contact with the bottom of reservoir 4. Then, the total weight was measured. Reservoir 4 was heated to about 130 ° C. A vaporization rate was calculated by weighing reservoir 4 at each passing moment until all the oil solvent was exhausted5. The results are shown in Table 7. As shown in figure 7, wicks A-F each sprayed the oleaginous solvent at a constant rate until the solvent in bottle 4 had been exhausted.

Then, using an aqueous solvent instead of the oleaginous solvent, the vaporization rate measurement was performed in the same manner as above for wicks A and F. The results were shown in Table 1. As shown in figure 8, the wick A vaporized the aqueous solvent at a constant rate until the solvent in bottle 4 had been exhausted as in the case of using an oleaginous solvent. The vaporization rate of wick F could not be measured because the wick dissolved immediately after being immersed in the aqueous solvent.

The average vaporization rates of the respective wicks are given in Table 1.

Table Wick Material base Inorganic particles % in Reason for Link Vaporization rate mean mg / h Example 1 Net o- leaginous Example 2 Net a- quoso THE KIMWIPE Colloidal Silica, average particle diameter = 20 nm 50 142 215 B KIMWIPE Colloidal Silica, average particle diameter = 70 nm 74 125

Wick Material base Inorganic particles % in Reason for Link Vaporization rate mean mg / h Ç KIMWIPE Colloidal Silica, mean particle diameter = 5 mm 57 118 D KIMWIPE Colloidal Silica, mean particle diameter = 20 nm mixture, 5 nm 57 128 AND Filter Colloidal Silica, average particle diameter = 20 nm 67 160 F Baby powder 143 Can not to be used

As shown in Table 1, wicks A-E, which are in accordance with the present invention, exhibited the ability to release steam equivalent to conventional wick F. In addition, while conventional wick F was dissolved in an aqueous solvent and therefore could not be used, wick A of the present invention exhibited excellent and stable vapor release ability even when the aqueous solvent was used.

Industrial Applicability

According to the present invention, a structural body that can stably absorb and vaporize liquid for a long period of time. The structural body can then be used appropriately for vaporizers that absorb and vaporize various insecticidal solutions, flavoring solutions, deodorizing solutions and the like.

Claims (17)

1. Structural body comprising: particles, and a fibrous structural body, 5 characterized by the fact that at least part of the particles is present in the form of an aggregate attached to the fibrous structural body. Structural body according to claim 1, characterized by the fact that the particles have an average particle diameter from 1 to 500 nm. 10 Structural body according to claim 1 or 2, characterized in that the particles are inorganic particles. Structural body according to claim 3, characterized by the fact that the inorganic particles are silica. 5. Structural body according to any of the claims 15 1 to 4, characterized by the fact that the fibrous structural body is paper, woven fabric or non-woven fabric. Structural body according to any one of claims 1 to 5, characterized in that the fibrous structural body is columnar in shape. 20 7. Vapor release device (5) comprising: a reservoir (4) containing a vaporizable liquid, and a wick (1), characterized by the fact that the wick (1) is made of the structural body as defined in any one of claims 1 to 6, and the wick (1) being 25 located in such a way that a part of the wick (1) is immersed within the vaporizable liquid and the other part of the wick is exposed to the outside of the reservoir (4). 8. Vapor release device (5) according to claim 7, characterized by the fact that it has 30 heating (2) for heating a portion of the wick (1), the portion being exposed to the outside of the reservoir. 9. Vapor release device (5) according to Petition 870170090594, of 11/23/2017, p. 7/13 claim 7 or 8, characterized by the fact that the vaporizable liquid comprises an insecticidal component, an organic solvent and water. 10. Vapor release device (5) according to claim 9, characterized by the fact that the insecticidal component is a 5 pyrethroid compound. 11. Steam release method, characterized by the fact that it comprises the following actions: immersing a part of the structural body as defined in any one of claims 1 to 6 in a vaporisable liquid, 10 causing the structural body to absorb the liquid, and releasing, from a surface of the structural body, steam generated from the absorbed vaporizable liquid. 12. Method for producing a structural body, characterized by the fact that it comprises: 15 an absorption step of bringing at least part of a fibrous structural body in contact with a dispersion liquid, in which particles are dispersed in a liquid medium, thereby causing the fibrous structural body to absorb the dispersion liquid, and a removal step removing the liquid medium from the 20 fibrous structural body that absorbed the dispersion liquid. 13. Method according to claim 12, characterized by the fact that in the absorption step the act of bringing at least part of a fibrous structural body in contact with a dispersion liquid is carried out by immersing at least part of the structural body fibrous in the liquid 25 dispersion. 14. Method according to claim 13, characterized by the fact that the fibrous structural body is in a columnar shape and in the absorption stage the act of bringing at least part of a fibrous structural body in contact with a dispersion liquid through immersion of 30 a longitudinal end portion of the fibrous structural body in the dispersion liquid. 15. Method according to any one of claims 12 to Petition 870170090594, of 11/23/2017, p. 8/13 14, characterized by the fact that in the removal step, the removal of the liquid medium from the fibrous structural body that absorbed the dispersion liquid is carried out by drying the fibrous structural body. 16. Method according to any one of claims 12 to 5 15, characterized by the fact that the absorption step and the removal step are repeated until the proportion of particles that were contained in the fibrous structural body becomes 10 to 95% by weight, as long as the structural body weight is left be 100% by weight. 17. Method according to any one of claims 12 to 10 16, characterized by the fact that the concentration of the particles in the dispersion liquid is 1 to 50% by weight. Petition 870170090594, of 11/23/2017, p. 9/13 1/7