JP2022190968A - deodorant - Google Patents

Abstract

To provide a simple deodorant excellent in deodorizing properties that can eliminate odorous components in a short period of time without receiving light on a wide range of various types of odorous components, capable of not only sustaining a deodorizing action for a long time and capable of repeatedly being used but also reused, by recovering the deodorant properties, having white color or pale color and not disturbing coloration of a base component, and containing deodorant components capable of deodorizing by using as it is or using by carrying on an aqueous solution, gel, a solid activator or fibers.SOLUTION: A deodorant material has a hydroxide layer containing one kind of metal element, and cations, anions, and/or water molecules are intercalated between the layers, and layered double hydroxide that intercalates, or adsorbs, or decomposes a deodorizing component is contained as a deodorant component.SELECTED DRAWING: None

Description

TECHNICAL FIELD The present invention relates to a deodorant material containing a layered double hydroxide as a deodorant component that deodorizes and deodorizes various odor components (hereinafter both are collectively referred to as deodorant).

Removes body odors and daily life odors emitted from humans and pets, space odors such as bad odors in rooms, vehicles, work sites, factories, etc., and liquid or solid odors emitted from waste liquids, sewage, chemical substances, etc. Various deodorants and deodorizing devices are used to reduce or eliminate odors

Various types of deodorizing measures are taken for deodorizing. For example, physical adsorption of odorous components by adsorbents with large surface areas such as activated carbon for various odorous components, and chemical adsorption of odorous components by adsorbents such as calcium carbonate for acidic odor components and aluminum sulfate for basic odor components. Adsorption means are commonly used for industrial or household deodorant product applications. In addition, among titanium oxides, photocatalyst chemical deodorants such as highly active anatase type titanium oxide, or decomposing/removing means for chemically decomposing or changing odorous components by ultraviolet irradiation, ozone generation, etc. Are known. Furthermore, there are also masking means for masking unpleasant odors with perfumes, fragrances, aromatic agents, etc., so that good smells are preferentially sensed with the sense of smell, and pairing means for incorporating malodorous components into aromatic components. Alternatively, there is a microbial deodorizing means that uses bacteria, enzymes, or activated sludge to decompose organic matter in garbage or sewage, or uses an antibacterial agent to suppress the growth of putrefactive bacteria. Deodorization is mostly carried out by any one of these means or a combination of any of them.

Activated carbon, which is a physical adsorption deodorant, is used in applications that do not require coloring because it is black and blocks the coloring of the material. Although it can adsorb a wide range of odor components, it cannot be used as a fabric for white or colored clothes, furniture, or automobiles.

Chemically adsorbed deodorants such as calcium carbonate and aluminum sulfate utilize an acid-base reaction, so they are specific to specific odor components, but on the other hand, the odor components that can be deodorized are limited.

Further, Patent Literature 1 discloses a pet urine treatment material containing water-absorbing granular materials and non-disintegrating moisture-controlling granular materials mainly composed of zeolite. The patent document describes that in addition to deodorizing additives such as water-soluble copper compounds, metal salts having deodorizing properties (eg, zinc chloride, silver nitrate, aluminum sulfate, etc.) may be contained. Further, US Pat. No. 6,200,000 discloses a liquid oral composition comprising a thickening agent and an abrasive. The same patent document describes that a deodorant such as zinc chloride may be contained. Since the metal salts such as zinc chloride described in these patent documents are water-soluble, the pet urinary treatment material of Patent document 1 and the liquid oral cavity composition of Patent document 2 are disposable and exhibit deodorizing properties. It is not intended to be reused for

Photocatalyst agents such as active titanium oxide decompose odorous components, bacteria, viruses, dirt, etc. when exposed to light energy. .

Masking and pairing do not inherently remove odor components. In addition, the microbial deodorizing means is used in vast large-scale facilities such as sewage treatment and industrial wastewater treatment, and is difficult to apply to general-purpose items such as daily necessities.

Ultraviolet irradiation and ozone generation, which are non-pharmaceutical deodorizing means, not only require large-scale equipment, but also cannot be directly exposed to the human body because exposure to large amounts of ultraviolet rays and ozone adversely affects the human body.

A deodorant that can be used against a wide range of odor components, has excellent persistence, repeatability and reusability, does not interfere with the essential properties of products such as coloring, and can be used in liquid, gel, and solid forms. was desired.

Japanese Patent Application Laid-Open No. 2021-23163 JP 2019-199466 A International Publication No. 2016/199905A1 JP 2015-38014 A

The present invention has been made to solve the above-mentioned problems. Not only can it last for a long period of time, it can be used repeatedly and continuously, it can be reused by recovering the deodorant property, it is white or light in color and does not interfere with the coloring of the base component, and it can be used as it is or in an aqueous solution. To provide a simple deodorizing material containing a deodorizing component capable of deodorizing even when it is carried on a gel/solid activator, fiber, or the like and used. Another object of the present invention is to provide a simple method for preparing the deodorant component which is efficient, excellent in reproducibility and good in yield.

A deodorizing material made to achieve the above object has a hydroxide layer containing one kind of metal element, has cations, anions, and/or water molecules intercalated between the layers, and has an odor. It is characterized by containing a layered double hydroxide that intercalates, adsorbs, or decomposes components as a deodorizing component.

In this deodorant, the metal element is preferably divalent.

In this deodorant, it is more preferable that the metal element is zinc.

In the deodorizing material, it is more preferable that the layered double hydroxide is simon collite.

In this deodorant, the layered double hydroxide may be hexagonal plate-like, scale-like, flake-like, or amorphous.

In the deodorant, the layered double hydroxide may have an aspect ratio of 100:1 to 1:1.

This deodorant material is, for example, a deodorant containing the deodorant component as it is or contained in either a solid carrier or a liquid or gel fluid carrier, the deodorant component attached to a fabric, or They are impregnated deodorant fabrics, clothes, clothes, clothing or their fibers, or building materials, industrial products, or daily necessities containing the deodorant component.

The method for preparing the deodorant component of the present invention, which has been made to achieve the above object, comprises mixing an aqueous solution of a water-soluble salt of one kind of metal and an aqueous solution of an alkali metal hydroxide, followed by neutralization. A layered composite that has a hydroxide layer containing one kind of metal element and has cations, anions, and/or water molecules intercalated between the layers, and that intercalates, adsorbs, or decomposes odorous components. It is characterized by crystallizing the hydroxide.

The deodorant of the present invention has a wide range of odors such as acidic, basic such as amine, sulfur, neutral alcohol, aldehyde, etc. The ingredients can be deodorized.

This deodorizing material can reduce or eliminate odorous components in a short period of time of several minutes to several hours without being subjected to treatment such as light reception or heating to the extent of human skin, and has excellent deodorizing properties. .

This deodorizing material is economical and convenient because it can maintain its deodorizing action against various odorous components for a long period of time and can be used repeatedly. In addition, since the deodorizing component is water-insoluble or sparingly soluble, the deodorizing material can be reused repeatedly by washing, for example, by washing with water to recover the deodorizing property, and therefore, it is necessary to dispose of the material. Since it does not degrade the environment, it is also compatible with the Sustainable Development Goals (SDGs).

Since the deodorant component is white or pale in color, the deodorant does not interfere with the coloring of base materials such as fibers, which are used as necessary. It does not impair the desired design such as.

This deodorizing material exhibits an excellent deodorizing effect even when the deodorizing component is used as it is in powder or particle form, or when it is supported on an aqueous solution, gel, solid activator, fiber, or the like. Since it is expressed, it is versatile.

Since this deodorizing material exhibits a deodorizing function if it contains the deodorizing component, it can have a simple structure, and can be used in various fields such as daily products, industrial products, and deodorizing devices for plants. can.

In addition, the method for preparing the deodorant component of the present invention is simple and has a short process, without heat treatment, etc., and can prepare the deodorant component efficiently, with good reproducibility, and with a high yield. It is possible to prepare an arbitrary amount from to a large amount, and it is possible to contribute to the simple and inexpensive production of the deodorant.

1 is a graph showing the deodorizing rate for each malodorous component by the deodorizing material of Example 1 to which the present invention is applied. FIG. 10 is a graph showing the deodorizing rate for each malodorous component by the deodorizing materials of Example 2 to which the present invention is applied and Comparative Examples 2-1 and 2-2 to which the present invention is not applied; FIG. FIG. 10 is a graph showing the deodorizing rate for each malodorous component of the deodorant gel of Example 3 to which the present invention is applied and the deodorant gel of Comparative Example 3 to which the present invention is not applied. FIG. 10 is a graph showing the deodorizing rate for each malodorous component by the deodorizing material, which is the deodorizing film of Example 4 to which the present invention is applied, and the deodorizing material, which is the deodorizing film of Comparative Example 4 to which the present invention is not applied. 5 is a graph showing the re-release rate of each malodorous component from the deodorant material of Example 5 to which the present invention is applied and the deodorant material of Comparative Example 5 to which the present invention is not applied. 10 is a graph showing the elution rate of malodorous components into an aqueous solution after deodorization of malodorous components by the deodorizing material of Example 6 to which the present invention is applied. The elution rate of each malodorous component into the aqueous solution for each number of repetitions of deodorizing and washing with water by the deodorant of Example 7 to which the present invention is applied and the deodorant of Comparative Example 7 to which the present invention is not applied is It is a graph showing. FIG. 10 is a graph showing the deodorizing rate for each malodorous component by the deodorizing material for each thickness of Examples 8-1 to 8-2 to which the present invention is applied; FIG. FIG. 10 is a graph showing the deodorizing rate for each malodorous component by the deodorizing material for each shape of Examples 9-1 to 9-3 to which the present invention is applied, and electron micrographs of each shape. FIG. is. A graph showing the change over time in the deodorizing rate for each malodorous component in the deodorant material of Example 10-1 to which the present invention is applied and the deodorant materials of Comparative Examples 10-1 to 10-2 to which the present invention is not applied. be.

Modes for carrying out the present invention will be described in detail below, but the scope of the present invention is not limited to these modes.

The deodorizing material of the present invention contains a layered double hydroxide containing substantially only one kind of metal element as a deodorizing component.

Such a layered double hydroxide has a plurality of hydroxide layers each composed of a basic hydroxide layer.

In such a layered double hydroxide, since the hydroxide layer has a positive charge, it is mainly intercalated with negatively charged anions and water molecules and/or cations in some cases between the layers. It has a laminated structure.

Such a layered double hydroxide is one in which the metal element is a divalent metal, preferably zinc. More specifically, the following chemical formula (1)
[M ²⁺ _x (OH) _(2x−y) ][A ny _/n ^· zH ₂ O] (1)
(In formula (1), M ²⁺ is a cation of a divalent metal element, preferably a zinc ion; A ^n- is an n-valent (n is 1 to 3, preferably 1 or 2, more preferably 1) anion, preferably is a chloride ion, x=1 to 5, preferably 5, y is 1 to 10, preferably 2, z is 1 to 10, preferably 1 to 8, and more preferably 1). Note that the layered double hydroxide may be substantially represented by the chemical formula (1), and the M ²⁺ in the layered double hydroxide substantially contains only one kind of metal element. means that it can contain impure metal ions other than zinc consisting of divalent and/or trivalent metal ions in ppm order, for example, up to 10,000 ppm.

A more specific and preferred layered double hydroxide is Simonkollite or Simonkolleite. Simoncolite is also called basic zinc chloride (monohydroxide) and zinc hydroxychloride (monohydrate), and is Zn ₅ (OH) ₈ Cl ₂ ·zH ₂ O (z=1-8 ), such as Zn ₅ (OH) ₈ Cl ₂ .H ₂ O. As for such simon collite, for example, Patent Document 3 discloses a skin wound or rough skin treatment agent containing zinc chloride hydroxide hydrate such as simon collite, and Patent Document 4 discloses Zn ₅ (OH) ₈ Examples of use in cosmetics containing flaky powder represented by Cl ₂ ·nH ₂ O (n = 1 to 8) are known, but it has not been known to have a deodorizing action.

The layered double hydroxide may be hexagonal plate-like, scale-like, flake-like, or amorphous, but the shape is not particularly limited.

This layered double hydroxide preferably has a hexagonal plate shape, and the average crossing diameter (length: L) of the hexagonal plane of the hexagonal plate crystal and the average height (thickness) in the direction perpendicular to the hexagonal plane The aspect ratio L:H, which is the ratio of L:H), is 100:1 to 1:1, preferably 20:1 to 1:1, more preferably 20:1 to 10:1, and even more preferably 10±2 : 1, more preferably 10:1, excellent deodorizing action can be exhibited against a wide range of odorous components such as acidic, basic such as amine, sulfur and neutral.

This layered double hydroxide has an average particle size of several 100 to several μm, which is determined by selecting arbitrary 10 particles among the particles measured by scanning electron microscope (SEM) observation. is preferably 50 to 0.5 μm, more preferably 20 to 1 μm, and even more preferably 10 μm. When the average particle diameter is within this range, there is a feature that the deodorant effect is exerted on a wider range of odor components (eg, methyl mercaptan, trimethylamine, etc.).

Although the details of the mechanism by which this layered double hydroxide functions as a deodorizing component are not necessarily clear, it is speculated as follows.

The anions A ^n- and water molecules H ₂ O that are originally intercalated between the layers of the hydroxide layers in the layered double hydroxide are replaced or not replaced, and the acidic/basic or neutral odor components In particular, acid-based odor components such as fatty acids, amine-based or base-based components such as ammonia gas and alkylamines, alcohol-based components such as fatty alcohols, or neutral-based odor components such as aldehyde-based components such as fatty aldehydes. It is presumed that the mechanism is that these odorous components are deodorized by adsorption due to intercalation by substitution or electrostatic interaction. This is common to most of the odorous ingredients, and the odorous ingredients intercalated in the layered double hydroxide do not separate from the layers as they are, but they separate from the layers when the deodorant is washed with water. Therefore, it seems that the intercalation-deintercalation occurs between the layers with a weak intermolecular force. However, since not all of the odorous components are removed and recovered by washing with water, it is presumed that some of them are decomposed by the metal elements of the layered double hydroxide.

On the other hand, among odorous components, sulfur-based odor components cannot be recovered even if they are washed with water after deodorization by treatment with layered double hydroxide. The calating anions A ^n- and water molecules H ₂ O are intercalated while chemically reacting sulfur-based odor components into ZnS-based compounds, with or without replacement, or sulfur-based odor components. It is presumed that deodorization is carried out by decomposing the components or oxidizing them into sulfonic acid components that do not emit offensive odors.

Such a layered double hydroxide, which is a deodorizing component, is prepared by mixing one of an aqueous solution of a water-soluble salt composed of one kind of metal, such as an aqueous zinc chloride solution, and an aqueous solution of an alkali metal hydroxide, such as an aqueous sodium hydroxide solution, into the other. For example, after dropping or pouring, neutralize with an inorganic acid such as hydrochloric acid, and then, if necessary, leave still to crystallize the layered double hydroxide, for example, for 0 to 24 hours to grow crystals. Prepared by

In addition, the preparation method thereof is that the zinc chloride hydroxide hydrate in Cited Document 3 is produced by aging for a certain period of time using a zinc salt aqueous solution and an alkaline aqueous solution, using an inorganic acid as a pH adjuster. It is different in that

This layered double hydroxide can be prepared in a hexagonal plate shape by using an aqueous zinc chloride solution as an aqueous solution of a water-soluble salt of one kind of metal, and an aqueous sodium hydroxide solution as an aqueous solution of an alkali metal hydroxide. Furthermore, by controlling the standing time, it is possible to prepare crystals with various thicknesses such as 0.5 μm thickness and 1.0 μm thickness. By changing the water-soluble aqueous solution of metal from zinc chloride to zinc iodide, flakes can be prepared, and irregular shapes can be prepared.

The deodorizing material of the present invention may be used as a deodorizing agent by itself as a deodorizing component or by mixing or adding additives other than a carrier by internal or external addition. Examples of additives in that case include polyethylene oxide and carboxymethyl cellulose.

The deodorizing material of the present invention is a powdery, bead-like, tablet-like, stick-like, sheet-like, plate-like, or rectangular solid deodorant contained in a solid carrier such as an excipient such as a resin. It may also be used as a liquid deodorant such as a spray contained in a liquid carrier such as water, alcohol, or any mixture thereof and optionally mixed with the above additives. . Alternatively, the deodorant material contains a deodorizing component mixed with a gel-like fluid carrier such as κ-carrageenan by internal or external addition, and if necessary, the additive is internally or externally added. It may be used as a gel deodorant that may be mixed. The deodorizing material contains a deodorizing component and a semi-kneaded component mixed internally or externally, and if necessary, the additives are mixed internally or externally to make a semi-kneaded toothpaste. It may be used as a paste-like deodorant such as.

The deodorizing material of the present invention comprises a deodorizing component and, if necessary, additives such as dyes, dyes, pigments, etc., which are externally added to paper or fabric such as woven fabric or non-woven fabric, or internally added by impregnation. It may also be used as deodorant materials such as deodorant paper and deodorant fabric, for example, fabrics, fabrics, clothes, sheets, blankets, curtains, covering materials for chairs or sofas, rugs, carpets, and the like.

The deodorant material of the present invention is produced by mixing the deodorant component and, if necessary, the above-mentioned additive with various base materials by internal or external addition, thereby producing a building material containing the deodorant component, such as a wall material. , Wallpaper, ceiling materials, flooring materials, tatami mats, flooring, air conditioning equipment filters, etc. Industrial products containing the deodorant component, such as exhaust gas and waste liquid treatment filters or filter units, water purifiers It may be used as a water filter, interior material for automobiles and vehicles, and daily necessities containing the deodorant component, such as futons, floor cushions, cushions, clothes deodorant spray, room deodorant spray, toothpaste, and bad breath preventatives. , Body odor prevention deodorants, pet sheets, and other daily necessities, clothing such as shirts, sweaters, and underwear, clothing products such as clothing, and fibers thereof.

Hereinafter, deodorant materials of examples to which the present invention is applied and deodorant materials of comparative examples to which the present invention is not applied will be described in detail.

(Working Preparation Example 1)
300 ml of 40% sodium hydroxide (NaOH) aqueous solution in a 1000 ml reaction vessel was set to 70°C, 400 ml of 25% by weight zinc chloride (ZnCl ₂ ) aqueous solution was added at once, and the temperature was set to 70°C and normal pressure was added. for 30 minutes. After that, 35 v/v% hydrochloric acid was added dropwise with stirring so that the pH was 7.0, and Zn ₅ (OH) ₈ Cl ₂ ·zH ₂ O (z = 1 to 8), which is a layered double hydroxide, was added. Simoncolite was synthesized and crystals were deposited, and the mixture was allowed to stand at room temperature for 6 hours to grow simoncolite crystals into hexagonal plate-like crystals. The hexagonal plate crystals of simoncolite, which is a deodorizing component, was filtered and the residue was dried in a dryer at 90° C. to obtain a powder of simoncolite hexagonal plate crystals. This hexagonal plate crystal simoncolite has an aspect ratio L, which is the ratio of the average crossing diameter (length: L) of the hexagonal faces to the average height (thickness: H) in the direction perpendicular to the hexagonal faces. H is 10:1, and the average particle size of the average particle size length L obtained by randomly selecting 10 particles out of the particles measured by scanning electron microscope (SEM) observation is 10 μm. rice field. It was used as a test sample in Preparation Example 1, which is a deodorant component (or deodorant or deodorant) consisting only of simoncollite hexagonal plate crystals.

(Evaluation test 1 for deodorant properties against various malodorous gases: Example 1 and Comparative Example 1 (control example))
Deodorant test method 1 for evaluating the deodorizing effect of various malodorous gases as odorous components is as follows. As Example 1, (1-i) a solution of hydrogen sulfide prepared by dissolving the gas generated by heating solid hydrogen sulfide in distilled water was introduced into a separate 300 ml sealed container, and the odor was reduced to 10 ppm. (1-ii) introduce a solution of methyl mercaptan prepared by diluting the methyl mercaptan standard solution to adjust the odor concentration to 20 ppm, and (1-iii) dilute 25-30% aqueous ammonia. (1-iv) introducing a solution of trimethylamine prepared by diluting a 30% trimethylamine solution to adjust the malodor concentration to 25 ppm, ( 1-v) A solution of isovaleric acid prepared by diluting a 99% isovaleric acid solution is introduced to adjust the malodor concentration to 40 ppm, and (1-vi) 99% isobutanol is introduced to adjust the malodor concentration to 80 ppm. It was adjusted. In an airtight container, 0.25 g of the test sample, which is a deodorizing material consisting only of the simoncolite hexagonal plate crystals prepared in Preparation Example 1, is placed in a 500 ml Erlenmeyer flask and sealed with a rubber stopper. Enclosed with Using a syringe, 0.1 to 2.0 ml of each malodorous solution was injected through the gap of the rubber plug so as to obtain a predetermined malodorous concentration, and after a predetermined period of time (2 hours in Evaluation Test 1), each malodorous concentration was measured.
As Comparative Example 1 (control example), the malodor concentration was measured in the same manner as in Example 1, except that Simoncolite was not used and the malodor concentration was measured immediately after the malodorous gas was injected.
For 2 hours after each Example 1 and Comparative Example 1 (control example), measurement detector tubes manufactured by AS ONE Corporation: (1-i) hydrogen sulfide 4LK, 4LT, (1-ii) methyl mercaptan 71, (1 -iii, iv) Amines 180, (1-v) acetic acid 81, (1-vi) isobutyl alcohol 116 were used, and each detector tube was used to measure the odor concentration using a detector tube gas meter. . For each malodorous gas, the rate of decrease in the malodorous gas concentration in each Example 1 after 2 hours with respect to the malodorous gas concentration in Comparative Example 1 (control example) was calculated as the deodorizing rate. The results are collectively shown in FIG.

As is clear from FIG. 1, the deodorant containing Simoncolite to which the present invention is applied has a wide range of sulfur-based odor components, nitrogen-based odor components, acidic odor components, and alcohol-based odor components. It was found to have a deodorizing effect.

(Comparative Preparation Example 2-1)
Activated carbon with the product name Kuraray Coal KW manufactured by Kuraray Co., Ltd. and the deodorant component (deodorant/deodorant material) of Comparative Preparation Example 2-1 were used as Comparative Test Sample 1-1.

(Comparative Preparation Example 2-2)
The product name KESMON NS-10 (active ingredient: zirconium phosphate), a deodorant manufactured by Toagosei Co., Ltd., which shows a deodorant effect specifically to amine-based odor components, was used as the deodorant component of Comparative Preparation Example 2-2. (Deodorant/Deodorant) was used as Comparative Test Sample 2-2.

(Deodorant test 2 for various malodorous gases: Example 2, Comparative Examples 2-1 and 2-2, and Control Example)
Using a deodorizing material containing Simoncolite to which the present invention is applied as a deodorizing component, and using hydrogen sulfide, methyl mercaptan, and isovaleric acid as odor components in Example 1, Example 2 is deodorized. Evaluation was made in the same manner as in Sex Test 1. On the other hand, using a deodorant made of activated carbon, which is the comparative test sample 1-1 of Comparative Preparation Example 1-1, and a deodorant made of kesmon, which is the comparative test sample 1-2 of Comparative Preparation Example 1-2, were compared. Examples 2-1 and 2-2 were evaluated in the same manner as deodorant test 1. A control example was also tested in the same manner as in Example 1. The deodorizing results are summarized in FIG.

As is clear from FIG. 2, the deodorant of Example 2, which uses Simoncolite to which the present invention is applied, as a deodorant component, has a sulfur-based odor component, a nitrogen-based odor component, and an acidic odor component. It exhibited a deodorant effect equal to or greater than that of the activated carbon of 2-1. On the other hand, in Comparative Example 2-2 using kesmon as test sample 2, there was no effect on sulfur-based odor components, whereas in Example 2, almost complete deodorizing effect was exhibited. Further, Comparative Example 2-2 exhibited a considerable deodorizing effect against acid-type smell components, although it could not be said to be complete, while Example 2 exhibited a complete deodorizing effect.

(Working Preparation Example 3)
The simoncolite hexagonal plate crystals obtained in Preparation Example 1 were used as a deodorizing component. 0.25 g of a deodorant component, 2.0 g of Adekatol LB (manufactured by ADEKA Corporation), and 2.5 ml of ethanol are added to a 50 ml beaker (i), and 0.1 g of potassium chloride, 1.5 g of diethylene glycol are added to a 50 ml beaker (ii), and distilled. 13.8 ml of water was added, 0.8 g of κ-carrageenan and 30 ml of distilled water were added to a 50 ml beaker (iii), and each was allowed to stand in a 70° C. dryer to dissolve each raw material. While stirring the 50 ml beaker (iii) at 70 ° C. and 400 rpm, the solutions of 50 ml beakers (i) and (ii) are added to (iii) respectively to obtain a deodorant gel containing simoncolite hexagonal plate crystals. The deodorant material was used as a test sample for Example 3 of the preparation.

(Comparative Preparation Example 3)
A deodorant gel that is a deodorant gel containing activated carbon was prepared in the same manner as the deodorant gel that is the deodorant gel of Example Preparation Example 3, except that activated carbon with the product name Kuraray Coal KW manufactured by Kuraray Co., Ltd. was used. , was used as a test sample for Comparative Preparation Example 3.

(Evaluation test 3 for deodorant properties in gel form against various malodorous gases: Example 3, Comparative Example 3, and Control Example)
Using 50 g of a deodorant gel (of which 0.25 g of the deodorant component) is a deodorant gel containing Simoncolite to which the present invention is applied as a deodorant component, hydrogen sulfide, ammonia, trimethylamine, Example 3 was obtained using isovaleric acid, and was evaluated in the same manner as in deodorant test 1. On the other hand, Comparative Example 3 was prepared using the deodorant material, which is a deodorant gel containing activated carbon, which is Comparative Test Sample 3 of Comparative Preparation Example 3, and was evaluated in the same manner as in Deodorant Test 1. A control example was also tested in the same manner as in Example 1. The deodorizing results are summarized in FIG.

As is clear from FIG. 3, in Example 3 of the deodorant material, which is a deodorant gel containing simoncolite hexagonal plate crystals to which the present invention is applied, all of hydrogen sulfide, ammonia, trimethylamine, and isovaleric acid are activated carbon. The deodorizing effect was higher than that of Comparative Example 3 of the deodorizing material, which is a deodorizing gel containing This is because the activated carbon having a high surface area of activated carbon was covered with a gel and could not exhibit a sufficient deodorant effect. It is presumed that the deodorant effect was exhibited by intercalating or trapping as sulfide.

(Working Preparation Example 4)
A deodorizing component consisting only of simoncolite hexagonal plate crystals obtained in Preparation Example 1 was used. 0.75 g of the deodorizing component, which is the simoncolite hexagonal plate crystals obtained in Preparation Example 1, is kneaded into 7.5 g of polyethylene resin and pressed with a press to form a deodorizing material, which is a deodorizing film having a thickness of 100 μm. , was used as a test sample for Example 4 of preparation.

(Comparative Preparation Example 4)
A deodorant film containing kesmon in the same manner as the deodorant material that is the deodorant film of Example Preparation Example 4, except that KESMON NS-10, a deodorant manufactured by Toagosei Co., Ltd. was used. The material was used as a test sample for Comparative Preparative Example 4. Since activated carbon is black and cannot be colored, it is not used as a comparative example because it is less necessary for use as a deodorizing material that is a deodorizing film.

(Evaluation Test 4 for Deodorizing Properties in Film Form Against Various Odorous Gases: Example 4, Comparative Example 4, and Control Example)
Using 1.0 g of deodorizing material (of which 0.01 g of deodorizing component), which is a deodorizing film containing Simoncolite to which the present invention is applied, as a deodorizing component, hydrogen sulfide and methyl mercaptan were used as odor components in Example 1. was used as Example 4 and evaluated in the same manner as in the deodorant test 1. On the other hand, Comparative Example 4 was prepared using the deodorizing material which is a deodorizing film containing kesmon, which is Comparative Test Sample 4 of Comparative Preparation Example 4, and was evaluated in the same manner as in Deodorant Test 1. A control example was also tested in the same manner as in Example 1. The deodorizing results are summarized in FIG.

As is clear from FIG. 4, in Example 4 of the deodorizing material, which is a deodorizing film containing simoncolite hexagonal plate crystals to which the present invention is applied, both hydrogen sulfide and methyl mercaptan had a high deodorizing effect. On the other hand, Comparative Example 3 of the deodorizing material, which is a deodorizing film containing kesmon, had no deodorizing effect at all. Therefore, in Example 4, the deodorant effect was significantly higher than that of the deodorant material containing an inorganic deodorant component such as in Comparative Example 4.

(Working Preparation Example 5)
The deodorizing material, which is a deodorizing component consisting only of simoncolite hexagonal plate crystals obtained in Preparation Example 1, was used as a test sample in Preparation Example 5.

(Comparative Preparation Example 5)
A deodorizing material, which is a deodorizing component consisting only of Kuraray Coal KW, which is an activated carbon manufactured by Kuraray Co., Ltd., was used as a test sample in Comparative Preparation Example 5.

(Evaluation Test 5 of Releasability of Odorous Components for Various Odorous Gases: Example 5, Comparative Example 5 and Control Example)
Using 1.0 g of a deodorizing material that is a deodorizing component consisting only of simoncolite hexagonal plate crystals to which the present invention is applied, ammonia, trimethylamine, methylmercaptan, acetaldehyde, and isobutanol were used instead of the odor components in Example 1. was used as Example 5, and deodorized in the same manner as in deodorant test 1. This deodorant was placed in a 500 ml container, stoppered, and left to stand in a dryer at 70 ° C. By measuring the gas concentration in the container in the same manner as in the deodorant test 1, the re-release rate of the odor component was calculated. On the other hand, Comparative Example 5 was prepared using the deodorant material which is KESMON, which is Comparative Test Sample 5 of Comparative Preparation Example 5, and was evaluated in the same manner as in Example 5. A control example was also tested in the same manner as in Example 1. The deodorizing results are summarized in FIG.

As is clear from FIG. 5, in Example 5 of the deodorizing material comprising the deodorizing component of simoncolite hexagonal plate crystals to which the present invention is applied, all of ammonia, trimethylamine, methylmercaptan, acetaldehyde, and isobutanol Since the rate of re-release of odorous components is low, even when the deodorizing component, which is the simoncolite hexagonal plate crystals, was heated, it was hardly observed to release adsorbed odorous components or decomposed secondary odorous components. . On the other hand, it was found that the deodorant component, which is activated carbon as in Comparative Example 5, releases a considerable amount of adsorbed odor components by heating.

(Working Preparation Example 6)
The deodorizing material, which is a deodorant component consisting only of simoncolite hexagonal plate crystals obtained in Preparation Example 1, was used as a test sample in Preparation Example 6.

(Evaluation Test 6 for Washing Releasability of Odorous Components in Various Malodorous Gases: Example 6 and Control Example)
Ammonia, trimethylamine, isovaleric acid, and isobutanol were used instead of the odor components in Example 1, using 1.0 g of the deodorant, which is a deodorant component consisting only of simoncolite hexagonal plate crystals to which the present invention is applied. After deodorizing the material used in Example 6 in the same manner as in deodorizing test 1, this deodorizing material was stirred with 30 ml of water at 400 rpm for 24 hours, and a pack test (model: WAK-NH4 (C )-4, manufactured by Kyoritsu Scientific Research Institute), and by performing colorimetric measurement 10 minutes after collecting the solution, and a liquid detection tube (detection tube: dissolved sulfide 211H, manufactured by GASTEC ) was used to measure the odor concentration using a detector tube type gas measuring instrument, the elution concentration of the odor component into the solution was measured, and the elution rate into the aqueous solution was calculated. A control example was also tested in the same manner as in Example 1. The elution results are collectively shown in FIG.

As is clear from FIG. 6, in Example 6 of the deodorizing material composed of the deodorizing component of simoncolite hexagonal plate crystals to which the present invention is applied, all of ammonia, trimethylamine, isovaleric acid, and isobutanol are odorless. The components were eluted at a high elution rate by washing with water.

(Evaluation Test 7 of Repeated Washing and Deodorization of Odor Components for Various Odorous Gases: Example 7 and Control Example)
The test was carried out in the same manner as in Example 6, except that hydrogen sulfide and ammonia were used instead of the odor components in Example 6, and the elution rate was measured after repeating deodorizing and washing with water five times. . The results are shown in FIG.

As is clear from FIG. 7, no decrease in deodorant performance was observed even after repeated deodorization and water washing, indicating that repeated use is possible only by washing with water.

(Working Preparation Example 8-1)
300 ml of 40% sodium hydroxide (NaOH) aqueous solution in a 1000 ml reaction vessel was set at 70°C, 400 ml of 25% by weight zinc chloride (ZnCl ₂ ) aqueous solution was added all at once, and the temperature was set at 70°C and normal pressure was applied. Stir for 30 minutes. After that, simoncolite hexagonal plate crystals (thickness 0.5 μm; aspect A deodorizing material, which is a deodorizing component consisting only of a ratio of 20:1), was used as a test sample in Preparation Example 8-1.

(Working Preparation Example 8-2)
300 ml of 40% sodium hydroxide (NaOH) aqueous solution in a 1000 ml reaction vessel was set at 70°C, 400 ml of 25% by weight zinc chloride (ZnCl ₂ ) aqueous solution was added all at once, and the temperature was set at 70°C and normal pressure was applied. Stir for 30 minutes. After that, 35 v/v% hydrochloric acid was added dropwise while stirring so that the pH was 7.0, and the simoncolite hexagonal plate crystals (thickness: 1 μm; aspect ratio: 10) were produced by aging with a standing time of 6 hours. : 1) was used as a test sample in Preparation Example 8-2.

(Evaluation test 8 of deodorant properties for each thickness (film thickness) of simoncolite hexagonal plate crystals as a deodorant component against various malodorous gases: Example 8 and Control Example)
Example 8 Using the test samples of Preparation Examples 8-1 and 8-2, using ammonia, hydrogen sulfide, and isovaleric acid in place of the odorous components in Example 1, was carried out in the same manner as in Example 1. A deodorant evaluation test was conducted. The results are shown in FIG.

As is clear from FIG. 8, in Example 8 of the deodorant material comprising the deodorizing component of simoncolite hexagonal plate crystals to which the present invention is applied, regardless of the thickness and aspect ratio of the simoncolite hexagonal plate crystals, It showed high deodorant performance.

(Working Preparation Example 9-1)
The deodorizing material, which is a deodorizing component, consisting only of simoncolite hexagonal plate crystals (thickness: 1 μm; aspect ratio: 10:1) obtained in Preparation Example 8-2 was used as a test sample in Preparation Example 9-1. Using.

(Working Preparation Example 9-2)
300 ml of 40% sodium hydroxide (NaOH) aqueous solution in a 1000 ml reaction vessel was set at 25°C, 400 ml of 25% by weight zinc iodide (ZnI ₂ ) aqueous solution was added all at once, and the temperature was set at 25°C and normal pressure was added. for 30 minutes. After that, 35 v/v% hydrochloric acid is added dropwise while stirring so that the pH becomes 7.0, and the deodorizing component consisting only of simoncolite (amorphous crystals) is produced by aging with a standing time of 6 hours. A certain deodorant was used as a test sample for Example Preparation 9-2.

(Working Preparation Example 9-3)
300 ml of 40% sodium hydroxide (NaOH) aqueous solution in a 1000 ml reaction vessel was set at 25°C, 400 ml of 25% by weight zinc chloride (ZnCl ₂ ) aqueous solution was added at once, and the temperature was set to 25°C and normal pressure was applied. Stir for 30 minutes. After that, 35 v/v% hydrochloric acid is added dropwise while stirring so that pH = 7.0, and the deodorant component consisting of only simoncolite (flake-like crystals) is aged by allowing it to stand for 6 hours. A deodorant was used as a test sample for Example Preparation 9-3.

(Evaluation test 9 of deodorant performance for each crystal shape of deodorant component against various malodorous gases: Example 9)
Using the test samples of Preparation Examples 8-1, 8-2 and 8-3, ammonia, trimethylamine, hydrogen sulfide, methyl mercaptan, isovaleric acid, and isobutanol were used instead of the odorous components in Example 1. , Example 9, and the deodorant evaluation test was conducted in the same manner as in Example 1. The results are shown in FIG. Also shown in FIG. 9 are electron micrographs of each crystal system.

As is clear from FIG. 9, in Example 9 of the deodorant material comprising the deodorizing component of simoncollite of various crystal shapes to which the present invention is applied, similarly high deodorization is achieved regardless of the crystal shape of simoncollite. It showed an odor.

(Working Preparation Example 10)
The deodorizing material, which is a deodorizing component, consisting only of simoncolite hexagonal plate crystals (thickness: 1 μm; aspect ratio: 10:1) obtained in Preparation Example 8-2 was used as a test sample in Preparation Example 10. .

(Comparative Preparation Example 10-1)
A deodorizing material, which is a deodorizing component consisting only of Kuraray Coal KW, which is an activated carbon manufactured by Kuraray Co., Ltd., was used as a test sample in Comparative Preparation Example 10-1.

(Comparative Preparation Example 10-2)
A deodorant material, which is a deodorant component consisting only of KESMON NS-10, a deodorant manufactured by Toagosei Co., Ltd., was used as a test sample in Comparative Preparation Example 10-2.

(Temporal Evaluation Test 10 for Deodorant Performance of Deodorant Components Against Various Odorous Gases: Example 10 and Comparative Example 10)
Using the test samples of Preparation Example 10 and Preparation Comparative Examples 10-1 and 10-2, hydrogen sulfide, methyl mercaptan, isovaleric acid, and isobutanol were used instead of the odorous components in Example 1. No. 10 and Comparative Example 10, the deodorant evaluation test was conducted in the same manner as in Example 1. The results are shown in FIG.

As is clear from FIG. 10, in Example 10 of the deodorizing material composed of simoncolite, which is the deodorizing component, to which the present invention is applied, hydrogen sulfide and isovaleric acid can be used for a short time, and methyl mercaptan and isobutanol can be used for a short time. At the same time, it exhibited high deodorant properties, and was substantially comparable to Comparative Example 10-1 of activated carbon. On the other hand, Comparative Example 10-1 of KESMON was inferior to these in some cases.

The deodorant material of the present invention comprises a deodorant containing a deodorant component comprising a layered double hydroxide, a deodorant fabric in which the deodorant component is applied to or impregnated with the fabric, and the deodorant component. It is used as building materials, industrial products, or daily necessities. The method for preparing deodorant components of the present invention is useful for producing deodorant components that are raw materials for these deodorants.

Claims (8)

A layered compound water having hydroxide layers containing one kind of metal element and intercalated with cations, anions and/or water molecules between the layers to intercalate, adsorb or decompose odorous components. A deodorant material containing an oxide as a deodorant component. 2. The deodorant material according to claim 1, wherein said metal element is divalent. 3. The deodorant material according to claim 1, wherein said metal element is zinc. The deodorant material according to any one of claims 1 to 3, wherein the layered double hydroxide is simon collite. The deodorant material according to any one of claims 1 to 4, wherein the layered double hydroxide is hexagonal plate-like, scale-like, flaky, or amorphous. The deodorant material according to any one of claims 1 to 5, wherein the layered double hydroxide has an aspect ratio of 100:1 to 1:1. A deodorant containing the deodorant component as it is or contained in either a solid carrier and a liquid or gel-like fluid carrier, and a deodorant fabric in which the deodorant component is attached to or impregnated with the fabric. The deodorant material according to any one of claims 1 to 6, wherein the deodorant material is clothes, clothes, clothing, or fibers thereof, or building materials, industrial products, or daily necessities containing the deodorizing component. An aqueous solution of a water-soluble salt of one kind of metal and an aqueous solution of an alkali metal hydroxide are mixed and then neutralized. A method for preparing a deodorant component, which comprises crystallizing a layered double hydroxide in which anions and/or water molecules are intercalated and which intercalate, adsorb, or decompose odor components.

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