JP2005139058A - Composition and resin composition - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a composition and a resin composition, which are produced by utilizing a polyfunctional mixed natural ore, and which simultaneously generate positive and negative ions in a state that the amount of negative ions is larger than that of positive ions, at the same time, radiates far-infrared rays in an amplified state, and sustainably form and radiates far-infrared rays. <P>SOLUTION: A mixed body comprising a sedimentary pudding stone natural ore and a natural ore containing rare earth elements is provided, and the composition is obtained by firing the mixed body composition at a high temperature. The mixed body and the composition simultaneously generate positive and negative ions in a state that the amount of negative ions is larger than that of positive ions, and at the same time, radiates far-infrared rays in an amplified state. The resin composition is obtained by mixing the composition with an antistatic resin. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a composition and a resin composition, which uses a multifunctional mixed natural ore, and simultaneously produces more negative ions than positive ions while simultaneously amplifying and radiating far-infrared rays, and continuously generating and emitting them. The present invention relates to a composition useful for a health treatment tool, a deodorant / antibacterial product, a freshness maintaining material, a water purification material and the like.

In recent years, interest in the living environment and health has increased greatly, and in particular, there has been an increase in interest in air and water in human living spaces. Has come to be.
As a method of generating negative ions, there are known a method of generating electrons by electromechanically generating negative ions and a method of ionizing air by the action of radiation using a rare element ore containing a radioactive substance. .
In the method of ionizing air by the action of radiation using rare element ore containing radioactive material, the air is ionized by the action of radiation, but it produces negative ions and positive ions at the same time. However, more positive ions are generated, and the negative ion effect is not praised. Also, if a large amount of radioactive material is used, handling must be very careful.
In addition, many products with far-infrared radiation characteristics are on the market. Far infrared rays are said to have hyperthermia, sweating, blood circulation, metabolism, and soreness.
Far-infrared rays are also called “growth rays” and are said to be good in that they emit at an emissivity of 50% in the temperature range of 4 to 14 μm at room temperature.
In this background, various prior arts have been filed.

Patent 3035279

It is a resin composition that contains a polymer compound that is not easily charged with static electricity, a mineral containing a rare element, and tourmaline or a far-infrared ceramic, and emits far-infrared rays simultaneously with the release of negative ions.
However, when a high molecular compound, that is, a resin that is not easily charged with static electricity, is captured, the property of the resin as an electrostatic phenomenon is divided into a positively charged resin, a negatively charged resin, and an uncharged resin.
If it is a resin that is not easily charged with static electricity as described in (Patent No. 303529), it is considered that the resin is slightly charged. If a resin that generates ions is mixed with such a resin, neither positive ions nor negative ions will be generated. Furthermore, if the resin is not easily charged with static electricity in proportion to the strength of the static magnetic field, the generated amount There is a problem that the amount of released ions is not generated in a large amount, and the amount of generated ions is greatly reduced as compared with the original ion generating material, and the effect of negative ions is small.
Furthermore, the ion generation mechanism is known as a substance that emits ions when radioactive substances such as thorium oxide and uranium oxide contained in rare element ores are taken from the ion generation substance, and are described in the (Patent No. 303529) document. Ore of this type has less negative ion effect because positive ions are generated much more than negative ions.
In addition, from the examples, even the composition of resin and far-infrared ceramic that is not easily charged with static electricity has a problem that more positive ions are generated, and the ore that generates the original ion is replaced with resin and far-infrared ceramic. There was a big problem that mixing and dilution would decrease rather than amplify.
There was no effect of amplifying ions by far infrared rays.

The problem to be solved is that since ions have a charge, it becomes a mechanism that does not jump out of the magnetic field, so a “resin that is not charged with static electricity” that does not interfere with the generation of ions was required. Is a point.
In addition, when a material using radioactive material is used, negative ions and positive ions are generated at the same time, and more positive ions are generated. The material that produces more negative ions than the negative ions has an effect of negative ions, and this kind of material has become necessary.
Furthermore, since radioactive materials are used, in consideration of safety, there is a need for a material that can produce a large amount of negative ions in a continuous manner even at low concentrations below the regulation value and extract the effects of negative ions. It is.

In view of the above problems, as a result of repeated studies to reduce the positive ions released by natural ores containing rare earth elements that emit extremely weak radiation, a specific natural ore, that is, sedimentary conglomerate natural It has been found that mixing ores has the effect of reducing positive ions. At the same time, even when the rare earth natural ore was in a low concentration, it was found to have an effect of amplifying negative ions continuously in large quantities.
At the same time, the sedimentary conglomerate natural ore was found to be an ore that emits far-infrared rays, but the ordinary infrared alone had a far-infrared emissivity of about 60%. It was found that the emissivity of far-infrared was amplified to 95% by mixing with ore.
In addition, regarding the combination with a resin necessary for commercialization, it has been found that only the resin that is not charged with static electricity has the amplification effect.

In the present invention, as a sedimentary conglomerate natural ore, as the ore component, silica oxide, aluminum oxide iron oxide, titanium oxide, calcium oxide, magnesium oxide, sodium oxide, calcium oxide, manganese oxide, boron oxide, chromium oxide, zirconium oxide Is a natural ore with a component mass.
Since it is a natural ore, more preferably, the mass% is silica oxide 47-55, aluminum oxide 10-14, iron oxide 6-8, titanium oxide 0.7-1.0, magnesium oxide 6-8, sodium oxide. 2-4, potassium oxide 0.08-0.3, manganese oxide 0.1-0.2, boron oxide 0.1-0.2, chromium oxide 0.07-0.2, zirconium oxide 0.01- Natural ores with a component mass of 0.02 can be used, ie sedimentary conglomerate.
As the particle size of the above-mentioned sedimentary conglomerate, those crushed to 1 mm or less can be used. More preferably, a powder whose particle size is pulverized to 30 microns or less is useful for the amplification effect by mixing.

In the present invention, as natural ores containing rare earth elements, ferrugsonite, monazite, bustness stone, xenotime stone, columbite, betajolite, samarsky stone, tantalum stone, tantalum stone, uranium stone, thorium stone, rubber stone There are gadolin stones. Of these ores, very weak radiation is emitted, radiation of 1.0 mSv / year or less, which is said to have no adverse effects on the human body, and radiation concentration is not required under the Nuclear Regulation Act. The most preferred natural ore with a radiation concentration of beclem / g or less is monazite natural ore.
As the particle size of the above natural ore, those pulverized to 1 mm or less can be used. More preferably, a powder whose particle size is pulverized to 30 microns or less is useful for the amplification effect by mixing.
In the present invention, as the resin to be mixed, a resin that does not affect the negative ion amplification effect and the far-infrared amplification effect, that is, a resin that is not charged with static electricity can be specified.

Non-statically charged resins such as silicone emulsion, silicone / acrylic copolymer emulsion, acrylic emulsion, vinyl acetate emulsion, fluorine emulsion, polyurethane emulsion, natural rubber latex, styrene butadiene rubber latex, isoprene latex, acrylonitrile latex, chloroprene latex, etc. Resin can be used, and as the solvent-containing resin, a polyurethane solvent-containing resin, an acrylic solvent-containing resin, and an ultraviolet curable resin can be used.
The mixing ratio of sedimentary conglomerate powder and rare earth ore powder is 10 to 100 parts by weight of rare earth ore powder with respect to 100 parts by weight of sedimentary conglomerate powder. More preferably, the rare earth ore powder is 10 to 40 parts by weight with respect to 100 parts by weight of the sedimentary conglomerate.
The mixing ratio of the resin not charged with static electricity, sedimentary conglomerate powder, and rare earth ore powder is 5 to 60 parts by weight of sedimentary conglomerate powder and 5 to 60 rare earth ore powder with respect to 100 parts by weight of resin solid content. It is the number of parts by weight.
More preferably, it is 5-30 parts by weight of sedimentary conglomerate powder and 5-30 parts by weight of rare earth ore powder with respect to 100 parts by weight of resin solid content.
The shape formed by mixing sedimentary conglomerate and rare earth ore, molding and firing is massive or spherical, and the size is 1 mm to 10 mm in diameter, more preferably 1 mm to 3 mm in diameter. .

  The present invention finds a natural ore called sedimentary conglomerate that promotes far-infrared radiation, and a large amount of negative ions is generated by the suppression effect of positive ions and the promotion effect of negative ions. Thus, it is radiated in a large amount and is useful for a wide range of antibacterial / sterilizing materials, deodorizing materials, freshness maintaining materials, health treatment tools and the like.

Hereinafter, the present invention will be described in detail with reference to examples and comparative examples.
“Example (1) and Comparative Example (1)”
Sedimentary conglomerate powder and monazite powder were ground to 15 microns or less. The mixing in the examples was performed by mixing for 1 hour with a mill mixer.

天然鉱石であるトルマリンは、黒トルマリンとも呼ぶショールトルマリンを用いて、１５ミクロン以下に粉砕したものを使用した。合成セラミック或いは遠赤外線セラミックとして、市販されている「商品名：セラジットＡＬ」（白石工業株式会社製）の粉体を使用した。

The tourmaline, which is a natural ore, was crushed to 15 microns or less using a shawl tourmaline also called black tourmaline. As a synthetic ceramic or far-infrared ceramic, a commercially available powder of “trade name: Serajit AL” (manufactured by Shiraishi Kogyo Co., Ltd.) was used.

下記に、実施例１〜３ならびに比較例１〜４の粉体のイオン測定結果と、遠赤外線放射測定結果を表３および表４に示した。
イオン測定方法は、各々の試料１０ｇとして、空気イオンカウンターＩＴＣ−２０１Ｃ（アンデス電気製）を用いて、５分間平均のマイナスイオン生成数と、プラスイオン生成数を測定した。
遠赤外線測定は、公的試験機関の環境イオン計測センターで、遠赤外線放射率のＦＴＩＲ測定をして、人体体温域３５℃、波長４〜１４μの平均放射率を求めた。

Tables 3 and 4 show the ion measurement results and far-infrared radiation measurement results of the powders of Examples 1 to 3 and Comparative Examples 1 to 4 below.
In the ion measurement method, the average number of negative ions produced and the number of positive ions produced for 5 minutes were measured for each sample 10 g using an air ion counter ITC-201C (manufactured by Andes Electric).
The far-infrared measurement was performed by FTIR measurement of the far-infrared emissivity at an environmental ion measurement center of a public testing institution, and the average emissivity in a human body temperature region of 35 ° C. and a wavelength of 4 to 14 μm was obtained.

実施例１、実施例２及び実施例３から明らかなように、堆積礫岩とモナズ石との組み合わせにより、プラスイオンよりもマイナスイオンの方が多く発生しつつ、遠赤外線放射率も、多く増幅している。
この現象は、堆積礫岩のもつ、遠赤外線及び其の他と、モナズ石の持つイオン生成能力および微弱な放射線とが、互いに、相互作用で反応し合い、またプラスイオンの抑制作用が生じたと判される。

As is clear from Example 1, Example 2, and Example 3, the combination of sedimentary conglomerate and monazite generates more negative ions than positive ions and also amplifies far-infrared emissivity. doing.
This phenomenon is caused by the interaction between the far-infrared rays of sedimentary conglomerate and others, the ion generation ability and weak radiation of monazite, and the positive ion suppression effect. It is judged.

On the other hand, in Comparative Example 1, Comparative Example 2, Comparative Example 3 and Comparative Example 4, not only the natural ore tourmaline, but also the synthetic far-infrared ceramic Serajit AL, not only more positive ions are generated, Far-infrared emissivity is also decreasing.
As is clear from Example (1) of the present invention, what has not been recognized so far as sedimentary conglomerate, which is a kind of natural ore, emits far-infrared rays. It became clear that this occurred.

“Example (2) and Comparative Example (2)”
The spheres were calcined with the formulation shown in the above examples and comparative examples.
Each mixture of Example 3, Comparative Example 3, and Comparative Example 4 was filled into a rubber mold by a rubber press method, compressed by hydraulic pressure, continuously molded into a sphere, and baked at 1000 ° C. for 3 hours. Thus, a sphere having a diameter of 3 mm was prepared.
Example 4: Sphere Molded Product of Example 3 Formulation Comparative Example 5: Sphere Molded Product of Comparative Example 3 Formulation Comparative Example 6: Sphere Molded Product of Comparative Example 4 Formulation Here, the present invention is proved to be more effective. In order to do this, we will clarify the details by giving examples of water purification materials using the negative ion effect and far-infrared effect that are in the practical stage.
In the water purification test “Table 5”, the hydrogen ion concentration was changed, and in “Table 6”, the free chlorine concentration was changed.
In the hydrogen ion concentration test method, 150 cc of tap water was put into a beaker, and 5 g of each of Example 4, Comparative Example 5 and Comparative Example 6 were put therein, and the hydrogen ion concentration after the lapse of time was measured with a pH meter. . The water temperature was 25 ° C. and stored in a sealed state.
In the measurement of free chlorine [Table 6], the free chlorine concentration was measured with the simple method for measuring water quality of the orthotolidine method in the same manner as described above.

実験結果から明らかように、水素イオン濃度変化では、実施例４では、時間経過ともに、弱アルカリ性に変化反応するのに対し、比較例５及び比較例６では、ブランクの水道水のみと大差なく、酸性水になり反応しなかった。
一方、遊離塩素濃度変化では、実施例４では、瞬時に遊離塩素が分解してなくなるのに対し、比較例５及び比較例６では、ブランクの水道水と大差なく、反応が起こらなかった。
この現象は、マイナスイオンが大量に発生し、遠赤外線が大量に放射するために生じた反応であることは明らかである。

As is clear from the experimental results, in the change in hydrogen ion concentration, in Example 4, the reaction changes to weak alkalinity over time, whereas in Comparative Example 5 and Comparative Example 6, there is not much difference from only blank tap water. It became acidic water and did not react.
On the other hand, in the change in the free chlorine concentration, in Example 4, the free chlorine was instantly decomposed, whereas in Comparative Example 5 and Comparative Example 6, the reaction did not occur without much difference from the blank tap water.
It is clear that this phenomenon is a reaction that occurs because a large amount of negative ions is generated and far infrared rays are emitted in large amounts.

"Example (3) and comparative example (3)"
Table 7 shows the formulation of the practical application test results of the examples of the present invention and the comparative examples.
In the formulation of Table 7, a resin composition prepared by mixing with a silicone / acrylic copolymer emulsion product name “Charine FE-230 (manufactured by Nissin Chemical Industry Co., Ltd.)” as a resin that is not charged with static electricity.

上記の実施例５、比較例７、比較例８の樹脂組成物を使用して、イオン測定試験と、また、遠赤外線測定、抗菌試験と、消臭試験は、公的試験機関で試験した。
実施するために、各々の試料を作成した。
試料の作成は、綿布に、実施例５、比較例７及び比較例８の樹脂組成物を、１００メッシュのプリント基板で、各々を捺染プリントを、全面プリント加工した。
そのときの塗布量は、
実施例５： ｗｅｔ塗布量 ２．５ｇ／２０ｃｍ角
比較例７： ｗｅｔ塗布量 ２．６ｇ／２０ｃｍ角
比較例８： ｗｅｔ塗布量 ２．５ｇ／２０ｃｍ角
抗菌試験は、財団法人日本紡績検査協会で、ＪＩＳ−Ｌ１９０２試験法で、試験した。
使用した菌は、黄色ぶどう球菌で、消臭試験は、ユニチカガーメンテックで、自社法のテトラバックでの検知管法で、脱臭率を試験した（表８）。

Using the resin compositions of Example 5, Comparative Example 7, and Comparative Example 8 above, the ion measurement test, the far-infrared measurement, the antibacterial test, and the deodorization test were tested at a public testing organization.
Each sample was made for implementation.
Samples were prepared by printing the entire surface of a cotton fabric with the resin compositions of Example 5, Comparative Example 7 and Comparative Example 8 on a 100-mesh printed circuit board.
The coating amount at that time is
Example 5: Wet coating amount 2.5 g / 20 cm square Comparative example 7: Wet coating amount 2.6 g / 20 cm square Comparative example 8: Wet coating amount 2.5 g / 20 cm square Antibacterial test was conducted by the Japan Spinning Inspection Association. The JIS-L1902 test method was used.
The used bacterium was Staphylococcus aureus, and the deodorization test was conducted by Unitika Garmentec, and the deodorization rate was tested by the detector tube method using Tetrabak (in-house method) (Table 8).

上記試験結果から明らかなように、実施例では、マイナスイオン効果と遠赤外線の大量放射の効果が現れて、抗菌効果、及び消臭効果の結果が非常に良好であった。
それに対し、比較例７及び比較例８は、良くない結果となった。

As is clear from the above test results, the negative ion effect and the effect of mass emission of far infrared rays appeared in the examples, and the results of the antibacterial effect and the deodorizing effect were very good.
On the other hand, Comparative Example 7 and Comparative Example 8 gave bad results.

"Example (4)"
In the following examples, in order to clarify the multi-functionality of the present invention, an experiment of the freshness maintaining effect that has been put into practical use was conducted to clarify the effect.
The sample of Example 4 used in Example 3 was used, and the size of the sample was 40 × 20 cm square.
The preservation | save method adjusted to 4 degreeC and preserve | saved in the vegetable room 84L of 2 420L refrigerators (product made from Sharp).
The test article was attached to the top of the vegetable room tray. There was no blank for comparison.
Vegetables and fruits to be preserved were eggplant and apples.

本発明の実験結果から明らかなように、実施例４は、鮮度保持試験において、３〜４日程度の鮮度保持効果が認められた。
この効果は、マイナスイオンの効果である抗菌・殺菌力と、細胞活性の効果であり、また、遠赤外線の増幅の多い放射による細胞活性の効果の二重効果であることはあきらかである。

As apparent from the experimental results of the present invention, in Example 4, the freshness retention effect of about 3 to 4 days was recognized in the freshness retention test.
It is obvious that this effect is an antibacterial and bactericidal power, which is an effect of negative ions, and a cell activity effect, and is also a dual effect of a cell activity effect by radiation with much far-infrared amplification.

  As is clear from the above-described examples, more negative ions than positive ions are simultaneously generated, and at the same time, far-infrared rays are amplified and emitted, and are used for compositions and resin compositions that are continuously generated and emitted. It can be used for health treatment tools, deodorant / antibacterial products, freshness maintaining materials, water purification materials, and the like.

Claims (2)

A mixture or mixture composition of sedimentary conglomerate natural ore containing rare earth elements and high-temperature calcined lump or sphere, and more negative ions than positive ions are generated simultaneously. A composition characterized in that far infrared rays are amplified and emitted at the same time Multifunctional mixed natural ore consisting of sedimentary conglomerate natural ore and natural ore containing rare earth elements and non-statically charged resin are mixed, and more negative ions than positive ions are generated at the same time, A resin composition characterized by being amplified and radiated