JPH02145653A - Synthetic resin composition produced by mixing far infrared radiation substance and magnetic substance - Google Patents

Abstract

PURPOSE:To obtain a synthetic resin composition having excellent radiation effect of far infrared radiation and utilizable in a wide temperature range corresponding to an irradiation object by compounding specific amounts of a specific far infrared radiating substance and a specific metal oxide. CONSTITUTION:The objective composition can be produced by compounding (A) 100 pts.wt. of a synthetic resin (e.g., urethane resin or vinyl chloride resin) with (B) 5-40 pts.wt. of a far infrared radiating substance radiating infrared ray of 3-500mum wavelength (e.g., natural inorganic material or far infrared- radiating ceramic) and (C) 3-20 pts.wt. of a metal oxide having a magnetic flux density of 200-2,000 Gauss (e.g., ferrite).

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial Field of Application) The present invention is characterized in that the corresponding temperature range of an irradiated object is 180 to 100.
The present invention relates to a synthetic resin composition containing a highly efficient far-infrared emitting substance and a magnetic field line emitting substance that can be used at °C.

(Prior Art) Conventionally, various ceramic materials have been used that emit infrared rays in the infrared wavelength range when attached to heating appliances or devices that heat at high temperatures (200 to 1200"C). The material is usually a composite sintered body made of transition element oxides and clay, which has excellent infrared radiation properties.However, this sintered body has low mechanical strength and poor thermal shock resistance. Because of the drawbacks such as low durability, molded products have been developed in which ceramic materials that emit infrared rays are mixed with synthetic resins and molded into arbitrary shapes.

The molded article is usually used at a temperature around room temperature.

(Problem B to be solved by the invention) However, since the above-mentioned molded product is mixed with synthetic resin and molded, the content of the infrared emitting substance is lower than that of the composite sintered body, so the infrared rays emitted are The amount of
In some cases, the above-mentioned ceramics used in the high temperature range are used as they are, and the current situation is that even if such molded products are used, a sufficient infrared radiation effect cannot be obtained.

The present invention has been made in view of the above-mentioned problems, and has a temperature range of 80 to 100 degrees.
The object of the present invention is to provide a synthetic resin composition which can obtain an excellent far-infrared ray radiation effect within this range.

(Means for Solving the Problems) The synthetic resin composition of the present invention contains 5 to 40 parts by weight of a far-infrared emitting substance whose radiation infrared wavelength range is 3 to 500 μm, and a magnetic flux density to 100 parts by weight of the synthetic resin. is 200~2
000 Gauss and 3 to 20 parts by weight of a metal oxide.

(Function) Substances are made up of molecules and have a unique structure, and each molecule constantly vibrates periodically. The frequency of this molecule is unique to the material, and when electromagnetic waves (e.g. infrared rays, far infrared rays) with the same frequency hit the material, the energy of the electromagnetic wave is absorbed and the amplitude of the molecular vibration increases.
As a result, frictional heat is generated between molecules, and the temperature of the substance increases.

The natural frequencies of many organic molecules match the frequencies of infrared rays, especially far infrared rays. Therefore, when far-infrared rays are applied to organic matter, it is selectively absorbed, increases the vibration amplitude, generates heat, and raises the internal temperature.

Based on the above characteristics, the present invention focuses on the fact that the infrared absorption band of the irradiated object is broadly involved in the far infrared region, and the far infrared radiation characteristics of the composition of the present invention are applied to the absorption characteristics of the irradiated object. The effect of far-infrared radiation is further promoted by adapting the material to enhance the effect of far-infrared radiation, and at the same time coexisting a magnetic material that generates magnetic lines of force.

Since the wavelength band of infrared rays absorbed by the irradiated object varies depending on the surface temperature of the irradiated object, the corresponding temperature range of the irradiated object is set to -80 to 100°C, and the irradiated object is The wavelength range of the infrared radiation emitted by the far-infrared emitting material is determined so that it emits a wavelength that matches the absorption wavelength band of
This further improves the effectiveness of far-infrared radiation.

(Example) First, the far-infrared emitting material used in the present invention will be explained.

As a far-infrared emitting material, the wavelength range of infrared radiation is 3.
Natural inorganic materials (for example, Oya stone, zeolite, diatomaceous earth, Maifan stone) having a diameter of ~500 μm, far-infrared emitting ceramics, etc. are used. Among these materials, materials whose far infrared rays emitted from the materials match the absorption band wavelength range of the object to be irradiated are appropriately selected and used alone or in combination.

The particle size of the radioactive substance is preferably 5 μm or less. If it exceeds 5μm, when mixing and kneading with synthetic resin,
This is because segregation occurs due to the difference in specific gravity with the synthetic resin, and the radioactive substance is not uniformly dispersed in the synthetic resin.

Further, the amount of the far-infrared emitting substance added is 5 to 40 parts by weight per 100 parts by weight of the synthetic resin. If the amount is less than 5 parts by weight, the amount of far-infrared emitting material will be insufficient, and a sufficient radiation effect will not be obtained. On the other hand, if it exceeds 40 parts by weight, it becomes difficult to mold the mixture with the synthetic resin and magnetic substance.

As the magnetic material used in the present invention, a metal oxide having a magnetic flux density of 200 to 2000 Gauss is appropriately used in order to promote the radiation effect of the far-infrared emitting material. For example, ferrite having a high coercive force is suitable because it is easily available.

The particle size of the magnetic substance is also desirably 5 μm or less for the same reason as in the case of the far-infrared/ray-emitting substance described above. By uniformly dispersing the far-infrared emitting material and the magnetic material within the synthetic resin, a synergistic effect of the far-infrared rays and magnetic field lines of the composition can be obtained.

Further, the amount of the magnetic substance added is 3 to 20 parts by weight per 100 parts by weight of the synthetic resin. If the amount is less than 3 parts by weight, the above synergistic effect cannot be obtained because the amount of magnetic substance is insufficient.

On the other hand, if it exceeds 20 parts by weight, it becomes difficult to mold the mixture of the synthetic resin and the far-infrared emitting substance.

As the synthetic resin used in the present invention, an optimal one can be selected and used depending on the method of molding the molded article of the composition of the present invention, the purpose of use, etc.

Examples of the synthetic resin used include urethane, vinyl chloride, EVA, polyethylene, and acrylonitrile resin. By kneading and molding a predetermined amount of the far-infrared emitting substance and magnetic substance into the synthetic resin, it is possible to obtain a molded product with excellent far-infrared radiation characteristics in any shape such as a film, sheet, plate, or container. . By the way, using olefin-based and vinyl chloride-based resin as the base material, 30 parts by weight of ceramic powder 5CR-3 (manufactured by Sansho Ceralife) as a far-infrared emitting substance and magnetic material for 100 parts by weight of the same resin. The sheet according to this example, which was obtained by adding and mixing 10 parts by weight of ferrite and kneading and molding, had a wavelength range of 3 um to 2 um at 20"C.
5 μm, spectral radiance 0.9 (mw-cm-”・sr
-' μm, maximum wavelength of 10 μm, and emissivity of 96% or more (measured by Fukuyama University Infrared Engineering Laboratory).

To briefly explain the above-mentioned kneading and molding, for example, for 100 parts by weight of the synthetic resin, within 40 parts by weight of a far-infrared emitting material that emits far-infrared rays matching the absorption band of the irradiated object and within 20 parts by weight of a magnetic material. And after adding the total of both within 50 parts by weight and further adding a small amount of dispersant,
The mixture is uniformly dispersed and mixed using a mixer (high-speed mixer), and then kneaded using a mixing roll or a kneading extruder. In the case of kneading with a mixing roll, angular pellets are obtained with a sheet pelletizer, and in the case of kneading with a kneading extruder, cylindrical or spherical pellets are obtained.

These pellets can be used as raw materials to be molded into any shape. Alternatively, instead of forming pellets, the mixture may be kneaded with the synthetic resin and then directly formed into a sheet using, for example, a calender roll.

During the above-mentioned molding process, a single-sided fabric or paper molded product can be obtained by pasting or topping with fabric, paper, or the like. Alternatively, a suitable number of the above sheets may be laminated to form a plate using a press processing method.

Alternatively, a mat-like processed product can also be obtained by sandwiching another synthetic resin sheet or a foamed sheet between sheets made of the composition of the present invention and performing lamination press processing.

In addition, when molding an extremely thin object by extrusion molding or injection molding in the above molding process, the total weight of the far-infrared emitting substance and magnetic substance to be mixed and contained in the synthetic resin should be 100% by weight of the synthetic resin due to problems in the molding process. It is desirable that the amount is 25 parts by weight or less.

Moreover, since most of the far-infrared emitting substances described above are porous substances, the molded article has hygroscopicity due to the presence of the emitting substance on the surface of the molded article. Furthermore, by molding a porous far-infrared emitting material segregated on the surface of the synthetic resin, rather than using a homogeneous mixture as described above, molding that has both the radiation characteristics of far-infrared rays and magnetic lines of force as described above and hygroscopicity can be achieved. You can get a body.

Specific usage examples of the present invention will be described below.

When a plate made of the composition of the present invention is used as an indoor material, it interacts with the water vapor contained in the room and adjusts the humidity well, thereby preventing the formation of mold or mold caused by condensation when using conventional synthetic resin materials. There was no bad odor caused by this, and it was effective in maintaining humidity, deodorizing, and preventing condensation.

When a plate material made of the composition of the present invention was installed at the cold air outlet of a freezer (inner volume 2000 nf, freezing temperature -30°C), frost formation inside the freezer could be prevented due to the humidity maintenance and dew condensation prevention effects. Therefore, the labor costs and electricity consumption costs for the conventional defrosting operation using hot air every two hours could be reduced.

If a plate or mat made of the composition of the present invention is placed in the bathtub when water is being boiled, the heat during water bathing will
The far infrared rays are conducted to the plate or mat, the surface of which is heated, and far infrared rays are emitted.

Therefore, even at 42°C, it was possible to obtain a mellow feel, and the effect of warming the deep part of the body was obtained. Additionally, the floor and bathtub in the bathroom were no longer slimy, and no dew condensation was observed on the bathroom walls.

When used in bedding sheets and shoulder rests, since the human body is an endless heat generator (36-37°C), body temperature is conducted to the sheet made of the composition of the present invention, causing the temperature of the sheet to rise, It radiates far-infrared rays corresponding to 36-37°C toward the human body to warm the human body from deep inside. For this reason,
Even when the outside temperature is low, the body temperature is maintained stably, improving heat retention. In addition, the synergistic effect with magnetic radiation promoted blood circulation, which was effective in relieving stiff shoulders and stress.

A typical shirt made of an acrylic, nylon, and cotton blend was worn, with a length of 550 cm (550 cm) made from the composition of the present invention attached to the back. In addition, as a comparative example, only a shirt made of the same material was worn. When the body surface temperature was observed by thermography after 10 minutes of wearing, a remarkable difference was observed in the surface temperature distribution on the back surface.

When a sheet made of the above composition was attached, the overall temperature of the back surface was maintained high even without applying heat from the outside, and the effect of far-infrared radiation was observed.

(Effects of the Invention) As described above, the present invention has a synthetic resin with a wavelength range of 3 to 500 μ-
Since a far-infrared emitting material that emits infrared rays and a magnetic material that generates magnetic lines of force that promote the effect of the infrared radiation of the emitting material coexist, it is possible to synergistically emit far-infrared rays and magnetic lines of force with high efficiency. A composition could be obtained.

In addition, in the above wavelength range, the corresponding temperature range of the irradiated object is -80 to 100°C, and by selecting a far-infrared emitting material that emits far-infrared rays that match the absorption wavelength band of the irradiated object in this temperature range. , we were able to further improve the far-infrared radiation effect.

Claims (1)

[Claims] (1) For 100 parts by weight of synthetic resin, 5 to 40 parts of a far-infrared emitting material whose radiation infrared rays have a wavelength range of 3 to 500 μm
1. A synthetic resin composition in which a far-infrared emitting substance and a magnetic substance are mixed, the composition containing 3 to 20 parts by weight of a metal oxide having a magnetic flux density of 200 to 2000 Gauss.