JPS63270787A - Far infrared radiator - Google Patents

Abstract

PURPOSE:To provide a far infrared radiator which permits ready preparation of a product having a large radiation area by the use of a small amt. of a raw material, is so flexible that cutting, etc., are facile, does not break when let fall and is free from water absorption and bacterium invasion, and which comprises a synthetic rubber and, blended therein, a powdery ceramic material capable of radiating far infrared rays. CONSTITUTION:A fine powder of a ceramic material capable of radiating far infrared rays is blended in a synthetic rubber in the blending step of the synthetic rubber manufacturing process, and subjected to procedures similar to those customary for preparing sheet-form synthetic rubbers, thereby obtaining a sheet-form far infrared radiator comprising the synthetic rubber and, blended therein, fine powder of the ceramic material. Due to the sheet form, the far infrared radiator provides a large radiation area by the use of a small amt. of a raw material. Also, the radiator can be cut or blanked into any desirable size and shape with extreme readiness. The radiator does not break when let fall, and is hygienic since it is free from water absorption and bacterium invasion. The radiator has high heat resistance, so that a radiator article stable at a temp. as high as about 200 deg.C can be produced.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] The present invention relates to a sheet-shaped far-infrared radiator that emits far-infrared rays.

[Conventional technology]

Far-infrared rays refer to infrared rays with longer wavelengths.

Currently, it is not generally agreed upon which wavelength range of infrared rays is referred to as far infrared rays, but in this specification, electromagnetic waves in the wavelength range of 4 to 50μ are referred to as far infrared rays. do.

There are three ways heat can be transferred from a substance with a high temperature to a substance with a low temperature: (a) conduction, (b) convection, and (c) radiation. Conduction and convection transfer heat through a solid, liquid, or gas medium, whereas radiation transfers heat without the need for a medium. Infrared rays have the effect of transferring heat through such radiation.

That is, infrared rays have the property of being absorbed and turning into heat when they resonate with the molecular motion of the other substance. For example, water absorbs almost all infrared rays of 1μ or more and is heated, and most polymers and organic compounds selectively absorb far infrared rays of 3 to 25μ and are heated. However, infrared rays are not absorbed at all by the main components of air, such as oxygen and nitrogen, so even for objects that are far away from the heat source, they are directly absorbed by the other object and transfer heat to the other object without warming the air on the way. I can tell you.

In particular, far infrared rays (particularly far infrared rays with a wavelength of about 5 to 14 microns) have the ability to penetrate deep into materials and heat them from within, and have recently been found to be extremely useful in a variety of fields. .

Now, among substances, there are substances that emit far infrared rays as mentioned above, and this type of substance has an absolute temperature of K (273℃ + X
While constantly absorbing the thermal energy of "C), it converts the thermal energy into far-infrared radiant energy. Ceramics are well known as a specific example of this type of material.

For this reason, conventional far-infrared radiators have been developed, such as molded products made only of ceramic bodies, and products processed into paper shapes containing ceramic powder or fiber as a main component.

[Problems to be solved by the invention] However, in the conventional far-infrared radiator, which is a molded product made only of ceramic bodies, (a) it is hard and cannot be cut or punched into arbitrary dimensions and shapes; It is impossible.

(b) Because it is hard, there is a risk of it breaking if dropped.

(c) Some far-infrared radiators of this type are shaped like unglazed ceramics, but in such cases,
Bacteria can get inside, and when you wash it with detergent, the detergent can seep into the inside.

There were problems such as.

Furthermore, in the conventional paper-like far-infrared radiator, (d) Not durable.

(e) The same problem as in case (c) above occurs.

There were problems such as.

[Purpose of the invention]

The present invention has been made in view of the above-mentioned conventional problems, and
Products with a large radiation area can be made with a small amount of raw materials.
It is flexible, can be easily cut or punched into desired dimensions and shapes, and will not break if dropped.
To provide a far-infrared radiator that does not absorb water, has no fear of bacteria entering the interior or penetration of harmful liquids such as detergent, is easy to manufacture, and is stable with respect to temperature.

[Means for solving problems]

The far-infrared radiator according to the present invention is produced by mixing powder of a ceramic material that emits far-infrared rays with synthetic rubber. -The □ is what it is.

[Effect]

Since the far-infrared radiator of the present invention is in the form of a sheet, the radiation area can be increased with a small amount of raw material.

In addition, since this far-infrared radiator is in the form of a rubber sheet, it is possible to make flexible far-infrared rays from thin to thick, and it can be extremely easily cut or punched into any size or shape. It won't break even if you drop it.

Furthermore, since this far-infrared radiator is in the form of a rubber sheet, it does not absorb water, and bacteria will not enter the body or liquid will seep into it, making it hygienic.

Also, unlike plastic, synthetic rubber has high heat resistance.
It is possible to create a far-infrared radiator that is stable even at temperatures around 200°C.

Further, the ceramic material can be easily and uniformly mixed into the synthetic rubber, for example, in the process of kneading the synthetic rubber. Moreover, this process has extremely good workability from small-scale production to mass production.

Furthermore, since rubber can be manufactured on a much smaller scale than plastics, this far-infrared radiator is very well suited to the production of a wide variety of products in small quantities.

〔Example〕

Hereinafter, the present invention will be explained based on embodiments shown in the drawings.

In the kneading process in the normal synthetic rubber manufacturing process,
By mixing fine powder of ceramic material (average particle size 2μ) and then performing the same process as the manufacturing process of ordinary sheet-like synthetic rubber, a sheet-like material containing fine powder of ceramic material mixed with synthetic rubber is produced. Created an infrared emitter. 1st
Figures 1 and 2 show this far-infrared radiator 1.

As the synthetic rubber, silicone rubber, butyl rubber, fluororubber, and other various synthetic rubbers can be used depending on the purpose.

Examples of the ceramic materials include silica stone, silica sand, diatomaceous earth, kibushi clay, frog's eye clay, kaolin, kaolinite, halloysite, montmorillonite, bauxite, bentonite, zeolite, phosphate rock, diasbore, gibbsite, clay-like Natural inorganic substances such as mica (sericite, illite, vermiculite), mica, acid clay, pottery stone, waxite, feldspar, limestone, wollastonite, gypsum, dolomite, magnesite, talc, mountain bark, aluminum hydroxide, Metal hydroxides such as magnesium hydroxide and ferric hydroxide, and calcium silicate-based hydrates or calcium aluminate hydrates such as tobermolite and xonotlite,
Hydrates of various oxides such as calcium sulfoaluminate hydrate, or alumina, silica, magnesia, calcia, zirconia, doria, beryllia, titanium oxide, spinel, synthetic cordierite, synthetic mullite, synthetic zeolite, chromium, chromium Magnesia, magnesia chromium, synthetic calcium carbonate, calcium phosphate, and other various carbides ('ricSZrC, HfC, VC%T a C
1N b CSW C1B 4 CSS t C etc.),
Nitride (TtN, VN, NbN5TaN, HfN.

AbN, BN, S t3N4, etc.), ferrous oxide, ferric oxide, lead oxide, zinc oxide, nickel oxide, manganese dioxide, cupric oxide, cobalt oxide, barium carbonate, manganese carbonate, metal titanate ( potassium titanate, calcium titanate, magnesium titanate, aluminum titanate, strontium titanate, barium titanate, etc.)
, graphite, activated carbon, carbon black, or artificial inorganic powders such as various inorganic pigments can be used one or more types as required.

Furthermore, the far-infrared absorption spectra of water and all organic compounds existing on the earth are concentrated in the range of 6 to 14μ.
It is preferable to select a ceramic material so as to efficiently radiate far-infrared rays having a wavelength in the range of 6 to 14 microns.

Since this far-infrared radiator is in the form of a sheet, the radiation area can be increased with a small amount of raw material.

In addition, since this far-infrared radiator is in the form of a rubber sheet, it is possible to make flexible far-infrared rays from thin to thick, and it can be extremely easily cut or punched into any size or shape. It won't break even if you drop it.

Furthermore, since this far-infrared radiator is in the form of a rubber sheet, it does not absorb water, and bacteria will not enter the body or liquid will seep into it, making it hygienic.

Also, unlike plastic, synthetic rubber has high heat resistance.
It is possible to create a far-infrared radiator that is stable even at temperatures around 200°C.

Furthermore, the mixing of the ceramic material into the synthetic rubber can be done, for example, in the synthetic rubber kneading process as in this example.
It can be done easily and uniformly. Moreover, this process has extremely good workability from small-scale production to mass production.

Furthermore, since rubber can be manufactured on a much smaller scale than plastics, this far-infrared radiator is very well suited to the production of a wide variety of products in small quantities.

Next, specific examples of use of this far-infrared radiator and its effects will be listed.

When this far-infrared emitter is placed in a fish tank or aquarium, it activates filtering bacteria, promotes water purification, and increases fish movement.

Placing sashimi or the like on this far-infrared radiator prevents drips from flowing out, maintains freshness, and prevents deterioration of taste.

Furthermore, by pasting this far-infrared radiator on the inner surface of a box and storing sashimi in the box, the sashimi will stay fresh for a long time in the refrigerator and prevent drips from flowing out.

When you place this far-infrared radiator on top of polished rice in a rice cooker and start cooking, it promotes alpha conversion of starch, resulting in extremely fluffy, sticky, and delicious rice. Also, the rice stays delicious for a long time without discoloring. When using it for cooking rice in this way, as shown in Figures 3 and 4, if you wrap the far-infrared radiator 1 in a cloth bag (especially preferably a cloth bag made of synthetic fibers), the rice will be cooked. When this occurs, rice grains do not adhere to the far-infrared radiator 1.

When boiling noodles, vegetables, etc., if you first put this far-infrared radiator in the boiling water and then heat it to bring it to a boil, the following excellent effects can be obtained.

(a) In the case of udon and soba noodles, the drippings of the noodles can be retained, so the corners will not collapse and there will be less slag. In addition, the noodles become sticky and delicious, and become chewy and difficult to spread. Furthermore, the boiling time is about 20%
It gets faster.

(b) Green vegetables (spinach, snow peas, edamame,
In the case of vegetables such as Komatsuna (Japanese mustard spinach), they are boiled at a low temperature so that the chlorophyll is not destroyed, resulting in a bright green color. Vitamin C is not destroyed and the natural flavor of the vegetable can be brought out.

(c) In the case of dashi soup or noodle soup, the original taste of the dashi is well dissolved, the soup is ready in a short time, and it has a very mellow taste.

When boiling beans, lotus roots, potatoes, etc., if you add this far-infrared emitter and boil them, you can quickly boil them to the core.

If you add this far-infrared emitter when boiling meat, it will be soft and will not harden over time.

When making stews or oden, the boiling time is halved.
The soup stock soaks in well.

When boiled in this way, the bonding lattice of water molecules that absorb far-infrared rays becomes stronger, strengthening electrostatic bonding forces and preventing water from separating, so even soft foods like daikon radish retain their shape.

When this far-infrared radiator is added to the kneading water for udon and soba noodles, the noodles can be prepared in 30 minutes, compared to the 12 hours required with conventional salt water kneading water. In addition, less force is required to knead the udon noodles, resulting in better hydration.

When ripening udon balls, if you place them on top of this far-infrared ray emitter, the ripening process, which normally takes about 3 hours, will last for about 30 minutes.
Complete in quantiles.

When pickled foods are soaked in this far-infrared radiator, the ingredients will pickle quickly and stay fresh for a long time. Also,
The color of natural salt is removed and the taste becomes mellow.

If you put this far-infrared emitter in a container containing tap water, the tap water will become delicious and free of chlorine odor. Just by placing a pot filled with tap water on top of this far-infrared ray emitter for a minute or two, the chlorine odor disappears and the water becomes delicious.

If you place miso, soy sauce, salted fish, ham, etc. on this far-infrared emitter for about an hour at room temperature, or if you place it in a box with this far-infrared emitter attached, the salt in these foods will be removed. The bitterness is removed and the taste becomes mellow.

Vinegar, mayonnaise, etc. also have a mellow flavor. Shiitake mushrooms, dried sardines, kelp, wakame, seaweed, etc. also have an enhanced flavor and do not deteriorate in quality even after long-term storage. Rice and wheat are activated and become fresh. Bread and sweets also store better. Rakkyo,
Pickles such as pickled plums, Fukujinzuke, and Chinese cabbage also stay fresh for a long time. Tea also keeps better and has more flavor and aroma.

Alcoholic beverages such as sake, whisky, wine, and brandy become more mellow as they age. For example, just by placing such alcoholic beverages in a glass and placing it on top of this far-infrared radiator, the taste will instantly change to a mellow taste. In the case of wine, if you put it in a flat-bottomed glass and place it on top of this far-infrared radiator, it will rapidly age in 2 to 3 minutes, resulting in a milder wine. Red wine in particular has a unique sibumi flavor.

Also, if you slowly roll a cigarette over this far-infrared emitter three or four times, the nicotine stimulation is immediately removed and the taste becomes mellower.

When drinking tea or coffee, first put this far-infrared emitter in water and then heat it to boil. If you also put this far-infrared emitter when storing hot water in a pot, you can enjoy the essence of tea or coffee. Because it is well extracted into hot water, it has a mellow flavor and is very delicious. Also, if you put this far-infrared radiator in the pot, it will store heat energy, making it harder to cool down than before.

When used in conjunction with a body warmer, the thermal effect penetrates to the core of the body, which warms the body, improves blood circulation, and has the effect of relieving fatigue.

If you place it under your bed sheets, your own body heat will emit far-infrared rays to your feet, keeping you warm.

Fresh flowers last about twice as long.

If you place this far-infrared emitter in the bathtub (it is a good idea to set this far-infrared emitter in the bathtub from the time you fill the bathtub with water), this far-infrared emitter will be best absorbed by water and the human body. It can efficiently radiate far-infrared rays with a wavelength of 5, 5 to 10 microns, so the hot water in the bathtub absorbs the far-infrared rays and has a mellow texture, and the human body absorbs the far-infrared rays emitted from the activated water. It fully absorbs infrared rays up to about 4cm deep inside the body, warming you to the core. A 10-minute bath in lukewarm water at around 40 degrees Celsius warms the body to its core, expands blood vessels, promotes blood circulation, and regulates the function of the autonomic nervous system. It also excretes fatigue and waste products from the body through insensible sweating. (When the inside of the body warms up to 38 degrees Celsius or higher than the cortex beneath the skin, the deep part of the body is secreted to regulate body temperature.) Blood circulation improves to the minute blood vessels, causing sweating.)

〔Effect of the invention〕

As described above, the far-infrared radiator according to the present invention can be made into a product with a large radiation area using a small amount of raw materials, is flexible, can be easily cut or punched into desired dimensions and shapes, and can be easily dropped. It does not crack, does not absorb water, has no risk of bacteria entering the interior, or harmful liquids such as detergent seeping into it, is easy to manufacture, and is stable against temperature. It is something.

[Brief explanation of drawings]

Fig. 1 is a plan view showing an embodiment of the far-infrared radiator according to the present invention, Fig. 2 is a side view showing the embodiment, and Fig. 3 shows the embodiment housed in a rice cooking bag. A plan view showing,
FIG. 4 is a sectional view taken along the line rV-rV in FIG. 3. , 1... far infrared ray emitter, 2... bag.

Claims (1)

[Claims] A sheet-shaped far-infrared radiator made by mixing powder of a ceramic material that emits far-infrared rays with synthetic rubber.