WO2000034411A1

WO2000034411A1 - Composition of multipurpose far-infrared radiation material

Info

Publication number: WO2000034411A1
Application number: PCT/KR1999/000138
Authority: WO
Inventors: Young Keun Kim
Original assignee: Young Keun Kim
Priority date: 1998-12-07
Filing date: 1999-03-26
Publication date: 2000-06-15
Also published as: AU2859199A; CN1329655A; KR20010101106A; KR20000038422A; JP2005507009A; EP1141168A1

Abstract

Provided with a composition of a multipurpose far-infrared radiation material including: 0.2-38 parts by weight of at least one non-metal compound selected from the group consisting of SiO2 and P2O5; 0.01-70 parts by weight of at least one metal compound selected from the group consisting of TiO2, Al2O3, Fe2O3, FeO, MnO, MgO, CaO, Na2O, K2O, Cr2O3, NiO, BaO and SrO; 0.01-2 parts by weight of at least one rare earth element selected from the group consisting of Nd, Y, Ce, Sm, La and Yb; and 0.02-18 parts by weight of at least one element selected from the group consisting of C, Cr, Ni, Ba, Sr, Co, Cu, Li, Nb, Zr, Zn and Ge, the material having multiple functions such as emission of non-thermal far-infrared rays, vital strength enhancement, air purification, absorption or neutralization of harmful electromagnetic waves, control of water vein, improvement of water and soil qualities, and the like, and being applicable to every fields of industry concerning environments, water quality and soil improvement, water purification, health products and hot medical applications, farm-livestock-fisheries products, floriculture, construction, building, food storage and processing, space-air, maglev magnetism, special alloyed steel, motor vehicle, sports, electrical and electronics, and so on.

Description

COMPOSITION OF MULTIPURPOSE FAR-INFRARED RADIATION MATERIAL

Technical Field

The present invention relates to provide a novel composition of a far-infrared radiation

material having multiple functions such as emission of non-thermal far-infrared rays, vital

strength enhancement, air purification, absorption or neutralization of harmful electromagnetic

waves, control of water vein, improvement of water and soil qualities, and the like.

Particularly, the present invention relates to a novel composition of a multipurpose far-infrared

radiation material which is applicable to every fields of industry concerning environments,

water quality and soil improvement, water purification, health products and hot medical

applications, farm-livestock-fisheries products, floriculture, construction, building, food

storage and processing, space-air, maglev magnetism, special alloyed steel, motor vehicle,

sports, electrical and electronics, and so on.

Background Art

A growing interest has been taken in far-infrared rays has a positive effect on human

body and food stuffs with high efficiency of energy. Far-infrared rays are lights having a long

wavelength in the range of 5-1000 μm out of the infrared component of visible solar lights.

Since the wavelength is almost the same as that of water which is the principle constituent of

our human body, far-infrared rays transmitted into the body have a direct effect upon the energy circulation and physiological activation and associate with water molecules strongly to

activate water. Also, far-infrared rays have multiple functions such as maintaining the freshness

of all food stuffs, making foods tasty, deodorization, promoting growth of plants and animals,

uniform heating or drying for a reduced time, and rising the temperature internal or external of

an object.

The related art techniques concerning far-infrared materials having such efficacies are

disclosed, for example, in Korean Patent Publication Nos. 94-2031, 94-5085 and 96-7375 and

relate to the materials that have far-infrared functions solely free from non-thermal far-infrared

radiation and give no effect involving vital strength enhancement, absoφtion or neutralization

of harmful electromagnetic wave, control of water vein, or the like. As for neutralizing agent

of harmful electromagnetic wave, the technique is described in Korean Patent Laid-open No.

97-21141, which relates to electromagnetic wave shielding only and does not mention other

effects such as non-thermal far-infrared radiation, vital strength enhancement, air purification,

water vein control, improvement of water and soil qualities, and so on.

Disclosure of Invention

An objective of the present invention is to provide a novel composition of a far-infrared

radiation material having multiple functions such as emission of non-thermal far-infrared rays,

vital strength enhancement, air purification, absorption or neutralization of harmful

electromagnetic waves, control of water vein, improvement of water and soil qualities, and the

like.

To accomplish the objective of the present invention, provided is a composition of a multipurpose far-infrared radiation material including: 0.2-38 parts by weight of at least one

non-metal compound selected from the group consisting of SiO₂ and P₂O₅; 0.01-70 parts by

weight of at least one metal compound selected from the group consisting of TiO₂, Al₂O₃,

FeA, FeO, MnO, MgO, CaO, NaA K₂O, Cr₂O₃, NiO, BaO and SrO; 0.01-2 parts by weight

of at least one rare earth element selected from the group consisting of Nd, Y, Ce, Sm, La and

Yb; and 0.02-18 parts by weight of at least one element selected from the group consisting of

C, Cr, Ni, Ba, Sr, Co, Cu, Li, Nb, Zr, Zn and Ge.

In addition, the present invention provides the composition of a multipurpose far-

infrared radiation material that may be used as a mixing or coating form in combination with all

sorts of metallic and nonmetallic materials such as loess, Mcbansuk, jade, feldspar, amphibole,

biotite, beryl, Yangkisuk, sericite, talc, green jadeite, serpentine, noble serpentine, tourmaline,

rare earth stone, actinolite, augite, agalmatolite, zeolite, charcoal, clay, silica, ilmenite, chlorite,

garnet, zircon, china stone (kaoline), olivine, malachite, quartz, jasper, pearl, sapphire, ruby,

turquoise, chalcedony, tiger's eye, emerald, agate, cat's eye, water stone, chalcopyrite,

copper, aluminum, tungsten, jet, scaly graphite, sand, heavy sand, granite, marble, cement,

water, metals, nonferrous metals, plastics, fibers, asphalt, wood, cotton, unwoven yarn, rubber,

pigment, paint, ink, pulp (paper), glass, ceramic wares, tile, artificial precious stone, vinyl,

cork, adhesives, silicon and the like.

The most preferable composition ratio is determined within the most effective range

that is obtained by measuring the amount and wavelength of far-infrared rays for a long time

while varying the composition ratio of the above-mentioned farinaceous far-infrared material,

followed by vital strength enhancement test, harmful electromagnetic wave shielding test, and water vein control test.

The components in the present invention composition of a far-infrared radiation

material are mixed as a farinaceous form to constitute the composition. The composition may

be used without a firing process or, if necessary, may be fired at high temperature of 100-2500

^°C (according to its use purpose) and then pulverized, or molded before use. Thus obtained

powder of the far-infrared radiation material is not limited in particle size and, preferably, may

be pulverized to about 10-1000 meshes in consideration of its mixture or moldability in various

applications that will be described later.

Brief Description of Drawings

Fig. 1 is thermographs before putting on the far-infrared radiation material of Example

1 (spot temperature: 27 °C) and after putting on the far-infrared radiation material of Example

1 for about 10 min (spot temperature: 30.4 °C increased by 0.7 °C. The body temperature rises

through economical promotion of the blood circulation.);

Fig. 2 is thermographs of the left hand before holding the far-infrared radiation material

of Example 1 with the right hand (spot temperature: 27.7 °C) and after holding the far-infrared

radiation material of Example 1 with the right hand for about 10 min (spot temperature: 28.7

^°C increased by 1 ^°C. The temperature on the fingers also rises.);

Fig. 3 is an NMR spectrum of water before passing through the filter; and

Fig. 4 is an NMR spectrum of water after the filter.

Best Mode for Carrying out the Invention Hereinafter, a composition of a far-infrared radiation material according to the present

invention will be described in detail by way of illustrative embodiments with reference to the

drawings.

(Example 1)

A far-infrared radiation material is prepared by the composition: 35 parts by weight of

SiO₂, 8 parts by weight of TiO₂, 13 parts by weight of Al₂O₃, 8 parts by weight of Fe₂O₃, 8

parts by weight of FeO, 0.2 parts by weight of MnO, 5 parts by weight of MgO, 6 parts by

weight of CaO, 2.5 parts by weight of Na^, 2.5 parts by weight of K₂O, 0.4 parts by weight

of Cr₂O₃, 0.5 parts by weight of P₂O₅, 0.2 parts by weight of NiO, 0.02 parts by weight of

BaO, 0.01 parts by weight of SrO, 0.02 parts by weight of Cr, 0.03 parts by weight of Ni, 0.1

parts by weight of Ba, 0.1 parts by weight of Sr, 0.05 parts by weight of Co, 0.5 parts by

weight of Cu, 0.08 parts by weight of Li, 0.08 parts by weight of Nb, 0.06 parts by weight of

Nd, 0.02 parts by weight of Y, 7 parts by weight of C, 2 parts by weight of Zr, 0.05 parts by

weight of Zn, 0.3 parts by weight of Ce, 0.2 parts by weight of Sn, 0.05 parts by weight of La,

0.02 parts by weight of Ge and 0.01 parts by weight of Yb.

(Test 1)

The efficacies of the far-infrared radiation material prepared in Example 1 are

determined through various tests as follows:

1. Measurement of far-infrared emissivity

The far-infrared radiation material prepared in Example 1 is compared in regards to the

far-infrared emissivity with jade, sericite, Mcbansuk, Keumkang yakdol and loess all of which

exhibit high emissivity of far-infrared rays. The results are listed in Table 1. [Table 1]

Measured Values of Far-infrared Emissivity.

As shown in Table 1, the present invention composition of a far-infrared radiation

material is more excellent in the far-infrared emissivity relative to natural ores (jade, sericite,

Mcbansuk, Keumkang yakdol and loess) which are known to have high far-infrared emissivity.

2. Test of Antimicrobial Function.

A test is performed for the antimicrobial function of the far-infrared radiation material

prepared in Example 1 and the results are listed in Table 2.

Test code: KICM-FIR-1002

Used strains: Escherichia coli ATCC 25922, Pseudomonas aeruginosa ATCC 15442

[Table 2]

Results of Antimicrobial Function Test.

As shown in the table, the present invention composition of a far-infrared radiation

material has an excellent antimicrobial function.

3. Test of Air Purification (Deodorization)

A deodorization test is performed for the far-infrared radiation material prepared in

Example 1 and the results are listed in Table 3.

Test code: KICM-FIR-1004

Name of gas tested: ammonia

Measurement of gas concentration: gas detection tube

[Table 3]

Results of Deodorization Test.

The table shows that the present invention composition of a far-infrared radiation

material has a good deodorization function.

4. Test of Anti-fungal Function

A test is performed for the anti-fungal function of the far-infrared radiation material

prepared in Example 1 and the results are listed in Table 4.

Test code: ASTM G-21

Test fungal isolate (mixed isolates): Aspergillus Niger ATCC 9642

Penicillium Pinophilum ATCC 11797

Chaetomium Globosum ATCC 6205

[Table 4]

Results of Anti-fungal Function Test.

The table shows that the present invention composition of far-infrared radiation

materials has a good anti-fungal function.

5. Test of Blood Circulation Activating Function

A test is performed to study the activation of blood circulation with the far-infrared radiation material prepared in Example 1.

At the room temperature of 17°C, the far-infrared radiation material prepared in

Example 1 is put around the neck of a person to be tested with his face being at 29.7 ^°C, and

the temperature of his face is measured after 10 min (the temperature is 30.4 °C risen from

29.7 °C by 0.7 °C). Photographs of the face taken with a thermography reveal that the blood

circulation has been activated all over the face (refer to Fig. 1).

Also, the temperature of the left hand is measured first at the room temperature of 17

°C, and the temperature is measured again for the left hand after holding the far-infrared

radiation material prepared in Example 1 with the right hand for about 10 min. The result

shows that the left hand is increased in the temperature by 1 °C after 10 min with the right hand

holding the far-infrared radiation material without an addition of external heat and that the

temperature rises dramatically on the end of fingers (refer to Fig. 2).

6. Test of Vital Strength (Grasping Power) Enhancement

Experiment 1 : O-ring test of vital strength enhancement

1 ) O-ring test is to determine as to whether or not a food stuff suits the physical

constitution of a person by compulsorily opening the O-ring formed with his thumb and index

fingers of the right hand with the left hand grasping the food stuff. If the food stuff is suitable

to the constitution, the fingers do not lose strength but persist in forming O-ring against any

external force.

2) It is general under the O-ring test that the grasping power of the index or middle

finger is strong enough but that of the ring or little finger is weakened even when the food stuff

suits the physical constitution of the person. However, the index, middle, ring and little fingers of the right hand are all strong in forming the O-ring in the O-ring test performed with the left

hand holding the multipurpose material of Example 1.

3) 2 or 3 out of 100 persons have ring fingers strong in nature in the O-ring test

normally, but the little fingers are still weak. However, the little finger of the right hand does

not lose the strength but becomes strong in forming the O-ring while the left hand grasps the

material of Example 1 in the O-ring test.

4) Persons who suffer from neck ruptured disk have grasping power not strengthened

with the material of Example 1 on occasion but, after holding the material of Example 1 for

about 10-30 min, have grasping power increased even with the ring and little fingers in the O-

ring test. This phenomenon appears more rapidly with the material placed under the feet than

grasped with the hand.

Experiment 2: Test with grasping power tester.

1) For 20 persons, the grasping power with the thumb and ring fingers is measured

before and after using the material of Example 1, and the results are listed in Table 5.

[Table 5]

Experiment 3 : Weight (barbell) lifting

1) All 10 persons in their forties can lift a 30 kg barbell with one hand more easily when

they holds the material of Example 1. 7. Function of Preventing Declination of Strength Due to Electromagnetic wave

(Reducing Electromagnetic Wave Effect).

Experiment 1 : Responses after using a cellular phone for 10 min or more.

1) Compared are responses of 15 persons before and after using a cellular phone with

the material of Example 1 for more than 10 min.

[Table 6]

2) O-ring tests are performed for 15 persons who form a O-ring with the ring and little

fingers while holding a cellular phone with the left hand and all persons have strength

weakened. However, the O-ring tests performed in the similar way but with the material of

Example 1 show that 14 persons have the strength (grasping power) promoted immediately

except for one person who suffers from a neck ruptured disk and has the strength increased

after 30 min.

8. Test of Water vein Control Function

A divining rod (L-rod) is deformed into X-shape when finding a water vein

(underground water or minerals) but into 11-shape in parallel when a water vein is controlled or

interrupted. After finding a spot having underground water or minerals with a divining rod (L

rod), a 5 cm x 5 cm x 0.1 mm non-woven fabric coated with the material of Example 1 is

placed on the spot. The divining rod over the spot on which the non-fabric is placed becomes

parallel into 11-shape, which indicates that the water vein is interrupted or controlled by the material of Example 1. It is noticeable that a copper or aluminum plate must cover the whole

area for the water vein to be interrupted but the material of Example 1 has an effect on the area

within the radius of more than 100 times as large as the area of it.

9. Test of Water Quality Improvement

Experiment 1 : pH control of water (Increase in the alkalinity)

The material of Example 1 is placed under a cup filled with water whose pH is 6-7.

After 3-10 min, pH of the water is increased to pH 8-8.3.

Experiment 2:

A filter is prepared from the material of Example 1 fired at 900-1300 °C and pulverized

to 30-40 meshes, and a water having pH 6-7 is passed through the filter. Then, the measured

pH of the water is 8-8.3.

Experiment 3:

NMR (Nuclear Magnetic Resonance) spectra of tap water are obtained before and after

the same filter as used in Experiment 2.

The spectrum of the tap water appears at 108 Hz before the filter made from the

material of Example 1 but is shifted to 51 Hz after the filter. It is reported that the movement

of water molecules is active to give a high water quality as the NMR spectrum appears higher.

Accordingly, the present invention material is turned out to have an effect to activate water

movement and improve water quality.

Fig. 3 shows an NMR spectrum of water before passing through the filter made from

the present invention material of Example 1, while Fig. 4 showing an NMR spectrum of water

after the filter. As described above, the composition of a far-infrared radiation material according to

the present invention has multiple functions such as emission of non-thermal far-infrared rays,

like. Especially, the present invention is applicable to every fields of industry concerning

environments, water quality and soil improvement, water purification, health products and hot

medical applications, farm-livestock-fisheries products, floriculture, construction, building,

food storage and processing, space-air, maglev magnetism, special alloyed steel, motor vehicle,

sports, electrical and electronics, and so on.

Industrial Applicability

As follows are the applications of the present invention composition of a far-infrared

radiation material:

1. Various materials participating in production of industrial products related to air

purification.

2. Materials for improving water quality to obtain clean and potable water and being

applicable to the fields of industry related to water purifier, purified water, sauna facilities,

purification of waste water, potable water, bath water, water for industrial uses, and the like.

3. Materials having special multipurpose functions that enhance health and life

environments in association with far-infrared rays for different industrial products in every

fields of industries concerning: construction materials, food life, confectionery, kitchen utensils,

medicine and medical applications, health-enhancing foods, food processing, beverage and

drinkables, alcoholic drink, accessories, sports, pharmacy, medical treatment and recuperation,

farm-livestock-fisheries products and the related processing, heating, electric appliances and

electronics, ceramics, paper manufacture, inks, petrochemicals, household articles, textile,

apparel, bedding, toiletries, motor vehicles, vessels, flight, space-air, maglev magnetism,

special alloyed steel, superconductivity and photocatalyst, heat resistant alloys, special fine

ceramic, housing, restaurant business, hotel and lodging, hairdressing, sanitation, nonferrous

metals, jewelry and precious metals, rubber, plastics, synthetic resins, timbers, necessities of

life such as footwear, headgear, gloves and so on, paints, labels, sticker, fancy, cement, iron

ore, office supplies and applications, infant articles, lighting fixtures, pipe, electromagnetic

wave and water vein control and shielding systems, energy power system, sanitary ware, bathtub, data communication appliances, apical new materials, etc..

Claims

ClaimsWhat is claimed is:

1. A composition of a multipurpose far-infrared radiation material, the composition

comprising:

0.2-38 parts by weight of at least one non-metal compound selected from the group

consisting of SiO₂ and P₂O₅;

0.01-70 parts by weight of at least one metal compound selected from the group

consisting of TiO₂, Al₂O₃, Fe₂O₃, FeO, MnO, MgO, CaO, NaA K₂O, Cr₂O₃, NiO, BaO and

SrO;

0.01-2 parts by weight of at least one rare earth element selected from the group

consisting of Nd, Y, Ce, Sm, La and Yb; and

0.02-18 parts by weight of at least one element selected from the group consisting of

C, Cr, Ni, Ba, Sr, Co, Cu, Li, Nb, Zr, Zn and Ge.