KR20000038422A - Multi-functional far-infrared radiating material composition - Google Patents

Abstract

PURPOSE: A far-infrared radiating material composition is provided, which radiates non-heating far-infrared light, improves vital force, cleans air adsorbs and neutralizes harmful electromagnetic wave, controls a water vein wave, and improves the quality of water and soil. CONSTITUTION: A far-infrared radiating material composition comprises 0.2-38 parts by weight of at least one non-metal compound selected from SiO2 and P2O5; 0.01-70 parts by weight of at least one metal compound selected from 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 Nd, Y, Ce, Sm, La and Yb; and 0.02-18 parts by weight of at least one element selected from C, Cr, Ni, Ba, Sr, Co, Cu, Li, Nb, Zr, Zn and Ge.

Description

Far-infrared radiation material composition with multipurpose function

The present invention relates to a novel far-infrared radiation material composition having a multi-purpose function such as non-heat source infrared radiation function, energy enhancement function, air purification function, harmful electromagnetic wave absorption or neutralization function, water wave control function, water quality and soil improvement function. In particular, the present invention is due to the above functions, environmental industry, water quality and soil improvement, water purification industry, health aids and thermal medical equipment industry, agricultural and fishery industry and flower cultivation industry, architecture, construction industry, New far-infrared rays with versatile functions that can be used in various industries such as food storage and cooking, aerospace, magnetic levitation, special alloy steel, automotive, sports, and electrical and electronics The present invention relates to a spinning material composition.

Far infrared rays are the focus of attention because of their energy efficiency and positive effects on human body and food. Far-infrared rays are rays of the wavelength range of 5-1000㎛, which is the longest wavelength among the infrared rays visible to our eyes, and has the same wavelength band as water, which is the main component of the human body. It has a direct effect on the body's physiological activation, strongly binds water molecules to activate water, keeps all food fresh, tastes good, removes odors, promotes growth of animals and plants, In the field of drying, it can be heated and dried uniformly, and it can reduce heating and drying time, and it is a light beam that has the effect of raising the temperature at the same time to the surface and the inside.

Conventional techniques related to the far-infrared radiation substance having the above-mentioned efficacy include, for example, Korean Patent Publication No. 94-2031, Korean Patent Publication No. 94-5085, Korean Patent Publication No. 96-7375, and the like. The prior art relates to a material having only a far infrared ray effect, and does not have a non-heat infrared ray radiation function in which far-infrared energy is radiated even without applying heat, and effects such as energy enhancement, absorption or neutralization of harmful electromagnetic waves, and water-wave control function can be obtained. There was no. In addition, there is a technique for neutralizing harmful electromagnetic waves, there is a Korean Patent Publication No. 97-21141, but this technique only relates to a technique for shielding harmful electromagnetic waves, non-heat source infrared radiation function, energy enhancement function, air purification function, water wave control function, water quality And effects such as soil improvement could not be obtained.

It is an object of the present invention to provide a novel far-infrared radiation material composition having a multipurpose function such as non-heat source infrared radiation function, energy enhancement function, air purification function, harmful electromagnetic wave absorption or neutralization function, water wave control function, water quality and soil improvement function. .

The novel far-infrared radiation material composition having a multipurpose function according to the present invention for achieving the above object is 0.2-38 parts by weight of at least one nonmetallic compound selected from SiO ₂ and P ₂ O ₅ , TiO ₂ , Al ₂ O ₃ , 0.01-70 parts by weight of at least one metal compound selected from Fe ₂ O ₃ , FeO, MnO, MgO, CaO, Na ₂ O, K ₂ O, Cr ₂ O ₃ , NiO, BaO, and SrO, Nd, Y, 0.01-2 parts by weight of at least one rare earth element selected from Ce, Sm, La, and Yb, and at least one selected from C, Cr, Ni, Ba, Sr, Co, Cu, Li, Nb, Zr, Zn, and Ge 0.02-18 weight part of above elements are contained.

In addition, the present invention in the far-infrared radiation material composition having the composition as described above ocher, elvan, feldspar, feldspar, hornblende, biotite, green stone, ammonite, biotite, talc, jade, serpentine, citrine serpentine, tourmaline, rare earth stone, permeability Island stone, stone, feldspar, zeolite, zeolite, charcoal, clay, silica, titanium iron, green stone, garnet, zirconite, quartz, stone, olive, malachite, crystal, jasper, pearl, sapphire, ruby, turquoise, chalcedony, tiger stone, Emerald, Agate, Cat's Eye, Water Stone, Brass, Copper, Aluminum, Tungsten, Black Jade, Garnet, Impression Graphite, Sand, Sinter Sand, Granite, Marble, Cement, Water, Metals, Nonferrous Metals, Plastic, Fiber, Asphalt, Wood, Cotton Yarn Non-wovens, rubbers, pigments, paints, inks, pulp (paper), glass, ceramics, tiles, artificial jewelry, vinyl, cork, adhesives, silicones, and all non-metallic materials and metal materials may be mixed or coated.

The composition ratio as described above is to select such materials that emit far-infrared rays, and to measure the powder and wavelength of the far-infrared radiation for a long period of time while changing the composition ratio of them, the energy enhancement test, harmful electromagnetic interference mitigation test, water wave as described below The control tests limit the most efficient range.

The component contained in the far-infrared radiation material composition of this invention is mix | blended as a powder and forms a composition. The composition may be used without firing, or as necessary (depending on the application), fired at a high temperature firing, that is, at a temperature of 100-2500 ° C., and then pulverized or molded. The powder particle size of the far-infrared radiation material thus obtained is not particularly limited, but is preferably pulverized to about 10-1000 mesh in consideration of compounding properties and molding processability in various applications as described below.

For example, the application field of the far-infrared radiation material according to the present invention is as follows:

1. Apply to all materials of environmental industry to produce industrial products for air purification.

2. As time goes by, the quality of water becomes muddy and the water for eating decreases, and it is used as a material to improve water quality, such as drinking water, bathing water, living water, industrial water, such as water purifier industry, bottled water, sauna industry, and waste water purification industry. Applies to the product.

3. With far-infrared and multi-purpose functions, construction materials industry, dietary life, confectionery industry, kitchen equipment, medical and medical device industry, health equipment, health supplement food, food processing industry, various drinks beverage and liquor industry , Health care equipment industry, accessories industry, sporting goods industry, pharmaceutical industry, nursing and recreation industry, concentrated fishery cultivation and processing, special mortar industry, heating industry, home appliance and electronics industry, ceramics industry, Paper, ink, petrochemical, furniture, textiles, clothing, bedding, cosmetics, automobiles, ships, airplanes, aerospace, magnetic levitation, special alloy steel, superconducting Photocatalyst industry, heat-resistant alloy industry, special fine ceramics industry, housing industry, catering industry, hotel and hospitality industry, beauty salon, sanitation industry Ya, non-ferrous metals, jewelry and precious metals, rubber, plastics, plastics, wood, shoes, hats, gloves, daily necessities, paints, labels, stickers, fancy, cement, iron ore Industrial sector, office equipment and office equipment industry, baby products industry, lighting equipment industry, pipe industry, electromagnetic wave and water wave control and blocking system industry, energy power system industry, sanitary ware and bathtub industry, information and communication It adds functions to products of all industries, such as the device industry and advanced new material industry, to promote human health and benefit the living environment.

Hereinafter, an example of the far-infrared radiation material composition which concerns on this invention is given and demonstrated.

(Example 1)

Far-infrared radiation material was manufactured at the following composition ratio.

Composition ratio: 35 parts by weight of SiO ₂ , 8 parts by weight of TiO ₂ , 13 parts by weight of Al ₂ O ₃ , 8 parts by weight of Fe ₂ O _3, 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, Na ₂ O 2.5 parts by weight, K ₂ O 2.5 parts by weight, Cr ₂ O ₃ 0.4 parts by weight, P ₂ O ₅ 0.5 parts by weight, NiO 0.2 parts by weight, BaO 0.02 parts by weight, SrO 0.01 parts by weight, Cr 0.02 parts by weight, Ni 0.03 part by weight, Ba 0.1 part by weight, Sr 0.1 part by weight, Co 0.05 part by weight, Cu 0.5 part by weight, Li 0.08 part by weight, Nb 0.08 part by weight, Nd 0.06 part by weight, Y 0.02 part by weight, C 7 part by weight, Zr 2 parts by weight, Zn 0.05 parts by weight, Ce 0.3 parts by weight, Sn 0.2 parts by weight, La 0.05 parts by weight, Ge 0.02 parts by weight, Yb 0.01 parts by weight.

(Test example)

In order to determine the efficacy of the far-infrared radiation material prepared as described above was tested as described below.

1. Far Infrared Emissivity Measurement Test

The far-infrared emissivity of the far-infrared emissive material prepared in Example 1 and the far-infrared emissivity of natural ore were measured and compared with jade, biotite, elvan, chalcopyrite, loess. The results are shown in Table 1.

Far Infrared Emissivity Measurement Results Sample name Measurement temperature (℃) Wavelength band (㎛) Emissivity (%) Radiation energy (W / m ² · ㎛) Spinning temperature (℃) Example 1 40 5-20 96 3.87 × 10 ² 36.8 purgatory 40 5-20 93 3.74 × 10 ² 35.3 Cicada 40 5-20 93 3.74 × 10 ² 35.7 Elvan 40 5-20 92 3.70 × 10 ² 35.7 Geumgang Stone 40 5-20 92 3.70 × 10 ² 35.4 ocher 40 5-20 93 3.74 × 10 ² 35.4 The measurement results were measured by comparing the black body using the FT-IR spectrometer. The radiation temperature was measured at a measurement temperature of 19 ° C. and a humidity of 70%.

As can be seen in Table 1, the far-infrared radiation material composition of the present invention is excellent in far-infrared emissivity compared to natural ore (purine, chorionic mica, elvan, chalcopyrite, loess) known to have high far-infrared emissivity.

2. Antibacterial function test

The antibacterial test of the far-infrared radiation material prepared in Example 1 was carried out as follows, and the results are shown in Table 2.

Test Method: KICM-FIR-1002

Strains used: Escherichia coli ATCC 25922, Pseudomonas aeruginosa ATCC 15442

Antibacterial test result Test Items Sample classification Initial concentration (dog / ml) After 6 hours (dog / ml) After 24 hours (pcs / ml) Bacterial Reduction Rate (%) Test by E. coli Control 267 271 261 2.2 Example 1 193 28 2 99.3 Test by Pseudomonas aeruginosa Control 680 660 660 2.9 Example 1 580 17 4 99.4 -The control was measured without the sample.-The number of bacteria on the medium was calculated by multiplying the dilution factor.

As can be seen from these results, the far-infrared radiation material composition of the present invention is excellent in antibacterial activity.

3. Air purification function test (deodorization test)

The deodorization test of the far-infrared radiation material prepared in Example 1 was as follows, and the results are shown in Table 3.

Test Method: KICM-FIR-1004

Test gas name: Ammonia

Gas concentration measurement: gas detector

Deodorization test result Elapsed time (minutes) Control concentration (ppm) Sample concentration (ppm) Deodorization rate (%) Early 500 500 - 30 490 140 71 60 440 80 82 90 390 30 92 120 390 20 95 Control was measured with no sample

As can be seen from this result, the far-infrared radiation material composition of the present invention is excellent in air purification function.

4. Antifungal function test

The antifungal function test of the far-infrared radiation material prepared in Example 1 was carried out as follows, and the results are shown in Table 4.

Test Method: ASTM G-21

Test fungal strains (mixed strains): Aspesgillus niger ATCC 9642

Penicillium Pinophilum ATCC 11797

Kaetoum Globosum ATCC 6205

Antifungal Test Results Culture test period 1 week later after 2 weeks 3 weeks later 4 weeks later result O O O O Reading of results: O cannot recognize the growth of bacteria in the sample

As can be seen from these results, the far-infrared radiation material composition of the present invention is excellent in antifungal function.

5. Blood circulation activation function

In order to determine the blood circulation activation function of the far-infrared radiation material prepared in Example 1, the following test was carried out.

The temperature was measured after 10 minutes by wearing the far-infrared radiation material prepared in Example 1 on the neck at a room temperature of 17 ° C. in a cold state (29.7 ° C.). When taken with an infrared thermal imager, it can be seen that blood circulation progresses over the entire face (see Figure 1 below).

In addition, when comparing the condition of the left hand after holding the material of Example 1 in the right hand and 10 minutes after holding the material of Example 1 in a cold state with a room temperature of 17 ° C., the temperature was increased by 1 ° C. than before the heat was applied without the need for heating. The temperature rose significantly (see Figure 2 below).

Pic 1

Picture 2

6. Energy improvement test

Experiment 1: Energy Enhancement Test by O-ring Test

1) When the food is constitution, hold the food on the left hand and make a "circle (O)" shape with the thumb and the second finger of the right hand to check whether or not the subject is going to give power to the operator is called "O-ring test". At this time, if it is beneficial to the body, the operator's fingers made of O-type does not fall out of force, the phenomenon appears.

2) When holding the material of Example 1 having a multi-purpose function in the left hand and performing the O-ring test on the second, third, fourth, and fifth fingers of the right hand, even if the food suitable for the constitution of the body, even the second or third finger appears strongly but the fourth Until the fifth finger is weak. However, in the material of Example 1, a strong force appears to the fourth and fifth fingers.

3) Normally, 2-3 of 100 people were born with strong fourth finger strength, but the fifth finger also showed weak strength. However, a strong force appeared on the fifth finger immediately with the material of Example 1.

4) Occasionally, a person with a symptom of neck disc did not get strong grip strength even when holding the material of Example 1, but after O-ring test after having the material of Example 1 for about 10-30 minutes, It was confirmed that the force increased to the fifth finger, and in this case, the effect appeared at a faster time when placed under the foot than held in the hand.

Experiment 2: Test by Grip Tester

1) As a result of measuring the grip strength of the fourth finger without the material of Example 1 with a weak thumb and strength with 20 grip strength testers, the after holding was measured as follows.

0.5kg more than before 5 people 1.0kg more than before 10 people 1.5kg more than before 3 people 1.7kg more than before 2 people

Experiment 3: Test by Lifting Barbell

1) When a 30kg barbell was lifted by one hand to 10 adults in their 40s, it was hardly lifted up before having the material of Example 1, but after lifting the material of Example 1, all 10 people were lightly lifted.

7. Test of electromagnetic decay prevention function (electromagnetic interference mitigation function) test

Experiment 1: Reaction Measurement Test After Using Mobile Phone for More Than 10 Minutes

1) Comparison of after 15 minutes of use of the mobile phone without using the material of Example 1 for at least 10 minutes

When used without attaching the material of Example 1 When the raw material of Example 1 is attached and used Thirteen out of fifteen patients had earring or headache symptoms Of the 13 who felt abnormal, 12 did not have any ringing or headache symptoms

2) When 15 people held a cell phone in their left hand and conducted an O-ring test on the fourth and fifth fingers of their right hand, all 15 showed weak strength. However, after the O-ring test of the fourth and fifth fingers after attaching the material of Example 1, it was confirmed that one person had a symptom of neck disc, and 30 minutes later, the remaining 14 immediately became strong (grip strength).

8. Water wave control function test

When water vein occurs, the water vein rods are severely crossed in X shape, but when water veins do not exist or are controlled or blocked, they appear in 11 shape in parallel, where the water vein flows through the water vein rods (L rod). After checking the material of Example 1 was coated with a nonwoven fabric having a size of 5 cm x 5 cm * 0.1 mm, and the exploration bar with the water vein probe was found to be parallel to the eleven shape. This shows that the water wave is blocked or controlled due to the material of Example 1. The unusual phenomenon is that when blocking the vein with a copper plate or an aluminum plate, they should be laid over the entire area where the vein flows, but in the case of the material of Example 1, a control effect of 100 times or more was shown.

9. Water quality improvement function test

Experiment 1: pH change function of water (alkaline concentration increase)

After putting the water having a pH concentration of 6-7 into the cup, the material of Example 1 was placed under the cup, and the pH was measured after 3-10 minutes. As a result, the alkaline concentration of pH 8-8.3 was increased.

Experiment 2

The material of Example 1 was calcined at 900-1300 ° C. and powdered to 30-40 # to make a filter, and then the pH was measured to be 8-8.3 after passing through water having a pH of 6-7. .

Experiment 3

The water spectrum was measured by a nuclear magnetic resonance apparatus (NMR) before and after the tap water was passed through the same filter used in Experiment 2 above.

As a result, the spectrum of water before passing through the filter of the material of Example 1 was 108 Hz, but the spectrum of water after passing through was changed to 51 Hz. (The smaller the nuclear magnetic resonance spectrum is, the better the water molecule motion is.) . Therefore, it can be seen that the material of the present invention has an effect of improving water quality by activating water.

Graph 1 shows the result of measuring the water before passing the filter made of the material of the present invention by a nuclear magnetic resonance device (NMR), graph 2 shows the nuclear magnetic water after passing the filter made of the material of the present invention It shows the result measured by the resonance apparatus.

Graph 1: Measurement result by nuclear magnetic resonance apparatus (NMR) before passing the filter

Graph 2: Measurement result by nuclear magnetic resonance device (NMR) after passing filter

As described above, the far-infrared radiation material composition according to the present invention has a multi-purpose function such as non-heat source infrared radiation function, energy enhancement function, air purification function, harmful electromagnetic wave absorption or neutralization function, water wave control function, water quality and soil improvement function Due to these functions, the environmental industry, water quality and soil improvement, water purification industry, health aid and thermal medical device industry, aquaculture and fishery industry and flower growing industry, architecture, construction industry, food storage and cooking industry It can be used in various industries such as field, aerospace, magnetic levitation, special alloy steel, automobile, sports, electric and electronics.

Claims (1)

0.2-38 parts by weight of at least one nonmetallic compound selected from SiO ₂ and P ₂ O ₅ , TiO ₂ , Al ₂ O ₃ , Fe ₂ O ₃ , FeO, MnO, MgO, CaO, Na ₂ O, K ₂ O, 0.01-70 parts by weight of at least one metal compound selected from Cr ₂ O ₃ , NiO, BaO, and SrO, 0.01-2 parts by weight of at least one rare earth element selected from Nd, Y, Ce, Sm, La, and Yb, And 0.02-18 parts by weight of at least one element selected from C, Cr, Ni, Ba, Sr, Co, Cu, Li, Nb, Zr, Zn and Ge. Material composition.