CN106495642A - A kind of radiative material that just can be efficiently releasing far infrared without the need for heating - Google Patents
A kind of radiative material that just can be efficiently releasing far infrared without the need for heating Download PDFInfo
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- CN106495642A CN106495642A CN201610923365.0A CN201610923365A CN106495642A CN 106495642 A CN106495642 A CN 106495642A CN 201610923365 A CN201610923365 A CN 201610923365A CN 106495642 A CN106495642 A CN 106495642A
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- far infrared
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- C—CHEMISTRY; METALLURGY
- C04—CEMENTS; CONCRETE; ARTIFICIAL STONE; CERAMICS; REFRACTORIES
- C04B—LIME, MAGNESIA; SLAG; CEMENTS; COMPOSITIONS THEREOF, e.g. MORTARS, CONCRETE OR LIKE BUILDING MATERIALS; ARTIFICIAL STONE; CERAMICS; REFRACTORIES; TREATMENT OF NATURAL STONE
- C04B28/00—Compositions of mortars, concrete or artificial stone, containing inorganic binders or the reaction product of an inorganic and an organic binder, e.g. polycarboxylate cements
- C04B28/24—Compositions of mortars, concrete or artificial stone, containing inorganic binders or the reaction product of an inorganic and an organic binder, e.g. polycarboxylate cements containing alkyl, ammonium or metal silicates; containing silica sols
- C04B28/26—Silicates of the alkali metals
Abstract
The invention discloses a kind of radiative material that just can be efficiently releasing far infrared without the need for heating, the material just can be efficiently releasing far infrared without the need for heating, and preferably Applicable temperature is 36 DEG C, including each raw material of following weight portion:4 ~ 6 parts of zinc oxide, 4 ~ 8 parts of Titanium Dioxide, 8 ~ 12 parts of zirconium oxide, 5 ~ 15 parts of silicon dioxide, 10 ~ 20 parts of Calcium Carbonate, 4 ~ 8 parts of lead oxide, 5 ~ 10 parts of ferroso-ferric oxide, 10 ~ 20 parts of sodium silicate, 40 ~ 50 parts of water.What the invention was provided need not heat radiative material that just can be efficiently releasing far infrared, raw material is relatively easily obtained, preparation technology flow process is simple, cost of manufacture is cheap,, up to more than 87%, far infrared release rate is high for the release rate of the far infrared of the radiative material for preparing, and need not provide high ambient conditions during application, suitable environment is simple, will not constitute the injury brought because of high temperature to human health.
Description
Technical field
The present invention relates to radiative material technical field, and in particular to a kind of need not heating just can be efficiently releasing far infrared
Radiative material.
Background technology
Far infrared is one section of most long infrared ray its wave-length coverage of infrared ray medium wavelength between 5 ~ 100um.It is electricity
One kind of magnetic wave;It is black light, but possesses all characteristics that visible ray has, and it can have stronger penetration and spoke
Power is penetrated, with significant temperature control effect and resonance effect, it is easily absorbed by object and is converted into the interior energy of object.Fluctuate as 8 ~
After the far infrared of 15nm is absorbed by the body, internal water can be made to produce resonance, made water molecule activation, strengthened which intermolecular
Adhesion, so as to biomacromolecules such as activation of protein, makes biological cell be in highest vibration level.As biological cell is produced
Far infrared heat energy can be delivered to the subcutaneous deeper part of human body by raw resonance effect, and following deep layer temperature rises, the warm of generation
Distribute from inside to outside.This action intensity, makes telangiectasis, blood circulation promoting strengthen the new old generation between each tissue
Thank, increase the regeneration capacity of tissue, improve the immunocompetence of body, adjust the exaltation state of spirit, so as to play medical treatment
The effect of health care.Far-infrared transmitting function under room temperature, by promoting blood circulation of human body, adjusts circulatory function, favourable human body
Health, and reach good warming effect.And the far-infrared radiation material for providing on the market at present is in use, all have to pass through
High-temperature heating, says from the angle of health care, and lasting hot environment is unhelpful to human health, or even causes skin mucosa to wait
The symptoms such as quick, aging, damage.In the past, the material for being capable of far infrared is limited to the condition of relatively-high temperature heating and cannot obtain
Arrive commonly used.
Content of the invention
Instant invention overcomes above-mentioned shortcoming, and a kind of radiation material that just can be efficiently releasing far infrared without the need for heating is provided
Material.
To achieve these goals, first of the invention purpose be to provide a kind of just efficiently can discharge without the need for heating far red
The radiative material of outside line, the material just can be efficiently releasing far infrared without the need for heating, including each raw material of following weight portion:Oxidation
4 ~ 6 parts of zinc, 4 ~ 8 parts of Titanium Dioxide, 8 ~ 12 parts of zirconium oxide, 5 ~ 15 parts of silicon dioxide, 10 ~ 20 parts of Calcium Carbonate, oxygen
Change 4 ~ 8 parts of lead, 5 ~ 10 parts of ferroso-ferric oxide, 10 ~ 20 parts of sodium silicate, 40 ~ 50 parts of water.
Preferably, should without the need for heating just can be efficiently releasing far infrared radiative material include each original of following weight portion
Material:4 parts of zinc oxide, 4 parts of Titanium Dioxide, 8 parts of zirconium oxide, 5 parts of silicon dioxide, 10 parts of Calcium Carbonate, lead oxide 4
Part, 5 parts of ferroso-ferric oxide, 10 parts of sodium silicate, 40 parts of water.
Preferably, should without the need for heating just can be efficiently releasing far infrared radiative material include each original of following weight portion
Material:5 parts of zinc oxide, 5 parts of Titanium Dioxide, 10 parts of zirconium oxide, 0 part of silica 1,15 parts of Calcium Carbonate, lead oxide
6 parts, 8 parts of ferroso-ferric oxide, 15 parts of sodium silicate, 45 parts of water.
Preferably, should without the need for heating just can be efficiently releasing far infrared radiative material include each original of following weight portion
Material:6 parts of zinc oxide, 8 parts of Titanium Dioxide, 12 parts of zirconium oxide, 5 parts of silica 1,20 parts of Calcium Carbonate, lead oxide
8 parts, 10 parts of ferroso-ferric oxide, 20 parts of sodium silicate, 50 parts of water.
Preferably, the Applicable temperature of the material is -40 DEG C ~ 39 DEG C.
It is furthermore preferred that the Applicable temperature of the material is 36 DEG C
Second object of the present invention is to provide a kind of preparation of radiative material that just can be efficiently releasing far infrared without the need for heating
Method, the preparation method are comprised the following steps:
1)Zinc oxide, Titanium Dioxide, zirconium oxide, silicon dioxide, Calcium Carbonate, lead oxide and four oxidations three are weighed in proportion respectively
Ferrum;
2)By step 1)In each raw material difference input air flow pulverizer in, crush respectively at normal temperatures;
3)By step 2)The middle each raw material for completing of crushing is put in agitator, is stirred 15 ~ 30min, until being sufficiently mixed uniformly, is obtained
A is expected to before pelletize;
4)Weigh sodium silicate and water in proportion respectively and stir mixing completely, before obtaining pelletize, expect b;
5)To expect before material a before pelletize and pelletize that b is sent in blender, stirs 30 ~ 45min, expects before obtaining pelletize;
6)Take out step 5)In pelletize before expect, send into comminutor in extruder grain, obtain base substrate, wherein, comminutor pressure sets
30 ~ 38 MPa are set to, base substrate is obtained;
7)The base substrate of extrusion molding is sent into, and wherein, oven temperature is 910 ~ 1125 DEG C, is down to naturally
Room temperature, obtains radiative material precursor;
8)By step 7)In radiative material precursor send into baking oven in dry 30min, oven temperature be 300 ~ 400 DEG C, naturally drop
To room temperature, radiative material is obtained.
Third object of the present invention be to provide this without the need for heating just can be efficiently releasing far infrared radiative material in oil
The application in the fields such as ink, coating, paint, pottery, glass, metal, leather, stationery.
The invention has the beneficial effects as follows:In the present invention without the need for heating just can be efficiently releasing far infrared radiative material former
Material is relatively easily obtained, and preparation technology flow process is simple, and cost of manufacture is cheap;The radiative material for preparing produces remote without the need for heating
, up to more than 87%, far infrared release rate is of a relatively high for ultrared qualified release rate;Hot environment need not be provided during application
Condition, suitable environment are simple;The injury brought because of high temperature will not be constituted to human health;The material ink, coating, paint,
The fields such as pottery, glass, metal, leather, stationery widely can be applied, and application market has a extensive future.
Specific embodiment
Embodiment 1
Comprise the following steps in the preparation method of radiative material that just can be efficiently releasing far infrared without the need for heating:
1)Weigh respectively in proportion zinc oxide 4kg, Titanium Dioxide 4kg, zirconium oxide 8kg, silicon dioxide 5kg, 10 kg of Calcium Carbonate,
4 kg of lead oxide, 5 kg of ferroso-ferric oxide;
2)By step 1)In each raw material difference input air flow pulverizer in, crush respectively at normal temperatures;
3)By step 2)The middle each raw material for completing of crushing is put in agitator, is stirred 15min, until being sufficiently mixed uniformly, is obtained
A is expected before pelletize;
4)Weigh sodium silicate 10kg and water 40kg in proportion respectively and stir mixing completely, before obtaining pelletize, expect b;
5)To expect before material a before pelletize and pelletize that b is sent in blender, stirs 30min, expects before obtaining pelletize;
6)Take out step 5)In pelletize before expect, send into comminutor in extruder grain, obtain base substrate, wherein, comminutor pressure sets
30 MPa are set to, base substrate is obtained;
7)The base substrate of extrusion molding is sent into, and wherein, oven temperature is 910 DEG C, is down to room temperature naturally, obtains
Radiative material precursor;
8)By step 7)In radiative material precursor send into, oven temperature is 300 DEG C ~ 400 DEG C, natural
Room temperature is down to, radiative material is obtained.
Wherein, the radiative material is added in a metal, when ambient temperature is -40 DEG C, far infrared
Qualified release rate reaches 87%.
Embodiment 2
Comprise the following steps in the preparation method of radiative material that just can be efficiently releasing far infrared without the need for heating:
1)Zinc oxide 5kg, Titanium Dioxide 6kg, zirconium oxide 10kg, silica 1 2kg, Calcium Carbonate 15 are weighed in proportion respectively
Kg, 6 kg of lead oxide, 8 kg of ferroso-ferric oxide;
2)By step 1)In each raw material difference input air flow pulverizer in, crush respectively at normal temperatures;
3)By step 2)The middle each raw material for completing of crushing is put in agitator, is stirred 20min, until being sufficiently mixed uniformly, is obtained
A is expected before pelletize;
4)Weigh sodium silicate 15kg and water 45kg in proportion respectively and stir mixing completely, before obtaining pelletize, expect b;
5)To expect before material a before pelletize and pelletize that b is sent in blender, stirs 35min, expects before obtaining pelletize;
6)Take out step 5)In pelletize before expect, send into comminutor in extruder grain, obtain base substrate, wherein, comminutor pressure sets
35MPa is set to, base substrate is obtained;
7)The base substrate of extrusion molding is sent into, and wherein, oven temperature is 1000 DEG C, is down to room temperature naturally, obtains
Radiative material precursor;
8)By step 7)In radiative material precursor send into baking oven in dry 30min, oven temperature be 350 DEG C, be down to naturally room
Temperature, obtains radiative material.
Wherein, the radiative material is added in ceramic material, when ambient temperature is 36 DEG C, far red
The qualified release rate of outside line reaches 88%.
Embodiment 3
Comprise the following steps in the preparation method of radiative material that just can be efficiently releasing far infrared without the need for heating:
1)Zinc oxide 6kg, Titanium Dioxide 8kg, zirconium oxide 12kg, silica 1 5kg, Calcium Carbonate 20 are weighed in proportion respectively
Kg, 8 kg of lead oxide, 10 kg of ferroso-ferric oxide;
2)By step 1)In each raw material difference input air flow pulverizer in, crush respectively at normal temperatures;
3)By step 2)The middle each raw material for completing of crushing is put in agitator, is stirred 30min, until being sufficiently mixed uniformly, is obtained
A is expected before pelletize;
4)Weigh sodium silicate 20kg and water 50kg in proportion respectively and stir mixing completely, before obtaining pelletize, expect b;
5)To expect before material a before pelletize and pelletize that b is sent in blender, stirs 45min, expects before obtaining pelletize;
6)Take out step 5)In pelletize before expect, send into comminutor in extruder grain, obtain base substrate, wherein, comminutor pressure sets
38 MPa are set to, base substrate is obtained;
7)The base substrate of extrusion molding is sent into, and wherein, oven temperature is 1125 DEG C, is down to room temperature naturally, obtains
Radiative material precursor;
8)By step 7)In radiative material precursor send into baking oven in dry 30min, oven temperature be 400 DEG C, be down to naturally room
Temperature, obtains radiative material.
Wherein, the radiative material is added in medicated clothing dyestuff, when ambient temperature is 36 DEG C, far red
The qualified release rate of outside line reaches 88%.
The ultimate principle and principal character and advantages of the present invention of the present invention has been shown and described above.The technology of the industry
Personnel it should be appreciated that the present invention is not restricted to the described embodiments, simply explanation described in above-described embodiment and description this
The principle of invention, without departing from the spirit and scope of the present invention, the present invention also has various changes and modifications, these changes
Change and improvement is both fallen within scope of the claimed invention.The claimed scope of the invention by appending claims and its
Equivalent thereof.
Claims (8)
1. a kind of without the need for heating just can be efficiently releasing far infrared radiative material, it is characterised in that the material without the need for heating just
Can be efficiently releasing far infrared, including each raw material of following weight portion:4 ~ 6 parts of zinc oxide, 4 ~ 8 parts of Titanium Dioxide, oxidation
8 ~ 12 parts of zirconium, 5 ~ 15 parts of silicon dioxide, 10 ~ 20 parts of Calcium Carbonate, 4 ~ 8 parts of lead oxide, 5 ~ 10 parts of ferroso-ferric oxide,
10 ~ 20 parts of sodium silicate, 40 ~ 50 parts of water.
2. a kind of without the need for heating just can be efficiently releasing far infrared radiative material, it is characterised in that should without the need for heating with regard to energy
The preparation method of efficiently releasing far infrared radiative material is comprised the following steps:
1)Zinc oxide, Titanium Dioxide, zirconium oxide, silicon dioxide, Calcium Carbonate, lead oxide and four oxidations three are weighed in proportion respectively
Ferrum;
1)By step 1)In each raw material difference input air flow pulverizer in, crush respectively at normal temperatures;
2)By step 2)The middle each raw material for completing of crushing is put in agitator, stirs 15 ~ 30 min, until be sufficiently mixed uniformly,
A is expected before obtaining pelletize;
3)Weigh sodium silicate and water in proportion respectively and stir mixing completely, before obtaining pelletize, expect b;
4)To expect before material a before pelletize and pelletize that b is sent in blender, stirs 30 ~ 45 min, expects before obtaining pelletize;
5)Take out step 5)In pelletize before expect, send into comminutor in extruder grain, obtain base substrate, wherein, comminutor pressure sets
30 ~ 38 MPa are set to, base substrate is obtained;
6)The base substrate of extrusion molding is sent into, and wherein, oven temperature is 910 ~ 1125 DEG C, drops naturally
To room temperature, radiative material precursor is obtained;
7)By step 7)In radiative material precursor send in baking oven and dry 30 min, oven temperature is 300 ~ 400 DEG C, natural
Room temperature is down to, radiative material is obtained.
3. the radiative material that need not heat according to claim 1 just can be efficiently releasing far infrared, its feature exist
In including each raw material of following weight portion:4 parts of zinc oxide, 4 parts of Titanium Dioxide, 8 parts of zirconium oxide, silicon dioxide 5
Part, 10 parts of Calcium Carbonate, 4 parts of lead oxide, 5 parts of ferroso-ferric oxide, 10 parts of sodium silicate, 40 parts of water.
4. the radiative material that need not heat according to claim 1 just can be efficiently releasing far infrared, its feature exist
In including each raw material of following weight portion:5 parts of zinc oxide, 5 parts of Titanium Dioxide, 10 parts of zirconium oxide, silica 10
Part, 15 parts of Calcium Carbonate, 6 parts of lead oxide, 8 parts of ferroso-ferric oxide, 15 parts of sodium silicate, 45 parts of water.
5. the radiative material that need not heat according to claim 1 just can be efficiently releasing far infrared, its feature exist
In including each raw material of following weight portion:6 parts of zinc oxide, 8 parts of Titanium Dioxide, 12 parts of zirconium oxide, silica 15
Part, 20 parts of Calcium Carbonate, 8 parts of lead oxide, 10 parts of ferroso-ferric oxide, 20 parts of sodium silicate, 50 parts of water.
6. the radiation material that need not heat according to any one in claim 1-5 just can be efficiently releasing far infrared
Material, it is characterised in that the Applicable temperature of the material is -40 DEG C ~ 39 DEG C.
7. the radiative material that need not heat according to claim 6 just can be efficiently releasing far infrared, its feature exist
In the Applicable temperature of the material is 36 DEG C.
8. a kind of as described in claim 1 without the need for heating if can be efficiently releasing far infrared radiative material in ink, painting
The application of the application in field such as material, paint, pottery, glass, metal, leather, stationery.
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Cited By (2)
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CN109437861A (en) * | 2019-01-11 | 2019-03-08 | 淮南尚奕电子科技有限公司 | A kind of 8 ~ 14 μm of absorbing materials of inorganic far infrared and preparation method thereof |
CN112225549A (en) * | 2020-08-25 | 2021-01-15 | 深圳京鲁计算科学应用研究院 | Bionic far infrared ceramic powder material and preparation method thereof |
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