CN110405910A - A kind of preparation method of the energy-saving integrated wall of Far infrared health preservation health-care environmental-protecting - Google Patents
A kind of preparation method of the energy-saving integrated wall of Far infrared health preservation health-care environmental-protecting Download PDFInfo
- Publication number
- CN110405910A CN110405910A CN201910680467.8A CN201910680467A CN110405910A CN 110405910 A CN110405910 A CN 110405910A CN 201910680467 A CN201910680467 A CN 201910680467A CN 110405910 A CN110405910 A CN 110405910A
- Authority
- CN
- China
- Prior art keywords
- parts
- far infrared
- integrated wall
- powder
- aqueous
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Granted
Links
Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B28—WORKING CEMENT, CLAY, OR STONE
- B28B—SHAPING CLAY OR OTHER CERAMIC COMPOSITIONS; SHAPING SLAG; SHAPING MIXTURES CONTAINING CEMENTITIOUS MATERIAL, e.g. PLASTER
- B28B1/00—Producing shaped prefabricated articles from the material
- B28B1/14—Producing shaped prefabricated articles from the material by simple casting, the material being neither forcibly fed nor positively compacted
- B28B1/16—Producing shaped prefabricated articles from the material by simple casting, the material being neither forcibly fed nor positively compacted for producing layered articles
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B28—WORKING CEMENT, CLAY, OR STONE
- B28B—SHAPING CLAY OR OTHER CERAMIC COMPOSITIONS; SHAPING SLAG; SHAPING MIXTURES CONTAINING CEMENTITIOUS MATERIAL, e.g. PLASTER
- B28B1/00—Producing shaped prefabricated articles from the material
- B28B1/50—Producing shaped prefabricated articles from the material specially adapted for producing articles of expanded material, e.g. cellular concrete
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B28—WORKING CEMENT, CLAY, OR STONE
- B28B—SHAPING CLAY OR OTHER CERAMIC COMPOSITIONS; SHAPING SLAG; SHAPING MIXTURES CONTAINING CEMENTITIOUS MATERIAL, e.g. PLASTER
- B28B11/00—Apparatus or processes for treating or working the shaped or preshaped articles
- B28B11/001—Applying decorations on shaped articles, e.g. by painting
-
- 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
-
- C—CHEMISTRY; METALLURGY
- C09—DYES; PAINTS; POLISHES; NATURAL RESINS; ADHESIVES; COMPOSITIONS NOT OTHERWISE PROVIDED FOR; APPLICATIONS OF MATERIALS NOT OTHERWISE PROVIDED FOR
- C09D—COATING COMPOSITIONS, e.g. PAINTS, VARNISHES OR LACQUERS; FILLING PASTES; CHEMICAL PAINT OR INK REMOVERS; INKS; CORRECTING FLUIDS; WOODSTAINS; PASTES OR SOLIDS FOR COLOURING OR PRINTING; USE OF MATERIALS THEREFOR
- C09D201/00—Coating compositions based on unspecified macromolecular compounds
-
- C—CHEMISTRY; METALLURGY
- C09—DYES; PAINTS; POLISHES; NATURAL RESINS; ADHESIVES; COMPOSITIONS NOT OTHERWISE PROVIDED FOR; APPLICATIONS OF MATERIALS NOT OTHERWISE PROVIDED FOR
- C09D—COATING COMPOSITIONS, e.g. PAINTS, VARNISHES OR LACQUERS; FILLING PASTES; CHEMICAL PAINT OR INK REMOVERS; INKS; CORRECTING FLUIDS; WOODSTAINS; PASTES OR SOLIDS FOR COLOURING OR PRINTING; USE OF MATERIALS THEREFOR
- C09D7/00—Features of coating compositions, not provided for in group C09D5/00; Processes for incorporating ingredients in coating compositions
- C09D7/40—Additives
- C09D7/60—Additives non-macromolecular
- C09D7/61—Additives non-macromolecular inorganic
-
- C—CHEMISTRY; METALLURGY
- C09—DYES; PAINTS; POLISHES; NATURAL RESINS; ADHESIVES; COMPOSITIONS NOT OTHERWISE PROVIDED FOR; APPLICATIONS OF MATERIALS NOT OTHERWISE PROVIDED FOR
- C09D—COATING COMPOSITIONS, e.g. PAINTS, VARNISHES OR LACQUERS; FILLING PASTES; CHEMICAL PAINT OR INK REMOVERS; INKS; CORRECTING FLUIDS; WOODSTAINS; PASTES OR SOLIDS FOR COLOURING OR PRINTING; USE OF MATERIALS THEREFOR
- C09D7/00—Features of coating compositions, not provided for in group C09D5/00; Processes for incorporating ingredients in coating compositions
- C09D7/40—Additives
- C09D7/70—Additives characterised by shape, e.g. fibres, flakes or microspheres
Abstract
The present invention relates to a kind of preparation methods of energy-saving integrated wall of Far infrared health preservation health-care environmental-protecting, use back reflection decorative layer made of integrated wall and aluminium foil as the basic outer framework component of processing, in the compound one layer of aqueous ceramic graphene conductive far infrared heating layer in the interior the inside of integrated wall, one layer of heat preservation layer is filled between aqueous ceramic graphene conductive far infrared heating layer and aluminium foil reflection decorative layer, required background color is uniformly finally applied as using the coating that healthcare function material and water are mixed into integrated wall outer surface, after drying, floral designs required for making on background color of special-purpose aqueous environmentally friendly heatproof pigment form decorative cover.The present invention can reach indoor far infrared fast energy-saving health-care heating function, mention indoor air quality, and decomposition reduces indoor poisonous and harmful substance, reinforce the absorption and decomposition of foreign flavor indoors, and have apparent sound insulation, heat-insulated and energy-conserving action.
Description
Technical field
The invention belongs to environmental-protection decoration integrated wall field more particularly to a kind of Far infrared health preservation health-care environmental-protecting are energy-saving
The preparation method of integrated wall.
Background technique
Integrated wall is quick for installation, good decorating effect, environmental protection, is suitble to batch production batch production, and hair wall can be installed,
Gradually replacing traditional inner powder, wallpaper and ceramic tile indoor wall decoration.Integrated wall is quickly grown these years recently, is also existed
Continuous to improve in maturation, existing integrated wall mainly payes attention to decorative effect, convenience and the feature of environmental protection, and functionality is also than relatively thin
It is weak, as the improvement of people's living standards, people also propose new hope and requirement to integrated wall.It is more real to wish that it has
Function, such as: heating, sound insulation, heat-insulated, health care, health, eliminates foreign flavor indoors, generates far infrared, generating and bear heat preservation
The functions such as ion really promote the quality in people's lives space, rather than just the promotion of visual effect.
Existing integrated wall mainly has: empty class in plasterboard class, wood moulding, empty class in stone modeling, bamboo-plastic middle empty class, in metal
Empty class, metal foaming class.These integrated walls have good decorative effect, and hollow and foaming class formation alleviates weight, drop
Low cost increases sound insulation, heat-insulated and thermal insulation property, and modeling class changes the intensity of plasterboard, and it is easy that metal class improves modeling class
Deformation and the bad disadvantage of plane conductivity of heat, metal foaming class improve the thermal insulation property of metal hollow class, reduce making for metal
Dosage.
The advantages of in order to keep existing integrated wall and its function of promotion, improve indoor air quality, and propose a kind of remote red
The preparation method of outside line health care environment-friendly and energy-efficient integrated wall.
Summary of the invention
The present invention is to be achieved through the following technical solutions:
A kind of preparation method of the energy-saving integrated wall of Far infrared health preservation health-care environmental-protecting comprising the steps of:
Step 1 uses back reflection decorative layer made of integrated wall and aluminium foil as the basic outer framework component of processing, the two
The mass-type foundation outer framework of built-in filled cavity can be formed after the splicing of front and back;
Step 2 in the compound one layer of aqueous ceramic graphene conductive far infrared heating layer in the interior the inside of integrated wall, wherein
Insulation processing is done between the inside and aqueous ceramic graphene conductive far infrared heating layer in integrated wall;
Step 3 one layer of guarantor of filling between aqueous ceramic graphene conductive far infrared heating layer and aluminium foil reflection decorative layer
Warm layer fills out aqueous ceramic graphene conductive far infrared heating layer and insulating layer as filled cavity in basic outer framework
Fill layer;
Required for step 4 integrated wall outer surface is uniformly applied as using the coating that healthcare function material and water are mixed into
Background color, after drying, floral designs required for being made on background color of special-purpose aqueous environmentally friendly heatproof pigment, or use aqueous, environmental protective
Wallpaper or face decoration membrane material are pasted on the background color after drying and form decorative cover by glue.
The recombination process of the aqueous ceramic graphene conductive far infrared heating layer on the one hand can be with the following method:
(201) it selects high-temperature insulation thin-film material or light sheet material as substrate, is sent out with aqueous ceramic graphene conductive
Heating far-infrared slurry is coated in substrate backside, through 200-500 DEG C of baking ceramics, then in the watersoluble plumbago alkene of ceramic
Aqueous ceramic graphene conductive far infrared heating thin plate is made in conductive far infrared heating plate two sides combination electrode;
(202) integrated wall, aqueous ceramic graphene conductive far infrared heating thin plate, insulating layer and aluminium foil are reflected
After decorative layer is arranged successively, by filled polyurethane foamed glue gluing at an entirety, wherein aqueous ceramic graphene conductive is remote
The one side that exothermal infrared thin plate is bonded with integrated wall is uncoated aqueous ceramic graphene conductive fever far infrared slurry
Preceding insulating surfaces.
It is wherein preferred, the high-temperature insulation substrate using heatproof insulating paper, micarex, PET film, epoxy resin board,
One of empire cloth.
On the other hand the recombination process of the aqueous ceramic graphene conductive far infrared heating layer can also use as follows
Method:
The inside sprays high-temperature insulation heat conducting coating in integrated wall, then applies at the high-temperature insulation heat conducting coating back side
Aqueous ceramic graphene conductive fever far infrared slurry is covered, through 160-260 DEG C of baking ceramics, then in the aqueous of formation
Ceramic graphene conduction far infrared heating coating two sides combination electrode is finally sent out in aqueous ceramic graphene conductive far infrared
The hot coating back side is coated with one layer of high-temperature insulation thermal insulation layer, final to realize aqueous ceramic graphene conductive far infrared heating layer
It is compound.
Further, the insulating layer is that hard polyurethane foam or the foaming of inorganic adhesive add expanded perlite, then
Fill what the remaining filled cavity between full water ceramics graphene conduction far infrared heating layer and aluminium foil reflection decorative layer was formed
Insulating foam layer.
The integrated wall is preferably metal integrated wall, wood moulding integrated wall, stone modeling integrated wall, inorganic integrated wall
One of.
The preferred preparation process of above-mentioned aqueous ceramic graphene conductive fever far infrared slurry is as follows:
(701) prepare the formula of size of following parts by weight: denatured conductive is glue 30-60 parts inorganic aqueous, bentonite 1-50
Part, 1-50 parts of kaolin, 10-60 parts of high purity graphite powder, 10-50 parts of silver-coated copper powder, 5-50 parts of negative ion powder, tourmaline powder 5-50
Part, 5-50 parts of silicon carbide;
(702) inorganic aqueous glue 30-60 parts of denatured conductive are placed in stirring container, are then successively pressed under stirring
Ratio is slowly added to 1-50 parts of bentonite, 1-50 parts of kaolin, 5-50 parts of tourmaline powder, 5-50 parts of silicon carbide, high purity graphite powder
10-60 parts, 10-50 parts of silver-coated copper powder, 5-50 parts of negative ion powder;
(703) the mixture ultrasonic wave that upper step is mixed to get is continued into dispersion 3-7 hours;
(704) mixture obtained after upper step ultrasonic disperse is ground to the fineness of needs with three-roller, then sieving claims
It measures spare;
(705) mixture after grinding is mixed with deionized water and can be made into required aqueous ceramic graphene conductive hair
Heating far-infrared slurry.
Wherein, the preferred disposition technique of the inorganic aqueous glue of denatured conductive is as follows:
(801) waterglass is heated to 50-70 DEG C, the hydrogen-oxygen of waterglass total amount 1-30% is sequentially added under stirring
Change the carbon nanometer of aluminium, the potassium methyl silicate of 2-20%, the graphene powder of 5-30%, the nanometer fine silver powder of 5-40%, 2-20%
Pipe continues to be dispersed with stirring 2-6 hours after the completion of being added, and continues dispersion 2-6 hours in ultrasonic dispersing machine later;
(802) the obtained colloid for completing upper step is placed in sand mill and grinds 2-10 hours, fineness of grind to 3 microns with
Interior, then it is spare to weigh subpackage storage for sieving.
The preferred preparation process of healthcare function material coated by integrated wall outer surface is as follows:
(901) prepare the composition of raw materials of following parts by weight: 20-60 parts of aqueous, environmental protective resin, 5-40 parts of kaolin, diatom
10-50 parts native, 10-50 parts of negative ion powder, 10-50 parts of photocatalyst, 2-30 parts of bentonite, 10-50 parts of tourmaline powder, infrared ray powder
10-50 parts;
(902) 20-60 parts of aqueous, environmental protective resin are placed in stirring container, hydrotropism's environmental protection tree under at the uniform velocity stirring
Sequentially be gradually added according to quantity in rouge the bentonites of above-mentioned parts by weight, diatomite, kaolin, infrared ray powder, tourmaline powder, bear from
Sub- powder, photocatalyst continue stirring 2-6 hours after adding;
(903) mixing for completing upper step is ground 3-8 times on three-roller, is reached required fineness, is then weighed
It is packed and stored spare.
The preferred preparation process of aqueous, environmental protective heatproof pigment used in integrated wall outer surface is as follows:
(101) prepare the composition of raw materials of following parts by weight: 20-60 parts of nanometer water Aluminum sol, inorganic high-temperature resistant toner
5-50 parts, 2-30 parts of bentonite, 5-40 parts of kaolin, 10-50 parts of negative ion powder, 20-50 parts of infrared ray powder, photocatalyst 5-30
Part, 2-30 parts of white carbon black;
(102) 20-60 parts of nanometer water Aluminum sol are placed in stirring container, under at the uniform velocity stirring sequentially according to quantity by
Step is slowly added to inorganic high-temperature resistant toner, bentonite, kaolin, negative ion powder, the infrared ray powder, photocatalyst of above-mentioned parts by weight
And white carbon black;
(103) the mixture ultrasonic wave that upper step is completed is continued into dispersion 3-6 hours;
(104) mixture that upper step ultrasonic disperse obtains is ground to the fineness of needs with three-roller, then sieving weighs
Subpackage storage is spare.
Compared with prior art, the invention has the following beneficial technical effects:
1, invention increases indoor far infrared fast energy-saving health-care heating functions;
2, indoor anion concentration is increased, indoor air quality is improved;
3, photocatalyst effect is increased, decomposition reduces indoor poisonous and harmful substance;
4, increase diatom ooze material, reinforce the absorption and decomposition of foreign flavor indoors;
5, infrared radiation functional material is increased, it can be efficiently by the thermal energy on integrated wall with far infrared mode spoke
It penetrates
Into air.
Detailed description of the invention
Fig. 1 is integrated wall cut-away drawing of the present invention;
Fig. 2 is the exothermal infrared layer of the integrated wall of the invention sectional structure chart compound using first method;
Fig. 3 is the exothermal infrared layer of the integrated wall of the invention sectional structure chart compound using second method.
In figure: 1 integrated wall outer surface decoration functions material layer;2 insulating layers;3 splicing slots;4 aluminium foils reflect decorative layer;
5 splicing plates;6 power input connectors;7 power input high temperature resistant wires;8 power supplys export high temperature resistant wire;The output of 9 power supplys connects
Plug-in unit;12 integrated walls;13 aqueous ceramic graphene conductive far infrared heating layers;131 aqueous ceramic graphene conductives are far red
Outside line fever thin plate;132 high-temperature insulation heat conducting coatings;133 high-temperature insulation heat insulating coats;134 aqueous ceramic graphenes are led
Electric far infrared heating coating;14 far infrared heating component electrodes;15 power supply line pads.
Specific embodiment
To better understand the objects, features and advantages of the present invention, with reference to the accompanying drawing and specific real
Applying example, the present invention will be described in detail.It should be noted that in the absence of conflict, embodiments herein and embodiment
In feature can be combined with each other.
In the following description, numerous specific details are set forth in order to facilitate a full understanding of the present invention, described embodiment is only
It is only a part of the embodiment of the present invention, instead of all the embodiments.Based on the embodiments of the present invention, ordinary skill
Personnel's every other embodiment obtained without making creative work, shall fall within the protection scope of the present invention.
Unless otherwise defined, all technical and scientific terms used herein and belong to technical field of the invention
The normally understood meaning of technical staff is identical.Term as used herein in the specification of the present invention is intended merely to description tool
The purpose of the embodiment of body, it is not intended that in the limitation present invention.
A kind of preparation method of the energy-saving integrated wall of Far infrared health preservation health-care environmental-protecting comprising the steps of:
Step 1 uses back reflection decorative layer made of integrated wall and aluminium foil as the basic outer framework component of processing, the two
The mass-type foundation outer framework of built-in filled cavity can be formed after the splicing of front and back;
Step 2 in the compound one layer of aqueous ceramic graphene conductive far infrared heating layer in the interior the inside of integrated wall, wherein
Insulation processing is done between the inside and aqueous ceramic graphene conductive far infrared heating layer in integrated wall;
Step 3 one layer of guarantor of filling between aqueous ceramic graphene conductive far infrared heating layer and aluminium foil reflection decorative layer
Warm layer fills out aqueous ceramic graphene conductive far infrared heating layer and insulating layer as filled cavity in basic outer framework
Fill layer;
Required for step 4 integrated wall outer surface is uniformly applied as using the coating that healthcare function material and water are mixed into
Background color, after drying, floral designs required for being made on background color of special-purpose aqueous environmentally friendly heatproof pigment, or use aqueous, environmental protective
Wallpaper or face decoration membrane material are pasted on the background color after drying and form decorative cover by glue.
Further, insulating layer is hard polyurethane foam or the foaming of inorganic adhesive plus expanded pearlite in above-mentioned steps 3
Rock, the remaining filled cavity being subsequently filled between full water ceramics graphene conduction far infrared heating layer and aluminium foil reflection decorative layer
The insulating foam layer of formation.
Further, integrated wall is to have figurate hollow metope, such as can be metal and integrate wall
Face, wood moulding integrated wall, bamboo-plastic integrated wall or stone mould integrated wall, inorganic integrated wall, wherein it is preferred that integrated using metal
Metope.
Wherein, the setting of aqueous ceramic graphene conductive far infrared heating layer, can increase the infrared ray of integrated wall
Thermal energy on metal integrated wall can be efficiently radiated in air by radiation function with far infrared mode;
The setting of insulating layer can enhance the integral heat insulation effect of the integrated wall so that metope present it is cool in summer and warm in winter
Effect;
The setting of back reflection decorative layer can play good protective action (by aqueous ceramic graphene conductive far infrared
Line heating layer and insulating layer are enclosed in inside integrated wall, both make will not directly it is exposed outside, to both effectively avoid anticipating
It is outer to be damaged and cause electric shock problem), while back reflection decorative layer can be by aqueous ceramic graphene conductive far infrared heating layer
The energy of generation is reflected, and is distributed so that far infrared generates heat concentration to the front end face of integrated wall, is reduced energy
Measure the lost problem in backwards face.
On the one hand the recombination process of aqueous ceramic graphene conductive far infrared heating layer in above-mentioned steps 2 can use
Following method (method one):
(201) it selects high-temperature insulation thin-film material or light sheet material as substrate, is sent out with aqueous ceramic graphene conductive
Heating far-infrared slurry is coated in substrate backside, through 200-500 DEG C of baking ceramics, then in the watersoluble plumbago alkene of ceramic
Aqueous ceramic graphene conductive far infrared heating thin plate is made in conductive far infrared heating plate two sides combination electrode;
(202) integrated wall, aqueous ceramic graphene conductive far infrared heating thin plate, insulating layer and aluminium foil are reflected
After decorative layer is arranged successively, by filled polyurethane foamed glue gluing at an entirety, wherein aqueous ceramic graphene conductive is remote
The one side that exothermal infrared thin plate is bonded with integrated wall is uncoated aqueous ceramic graphene conductive fever far infrared slurry
Preceding insulating surfaces.
High-temperature insulation substrate therein preferably uses heatproof insulating paper, micarex, PET film, epoxy resin board, empire cloth
One of.
The recombination process of aqueous ceramic graphene conductive far infrared heating layer in above-mentioned steps 2 on the other hand can also be with
With the following method (method two):
The inside sprays high-temperature insulation heat conducting coating in integrated wall, then applies at the high-temperature insulation heat conducting coating back side
Aqueous ceramic graphene conductive fever far infrared slurry is covered, through 160-260 DEG C of baking ceramics, then in the aqueous of formation
Ceramic graphene conduction far infrared heating coating two sides combination electrode is finally sent out in aqueous ceramic graphene conductive far infrared
The hot coating back side is coated with one layer of high-temperature insulation thermal insulation layer, final to realize aqueous ceramic graphene conductive far infrared heating layer
It is compound.
It in the actual construction process, need to also be in two lateral electrodes of aqueous ceramic graphene conductive far infrared heating coating
Corresponding high temperature resistant wire is welded, and in high temperature resistant wire end connector mounting;In this way, being showed using this integrated wall
When the concatenation construction of field, adjacent two pieces of integrated walls need to only be spliced using splicing slot and splicing plate, it then will be adjacent
The power supply line of two pieces of integrated walls is docked using the connector on high temperature resistant wire, and the cascade process of route can be realized.
In the complex method of above two aqueous ceramic graphene conductive far infrared heating layer, aqueous ceramic graphene is led
The preparation process of electricity fever far infrared slurry is all made of following process:
(701) waterglass is heated to 50-70 DEG C, the hydrogen-oxygen of waterglass total amount 1-30% is sequentially added under stirring
Change the carbon nanometer of aluminium, the potassium methyl silicate of 2-20%, the graphene powder of 5-30%, the nanometer fine silver powder of 5-40%, 2-20%
Pipe continues to be dispersed with stirring 2-6 hours after the completion of being added, and continues dispersion 2-6 hours in ultrasonic dispersing machine later;
(702) the obtained colloid for completing upper step is placed in sand mill and grinds 2-10 hours, fineness of grind to 3 microns with
Interior, then it is spare to weigh subpackage storage for sieving;
(703) prepare the formula of size of following parts by weight:
(704) inorganic aqueous glue 30-60 parts of the denatured conductive produced above are placed in stirring container, then in stirring shape
Successively be slowly added in proportion under state 1-50 parts of bentonite, 1-50 parts of kaolin, 5-50 parts of tourmaline powder, 5-50 parts of silicon carbide,
10-60 parts of high purity graphite powder, 10-50 parts of silver-coated copper powder, 5-50 parts of negative ion powder;
(705) the mixture ultrasonic wave that upper step is mixed to get is continued into dispersion 3-7 hours;
(706) mixture obtained after upper step ultrasonic disperse is ground to the fineness of needs with three-roller, then sieving claims
It measures spare;
(707) mixture after grinding is mixed with deionized water and can be made into required aqueous ceramic graphene conductive hair
Heating far-infrared slurry.
Above-mentioned aqueous ceramic graphene conductive far infrared heating layer, generated far infrared dominant wavelength ranges are
8-14 μm, medical field also appellation its " healthy light " and " life light ";It can activate the activity of large biological molecule, make biology
The molecule of body can be excited and be in the work for making to have activated the big hydrone of the biology such as nucleic acid protein in this way compared with high vibration state
Property, so that having played large biological molecule adjusts the movable function such as organism metabolism, immune, be conducive to the recovery and balance of function,
So as to achieve the aim of preventing and treating diseases promotion and improvement blood circulation.
The following are the inorganic aqueous glue of denatured conductive in aqueous ceramic graphene conductive fever far infrared blank preparation technics
With aqueous ceramic graphene conductive fever far infrared slurry optimization formula:
The inorganic aqueous glue of denatured conductive:
100 parts of waterglass, 1 part of aluminium hydroxide, 2 parts of potassium methyl silicate, 5 parts of graphene powders, 40 parts of nanometer fine silver powder,
20 parts of carbon nanotubes;
100 parts of waterglass, 30 parts of aluminium hydroxides, 20 parts of potassium methyl silicates, 5 parts of graphene powders, 5 parts of nanometer fine silver powder, 2
Part carbon nanotube;
100 parts of waterglass, 30 parts of aluminium hydroxides, 2 parts of potassium methyl silicates, 30 parts of graphene powders, 5 parts of nanometer fine silver powder, 2
Part carbon nanotube;
100 parts of waterglass, 30 parts of aluminium hydroxides, 2 parts of potassium methyl silicates, 5 parts of graphene powders, 40 parts of nanometer fine silver powder, 2
Part carbon nanotube;
100 parts of waterglass, 30 parts of aluminium hydroxides, 2 parts of potassium methyl silicates, 5 parts of graphene powders, 5 parts of nanometer fine silver powder, 20
Part carbon nanotube;
100 parts of waterglass, 15 parts of aluminium hydroxides, 10 parts of potassium methyl silicates, 17 parts of graphene powders, 22 parts of nanometer fine silver
Powder, 11 parts of carbon nanotubes;
Aqueous ceramic graphene conductive fever far infrared slurry:
30 parts of the inorganic aqueous glue of denatured conductive, 25 parts of bentonite, 25 parts of kaolin, 35 parts of high purity graphite powder, silver-coated copper powder
30 parts, 27 parts of negative ion powder, 27 parts of tourmaline powder, 50 parts of silicon carbide;
30 parts of the inorganic aqueous glue of denatured conductive, 25 parts of bentonite, 25 parts of kaolin, 35 parts of high purity graphite powder, silver-coated copper powder
30 parts, 27 parts of negative ion powder, 50 parts of tourmaline powder, 27 parts of silicon carbide;
30 parts of the inorganic aqueous glue of denatured conductive, 25 parts of bentonite, 25 parts of kaolin, 35 parts of high purity graphite powder, silver-coated copper powder
30 parts, 50 parts of negative ion powder, 27 parts of tourmaline powder, 27 parts of silicon carbide;
30 parts of the inorganic aqueous glue of denatured conductive, 25 parts of bentonite, 25 parts of kaolin, 35 parts of high purity graphite powder, silver-coated copper powder
50 parts, 27 parts of negative ion powder, 27 parts of tourmaline powder, 27 parts of silicon carbide;
30 parts of the inorganic aqueous glue of denatured conductive, 25 parts of bentonite, 25 parts of kaolin, 60 parts of high purity graphite powder, silver-coated copper powder
30 parts, 27 parts of negative ion powder, 27 parts of tourmaline powder, 27 parts of silicon carbide;
30 parts of the inorganic aqueous glue of denatured conductive, 25 parts of bentonite, 40 parts of kaolin, 35 parts of high purity graphite powder, silver-coated copper powder
30 parts, 27 parts of negative ion powder, 27 parts of tourmaline powder, 27 parts of silicon carbide;
30 parts of the inorganic aqueous glue of denatured conductive, 50 parts of bentonite, 25 parts of kaolin, 35 parts of high purity graphite powder, silver-coated copper powder
30 parts, 27 parts of negative ion powder, 27 parts of tourmaline powder, 27 parts of silicon carbide;
60 parts of the inorganic aqueous glue of denatured conductive, 1 part of bentonite part, 25 parts of kaolin, 35 parts of high purity graphite powder, silver-coated copper powder
30 parts, 27 parts of negative ion powder, 27 parts of tourmaline powder, 27 parts of silicon carbide;
60 parts of the inorganic aqueous glue of denatured conductive, 25 parts of bentonite, 1 part of kaolin, 35 parts of high purity graphite powder, silver-coated copper powder 30
Part, 27 parts of negative ion powder, 27 parts of tourmaline powder, 27 parts of silicon carbide;
60 parts of the inorganic aqueous glue of denatured conductive, 25 parts of bentonite, 25 parts of kaolin, 10 parts of high purity graphite powder, silver-coated copper powder
30 parts, 27 parts of negative ion powder, 27 parts of tourmaline powder, 27 parts of silicon carbide;
60 parts of the inorganic aqueous glue of denatured conductive, 25 parts of bentonite, 25 parts of kaolin, 35 parts of high purity graphite powder, silver-coated copper powder
10 parts, 27 parts of negative ion powder, 27 parts of tourmaline powder, 27 parts of silicon carbide;
60 parts of the inorganic aqueous glue of denatured conductive, 25 parts of bentonite, 25 parts of kaolin, 35 parts of high purity graphite powder, silver-coated copper powder
30 parts, 5 parts of negative ion powder, 27 parts of tourmaline powder, 27 parts of silicon carbide;
60 parts of the inorganic aqueous glue of denatured conductive, 25 parts of bentonite, 25 parts of kaolin, 35 parts of high purity graphite powder, silver-coated copper powder
30 parts, 27 parts of negative ion powder, 5 parts of tourmaline powder, 27 parts of silicon carbide;
60 parts of the inorganic aqueous glue of denatured conductive, 25 parts of bentonite, 25 parts of kaolin, 35 parts of high purity graphite powder, silver-coated copper powder
30 parts, 27 parts of negative ion powder, 27 parts of tourmaline powder, 5 parts of silicon carbide;
To aqueous ceramic graphene conductive far infrared heating layer made of above-mentioned optimization formula according to GB/T7287-2008
" infrared radiation heater test method " tests, inspection result are as follows: aqueous ceramic graphene conductive made of each formula
The normal direction total emissivity of far infrared heating layer is 87% or more, and infra red energy density is in 4.5-4.7 × 102W/m2
(37 DEG C), infra-red radiation conversion ratio is 70% or more.
The preparation process of healthcare function material coated by integrated wall outer surface is as follows:
(91) prepare the composition of raw materials of following parts by weight: 20-60 parts of aqueous, environmental protective resin, 5-40 parts of kaolin, diatom
10-50 parts native, 10-50 parts of negative ion powder, 10-50 parts of photocatalyst, 2-30 parts of bentonite, 10-50 parts of tourmaline powder, infrared ray powder
10-50 parts;
(92) 20-60 parts of aqueous, environmental protective resin are placed in stirring container, hydrotropism's environmental protection tree under at the uniform velocity stirring
Sequentially be gradually added according to quantity in rouge the bentonites of above-mentioned parts by weight, diatomite, kaolin, infrared ray powder, tourmaline powder, bear from
Sub- powder, photocatalyst continue stirring 2-6 hours after adding;
(93) mixing for completing upper step is ground 3-8 times on three-roller, reaches required fineness, then weighs packet
It is spare to be packed into library.
The following are the optimization formulas of healthcare function material coated by integrated wall outer surface:
20 parts of aqueous, environmental protective resin, 40 parts of kaolin, 30 parts of diatomite, 30 parts of negative ion powder, 30 parts of photocatalyst, bentonite
17 parts, 30 parts of tourmaline powder, 30 parts of infrared ray powder;
20 parts of aqueous, environmental protective resin, 22 parts of kaolin, 50 parts of diatomite, 30 parts of negative ion powder, 30 parts of photocatalyst, bentonite
17 parts, 30 parts of tourmaline powder, 30 parts of infrared ray powder;
20 parts of aqueous, environmental protective resin, 22 parts of kaolin, 30 parts of diatomite, 50 parts of negative ion powder, 30 parts of photocatalyst, bentonite
17 parts, 30 parts of tourmaline powder, 30 parts of infrared ray powder;
20 parts of aqueous, environmental protective resin, 22 parts of kaolin, 30 parts of diatomite, 30 parts of negative ion powder, 50 parts of photocatalyst, bentonite
17 parts, 30 parts of tourmaline powder, 30 parts of infrared ray powder;
20 parts of aqueous, environmental protective resin, 22 parts of kaolin, 30 parts of diatomite, 30 parts of negative ion powder, 30 parts of photocatalyst, bentonite
30 parts, 30 parts of tourmaline powder, 30 parts of infrared ray powder;
20 parts of aqueous, environmental protective resin, 22 parts of kaolin, 30 parts of diatomite, 30 parts of negative ion powder, 30 parts of photocatalyst, bentonite
17 parts, 50 parts of tourmaline powder, 30 parts of infrared ray powder;
20 parts of aqueous, environmental protective resin, 22 parts of kaolin, 30 parts of diatomite, 30 parts of negative ion powder, 30 parts of photocatalyst, bentonite
17 parts, 30 parts of tourmaline powder, 50 parts of infrared ray powder;
60 parts of aqueous, environmental protective resin, 5 parts of kaolin, 30 parts of diatomite, 30 parts of negative ion powder, 30 parts of photocatalyst, bentonite
17 parts, 30 parts of tourmaline powder, 30 parts of infrared ray powder;
60 parts of aqueous, environmental protective resin, 22 parts of kaolin, 10 parts of diatomite, 30 parts of negative ion powder, 30 parts of photocatalyst, bentonite
17 parts, 30 parts of tourmaline powder, 30 parts of infrared ray powder;
60 parts of aqueous, environmental protective resin, 22 parts of kaolin, 30 parts of diatomite, 10 parts of negative ion powder, 30 parts of photocatalyst, bentonite
17 parts, 30 parts of tourmaline powder, 30 parts of infrared ray powder;
60 parts of aqueous, environmental protective resin, 22 parts of kaolin, 30 parts of diatomite, 30 parts of negative ion powder, 10 parts of photocatalyst, bentonite
17 parts, 30 parts of tourmaline powder, 30 parts of infrared ray powder;
60 parts of aqueous, environmental protective resin, 22 parts of kaolin, 30 parts of diatomite, 30 parts of negative ion powder, 30 parts of photocatalyst, bentonite
2 parts, 30 parts of tourmaline powder, 30 parts of infrared ray powder;
60 parts of aqueous, environmental protective resin, 22 parts of kaolin, 30 parts of diatomite, 30 parts of negative ion powder, 30 parts of photocatalyst, bentonite
17 parts, 10 parts of tourmaline powder, 30 parts of infrared ray powder;
60 parts of aqueous, environmental protective resin, 22 parts of kaolin, 30 parts of diatomite, 30 parts of negative ion powder, 30 parts of photocatalyst, bentonite
17 parts, 30 parts of tourmaline powder, 10 parts of infrared ray powder;
The preparation process of aqueous, environmental protective heatproof pigment used in integrated wall outer surface is as follows:
(101) prepare the composition of raw materials of following parts by weight: 20-60 parts of nanometer water Aluminum sol, inorganic high-temperature resistant toner
5-50 parts, 2-30 parts of bentonite, 5-40 parts of kaolin, 10-50 parts of negative ion powder, 20-50 parts of infrared ray powder, photocatalyst 5-30
Part, 2-30 parts of white carbon black;
(102) 20-60 parts of nanometer water Aluminum sol are placed in stirring container, under at the uniform velocity stirring sequentially according to quantity by
Step is slowly added to inorganic high-temperature resistant toner, bentonite, kaolin, negative ion powder, the infrared ray powder, photocatalyst of above-mentioned parts by weight
And white carbon black;
(103) the mixture ultrasonic wave that upper step is completed is continued into dispersion 3-6 hours;
(104) mixture that upper step ultrasonic disperse obtains is ground to the fineness of needs with three-roller, then sieving weighs
Subpackage storage is spare.
The following are the optimization formulas of aqueous, environmental protective heatproof pigment used in integrated wall outer surface:
20 parts of nanometer water Aluminum sol, 50 parts of inorganic high-temperature resistant toner, 11 parts of bentonite, 22 parts of kaolin, negative ion powder
30 parts, 35 parts of infrared ray powder, 17 parts of photocatalyst, 16 parts of white carbon black;
20 parts of nanometer water Aluminum sol, 27 parts of inorganic high-temperature resistant toner, 30 parts of bentonite, 22 parts of kaolin, negative ion powder
30 parts, 35 parts of infrared ray powder, 17 parts of photocatalyst, 16 parts of white carbon black;
20 parts of nanometer water Aluminum sol, 27 parts of inorganic high-temperature resistant toner, 11 parts of bentonite, 40 parts of kaolin, negative ion powder
30 parts, 35 parts of infrared ray powder, 17 parts of photocatalyst, 16 parts of white carbon black;
20 parts of nanometer water Aluminum sol, 27 parts of inorganic high-temperature resistant toner, 11 parts of bentonite, 22 parts of kaolin, negative ion powder
50 parts, 35 parts of infrared ray powder, 17 parts of photocatalyst, 16 parts of white carbon black;
20 parts of nanometer water Aluminum sol, 27 parts of inorganic high-temperature resistant toner, 11 parts of bentonite, 22 parts of kaolin, negative ion powder
30 parts, 50 parts of infrared ray powder, 17 parts of photocatalyst, 16 parts of white carbon black;
20 parts of nanometer water Aluminum sol, 27 parts of inorganic high-temperature resistant toner, 11 parts of bentonite, 22 parts of kaolin, negative ion powder
30 parts, 35 parts of infrared ray powder, 30 parts of photocatalyst, 16 parts of white carbon black;
20 parts of nanometer water Aluminum sol, 27 parts of inorganic high-temperature resistant toner, 11 parts of bentonite, 22 parts of kaolin, negative ion powder
30 parts, 35 parts of infrared ray powder, 17 parts of photocatalyst, 30 parts of white carbon black;
60 parts of nanometer water Aluminum sol, 5 parts of inorganic high-temperature resistant toner, 11 parts of bentonite, 22 parts of kaolin, negative ion powder 30
Part, 35 parts of infrared ray powder, 17 parts of photocatalyst, 16 parts of white carbon black;
60 parts of nanometer water Aluminum sol, 27 parts of inorganic high-temperature resistant toner, 2 parts of bentonite, 22 parts of kaolin, negative ion powder 30
Part, 35 parts of infrared ray powder, 17 parts of photocatalyst, 16 parts of white carbon black;
60 parts of nanometer water Aluminum sol, 27 parts of inorganic high-temperature resistant toner, 11 parts of bentonite, 5 parts of kaolin, negative ion powder 30
Part, 35 parts of infrared ray powder, 17 parts of photocatalyst, 16 parts of white carbon black;
60 parts of nanometer water Aluminum sol, 27 parts of inorganic high-temperature resistant toner, 11 parts of bentonite, 22 parts of kaolin, negative ion powder
10 parts, 35 parts of infrared ray powder, 17 parts of photocatalyst, 16 parts of white carbon black;
60 parts of nanometer water Aluminum sol, 27 parts of inorganic high-temperature resistant toner, 11 parts of bentonite, 22 parts of kaolin, negative ion powder
30 parts, 20 parts of infrared ray powder, 17 parts of photocatalyst, 16 parts of white carbon black;
60 parts of nanometer water Aluminum sol, 27 parts of inorganic high-temperature resistant toner, 11 parts of bentonite, 22 parts of kaolin, negative ion powder
30 parts, 35 parts of infrared ray powder, 5 parts of photocatalyst, 16 parts of white carbon black;
60 parts of nanometer water Aluminum sol, 27 parts of inorganic high-temperature resistant toner, 11 parts of bentonite, 22 parts of kaolin, negative ion powder
30 parts, 35 parts of infrared ray powder, 17 parts of photocatalyst, 2 parts of white carbon black;
The healthcare function material of integrated wall outer surface and aqueous, environmental protective heatproof pigment can persistently discharge greatly in the present invention
The anion of amount can facilitate human body to synthesize since anion is the very useful far-infrared radiation material of a kind of pair of human health
And vitamin storage, strengthen the physiological activity with human activin, therefore it is otherwise known as " air vitamin ", it is believed that it is as food
Vitamin it is the same, have highly important influence to the vital movement of human body and other biological.In medical field, anion is true
Recognizing is the effective means with germ and purification air is killed.After its mechanism essentially consists in anion in conjunction with bacterium, make bacterium
The change of structure or the transfer of energy are generated, leads to bacterial death, most final decline is sunken to ground.Medical research shows band in air
The particle of negative electricity increases oxygen content in blood, is conducive to blood oxygen conveying, absorbs and utilize, has and promote human metabolism, mention
High human immunological competence enhances human muscle energy, adjusts the effect of body function balance.Anion is to 7 systems of human body, more than nearly 30
Kind disease has inhibition, alleviation and auxiliary therapeutic action, especially becomes apparent to the health-care effect of human body, therefore, in the present invention
Air purifying preparation have apparent healthcare function.
First due to containing anion and photocatalyst in the functional material of integrated wall outer surface, in the rapid decomposition space of energy
The pernicious gases such as aldehyde, benzene, ammonia, and clearance rate reaches 99% or more, ultrahigh in efficiency, anion ingredient therein is not necessarily to photocatalysis,
Its antibiotic rate can be up to 99.9% or more, and anion burst size is in 30000 or more/cm3, more than international standard (1600/cm3),
Obvious effect.
It is obvious to a person skilled in the art that invention is not limited to the details of the above exemplary embodiments, Er Qie
In the case where without departing substantially from spirit or essential attributes of the invention, the present invention can be realized in other specific forms.Therefore, no matter
From the point of view of which point, the present embodiments are to be considered as illustrative and not restrictive, and the scope of the present invention is by appended power
Benefit requires rather than above description limits, it is intended that all by what is fallen within the meaning and scope of the equivalent elements of the claims
Variation is included in the present invention.Any reference signs in the claims should not be construed as limiting the involved claims.This
Outside, it is clear that one word of " comprising " does not exclude other units or steps, and odd number is not excluded for plural number.It is stated in mobile terminal claim
Multiple units or mobile terminal can also be implemented through software or hardware by the same unit or mobile terminal.The first, the
Second-class word is used to indicate names, and is not indicated any particular order.
Finally it should be noted that the above examples are only used to illustrate the technical scheme of the present invention and are not limiting, although reference
Preferred embodiment describes the invention in detail, those skilled in the art should understand that, it can be to of the invention
Technical solution is modified or equivalent replacement, without departing from the spirit and scope of the technical solution of the present invention.
Claims (10)
1. a kind of preparation method of the energy-saving integrated wall of Far infrared health preservation health-care environmental-protecting, which is characterized in that include following step
It is rapid:
Step 1 uses back reflection decorative layer made of integrated wall and aluminium foil as the basic outer framework component of processing, the two front and back
The mass-type foundation outer framework of built-in filled cavity can be formed after splicing;
Step 2 is in the compound one layer of aqueous ceramic graphene conductive far infrared heating layer in the interior the inside of integrated wall, wherein aqueous
Insulation processing is done between ceramic graphene conduction far infrared heating layer;
Step 3 fills one layer of heat preservation between aqueous ceramic graphene conductive far infrared heating layer and aluminium foil reflection decorative layer
Layer finally makes aqueous ceramic graphene conductive far infrared heating layer and insulating layer as the filling of filled cavity in basic outer framework
Layer;
Step 4 integrated wall outer surface is uniformly applied as required bottom using the coating that healthcare function material and water are mixed into
Color, after drying, floral designs required for being made on background color of special-purpose aqueous environmentally friendly heatproof pigment, or with aqueous, environmental protective glue
Wallpaper or face decoration membrane material are pasted on the background color after drying and form decorative cover.
2. a kind of preparation method of energy-saving integrated wall of Far infrared health preservation health-care environmental-protecting according to claim 1,
Be characterized in that: the recombination process of the aqueous ceramic graphene conductive far infrared heating layer with the following method:
(201) select heatproof insulating film material or light sheet material as substrate, it is remote red with the fever of aqueous ceramic graphene conductive
Outside line slurry is coated in substrate backside, through 200-500 DEG C of baking ceramics, then in the watersoluble plumbago alkene conductive distal of ceramic
Aqueous ceramic graphene conductive far infrared heating thin plate is made in infrared heating plate two sides combination electrode;
(202) integrated wall, aqueous ceramic graphene conductive far infrared heating thin plate, insulating layer and aluminium foil are reflected and is decorated
After layer is arranged successively, by filled polyurethane foamed glue gluing at an entirety, wherein aqueous ceramic graphene conductive far infrared
The one side that line fever thin plate is bonded with integrated wall is generated heat for uncoated aqueous ceramic graphene conductive before far infrared slurry
Insulating surfaces.
3. a kind of preparation method of energy-saving integrated wall of Far infrared health preservation health-care environmental-protecting according to claim 2,
Be characterized in that: the heatproof insulating substrate is using one in heatproof insulating paper, micarex, PET film, epoxy resin board, empire cloth
Kind.
4. a kind of preparation method of energy-saving integrated wall of Far infrared health preservation health-care environmental-protecting according to claim 1,
Be characterized in that: the recombination process of the aqueous ceramic graphene conductive far infrared heating layer with the following method:
The inside sprays high-temperature insulation heat conducting coating in integrated wall, then in high-temperature insulation heat conducting coating backside coating water
Property ceramics graphene conductive exothermal far infrared slurry, through 160-260 DEG C of baking ceramics, then in the aqueous ceramic of formation
Graphene conductive far infrared heating coating two sides combination electrode is finally applied in aqueous ceramic graphene conductive far infrared heating
The layer back side is coated with one layer of high-temperature insulation thermal insulation layer, final to realize answering for aqueous ceramic graphene conductive far infrared heating layer
It closes.
5. a kind of system of the energy-saving integrated wall of Far infrared health preservation health-care environmental-protecting described in any one of -4 according to claim 1
Preparation Method, it is characterised in that: the insulating layer is that hard polyurethane foam or the foaming of inorganic adhesive add expanded perlite, then
Fill what the remaining filled cavity between full water ceramics graphene conduction far infrared heating layer and aluminium foil reflection decorative layer was formed
Insulating foam layer.
6. a kind of system of the energy-saving integrated wall of Far infrared health preservation health-care environmental-protecting described in any one of -4 according to claim 1
Preparation Method, it is characterised in that: the integrated wall is metal integrated wall, wood moulding integrated wall, bamboo-plastic integrated wall, stone modeling collection
At one of metope, inorganic integrated wall.
7. a kind of preparation method of energy-saving integrated wall of Far infrared health preservation health-care environmental-protecting according to claim 2 or 4,
It is characterized by: the preparation process of the aqueous ceramic graphene conductive fever far infrared slurry is as follows:
(701) prepare the formula of size of following parts by weight: denatured conductive is glue 30-60 part inorganic aqueous, 1-50 parts of bentonite, height
Soil 1-50 parts of ridge, 10-60 parts of high purity graphite powder, 10-50 parts of silver-coated copper powder, 5-50 parts of negative ion powder, 5-50 parts of tourmaline powder, carbon
5-50 parts of SiClx;
(702) inorganic aqueous glue 30-60 parts of denatured conductive are placed in stirring container, then under stirring successively in proportion
It is slowly added to 1-50 parts of bentonite, 1-50 parts of kaolin, 5-50 parts of tourmaline powder, 5-50 parts of silicon carbide, high purity graphite powder 10-60
Part, 10-50 parts of silver-coated copper powder, 5-50 parts of negative ion powder;
(703) the mixture ultrasonic wave that upper step is mixed to get is continued into dispersion 3-7 hours;
(704) mixture obtained after upper step ultrasonic disperse is ground to the fineness of needs with three-roller, then sieving weighs standby
With;
(705) mixture after grinding is mixed with deionized water and can be made into required aqueous ceramic graphene conductive fever far
Infrared ray slurry.
8. a kind of preparation method of energy-saving integrated wall of Far infrared health preservation health-care environmental-protecting according to claim 7,
Be characterized in that: the configuration technique of the inorganic aqueous glue of denatured conductive is as follows:
(801) waterglass is heated to 50-70 DEG C, the hydroxide of waterglass total amount 1-30% is sequentially added under stirring
Aluminium, the potassium methyl silicate of 2-20%, the graphene powder of 5-30%, the nanometer fine silver powder of 5-40%, 2-20% carbon nanotube,
Continue to be dispersed with stirring 2-6 hours after the completion of being added, continues dispersion 2-6 hours in ultrasonic dispersing machine later;
(802) the obtained colloid for completing upper step is placed in sand mill and grinds 2-10 hours, fineness of grind within 3 microns,
Then it is spare to weigh subpackage storage for sieving.
9. a kind of system of the energy-saving integrated wall of Far infrared health preservation health-care environmental-protecting described in any one of -4 according to claim 1
Preparation Method, it is characterised in that: healthcare function material preparation process coated by integrated wall outer surface is as follows:
(901) prepare the composition of raw materials of following parts by weight: 20-60 parts of aqueous, environmental protective resin, 5-40 parts of kaolin, diatomite
10-50 parts, 10-50 parts of negative ion powder, 10-50 parts of photocatalyst, 2-30 parts of bentonite, 10-50 parts of tourmaline powder, infrared ray powder
10-50 parts;
(902) 20-60 parts of aqueous, environmental protective resin are placed in stirring container, under at the uniform velocity stirring in hydrotropism's environment-friendly resin
It is sequentially gradually added bentonite, diatomite, kaolin, infrared ray powder, the tourmaline powder, anion of above-mentioned parts by weight according to quantity
Powder, photocatalyst continue stirring 2-6 hours after adding;
(903) mixing for completing upper step is ground 3-8 times on three-roller, reaches required fineness, then weighing and bagging
It is put in storage spare.
10. a kind of energy-saving integrated wall of Far infrared health preservation health-care environmental-protecting described in any one of -4 according to claim 1
Preparation method, it is characterised in that: aqueous, environmental protective heatproof pigment preparation process used in integrated wall outer surface is as follows:
(101) prepare the composition of raw materials of following parts by weight: 20-60 parts of nanometer water Aluminum sol, inorganic high-temperature resistant toner 5-50
It is part, 2-30 parts of bentonite, 5-40 parts of kaolin, 10-50 parts of negative ion powder, 20-50 parts of infrared ray powder, 5-30 parts of photocatalyst, white
2-30 parts of carbon black;
(102) 20-60 parts of nanometer water Aluminum sol are placed in stirring container, are sequentially gradually delayed according to quantity under at the uniform velocity stirring
Slowly the inorganic high-temperature resistant toners of above-mentioned parts by weight, bentonite, kaolin, negative ion powder, infrared ray powder, photocatalyst and white is added
Carbon black;
(103) the mixture ultrasonic wave that upper step is completed is continued into dispersion 3-6 hours;
(104) mixture that upper step ultrasonic disperse obtains is ground to the fineness of needs with three-roller, then sieving weighs subpackage
It is put in storage spare.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201910680467.8A CN110405910B (en) | 2019-07-26 | 2019-07-26 | Preparation method of far infrared health-preserving, health-care, environment-friendly and energy-saving integrated wall surface |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201910680467.8A CN110405910B (en) | 2019-07-26 | 2019-07-26 | Preparation method of far infrared health-preserving, health-care, environment-friendly and energy-saving integrated wall surface |
Publications (2)
Publication Number | Publication Date |
---|---|
CN110405910A true CN110405910A (en) | 2019-11-05 |
CN110405910B CN110405910B (en) | 2021-11-26 |
Family
ID=68363417
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN201910680467.8A Active CN110405910B (en) | 2019-07-26 | 2019-07-26 | Preparation method of far infrared health-preserving, health-care, environment-friendly and energy-saving integrated wall surface |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN110405910B (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN112573891A (en) * | 2020-12-10 | 2021-03-30 | 山东省泥博士新型材料有限公司 | Far infrared health maintenance diatom ooze board and preparation method thereof |
CN114654830A (en) * | 2021-04-01 | 2022-06-24 | 上海涂固安高科技有限公司 | Far infrared graphene thermal radiation constant-temperature composite aluminum plate and preparation method thereof |
Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103612452A (en) * | 2013-11-22 | 2014-03-05 | 袁伟 | Environment-friendly multifunctional water-based coating |
US20140131757A1 (en) * | 2012-11-12 | 2014-05-15 | Ritedia Corporation | Heat conducting composite material and light-emitting diode having the same |
CN106470505A (en) * | 2016-07-29 | 2017-03-01 | 李哲元 | Energy-conserving and environment-protective high temperature resistant type far-infrared health-care semiconductor heating slurry |
CN106592902A (en) * | 2016-12-06 | 2017-04-26 | 威骏(湖北)高新实业股份有限公司 | Low-temperature far-infrared integral electric heating tender porcelain decorative material and preparation method thereof |
CN206929847U (en) * | 2017-07-10 | 2018-01-26 | 广东康烯科技有限公司 | A kind of graphene far infrared heating floor |
CN108811206A (en) * | 2018-06-27 | 2018-11-13 | 四川省安德盖姆石墨烯科技有限公司 | A kind of graphene euthermic chip production method |
CN109233474A (en) * | 2018-09-14 | 2019-01-18 | 深圳市博原实业有限公司 | A kind of inner wall decorative coating and its preparation process |
-
2019
- 2019-07-26 CN CN201910680467.8A patent/CN110405910B/en active Active
Patent Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20140131757A1 (en) * | 2012-11-12 | 2014-05-15 | Ritedia Corporation | Heat conducting composite material and light-emitting diode having the same |
CN103612452A (en) * | 2013-11-22 | 2014-03-05 | 袁伟 | Environment-friendly multifunctional water-based coating |
CN106470505A (en) * | 2016-07-29 | 2017-03-01 | 李哲元 | Energy-conserving and environment-protective high temperature resistant type far-infrared health-care semiconductor heating slurry |
CN106592902A (en) * | 2016-12-06 | 2017-04-26 | 威骏(湖北)高新实业股份有限公司 | Low-temperature far-infrared integral electric heating tender porcelain decorative material and preparation method thereof |
CN206929847U (en) * | 2017-07-10 | 2018-01-26 | 广东康烯科技有限公司 | A kind of graphene far infrared heating floor |
CN108811206A (en) * | 2018-06-27 | 2018-11-13 | 四川省安德盖姆石墨烯科技有限公司 | A kind of graphene euthermic chip production method |
CN109233474A (en) * | 2018-09-14 | 2019-01-18 | 深圳市博原实业有限公司 | A kind of inner wall decorative coating and its preparation process |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN112573891A (en) * | 2020-12-10 | 2021-03-30 | 山东省泥博士新型材料有限公司 | Far infrared health maintenance diatom ooze board and preparation method thereof |
CN114654830A (en) * | 2021-04-01 | 2022-06-24 | 上海涂固安高科技有限公司 | Far infrared graphene thermal radiation constant-temperature composite aluminum plate and preparation method thereof |
Also Published As
Publication number | Publication date |
---|---|
CN110405910B (en) | 2021-11-26 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN206807799U (en) | A kind of electric heat-emitting board based on graphene technology | |
CN110405910A (en) | A kind of preparation method of the energy-saving integrated wall of Far infrared health preservation health-care environmental-protecting | |
CN109185958A (en) | Graphene Far-infrared negative oxygen ion electric heating mural painting | |
CN107080405B (en) | Graphene nano far-infrared negative-ion multifunctional electro-heating screen and preparation method thereof | |
CN101982205A (en) | Method for manufacturing tourmaline health-care products and applications thereof | |
CN107277948A (en) | Far infrared compound resin heating base plate, its preparation method and application | |
CN106974835A (en) | A kind of intelligent facial mask | |
CN209500532U (en) | A kind of self-heating physiotherapy electrode plate | |
CN105588169A (en) | Far infrared carbon fiber integrated wall heating plate and production technology thereof | |
CN201530252U (en) | Far infrared electric heating picture | |
CN204534798U (en) | A kind of heating picture based on carbon system Electric radiant Heating Film | |
CN106642283A (en) | Fresco suitable for indoor heating | |
CN206164874U (en) | Apposition has biological ore material to scribble thermo electric material a little | |
CN208190950U (en) | A kind of integrated electric hot plate of anion | |
CN206929847U (en) | A kind of graphene far infrared heating floor | |
CN204629672U (en) | Far-infrared physiotherapy heating decoration painting | |
CN202099972U (en) | Electric heating bamboo floor | |
CN106998598A (en) | A kind of intelligent heating body, its preparation method and application | |
CN103256646A (en) | Folding type electric heating pad and manufacturing method thereof | |
CN207196607U (en) | electric heating device capable of purifying air | |
CN111396973A (en) | Graphite alkene electric heat is drawn | |
CN205536082U (en) | Warm board of integrated wall of far infrared carbon fiber | |
CN212511361U (en) | Graphite alkene electric heat is drawn | |
CN105605654B (en) | A kind of quick-heating type nanometer heating floor | |
CN102839807A (en) | Novel floor |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
PB01 | Publication | ||
PB01 | Publication | ||
SE01 | Entry into force of request for substantive examination | ||
SE01 | Entry into force of request for substantive examination | ||
GR01 | Patent grant | ||
GR01 | Patent grant |