CN108483912A - Far infrared overglaze - Google Patents

Abstract

The present invention discloses a kind of far infrared overglaze, and the component of the far infrared overglaze includes aluminium oxide, silica, calcium oxide, potassium oxide, magnesia, barium monoxide, sodium oxide molybdena and far infrared additive；The component of the far infrared additive includes kaolin, feldspar, quartz, nano-tourmaline, zirconium carbide, zirconium dioxide.Technical scheme of the present invention enables to ceramic tile to have far infrared emission function.

Description

Far infrared overglaze

Technical field

The present invention relates to ceramic tile technical field, more particularly to a kind of far infrared overglaze.

Background technology

In recent years, with the continuous deterioration of ecological environment and stepping up for people's living standard, public space and household The construction of health environment in space becomes the topic of people's close attention.

Far infrared can effectively be absorbed as a kind of electromagnetic wave by human body.Deeply far infrared into the human body Line can cause the vibration of atom and molecule, and by resonant absorption, form thermal response and promote in subcutaneous deep tissues temperature It rises, fine vascular expansion；To promote blood circulation, the obstacle cleaning that extravasated blood etc. is harmed to metabolism is clean, and tissue is made to obtain To bring back to life, and ferment is promoted to grow, so that it is trapped in old waste and the harmful substance in human body originally, it can be with new Old metabolism is excreted by sweat gland.Concurrently there are the residue of such as cosmetics in pore, also can directly by pore with Sweat excretes together, effectively to mitigate the burden of kidney.

Currently, use of the ceramic tile in public space and home room is more and more extensive, still, most of ceramic tile is only Only have decoration functions.Therefore, how far infrared emission function organically to be combined with ceramic tile, becomes ceramic tile field Very popular research topic.

Invention content

The main object of the present invention is to provide a kind of far infrared overglaze, it is intended to so that ceramic tile has far infrared transmitting work( Energy.

To achieve the above object, the component of far infrared overglaze proposed by the present invention include aluminium oxide, silica, calcium oxide, Potassium oxide, magnesia, barium monoxide, sodium oxide molybdena and far infrared additive；

The component of the far infrared additive includes kaolin, feldspar, quartz, nano-tourmaline, zirconium carbide, titanium dioxide Zirconium.

Optionally, the mass fraction of each component of the far infrared overglaze is：

Optionally, the component of the far infrared overglaze further includes fatty alcohol sulfonate and silanol class non-ionic surface active Agent.

Optionally, the mass fraction of the fatty alcohol sulfonate is 5w%-8w%, the silanol class non-ionic surface active The mass fraction of agent is 0.3w%-2w%.

Optionally, the silanol class nonionic surfactant is triphenyl silicone.

Optionally, the hydrophilic-hydrophobic balance value of the fatty alcohol sulfonate is 8-10, and the silanol class non-ionic surface is lived Property agent hydrophilic-hydrophobic balance value be 9-16.

Optionally, the mass fraction of each component of the far infrared additive is：

Optionally, the nano-tourmaline includes in a nanometer schorl, nanometer elbaite and nanometer dravite It is at least one.

Optionally, the component of the nano-tourmaline includes：

Nanometer schorl 50w%-75w%；

Nanometer elbaite 12w%-45w%；

Nanometer dravite 3w%-25w%.

Optionally, the nano-tourmaline is modified Nano tourmaline.

Technical scheme of the present invention adds far infrared additive in the component of overglaze, in the far infrared additive Tourmaline has far infrared emission function, also, its far infrared emission function is with the reduction of its grain size and in enhancing Trend, the present invention is using nano-tourmaline, it is possible to understand that, it may make the ceramic tile of overglaze and the application overglaze to have Excellent far infrared emission function, simultaneously as nano-tourmaline itself also has a series of excellent surfaces, interface characteristics Can, be conducive to its dispersion and homogenization in overglaze, to further promote overglaze and apply the remote of the ceramic tile of the overglaze The strength and stability of infrared ray transmitting function.

Also, in the far infrared additive, zirconium dioxide also has far infrared emission function, meanwhile, zirconium carbide is not Only can efficient absorption visible light, be also equipped with far infrared reflection characteristic.The two with nano-tourmaline when coordinating, nano-tourmaline The far infrared discharged with zirconium dioxide may make overglaze and using the overglaze after the zirconium carbide reflection of disperse Ceramic tile has broader far infrared launch angle and more stable far infrared transmission power.

Also, technical scheme of the present invention is added with kaolin, feldspar and stone also in the component of far infrared additive English, kaolin, which can play the role of optimization glaze suspension and wearability, feldspar, can play fluxing effect, and quartz can be played and be carried For the effect of glaze skeleton structure.

Specific implementation mode

Hereinafter, preferred embodiments of the present invention will be described, it should be understood that preferred embodiment described herein is only used In description and interpretation the present invention, be not intended to limit the present invention, and in the absence of conflict, the present invention in embodiment and Feature in embodiment can be combined with each other.

The present invention proposes a kind of far infrared overglaze, is applied to ceramic tile, ceramic tile may make to have far infrared emission function.

In one embodiment of far infrared overglaze of the present invention, the component of the far infrared overglaze includes aluminium oxide, silica, oxidation Calcium, potassium oxide, magnesia, barium monoxide, sodium oxide molybdena and far infrared additive；

The component of the far infrared additive includes kaolin, feldspar, quartz, nano-tourmaline, zirconium carbide, titanium dioxide Zirconium.

Technical scheme of the present invention adds far infrared additive in the component of overglaze, in the far infrared additive Tourmaline has far infrared emission function, also, its far infrared emission function is with the reduction of its grain size and in enhancing Trend, the present invention is using nano-tourmaline, it is possible to understand that, it may make the ceramic tile of overglaze and the application overglaze to have Excellent far infrared emission function, simultaneously as nano-tourmaline itself also has a series of excellent surfaces, interface characteristics Can, be conducive to its dispersion and homogenization in overglaze, to further promote overglaze and apply the remote of the ceramic tile of the overglaze The strength and stability of infrared ray transmitting function.

Also, in the far infrared additive, zirconium dioxide also has far infrared emission function, meanwhile, zirconium carbide is not Only can efficient absorption visible light, be also equipped with far infrared reflection characteristic.The two with nano-tourmaline when coordinating, nano-tourmaline The far infrared discharged with zirconium dioxide may make overglaze and using the overglaze after the zirconium carbide reflection of disperse Ceramic tile has broader far infrared launch angle and more stable far infrared transmission power.

Also, technical scheme of the present invention is added with kaolin, feldspar and stone also in the component of far infrared additive English, kaolin, which can play the role of optimization glaze suspension and wearability, feldspar, can play fluxing effect, and quartz can be played and be carried For the effect of glaze skeleton structure.

Specifically, the mass fraction of each component of the far infrared overglaze is：

Wherein, the mass fraction of each component of the far infrared additive is：

In this way, by the optimization of formula and dosage to far infrared overglaze, that is, the formulation content of aluminium oxide is improved, reduced The formulation content with melting behaviour such as calcium oxide, magnesia lacks in this way, the glazes such as solution cavity, pin hole, glaze bubble can be effectively reduced It falls into, improves the quality of overglaze and ceramic tile.

Preferably, the component of the far infrared overglaze further includes fatty alcohol sulfonate and silanol class non-ionic surface active Agent.Specifically, the silanol class nonionic surfactant is triphenyl silicone.

Due to the addition of overglaze component mid and far infrared additive, the case where exacerbating overglaze surface tension unbalance stress, cause The problem of making overglaze reunite.Therefore, technical scheme of the present invention also adds fatty alcohol sulfonate in the component of overglaze With silanol class nonionic surfactant.Since fatty alcohol sulfonate has longer hydrophobic grouping-aliphatic chain hydroxyl, also, Chain length is longer, and the dynamics stretched out to surface layer overglaze is bigger, reduces with joint efforts suffered by the overglaze of surface layer to may make so that overglaze Surface tension be minimized.

At the same time, silanol class nonionic surfactant does not occur ionization in overglaze and exists in the form of molecule, Its stability is high, is not easy to be influenced by strong electrolyte inorganic salts and pH value.At this point, silanol class nonionic surfactant molecule In lipophilic group it is roughly the same with the lipophilic group of ionic surfactant, but its hydrophilic radical then mainly by having A certain number of oxygen-containing groups (such as hydroxyl and polyoxyethylene chain) are constituted：Lipophilic group is attached to the surface of solids, hydrophilic radical to It stretches in liquid outside, so that the reduction in surface tension of overglaze, and then the mobility of overglaze is effectively increased, improve density The uniformity of distribution.

Also, silanol class nonionic surfactant also has mutual promoting action with fatty alcohol sulfonate, can not only have Effect promotes dispersibility, uniformity of the two in overglaze, also may make that the two increases the reducing effect of overglaze surface tension By force.

In addition, silanol class nonionic surfactant also has the characteristics that low foaming characteristic, bubble in overglaze is effectively reduced Generation, improve the quality of product.

Further, in order to effectively promoted fatty alcohol sulfonate and silanol class nonionic surfactant it is respective effect with And its common cooperation, the mass fraction of the fatty alcohol sulfonate is 5w%-8w%, the silanol class non-ionic surface active The mass fraction of agent is 0.3w%-2w%.

Preferably, the hydrophilic-hydrophobic balance value of the fatty alcohol sulfonate is 8-10, and the silanol class non-ionic surface is lived Property agent hydrophilic-hydrophobic balance value be 9-16.

At this point, the hydrophilic-hydrophobic balance value of fatty alcohol sulfonate and silanol class nonionic surfactant is 10 or so, In this way, may make fatty alcohol sulfonate and silanol class nonionic surfactant that both there is preferable hydrophily, it may have preferably Lipophile so that fatty alcohol sulfonate and silanol class nonionic surfactant can further decrease the surface of overglaze Tension so that the mobility of overglaze and further being promoted for uniformity reduce possibility, promotion overglaze that overglaze bubble generates With the bond strength of ground-coat enamel.

Preferably, the nano-tourmaline is modified Nano tourmaline.

Specifically, modifying process is as follows：According to mass fraction meter, 0.3 part of -0.5 part of phthalic acid is added 300 part -380 In part deionized water, stirring is warming up to 70 DEG C -80 DEG C, adds 6 parts of -10 parts of nano-tourmalines, stirs 10min-15min, according to 0.1-0.2 parts of manganese powders of secondary addition and 0.05-0.22 parts of molybdenum powders, are continuously heating to 85 DEG C -90 DEG C, constant temperature at the uniform velocity stirs 45min- 55min is continuously heating to 100-110 DEG C, sequentially add 0.3 part of -0.5 part of nano calcium oxide, 0.15 part -0.3 part it is nano oxidized Zinc, 0.8 part of -1 part of nano barium carbonate, 0.1 part of -0.2 part of nanometer titanium silicate, constant temperature at the uniform velocity stir 1h-2h, stop reaction, filter, Filter residue is taken, it is dry to get modified Nano tourmaline.

In the above process, the deionized water of nano-tourmaline particle and its adsorption occurs dissociation and forms hydroxyl, benzene two Esterification occurs for the great amount of hydroxy group of carboxyl and nano-tourmaline particle surface in formic acid, and in nano-tourmaline particle surface Monomolecular film is formed, i.e., surface modification is carried out to nano-tourmaline particle so that nano-tourmaline particle surface is by dipole inversion At nonpolarity, polarity is reduced.Also, the monomolecular film that nano-tourmaline particle surface generates can also reduce nano-tourmaline Interaction force between particle surface improves the mobility of modified Nano tourmaline.In addition, the carboxyl that phthalic acid provides There is electrostatic repulsion as anion, additionally it is possible to the molecular dispersivity in system, uniformity be made further to be promoted.

In this way, dispersibility and uniformity of the modified Nano tourmaline in overglaze are effectively improved, in this way, not only can be effective Enhance the far infrared emission function of overglaze and ceramic tile, widen the far infrared launch angle of overglaze and ceramic tile, promoted overglaze and The stability of ceramic tile far infrared transmitting；And the polarity of modified nano-tourmaline particle surface is relatively low, and it is dispersed, uniform Property it is extremely strong, also can effectively avoid the generation of agglomeration in overglaze, reduce the glaze planar defects such as solution cavity, pin hole, glaze bubble, to effectively Improve the quality of overglaze and ceramic tile.

At this point, the nano-tourmaline in overglaze uses modified Nano tourmaline, the negative of nano-tourmaline can be also effectively improved Ion release assigns the good anion function of ceramic tile using the overglaze.

Specifically, the nano-tourmaline includes in a nanometer schorl, nanometer elbaite and nanometer dravite It is at least one.That is, carry out nano-tourmaline selection when, both can independent choice nanometer schorl, nanometer elbaite and Nanometer any one of dravite, also can be in simultaneous selection nanometer schorl, nanometer elbaite and nanometer dravite Any two, can also nanometer schorl, nanometer elbaite and nanometer dravite three's simultaneous selection.

Preferably, the component of the nano-tourmaline includes：

Nanometer schorl 50w%-75w%；

Nanometer elbaite 12w%-45w%；

Nanometer dravite 3w%-25w%.

At this point, the nano-particle of a variety of crystallographic systems is contained in nano-tourmaline, and when such nano-tourmaline is scattered in When in overglaze, the nano-particle of a variety of crystallographic systems can form random spread pattern, not only effectively reduce solution cavity, pin hole, glaze The glaze planar defects such as bubble, but also the bond strength between overglaze and ground-coat enamel is effectively enhanced, to effectively improve overglaze and porcelain The quality of brick.

The foregoing is merely the preferred embodiment of the present invention, are not intended to limit the scope of the invention, every at this Under the inventive concept of invention, using equivalent structure transformation made by present specification, or directly/it is used in other indirectly Relevant technical field is included in the scope of patent protection of the present invention.

Claims (10)

1. a kind of far infrared overglaze, which is characterized in that the component of the far infrared overglaze include aluminium oxide, silica, calcium oxide, Potassium oxide, magnesia, barium monoxide, sodium oxide molybdena and far infrared additive；

The component of the far infrared additive includes kaolin, feldspar, quartz, nano-tourmaline, zirconium carbide, zirconium dioxide.

2. far infrared overglaze as described in claim 1, which is characterized in that the mass fraction of each component of the far infrared overglaze For：

3. far infrared overglaze as described in claim 1, which is characterized in that the component of the far infrared overglaze further includes fatty alcohol Sulfonate and silanol class nonionic surfactant.

4. far infrared overglaze as claimed in claim 3, which is characterized in that the mass fraction of the fatty alcohol sulfonate is The mass fraction of 5w%-8w%, the silanol class nonionic surfactant are 0.3w%-2w%.

5. far infrared overglaze as claimed in claim 3, which is characterized in that the silanol class nonionic surfactant is triphen Base silicone.

6. far infrared overglaze as claimed in claim 3, which is characterized in that the hydrophilic-hydrophobic balance value of the fatty alcohol sulfonate Hydrophilic-hydrophobic balance value for 8-10, the silanol class nonionic surfactant is 9-16.

7. far infrared overglaze as described in claim 1, which is characterized in that the quality of each component of the far infrared additive point Number is：

8. the far infrared overglaze as described in any one of claim 1 to 7, which is characterized in that the nano-tourmaline includes receiving At least one of rice schorl, nanometer elbaite and nanometer dravite.

9. far infrared overglaze as claimed in claim 8, which is characterized in that the component of the nano-tourmaline includes：

Nanometer schorl 50w%-75w%；

Nanometer elbaite 12w%-45w%；

Nanometer dravite 3w%-25w%.

10. the far infrared overglaze as described in any one of claim 1 to 7, which is characterized in that the nano-tourmaline is to be modified Nano-tourmaline.