CN106396402B

CN106396402B - High radiofrequency far infrared, anion ceramics and its manufacturing process

Info

Publication number: CN106396402B
Application number: CN201610794670.4A
Authority: CN
Inventors: 林鸿福
Original assignee: Dehua Heng Yi Ceramic Art Limited-Liability Co
Current assignee: Beijing shuangao Tiguan Sports Culture Club Co.,Ltd.
Priority date: 2016-08-31
Filing date: 2016-08-31
Publication date: 2019-01-22
Anticipated expiration: 2036-08-31
Also published as: CN106396402A

Abstract

The invention belongs to ceramic fields, and in particular to a kind of high radiofrequency far infrared, anion ceramics and its manufacturing process.This kind of ceramics, including ceramic body and ceramic glaze.High radiofrequency far infrared provided by the invention, anion ceramics, it is a performance upgrade to such ceramics of tradition, anion and far infrared are discharged jointly by ceramic body and ceramic glaze, the burst size of anion and infrared ray is greatly improved, the environment of surrounding ceramics can be played a role.The selected extraordinary rare earth mineral high molecule nano material of this kind of ceramic glaze, reduce the raw material to glaze hair face influential effect, increase and replace part material, glaze layer is enabled to release release anion and far infrared simultaneously, the radiofrequency for improving ceramics whole anion and far infrared, can influence the environment of surrounding ceramics, be suitable as the art work and home decoration goods of furniture for display rather than for use, it can play the role of sterilization and purification air, improve the environmental quality of surrounding ceramics.

Description

High radiofrequency far infrared, anion ceramics and its manufacturing process

Technical field

The invention belongs to ceramic fields, and in particular to a kind of high radiofrequency far infrared, anion ceramics and its manufacture Technique.

Background technique

With the continuous development and progress of human society, due to the deterioration of environment, the change of human body living habit and long-term Work is overworked for a very long period, and is led to the constitution of people gradually slant acidity, is assembled the acidic materials being largely harmful to the human body both free radicals in vivo, Afterwards make sluggish metabolism, internal organ burden, be easy fatigue excessive internal heat, constipation, it is serious to can lead to hypertension, hyperlipidemia etc. Chronic disease, the probability for causing cancer stricken to be suffered from greatly improve.

To solve the above problems, applicant provides a kind of energy porcelain and manufacturing process, grant number are CN104003698B, this kind of ceramic ceramic formula include quartz, potassium feldspar, kaolin, water, silver, titanium, tin, organosilicon, Potassium, magnesium, calcium, zinc, germanium, Brazilian tourmaline, medical stone, pelelith, old stove soil, magnetite mine, inorganic salt mineral, selected special type are dilute Native minerals high molecule nano material, can be during high temperature firing, it is ensured that each substance will not fail, stabilization with super strength Property and safety.Through detecting, the present invention, which provides energy porcelain, can discharge the anion and far infrared beneficial to human body, have super Strong antibiotic property.The ceramic body of existing energy porcelain is closed in glaze layer, and the anion and far infrared of green body release need Penetrating glaze layer could externally be reacted, and the influence of anion and far infrared is subject to certain restrictions, furthermore far infrared and An important factor for radiofrequency of anion is this kind of ceramic effect of decision, therefore improve the radiation frequency of far infrared and anion Rate is an important factor for improving this kind ceramics overall performance.

Summary of the invention

To solve the above-mentioned problems, the present invention provides a kind of high radiofrequency far infrared, anion ceramics and its systems Make technique.

For achieving the above object, the present invention provides high radiofrequency far infrareds, anion ceramics, including ceramics Green body, it is characterised in that: the ceramic body is externally provided with ceramic glaze；

Institute's ceramic glaze is as follows in parts by weight: 20-25 parts of kaolin, 10-15 parts of clear frit, nano silver 10-15 Part, Brazilian 10-15 parts of tourmaline, mill base 0-10,5-10 parts of quartz, talcum 5-10,1-5 parts of rock quartz, 1-5 parts of organosilicon, 1-5 parts of potassium, 1-5 parts of magnesium, 1-5 parts of calcium, 1-5 parts of zinc, 1-5 parts of germanium, 1-5 parts of magnetite mine, 1-5 parts of inorganic salt mineral.

Optimization, amount glaze is as follows in parts by weight: 23 parts of kaolin, 13 parts of clear frit, nano silver 12 part, bar 12 parts of western tourmaline, 8 parts of quartz, talcum 6,2 parts of rock quartz, 3 parts of organosilicon, 3 parts of potassium, 1 part of magnesium, 4 parts of calcium, 5 parts of zinc, germanium 2 Part, 4 parts of magnetite mine, 2 parts of inorganic salt mineral.

Optimization, amount glaze is as follows in parts by weight: 23 parts of kaolin, 11 parts of clear frit, nano silver 14 part, bar 10 parts of western tourmaline, mill base 3,6 parts of quartz, talcum 8,3 parts of rock quartz, 4 parts of organosilicon, 2 parts of potassium, 4 parts of magnesium, 1 part of calcium, zinc 4 Part, 1 part of germanium, 3 parts of magnetite mine, 3 parts of inorganic salt mineral.

Optimization, ceramic glaze is as follows in parts by weight: 21 parts of kaolin, 10 parts of clear frit, nano silver 11 part, bar 11 parts of western tourmaline, mill base 8,10 parts of quartz, talcum 5,5 parts of rock quartz, 1 part of organosilicon, 4 parts of potassium, 3 parts of magnesium, 3 parts of calcium, zinc 2 Part, 3 parts of germanium, 2 parts of magnetite mine, 1 part of inorganic salt mineral.

The manufacturing process of high radiofrequency far infrared, anion ceramics, it is characterised in that: make above-mentioned any one institute The ceramics stated, which comprises the following steps:

Step 1, biscuit of ceramics is made；

Step 2, proportion weighing is carried out according to ceramic glaze raw material, the raw material other than mill base is mixed, is crushed, is wet Slurry is made in ball milling, sieving；

Step 3, slurry step 2 obtained is mixed with mill base, obtains ceramic glaze；

Step 4, ceramic glaze is imposed on biscuit of ceramics；

Step 5, it after biscuit of ceramics is dry, is put into kiln and forms by a firing, firing temperature is 1310-1350 DEG C, firing Time 6-9 hour.

Further, in step 2 when wet ball mill material, ball, water ratio are as follows: 1:0.8-1.2:1.5-2.

Further, in step 4 when ceramic glaze glazing, by ceramic glaze specific gravity be adjusted to 20-25 ° of Baume Hydrometer concentration it Between.

Further, in step 1 ceramic glaze glazing with a thickness of 0.1mm-0.3mm.

Further, the biscuiting temperature of biscuit of ceramics is 1100-1150 DEG C in step 1.

Further, it is characterised in that: firing temperature control is as follows in step 5: kiln was crossed through 1-2 hours and is at the uniform velocity warming up to 800 DEG C, kiln is continuously heating to 1100-1150 DEG C for 2-3 hours, keeps the temperature 1 hour, and kiln continues to heat up, and is heated up through 2-3 hours To firing temperature, subsequent cooled to room temperature acquires high radiofrequency far infrared, anion ceramics.

Seen from the above description, high radiofrequency far infrared provided by the invention, anion ceramics, be to tradition such Performance upgrade of ceramics discharges anion and far infrared by ceramic body and ceramic glaze jointly, greatly improves The burst size of anion and infrared ray can play a role the environment of surrounding ceramics.

This kind of ceramic glaze uses advanced technology and scientific formula, selected special type rare earth mineral high molecular nanometer material Material reduces the raw material to glaze hair face influential effect, increases and replaces part material, glaze layer is enabled to release release simultaneously Anion and far infrared improve the radiofrequency of ceramics whole anion and far infrared, can be to the environment of surrounding ceramics It is influenced, is suitable as the art work and home decoration goods of furniture for display rather than for use, sterilization and purification air can be played the role of, improve surrounding ceramics Environmental quality；In addition, the conjugation of this kind of ceramic glaze and ceramic body is good, glossiness is good.

Specific embodiment

For a better understanding of the technical solution of the present invention, embodiment provided by the invention is described below in detail.

High radiofrequency far infrared, anion ceramics, including ceramic body, it is characterised in that: outside the ceramic body Equipped with ceramic glaze；

Specific embodiment one:

High radiofrequency far infrared, anion ceramics, including ceramic body, ceramic glaze；

Energy measuring device green body is as follows in parts by weight: 21 parts of quartz, 26 parts of potassium feldspar, 11 parts of kaolin, 6 parts of water, silver 2 Part, 2 parts of titanium, 1 part of tin, 2 parts of organosilicon, 3 parts of potassium, 1 part of magnesium, 3 parts of calcium, 3 parts of zinc, 3 parts of germanium, Brazilian 2 parts of tourmaline, medical stone 3 Part, 2 parts of pelelith, old stove native 2 parts, 3 parts of magnetite mine, 1 part of inorganic salt mineral；

Ceramic glaze is as follows in parts by weight: 23 parts of kaolin, 13 parts of clear frit, 12 parts of nano silver, Brazil are electrical 12 parts of stone, 8 parts of quartz, talcum 6,2 parts of rock quartz, 3 parts of organosilicon, 3 parts of potassium, 1 part of magnesium, 4 parts of calcium, 5 parts of zinc, 2 parts of germanium, magnetite 4 parts of mine, 2 parts of inorganic salt mineral

Specific embodiment two:

Energy measuring device green body is as follows in parts by weight: 23 parts of quartz, 27 parts of potassium feldspar, 11 parts of kaolin, 7 parts of water, silver 3 Part, 2 parts of titanium, 2 parts of tin, 3 parts of organosilicon, 1 part of potassium, 1 part of magnesium, 1 part of calcium, 2 parts of zinc, 2 parts of germanium, Brazilian 2 parts of tourmaline, medical stone 3 Part, 2 parts of pelelith, old stove native 2 parts, 4 parts of magnetite mine, 2 parts of inorganic salt mineral；

Ceramic glaze is as follows in parts by weight: 23 parts of kaolin, 11 parts of clear frit, 14 parts of nano silver, Brazil are electrical 10 parts of stone, light mill base 3,6 parts of quartz, talcum 8,3 parts of rock quartz, 4 parts of organosilicon, 2 parts of potassium, 4 parts of magnesium, 1 part of calcium, 4 parts of zinc, 1 part of germanium, 3 parts of magnetite mine, 3 parts of inorganic salt mineral

Specific embodiment three:

Energy measuring device green body is as follows in parts by weight: 25 parts of quartz, 25 parts of potassium feldspar, 12 parts of kaolin, 8 parts of water, silver 1 Part, 1 part of titanium, 2 parts of tin, 3 parts of organosilicon, 2 parts of potassium, 2 parts of magnesium, 3 parts of calcium, 2 parts of zinc, 2 parts of germanium, Brazilian 1 part of tourmaline, medical stone 2 Part, 3 parts of pelelith, old stove native 2 parts, 2 parts of magnetite mine, 2 parts of inorganic salt mineral.

Ceramic glaze is as follows in parts by weight: 21 parts of kaolin, 10 parts of clear frit, 11 parts of nano silver, Brazil are electrical 11 parts of stone, dark mill base 8,10 parts of quartz, talcum 5,5 parts of rock quartz, 1 part of organosilicon, 4 parts of potassium, 3 parts of magnesium, 3 parts of calcium, zinc 2 Part, 3 parts of germanium, 2 parts of magnetite mine, 1 part of inorganic salt mineral.

The manufacturing process of high radiofrequency far infrared, anion ceramics makes any one in specific embodiment one to three Ceramics described in, comprising the following steps:

Step 1, proportion weighing is carried out according to ceramic batch raw material, blank is made in mixing, broken, wet ball mill, sieving, by base Material production ceramic body, ceramic body are put into 1100-1150 DEG C of biscuiting in kiln, biscuit of ceramics are made；

Step 2, proportion weighing is carried out according to ceramic glaze raw material, the raw material other than mill base is mixed, is crushed, is wet Ball milling, sieving are made slurry, the ratio of material, ball, water when wet ball mill are as follows: 1:0.8-1.2:1.5-2；

Step 4, ceramic glaze is imposed on biscuit of ceramics, by ceramic glaze specific gravity be adjusted to 20-25 ° of Baume Hydrometer concentration it Between, glazing is with a thickness of 0.1mm-0.3mm；

Optimization, firing temperature control is as follows in step 5:

Kiln was crossed through 1-2 hours and is at the uniform velocity warming up to 800 DEG C,

Kiln is continuously heating to 1100-1150 DEG C for 2-3 hours, keeps the temperature 1 hour,

Kiln continues to heat up, and is warming up to firing temperature through 2-3 hours,

Subsequent cooled to room temperature acquires high radiofrequency far infrared, anion ceramics.

Above-mentioned high radiofrequency far infrared, anion ceramics are passed through to a performance upgrade of such ceramics of tradition Ceramic body and ceramic glaze discharge anion and far infrared jointly, greatly improve the burst size of anion and infrared ray, The environment of surrounding ceramics can be played a role.

The above is only the preferred embodiment of the present invention, therefore cannot be limited the scope of implementation of the present invention with this, i.e., according to Equivalent changes and modifications made by scope of the present invention patent and description should still belong to the model that the invention patent covers In enclosing.

Claims

1. high radiofrequency far infrared, anion are ceramic, including ceramic body, it is characterised in that: the ceramic body peripheral hardware There is ceramic glaze；

The ceramic glaze is as follows in parts by weight: 20-25 parts of kaolin, 10-15 parts of clear frit, 10-15 parts of nano silver, Brazilian tourmaline 10-15 parts, 0-10 parts of mill base, 5-10 parts of quartz, 5-10 parts of talcum, 1-5 parts of rock quartz, 1-5 parts of organosilicon, 1-5 parts of potassium, 1-5 parts of magnesium, 1-5 parts of calcium, 1-5 parts of zinc, 1-5 parts of germanium, 1-5 parts of magnetite mine, 1-5 parts of inorganic salt mineral.

2. high radiofrequency far infrared according to claim 1, anion are ceramic, which is characterized in that the ceramic glaze Expect as follows in parts by weight: 23 parts of kaolin, 13 parts of clear frit, 12 parts of nano silver, Brazilian 12 parts of tourmaline, quartz 8 Part, 6 parts of talcum, 2 parts of rock quartz, 3 parts of organosilicon, 3 parts of potassium, 1 part of magnesium, 4 parts of calcium, 5 parts of zinc, 2 parts of germanium, 4 parts of magnetite mine, inorganic salts 2 parts of minerals.

3. high radiofrequency far infrared according to claim 1, anion are ceramic, which is characterized in that the ceramic glaze Expect as follows in parts by weight: 23 parts of kaolin, 11 parts of clear frit, 14 parts of nano silver, Brazilian 10 parts of tourmaline, 3 parts of mill base, 6 parts of quartz, 8 parts of talcum, 3 parts of rock quartz, 4 parts of organosilicon, 2 parts of potassium, 4 parts of magnesium, 1 part of calcium, 4 parts of zinc, 1 part of germanium, magnetite mine 3 Part, 3 parts of inorganic salt mineral.

4. high radiofrequency far infrared according to claim 1, anion are ceramic, which is characterized in that the ceramic glaze Expect as follows in parts by weight: 21 parts of kaolin, 10 parts of clear frit, 11 parts of nano silver, Brazilian 11 parts of tourmaline, 8 parts of mill base, 10 parts of quartz, 5 parts of talcum, 5 parts of rock quartz, 1 part of organosilicon, 4 parts of potassium, 3 parts of magnesium, 3 parts of calcium, 2 parts of zinc, 3 parts of germanium, magnetite mine 2 Part, 1 part of inorganic salt mineral.

5. the manufacturing process of high radiofrequency far infrared, anion ceramics, it is characterised in that: appoint in production claim 1-4 Ceramics described in meaning one, which comprises the following steps:

Step 1, biscuit of ceramics is made；

Step 2, proportion weighing is carried out according to ceramic glaze raw material, the raw material other than mill base is mixed, is crushed, wet bulb Slurry is made in mill, sieving；

Step 4, ceramic glaze is imposed on biscuit of ceramics；

Step 5, it after biscuit of ceramics is dry, is put into kiln and forms by a firing, firing temperature is 1310-1350 DEG C, firing time 6-9 hours.

6. the manufacturing process of high radiofrequency far infrared according to claim 5, anion ceramics, it is characterised in that: In step 2 when wet ball mill material, ball, water ratio are as follows: 1:0.8-1.2:1.5-2.

7. the manufacturing process of high radiofrequency far infrared according to claim 5, anion ceramics, it is characterised in that: In step 4 when ceramic glaze glazing, ceramic glaze specific gravity is adjusted between 20-25 ° of Baume Hydrometer concentration.

8. the manufacturing process of high radiofrequency far infrared according to claim 5, anion ceramics, it is characterised in that: Ceramic glaze glazing is in step 4 with a thickness of 0.1mm-0.3mm.

9. the manufacturing process of high radiofrequency far infrared according to claim 5, anion ceramics, it is characterised in that: The biscuiting temperature of biscuit of ceramics is 1100-1150 DEG C in step 1.

10. the manufacturing process of high radiofrequency far infrared, anion ceramics, feature according to claim 5 or 9 exist In: it is as follows that temperature control is formed by a firing in step 5:

Kiln was at the uniform velocity warming up to 800 DEG C through 1-2 hours,