CN101928479A - High-temperature nanometer energy-saving coating - Google Patents

Abstract

The invention discloses a high-temperature nanometer energy-saving coating, which consists of a component A, a component B and a component C, the component A contains the following components in parts by weight: 5-20 parts of feldspar, 5-15 parts of kaolin, 1-15 parts of Suzhou clay, 5-15 parts of mullite, 10-40 parts of cordierite, 1-10 parts of mineral glass-ceramics, 1-20 parts of zeolite, 0.5-3 parts of nanometer alumina, 0.5-15 parts of ferroferric oxide, 0.5-10 parts of mica, 1-15 parts of talcum powder and 1-25 parts of zircon sand; the component B contains the following components in parts by weight: 1-10 parts of nanometer titanium dioxide, 20-60 parts of titanium dioxide, 1-10 parts of nanometer silica and 20-60 parts of silica; and the component C is water glass or aluminum dihydrogen phosphate. The high-temperature nanometer energy-saving coating has long-term stable and high infrared emissivity and long service life, does not need high-temperature doped synthesis, is convenient for industrialization and has good energy-saving effect after industrial application.

Description

A kind of high-temperature nanometer energy-saving coating

Technical field

The present invention relates to nano paint, specifically is a kind of high-temperature nanometer energy-saving coating.

Background technology

At present domestic and international high-temperature nanometer energy-saving coating can be divided into two classes substantially.One class is the infrared radiation coating based on silicon carbide, as the multinational Encoat infrared radiation coating of uniting release of Britain Harbert Beven company and Europe Australia.Another kind of is infrared radiant material based on transition metal oxide compound (as chromic oxide, nickel oxide etc.).As infrared radiation coating CRC1100, CRC1500 that Japanese CRC company releases, the radiation powder is made up of cobalt oxide, chromic oxide, nickel oxide, Manganse Dioxide etc.The former is being because the high temperature oxidation problem of silicon carbide is perplexing the investigator always, although people all by every means at the various anti-oxidation protective materials of research, head it offs up hill and dale all.Therefore, this type of coating all exists the constantly problem of decay of infrared emittance to some extent.The employed prices of raw and semifnished materials of the latter are comparatively expensive and want operations such as high temperature (1200 ℃-1400 ℃) calcining, pulverizing, ball milling, complex production process, and contaminate environment, the cost height is difficult to promote.The present invention has overcome the deficiencies in the prior art, provides a kind of environmental protection, infrared emittance high and stablize, be convenient to the new type water-solubility high-temperature nanometer energy-saving coating of industrialization.

Summary of the invention

The object of the present invention is to provide a kind of high-temperature nanometer energy-saving coating, it both can use on metal, can also be coated on refractory materials, heat-insulation and heat-preservation material and was on the Industrial Stoves, boiler of burner hearth.

A kind of high-temperature nanometer energy-saving coating is made up of A component, B component and C component.

In the present invention, described A component contains with composition by weight: feldspar 5-20 part, kaolin 5-15 part, Suzhou soil 1-15 part, mullite 5-15 part, trichroite 10-40 part, mineral devitrified glass 1-10 part, zeolite 1-20 part, nano aluminium oxide 0.5-3 part, Z 250 0.5-15 part, mica 0.5-10 part, talcum powder 1-15 part, zircon sand 1-25 part.

In the present invention, described B component contains the component of following weight: nano titanium oxide 1-10 part, titanium dioxide 20-60 part, nano silicon 1-10 part, silicon-dioxide 20-60 part.

In the present invention, described C component: be respectively water glass or aluminium dihydrogen phosphate.

The weight ratio of described A component and C component is 1: 1.0～1.8.

The weight ratio of described B component and C component is 1: 1.2～1.5.

Described C component is two kinds of different binding agents, uses water glass when coating is used on metal, uses when coating and use aluminium dihydrogen phosphate on refractory materials, heat-insulation and heat-preservation material.

In described A component and the B component, except that nanometer materials, the fineness of other components all requires to be preferably the 400-600 order more than 325 orders.

High-temperature nanometer energy-saving coating of the present invention by with the various components of A component and B component after mixing under normal temperature, the normal pressure, under homogenizer, fully stir and make with the C component again.

It is various boilers, Industrial Stoves and other various thermotechnical furnaces of the energy with coal, oil, electricity, gas that coating of the present invention can be applied to 100 ℃-1300 ℃.

Advantage of the present invention

1, the stable mineral material that uses high temperature to form down, crystalline network is stable under the high temperature, coating ir radiation long-term stability, coating can reach more than 2 years work-ing life.

2, need not high temperature (1200 ℃-1400 ℃) calcining, pulverizing, ball milling, production technique is simple relatively, and is free from environmental pollution, is convenient to industrialization.

3, for to guarantee that coating has higher infrared emittance, we have used special blackening agent, as titanium dioxide, silicon-dioxide etc., have used Nano compound simultaneously, as nano aluminium oxide, are to be sent to total emissivity 〉=0.9 under 800 ℃ of-1400 ℃ of temperature to give security.

4, this coating is that water-soluble, nontoxic, cold environmental protection is coated with the type energy-saving coatings, substantially exceeds national standard not stratified requirement in 24 hours, and is not stratified in the lay up period.

5, printing performance is good, and when coating was subjected to shear action, viscosity reduced rapidly, so printing becomes very easy; When shearing force stopped, dope viscosity increased rapidly, so the sagging phenomenon can not occur.

Embodiment:

Below in conjunction with embodiment high-temperature nanometer energy-saving coating application involved in the present invention is described further.

Embodiment 1: be used for the high-temperature nanometer energy-saving coating on the metal in the boiler.

The A component is made up of following parts by weight:

Feldspar 12

Suzhou soil 15

Kaolin 8

Mullite 10

Trichroite 20

Mineral devitrified glass 5

Z 250 6

Mica 1

Talcum powder 3

Zircon sand 2

Zeolite 5

Nano aluminium oxide 1

With the A component put into V-arrangement mixer thorough mixing evenly after, slowly inject in the homogenizer and 92 parts of the water glass of C component, stir, promptly get parts by weight and be 180 parts metal high-temperature nanometer energy-saving coating.

Embodiment 2: be used for the high-temperature nanometer energy-saving coating on the refractory materials in the boiler.

The A component is made up of following parts by weight:

Feldspar 15

Suzhou soil 10

Kaolin 16

Mullite 13

Trichroite 25

Mineral devitrified glass 4

Mica 1.5

Talcum powder 3

Zircon sand 2

Zeolite 10

Nano aluminium oxide 0.5

The B component is made up of following parts by weight:

Nano titanium oxide 1.5

Titanium dioxide 45

Nano silicon 1.5

Silicon-dioxide 52

Use 140 parts of aluminium dihydrogen phosphates in the C component with after the A component cooperates, stir, promptly getting parts by weight is 240 parts; Use 120 parts of aluminium dihydrogen phosphates in the C component with after the B component cooperates, stir, promptly getting parts by weight is 220 parts, and specifically production technique is with example 1; Brushing B component coating is treated promptly to brush the A component coating behind the coating surface drying earlier, can use in dry 2 hours down in 100 ℃ then.Use above-mentioned energy-saving coatings on 4 tons of coal firing boilers, through the actual use in 1 year, fractional energy savings reached more than 18.1%.

Embodiment 3: be used for the high-temperature nanometer energy-saving coating on the refractory materials in the Industrial Stoves.

The A component is made up of following parts by weight:

Feldspar 20

Suzhou soil 10

Kaolin 10

Mullite 5

Trichroite 25

Mineral devitrified glass 10

Mica 0.5

Talcum powder 3

Zircon sand 2

Zeolite 4

Nano aluminium oxide 0.5

The B component is made up of following parts by weight:

Nano titanium oxide 3

Titanium dioxide 46

Nano silicon 3

Silicon-dioxide 48

130 parts of aluminium dihydrogen phosphates in the C component stir with after the A component cooperates, and promptly getting parts by weight is 220; 100 parts of aluminium dihydrogen phosphates in the C component stir with after the B component cooperates, and promptly getting parts by weight is 250 parts, and concrete production technique is with example 1.Brushing B component coating is treated promptly to brush the A component coating behind the coating surface drying earlier, and seasoning can be used in 2 days then.At R28 rice annular heater for rolling steel, 1300 ℃ of working temperatures are used above-mentioned energy-saving coatings, and through the actual use of half a year, fractional energy savings reaches more than 12%.

Embodiment 4: the high-temperature nanometer energy-saving coating that is used for industrial furnace.

The A component is made up of following parts by weight:

Feldspar 15

Suzhou soil 10

Kaolin 10

Mullite 25

Trichroite 10

Mineral devitrified glass 4

Mica 5

Talcum powder 10

Zircon sand 2

Zeolite 8

Nano aluminium oxide 1

The B component is made up of following parts by weight:

Nano titanium oxide 5

Titanium dioxide 50

Nano silicon 5

Silicon-dioxide 40

130 parts of aluminium dihydrogen phosphates in the C component stir with after the A component cooperates, and promptly getting parts by weight is 230 parts; 130 parts of aluminium dihydrogen phosphates in the C component stir with after the B component cooperates, and promptly getting parts by weight is 230, and concrete production technique is with example 1.Brushing B component coating is treated promptly to brush the A component coating behind the coating surface drying earlier, can use in dry 2 hours down in 100 ℃ then.Use above-mentioned energy-saving coatings on the thermal treatment electric furnace, through nearly 2 years actual use, fractional energy savings reaches on 20.9%.

More than show and described ultimate principle of the present invention and principal character and advantage of the present invention.The technician of the industry should understand; the present invention is not restricted to the described embodiments; that describes in the foregoing description and the specification sheets just illustrates principle of the present invention; without departing from the spirit and scope of the present invention; the present invention also has various changes and modifications, and these changes and improvements all fall in the claimed scope of the invention.The claimed scope of the present invention is by appended defining according to claims and equivalent thereof.

Claims (5)

1. high-temperature nanometer energy-saving coating, it is characterized in that, be made up of A component, B component and C component, described A component contains the component of following weight: feldspar 5-20 part, kaolin 5-15 part, Suzhou soil 1-15 part, mullite 5-15 part, trichroite 10-40 part, mineral devitrified glass 1-10 part, zeolite 1-20 part, nano aluminium oxide 0.5-3 part, Z 250 0.5-15 part, mica 0.5-10 part, talcum powder 1-15 part, zircon sand 1-25 part; Described B component contains the component of following weight: nano titanium oxide 1-10 part, titanium dioxide 20-60 part, nano silicon 1-10 part, silicon-dioxide 20-60 part; Described C component: be respectively water glass or aluminium dihydrogen phosphate.

2. a kind of high-temperature nanometer energy-saving coating according to claim 1 is characterized in that, described A component and B component must be used, and brushing B component is brushed the A component more earlier.

3. a kind of high-temperature nanometer energy-saving coating according to claim 1 is characterized in that, when being coated on the metal, the C component uses water glass.

4. a kind of high-temperature nanometer energy-saving coating according to claim 1 is characterized in that, when being coated on refractory materials, heat-insulation and heat-preservation material, the C component uses aluminium dihydrogen phosphate.

5. a kind of high-temperature nanometer energy-saving coating according to claim 1 is characterized in that, in A component and the B component, its fineness is preferably the 400-600 order.