CN114958119A - Application of cordierite in low-interface heat-gaining building energy-saving coating - Google Patents

Abstract

The invention relates to a building energy-saving coating with low interface heat gain and a preparation method thereof, which comprises the steps of selecting cordierite to prepare heat insulation slurry, and further preparing the building energy-saving coating with low interface heat gain, wherein the coating has an obvious energy-saving effect, the emissivity can reach 0.85, and the heat insulation temperature difference can reach 0.8 ℃.

Description

Application of cordierite in low-interface heat-gaining building energy-saving coating

Technical Field

The invention belongs to the technical field of coatings, and particularly relates to a low-interface heat-gaining building energy-saving coating, which comprises the steps of selecting low-interface heat-gaining ores to prepare heat-insulating slurry, and further preparing the low-interface heat-gaining building energy-saving coating, wherein the coating has an obvious energy-saving effect, the emissivity can reach 0.96, the heat-insulating temperature difference can reach 1.6 ℃, the energy can be saved by more than 10% in summer, and the energy can also reach 7% in winter.

Background

The traditional heat preservation and insulation of buildings usually adopt external-hanging organic or inorganic heat preservation plates, but the occupied area is large, the construction period is long, the construction process is complex, and meanwhile, the traditional heat preservation and insulation method has the potential safety hazards of flammability, easiness in layer lifting, easiness in falling, easiness in leakage and the like. While various hidden dangers appear only depending on the traditional heat preservation, the building energy-saving coating has the advantages of economy, environmental protection, convenient use, obvious energy-saving effect and the like, and along with the implementation and promotion of the national double-carbon strategy, the technical trend of replacing an external hanging type outer wall heat preservation layer with the energy-saving coating is achieved. At present, heat preservation and insulation coatings are available on the market, such as Chinese patent applications CN108117812 and CN113201256, but the reflective insulation coatings of the buildings only have the insulation effect equivalent to that of polystyrene boards with the thickness of 0.5mm in summer and daytime, have no effect at night and have side effects in winter. The aerogel thermal insulation coating is also available in the market, the thickness of the aerogel thermal insulation coating needs to reach 30mm to meet the energy-saving requirement, and the cracking problem of the thick coating is difficult to avoid. Therefore, the market still lacks an energy-saving thin layer coating which really reduces the heat gain of the building interface.

Disclosure of Invention

The invention aims to provide a low-interface heat-gaining building energy-saving coating and a preparation method thereof, and the low-interface heat-gaining building energy-saving coating is further prepared by selecting low-interface heat-gaining ores to prepare heat-insulating slurry, has an obvious energy-saving effect, has an emissivity of 0.96, can achieve a heat-insulating temperature difference of 1.6 ℃, can save energy by more than 10% in summer, and can also save energy by 7% in winter.

The invention firstly provides a group of new uses of low interface heat gain ore, comprising:

the application of the low interface heat-gaining ore in preparing the heat-insulating slurry of the low interface heat-gaining building energy-saving coating is characterized in that the low interface heat-gaining ore comprises any one of cordierite, monazite, phosphogypsum and manganese ore;

the application of the low interface heat-gaining ore in preparing the low interface heat-gaining building energy-saving coating, wherein the low interface heat-gaining ore comprises any one of cordierite, monazite, phosphogypsum and manganese ore;

the application of the mixture of cordierite, monazite, phosphogypsum and manganese ore in preparing the heat insulation slurry of the low interface heat-gaining building energy-saving coating;

the application of the mixture of cordierite, monazite, phosphogypsum and manganese ore in preparing the low-interface heat-gaining building energy-saving coating.

In a first aspect of the invention, the invention provides a thermal insulation slurry for building energy-saving coating, which comprises the following components in parts by weight:

70-90 parts of low-interface heat-gaining ore

3-10 parts of silica aerogel wet material

5-25 parts of water

The low interface heat gain ore includes any one of cordierite, monazite, phosphogypsum and manganese ore, based on the weight of the insulation slurry.

In another preferred embodiment, the insulation slurry comprises the following components in parts by weight:

80 portions of low-interface heat-gaining ore

5 parts of silica aerogel wet material

15 portions of water

Based on the weight of the insulation slurry.

In a second aspect of the present invention, there is provided a method of preparing a thermal insulating paste as defined in the first aspect:

calcining the low-interface heat-gaining ore at high temperature, and performing ball milling to obtain powder;

and uniformly mixing the powder, the silica aerogel wet material and water according to a proportion to prepare the heat insulation slurry.

In another preferred embodiment, the low interface heat-gaining ore is calcined for 5-8h under the condition of 300-500 ℃, and the powder is prepared by ball milling for 8-10 h;

in a third aspect of the invention, a low interface heat gain building energy-saving coating is provided, which comprises the following components in parts by weight:

based on the weight of the building energy-saving coating.

The film-forming material is selected from the group consisting of: an acrylic emulsion, an aqueous polyurethane dispersion, or a combination thereof.

The titanium dioxide is selected from the following groups: rutile titanium dioxide, anatase titanium dioxide, or a combination thereof.

The filler is selected from the group consisting of: barium sulfate, kaolin, bentonite, calcium carbonate, or combinations thereof.

The auxiliary agent is selected from the following group: a film forming aid, a dispersant, a thickener, or a combination thereof.

In a further preferred embodiment of the method,

the film forming material is acrylic emulsion;

the titanium dioxide is rutile type titanium dioxide;

the filler is barium sulfate, kaolin and bentonite;

the auxiliary agent is film-forming auxiliary agent alcohol ester twelve, dispersant D-28 and thickener A-016.

In another preferred embodiment, the composition comprises the following components in parts by weight:

in a fourth aspect of the invention, a method for preparing the building energy-saving coating according to the third aspect is provided, wherein the building energy-saving coating is prepared by mixing the components in proportion and dispersing at a high speed.

In a fifth aspect of the invention, a thermal insulation slurry for a building energy-saving coating is provided, which comprises the following components in parts by weight:

based on the weight of the insulation slurry.

In another preferred embodiment, the insulation slurry comprises the following components in parts by weight:

based on the weight of the insulation slurry.

In a sixth aspect of the present invention, there is provided a method of preparing a thermal insulating paste according to the first aspect:

(1) uniformly mixing cordierite, monazite, phosphogypsum and manganese ore in proportion, calcining at high temperature, and ball-milling to obtain powder;

(2) and uniformly mixing the powder, the silica aerogel wet material and water according to a proportion to prepare the heat insulation slurry.

In another preferred embodiment, cordierite, monazite, phosphogypsum and manganese ore are uniformly mixed according to a proportion, calcined for 5-8h under the condition of 300-500 ℃, and ball-milled for 8-10h to prepare powder;

in another preferred embodiment, cordierite, monazite, phosphogypsum and manganese ore are uniformly mixed according to a proportion, calcined for 6 hours at the temperature of 450 ℃, and ball-milled for 8 hours to prepare powder;

in a seventh aspect of the present invention, there is provided a low interfacial heat gain building energy saving coating, comprising the following components in parts by weight:

based on the weight of the building energy-saving coating.

The film-forming material is selected from the group consisting of: an acrylic emulsion, an aqueous polyurethane dispersion, or a combination thereof.

The titanium dioxide is selected from the following groups: rutile titanium dioxide, anatase titanium dioxide, or a combination thereof.

The filler is selected from the group consisting of: barium sulfate, kaolin, bentonite, calcium carbonate, or combinations thereof.

The auxiliary agent is selected from the following group: a film forming aid, a dispersant, a thickener, or a combination thereof.

In a further preferred embodiment of the method,

the film forming material is acrylic emulsion;

the titanium dioxide is rutile type titanium dioxide;

the filler is barium sulfate, kaolin and bentonite;

the auxiliary agent is film-forming auxiliary agent alcohol ester twelve, dispersant D-28 and thickener A-016.

In another preferred embodiment, the composition comprises the following components in parts by weight:

in another preferred embodiment, the composition comprises the following components in parts by weight:

in an eighth aspect of the present invention, there is provided a method for preparing the building energy saving coating according to the seventh aspect, wherein the building energy saving coating is prepared by mixing the components in proportion and dispersing at a high speed.

The invention has the advantages that:

1. it is unexpectedly found that ores such as cordierite, monazite, phosphogypsum and manganese ore have the performance of reducing interface heat gain, and can be mixed with common silica aerogel wet materials and the like to prepare heat insulation slurry, and further mixed with a common carrier acceptable by coating to complete the invention.

2. The coating has low interface heat gain, emissivity of more than 0.85, heat insulation temperature difference of more than 0.8 ℃, better emissivity of 0.96 and heat insulation temperature difference of 1.6 ℃.

3. The coating has obvious energy-saving effect, saves more than 10 percent of energy in summer, and can also save 7 percent of energy in winter.

It is to be understood that within the scope of the present invention, the above-described features of the present invention and those specifically described below (e.g., in the examples) may be combined with each other to form new or preferred embodiments. For reasons of space, they will not be described in detail.

Detailed Description

The invention obtains a low interface heat-gaining building energy-saving coating and a preparation method thereof through extensive and intensive research, and the preparation method comprises the steps of selecting low interface heat-gaining ore to prepare heat-insulating slurry, and further preparing the low interface heat-gaining building energy-saving coating, wherein the coating has an obvious energy-saving effect, the emissivity can reach 0.96, the heat-insulating temperature difference can reach 1.6 ℃, the energy-saving performance in summer is more than 10%, and the energy-saving performance in winter can also reach 7%.

The invention is further illustrated by the following examples, which are not intended to limit the scope of the invention. The experimental methods without specifying specific conditions in the following examples were selected according to the conventional methods and conditions, or according to the commercial instructions.

Description of the raw materials

The raw materials such as ores and carriers (including film-forming substances, titanium dioxide, fillers and auxiliaries) acceptable for various coatings are all sold in the ordinary market, and the commercially available sources of the following raw materials include but are not limited to: cordierite, monazite, phosphogypsum, manganese ore and the like on 1688 website; silica aerogel wetstock, love petasites and new materials; acrylic emulsion, commonly new materials; rutile type titanium dioxide, boa herboria; barium sulfate, riches trade in shanxi; kaolin, Shanxi Jinyucline technology; bentonite, a new material of Zhejiang Huate; alcohol ester twelve, eastman; dispersant D-28, which is a new material in general; thickener A-016, which is a new material.

Example 1

4kg of ore (prepared by uniformly mixing 30% of cordierite, 30% of monazite, 20% of phosphogypsum and 20% of manganese ore, calcining for 6h at 400 ℃, and ball-milling for 8 h) is added with 0.75kg of water and 0.25kg of silicon dioxide aerogel wet material, and the mixture is uniformly mixed to prepare the heat insulation slurry.

4kg of the prepared heat insulation slurry is added with 2kg of acrylic emulsion, 1kg of rutile type titanium dioxide, 1kg of barium sulfate, 0.4kg of kaolin, 0.1kg of bentonite, 0.3kg of alcohol ester dodeca, 0.1kg of dispersing agent D-28, 0.1kg of thickening agent A-016 and 1kg of water to be dispersed at high speed to prepare the energy-saving coating.

Example 2

4kg of ore (prepared by uniformly mixing 30% of cordierite, 30% of monazite, 20% of phosphogypsum and 20% of manganese ore, calcining for 6h at 450 ℃ and carrying out ball milling for 8 h) is added with 0.75kg of water and 0.25kg of silicon dioxide aerogel wet material and uniformly mixed to prepare the heat insulation slurry.

4kg of the prepared heat insulation slurry is added with 2kg of acrylic emulsion, 1.5kg of rutile type titanium dioxide, 0.5kg of barium sulfate, 0.4kg of kaolin, 0.1kg of bentonite, 0.3kg of alcohol ester dodeca, 0.1kg of dispersing agent D-28, 0.1kg of thickening agent A-016 and 1kg of water to be dispersed at high speed to prepare the energy-saving coating.

Example 3

4kg of ore (cordierite, prepared by calcining at 400 ℃ for 6h and ball milling for 8 h) is taken, 0.75kg of water and 0.25kg of silica aerogel wet material are added and mixed uniformly to prepare the heat insulation slurry.

4kg of the prepared heat insulation slurry is added with 2kg of acrylic emulsion, 1kg of rutile type titanium dioxide, 1kg of barium sulfate, 0.4kg of kaolin, 0.1kg of bentonite, 0.3kg of alcohol ester dodeca, 0.1kg of dispersing agent D-28, 0.1kg of thickening agent A-016 and 1kg of water to be dispersed at high speed to prepare the energy-saving coating.

Example 4

4kg of ore (monazite, prepared by calcining at 400 ℃ for 6h and ball milling for 8 h) is taken, 0.75kg of water and 0.25kg of silicon dioxide aerogel wet material are added, and the mixture is uniformly mixed to prepare the heat insulation slurry.

4kg of the prepared heat insulation slurry is added with 2kg of acrylic emulsion, 1kg of rutile type titanium dioxide, 1kg of barium sulfate, 0.4kg of kaolin, 0.1kg of bentonite, 0.3kg of alcohol ester dodeca, 0.1kg of dispersing agent D-28, 0.1kg of thickening agent A-016 and 1kg of water to prepare the energy-saving coating through high-speed dispersion.

Example 5

4kg of ore (ardealite, prepared by calcining at 400 ℃ for 6h and ball milling for 8 h) is taken, 0.75kg of water and 0.25kg of silicon dioxide aerogel wet material are added and mixed uniformly to prepare the heat insulation slurry.

4kg of the prepared heat insulation slurry is added with 2kg of acrylic emulsion, 1kg of rutile type titanium dioxide, 1kg of barium sulfate, 0.4kg of kaolin, 0.1kg of bentonite, 0.3kg of alcohol ester dodeca, 0.1kg of dispersing agent D-28, 0.1kg of thickening agent A-016 and 1kg of water to be dispersed at high speed to prepare the energy-saving coating.

Example 6

4kg of ore (manganese ore prepared by calcining at 400 ℃ for 6h and ball milling for 8 h) is taken, 0.75kg of water and 0.25kg of silicon dioxide aerogel wet material are added, and the mixture is uniformly mixed to prepare the heat insulation slurry.

4kg of the prepared heat insulation slurry is added with 2kg of external wall acrylic emulsion, 1kg of rutile type titanium dioxide, 1kg of barium sulfate, 0.4kg of kaolin, 0.1kg of bentonite, 0.3kg of alcohol ester dodeca, 0.1kg of dispersant D-28, 0.1kg of thickener A-016 and 1kg of water to be dispersed at high speed to prepare the energy-saving coating.

The following examples are directed to cordierite-based coating formulations for comparison, wherein the thermal insulating slurries are the same as those of example 3. Similar research results of replacing monazite, phosphogypsum or manganese ore with the similar research results are the same, and are not repeated.

Comparative example 1

The coating is prepared according to the embodiment of the Chinese invention patent application CN108117812A, the coating is tested according to GB/T4653-1984, the emissivity is 0.84, the coating is tested according to T/CIE082-2020, no obvious heat insulation temperature difference exists, the coating is tested according to T/CSTM 00291-2021, the energy is saved by 5% in summer, and the negative energy consumption is 2% in winter.

Comparative example 2

4kg of kaolin (prepared by calcining at 400 ℃ for 6h and ball milling for 8 h) is added with 0.75kg of water and 0.25kg of silica aerogel wet material and evenly mixed to prepare the heat insulation slurry.

4kg of the prepared heat insulation slurry is added with 2kg of external wall acrylic emulsion, 1kg of rutile type titanium dioxide, 1kg of barium sulfate, 0.4kg of kaolin, 0.1kg of bentonite, 0.3kg of alcohol ester dodeca, 0.1kg of dispersant D-28, 0.1kg of thickener A-016 and 1kg of water to prepare the coating through high-speed dispersion.

The paint can reach the excellent quality performance of the paint through GB/T9755-2014 tests, and meanwhile, the paint passes GB/T4653-1984 tests, and the emissivity is 0.8; no significant insulating temperature difference is detected by the T/CIE082-2020 test.

Comparative example 3

A coating was prepared according to CN113201256, example 1, the coating having an emissivity of 0.74 as measured by GB/T4653-1984 and no significant insulating temperature difference as measured by T/CIE 082-2020.

Comparative example 4

A coating was prepared as in example 3, but the cordierite was not calcined at high temperature and the coating had an emissivity of 0.80 as measured by GB/T4653-1984 and an insulating temperature differential of 0.6 ℃ as measured by T/CIE 082-2020.

Before the present invention is described, it is to be understood that this invention is not limited to the particular methodology and experimental conditions described, as such methodologies and conditions may vary. It is also to be understood that the terminology used herein is for the purpose of describing particular embodiments only, and is not intended to be limiting, since the scope of the present invention will be limited only by the appended claims.

The following will describe the relevant performance test cases of the coating material of the present invention to illustrate the practical effects of the present invention, but the present invention is not limited to the following examples.

The test method comprises the following steps:

(1) the interface heat gain is an important index for evaluating the energy-saving effect, wherein the emissivity is tested by GB/T4653-1984, the method 'Universal technical Condition of Infrared radiation paint' is one of the national standards for coating infrared testing and is mainly used for measuring the infrared emissivity of a coating, the testing method of the thermal insulation temperature difference is T/CIE082-2020, the method 'Heat preservation and insulation paint thermal insulation temperature difference detection method' is used for testing the thermal insulation temperature difference (non-visible light is used as a heat source) of the radiation paint relative to the common paint, and the material with the emissivity larger than 0.85 and the thermal insulation temperature difference larger than 0.8 ℃ is generally defined as low interface heat gain.

(2) The coating energy-saving effect is measured according to T/CSTM 00291-2021 building thermal insulation coating energy-saving evaluation method, the method is used for comparing the relative energy-saving effect of the test material under different environments, the larger the emissivity and the thermal insulation temperature difference are, the lower the interface heat gain is, and the better the energy-saving effect is.

(3) The general performance test standards of the coating refer to GB/T9755-2014 and GB/T9756-2018, GB/T9755-2014 synthetic resin emulsion exterior wall coating and GB/T9756-2018 synthetic resin emulsion interior wall coating, and are basic test standards of the coating for the interior and exterior walls of the building.

And (4) analyzing results:

examples 1 to 6 all achieve the object of the present invention, solve the technical problems, and achieve the technical effects, wherein examples 1 and 2 show that the energy saving effect of the combined use of four kinds of ores is significant, the energy saving in summer is more than 10%, and the energy saving in winter can also reach 7%. Examples 3-6 show that the single use of four kinds of ores also has a good energy-saving effect, the interface of the prepared coating has low heat gain, the emissivity is more than 0.85, the heat insulation temperature difference is more than 0.8 ℃, and the energy is saved by 7% in summer.

Examples 7-11 show that too high a mineral content, preferably in the range of 20% to 40% based on the finished coating, results in a reduction in the properties of the coating.

Comparative example 1 illustrates that the prior art thermal barrier coating is not an architectural energy saving coating with low interfacial heat gain properties

Comparative example 2 illustrates that ores such as kaolin do not have low interfacial heat gain properties.

The emissivity of the coating of comparative example 3 is 0.74 and no significant thermal insulation temperature difference exists, which indicates that cordierite is not found to have the performance of low interface heat gain, and the cordierite is not suggested to be used for preparing the low interface heat gain building energy-saving coating.

All documents referred to herein are incorporated by reference into this application as if each were individually incorporated by reference. Furthermore, it should be understood that various changes and modifications of the present invention can be made by those skilled in the art after reading the above teachings of the present invention, and these equivalents also fall within the scope of the present invention as defined by the appended claims.

Claims (10)

1. The heat insulation slurry for the building energy-saving coating is characterized by comprising the following components in parts by weight:

70-90 parts of cordierite

3-10 parts of silica aerogel wet material

5-25 parts of water

Based on the weight of the insulation slurry.

2. The insulation paste of claim 1, wherein the insulation paste comprises the following components in parts by weight:

80 parts of cordierite

5 parts of silica aerogel wet material

15 portions of water

Based on the weight of the insulation slurry.

3. The method of preparing a thermal insulating paste according to claim 1, comprising the steps of:

calcining cordierite at high temperature, and performing ball milling to obtain powder;

and uniformly mixing the powder, the silica aerogel wet material and water according to a proportion to prepare the heat insulation slurry.

4. The method of claim 3, comprising the steps of: calcining cordierite at the temperature of 300-500 ℃ for 5-8h, and ball-milling for 8-10h to obtain powder.

5. The building energy-saving coating with low interface heat gain is characterized by comprising the following components in parts by weight:

based on the weight of the building energy-saving coating,

the film-forming material is selected from the group consisting of: an acrylic emulsion, an aqueous polyurethane dispersion, or a combination thereof,

the titanium dioxide is selected from the following groups: rutile titanium dioxide, anatase titanium dioxide, or a combination thereof,

the filler is selected from the group consisting of: barium sulfate, kaolin, bentonite, calcium carbonate, or combinations thereof,

the auxiliary agent is selected from the following group: a film forming aid, a dispersant, a thickener, or a combination thereof.

6. The building energy saving paint of claim 5,

the film forming material is acrylic emulsion;

the titanium dioxide is rutile titanium dioxide;

the filler is barium sulfate, kaolin and bentonite;

the auxiliary agent comprises a film-forming auxiliary agent alcohol ester twelve, a dispersant D-28 and a thickening agent A-016.

7. The building energy-saving coating as claimed in claim 5, characterized by comprising the following components in parts by weight:

based on the weight of the building energy-saving coating.

8. The preparation method of the building energy-saving coating as claimed in claim 5, characterized by comprising the following steps: mixing the components in proportion, and dispersing at high speed.

9. The cordierite is applied to the preparation of the heat insulation slurry of the low interface heat-gaining building energy-saving coating.

10. The application of cordierite in preparing low interface heat-gaining building energy-saving coating.