CN107418264B - Fullerene negative ion dry powder coating and use method thereof - Google Patents

Abstract

The invention belongs to the technical field of dry powder coatings, and relates to a fullerene negative ion dry powder coating and a using method thereof. The invention comprises the following components in parts by mass: 50-60 parts of base material, 0.01-0.5 part of nano fullerene and/or nano fullerene derivative, 25-35 parts of mineral powder additive, 1-2 parts of binder, 1-2 parts of thixotropic agent and 1-2 parts of dispersing agent. The invention has the effects of releasing negative ions and inhibiting bacteria.

Description

Fullerene negative ion dry powder coating and use method thereof

Technical Field

The invention belongs to the technical field of dry powder coatings, and relates to a fullerene negative ion dry powder coating and a using method thereof.

Background

With the pursuit of human beings for happy life, the research and development of technological progress is promoted. Tracing back to the age of the neolithic apparatus, people have begun to understand the use of plant mucilage glue until the development of the chemical industry enters the wide application stage of the artificial chemical synthetic resin. However, most of the synthetic materials can generate harmful substances such as formaldehyde, benzene series and the like, and particularly in living rooms and passenger cars, the peculiar smell of formaldehyde, benzene, xylene and the like is absorbed by the respiratory tract of human bodies to cause the occurrence of leukemia, cancer, skin allergy and the like. Therefore, people hope to come out of low-carbon non-toxic ecological paint.

In Japan abroad as early as ninety years in the last century, green paint is applied in a large quantity; however, these green paints are still largely synthesized from high molecular resin paints.

The main material of the dry powder latex paint is artificially synthesized resin paint; the main material of the general-concept dry powder coating also contains synthetic chemical resin, however, compared with the dry powder coating taking synthetic chemical products as the main material, such as diatom ooze dry powder coating, shell powder coating, lime coating and the like, the dry powder coating has the improvement.

Disclosure of Invention

The invention aims to solve the problems and provides a fullerene negative ion dry powder coating.

The invention also aims to provide a using method of the fullerene negative ion dry powder coating.

In order to achieve the purpose, the invention adopts the following technical scheme:

a fullerene negative ion dry powder coating comprises the following components in parts by mass:

50-60 parts of a base material,

0.01-0.5 parts of nano fullerene and/or nano fullerene derivative,

25-35 parts of mineral powder additive.

The fullerene negative ion dry powder coating also comprises the following components in parts by mass,

1-2 parts of a binder,

1-2 parts of a thixotropic agent,

1-2 parts of a dispersing agent,

the base material is nano shell powder, the nano fullerene derivative is fullerol, the binder is plant glue powder, the thixotropic agent is hydrogenated castor oil, the dispersing agent is a nano resin dispersing agent, and the mineral powder additive comprises black tourmaline powder and titanium dioxide phosphate.

A fullerene negative ion dry powder coating comprises the following components in parts by mass:

a fullerene negative ion dry powder coating comprises the following components in parts by mass:

a fullerene negative ion dry powder coating comprises the following components in parts by mass:

a fullerene negative ion dry powder coating comprises the following components in parts by mass:

the fullerene negative ion dry powder coating also comprises the following components in parts by mass,

1-2 parts of a binder,

1-2 parts of a thixotropic agent,

1-2 parts of a dispersing agent,

the binder is vegetable rubber powder, the thixotropic agent is hydrogenated labyrinth oil, and the dispersant is a nano resin dispersant.

A method for using a fullerene negative ion dry powder coating comprises the following steps:

A. calculating the wall area according to 3-3.5 times of the room area, calculating the amount of the dry powder coating according to the thickness of the dry powder coating on the painting operation surface of 1.5-2mm, weighing the required amount of the dry powder coating,

B. mixing the dry powder coating and deionized water according to the mass ratio of 70-80:20-30, fully and uniformly stirring until no particles can be seen by naked eyes to obtain the water-based coating,

C. and (4) performing brushing or spraying operation on the operation surface until the paint completely covers the operation surface.

In the using method of the fullerene negative ion dry powder coating, in the step C, a small-area brushing or spraying test is firstly carried out, and after the test is qualified, a large-area brushing or spraying is carried out.

In the using method of the fullerene negative ion dry powder coating, in the step C, brushing or spraying operation is carried out twice, and after the first brushing or spraying operation is finished and the wall surface is basically dried, the second brushing or spraying operation is carried out.

The invention is derived from inheritance of traditional lime coating, and based on the development of modern nanotechnology, the deep sea special natural shell is selected to form white nano-scale shell powder after being calcined, ground and sieved, and the white nano-scale shell powder is used as a base material of the dry powder coating. Secondly, the key point of the invention is that water-soluble fullerene (hydroxylated fullerene-fullerene alcohol) and nano-scale tourmaline powder are mixed and chemically reacted to release high-concentration negative oxygen ions.

Compared with the prior art, the invention has the advantages that:

1. the self-body is a natural material and does not contain toxic and harmful substances;

2. the combination of fullerene (or fullerol) and tourmaline can release high-concentration and strong-activity small-particle-size negative oxygen ions;

3. the composition has the advantages of powerfully killing virus and germs suspended in indoor air;

4. the construction of the wall surface is convenient to operate, and odor such as formaldehyde, benzene series, ammonia, sulfur compounds and the like can be permanently eliminated when the wall is painted;

5. constantly releases air vitamin, namely negative oxygen ions, with the concentration of 1000-;

6. good painting effect, no powder falling, no bubbling, no trace left in repairing, no dust sticking, no mildew, acid resistance, alkali resistance and water resistance.

Detailed Description

The reagents used in the following examples, unless otherwise specified, were purchased from conventional biochemical reagent stores.

Example 1

A fullerene negative ion dry powder coating comprises the following components: 50kg of nano shell powder, 0.01kg of fullerene, 0.1kg of fullerol, 12kg of black tourmaline powder and 13kg of phosphoric acid titanium dioxide, and the components are uniformly mixed to obtain the fullerene negative ion dry powder coating.

Example 2

A fullerene negative ion dry powder coating comprises the following components: 60kg of nano shell powder, 0.5kg of fullerol, 17kg of black tourmaline powder and 18kg of titanium dioxide phosphate, and the fullerene negative ion dry powder coating is obtained after the components are uniformly mixed.

Example 3

A fullerene negative ion dry powder coating comprises the following components: 55kg of nano shell powder, 0.01kg of fullerene, 15kg of black tourmaline powder and 14kg of titanium dioxide phosphate, and the components are uniformly mixed to obtain the fullerene negative ion dry powder coating.

Example 4

A fullerene negative ion dry powder coating comprises the following components: 55kg of nano shell powder, 0.01kg of fullerene, 15kg of black tourmaline powder, 14kg of titanium dioxide phosphate, 1kg of plant rubber powder, 1kg of hydrogenated castor oil and 1kg of nano resin dispersant, and the components are uniformly mixed to obtain the fullerene negative ion dry powder coating.

The plant gum powder comprises one or more of sesbania gum, guar gum, flax gum and fenugreek gum, and is ground into powder of 100-300 nanometers by a nanometer grinding machine. The vegetable gum powder of this example is guar gum. The nano resin dispersant of the embodiment is alkyl aryl polyether.

Example 5

A fullerene negative ion dry powder coating comprises the following components: 60kg of nano shell powder, 0.5kg of fullerol, 17kg of black tourmaline powder, 18kg of titanium dioxide phosphate, 2kg of plant rubber powder, 2kg of hydrogenated castor oil and 2kg of nano resin dispersant, and the components are uniformly mixed to obtain the fullerene negative ion dry powder coating.

The plant glue powder is flax glue and is ground into powder of 100-300 nm by a nano grinder. The nano resin dispersant of the present embodiment is polyacrylamide.

Example 6

A fullerene negative ion dry powder coating comprises the following components: 60kg of nano shell powder, 0.5kg of fullerol, 17kg of black tourmaline powder, 18kg of titanium dioxide phosphate, 2kg of plant rubber powder, 2kg of hydrogenated castor oil and 2kg of nano resin dispersant, and after the components are uniformly mixed, a nano grinder is used for grinding to obtain the fullerene negative ion dry powder coating.

The plant gum powder is a mixture of sesbania gum and fenugreek gum, and is mixed according to the weight ratio of 1:1, and is ground into powder of 100-300 nanometers by a nanometer grinding machine. The nano resin dispersant of this example is a high molecular weight alkyl ammonium salt copolymer.

Example 7

60kg of nano shell powder, 0.01kg of fullerol, 2kg of titanium dioxide phosphate, 12.5kg of shale opal powder, 1.5kg of zeolite powder, 1kg of guar gum, 2kg of hydrogenated castor oil and 1kg of polyacrylamide are put into a stirrer to be uniformly stirred, so as to obtain the fullerene negative ion dry powder coating.

Example 8

60kg of nano shell powder, 0.01kg of fullerol, 5kg of titanium dioxide phosphate, 10kg of shale powder, 2kg of zeolite powder, 2kg of guar gum, 1kg of hydrogenated castor oil and 2002kg of polyethylene glycol are put into a stirrer to be uniformly stirred, so as to obtain the fullerene negative ion dry powder coating.

Example 9

60kg of nano shell powder, 0.01kg of fullerol, 3kg of titanium dioxide phosphate, 10kg of shale powder, 2kg of zeolite powder, 1.4kg of guar gum, 1.2kg of hydrogenated castor oil and 4001.5 kg of polyethylene glycol are put into a stirrer to be uniformly stirred, so as to obtain the fullerene negative ion dry powder coating.

Example 10

60kg of nano shell powder, 0.01kg of fullerol, 2kg of titanium dioxide phosphate, 12.5kg of shale opal powder, 10kg of zeolite powder, 10kg of attapulgite powder and 10kg of black tourmaline powder are accurately weighed and put in a stirrer to be uniformly mixed, so as to obtain the fullerene negative ion dry powder coating.

Example 11

60kg of nano shell powder, 0.01-0.5kg of fullerol, 5kg of titanium dioxide phosphate, 10kg of shale protein powder, 10kg of zeolite powder, 5kg of attapulgite powder and 10kg of black tourmaline powder are accurately weighed and put into a stirrer to be uniformly mixed, so as to obtain the fullerene negative ion dry powder coating.

Example 12

The preparation method comprises the steps of accurately weighing 60kg of nano shell powder, 0.05kg of fullerol, 3kg of titanium dioxide phosphate, 11kg of shale powder, 10kg of zeolite powder, 8kg of attapulgite powder, 10kg of black tourmaline powder, 2kg of flax gum, 1kg of hydrogenated castor oil and 2002kg of polyethylene glycol, and uniformly mixing the materials in a stirrer to obtain the fullerene negative ion dry powder coating.

Example 13

The preparation method comprises the steps of accurately weighing 60kg of nano shell powder, 0.05kg of fullerol, 3kg of titanium dioxide phosphate, 12kg of shale powder, 10kg of zeolite powder, 7kg of attapulgite powder, 10kg of black tourmaline powder, 1kg of flax gum, 2kg of hydrogenated castor oil and 2001kg of polyethylene glycol, and uniformly mixing in a stirrer to obtain the fullerene negative ion dry powder coating.

Example 14

The preparation method comprises the steps of accurately weighing 60kg of nano shell powder, 0.1kg of fullerol, 2kg of titanium dioxide phosphate, 3kg of monazite powder, 20kg of hexacyclic ring stone powder, 8kg of attapulgite powder, 1kg of flaxseed gum, 2kg of hydrogenated castor oil and 1kg of polyethylene wax, and uniformly mixing in a stirrer to obtain the fullerene negative ion dry powder coating.

Example 15

The preparation method comprises the steps of accurately weighing 60kg of nano shell powder, 0.1kg of fullerol, 3kg of titanium dioxide phosphate, 1kg of monazite powder, 25kg of hexacyclic ring stone powder, 5kg of attapulgite powder, 2kg of flaxseed gum, 1kg of hydrogenated castor oil and 2kg of polyacrylamide, and uniformly mixing in a stirrer to obtain the fullerene negative ion dry powder coating.

Example 16

60kg of nano shell powder, 0.1kg of fullerol, 2.4kg of titanium dioxide phosphate, 2kg of monazite powder, 22kg of hexacyclic ring stone powder, 6kg of attapulgite powder, 1.2kg of flaxseed gum, 1.5kg of hydrogenated castor oil and 2001.4 kg of polyethylene glycol are accurately weighed and put into a stirrer to be uniformly mixed, so as to obtain the fullerene negative ion dry powder coating.

Example 17

60kg of nano shell powder, 0.1kg of fullerol, 20kg of hexacyclic ring stone powder, 10kg of montmorillonite powder, 1kg of diatomite, 2.5kg of muscovite powder, 1kg of guar gum, 2kg of hydrogenated castor oil and 1kg of polyethylene wax are accurately weighed and put in a stirrer to be uniformly mixed, so as to obtain the fullerene negative ion dry powder coating.

Example 18

60kg of nano shell powder, 0.1kg of fullerol, 20-25kg of hexacyclic ring stone powder, 5kg of montmorillonite powder, 3kg of diatomite, 1kg of muscovite powder, 1.8kg of guar gum, 1.4kg of hydrogenated castor oil and 2001.3 kg of polyethylene glycol are accurately weighed and placed in a stirrer to be uniformly mixed, so as to obtain the fullerene negative ion dry powder coating.

Example 19

60kg of nano shell powder, 0.1kg of fullerol, 23kg of hexacyclic ring stone powder, 7.5kg of montmorillonite powder, 2.5kg of diatomite, 2.2kg of muscovite powder, 2kg of guar gum, 1kg of hydrogenated castor oil and 2kg of polyethylene glycol 4002 kg are accurately weighed and placed in a stirrer to be uniformly mixed, so as to obtain the fullerene negative ion dry powder coating.

Example 20

The application method of the fullerene negative ion dry powder coating comprises the following steps:

A. calculating the wall area according to 3-3.5 times of the room area, calculating the amount of the dry powder coating according to the thickness of the dry powder coating on the painting operation surface of 1.5-2mm, weighing the required amount of the dry powder coating,

B. mixing the dry powder coating and deionized water according to the mass ratio of 70-80:20-30, fully and uniformly stirring until no particles can be seen by naked eyes to obtain the water-based coating,

C. and (4) performing brushing or spraying operation on the operation surface until the paint completely covers the operation surface.

Preferably, in the step C, a small-area brushing or spraying test is firstly carried out, and after the test is qualified, a large-area brushing or spraying is carried out.

More preferably, in step C, the painting or spraying operation is performed twice, and after the first painting or spraying operation is completed, the second painting or spraying operation is performed after the wall surface is substantially dry.

Application example 1

The dry powder coating of example 12 was taken and had a bulk density of 2.8g/cm³Selecting a public toilet as a construction site, wherein the area of the public toilet is 120m2, the painting area is 360m2, the paint thickness is 1.5mm, 1512kg of dry powder paint is needed, and the paint weight is as follows: weighing 1512kg of dry powder coating and 432kg of deionized water according to the proportion of 70:20, adding water into the dry powder coating, fully stirring until no particles are visible to naked eyes to obtain water-based dry powder coating, painting the wall surface by using a roller, and painting for the second time after the first time is dried.

After the wall surface is completely dried, the releasing amount of negative ions is detected by a negative ion detector, and the detection result is 2110 per cubic centimeter second. The viscosity of the water paint is Ku80, the brushing resistance is more than 5000 times, and the alkali resistance is not abnormal within 96 hours.

And (4) when the wall surface is dried for 48 hours, carrying out bacteriostasis detection on the wall surface, wherein the test strains comprise staphylococcus aureus, bacillus subtilis and escherichia coli. The culture medium is beef extract peptone culture medium. Colonies were counted by plate dilution and spreading, and the results were shown in the bacteriostatic test table.

Application example 2

The dry powder coating of example 12 was taken and had a bulk density of 2.8g/cm³Selecting a public toilet as a construction site, wherein the area of the public toilet is 120m²The painting area is 360m²1512kg of dry powder coating is required, calculated as coating thickness of 1.5mm, based on dry powder coating: weighing 1512kg of dry powder coating and 378kg of deionized water according to the proportion of 80:20, fully stirring until no visible particles exist to obtain the water-based dry powder coating, and spraying the water-based dry powder coating on the wall surface by using a spray gun until the coating completely covers the wall surface. After the wall surface is completely dried, the release amount of negative ions is detected by a negative ion detector, and the detection result is 1730 per cubic centimeter second. The viscosity of the water paint is Ku80, the brushing resistance is more than 5000 times, and the alkali resistance is not abnormal within 96 hours.

And (4) when the wall surface is dried for 48 hours, carrying out bacteriostasis detection on the wall surface, wherein the test strains comprise staphylococcus aureus, bacillus subtilis and escherichia coli. The culture medium is beef extract peptone culture medium. Colonies were counted by plate dilution and spreading, and the results were shown in the bacteriostatic test table.

Application example 3

The dry powder coating of example 14 was taken and had a bulk density of 2.75g/cm³Selecting a kindergarten as a construction site, setting the wall area according to 3.5 times of the indoor area of the kindergarten as 1350m2, calculating the using amount of the coating according to the thickness of the coating layer as 2mm, and probably needing 25987.5kg of dry powder coating according to the dry powder coating: weighing 25987.5kg of dry powder and 11137.5kg of deionized water according to the proportion of 70:30, stirring uniformly in batches to obtain the water-based fullerene negative ion coating, wherein the viscosity of the water-based fullerene negative ion coating is Ku80, the brushing resistance is more than 5000 times, the alkali resistance is no abnormality after 96 hours, coating a wall surface with a roller, fully drying, and measuring the release amount of negative ions, wherein the detection result is 2100 per cubic centimeter second.

And (4) when the wall surface is dried for 48 hours, carrying out bacteriostasis detection on the wall surface, wherein the test strains comprise staphylococcus aureus, bacillus subtilis and escherichia coli. The culture medium is beef extract peptone culture medium. Colonies were counted by plate dilution and spreading, and the results were shown in the bacteriostatic test table.

Application example 4

The dry powder coating of example 13 was taken and had a bulk density of 2.7g/cm³Selecting a kindergarten as a construction site, setting the wall area according to 3.5 times of indoor area, calculating the coating using amount according to the coating thickness of 1.6mm, and probably requiring 20412kg of dry powder coating according to the dry powder coating: weighing 20412kg of dry powder coating and 7654.5kg of deionized water according to a grey water ratio fixed by 80:30, mixing the materials in batches, stirring uniformly, wherein no visible particles are water-based coating, the viscosity Ku80 of the water-based coating is more than 5000 times of brushing resistance, alkali resistance is no abnormality in 96 hours, spraying the wall surface by using a spray gun spraying method, after the first spraying, spraying the second spraying after the first spraying is basically dried, carefully checking the missing places when the second spraying is carried out, if the missing places exist, replenishing the spraying in time, after the second spraying is finished, after the wall surface is completely dried, detecting the release amount of the negative ions by using a negative ion detector to be 2320 per cubic centimeter second.

And (4) when the wall surface is dried for 48 hours, carrying out bacteriostasis detection on the wall surface, wherein the test strains comprise staphylococcus aureus, bacillus subtilis and escherichia coli. The culture medium is beef extract peptone culture medium. Colonies were counted by plate dilution and spreading, and the results were shown in the bacteriostatic test table.

Application example 5

The dry powder coating obtained in example 17 was taken and had a bulk density of 2.8g/cm³The paint is used for painting the kitchen. Kitchen area is 15m2, sets up the area of brushing with a brush according to 3 times kitchen area, and the dope layer thickness is set up to 1.5mm, needs 189kg of dry powder, with dry powder coating: weighing 189kg of dry powder coating and 63kg of deionized water accurately, putting the dry powder coating and the deionized water into a stirrer for fully stirring, uniformly mixing the dry powder coating and the deionized water until no visible particles exist, sieving the mixture by a 100-mesh sieve to remove particle impurities,the water-based paint is obtained, the viscosity of the water-based paint is Ku80, the brushing resistance is more than 5000 times, the alkali resistance is not abnormal for 96 hours, the deodorization rate is 95 percent, the sterilization rate is 99 percent, and the formaldehyde-removing benzene is 100 percent.

And (3) coating the wall surface by using a roller until the wall surface is completely coated, drying for 48 hours, and detecting the release amount of negative ions by using a negative ion detector to obtain the release amount of the negative ions of 1960 per cubic centimeter second.

And (4) when the wall surface is dried for 48 hours, carrying out bacteriostasis detection on the wall surface, wherein the test strains comprise staphylococcus aureus, bacillus subtilis and escherichia coli. The culture medium is beef extract peptone culture medium. Colonies were counted by plate dilution and spreading, and the results were shown in the bacteriostatic test table.

Comparative examples 1 to 5

And (3) selecting the places of application examples 1-5, and carrying out bacteriostatic detection before coating the dry powder coating, wherein the test strains are staphylococcus aureus, bacillus subtilis and escherichia coli. The culture medium is beef extract peptone culture medium. Colonies were counted by plate dilution plating.

And (6) analyzing results.

Bacteriostatic property test table

The results show that the application examples 1-5 have obvious inhibition effect on staphylococcus aureus, bacillus subtilis and escherichia coli, and the effect is obvious. The bacteriostasis rate is as high as 99% and above.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the spirit or ambit of the invention as defined in the appended claims.

Claims (6)

1. The fullerol negative ion dry powder coating is characterized by comprising the following components in parts by mass:

60 parts of nano shell powder, namely shell powder,

0.01-0.5 parts of fullerol,

2-5 parts of titanium dioxide phosphate,

10 to 12.5 portions of shale protein powder,

10 parts of zeolite powder, namely 10 parts of zeolite powder,

5-10 parts of attapulgite powder,

10 parts of black tourmaline powder, namely 10 parts of black tourmaline powder,

1-2 parts of a binder,

1-2 parts of a thixotropic agent,

1-2 parts of a dispersing agent,

the adhesive is vegetable rubber powder, the thixotropic agent is hydrogenated castor oil, and the dispersing agent is a nano resin dispersing agent.

2. The fullerol negative ion dry powder coating is characterized by comprising the following components in parts by mass:

60 parts of nano shell powder, namely shell powder,

0.1 part of fullerol, namely 0.1 part of fullerol,

2-3 parts of titanium dioxide phosphate,

1-3 parts of monazite powder,

20-25 parts of hexacyclic ring stone powder,

5-8 parts of attapulgite powder,

1-2 parts of a binder,

1-2 parts of a thixotropic agent,

1-2 parts of a dispersing agent,

the adhesive is vegetable rubber powder, the thixotropic agent is hydrogenated castor oil, and the dispersing agent is a nano resin dispersing agent.

3. The fullerol negative ion dry powder coating is characterized by comprising the following components in parts by mass:

60 parts of nano shell powder, namely shell powder,

0.1 part of fullerol, namely 0.1 part of fullerol,

20-25 parts of hexacyclic ring stone powder,

5-10 parts of montmorillonite powder,

1-3 parts of diatomite,

1 to 2.5 parts of white mica powder,

1-2 parts of a binder,

1-2 parts of a thixotropic agent,

1-2 parts of a dispersing agent,

the adhesive is vegetable rubber powder, the thixotropic agent is hydrogenated castor oil, and the dispersing agent is a nano resin dispersing agent.

4. A method of using a fullerol anion dry powder coating according to any one of claims 1-3, comprising the steps of:

A. calculating the wall area according to 3-3.5 times of the room area, calculating the amount of the dry powder coating according to the thickness of the dry powder coating on the painting operation surface of 1.5-2mm, weighing the required amount of the dry powder coating,

B. mixing the dry powder coating and deionized water according to the mass ratio of 70-80:20-30, fully and uniformly stirring until no particles can be seen by naked eyes to obtain the water-based coating,

C. and (4) performing brushing or spraying operation on the operation surface until the paint completely covers the operation surface.

5. A method for using fullerol anion dry powder paint as claimed in claim 4, wherein in step C, a small area brushing or spraying test is firstly carried out, and after the test is passed, a large area brushing or spraying is carried out.

6. A method for using the Fullerol negative ion dry powder paint as claimed in claim 4, wherein in step C, the painting or spraying operation is performed twice, and after the first painting or spraying operation is completed and the wall surface is dried, the painting or spraying operation is performed for the second time.