KR102103403B1 - Method for treating a surface of daily supplies - Google Patents

Abstract

The disclosed content relates to a surface treatment method of household goods such as medical devices, textile products, food products, household appliances, etc. More specifically, an antibacterial coating film forming step of forming an antibacterial coating film by vacuum-depositing a silane compound on the surface of the household goods, Through the antibacterial coating film forming step, a mineral deposition film forming step of depositing mineral ions on the surface of a household product on which an antibacterial coating film is formed, and a far infrared ray irradiating far-infrared rays emitted from rare earth powder to the household product on which the mineral deposition film is formed through the mineral deposition film forming step It consists of an investigation phase.
The surface treatment method made through the above process provides not only the surface of a household product, but also a sterilization process to the inside, showing excellent antibacterial properties, and emitting far infrared rays and anions to provide a household product that can maintain the freshness of food ingredients for a long time. .

Description

Surface treatment method of household goods {METHOD FOR TREATING A SURFACE OF DAILY SUPPLIES}

The disclosed content relates to a surface treatment method of household goods, and more specifically, not only the surfaces of household goods such as medical devices, textile products, food products, household appliances, etc., but also has excellent sterilization process to the inside to show excellent antibacterial properties and far infrared rays and anions. It relates to a surface treatment method of household goods that provide household goods that can maintain freshness of food materials and the like for a long period of time by emitting light.

Household products such as medical devices, textile products, food products, household appliances, etc. are required to have antimicrobial properties, and textile products used to manufacture containers or clothing containing food materials, such as food materials, can provide various functions through far-infrared radiation. .

Conventionally, efforts have been made to meet the above objectives by forming a film made of a method such as antibacterial coating on the surface of a household product or a mineral that emits far infrared rays.

However, the above methods simply form a film on the surface of the household goods, and there is a problem that it is difficult to fundamentally block bacteria and the like that grow inside the household goods.

Korean Patent Publication No. 10-2001-0100282 (2001.11.14) Korean Patent Publication No. 10-2004-0102659 (2004.12.08)

Disclosed is a surface treatment method of a household product that is provided with a household product that can maintain not only the surface of the household product, but also the interior, and has excellent antimicrobial properties and emits far-infrared rays and negative ions to maintain the freshness of food materials for a long period of time. Is to provide

As one embodiment, the contents of this disclosure are an antimicrobial coating film forming step of forming an antibacterial coating film by vacuum-depositing a silane compound on the surface of a household product, and mineral ions on the surface of a household product having an antibacterial coating film formed through the antibacterial coating film forming step. Describes a surface treatment method of a household product characterized by comprising a far-infrared irradiation step of irradiating a far-infrared light emitted from a rare earth powder to the mineral deposition film forming step of depositing a mineral product and the mineral deposition film formed through the step of forming the mineral deposition film, have.

Preferably, the vacuum deposition may be performed for 10 to 30 seconds at a temperature of 80 to 100 ℃.

More preferably, the mineral deposition film forming step may be performed by ion deposition after melting the mineral.

More preferably, the ion deposition may be performed at a temperature of 120 to 1850 ° C and a voltage of 1.5 to 18V for 10 to 30 seconds.

Even more preferably, the mineral is at least one selected from the group consisting of platinum, gold, silver, titanium, calcium, silicon, magnesium, zircon, germanium, zinc, copper, aluminum, bismuth, sulfur, selenium, strontium and rare earths. It can be done.

Even more preferably, the far-infrared irradiation step is a mineral deposition film formed through the mineral deposition film forming step, after putting the household goods in a high pressure sealer, 1Kg per 1 rub and 1-20 g of rare earth powder is not in contact with the household goods It can be made by pressing for 30 to 180 minutes at the pressure of.

Even more preferably, the rare earth powder may have a particle size of 180 to 60000 mesh.

As described above, the surface treatment method of household products provides not only the surface of the household products, but also a sterilization process to the inside, showing excellent antibacterial properties, and emitting far infrared rays and anions to provide household products that can maintain the freshness of food ingredients for a long period of time. Exhibits an excellent effect.

1 is a flow chart showing a surface treatment method of the disclosed household goods.
2 is a photograph showing a vacuum evaporator used in the surface treatment method of the disclosed household goods.
Figure 3 is a photograph showing a mineral ion deposition used in the surface treatment method of the disclosed household goods.

Hereinafter, the preferred embodiment of the present invention and the physical properties of each component will be described in detail, but it is intended to be described in detail so that a person skilled in the art to which the present invention pertains can easily implement the invention. This does not mean that the technical spirit and scope of the present invention is limited.

The disclosed method of surface treatment of household products is a surface of a household product on which an antibacterial coating film is formed through an antibacterial coating film forming step (S101) and an antibacterial coating film forming step (S101) in which a silane compound is vacuum-deposited on the surface of the household goods to form an antibacterial coating film. It consists of a mineral deposition film forming step (S103) for depositing mineral ions and a far infrared ray irradiation step (S105) for irradiating far-infrared rays emitted from rare earth powders to the household goods on which the mineral deposition film is formed through the mineral deposition film formation step (S103).

The antimicrobial coating film forming step (S101) is a step of forming an antimicrobial coating film by vacuum-depositing a silane compound on the surface of a household product. After the silane compound is introduced into a vacuum evaporator and heated to a temperature of 80 to 100 ° C. to evaporate, the silane It consists of a process in which a silane compound is deposited on the surface of a household product by putting the household product in a vacuum evaporator where the compound is evaporated for 10 to 30 seconds.

Through the above process, a household product formed with an antimicrobial coating film made of a silane compound is not only antimicrobial, but also has improved water repellency, so that it is possible to suppress the growth of bacteria and the like due to moisture, and also improve the stain resistance.

At this time, the silane compound is evaporated as described above, as long as it can form a coating film on the surface of household items, any one can be used without particular limitation, hexakis (monoalkylamino) disilane or hexakis (ethylamino) It is preferable to use disilane or the like.

The mineral deposition film forming step (S103) is a step of depositing mineral ions on the surface of a household product on which an antibacterial coating film is formed through the antibacterial coating film forming step (S101), which consists of a silane compound through the antibacterial coating film forming step (S101). The household goods on which the antibacterial coating film is formed are put into a mineral ion deposition machine and heated to a temperature of 120 to 1850 ° C by sputtering or cathodic sputtering to vacuum deposit ions generated from minerals to form a coating film made by depositing mineral ions on the surface of the household goods. And release the vacuum.

The deposition of minerals in the mineral deposition film forming step (S103) is performed by using a mineral ion vapor deposition device to melt the minerals and then deposit mineral ions generated from the molten minerals on the surface of household items. The conditions of the ion deposition are preferably made for 10 to 30 seconds at a temperature of 120 to 1850 ° C and a voltage of 1.5 to 18V.

In more detail, when the mineral is introduced into the evaporator provided in the mineral ion evaporator and the current is supplied to a heat source made of tungsten, the temperature increases to the melting point of the mineral, wherein the current is of a heat source made of tungsten. According to the shape (W type, snail type, spiral type, spring type, funnel type and horizontal complex type, etc.), the amount is adjusted to 1.5 to 18 V and supplied for 10 to 30 seconds.

In this case, the mineral is made of at least one selected from the group consisting of platinum, gold, silver, titanium, calcium, silicon, magnesium, zircon, germanium, zinc, copper, aluminum, bismuth, sulfur, selenium, strontium and rare earth, 300 It is preferable to use powdered ones having a particle size of 20000 mesh, and the heating conditions of the ion evaporator should be adjusted to suit the melting point of each mineral.

In addition, the rare earths are scandium, yttrium, lanthanum, cerium, paraseodymium, neodymium, promethium, samarium, europium, gadolinium, terbium, dysprosium, holmium, erbium, tulium, diterbium and ruthenium. It consists of one or more selected from the group consisting of.

The melting points of the minerals listed above are 1770 ° C for Pt (platinum), 1064 ° C for Au (gold), 962 ° C for Ag (silver), 1660 ° C for Ti (titanium), and Ca (calcium) 850 ℃, 1412 ℃ for Si (silicon), 649 ℃ for Mg (magnesium), 1850 ℃ for Zr (zircon), 938 ℃ for Ge (germanium), 420 ℃ for Zn (zinc), Cu ( 1083 ° C for copper), 659 ° C for Al (aluminum), 217 ° C for Bi (bismuth), 119 ° C for S (sulfur), 217 ° C for Se (selenium), 769 for Sr (strontium) Since ℃ and rare earth minerals generally represent 935 ° C, it is preferable to adjust the heating conditions of the ion deposition machine in consideration of the melting point of the mineral applied to the deposition.

Since the mineral deposition film formed through the above-described process is transparently formed by using a powdered mineral having a particle size of 300 to 20000 mesh, it is possible to maintain the color of the household goods.

In addition, the mineral deposition film not only exhibits excellent antibacterial performance, but also can be maintained for a long period of time when applied as a container for food materials by far infrared rays and anions emitted from the mineral deposition film.

The far infrared ray irradiation step (S105) is a step of irradiating the far infrared rays emitted from the rare earth powder to the household goods on which the mineral deposition film is formed through the mineral deposition film formation step (S103), and the mineral deposition film is formed through the mineral deposition film formation step (S103). It is made by putting the formed daily necessities into a high-pressure sealer and then adding 1Kg per rube so that rare earth powder is not in contact with the necessities and pressing for 30 to 180 minutes at a pressure of 1 to 20 bar.

The rare earth powder preferably has a particle size of 180 to 60000 mesh, since the rare earth powder having the particle size emits a large amount of far infrared rays at a pressure of 1 to 20 bar, so that the rare earth powder is introduced into the interior of a household product put into a high pressure sealer. The far-infrared rays emitted from the powder are transmitted, and the sterilization process proceeds to the interior of the household goods, thereby providing a household goods with excellent antibacterial performance.

At this time, when the household product is made of a metal material, it is preferable to apply a pressure of 8 to 20 bar, and after the household product and the rare earth powder are formed so as not to contact each other, a process of irradiating far infrared rays is performed. Preferably, after the far-infrared irradiation step (S105) is completed, the rare earth powder is recovered by a recovering machine and circulated continuously.

In addition, the rare earths are scandium, yttrium, lanthanum, cerium, paraseodymium, neodymium, promethium, samarium, europium, gadolinium, terbium, dysprosium, holmium, erbium, tulium, diterbium and ruthenium. It consists of one or more selected from the group consisting of.

The surface treatment method of the household goods made through the above process is not only the surface of the household goods, but also the sterilization process to the inside to show excellent antimicrobial properties, and far-infrared rays and anions are released to keep the freshness of food materials for a long time. Gives

S101; Antibacterial coating film forming step
S103; Mineral deposition film formation step
S105; Far infrared ray irradiation step

Claims (7)

An antibacterial coating film forming step of forming a antibacterial coating film by vacuum-depositing a silane compound on the surface of a household product;
A mineral deposition film forming step of depositing mineral ions on the surface of a household product having an antibacterial coating film formed through the antibacterial coating film forming step; And
A method of treating a surface of a household product, comprising: a far-infrared ray irradiation step of irradiating a far-infrared ray emitted from a rare earth powder at a certain pressure for a period of time to a household product on which the mineral-deposited film is formed through the mineral deposition film forming step.
The method according to claim 1,
Vacuum deposition in the antibacterial coating film forming step is a surface treatment method of household products, characterized in that made for 10 to 30 seconds at a temperature of 80 to 100 ℃.
The method according to claim 1,
The mineral deposition film forming step is a surface treatment method of household goods, characterized in that it is made by ion deposition after melting the mineral.
The method according to claim 3,
The ion deposition is a surface treatment method of household goods, characterized in that made for 10 to 30 seconds at a temperature of 120 to 1850 ℃ and a voltage of 1.5 to 18V.
The method according to claim 1 or 3,
The mineral is characterized in that it consists of at least one selected from the group consisting of platinum, gold, silver, titanium, calcium, silicon, magnesium, zircon, germanium, zinc, copper, aluminum, bismuth, sulfur, selenium, strontium and rare earths. Method of surface treatment of article.
The method according to claim 1,
In the far infrared ray irradiation step, after the mineral deposition film is formed through the mineral deposition film-forming step, the household goods on which the mineral deposition film is formed are put into a high pressure sealer, and then 1Kg per rube is added so that rare earth powder is not in contact with the household goods and 30 to 180 at a pressure of 1 to 20 bar. Method of surface treatment of household goods, characterized in that it is made by pressing for a minute.
The method according to claim 6,
The rare earth powder is a surface treatment method of household goods, characterized in that it has a particle size of 180 to 60000 mesh.

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