KR102061473B1 - Silver nano filter system - Google Patents

Abstract

The present invention relates to a silver nanofilter system which discharges a high voltage through a coated silver nano to sterilize viruses, and charges to collect ultra-fine dust. The silver nanofilter system applied in the present invention is as follows: installing a high voltage supplying end portion (120) on both end portions of a lower part of an insertion groove (110) in one side thereof; inserting and mounting a silver nanofilter (100) on an upper end of the high voltage supplying end portion (120) and on both end portions of the insertion groove (110) of the other side thereof; installing the high voltage supplying end portion (120) on both end portions of an upper part of the insertion groove (110) in the other side thereof; and inserting and mounting the silver nanofilter (100) on a lower end of the high voltage supplying end portion (120) and on both end portions of the insertion groove (110) of the other side thereof. The silver nanofilter (100) is silver nano-coated on one side and the other side of the inside of glass, and a high voltage of the high voltage supplying end portion (120) is discharged through the coated one side unit and is charged in the coated other side unit. According to the present invention, the present invention discharges by applying a high voltage to one portion having silver nano-coated thereon to sterilize viruses entering a system, and charges in the other portion having silver nano-coated thereon to collect ultra-fine dust, thereby removing the same.

Description

Silver nano filter system {Silver nano filter system}

The present invention relates to a silver nano filter system, and more particularly, to a silver nano filter system capable of discharging high voltage through silver nano coating to sterilize and charge viruses to collect ultrafine dust.

A silver nano filter device similar to the present invention is a pre-pending patent application 10-2011-0031634 (published No. 10-2012-0113938) "silver nano photocatalyst hepa filter".

According to the conventional technology, when a nanoparticle photocatalyst solution composed of silver nanoparticles on titanium dioxide (35%) is light-implanted onto a hepa filter yarn or fabric, a nano thin polymer film containing silver nanoparticles is formed on the surface of the hepa filter yarn or hepa filter. Containing poly film reacts with oxygen in the air by the oxygen catalyst of silver nano so that oxidative hydroxyl radical (OH-) and super oxide ion (O2-) are generated, it is collected in the HEPA filter by strong oxidation and contaminated. It sterilizes staphylococcus, E. coli, virus, bacteria, etc. and oxidizes and deodorizes formaldehyde, VOC ammonia, volatile organic compounds harmful gases, and has excellent wear resistance. It is a silver nano photocatalyst hepa filter that is configured to emit clean and clean air.

The silver nano photocatalyst solution, which is made by photo-implanting silver nano to titanium dioxide, is sprayed onto a hepa filter yarn or fabric to form a polymer thin film containing silver nano to remove harmful substances such as viruses.

On the other hand, the conventional silver nano filter device has a problem of low efficiency in removing viruses and the like.

The present invention aims to solve the above problems by using a silver nano filter to sterilize viruses and to collect and remove ultrafine dust.

Silver nano-filter system applied to the present invention, the high voltage supply stage 120 is installed on both ends of the lower end of one side insertion groove 110 and the silver nano filter 100 is inserted into the upper end of the high voltage supply terminal 120 and another one side The silver nano filter 100 is inserted and mounted at both ends of the insertion groove 110, the high voltage supply terminal 120 is installed at both ends of the upper end of the other insertion groove 110, and the silver nano filter 100 is disposed at the bottom of the high voltage supply terminal 120. In the mounting and mounting the silver nano filter 100 on both ends of the other insertion groove 100, the silver nano filter 100 is silver nano-coated on one side and the other side of the inner surface of the glass and the high voltage supply stage 120 The high voltage of the) is discharged through the coated one side and characterized in that it is made by charging the other side coated.

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The silver nano filter system is characterized in that the left and right pair of high voltage supply stage 120 and the two silver nano filter 100 as a pair consisting of a plurality of silver nano filters.

According to the present invention, the high voltage is applied to the silver nano-coated portion to disinfect the virus introduced into the system, and the other silver nano-coated portion can collect and remove the ultra fine dust by charging.

1 is a perspective view of a silver nano filter system applied to the present invention.
Figure 2 is a front side view of the silver nano filter system applied to the present invention.
Figure 3 is a rear view of the other side of the silver nano-filter system applied to the present invention.

1 is a perspective view of a silver nano filter system applied to the present invention.

2 is a front view (one side) of a silver nano filter system applied to the present invention.

3 is a rear view (the other side) of the silver nano filter system to which the present invention is applied.

The silver nano filter system applied to the present invention will be described with reference to FIGS. 1 to 3 as follows.

The silver nano filter 100 applied to the present invention is manufactured by reinforcing silver nano coating on glass.

As shown in Figures 1 to 3, the silver nano filter 100 is made of a plurality, the silver nano filter 100 is a silver nano coating on the inner surface of the glass. In other words, the two glass is a pair of two glass inner surface is silver nano-coated and the outer surface is uncoated.

Viruses and ultrafine dust are introduced from one side and the other side shown in Figs.

First, the process of the silver nano filter when it is introduced from one side as shown in Figure 2 as follows.

The high voltage supply stage 120 for supplying a high voltage is installed at the lower end of the one side insertion groove 110, the silver nano filter 100 is inserted into the top of the high voltage supply stage 120, this configuration is virus sterilization and ultrafine It is a configuration that works when dust is collected.

In addition, the high voltage supply terminal 120 is installed at both ends of the one side insertion groove 130, and the silver nano filter 100 is mounted. The two silver nano filters 100 configured as described above become a set to perform virus sterilization and ultra-fine dust collection.

Subsequently, when a high voltage is generated in the high voltage supply terminal 120 and plasma discharged to the lower silver nano filter 100 through the upper silver nano filter 100, the high voltage is charged to the lower silver nano filter 100 at the lower side. Electricity flows through the silver nano filter. At this time, as the high voltage is discharged and charged, the virus in the silver nano filter 100 is sterilized and ultrafine dust is collected.

That is, the high voltage generated by the high voltage supply stage 120 is discharged through the silver nano filter 100 at the top to sterilize the virus and collect the ultrafine dust through the silver nano filter 100 at the bottom.

The silver nano filter 100 is a set of two to collect the virus sterilization and ultra-fine dust, at this time, the bottom surface of the upper silver nano filter 100 and the upper surface of the lower silver nano filter 100 is coated with silver nano Through the discharge and charging by high voltage occurs.

Ultrafine dust is collected inside the space of the lower surface of the lower silver nano filter 100 and the upper surface of another lower silver nano filter 100.

That is, the lower surface of the lower silver nano filter 100 and the upper surface of another lower silver nano filter 100 are not coated with silver nano so that only the dust collecting function is performed without virus sterilization. An interval between the lower surface of the lower silver nano filter 100 and the upper surface of another lower silver nano filter 100 may be spaced without limitation.

The voltage of the high voltage supply terminal 120 supplied to the upper silver nano filter 100 is 7KV, and the voltage of the lower silver nano filter 100 is 0V. In addition, the voltage of the high voltage supply terminal 120 supplied to the upper silver nano-filter 100 may be 7KV, the voltage of the lower silver nano-filter 100 may be 7KV.

Referring to the process of the silver nano filter when it is introduced from the other side as shown in Figure 3 as follows.

The high voltage supply stage 120 for supplying a high voltage is installed at the upper end of the other insertion groove 110, the silver nano filter 100 is inserted into the lower end of the high voltage supply stage 120, this configuration is virus sterilization and ultrafine It is a configuration that works when dust is collected.

It is a configuration that the silver nano filter 100 is mounted on both ends of the other insertion groove 110 is not installed. The two silver nano filters 100 configured as described above become a set to perform virus sterilization and ultra-fine dust collection.

Subsequently, when a high voltage is generated in the high voltage supply terminal 120 and plasma discharged to the upper silver nano filter 100 through the lower silver nano filter 100, the high voltage is charged to the upper silver nano filter 100 at the upper end. Electricity flows to the silver nano filter 100.

At this time, as the high voltage is discharged and charged, the virus in the silver nano filter 100 is sterilized and ultrafine dust is collected.

That is, the high voltage generated by the high voltage supply stage 120 is discharged through the silver nano filter 100 at the bottom to sterilize the virus and collect ultrafine dust through the silver nano filter 100 at the top.

The silver nano filter 100 is a set of two to collect the virus sterilization and ultra-fine dust, at this time the upper surface of the lower silver nano filter 100 and the lower surface of the upper silver nano filter 100 is coated with silver nano Through the discharge and charging by high voltage occurs.

Ultrafine dust is collected inside the space of the lower surface of the lower silver nano filter 100 and the upper surface of another lower silver nano filter 100.

That is, the lower surface of the lower silver nano filter 100 and the upper surface of another lower silver nano filter 100 are not coated with silver nano so that only the dust collecting function is performed without virus sterilization. An interval between the lower surface of the lower silver nano filter 100 and the upper surface of another lower silver nano filter 100 may be spaced without limitation.

The voltage of the high voltage supply terminal 120 supplied to the lower silver nano filter 100 is 7KV, and the voltage of the upper silver nano filter is 0V. In addition, the voltage of the high voltage supply terminal 120 supplied to the lower silver nano filter 100 may be 7KV, the voltage of the upper silver nano filter 100 may be 7KV. In addition, the high voltage applied to the system of the present invention is preferably 5 KV or more.

Then, the silver nano filter 100 of the glass material is mounted on the insertion groove 110 of the system to remove the ultra-fine dust collected by air or wipe with a rag to remove the ultra-fine dust. Also, the silver nano filter 100 made of glass is immersed in water to wash the ultrafine dust.

As such, the present invention collects the virus sterilization and ultrafine dust in both the one side and the other side of the system.

In addition, the silver nano-filter system applied to the present invention has an efficiency of 80% or more due to virus sterilization and ultra-fine dust collection.

100: silver nano filter 110: insertion groove 120: high voltage supply terminal

Claims (3)

Install the high voltage supply terminal 120 at both ends of the lower end of the one side insertion groove 110 and insert the silver nano filter 100 into the upper end of the high voltage supply terminal 120 and the silver nano filter at both ends of the other insertion groove 110. Insert and insert (100), install the high voltage supply terminal 120 at both ends of the upper end of the other insertion groove 110 and insert the silver nano filter 100 in the lower end of the high voltage supply terminal 120 and the other insertion groove In mounting the silver nano filter 100 at both ends of the (100),
The silver nano filter 100 is silver nano coated on one side and the other side of the inner surface of the glass to discharge through the high voltage coated one side portion of the high voltage supply terminal 120, and the silver nano to be made by charging it on the other side coated. Filter system. delete The silver nano-filter system according to claim 1, wherein the silver nano-filter system comprises a plurality of silver nano-filters in a pair of left and right pairs of high voltage supply stages (120) and two silver nano-filters (100).

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