KR200440411Y1 - apparatus of sterilization sliver ion - Google Patents

Abstract

The present invention is provided with a supply line and a discharge line, respectively, the drinking water is stored therein, and the drinking water introduced into the housing through the through hole formed in the housing and the upper surface is supplied with external (-) current is applied A receiving cylinder, and a plurality of micro holes formed inside the cylinder and passing through the drinking water introduced into the cylinder, and are accommodated in the mesh pipe receiving external positive current; It comprises a plurality of silver beads to sterilize drinking water by generating silver ions through the (+), (-) current applied to the cylinder and the net tube in the state in contact with the drinking water, the cylinder and the net tube Is made of titanium, which prevents harmful impurities from being dissolved in drinking water during sterilization of drinking water. It provides jangchieul.

Vessel, water purification, silver ion sterilizer, cylinder, mesh tube, silver bead, titanium

Description

Silver ion sterilizer {apparatus of sterilization sliver ion}

1 is a view schematically showing a water purification system of a ship equipped with a silver ion sterilization apparatus according to a preferred embodiment of the present invention.

2 is a diagram three-dimensionally showing the configuration of the silver ion sterilizer shown in FIG.

3 is a cross-sectional view of the silver ion sterilizer shown in FIG.

             <Description of the symbols for the main parts of the drawings>

20: silver ion sterilizer 22: housing

28: cylinder 30: mesh tube

32: silver bead

The present invention relates to a silver ion sterilizer, and more particularly, to a silver ion sterilizer which prevents impurities harmful to human body from melting in drinking water during sterilization of drinking water.

As is well known, the water purification system of a ship is equipped with a sterilizer for the purpose of sterilizing harmful bacteria contained in drinking water.

Examples of such sterilizers include ultraviolet sterilizers, chemical sterilizers and silver ion sterilizers.

First, the chemical sterilizer is a method of sterilizing various harmful bacteria by injecting chemicals into drinking water, but this chemical sterilizer may not be a desirable sterilization method because chemicals harmful to human body are dissolved in drinking water.

The second ultraviolet sterilizer sterilizes harmful germs contained in drinking water by irradiating ultraviolet water to the drinking water, but this ultraviolet sterilizer is an instant sterilization method. There is a drawback that bacteria can multiply again in the process of feeding to the place of use.

The third silver ion sterilizer is electrolytically composed of a plurality of silver plates and (+) and (-) electrode terminals which support the silver plate and apply (+) current and (-) current to the silver plate, respectively. The silver ions (Ag ⁺ ) are eluted from the silver plate to which (+) current is applied by using the principle of so that a certain concentration of silver ions are dissolved in the water. It is a method of sterilizing various harmful bacteria included.

Conventional positive (+) and (-) electrode terminals used in the silver ion sterilizer are usually made of a metal material having a relatively excellent durability that can pass a current, and can support the silver plate, preferably It is common to use stainless steel.

On the other hand, the silver plate and the electrode terminals are always submerged in water for sterilization treatment, although the electrode terminals are made of stainless steel with good corrosion resistance, corrosion occurs after a certain time to the iron component or other human body There is a problem of generating a harmful metal component, this time the harmful metal component is dissolved in drinking water has brought a problem that contaminated drinking water.

Therefore, the object of the present invention for solving the problems as described above, by making a cylinder and the mesh tube to which the (-) current and (+) current is applied made of titanium (titanium) to have a good durability and to prevent corrosion It is to provide a silver ion sterilizer which can block the emission of harmful metals.

Another technical problem to be achieved by the present invention is to provide a silver ion sterilization apparatus capable of preventing impurities from being included in a processing process by using the silver processed silver beads without secondary processing.

Another technical problem to be achieved by the present invention is to provide a silver ion sterilization apparatus that can easily accommodate silver beads by manufacturing the shape of a mesh tube, which is an electrode terminal for applying a positive current, to a mesh structure of a circular tube. .

Another technical problem to be achieved by the present invention is to provide a silver ion sterilization apparatus which can realize the convenience of use by not performing periodic replacement work of the electrode.

The present invention for achieving the above object is a silver ion sterilization apparatus, the supply pipe and the discharge pipe are each provided with a housing in which drinking water is stored, and installed in the housing through the through hole formed in the housing to the housing A cylinder receiving the drinking water introduced thereto and receiving an external (-) current, and a plurality of micropores installed inside the cylinder and passing through the drinking water introduced into the cylinder, have an external positive current. And a plurality of sterilizing drinking water by generating silver ions through (+) and (-) currents applied to the cylinder and the net light tube in a state of being in contact with the drinking water. It consists of including four silver beads.

The cylinder and the mesh tube is preferably made of titanium.

On the other hand, the following description will be described for the silver ion sterilizer applied to the purification system of the ship, but the technical features of the silver ion sterilizer of the present invention is not limited to the water purification system of the vessel, various public institutions and industrial It is obvious that it can be used in the field water purification system.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

First, prior to describing the configuration of the silver ion sterilization apparatus of the present invention, as an example, to describe the purification system of the vessel in which the silver ion sterilization apparatus of the present invention is installed.

As shown in FIG. 1, the purification system of the vessel is connected to the water tanker 10 for desalination of the seawater, and the water tanker 10 and the pipe 40, and stores the drinking water introduced from the water tanker 10. Each branch is connected to the tank 50 and the storage tank 50, and comprises a branch pipe 60 for discharging drinking water to each place of use of the ship. The silver ion sterilizer 20 to be implemented in the present invention is installed between the water tank 10 and the pipes 40a and 40b connecting the storage tank 50.

2 and 3 are views showing in detail the configuration of the silver ion sterilizer according to the present invention.

As shown, the silver ion sterilizer 20 is a device for sterilizing drinking water by generating silver ions using the electrolysis principle, the housing 22, the cylinder 28, the mesh pipe 30 and a plurality of It consists of silver beads (32).

The housing 22 is hollow in the form of a cylindrical tube, the supply line 24 is formed at the bottom, the discharge line 26 is formed on one side. The supply pipe 24 supplies the drinking water that has passed through the water tank 10 of the vessel into the housing 22, and the discharge pipe 26 stores the sterilized drinking water through silver ions in the storage tank 50. To be discharged.

The cylinder 28 is to be installed in the housing 22, the upper surface is manufactured so that the through hole 28a is formed. The through hole 28a passes the drinking water supplied into the housing 22 through the supply line 24 into the cylinder 28. In addition, the circumferential surface of the cylinder 28 is configured to further form a plurality of auxiliary through holes (28b) to perform the same function as the through hole (28a). The cylinder 28 functions to support the mesh tube 30 and the silver beads 32 in the housing 22 and functions as a (-) electrode terminal to which a negative current is applied among currents supplied from the outside. Will be performed.

The mesh tubular body 30 is installed inside the cylinder 28, and the upper and lower surfaces are configured to be opened in a state in which the circumferential surface and the lower surface are sealed, and a plurality of fine holes 30a are formed in the circumferential surface and the lower surface. Make it as possible. The silver beads 32 accommodated in the mesh pipe 30 through the fine holes 30a are always in contact with the drinking water introduced into the cylinder 28, so that silver ions are eluted during electrolysis to sterilize the drinking water. Done. In addition, the mesh tube 30 performs a function as a (+) electrode terminal receiving a (+) current from a current supplied from the outside in addition to the function of accommodating the silver beads 32.

On the other hand, the cylinder 28 and the mesh tube 30 to perform the function of the (+), (-) electrode terminal as described above can be made of a variety of materials, but in the present design is preferably made of titanium (Ti) Do. In general, titanium itself is known as a metal material having excellent electrical conductivity, that is, conductive, as well as durability over a certain strength, and corrosion does not occur through excellent corrosion resistance.

That is, the cylinder 28 and the mesh tube 30 of the present invention are always locked to drinking water in the state installed in the housing 22 together with the silver beads 32, the cylinder 28 and the mesh tube ( In case of manufacturing 30) with general materials such as stainless steel or iron, corrosion may occur and contaminated drinking water by generating iron or other harmful metal substances harmful to human body in the drinking water. By producing the 28 and the mesh pipe 30, it is possible to fundamentally block the discharge of pollutants due to corrosion. In addition, it is possible to extend the service life of the sterilizing apparatus by preventing the cylinder 28 or the mesh pipe 30 from being easily damaged by the impact applied from the outside through the durability of titanium.

On the other hand, the shape of the cylinder 28, as described above, can be manufactured in the shape of the tubular body formed with the through hole 28a and the auxiliary through hole 28b on the upper surface and the circumferential surface, but the same structure as the mesh pipe body 30, That is, it can be produced in the form of a plurality of micro-holes formed along the circumferential surface, in which the micro-pores perform a function as a passage for introducing the drinking water into the cylinder 28, the same function as the through-hole and the auxiliary through-holes.

The silver bead 32 is a means for generating silver phosphorus by causing an electrolysis reaction to a power source applied from the outside, and configured to accommodate a plurality of the inside of the mesh pipe 30 described above. The silver beads 32 accommodated in the mesh tube 30 are always in contact with the drinking water introduced into the cylinder 28 through the micropores 30a of the mesh tube 30, and in this state, the cylinder 28 And when supplying (+), (-) current to the network pipe 30 to contact the drinking water in the network pipe (30) to which the (+) current is applied, causing electrolysis to elute silver ions to sterilize the drinking water Will be.

On the other hand, as mentioned in the present invention as a means for generating silver ions, the use of silver beads 32 is to prevent impurities from being contained in the silver so as not to go through a separate processing process. That is, a representative example used as a conventional silver ion generating means is a silver plate, and the silver plate is a secondary processing process such as cutting the workpiece to meet the size and specifications or its use again in the state of primary processing in the plate type In this case, impurities may be included in the silver during the secondary processing, and these impurities may be dissolved in the drinking water during the sterilization of the drinking water to contaminate the drinking water. Therefore, in the present invention, the silver beads 32 processed in the form of beads are not secondary processed into specific shapes again, and the silver beads 32 are contained in the net mesh 30 to be used so that the impurities are contained in the silver. It can minimize the pollution of drinking water.

Hereinafter, the operation of the silver ion sterilizer according to the present invention.

First, when installing the silver ion sterilization apparatus 20 of the present invention on the vessel, install the housing 22 of the silver ion sterilization apparatus 20 between the water storage device 10 and the storage tank 50, and then the water storage device 10 The supply pipe 24 is connected to the pipe 40a of the tank, and the discharge pipe 26 is connected to the pipe 40b of the storage tank 50, respectively.

Next, the drinking water into the housing 22 through the supply pipe 24 in the state in which the positive and negative currents are applied to the cylinder 28 and the mesh pipe 30 constituting the silver ion sterilizer 20, respectively. When the water is supplied, the drinking water flows into the cylinder 28 through the through hole 28a and the auxiliary through hole 28b of the cylinder 28, and then the fine of the network pipe 30 installed in the cylinder 28. It passes through the holes 30a and comes into contact with the silver bead 32 housed in the mesh tube 30. At this time, the silver beads 32 elute silver ions in the state accommodated in the mesh tube body 30 to which (+) current is applied through (+) and (-) currents applied to the cylinder 28 and the mesh tube body 30. The eluted silver ions will sterilize various harmful bacteria contained in the drinking water.

Drinking water sterilized through the sterilization silver bead 32 is in a state in which silver ions are dissolved, and silver ions dissolved in the drinking water do not disappear even in the process of being supplied to the destination through each branch pipe 60. As it remains, it is possible to realize continuous sterilization effect without secondary pollution in the process of supplying drinking water.

On the other hand, the silver ion sterilizer 20 installed in the vessel as described above is to maintain the installed state for a long time, at this time the cylinder 28 and the mesh pipe 30 is installed in the housing 22 and the drinking water and Corrosion may occur due to contact to discharge harmful metal materials, but in the present invention, the cylinder 28 and the mesh pipe 30 may be made of titanium to prevent contamination of drinking water due to corrosion.

As described above, the present invention manufactures a cylinder and a mesh tube to which the (-) and (+) currents are applied by using titanium to prevent corrosion and to prevent various harmful metal substances from being discharged with excellent durability. It has the effect of preventing contamination.

In addition, the present invention has the effect of preventing the inclusion of impurities in the processing by using the silver bead, a means for eluting silver ions, without the secondary processing in the state of primary processing.

In addition, the present invention has an effect that can easily accommodate the silver beads by making the shape of the mesh tube of the electrode terminal to apply a (+) current to the mesh structure of the circular tube.

Claims (2)

In silver ion sterilizer, A housing 22 having a supply line 24 and a discharge line 26, respectively, and storing drinking water therein; A cylinder installed in the housing 22 and receiving drinking water introduced into the housing 22 through a through hole 28a formed in an upper surface thereof and receiving an external (-) current; It is installed in the cylinder 28 and the peripheral surface is formed with a plurality of micro holes 30a for passing the drinking water introduced into the cylinder 28 and the network pipe 30 to receive an external (+) current and ; The sterilization of drinking water by generating silver ions through (+) and (-) currents applied to the cylinder 28 and the net light tube 30 in a state in which the mesh pipe 30 is in contact with the drinking water. Silver ion sterilizer, characterized in that comprising a plurality of silver beads (32). The method of claim 1, Silver cylinder sterilization apparatus, characterized in that the cylinder 28 and the mesh pipe 30 is made of titanium.

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