KR20050029132A - Method and device for instantaneously producing silver ion(ag+) water - Google Patents

Abstract

To provide a method and a device capable of instantaneously producing silver ion(Ag+) water with high silver ion(Ag+) effect in a large quantity economically and easily, and an instantaneous silver ion(Ag+) water shower apparatus capable of instantaneously producing the silver ion(Ag+) water using the method and the device. The device(20) for instantaneously producing silver ion(Ag+) water comprises: an electrolysis pipe(30) in which a pipe having a certain length and electric conductivity and corrosion resistance is formed as a combination electrolyzer and cathode such that water that is electrolyte and raw water for extracting silver ion(Ag+) water passes through the pipe; silver anodes(40) at least one or more of which are longitudinally installed with being spaced from the inner wall circumference of the electrolysis pipe in a certain distance, and which are formed in silver rods or silver plates having a certain length and purity of 99.99%; spacers(50) of electric insulator for partially supporting the silver anodes with the silver anodes being spaced from the inner wall circumference of the electrolysis pipe in a certain distance; and a power supply control unit(60) for controlling supply of a certain voltage to the electrolysis pipe of the cathode as the negative pole and to the silver anodes as the positive pole only while water passes through the electrolysis pipe of cathode formed as the electrolysis pipe.

Description

Method for producing instantaneous ionized water and apparatus {Method and device for instantaneously producing silver ion (Ag +) water}

The present invention relates to a method and apparatus for producing instantaneous silver ion (Ag +) water and a shower device for silver ion (Ag +) water instantaneous using the same, in particular, in the production of silver ion (Ag +) water by electrolysis, the electrolytic cell is conductive. It is composed of an electrolytic tube that passes water while using a pipe as a cathode, and installs silver rods of a certain diameter and length at a certain interval inside the electrolytic tube by anodes. , By dissolving silver ions (Ag +) generated in the silver bar of the anode by electrolysis in the process of passing water through the electrolytic tube using water as an electrolyte, instantaneously producing a suitable concentration of silver ions (Ag +) water. It is characterized by.

As is known, silver ions (Ag +) water containing silver and silver ions (Ag +), which are ionizing substances, in a certain concentration are used in various fields because they have excellent sterilization and antibacterial effects.

The field of application of silver ions (Ag +), which is noted in connection with the present invention, is a method and apparatus for preparing silver ions (Ag +) water containing an appropriate concentration of silver ions (Ag +), and thus the production of silver ions (Ag +) As the method, an electrolysis method, a chemical decomposition method, a grinding method and the like are known.

Among the known methods for producing silver ion (Ag +) water, the method for producing silver ion (Ag +) water by electrolysis is superior to chemical decomposition, pulverization, or other manufacturing methods in terms of manufacturing facilities or economical efficiency, and applied silver Many ion (Ag +) water production apparatuses are provided.

As a representative example of the method and apparatus for producing silver ion (Ag +) water by the electrolysis method, distilled or purified water is filled into an electrolytic cell of a box-shaped or cylindrical non-conductor with an electrolyte solution, and the electrolyte solution is fixed. Purity 99.99% of the standard Silver plate or two silver bars are immersed in the positive electrode (+) and the negative electrode (-) at regular intervals, respectively, for a certain period of time. There is a so-called immersion silver ion (Ag +) water electrolysis device which electrolysis by supplying DC power to (-) for a certain time.

According to the immersion type silver ion (Ag +) water electrolysis device, ionization occurs between the positive electrode (+) and the negative electrode (-) according to the electrolysis principle, and thus the silver ions generated from the silver rod, the positive electrode (+), on one side. When (Ag +) is dissolved in distilled or purified water as an electrolyte and contained therein, a silver solution having a predetermined concentration, that is, silver ion (Ag +) water is produced.

However, an immersion type silver ion (Ag +) water electrolysis method and apparatus for preparing silver ion (Ag +) water by filling water in an electrolytic cell with electrolyte as described above and immersing two silver bars or silver plates with positive electrode electrodes,

By using purified water or distilled water with very little electrolyte as an electrolyte, it takes a long time to produce silver ion (Ag +) water due to the characteristics of electrolysis during immersion, and the production characteristics of electrolyzer and silver electrode, or the price of distilled or purified water and silver electrode as raw water In view of the above, it is difficult to manufacture a large amount of silver ions (Ag +) water to produce a large size, and when produced in a small size, there is a problem that the production of silver ions (Ag +) water per hour is very small.

For example, the production performance of silver ion (Ag +) water by the immersion type manufacturing method and apparatus described above varies depending on the manufacturer and the specification and capacity of the apparatus, but on average, 120 ml to 250 ml It is known that it takes about 20 to 60 minutes to decompose water.

Importantly, distilled or purified water, which is the raw water of silver ion (Ag +) water, is filled in the electrolytic cell during the manufacturing process to produce the appropriate concentration of silver ion (Ag +) water, thereby producing silver ion (Ag +) water. The open electrolyzer is in contact with oxygen in the air and exposed to visible light. After a certain time, the silver ion (Ag +) water is oxidatively deteriorated due to the characteristic of silver having high oxidizing property, that is, non-corrosion resistance. There is a fatal problem that the unique sterilization and antimicrobial effect of silver ions (Ag +) water is significantly lowered.

Therefore, the silver ion (Ag +) water produced by the above-described conventional immersion electrolysis method and apparatus has a sealed structure or a shielding structure that prevents contact with air and visible light during the manufacturing process of distilled or purified water as an electrolyte. If it is not provided, the sterilization and antimicrobial efficiency is inevitably low. Even if the prepared silver ion (Ag +) water is stored in a non-metallic sealed container, the effect of silver ion (Ag +) is very low if not used immediately. have.

For this reason, until now, silver ions (Ag +) water has been produced in small amounts and used immediately, such as domestic drinking water, functional lotion, medical small-capacity sterilization water, large-capacity sterilizing water, face water, bath water and crop water, various industrial sterilization, When a large amount of silver ion (Ag +) water is needed at a time or at any time, such as antibacterial water, a small amount of silver ion (Ag +) water produced by a small-capacity manufacturing apparatus is gradually stored and used. The efficacy of the ions (Ag +) water was deteriorated depending on the storage time, and a large amount of silver ions (Ag +) water was added due to another property that the oxidation rate is increased when the silver ions (Ag +) water are in contact with a metal component or some synthetic resins for a long time. There was also a difficulty in the means of storage, and there were many limitations on the availability of silver ion (Ag +) water.

Disclosure of the Invention

The present invention solves the problems of the silver ion (Ag +) water production method and manufacturing apparatus by a conventional immersion electrolysis method of filling the electrolyte in a non-flow state while using distilled or purified water as the electrolyte as described above. Is provided to

The electrolytic cell is replaced with an electrolytic tube and formed into a negative electrode at the same time, and the anode body is insulated from the inside of the electrolytic tube with a predetermined distance from the inner wall of the insulated tube by using a silver material having a purity of 99.99%. The current is supplied while continuously passing the water through the electrolytic tube only during the production of silver ion (Ag +) water, so that instantaneously and a large amount of silver ion (Ag +) water of an appropriate concentration can be produced. ,

One object of the present invention is to provide a method of preparing silver ion (Ag +) water, which is capable of producing silver ion (Ag +) water having a high silver ion (Ag +) effect instantaneously and easily in large quantities.

Still another object is to provide a silver ion (Ag +) water production apparatus capable of producing silver ion (Ag +) water having a high silver ion (Ag +) effect instantaneously and easily in large quantities.

Another object is the instantaneous silver ion (Ag +) water instant that can be easily produced in a large amount of silver ion (Ag +) water having a high effect of silver ions (Ag +) instantaneously using the production method and apparatus of the above object In providing a shower device.

A common object of the present invention is to enable the production of a large amount of silver ions (Ag +) water rapidly and economically in succession when necessary, and thus high efficiency before silver ions (Ag +) water is oxidized and sterilization and antibacterial falls. The ability to immediately utilize silver ion (Ag +) water greatly improves the utility of silver ion (Ag +) water.

Other objects may also be provided from the description of the invention which will be described later.

1 is a schematic view of the structure of an instantaneous silver (Ag +) water production apparatus according to an embodiment of the present invention;

Figure 2 is an overall view of one embodiment silver ion (Ag +) water instant shower device according to the present invention,

Figure 3 is a cross-sectional view of the inside of an embodiment of the present invention silver ion (Ag +) instantaneous shower device,

Figure 4 is an exploded perspective view of an electrolytic device of an embodiment of the present invention the silver (Ag +) water instant shower device,

Figure 5 is a side cross-sectional view of an internal main configuration of an ion (Ag +) water instant shower device according to an embodiment of the present invention;

6 is an enlarged cross-sectional view taken along line 6-6 of the configuration of FIG. 3;

7 is an enlarged cross-sectional view taken along line 7-7 of the configuration of FIG. 3;

8 is an enlarged cross-sectional view of a power connection portion of a silver positive electrode of an internal main configuration of an ion (Ag +) water instantaneous shower device according to an embodiment of the present invention;

Figure 9 is an enlarged view of the installation structure of the water flow detection device of the main configuration of the ion (Ag +) water instantaneous shower device according to an embodiment of the present invention,

FIG. 10 is an enlarged cross-sectional side view of the installation structure of the oil / water detection device in the main configuration of the ion (Ag +) water instantaneous shower device according to an embodiment of the present invention;

11 is an enlarged view of an operation state of the cross section of the installation structure of the oil / water detection device of the main configuration of the ion (Ag +) water instantaneous shower device according to an embodiment of the present invention;

Figure 12 is an exploded perspective view of an embodiment of the main flow configuration of the main configuration of the ion (Ag +) water instant shower device according to the present invention.

Best Mode of Invention

Silver ion (Ag +) water production method of the present invention for achieving the above object,

In the method of producing silver ion (Ag +) water using the electrolysis method, an electroconductive pipe of a certain length that can pass water is formed into an electrolytic tube of a cathode.

In the electrolytic tube, water is used as an electrolyte for an electrolytic apparatus having at least one purity 99.99% silver anode formed in a longitudinal direction at a predetermined distance from the inner wall of the electrolytic tube. While passing through the inner wall of the electrolytic tube and around the outer surface of the silver anode and controlling the direct current of a constant voltage only during the passage of water, the silver ion generated in the silver anode of the anode according to the electrolysis principle ( Ag +) is dissolved in water, and instantaneously, a method of producing silver ion (Ag +) water at an appropriate concentration is characterized in that it is configured continuously.

In addition, the silver ion (Ag +) water production apparatus of the present invention using the production method of the present invention for achieving the above object,

By using the manufacturing method of the present invention, a pipe having electroconductivity and corrosion resistance of a certain length capable of passing water, which is an electrolyte solution and silver ion (Ag +) water extraction raw water, is formed by a combination of an electrolytic cell and a cathode. One electrolytic tube;

A silver anode formed of a predetermined length of 99.99% silver rod or silver plate at least one of which is installed in the longitudinal direction at a predetermined distance from the inner wall of the electrolytic tube;

A spacer of an electrical insulator which partially supports the silver anode while maintaining a predetermined distance from the circumference of the inner wall of the electrolytic tube;

Only while water is passed through the electrolytic tube of the cathode formed by the electrolytic cell, the cathode (-) is used for the electrolytic tube of the cathode and the anode (+) for the silver anode. It is characterized by comprising a power supply control device for controlling and supplying a constant voltage.

In addition, the configuration of the silver ion (Ag +) water instant shower device of the present invention using the silver ion (Ag +) water production method and apparatus of the present invention for achieving the above object,

A plate-shaped base plate that can be attached to the wall;

Corrosion-resistant stainless steel pipe, which is an electrolyte and can pass water, which is silver ion (Ag +) water extraction raw water, is formed by using an electrolytic cell and a cathode, and a predetermined distance is formed in two rows from the front of the base plate in two rows. Electrolytic tubes placed and fixed with a conductive fixing clip;

A silver anode formed of a predetermined length of 99.99% silver rods or silver plates installed in the longitudinal direction at predetermined intervals from the inner wall of the respective electrolytic tubes;

A porous tubular spacer for supporting the silver anode with electrical insulation while maintaining a predetermined distance from the inner wall of the electrolytic tube;

A watering connecting pipe interconnecting the upper ends of the two rows of electrolytic pipes with a watertight sealing structure;

Positive power supply means for connecting a positive (+) wire from a power control device by a silver positive electrode body and a watertight sealing structure built into the electrolytic tube on each of the upper left and right sides of the watering connector;

Only while water is passed through the electrolytic tubes of the two rows of cathodes, the anode is positively connected to the silver anode and the cathode is fixed through an electroconductive fixing clip to the cathode of the cathode. A power controller for controlling and supplying a negative voltage to a constant voltage,

The lower part of the two rows of electrolytic tubes are connected to each other by a watertight sealing structure and a part of the base plate protrudes to the outside of the lower end, and connected to the lower end of any one of the electrolytic tubes in the pipeline with a flow water detection device A water supply pipe connector, which is connected to a lower end of the other electrolytic pipe and is connected to a shower hose;

The base plate is externally equipped with a standard for accommodating the electrolytic devices, and fixedly attaches a power control device electrically connected to the water flow detection device to a rear side, and on the front side, switches and operation pilots of the power control device are disposed. It is characterized by comprising a shell-like exterior body.

Hereinafter, the present invention will be described in detail by the silver ion (Ag +) water instantaneous preparation device and silver ion (Ag +) water instant shower apparatus using the same.

Figure 1 shows a schematic diagram of an apparatus 20 for producing an ion (Ag +) water instantaneous embodiment of the present invention.

Reference numeral 30 denotes an electrolytic tube in which a stainless steel pipe of a predetermined length having electrical conductivity and corrosion resistance can be passed through water, which is an electrolyte, and is formed by a combination of an electrolytic cell and a cathode.

This stainless pipe electrolytic tube adopts 18-8 series STS 304 or STS 316 stainless steel containing 18% chromium and 8% nickel.

Reference numeral 40 is a silver anode formed of a predetermined length of 99.99% silver rods at least one of which is installed in the longitudinal direction at a distance from the periphery of the inner wall of the electrolytic tube 30.

Reference numeral 50 denotes a spacer made of a material of an electrical insulator and partially supporting the silver anode 40 while maintaining a predetermined distance from the circumference of the inner wall of the electrolytic tube 30.

Reference numeral 60 denotes a negative electrode (-) in the electrolytic tube 30 of the cathode (Cathode) only while water passes through the electrolytic tube 30 of the cathode (Cathode) formed by the electrolytic cell, the silver anode An anode 40 is a power supply control device for controlling and supplying a positive voltage to a predetermined voltage.

According to one embodiment of the present invention described above, according to the configuration of the ion (Ag +) water instantaneous manufacturing apparatus 20, a power supply control device is provided while continuously supplying water, which is an electrolyte solution, to one side of the electrolytic tube 30 and discharged to the other side. 60, a cathode (−) is supplied to the electrolytic tube 30, and a constant voltage of the anode (+) is controlled and supplied to the silver anode 40, so that water flowing into the electrolytic tube 30 is supplied to the electrolytic tube 30. As an electrolyte, ionization occurs between the electrolytic tube 30 and the silver anode 40, whereby electrolysis is performed.

Therefore, silver ions (Ag +) generated in the silver anode 40 are dissolved in water flowing through the electrolyte tube 30 as an electrolyte in the process of moving to the cathode tube 30 of the cathode. The water discharged to the discharge port of the electrolytic tube 30 is generated and discharged as a silver solution containing silver ions (Ag +) at an appropriate concentration, that is, silver ions (Ag +) water.

One embodiment of the present invention as described above, in the process of producing silver ion (Ag +) water by the composition of the ion (Ag +) instantaneous production apparatus 20, the flow of water to the electrolytic tube 30 is stopped, that is, When the supply is stopped, the power supply control device 60 simultaneously cuts off the supply of power, thereby stopping ionization and stopping ionization of water.

The ionization action of silver ions (Ag +) by the silver anode (40) in the ionization in the above operation is a silver anode that is used when the silver ion (Ag +) water production apparatus is used for a certain period of time. Although there is a difference depending on the size and shape of the anode 40, the silver anode material gradually consumes the material. Therefore, when a predetermined silver ion (Ag +) concentration cannot be obtained, new silver The anode 40 is used by replacing.

As described above, according to the embodiment of the present invention, the ion (Ag +) water instantaneous production apparatus 20 is constructed in comparison with the immersion type electrolysis method and apparatus, which are typical devices of the conventional silver ion (Ag +) water production apparatus. And the following enhanced effects in function.

First, the configuration of the electrolytic cell was conventionally a bulky container type for filling a certain amount of electrolyte and used two positive (+,-) silver rods as the electrode, but in the present invention, the electrolytic cell is thin and small volume pipe type electrolysis It is formed as a tube, and at the same time formed as a cathode (cathode), the volume of the electrolytic cell is reduced, the configuration is simple, and the number of silver electrodes can be reduced, as well as the handling of the manufacturing apparatus, as well as to ensure the production and economic efficiency.

These effects ultimately allow the construction of small-capacity silver ion (Ag +) water production equipment as well as the construction of medium and large production equipment with ease and economic feasibility.

Secondly, in the electrolyte solution, the conventional configuration is a configuration in which the electrolyte uses minute distilled water and purified water and fills it to a static state in the electrolytic cell during the ionization process. Since the pipe-type electrolytic tube penetrates at a constant flow rate, the silver ion (Ag +) ionization in the silver anode (40) is very fast, and the ion concentration of the silver ion (Ag +) water is controlled by adjusting the supply voltage. It is easy to adjust, and ultimately, it is possible to manufacture silver ion (Ag +) water at a suitable concentration quickly and economically, so that it is possible to maximize sterilization and antimicrobial activity immediately when it is operated when silver ion (Ag +) water is needed. High-efficiency silver ion (Ag +) water can be obtained.

The effects of the rapid manufacturing and securing the silver ion (Ag +) water efficiency of the present invention also prevent the degradation of silver ion (Ag +) water by completely eliminating the need for storing the prepared silver ion (Ag +) water. In addition, by removing the storage cost of the storage tank, the utilization range of the silver ion (Ag +) water, which has been limited by the above problems, can be significantly expanded.

In the composition of the silver ion (Ag +) water production method and apparatus of the present invention and the silver ion (Ag +) instantaneous shower device using the same, to increase the extraction efficiency of silver ion (Ag +) water and to prevent the formation of harmful compounds It is preferable to use high purity silver, named silver dust, which is a purity of 99.99% or more for the adoption of the positive electrode body, and it is preferable to use tap water as the kind of water that is an electrolyte.

In the above configuration of the silver ion (Ag +) water production apparatus of the present invention, preferably, as a means for reducing the volume of the production apparatus while increasing the production performance of silver ion (Ag +) water,

At least two or more coupling configurations of the electrolytic tube 30 and the silver anode body 40 are arranged with a predetermined interval in the vertical direction or the left and right direction, and the ends are connected to each other in a watertight structure to supply power. You can also carry out.

In addition, in the configuration of the silver ion (Ag +) water production apparatus of the present invention, preferably, as the means for reducing the volume of the production apparatus while increasing the production performance of silver ion (Ag +) water, the electrolytic tube 30 and the silver anode body In addition to the configuration of forming 40 in a straight line, it may be formed in the form of a curved tube or a spiral tube of a certain curvature.

In addition, one embodiment of the present invention is a configuration of an ion (Ag +) water production apparatus, preferably illustrating a configuration of a spacer for maintaining a predetermined distance from the inner wall of the electrolytic tube, the silver anode inserted into the interior of the electrolytic tube, Like the spacer 50 of one embodiment, in addition to the fragmentary type that is separated and supported in the entire length of the electrolytic tube, the ionization action smoothly occurs between the silver positive electrode and the inner wall of the electrolytic tube while supporting and supporting the silver anode. It has a porous structure that can be used, and it can be configured in a tubular shape which prevents the power supply from being shorted by connection with an electrolytic tube because the silver anode body becomes thinner or the middle part is disconnected with use for a considerable time.

In addition, an embodiment of the present invention is a means for adjusting the concentration of silver ions (Ag +) of the silver ions (Ag +) water to be prepared according to the user and the user in the configuration of the ion (Ag +) water production apparatus, The power supply control device may further include a supply voltage manual variable circuit that allows a user to arbitrarily select a supply voltage of various stages preset to a predetermined control value.

In addition, in one embodiment of the present invention, in the configuration of the ion (Ag +) water production apparatus, preferably, as the silver anode body becomes thinner with the use for a considerable period of time, the ionization action of the silver ions (Ag +) is increased by increasing the distance from the electrolytic tube. A means for compensating for a decrease in the concentration of silver ions (Ag +) water produced per hour; or a means for automatically maintaining the concentration of silver ions (Ag +) in silver ions (Ag +) water at a constant concentration. The apparatus may further include a voltage automatic variable circuit which senses the induced voltage of the sieve and automatically increases and corrects the supply voltage with a predetermined correction value.

In addition, an embodiment of the present invention preferably in the configuration of the ion (Ag +) water production apparatus, and detects the flow rate of the water obtained at the water inlet side of the electrolytic tube and only when the water is obtained above a certain flow rate and The silver may further include a flow rate detecting device for supplying power to the positive electrode.

Silver ion (Ag +) water instantaneous production apparatus of the present invention and one embodiment thereof Another embodiment of the present invention using silver ion (Ag +) water instantaneous production apparatus (20) is an ion silver (Ag +) water instant shower The configuration of the device 100 is shown in FIGS.

One embodiment is the configuration of the ion (Ag +) instant shower device 100,

A base plate (101) formed of a rectangular plate of an electrical conductive material synthetic resin material which can be attached to a wall;

External to the base plate 101 to accommodate the electrolytic devices, is fixed to the power control device 60 and the back, the front of the control switch 61 of the power control device 60 and the operation A casing outer body 102 having the pilots 62 disposed thereon is provided as a case.

On the front surface of the base plate 101, a corrosion-resistant, electroconductive stainless steel pipe having a predetermined length, which is allowed to pass water, which is an electrolyte and extracting silver ion (Ag +) water, is formed as a combination of an electrolytic cell and a cathode. The left and right electrolytic tubes 30a and 30b fixed to the two conductive fixing clips 91, 91a and 91b are spaced in two rows on the left and right water lines.

Inside the left and right electrolytic tubes 30a and 30b of each of the two rows, an electrically insulating and several holes 52 are formed around the outer surface to maintain a predetermined interval circumferentially with respect to the inner wall circumference. 99.99% purity left and right silver anode rods 40a and 40b of a predetermined length, supported by a porous support tube 51 in which cross-shaped support pieces 53 are formed in the middle and lower positions. This is installed.

On each of the upper end portions of the left and right silver anode rods 40a and 40b, an annular groove 41 is formed circumferentially so that the O-ring 42 restrained on the upper end of the support tube 51.

The lower end 54 of the support tube 51 is blocked, and the upper end of the support tube 51 is provided with a paper ring 55 having a bore circumferentially restrained by a single tick of the left and right electrolytic tubes 30a and 30b.

The upper and lower ends of the two rows of left and right electrolytic tubes 30a and 30b are formed with thread portions 31 and 32, respectively, and screwed inlets 71 connected to the water supply pipe 81 at the lower end of the left electrolytic tube 30a. Is connected to the upper screw tube 72 and the watertight structure of the water flow detection device 70 having a,

The lower end of the right electrolytic pipe (30b) is connected to the upper end of the discharge pipe 83 having a threaded discharge port 84 screwed with the shower hose 85 of the shower head 86 in a watertight structure.

The upper ends of the two rows of left and right electrolytic tubes 30a and 30b are non-conducting synthetic resins on the upper threaded portions 32, respectively, and each of the left and right downward connecting tubes 98a have a female screw portion on the inner surface and are bent left and right. 98b) is connected to the water-tight structure by the irrigation connecting pipe (95).

The watering connection pipe 95 is fixed by a fixing clip 93 fixed to the fixing base 103 of the base plate 101, the left and right silver anodes built in the left and right electrolytic tubes 30a, 30b respectively on both sides of the top Wiring ports 96a and 96b for connecting the positive (+) power line 65b from the power control device 60 to the rods 40a and 40b are provided with a watertight sealing structure.

Electrically conductive wiring caps 97a and 97b are respectively joined to the wiring ports 96a and 96b in a watertight structure, and the left and right silver anode bars 40a (from the lower ends of the wiring caps 97a and 97b) ( An electroconductive spring 45 is connected between the upper ends of 40b).

Power wire clips 97a and 97b are elastically coupled to the wire caps 97a and 97b to electrically connect the positive (+) power lines 65b from the power control device 60.

The power control device 60 wires the negative power supply line 65a of the DC power supply to the control switch 61 via the reed switch 74 of the oil / water detection device 70, and on the other hand, the electroconductive fixing clip 91. (91a) and (91b) are connected to the left and right electrolytic tubes (30a) and (30b) by the negative electrode power line (65a), the positive electrode power line (65b) via the control switch 61, the silver positive electrode (40a) ( The wiring is connected to the wiring caps 97a and 97b connected to 40b.

9 to 12 show a detailed internal structure and an exploded state of the water flow detecting device 70.

One side of the housing of the water flow detection device 70 is a water flow detection unit 76 coupled to the watertight structure by the flow path and the O-ring 79, a fixing plate 77 for fixing the water flow detection unit, and the water flow detection unit 76. It is composed of a water flow sensor (75) installed on the inner wall of the hinge structure 78, the magnet 75a is attached to the rear surface, and a reed switch (74) built in the water flow sensor (76).

The water flow sensing zone 75 is rotatably installed up and down in a state in which a hinge structure is attached to the inner wall of the water flow sensing zone 76 to block the internal water flow pipe when descending, and when the water rises to a certain pressure, the hinge The structure 75 is rotated upwards and downwards by 90 degrees from the beginning, and the magnet 75a attached to the rear surface connects the reed switch 74 to each other.

Reference numeral 73 is a water temperature sensor exposed to the flow rate pipe portion of the water flow detection device (70).

One embodiment of the present invention configured as described above is the configuration of the ion (Ag +) instantaneous shower device 100 is operated as follows.

In one embodiment, the ion (Ag +) instantaneous shower device 100 is ready for operation, the DC power supply is connected to the power controller 60 from the inside or outside, the water supply pipe 81 is connected to the tap water, and the control The switch 61 is in the OFF state, and the power is cut off from the left and right electrolytic tubes 30a and 30b which are the cathode bodies and the left and right silver anode bars 40a and 40b which are the anode bodies.

When the user turns on the tap water to use as a general shower device, the tap water passes through the water flow detection device 70, the left electrolytic pipe 30a, the watering connection pipe 95, the right electrolytic pipe 30b and the discharge pipe 83 It is sprayed to the shower head 86 in order through.

In the state of using the shower apparatus as the general shower water, when the silver ion (Ag +) water is to be produced, pressing the control switch 61 to turn on the silver ion (Ag +) water is produced as follows, and the shower head 86 Sprayed).

When the tap water continues to rise into the inlet 71 of the water flow detection device 70 at a constant pressure, the flow water detection zone 75 is rotated about 80 to 90 degrees around the hinge structure 78 and rotates. The action of connecting the switch 74 is maintained.

When the reed switch 74 is connected, DC power is supplied to the left and right electrolytic tubes 30a and 30b, which are the cathode body, and the left and right silver anode bars 40a, 40b, which are the anode body. The tap water passing through the pipe 30a, the watering connecting pipe 95, the right electrolytic pipe 30b, and the discharge pipe 83 in order acts as an electrolyte in the left and right electrolytic pipes 30a and 30b.

That is, in the process of passing tap water between the left and right electrolytic tubes 30a and 30b through which the negative electrode power is supplied, the ionizing action occurs in the process of passing through the left and right silver anode rods 40a and 40b through which the positive electrode power is supplied. Silver ions (Ag +) are generated and melted in the anode rods (40a) and (40b) to be made of silver ions (Ag +) water.

In the process of manufacturing silver ion (Ag +) water as described above, when the control switch 61 is turned OFF, the left and right electrolytic tubes 30a and 30b, which are cathode bodies, and the left and right sides, which are anode bodies, are supplied to the anode rods 40a and 40b. The DC power supply is cut off and the production of silver ions (Ag +) water is stopped.

In addition, when the water supply is shut off and the supply of tap water is cut off, since the water flow detection zone 75 of the water flow detection device 70 is lowered to the inlet side by its own weight, the magnet 75a attached to the water flow detection zone 75 is leaded. The reed switch 74 is turned off from the switch 74 to cut off the DC power as a whole to stop the electrolysis.

As described above, according to the exemplary embodiment of the present invention, according to the ion (Ag +) instantaneous shower device 100, when the user desires, the tap water is turned on and the tap water is turned on while the control switch 61 is turned on. If supplied to the) side, the shower head 86 can be sparged with the proper concentration and silver ion (Ag +) water immediately after the passage.

In addition, the ion concentration can be arbitrarily adjusted by changing the voltage of the power supply.

One embodiment of the present invention in the configuration of the ion (Ag +) instantaneous shower device 100, the specifications of the left and right electrolytic tubes 30a, 30b of one embodiment is 18-8 series stainless steel commonly distributed Among the steel pipes, the outside diameter of 21.7mm, inner diameter 16.7mm, thickness 2.5mm length 210mm is used,

The left and right silver positive electrode bars 40a and 40b use a diameter of about 5.0 mm, and between each of the left and right silver positive electrode bars 40a and 40b which are anodes and the inner diameters of the left and right electrolytic tubes 30a and 30b which are cathodes, respectively. To keep the gap within 5mm

Tap water was supplied at room temperature of about 4 to 10 degrees Celsius, and DC voltage was supplied to within 2AMP at 24 to 36V. Therefore, 1 ppm to 3 ppm of silver ion (Ag +) water having the best effect as a sterilizing and antibacterial agent was supplied. Could be manufactured.

In the implementation of the present invention as described above, the configuration of the above-described embodiment is presented as a preferred embodiment for carrying out the present invention, but is not necessarily limited thereto.

For example, the shape and specifications of the electrolytic tube and the silver bar may be changed to any size and shape for medium or large capacity devices in addition to the standard or shape shown above. Depending on the configuration of the control device, the silver bar may be inspected. By checking the replacement time, you can control or replace with reverse polarity.

As described above, according to the silver ion water instantaneous preparation method and apparatus of the present invention and the silver ionized water instantaneous shower apparatus using the same, the conventional silver ion (Ag +) water producing apparatus is the most excellent and representative apparatus compared to the immersion type electrolysis method and apparatus. It has the following enhanced effects in composition and function.

First, by forming the electrolytic cell into a pipe-type electrolytic tube having electrical conductivity and corrosion resistance, the electrolytic cell can be formed into a thin and small pipe type, and at the same time, the electrolytic tube is formed of a cathode body to form an electrolytic cell. The volume is reduced, the configuration is simple, and since one silver electrode is used as the cathode, the number of installations is reduced, thereby making it possible to secure manufacturing and economical efficiency as well as handling of the manufacturing apparatus.

Second, by the first effect described above, even in the case of forming a small-capacity silver ion (Ag +) water production apparatus as well as a medium and large production apparatus, the length of the electrolytic tube serving as an electrolytic cell is increased, Installing several electrolytic tubes in any planar or three-dimensional arrangement can produce a large amount of instantaneous silver ions (Ag +) water at an appropriate concentration while being economical and small in volume.

Third, it is possible to use tap water, which is generally passed through the home, without using distilled and purified water, which is expensive, as in the prior art, and thus the production cost of silver ions (Ag +) water is low, and silver ions (Ag +) water. As it is not filled in the electrolytic cell during the manufacturing process, it is discharged immediately, and the silver ion (Ag +) ionization in the silver anode body is very fast, and the adjustment of the ion concentration of the silver ion (Ag +) water is controlled by controlling the supply voltage. It is easy, and ultimately, it is possible to manufacture silver ion (Ag +) water at an appropriate concentration quickly and economically, and when it is operated at the point where silver ion (Ag +) water is needed, high potency silver which maximizes sterilization and antibacterial activity immediately Ion (Ag +) water can be obtained.

Fourth, according to the method and apparatus of the present invention, it is possible to rapidly and rapidly produce a large amount of silver ions (Ag +) high-efficiency live silver ions (Ag +) water, thereby requiring storage of the produced silver ions (Ag +) water. It completely prevents the reduction of silver ion (Ag +) water efficiency due to storage, removes the storage cost of the storage tank, and also overcomes the conventional pharmaceutical field, and is very suitable for medical small-capacity sterilizing water as well as for washing, neck and shower water. It can be used conveniently and suitably, and depending on the configuration of the device, the range of application can be extended to the large-capacity sterilizing water input to the germ sterilization and pollution prevention device of the sewer, and the growing water of various crops.

Fifth, according to the present invention, since silver ions (Ag +) water can be produced quickly, economically, and continuously in large quantities, such as those used for tap water using general tap water when necessary, all conventionally provided silver ions ( Ag + is the most vulnerable of the water production apparatus, which has the effect that can completely solve the point that oxidization of silver ions (Ag +) that fall as sterilization and antibacterial over time after manufacture.

Claims (15)

An electrolytic tube in which a pipe having electroconductivity and corrosion resistance of a predetermined length capable of passing water, which is an electrolyte solution and silver ion (Ag +) water extraction raw water, is formed by a combination of an electrolytic cell and a cathode; A silver anode formed of a predetermined length of 99.99% silver rod or silver plate at least one of which is installed in the longitudinal direction at a predetermined distance from the inner wall of the electrolytic tube; A spacer of an electrical insulator which partially supports the silver anode while maintaining a predetermined distance from the circumference of the inner wall of the electrolytic tube; Only while water is passed through the electrolytic tube of the cathode formed by the electrolytic cell, the cathode (-) is used for the electrolytic tube of the cathode and the anode (+) for the silver anode. Silver ion water instantaneous production apparatus characterized in that it comprises a power supply control device for controlling and supplying at a constant voltage. The apparatus for instantaneous production of silver ionized water according to claim 1, wherein the electrolytic tube is composed of an 18-8 series STS 304 or STS 316 stainless steel containing 18% chromium and 8% nickel. The method of claim 1, wherein the spacer is composed of a tube of an electrical insulator having a porous structure in which an ionization action can be smoothly induced between the inner wall of the electrolytic tube and the silver anode while surrounding the silver anode. Silver ionized water instantaneous production apparatus, characterized in that. The power supply control device according to claim 1, wherein the power supply control device is a means for manually adjusting silver ion (Ag +) concentration of silver ion (Ag +) water to be manufactured according to a user and a user. Silver ionized water instantaneous production apparatus, characterized in that the configuration further comprises a supply voltage manual variable circuit that the user can arbitrarily select a predetermined supply voltage of a plurality of stages. The power supply control device according to claim 1, wherein the power control device is a means for automatically maintaining a concentration of silver ions (Ag +) of silver ions (Ag +) to be produced at a constant concentration. And a voltage automatic variable circuit for automatically correcting and increasing the supply voltage. According to claim 1, wherein the power supply control device, the water flow detection device for sensing the flow rate of the water entering the water inlet side of the electrolytic tube to supply power to the electrolytic tube and the silver positive electrode only when water is supplied over a certain flow rate Silver ionized water instantaneous production apparatus characterized in that it further comprises a. A plate-shaped base plate that can be attached to the wall; Corrosion-resistant stainless steel pipe, which is an electrolyte and can pass water, which is silver ion (Ag +) water extraction raw water, is formed by using an electrolytic cell and a cathode, and a predetermined distance is formed in two rows from the front of the base plate in two rows. Electrolytic tubes placed and fixed with an electroconductive fixing clip; A silver anode formed of a predetermined length of 99.99% silver rods or silver plates installed in the longitudinal direction at predetermined intervals from the inner wall of the respective electrolytic tubes; A porous tubular spacer for supporting the silver anode with electrical insulation while maintaining a predetermined distance from the inner wall of the electrolytic tube; A watering connecting pipe interconnecting the upper ends of the two rows of electrolytic pipes with a watertight sealing structure; Positive power supply means for connecting a positive (+) wire from a power control device by a silver positive electrode body and a watertight sealing structure built into the electrolytic tube on each of the upper left and right sides of the watering connector; Only while water is passed through the electrolytic tubes of the two rows of cathode bodies, the positive electrode (+) is applied to the silver anode, and the fixed clip is connected to the electrolytic tube of the cathode. Power control device for controlling and supplying The lower part of the two rows of electrolytic tubes are connected to each other by a watertight sealing structure and a part of the base plate protrudes to the outside of the lower end, and connected to the lower end of any one of the electrolytic tubes in the pipeline with a flow water detection device A water supply pipe connector, which is connected to a lower end of the other electrolytic pipe and is connected to a shower hose; The base plate is externally equipped with a standard for accommodating the electrolytic devices, and fixedly attaches a power control device electrically connected to the water flow detection device to a rear side, and on the front side, switches and operation pilots of the power control device are disposed. Silver ionized instant shower device characterized in that it comprises a shell-like exterior body. The silver ionized instantaneous shower device according to claim 7, wherein the electrolytic tubes have screw portions at upper and lower ends, and are arranged in two rows parallel to the water column at a predetermined interval on the left and right sides with respect to the base plate. The method according to claim 2 or 8, wherein the electrolytic tube is formed of 18-8 series stainless steel pipes containing 18% chromium and 8% nickel, having a diameter of 21.7 mm, an inner diameter of 16.7 mm, and a thickness of 2.5 mm. Silver ionized water instantaneous shower, characterized in that consisting of the left and right electrolytic tubes (30a, 30b) of the heat. The silver ionized instant shower device according to claim 7, wherein the electrolytic tube and the silver anode are installed at intervals of 5 mm between the outer diameter of the silver anode and the inner wall of the electrolytic tube. According to claim 3, The spacer is provided with a plurality of cross-shaped support piece 53 of the standard that is supported without being inserted into the inner wall of the left and right electrolytic tubes (30a, 30b), between the several constant standards Silver ionized instantaneous shower device, characterized in that the hole 52 is formed, the lower end 54 is blocked and the upper end is composed of a support tube 51 of an open porous structure. The structure of the irrigation connection pipe connecting the upper end of the left and right electrolytic pipes 30a and 30b in a watertight structure is a non-conductive synthetic resin material, and the two rows of left and right electrolytic pipes 30a ( 30b) has left and right downward connecting pipes 98a and 98b of a shape bent left and right and down while having a female screw threaded to the threaded portion 32, and the fixing base 103 of the base plate 101. It is fixed by a fixing clip 93 fixed to the positive and negative power supply with a watertight sealing structure on the left and right silver positive electrode rods 40a and 40b built into the left and right electrolytic tubes 30a and 30b, respectively, on both sides of the upper end. Silver ionized instantaneous shower device, characterized in that consisting of a watering connecting pipe (95) having wiring holes (96a, 96b) for connecting the lines (65a, 65b). The power supply device 60 and the positive power supply line 65b of claim 7, wherein the positive power supply connecting means is provided with respect to the wiring ports 96a and 96b provided at the upper left and right sides of the irrigation connector. Power clips 92a and 92b electrically connected to each other and the power clips 92a and 92b are elastically coupled to the outer surface and have watertightness on the outer surface of the wiring ports 96a and 96b. Screw-coupled electrically conductive wiring caps 97a and 97b, the inner surface of the conductive wiring caps 97a and 97b, and the left and right sides have a predetermined elasticity between the upper ends of the anode rods 40a and 40b. Silver ionized instant shower device, characterized in that consisting of a conductive spring (45). According to claim 7, wherein the water flow detecting device, the upper screw tube 72 is formed in the housing structure is screwed tightly to the lower end of the electrolytic tube, the screw inlet connected to the water supply pipe 81 at the lower end ( 71, having a water flow sensor 76 coupled to the watertight structure by the O-ring 79 laterally with respect to the middle flow channel, a fixing plate 77 for fixing it, and an inner wall of the water flow sensor 76 It is installed in the hinge structure 78 and the magnet (75a) is attached to the back side is installed freely up and down in the state attached to the hinge structure on the inner wall of the oil sensor (76), and when lowered to block the internal water flow pipe When the water rises at a certain pressure, the water flow sensing zone 75 and the water flow sensing zone 76 are rotated upward and upward by 90 degrees starting from the hinge structure 78, and the water flow sensing zone 76 is inserted into the water flow sensing zone 75. Is increased by the magnetic force of the magnet 75a. Silver ionized water instantaneous shower device, characterized in that consisting of a water flow detection device (70) having a reed switch (74) for connecting a power line to the furnace. In the method for producing silver ion (Ag +) water using the electrolysis method, an electroconductive pipe having a certain length through which water can pass is formed into an electrolytic tube of a cathode, and the electrolytic tube has a purity of 99.99 with a predetermined length. % In the electrolytic apparatus in which at least one silver material anode is provided in the longitudinal direction at least one at a predetermined distance from the inner wall of the electrolytic tube, water is used as the electrolyte and the inner wall of the electrolytic tube and the silver anode While passing around the outer surface of (Anode) while controlling the direct current of a constant voltage while water is passing, by electrolysis principle, silver ions (Ag +) generated in the silver electrode of the anode are dissolved in water, A method for instantaneous production of silver ion water, characterized by continuously producing an appropriate amount of silver ion (Ag +) water.