KR20100076533A - Alkali ion water create a device using mg - Google Patents

Abstract

The present invention relates to an alkaline ionized water generating device using magnesium.

The present invention provides an alkaline ionized water generating device for generating ionized water by electrolyzing raw water introduced into an inlet, and discharging the generated ionized water to an outlet, comprising: a power supply for supplying a voltage of 0.5 to 24V; Press plate operating due to the pressure of the water flowing from the inlet portion, a spring provided on the upper portion of the press plate to act as a buffer of the press plate, the press plate and the spring to support the spring and formed between the inlet and the outlet A power switch including a switch and a permanent magnet installed on a side of the pressing plate; And a first electrode terminal and a second electrode terminal including a protrusion protruding to the outside of the insulating case, a spring supporting the protrusion, and a contact terminal in electrical contact with the spring, and turned on according to an operation of the magnet switch. A power supply including a circuit module including a magnetization switch turned on and turned off, and a light emitting part electrically connected to the first electrode terminal and the second electrode terminal to emit light; A conductive structure including magnesium (Mg) electrolyzed by a voltage supplied from the power driver; And a first conductive network electrically connected to the first electrode terminal and accommodating the conductive structure, a second conductive network electrically connected to the second electrode terminal and accommodating the first conductive network and the first conductive network. An insulating net disposed between the first conductive net and the second conductive net such that the net and the second conductive net are insulated from each other, the electrolytic net including the conductive structure and electrically connected to the power driver. Provided is an alkaline ionized water generating device using magnesium, which is configured to include.

According to the present invention, there is provided an alkaline ionized water generating apparatus using magnesium as a raw material, including an electrolysis network containing a conductive structure composed of magnesium as a main raw material, and a power driving unit driven to electrically connect the electrolysis network by hydraulic pressure of water. It is easy to use and easy to manage.

Description

Alkali Ion Water Create A Device Using Mg}

The present invention relates to a device for generating alkaline ionized water using magnesium, and more particularly, including an electrolysis network accommodating a conductive structure and a power driver driven to electrically connect the electrolysis network by hydraulic pressure of water. The present invention relates to a device for generating ionized water.

Alkaline ionized water contains a large amount of minerals that are beneficial to the human body compared to general water, and has excellent antibacterial and deodorizing effect and is used for various living waters. A conventional ionized water generating device includes a water supply device to which water is supplied, a conductive structure disposed in the water, and a power supply device electrically connected to the conductive structure.

The ionized water generating device generates ionized water by electrolytic decomposition of the conductive structure when the power is supplied to the conductive structure to elute ions in water. Typically, the material of the conductive structure is limited to one according to the completion of the ionized water generating device. In addition, since the rough shape is determined according to the size and shape of the water supply device, there is a problem in that the use of the conductive structure is limited, and thus various kinds of ionized water cannot be generated.

On the other hand, the ionized water generating device is configured to control the supply device and the power supply device, respectively. That is, since the configuration for supplying water and the configuration for supplying power are made separately, the power is turned on while the water is not supplied, or the supply of power is not immediately performed while the water is supplied. Since the power supply and the supply device are electrically connected by wires, etc., it is inconvenient to assemble and once assembled, there is a problem of separating the supply device and the power supply device.

In order to solve this problem, there is provided an alkaline ionized water generating device that is easy to use and easy to manage, including a power supply unit driven to electrically connect the electrolytic network by the water pressure of the electrolytic network containing the conductive structure. There is a purpose.

In order to achieve this object, an alkaline ionized water generating device for generating ionized water by electrolyzing raw water flowing into the inlet of the present invention, and discharging the generated ionized water to the extraction unit, the power supply for supplying a voltage of 0.5 ~ 24V; Press plate operating due to the pressure of the water flowing from the inlet portion, a spring provided on the upper portion of the press plate to act as a buffer of the press plate, the press plate and the spring to support the spring and formed between the inlet and the outlet A power switch including a switch and a permanent magnet installed on a side of the pressing plate; And a first electrode terminal and a second electrode terminal including a protrusion protruding to the outside of the insulating case, a spring supporting the protrusion, and a contact terminal in electrical contact with the spring, and turned on according to an operation of the magnet switch. A power supply including a circuit module including a magnetization switch turned on and turned off, and a light emitting part electrically connected to the first electrode terminal and the second electrode terminal to emit light; A conductive structure including magnesium (Mg) electrolyzed by a voltage supplied from the power driver; And a first conductive network electrically connected to the first electrode terminal and accommodating the conductive structure, a second conductive network electrically connected to the second electrode terminal and accommodating the first conductive network and the first conductive network. An insulating net disposed between the first conductive net and the second conductive net such that the net and the second conductive net are insulated from each other, the electrolytic net including the conductive structure and electrically connected to the power driver. Provided is an alkaline ionized water generating device using magnesium, which is configured to include.

In addition, in the present invention, the conductive structure 130 includes magnesium (Mg), and the concentration of magnesium (Mg) is maintained to be at least 1.0 mmol / dm ³ or less of the concentration of the entire conductive structure 130. Provided is an alkaline ionized water generating device using magnesium.

Alkaline ionized water generating device based on magnesium of the present invention as described above has the effect of preventing and treating diseases while promoting the growth of animals and plants by discharging alkaline ionized water by magnesium.

In addition, according to the present invention, by assembling the power drive unit and the electrolysis network by simply contacting the first electrode terminal and the second electrode terminal of the ionized water generating device with the first bolt terminal and the second bolt terminal, It is easy to assemble and separate the electrolysis network.

Further, according to the present invention, since the conductive structure is accommodated in the first conductive network, there is an effect that various types of conductive structures can be used within the range that can be accommodated in the first conductive network.

In addition, according to the present invention, the filtering net is provided in the water inflow portion of the electrolysis network has the effect of generating more clean ion water by filtering foreign matter.

In addition, according to the present invention, there is an effect that the conductive structure can be replaced at any time through the opening and closing of the cover support provided in the electrolysis network.

Hereinafter, an ionized water generating device according to the present invention will be described in detail with reference to the accompanying drawings and examples. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

First, the ionized water generating device according to an embodiment of the present invention will be described.

1 is a cross-sectional view showing an ionized water generating device according to a preferred embodiment of the present invention, Figure 2 is a cross-sectional view showing an electrode terminal of the ionized water generating device according to a preferred embodiment of the present invention, Figure 3 is a preferred embodiment of the present invention It is an exploded perspective view showing the electrolysis network of the ionized water generating device according to.

As shown in FIG. 1, the ionized water generating device 100 according to an embodiment of the present invention is driven by the pressure of the water flowing into the inlet 110 and the inlet 110 into which the water W is introduced. Power supply unit 120 for supplying a predetermined voltage, the conductive structure 130 is electrolyzed by the voltage supplied from the power driver 120, the electrolytic network 140 for receiving and electrolyzing the conductive structure 130, water It may include a withdrawal unit 150 for discharging the ionized water (WN) eluted by the ion particles and the outer case 160 surrounding the inlet unit 110 to the outlet unit 150.

The inlet 110 is a portion in which water (W), which is raw water, is introduced to generate ionized water, and is connected to a water pipe or a hose to receive raw water, and may be formed of a socket or a nipple. It can be installed to be connected to pipes or hoses.

The power driver 120 is a portion for substantially driving the ionized water generating device 100, and is configured to automatically supply electricity by hydraulic pressure of water flowing into the inlet 110.

The power driver 120 includes a power source 121, a magnetic switch 123, and a circuit module 125.

The power source 121 is installed inside or outside the ionized water generating device 100, and supplies the circuit module 125 with a predetermined voltage required to electrolyze the conductive structure 130. Here, the voltage supplied by the power source 121 may be within a range of about 0.5 to 24V (volts), but the present invention does not limit the magnitude of the voltage supplied from the power source 121, and the conductive structure to be electrolyzed. Of course, it can be changed according to the electrical characteristics of the 130.

In addition, the magnetic switch 123 serves to electrically connect the power supply 121 and the circuit module 125 to drive the circuit module 125 by the power supply 121, and includes a pressing plate 123a and a spring 123b. ), A spring pedestal 123c and a permanent magnet 123d.

On the other hand, the pressing plate 123a provided in the magnet switch 123 is connected to the inlet portion 110 through which water is introduced, and when the water flows into the inlet portion 110 for a predetermined time, it is pressed in the direction of inflow of water by hydraulic pressure. Lose.

In addition, the spring 123b is provided on the upper portion of the pressing plate 123a to act as a buffer of the pressing plate 123a. The spring pedestal 123c is formed between the lead portion 110 and the lead portion 150 to support the pressing plate 123a and the spring 123b.

Here, the spring support 123c supports the pressing plate 123a and the spring 123b so that they are no longer separated due to the hydraulic pressure of the water.

In addition, the permanent magnet 123d is assembled to the side of the pressing plate 123a and installed for magnetization of the circuit module 125. Substantially, when water flows in and the pressing plate 123a is pressed, the permanent magnet 123d is positioned substantially in line with the circuit module 125 to drive the circuit module 125.

The circuit module 125 includes a first electrode terminal 125a and a second electrode terminal 125b, a magnetization switch 125c, and a light emitting unit 125d.

The first electrode terminal 125a is a terminal for supplying a first voltage (or positive voltage) to the conductive structure 130 and is electrically connected to the first conductive network 141 which will be described later.

In addition, the second electrode terminal 125b is a terminal for supplying a second voltage (or negative voltage), and is electrically connected to the second conductive network 142.

As such, the circuit module 125 including the first electrode terminal 125a and the second electrode terminal 125b is preferably fixed to an insulating case (not shown) so as not to be exposed to water.

In addition, as illustrated in FIG. 2, the first electrode terminal 125a and the second electrode terminal 125b support the protrusion 210 and the protrusion 210 formed to protrude out of an insulating case (not shown). A spring 220, a contact terminal 230 electrically contacting the spring 220, and a screw part connected to the wire 240 to electrically connect the contact terminal 230 and the circuit module 125 ( 250).

Since the first electrode terminal 125a and the second electrode terminal 125b are preferably configured in the same shape, the electrode terminal illustrated in FIG. 2 according to the preferred embodiment of the present invention may be the first electrode terminal 125a. Alternatively, only one of the second electrode terminals 125b is illustrated.

Meanwhile, the protrusions 210 of the first electrode terminal 125a and the second electrode terminal 125b may be in elastic contact with the electrolysis network 140 to be electrically connected to the contact terminal 240, but is not limited thereto. .

The magnetization switch 125c is a switch electrically connected between the power source 121 and the circuit module 125 and is turned on or turned off in accordance with the operation of the magnet switch 123. That is, the magnetization switch 125a is magnetized by the permanent magnet 123d so that when the permanent magnets 123d are located in a straight line, the two terminals 1 and 2 are in contact with each other to allow electricity to flow.

When the power supply 121 is connected and a voltage is supplied to each of the first electrode terminal 125a and the second electrode terminal 125b, the circuit module 125 may have the first electrode terminal 125a and the second electrode terminal ( By causing the light emitting unit 125d electrically connected between 125b to emit light, the driving state of the circuit module 125 is displayed.

According to the present invention, at the same time water is supplied to the ionized water generating device 100, the power drive unit 120 automatically operates due to the hydraulic pressure of the water, and when the power source 121 is normally connected, the driving state is generated through the light emitting unit 125d. It is displayed that the ionized water is supplied.

Reference numeral A indicates that A 'is electrically connected to B'.

The conductive structure 130 is made of a conductive metal material and is a component that is accommodated in the electrolysis network 140 to be electrolyzed.

The conductive structure 130 is electrolyzed by a constant voltage (for example, 0.5 to 24V) to form ion particles, and the ion particles are eluted in water to produce relatively ionic particles. It is preferable to be composed of a material having excellent antibacterial and purifying effects to prevent reproduction.

In addition, the conductive structure 130 according to the present invention is composed of any one selected from copper (Cu), gold (Au), platinum (Pt), magnesium (Mg) and silver (Ag) or equivalent conductive material. Preferably, in the present invention, the conductive structure is formed by using magnesium (Mg).

Meanwhile, the magnesium (Mg) included in the conductive structure 130 is preferably maintained at 1.0 mmol / dm ³ or less of the entire conductive structure 130 so that the flow path of the ionized water generator 100 is not blocked.

That is, when alkaline water is generated by electrolysis and used as washing water, scale (Scale) precipitates in the electrolytic cell or the pipe, thereby blocking the flow path of the ionized water generating device 100, and thus, magnesium (Mg) It is preferable to maintain the concentration of at least 1.0 mmol / dm ³ of the concentration of the entire conductive structure 130.

In addition, the conductive structure 130 may be formed of a structure including a plurality of pores in order to improve the efficiency of generating the ion particles. That is, the conductive structure 130 can be contacted with water through a plurality of pores is widened, it is possible to discharge a large number of ion particles in a short time.

The conductive structure 130 may be formed in a substantially columnar shape, and may be formed in any one of a square pillar, a triangular pillar, and a circular pillar, and may include a sphere, an ellipsoid, an ingot, and a chip. It may be made of any one selected form, but is not limited thereto.

That is, since the conductive structure 130 according to the present invention is electrolyzed in the form accommodated in the electrolysis network 140, the size sufficient to be accommodated in the electrolysis network 140 is sufficient.

Electrolysis network 140 is formed to receive the conductive structure 130 to elute the electrolyzed ions particles in water, made of a conductive material, so that the electrolyzed ions particles in water can be eluted It is preferably formed in the form.

The electrolysis network 140 includes a first conductive network 141 for receiving the conductive structure 130, a second conductive network 142 for receiving the first conductive network 141, and a first conductive network 141. ) And an insulating net 143 that insulates the second conductive net 142.

In addition, the electrolysis net 140 is preferably configured to remove foreign matter in the water, including the sieve 144, the cover base covering the opening of the first conductive net 141 of the electrolysis net 140. It is preferable to support the conductive structure 130 including the 145 so as not to leave the first conductive network 141. However, it is not limited thereto.

In this case, the first conductive network 141 and the second conductive network 142 may be formed of the first electrode terminal 125a and the second electrode terminal through the first bolt terminal 141a and the second bolt terminal 142a, respectively. 125b) are each electrically connected.

Here, the first bolt terminal 141a and the second bolt terminal 142a are formed to have sizes corresponding to the sizes of the first electrode terminal 125a and the second electrode terminal 125b, respectively, so that electrical contact is made relatively accurate. To lose.

As shown in FIG. 3, the electrolytic network 140 accommodates the conductive structure 130 in the first conductive network 141 and sequentially the remaining second conductive network 142 to the cover base 145. Assemble with

The first conductive network 141 is formed in a pillar shape surrounding the outer circumferential surface of the conductive structure 130, and an opening 141b for accommodating the conductive structure 130 is formed in at least one surface of the first conductive network 141. .

Here, the opening 141b is sealed by the cover support 145, and at least one coupling protrusion 141c is formed in the opening 141b so that the cover support 145 and the first conductive network 141 are firmly secured. It is preferable to combine.

The first conductive network 141 is made of a material having excellent electrical conductivity and durability. For example, the first conductive network 141 may be made of a material including iron (Fe) or an iron alloy, but is not limited thereto.

In addition, at least one screw hole (not shown) formed to be electrically contacted with the first bolt terminal 141 is formed on one surface of the first conductive net 141. Accordingly, the first conductive network 141 and the conductive structure 130 are electrically connected to the first electrode terminal 125a to receive a first voltage (or positive voltage).

The second conductive net 142 is formed to accommodate the first conductive net 141 in which the conductive structure 130 is accommodated, and the second conductive net 142 is formed through the insulating net 143. It is formed to be electrically insulated from and spaced apart.

Accordingly, a short circuit during the supply of electricity to the first conductive network 141 and the second conductive network 142 may be prevented, thereby preventing a safety accident.

In addition, the second conductive net 142 is formed on at least one surface is formed with a coupling protrusion (142c) for coupling with the opening portion 142b and the cover support 145 to accommodate the first conductive net 141, At least one screw hole (not shown) may be further formed in the second conductive network 142 to be electrically contacted with the second bolt terminal 142a.

Accordingly, the second conductive network 142 is electrically connected to the second electrode terminal 125b to receive a second voltage (or negative voltage).

The second conductive net 142 may be formed of the same material and shape as the first conductive net 141, and the insulating net 143 may insulate the first conductive net 141 and the second conductive net 142. Is formed.

That is, the insulating net 143 is formed to surround the outer circumferential surface of the first conductive net 141 and an opening 143a is formed in one surface to accommodate the first conductive net 141. The insulating network 143 is preferably formed of an insulating material made of plastic or fiber, but is not limited thereto.

The strainer 144 is formed on the inlet 110 to filter foreign matters from the inflow water, and the foreign matters are not included in the ionized water discharged to the outlet 150.

The filter net 144 is preferably formed in the form of a relatively dense net compared to the first conductive net 141 and the second conductive net 142.

The cover pedestal 145 is formed to cover the openings 143a of the first conductive net 141 to the insulating net 143, and the coupling protrusions of each of the first conductive net 141 and the second conductive net 142 ( It comprises a coupling hole 145c coupled to 141c and 142c.

In addition, the cover support 145 is made to open the opening 143a of the first conductive net 141 to the insulating net 143 as necessary, so that the replacement operation of the conductive structure 130 is made relatively easy. .

The cover support 145 may be made of plastic or an equivalent material as the insulating material, but the material of the cover support 145 is not limited thereto.

The outlet 150 is a portion where ionized water is discharged and is connected to a shower head, a water pipe, a hose, and the like, and is formed to be connected to a shower head, a water pipe, a hose, and the like in the form of a bolt or nut like the inlet 110. .

The outer case 160 is formed in a substantially columnar shape to seal the inlet 110 to the outlet 150, and the outer case 160 includes an upper case 160a and a power driving unit surrounding the electrolytic network 140. It consists of a lower case 160b surrounding the 120.

Here, the upper case 160a and the lower case 160b may be made detachable as necessary so that the replacement of the conductive structure 130 or the repair of the power driver 120 may be easily performed.

For example, the upper case 160a and the lower case 160b may be connected in the form of sockets and nipples, respectively, but are not limited thereto.

As described above, the ionized water generating apparatus 100 according to the preferred embodiment of the present invention electrolyzes the conductive structure 130 to discharge the ionized water having functionalities such as antibacterial activity, and the first electrode terminal 125a and the first electrode terminal 125a. The power driver 120 and the electrolysis network 140 may be assembled by simply contacting the second electrode terminal 125a with the first bolt terminal 141a and the second bolt terminal 142a.

Therefore, the power supply unit 120 and the electrolysis network 140 can be assembled relatively simply as compared to soldering using a wire. In addition, since the power drive unit 120 or the electrolysis network 140 can be easily separated electrically, it can be conveniently used when a repair is necessary, and since the conductive structure 130 is accommodated in the first conductive network 141. Various types of conductive structures 130 may be used within the range that can be accommodated in the first conductive network 141.

In addition, the electrolysis net 140 according to the present invention is provided with a filter net 144 in the water inlet portion to increase the electrolysis efficiency by the generation of more debris, such as rust or moss, it is possible to create a cleaner ionized water As the foreign matter is further filtered, clean ionized water can be produced. In addition, the conductive structure 130 may be replaced at any time by opening and closing the cover support 145 provided in the electrolysis network 140. Overall, the ionized water generating device 100 is easy to use and manage, and can generate relatively clean ionized water.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention but to describe the present invention, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

1 is a cross-sectional view showing an ionized water generating device according to a preferred embodiment of the present invention,

2 is a cross-sectional view showing an electrode terminal of the ionized water generating device according to a preferred embodiment of the present invention;

Figure 3 is an exploded perspective view showing an electrolysis network of the ionized water generating device according to a preferred embodiment of the present invention.

 <Description of Symbols for Main Parts of Drawings>

100: ionized water generating device 110: inlet

120: power drive unit 125a: first electrode terminal

125b: second electrode terminal 130: conductive structure

140: electrolysis network 141: first conductive network

142: second conductive network 143: insulating network

144: sieve 145: cover base

Claims (2)

In the alkaline ionized water generating device for generating the ionized water by electrolyzing raw water flowing into the inlet portion, and discharges the generated ionized water to the outlet portion, Power supply for supplying a voltage of 0.5 to 24 V; Press plate operating due to the pressure of the water flowing from the inlet portion, a spring provided on the upper portion of the press plate to act as a buffer of the press plate, the press plate and the spring to support the spring and formed between the inlet and the outlet A power switch including a switch and a permanent magnet installed on a side of the pressing plate; And A protrusion protruding out of the insulating case, a spring supporting the protrusion, a first electrode terminal and a second electrode terminal including a contact terminal in electrical contact with the spring, and turned on according to an operation of the magnetic switch; A power supply including a circuit module including a magnetization switch turned on and turned off and a light emitting part electrically connected to the first electrode terminal and the second electrode terminal to emit light; A conductive structure including magnesium (Mg) electrolyzed by a voltage supplied from the power driver; And A first conductive network electrically connected to the first electrode terminal and accommodating the conductive structure, a second conductive network electrically connected to the second electrode terminal and accommodating the first conductive network and the first conductive network And an insulating net disposed between the first conductive net and the second conductive net such that the second conductive net is insulated from each other, the electrolytic net including the conductive structure and electrically connected to the power driver. Alkaline ionized water generating device using magnesium, characterized in that comprising a. The method of claim 1, The conductive structure 130 includes magnesium (Mg), and the concentration of magnesium (Mg) is characterized in that to maintain at least 1.0mmol / dm ³ or less of the concentration of the entire conductive structure 130 Alkaline ionized water generating device using magnesium.

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