KR20130027817A - Apparatus for producing acid-ion water - Google Patents

Abstract

PURPOSE: An apparatus for manufacturing acid ionic water is provided to control the pH of the acid ionic water according to the uses thereof. CONSTITUTION: An apparatus for manufacturing acid ionic water comprises water bottle(200) and a control case(100). The water bottle is divided into a storage chamber(211) and a space part(221) which is an empty space, by an electrolyte unit(230) arranged in the lower part of the water bottle. The water bottle is removably mounted to the mounting groove of the control case.

Description

Acid ionized water production equipment {APPARATUS FOR PRODUCING ACID-ION WATER}

The present invention relates to an acidic ionized water production apparatus for producing acidic ionized water, and more particularly, to prepare an acidic ionized water producing acidic ionized water in a water bottle by means of an electrolyte means of a water bottle by mounting a water bottle in a control case and supplying a DC power source. Relates to a device.

Republic of Korea Patent No. 10-1020925 (registered March 2, 2011) "Ion water production apparatus" is introduced.

The ionized water production apparatus includes an ionization electrolysis cell formed to have a predetermined volume to ionize the supplied raw water, and provided at one side of the ionization electrolysis cell so that only one of the anode and the cathode is directly received with the raw water. An ionization electrode unit, an ionized water control unit for controlling the ionization electrode unit in accordance with the discharge of the ionized water and an operation unit for inputting a user's operation signal to the ionized water control unit.

Here, the ionization electrolytic cell is formed by selecting any one of a rectangular box or a polygonal plate shape, a circular plate shape and a cylindrical shape to form an ionization chamber having a predetermined volume therein, and the raw water inflow pipe into which raw water is introduced, and the crude oil An ion water discharge pipe having an ionized water discharge pipe through which ionized ionized water is discharged in an opposite direction to the inlet pipe, and an electrode mounting part installed at one side of the raw water flow direction from the raw water inlet pipe of the ionization chamber to the ionized water discharge pipe so that the outer surface is exposed to the outside. The ionization electrode unit is tightly coupled to one side of an ion diaphragm formed of any one of a proton exchange membrane and a polymer electrolyte membrane through which only ionic materials pass, thereby contacting raw water and allowing ionic materials to pass through. To the ion diaphragm on the opposite side of the raw contact electrode and the raw contact electrode. In combination is exposed to the outside is configured over the outside electrode and the oxygen and ozone or hydrogen gas formed to enable passage occurred in the ionization process.

However, the ionized water production apparatus is not a portable type and has a disadvantage in that it is a direct water method in which raw water is changed into ionized water (acidic or alkaline water) while passing through the ionized electrolytic cell, and thus pH concentration of the ionized water cannot be adjusted.

Accordingly, an object of the present invention is to mount the water bottle in the control case, the water of the water bottle is changed to the acidic ionized water by the electrolyte means of the water bottle, it is possible to adjust the pH concentration of the acidic ionized water according to the vaginal cleaning solution in the fresh water method To provide a portable acidic ionized water production apparatus.

Acid ionized water production apparatus according to the present invention for achieving the above object is divided into a storage compartment and the empty space of the water bottle is filled with water by the electrolyte means disposed at the bottom of the water bottle, the water bottle in the seating groove of the control case This detachably seated, negative and positive electrode terminals of the control case are connected to the first and second connecting terminals arranged on the bottom of the water bottle, the first connecting terminal is connected to the negative electrode plate of the electrolyte means, and The connecting terminal is connected to the positive electrode plate of the electrolyte means through the connecting terminal, so that the water filled in the reservoir of the water bottle is converted into acidic ionized water.

The control case is coupled to the upper case and the lower case, a printed circuit board is disposed between the upper case and the lower case, a seating groove is formed in the center of the upper case, the first case is provided with first to third operation buttons The negative electrode terminal and the positive electrode terminal are respectively mounted on the printed circuit board, and the negative electrode terminal and the positive electrode terminal protrude upward from the bottom surface of the mounting groove of the upper case.

The upper case is formed on the circumferential surface of the seating groove is formed with a coupling protrusion for inducing the water bottle is correctly seated, so that the water bottle is seated correctly in the seating groove of the control case, the coupling groove formed at the bottom of the water bottle is coupled to the coupling protrusion of the seating groove It is characterized by.

The water bottle is hollow and the upper end of the lower cup is coupled to the lower end of the main body formed with a storage compartment, the electrolyte means is mounted on the lower cup, the space formed in the storage compartment and the lower cup of the main body by the electrolyte means is isolated from each other, A gas discharge hole is formed, the lid is coupled to the top of the body in a spiral fastening manner, a gas discharge hole for discharging oxygen to the lid is formed, the disc which can be rotated around the projection shaft formed on both ends of the lid The member is disposed.

The electrolyte means has a lower housing having a hollow portion coupled to an upper housing having a hollow portion, and a perforated positive electrode plate, an electrolyte diaphragm, and a perforated net shaped negative electrode plate are disposed between the upper housing and the lower housing. The electrolyte membrane is disposed between the electrode plates.

One end of the first connection terminal is coupled to the upper end protrusion of the second connecting terminal, the lower bolt part of the second connection terminal is coupled to a nut formed on the other end of the first connection terminal, and the second connection terminal is the electrolyte. The upper bolt portion of the second connector is fastened to the nut formed on the upper horizontal portion of the third connector, and the upper horizontal portion of the third connector is lowered by the vertical portion. It is connected to the horizontal portion, characterized in that the lower horizontal portion is bonded to the negative electrode plate.

Thereby, the acidic ionized water production apparatus according to the present invention has the effect of adjusting the pH concentration of the acidic ionized water according to the vaginal cleaning solution in the fresh water method.

1 is a perspective view showing an acidic ionized water production apparatus according to the present invention, a state before the water bottle is seated in the control case.
Figure 2 is a perspective view of the acidic ionized water production apparatus according to the present invention, the water bottle is mounted on the control case.
3 is a cross-sectional view taken along the line AA of Figure 2 showing the acidic ionized water production apparatus according to the present invention.
4 is an enlarged detailed cross-sectional view of the electrolyte unit of FIG. 3.
5 is an exploded perspective view showing the electrolyte means.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

1 to 4, the acidic ionized water production apparatus according to the present invention is a storage chamber 211 and the empty space in which the water bottle 200 is filled with water by the electrolyte means 230 disposed at the bottom of the water bottle 200 The water bottle 200 is detachably seated in the seating groove 111 of the control case 100, and the negative and positive electrode terminals 131 and 132 of the control case 100 are separated. Connected to the first and second connecting terminals 241 and 242 disposed on the bottom surface of the water bottle 200, the first connecting terminal 241 is connected to the negative electrode plate 231 of the electrolyte means 230, As the second connecting terminal 242 is connected to the positive electrode plate 232 of the electrolyte means 230 through the connection terminal 250, the water filled in the storage chamber 211 of the water bottle 200 is changed into acidic ionized water.

As a result, the apparatus for producing acidic ionized water according to the present invention may carry only the water bottle 200 filled with the acidic ionized water, or transport the control case 100 and the water bottle 200 to a place of use. This is because the acidic ionized water produced by the acidic ionized water production apparatus according to the present invention is used for the vaginal cleaning solution with a pH of 3.5 to 4.5, the place where the water bottle 200 or the control case 100 and the water bottle 200 filled with the acidic ionized water are used. Because it is essential to transport them.

The control case 100 is coupled to the upper case 110 and the lower case 120, the printed circuit board 130 is disposed between the upper case 110 and the lower case 120, the upper case 110 The mounting groove 111 is formed at the center of the upper case 110, and the first to third operation buttons 135, 136, and 137 are provided on the upper case 110, and the negative electrode terminal 131 is disposed on the printed circuit board 130. The positive electrode terminal 132 is mounted, so that the negative electrode terminal 131 and the positive electrode terminal 132 protrude upward from the bottom surface of the mounting groove 111 of the upper case 110.

The upper case 110 has a coupling protrusion 112 that guides the water bottle 200 to be seated correctly on the circumferential surface of the seating groove 111, the water bottle 200 is seating groove 111 of the control case 100 In order to be seated correctly), a coupling groove (not shown) formed at the bottom of the water bottle 200 is coupled to the coupling protrusion 112 of the mounting groove 111.

In addition, the control case 100 to select any one of the first to third operation buttons 135, 136, 137 according to the amount of water (120ml, 240ml or 360ml) filled in the water bottle 200. It is. That is, when the amount of water to be filled in the water bottle 200 is 120ml, the first operation button 135 is selected, it takes about 5 minutes to produce acidic ionized water of pH 3.5 ~ 4.5, the water bottle 200 When the amount of water to be filled is 240ml, the second operation button 136 is selected, it takes about 8 minutes to produce acidic ionized water of pH 3.5-4.5, and the amount of water filled in the water bottle 200 is 360ml , The third operation button 137 is selected, it takes about 12 minutes to produce acidic ionized water of pH 3.5 ~ 4.5. Therefore, the pH of the acidic ionized water can be adjusted in proportion to the electrical energy and time.

The water bottle 200 is hollow and the upper end of the lower cup 220 is coupled to the lower end of the body 210, the storage compartment 211 is formed, the electrolyte means 230 is mounted on the lower cup 220, the electrolyte means ( The storage compartment 211 of the main body 210 and the space 221 formed in the lower cup 220 are separated from each other by 230, and a gas discharge hole (not shown) is formed in the lower cup 220. The lid 260 is coupled to the top of the 210 in a spiral fastening manner, and a gas discharge hole 261 for discharging oxygen (including ozone) is formed in the lid 260, and the top of the lid 260 is formed. A disc member 265 that can be rotated about a projection shaft (not shown) formed at both ends is disposed.

As a result, water filled in the storage chamber 211 of the main body 210 by the electrolyte means 230 is converted into acidic water, and oxygen is discharged to the outside through the gas discharge hole 261 of the lid 260. Hydrogen is discharged to the outside through the gas discharge hole in the lower cup (220).

4 and 5, the electrolyte means 230 has a lower housing 235 having a hollow portion 235a coupled to an upper housing 234 having a hollow portion 234a, and an upper housing 234. The positive electrode plate 232 of the perforated network shape, the electrolyte diaphragm 233, and the negative electrode plate 231 of the perforated network shape are disposed between the lower housing 235 and the positive electrode plate 232 and the negative electrode plate 231. The electrolyte diaphragm 233 is disposed in between.

As a result, the water supplied to the water bottle 200 is in contact with the positive electrode plate 232, but is not in contact with the negative electrode plate 231 by the electrolyte diaphragm 233, thereby oxidizing the positive electrode plate 232. The water is acidified and oxygen is generated by the reaction, and a small amount of hydrogen gas is generated in the negative electrode plate 231.

The upper housing 234 has a ring groove 234b formed on an outer circumferential surface thereof, and an O-ring 236 is mounted on the ring groove 234b.

As a result, when the upper housing 234 is in close contact with the inner circumferential surface of the lower cup 220 of the water bottle 200, the water filled in the storage compartment 211 of the water bottle 200 is sealed by the O-ring 236. Blocking the flow into the cup 220.

The lower housing 235 has a mounting protrusion plate 235b formed therein, and a mounting groove 235c is formed at a lower surface of the mounting protrusion plate 235b, so that the second connecting terminal 242 is mounted on the mounting groove 235c. The top protrusion 242a of the) is fixed.

The first connecting terminal 241 is formed with a concave groove 241a in the lower surface, and the upper convex portion 131a of the negative electrode terminal 131 is fitted into the concave groove 241a.

The second connecting terminal 242 has a concave groove 242a formed at a lower surface thereof, and the upper convex portion 132a of the positive electrode terminal 131 is fitted into the concave groove 242b.

One end of the first connection terminal 251 is coupled to the upper end protrusion 242a of the second connecting terminal 242, and the nut terminal 251a formed at the other end of the first connection terminal 251. The lower bolt portion 252a of the second connector 252 is fastened to the second connector 252, and the second connector 252 penetrates the upper housing 234 of the electrolyte means 230 to protrude above the upper housing 234. The upper bolt portion 252b of the second connection terminal 252 is fastened to the nut portion 253b formed on the upper horizontal portion 253a of the third connection terminal 253, and the upper horizontal portion of the third connection terminal 253 is horizontal. The portion 253a is connected to the lower horizontal portion 253d by the vertical portion 253c, and the lower horizontal portion 253d is joined to the negative electrode plate 231.

As such, although the second connecting terminal 242 is electrically connected to the negative electrode plate 231 through the connection terminal 250, water filled in the storage chamber 211 of the water bottle 200 flows into the lower cup 220. It can't be.

100: control case 200: water bottle
230: electrolyte means

Claims (6)

The water bottle 200 is divided into a storage chamber 211 in which water is filled by the electrolyte means 230 disposed at the bottom of the water bottle 200 and a space 221 which is an empty space, and a seating groove of the control case 100. The water bottle 200 is detachably seated on the 111 so that the negative and positive electrode terminals 131 and 132 of the control case 100 are disposed on the bottom surface of the water bottle 200. 241 and 242, the first connecting terminal 241 is connected to the negative electrode plate 231 of the electrolyte means 230, and the second connecting terminal 242 is connected to the electrolyte means through the connection terminal 250. By connecting to the positive electrode plate 232 of the 230, the acid ionized water production apparatus, characterized in that the water filled in the storage compartment 211 of the water bottle 200 is converted into acidic ionized water.
The method of claim 1,
The control case 100 is coupled to the upper case 110 and the lower case 120, the printed circuit board 130 is disposed between the upper case 110 and the lower case 120, the upper case 110 The mounting groove 111 is formed at the center of the upper case 110, and the first to third operation buttons 135, 136, and 137 are provided on the upper case 110, and the negative electrode terminal 131 is disposed on the printed circuit board 130. The positive electrode terminal 132 is mounted, respectively, the negative electrode terminal 131 and the positive electrode terminal 132 is an acidic ionized water production apparatus, characterized in that protruding upward from the bottom surface of the mounting groove 111 of the upper case 110 .
The method of claim 2,
The upper case 110 has a coupling protrusion 112 that guides the water bottle 200 to be seated correctly on the circumferential surface of the seating groove 111, the water bottle 200 is seating groove 111 of the control case 100 In order to be seated correctly), the acidic ionized water production apparatus, characterized in that the coupling groove formed on the bottom of the water bottle 200 is coupled to the coupling protrusion 112 of the seating groove (111).
The method of claim 1,
The water bottle 200 is hollow and the upper end of the lower cup 220 is coupled to the lower end of the body 210, the storage compartment 211 is formed, the electrolyte means 230 is mounted on the lower cup 220, the electrolyte means ( The storage compartment 211 of the main body 210 and the space portion 221 formed in the lower cup 220 are separated from each other by 230, and a gas discharge hole is formed in the lower cup 220, and an upper end of the main body 210 is formed. The lid 260 is coupled in a spiral fastening manner, and a gas discharge hole 261 for discharging oxygen is formed in the lid 260, and is rotated about a protrusion shaft formed at both ends of the lid 260. Acid ion water production apparatus, characterized in that the disc member 265 is disposed.
The method of claim 1,
The electrolyte means 230 has a lower housing 235 having a hollow portion 235a coupled to an upper housing 234 having a hollow portion 234a formed therein, and a perforated network between the upper housing 234 and the lower housing 235. The positive electrode plate 232, the electrolyte diaphragm 233, and the perforated negative electrode plate 231 are disposed, and the electrolyte diaphragm 233 is disposed between the positive electrode plate 232 and the negative electrode plate 231. Acid ionized water production apparatus, characterized in that.
The method of claim 1,
One end of the first connection terminal 251 is coupled to the upper end protrusion 242a of the second connecting terminal 242, and the nut terminal 251a formed at the other end of the first connection terminal 251. The lower bolt portion 252a of the second connector 252 is fastened to the second connector 252, and the second connector 252 penetrates the upper housing 234 of the electrolyte means 230 to protrude above the upper housing 234. The upper bolt portion 252b of the second connection terminal 252 is fastened to the nut portion 253b formed on the upper horizontal portion 253a of the third connection terminal 253, and the upper horizontal portion of the third connection terminal 253 is horizontal. The unit 253a is connected to the lower horizontal portion 253d by the vertical portion 253c, and the lower horizontal portion 253d is bonded to the negative electrode plate 231.

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