KR20000021182A - Method for managing water using ionization. - Google Patents

Abstract

PURPOSE: A method for managing waste water resolves and activates water using ionization to purify the water. CONSTITUTION: The method for treating waste water uses ionization. The device resolves water and activates to purify the water and to wash the pipe. Pipes tend to corrode by reacting with activated oxygen. Substances like corrosion will be accumulated at the inside of the pipe as scale. The method is composed of several pipes. Carbon sticks and copper sticks are installed gradually at the inside of the first pipe, which generates static electricity. The second pipe is also have carbon sticks and copper sticks in order. Ionized water will be resolved into detailed molecules, and the molecules' density will increase. Then, the water molecule will rotate rapidly, and the water will have activity. So, the method can prevent from corrosion.

Description

Ion water processor

The present invention relates to an ion water treatment device, and more particularly, to an ion water treatment device configured to purify the water by decomposing and activating the water passing through the pipe with an electrostatic field and to wash the inside of the water pipe. .

In general, pipes that transport water such as water pipes or boiler supply and drain pipes are oxidized by the active oxygen in the water reacting with the iron in the pipes. The substance is deposited and scale is generated in the tube, and thus water passing through the tube is also in an unsanitary condition because it contains iron oxide, impurities, and bacteria that are harmful to the human body.

Therefore, in order to solve such an unsanitary factor, in the past, a brush or the like, which is a cleaning tool, is introduced into the tube to remove rust or scale, or to replace the corroded tube with a new tube. Solved.

However, such a conventional method can solve the unsanitary factor of the work, but it requires a relatively large amount of time, manpower and equipment in the situation of work, for example, cleaning or replacing the tube, and again within a short period of time. There was a problem in that it was inefficient because it was necessary to repeat the operation of washing the tube or replacing it with a new tube.

The present invention has been proposed in view of the problems described above, the object of which is to purify water by ionizing the water passing through the tube by using an electrostatic field to be activated by finely decomposed water molecules, as well as the tube passing through the water It is to provide an ion water treatment device configured to clean the interior of the.

According to a feature of the invention, the carbon rod copper rod carbon rods in the interior of the first pipe at a predetermined interval and disposed electrostatic generating rods sequentially; An electrostatic generating tube in which carbon tubes, copper tubes, and carbon tubes are arranged at a predetermined interval on the outer circumferential edge of the second pipe; An insulation tube for blocking internal and external temperature transfer; A finishing element for preventing water from flowing between the static electricity generating tube and the heat insulating tube; A housing in which the electrostatic generating rod electrostatic generating tube insulating tube finishing element is inserted therein, and a ground portion in which an electrostatic generating rod is insulated from the copper tube of the electrostatic generating tube is grounded; The housing is connected to the tubular body, there is provided an ion water treatment device comprising a housing connector formed therein a support for supporting the electrostatic generating rod.

1 is an exploded perspective view showing an ion water treatment device according to an embodiment of the present invention.

Figure 2 is a cross-sectional view showing an assembled state of the ion water treatment device of the present invention.

3A and 3B are sectional views taken along line A-A and line B-B in FIG.

Figure 4 is a cross-sectional view showing that the zinc tube is included in the ion water treatment device of the present invention.

Figure 5 is a cross-sectional view showing an ion water treatment device according to another embodiment of the present invention. (Zinc tube is disposed in the central portion)

Figure 6 is an exploded perspective view showing an ion water treatment device according to another embodiment of the present invention.

FIG. 7 is a cross-sectional view illustrating an assembled state of the ion water processor shown in FIG. 6.

<Explanation of symbols for main parts of the drawings>

20: tube 100: static electricity generating rod

110: first pipe 120: carbon rod

130: copper rod 140: carbon rod

200: static electricity generating tube 210: second pipe

220: carbon tube 230: copper tube

240: carbon tube 250: pipe

260: carbon cylinder 261: insertion hole

270: copper cylinder 271: insertion hole

280: carbon cylinder 281: insertion hole

290: zinc pipe 300: heat insulation pipe

400: finishing element 500: housing

510: ground portion 520: hollow portion

540: insulation member 600: housing connector

610: support portion 700: zinc tube

800: finishing element 900: housing connector

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is an exploded perspective view showing an ion water treatment device according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing an assembled state of the ion water treatment device of the present invention, Figures 3a and 3b is a line AA and BB of Figure 2 It is a cross section.

As shown, the ion water treatment device 10 of the present invention includes a static electricity generating rod 100 sequentially disposed at predetermined intervals with a carbon rod 120, a copper rod 130, and a carbon rod 140 inside the first pipe 110. The carbon pipe 220, the copper pipe 230, the carbon pipe 240 are sequentially disposed at predetermined intervals on the outer circumference of the second pipe 210, and the static electricity generating pipe 200 is disposed therein ( 200 is inserted and the insulating tube 300 to block the temperature transfer inside and outside, the finishing element 400 to prevent water from flowing between the electrostatic generating tube 200 and the insulating tube 300, and the inside Electrostatic generating rod 100 Electrostatic generating tube 200 Insulation tube 300 Finishing element 400 is inserted and the ground portion 510 is grounded with the copper tube 230 of the electrostatic generating tube 200 in the middle portion The support part 610 which connects the formed housing 500 and the said housing 500 to the tubular body 20, and supports the said static electricity generating rod 100 inside. Is formed of a housing connector 600.

The static electricity generating rod 100 is formed in the longitudinal direction in the insertion hole 111 inside the first pipe 110, the carbon rod 120, copper rod 130, carbon rod 140 in the insertion hole 111 a predetermined interval. And are sequentially inserted and disposed, and the support cap 112 is supported at the end of the first pipe 110 while being supported by the support 610 of the housing connector 600 and at the same time blocking the end of the insertion hole 111. Are constructed in combination.

The static electricity generating tube 200 has a hollow portion larger than the diameter of the static electricity generating rod 100 to allow water to pass through the inside of the second pipe 210 and to be inserted into the static electricity generating rod 100. 211 is formed in the longitudinal direction, and the carbon pipe 220, the copper pipe 230, the carbon pipe 240 are sequentially coupled to the outer circumference of the second pipe 210 at predetermined intervals, and the second pipe ( The thread portion 212 is formed on the outer periphery of the end of the 210.

The carbon rods 120 and 140 and the copper rods 130 of the static electricity generating rod 100 are disposed at positions corresponding to the carbon tubes 220 and 240 and the copper tubes 230 of the static electricity generating tube 200. The copper rod 130 and the copper pipe 230 are formed of pure copper pure copper, the housing 500 and the housing connector 600 is formed of brass of copper and zinc alloy, the first pipe 110 And the second pipe 210 may be a tube formed of durable polytetrafluoroetylene so as not to be deformed with respect to low temperature or high temperature.

The heat insulation tube 300 is formed by forming a hollow portion 311 larger than the diameter of the static electricity generating tube 200 in the longitudinal direction so that the static electricity generating tube 200 is inserted therein, the static electricity generating tube It is possible to prevent the generation of moisture due to the temperature difference between the temperature of the water passing through the inside of the 200 and the external temperature, thereby suppressing deterioration of device performance.

The finishing element 400 has a through-hole 410 is formed in communication with the hollow portion 211 of the second pipe 210 therein, the threaded portion 212 of the second pipe 210 on one side of the inner circumference A screw portion 420 is formed to be fastened, and one side of the outer periphery is formed with a coupling step 430 fitted to an end of the hollow part 311 of the heat insulation tube 300, and the other side of the inner periphery flows in from the tubular body 20. The inclined portion 440 is formed so that the water is easily introduced into the hollow portion 211 of the static electricity generating tube 200.

The housing 500 has a hollow portion 520 which is greater than or equal to the diameter of the insulation tube 300 and the finishing element 400 so that the insulation tube 300 and the finishing element 400 are inserted and disposed therein. At the end, a screw portion 530 is formed, and a ground portion 510 for grounding the copper tube 230 and the housing 500 of the static electricity generating tube 200 is formed at the middle portion. 510 is a screw hole 511 is formed in the housing 500, the screw hole 511 is formed by coupling the ground bolt 512 formed of copper.

The housing connector 600 is formed with a through hole 620 through which water passes, and a screw part 630 fastened to the screw part 530 of the housing 500 is formed at one inner circumference of the through hole 620. And, the other inner edge of the through hole 620 is formed with a screw portion 640 is coupled to the end of the tubular body 20, the support cap 112 of the electrostatic generating rod 100 is formed in the central portion of the through hole 620 A support part 610 is formed to be supported. The support part 610 is coupled to the through hole 620 by a connecting rib 611, and a support cap of the electrostatic generating rod 100 is formed inside the support part 610. An insertion groove 612 is formed into which the 112 is inserted.

Meanwhile, a packing 650 is installed between the housing 500 and the housing connector 600 coupled to each other to prevent water leakage.

In some cases, as illustrated in FIG. 4, a zinc tube 700 having a through hole 710 communicating with the static electricity generating tube 200 is coupled between the housing 500 and the housing connector 600. The ion water processor 10 can be configured.

5 is a cross-sectional view showing an ion water treatment device according to another embodiment of the present invention.

As shown in the ion water treatment device 10 according to another embodiment of the present invention, the carbon rods 120, the copper rods 130, and the carbon rods 140 are disposed in the interior of the first pipe 110 at predetermined intervals. Generating rod 100 and a pair of second pipes 210 provided with a carbon tube 220 on the outer circumference of the electrostatic generator tube 200 is coupled in communication by the zinc tube 290, and the inside An electrostatic generating tube 200 is inserted and the insulating tube 300 to block the temperature transfer inside and outside, and the finishing element 400 to prevent water from flowing between the electrostatic generating tube 200 and the insulating tube 300 and The grounding part is inserted into the electrostatic generating rod 100, the electrostatic generating tube 200, the heat insulating tube 300, the finishing element 400, and is grounded with the copper tube 230 of the electrostatic generating tube 200 at an intermediate portion thereof. Housing 510 is formed, and the housing 500 is connected to the tubular body 20 to support the electrostatic generating rod 100 therein It consists of a housing connector 600 is formed with a support portion 610, a through-hole screw hole 291 is formed in the central portion of the zinc pipe 290, the zinc pipe on the outer periphery of the end of the second pipe (210) A screw portion 213 is fastened to the screw hole 291 of 290.

The ion water treatment device 10 including the zinc tube 290 as described above is such that the water passing through the second pipe 210 of the electrostatic generator tube 200 is directly contacted with the zinc tube 290 and flows into the electrostatic generator tube. When water flows into the 200, zinc ions eluted from the zinc tube 290 are dissolved in the water passed by the potential difference between the housing 500 and the zinc tube 290, which are brass, and flow together with the zinc ions. (20) The occurrence of rust and scale inside is suppressed.

FIG. 6 is an exploded perspective view illustrating an ion water processor according to still another embodiment of the present invention, and FIG. 7 is a cross-sectional view illustrating an assembled state of the ion water processor shown in FIG. 6.

As shown, the ion water treatment device 10 according to another embodiment of the present invention increases the cross-sectional area in contact with water so that more static electricity is generated, so that water treatment by ions can be more easily performed. The configuration is disposed between the pair of carbon cylinders 260 and 280 formed with a plurality of insertion holes 261 and 281 into which the pipe 250 is fitted, and the carbon cylinders 260 and 280 are disposed therein. Copper cylinder 270 is formed with a plurality of insertion holes (271) to be inserted into the pipe 250, and the carbon cylinder 260, the copper cylinder 270 and the carbon cylinder 260 at a predetermined interval in sequence A hollow part 520 is formed and a heat insulating member 540 is provided on the inner circumference of the hollow part 520 to block temperature transfer. A ground part 510 which is grounded with the copper cylinder 270 is grounded at an intermediate part. Is formed in the housing 500, the carbon cylinder 260, 280 and the insulating member 540 And a housing element 900 for preventing the end of the end from contacting water and a housing connector 900 for connecting the housing 500 to the tubular body 20.

The closing element 800 is formed with an insertion hole 810 into which the end of the pipe 250 is inserted, and on one surface water between the pipes 250 coupled to the insertion hole 810 of the finishing element 800. The filling groove 830 is formed to fill the mold 820 to prevent the leakage, and the coupling protrusion 840 is formed around the filling groove 830, and the hollow part of the housing 500 is formed. An end of the coupling protrusion 550 is formed at the end of the coupling protrusion 840. Between the coupling protrusion 550 of the housing 500 and the coupling protrusion 840 of the finishing element 800, the coupling protrusion 840 is fitted. The packing 560 is inherently configured to prevent leakage.

When described in detail with reference to Figure 2 the action of the ion water treatment device 10 of the present invention configured as described above.

As shown in FIG. 2, when water flows through the second pipe 210 of the static electricity generating tube 200 in which the static electricity generating rod 100 is installed, the water and the first pipe 110 and between the water and the second pipe The friction between the 210 causes static electricity to be generated in the first pipe and the second pipe, and the static electricity is accumulated in the carbon pipes 220 and 240 (+) and the carbon rods 120 and 140 and the copper. A high-pressure thin electrostatic field is formed in the direction perpendicular to the water flow between the carbon tubes 220 and 240 and the copper tube 230 while being discharged into the tube 230 (-) and the copper rod 130 (-). Water passing through the electrostatic field is ionized as in Scheme 1

^{_{H 2 O → H +: OH}} -

In this case, the static electricity generating rod 100 is to prevent the flow of water flowing through the static electricity generating tube 200 flows faster on the central portion than the portion in contact with the inner circumference of the second pipe 210, the static electricity generating tube 200 The flow rate of the water passing through the second pipe 210 of the) is made uniform so that the generation of static electricity more easily, the heat insulation pipe 300 is the internal temperature of the static electricity generating tube 200 through which water passes By maintaining it, the generation of moisture due to the temperature difference between the inside and the outside of the housing 500 is suppressed, thereby preventing the deterioration of the device performance.

In addition, the ionized water as described above is finely decomposed in the crystal structure of the water molecules, the finely decomposed water molecules by increasing the specific gravity is active while rotating more quickly in the front, rear, left and right direction inside the static electricity generating tube (200) This activated water is converted into strong water, and the activated water absorbs the active oxygen into the crystal structure of the water, thereby degrading the active force of oxygen contained in the water passing through the tube 20, which causes corrosion of the tube 20, and thus the tube body ( 20) In addition to inhibiting the formation of rust inside, the ion-activated water as described above generates a force to attract oxygen into the water, causing a reduction reaction as shown in Scheme 2, red blue (Fe ₂ O ₃ ) to black blue (Fe ₃ O ₄ ) to remove rust.

Further, the finely decomposed crystal structure of the water molecules are combined with atoms and molecules in the water there is the exercise to become a single, large crystal structure is given to the near solubility in pure water by such a phenomenon of water molecules OH ^-, H ⁺ The ions smoothly dissolve various minerals and organics in the water to remove and remove foreign substances or scales attached to the inside of the tubular body 20, as well as to suppress the growth of slime bacteria and bacteria contained in the water.

Meanwhile, as illustrated in FIGS. 4 and 5, the ion water processor 10 provided with the zinc tubes 700 and 260 is used to prevent rust from the zinc tubes 700 and 260 due to the potential difference between brass and zinc. Zinc ions having a bactericidal effect are eluted, and the zinc ions thus eluted dissolve bacteria inside the tubular body 20 through which water is passed, as well as sterilizing bacteria contained in the water with water passing through the static electricity generating tube 200. To prevent it from being generated or attached.

As described above, an electrostatic generating rod having a carbon rod and a copper rod therein, an electrostatic generating tube having a carbon tube and a copper tube on the outer circumference, an insulation tube surrounding the electrostatic generating tube, and an electrostatic generating tube and heat insulation The ion water treatment device of the present invention comprises a finishing element coupled to an end of the tube, a housing into which the heat insulating tube and the finishing element are inserted, and a housing connector connecting the housing to the tube, and the water and first pipe and the second pipe. By using the static electricity generated by the friction of the electrostatic field to generate the electrostatic field, and the water passing through the electrostatic field to ion-activated to remove this substance contained in the water as well as to sterilize the bacteria, This prevents rust from occurring inside the pipe to be transported and removes the scale already created inside the pipe. It has the effect that you want to allow to supply yet more hygienic clean water.

Claims (4)

An electrostatic generating rod 100 sequentially disposed at a predetermined interval between the carbon rods 120, the copper rods 130, and the carbon rods 140 in the first pipe 110; An electrostatic generator tube 200 in which carbon pipes 220, copper pipes 230, and carbon pipes 240 are sequentially arranged at predetermined intervals on an outer circumference of the second pipe 210; An insulation tube 300 for blocking internal and external temperature transfer; A finishing element 400 for preventing water from flowing between the static electricity generating tube 200 and the heat insulating tube 300; A housing 500 in which the insulation tube 300 and the finishing element 400 are inserted, and a ground portion 510 is grounded at a central portion thereof and is grounded with the copper tube 230 of the electrostatic generating tube 200; The housing 500 is connected to the tubular body 20, and a housing connector 600 including a support part 610 for supporting the static electricity generating rod 100 is included therein. The ion water treatment device according to claim 1, wherein a zinc pipe (700) is installed between the housing (500) and the housing connector (600). An electrostatic generating rod 100 sequentially disposed at a predetermined interval between the carbon rods 120, the copper rods 130, and the carbon rods 140 in the first pipe 110; A pair of second pipes 210 having a carbon tube 220 at an outer circumference thereof, the electrostatic generator tube 200 coupled to communicate with the zinc tube 290; An insulation tube 300 for blocking internal and external temperature transfer; A finishing element 400 for preventing water from flowing between the static electricity generating tube 200 and the heat insulating tube 300; A housing 500 into which the insulation tube 300 and the finishing element 400 are inserted, and the ground portion 510 which is grounded with the copper tube 230 of the electrostatic generating tube 200 in the middle portion is formed; The housing 500 is connected to the tubular body 20, and a housing connector 600 including a support part 610 for supporting the static electricity generating rod 100 is included therein. A pair of carbon cylinders 260 and 280 in which a plurality of insertion holes 261 and 281 into which the pipe 250 is fitted are formed; A copper cylinder 270 having a plurality of insertion holes 271 into which the pipe 250 is fitted; Inside the carbon cylinder 260, the copper cylinder 270 and the carbon cylinder 280 is formed a hollow portion 520 sequentially arranged at a predetermined interval, the temperature transfer to the inner circumference of the hollow portion 520 It is provided with a thermal insulation member 540 for blocking the housing 500 is formed in the middle portion is the copper cylinder 270 and the ground portion 510 is grounded; A finishing element 800 for preventing the carbon cylinder 260 and 280 and the insulating member 540 from contacting with water; Ion water processor, characterized in that it comprises a housing connector 900 for connecting the housing 500 to the tubular body (20).