KR20150097176A - Self power generating magnetic water purifier - Google Patents

Abstract

The present invention relates to a self-powered generating magnetic water purifier which includes: an entrance part including a first pipe member where a water path hole is formed to spray induced water in a direction; a magnetic part provided to generate electricity between a magnet installed to be rotated by the water pressure and a coil arranged around the magnet; and an exit part provided to collect and discharge water purified by the magnetic power and the electricity. Therefore, the magnet is rotated by the induced water pressure, generating the electricity as a linked action with the coil arranged peripherally; and furthermore, the flowing water is sterilized by turning on a UV lamp with the electricity and salts are absorbed by a first absorbing member.

Description

[0001] Self-generating magnetic water purifier [0002]

The present invention relates to a magnetically purified water purification apparatus, and more particularly, to a self-generated magnetization purification apparatus that is capable of generating electricity by rotating a magnet built in a water purification apparatus to nano particles of water while removing some harmful components contained in water .

The World Health Organization (WHO) says that drinking clean water can eliminate 80 percent of the disease. Heo Jun pointed out that 'Water is the source of life' and 'Water is the source of life' through 'East and West'. . Water has to do with all life activities, and it can not be objected that good or bad water affects the vital tissues, or life activities at the cellular level.

Generally, waste such as garbage is discharged from homes, factories, farms, etc., so that water with self-cleaning ability that is self-cleansing property over time is severely polluted and can not be used as drinking water directly. Of course, the fact that many ecosystems such as rivers and oceans are damaged is already well known.

As a result, various devices and methods have been used for the purification of water to clean the water, and researches for more efficient purification have been carried out steadily.

One example of such studies is a magnetizer that magnetizes water through the arrangement of N and S poles of permanent magnets or electric magnets. As shown in Figs. 1A to 1C, the magnetizing machine includes an inlet 10 into which water is introduced, a magnetization portion 20 in which the magnet 22 is embedded in the body 21, a discharge portion 30 through which water is discharged ).

Here, the inlet portion 10 is provided with a first pipe member 11 having a plurality of first flow holes formed therein to divide the supplied water around the magnets 22, and the discharge portion 30 is provided with water And a second pipe member 31 having a plurality of second flow holes for collecting and discharging the second flow holes. At this time, the first and second pipe members 11 and 31 have the same shape and structure, and are disposed corresponding to each other.

The magnetization part 20 is disposed between the inner surface of the body 21 and the magnet 22 and has a harmful property such as calcium (Ca), magnesium (Mg), iron (Fe) And an adsorption member 23 for adsorbing the components, particularly potassium bicarbonate.

The water is converted into magnetized water by the magnetic field of the magnet 22 in the magnetizing portion 20 while the water flows into the inlet portion 10 and is discharged to the discharge portion 30 through the periphery of the magnet 22 The adsorption member 23 is made to adsorb metal components and impurities.

However, merely flowing around the magnet 22 is insufficient to completely convert water into magnetized water, and there is no sterilizing ability. As time elapses, the metal components and impurities adsorbed on the adsorption member 23, Particularly, there is a problem that potassium carbonate is aggregated and falls into a large lump form.

KR0918827 10

In order to solve the above-described problems, the present invention is directed to a method of manufacturing an apparatus for generating electricity by rotating a magnet with a flow pressure of water, forming a plurality of perforated holes in a member to which potassium bicarbonate is adsorbed, It is an object of the present invention to provide a self-generated magnetizing water purification apparatus which is provided with an integral function and prevents the phenomenon of accumulation of impurities.

In order to achieve the above-mentioned object, the self-generated magnetizing water purifying apparatus according to the present invention comprises: an inlet portion including a first pipe member having a water passage for spraying inflow water in one direction; A magnetization portion adapted to generate electricity between a magnet provided to rotate by the pressure of water and a coil disposed around the magnet; And an outlet for collecting and discharging the magnetically cleaned and electrically purified water.

Here, the magnet is characterized in that one or more rotating blades are protruded outward from the outer surface so as to interfere with the water sprayed from the water channel.

Further, the rotary vane is characterized by being formed in an oblique or straight line with a height direction of the magnet.

Further, the rotary blades are higher in height than the other side, and the adjacent rotary blades are arranged in the same shape or in a symmetrical shape.

The magnetizing unit may further include a suction body having a magnet disposed therein and a third body having the suctioning mesh disposed therein.

Further, the coil may be wound on at least one fixing protrusion formed on the outer surface of the adsorption net, or may be attached so as to surround the outer circumference of the adsorption net, or may be attached to one or more of the granules along the outer circumference of the adsorption net .

In addition, the magnetization part is provided with an electrode plate so that the coil is positioned inside the magnet, the attraction network is disposed so that the magnet is located inside the electrode, and the electrode plate is disposed so that the attraction network is located inside. And a drain port is formed in the third body so that the water contained in the coil can be discharged. The electrode plate includes an AC / DC converter or a DC / DC converter, or a battery connected to the converter while storing the coil electricity, and sterilized by electrolysis by an electrode plate by electricity.

At this time, the adsorption network is characterized in that a plurality of perforation holes are formed in order to prevent aggregation of adsorbed potassium bicarbonate.

The magnetizing portion includes a first adsorption member installed to adsorb the salt and impurities contained in the water by the electricity generated by the magnet and the coil while the adsorption net is disposed therein, the UV ultraviolet LED mounted on the first adsorption member, And a second adsorption member arranged to adsorb the metal components and impurities remaining in the water while the adsorption member is disposed therein.

In addition, a DC / DC converter or a battery connected to the converter while charging the coil electric power is provided for converting electricity into electricity that can be used for the coil electricity generated in the coil, and salinity is adsorbed to the first adsorption member by electricity, And then sterilized.

The inlet has a first body formed with an inlet for the inflow of water, a bearing mounted on one side of the magnet for supporting the rotation of the magnet, a second body mounted between the first body and the third body with a bearing installed therein; And the first pipe member is installed to disperse the water introduced through the inlet through one or more water holes in one rotation direction and to spray the water on the magnets.

Here, the outlet includes a fourth body having an outlet for discharging water, a bearing mounted on the other side of the magnet for supporting the rotation of the magnet, a second body mounted between the third body and the fourth body, And a second piping member built in the fourth body to collect the water around the magnet through one or more water holes and flow to the outlet.

The first and second pipe members further include at least one channel groove formed at a bottom surface of the first and second pipe members so as to be inclined at a predetermined angle in a rotation direction. And a sphere is formed.

And the water channel is formed such that one side of the center of the first pipe member is inclined so that the floor area is smaller than the area of the opened upper surface.

The small self-generating type magnetizing water purifying apparatus according to the present invention comprises: an inlet portion through which water flows; A magnetization portion for generating electricity between a magnet provided to rotate in contact with the introduced water and a coil disposed around the magnet; And an outlet part for discharging water from the magnetizing part.

Here, the magnet is characterized in that one or more rotary blades protruding from the outer surface so as to interfere with the water introduced from the inlet portion and formed diagonally with respect to the height direction are formed.

The magnetizing portion may further include an adsorption network having at least one fixing protrusion formed on an outer circumference of the magnetizing portion so that the coil is wound, and a plurality of perforation holes formed therein.

In addition, the inlet portion and the outlet portion include a bearing mounted on both ends of the magnet to support the rotation of the magnet, and a second body having a bearing embedded therein. The magnetization portion includes a suction body and a coil, And a third body mounted on the base.

The small self-generating magnetized water purifying device according to the present invention includes a battery for storing the coil electricity generated in the coil, an AC / DC converter or a DC / DC converter for converting electricity of the battery, a body And an auxiliary water purifier equipped with a UV absorber and a UV absorber, wherein the first adsorbing member adsorbs the salts and impurities contained in the water when the electricity is supplied to the auxiliary water purifier, And the LED is lit to sterilize.

As described above, according to the present invention, the magnet is rotated by the hydraulic pressure of the inflowing water to generate electricity by the action of the coil and the coil disposed around the magnet, and the electric UV UV lamp is turned on to sterilize the flowing water And a function of adsorbing salinity by the first adsorption member is also added.

Further, this electricity is charged in a separate battery, and sterilization and salinity adsorption can be continued by using electricity charged for a short time which can not be generated by the magnet at the initial stage or the late stage of the purification apparatus.

Further, water is stirred by the rotating magnet, and metal components and impurities in the water are easily adsorbed to the magnet, the adsorption net, and the first and second adsorption members, thereby improving the water purification ability.

In addition, since a large number of perforated holes are formed in the adsorption net on which the impurities are adsorbed, it is possible to prevent the impurities adsorbed on the adsorption net, especially the potassium bicarbonate, from being aggregated.

Further, as the water is stirred, a strong magnetic field of the magnet penetrates and the water can be easily converted into nanoparticles, and the water is smoother and the amount of dissolved oxygen is increased.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate preferred embodiments of the invention and, together with the description, serve to further the understanding of the technical idea of the invention, It should not be interpreted.
1A is a side view showing a conventional magnetizing water purifier.
1B and 1C are a side sectional view and a cross-sectional perspective view showing the inside of the magnetizing purifier of FIG. 1A.
FIG. 2 is a side view illustrating a self-generating magnetized water purification apparatus according to a first embodiment of the present invention. FIG.
3A and 3B are a side sectional view and a cross-sectional perspective view showing the interior of the magnetically supple water purification apparatus shown in FIG.
4 is an exploded perspective view of the magnetizing water purification apparatus shown in Fig.
5A and 5B are a plan view and a side view of the first pipe member shown in FIG.
6A and 6B are a side sectional view and a cross-sectional perspective view showing a second embodiment of the present invention.
7A to 7C are a side sectional view, an interior view, and a cross-sectional perspective view showing a third embodiment of the present invention.
8A to 8D are a side view, a side sectional view, an internal view, and a cross-sectional perspective view showing a fourth embodiment of the present invention.
9A to 9C are a side view, a side sectional view and a cross-sectional perspective view showing a fifth embodiment of the present invention.
10 is a use state diagram of the small magnetically fixed apparatus of FIG. 9A.
11A and 11B are a side view and a side sectional view showing the auxiliary water purifier constructed by separately configuring the first adsorption member and the sterilizing LED of the magnetically water purified apparatus shown in FIG.
Fig. 12 is a state of use in which the auxiliary water purifier of Fig. 11A is installed in the magnetically cleaned water purification apparatus of Fig. 2. Fig.
FIG. 13 is a state in which the auxiliary water purifier of FIG. 11A and the small magnetizing water purification apparatus of FIG. 9A are mounted on the magnetizer of FIG. 1A.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the detailed description of known functions and configurations incorporated herein will be omitted when it may unnecessarily obscure the subject matter of the present invention.

≪ Embodiment 1 >

FIG. 2 is a side view illustrating a self-generating magnetized water purification apparatus according to a first embodiment of the present invention, FIGS. 3A and 3B are a side sectional view and a cross-sectional perspective view showing the inside of the magnetized water purification apparatus shown in FIG. FIG. 4 is an exploded perspective view of the magnetically purified water purification apparatus shown in FIG. 2, and FIGS. 5A and 5B are a plan view and a side view of the first piping member shown in FIG.

As shown in FIGS. 2 to 4, the self-powered magnetizing water purifying apparatus according to the present invention includes an inlet 100 through which water flows, a magnetizing unit 200 through which water is purified, (300). At this time, arrows in Fig. 3A indicate the flow direction of the water.

The inlet portion 100 includes a first body 110, a first pipe member 120, a second body 130, and a bearing 140.

Here, the first body 110 has an inlet 111 through which external water flows.

The first pipe member 120 is a member that injects the water introduced from the inlet 111 to the magnet 210 to rotate the magnet 210 of the magnetizing unit 200. More specifically, the first pipe member 120 is embedded in the first body 110, as shown in FIG. 3A, is positioned such that water is introduced from the inlet 111, Or dispersed in various places and fixed to the magnet 210 for spraying. The first piping member 120 allows the water to flow while forming a vortex, and the inside of the magnetizing and purifying apparatus can be always kept clean by the vortex of the water.

As shown in FIGS. 5A and 5B, a plurality of water channel grooves 121 are formed on the bottom surface of the first pipe member 120 at predetermined angles in a certain rotation direction, 121, respectively. At this time, the arrow in Fig. 5A indicates the flow direction of the water.

5A, the one side of the center of the first pipe member 120 is formed to be inclined so that the bottom surface area is smaller than the open top surface area. This is because the water introduced from the inlet 111 So that it can flow more easily to the water passage 122. In addition, the water channel 121 is formed by being inclined by a predetermined angle so as to discharge the water clockwise or counterclockwise, which causes the discharged water to be discharged in one direction. This is to cause the magnet 210 of the magnetizing portion 200 to rotate by the discharged water pressure. Details of the rotation of the magnet 210 are mentioned in the description of the magnetizing portion 200 described later.

The second body 130 is mounted on the lower portion of the first body 110, and the bearing 140 is embedded therein. Since the bearing 140 is provided on both sides of the magnet 210 to support the magnet 210 so that one side of the magnet 210 can be rotated, the second body 130 is also supported by the first body 110 and the third body The body 250 is mounted between the third body 250 and the fourth body 320. Meanwhile, in order to simplify the structure, the second body 130 may not be installed. In this case, the bearing 140 may be built in the first body 110 and the fourth body 320. That is, the first body 110 and the fourth body 320 may be made longer to be directly coupled to the third body 250, and the first body 110 and the fourth body 320 may be fixed to bearings (140).

3A to 4, the magnetization unit 200 includes a magnet 210, an adsorption net 220, a first adsorption member 230, a second adsorption member 240, and a third body 250 .

First, the magnet 210 has a predetermined height, and both ends of the magnet 210 are mounted on the second body 130 by the bearings 140, respectively. On the surface of the magnet 210, a plurality of rotary blades 211 formed diagonally with respect to the height direction are provided. Accordingly, when the water flowing in one direction through the first pipe member 120 pushes the rotary vane 211, the magnet 210 rotates in one direction via the bearing 140. [ Impurities such as metal components, minerals, and scale and rust are adsorbed on the magnets 210.

Of course, the rotary vane 211 may protrude vertically from the surface of the magnet 210, as in FIGS. 3A, 6A, 7A, and 8C, It may be more inclined and protruding. The rotary vane 211 is preferably equal to the number of water streams injected from the first pipe member 120, that is, the number of the water channel 122, Is preferably formed at a certain position.

One of the rotary blades 211 is disposed in a shape such that a protruded height lower than the upper portion of the magnet 210 is higher than a height of the magnet 210. The rotary blades 211 adjacent to the rotary blades 211, Are arranged in the opposite shape or arranged in the same shape.

At this time, the water pressure is preferably about 1 bar to induce the rotation of the magnet 210 for generating electricity, and the maximum water pressure is 3 bar or less, thereby avoiding unnecessary generation of surplus electricity. Here, if the water pressure is less than about 1 bar, a separate small pump may be installed outside the first body 110 to raise the water pressure to a level suitable for electricity generation.

Here, the magnet 210 is preferably a permanent magnet, for example, a super magnet, and it is preferable to use a neodymium magnet having the strongest magnetic energy on earth at the present time while using a rare earth element.

The line of magnetic force from the magnet 210 forms a strong magnetic field in the third body 250 by induction of a strong magnetic field based on Faraday's (MHD theory) magnetofluidics (MHD theory). The metal ions (Ca ++, Mg ++, SiO _2, etc.) contained in the water by the magnetic force lines generated in the magnet 210 are neutralized by neutral law (Ca, Mg, SiO _2, etc.) (Ca-, Mg-, SiO _2, etc.). Further, the ionized water ionized by the magnetic force is changed to alkaline, and the generation of bacterial bacterium contained in the water is suppressed by this change.

As the water flows due to the magnetic force of the magnet 210, the water molecule group is changed to micro-clustered water by the action of the magnetic field, and the water particles at this time have a diameter of nano Respectively. Here, the water purifying function of water is easy to remove bacteria by electrolysis at low voltage using electricity generated by the magnets 210 and the coils 221 because the water is nanoparticles, and the effect of the magnetic field waves and high frequencies is obtained.

On the other hand, the adsorption net 220 includes at least one fixing protrusion 222 having a magnet 210 disposed therein, a coil 221 wound around the outer circumference thereof, Respectively. Therefore, when the magnet 210 rotates, coil electricity is generated by the coil 221. The coil electricity thus generated is stored in a separate battery (not shown) and then used as an electricity of a stable DC voltage through an AC / DC converter or a DC / DC converter (not shown) UV ultraviolet LED 223 (or a lamp, hereinafter collectively referred to as an LED, see FIG. 10B) mounted on the first adsorption member 230 to activate an auxiliary water purification function such as sterilization do. In addition, hypochlorous acid (HOCI) and hypochlorite ions (OCI-) can be produced by electrolysis, electrophoresis, electric levitation, and potential difference generation using electricity.

Of course, coil electricity can also be used as a one-time through an AC / DC or DC / DC converter without accumulation. In addition, electricity accumulated in the battery can be sterilized for a short period of time, in which the magnetizing water purification apparatus does not operate, or electricity can not be generated by the magnet, such as the initial or late period of driving the magnetized water purification apparatus.

The adsorption net 220 is a member in which impurities such as metal components, minerals and rust and scale are adsorbed by the magnetic force of the magnet 210. Particularly, in order to prevent the adsorbed potassium bicarbonate from aggregating and lumping together, In which a plurality of perforated holes are formed.

In addition, the first adsorption member 230 is disposed so that the adsorption net 220 is located therein, and both ends thereof are fixed to the second body 130. The first adsorption member 230 is a member in which salinity in water is adsorbed by electricity generated by the magnets 210 and the coils 221. A UV ultraviolet LED for sterilizing action is mounted on the first adsorption member 230. The LED is installed to receive electricity generated by the magnet 210 and the coil 221. [ Accordingly, when electricity is generated and applied to the first adsorption member 230 and the LED, the salt contained in the water is adsorbed on the first adsorption member 230, and the LED is turned on to perform a sterilizing action. The first adsorption member 230 may be formed with a plurality of perforations.

The second adsorption member 240 is disposed so that the first adsorption member 230 is located inside and both ends are fixed to the second body 130. The second adsorption member 240 is a member for adsorbing residual metal components, minerals, and impurities that are not adsorbed by the adsorption net 220 and the first adsorption member 230. Specifically, the second adsorption member 240 is an aluminum alloy suitable for adsorbing potassium bicarbonate .

In addition, the third body 250 is disposed so that the second adsorption member 240 is positioned on the inner surface, and the second body 130 is mounted on both ends.

The discharge unit 300 is arranged symmetrically with respect to the inlet unit 100 so as to collect and discharge purified water from the magnetizing unit 200. The discharge unit 300 includes a bearing 140, a second body 130, a second pipe member 310, and a fourth body 320.

Here, the second body 130 is mounted on one end of the third body 250, and the bearing 140 is embedded therein. The bearing 140 is attached to one end of the magnet 210 and interlocks with the bearing 140 of the inlet 100 to support the magnet 210 so that the magnet 210 can rotate.

The second pipe member 310 is a member for collecting purified water flowing around the magnet 210. The second piping member 310 has the same shape as the first piping member 120 having a plurality of water channel grooves 121 formed on the bottom surface and a plurality of water channels 122 formed on the side surface thereof, Are arranged symmetrically with respect to the member (120). The second piping member 310 is mounted on the fourth body 320 or integrally formed on the fourth body 320. Accordingly, the water introduced through the plurality of water channels 122 is collected along the water channel 121 and then flows to the outlet 321 of the fourth body 320.

The fourth body 320 has an outlet 321 and is arranged to discharge the collected water through the second pipe member 310 through the outlet 321.

Meanwhile, the magnetizing water purifying apparatus of the present invention may further include a filter unit in addition to an integer by the magnetic force, and the filter unit may further remove various chemicals and heavy metals. At this time, the filter unit may be installed outside the first body 110 to purify the water and supply the purified water to the inlet 111 of the first body 110, purify the water flowing into the inlet 111, And may be installed inside the first body 110 to supply the member 120. [

In the following embodiments, the shape or structure of some of the constituent elements is changed on the basis of the first embodiment of Fig. 2. The same constituent elements having the same function as those of the first embodiment are denoted by the same reference numerals The description thereof will be briefly described as necessary, and the shape or structure of the changed components will be described in detail.

≪ Embodiment 2 >

6A and 6B are a side sectional view and a cross-sectional perspective view showing a second embodiment of the present invention.

Compared with the first embodiment of FIG. 2, the magnetizing water purifying apparatuses shown in FIGS. 6A and 6B are structurally different in that the structure of the coil 221 is changed, the first adsorption member 230 is excluded, Are the same.

The coil 221 has a height equal to or similar to the height of the adsorbing net 220 and is attached to the outer circumferential edge of the adsorbing net 220 at a predetermined interval with a standing image.

Since the first adsorption member 230 is excluded, only the second adsorption member 240 is disposed between the coil 221 and the third body 250. Of course, the first adsorption member 230 may be provided, and the installation or non-installation of the first adsorption member 230 is merely a structural change for suggesting various embodiments of the first embodiment.

All other functions including rotation of the magnet 210 due to water pressure and generation of electricity are the same as those of the first embodiment.

≪ Third Embodiment >

7A to 7C are a side sectional view, an interior view, and a cross-sectional perspective view showing a third embodiment of the present invention.

The magnetized water purification apparatus shown in FIGS. 7A to 7C also differs from the first embodiment of FIG. 2 in that the structure of the coil 221 is changed and the first adsorption member 230 is excluded, The functions and structures of the other components are the same.

Here, the coils 221 are ring-shaped to surround the outer periphery of the adsorption net 220 and are mounted at a predetermined interval in the height direction of the adsorption net 220. Of course, it may be mounted so as to surround the entire outer periphery of the adsorption net 220.

The removal and installation of the first adsorption member 230 is also the same as that described in the second embodiment, and the other components have the same function and structure.

<Fourth Embodiment>

8A to 8D are a side view, a side sectional view, an internal view, and a cross-sectional perspective view showing a fourth embodiment of the present invention.

8A to 8D are different from the first embodiment in that the structure in which the coil 221 is located inside the magnet 210 is different and the electrode plate 241 for electrolysis is embedded . Therefore, this structure will be described intensively and other components will be briefly described as necessary.

As shown in FIG. 8A, a drain port 131 is formed in the second body 130 on the side of the fourth body 320 so that water containing a large amount of contaminants, impurities and the like can be discharged.

8B to 8D, a plurality of coils 221 are fixed between the second bodies 130 on both sides, the magnets 210 are disposed such that the coils 221 are positioned inside the coils 221, An adsorption net 220 is disposed so that the magnet 210 having the wing 211 formed therein is located therein and an electrode plate 241 is disposed so that the adsorption net 220 is located inside.

Therefore, the magnet 210 rotates around the fixed coil 221 to generate electricity. The electricity is applied to the electrode plate 241, whereby water is changed into nanoparticles by magnetic force, and sterilization by electrolysis Is provided to improve the water purification effect on water.

Here, the first adsorption member 230 and the second adsorption member 240 may be disposed between the adsorption net 220 and the electrode plate 241.

<Fifth Embodiment>

FIGS. 9A to 9C are a side view, a side sectional view, and a cross-sectional perspective view showing a fourth embodiment of the present invention, and FIG. 10 is a use state view of the small magnetically fixed apparatus of FIG.

The magnetizing water purifying apparatus shown in Figs. 9A to 9C is a miniaturization of the magnetizing water purifying apparatus of the first embodiment. The magnetizing water purifying apparatus shown in Figs. 9A to 9C includes a magnet 210 having a rotary vane 211 formed on the outer periphery thereof, One or more fixing protrusions 222 protruding outward from the outer periphery of the adsorption net 220 to wind the coil 221 and the adsorption net 220 and the fixing protrusions 222 And a second body 130 mounted on both ends of the third body 250 with the bearings 140 mounted on both ends of the magnets 210. [ . At this time, the height of the magnet 210 is much smaller than that of the magnet 210 of the first embodiment.

2, the small magnetizing water purification device includes a first body 110, a first adsorption member 230, a UV ultraviolet LED, a second adsorption member 240, a fourth body 320, And the height and the diameter are reduced.

This small magnetizing water purification device can be used in a conventional magnetizer (see FIG. 1A) as shown in FIG. At this time, the first body 110 may be interposed to connect the small magnetized water purification apparatus and the magnetizing apparatus. Of course, the small magnetizing water purifying device can be used in a variety of conventional water purifiers including conventional filters and ionizers in addition to conventional magnetizers.

<Auxiliary water purifier>

11A and 11B are a side view and a side sectional view showing an auxiliary water purifier constructed by separately constituting the first adsorption member of the magnetically purified water purification apparatus shown in FIG. 2 and the sterilizing LED, FIG. 12 is a cross- Fig. 13 is a state of use in which the auxiliary water purifier of Fig. 11A and the small magnetizing water purification device of Fig. 9A are mounted in the magnetizing device of Fig. 1A.

The auxiliary water purifier shown in FIGS. 11A and 11B is manufactured by separately fabricating the first adsorbing member 230 and the UV ultraviolet LED excluding the small magnetizing water purification apparatus shown in FIG. 9A, The first adsorption member 230 and the LED 223 are installed in a distributed manner. The auxiliary water purifier may further include a second adsorption member 240 in addition to the first adsorption member 230 and the LED 223. These components are the same as those of the first embodiment.

In this auxiliary water purifier, electric power generated by a small magnetizing water purifier is applied, the first adsorption member 230 adsorbs the salt and impurities contained in water, and the LED 223 is turned on to perform a sterilizing action.

12, the auxiliary water purifier may be connected to the magnetizing water purifying apparatus of the first embodiment to improve the purification ability. Alternatively, the auxiliary water purifier may be connected to the conventional magnetizing unit as shown in FIG. It is possible. Of course, it is natural that these connections should be concluded to allow water to flow in and out.

As described above, those skilled in the art will appreciate that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are to be considered in all respects as illustrative and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included within the scope of the present invention.

100:
110: first body
111: entrance
120: first pipe member
121: Waterway home
122: Waterway
130: Second body
131: Drain
140: Bearings
200: magnetization part
210: magnet
211: rotating blade
220: adsorption network
221: Coil
222: Fixing projection
223: UV UV LED
230: first adsorption member
240: second adsorption member
241: electrode plate
250: Third body
300:
310: second pipe member
320: fourth body
321: Exit
400: Body.

Claims (19)

(100) including a first pipe member (120) having a water channel (122) formed therein to inject the inflow water in one direction;
A magnet (210) configured to rotate by the pressure of water, and a magnetization part (200) configured to generate electricity between the coil (221) disposed around the magnet (210); And
And a discharge unit (300) configured to collect and discharge the magnetically cleaned water and the purified water by the electricity of the magnet (210).
The method according to claim 1,
Wherein the magnet (210) is formed with at least one rotary vane (211) projecting outwardly on the outer surface thereof so as to interfere with water sprayed from the water passage (122).
3. The method of claim 2,
Wherein the rotary vane (211) is formed in a slanting line or a straight line in a height direction of the magnet (210).
The method according to claim 2 or 3,
Wherein the one side of the rotary vane is higher in height than the other side and the adjacent rotary vanes are arranged in the same shape or in a symmetrical shape.
The method according to claim 1,
The magnetization unit 200 further includes an adsorption network 220 in which the magnet 210 is located and a third body 250 in which the adsorption network 220 is installed to be located inside the magnetization unit 220 Self - powered magnetizing water purification device.
6. The method of claim 5,
The coil 221 may be wound on one or more fixing protrusions 222 protruding from the outer surface of the adsorption net 220 or may be attached to surround the outer circumference of the adsorption net 220, Wherein at least one of the adsorbing net (220) is attached in a granular form along the outer periphery of the adsorption net (220).
6. The method of claim 5,
The magnetization unit 200 is fixed to the magnet 210 by locating the coil 221 inside the magnet 210. The magnetization unit 220 is disposed such that the magnet 210 is positioned inside the magnetization unit 220, A drain port 131 is formed in the third body 250 so that water containing a large amount of contaminants and impurities, which are separated and purified, can be discharged from the inside of the electrode plate 241 ,
An AC / DC converter or a DC / DC converter (not shown) for converting electricity that can be used for the coil electricity generated in the coil 221 to apply electricity formed by the magnet 210 and the coil 221 to the electrode plate 241, Or a battery connected to the converter while charging the coil electricity,
Wherein the electrode plate (241) is sterilized by electrolysis by the electricity.
The method according to claim 5 or 7,
Wherein a plurality of perforated holes are formed in the adsorption net (220) to prevent aggregation of adsorbed potassium bicarbonate.

6. The method of claim 5,
The magnetization unit 200 includes:
A first adsorption member 230 disposed inside the adsorption net 220 to adsorb the salt and impurities contained in the water by the electricity generated by the magnet 210 and the coil 221, The UV ultraviolet LED 223 mounted on the member 230 and the second adsorption member 240 installed to adsorb the metal components and impurities remaining in the water while the first adsorption member 230 is disposed therein Wherein the self-generated magnetizing water purification device comprises a self-generated magnetizing water purification device.
10. The method of claim 9,
An AC / DC converter or a DC / DC converter or a battery connected to the converter while charging the coil electricity, for converting electricity that can be used for coil electricity generated in the coil 221,
Wherein the salt is adsorbed to the first adsorption member (230) by electricity, and the LED (223) is lighted to sterilize.
The method according to claim 1 or 5 or 7 or 9 or 10,
The inlet 100 includes a first body 110 having an inlet 111 for the inflow of water, a bearing 140 mounted on one side of the magnet 210 to support the rotation of the magnet 210, And a second body 130 mounted between the first body 110 and the third body 250 with the bearing 140 installed therein,
The first pipe member 120 is installed to disperse the water introduced through the inlet 111 through one or more water holes 122 in the direction of rotation of one of the first pipe member 120 and the second pipe member 120, Self - powered magnetizing water purification device.
12. The method of claim 11,
The discharge unit 300 includes a fourth body 320 having an outlet 321 for discharging the water, a bearing 140 mounted on the other side of the magnet 210 to support the rotation of the magnet 210, A second body 130 mounted between the third body 250 and the fourth body 320 with the bearings 140 installed therein and at least one water passage 122 And a second piping member (310) installed in the fourth body (320) so as to be collected through the first piping member (320) and flow to the outlet (321).
13. The method of claim 12,
The first and second piping members 120 and 310 further include at least one channel groove 121 formed at a bottom surface of the first and second piping members 120 and 110,
And a water channel (122) is formed in a side surface of the first and second pipe members (120, 310) so as to communicate with the water channel groove (121).
14. The method of claim 13,
Wherein the water channel groove (121) is formed such that one side of the center of the first pipe member (120) is inclined so that the floor area is smaller than the area of the opened top face.
An inlet (100) through which water flows;
A magnetization part 200 for generating electricity between the magnet 210 installed to rotate in contact with the incoming water and the coil 221 disposed around the magnet 210; And
And a discharge unit (300) for discharging water from the magnetization unit (200).
16. The method of claim 15,
The magnet (210) is formed with at least one rotary vane (211) protruding from the outer surface so as to interfere with the water introduced from the inlet (100) and formed diagonally with respect to the height direction. Water purification device.
16. The method of claim 15,
The magnetizing unit 200 further includes an adsorption net 220 having one or more fixing protrusions 222 formed on the outer circumference of the magnet 221 so as to wind the coil 221 and having a plurality of perforations formed therein. Self - powered magnetizing water purification device.
16. The method of claim 15,
The inlet part 100 and the discharge part 300 are respectively installed at both ends of the magnet 210 and include bearings 140 for supporting the rotation of the magnets 210 and second bearings 140, (130)
The magnetization unit 200 may further include a third body 250 having the absorption body 220 and the coil 221 disposed therein and having the second body 130 mounted on both sides thereof Self - powered self - priming water purifier.
19. The method according to any one of claims 15 to 18,
A battery for storing coil electricity generated in the coil 221, an AC / DC converter or DC / DC converter for converting electricity of the battery,
An auxiliary water purifier equipped with a body 400 mounted on the discharge unit 300 and a first suction member 230 and a UV ultraviolet LED 223 mounted in the body 400 Including,
Wherein the first adsorption member (230) adsorbs salt and impurities contained in water when the electricity is applied to the auxiliary water purifier, and the LED (223) is lit to sterilize the water.

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