KR20150104394A - Ionized Water Generating Apparatus - Google Patents

Abstract

The present invention relates to an ionized water producing device, which comprises: a tubular casing (3) forming an outer body; and a magnetic module (5) formed as two or more unit magnetic units (7) are stacked in the longitudinal direction. The unit magnetic unit (7) includes: a magnetic tube (11) for passing water, supplied to a water supply side, through a water inlet (21) to a water outlet side; a plurality of magnets (13) facing each other and surrounding the outer periphery of the water inlet (21); and a plurality of sealing rings (15) for sealing a gap between the inner circumferential surface of the casing (3) and the outer circumferential surface of the magnetic tube (11). The magnetic tube (11) has a swirl groove (26) depressed on top and bottom surfaces through which the water inlet (21) is opened, in order to form a swirl chamber (25) by coming into contact with the magnetic tube (11) of a neighboring unit magnetic unit (7). Accordingly, the cross-sectional area of flow of water discharged from the water inlet (21) is widened due to a swirl chamber formed between stacked unit magnetic units; and water smoothly flows while being magnetized as the entire flow line formed by the water inlet is rotated in a spiral direction.

Description

[0001] IONIZED WATER GENERATING APPARATUS [0002]

The present invention relates to an ionized water generating apparatus, and more particularly, to an ionized water generating apparatus that magnetizes water, that is, ionized by a magnet disposed on a conduit, through a shower channel or a conduit such as a water pipe.

Generally, an ionized water generating device magnetizes water on a conduit, such as a shower hole or a water pipe, which is directly used by a user, by using a magnet. Among them, a universal adapter equipped with a magnet module, 10-1081266.

According to the adapter 200, as shown in FIG. 1, a plurality of magnets 240 are inserted into both sides of the body 210 through a plurality of receiving grooves 230. However, when the adapter 200 needs only one pair of magnets, the remaining receiving grooves 230 are unnecessary spaces. On the other hand, when four or more magnets 240 are required, There were problems in utilization. Further, when the body 210 is manufactured again according to the number of stages of the magnets 240, there is also a problem in efficiency that additional time and cost are added, such as the necessity of manufacturing a new mold.

According to the ionized water generating apparatus disclosed in Korean Patent No. 10-1119731, as shown in FIG. 2, when two or more ionized water generating apparatuses 301 are connected in series, that is, In order to allow the water to flow, the holes 314 penetrating the upper and lower parts of the body 310 must be aligned in a straight line. This assembly is not only difficult to work, but also works in an angular direction about the axis There is a problem that a deviation may occur and a failure may be caused.

In addition, when the cover 320 is engaged with the body 310, it is difficult to work because the cover 320 must be forcedly inserted in order to prevent water from leaking out. Therefore, when the cover 320 is used for a long time, There was a problem that it could be broken.

In addition, in order to improve the function of the outflow side, when ceramic is charged, there is a problem that the ceramic adjacent to the outflow side may be damaged due to the water having increased in speed as it exits through the narrow passage 314.

KR 10-1081266 KR 10-1119731

The present invention has been proposed in order to solve the problems of the conventional ionized water generating apparatus as described above. By combining two or more unit magnetized units at a desired angle in a multi-stage combination to constitute one magnetized module, And an object thereof is to provide an excellent ionized water generating device.

Yet another object of the present invention is to provide an ionized water generating device capable of preventing breakage of ceramics when ceramic is charged in an adjacent portion in order to improve the functionality of water in order to be easily inserted into a channel of a conduit to produce effective ionization I have to.

In order to accomplish the above object, the present invention provides an air conditioner comprising: a tubular casing constituting an outer body; And a magnetization module inserted into the casing, the magnetization module being formed by stacking two or more unit magnetized portions in the longitudinal direction, wherein the unit magnetized portion extends from the water supply side to the water discharge side by the water discharge port, To the water outlet side through the water outlet; A plurality of magnets surrounding the outflow port of the water outlet while facing each other; And a plurality of sealing rings sandwiched between upper and lower ends of the outer circumferential surface of the magnetizing tube and sealing the gap between the inner circumferential surface of the casing and the outer circumferential surface of the magnetizing tube and the magnetizing tube is in contact with the magnetizing tube of the neighboring unit magnetizing portion And a vortex groove is recessed in the upper and lower openings of the water hole to form a swirl chamber.

In addition, the unit magnetization part may have a female or male concave / convex portion formed around the vortex groove in the upper and lower portions of the magnetizing tube so as to be engaged with the corresponding concave / convex portion of the adjacent unit magnetized portion, So as to have an angular phase difference with respect to the axis of the light source.

In addition, among the plurality of unit magnetizing units, the unit magnetizing unit located at the downstream side of the magnetization module is formed on the opposite side facing the water-flowing-out water side, and primarily absorbs the impact of water discharged from the water- And an attenuation plate.

In addition, it is preferable that the flow channel has a rectangular cross-sectional shape such that the distance between the magnets is kept close to the flow channel while keeping the cross-sectional area of the flow channel of the flow channel constant.

It is preferable that the unit magnetization unit further includes a plurality of shield plates which are superimposed on exposed portions of the magnets to suppress magnetic flux leakage.

The present invention also provides a self-supporting pipe inserted into a channel of a conduit, the self-heating pipe extending from a water supply side to an outflow side of the conduit by a water drain port and allowing water supplied to the water supply side to flow to the outflow side through the water drain; A plurality of magnets surrounding the outflow port of the water outlet while facing each other; A plurality of sealing rings sandwiched between upper and lower ends of the outer circumferential surface of the magnetizing tube and sealing between the inner circumferential surface of the casing and the outer circumferential surface of the magnetizing tube; And a plurality of shielding plates which are superimposed on exposed portions of the magnets to suppress magnetic flux leakage. The present invention also provides an apparatus for producing ionized water.

The magnetizing device may further include an attenuation plate formed on an opposite side of the water retention water side to primarily absorb the impact of water discharged from the water retention port.

According to the ionized water generating apparatus of the present invention, since the magnetization module disposed on the conduit for magnetizing water in the conduit is constituted by stacking a plurality of unit magnetized portions, the magnetization performance can be greatly enhanced.

Also, since the swirling chamber is formed between the stacked unit magnetizing portions, the water discharged from the water outlet of one unit magnetizing portion is vortexed due to the widened flow cross-sectional area, so that the water flows smoothly without clogging.

Further, since each unit magnetization part 7 is coupled to have a certain phase difference in the rotation direction of the axis center with respect to the other unit magnetization parts neighboring to the upper and lower sides, the wire formed by the whole water hole can rotate in the spiral direction Thus allowing water flowing through the magnetization module to flow more smoothly.

In addition, since the unit magnetizing portion disposed on the downstream side of the magnetization module has the attenuation plate on the opposite side to the water outlet side of the water outlet, the internal product such as ceramic particles filled on the water outlet side is damaged due to the high- It is possible to improve the endurance performance of the device.

Finally, unlike the conventional single magnetizers, the magnetizers are formed by one unit magnetization unit. Unlike the conventional single magnetizers, a flange is formed at the upper and lower ends of the magnetization tube, a sealing ring is wound around the flange, The waterproof performance and durability life of the device can be further improved.

1 and 2 are a perspective view and a longitudinal sectional view showing a conventional ionized water producing apparatus.
3 is a longitudinal sectional view of an ionized water generating apparatus according to an embodiment of the present invention.
4 is a longitudinal front view of the unit magnetized portion shown in Fig.
Fig. 5 is a plan sectional view of Fig. 4; Fig.
FIG. 6 is an exploded perspective view of FIG. 4;
Figure 7 is a bottom view of Figure 4;
8 is a longitudinal sectional view of an ionized water generating apparatus according to another embodiment of the present invention.
FIG. 9 is a bottom view of the unit magnetized portion shown at the lowermost one of the unit magnetized portions in FIG. 8; FIG.
10 is a longitudinal sectional view of an ionized water generating apparatus according to another embodiment of the present invention.
11 is a longitudinal sectional view of an ionized water generating apparatus according to another embodiment of the present invention.

Hereinafter, an ion generating device according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The ionized water generating apparatus of the present invention is installed on the flow path of the conduit 20 such as the shower head 10 as shown in reference numeral 1 in FIG. ).

3, the casing 3 is a part constituting the outer body of the ionized water generating apparatus 1, and is formed in the interior of various ducts 20 such as a showerhead or a water pipe, Coaxially. In the casing 3, a plurality of unit magnetizing portions 7 as shown in Fig. 4 are stacked and installed.

As shown in FIG. 3, the magnetization module 5 is a unit for substantially magnetizing water passing through the conduit 20 to ionize the magnetized water. The magnetization module 5 includes a plurality of unit magnetizations 7 And a plurality of unit magnetized portions 7 are inserted in the casing 3 along the flow path of the conduit 20, that is, in the longitudinal direction of the ionized water generating device 1, and laminated.

Each of the unit magnetizing portions 7 includes a magnetizing tube 11, a magnet 13 and a seal ring 15 as shown in Figs. 3 to 6, and the shielding plate 17 ).

The magnetizing tube 11 is a part of the columnar body of the unit magnetizing part 7 and accommodates the magnet 13 while lying on the flow path of the casing 3, So that the water supplied from the magnet 13 is discharged to the water outlet side through the space between the magnets 13. 3 to 6, the magnetizing tube 11 includes a body 18 forming a water hole 21 at the center so as to connect the water supply side and the water outlet side of the casing 3, And a pair of flanges 19 that are diametrically enlarged in the upper and lower radial directions of the body portion 18.

Accordingly, the magnetizing tube 11 flows the water supplied to the water supply side through the water outlet 21 to the water outlet side. The water outlet 21 keeps the magnet 13 facing each other while keeping the flow cross- And has a rectangular cross-sectional shape with a large aspect ratio as shown in order to make the distance between the pairs as close as possible. The magnetizing tube 11 is provided with a pair of receiving grooves 23 between the upper and lower flanges 19 in order to mount a pair of magnets 13 between the body portions 18 as described above. 3, the magnetizing tube 11 is stacked upside and down in the casing 3 to form a swirling chamber 25 between the adjacent magnetizing unit 7 and the magnetizing tube 11. [ And this swirl chamber 25 enlarges the water flow port 21 from the water supply side or the water outlet side to a cylindrical shape to further smooth the flow of water by the vortex phenomenon. To this end, a circular vortex groove 26 is recessed in the upper and lower surfaces of the respective flanges 19, in which the water flow holes 21 are opened. The vortex groove 26 also serves to reduce the thickness of the flange 19 of the magnetizing tube 11 which is injection-molded by a synthetic resin material.

4 to 6, the magnet 13 is provided between the upper and lower flanges 19 of the magnetizing tube 11 so as to magnetize water passing through the magnetizing tube 11, (23) so as to face each other with the space (18) therebetween. At this time, the polarities of the facing surfaces of the plurality of magnets (13) are opposite to each other so that the facing pairs are attracted to each other. Therefore, the magnet 13 surrounds the outer periphery of the water outlet 21, thereby magnetizing water passing through the water outlet 21.

The sealing ring 15 is a means for sealing between the magnetizing tube 11 and the casing 3. The sealing ring 15 is provided at the upper and lower ends of the outer circumferential surface of the magnetizing tube 11, So that the peripheral surface of the flange 19 of the magnetizing tube 11 and the inner peripheral surface of the casing 3 are tightly sealed. Therefore, the magnet 13 between the flanges 19 is held watertight by the seal ring 15. [

As shown in FIGS. 4 to 6, the shield plate 17 is a means for suppressing leakage of the magnetic flux of the magnet 13, for example, by a plurality of bent plates bent in a U- So that the magnetic flux of the magnet 13 is directed only toward the magnet 13 facing the magnet 13 so that the water passing through the water hole 21 is directed toward the magnet 13 Thereby effectively ionizing it.

Particularly, the unit magnetizing portion 7 according to the present invention is characterized in that the magnetizing tube 11 is provided with a cylindrical or male concave or convex shape around the vortex groove 26 of the flange 19, as shown in Figs. 4, 6, And the portions 27 and 28 are formed to correspond to each other. That is, when the female flange 19 is recessed and formed in the upper flange 19 as shown in FIG. 4, the male flange 19 is protruded and formed with the male flange 19. 3, the female grooves 27 of the upper flange 19 are formed in the shape of the male projections 28 at the lower end of the upper unit magnetization portion 7 when the plurality of unit magnetization portions 7 are stacked up and down. The male protrusion 28 of the lower flange 19 is engaged with the female groove 27 at the upper end of the lower unit magnetization portion 7. [

As shown in FIG. 3, when the unit magnetizing portions 7 are vertically coupled, if the water injecting holes 21 of all the unit magnetizing portions 7 are arranged long back and forth as shown in FIG. 7, The spherical member 21 as a whole does not cause any angular deviation in the rotational direction about the axis of the casing 3, as shown in Fig. However, when the unit magnetization part 7 coupled to the unit magnetization part 7 is rotated one click further than the unit magnetization part 7 below the unit magnetization part 7, the upper water hole 21 is connected to the lower water hole 21, the phase difference is generated in the angular direction by one click, and the stream formed by the total water flow port 21 is rotated in the spiral direction. At this time, the angular interval between the concave and convex portions 27 and 28 is referred to as one click.

On the other hand, as shown in Fig. 8, when the unit magnetization part 7 is positioned at the downstream side of the magnetization module 5 comprising a plurality of unit magnetization parts 7, 21) The attenuation plate 31 may be formed on the opposite side facing the water outlet side. At this time, since the ionized water generating apparatus 1 is inversely partitioned, the water supplied from the upper side in the drawing as shown by an arrow passes through the magnetization module 5 while flowing downward, and is discharged to the lower side of the drawing. 8 and 9, the damping plate 31 is integrally formed with the stationary ring body 33 in the form of a dome maintaining the same radius around the water outlet 21 side, The water discharged from the water outlet side of the water outlet 21 collides with the attenuating plate 31 as shown by the arrows. Therefore, as shown in FIG. 11, materials such as ceramic particles C filled under the casing 3 are prevented from direct collision with water, so that they are not damaged or deteriorated in performance.

The ionized water generating apparatus 1 according to the present invention is a still further embodiment of the ionized water generating apparatus 1 of the present invention in which a magnetizing machine 7 using only one of the unit magnetizing units 7 described above and a casing 3 surrounding the magnetizing machine 7, The casing 3 constitutes the outer body of the ionized water generating apparatus 1 as mentioned above. As shown in FIGS. 10 and 11, the casing 3 is provided with various conduits 20 ) Coaxially along the flow path.

The magnetizing device 7 is also composed of a magnetizing tube 11, a plurality of magnets 13, a plurality of sealing rings 15, and a plurality of shielding plates 17, Are the same as the respective corresponding configurations described above, and thus a detailed description thereof will be omitted. However, since the magnetizing device 7 is a single piece, the concave and convex portions 27 and 28 are not required. 8, an attenuation plate 31 is formed on the opposite side facing the water outlet 21 side in the water outlet 21, and the water outlet 21 So that the impact of the discharged water is likewise absorbed first.

Now, the operation of the ionized water generating apparatus 1 according to the preferred embodiment of the present invention will be described as follows.

As shown in FIG. 3, when water is supplied to the conduit 20 such as the shower head 10 into which the ionized water generating device 1 is inserted, water is primarily introduced into the inlet of the casing 3. Water flowing into the inlet of the casing 3 passes through the unit magnetizing portion 7 in the direction of the arrow and is magnetized, that is, ionized, primarily by the magnet 13 while passing through the water outlet 21. [ At this time, since the water port 21 has a long and thin rectangular cross-sectional shape, the distance between the opposed magnets 13 can be narrowed under the condition that the cross-sectional area of the flow channel is constant, and accordingly the magnetization performance of water can be increased accordingly. Further, since the shield plate 17 is superimposed on the outside of the magnet 13 to suppress magnetic flux leakage in the exposed portion, the magnetization performance can be further enhanced.

 On the other hand, the water discharged toward the water outlet side of the first water flow port 21 flows into the first swirl chamber 25, and the flow cross-sectional area is greatly increased to reach the first swirl chamber 25, thereby generating vortices , Resulting in smooth flow.

The water that has passed through the swirling chamber 25 passes through the unit magnetization part 7 at the uppermost end, that is, the most downstream side of the drawing, and is sufficiently magnetized in this process, Lt; / RTI >

As described above, the unit magnetization part 7 stacked up and down may have an angular phase difference in the upper and lower directions. In this case, since the entire water hole 21 extends while rotating in the spiral direction, As shown in FIG. 3, the flowing water 21 is arranged in a line, so that the flowing water flows more smoothly than the water forming the straight line.

4, 8, 10 and 11, each of the magnetizing tubes 11 has a sealing ring 15 fitted in the upper and lower ends of the outer peripheral surface, that is, around the upper and lower flanges 19, 4 and 6, each of the seal rings 15 is inserted into the female groove 27 of the flange 19 so as to be inserted into the female groove 27 of the flange 19, Therefore, when the magnetizing tube (11) is inserted into the casing (3), it is not greatly deformed or damaged, so that the durability life and airtight performance can be improved.

The magnetizing tube 11 or the single magnetizing tube 11 of the magnetizing device 7 located at the downstream end of the magnetization module 5 is connected to the attenuation plate 31 The damping plate 31 primarily absorbs the impact of the water discharged from the water outlet 21 so that the ceramic particles C filled in the vicinity of the magnetizing tube 11 It can be prevented from being damaged by the breakage.

1: ionized water generating device 3: casing
5: magnetization module 7: unit magnetization part, magnetizer
10: Shower head 11:
13: magnet 15: seal ring
17: shield plate 19: flange
20: conduit 21:
23: receiving groove 25: swirl chamber
26: Vortex grooves 27, 28: concave and convex portions
31: attenuation plate C: ceramic particle

Claims (7)

A tubular casing (3) forming an outer body; And
And a magnetization module (5) inserted into the casing (3) and formed by stacking two or more unit magnetized portions (7) in the longitudinal direction,
The unit magnetization unit 7 includes:
A magnetizing tube (11) extending from a water supply side to an outflow side by a water flow port (21) and causing the water supplied to the water supply side to flow to the outflow side through the water flow hole (21);
A plurality of magnets (13) surrounding the outer periphery of the water hole (21) while facing each other; And
And a plurality of sealing rings (15) sandwiched between upper and lower ends of the outer circumferential surface of the magnetizing tube (11) and sealing between the inner circumferential surface of the casing (3) and the outer circumferential surface of the magnetizing tube (11)
The magnetizing tube 11 has a vortex groove 26 formed in the upper and lower openings of the water hole 21 so as to form the swirl chamber 25 in contact with the magnetizing tube 11 of the neighboring unit magnetization part 7. [ ) Is concavedly embedded in the ionized water. The method according to claim 1,
The unit magnetization part 7 is provided with female or male irregular parts 27 and 28 around the vortex groove 26 on the upper and lower surfaces of the magnetizing tube 11, Wherein the ionized water generating device is configured to have an angular phase difference about the axis of the unit magnetizing part (7) and the casing (3) which are adjacent to each other and which are engaged with the corresponding concave and convex parts (27, 28). The method according to claim 1,
The unit magnetization part (7) located at the downstream end of the magnetization module (5) among the plurality of unit magnetization parts (7) is formed on the opposite side facing the water outlet (21) And an attenuation plate (31) for primarily absorbing the impact of water discharged from the spheres (21). The method according to any one of claims 1 to 3,
Wherein the magnetizing tube (11) has a rectangular cross-sectional shape such that a distance between the magnets (13) is kept close to the flow channel while maintaining a flow path cross-sectional area of the flow- Device. The method according to any one of claims 1 to 3,
Wherein the unit magnetization part (7) further comprises a plurality of shielding plates (17) superimposed on exposed portions of the magnets (13) to suppress flux leakage. Is inserted into the flow path of the conduit (20) and is led from the water supply side to the water outlet side of the conduit (20) by the water flow port (21) so that water supplied to the water supply side flows to the water outlet side through the water outlet A magnetizing tube (11);
A plurality of magnets (13) surrounding the outer periphery of the water hole (21) while facing each other;
A plurality of sealing rings (15) sandwiched between upper and lower ends of the outer circumferential surface of the magnetizing tube (11) and sealing between the inner circumferential surface of the casing (3) and the outer circumferential surface of the magnetizing tube (11); And
And a plurality of shielding plates (17) superimposed on exposed portions of the magnets (13) to suppress magnetic flux leakage. The method of claim 6,
The magnetizing device (7) further includes an attenuation plate (31) formed on an opposite side facing the water outlet (21) to absorb the impact of water discharged from the water outlet (21) And the ionized water generated by the ionized water generating device.

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