JP2015044136A - Electronic water generator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electronic water generator capable of producing activated water by exposing water to many strong magnetic fields.SOLUTION: An electronic water generator 10 has: a first forward flow channel part 31 in which water flows in a forward flow direction 4; a backward flow channel part in which water from the first forward flow channel part 31 flows in a backward flow direction 5; and a second forward flow channel part 34 disposed in parallel with the first forward flow channel part 31, in which water from the backward flow channel part flows in the forward flow direction 4; inside a cylindrical member 20. Permanent magnets 50 are juxtaposed in the direction crossing the water flow direction, across each of the forward flow channel parts 31 and 34.

Description

  The present invention relates to an electronic water device that generates activated water by passing a magnetic field.

  Conventionally, for example, a water activation device described in Patent Document 1 has been proposed as a method of generating a magnetic field in a pipe by sandwiching a water pipe or the like between permanent magnets and activating water through the magnetic field. According to this device, the water pipe is sandwiched between the S pole and the N pole that are opposed to each other. It is considered that the water passing through the magnetic field generated between the S pole and the N pole contains more electrons in the water molecule than before passing, and is activated with a smaller cluster.

Japanese Patent No. 3469541

  It is considered that the above-described activation of water further improves the effect by increasing the strength of the magnetic field to be passed. Accordingly, an object of the present invention is to provide an electronic water device capable of generating activated water by exposing water to many strong magnetic fields.

  In order to achieve the above object, an electronic water device according to the present invention is provided with a cylindrical member in which a plurality of flow passage portions through which water flows are formed, and the flow passage portion has a first passage through which the water flows in a forward flow direction. One forward flow path section, a reverse flow path section in which the water flowing through the first forward flow path section flows in a reverse flow direction, and the water that is arranged in parallel with the first forward flow path section and flows through the reverse flow path section A second forward flow path portion that flows in the forward flow direction, and is arranged in parallel in a direction that intersects the direction in which the water flows, and each of the first forward flow path portion and the second forward flow path portion. The present invention is characterized in that a plurality of permanent magnets arranged with being sandwiched are provided.

  In the electronic water device according to the present invention, the reverse flow path portion is formed in the second forward flow path portion and the downstream blocking plate provided facing the outlet portion formed in the first forward flow path portion. It is characterized by comprising an upstream blocking plate provided to face the inlet portion, and an area partitioned by the downstream blocking plate and the upstream blocking plate.

  In the electronic water device according to the present invention, an interval between the permanent magnets disposed with the first forward flow path portion interposed therebetween, and an interval between the permanent magnets disposed with the second forward flow passage portion interposed therebetween is about 0.5 mm. Is about 8 mm.

  In the electronic water device according to the present invention, six permanent magnets are arranged in parallel in the direction in which the water flows and are arranged in parallel in a direction intersecting the direction in which the water flows. And it is arrange | positioned on both sides of said 2nd forward flow path part, It is characterized by the above-mentioned.

  The electronic water device according to the present invention has the above-described configuration. With this configuration, water is exposed to the magnetic field in the first forward flow path part, then flows backward through the reverse flow path part, and is further exposed to the magnetic field in the second forward flow path part. Therefore, activated water can be generated by exposing water to a large number of magnetic fields in a limited space inside the cylindrical member.

  Further, with the configuration described above, the vector amount is added to the magnetic field generated between the permanent magnets arranged in parallel. Therefore, the magnetic field to which water is exposed can be strengthened and activated water can be generated.

  An electronic water device according to the present invention includes a downstream blocking plate having a reverse flow path portion facing an outflow portion formed in the first forward flow path portion, and an inflow port formed in the second forward flow path portion. And an area separated by the downstream blocking plate and the upstream blocking plate. With this configuration, water flowing out from the outlet portion of the first forward flow path portion collides with the downstream blocking plate, and the flow path is reversed from the forward flow direction to the reverse flow direction to flow backward. The backflowed water collides with the upstream blocking plate, the flow path is reversed from the reverse flow direction to the forward flow direction, and flows in from the inlet portion of the second forward flow path portion. Therefore, it is not necessary to connect each forward flow path portion and the reverse flow path portion with a U-shaped or S-shaped tube member that is difficult to be miniaturized, and each member can be easily miniaturized.

  In the electronic water device according to the present invention, the interval between the permanent magnets disposed across the first forward flow path portion and the interval between the permanent magnets disposed across the second forward flow path portion are each about 0.5 mm to about 8 mm. With this configuration, a strong magnetic field is formed, and a large amount of electrons that could not be obtained by the conventional method are contained in water molecules, and a smaller cluster than that obtained by the conventional method can be obtained. Therefore, water can be exposed to a strong magnetic field to generate activated water.

  In the electronic water device according to the present invention, six permanent magnets are arranged in the direction in which water flows, and are arranged in parallel in five rows in a direction intersecting with the direction in which water flows, and the first forward flow path section and the second It arrange | positions on both sides of each forward flow path part. Therefore, water can be exposed to many strong magnetic fields to produce activated water.

It is a longitudinal cross-sectional view of the electronic water apparatus which concerns on embodiment of this invention. It is an AA transverse cross section of an electronic water device concerning an embodiment of the present invention. It is a BB transverse sectional view of an electronic water device concerning an embodiment of the present invention. It is CC cross-sectional view of the electronic water apparatus which concerns on embodiment of this invention. It is DD cross-sectional view of the electronic water apparatus which concerns on embodiment of this invention. It is cross-sectional explanatory drawing explaining the effect of the Example of this invention compared with the comparative example, (a) And (b) is a comparative example, (c) is an Example of this invention. It is longitudinal cross-sectional explanatory drawing explaining the effect of the Example of this invention compared with the comparative example, (a) And (b) is a comparative example, (c) is an Example of this invention.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a longitudinal section of an electronic water device 10 according to an embodiment of the present invention, and FIGS. 2, 3, 4 and 5 show cross-sectional views of the electronic water device 10 according to an embodiment of the present invention. It is shown.

  In FIG. 1, an electronic water device 10 according to this embodiment includes a cylindrical member 20 that is formed in a cylindrical shape through which water (not shown) passes, and a plurality of flow path portions that are formed inside the cylindrical member 20. A plurality of permanent magnets 50 are arranged in parallel with each other in a direction intersecting with the direction in which water flows, and are arranged with the respective flow path portions interposed therebetween. The flow path part is comprised from the 1st forward flow path part 31, the 2nd forward flow path part 34, and the reverse flow path part 40 (refer FIG. 3 and FIG. 4).

  The cylindrical member 20 is substantially cylindrical, and an upstream port portion 21 that is upstream of the water flow is formed on one end side, and a downstream port portion 22 that is downstream of the water flow is formed on the other end side. On the inner side of the cylindrical member 20, two blocking plates formed in accordance with the inner diameter of the cylindrical member 20 are attached. The blocking plates are an upstream blocking plate 23 attached in the vicinity of the upstream opening 21 and a downstream blocking plate 24 attached in the vicinity of the downstream opening 22. The inner sides are partitioned by the respective blocking plates 23 and 24, and the cylindrical member 20 is formed with three zones in the direction in which water flows. The three zones are an upstream zone 25 on the upstream port 21 side, a downstream zone 26 on the downstream port 22 side, and a flow zone 27 between the upstream zone 25 and the downstream zone 26.

  The circulation area 27 is divided by a separator plate 28 (see FIGS. 3 and 4), and two flow paths are formed in parallel in a direction intersecting with the direction in which water flows. The two flow paths are the forward flow path 30 and the reverse flow path 40. The forward flow path portion 30 is formed in the forward flow direction 4, which is the direction in which water flows from the upstream port portion 21 side to the downstream port portion 22 side, while the reverse flow path portion 40 is configured such that water flows from the downstream port portion 21 side to the upstream port portion. It is formed in the reverse flow direction 5 which is the direction of reverse flow toward the 22 side.

  The forward flow path portion 30 is provided with four square water channels arranged in parallel in a direction intersecting with the direction in which water flows. The square water channel is, for example, a straight pipe having a quadrangular cross section. Among the square water channels, two are the first forward flow path portions 31 and two are the second forward flow path portions 34. Each forward flow path portion 31, 34 is formed with an inlet portion into which water flows in and an outlet portion from which water flows out at the tip. In addition, the number of each forward flow path parts 31 and 34 is arbitrary.

  In the first forward flow path portion 31, the first inlet port portion 32 penetrates the upstream blocking plate 23 and is opened in the upstream zone 25, and the first outlet port portion 33 faces the downstream blocking plate 24 in the flow zone 27. . The first outlet part 33 is supported by a downstream holding plate 38 attached in the vicinity of the downstream blocking plate 24. A water flow path from the upstream area 25 to the circulation area 27 is formed by the first forward flow path portion 31.

  In the second forward flow path portion 34, the second inlet portion 35 faces the upstream blocking plate 23 in the flow zone 27, and the second outlet portion 36 passes through the downstream blocking plate 24 and is opened in the downstream zone 26. ing. The second inflow port portion 35 is supported by an upstream holding plate 37 attached in the vicinity of the upstream blocking plate 23. A flow path of water from the flow area 27 to the downstream area 26 is formed by the second forward flow path portion 34.

  The upstream holding plate 37 and the downstream holding plate 38 are formed in a substantially semicircular shape, and are attached to both ends of the separator plate 28 (see FIGS. 3 and 4).

  The reverse flow path portion 40 is disposed so as to face the downstream blocking plate 24 disposed so as to face the first outlet portion 33 of the first forward flow path portion 31 and the second inlet portion 35 of the second forward flow path portion 34. The upstream blocking plate 23 and the flow area 27 divided by the downstream blocking plate 24 and the upstream blocking plate 23 are formed. As for the reverse flow path part 40, the 1st outflow part 33 of the 1st forward flow path part 31 and the 2nd inflow part 35 of the 2nd forward flow path part 34 are opened (refer FIG. 3 and FIG. 4). In addition, the reverse flow path part may be comprised by the square water channel pinched | interposed into the permanent magnet 50 similarly to each forward flow path part 31 and 34. FIG.

  The permanent magnet 50 is, for example, neodymium, and is disposed in parallel in a direction intersecting with the direction in which water flows, and is disposed with the forward flow path portions 31 and 34 interposed therebetween. In other words, each of the forward flow path portions 31 and 34 is attached to one surface (upper surface) in a line of six permanent magnets 50 along the direction in which water flows. The permanent magnets 50 are attached in a line on the opposite surface (lower surface). The distance between the pair of permanent magnets 50 sandwiching the forward flow path portions 31 and 34 is about 0.5 mm to about 8 mm. In this embodiment, since each of the forward flow path portions 31 and 34 is composed of four pieces, five rows of permanent magnets 50 are attached. The permanent magnet 50 in the first row and the permanent magnet 50 in the fifth row attached to the forward flow passage portions 31, 34 arranged at the end of the parallel forward flow passage portions 31, 34 are arranged in the respective forward flow passage portions. An iron plate 51 as a yoke is attached to the side not in contact with 31, 34. In addition, the number of permanent magnets 50 as a pair, the number of rows of permanent magnets 50, and the like are arbitrary, and are changed according to the lengths and intervals of the respective forward flow path portions 31 and 34.

  As described above, the electronic water device 10 is formed.

  Next, the operation according to this embodiment will be described.

  The electronic water device 10 is attached in series to a water pipe (not shown) or the like, and water passes through the inside of the tubular member 20. In the tubular member 20, water flows into the upstream area 25, is activated in the circulation area 27, and flows out from the downstream area 26.

  In the upstream area 25, the water flowing in from the upstream port portion 21 flows into the first inflow port portion 32 and flows through the first forward flow path portion 31 (first forward flow path 1).

  In the circulation zone 27, the water flowing through the first forward flow path portion 31 is exposed to the magnetic field generated in the direction intersecting the forward flow direction 4 by the permanent magnet 50 and flows out from the first outlet portion 33. The water flowing out from the first outlet part 33 collides with the downstream blocking plate 24, and the flow path is reversed from the forward flow direction 4 to the reverse flow direction 5 to flow backward (reverse flow path 3). The backflowed water flows through the reverse flow path portion 40 and collides with the upstream blocking plate 23, and the flow path is reversed from the reverse flow direction 5 to the forward flow direction 4 and flows into the second inflow port portion 35 to enter the second forward flow path portion. 34 (second forward flow path 2). The water flowing through the second forward flow path portion 34 is exposed to a magnetic field generated in the direction intersecting the forward flow direction 4 by the permanent magnet 50 and flows out from the second outlet portion 36.

  In the downstream area 26, the water flowing out from the second outlet part 36 flows out from the downstream port part 22.

  Next, the effect of this embodiment will be described.

  As described above, according to the present embodiment, in the electronic water device 10, the flow area 27 is divided by the separator plate 28 (see FIGS. 3 and 4), and the forward flow path portion 30 and the reverse flow path portion 40 flow in the direction of water. Are formed in parallel in the direction intersecting. The forward flow path portion 30 is provided with four square water channels arranged in parallel in a direction intersecting with the direction of water flow. Of the square water channels, two are first forward flow channel portions 31 and two are second flow channels. This is the forward flow path portion 34. Each of the forward flow path portions 31 and 34 is attached to one surface (upper surface) by arranging six permanent magnets 50 arranged in a line along the direction in which water flows. Permanent magnets 50 are mounted in a line on the opposite surface (lower surface).

  With this configuration, after the water flowing through the first forward flow path portion 31 is exposed to the magnetic field generated in the direction intersecting the forward flow direction 4 by the permanent magnet 50, the water flows backward and flows through the reverse flow path portion 40. It flows through the part 34 and is exposed to a magnetic field generated by the permanent magnet 50 in a direction crossing the forward flow direction 4. That is, the number of times the water flows in the forward flow direction 4 through the cylindrical member 20 is two. Therefore, activated water can be generated by exposing water to a large number of magnetic fields in a limited space inside the cylindrical member 20.

Further, with the above-described configuration, one row of permanent magnets 50 (for example, the second row, third row, and fourth row permanent magnets) carry the magnetic poles of the respective forward flow path portions 31 and 34 arranged in parallel. Therefore, the number of permanent magnets 50 can be reduced.

  According to this embodiment, since each of the forward flow path portions 31 and 34 is composed of four pieces, five rows of permanent magnets 50 are attached. With this configuration, the vector amount is added to the magnetic field generated between the permanent magnets 50 arranged in parallel in the direction intersecting the direction in which water flows. Therefore, the magnetic field to which water is exposed can be strengthened and activated water can be generated. Further, by arranging the permanent magnets 50 in parallel, the magnetic field can be enhanced as compared with the case where the same number of permanent magnets 50 are arranged in series.

  According to the present embodiment, the reverse flow path portion 40 includes the downstream blocking plate 24 disposed facing the first outlet portion 33 of the first forward flow path portion 31 and the second inlet portion of the second forward flow path portion 34. 35, an upstream side blocking plate 23 disposed facing the surface 35, and a flow area 27 partitioned by the downstream side blocking plate 24 and the upstream side blocking plate 23. With this configuration, the water flowing out from the first outlet part 33 collides with the downstream blocking plate 24, and the flow path is reversed from the forward flow direction 4 to the reverse flow direction 5 to flow backward (reverse flow path 3). The backflowed water flows through the reverse flow path portion 40 and collides with the upstream blocking plate 23, and the flow path is reversed from the reverse flow direction 5 to the forward flow direction 4 and flows into the second inflow port portion 35 to enter the second forward flow path portion. 34 (second forward flow path 2). Therefore, it is not necessary to connect each of the forward flow path portions 31 and 34 and the reverse flow path portion 40 with a U-shaped or S-shaped tube member that is difficult to be downsized, and each member can be easily downsized. be able to.

  According to the present embodiment, the interval between the permanent magnets 50 disposed with the first forward flow path portion 31 interposed therebetween and the interval between the pair of permanent magnets 50 disposed with the second forward flow passage portion 34 interposed therebetween are approximately 0.5 mm. To about 8 mm. With this configuration, a strong magnetic field is formed. Therefore, water can be exposed to a strong magnetic field to generate activated water.

  According to the present embodiment, six permanent magnets 50 are attached in a line along the direction in which water flows, and five rows of permanent magnets 50 are attached. Therefore, water can be exposed to many strong magnetic fields to produce activated water.

  Next, embodiments of the present invention will be described with reference to the drawings. 6 and 7 show the effect of the example compared with the comparative example.

<Example>
6 (c) and 7 (c), the number of permanent magnets 50 arranged in a row in the direction in which water flows is six, and there are five rows in parallel in the direction intersecting with the direction in which water flows (that is, The total number of the permanent magnets 50 sandwiching the forward flow passage portions 31 and 34 is 6 pairs, so that 12 pairs as a whole), and the interval between the forward flow passage portions 31 and 34 is about 5 mm. The magnetic field generated between the permanent magnets 50 has a magnetic field strength of H = K / 5 ² (K is a constant). The ability to make electrons (ratio of magnetic field strength per set of permanent magnets 50 × number of sets of permanent magnets 50) is 49 × 12 = 588.

<Comparative Example 1>
6 (a) and 7 (a), the number of permanent magnets arranged in one row in the direction in which water flows is four, and two rows in parallel in the direction crossing the direction in which water flows (that is, four rows). Set), and the interval between each forward flow path portion is about 35 mm. The magnetic field generated between the permanent magnets has a magnetic field strength of H1 = K / 35 ² (K is a constant). The ability to make electrons is 1 × 4 = 4.

<Comparative example 2>
6 (b) and 7 (b), the number of permanent magnets arranged in one row in the direction in which water flows is seven, and two rows in parallel in the direction intersecting with the direction in which water flows (that is, seven rows). Set), and the interval between each forward flow path portion is about 27.5 mm. The magnetic field generated between the permanent magnets has a magnetic field strength of H2 = K / 27.5 ² (K is a constant). The ability to make electrons is 1.6 × 7 = 11.2.

  If Comparative Example 1, Comparative Example 2, and Examples are compared with Comparative Example 1 as a reference, Table 1 is obtained.

  More specifically, the amount of electrons generated in water passing between magnetic fields is proportional to the strength of the magnetic field in accordance with Faraday's power generation principle. Since the strength of the magnetic field is inversely proportional to the square of the distance between the permanent magnets, the strength of the magnetic field increases as the distance between the permanent magnets decreases. Also, if the number of permanent magnets is large, the number of times that water passes through the magnetic field increases, so the amount of electrons contained in the water increases. Since water reciprocates inside the electronic water device 10 and passes through the magnetic field, the strength of the magnetic field through which water passes within a limited length increases, so the amount of electrons generated in the water increases. . Further, by arranging five rows of permanent magnets with an interval of 5 mm or less, the vector amount is added to each magnetic field, and a magnetic field having a strength that cannot be realized in the comparative example can be generated.

  As mentioned above, although embodiment of this invention was explained in full detail, this invention is not limited to the said embodiment. The present invention can be modified in various ways without departing from the scope of the claims.

DESCRIPTION OF SYMBOLS 1 1st forward flow path 2 2nd forward flow path 3 Backflow path 4 Forward flow direction 5 Reverse flow direction 10 Electronic water apparatus 20 Cylindrical member 21 Upstream port part 22 Downstream port part 23 Upstream side blocking plate 24 Downstream side blocking plate 25 Upstream area 26 Downstream Zone 27 Flow zone 28 Separating plate 30 Forward flow path portion 31 First forward flow path portion 32 First inflow port portion 33 First outflow port portion 34 Second forward flow path portion 35 Second inflow port portion 36 Second outflow port portion 37 Upstream holding plate 38 Downstream holding plate 40 Reverse flow path 50 Permanent magnet 51 Iron plate

Claims (4)

A cylindrical member having a plurality of flow path portions through which water flows is provided,
The flow path section is
A first forward flow path portion through which the water flows in a forward flow direction;
A reverse flow path portion in which the water flowing through the first forward flow path portion flows in a reverse flow direction;
A second forward flow path portion arranged in parallel with the first forward flow path portion, and the water flowing through the reverse flow path portion flowing in the forward flow direction;
Consisting of
A plurality of permanent magnets arranged in parallel with the direction in which the water flows and arranged across the first forward flow path part and the second forward flow path part were provided,
An electronic water device characterized by that. The reverse flow path part is
A downstream blocking plate provided facing the outlet portion formed in the first forward flow path portion;
An upstream blocking plate provided facing the inlet portion formed in the second forward flow path portion;
An area partitioned by the downstream blocking plate and the upstream blocking plate;
Composed of,
The electronic water device according to claim 1. The interval between the permanent magnets arranged across the first forward flow path portion and the interval between the permanent magnets arranged across the second forward flow path portion are about 0.5 mm to about 8 mm, respectively.
The electronic water device according to claim 1 or 2, characterized by the above. Six of the permanent magnets are arranged in the direction in which the water flows, and are arranged in parallel in five rows in a direction crossing the direction in which the water flows, and the first forward flow path portion and the second forward flow path portion Arranged across each other,
The electronic water device according to any one of claims 1 to 3, wherein the electronic water device is characterized by that.

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