KR101664972B1 - Hydrogen-containing water generating device - Google Patents

Abstract

The hydrogen-containing water producing apparatus is a tubular conductor, which is a cylindrical conductor having a plurality of openings on its side, an insulator provided on the outer periphery of the positive electrode, and a cylindrical conductor provided on the outer periphery of the insulator, And a first mounting portion mounted on the first end side of the positive electrode and the negative electrode and having a first mounting portion in contact with an installation target of the hydrogen containing water generating device; And a distance from the side portion of the positive electrode to the second mounting portion in a direction orthogonal to the side portion of the positive electrode is a distance from the side of the positive electrode that is perpendicular to the side of the positive electrode And a second support member which is larger than a distance from a side portion of the positive electrode in the direction of the first support portion to the first installation portion.

Description

[0001] HYDROGEN-CONTAINING WATER GENERATING DEVICE [0002]

The present invention relates to a technique for obtaining hydrogen-containing water from raw water such as tap water.

As a technique for producing hydrogen-containing water (hydrogen-containing water) from tap water, for example, a technique is known in which an electrolytic cell is provided with an ion exchange membrane between a pair of positive and negative electrodes to obtain electrolytic water containing hydrogen (For example, Patent Documents 1 to 3).

Japanese Patent Application Laid-Open No. 2010-88972 Japanese Patent Application Laid-Open No. 2010-88973 Japanese Patent Application Laid-Open No. 2010-284504

In the techniques described in Patent Documents 1 to 3, a positive electrode and a negative electrode are provided in an electrolytic bath, and raw water is supplied into an electrolytic bath to produce a hydrogen-containing water. The techniques described in Patent Documents 1 to 3 are used by fixing an electrolytic bath to a bath or a tank for collecting beverage. In recent years, in consideration of convenience, it is not a fixed type as described in Patent Documents 1 to 3, but rather a movable type capable of carrying hydrogen-containing water by carrying it to a place of use, that is, (Portable) type device is expected.

In the technologies described in Patent Documents 1 to 3, since raw water is forcibly passed through the positive electrode and the negative electrode, oxygen generated on the positive electrode side can be easily discharged to the outside. In the portable type apparatus, since forced passage of the raw water can not be expected, there is room for improvement in order to release oxygen generated from the positive electrode to the outside.

An object of the present invention is to rapidly release oxygen generated at the positive electrode side to generate hydrogen-containing water containing hydrogen.

According to the present invention, there is provided a hydrogen-containing water producing apparatus for producing hydrogen-containing water, comprising: a positive electrode having a tubular conductor and having a plurality of openings on its side; an insulator provided on an outer periphery of the positive electrode; Containing water, a negative electrode having a plurality of openings in a side portion thereof, a negative electrode disposed on a side of the positive electrode and the first end of the negative electrode, And a second mounting portion mounted on the second end side of the positive electrode and the negative electrode so as to be in contact with the object to be mounted, and a second mounting portion provided on the side of the positive electrode in a direction orthogonal to the side portion of the positive electrode, Wherein the distance from the first mounting portion to the second mounting portion is larger than the distance from the side portion of the positive electrode in the direction orthogonal to the side portion of the positive electrode to the first mounting portion Containing water generating apparatus.

When the first support and the second support are provided on the object to be installed, the angle between the object to be installed and the positive electrode and the negative electrode is preferably not less than 2 degrees and not more than 10 degrees.

A positive electrode power supply member protruding from the first end side of the positive electrode and a rod-shaped member mounted inside the side portion of the positive electrode, the rod-like conductor being mounted on the inner side of the side portion of the positive electrode, A positive electrode support member protruding from the second end side of the positive electrode and a negative electrode power supply member protruding from the first end side of the negative electrode and being a rod-shaped conductor mounted on an outer side of the side portion of the negative electrode, And the first support member supports the positive electrode power supply member and the negative electrode power supply member, and the first support member supports the negative electrode power supply member and the negative electrode support member, It is preferable that the second support body supports the positive electrode support member and the negative electrode support member.

A positive electrode power supply member protruding from at least one of a first end side of the positive electrode and a second end side of the positive electrode and a rod-shaped conductor mounted on the inner side of the side portion of the positive electrode, And a negative electrode power supply member protruding from at least one of a first end side of the negative electrode and a second end side of the negative electrode, wherein the first support member or the second support member is a rod- The positive electrode power supply member and the negative electrode power supply member.

It is preferable that at least one of the first support and the second support has an opening connected to a space surrounded by the side of the positive electrode.

Wherein the first end of the protection member is supported by the first support member and the second end of the protection member is formed by the second end of the second member, And is preferably supported on a support.

The plurality of openings of the protective member are preferably larger than the plurality of openings of the negative electrode.

It is preferable that the insulator has a plurality of openings.

INDUSTRIAL APPLICABILITY The present invention can quickly release the oxygen generated at the positive electrode side to the outside in generating hydrogen-containing water containing hydrogen.

1 is a perspective view showing an electrode for producing hydrogen-containing water according to the present embodiment.
2 is a perspective view showing an electrode for producing hydrogen-containing water according to the present embodiment.
3 is a view showing the use of the electrode for producing hydrogen-containing water according to the present embodiment.
4 is a side view showing an electrode for producing hydrogen-containing water according to the present embodiment.
5 is a cross-sectional view of the electrode for hydrogen-containing water according to the present embodiment, taken along a plane including its central axis.
6 is a cross-sectional view taken along line AA of Fig.
Fig. 7 is an enlarged view of part of Fig. 6. Fig.
8 is a side view showing a modified example of the electrode for producing hydrogen-containing water.
9 is a side view showing a modified example of the electrode for producing hydrogen-containing water.
10 is a cross-sectional view showing a modified example of an electrode for producing hydrogen-containing water.
11 is a cross-sectional view showing a modified example of the electrode for producing hydrogen-containing water.
12 is an enlarged view of a part of the positive electrode and the negative electrode.
13 is an enlarged view of the openings of the positive electrode and the negative electrode.
14 is a cross-sectional view taken along the line BB of Fig.
15 is an enlarged view of a part of the insulator.
16 is a flow chart of a method of manufacturing an electrode for producing hydrogen-containing water according to this embodiment.
17 is a view showing each step of the method for producing an electrode for producing hydrogen-containing water according to the present embodiment.
18 is a view showing each step of the method for producing an electrode for producing hydrogen-containing water according to the present embodiment.
19 is a view showing each step of the method for producing an electrode for producing hydrogen-containing water according to the present embodiment.
20 is a view showing each step of the method for producing an electrode for producing hydrogen-containing water according to the present embodiment.
21 is a view showing each step of the method for producing an electrode for producing hydrogen-containing water according to the present embodiment.
22 is a view showing each step of the method for producing an electrode for producing hydrogen-containing water according to the present embodiment.
23 is a view showing each step of the method for producing an electrode for producing hydrogen-containing water according to the present embodiment.
24 is a view showing each step of the method for producing an electrode for producing hydrogen-containing water according to the present embodiment.
25 is a view showing each step of the method for producing an electrode for producing hydrogen-containing water according to the present embodiment.
26 is a view showing each step of the method for producing an electrode for producing hydrogen-containing water according to the present embodiment.
27 is a view showing a hydrogen-containing water producing apparatus according to the present embodiment.
28 is a view showing a first support provided in the hydrogen-containing water producing apparatus according to the present embodiment.
29 is a view showing a second support provided in the hydrogen-containing water producing apparatus according to the present embodiment.
30 is a view showing an opening of a protective member and an opening of a negative electrode included in the hydrogen-containing water generating device according to the present embodiment.
31 is a view showing another embodiment of the hydrogen-containing water producing apparatus according to the present embodiment.
32 is a view showing a mounting structure when an electrode for producing hydrogen-containing water is mounted on the hydrogen-containing water producing device according to the present embodiment.
33 is a view showing a mounting structure when an electrode for producing hydrogen-containing water is mounted on the hydrogen-containing water producing device according to the present embodiment.
34 is a view showing another mounting structure when an electrode for producing hydrogen-containing water is mounted on the hydrogen-containing water producing device according to the present embodiment.
35 is a diagram showing a modified example of the hydrogen-containing water producing apparatus according to the present embodiment.
36 is a diagram showing a modified example of the hydrogen-containing water producing device according to the present embodiment.
37 is a diagram showing a modified example of the hydrogen-containing water producing device according to the present embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A mode (embodiment) for carrying out the present invention will be described in detail with reference to the drawings. First, an electrode used for producing a hydrogen-containing water will be described.

≪ Electrode for producing hydrogen-containing water &

1 and 2 are perspective views showing an electrode for producing hydrogen-containing water according to the present embodiment. The hydrogen-containing water generating electrode 10 generates hydrogen-containing water, which is water containing hydrogen, from raw water such as tap water by utilizing the electrolytic action of water. The hydrogen-containing water is water exhibiting alkalinity. 1 and 2, the hydrogen-containing water generating electrode 10 has a positive electrode 11, a negative electrode 12, and an insulator 13. The positive electrode 11 and the negative electrode 12 are both tubular conductors. In the present embodiment, the shapes of the positive electrode 11 and the negative electrode 12 are all cylindrical, but are not limited thereto. The insulator 13 is provided on the outer periphery of the positive electrode 11 and is in contact with the positive electrode 11. The negative electrode 12 is provided on the outer peripheral portion of the insulator 13 and is in contact with the insulator 13. That is, the insulator 13 is disposed between the positive electrode 11 and the negative electrode 12 provided outside the positive electrode 11 to contact the positive electrode 11 and the negative electrode 12. The positive electrode 11, the negative electrode 12, and the insulator 13 are both net members. Although the insulator 13 is in contact with the positive electrode 11 and the negative electrode 12 in this embodiment, the insulator 13 may not necessarily be in contact with the positive electrode 11 and the negative electrode 12.

The positive electrode 11 is electrically connected to the positive electrode power supply member 14 which is a bar-shaped conductor. The negative electrode 12 is electrically connected to the negative electrode power supply member 15 which is a bar-shaped conductor. The positive-electrode power-supply member 14 is electrically connected to the positive electrode of the power source (direct-current power source) 20. The negative-electrode power-supply member 15 is electrically connected to the negative electrode of the power source 20. The positive electrode 11 is electrically connected to the positive electrode of the power source 20 via the positive electrode power supply member 14 and the negative electrode 12 is electrically connected to the negative electrode of the power supply 20 and the negative electrode power supply member 14. [ (15).

In the present embodiment, the positive electrode 11 is provided with a positive electrode support member 18 which is a rod-like member. The positive electrode support member 18 is mounted on the opposite side of the positive electrode 11 from the side on which the positive electrode power supply member 14 is mounted. The negative electrode 12 is provided with a negative electrode support member 19 which is a rod-like member. The negative electrode support member 19 is mounted on the side opposite to the side of the negative electrode 12 on which the negative-side power supply member 15 is mounted. In the present embodiment, the positive electrode support member 18, the negative electrode support member 19, the positive electrode power supply member 14, and the negative electrode power supply member 15 are all made of the same material, but are not limited thereto. For example, the positive electrode power supply member 14 and the negative electrode power supply member 15 may be made of the same material, and the positive electrode support member 18 and the negative electrode support member 19 may be made of different materials. In the present embodiment, the positive electrode 11 and the negative electrode 12 are not necessarily provided with the positive electrode support member 18 and the negative electrode support member 19.

As shown in Figs. 1 and 2, the hydrogen-containing water generating electrode 10, more specifically, the positive electrode 11 and the negative electrode 12 are provided with end-side openings 10HA and 10HB as openings at both ends, . The hydrogen-containing water generating electrode 10 may not have the end side openings 10HA and 10HB and may have the end side opening 10HA or the end side opening 10HB at at least one end.

The positive electrode 11 has a slit 11SL extending in the longitudinal direction, that is, the direction in which the positive electrode 11, which is a tubular member, extends. The negative electrode 12 has a slit 12SL extending in the longitudinal direction, that is, the direction in which the negative electrode 12, which is a tubular member, extends. 1 and 2, the hydrogen-containing water generating electrode 10 is provided between the negative-electrode power supply member 15 and the negative-electrode support member 19, and on the outer side of the negative electrode 12, 40 are provided. The restricting member 40 closes the slit 11SL of the positive electrode 11 and the slit 12SL of the negative electrode 12 to seal the negative electrode 12, the insulator 13, and the positive electrode 11 to the negative electrode 12, And is restrained from the circumferential direction of the positive electrode (11). Next, the use of the electrode 10 for producing hydrogen-containing water will be described.

3 is a view showing the use of the electrode for producing hydrogen-containing water according to the present embodiment. The hydrogen-containing water generating electrode (10) is charged into the raw water (W) to generate hydrogen-containing water in the raw water (W). The electrode 10 for producing hydrogen-containing water is not a stationary type, but is a movable portable device for transporting the hydrogen-containing water-producing electrode 10 to a place where it is used, that is, . The raw water W is, for example, hot water collected in a bathtub, beverage water collected in a drinking water tank, or washing water collected in a washing water tank. When a predetermined voltage (DC voltage) is applied between the positive electrode 11 and the negative electrode 12 of the hydrogen-containing water generating electrode 10 charged in the raw water W from the power source 20, The raw water W existing around the electrode 10 is ionized by hydrogen ions (H ⁺ ) and hydroxide ions (OH ^- ).

Of the insulator 13, the case that does not have an ion-exchange function, the ionization of hydrogen ions (H ⁺⁾ is passed through the insulator 13 gather to the negative electrode 12 side, hydrogen gas to the negative electrode (12) (H ₂₎ Bubbles are created. This bubble is a minute bubble whose diameter is on the order of nanometers. The raw water W (2H ₂ O) is purified by H ₂ + 2OH ^- by electrons 2e ^- . By this water purifying action, hydrogen gas is dissolved in the raw water W, so that hydrogen-containing water in which hydrogen is dissolved in the raw water W is produced. The electrolytic hydroxide ion (OH < ^- & gt ^; ) passes through the insulator 13 and collects toward the cathode 11, and the raw water W (2H ₂ O) is purified by O ₂ + 4H ⁺ + 4e ^- Is generated. O ₂ collects as air bubbles inside the tubular positive electrode 11 and moves along the inside of the positive electrode 11 to be discharged from the end side openings 10HA and 10HB to the outside of the positive electrode 11. Next, the hydrogen-containing water generating electrode 10 will be described in more detail.

4 is a side view showing an electrode for producing hydrogen-containing water according to the present embodiment. Fig. 4 shows a state in which the negative electrode 12 and part of the insulator 13 of the hydrogen-containing water generating electrode 10 are removed. 5 is a cross-sectional view of the electrode for hydrogen-containing water according to the present embodiment, taken along a plane including its central axis. 6 is a cross-sectional view taken along line A-A of Fig. Fig. 7 is an enlarged view of part of Fig. 6. Fig. In the present embodiment, the direction parallel to the direction in which the cylindrical positive electrode 11 and the negative electrode 12 extend (appropriately referred to as the longitudinal direction) in the present embodiment is their central axis Zt. The central axis Zt is an axis passing through the center (center of gravity) in the cross section of the positive electrode 11 and the negative electrode 12 orthogonal to the central axis Zt.

As shown in Fig. 4, the positive electrode 11 has a plurality of openings 11H on its side, and the negative electrode 12 has a plurality of openings 12H on its side. The plurality of openings 11H of the positive electrode 11 penetrate the side portion of the positive electrode 11 in the thickness direction of the positive electrode 11. The plurality of openings 12H of the negative electrode 12 penetrate the side portion of the negative electrode 12 in the thickness direction of the negative electrode 12. In the present embodiment, the positive electrode 11 and the negative electrode 12 are made of a conductor, and in the present embodiment, platinum (Pt) is plated with titanium (Ti). The plating may be platinum (Pt) -Id (Ir) plating, for example. In the present embodiment, titanium is pure titanium. The positive electrode 11 and the negative electrode 12 are preferably made of a material (for example, vanadium (V)) which does not dissolve in the raw water W, though it is not limited to platinum plated with titanium. In this embodiment, both the positive electrode 11 and the negative electrode 12 are plated, but only the positive electrode 11 in which calcium hydroxide or magnesium hydroxide precipitates in the raw water is plated, and the negative electrode 12 is not plated. By doing so, the manufacturing cost of the hydrogen-containing water generating electrode 10 can be reduced.

An insulator 13 interposed between a side portion (outer portion) 11So on the outer side of the positive electrode 11 and a side portion (inner portion) 12Si on the inner side of the negative electrode 12 as shown in Fig. 11 and the inner side 12Si of the negative electrode 12. In this case, The insulator 13 has a plurality of openings 13H. The opening 13H penetrates the insulator 13 in its thickness direction. As the insulator 13, for example, a net made of fibers of an insulating material (e.g., resin) can be used. The insulator 13 may have an ion exchange function. For example, the insulator 13 may be an ion exchange membrane (cation exchange membrane). In this case, the insulator 13 may not have the opening 13H.

The cation exchange membrane is negatively charged because of the negative ion group fixed on the membrane. For this reason, negative ions can not pass through repulsion, and only positive ions pass through. Therefore, in the hydrogen generating electrode (10) for containing water, an insulator (13) using a cation exchange membrane, a cation, that is only transmitted through the hydrogen ion (H ⁺⁾ and negative ions, that is, ionizing a hydroxyl ion (OH ^-) for resisting do. Therefore, the amount of the hydroxide ions (OH ^- ) passing through the insulator 13 and moving toward the positive electrode 11 can be reduced. As a result, generation of oxygen and acidic ionized water on the side of the positive electrode 11 is suppressed.

As described above, the insulator 13 may be an ion exchange membrane, but an electrically neutral material is used. By doing so, the manufacturing cost of the insulator can be reduced, and the processing can be facilitated. The ion exchange membrane has a hole through which ions can pass but water molecules can not pass through. When the ion exchange membrane is used for the insulator 13, the hydrogen-containing water generating electrode 10 having the insulator 13 has a high voltage required to generate hydrogen-containing water, and has a possibility of increasing power consumption . In this embodiment, the insulator 13 is an electrically neutral mesh member. Therefore, hydrogen-containing water can be generated at a lower voltage than the ion exchange membrane, and power consumption can be suppressed.

In the case of using a meshed net made of insulating fibers for the insulator 13, the thickness of the insulator 13 should be about 0.1 mm to about 1 mm. 6, in this embodiment, an insulator 13 (corresponding to an outer peripheral portion) 11So provided between the outer side portion (corresponding to the outer peripheral portion) of the positive electrode 11 and an inner side portion Is taken out from the slit 12SL of the negative electrode 12 toward the outer side portion (corresponding to the outer peripheral portion) 12So of the negative electrode 12. The end of the insulator 13 may be taken out from the slit 11SL of the positive electrode 11 toward the inner side portion (corresponding to the inner peripheral portion) 11Si of the positive electrode 11. Next, the influence of the size (t) of the gap (appropriately called inter-electrode gap) formed between the positive electrode 11 and the negative electrode 12 shown in Fig. 7 will be described. The size t of the interelectrode gap is a distance between the outer side portion 11So of the positive electrode 11 and the inner side portion (inner peripheral portion) 12Si of the negative electrode 12.

The amount of dissolved hydrogen in the hydrogen-containing water when the size (t) of the inter-electrode gap shown in Fig. 7 is made different is compared. In this evaluation, t = 0.4 mm, 3 mm. When t = 0.4 mm, the voltage applied to the hydrogen-containing water generating electrode 10 is 18V and the current is 5A. When t = 3 mm, the voltage applied to the electrode 10 for producing hydrogen-containing water is 60 V and the current is 5 A. The results are shown in Table 1. The dissolved hydrogen in Table 1 indicates that the hydrogen-containing water generating electrode 10 was charged into 120 liters of hot water at 41 ° C and then 15 minutes after the voltage was applied to the positive electrode 11 and the negative electrode 12 Measured value.

From the evaluation results shown in Table 1, it can be seen that as the size (t) of the interelectrode gap becomes smaller, the amount of dissolved hydrogen (dissolved hydrogen) in the raw water increases. Specifically, when the size (t) of the inter-electrode gap is 0.4 mm, the amount of dissolved hydrogen is increased by 8% as compared with t = 3.0 mm. When the size (t) of the interelectrode gap is 0.4 mm, the power consumption becomes one-third as compared with t = 3.0 mm. When the size (t) of the inter-electrode gap is 0.4 mm, much hydrogen can be dissolved in the raw water with a small power consumption as compared with t = 3.0 mm. That is, by reducing the size (t) of the interelectrode gap in the electrode 10 for generating hydrogen-containing water, the efficiency of dissolving hydrogen in the raw water is improved.

In the present embodiment, the size (t) of the interelectrode gap is preferably 0.1 mm or more and 1 mm or less. The electric potential difference between the voltage applied to the positive electrode 11 and the voltage applied to the negative electrode 12 is relatively high when the hydrogen containing water generating electrode 10 generates the hydrogen containing water by setting the size t of the inter- Even if it is small, the hydrogen-containing water generating electrode 10 can generate a sufficient amount of hydrogen. Even if the voltage applied to the hydrogen-containing water generating electrode 10 is a comparatively low voltage, the electrode 10 for generating hydrogen can be supplied in a sufficient amount Hydrogen can be dissolved in raw water to produce a hydrogen-containing water in which a large amount of hydrogen is dissolved. For this reason, the electrode 10 for producing hydrogen-containing water can also be used in applications where, for example, the hydrogen-containing water generating electrode 10 is charged into hot water collected in a bath to produce hydrogen-containing water. When the amount of hydrogen dissolved in the hydrogen-containing water is the same, the power consumption of the electrode 10 for hydrogen-containing water generation can be suppressed.

When the size (t) of the interelectrode gap is large, the voltage applied to the electrode 10 for generating hydrogen-containing water is made large in order to allow a sufficient amount of hydrogen to be dissolved in the raw water. By setting the size t of the inter-electrode gap to 1 mm or less, preferably 0.6 mm or less, a sufficient amount of hydrogen can be supplied to the hydrogen-containing water generating electrode 10 even if the voltage applied to the electrode 10 for generating hydrogen- Lt; / RTI > The positive electrode 11 and the negative electrode 12 formed by the insulator 13 interposed between the positive electrode 11 and the negative electrode 12 can be formed by setting the size t of the interelectrode gap to 0.1 mm or more, Can be sufficiently secured. As a result, the hydrogen-containing water generating electrode 10 can exhibit stable performance. When a resin is used as the insulator 13 as described above, it is possible to suppress the decrease in durability of the insulator 13 by setting the size (t) of the inter-electrode gap to be 0.1 mm or more, preferably 0.2 mm or more have. In the present embodiment, the insulator 13 interposed between the positive electrode 11 and the negative electrode 12 is in contact with both of them. Therefore, the size t of the interelectrode gap is determined by the thickness of the insulator 13.

In the present embodiment, the hydrogen-containing water generating electrode 10 is directly charged into a bath or a water tank or the like to produce hydrogen-containing water. When it is not necessary to generate hydrogen-containing water, the hydrogen-containing water generating electrode 10 is taken out from a bathtub, a beverage tank, or the like. As described above, the electrode 10 for producing hydrogen-containing water is not fixedly used and can be moved and transported. For this reason, the electrode 10 for producing hydrogen-containing water is more susceptible to vibration and impact as compared with that used for fixing. The hydrogen-containing water generating electrode 10 is restricted in the movement of the positive electrode 11 and the negative electrode 12 when the insulator 13 is interposed between the positive electrode 11 and the negative electrode 12 and brought into contact with them . As a result, the hydrogen-containing water generating electrode 10 is improved in resistance to vibration and impact.

When the insulator 13 is sandwiched between the positive electrode 11 and the negative electrode 12 and brought into contact with the positive electrode 11 and the negative electrode 12, the insulator 13 forms the positive electrode 11 And the negative electrode 12 can be made uniform. As a result, in the electrode 10 for producing hydrogen-containing water, the variation of the electric resistance between the positive electrode 11 and the negative electrode 12 is suppressed and the deviation of the current density is suppressed, . It is preferable that the insulator 13 is easily brought into contact with both the positive electrode 11 and the negative electrode 12 by making the size t of the interelectrode gap equal to the thickness of the insulator 13. Next, the positive-electrode power-supply member 14 and the negative-electrode power-supply member 15 will be described.

4, the positive-electrode power-supply member 14 has a rod-like shape extending from the first end (one end) 11T1 to the second end (the other end) 11T2 of the positive electrode 11 . 5 and 6, the positive-electrode power-supply member 14 has a length L of the dimension L of the positive electrode 11 in the direction (longitudinal direction) E in which the positive electrode 11 extends / 2) is mounted on the inner side 11Si of the positive electrode 11. The negative-electrode power-supply member 15 is a rod-shaped conductor extending from the first end 12T1 of the negative electrode 12 toward the second end 12T2. 5 and 6, the negative-electrode power supply member 15 has a length L (L) of the negative electrode 12 in the direction (longitudinal direction) E in which the negative electrode 12 extends / 2) is mounted on the outer side 12So of the negative electrode 12. The length of the portion of the positive electrode power supply member 14 mounted on the positive electrode 11 and the length of the portion of the negative power supply member 15 mounted on the negative electrode 12 are all LS. In the present embodiment, LS < L / 2.

4, the positive electrode support member 18 is a bar-shaped conductor extending from the second end portion 11T2 of the positive electrode 11 toward the first end portion 11T1. 5, the portion of the positive electrode support member 18 which is shorter than half (L / 2) of the dimension L of the positive electrode 11 in the longitudinal direction E of the positive electrode 11, And is mounted on the inner side 11Si of the positive electrode 11. The negative electrode directing member 19 is a bar-shaped conductor extending from the second end 12T2 of the negative electrode 12 toward the first end 12T1. 5, a portion of the negative electrode support member 19, which is shorter than half (L / 2) of the dimension L of the negative electrode 12 in the longitudinal direction E of the negative electrode 12, And is mounted on the outer side portion 12So of the negative electrode 12.

The positive electrode power supply member 14 and the negative electrode power supply member 15 and the positive electrode support member 18 and the negative electrode support member 19 are formed in the same manner as the positive electrode 11 and the negative electrode 12 , And platinum-plated members of titanium. Like the positive electrode 11 and the negative electrode 12, the positive electrode power supply member 14, the negative electrode power supply member 15, the positive electrode support member 18 and the negative electrode support member 19 are plated with platinum But is preferably a material which does not dissolve in the raw water W. The positive electrode power supply member 14 and the negative electrode power supply member 15 are bonded to the positive electrode 11 and the negative electrode 12 and are electrically connected to each other by welding means such as welding. The positive electrode power supply member 14 and the negative electrode power supply member 15 are attached to the positive electrode 11 and the negative electrode 12 by bonding means such as welding.

The plating to be performed on the positive electrode power supply member 14 and the negative electrode power supply member 15 and the positive electrode support member 18 and the negative electrode support member 19 may be performed by using a platinum (Pt) -Iridium (Ir) plating . In this embodiment, the negative electrode 12 is not required to be plated, but in this case, the negative electrode power supply member 15 may not be plated.

5, the positive-electrode power-supply member 14 and the negative-electrode power-supply member 15 are connected to the positive electrode 11 and the negative electrode 12 at a plurality of joint portions CP by spot welding, respectively, (Not shown). The positive electrode support member 18 and the negative electrode support member 19 are also the same as the positive electrode power supply member 14 and the negative electrode power supply member 15. The bonding of the positive electrode power supply member 14 and the negative electrode power supply member 15 is not limited to spot welding.

The plurality of joint portions CP are provided so as not to be offset to some extent in the longitudinal direction of the positive electrode power supply member 14 and the negative electrode power supply member 15. [ In this way, the positive-electrode power-supply member 14 and the negative-electrode power-supply member 15 can supply power from the entire lengthwise direction E thereof. The negative electrode power supply member 15 and the negative electrode support member 19 are different members and each has a dimension L of the negative electrode 12 in the direction in which the negative electrode 12 extends A portion shorter than half (L / 2) is mounted on the outer side portion 12So of the negative electrode 12. Therefore, in the outer portion 12So of the negative electrode 12, portions (gaps) in which they do not exist are formed between the negative electrode power supply member 15 and the negative electrode support member 19. The hydrogen-containing water generating electrode 10 is provided with the restricting member 40 at a portion where the negative-side power supply member 15 and the negative-electrode support member 19 of the outer side portion 12So of the negative electrode 12 do not exist . The restricting member 40 does not interfere with the negative electrode power supply member 15 and the negative electrode support member 19 and the negative electrode 12, the insulator 13 and the positive electrode 11 can be disposed on the entire outer peripheral portion of the negative electrode 12 The force can be restrained by an even force.

4 and 5, the positive electrode power supply member 14 protrudes from the first end portion 11T1 of the positive electrode 11 and the negative electrode power supply member 15 protrudes from the first end portion 11T1 of the negative electrode 12 And protrudes from the first end 12T1. 4, the portion protruding from the first end portions 11T1 and 12T1 can be mounted on the mounting object ST1, as shown in Fig. 4, so that the positive electrode power supply member 14 and the negative electrode power supply member 15 can be mounted have. As a result, the positive electrode 11 and the negative electrode 12 are mounted on the mounting object ST1 via the positive electrode power supply member 14 and the negative electrode power supply member 15. [

The negative electrode power supply member 14 and the negative electrode power supply member 15 are provided with the male screws 14S and 15S at the portions protruding from the first ends 11T1 and 12T1 Is installed. The positive electrode power supply member 14 and the negative electrode power supply member 15 are fixed to the mounting object ST1 by the bolts 32 and 32 which are respectively turned on the male screws 14S and 15S.

The positive electrode 11 is fixed to the mounting object ST1 by the bolt 32 via the first power supply member 14 and the first end portion 11T1 in contact with the mounting object ST1. Likewise, the negative electrode 12 is fixed to the mounting object ST1 by the bolt 32 via the first power supply terminal 15 and the first end portion 12T1 in contact with the mounting object ST1. Therefore, the positive electrode 11 and the negative electrode 12 come in contact with the mounting object ST1 in a wide range, and are stably mounted on the mounting object ST1.

The terminals 34 and 34 for electrically connecting the positive-electrode power supply member 14 and the wiring with the bolts 33 and 33 respectively turned on the bolts 32 and 32 and the male screws 14S and 15S, And the terminal 34 for electrically connecting the negative-electrode power supply member 15 and the wiring is fixed. With this structure, electric power is applied to the positive electrode 11 and the negative electrode 12 via the terminals 34 and 34, the positive electrode power supply member 14, and the negative electrode power supply member 15.

4 and 5, the positive electrode support member 18 protrudes from the second end portion 11T2 of the positive electrode 11 and the negative electrode support member 19 protrudes from the second end portion 11T2 of the negative electrode 12 And protrudes from the second end portion 12T2. 4, the portion projecting from the second end portions 11T2 and 12T2 can be mounted on the mounting object ST2, as shown in Fig. 4, so that the positive electrode power supply member 14 and the negative electrode power supply member 15 can be mounted have. As a result, the positive electrode 11 and the negative electrode 12 are mounted on the mounting object ST2 via the positive electrode support member 18 and the negative electrode support member 19.

4, the positive electrode support member 18 and the negative electrode support member 19 are provided with male screws 18S and 19S at portions protruding from the second end portions 11T2 and 12T2 Is installed. The positive electrode support member 18 and the negative electrode support member 19 are fixed to the mounting object ST2 by the bolts 31 and 31 which are respectively turned on the male screws 18S and 19S.

The positive electrode 11 is fixed to the mounting object ST2 by the bolt 31 via the positive electrode support member 18 and the second end portion 11T2 is in contact with the mounting object ST2. Likewise, the negative electrode 12 is fixed to the mounting object ST2 by the bolt 31 via the second end portion 12T2 and the negative electrode support member 19 in contact with the mounting object ST2. Therefore, the positive electrode 11 and the negative electrode 12 come in contact with the mounting object ST2 in a wide range, and are stably mounted on the mounting object ST2.

The hydrogen-containing water generating electrode 10 is constituted by the positive electrode power supply member 14 and the negative electrode power supply member 15, the positive electrode support member 18 and the negative electrode support member 19, And can be mounted on the mounting targets ST1 and ST2 from both sides of the negative electrode 12. The hydrogen-containing water generating electrode 10 is formed by using one of the positive electrode power supply member 14 and the negative electrode power supply member 15 or the positive electrode support member 18 and the negative electrode support member 19 May be mounted on the mounting object. Thus, the hydrogen-containing water generating electrode 10 has an advantage of high degree of freedom in mounting.

Figs. 8 and 9 are side views showing a modified example of the electrode for producing hydrogen-containing water. Fig. In this modification, the retaining member 40 shown in Fig. 4 and the like is omitted in Fig. 8 and Fig. The hydrogen-containing water generating electrode 10a shown in Fig. 8 and the hydrogen-containing water generating electrode 10b shown in Fig. 9 are arranged on the outer side of the negative electrode power supply members 15a and 15b mounted on the outer side of the negative electrode 12 The restraint member 40 is mounted.

8, the positive electrode power supply member 14a has a length L of half the length L of the positive electrode 11 in the longitudinal direction E of the positive electrode 11 L / 2) is mounted on the inner side 11Si of the positive electrode 11 shown in Fig. The negative electrode power supply member 15a has a portion longer than half (L / 2) of the dimension L of the negative electrode 12 in the longitudinal direction E of the negative electrode 12, As shown in Fig. The length of the portion of the positive electrode power supply member 14a mounted on the positive electrode 11 and the length of the portion of the negative power supply member 15a mounted on the negative electrode 12 are both LS. In the present embodiment, LS > L / 2. LS is preferably 70% or more of the dimension L in the longitudinal direction E of the positive electrode 11 and the negative electrode 12, and more preferably 80% or more of L. In the present embodiment, LS is 95% or more of L.

8, the positive electrode power supply member 14a and the negative electrode power supply member 15a are electrically connected to the positive electrode 11 and the negative electrode 12 at a plurality of joint portions CP by spot welding, Respectively. The plurality of joint portions CP are provided so as not to be offset to some extent in the longitudinal direction of the positive electrode power supply member 14a and the negative electrode power supply member 15a. The positive electrode power supply member 14a and the negative electrode power supply member 15a can supply power to the positive electrode 11 and the negative electrode 12 from the whole of the longitudinal direction E thereof. Therefore, the hydrogen-containing water generating electrode 10a can make the current distribution in the longitudinal direction E of the positive electrode 11 and the negative electrode 12 close to uniformity, Hydrogen can be generated from the entire region of the solid electrolyte (E). Since the positive electrode 11 and the negative electrode 12 are electrically connected to the positive electrode power supply member 14a and the negative electrode power supply member 15a in a wide range of the respective longitudinal directions E, The electrode 10a for water generation suppresses a decrease in the efficiency of the current and can efficiently use the current. In other words, the hydrogen-containing water generating electrode 10a can suppress the deterioration of the utilization efficiency of the applied current. As a result, the hydrogen-containing water generating electrode 10a can increase the hydrogen content per unit electric power. By setting the length of the portion of the positive electrode power supply member 14a mounted on the positive electrode 11 and the length LS of the portion of the negative electrode power supply member 15a mounted on the negative electrode 12 within the above- The negative electrode 11 and the negative electrode 12 may be reinforced.

The positive electrode power supply member 14a protrudes from both the first end portion 11T1 and the second end portion 12T2 of the positive electrode 11 as shown in Fig. The negative electrode power supply member 15a protrudes from both the first end portion 12T1 and the second end portion 12T2 of the negative electrode 12. 8, the portion protruding from the first end portions 11T1 and 12T1 is attached to the mounting object ST1, and the portion protruding from the first end portions 11T1 and 12T1 is attached to the second mounting portion ST1, The portion protruding from the end portions 11T2 and 12T2 can be mounted on the mounting object ST2. As a result, the positive electrode 11 and the negative electrode 12 are mounted on the mounting targets ST1 and ST2 via the positive electrode power supply member 14a and the negative electrode power supply member 15a.

The positive power supply member 14a and the negative electrode power supply member 15a are provided with male screws 14S1 and 15S1 at portions projecting from the first ends 11T1 and 12T1 Is installed. The positive electrode power supply member 14a and the negative electrode power supply member 15a are provided with male screws 14S2 and 15S2 at portions protruding from the second end portions 11T2 and 12T2. The positive electrode power supply member 14a and the negative electrode power supply member 15a are mounted on the mounting object ST1 by the bolts 32 and 32 which are respectively turned on the male screws 14S1 and 15S1 on the first end portion 11T1 side And fixed. The positive electrode power supply member 14a and the negative electrode power supply member 15a are fixed to the mounting object ST2 by the bolts 31 and 31 which are respectively turned on the male screws 14S2 and 15S2 on the second end portion 12T2 side, And is fixed.

The bolts 32 and the terminals 34 and 34 for connecting the positive power supply member 14 and the negative power supply member 15 to the wiring are formed by the bolts 33 each turned on the male screws 14S1 and 15S1 . With this structure, electric power is applied to the positive electrode 11 and the negative electrode 12 via the terminals 34 and 34, the positive electrode power supply member 14a, and the negative electrode power supply member 15a. The hydrogen-containing water generating electrode 10a projects the positive electrode power supply member 14 and the negative electrode power supply member 15 from both sides of the positive electrode 11 and the negative electrode 12. Therefore, the same operation and effect as those of the hydrogen-containing water generating electrode 10 (see FIG. 4, etc.) can be obtained.

The hydrogen-containing water generating electrode 10b shown in Fig. 9 is a member in which the positive electrode power supply member 14b and the negative electrode power supply member 15b are connected to the first ends 11T1 and 12T1 of the positive electrode 11 and the negative electrode 12, And does not protrude from the second end portions 11T2 and 12T2, which is different from the electrode 10a for generating hydrogen-containing water shown in Fig. The other structure of the hydrogen-containing water generating electrode 10b is the same as that of the hydrogen-containing water generating electrode 10a shown in Fig. Therefore, the hydrogen-containing water generating electrode 10b is configured such that only the first end portions 11T1 and 12T1 of the positive electrode 11 and the negative electrode 12 are attached to the mounting object ST, The same action and effect as those of the electrode 10a for producing a water containing water can be obtained.

10 and 11 are cross-sectional views showing a modified example of the electrode for producing hydrogen-containing water. Figs. 10 and 11 show cross sections orthogonal to the central axis Zt of the electrodes 10c and 10d for producing hydrogen-containing water. 10 includes a positive electrode 11c, a negative electrode 12c and an insulator 13c, and further includes a flat portion 10P and a curved portion 10c connected thereto 10R). The positive electrode 11c has a slit 11SLa extending in the longitudinal direction, that is, the direction in which the positive electrode 11c, which is a tubular member, extends. The negative electrode 12c has a slit 12SLa extending in the longitudinal direction, that is, the direction in which the negative electrode 12c, which is a tubular member, extends. The hydrogen-containing water generating electrode 10d shown in Fig. 11 includes a positive electrode 11d, a negative electrode 12d and an insulator 13d, and further includes a first flat portion 10PA and both ends And a curved surface portion 10R connecting the pair of second planar portions 10PB and 10PB to the second planar portions 10PB and 10PB. The positive electrode 11d has a slit 11SLb extending in the longitudinal direction, that is, the direction in which the positive electrode 11d, which is a tubular member, extends. The negative electrode 12d has a slit 12SLb extending in the longitudinal direction, that is, the direction in which the negative electrode 12d, which is a tubular member, extends.

The positive electrodes 11c and 11d and the negative electrodes 12c and 12d included in the electrodes 10c and 10d for producing hydrogen-containing water are a combination of a plane and a curved surface. The electrodes 10, 10a and 10b for producing hydrogen-containing water shown in Figs. 1, 2, 8 and 9 and the like have a cylindrical shape, and therefore, the entire surface of the positive electrode 11 and the negative electrode 12, to be. As described above, in this embodiment, the positive electrodes 11, 11c, and 11d and the negative electrodes 12, 12c, and 12d included in the electrodes 10, 10a, 10b, 10c, . The hydrogen-containing water generating electrode 10 is formed by arranging the positive electrode 11 and the negative electrode 12 in a cylindrical shape so that hydrogen bubbles are effectively separated from the negative electrode 12 over the entire circumference and dissolved in the raw water W . In addition, the positive electrode 11 and the negative electrode 12 are formed into a cylindrical shape, which is easy to manufacture.

The hydrogen-containing water producing electrodes 10, 10a, 10b, 10c, and 10d are formed by forming the positive electrodes 11, 11c, and 11d and the negative electrodes 12, 12c, and 12d into shapes having curved surfaces, . When the electrodes 10, 10a, 10b, 10c, and 10d for generating hydrogen-containing water are charged into the raw water W and used, the portions of the curved surfaces face upward (toward the direction opposite to the direction in which gravity acts) . Next, the openings 11H, 12H, and 13H of the positive electrode 11, the negative electrode 12, and the insulator 13 will be described.

12 is an enlarged view of a part of the positive electrode and the negative electrode. 13 is an enlarged view of the openings of the positive electrode and the negative electrode. 14 is a sectional view taken along the line B-B in Fig. 15 is an enlarged view of a part of the insulator. The positive electrode 11 and the negative electrode 12 are mesh-like members in which a plurality of linear portions (linear portions) 16 cross each other. The portions surrounded by the plurality of linear portions 16 are the openings 11H and 12H of the positive electrode 11 and the negative electrode 12, respectively. In the present embodiment, the openings 11H and 12H of the positive electrode 11 and the negative electrode 12 have a rhombic shape. One of the openings 11H and 12H has a diagonal line (first diagonal line) TL1 longer than the other diagonal line (second diagonal line) TLs. The openings 11H and 12H are formed such that the angle at the tops Pa and Pb on the first diagonal line TLl is smaller than the angle at the tops Pc and Pd on the second diagonal lines TLs.

The positive electrode 11 and the negative electrode 12 have a plurality of openings 11H and 12H so that they can rotate through the openings 11H and 12H and inside and outside. Because of this, both the positive electrode 11 and the negative electrode 12 can use both surfaces for electrolysis, so that hydrogen can be efficiently generated. The negative electrode 12 is capable of releasing bubbles of hydrogen from a small state because the opening angle 12H surrounded by the linear portion 16 can reduce the wetting angle of hydrogen bubbles generated by the negative electrode 12 . That is, the attraction force generated between the generated hydrogen and the surface of the negative electrode 12 is close to the point contact state and the surface tension is suppressed. As a result, the negative electrode 12 releases the hydrogen bubbles in a small state , A hydrogen-containing water in which many bubbles of hydrogen are dissolved can be produced.

In the present embodiment, the linear portions 16 of the positive electrode 11 and the negative electrode 12 are rectangular in cross section (square in the example of Fig. 14) as shown in Fig. The negative electrode 12 can reduce the surface tension by further decreasing the wetting angle of hydrogen bubbles by the corner portion 16T of the linear portion 16 and therefore the hydrogen bubbles can be released in a smaller state . For this reason, the negative electrode 12 can generate hydrogen water in which bubbles of smaller hydrogen are dissolved. Further, since the negative electrode 12 has the linear portion 16 having a rectangular cross section, the surface area usable for generation of hydrogen can be increased. By these actions, the efficiency of the negative electrode 12 to dissolve hydrogen in the raw water is improved.

13, the first diagonal line TLl is formed in the direction in which the positive electrode 11 and the negative electrode 12 extend, that is, in the longitudinal direction E, It is heading. The second diagonal lines TLs are directed in the circumferential direction C of the cylindrical positive electrode 11 and the negative electrode 12. The positive electrode 11 and the negative electrode 12 have end side openings 10HA and 10HB on both sides in the longitudinal direction E as shown in Figs. The bubbles of oxygen generated inside the positive electrode 11 are discharged from the end side openings 10HA and 10HB to the outside of the hydrogen-containing water generating electrode 10 as shown in Fig. At this time, since the longitudinal direction of the opening 11H of the positive electrode 11 is aligned in the direction in which the bubbles of oxygen move, the bubbles of oxygen easily move to the end side openings 10HA and 10HB. As a result, the hydrogen-containing water generating electrode 10 can effectively release oxygen bubbles to the outside. The opening 11H of the positive electrode 11 is formed such that the angle of the tops Pa and Pb on the first diagonal line TLl is an acute angle so that the contact area between the bubbles of oxygen and the linear portion 16 can be made small have. As a result, the oxygen bubbles are easily separated from the linear portion 16, so that the hydrogen-containing water generating electrode 10 can efficiently release oxygen bubbles to the outside. Since the linear portion 16 of the positive electrode 11 has the edge portion 16T, the edge angle of the oxygen bubbles can be further reduced by the edge portion 16T, and the surface tension can be suppressed . As a result, the positive electrode 11 can quickly move the bubbles of oxygen from the linear portion 16 to the end side openings 10HA and 10HB. For this reason, the electrode 10 for producing hydrogen-containing water can efficiently release oxygen bubbles to the outside. Further, in the process of moving the bubbles of oxygen along the inside of the positive electrode 11, the air bubbles of oxygen newly formed at the side of the positive electrode 11 are received and the bubbles of oxygen are grown. Therefore, the area of contact between the bubbles of oxygen and the raw water W can be reduced, and the dissolved oxygen in the raw water W can be suppressed.

As shown in Fig. 15, the insulator 13 is a mesh-like member which crosses a plurality of linear members 17 and which is surrounded by the linear members 17 as openings 13H. The opening 13H has a rectangular shape (square shape in this embodiment). The length of one side of the opening 13H is La, and the length of the side adjacent to this side is Lb. In the present embodiment, since the opening 13H has a square shape, La = Lb. The side having the length La is parallel to the longitudinal direction E of the positive electrode 11 and the negative electrode 12 and the side having the length Lb is a cylindrical positive electrode 11 and a negative electrode 12 in the circumferential direction C ).

The opening 11H of the positive electrode 11 and the opening 12H of the negative electrode 12 are larger than the opening 13H of the insulator 13 in this embodiment. The areas of the openings 11H and 12H are Ll 占 Ls / 2 where the length of the first diagonal line TLl is Ll and the length of the second diagonal line TLs is Ls. The area (opening area) of the opening 13H is La 占 Lb. Therefore, Ll x Ls / 2 > La x Lb. The length Ll of the first diagonal line TLl is 6 mm and the length Ls of the second diagonal line TLs is 3 mm so that the area of the openings 11H and 12H is, 9 mm 2. The opening 13H is, for example, La = Lb = 1.06 mm. That is, in the insulator 13, twenty-four openings 13H per inch are arranged. The area of the opening 13H (opening area) is 1.12 mm &lt; 2 &gt;. Thus, in the present embodiment, the areas of the openings 11H and 12H of the positive electrode 11 and the negative electrode 12 are about eight times the area of the opening 13H.

When the opening 13H of the insulator 13 is larger than the openings 11H and 12H of the positive electrode 11 and the negative electrode 12, the negative electrode 12 and the positive electrode 11 pass through the opening 13H of the insulator 13, Is likely to be in contact. The hydrogen-containing water generating electrode 10 is formed in the opening 13H of the insulator 13 by making the opening 13H of the insulator 13 smaller than the openings 11H and 12H of the positive electrode 11 and the negative electrode 12, It is possible to prevent the positive electrode 11 and the negative electrode 12 from coming into contact with each other. As described above, the hydrogen-containing water generating electrode 10 avoids a short circuit between the positive electrode 11 and the negative electrode 12 even if the distance between the positive electrode 11 and the negative electrode 12 is small, . Therefore, the hydrogen-containing water generating electrode 10 is suitable for the method of charging into the raw water W which is required to suppress the voltage applied to the positive electrode 11 and the negative electrode 12 to a low level.

In the present embodiment, the insulator 13 is a mesh-like member crossing a plurality of linear members 17. [ When such a mesh-like member is used, the insulator 13 is allowed to be deformed to some extent in the thickness direction, so that when the hydrogen-containing water generating electrode 10 is vibrated or impacted, the insulator 13 absorbs can do. When the insulator 13 is provided with a mesh-shaped member crossing a plurality of linear members 17, it is suitable for a movable hydrogen-containing water generating electrode 10 capable of movement and transportation.

The hydrogen-containing water generating electrode 10 is formed such that the opening 13H of the insulator 13 is smaller than the opening 11H of the positive electrode 11 and the opening 12H of the negative electrode 12, The generated bubbles of oxygen can be trapped by the linear members 17 of the insulator 13 to make large bubbles. As the bubbles of oxygen are increased, the dissolved oxygen in the raw water W is suppressed, so that the hydrogen-containing water generating electrode 10 can generate a hydrogen-containing water having a high hydrogen bubble dissolution rate. As a result, the bubbles of oxygen easily move inside the positive electrode 11 and the bubbles of the oxygen easily move through the opening 13H. As a result, the hydrogen-containing water generating electrode 10 , It becomes easy to release the bubbles of oxygen from the inside.

The bubbles of oxygen that have not been captured by the linear member 17 pass through the openings 13H of the insulator 13 and form bubbles of hydrogen attached to the linear portions 16 of the negative electrode 12 And is released from the linear portion 16. Therefore, the hydrogen-containing water generating electrode 10 can quickly dissociate hydrogen bubbles generated in the negative electrode 12 from the negative electrode 12 and dissolve in the raw water W. Next, a method of manufacturing the hydrogen-containing water generating electrode 10 will be described.

&Lt; Method for producing hydrogen-containing water generating electrode >

16 is a flow chart of a method of manufacturing an electrode for producing hydrogen-containing water according to this embodiment. Fig. 17 to Fig. 26 are diagrams showing respective steps of the method for producing an electrode for producing hydrogen-containing water according to the present embodiment. In producing the hydrogen-containing water producing electrode 10, first, in step S101, as shown in Figs. 17 and 18, the positive electrode material 11M and the negative electrode material 12M as the conductive material are bent to form a substantially cylindrical . The positive electrode material 11M and the negative electrode material 12M correspond to the openings 12H of the positive electrode 11 and the negative electrode 12 shown in Fig. ). The substantially cylindrical member in which the positive electrode material 11M and the negative electrode material 12M are bent is partly removed in the circumferential direction C so that the longitudinal direction E, And slits 11SL and 12SL in the direction of the arrows. As shown in Fig. 17, the slits 11SL are formed between the opposing end portions 11MT and 11MT of the positive electrode material 11M. As shown in Fig. 18, the slits 12SL are formed between the opposing end portions 12MT and 12MT of the anode material 12M.

The longitudinal direction E of the positive electrode material 11M is parallel to the first diagonal line TLl of the opening 11H of the positive electrode material shown in Fig. The first diagonal line TLl of the opening 11H is longer than the second diagonal line TLs. Therefore, in the opening 11H shown in Fig. 19, the second diagonal lines TLs shorter than the first diagonal line TLl are directed in the circumferential direction C of the substantially cylindrical member in which the positive electrode material 11M is bent have. As a result, it becomes easy to bend the positive electrode material 11M into a cylindrical shape, and it becomes easy to ensure the dimensional accuracy of the positive electrode 11.

The negative electrode material 12M has a longitudinal direction E parallel to the first diagonal line TLl of the opening 12H of the negative electrode material shown in Fig. The first diagonal line TLl of the opening 12H is longer than the second diagonal line TLs. 20, the second diagonal lines TLs shorter than the first diagonal line TLl are directed in the circumferential direction C of the substantially cylindrical member in which the negative electrode material 12M is bent have. As a result, it becomes easy to bend the negative electrode material 12M in a cylindrical shape, and it becomes easy to ensure the dimensional accuracy of the negative electrode 12.

Next, in step S102, the power supply member and the support member are mounted on the positive electrode material 11M and the negative electrode material 12M which are bent into a cylindrical shape, respectively (see Figs. 21 and 22). The power supply member refers to the positive-electrode power-supply member 14 shown in Fig. 21 and the negative-electrode power-supply member 15 shown in Fig. The support member refers to the positive electrode support member 18 shown in Fig. 21 and the negative electrode support member 19 shown in Fig.

As shown in Fig. 21, the positive electrode power supply member 14 and the positive electrode support member 18 are mounted on the inner surface 11Mi of the bending of the positive electrode material 11M. The positive electrode power supply member 14 and the positive electrode support member 18 are connected to the positive electrode material 11M such that the longitudinal direction thereof is parallel to the first diagonal line TLl of the opening 11H shown in Fig. do. The positive electrode power supply member 14 and the positive electrode support member 18 are bonded to the positive electrode material 11M by, for example, welding. For this reason, the positive electrode power supply member 14 and the positive electrode material 11M are electrically connected.

22, the negative electrode power supply member 15 and the negative electrode support member 19 are mounted on the outer surface 12Mo of the bending of the negative electrode material 12M. The negative electrode power supply member 15 and negative electrode support member 19 are connected to the negative electrode material 12M such that the longitudinal direction thereof is parallel to the first diagonal line TLl of the opening 12H shown in Fig. do. The negative electrode power supply member 15 and the negative electrode support member 19 are bonded to the negative electrode material 12M by, for example, welding. Therefore, the negative-electrode power-supply member 15 and the negative-electrode material 12M are electrically connected.

The positive electrode material 11M on which the positive electrode power supply member 14 and the positive electrode support member 18 are mounted and the negative electrode material 12M on which the negative electrode power supply member 15 and the negative electrode support member 19 are mounted, Plating (platinum plating in this embodiment) is performed. In the case where the negative electrode 12 is not plated, only the positive electrode material 11M on which the positive electrode power supply member 14 and the positive electrode support member 18 are mounted is plated. Thus, the positive electrode 11 and the negative electrode 12 are completed. The positive electrode 11 and the negative electrode 12 are both tubular conductors and have a plurality of openings in the side portions and a part in the circumferential direction is removed so that the longitudinal direction E, And has slits 11SL and 12SL extending in the extending direction.

23, the side portion 11S of the positive electrode 11, which is a cylindrical conductor and has a plurality of openings 11H in the side portion 11S, is formed into a net- And is covered with an insulator 13. The position of the slit 11SL is not particularly limited in covering the side portion 11S of the positive electrode 11 with the insulator 13.

24, the negative electrode 12 is mounted on the outside of the insulator 13 from the slit 12SL through the positive electrode 11 and the insulator 13, as shown in Fig. When the positive electrode 11 and the insulator 13 are passed through the slit 12SL of the negative electrode 12, the slit 12SL is opened. When the positive electrode 11 and the insulator 13 are disposed inside the negative electrode 12, the slit 12SL that has been opened is closed in step S105.

25, a constraining member 40 is attached to the outside of the negative electrode 12 to constrain the negative electrode 12, the insulator 13, and the positive electrode 11 at step S106. A plurality of restraint members (40) are mounted between the negative electrode power supply member (15) and the negative electrode support member (19). The constraining member 40 can be made of, for example, a binding band made of resin, or can be made of a metal wire rod or the like which has high corrosion resistance and does not elute into the raw water W. The negative electrode 12, the insulator 13 and the positive electrode 11 are confined by the restricting member 40 to complete the hydrogen-containing water generating electrode 10 as shown in Fig. The extra insulator 13 may be taken out from the closed slit 12SL to the outside of the negative electrode 12.

The negative electrode 12 and the positive electrode 11, which are cylindrical members, are imparted with a force directed in the circumferential direction by the confining member 40. Therefore, the slits 11SL and 12SL of the positive electrode 11 and the negative electrode 12 are closed. The positive electrode 11 is an elastic material together with the conductive material and the deformation to the degree of closing the slit 11SL is deformation within the range of the elastic deformation of the material of the positive electrode 11. Therefore, when the slit 11SL of the positive electrode 11 is closed, a force for opening the closed slit 11SL is generated in the positive electrode 11.

The positive electrode 11 is restrained by the restricting member 40 via the negative electrode 12 so that the above-described force generated in the positive electrode 11 causes the positive electrode 11 and the insulator 13 to contact the negative electrode 12 ). As a result, since the insulator 13 reliably contacts the positive electrode 11 and the negative electrode 12, the gap formed between the positive electrode 11 and the negative electrode 12 by the thickness of the insulator 13 has a good accuracy . Displacement between the positive electrode 11, the insulator 13, and the negative electrode 12 is suppressed by the above-described force generated in the positive electrode 11. In this way, the hydrogen-containing water generating electrode 10 used in the moveable portable device can be manufactured.

The method for producing an electrode for producing hydrogen-containing water according to the present embodiment does not use welding or the like other than attaching the power supply member and the support member to the positive electrode material 11M and the negative electrode material 12M. Therefore, by separating the restricting member 40, the hydrogen-containing water generating electrode 10 can be easily decomposed into the positive electrode 11, the negative electrode 12, and the insulator 13, It is easy to check, repair and replace parts. Further, the electrode 10 for producing hydrogen-containing water can be easily recycled. Next, a hydrogen-containing water producing apparatus having an electrode 10 for producing hydrogen-containing water will be described.

&Lt; Hydrogen-containing water producing device >

27 is a view showing a hydrogen-containing water producing apparatus according to the present embodiment. 28 is a view showing a first support provided in the hydrogen-containing water producing apparatus according to the present embodiment. 29 is a view showing a second support provided in the hydrogen-containing water producing apparatus according to the present embodiment. 30 is a view showing an opening of a protective member and an opening of a negative electrode included in the hydrogen-containing water generating device according to the present embodiment. The hydrogen-containing water producing apparatus 100 is provided with the hydrogen-containing water generating electrode 10 described above and is charged into the raw water W to generate hydrogen-containing water.

The hydrogen-containing water producing apparatus 100 includes a first support 101, a second support 102, and an electrode 10 for producing hydrogen-containing water. In the present embodiment, the hydrogen-containing water producing apparatus 100 further has a protective member 103. [ The first support 101 is mounted on the first end 10T1 side of the electrode 10 for producing hydrogen-containing water. The first support member 101 has a first installation portion 101C which is in contact with an installation object FL of the hydrogen-containing water producing apparatus 100. [ The installation object FL is, for example, a bottom portion of a bathtub or a bottom portion of a drinking water tank. In the present embodiment, the first mounting portion 101C is a side portion around the center axis Zt of the electrode 10 for producing hydrogen-containing water, among the side portions of the first supporting body 101. [

The second support member 102 is mounted on the second end portion 10T2 side of the electrode 10 for producing hydrogen-containing water. The second supporting member 102 has a second mounting portion 102C that is in contact with the mounting target FL. The second mounting portion 102C is a side portion around the center axis Zt of the electrode 10 for producing hydrogen containing water among the side portions of the second supporting member 102 in this embodiment. The second support member 102 is formed from the side portion 11S of the positive electrode 11 in the direction orthogonal to the side portion 11S of the positive electrode 11 of the hydrogen- (Second support side height) h2 from the side 11S of the positive electrode 11 in the direction orthogonal to the side portion 11S of the positive electrode 11 to the first installation portion 101C (The first support side height) h1. The height H1 of the first support body 101 shown in Fig. 28 is smaller than the height H2 of the second support body 102 shown in Fig. In this example, the height h1 on the first support side and the height h2 on the second support side are all based on the installation object FL and the installation part.

The first end portion 10T1 of the hydrogen-containing water generating electrode 10 corresponds to the first end portions 11T1 and 12T1 of the positive electrode 11 and the negative electrode 12 shown in Fig. 4 and the second end portion 10T2, Correspond to the second ends 11T2 and 12T2 of the positive electrode 11 and the negative electrode 12, respectively. The direction orthogonal to the side portion 12S of the negative electrode 12 corresponds to a direction orthogonal to the central axis Zt of the electrode 10 for producing hydrogen-containing water. The first support 101 and the second support 102 are manufactured, for example, by molding a resin. The first support 101 and the second support 102 support the hydrogen-containing water generating electrode 10 when installed in the installation target FL.

The protective member 103 is a tubular member (cylindrical in this embodiment) and has a plurality of openings 103H on its side. The plurality of openings 103H of the protective member 103 penetrate the side portion of the protective member 103 in the thickness direction of the protective member 103. [ The protective member 103 is provided on the outer side of the hydrogen-containing water generating electrode 10, more specifically, on the outer side of the negative electrode 12. The first end portion 103T1 of the protective member 103 is supported by the first support member 101 and the second end portion 103T2 is supported by the second support member 102. [ With this structure, the electrode 10 for generating hydrogen-containing water and the protective member 103 are supported by the first support body 101 and the second support body 102 at the both end sides thereof.

The protective member 103 is provided outside the hydrogen-containing water generating electrode 10 to protect it. When the hydrogen-containing water producing apparatus 100 is used, the protective member 103 is put into the raw water W and comes into contact with the raw water W. [ For this reason, the protective member 103 is made of, for example, stainless steel having high strength and corrosion resistance. The protective member 103 mounted on the first support body 101 and the second support body 102 has a certain degree of strength to protect the hydrogen-containing water generating electrode 10. For this reason, the protective member 103 also has a function as a structural member for securing the strength of the hydrogen-containing water producing apparatus 100 together with the first support body 101 and the second support body 102. [

27 and 28, the first support 101 has a first opening 101H as an opening connected to a space surrounded by the side of the positive electrode 11. As shown in Figs. 27 and 29, the second support member 102 has a second opening portion 102H as an opening portion connected to a space surrounded by the side portion of the positive electrode 11. The first opening 101H and the second opening 102H connect the inside and the outside of the positive electrode 11 of the hydrogen-containing water generating electrode 10, It becomes a passage. The opening portion connected to the space surrounded by the side portion of the positive electrode 11 may have at least one of the first supporting member 101 and the second supporting member 102. [

Thus, by making the height h2 of the second support member side larger than the height h1 of the first support member, the electrode 10 for generating hydrogen is directed from the first support member 101 to the second support member 102 So that the distance from the installation target FL is increased according to the distance from the installation target FL to the installation target FL. The positive electrode 11 of the electrode 10 for producing hydrogen-containing water is in the shape of a cylinder, and the cross-sectional shape orthogonal to the central axis Zt is constant in a direction parallel to the central axis Zt. Therefore, the inside (upper inside of the positive electrode) of the positive electrode 11, particularly the side of the positive electrode 11 farther from the first and second mounting portions 101C and 102C, 2 support member 102, the distance from the installation target FL is increased.

The hydrogen-containing water producing apparatus 100 is configured such that the inside of the upper portion of the positive electrode 11 and the upper portion of the positive electrode 11 are inclined as described above so that the bubbles of oxygen generated on the side of the positive electrode 11, . The bubbles of oxygen move toward the second opening portion 102H of the second support member 102 along the inside of the upper portion of the positive electrode due to the influence of the buoyancy and are discharged outside the hydrogen-containing water producing apparatus 100, And is discharged to the outside of the electrode 10 for producing hydrogen-containing water. As described above, the hydrogen-containing water producing apparatus 100 is configured such that the positive electrode 11 is tilted so as to fall away from the ground surface of the installation target FL toward the second opening portion 102H, , The bubbles of oxygen in the positive electrode 11 can be efficiently and rapidly discharged from the second opening portion 102H to the outside. Therefore, the hydrogen-containing water producing apparatus 100 can release the bubbles of oxygen in the positive electrode 11 to the outside even when there is no water in the hydrogen-containing water generating electrode 10.

(Angle of inclination) formed between the electrode 10 for generating hydrogen-containing water and the ground face of the installation target FL is defined as?. In this embodiment, the tilting angle? Is, for convenience, an imaginary ground plane FLv parallel to the ground plane of the installation target FL and a central axis Zt of the hydrogen-containing water generating electrode 10 The angle is made. The inclination angle? Is preferably 0.5 deg. Or more, more preferably 1 deg. Or more, more preferably 1.5 deg. Or more, in view of discharging oxygen bubbles to the outside of the hydrogen-containing water generating electrode 10 efficiently Suitable. When the inclination angle? Is within this range, the hydrogen-containing water producing apparatus 100 can efficiently and rapidly discharge the bubbles in the hydrogen-containing water generating electrode 10. [

When the inclination angle? Is increased, the bubbles of oxygen generated in the positive electrode 11 coalesce and are discharged into the raw water before becoming a sufficient size. As a result, if the inclination angle? Is large, the amount of oxygen dissolved in the raw water tends to increase. From the viewpoint of suppressing the amount of dissolved oxygen in the raw water, it is preferably 5 degrees or less, more preferably 4 degrees or less, and further preferably 3 degrees or less. When the inclination angle? Is within this range, the hydrogen-containing water producing apparatus 100 can suppress the amount of dissolved oxygen in the raw water. If the inclination angle? Is within this range, the height of the hydrogen-containing water producing apparatus 100, specifically, the height H2 of the second support member 102 shown in Fig. 27 is prevented from being excessively increased, The hydrogen-containing water producing apparatus 100 can be made compact. The inclination angle? Is preferably 0.5 to 5 degrees, more preferably 1 to 4 degrees, further more preferably 1.5 to 3 degrees. In this embodiment, the inclination angle? Is 2 degrees.

The hydrogen-containing water producing apparatus 100 has the first opening 101H in the first supporting member 101 and the second opening 102H in the second supporting member 102. [ Therefore, the hydrogen-containing water generating electrode 10 can be cleaned from at least one of the first opening 101H and the second opening 102H. For example, the cleaning water is sprayed from the first opening 101H to the hydrogen-containing water generating electrode 10 by a hose or the like to clean it, or a brush or the like is inserted from the first opening 101H, It is possible to remove the dirt of the electrode 10, particularly the positive electrode 11. [ As described above, since the hydrogen-containing water producing apparatus 100 has the first opening 101H and the second opening 102H, it is possible to easily perform the operation for cleaning the hydrogen-containing water generating electrode 10 have. The hydrogen-containing water generating electrode 10 is immersed in a cleaning liquid (for example, an aqueous solution of citric acid) for a predetermined time in the hydrogen-containing water producing apparatus 100, in addition to the cleaning with water, The minerals precipitated on the surface of the substrate 12 are removed. As described above, the hydrogen-containing water generating electrode 10 does not need to supply the water or the cleaning liquid used for cleaning separately from the raw water W, so that the electrode 10 can have a simple structure. Further, the above-described operation and effect can be obtained when the hydrogen-containing water producing apparatus 100 has at least one of the first opening 101H and the second opening 102H. Next, the relationship between the opening 103H of the protective member 103 and the opening 12H of the negative electrode 12 will be described.

In the present embodiment, as shown in Fig. 30, the shape of the opening 103H of the protective member 103 is a circle having a diameter of D. Fig. The opening 103H of the protective member 103 is larger than the opening 12H of the negative electrode 12. [ Specifically, the area of the opening (103H) is, π × D ^2/4 of the area, and the aperture (12H) is Ll × Ls / 2 ^{because, π × D 2/4>} Ll × Ls / 2. By doing so, the bubbles of hydrogen generated on the side of the negative electrode 12 can efficiently pass through the openings 103H of the protective member 103, and hydrogen bubbles can efficiently be dissolved in the raw water W. By making the shape of the opening 103H of the protective member 103 circular, the opening 103H can be easily manufactured.

31 is a view showing another embodiment of the hydrogen-containing water producing apparatus according to the present embodiment. The hydrogen-containing water producing apparatus 100 may be provided so that the second opening 102H side of the second support member 102 faces the installation target FL. Alternatively, the hydrogen-containing water producing apparatus 100 may be provided so that the first opening 101H side of the first supporting member 101 faces the installation target FL. In this way, the center axis Zt of the electrode 10 for producing hydrogen-containing water becomes orthogonal to the ground plane of the installation target FL. The air bubbles of oxygen generated on the side of the positive electrode 11 of the electrode 10 for generating a hydrogen-containing water from the first opening 101H of the first supporting member 101 disposed on the side opposite to the installation object FL are mixed with the raw water W). When the side of the first opening 101H of the first supporting member 101 is directed toward the installation target FL, the electrode 10 for hydrogen-containing water is discharged from the second opening 102H of the second supporting member 102, The air bubbles of oxygen generated on the side of the positive electrode 11 of the electrode 11 are discharged into the raw water W.

The hydrogen bubbles generated on the side of the negative electrode 12 of the hydrogen-containing water generating electrode 10 are discharged into the raw water W from the entire periphery of the negative electrode 12 and pass through the opening 103H of the protection member 103 I'll go. Thus, in the hydrogen-containing water producing apparatus 100, both the first support body 101 and the second support body 102 may be provided on the installation object FL, and only the second support body 102 may be installed on the installation object FL As shown in Fig. Therefore, the hydrogen-containing water producing apparatus 100 can be used in different modes depending on the environment in which it is used.

It is preferable that the hydrogen-containing water producing apparatus 100 is provided so that the first supporting body 101 and the second supporting body 102 have larger areas toward the installation target FL. By doing so, the hydrogen-containing water producing apparatus 100 can be stably installed.

(Mounting structure of electrode for producing hydrogen-containing water)

Figs. 32 and 33 are views showing a mounting structure when an electrode for producing hydrogen-containing water is mounted on the hydrogen-containing water producing device according to the present embodiment. Fig. 34 is a view showing another mounting structure when an electrode for producing hydrogen-containing water is mounted on the hydrogen-containing water producing device according to the present embodiment. 32 and 33 show the case where the hydrogen-containing water producing apparatus 100 is put into a bath and used. 32 and 33, in the present embodiment, the hydrogen-containing water generating electrode 10 is formed by the positive electrode power supply member 14 and the negative electrode power supply member 15, And the second support member 102 are supported. By using the positive electrode power supply member 14 and the negative electrode power supply member 15 and the positive electrode support member 18 and the negative electrode support member 19, the hydrogen-containing water generating electrode 10 is formed into a relatively simple structure And can be mounted on the first support body 101 and the second support body 102.

The negative electrode power supply member 14 protruded from the first end portion 11T1 side of the positive electrode 11 and the negative electrode power supply member 14 protruded from the first end portion 12T1 side of the negative electrode 12 15 are mounted on the first support body 101. As shown in Fig. The first support 101 corresponds to a mounting object ST1 shown in Fig. The positive electrode support member 18 protruded from the second end portion 11T2 side of the positive electrode 11 and the negative electrode support member 18 protruded from the second end portion 12T2 side of the negative electrode 12 19 are attached to the second support member 102. [ The second support member 102 corresponds to the mounting object ST2 shown in Fig.

The first support 101 has a mounting seat 101B, a cylindrical side cover 101CS and a lid 101CB in the form of a flat plate. The mounting seat 101B supports the electrode 10 for generating hydrogen-containing water and the protective member 103. [ The mounting seat 101B has a tubular member 101IW (hereinafter referred to as tubular member) extending toward the direction away from the mounting seat 101B on the side opposite to the electrode 10 for producing hydrogen- I have. The inner portion of the tubular member 101IW is a passage connecting the inside of the positive electrode 11 and the outside of the first support member 101. [ The lid 101CB is attached to the end of the side cover 101CS and the end of the tubular member 101IW. The lid 101CB has an opening 101CBH connected to the inside of the tubular member 101IW. The inside of the tubular member 101IW and more specifically the tubular member 101IW and the opening 101CBH of the lid 101CB become the first opening 101H.

The mounting sheet 101B is a member for mounting the positive electrode power supply member 14 and the negative electrode power supply member 15 and supporting the hydrogen-containing water generating electrode 10 therebetween. The positive electrode power supply member 14 and the negative electrode power supply member 15 are mounted on the mounting seat 101B by the bolts 32 each turned on the male screws 14S and 15S, . The first ends 11T1 and 12T1 of the positive electrode 11 and the negative electrode 12 come into contact with the mounting surface 101P which is one surface of the mounting sheet 101B. The mounting seat 101B is sandwiched between the first ends 11T1 and 12T1 of the positive electrode 11 and the negative electrode 12 and the bolts 32 and 32. [ With this structure, the hydrogen-containing water generating electrode 10 is mounted on and supported by the mounting sheet 101B via the positive electrode power supply member 14 and the negative electrode power supply member 15. [

The first openings 101H of the first support member 101 are opposed to the openings on the first end portions 11T1 and 12T1 sides of the positive electrode 11 and the negative electrode 12, Passes through the first opening 101H and is discharged to the outside of the hydrogen-containing water producing apparatus 100. [

A space 101J is formed in a space (a first supporting member internal space) 101SP surrounded by the mounting sheet 101B, the lid 101CB, the side cover 101CS and the tubular member 101IW, And a terminal 34 for connecting the negative power supply member 15 and the wiring 25 are disposed in the vicinity of the terminal 34. [ The wiring 25 passes through a grommet 26 provided in a hole 102SPH provided in the side cover 101CS and is drawn out from the first supporting member internal space 101SP. The wiring lines 25 are electrically connected to the terminals 34 and 34. The grommet 26 interposed between the wiring 25 and the side cover 101CS of the first support 101 protects the wiring 25 and protects the first support member internal space 101SP For example, made of rubber. The first support member inner space 101SP is filled with a waterproofing agent, for example. The positive electrode power supply member 14, the negative electrode power supply member 15, the terminal 34 and the wiring 25 are waterproofed with a waterproofing agent.

33, the positive electrode support member 18 and the negative electrode support member 19 are attached to the second support member 102 by the bolts 31 which are respectively turned on the male screws 18S and 19S, . The second ends 11T2 and 12T2 of the positive electrode 11 and the negative electrode 12 are in contact with the mounting surface 102P which is one surface of the second support member 102. [ The second support member 102 is sandwiched between the second ends 11T2 and 12T2 of the positive electrode 11 and the negative electrode 12 and the bolts 31 and 31. [ The bolt 31 is embedded in a locating hole 102BH provided on a surface opposite to the mounting surface 102P of the second support member 102. [ With this structure, the hydrogen-containing water generating electrode 10 is attached to and supported by the second support member 102 via the positive electrode support member 18 and the negative electrode support member 19. The second support member 102 also supports the protection member 103 together with the first support member 101.

As described above, the hydrogen-containing water generating electrode 10 and the protective member 103 are supported by the first support 101 and the second support 102 at both ends in the longitudinal direction. The hydrogen-containing water producing apparatus 100 can be made strong by supporting the hydrogen-containing water generating electrode 10 and the protection member 103 from both sides in the longitudinal direction thereof.

The first supporting body 101a of the hydrogen-containing water producing apparatus 100a shown in Fig. 34 has a mounting seat 101Ba, a cylindrical side-side cover 101CSa, and a flat lid 101CBa . The mounting seat 101Ba does not have the cylindrical member 101IW of the mounting seat 101B shown in Fig. Therefore, the first support 101a does not have the first opening 101H of the first support 101 shown in Fig. The positive electrode power supply member 14, the negative electrode power supply member 15, the terminal 34 and the wiring 25 are provided with a mounting sheet 101Ba, a side cover 101CSa and a cover member 101CBa 1 support member inner space 101SPa. A waterproofing agent is filled in the first support member inner space 101SPa. The other structures of the first support 101a and the relationship with the electrode 10 for producing hydrogen-containing water are the same as those of the first support 101 shown in Fig. The second support member 102 shown in Fig. 33 is directly applied to the hydrogen-containing water producing apparatus 100a.

The wiring 25 is connected to the power source 20 via the connector 27. [ The power source 20 is, for example, a secondary battery, and in this embodiment, it is a lead acid battery. The power source 20 has a control panel 21. The control panel 21 includes a control device (e.g., a microcomputer) 21C, a power switch 22, and a display device 23. The display device 23 is, for example, a single or plural light emitting diodes or liquid crystal display panels. The power source 20 is connectable to an AC (Alternative Current) adapter 24 for charging. When the power switch 22 is turned on, electric power is applied to the electrode 10 for generating hydrogen-containing water from the power source 20, and the hydrogen-containing water generating electrode 10 electrolyzes the raw water W, Containing water. In this embodiment, the control device 21C automatically stops supplying power when a predetermined time (for example, about 10 minutes to 20 minutes) elapses after the power switch 22 is turned on. In this way, in the case of generating the hot water containing hydrogen by putting the hydrogen-containing water generating apparatus 100 into the bath, it is possible to avoid the continuous supply of electric power until the bathing is completed, Can be suppressed.

The AC adapter 24 converts the alternating current into a direct current to charge the power source 20. In the present embodiment, the hydrogen-containing water producing apparatus 100 generates the hydrogen-containing water by the DC power supplied from the power source 20, but generates, for example, by the DC power supplied from the AC adapter 24 Hydrogen-containing water may also be produced. In this case, for example, the control device 21C switches the supply of electric power to the hydrogen-containing water generating electrode 10 to the power source 20 or the AC adapter 24. [

The display device 23 displays timing for charging the power source 20, timing for cleaning or maintenance of the hydrogen-containing water generating electrode 10, and the like. When the charging timing is reached, for example, the controller 21C flickers the lamp for charging notification of the display device 23, or when the cleaning timing is reached, for example, the display device 23 ) Is turned on or off. By doing so, the user of the hydrogen-containing water producing apparatus 100 can grasp the timing of charging or cleaning.

When the connector 27 connected to the wiring 25 is disconnected from the power source 20 or when the hydrogen-containing water generating apparatus 100 is pulled up from the raw water W, The output of the power from the power source 20 is stopped, that is, the power switch 22 is turned off. For example, the controller 21C stops the output of electric power from the power source 20 when the current flowing through the hydrogen-containing water generating electrode 10 is equal to or smaller than a predetermined value or becomes zero. When the hydrogen-containing water generating electrode 10 is pulled up from the water, the raw water W is not present between the positive electrode 11 and the negative electrode 12. As a result, The current is less than or equal to a predetermined value. This is because, when the connector 27 is pulled out from the power supply 20, no current flows through the electrode 25 for hydrogen-containing water generation via the wiring 25. The control device 21C can improve the safety by controlling the output of the power of the power source 20 as described above.

In the present embodiment, although the AC adapter 24 is connected to the power source 20 and charged, the charging of the power source 20 is not limited to this embodiment. For example, the power source 20 may be charged by a non-contact charging method using electromagnetic induction. This makes it easier to ensure the waterproof of the power source 20 and the charging device. Next, a modified example of the hydrogen-containing water producing apparatus 100 will be described.

(Modified example)

Fig. 35 to Fig. 37 are views showing a modified example of the hydrogen-containing water producing device according to the present embodiment. In use, the hydrogen-containing water producing apparatus 100b of this hydrogen-containing water producing apparatus 100b removes the collapsible retractable leg portion 104 from the second support member 102b and installs it on the installation target FL. 36, the leg portion 104 is a rod-like member that rotates around a rotational axis Zr provided on the installation target FL side of the second support body 102b, for example, to be. The leg portions 104 are arranged on both sides in the width direction of the second support member 102b. When the hydrogen-containing water producing apparatus 100b is not used, the leg portion 104 is stored in the storage portion 106 provided on the installation target FL side of the second support member 102b. When the hydrogen-containing water producing apparatus 100b is used, the leg portion 104 is drawn out from the storage portion 106 and rotates around the rotational axis Zr. Then, an end portion 104S on the opposite side of the rotation axis Zr comes into contact with the installation target FL.

37, the hydrogen-containing water producing apparatus 100b is installed by the first mounting portion 101C of the first supporting member 101 and the end portion 104S of the leg portion 104 And is installed in the object FL. The second support member 102b is separated from the installation target FL by the leg portion 104 more than the first support member 101. [ Therefore, the hydrogen-containing water generating electrode 10 of the hydrogen-containing water producing apparatus 100b is arranged so as to face the ground surface of the installation target FL from the first support 101 to the second support 102b Is inclined to fall away from the installation target FL. At this time, the angle formed between the center axis Zt of the electrode 10 for generating hydrogen-containing water and the installation target FL (virtual ground plane FLv in this example) is the above-mentioned inclination angle?.

The hydrogen-containing water producing apparatus 100b has a retractable leg portion 104 on the second support member 102. The water- Therefore, the second support member 102b and the first support member 101 can be formed in the same shape, so that it is possible to make the parts common. Since the second support member 102 has to take out the leg portion 104 at the time of use, the second support member 102 can have a dimension equivalent to that of the first support member 101. Therefore, the size of the second support member 102b can be reduced, and consequently, the hydrogen-containing water producing apparatus 100b can be made compact.

Although the present embodiment has been described above, the present embodiment is not limited to the above-described embodiments. It should be noted that the above-mentioned constituent elements include those that can be readily imagined by those skilled in the art, substantially the same, and so-called equivalent ranges. Furthermore, the above-described components can be combined appropriately. In addition, various omissions, substitutions or alterations of the constituent elements can be made without departing from the gist of the present embodiment.

10, 10a, 10b, 10c, 10d: electrode for hydrogen-containing water
10R: curved portion 10T1: first end
10T2: second end portion 10HA, 10HB: end opening portion
11, 11c, 11d: positive electrode 11H: opening
11S: side 11SL: slit
11Si: medial portion 11So:
11T1, 12T1: first end portion 11T2, 12T2: second end portion
12, 12c, 12d: negative electrode 12H: opening
12S: side 12SL: slit
12Si: medial side 12So: lateral side
13, 13c, 13d: insulator 13H: opening
14: power supply member for positive electrode 15: power supply member for negative electrode
20: power supply 21C: control device
22: power switch 23: display device
24: AC adapter 25: Wiring
27: connector 34: terminal
100, 100a, 100b: a hydrogen-containing water producing device
101: first support member 101H: first support member
101C: first mounting portion 102: second supporting portion
102H: second opening portion 102C: second mounting portion
103: protective member 104:
FL: installation target W: enemy

Claims (8)

A hydrogen-containing water producing apparatus for producing hydrogen-containing water,
A positive electrode comprising a positive electrode having a tubular conductor and having a plurality of openings on its side,
An insulator provided on an outer peripheral portion of the positive electrode,
A negative electrode having a tubular conductor provided on an outer peripheral portion of the insulator and having a plurality of openings in a side portion,
A first supporter mounted on the first end side of the positive electrode and the negative electrode and having a first installation section in contact with an installation target of the hydrogen-
And a second mounting portion mounted on the second end side of the positive electrode and the negative electrode and in contact with the object to be mounted, and the distance from the side portion of the positive electrode to the second mounting portion in a direction orthogonal to the side of the positive electrode And a second support member that is larger than a distance from a side portion of the positive electrode in a direction orthogonal to the side portion of the positive electrode to the first installation portion,
Wherein the first support body and the second support body are provided so as to be in contact with a bottom portion of a tank in which raw water to be installed is collected. The method according to claim 1,
Wherein an angle formed between the object to be installed and the positive electrode and the negative electrode when the first support member and the second support member are provided on the object to be installed is not less than 2 degrees and not more than 10 degrees. The method according to claim 1,
Add to,
A positive electrode power supply member protruding from a first end side of the positive electrode,
A positive electrode support member protruding from a second end side of the positive electrode;
A negative electrode power supply member protruding from a first end side of the negative electrode;
And a negative electrode supporting member protruding from a second end side of the negative electrode,
Wherein the first support member supports the positive electrode power supply member and the negative electrode power supply member and the second support member supports the positive electrode support member and the negative electrode support member. The method according to claim 1,
Add to,
A positive electrode power supply member protruding from at least one of a first end side of the positive electrode and a second end side of the positive electrode,
And a negative electrode power supply member protruding from at least one of a first end side of the negative electrode and a second end side of the negative electrode,
Wherein the first support member or the second support member supports the positive electrode power supply member and the negative electrode power supply member. The method according to claim 1,
Wherein at least one of the first support member and the second support member has an opening portion connected to a space surrounded by the side portion of the positive electrode. The method according to claim 1,
And a protective member having a plurality of openings in a side portion thereof on the outside of the negative electrode,
Wherein the first end of the protection member is supported by the first support body and the second end of the protection member is supported by the second support body. The method according to claim 6,
Wherein the plurality of openings of the protective member are larger than the plurality of openings of the negative electrode. 8. The method according to any one of claims 1 to 7,
Wherein the insulator has a plurality of openings.

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