JP2002292370A - Ozone water producer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ozone water producer wherein the surface contact of the electrode plate with the solid electrolyte membrane is achieved by eliminating the unevenness of the contact without processing accuracy. SOLUTION: The ozone water producer is constructed by encasing a solid electrolyte membrane 14 and an anode plate 18 and a cathode plate 20 which are in contact with the respective surfaces of the membrane 14 and are opposite to each other in a cage comprising an anode-side cover 10 and a cathode-side cover 12 and produces ozone water by passing a direct electric current between the plates 18 and 20 and electrolyzing water. The producer is provided with a press means provided with a back pressure plate 34 and a back pressure cushion 32 interposed between the plate 18 or 20 and the plate 34 and constructed so that the plates 18 and 29 may be pressed against membrane 14 by pressing the plate 34.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an ozone water producing apparatus, and more particularly to an ozone water producing apparatus capable of stably producing ozone water having a high ozone concentration.

[0002]

2. Description of the Related Art Ozone water is widely used as washing water and the like because of its strong sterilizing property. Conventionally, as an ozone water production apparatus for producing ozone water, a discharge type in which gas phase ozone is produced by discharging in oxygen gas or air to produce gas phase ozone, and irradiating ultraviolet rays to water. An apparatus for producing ozone water by an ultraviolet irradiation method in which oxygen dissolved in water is ozonized, an electrolysis method in which ozone obtained by electrolyzing water is dissolved in water, and the like.

[0003] Among the electrolysis methods, an electrode which also serves as a catalyst for generating ozone is superposed on both surfaces of a solid electrolyte membrane, and a direct current is supplied between the two electrodes to electrolyze water to generate ozone. Attention has been paid to the high ozone generation efficiency.

Here, the operation of the configuration of the ozone water generating electrode using the solid electrolyte membrane will be described with reference to FIG.
FIG. 7 is a cross-sectional view illustrating the configuration of the ozone water generation electrode body. As shown in FIG. 7, the basic structure of the ozone water generation electrode body 40 includes a solid electrolyte membrane 42, a positive electrode 44 in surface contact with one surface of the solid electrolyte membrane 42, and a solid electrolyte membrane 42. A negative electrode 46 which is in surface contact with the other surface, and a lead wire 48 connected to the edges of the positive electrode 44 and the negative electrode 46 and connected to the anode and cathode of a DC power supply (not shown), respectively.
50. Further, the ozone water generating electrode body 40 has air-permeable supporting plates 52A, B on the outside of the positive electrode 44 and the negative electrode 46, respectively. The solid electrolyte membrane 42, the positive electrode 44 , And the negative electrode 46
And the whole is integrally held.

The solid electrolyte membrane 42 has a thickness of 100 μm or more and 80 μm or more.
It is formed of a fluorine-based cation exchange membrane having a thickness of 0 μm or less. The positive electrode 44 and the negative electrode 46 are each a porous electrode having an aperture ratio of 50% or more, for example, a metal net-like metal electrode. The contact layer of the positive electrode 44 which is in contact with the solid electrolyte membrane 42 is formed of platinum also having a catalytic function, while the contact layer of the negative electrode 46 which is in contact with the solid electrolyte membrane 42 is an electrode made of platinum which also has a catalytic function. It is formed with. 6 V or more and 30 V between the positive electrode 44 and the negative electrode 46
The following DC voltage is applied. The electrode may be a metal plate provided with a number of small holes or a slit-shaped through hole.

The mechanism by which ozone is generated when water is electrolyzed is not necessarily theoretically elucidated. However, on the positive electrode 44 side, cations, ie, hydrogen ions, are separated from water molecules by negative ions. It moves to the electrode 46 side. As a result, oxygen is generated on the positive electrode 44 side, and the negative electrode 4
Hydrogen is generated on the 6 side. When oxygen is generated on the positive electrode 44 side, if the potential difference between the positive electrode 44 and the negative electrode 46 is larger than the potential difference required for oxygen generation, it is said that ozone is generated together with oxygen. Further, the solid electrolyte membrane 42 has a function of promoting the passage of hydrogen ions from the positive electrode 44 to the negative electrode 46. Water obtained by dissolving ozone generated by using the above-described ozone water generating electrode body 40 in water is extremely clean, and has high sterilizing properties and great purifying properties. It is frequently used as raw water, or as disinfecting water or cleaning water at medical sites.

By the way, in the ozone water producing apparatus having the structure as shown in FIG. 7, the performance of the solid electrolyte membrane itself deteriorates with time, and the ozone water to be produced maintains a good ozone concentration. Can not be done. In that case,
In order to maintain the ozone concentration, it is necessary to increase the applied voltage to increase the current density. However, there is a limit to the allowable applied voltage. Therefore, when the performance of the solid electrolyte membrane is deteriorated and the ozone concentration is lowered, a method of recovering the membrane performance by changing the pressure contact state of the electrode with the solid electrolyte membrane is known. By this method, the membrane can be used repeatedly until the end of the membrane life without replacing the membrane immediately, so the number of times of disassembling the ozone water production equipment and replacing the solid electrolyte membrane is greatly reduced, and the operation of the ozone water production equipment is started The rate can be improved.

As an example of the above-mentioned ozone water producing apparatus, there is one described in, for example, JP-A-11-172482.
In this ozone water producing apparatus, as shown in FIG. 8, the inside of a casing 54 is partitioned into an anode chamber 58 and a cathode chamber 60 by a solid electrolyte membrane 56, and a positive electrode 62 having an ozone generating catalytic function is connected to the anode chamber 58 side. The negative electrode 64 is pressed against the surface of the solid electrolyte membrane 56 on the side of the cathode chamber 60, and the inlets 66, 68 and the outlet 70 are respectively connected to the anode chamber 58 and the cathode chamber 60. 72 are formed,
It is configured to apply a DC voltage between the positive electrode 62 and the negative electrode 64. Further, a configuration is provided in which each central portion of the positive electrode 62 and the negative electrode 64 is supported by hydraulic cylinders 78 and 80 that project rod-shaped electrodes 74 and 76 into the casing 54 from the upper and lower sides of the casing 54. I have.

In the above-mentioned ozone water producing apparatus, ozone water is produced by controlling while increasing the current density so as to maintain the ozone concentration at a desired value. Then, when the increase in the current density reaches the upper limit of the current density variable region, which is the limit of the ozone water producing apparatus, the supply of the direct current is stopped,
The pair of opposing hydraulic cylinders 78 and 80 are retracted to separate from the positive electrode 62 and the negative electrode 64, and in this state, the solid electrolyte membrane 56 is stopped for a predetermined time until the solid electrolyte membrane 56 returns to a recovery state that can be used for an electric field. . Then, the hydraulic cylinder 7
8, 80 are again advanced, and the positive electrode 62 and the negative electrode 64 are operated.
After the positive electrode 62 and the negative electrode 64 are pressed against the solid electrolyte membrane 56, the operation is resumed. Therefore, even if the solid electrolyte membrane 56 is deteriorated in performance and the ozone concentration is lowered, the current density is not increased and the electrode 6
The film performance can be restored by pressing or releasing the 2, 64.

[0010] Japanese Patent No. 3040621 discloses a water electrolysis cell structure having another structure for changing the pressure contact state of an electrode with a solid electrolyte membrane. This water electrolysis cell structure is a cell using a solid polymer electrolyte membrane, a separator disposed on both sides of the cell and laminated integrally with the cell, and a pair of front and back sandwiching the laminate of the cell and the separator. End flanges, four fastening bolts arranged near the edges of the front and back end flanges, and four bolts for pressing cells from the front and back sides near the center of the end flanges, for a total of eight bolts And a back pressure adjusting screw. Therefore, the contact state between the cell and the separator can be changed by adjusting the degree of tightening of the eight back pressure adjusting screws.

[0011]

However, the above-described conventional ozone water producing apparatus and water electrolysis cell structure have the following problems. That is, in the ozone water production apparatus described in Japanese Patent Application Laid-Open No. H11-172482, since only the central portion of the solid electrolyte membrane 56 is pressed from above and below, the anode electrode 62 and the cathode electrode 64 are solid electrolyte. It is pressed against the film 56 in an inclined state. In this case, the anode electrode 62 and the cathode electrode 64 cannot make good surface contact with the solid electrolyte membrane 56,
Further, in order to make the current density applied to the cathode electrode 64 uniform, processing with higher precision is required.

In the water electrolysis cell structure described in Japanese Patent No. 3040621, although the contact between the cell and the separator can be improved by appropriately adjusting the eight back pressure adjusting screws on the front and back, Since the number of back pressure adjusting screws is large, it is difficult to uniformly adjust the degree of tightening, and the separator and the cell are pressed against each other in a state of being inclined with respect to each other. In that case, as in the ozone water producing apparatus disclosed in Japanese Patent Application Laid-Open No. H11-172482, more accurate processing is required to make the current density applied between the separators uniform.

Accordingly, an object of the present invention is to eliminate the unevenness in contact between the electrode plate and the solid electrolyte membrane easily and surely while eliminating the need for higher processing accuracy, and to satisfactorily separate the electrode plate and the solid electrolyte membrane. An object of the present invention is to provide an ozone water producing apparatus capable of making surface contact.

[0014]

In order to achieve the above object, an ozone water producing apparatus according to the present invention comprises a solid electrolyte membrane, a solid electrolyte membrane and a solid electrolyte membrane in a housing comprising an anode side cover and a cathode side cover. Ozone production in which a positive electrode plate and a negative electrode plate provided in contact with and opposed to both surfaces are housed, and a direct current is supplied between the positive electrode plate and the negative electrode plate to electrolyze water to produce ozone water. The device includes a pressing plate, and a pressing cushion member interposed between the positive electrode plate or the negative electrode plate and the pressing plate. By pressing the pressing plate, the positive electrode plate and the negative electrode are interposed via the pressing cushion member. It is characterized by comprising a pressing means configured to press the electrode plate against the solid electrolyte membrane.

In the ozone water producing apparatus according to the present invention, the pressing cushion member absorbs the slight inclination of the positive electrode plate and the negative electrode plate with respect to the solid electrolyte membrane, and converts the positive electrode plate and the negative electrode plate into the solid electrolyte membrane. Pressing makes it possible to eliminate unevenness in contact between the positive and negative electrode plates and the solid electrolyte membrane, while maintaining high processing accuracy. Can be contacted. This makes it possible to make the density of current flowing between the positive electrode plate and the negative electrode plate uniform.

In a preferred embodiment of the present invention, an anode-side flow path forming member for forming a flow path of raw water is provided on a side of the positive electrode plate opposite to the solid electrolyte membrane, on a side opposite to the solid electrolyte membrane of the negative electrode plate. The cathode side flow path forming member forming the flow path of the electrolyte is disposed so as to freely move with respect to the solid electrolyte membrane, and the pressing plate is provided between the positive electrode plate and the anode side cover. Or, between the negative electrode plate and the cathode side cover, disposed so as to freely move with respect to the anode side cover or the cathode side cover, and the pressing cushion member is formed of an elastic body having substantially the same shape as the pressing plate. The pressing means is configured to press one of the anode side channel forming member and the cathode side channel forming member and the pressing cushion member by pressing a pressing plate by screwing a pressing screw into the housing from the anode side cover or the cathode side cover. Through the anode and cathode plates And it is configured to press the solution membrane. In this case, since the pressing plate, the anode-side channel forming member, and the cathode-side channel forming member can take a free posture with respect to the solid electrolyte membrane, when the pressing screw is screwed to press the pressing plate, the pressing is performed. The cushion member can make good surface contact between the positive electrode plate and the negative electrode plate and the solid electrolyte membrane while absorbing the inclination of the positive electrode plate and the negative electrode plate.

As the pressing cushion member, any material having elasticity, that is, any elastic material can be used. As this elastic body, for example, silicone rubber (silicic)
onerubber), natural rubber, natural rubber,
Propylene rubber, chloroprene rubber, butadiene rubber,
Examples include various rubbers such as styrene rubber, ethylene rubber, ethylene propylene rubber, butyl rubber, nitrile rubber, and urethane rubber. Further, as the elastic body, a vinyl chloride elastomer and a thermoplastic polyurethane elastomer, or an olefin-based, a styrene-based,
Examples include various thermoplastic elastomers of polyamide type, polyester type and nitrile type. Further, as the elastic body, a leaf spring, a compression spring, an air cushion in which a gas such as air is sealed in a balloon shape of a flexible material, or an oil cushion in which oil is sealed can be used. When a leaf spring or a compression spring is used for the pressing cushion member, for example, a plurality of leaf springs and / or compression springs are evenly distributed between a pair of opposed plates and received from the pressing means. The pressing force is configured to be uniformly distributed over the entire surface of the plate. When the above various rubbers and various thermoplastic elastomers are used, for example, metals such as titanium, or polytetrafluoroethylene (Teflon: trademark) or vinyl chloride resin, etc.
The surface is coated with a material having resistance to electrolyte and resistance to ozone. As a result, it is possible to obtain a pressing cushion member that can be disposed in both the anode-side cover and the cathode-side cover. When a leaf spring or a compression spring is used, the plate together with the leaf spring and the compression spring is made of a metal having ozone resistance and electrolytic solution resistance, such as titanium, so that the inside of the anode-side cover can be formed. And a pressure cushion member that can be disposed both inside the cathode side cover.

In a further preferred embodiment of the present invention, the pressing screw is screwed to the anode-side cover or the cathode-side cover at a position symmetrical by the same number with respect to the center of symmetry along the longitudinal direction of the positive electrode plate and the negative electrode plate. Have been. This allows the solid electrolyte membrane to be pressed while allowing the pressing plate and the anode-side flow path forming member or the pressing plate and the cathode-side flow path forming member to move with respect to the positive electrode plate or the negative electrode plate. In addition, variations in the height of each pressing screw can be absorbed by the pressing cushion member, and good surface contact between the positive electrode plate and the negative electrode plate and the solid electrolyte membrane can be ensured.

In a preferred embodiment of the present invention, the anode-side flow path forming member forms a flow path having a plurality of protrusions arranged so as to be alternately arranged in the water flow direction, and comprises a cathode-side flow path. The forming member forms a plurality of linear flow paths along the flow of the electrolytic solution. In this case, on the anode side, ozone gas generated by electrolysis can be quickly mixed into raw water by a flow path having a plurality of protrusions, and on the cathode side, the electrolyte solution is formed by a linear flow path. It can drain while quickly flushing out the hydrogen generated in it.

[0020]

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings. Embodiment 1 This embodiment is an example of an embodiment of a water electrolysis type ozone water producing apparatus according to the present invention, and FIG. 1 shows the configuration of the ozone water producing apparatus of this embodiment in an exploded state. Perspective view, FIG. 2
Is a plan view showing the anode (anode) side cover of FIG. 1 as viewed from above, FIG. 3 is a bottom view of the cathode (cathode) side cover of FIG. 1 as viewed from below, and FIG. FIG. 5 is a longitudinal sectional view showing an assembled state of the ozone water producing apparatus of FIG. 1 (or a cathode side electrode pin).

The ozone water producing apparatus according to this embodiment is
As shown in FIG. 1, the anode side cover 10 and the cathode side cover 1
2 is provided. In the housing, the solid electrolyte membrane 14 and the positive electrode plate 18 and the negative electrode plate 2 provided in contact with and opposed to both surfaces of the solid electrolyte membrane 14 are provided.
0 is stored. The solid electrolyte membrane 14 has flexibility, and transmits the movement of the negative electrode plate 20 pressed as described later to the mesh member 22 and the positive electrode plate 18 while bending. The anode-side cover 10 is made of polytetrafluoroethylene, vinyl chloride resin, or the like so that the anode-side cover 10 has insulation and ozone resistance, and the cathode-side cover 12 has insulation and electrolyte resistance. Have been.

Also, facing the one surface (the surface facing downward in FIG. 1) of the solid electrolyte membrane 14, the turbulent flow forming the mesh member 22, the positive electrode plate 18, and the water channel is formed in the anode-side cover 10. The plate (anode-side channel forming member) 24 is accommodated. Each of the mesh member 22, the positive electrode plate 18, and the turbulent flow plate 24 is formed in a rectangular shape having substantially the same size in plan view, and has a rectangular parallelepiped shape formed on the anode-side cover 10 shown in FIG. The solid electrolyte membrane 14 is stacked in the concave portion 28 and accommodated freely with respect to the solid electrolyte membrane 14 without being fixed by screws or the like.

The reticulated member 22 is in contact with the solid electrolyte membrane 14, and is formed thinly and with good flatness using a metal material such as platinum (Pt) having an ozone generating catalytic function. The positive electrode plate 18 is formed as a square plate material obtained by crushing a lath net formed of a titanium (Ti) material from above and below, and a central portion thereof has a base end of a conductive shaft 18a projecting downward. Welded.

The turbulence plate 24 is provided at the center with the positive electrode plate 18.
Has a through hole 24a through which the conductive shaft 18a is inserted. The inner diameter of the through-hole 24a is formed slightly larger than the outer diameter of the conductive shaft 18a, so that the turbulent flow plate 24 through which the conductive shaft 18a is
8 can be freely moved.

In the anode side cover 10, when raw water flows in from an inlet 40 described later and ozone water is drained from an outlet 42, oxygen gas (O ₂ ) is generated, and the current exceeds a certain value. Ozone (O ₃ ) gas is sometimes obtained from O ₂ . Therefore, in order to quickly mix the generated ozone gas into the raw water, the water flow direction is formed on the surface of the turbulent flow plate 24 such that the flow path of the raw water from the inlet 40 to the outlet 42 is zigzag to generate a vortex. Are formed with a plurality of protrusions 24b which are alternately arranged.

On the other hand, opposite to the other surface of the solid electrolyte membrane 14 (the surface facing upward in FIG. 1), on the cathode cover member 12 side, a negative electrode plate 20 and a rectifying plate for forming a flow path for the electrolyte. A (cathode-side channel forming member) 30, a back pressure cushion (pressing cushion) 32, and a back pressure plate (pressing plate) 34 are accommodated.
The current plate 30 is made of polytetrafluoroethylene, vinyl chloride, or the like so as to have electrolytic solution resistance. The back pressure plate 34 is formed of a metal material such as titanium having an electrolytic solution resistance.

The back pressure cushion 32 is made of an elastic body having an elastic force necessary for adjusting the back pressure. Examples of the elastic body include various rubbers such as silicone rubber, natural rubber, fluorine rubber, propylene rubber, chloroprene rubber, butadiene rubber, styrene rubber, ethylene rubber, ethylene propylene rubber, butyl rubber, nitrile rubber, and urethane rubber. Can be mentioned. Examples of the elastic body include a vinyl chloride elastomer and a thermoplastic polyurethane elastomer, or various thermoplastic elastomers of olefin, styrene, polyamide, polyester, and nitrile types.

Further, as the above-mentioned elastic body, a leaf spring, a compression spring, an air cushion in which a gas such as air is sealed in a balloon shape of a flexible material, or an oil cushion in which oil is sealed can be used. Here, an example in which a compression spring is used for the back pressure cushion 32 will be described with reference to FIG. As shown in FIG. 6, two plates 31a and 31b formed in substantially the same shape as the back pressure plate 34 (see FIG. 1) are opposed to each other, and a plurality of compression springs (compression springs) are provided between the two plates 31a and 31b. (Coil springs) 33 are evenly distributed. Thus, the pressing force received via the back pressure plate 34 can be configured to be uniformly distributed over the entire surfaces of the plates 31a and 31b. A through hole 35 for inserting the conductive shaft 20a is formed in each central portion of the plates 31a and 31b. The through-hole on the plate 31b side is not shown. When the above-mentioned various elastic bodies are disposed in the anode-side cover 10, they are configured to have ozone resistance, and when they are disposed in the cathode-side cover 12, they have electrolytic solution resistance. The configuration is as follows.

The negative electrode plate 20, the rectifying plate 30, the back pressure cushion 32, and the back pressure plate 34 are all formed in a rectangular shape having substantially the same size in plan view, and are formed on the back surface of the cathode side cover 12 shown in FIG. The solid electrolyte membrane 14 is stacked in the rectangular parallelepiped housing recess 36 and is freely movable with respect to the solid electrolyte membrane 14 without being fixed with screws or the like.

The anode-side cover 10 is formed in a long box shape having a housing recess 28 facing the cathode-side cover 12, and has a through hole 38 at the center in plan view. The anode side cover 10 has an inlet 40 and an outlet 42 at positions symmetrical about the center of symmetry along the longitudinal direction. On the inner surface of the through hole 38, a female screw is formed for screwing the anode electrode pin 44 having a male screw formed on the outer periphery of the tip. In the anode-side cover 10, a plurality of fixing through holes 46 are formed along the long side and the short side.

As shown in FIG. 2, a packing 48 is attached to the contact surface of the anode cover 10 with the cathode cover 12 so as to surround the entire housing recess 28. Further, the packing 4 on the contact surface of the anode side cover 10
8 are engraved so as to be slightly receded from the contact surface to form a concave portion 50 for accommodating the outer peripheral edge of the solid electrolyte membrane 14 protruding from the accommodating concave portion 36. Have been. As shown in FIG. 3, a packing groove 52 that is symmetrical to the shape of the packing 48 of the anode-side cover 10 is formed on the contact surface of the cathode-side cover 12 with the anode-side cover 10. Packing 48, recess 50
The packing groove 52 is not shown in FIG.
The anode side cover 10 and the cathode side cover 12 are tightened with fixing bolts passing through the fixing through holes 46 and 56 in a state where the packing 48 is engaged with the packing groove 52 and the contact surfaces are aligned. A case is formed in which the inside is kept liquid-tight. At this time, since the solid electrolyte membrane 14 has an area slightly larger than the opening area of the housing recess 28 and the housing recess 36, the solid electrolyte membrane 14 is supported in a state where the outer peripheral edge is sandwiched between the packing 48 and the packing groove 52 in the recess 50. Will be done. FIG. 3 shows only a through hole into which one back pressure adjusting screw is screwed.

On the other hand, as shown in FIG. 1, the cathode side cover 12 has a housing recess 36 on the side facing the anode side cover 10.
It is formed in a long box shape having (FIG. 3). The cathode side cover 12 has a through hole 58 at the center of the square. The cathode side cover 12 has through holes 64, 66 for screwing back pressure adjusting screws (pressing screws) 60, 62 having external threads on the outer peripheral surface at positions symmetrical about the center of symmetry along the longitudinal direction. Have. Further, the through holes 64, 66
On each outside, an inlet 68 and an outlet 70 are formed.

A pair of back pressure adjusting screws 60 and 62 penetrate the cathode side cover 12, and are connected to the back pressure plate 34 and the back pressure cushion 3.
A pressing force is applied to the negative electrode plate 20 through the rectifying plate 2 and the rectifying plate 30. A back pressure adjusting screw 6 is provided on each inner surface of the through holes 64 and 66.
Female threads corresponding to the male threads 0 and 62 are formed. On the inner surface of the through hole 58, a female screw is formed for screwing the cathode electrode pin 72 having a male screw formed on the outer periphery of the distal end. Further, a plurality of fixing through holes 56 are formed in the cathode side cover 12 along the long side and the short side. Further, the inflow port 68 and the outflow port 70 face the inflow port 40 and the outflow port 42 of the anode-side cover 10, respectively. Is formed so as to face the fixing through hole 46.

The negative electrode plate 20 adjacent to the solid electrolyte membrane 14 on the side of the cathode side cover 12 is formed of a rectangular plate made of titanium, similarly to the positive electrode plate 18, and has a The base end of the conductive shaft 20a protruding from is welded. At the center of each of the current plate 30, the back pressure cushion 32, and the back pressure plate 34, a conductive shaft 20 is provided.
a are formed through holes 30a, 32a, and 34a. The inner diameter of each of the through holes 30a, 32a, 34a is formed slightly larger than the outer diameter of the conductive shaft 20a. Thus, the rectifying plate 30, the back pressure cushion 32, and the back pressure plate 34 through which the conductive shaft 20a passes.
Are freely movable with respect to the negative electrode plate 20, respectively.

On the cathode side, the electrolytic solution flows in from the inlet 68 and is discharged from the outlet 70. The discharged electrolytic solution is once collected in a liquid tank (not shown), and then is again pumped into the inlet 68. Circulate by feeding. Therefore, in order to quickly flush generated hydrogen, the current plate 30 extends in the long side direction and has a plurality of linear flow paths along the flow of the electrolyte between the inlet 68 and the outlet 70. Have a plurality of linear grooves 30b parallel to each other.

As shown in FIG. 4, the anode-side electrode pin 44 and the cathode-side electrode pin 72 are formed in the same shape, respectively. A large-diameter portion 44a (72a) having an oval cross section and a male screw are formed on the outer periphery. And a small diameter portion 44c (72c) at the tip. In addition, the anode electrode pin 44 and the cathode electrode pin 72 are formed with a large diameter portion 44a.
A small diameter portion 44c (72c) from the upper central portion of (72a).
And a through hole 44e (72e) through which the conductive shaft 18a (20a) is inserted, and an oval flat surface formed with a fixing screw 78.
A screw hole 44f (72f) for screwing with a screw and a fixing screw 80 are passed through and screwed into the through hole 44e (72e), and the conductive shaft 18a (20a) is connected to the electrode pin 44 (7).
It has a female screw hole 44g (72g) for fixing to 2).

In the ozone water producing apparatus having the above-described structure, raw water flows through the inlet 40 and an electrolytic solution flows through the inlet 68 while a direct current is supplied between the positive electrode plate 18 and the negative electrode plate 20. Thus, raw water is electrolyzed to produce ozone water.

The ozone water producing apparatus according to this embodiment is
When the product is shipped, it is assembled as shown in FIG. That is, the conductive shaft 18a is inserted into the through-hole 24a of the turbulent plate 24 and the through-hole 38 of the anode-side cover 10, and the turbulent plate 24 is accommodated in the accommodating recess 28 of the anode-side cover 10. The positive electrode plate 1 is provided on the plurality of protrusions 24b.
8, the mesh member 22 is further placed on the positive electrode plate 18, and the solid electrolyte membrane 14 is placed on the mesh member 22.

Next, the current plate 30 and the back pressure cushion 32
When the conductive shaft 20a is inserted through the through holes 30a, 32a, and 34a of the back pressure plate 34, and the conductive shaft 20a is further inserted through the through hole 58 of the cathode-side cover 12, the rectifying plate 30, the back pressure cushion 32 and the back The pressure plate 34 is housed in the housing recess 36 of the cathode side cover 12. Then, while the cathode plate 20 is stacked on the solid electrolyte membrane 14, the packing 48,
The anode-side cover 10 and the cathode-side cover 12 are brought into contact with each other while aligning the outer peripheral edge of the solid electrolyte membrane 14 with the packing grooves 52, 54 and 50.

Next, with the anode side cover 10 and the cathode side cover 12 in contact with each other,
A fixing bolt (not shown) is penetrated between 6 and 56, and a nut (not shown) is screwed together to fix the nut. Thereby, the contact surface is assembled as a housing in which the contact surface is kept liquid-tight.

Thereafter, the through hole 44e of the cathode electrode pin 44 is inserted into the tip of the conductive shaft 18a projecting into the through hole 38 of the anode cover 10, and the conductive shaft 20a and the cathode electrode pin 72 are fixed with the fixing screw 80. And are mechanically and electrically coupled. Further, the fixing screw 78 is used to fix the cathode side electrode pin 4
4 is fixed to the lead wire 76. On the other hand, the cathode side cover 12
The through hole 72e of the cathode electrode pin 72 is inserted into the tip of the conductive shaft 20a protruding into the through hole 58, and the conductive shaft 20a and the cathode electrode pin 72 are mechanically and electrically coupled with the fixing screw 80. . Further, the lead wire 76 is fixed to the cathode electrode pin 72 with a fixing screw 78. Note that the anode electrode pin 44 and the cathode electrode pin 72 are
c (72c), and the O-ring inserted into the through holes 38 and 58 together with the small diameter portion 44c (72c) keeps the housing liquid-tight.

In this state, the through holes 6 of the cathode side cover 12
The back pressure adjusting screws 60 and 62 are screwed into the back pressure plate 34 and the back pressure plate 34, respectively. The back pressure adjusting screws 60 and 62 are
O-rings are fitted to the respective end portions 60a, 62a.
The O-ring is inserted into the through holes 64 and 66 together with a to maintain the liquid tightness of the housing. Further, the back pressure adjusting screw 6
By engaging a flathead screwdriver with a notch formed in the head exposed from the through holes 64 and 66 of the reference numerals 0 and 62 and turning the screw in one direction, the back pressure adjusting screws 60 and 62 have their tips 60a and 62a. Screw it in until it comes into contact with the back pressure plate 34. Further, while measuring the voltage applied between the electrode pins 44 and 72 using a voltmeter, the back pressure adjusting screws 60 and 62 are measured.
Continue to screw in when the voltage reaches the optimal value. It will be shipped in this state. In fact, by adjusting the back pressure adjusting screws 60 and 62, it was confirmed that the voltage under a constant current condition changed by 1 to 3 V or more.
This confirms that the ozone concentration also changes.

In operation, the ozone water producing apparatus in a product state shown in FIG.
And a DC power supply 82 is connected. That is, on the anode side, raw water flows in from the inflow port 40 and passes through the flow path formed by the plurality of projections 24b of the turbulent flow plate 24. On the cathode side, the electrolytic solution is supplied from the inflow port 68, The electrolyte flows through a straight flow path formed by the plurality of straight grooves 30b. In this state, when a current is supplied between the electrode pins 44 and 72 from the DC power supply 82, the raw water is electrolyzed between the positive electrode plate 18 and the solid electrolyte membrane 14 with the solid electrolyte membrane 14 interposed therebetween, and oxygen gas is generated. And ozone gas, and hydrogen gas is generated between the negative electrode plate 20 and the solid electrolyte membrane 14.

During operation, on the positive electrode plate 18 side, the turbulent flow plate 24 agitates the raw water by a number of protrusions 24b to form a vortex, so that the ozone gas is quickly and effectively dissolved in the raw water, and Water can be continuously and stably discharged from the outlet 42. On the other hand, the electrolyte containing hydrogen drained from the outlet 70 is once collected in a collection tank,
After hydrogen is separated by a gas-liquid separation mechanism (not shown), it is fed into an inlet 68 while being mixed with another electrolyte by a pump (not shown) for recirculation.

In the ozone water producing apparatus according to this embodiment, the back pressure adjusting screws 60, 6
2 and presses the back pressure plate 34, through the rectifying plate 30 and the back pressure cushion 32, the negative electrode plate 2
The positive and negative electrode plates 18 can be pressed against the solid electrolyte membrane 14. At this time, the back pressure cushion 32 presses the negative electrode plate 20 against the solid electrolyte membrane 14 while absorbing a slight inclination of the negative electrode plate 20 with respect to the solid electrolyte membrane 14. Further, the pressing force of the negative electrode plate 20 is transmitted to the mesh member 22 and the positive electrode plate 18 via the solid electrolyte membrane 14 having flexibility.

At this time, the turbulent flow plate 24 is formed of a machined part, the thickness processing accuracy is increased, and a large number of protrusions 24b are formed.
The flatness of the surface formed by the front end of each of the first and second portions and the inclination accuracy of the housing recess 28 with respect to the bottom surface are increased. Therefore, the solid electrolyte membrane 14 pressed through the back pressure cushion 32
Together with the mesh member 22 and the positive electrode plate 18 are pressed against a high-precision flat surface composed of a large number of protrusions 24b. As a result, the surface contact accuracy of the solid electrolyte membrane 14 via the back pressure cushion 32 is further enhanced. Can be

As described above, the ozone water producing apparatus according to the present embodiment has a relatively simple structure and does not require higher processing accuracy, but also has a negative electrode plate 20 and a positive electrode plate 1.
The contact unevenness between the solid electrolyte membrane 14 and the solid electrolyte membrane 14 can be reliably eliminated, and the solid electrolyte membrane 14 can be brought into good surface contact with the negative electrode plate 20 and the positive electrode plate 18. Thereby, the current density applied between the positive electrode plate 18 and the negative electrode plate 20 can be made uniform. When the performance of the solid electrolyte membrane 14 is deteriorated due to the continuous use of the ozone water producing apparatus and the ozone concentration is lowered, maintenance for re-adjusting the tightening state of the back pressure adjusting screws 60 and 62 is performed. In addition, membrane performance can be restored.

Further, the back pressure adjusting screws 60 and 62 are screwed to the anode side cover 12 at positions symmetrical one by one with respect to the center of symmetry along the longitudinal direction of the negative electrode plate 20 and the positive electrode plate 18. Therefore, it is possible to press against the solid electrolyte membrane 14 while allowing the back pressure plate 34 and the rectifying plate 30 to move with respect to the negative electrode plate 20. Further, the back pressure adjusting screw 6
Absorption of heights 0 and 62 is absorbed by the back pressure cushion 32 so that the solid electrolyte membrane 14 and the electrode plates 18 and 20 are absorbed.
Good surface contact with the surface can be guaranteed. Here, the back pressure adjusting screw is not limited to one at a time with respect to the center of symmetry, but can be arranged at least two at a time with respect to the center of symmetry. In this case, the same effect as described above can be obtained. Can be.

In this embodiment, the back pressure cushion 3
2. Although the back pressure plate 34 and the back pressure adjusting screws 60 and 62 are disposed on the cathode side cover 12 side, the present invention is not limited to this configuration, and the back pressure cushion 32 for back pressure adjustment, the back pressure plate 34 and the back pressure adjustment. The screws 60 and 62 can be provided on the anode cover 10 side. In this case, the same effect as described above can be obtained. Specifically, the turbulence plate 24 and the anode-side cover 10
And a back pressure plate 34 is interposed between the back pressure cushion 32 and the anode side cover member 10. The back pressure adjusting screws 60 and 62 are provided in the anode-side cover 10 with through holes 64 and 6 similar to the cathode-side cover 12.
After forming 6, the screws 6 are screwed into the through holes 64 and 66, respectively. At this time, the current plate 30 is formed of a machined component, the thickness processing accuracy is increased, the flatness of the surface formed by the tips of the plurality of linear grooves 30b, and the accommodation concave portion 36 are formed.
The inclination accuracy with respect to the bottom surface is high. For this reason,
Solid electrolyte membrane 1 pressed through back pressure cushion 32
4 is pressed together with the negative electrode plate 20 onto a high-precision flat surface composed of a plurality of straight grooves 30b, and as a result,
The surface contact accuracy of the solid electrolyte membrane 14 via the back pressure cushion 32 is further enhanced.

[0050]

As described above, according to the present invention,
An ozone water production apparatus that can easily and surely eliminate contact unevenness between the electrode plate and the solid electrolyte membrane and make good surface contact between the electrode plate and the solid electrolyte membrane while eliminating the need for higher processing accuracy. Obtainable.

[Brief description of the drawings]

FIG. 1 is a perspective view showing a configuration of an ozone water producing apparatus according to an embodiment in an exploded state.

FIG. 2 is a plan view showing the anode-side cover of FIG. 1 viewed from above.

FIG. 3 is a bottom view of the cathode side cover of FIG. 1 as viewed from below.

FIG. 4 is an enlarged perspective view showing an anode electrode pin (cathode electrode pin).

FIG. 5 is a longitudinal sectional view showing the ozone water producing apparatus of FIG. 1 in an assembled state.

FIG. 6 is a perspective view showing an example in which a compression spring is used for a back pressure cushion.

FIG. 7 is a longitudinal sectional view showing a configuration of a conventional ozone water generating electrode body.

FIG. 8 is a longitudinal sectional view showing a conventional ozone water producing apparatus.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Anode side cover 12 Cathode side cover 14 Solid electrolyte membrane 18 Positive electrode plate 20 Negative electrode plate 22 Net-like member 24 Turbulence plate (Anode side flow path forming member) 24b Projection 28 Housing recess 30 Rectification plate (Cathode side flow path formation) Members) 30b Linear grooves 31a, 31b Plate 32 Back pressure cushion (press cushion member) 33 Compression spring 34 Back pressure plate (press plate) 36 Housing recess 40, 68 Inflow 42, 70 Outflow 44 Anode electrode pin 60, 62 Back Pressure adjusting screw (pressing screw) 72 Cathode side electrode pin

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 4D050 AA04 AB06 BB02 BC10 BD04 4D061 DA03 DB09 EA02 EB01 EB04 EB12 EB16 EB19 EB33 4G035 AA01 AE13 AE17 4K021 AA01 AA09 BA02 DB31 DC15

Claims (4)

[Claims] 1. A housing comprising an anode side cover and a cathode side cover, a solid electrolyte membrane, and a positive electrode plate and a negative electrode plate which are provided in contact with and opposed to both surfaces of the solid electrolyte membrane, are housed therein. In an ozone production apparatus for producing ozone water by supplying a direct current between a positive electrode plate and a negative electrode plate to electrolyze water, an ozone producing device is provided between the pressing plate and the positive or negative electrode plate and the pressing plate. And a pressing means configured to press the pressing plate to press the positive electrode plate and the negative electrode plate against the solid electrolyte membrane via the pressing cushion member. Ozone water production equipment. 2. On the opposite side of the positive electrode plate from the solid electrolyte membrane,
The anode-side flow path forming member that forms the flow path of the raw water has a cathode-side flow path forming member that forms the flow path of the electrolytic solution on the opposite side of the solid electrolyte membrane of the negative electrode plate, respectively. The pressing plate is freely movable with respect to the anode cover or the cathode cover between the positive electrode plate and the anode cover, or between the negative electrode plate and the cathode cover. The pressing cushion member is made of an elastic body formed in substantially the same shape as the pressing plate, and the pressing means is configured to screw a pressing screw into the housing from the anode side cover or the cathode side cover to press the pressing plate. By pressing the positive electrode plate and the negative electrode plate against the solid electrolyte membrane via one of the anode-side channel forming member and the cathode-side channel forming member and the pressing cushion member. The Ozo according to claim 1, characterized in that: Water production system. 3. The pressing screw is screwed to the anode-side cover or the cathode-side cover at a position symmetrical by the same number with respect to the center of symmetry along the longitudinal direction of the positive electrode plate and the negative electrode plate. The ozone water production device according to claim 2. 4. The anode-side flow path forming member forms a flow path having a plurality of protrusions arranged alternately in the direction of water flow, and the cathode-side flow path forming member forms a flow path for the electrolyte. The ozone water production apparatus according to claim 2 or 3, wherein a plurality of linear flow paths are formed along the flow path.