JP6628160B2 - Electrolyzed water generation system - Google Patents

Description

  The present disclosure relates to an electrolyzed water generation system that generates electrolyzed water by electrolysis of water.

  Conventionally, an electrolyzed water generation system has been developed. A conventional electrolyzed water generation system includes a flow path for receiving raw water, and an electrolyzed water generation device connected in the flow path. The electrolyzed water generation device is switched to one of a generation state in which electrolyzed water is generated from raw water flowing through the flow path and a non-generation state in which electrolyzed water is not generated. A conventional electrolyzed water generating apparatus includes an anode, a cathode, and a cation exchange membrane provided between the anode and the cathode.

JP 2011-136333 A

When raw water is supplied to the cation exchange membrane when the electrolyzed water generator does not generate electrolyzed water, that is, when no voltage is applied between the anode and the cathode, the cation exchange membrane is Cations contained in the supplied raw water are taken up. In this state, when a voltage is applied between the anode and the cathode, the cations taken into the cation exchange membrane are released into the electrolyzed water. As a result, poorly soluble metal salts, for example, CaCO ₃ (hereinafter, referred to as “scale”) are generated in the electrolyzed water. In this case, the performance of the electrolyzed water generation device is reduced due to the reduced area of the portion of the cathode contributing to electrolyzed water generation. Therefore, when the electrolyzed water generator does not generate electrolyzed water, it is not possible to use raw water while suppressing generation of scale.

  The present disclosure has been made in view of such problems of the related art. An object of the present disclosure is to provide an electrolyzed water generation system that can use raw water while suppressing generation of scale when the electrolyzed water generation device does not generate electrolyzed water.

  In order to solve the above problems, an electrolyzed water generation system according to an aspect of the present disclosure includes a main flow path that receives raw water, a first branch flow path branched from the main flow path, an anode, a cathode, and the anode. A generating state for generating electrolyzed water from the raw water flowing from the raw water flowing through the first branch flow path, including a cation exchange membrane provided between the cathode and the electrolytic water; An electrolyzed water generation device that is switched to one of a non-generation state and a second branch flow path that branches from the main flow path and guides the raw water flowing through the main flow path to the downstream, and the raw water flows in the main flow path. Which can selectively form one of a first state where the raw water is guided from the main flow path to the first branch flow path and a second state where the raw water is guided from the main flow path to the second branch flow path. A change mechanism.

  According to the present disclosure, when the electrolyzed water generator does not generate electrolyzed water, raw water can be used while suppressing generation of scale.

1 is an external perspective view of an electrolyzed water generation system according to a first embodiment. FIG. 2 is a longitudinal sectional view of the electrolyzed water generation device according to the first embodiment. FIG. 2 is an exploded perspective view of a laminated structure of the electrolyzed water generation device according to the first embodiment. FIG. 2 is an enlarged vertical sectional view of a laminated structure of the electrolyzed water generation device according to the first embodiment. FIG. 2 is a first diagram for explaining a chemical action of the electrolyzed water generation device of the first embodiment. FIG. 2 is a second diagram for describing a chemical action of the electrolyzed water generation device of the first embodiment. FIG. 3 is a third diagram for explaining a chemical action of the electrolyzed water generation device of the first embodiment. FIG. 3 is a perspective view of a cathode of another example of the electrolyzed water generation device of the first embodiment. 4 is a timing chart for explaining a control mode of the electrolyzed water generation system according to the first embodiment. It is a schematic diagram of the electrolyzed water generation system of the second embodiment. FIG. 9 is a schematic diagram of another example of an electrolyzed water generation system according to the second embodiment. 9 is a graph showing the relationship between the voltage applied between the anode and the cathode and the time during which the voltage is applied in each of the intermittent operation operation and the continuous operation operation of the electrolytic water generation system according to the second embodiment. It is a graph which shows the relationship between the density | concentration of the produced | generated ozone, and the time when a voltage is applied between an anode and a cathode in each of the intermittent operation operation and the continuous operation operation of the electrolytic water generation system of the second embodiment. . It is a chemical formula of the cation exchange membrane of the electrolyzed water generation apparatus of the electrolyzed water generation system of the second embodiment. FIG. 9 is a first diagram for explaining a chemical action generated inside the electrolyzed water generation device of the second embodiment. FIG. 10 is a second diagram for describing a chemical action generated inside the electrolyzed water generation device of the second embodiment. FIG. 13 is a third diagram for describing a chemical action generated inside the electrolyzed water generation device of the second embodiment.

  Hereinafter, an electrolyzed water generation system of each embodiment and an electrolyzed water generation device used therein will be described with reference to the drawings. In the following embodiments, portions denoted by the same reference numerals have the same function as each other unless otherwise specified, even if there is a slight difference in shape in the drawings. I do.

(Embodiment 1)
The electrolytic water generation system 1000 according to the first embodiment will be described with reference to FIGS.

(System structure)
As shown in FIG. 1, the electrolyzed water generation system 1000 includes a flow path through which water flows. The channels provided in the electrolyzed water generation system 1000 include a main channel 15, an upstream first branch channel 10A, a downstream first branch channel 20A, and an upstream second branch channel 10B. , And the second branch flow path 20B on the downstream side. The main channel 15 receives the raw water sent out by the pump P. The first branch flow path 10A and the second branch flow path 10B are each branched from the main flow path 15.

  The first branch passages 10A and 20A include an upstream first branch passage 10A and a downstream first branch passage 20A. A first electrolyzed water generator 100A is connected between the upstream first branch flow path 10A and the downstream first branch flow path 20A. The second branch passages 10B and 20B include an upstream second branch passage 10B and a downstream second branch passage 20B. The second electrolyzed water generator 100B is connected between the upstream second branch flow path 10B and the downstream second branch flow path 20B. The main channel 15, the upstream first branch channel 10A, the downstream first branch channel 20A, the upstream second branch channel 10B, and the downstream second branch channel 20B are: Each is a hollow rectangular cylinder made of acrylic resin.

  The electrolyzed water generation system 1000 includes a branch portion between the main flow channel 15 and the first branch flow channel 10A on the upstream side, and a branch portion between the main flow channel 15 and the second branch flow channel 10B on the upstream side. A channel changing mechanism V is provided. In the present embodiment, the flow path changing mechanism V is a three-way valve that functions as a flow path switching valve. In the electrolyzed water generation system 1000 according to the present embodiment, the raw water flowing through the main flow path 15 passes through the flow path changing mechanism V, and the first branch flow path 10A on the upstream side and the second branch flow on the upstream side. It flows into one of the roads 10B.

  The raw water flowing into the upstream first branch flow path 10A flows into the first electrolyzed water generator 100A. When the raw water flowing into the first electrolyzed water generator 100A passes through the first electrolyzed water generator 100A, the raw water changes into electrolyzed water and flows into the downstream first branch flow path 20A.

  The raw water flowing into the upstream second branch flow path 10B flows into the second electrolyzed water generator 100B. When the raw water flowing into the second electrolyzed water generator 100B passes through the second electrolyzed water generator 100B, the raw water is changed to electrolyzed water and flows into the second branch flow path 20B on the downstream side.

(Control unit)
As shown in FIG. 1, the electrolyzed water generation system 1000 includes control units CA, CB, CC, and CD. The control unit CA controls the first electrolyzed water generator 100A. The control unit CB controls the second electrolyzed water generator 100B. The control unit CC controls the flow path changing mechanism V. The control unit CD controls the pump P. In the present embodiment, the control units CA, CB, CC, and CD are depicted as separate components, but may be a single control unit including one component that is integrally formed.

  The electrolyzed water generation system 1000 includes an input unit I operated by an operator. The input unit I transmits a command signal to each of the control units CA, CB, CC, and CD based on the operation of the operator. Each of the control unit CA and the control unit CB includes a sensor S, a memory M, a processor PR, and the like. In the control units CA and CB, the processor PR uses the program stored in the memory M to generate the DC power DC from the AC power AC. Thereby, the control units CA and CB apply a DC voltage to the anode 1A (see FIG. 2) and the cathode 1C (see FIG. 2) in each of the first electrolyzed water generator 100A and the second electrolyzed water generator 100B. Apply. Although not shown, each of the control unit CC and the control unit CD also has a sensor, a memory, a processor, and the like.

  The control units CA and CB each receive a current flowing between the anode 1A and the cathode 1C via the resistor (r). Thereby, the control units CA and CB respectively determine the voltage applied between the anode 1A and the cathode 1C based on the information on the value of the current flowing between the anode 1A and the cathode 1C detected by the sensor S. Control the value of. Specifically, the control units CA and CB respectively determine the value of the voltage applied between the anode 1A and the cathode 1C so that the value of the current flowing between the anode 1A and the cathode 1C becomes a predetermined value. Control. The concentration of the electrolyzed water, for example, the concentration of the ozone water is estimated to be proportional to the value of the current flowing between the anode 1A and the cathode 1C. Therefore, in order to maintain the concentration of the available electrolyzed water at a substantially constant value, the control units CA and CB respectively operate the anodes so as to maintain the value of the current flowing between the anode 1A and the cathode 1C at a substantially constant value. The voltage applied between 1A and the cathode 1C is changed.

  For example, if one of the first electrolyzed water generator 100A and the second electrolyzed water generator 100B is continuously used, the value of the current detected by the sensor S may be lower than a predetermined value. In this case, one of the control unit CA and the control unit CB, which are being used, controls the anode 1A and the cathode 1C so that the value of the current flowing between the anode 1A and the cathode 1C increases to a predetermined value. The control for increasing the value of the voltage applied during is performed.

  The control unit CA controls the first electrolyzed water generator 100A based on the command signal received from the input unit I. The control unit CB controls the second electrolyzed water generator 100B based on the command signal received from the input unit I. The control unit CC controls the flow path changing mechanism V based on the command signal received from the input unit I. The control unit CD controls the pump P based on the command signal received from the input unit I.

  The control units CA, CB, CC, and CD stop the first electrolyzed water generator 100A and the second electrolyzed water generator 100B when an abnormal situation such as a full state or an electrical connection occurs. If no abnormal situation occurs, the control units CA, CB, CC, and CD execute subsequent normal processing.

(Channel change mechanism)
The flow path changing mechanism V shown in FIG. 1 is controlled by the control unit CC to perform a first state of leading raw water from the main flow path 15 to the first branch flow path 10A on the upstream side and an upstream state from the main flow path 15. One of the second states of leading the raw water to the second side branch flow path 10B is selectively formed. In the present embodiment, the flow path changing mechanism V is a single three-way valve, that is, a flow path switching valve. However, the flow path changing mechanism V is connected to the upstream first branch flow path 10A and the upstream second branch flow path 10B. There may be two on-off valves provided respectively. In this case, the control unit CC controls the opening / closing operation of the two switching valves so that the opening / closing operation of the two switching valves is the same as the channel switching operation of the channel switching valve.

(Structure of electrolyzed water generator)
The first electrolyzed water generator 100A and the second electrolyzed water generator 100B of the first embodiment shown in FIG. 2 will be described. Each of the first electrolyzed water generation device 100A and the second electrolyzed water generation device 100B is shown as an example of a plurality of electrolyzed water generation devices. Therefore, any one of the three or more electrolyzed water generators may be controlled to a state in which electrolyzed water is selectively and sequentially generated.

  Each of the first electrolyzed water generation device 100A and the second electrolyzed water generation device 100B functions as an ozone water generation device that generates ozone water as electrolyzed water. In the present embodiment, the first electrolyzed water generator 100A and the second electrolyzed water generator 100B have the same structure, but may have different structures.

  Each of the first electrolyzed water generator 100A and the second electrolyzed water generator 100B includes a housing 101 and a laminated structure 1 provided in the housing 101. The housing 101 has an electrode case 102 and an electrode case lid 103 for closing an opening above the electrode case 102.

(Electrode case)
As shown in FIG. 2, the electrode cases 102 of the first electrolyzed water generator 100A and the second electrolyzed water generator 100B have the same structure. The electrode case 102 is made of an acrylic resin. The electrode case 102 has a container structure whose upper surface is open.

  An upstream first branch channel 10A and a downstream first branch channel 20A are connected to two opposing side surfaces of the electrode case 102 of the first electrolyzed water generator 100A, respectively. An upstream second branch flow path 10B and a downstream second branch flow path 20B are connected to two opposing side surfaces of the electrode case 102 of the second electrolyzed water generation device 100B, respectively. A rib (not shown) for supporting the laminated structure 1 is provided inside the electrode case 102.

  The electrode case 102 has two through holes 104 and 105 on the bottom surface. The power supply shafts 106 and 107 extend to the outside of the electrode case 102 via the two through holes 104 and 105, respectively. Further, wiring (not shown) extending from the tip of the power supply shafts 106 and 107 of the first electrolyzed water generation device 100A is electrically connected to the control unit CA. The wiring extending from the power supply shafts 106 and 107 of the second electrolyzed water generator 100B is electrically connected to the control unit CB.

(Laminated structure)
As shown in FIGS. 2 and 3, each of the first electrolyzed water generation device 100A and the second electrolyzed water generation device 100B includes the same laminated structure 1. The laminated structure 1 includes a power supply 1S, an anode 1A, a cation exchange membrane 5, and a cathode 1C. An anode 1A is formed on one main surface of the power supply 1S by a plasma CVD (Chemical Vapor Deposition) method. The power supply 1S is a boron-doped conductive diamond material. A cation exchange membrane 5 is laminated on the anode 1A. The cathode 1C is stacked on the cation exchange membrane 5.

  As shown in FIG. 2, the upstream first branch channel 10A is connected to the upstream inflow port of the first electrolyzed water generator 100A. The upstream first branch flow path 20A is connected to the downstream outlet of the first electrolyzed water generator 100A. The first electrolyzed water generation device 100A includes a first generation state in which first electrolyzed water is generated from raw water flowing through the first branch flow path 10A on the upstream side, and a first non-electrolyte that does not generate first electrolyzed water. The state is switched to one of the generation states.

  As shown in FIG. 2, the second branch channel 10B is connected to the upstream inlet of the second electrolyzed water generator 100B. The second branch channel 20B is connected to an outlet on the downstream side of the second electrolyzed water generator 100B. The second electrolyzed water generation device 100B has a second generation state in which the second electrolyzed water is generated from the raw water flowing through the second branch flow path 10B and a second non-generation state in which the second electrolyzed water is not generated. It can be switched to either.

  As can be seen from FIG. 2, the laminated structure 1 electrolyzes raw water to generate ozone water as electrolyzed water. The laminated structure 1 has a thin plate shape of 10 mm × 50 mm × 1.2 mm. As described in detail later, the laminated structure 1 has a hole that penetrates the cathode 1C and the cation exchange membrane 5 and exposes the surface of the anode 1A on the bottom surface, more specifically, a groove or a slit. are doing.

  As can be inferred from the cross-sectional view of FIG. 2, the cation exchange with the cathode 1C is performed such that the slit as the cathode hole 1CTH of the cathode 1C and the slit as the membrane hole 5TH of the cation exchange membrane 5 overlap in plan view. The membrane 5 is arranged. Therefore, the above-mentioned hole of the laminated structure 1 communicates from the upper channel of the cathode 1C to the upper surface of the anode 1A.

  In each of the first electrolyzed water generator 100A and the second electrolyzed water generator 100B of the present embodiment, anode 1A and cation exchange membrane 5 are in contact with each other, and cation exchange membrane 5 and The cathode 1C is in contact. However, the anode 1A and the cation exchange membrane 5 may be provided at a distance. Further, the cation exchange membrane 5 and the cathode 1C may be provided at a distance.

(Power feeder)
The feeder 1S shown in FIGS. 2 and 3 applies a positive charge to the anode 1A of the multilayer structure 1. The power supply 1S has a thin plate shape of 10 mm x 50 mm x 0.5 mm. The extended portion of one edge of the power supply 1S constitutes a shaft mounting piece 1SA. The power supply 1S is made of titanium. The anode 1A is formed on the surface of the power supply 1S by a plasma CVD (Chemical Vapor Deposition) method. The power supply 1S is supported by the electrode case 102. The power supply shaft 106 pulled out from the shaft mounting piece 1SA is electrically connected to the control unit CA or the control unit CB.

(anode)
The anode 1A shown in FIGS. 2 and 3 receives positive charges from the control units CA and CB and generates ozone bubbles as electrolyzed water. The anode 1A has a thin plate shape of 10 mm × 50 mm × 3 μm. The anode 1A is a boron-doped conductive diamond film.

(Cation exchange membrane)
The cation exchange membrane 5 shown in FIGS. 2 and 3 is held between the anode 1A and the cathode 1C. Positive charges move from the anode 1A to the cathode 1C. The cation exchange membrane 5 has a thin plate shape of 10 mm × 50 mm × 0.2 mm. The cation exchange membrane 5 has a slit membrane hole 5TH penetrating from its upper surface to its lower surface.

  The longitudinal direction of the slit-shaped membrane hole 5TH is a direction orthogonal to the longitudinal direction of the cathode 1C. The dimensions of the slit-shaped membrane hole 5TH are 7 mm × 1 mm × 0.5 mm. The membrane holes 5TH are provided at ten positions on the cation exchange membrane 5, although not shown in the figure. Grooves or notches that form the gaps C1 or C2 that connect the adjacent membrane holes 5TH are provided. This groove or notch may be a depression necessarily formed in the manufacturing process.

(cathode)
The cathode 1C shown in FIGS. 2 and 3 receives the positive charges passing through the cation exchange membrane 5 to generate hydrogen bubbles. The cathode 1C has a thin plate shape of 10 mm × 50 mm × 0.5 mm. An extension of one edge of the cathode 1C forms a shaft mounting piece 1SC. The cathode 1C has a slit-shaped cathode hole 1CTH penetrating from the upper surface of the cathode 1C to the lower surface of the cathode 1C. The longitudinal direction of the cathode hole 1CTH is a direction orthogonal to the longitudinal direction of the cathode 1C.

  The dimensions of the slit-shaped cathode hole 1CTH are 7 mm × 1 mm × 0.5 mm. Although different from the drawing, the cathode holes 1CTH are provided at ten positions of the cathode 1C. A high electric resistance material R, which is a resin coating material, is applied to the inner peripheral surface of the cathode hole 1CTH. The high electrical resistance material R has a higher electrical resistance than the cathode 1C. The cathode 1C is made of stainless steel. The power supply shaft 107 pulled out from the shaft mounting piece 1SC of the cathode 1C is electrically connected to the control unit CA or the control unit CB.

(Chemical action)
As shown in FIG. 4, in each of the first electrolyzed water generator 100A and the second electrolyzed water generator 100B, no voltage is applied to the anode 1A and the cathode 1C, and the raw water is flowing. When not, little chemistry is occurring.

As shown in FIG. 5, when a voltage is applied to the anode 1A and the cathode 1C, the following chemical action occurs. Anode 1A side 3H ₂ O → O ₃ + 6H ⁺ + 6e ⁻
2H ₂ O → O ₂ + 4H ⁺ + 4e ⁻
Cathode 1C side 2H ₂ O + 2e ⁻ → H ₂ + 2OH ⁻
That is, in each of the first electrolyzed water generator 100A and the second electrolyzed water generator 100B, oxygen and ozone are generated near the anode 1A, and hydrogen is generated near the cathode 1C. Whether or not ozone is generated near the anode 1A depends on the voltage applied between the anode 1A and the cathode 1C. In the present embodiment, a voltage at which ozone is generated at the interface between anode 1A and cation exchange membrane 5 is applied between anode 1A and cathode 1C. However, a voltage that does not generate ozone at the interface between the anode 1A and the cation exchange membrane 5 may be applied between the anode 1A and the cathode 1C. As an electrode for generating ozone, a lead dioxide electrode, a diamond electrode, a platinum electrode, a tantalum oxide electrode, or the like can be used.

As shown in FIG. 6, when the raw water continues to be supplied to the cation exchange membrane 5 in a state where no voltage is applied between the anode 1A and the cathode 1C, the cation exchange membrane 5 It takes in the metal cations (M ⁺ ) contained and releases hydrogen ions (H ⁺ ) into the raw water. When hydrogen ions (H +) are bonded to each other, hydrogen (H ₂ ) is generated. The metal cation (M ⁺ ) is, for example, a calcium ion (Ca ²⁺ ) or a sodium ion (Na ⁺ ).

Thereafter, when a voltage is applied between the anode 1A and the cathode 1C, a chemical reaction of 2H ₂ O + 2e ⁻ + M ²⁺ → H ₂ + M (OH) ₂ is caused near the interface between the anode 1A and the cation exchange membrane 5. Occurs. That is, metal cations (for example, Ca ²⁺ or Na ⁺ ) contained in the raw water combine with hydroxide ions (OH ⁻ ) in the vicinity of the anode 1A to generate metal hydroxide M (OH) _2. You.

For example, when the metal cation (M ²⁺ ) is a calcium ion (Ca ²⁺ ), the carbonate ion (CO ²⁻ ) and the calcium ion (Ca ²⁺ ) in the water are combined. Therefore, as shown by the two-dot chain line in FIG. 6, the scale (CaCO ₃ ) may adhere to the inner peripheral surface of the membrane hole 5TH and the inner periphery of the cathode hole 1CTH near the interface between the cathode 1C and the cation exchange membrane 5. is there. However, according to the first electrolyzed water generation device 100A and the second electrolyzed water generation device 100B of the present embodiment, due to the presence of the high electric resistance material R described later, the membrane holes 5TH of the scale (CaCO ₃ ) and Adhesion of the cathode hole 1CTH to the inner peripheral surface is suppressed. As a result, a decrease in ozone generation efficiency caused by the membrane hole 5TH and the cathode hole 1CTH being narrowed by the scale is suppressed.

(Gap)
As understood from FIG. 7, the anode 1A and the cation exchange membrane 5 are in contact with each other. This is because it is preferable to increase the efficiency of positive charge transfer from the anode 1A to the cation exchange membrane 5 in order to increase the generation efficiency of electrolyzed water. Therefore, there is a possibility that ozone bubbles may stay in a small space between the contact surfaces of the anode 1A and the cation exchange membrane 5 where water does not flow. Therefore, in the present embodiment, a gap C1 is provided between the anode 1A and the cation exchange membrane 5 so that water flows between the anode 1A and the cation exchange membrane 5. As a result, the ozone present between the contact surface of the anode 1A and the contact surface of the cation exchange membrane 5 is discharged from the water passing through the gap C1 in a direction parallel to the respective contact surfaces of the anode 1A and the cation exchange membrane 5. Is naturally mixed into water by the siphon action caused by the flow of water. Therefore, ozone is prevented from staying between the anode 1A and the cation exchange membrane 5. From the above, it is possible to suppress an increase in the voltage applied between the anode 1A and the cathode 1C necessary for generating the electrolyzed water.

  As understood from FIG. 7, the cation exchange membrane 5 and the cathode 1C are in contact with each other. This is because it is preferable to increase the efficiency of positive charge transfer from the cation exchange membrane 5 to the cathode 1C in order to increase the generation efficiency of electrolyzed water. Therefore, there is a possibility that hydrogen bubbles may stay in a small space where water does not flow between the contact surfaces of the cation exchange membrane 5 and the cathode 1C. Therefore, in the present embodiment, a gap C2 is provided between the cation exchange membrane 5 and the cathode 1C so that water flows between the cation exchange membrane 5 and the cathode 1C. As a result, hydrogen existing between the contact surface of the cation exchange membrane 5 and the contact surface of the cathode 1C is converted into water passing through the gap C2 in a direction parallel to the respective contact surfaces of the cation exchange membrane 5 and the cathode 1C. Is naturally mixed into water by the siphon action caused by the flow of water. Therefore, stagnation of hydrogen between the cation exchange membrane 5 and the cathode 1C is suppressed. As a result, it is possible to suppress an increase in the voltage applied between the anode 1A and the cathode 1C required for generating the electrolyzed water.

  As shown in FIG. 7, the gap C1 is a groove or a notch provided on the surface of the cation exchange membrane 5 facing the anode 1A. However, the gap C1 may be a groove or a notch formed on the surface of the anode 1A facing the cation exchange membrane 5. The gap C1 is formed by both a groove or a notch formed on the surface of the cation exchange membrane 5 facing the anode 1A and a groove or notch formed on the surface of the anode 1A facing the cation exchange membrane 5. There may be. The gap C1 may be formed naturally between the anode 1A and the cation exchange membrane 5 during manufacturing.

  The gap C1 is different from a large groove or notch as depicted in the drawing, and is actually a large number of small notches or grooves formed in the nonwoven fabric constituting the cation exchange membrane 5. The position and size of the gap C1 may be any value as long as water flows between the anode 1A and the cation exchange membrane 5 and the anode C has a portion where the anode 1A and the cation exchange membrane 5 are in contact with each other. It may be something.

  As shown in FIG. 7, the gap C2 is a groove or a notch provided on the surface of the cation exchange membrane 5 facing the cathode 1C. However, the gap C2 may be a groove or a notch formed on the surface of the cathode 1C facing the cation exchange membrane 5. The gap C2 is formed by both a groove or a notch formed on the surface of the cation exchange membrane 5 facing the cathode 1C and a groove or notch formed on the surface of the cathode 1C facing the cation exchange membrane 5. There may be. The gap C2 may be formed naturally between the cathode 1C and the cation exchange membrane 5 during manufacturing.

  The gap C2 is different from a large groove or notch as depicted in the drawing, and is actually a large number of small notches or grooves formed in the nonwoven fabric constituting the cation exchange membrane 5. The position and size of the gap C2 can be determined as long as water flows between the cation exchange membrane 5 and the cathode 1C and the cation exchange membrane 5 has a portion in contact with the cathode 1C. It may be something.

  As shown in FIG. 7, each of the anode 1A and the cathode 1C has a plate shape. The plate-shaped anode 1A, the cation exchange membrane 5, and the plate-shaped cathode 1C form a laminated structure 1 that is laminated in this order. The cation exchange membrane 5 has a plurality of membrane holes 5TH penetrating in the thickness direction of the cation exchange membrane 5. The cathode 1C has a plurality of cathode holes 1CTH that penetrate in the thickness direction of the cathode 1C and communicate with the plurality of membrane holes 5TH, respectively. Therefore, the surface of the anode 1A on the cation exchange membrane 5 side, the inner surface of the plurality of membrane holes 5TH, and the inner surface of the plurality of cathode holes 1CTH constitute a plurality of holes each having a bottom surface and a peripheral surface.

  As shown in FIG. 7, the gap C1 between the anode 1A and the cation exchange membrane 5 connects adjacent ones of the plurality of holes formed in the laminated structure 1. Therefore, ozone existing between the anode 1A and the cation exchange membrane 5 can be efficiently mixed into the flow of water. The gap C2 between the cation exchange membrane 5 and the cathode 1C allows adjacent ones of the plurality of holes formed in the laminated structure 1 to communicate with each other. Therefore, hydrogen existing between the cation exchange membrane 5 and the cathode 1C can be efficiently introduced into water.

(High electrical resistance material)
4 to 8, the inner peripheral surface of the cathode hole 1CTH is covered with a high electric resistance material R having an electric resistance higher than the electric resistance of the cathode 1C. Therefore, the force of the inner peripheral surface of cathode hole 1CTH to attract cations contained in water is reduced. This suppresses cations from remaining in the cathode hole 1CTH. Therefore, the binding between the cations remaining on the inner peripheral surface of the cathode hole 1CTH and the anions contained in the water is suppressed. As a result, generation of scale due to the binding of the cation and the anion is suppressed. Therefore, it is possible to suppress a reduction in the ability to generate electrolyzed water due to the scale remaining in the cathode hole 1CTH.

  In the present embodiment, the high electrical resistance material R may be one in which the inner peripheral surface of the stainless steel cathode hole 1CTH constituting the cathode 1C is changed by heating or a chemical reaction. It is preferable that the entire inner peripheral surface of cathode hole 1CTH is covered with high electrical resistance material R. The high electric resistance material R is preferably an insulating material.

  A portion of the contact surface between the cathode 1C and the cation exchange membrane 5 around the inner peripheral surface of the cathode hole 1CTH, for example, a part of the lower surface and the upper surface of the cathode 1C may be covered with the high electrical resistance material R. . However, since the cathode 1C and the cation exchange membrane 5 are in contact at any position, cations can be transmitted from the cation exchange membrane 5 to the cathode 1C. According to this, the occurrence of scale can be suppressed more reliably. It is preferable that the entire inner peripheral surface of each of the plurality of cathode holes 1CTH is covered with the high electrical resistance material R. According to this, generation of scale can be suppressed more reliably while increasing the generation efficiency of the electrolyzed water.

  The high electrical resistance material R is a coating material applied to the cathode 1C. Therefore, the high electric resistance material R can be easily attached to the inner peripheral surface of the cathode 1C. If the high electrical resistance material R is an insulating material, the generation of scale can be suppressed more reliably.

  In the present embodiment, cathode 1C is formed of a stainless steel material, and high electric resistance material R is formed of a fluororesin material. Therefore, both the value of the adhesive strength between the cathode 1C and the coating material and the value of the electrical resistance of the necessary coating material can be set to desired values.

(Other examples of cathode and high electrical resistance materials)
As shown in FIG. 8, the first electrolyzed water generator 100A and the second electrolyzed water generator 100B may include a cathode 1C of another example. The cathode 1C of another example has a frame shape. The lower surface of the cathode 1C of another example having a frame shape is provided so as to be in contact with the upper surface of the cation exchange membrane 5. In this case, the gap C1 and the gap C2 of the cation exchange membrane 5 need not be provided.

  The high electrical resistance material R is fitted into the frame-shaped cathode 1C so as to cover the inner peripheral surface of the frame-shaped cathode 1C. The high electrical resistance material R has a structure like a lattice window. Specifically, the high electrical resistance material R has an outer shape of a plate-shaped member, and has a plurality of communication holes RTH that communicate with the plurality of membrane holes 5TH, respectively. The high electric resistance material R has an electric resistance value higher than the electric resistance value of the cathode.

  According to this, the inner circumferential surface of the frame-shaped cathode 1C and the inner circumferential surfaces of the plurality of membrane holes 5TH of the cation exchange membrane 5 are insulated by the high electrical resistance material R. Therefore, the possibility of generation of scale near the membrane hole 5TH can be reduced. The ozone generated on the upper surface of the anode 1A exposed to the water below the membrane hole 5TH is mixed into the water flowing above the cathode 1C through the plurality of communication holes RTH.

(System switching control)
As shown in FIG. 9, when the control unit CD drives (ON) the pump P, the raw water is fed into the main flow path 15. The flow path changing mechanism V is selectively switched to one of the first state and the second state by the control unit CC. In the present embodiment, the first state is a state in which the flow path changing mechanism V guides raw water from the main flow path 15 to the first branch flow path 10A on the upstream side. The second state is a state in which the flow path changing mechanism V guides raw water from the main flow path 15 to the second branch flow path 10B on the upstream side.

  First, the control unit CC switches the flow path changing mechanism V from the closed state to the above-described first state. Thereby, the raw water is guided from the main channel 15 to the first branch channel 10A on the upstream side. Thereafter, the raw water is supplied to the first electrolyzed water generator 100A.

  Next, the control unit CA executes a control in which the first electrolyzed water generation device 100A generates electrolyzed water during any of the periods in which the flow path changing mechanism V is in the first state. That is, a voltage is applied between the anode 1A and the cathode 1C of the first electrolyzed water generator 100A. In the first electrolyzed water generator 100A, electrolyzed water is generated by applying (ON) a voltage between the anode 1A and the cathode 1C.

  In addition, when the flow path changing mechanism V is in the first state described above, the control unit CB performs control in which the second electrolyzed water generation device 100B does not generate electrolyzed water. That is, no voltage is applied between the anode 1A and the cathode 1C of the second electrolyzed water generator 100B. In other words, the second electrolyzed water generator 100B is in a stopped (OFF) state.

  After that, the control unit CD executes control to stop the pump P, and the control unit CC switches the flow path changing mechanism V to a closed state. At this time, in each of the first electrolyzed water generation device 100A and the second electrolyzed water generation device 100B, the control units CA and CB do not apply a voltage between the cathode 1C and the anode 1A, respectively.

  Next, in a state where the control unit CD is executing control for driving the pump P, the control unit CC switches the flow path changing mechanism V to the above-described second state. Thereby, the raw water is guided from the main flow path 15 to the second branch flow path 10B on the upstream side. Thereafter, the raw water is supplied to the second electrolyzed water generator 100B.

  When the flow path changing mechanism V is in the above-described second state, the control unit CA performs control in which the first electrolyzed water generation device 100A does not generate electrolyzed water. That is, no voltage is applied between the anode 1A and the cathode 1C of the first electrolyzed water generator 100A. In other words, the first electrolyzed water generator 100A is in a stopped (OFF) state.

  Further, the control unit CB executes control for causing the second electrolyzed water generation device 100B to generate electrolyzed water during any of the periods in which the flow path changing mechanism V is in the above-described second state. That is, a voltage is applied between the anode 1A and the cathode 1C of the second electrolyzed water generator 100B. In the second electrolyzed water generator 100B, electrolyzed water is generated by applying (ON) a voltage between the anode 1A and the cathode 1C.

  Generally, if the first electrolyzed water generator 100A and the second electrolyzed water generator 100B are continuously used, the scale will adhere to the cathode 1C or the like due to an increase in the pH of the electrolyzed water. Scales include those referred to as calcium scales, magnesium scales, and hardness component scales. Examples of these scales include calcium carbonate, magnesium carbonate, calcium sulfate, magnesium hydroxide, and calcium phosphate, or iron hydroxide scales (iron rust), such as iron hydroxide and iron oxide. It is.

  When the scale is generated, the value of the current flowing between the anode 1A and the cathode 1C decreases. Therefore, the control unit CA or CB controls the control to increase the value of the voltage applied between the anode 1A and the cathode 1C. Execute. Therefore, when the first electrolyzed water generator 100A or the second electrolyzed water generator 100B is continuously used, the generation of the electrolyzed water of the first electrolyzed water generator 100A or the second electrolyzed water generator 100B is continued. The efficiency of the system decreases.

  From the above, in order to suppress the generation of scale, it is conceivable to shorten the time for continuously using each of the first electrolyzed water generator 100A and the second electrolyzed water generator 100B. Therefore, an electrolyzed water generator that generates electrolyzed water and an electrolyzed water generator that does not generate electrolyzed water are switched in a time-division manner. According to this, the electrolyzed water generation system 1000 as a whole can continuously generate electrolyzed water while shortening the time for using one electrolyzed water generation device. As a result, the ability to generate electrolyzed water can be maintained while suppressing an increase in the voltage applied between the anode 1A and the cathode 1C to obtain electrolyzed water having a desired concentration.

(Intermittent operation control of the system)
As shown in FIG. 9, the control unit CA of the first electrolyzed water generation device 100A and the control unit CB of the second electrolyzed water generation device 100B both intermittently apply a voltage between the anode 1A and the cathode 1C. Voltage. Therefore, while the application of the voltage between the anode 1A and the cathode 1C is stopped, the ozone staying between the anode 1A and the cation exchange membrane 5 flows out into the water, Hydrogen retained between the exchange membrane 5 and the cathode 1C flows out into water. As a result, ozone is prevented from staying between the anode 1A and the cation exchange membrane 5, and hydrogen is prevented from staying between the cation exchange membrane 5 and the cathode 1C.

  As shown in FIG. 9, the control units CA, CB, CC, and CD control the pump P and the flow path changing mechanism V. Thus, the raw water is supplied to the electrolyzed water generators 100A and 100B not only during the period in which the voltage is applied between the anode 1A and the cathode 1C, but also during part of the period in which the application of the voltage is stopped. I will be. More specifically, in addition to a period in which a voltage is applied between the anode 1A and the cathode 1C, a predetermined period before and after a period in which a voltage is applied between the anode 1A and the cathode 1C, Raw water is guided to the electrolyzed water generators 100A and 100B. Therefore, ozone is more reliably suppressed from staying between the anode 1A and the cation exchange membrane 5, and hydrogen is more reliably suppressed from staying between the cation exchange membrane 5 and the cathode 1C. Is done. However, the control unit CD may control the on / off of the pump P so as to send out the raw water to the main flow path 15 in synchronization with the on / off of the application of the voltage.

(Operation of the electrolyzed water generation system)
The operator operates the input unit I and transmits a command signal from the input unit I to the control units CA, CB, CC, and CB. Thus, first, the pump P is driven, and the raw water is sent to the first electrolyzed water generator 100A. Thereafter, a voltage is applied between the anode 1A and the cathode 1C of the first electrolyzed water generator 100A. Thereby, electrolyzed water is generated in the first electrolyzed water generation device 100A. In the case of the present embodiment, ozone bubbles are generated near the interface between the cation exchange membrane 5 and the anode 1A in the first electrolyzed water generator 100A. Further, hydrogen is generated near the interface between the cation exchange membrane 5 and the cathode 1C in the first electrolyzed water generator 100A. Ozone bubbles and hydrogen bubbles dissolve in raw water. As a result, ozone water is generated as electrolyzed water.

  The ozone bubbles are inevitable between the anode 1A and the cation exchange membrane 5 as time passes while a voltage is applied between the anode 1A and the cathode 1C of the first electrolyzed water generator 100A. Stay in the gap. The unavoidable gap is too small to be shown. The ozone bubbles function as an insulator between the anode 1A and the cathode 1C. However, the ozone staying in the inevitable gap between the anode 1A and the cation exchange membrane 5 is sucked into the water by a siphon action caused by the flow of the water flowing through the gap C1, and the first electrolytic water is generated. It flows out from the apparatus 100A to the first branch flow path 20A on the downstream side.

  In the state where a voltage of hydrogen is applied between the anode 1A and the cathode 1C of the first electrolyzed water generator 100A, the time between the cation exchange membrane 5 and the cathode 1C increases with time. Stays in the unavoidable gaps. The unavoidable gap is too small to be shown. The hydrogen bubbles function as an insulator between the anode 1A and the cathode 1C. However, the hydrogen remaining in the inevitable gap between the cathode 1C and the cation exchange membrane 5 is sucked into the water by the siphon action caused by the flow of the water flowing through the gap C2, and the first electrolyzed water generator 100A From the first branch flow path 20A on the downstream side.

  In the above case, the hydroxide ion concentration increases. As a result, in the hole formed by the surface of the membrane hole 5TH, the cathode hole 1CTH (or the communication hole RTH) and the anode 1A of the laminated structure 1 of the first electrolyzed water generating apparatus 100A, that is, the hydroxide salt, (Scale) temporarily stays. In the present embodiment, the inner peripheral surface of cathode hole 1CTH is covered with high-resistance material R. Therefore, the generated scale is mixed into the electrolyzed water without adhering to the cathode hole 1CTH, and flows out together with the electrolyzed water from the first electrolyzed water generator 100A to the first branch flow path 20A on the downstream side.

When the raw water is being sent to the first electrolyzed water generator 100A, the raw water is not sent to the second electrolyzed water generator 100B. Therefore, accumulation of metal cations contained in the raw water in the cation exchange membrane 5 of the second electrolyzed water generator 100B is suppressed. For example, exchange between hydrogen ions (H ⁺ ) of the cation exchange membrane 5 of the second electrolyzed water generator 100B and calcium ions (Ca ²⁺ ) in the raw water is suppressed.

  When a predetermined time has elapsed since the voltage was applied between the anode 1A and the cathode 1C of the first electrolyzed water generator 100A, the voltage between the anode 1A and the cathode 1C of the first electrolyzed water generator 100A was changed. The application is stopped. Thus, generation of ozone between the anode 1A and the cation exchange membrane 5 and generation of hydrogen between the cation exchange membrane 5 and the cathode 1C are stopped. Thereafter, the pump P continues to be driven for a predetermined time. As a result, the raw water is sent to the first electrolyzed water generator 100A in a state where the application of the voltage between the anode 1A and the cathode 1C of the first electrolyzed water generator 100A is stopped. As a result, most of the ozone bubbles staying between the anode 1A and the cation exchange membrane 5 flow out into the raw water and are almost completely discharged together with the raw water from the first electrolyzed water generator 100A. You. Most of the hydrogen bubbles remaining between the cation exchange membrane 5 and the cathode 1C flow out into the raw water and are almost completely discharged together with the raw water from the first electrolyzed water generator 100A. .

When a predetermined time elapses after the application of the voltage between the anode 1A and the cathode 1C of the first electrolyzed water generator 100A is stopped, the pump P is stopped. Thereby, the raw water is not sent to the first electrolyzed water generator 100A. Thus, hydroxide ions (OH ⁻ ) are completely discharged from the first electrolyzed water generator 100A. As a result, the alkalinity inside the first electrolyzed water generator 100A is reduced. Therefore, generation of scale in the first electrolyzed water generation device 100A is suppressed.

  Thereafter, in a state where the control CD continues to execute the control for driving the pump P, the control unit CC executes the control for switching the flow path changing mechanism V, thereby being sent to the first electrolyzed water generating apparatus 100A. The raw water that has been sent is sent to the second electrolyzed water generator 100B. Thereafter, a voltage is applied between the anode 1A and the cathode 1C of the second electrolyzed water generator 100B.

  Thereby, electrolyzed water is generated in the second electrolyzed water generation device 100B. In the case of the present embodiment, ozone bubbles are generated near the interface between the cation exchange membrane 5 and the anode 1A. Ozone bubbles dissolve in the raw water. As a result, ozone water is generated.

  Ozone bubbles are inevitable between the anode 1A and the cation exchange membrane 5 as time passes in a state where a voltage is applied between the anode 1A and the cathode 1C of the second electrolyzed water generator 100B. Stay in the gap. The inevitable gap is too small to be shown. The ozone bubbles function as an insulator between the anode 1A and the cathode 1C. However, the ozone staying in the inevitable gap between the anode 1A and the cation exchange membrane 5 is sucked into the water by the siphon action caused by the flow of the water flowing through the gap C1, and the second electrolytic water is generated. It flows out from the device 100B to the downstream second branch channel 20B.

  Further, in a state where a voltage is applied between the anode 1A and the cathode 1C of the second electrolyzed water generator 100B, as time passes, hydrogen bubbles are generated in the cathode 1C of the second electrolyzed water generator 100B. Stays in the inevitable gap between the cation exchange membrane 5 and the cation exchange membrane 5. The inevitable gap is too small to be shown. The hydrogen bubbles function as an insulator between the anode 1A and the cathode 1C. However, the hydrogen remaining in the inevitable gap between the cathode 1C and the cation exchange membrane 5 is sucked into the water by the siphon action caused by the flow of the water flowing through the gap C2, and the second electrolyzed water generator 100B From the second branch flow path 20B on the downstream side.

  In the above case, the hydroxide salt (scale) stays as a result of the increase in the hydroxide ion concentration in the hole of the laminated structure 1 of the second electrolyzed water generator 100B, that is, in the slit.

When the raw water is being sent to the second electrolyzed water generator 100B, the raw water is not sent to the first electrolyzed water generator 100A. Therefore, accumulation of metal cations contained in the raw water in the cation exchange membrane 5 of the first electrolyzed water generator 100A is suppressed. For example, exchange of hydrogen ions (H ⁺ ) of the cation exchange membrane 5 of the first electrolyzed water generator 100A with calcium ions (Ca ²⁺ ) in raw water is suppressed.

  When a predetermined time elapses after the voltage is applied between the anode 1A and the cathode 1C of the second electrolyzed water generator 100B, the voltage between the anode 1A and the cathode 1C of the second electrolyzed water generator 100B is changed. The application is stopped. This stops the generation of ozone between the anode 1A and the cation exchange membrane 5 and the generation of hydrogen between the cation exchange membrane 5 and the cathode 1C. Thereafter, the pump P continues to be driven for a predetermined time. As a result, the raw water is sent to the second electrolyzed water generator 100B in a state where the application of the voltage between the anode 1A and the cathode 1C of the second electrolyzed water generator 100B is stopped.

  As a result, most of the ozone bubbles staying between the anode 1A and the cation exchange membrane 5 flow out into the raw water and are almost completely discharged together with the raw water from the second electrolyzed water generator 100B. You. Most of the hydrogen bubbles remaining between the cation exchange membrane 5 and the cathode 1C flow out into the raw water, and then are almost completely discharged together with the raw water from the second electrolyzed water generator 100B. .

When a predetermined time elapses after the application of the voltage between the anode 1A and the cathode 1C of the second electrolyzed water generator 100B is stopped, the pump P is stopped. Thereby, the raw water is no longer sent to the second electrolyzed water generator 100B. Thereby, hydroxide ions (OH ⁻ ) are discharged from the second electrolyzed water generator 100B. As a result, the alkalinity inside the second electrolyzed water generator 100B is reduced. Further, the generation of scale in the second electrolyzed water generator 100B is suppressed.

  Thereafter, in a state where the control CD continues to execute the control for driving the pump P, the control unit CC executes the control for switching the flow path changing mechanism V, thereby being sent to the second electrolyzed water generating apparatus 100B. The raw water that has been used is sent back to the first electrolyzed water generator 100A. Thereafter, a voltage is again applied between the anode 1A and the cathode 1C of the first electrolyzed water generator 100A.

  The electrolyzed water generation system 1000 of the present embodiment as described above is used for a place where only normal ozone water is used without using normal water, for example, for flushing toilet bowls.

(Embodiment 2)
The electrolyzed water generation system 1000 of the present embodiment is substantially the same as the electrolyzed water generation system 1000 of the first embodiment. Hereinafter, the point that the electrolyzed water generation system 1000 of the present embodiment is different from the electrolyzed water generation system 1000 of the first embodiment will be mainly described. It should be noted that the electrolyzed water generator 100A of the present embodiment is the same as the first electrolyzed water generator 100A and the second electrolyzed water generator 100B of the first embodiment.

  However, the electrolyzed water generator 100A of the present embodiment may be different from the first electrolyzed water generator 100A and the second electrolyzed water generator 100B of the first embodiment. For example, the electrolyzed water generator 100A may be one in which an ion exchange membrane and a cathode made of a metal mesh are wound around the anode made of a metal mesh made of platinum by pressure welding in this order.

  As shown in FIG. 10, the electrolyzed water generation system 1000 includes a main flow path 15, an upstream first branch flow path 10A, a downstream first branch flow path 20A, an electrolyzed water generation apparatus 100A, and an upstream water flow path. A second branch flow path 10B and a downstream second branch flow path 20B are provided. The electrolyzed water generation system 1000 includes a flow path changing mechanism V. The flow path changing mechanism V includes an on-off valve V1 and an on-off valve V2. In the present embodiment, the on-off valve V1 is provided in the first branch flow path 10A on the upstream side. The on-off valve V2 is provided in the second branch flow path 10B on the upstream side. However, instead of the on-off valve V1 and the on-off valve V2, the three-way valve as the flow path switching valve according to the first embodiment is the main flow path 15, the first branch flow path 10A on the upstream side, and the second branch flow on the upstream side. It may be provided at a branch point with each of the roads 10B.

  As shown in FIG. 10, the main channel 15 receives raw water. The first branch flow path 10 </ b> A on the upstream side is branched from the main flow path 15. The electrolyzed water generator 100A includes an anode 1A, a cathode 1C, and a cation exchange membrane 5 provided between the anode 1A and the cathode 1C. The electrolyzed water generator 100A is connected to an upstream first branch channel 10A and a downstream first branch channel 20A.

  The electrolyzed water generation device 100A is switched to one of a generation state in which electrolyzed water is generated from raw water flowing through the upstream first branch flow path 10A and a non-generation state in which electrolyzed water is not generated. The second branch flow path 10B on the upstream side branches from the main flow path 15 and guides raw water flowing through the main flow path 15 to the downstream. The on-off valves V1 and V2 are changed by the control unit C to one of the first state and the second state. The first state is a state in which the on-off valve V1 is open and the on-off valve V2 is closed, and a state in which raw water is guided from the main flow path 15 to the first branch flow path 10A on the upstream side. The second state is a state in which the on-off valve V1 is closed and the on-off valve V2 is open, and a state in which raw water is guided from the main flow path 15 to the second branch flow path 10B on the upstream side.

  According to the above configuration, when no voltage is applied between the anode 1A and the cathode 1C, the on-off valves V1 and V2 are set in the second state so that raw water is not supplied to the cation exchange membrane 5. Can be switched to That is, the control unit C closes the on-off valve V1 and opens the on-off valve V2. Thereby, it is possible to suppress the cation exchange membrane 5 in the electrolyzed water generator A from taking inevitable cations contained in the raw water.

  Therefore, when the electrolyzed water generator 100A is generating electrolyzed water, that is, when a voltage is applied between the anode 1A and the cathode 1C, the cations taken into the cation exchange membrane 5 are electrolyzed. Release to water is suppressed. As a result, the generation of scale due to the release of cations from the cation exchange membrane 5 to the electrolytic water is suppressed. Further, when the electrolyzed water generator 100A is not generating electrolyzed water, water that is not electrolyzed water can be taken out from the second branch flow path 20B. Therefore, when the electrolyzed water generator 100A is not generating electrolyzed water, it is possible to use water that is not electrolyzed water, for example, water that is not ozone water, while suppressing generation of scale.

  As shown in FIG. 10, the electrolyzed water generation system 1000 includes a purification device 200. The purification device 200 is connected between the upstream second branch flow path 10B and the downstream second branch flow path 20B, and uses the raw water flowing through the second branch flow paths 10B, 20B as purified water as downstream water. Out to the main flow path 15. Therefore, when the electrolyzed water generator 100A does not generate electrolyzed water, purified water can be used instead of raw water. Note that the purification device 200 may not be provided.

  The above-described electrolyzed water generation system 1000 of the present embodiment can be used for tap water used in a home kitchen. In this case, the inner surface of the kitchen sink can be sterilized and washed with ozone water, while tap water containing no ozone can be used for washing dishes and the like.

(Another example of electrolyzed water generation system)
As shown in FIG. 11, an electrolyzed water generation system 1000 according to another example of the second embodiment includes a purification device 200. The purification device 200 is connected to the main channel 15. The purification device 200 causes the raw water flowing through the main flow path 15 to flow out to the downstream main flow path 15 as purified water. Note that the purification device 200 may not be provided.

  In the electrolyzed water generation system 1000 of another example, the electrolyzed water generation device 100A generates electrolyzed water from purified water instead of raw water. Therefore, the possibility that foreign matter enters the inside of the electrolyzed water generation device 100A can be reduced. When the electrolyzed water generator 100A does not generate electrolyzed water, purified water can be used instead of raw water.

  The ozone generation efficiency will be compared using FIG. 12 and FIG. FIGS. 12 and 13 show the case where ozone is continuously generated and the case where ozone is generated intermittently in one electrolyzed water generator under the same total ozone generation time. It is a graph for comparing the aspect of the fall of the production capacity of ozone water. Continuous generation of ozone water means that a voltage is continuously applied between the anode 1A and the cathode 1C of the electrolyzed water generator 100A. Intermittent generation of ozone water means intermittent application between the anode 1A and the cathode 1C of the electrolyzed water generator 100A.

  FIG. 12 shows the relationship between time and voltage in the electrolyzed water generation device 100A when the pump P is on and the on-off valve V1 is open when the electrodes (1A, 1C) are off. ing. FIG. 12 shows the electrolyzed water when the electrodes (1A, 1C) are OFF, the pump P is in the OFF state, or the pump P is in the ON state and the on-off valve V1 is in the closed state. The relationship between time and voltage in the generator 100A is also shown. FIG. 13 shows the relationship between the time and the ozone generation amount in the electrolyzed water generation device 100A when the pump P is on and the on-off valve V1 is open when the electrodes (1A, 1C) are off. Shows the relationship. FIG. 13 shows the electrolyzed water when the electrodes (1A, 1C) are off, the pump P is off, or the pump P is on and the on-off valve V1 is closed. The relationship between the time and the amount of ozone generated in the generator 100A is also shown.

  In FIGS. 12 and 13, “when the electrodes (1A, 1C) are OFF” means a state in which no voltage is applied between the anode 1A and the cathode 1C of the electrolyzed water generator 100A. In FIGS. 12 and 13, “the state in which the pump P is ON” is a state in which the raw water flows through the main flow path 15 by driving the pump P. “The on-off valve V1 is in the open state” is a state in which the raw water flows into the electrolytic water generation device 100A by opening the on-off valve V1. “The on-off valve V1 is in the closed state” means a state in which the raw water does not flow into the electrolyzed water generation device 100A by closing the on-off valve V1.

  In FIG. 12, when the on-off valve V1 is opened when the electrodes (1A, 1C) are off, compared to when the on-off valve V1 is closed when the electrodes (1A, 1C) are off. In a shorter time, the voltage applied between the anode 1A and the cathode 1C increases. As shown in FIG. 12, when the supply of raw water to the electrolyzed water generator 100A is stopped when no voltage is applied between the anode 1A and the cathode 1C, the anode 1A required to generate ozone at a desired concentration is obtained. It can be seen that an increase in the voltage applied between the cathode and the cathode 1C can be suppressed. This is because generation of scale near the cathode 1C when no voltage is applied between the anode 1A and the cathode 1C is suppressed.

  In FIG. 13, when the on-off valve V1 is opened when the electrodes (1A, 1C) are off, the opening time of the on-off valve V1 is shorter than when the on-off valve V1 is closed when the electrodes are off. The concentration of ozone obtained downstream of the electrolyzed water generator 100A is decreasing. In other words, from FIG. 13, when the supply of the raw water to the electrolyzed water generator 100A is stopped when no voltage is applied between the anode 1A and the cathode 1C, it is possible to suppress a decrease in the concentration of ozone. I understand. This is because generation of scale near the cathode 1C when no voltage is applied between the anode 1A and the cathode 1C is suppressed.

As shown in FIG. 14, the cation exchange membrane 5 of another example of the electrolyzed water generator 100A has a sulfonic acid group (—SO ₃ H). As shown in FIG. 15, when no voltage is applied between the anode 1A and the cathode 1C, the cation exchange membrane 5 accepts metal cations (Ca ²⁺ , Na ⁺ ) in water and receives hydrogen. Releases ions (H ⁺ ) into water. That is, the cation is replaced.

  As shown in FIG. 15, in the first electrolyzed water generation device 100A of another example, the anode 1A, the cation exchange membrane 5, and the cathode 1C do not have a laminated structure and may be arranged apart from each other. Good. Further, the anode 1A and the cathode 1C are not in the form of a flat plate but in the form of a mesh. In the first electrolyzed water generation device 100A of another example, ozone is not generated, and hydrogen and oxygen may be generated in water.

As shown in FIG. 16, immediately after a voltage is applied between the anode 1A and the cathode 1C, water (H ₂ O) is converted into hydroxyl groups (OH ⁻ ) and hydrogen ions (H ⁺ ) near the anode 1A. And is decomposed into As a result, the cation exchange membrane 5, captures the hydrogen ion ^{(H +),} metal cation ^(Ca 2+, Na ⁺⁾ in water to release. Hydrogen (H ₂ ) is generated near the cathode 1C. Therefore, in the state shown in FIG. 16, the concentration of metal cations (Ca ²⁺ , Na ⁺ ) in the water increases, and the pH of the water increases.

As shown in FIG. 17, when the voltage is continuously applied between the anode 1A and the cathode 1C, the release of metal cations (Ca ²⁺ , Na ⁺ ) into water stops. In the state shown in FIG. 17, the concentration of metal cations (Ca ²⁺ , Na ⁺ ) in the water decreases, and the pH of the water decreases.

Also in the case of using the electrolyzed water generator 100A of another example shown in FIGS. 14 to 17, similarly to the first electrolyzed water generator 100A and the second electrolyzed water generator 100B of the first embodiment, the scale Can be suppressed. Specifically, similarly to Embodiment 1 described above, the generation of scale due to the incorporation of metal cations (Ca ²⁺ , Na ⁺ ) in cation exchange membrane 5 contained in flowing water is suppressed. be able to.

  Hereinafter, the characteristic configurations of the electrolyzed water generation apparatuses 100A and 100B and the electrolyzed water generation system 1000 of the embodiment and the effects obtained thereby will be described.

  (1) The electrolyzed water generation system 1000 includes the main flow path 15, the first branch flow paths 10A and 20A, the electrolyzed water generation apparatus 100A, the second branch flow paths 10B and 20B, and the flow path changing mechanisms V, V1 and V2. It has. The main channel 15 receives raw water. The first branch passages 10A and 20A are branched from the main passage 15. The electrolyzed water generator 100A includes an anode 1A, a cathode 1C, and a cation exchange membrane 5 provided between the anode 1A and the cathode 1C. The electrolyzed water generator 100A is connected to the first branch channels 10A and 20A. The electrolyzed water generation device 100A is switched to one of a generation state in which electrolyzed water is generated from raw water flowing through the first branch flow paths 10A and 20A and a non-generation state in which electrolyzed water is not generated. The second branch flow paths 10B and 20B branch off from the main flow path 15 and guide raw water flowing through the main flow path 15 downstream. The flow path changing mechanisms V, V1, and V2 are provided in the first state in which the raw water is guided from the main flow path 15 to the first branch flow paths 10A and 20A, and the raw water flows from the main flow path 15 to the second branch flow paths 10B and 20B. Either one of the guided second states can be selectively formed.

  According to the above configuration, when no voltage is applied between the anode 1A and the cathode 1C, the flow path changing mechanisms V, V1, V2 are set to the second position so that raw water is not supplied to the cation exchange membrane 5. State can be switched. Thereby, it is possible to suppress the cation exchange membrane 5 from taking inevitable cations contained in the raw water. Therefore, when the electrolyzed water generator 100A is generating electrolyzed water, that is, when a voltage is applied between the anode 1A and the cathode 1C, the cations taken into the cation exchange membrane 5 are electrolyzed. Release to water is suppressed. As a result, the generation of scale due to the release of cations from the cation exchange membrane 5 to the electrolytic water is suppressed. Further, when the electrolyzed water generator 100A is not generating electrolyzed water, water that is not electrolyzed water can be taken out from the second branch channel 10B. Therefore, when the electrolyzed water generator 100A is not generating electrolyzed water, water that is not electrolyzed water can be used while suppressing generation of scale.

  (2) The electrolyzed water generation system 1000 further includes a purification device 200 that is connected to the second branch flow paths 10B and 20B and that causes raw water flowing through the second branch flow paths 10B and 20B to flow downstream as purified water. I have. According to this, when the electrolyzed water generator 100A does not generate electrolyzed water, purified water can be used instead of raw water.

  (3) It is preferable that the electrolyzed water generation system 1000 further includes a purification device 200 connected to the main flow path 15 and configured to flow raw water flowing through the main flow path 15 to the downstream main flow path 15 as purified water. In this case, the electrolyzed water generator 100A generates electrolyzed water from purified water. According to this, since the electrolyzed water is generated from the purified water, it is possible to reduce a possibility that foreign matter enters the inside of the electrolyzed water generation device 100A. When the electrolyzed water generator 100A does not generate electrolyzed water, purified water can be used instead of raw water.

1A Anode 1C Cathode 5 Cation exchange membrane 10A, 20A First branch flow path (branch flow path)
10B, 20B Second branch channel (branch channel)
15 Trunk flow path 100A Electrolyzed water generator 200 Purifier 1000 Electrolyzed water generation system V, V1, V2 Flow path changing mechanism

Claims (3)

A main channel for receiving raw water,
A first branch channel branched from the main channel,
An anode, a cathode, and a cation exchange membrane provided between the anode and the cathode, wherein the cation exchange membrane is connected to the first branch flow path and flows through the first branch flow path. An electrolyzed water generation device that is switched to one of a generation state in which electrolyzed water is generated from raw water and a non-generation state in which electrolyzed water is not generated,
A second branch flow path that branches from the main flow path and guides the raw water flowing through the main flow path to the downstream, and is not connected to an electrolyzed water generation device that generates electrolyzed water ,
Selectively one of a first state in which the raw water is guided from the main flow path to the first branch flow path and a second state in which the raw water is guided from the main flow path to the second branch flow path. and a flow path changing mechanism capable of forming a,
When the flow path changing mechanism is in the first state, in at least a part of the period of the first state, the electrolyzed water generation device is in the generation state,
An electrolyzed water generation system, wherein the electrolyzed water generation device is set to the non-generation state when the flow path changing mechanism is in the second state .   2. The electrolyzed water generation system according to claim 1, further comprising a purification device connected to the second branch flow path and configured to cause the raw water flowing through the second branch flow path to flow downstream as purified water. 3. A purification device connected to the trunk flow path, further comprising a purification device for flowing the raw water flowing through the trunk flow path to the downstream main flow path as purified water,
The electrolyzed water generation system according to claim 1, wherein the electrolyzed water generation device generates the electrolyzed water from the purified water.

Images