JP2002079250A - Hypochlorous acid water making apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hypochlorous acid water making apparatus capable of supplying even high temperature hypochlorous acid water without lowering electrolytic capacity at the time of electrolysis. SOLUTION: A mixing means 6 is provided in the hypochlorous acid water making apparatus so as to freely change over a mixing state, wherein hypochlorous acid water, made in a hypochlorous acid water making part 3 for electrolyzing water supplied to an electrolytic cell 2 from a water supply passage 1 to make hypochlorous acid water, is mixed with hot water supplied through a hot water passage 4 to be supplied to a hot water supply passage 5 and a non-mixing state, wherein hypochlorous acid water made in the hypochlorous acid water making part 3 is supplied to the hot water supply passage without being mixed with hot water from the hot water passage. A control means 7 is constituted so as to freely change over a hot water supply control part for changing over the mixing means 6 to the mixing state to operate the hypochlorous acid water making part 3 and a cooling water supply control state for changing over the mixing means 6 to the non-mixing state to operate the hypochlorous acid water making part 3.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hypochlorous acid water generator for electrolyzing water supplied from a water supply channel to an electrolytic cell to generate hypochlorous acid water, and a hypochlorous acid water generation unit. And a control means for controlling the operation of the section.

[0002]

2. Description of the Related Art An apparatus for producing hypochlorous acid water as described above comprises:
Water containing chlorine ions, such as tap water, is supplied to the electrolytic cell, and the water is electrolyzed to produce hypochlorite water having a disinfecting effect, and the hypochlorous water is converted to water. It is supplied to a predetermined place such as a kitchen or a washroom, and enables a user to use hypochlorous acid water having a disinfecting effect in a predetermined place such as a kitchen or a washroom.

[0003] This type of hypochlorous acid water generator generally electrolyzes water such as tap water, and supplies hypochlorous acid water generated by the electrolysis. The temperature of the hypochlorous acid water is substantially the same as the temperature of water such as tap water supplied through a water supply channel.

[0004]

However, in the above-described conventional hypochlorous acid water generating apparatus, the temperature of the supplied hypochlorous acid water is substantially the same as the temperature of the water supplied through the water supply passage. In winter, the temperature of water supplied through the water supply channel drops, so low-temperature hypochlorous acid water is supplied, and users use the low-temperature hypochlorous acid water. It is desired that high-temperature hypochlorous acid water can be supplied, for example, it is hot and the user needs high-temperature hypochlorous acid water.

Therefore, in order to supply hot hypochlorous acid water, hot water can be supplied from a hot water supply device such as a hot water supply device to an electrolytic cell, and the hot water supplied to the electrolytic cell is electrolyzed. This produces hot water hypochlorous acid water,
It is conceivable to supply the hot water hypochlorous acid solution.In this case, however, the temperature of the target water to be electrolyzed increases because the hot water is electrolyzed in the electrolytic cell.
The electrolysis performance when performing electrolysis is reduced, the amount of generated hypochlorous acid is reduced, and the hypochlorous acid concentration of the supplied hypochlorous acid water is reduced to a concentration at which the disinfecting effect is not obtained There is a risk of doing this. To add an explanation, the electrolysis performance when performing electrolysis is proportional to the electrical conductivity of the water to be electrolyzed, but the electrical conductivity increases as the temperature of the water to be electrolyzed increases. When the temperature of the target water to be electrolyzed is high, the electrolytic performance is reduced and the amount of generated hypochlorous acid is reduced.

The present invention has been made in view of such a point, and an object of the present invention is to make it possible to supply a high-temperature aqueous solution of hypochlorous acid without deteriorating the electrolytic performance when performing electrolysis. Another object of the present invention is to provide a hypochlorous acid water generator.

[0007]

To achieve this object, according to the first aspect of the present invention, water supplied to an electrolytic cell from a water supply channel is electrolyzed to produce hypochlorous acid water. And a mixed state of mixing hypochlorous acid water generated in the hypochlorous acid water generating section and hot water supplied through a hot water path and supplying the hot water supply path with Mixing means that can be switched to a non-mixing state in which the hypochlorous acid water generated in the hypochlorous acid water generation unit is supplied to the hot water supply path without mixing the hot water from the hot water path, A control unit for controlling the operation of the hypochlorous acid water generation unit and the mixing unit; and the control unit switches the mixing unit to the mixing state to operate the hypochlorous acid water generation unit. And the mixing means is switched to the non-mixing state. Recombinant and is configured to be freely switchable between the cold water supply control state for operating the hypochlorite water production unit.

That is, the control means switches to one of the hot water supply control state and the cold water supply control state, and the hypochlorous acid water generation unit causes the hot water supply control state and the cold water supply control state to change to one of the states. Even in the state, since the water supplied from the water supply channel is configured to be electrolyzed in the electrolytic cell, the control unit switches to the hot water supply control state, thereby electrolyzing the water from the water supply channel. It is possible to mix the hypochlorous acid water generated by the electrolysis with the hot water and supply the hot hypochlorous acid water through the hot water supply path, and switch the control means to the cold water supply state. Therefore, while the water from the water supply channel is electrolyzed, the hypochlorous acid water generated by the electrolysis is not mixed with the warm water, and the cold hypochlorous acid water is passed through the hot water supply channel. It is possible to supply.

Accordingly, it is possible to supply hot water hypochlorous acid water, and when supplying the hot water hypochlorous acid water,
Since it is possible to electrolyze low-temperature water from the water supply channel, it is possible to supply high-temperature hypochlorous acid water without lowering the electrolytic performance when performing electrolysis. It has become possible to provide a generator.

[0010] According to the second aspect of the present invention, in the chilled water supply control state, the control means determines that a flow rate of water supplied through the water supply passage is equal to or greater than a set flow rate for chilled water supply. Perform electrolysis in the electrolytic cell, and
In the hot water supply control state, the electrolysis in the electrolytic cell is performed when the flow rate is equal to or greater than the hot water supply set water quantity that is smaller than the cold water supply set water quantity.

That is, in the cold water supply control state,
While the hypochlorous acid water generated in the hypochlorous acid water generating section is supplied to the hot water supply path without mixing the hot water from the hot water path, in the hot water supply control state, hypochlorous acid is supplied. Since the hypochlorous acid water generated in the water generator and the hot water supplied through the hot water channel are mixed and supplied to the hot water supply channel, the hypochlorous acid water supplied through the hot water supply channel is supplied The concentration of chloric acid is lower in the hot water supply control state than in the cold water supply state by the amount of hot water mixed, and there is a possibility that a sufficient disinfection effect cannot be obtained in the hot water supply control state.

However, according to the second aspect of the present invention, in the hot water supply control state, the control means sets the hot water supply setting such that the amount of water supplied through the water supply passage is smaller than the cold water supply setting water amount. Since the electrolysis is performed in the electrolytic cell when the amount of water is equal to or more than that, the electrolysis is performed in a state in which the amount of water supplied to the electrolytic cell is smaller in the hot water supply control state than in the cold water supply control state. Becomes
Then, the flow rate of water supplied through the water supply passage is adjusted by a manual operation or the like so that the amount of water supplied to the electrolytic cell is smaller in the hot water supply control state than in the cold water supply control state. By making it smaller in the supply control state than in the cold water supply control state, the amount of water flowing to the electrolytic cell is smaller in the hot water supply control state than in the cold water supply control state. The electrolysis can be performed in the state, and the concentration of hypochlorous acid generated by the electrolysis can be higher in the hot water supply control state than in the cold water supply control state. .

Therefore, the control means generates hypochlorous acid water having a higher hypochlorous acid concentration in the electrolytic cell in the hot water supply control state than in the cold water supply control state, and generates the hypochlorous acid water having the higher concentration. Since the hypochlorous acid water is supplied through the hot water supply passage by mixing the hot water with the acid water, the hypochlorous acid concentration of the supplied hypochlorous acid water supplied through the hot water supply passage in the hot water supply control state. Can be maintained at a concentration at which a sufficient disinfection effect can be obtained.

According to the third aspect of the present invention, in the chilled water supply control state, the control means sets the amount of electricity supplied to the electrolytic cell to a set amount for chilled water supply, and executes electrolysis. Further, in the hot water supply control state, the electrolysis is performed by setting the supply energization amount to a set amount for hot water supply larger than the set amount for cold water supply.

In other words, the hypochlorous acid concentration of the supplied hypochlorous acid water supplied through the hot water supply passage is higher in the hot water supply control state than in the cold water supply state. The concentration becomes lower by the amount of the hot water mixed, and there is a possibility that a sufficient disinfection effect may not be obtained in the hot water supply control state.However, in the hot water supply control state,
The electrolysis is performed by setting the amount of electricity supplied to the electrolytic cell to a set amount for hot water supply larger than the set amount for cold water supply, so that the hot water supply control state is more than the cold water supply control state. Also, it is possible to increase the concentration of hypochlorous acid generated by electrolysis, and in the hot water supply control state, the disinfecting effect of the hypochlorous acid concentration of the supplied hypochlorous acid water supplied through the hot water supply passage is sufficient. Can be maintained at a concentration at which can be obtained.

According to the fourth aspect of the present invention, the control means controls the supply hypochlorous acid water supplied through the hot water supply passage in each of the cold water supply control state and the hot water supply control state. The operation of the hypochlorous acid water generating unit is controlled so that the hypochlorous acid concentration becomes the same or substantially the same.

That is, the hypochlorous acid concentration of the supplied hypochlorous acid water supplied through the hot water supply passage is higher in the hot water supply control state than in the cold water supply state. There is a possibility that the concentration becomes lower by the amount of mixing the hot water, and a sufficient disinfection effect may not be obtained in the hot water supply control state. Since the hypochlorous acid water generation unit is operated so that the hypochlorous acid concentration of the acid water becomes the same or almost the same concentration, in any of the cold water supply control state and the hot water supply control state, The supply hypochlorous acid water having the same or almost the same concentration of hypochlorous acid can be supplied through the hot water supply passage, and the hypochlorous acid water can be supplied in any of the cold water supply control state and the hot water supply control state. Chloric acid concentration It is possible to supply the feed hypochlorous acid water having a concentration obtained a sufficient disinfecting effect.

Further, in any of the cold water supply control state and the hot water supply control state, it is possible to supply the supply hypochlorous acid water having the same or substantially the same concentration of hypochlorous acid. In any of the supply control state and the hot water supply control state, the same disinfection effect can be obtained, and the usability of the user can be improved.

According to the fifth aspect of the present invention, a hot water supply state in which hot hypochlorous acid water is supplied through the hot water supply path, and a cold water supply state in which cold water hypochlorous acid water is supplied through the hot water supply path. Manual command means for commanding the supply state is provided, and the control means switches to the hot water supply control state when the hot water supply state is commanded by the command means, and controls the cold water supply state by the command means. When the supply state is commanded, the apparatus is configured to switch to the cold water supply state.

That is, when the user instructs the hot water supply state by manual instruction means, the control means switches to the hot water supply control state, and the user instructs the cold water supply state by manual instruction means. Then, since the control means switches to the cold water supply state, the user can manually switch between the hot water supply control state and the cold water supply control state. Therefore, the hot water supply control state and the cold water supply control state are appropriately switched to supply hot water hypochlorous acid water or cold water hypochlorous acid water as required by the user. Is possible, and the usability of the user can be improved.

According to the sixth aspect of the present invention, there is provided temperature setting means for variably setting a target temperature of the supply hypochlorous acid water supplied through the hot water supply passage, and the control means comprises In the hot water supply control state, based on the target temperature set by the temperature setting means, mixing of the hypochlorous acid water generated in the hypochlorous acid water generation unit and the hot water supplied through the hot water passage It is configured to adjust the ratio.

That is, in the hot water supply control state, the control means controls the mixing ratio of the hypochlorous acid water and the hot water so that the temperature of the supplied hypochlorous acid water becomes the target temperature set by the temperature setting means. Can be adjusted, so that the hypochlorous acid water at the target temperature set by the temperature setting means is supplied from the hot water supply path, and only the hypochlorous acid water at a constant temperature can be supplied. It is possible to improve the usability of the device as compared with the device.

[0023]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An example in which a hypochlorous acid water producing apparatus according to the present invention is installed in a washroom will be described with reference to the drawings. [First Embodiment] This hypochlorous acid water generating apparatus T has the structure shown in FIG.
As shown in FIG. 2 and FIG. 2, a hypochlorous acid water generating section 3 for electrolyzing water supplied from the water supply channel 1 to the electrolytic cell 2 to generate hypochlorous acid water, Hypochlorous acid water generated in the section 3 is mixed with hot water supplied through the hot water channel 4 and supplied to the hot water supply channel 5, or hot water is supplied without mixing hot water with hypochlorous acid water. A mixing unit 6 for supplying to the passage 5, a control unit 7 as a control unit for controlling the operation of the hypochlorous acid water generating unit 3 and the mixing unit 6, an operation unit 8 for instructing the control unit 7 to send control information, and the like. In the casing K, a hypochlorous acid water generating unit 3, a mixing unit 6, and a control unit 7 are accommodated. Incidentally, FIG. 1 is a diagram showing an overview and a connection state of the hypochlorous acid water generator T in a state where the front surface of the casing K is installed.
FIG. 2 is a schematic configuration diagram of the hypochlorous acid water generator T.

The water supply channel 1 is connected to a water supply curan 9 and provided with a water amount sensor S for detecting the amount of water supplied from the water supply curan 9 to the hypochlorous acid water generator T. A manual switching valve 10 is provided at a connection point with the water supply curan 9. By switching the switching valve 10, the tap water from the water supply curan 9 is supplied to the hypochlorous acid water generator T. And a state in which tap water is supplied from the water supply curran 9. Further, a water heater 11 is connected to the hot water channel 4, and the hot water from the hot water device 11 is supplied to the hypochlorous acid water generator T through the hot water channel 4. Incidentally, as the water heater 11, various water heaters such as a gas-fired water heater, an electric water heater, and a solar water heater can be applied, but a constant temperature hot water supply type for supplying hot water at a constant temperature is applicable. Are preferred.

The hypochlorous acid water generator 3 comprises an electrolytic cell 2 for electrolyzing tap water supplied through a water supply channel 1, and both a positive electrode 12 and a negative electrode 13 inserted into the electrolytic cell 2. It is composed of an electrode, a direct current energizing section 14 for energizing the positive electrode 12 and the negative electrode 13 and the like, and the tap water in the electrolytic cell 2 is supplied by energizing the positive electrode 12 and the negative electrode 13 from the direct current energizing section 14. It is configured to generate an aqueous solution of hypochlorous acid upon electrolysis. The number of electrodes can be appropriately changed, and the number of the positive electrode 12 and the number of the negative electrode 13 may be two or more. When the number of the electrodes is two or more, the positive electrode 12 and the negative electrode 13 are alternately arranged. It is arranged so that it becomes.

The electrolysis in the electrolytic cell 2 will be specifically described.
0ppm of chloride ion (Cl ^-) are included, the electrolysis of the tap water, hydrogen gas to the negative electrode 13 (H _2), chlorine gas (Cl ₂₎ is generated in the positive electrode 12. -Pole: 2H ⁺ + 2e ⁻ → H ₂ + Pole: 2Cl ⁻ → Cl ₂ + 2e ⁻

Then, chlorine is more reactive than hydrogen, and chlorine gas is generated earlier than hydrogen gas. The chlorine gas generated earlier is immediately converted into the surrounding water (H
₂ O), hydrochloric acid (HCl) and hypochlorous acid (HCl)
O). Hydrochloric acid (HCl) ionizes almost 100% to hydrogen ions (H ⁺ ) and chlorine ions (Cl ⁻ ) in water, so that only hypochlorous acid (HClO) is several to
Several tens of ppm are generated, and hypochlorous acid water is generated. _{Cl 2 + H 2 O → HCl} + HClO → H + + Cl - + HClO

In the hypochlorous acid water generating section 3, a gas-liquid separating section 15 for gas-liquid separating an electrolytic gas such as hydrogen generated in the electrolytic cell 2 from the hypochlorous acid water is generated by electrolysis. A generated hydrogen treatment means 16 for oxidizing the generated hydrogen with the catalyst B is provided. More specifically, the gas-liquid separation unit 15 is formed in a vertically long cylindrical shape, and is connected to the upper communication pipe 17.
The lower and upper communication pipes 18 connect the upper and lower portions to the electrolytic cell 2, and a hypochlorous acid water supply passage 19 for supplying hypochlorous acid water is connected to the lower side of the gas-liquid separation unit 15. Have been. Then, the hypochlorous acid water generated in the electrolytic cell 2 overflows and flows downward, and then flows into the lower part of the gas-liquid separation unit 15 through the lower communication pipe 18, so that the gas-liquid separation unit The lower side of 15 is a liquid layer in which hypochlorous acid water is present. The electrolytic gas containing hydrogen gas generated by the electrolysis flows into the upper part of the gas-liquid separator 15 through the upper communication pipe 17, and the upper part of the gas-liquid separator 15 accumulates the electrolytic gas containing hydrogen gas. It is to be a gas layer.

A gas communication passage 21 for supplying an electrolytic gas containing hydrogen gas after gas-liquid separation to the generated hydrogen processing means 16 through a gas vent 20 is connected to the upper end of the gas-liquid separation unit 15. The gas-liquid separation unit 15 has a float 22 that can move up and down according to the liquid level of hypochlorous acid water,
Further, a valve body 23 that opens and closes the gas vent 20 in conjunction with the float 22 is provided. In this way,
The gas-liquid separation unit 15 separates gas and liquid into hypochlorous acid water and an electrolytic gas containing hydrogen gas, and the hypochlorous acid water is supplied to a hypochlorous acid water supply path 19, and the electrolytic gas Is supplied to the generated hydrogen treatment means 16.

The generated hydrogen treatment means 16 is provided with a catalyst B in a reaction vessel 24 for oxidizing the hydrogen gas in the electrolytic gas and the oxygen in the air, and for introducing external air into the reaction vessel 24. An opening 25 is formed. And
The electrolytic gas containing hydrogen gas flows from the lower side to the upper side, and in the reaction vessel 24, the catalyst B causes an oxidation reaction with oxygen in the air, that is, a catalytic reaction. Is discharged to the outside of the hypochlorous acid water generator T. In addition,
As the catalyst B, for example, platinum, copper, or another metal catalyst for reacting hydrogen gas with oxygen is used.

The hot water channel 4 is provided with a hot water flow control valve 26 and a hot water valve 27 in order from the water heater 11 side.
The hypochlorous acid water supply passage 19 is located downstream of the hot water valve 27.
Are connected to each other, and a mixing valve 28 is provided at the connection point. The mixing means 6 is configured by the hot water valve 27 and the mixing valve 28. And this mixing means 6
The hot water valve 27 is opened, the mixing valve 28 mixes the hypochlorous acid water from the hypochlorous acid water supply passage 19 with the warm water from the hot water passage 4 and supplies the mixed water to the hot and cold water supply passage 5. ,
The hot water valve 27 is closed, and the mixing valve 28 supplies the hypochlorous acid water from the hypochlorous acid water supply passage 19 to the hot water supply passage 5 without mixing the hot water from the hot water passage 4. It is configured to be switchable between and.

The operating section 8 is provided with a hypochlorous acid water generator T
Power lamp 2 that indicates that power is on
9. An operation lamp 30 indicating that the hypochlorous acid water generator T is in operation, a hot water supply state in which hot hypochlorous acid water is supplied through the hot water supply path 5, and a cold water supply state through the hot water supply path 5. A hot water switch 31 as a command means for instructing a cold water supply state for supplying hypochlorous acid water, a water amount overlamp 32 indicating that the amount of water supplied from the water supply curran 9 is over, and a hot water supply passage 5 The apparatus is provided with a manual temperature controller 33 as temperature setting means for variably setting a target temperature of the supplied hypochlorous acid water to be supplied. The temperature adjusting section 33 is of a dial type, and can adjust the target temperature in five steps from high to low when the user dials the knob.

The control section 7 switches the mixing means 6 to the mixing state, switches the hot water supply control state for operating the hypochlorous acid water generating section 3 and the mixing means 6 to the non-mixing state,
It is configured to be freely switchable to a cold water supply control state in which the hypochlorous acid water generating section 3 is operated. And the control unit 7
Is switched to the hot water supply control state when the hot water switch 31 is turned on and the hot water supply state is commanded, and is switched to the cold water supply state when the hot water switch 31 is turned off and the cold water supply state is commanded. It is configured to switch to the state.

In the chilled water supply control state, the controller 7 executes electrolysis in the electrolytic cell 2 when the amount of water supplied through the water supply passage 1 is equal to or larger than the set amount of chilled water supply. In the hot water supply control state, the electrolysis in the electrolytic cell 2 is performed when the flow rate is equal to or more than the set amount of hot water supply smaller than the set amount of cold water supply.

The control unit 7 turns on the operation lamp 30 when the water amount detected by the water amount sensor S becomes equal to or more than the set water amount for cold water supply (for example, 2.0 liter / minute). And the DC power supply 1
4, the positive electrode 12 and the negative electrode 13 are energized to perform electrolysis in the electrolytic cell 2. If the detected water amount is equal to or more than the set water amount for cold water supply (for example, 2.0 liter / min), The energization from the energizing section 14 to the plus electrode 12 and the minus electrode 13 is continued. And the control unit 7
When the water amount detected by the water amount sensor S is equal to or more than the chilled water supply capacity limit water amount (for example, 4.0 liters / minute), the water amount over-lamp 32 is turned on, and the water amount from the water supply curran 9 is given to the user. It is configured to notify that it is in a state where the desired electrolytic performance cannot be maintained at the time of electrolysis due to too much electrolysis. When the water amount overlamp 32 is turned on, the user reduces the amount of water to the hypochlorous acid water generator T with the water supply curan 9 until the water amount overlamp 32 is turned off.

In addition to the description of the hot water supply control state, the control unit 7 determines that the amount of water detected by the water amount sensor S is smaller than the set amount of cold water supply (for example, the set amount of hot water supply).
1.0 liter / min) or more, the operation lamp 30 is turned on, and the DC
And the negative electrode 13 is energized to perform electrolysis in the electrolytic cell 2. If the detected water amount is equal to or more than the set amount of hot water supply (for example, 1.0 liter / min), the DC current supply unit 14 The energization of the electrode 12 and the negative electrode 13 is continued. When the water amount detected by the water amount sensor S becomes equal to or more than the capacity limit water amount for hot water supply (for example, 3.0 liters / minute), the control unit 7 turns on the water amount over-lamp 32, and instructs the user to supply water. It is configured to notify that the amount of water from 9 is too large to maintain the desired electrolytic performance when performing electrolysis.

That is, the controller 7 controls the electrolytic cell 2 in the hot water supply control state more than in the cold water supply control state.
By performing electrolysis in the electrolytic cell 2 while reducing the amount of water supplied to the water, the concentration of hypochlorous acid in the hypochlorous acid water generated in the hypochlorous acid water generation unit 3 increases. It is configured to be. The hypochlorous acid water generation unit 3 increases the concentration of the generated hypochlorous acid water in the hot water supply control state more than in the cold water supply control state. Mixing the generated hypochlorous acid water with the warm water from the hot water passage 4 and supplying the mixed hypochlorous acid water as the supply hypochlorous acid water through the hot water supply passage 5, Even if hot water hypochlorous acid is supplied, the hypochlorous acid supplied is maintained at a concentration such that a sufficient disinfection effect can be obtained. By the way, in order to obtain a disinfecting effect when the hypochlorous acid concentration of the supplied hypochlorous acid water is 4 ppm or more, the hypochlorous acid concentration of the supplied hypochlorous acid water supplied through the hot water supply passage 5 is 4 ppm or more. It is configured to be.

As described above, in either the hot water supply control state or the cold water supply control state, the target water to be electrolyzed is set to the low-temperature water from the water supply channel 1 while the hypochlorite generated by the electrolysis is used. By mixing hot water with chloric acid water, it is possible to supply hot water hypochlorous acid water as well. Also, by increasing the concentration of hypochlorous acid generated in the electrolysis in the hot water supply control state compared to the cold water supply control state, the hypochlorous acid water generated in the electrolysis is reduced. Even if hot water is mixed and hot water is supplied to supply hypochlorous acid water, a sufficient disinfection effect can be obtained.

In the hot water supply control state, the control unit 7 controls the hypochlorous acid water generated by the hypochlorous acid water generation unit 3 based on the target temperature set by the temperature adjustment unit 33. The mixing ratio with the hot water supplied through the hot water channel 4 is adjusted. That is, in the hot water supply control, the control unit 7 controls the temperature adjusting unit 33 so that the temperature of the supplied hypochlorous acid water supplied through the hot water supply passage 5 becomes the target temperature set by the temperature adjusting unit 33. The opening degree of the hot water flow rate adjustment valve 26 is adjusted so that the opening degree of the hot water flow rate adjustment valve 26 increases as the target temperature set in the equation (2) increases.

The usage of the hypochlorous acid water generator T will be described. When the user needs cold water hypochlorous acid water, the user turns off the hot water switch 31.
By switching the switching valve 10 to a state in which the tap water from the water supply curan 9 is supplied to the hypochlorous acid water generator T, the tap water from the water supply channel 1 is supplied to the hypochlorous acid water generator 3. Is electrolyzed to produce hypochlorous acid water, and the hypochlorous acid water is supplied from the hot water supply passage 5 as supply hypochlorous acid water without mixing the hot water from the hot water passage 4. Become. Also, when the user needs hot water hypochlorous acid water, the user turns on the hot water switch 31 and switches the switching valve 10 to supply the tap water from the water supply curan 9 to the hypochlorous acid water generator. By switching to the state of supply to T, the hypochlorous acid water generating unit 3 electrolyzes tap water from the water supply channel 1 to generate hypochlorous acid water, and the hypochlorous acid water is converted into hot water. The mixed hypochlorous acid water is mixed with the warm water from the passage 4 and supplied from the hot water supply passage 5 as supply hypochlorous acid water.

[Second Embodiment] The second embodiment shows another embodiment of the operation of the control section 7 in the first embodiment, and other configurations are the same as those in the first embodiment. is there. Incidentally, in the second embodiment, only the configuration different from that of the first embodiment will be described, and the other configurations will be denoted by the same reference numerals and the detailed description thereof will be omitted.

In the cold water supply control state, the controller 7 sets the amount of electricity supplied to the electrolytic cell 2 to a set amount for cold water supply, performs electrolysis, and in the hot water supply control state, The electrolysis is performed by setting the amount of power supplied to 2 to the set amount for hot water supply larger than the set amount for cold water supply. More specifically, the control unit 7
In the chilled water supply control state, the amount of current supplied to the plus electrode 12 and the minus electrode 13 from the DC current supply unit 14 is set as a chilled water supply set amount, and the current is supplied to the plus electrode 12 and the minus electrode 13 from the DC current supply unit 14. ,Also,
In the hot water supply control state, the amount of current supplied from the DC current supply unit 14 to the plus electrode 12 and the minus electrode 13 is set as a set amount for hot water supply larger than the set amount for cold water supply. The negative electrode 13 is configured to be energized.

That is, the controller 7 controls the hypochlorous acid water generated by the hypochlorous acid water generator 3 in the hot water supply control state more than in the cold water supply control state. The acid concentration is increased, and the hypochlorous acid water generated in the hypochlorous acid water generation unit 3 and the hot water from the hot water channel 4 are mixed, and the mixed hypochlorous acid water is mixed. Even if the supply hypochlorous acid water is supplied through the hot water supply passage 5, a sufficient disinfection effect can be obtained.

Incidentally, in the second embodiment, the control unit 7 determines that the amount of water detected by the water amount sensor S is equal to or greater than the set working water amount in either the cold water supply control state or the hot water supply control state. 2 to perform the electrolysis, or as in the first embodiment,
In the cold water supply control state, if the flow rate of water supplied through the water supply channel 1 is equal to or greater than the set flow rate for cold water supply, electrolysis in the electrolytic cell 2 is performed. The electrolysis in the electrolytic cell 2 may be performed when the temperature is equal to or more than the set amount of hot water supply smaller than the set amount of cold water supply.

[Third Embodiment] The third embodiment shows another embodiment of the operation of the control section 7 in the first embodiment, and other configurations are the same as those in the first embodiment. is there. Incidentally, in the third embodiment, only the configuration different from the first embodiment will be described, and the other configurations will be denoted by the same reference numerals and the detailed description thereof will be omitted.

The controller 7 controls the supply hypochlorite water supplied through the hot water supply passage 5 to have the same or substantially the same concentration of hypochlorous acid water in each of the cold water supply control state and the hot water supply control state. It is configured to control the operation of the hypochlorous acid water generating unit 3 so that More specifically, a hot water flow sensor for detecting the flow rate of hot water supplied through the hot water channel 4 is provided, and the cold water supply control state is determined based on the hot water flow detected by the hot water flow sensor and the water flow detected by the water flow sensor S. In each of the hot water supply control states, the opening degree of the hot water flow control valve 26 is adjusted so that the concentration of the hypochlorous acid water supplied through the hot water supply passage 5 becomes the same or substantially the same. In addition to the adjustment, it is configured to prompt the user to adjust the amount of water with the water supply curran 9.

Incidentally, the specific configuration in the third embodiment is not limited to the above-described configuration. For example, in addition to the above-mentioned hot water flow sensor, a water flow control for adjusting the flow of water supplied through the water supply passage 1 is also possible. A valve or the like is provided to supply hypochlorous acid supplied through the hot / cold water supply path 5 in each of the cold water supply control state and the hot water supply control state based on the hot water amount detected by the hot water amount sensor and the water amount detected by the water amount sensor S. The opening degree of the hot water flow rate adjusting valve 26 and the opening degree of the water amount adjusting valve may be configured and implemented so that the hypochlorous acid water concentration of water becomes the same or substantially the same.

As another specific configuration in the third embodiment, the above-described hot water amount sensor is provided, and based on the hot water amount detected by the hot water amount sensor and the water amount detected by the water amount sensor S, the cold water supply control state and the hot water supply In each of the control states, the amount of electricity supplied to the electrolytic cell 2 is adjusted so that the concentration of the hypochlorous acid water supplied through the hot water supply passage 5 becomes the same or substantially the same. It is also possible to implement with such a configuration.

[Other Embodiments] (1) In the first to third embodiments, the entire amount of water supplied through the water supply channel 1 is configured to be supplied to the electrolytic cell 2. A part of the water to be supplied is supplied to the electrolytic cell 2, and the remaining part of the water supplied through the water supply channel 1 is mixed with the hypochlorous acid water generated in the electrolytic cell 2 and supplied. It is also possible to implement it. More specifically, as shown in FIG. 3, a part of the water supplied through the water supply channel 1 bypasses the electrolytic cell 2 and is located downstream of the mixing valve 28 in the flow direction of the hypochlorous acid water. A bypass valve 34 is provided on the side of the electrolysis tank 2, and a bypass valve 35 capable of adjusting the flow rate of water in the bypass 34 is provided in the bypass 34.
And a portion of the water is electrolyzed to generate hypochlorous acid water. The hypochlorous acid water is mixed with water supplied through the bypass passage 34, and supplied through the hot water supply passage 5. It is configured to supply chloric acid water. Incidentally, the bypass valve 35 may be an intermittent valve that interrupts the flow of water in the bypass passage 34, or may be an adjusting valve that can adjust the flow rate of water in the bypass passage 34 to zero.

That is, in the one shown in FIG.
For supplying water from the tank to the electrolytic cell 2 and a bypass 34
The water is supplied through the hot water supply passage 5 by mixing the water from the bypass passage 34 with the hypochlorous acid water generated by the electrolysis and supplying the mixed water through the hot water supply passage 5. The supply hypochlorite water is configured to secure the supply amount.

3, the downstream end of the bypass passage 34 in the direction of flow of water is connected to the downstream side of the mixing valve 28 in the direction of flow of hypochlorous acid water. A part of the water supplied through the water supply path 1 is supplied to the downstream side of the mixing valve 28 in the flow direction of the water, bypassing the electrolytic cell 2. Is connected to the hypochlorous acid water supply passage 19, that is, upstream of the mixing valve 28 in the flow direction of hypochlorous acid water, and supplied through the water supply passage 1. A part of the water may be supplied to the hypochlorous acid water supply passage 19 bypassing the electrolytic cell 2. By the way,
In this case, the bypass passage 34 and the hypochlorous acid water supply passage 1
A check valve for preventing backflow to the electrolytic cell 2 is provided on the downstream side in the direction of flow of the hypochlorous acid water from the connection point with the cell 9. That is, when a part of the water supplied through the water supply channel 2 is supplied to the electrolytic cell 2, the remaining water is mixed with the hypochlorous acid generated in the electrolytic cell 2. Good.

(2) In the first embodiment, the amount of water supplied to the electrolytic cell 2 in the hot water supply control state is smaller than that in the cold water supply control state due to a manual operation of the user. For example, as shown by a dotted line in FIG. 2, a water amount adjusting valve 36 for adjusting the amount of water from the water supply curran 9 is provided in the water supply channel 1, and the control unit 7 controls the water amount adjusting valve 36.
By automatically adjusting the opening of the electrolyzer 2 in the hot water supply control state rather than in the cold water supply control state.
The amount of water supplied to the container may be small. Further, as shown by the dotted line in FIG. 2, the cooling water supply control is performed by adjusting the flow rate of the hypochlorous acid water from the hypochlorous acid water supply passage 19 by the mixing valve 28 without providing the water amount adjusting valve 36. It is also possible to carry out the process such that the amount of water supplied to the electrolytic cell 2 is smaller in the hot water supply control state than in the state.

(3) In the first to third embodiments, the example in which the hypochlorous acid water generating section 3 is provided with the gas-liquid separating section 15 and the generated hydrogen treatment means 16 has been described. It is also possible to carry out without providing the hydrogen treatment means 16.

(4) In the first to third embodiments, the controller 7 switches between the hot water supply control state and the cold water supply control state depending on whether the hot water switch 31 is turned on or off. However, for example, the control means automatically switches between the hot water supply control state and the cold water supply control state depending on the season, such as switching to the cold water supply control state in summer and switching to the hot water supply control state in winter. It is also possible to

(5) In the first to third embodiments, the example in which the hypochlorous acid water producing apparatus according to the present invention is installed in a washroom is shown, but it can be installed in various places such as a kitchen.

[Brief description of the drawings]

FIG. 1 is a diagram showing an overview and a connection state of a hypochlorous acid water generating apparatus.

FIG. 2 is a schematic configuration diagram of a hypochlorous acid water generating apparatus.

FIG. 3 is a schematic configuration diagram of a hypochlorous acid water generating apparatus according to another embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Water supply path 2 Electrolysis tank 3 Hypochlorous acid water generation part 4 Hot water path 5 Hot water supply path 6 Mixing means 7 Control means 31 Command means 33 Temperature setting means

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 2D060 CD02 4C058 AA06 AA07 BB02 BB07 DD04 EE26 JJ07 4D061 DA03 DB10 EA03 EA04 EB04 EB14 EB17 EB19 EB37 EB38 EB39 GA02 GB11 GC02 GC16 GC18

Claims (6)

[Claims] 1. A hypochlorous acid water generation section for electrolyzing water supplied from a water supply channel to an electrolytic cell to generate hypochlorous acid water, and a hypochlorous acid water generation section. A mixed state of mixing hypochlorous acid water and hot water supplied through a hot water channel and supplying the mixed water to a hot water supply channel, and mixing the hypochlorous acid water generated in the hypochlorous acid water generating section with the hot water channel Mixing means that can be switched to a non-mixing state in which the hot water is supplied to the hot and cold water supply path without mixing, and control means that controls the operations of the hypochlorous acid water generating unit and the mixing means. The control means switches the mixing means to the mixing state, and switches the mixing means to the non-mixing state; Switch to cold water supply control state to activate acid water generation unit Hypochlorous acid water generator that is freely configured. 2. In the chilled water supply control state, when the amount of water supplied through the water supply passage is equal to or greater than a set amount of chilled water supply, the control unit executes electrolysis in the electrolytic cell. And, in the hot water supply control state, the electrolysis in the electrolytic cell is performed when the flow rate is equal to or more than the set amount of hot water supply smaller than the set amount of cold water supply. The hypochlorous acid water generator according to claim 1. 3. In the cold water supply control state, the control unit sets the amount of electricity supplied to the electrolytic cell to a set amount for cold water supply, performs electrolysis, and performs the electrolysis in the hot water supply control state. 2. The hypochlorous acid water generating apparatus according to claim 1, wherein the supply current is set to a set amount for hot water supply greater than the set amount for cold water supply, and electrolysis is performed. 3. 4. The control unit according to claim 1, wherein the hypochlorous acid concentration of the supplied hypochlorous acid water supplied through the hot water supply passage is the same or substantially the same in the cold water supply control state and the hot water supply control state. The hypochlorous acid water generating apparatus according to claim 1, wherein the apparatus is configured to control the operation of the hypochlorous acid water generating unit so as to have the same concentration. 5. A manual water supply state in which hot water hypochlorous acid water is supplied through the hot water supply path and a cold water supply state in which cold water hypochlorous acid water is supplied through the hot water supply path. Command means is provided, the control means switches to the hot water supply control state when the hot water supply state is commanded by the command means, and when the cold water supply state is commanded by the command means, Claim 1 configured to switch to a cold water supply state.
5. The apparatus for producing hypochlorous acid water according to any one of 4. 6. A temperature setting means for variably setting a target temperature of supply hypochlorous acid water supplied through the hot water supply passage, wherein the control means sets the temperature in the hot water supply control state. Based on the target temperature set by the means, it is configured to adjust the mixing ratio of the hypochlorous acid water generated in the hypochlorous acid water generation unit and the hot water supplied through the hot water channel. The apparatus for producing hypochlorous acid water according to any one of claims 1 to 5.