JPH063487U - Electrolytic water conditioner - Google Patents

Abstract

(57) [Abstract] [Purpose] The present invention relates to an electrolyzing water conditioner that can always keep the pH value of electrolyzed water constant. [Structure] A flow meter is installed on the upstream or downstream side of the reaction tank, and the controller automatically controls the current value applied to the electrode of the reaction tank based on the increase or decrease of the detected value of the flow meter. The amount of additive supplied from the additive supply device to the reaction tank is controlled. Therefore, the electrolytic capacity can be increased or decreased in proportion to the flow rate to obtain electrolyzed water suitable for drinking at all times, and the supply amount of the additive can be changed to automatically control the addition amount suitable for drinking.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to an electrolyzing water conditioner that can always keep the pH value of electrolytic water constant regardless of the production amount of electrolytic water such as alkaline water in a reaction tank.

[0002]

[Prior art]

 Conventionally, ion water purifiers and the like configured to electrolyze tap water or the like to generate and separate alkaline water and acidic water have been used.

This is because tap water or the like is once purified with activated carbon or the like and then fed to a reaction tank, and applied between both electrodes by a diaphragm interposed between the cathode electrode and the anode electrode in the reaction tank. When tap water is electrolyzed by the generated voltage, it is configured to separate into alkaline water and acidic water, and the generated alkaline water and acidic water are the alkaline water outlet channel and the acidic water outlet channel, respectively. It is outsourced through and can be used according to each application.

In addition, such an electrolysis water conditioner is provided with a constant flow valve on the upstream side of the reaction tank to limit the flow rate of raw water flowing into the reaction tank or purified water purified by a purifier.

This is because in order to prevent the generation of electrolytic water having an abnormally high pH value when the flow rate of raw water or the like flowing into the reaction tank is small, a constant-current current applied to the reaction tank is used. It is necessary to keep the value below a certain level. Therefore, the processing capacity of the reaction tank can be suppressed. If an excessive flow rate of raw water, etc. flows into the reaction tank with such limited capacity, the pH value of the electrolyzed water will drop significantly.To prevent this, a constant flow valve is used. This is because it is necessary to keep the maximum allowable flow rate of raw water, etc. flowing into the reaction tank below a certain value.

[0006]

[Problems to be Solved by the Invention] However, the above-mentioned electrolytic water purifier still has the following problems to be solved.

That is, the pH value of the electrolyzed water is not significantly lowered by providing the constant flow valve, but on the other hand, the maximum allowable flow rate is limited by the constant flow valve. As described above, it was not possible to cope with the large-capacity discharge of electrolyzed water that is being demanded by general households and companies.

On the contrary, in some cases, the amount of water flowing from the faucet is less than the value set by the metering valve. At this time, the processing capacity of the reaction tank becomes excessive with respect to the flow rate, and water with too high alkalinity is generated. If taken, it may have adverse health effects.

An object of the present invention is to provide an electrolytic water rectifier capable of solving the above problems.

[0010]

[Means for Solving the Problems]

 The present invention is an electrolyzing water conditioner capable of generating alkaline water and acidic water by energizing electrodes in a reaction tank, by providing a flow meter upstream or downstream of the reaction tank and detecting with the same flow meter. The present invention relates to an electrolytic water dissipating water conditioner, which is characterized in that the value of current flowing to electrodes is controlled based on the flow rate value.

The present invention also provides a flowmeter provided upstream or downstream of the reaction tank in an electrolytic water purifier capable of generating alkaline water and acidic water by energizing electrodes in the reaction tank. The present invention relates to an electrolyzing water conditioner characterized by controlling an additive supply amount of an additive supply device for supplying an additive to a reaction tank based on a flow rate value detected by a flow meter.

[0012]

【Example】

 Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings.

FIG. 1 shows an electrolyzing water purifier A according to the present invention and a water regulating system B including a plurality of flow paths connected thereto.

(Electrolytic Water Conditioner A) First, the configuration of the electrolytic water conditioner A will be described.
It consists of a reaction tank 10, a partition 11 provided in the center thereof, an alkaline water tank 12 and an acidic water tank 13 defined by the partition 11, and electrodes 8 and 9 arranged in each of the water tanks 12 and 13. It is being touched.

Further, an alkaline water outlet 14 is formed in the upper part of the alkaline water tank 12, and a purified water inlet 15 is formed in the lower part thereof. Further, an acidic water outlet 16 is formed in the upper part of the acidic water tank 13 and a calcium water flow is formed in the lower part. Each entrance 17 is formed.

An alkaline water outlet channel E and an acidic water outlet channel H, which will be described later, are connected to the alkaline water outlet 14 and the acidic water outlet 16.

In the electrolytic water purifier A configured as described above, the electrode 8 provided on the alkaline water tank 12 side functions as a negative electrode made of stainless steel, carbon, or the like during normal water conditioning operation, The electrode 9 on the acidic water tank side is configured to function as an anode made of stainless steel, platinum, titanium oxide or the like.

The electrodes 8 and 9 are configured to apply a desired forward voltage from the power source 40 to the electrodes 8 and 9 based on a control signal from the controller R.

Then, by applying such a voltage, tap water or the like is electrolyzed, and the pH value of water in the alkaline water tank 12 is increased during normal operation, and alkaline water is generated in the alkaline water tank 12. On the other hand, the pH value of the acidic water tank 13 becomes low, and acidic water is generated in the same water tank 13.

Further, when a reverse voltage is applied to the electrodes 8 and 9, the deposits adhered to the electrodes 8 and 9 can be dissolved and removed from the electrodes 8 and 9.

(Flow Path Around Electrolytic Water Conditioner A) First, the inflow side of the electrolytic water conditioner A is connected to a tap water supply unit 1 such as a water tap through a raw water supply flow path C. It is configured to supply tap water as raw water.

That is, the raw water supply channel C from the tap water supply section 1 such as a faucet is bifurcated at a branch section S provided in the middle, and one branch channel 24 is a clean water inlet of an alkaline water tank. It is connected to 15 via the water purifier 2, and the other branch flow path 28 is connected to the calcium water inlet 17 of the acidic tank 13. Further, an additive supply device is connected to the middle of the branch channel 28 so that an additive for increasing the pH value and increasing the calcium ion concentration can be supplied.

In this embodiment, since the additive is a calcium solution, the additive supply device is composed of the calcium tank 3a and the calcium feed pump 3b.

However, various additives such as minerals, medicinal agents, etc. relating to improvement of drinking water can be considered.

The water purifier 2 attached to the branch flow path 24 includes activated carbon and a hollow fiber membrane and has a filtering function. If necessary, a heater (not shown) or the like may be provided to heat or purify the water. It is configured so that it can be sterilized by heating, and when equipped with a heater, it plays the function of regenerating activated carbon.

Further, a flow path switching device 41, which will be described later, is disposed on the upper side of the branch portion S of the raw water supply flow path C from the tap water supply section 1, and by the flow path switching operation of the valve 41, The water from the tap water supply unit 1 can be selectively supplied to the raw water supply passage C communicating with the electrolysis water conditioner A and the raw water direct extraction passage D.

Further, in the flow path switching device 41, as will be described later, there is provided a communication path 63 capable of connecting the alkaline water derivation flow path E to the alkaline water extraction flow path F so as to communicate with each other.

As will be described later, the alkaline water outlet passage E and the alkaline water outlet passage F are used as an electrode cleaning water outlet passage and an electrode cleaning water outlet passage, respectively, during electrode cleaning. It will be.

(Structure of Flow Channel Switching Device 41) In the present embodiment, the flow channel switching device 41 is, as shown in FIG. 1, formed on the upper surface of a block-shaped valve body 50 at regular intervals with a raw water inlet 51. And the alkaline water inlet 52, the raw water direct outlet 53 and the electrode cleaning water outlet 54 are provided on the lower surface, and the alkaline water outlet (also functions as an electrode cleaning water outlet) on one side surface thereof. ) Is provided.

In the valve body 50, a first communication passage 58 connected to the raw water inlet 51, a second communication passage 59 connected to the alkaline water outlet 55, and a third electrode cleaning water communication passage 60. The first communication passage 58 is selectively connected to the second communication passage 59 or the third communication passage 60 by the turning operation of the flow passage switching device shaft 61.

In FIG. 1, reference numeral 62 denotes a rotary handle for rotating the flow path switching device shaft 61.

Further, a fourth communication passage 63 is provided in the valve body 50 of the flow passage switching device 41, and the alkaline water outlet flow passage E is connected to the alkaline water extraction flow passage F through the communication passage 63. can do.

In such a configuration, during normal use (during water conditioning), the flow path switching device shaft 61 is in the state shown in FIG. 1 and is connected to the tap water supply unit 1 by operating the rotary handle 62. The upstream side of the raw water supply passage C communicates with the downstream side of the raw water supply passage C through the first communication passage 58 and the second communication passage 59, while the alkaline water derivation passage E is It communicates with the alkaline water extraction flow passage F through the 4 communication passage 63.

Similarly, during electrode cleaning, as in the case of normal use, the flow path switching device shaft 61 is in the state shown in FIG. 1, and the upstream side of the raw water supply flow path C connected to the tap water supply unit 1 is , The first communication passage 58 and the second communication passage 59 communicate with the downstream side of the raw water supply passage C, while the alkaline water discharge passage E takes out the alkaline water through the fourth communication passage 63. It communicates with the flow path F.

However, at the time of electrode cleaning, the alkaline water discharge flow path E is connected to the alkaline water discharge flow path F via the fourth communication path 63 as an electrode cleaning water discharge flow path and an electrode cleaning water discharge flow path, respectively. Will work.

On the other hand, when the flow path switching device shaft 61 is rotated by 90 ° in the clock direction in FIG. 1 by the operation of the rotary handle 62, it is connected to the upstream side of the raw water supply flow path C connected to the tap water supply unit 1. Although the communication with the downstream side of the raw water supply channel C is blocked, the upstream side of the raw water supply channel C is communicated and connected with the raw water direct extraction channel D via the third communication passage 60.

(Switch and Indicator Lamp) As shown in FIG. 1, a pressure switch S ₁ is attached to the downstream side of the branch channel 24 of the raw water supply channel C and the alkaline water outlet channel E. This pressure switch S ₁ is operated by the supply water pressure when the raw water is supplied from the raw water supply passage C to the electrolysis water purifier A through the water purifier 2, and a predetermined voltage is supplied from the power supply 40 to the electrode via the controller R. When applied to Nos. 8 and 9, alkaline water can be generated in the alkaline water tank 12 and acidic water can be generated in the acidic water tank 13.

As described above, in the present embodiment, it is not necessary to separately provide a switch for operating the electrolyzed water conditioner A, and the control is simplified.

Further, a flow meter Q, which is the gist of the present invention, is provided on the upstream side of the water purifier 2, and the flow meter Q includes the branch flow path 24 provided with the water purifier 2 and another branch flow. The total amount of purified water and raw water flowing into the reaction tank 10 through the path 28 is detected.

Then, the detection value by the flow meter Q is sent to the control device R, and the control device R controls the current value applied to the electrodes 8 and 9 of the reaction tank 10 based on the detection value, as will be described later. Then, the electrolysis performance can be increased or decreased, and the rotation speed of the drive motor of the calcium supply pump 3b can be controlled to increase or decrease the supply amount of the calcium solution to the reaction tank 10.

Further, an operation panel OP is connected to the control device R, and a power switch S ₂ and an electrode cleaning switch S ₃ are attached to the operation panel OP.

Here, the power switch S ₂ is used for supplying electric power to the electrolytic water conditioner A and various switch groups.

On the other hand, the electrode cleaning switch S ₃ is used for cleaning the electrodes by applying a predetermined voltage from the power supply 40 to the electrodes 8 and 9 via the control device R to remove the deposits on the electrodes 8 _and 9. It is something.

Further, as shown in FIG. 1, in the display unit of the controller R, a power source display lamp L ₁ showing that the power source 40 is turned on, and deposits on the electrodes 8 _and 9 are washed. The electrode-cleaning display lamp L ₂ as an electrode-cleaning display section and the electrode-cleaning display lamp L ₃ indicating that electrode cleaning is in progress are installed. It

(Structure of Control Circuit R) FIG. 2 conceptually shows the control circuit R for the water conditioning work of the water conditioning system B including the above-described electrolytic water conditioning apparatus A.

As shown, the control circuit R includes an input interface a, a microprocessing unit b, an output interface c, a memory d, and a timer e.

A power switch S ₂ , a pressure switch S ₁ , an electrode cleaning switch S ₃ and a flowmeter Q are connected to the input interface a, and a power source 40 and a power supply 40 are connected to the output interface c. calcium supply pump 3b, a power indicator lamp L _1, the main electrodes wash display lamp L _2, and the electrode cleaning indicator lamp L ₃ is connected.

Further, in the present invention, the control circuit R is provided with the timer e, and the timer e causes the control circuit R to perform the following operation control.

First, based on a control signal from the control circuit R, the cumulative time of electrolyzed water conditioning performed by applying a forward voltage from the power source 40 to the electrodes 8 and 9 exceeds a set time (for example, 40 minutes). Then, the electrode cleaning indicator lamp L ₂ is turned on to inform the user that the electrodes 8 _and 9 need cleaning.

When the user presses the electrode cleaning switch S ₃ when the electrode cleaning indicator lamp L ₂ is lit, the reverse voltage from the power supply 40 is applied to the electrodes 8, 9 based on the control signal from the control circuit R. After a preset electrode cleaning time (for example, 2 minutes) has passed, the forward voltage is again applied to the electrodes 8 and 9 from the power source 40, and the normal operation of electrolytic water preparation is restarted.

Immediately after the normal operation is resumed, the cleaning waste water and the electrolytically prepared water are mixed, so in order to prevent accidental ingestion of the mixed water, immediately after the restart, for example, for 10 seconds, the electrode cleaning indicator lamp It is desirable to make some efforts such as keeping displaying L ₃ .

(Other Configuration) Explaining the other configuration in FIG. 1, reference numeral 42 is a safety valve provided in the middle of the raw water supply channel C, and is composed of, for example, a switching valve using a shape memory alloy, and a tap water supply unit. When the water from 1 is hot water from a water heater, etc., if hot water of a certain temperature or higher is supplied, the function of the shape memory alloy prevents the water from flowing in the direction of the electrolytic water purifier A. It can be discharged to the outside through a hot water discharge passage (not shown).

(Operation of Electrolytic Water Conditioner A) Next, a method of using the electrolytic water conditioner A having the above configuration will be described with reference to the graphs shown in FIGS. 1 and 3.

First, during normal use, the water conditioning system B is in the state shown in FIG. 1, and the upstream side of the raw water supply channel C has the first communication passage 58 and the second communication passage 59 in the flow passage switching device 41. Through which the alkaline water outlet channel E communicates with the downstream side of the raw water supply channel C, while the alkaline water outlet channel E communicates with the alkaline water outlet channel F through the fourth communication channel 63 in the channel switching device 41.

After turning on the power switch S ₂ , when the tap water supply unit 1 such as a faucet is opened, the raw water is supplied from the tap water supply unit 1 through the raw water supply channel C to the inflow side of the electrolytic water conditioner A. It will be.

The pressure switch S ₁ is actuated by this supplied water pressure, a predetermined forward voltage is applied to the electrodes 8 and 9 from the power source 40 via the control device R, and at the same time, the feed pump 3b is actuated to remove calcium. The alkaline water is supplied to the acidic water tank 13 and electrolyzed to generate alkaline water in the alkaline water tank 12 and acidic water in the acidic water tank 13.

The generated alkaline water can flow out to the outside through the alkaline water outlet channel E → the third connecting channel 60 in the channel switching device 41 → the alkaline water outlet channel F, and is used as drinking water. be able to.

On the other hand, the acidic water produced in the electrolytic water purifier A can flow out to the outside through the acidic water outlet flow passage H, and attention is paid to its astringent effect as washing water for hand washing. Can be used as

Next, when the cumulative electrolytic water conditioning time calculated by the timer e in the control circuit R exceeds the set time (for example, 40 minutes), the electrode cleaning indicator lamp L ₂ is turned on and the electrodes 8 _, 9 Notify the user that the cleaning of is required.

When the user presses the electrode cleaning switch S ₃ when the electrode cleaning indicator lamp L ₂ is lit, a reverse voltage is generated from the power source 40 based on the control signal from the control circuit R. It is possible to dissolve and remove the deposits applied to the electrodes 8 and 9 and applied to the electrodes.

The post-cleansing acidic water containing the dissolved and removed deposits flows out to the outside through the alkaline water outlet channel E → the third connecting channel 60 in the channel switching device 41 → the alkaline water extracting channel F. In addition, the alkaline water can be discharged to the outside through the acidic water outlet flow path H after cleaning.

While the electrolytic cleaning operation is continuing, the electrode cleaning in-progress display lamp L ₃ is turned on to inform the user of the fact.

The electrode-cleaning display lamp L ₂ and the electrode-cleaning display lamp L ₃ described above are examples of the display means, and display means or warning means other than the lamp, such as a buzzer, may be used. .

By the way, in the course of the above-mentioned electrolytic water conditioning, there are cases where a large amount of raw water or purified water must be supplied to the reaction tank 10 of the electrolytic water purifier A depending on the required load on the outlet side. If the electrolysis capacity of 10 is constant, the pH value of alkaline water will be significantly reduced.

However, in this embodiment, the flow meter Q is installed on the upstream side of the reaction tank 10, and the controller energizes the electrodes 8 and 9 of the reaction tank 10 based on the increase and decrease of the detected value of the flow meter Q. The current value is controlled to increase or decrease the electrolytic performance. Therefore, as shown in FIG. 3, even when a large amount of raw water or the like is supplied to the reaction tank 10 of the electrolytic water purifier A, the electrolytic performance of the reaction tank 10 can be proportionally increased. The pH value of alkaline water can be maintained at an appropriate value. On the other hand, when the flow rate of raw water or the like flowing into the reaction tank 10 is small, the pH value of the alkaline water can be maintained at an appropriate value by reducing the electrolytic performance of the reaction tank 10.

Note that, instead of the flow meter Q, means for detecting an increase / decrease in pressure by the pressure detecting means and detecting the flow rate from the pressure can also be applied. Therefore, by disposing the pressure detecting means at the position of the pressure switch S ₁ shown in FIG. 1, the function as a pressure switch and the function as a flowmeter can be combined into one member.

As described above, in this embodiment, the pH value of the alkaline water can be constantly maintained at an appropriate value regardless of the increase or decrease in the amount of raw water or purified water supplied to the reaction tank 10, and the electrolysis can be performed. The usability of the water conditioner A can be significantly improved.

Further, based on the increase / decrease in the detected value of the flow meter Q, the rotation speed of the driving motor of the calcium supply pump 3b is increased / decreased to change the supply amount of the calcium solution from the calcium solution tank 3a to the reaction tank 10. By proportionally increasing / decreasing, the pH value of alkaline water can always be maintained at an appropriate value regardless of the increase / decrease in the amount of raw water or purified water supplied to the reaction tank 10. The usability of A can be significantly improved.

Furthermore, if the additive is a substance other than the above-mentioned calcium that contributes to the improvement of the pH value, for example, magnesium, potassium, sodium, etc., the increase in the electrolytic current value and the increase in the addition amount are linked, and the efficiency is high. The electrolytic performance will be improved and it will be possible to sufficiently cope with the increase in water flow.

Although the flowmeter Q is provided on the upstream side of the water purifier 2 in the above-described embodiment, it may be provided on the downstream side of the water purifier 2 or the downstream side of the reaction tank 10.

Further, in the above-described embodiment, the configuration without the constant flow valve is described, but a constant flow valve for limiting an excessive flow rate is provided on the upstream side of the flow meter Q shown in FIG. Embodiments are also conceivable, and in this case as well, there is an effect of preventing the generation of excess alkaline water when the flow rate is smaller than the flow rate set by the constant flow valve.

[0072]

[Effect of device]

 According to the present invention, a flow meter is installed on the upstream side or the downstream side of the reaction tank, and the controller automatically controls the current value to be applied to the electrode of the reaction tank based on the increase or decrease of the detection value of the flow meter. Control, and the amount of additive supplied from the additive supply device to the reaction tank is controlled. Therefore, the electrolytic capacity can be increased or decreased in proportion to the flow rate to obtain electrolyzed water suitable for drinking at all times, and the supply amount of the additive can be changed to automatically control the addition amount suitable for drinking. .

[Brief description of drawings]

FIG. 1 is a conceptual overall configuration diagram of a water regulation system including an electrolytic water regulator according to the present invention.

FIG. 2 is a block diagram of a control circuit.

FIG. 3 is a graph showing the relationship between the amount of feed water such as raw water and the pH of alkaline water produced by an electrolyzer.

[Explanation of symbols]

 A Electrolytic water conditioner B Water conditioning system C Raw water supply channel D Raw water direct discharge channel E Alkaline water outlet channel F Alkaline outlet channel H Acidic water outlet channel Q Flowmeter 8 Anode electrode 9 Cathode electrode 12 Alkaline water tank 13 Acidic water tank 40 Power supply 41 Flow path switching device

Claims (2)

[Scope of utility model registration request] 1. An electrolyzed water purifier (A) capable of generating alkaline water and acidic water by energizing electrodes (8) (9) in a reaction tank (10), the upstream of the reaction tank (10). Side or downstream side is equipped with a flow meter (Q), and based on the flow rate value detected by the flow meter (Q), the value of current flowing to the electrodes (8) and (9) is controlled. Water conditioner. 2. An electrolyzing water conditioner (A) capable of generating alkaline water and acidic water by energizing electrodes (8) (9) in a reaction tank (10), the upstream of the reaction tank (10). A flow meter (Q) is installed on the downstream side or the downstream side, and the additive supply amount of the additive supply device that supplies the additive to the reaction tank (10) is controlled based on the flow rate value detected by the flow meter (Q). An electrolytic water purifier characterized by: