KR20030071018A - Apparatus for producting a multi function electrolytic water and method thereof - Google Patents

Abstract

TECHNICAL FIELD This invention relates to the improvement of the multifunctional electrolytic water production | generation system which electrolyzes using tap water as raw water, and discharges alkaline ionized water and strong acidic water as desired. More specifically, the present invention relates to a mechanism for obtaining jet water having a stable characteristic when adding electrolyte to raw water and jetting strong acidic water as desired.

Description

Apparatus for producting a multi function electrolytic water and method

Industrial use field

TECHNICAL FIELD This invention relates to the improvement of the multifunctional electrolytic water production | generation system which electrolyzes using tap water as raw water, and discharges alkaline ionized water and strong acidic water as desired. More specifically, the present invention relates to a mechanism for obtaining jet water having a stable characteristic when adding electrolyte to raw water and jetting strong acidic water as desired.

Conventional technology

In order to remove components unsuitable for the beverage contained in the raw water, a water purifier is installed before the inflow of the electrolytic cell, and the raw water such as tap water is supplied to the water purifier to be filtered and purified, and at the same time, the mineral component flows to the positive electrode chamber of the filtered raw water. As an example, there is an electrolytic water generating device configured to add an alkaline earth metal salt and then flow into an electrolytic cell. The electrolytic cell used for this is separated into a cathode chamber and an anode chamber by ion permeable diaphragm, the negative electrode and the positive electrode are provided in each room, and the energization of the direct current which applied the raw water supplied in the negative electrode chamber between electrodes. By electrolysis. As a result of the electrolysis of raw water, the high pH cathodic water is discharged from the cathode chamber and the low pH anode water is discharged from the anode chamber.

The catholyte generated in this way is supplemented with minerals that are likely to be lacking in the human body, and an appropriate degree of alkalinity is effective for preventing acidification of the human body. Mainly used as a drink. On the other hand, the positive water discharged at the same time is used as an austerene water and the like.

Apart from the above alkaline ionized water, a small amount of chlorine and chlorine ions themselves contained in tap water are actively used, or halogen compounds such as NaCl and KCl are added to the raw water before the electrolytic cell supply at a predetermined ratio, thereby providing an electrolytic cell. When electrolysis is carried out at, a low pH positive water containing hypochlorous acid or the like is obtained from the anode chamber. That is, since the pH of 2.7 or less and the ORP of 1100 mV or more have a strong disinfection and sterilization effect, it is commercially available as a dedicated electrolytic water generating device for generating strong acidic water in the name of strong acidic water as a disinfecting or sterilizing washing water.

The electrolyzed water generating device that generates alkaline ionized water is mainly for homes and restaurants because of its use, whereas the electrolyzed water generating device that generates strong acidic water has been mainly used for medical institutions such as hospitals because of its use. Has been commercially available as dedicated devices. However, since the sterilization effect and the stability of strong acidic water are recognized, there is a strong desire to use an electrolytic water generating device for generating strong acidic water for disinfection and sterilization in homes and the like. The use of strong acidic water in the home does not require as much as a medical institution. For this reason, the multifunctional electrolytic water production | generation apparatus which has water jet of alkaline ionized water and an appropriate amount of strong acidic water as desired is developed.

The apparatus for jetting alkaline ionized water and the apparatus for jetting strong acidic water have almost the same configuration as the electrolytic cell itself, so that both functions can be obtained by changing the dissolved components of the raw water supplied to the electrolytic cell. In other words, by making the electrolyzer the same and appropriately changing the pipe path, the chemical liquid to be added, the voltage applied to the electrolyzer, etc., the device mainly generates alkali ion water, and sometimes the device mainly produces strong acidic water. It is possible to use a multifunctional electrolytic water generating device that can be used.

A multifunctional electrolytic water generating device for producing treated water having different uses, that is, alkaline ionized water and strong acidic water, using the same apparatus. In the Japanese Patent Application Laid-open No. Hei 10-327556, the applicant adds a first addition passage through which calcium is added. Inserting the cylinders interchangeably at the same place, supplying the first electrolytic source when the first additive cylinder was inserted, supplying the second electrolyte when the second additive cylinder was inserted, and downward from the top of the electrolytic cell. A switch means is provided in the vicinity of the installed addition cylinder, the difference between the first and second addition cylinders is identified by the switch means, and at the same time the discharge dissolution amount of the electrolyte is changed to a specific value in the structure of each addition cylinder itself, When the first and second addition cylinders are replaced, the voltage polarity applied to the negative anode is reversed, and the alkaline ionized water for beverages and the strong acidity for sterilization are discharged from the same discharge tube. To the device proposed for the ejection.

6 shows the device. Two types of addition cylinder, the 1st addition cylinder 8-1, and the 1st addition cylinder 8-2 have a structure which is mutually compatible and is removable. That is, by changing the addition vessel filled with alkaline earth metal salt and the strong electrolyte, for example, the addition vessel filled with salt, the alkaline ionized water and sometimes the strong acidic water are jetted respectively. FIG. 6A is a view for explaining the case of jetting alkaline ionized water, and FIG. 6B is a view for explaining the case of discharging strong acidic water.

In FIG. 6A, raw water flows into the pipe 4 and the electrolytic cell that flows through the water purifier 2, is purified, flows out through the pipe 3, and reaches the first addition cylinder 8-1 filled with alkaline earth metal salts. Branched to a pipe (5). The purified water that has passed through the pipe 4 passes through the first addition cylinder 8-1 and joins the purified water flowing through the pipe 5 in the lower tube portion 11a via the pipe 7. The purified water which flowed through the piping 5 was the cathode chamber 15 and the anode 16 which provided the cathode 14 which isolate | separated with the ion permeable diaphragm 13 from the lower part piping part 11a, 11b of the electrolytic cell 12. Is electrolyzed in the anode chamber 17 provided with water, and the cathode water and the anode water are jetted out from the water jet holes 18 and 19 of each of the polar chambers. In FIG. 6B, the purified water flowing through the pipe 4 branched from the water discharge pipe 3 passes through the second addition cylinder 8-2, and then joins the purified water flowing through the pipe 5 via the pipe 6. . In addition, 29 is a flow rate sensor which measures the quantity of the purified water which flows into an electrolytic cell, and can measure the flow volume of a negative electrode room volume ratio from the negative electrode room flow volume ratio by measuring the flow volume of one polar chamber side.

As shown in FIG. 7, the 1st addition cylinder 8-1 and the 2nd addition cylinder 8-2 are the cylindrical storage containers which formed substantially the same shape, and the piping 4, the piping 6, It has an end portion of the pipe 7 and the target pipe parts 25, 26, 27 to be inserted, and moves through the packing 28 by moving in the drawing transverse direction with respect to the pipe 4, the pipe 6, and the pipe 7. Removable free inserts. In the addition cylinder 8-1, the hole of the tube portion 26a is closed, and the purified water flowing from the pipe 4 flows from the tube portion 25 to the tube portion 27. Therefore, when the gap 30 is opened to fill the chemicals containing calcium in the addition container, the chemicals are dissolved in purified water and discharged from the purified water inlet 27a containing the chemicals. Similarly, in the addition cylinder 8-2, the hole of the tube part 27b is closed and the purified water which flows in from the piping 4 flows from the tube part 25 to the tube part 26b. Therefore, when the salt is inserted into the addition barrel 8-2, the salt dissolves in purified water to become saline solution and is discharged from the tube portion 26b.

When one of the first addition cylinder 8-1 and the second addition cylinder 8-2 is used to add the required amount and the chemical liquid to the predetermined electrolytic chamber from the addition cylinder 8, the chemical liquid is The flow path and amount flowing selectively change. As shown by the solid line of FIG. 6A, when the 1st addition cylinder 8-1 is inserted, a part of the purified water which exited the piping 3 from the water purifier 2 passes through the piping 4, and the addition cylinder 8- After dissolving a calcium agent in 1), it is electrolyzed with the purified water which flows through the piping 7 to the anode chamber of an electrolytic cell. In this case, since the piping 6 shown by the broken line is closed, it is not related to operation | movement substantially. On the other hand, when the 2nd addition cylinder 8-2 is inserted, as shown by the solid line of FIG. 6B, a part of the purified water which exited the piping 3 from the water purifier 2 removes salt from the addition cylinder 8-2. After melt | dissolution, it returns to the piping 5 via the piping 6, is branched from the piping parts 11a and 11b to the positive and negative anode chamber of an electrolytic cell, and is electrolyzed. In this case, as shown by the broken line of FIG. 6B, since the piping 7 is closed, it is not concerned with operation | movement substantially. In addition, when switching from the first addition cylinder 8-1 to the second addition cylinder 8-2, the switch means 9 operates to give a signal of adding an electrolyte such as NaCl and to the electrode. By reversing the polarity of the applied voltage, the alkaline ionized water for drink and the strong acidic water for sterilization can be jetted from the same discharge tube as described above.

However, in the above apparatus, since the supply amount of the raw water is supplied through the same flow path in the case of alkaline ionized water or in the case of strong acidic water, the concentration of the electrolyte dissolved in the purified water in accordance with the amount of electrolyte in the addition cylinder that decreases with the passage of the electrolysis time. Fluctuates. In particular, when an electrolyte such as NaCl is inserted into the second addition vessel, when sufficient electrolyte remains in the addition passage, the supply water to the electrolytic cell shows high electrical conductivity, whereas when the remaining amount of electrolyte in the addition passage is small, Since the concentration of the electrolyte is low, its electrical conductivity is lowered. If the voltage applied to the electrolytic cell is the same, the degree of electrolysis cannot be raised to a predetermined level, and if the predetermined degree of electrolysis corresponding to a suitable concentration as sterilizing water, for example, water of ORP 1100 or more is not discharged to a pH of 2.7 or less As a result, the user may not be able to use acidic water effective for sterilization or the like. In particular, when the device is used in a home or the like, when the second addition container is loaded, the anolyte water jetted with water can be used in strong acidic water and a desired container and washed by hand without checking the pH and ORP. Indeed, the ratio of strong acidic water discharged at high electrolyticity and strong acidic water discharged at low electrolytic conductivity is mixed with each other, and the strong acidic water in the container does not reach a predetermined value. Occurs. In addition, since a mechanism corresponding to fluctuations in the supply amount of raw water due to fluctuations in the water pressure is not provided, there is a problem that the load of the electrolyzer varies with respect to the increase and decrease of the water pressure, and it is difficult to obtain a stable strong acidic water.

Therefore, the present inventors provide a mechanism for changing the supply amount of raw water to alkaline ionized water and strong acidic water, and an inlet control member to the raw water inlet of the electrolytic cell, and to control the inlet control material to jet the strong acidic water. In this case, in accordance with the amount of electrolyte in the addition vessel filled with the electrolyte, by applying an optimal electrolytic voltage to the electrode to flow a current for obtaining a strong acidic water of the desired water quality, to provide an economical multi-functional electrolytic water generating device that discharges a stable strong acidic water I'm trying to.

Means to solve the problem

The multifunctional electrolyzed water generating device according to claim 1 of the present invention is a multifunctional electrolyzed water generating device that discharges alkaline ionized water and strong acidic water as desired. It characterized in that the inlet is provided with a control means for controlling the water supply of the raw water in conjunction with the strong acid water jetting.

A method of producing multi-functional electrolytic water, characterized in that the operation of the control means is performed for a period of time or intermittently for increasing the solubility of the electrolyte.

The multifunctional electrolytic water generating device according to claim 3 of the present invention is characterized in that the applied voltage of the electrolytic voltage is controlled to a predetermined value in accordance with the operation of the control means and the addition amount of the electrolyte.

A multifunctional electrolytic water generating device, characterized in that the applied voltage of the electrolytic voltage is controlled to a predetermined value in accordance with the operation of the control means and the addition amount of the electrolyte.

1 is a block diagram of a multifunctional generating device of the present invention.

Fig. 2 is a diagram showing an example of a time chart in the case of opening and closing the solenoid valve of the water supply control member for dissolving the electrolyte of the addition cylinder in accordance with the component of the strongly acidic water of the present invention.

3 is a diagram illustrating a configuration of a flow path distributor equipped with an acquisition control member according to the present invention.

4 is a view showing an operation flow of strong acidic water generation of the multifunctional electrolytic water generator according to the present invention;

Fig. 5 is a diagram showing the relationship between the electrolysis time at the time of generating strong electrolytic water based on the operational flow of generating strong acidic water according to the present invention and the change of electrolytic current based on the shift-up of the applied voltage of the electrolytic cell.

6 shows a conventional multifunctional electrolytic water device.

The figure which shows the addition cylinder of the multifunctional electrolytic water apparatus.

* Description of the symbols for the main parts of the drawings *

8-1: First Addition Cylinder 8-2: Second Addition Cylinder

9: switch means 10: control means

12: electrolyzer 21: acquisition control member

23: constant flow valve 24: solenoid valve

Example

1 is a configuration diagram of a multifunctional generating device of the present invention, in contrast to FIG. The same reference numerals are given to the same members as in FIG. 6, and redundant descriptions are omitted.

An acquisition control unit 21 is provided as a control means for controlling the amount of water in response to the kind of electrolyzed water to be jetted into the flow path from the water supply section 20 for tap water to the water purifier 2 and the fluctuation of raw water pressure. It is. The water acquisition control member 21 is comprised with the solenoid valve 245 which opens and closes according to the kind of addition tank, ie, the kind of electrolytic water, and the rectification amount valve 23 which controls the flow volume at the time of jetting strong acidic water. In the figure, the solenoid valve is opened and closed by the movement of the flanger 22-1 and the flanger 22-2, which move as indicated by the arrow by the signal on / off from the control means 10, for ease of understanding. Although it is shown by itself, other things can be used as long as it is a solenoid valve which imposes the same function. The solenoid valve 24 is controlled by the control means 10 acting on the signal of the switch means 9, and when the first addition cylinder 8-1 is inserted, the solenoid valve 24 releases the operation from the fitting portion 20. All the flow paths leading to the water purifier 2 are opened. Moreover, when the 2nd addition cylinder 8-2 is inserted, the flow path which concerns on a solenoid valve is closed and raw water reaches the water purifier 2 through the rectification valve 23.

Even if the second addition cylinder 8-2 is filled with an electrolyte showing high electrical conductivity by slight dissolution in water such as NaCl, the amount of inflow water into the electrolytic cell is reduced, so that the current load of the electrolytic cell is reduced. The strong electric water can be jetted for a predetermined time as a current value equivalent to the current load in alkaline ionized water jetting. For example, in the case of household use, a bucket full amount, for example, about 31, is used as strong seawater. However, in a normal water pressure state, the rectifier valve 23 is used to discharge water for 3 minutes, for example. The desired purpose can be achieved by setting the amount of outflow.

In addition, even when the generating device is used for the purpose of generating strong electric water, when the electrolyte is rapidly dissolved, the amount of water flowing through the addition cylinder by intermittently flowing an on / off signal from the control means 10 to the water supply control member 21. By time-series increase and decrease, the electrolyte can be dissolved by the impact of the inlet pressure to increase the solubility of the electrolyte in the purified water, and the electrical conductivity of the raw water can be temporarily increased.

FIG. 2 is a diagram showing an example of a time chart in the case of opening and closing the solenoid valve 24 of the water supply control member 21 for dissolving the electrolyte in the addition cylinder in accordance with the component of the strongly acidic water. In the drawing, 10 seconds is set as an initial value in accordance with the time when the raw water in the tube 20 reaches the addition cylinder, and then the interruption every three seconds is repeated, and the electrolytic degree in the addition cylinder is shocked. 24). The impact can dissolve a predetermined amount of electrolyte in purified water even when the water pressure of the raw water is small or the electrolyte shows a lump state and is difficult to dissolve. In the figure, an interval of 10 seconds is set as an initial value and 3 seconds is set as an impact time. However, the number of repetitions and time can be selected according to the structure of the apparatus or the like.

The rectifier valve 23 controls the amount of raw water flowing from the tube 20 to the water purifier 2 in conjunction with the increase in the water pressure. As the rectifier valve 23, a known one can be used. For example, the rectifier valve disclosed in Japanese Unexamined Patent Application, First Publication No. Hei 3-123595 can be suitably used to flow water of about 1.5 l / min irrespective of fluctuations in water pressure.

3 is a view showing the configuration of a flow path distributor provided with a water flow control member according to the present invention, Figure 3a shows the appearance and the flow path, Figure 3b is a view of the water flow control member installed in the inlet of the flow path distributor 3 shows a cross section of the flow distributor. The flow path distributor is a member for controlling the water supply and drainage of the apparatus, and the installed tube portion is connected to the water purifier, the addition cylinder, the inlet and the outlet of the electrolytic cell, respectively.

Flow path distributor (1) has a first conduit a third conduit (d of (d ₁₎ and, in communication with the second duct (d ₂₎ and, once the intersection of the second duct (d ₂₎ in communication across the one end ₃ ) There are three main pipelines.

The first pipe line d ₁ has a pipe part 20 for connecting tap water at one end thereof, and is provided with a water supply control member 21. The connecting tube portion 20 is divided into a flow passage 41 leading to the constant flow rate valve 23 and a flow passage 42 leading to the solenoid valve 24. The raw water passing through the flow path 41 passes through the rectifier valve 23 through the one flow path 42 flowing from the fine hole 43 to the first conduit d ₁ , and the diaphragm constituting the solenoid valve 24 ( 44) and flows through the first pipe (d ₁₎ through the valve formed by the annular gap between the projection-like portion (45).

In addition, the second conduit is (d ₂₎ and Province 31 is connected to the inlet of the water purifier (2) near the intersecting portions are provided. In the second conduit d ₂ , a pipe part 32 connected to the outlet of the water purifier is provided at a portion that intersects with the third conduit d ₃ , and an inlet 25 of the addition cylinder 8 is provided near the second conduit d ₂ . In the front part, a rectifying part control part 34 functioning in the case of the generation of alkaline ionized water is provided, and in front of it, a cathode chamber side nozzle part 11b of the electrolytic cell and an anode are provided. The fitting part 35 connected to the actual measuring part 11a is provided. At one end of the third pipe line d ₃ , a pressure switch means 36 which is operated by the water pressure and the water flow change of the pipe line is provided, and the electrolytic cell can be started, stopped, and the polarity switching operation can be performed.

In addition, a check valve portion made of a ball 37 and a valve port 38 is provided at a portion opposite to the pressure switch means 36 in the third pipe line d ₃ , and a drain pipe portion 39 is provided in front of the third pipe line d ₃ . have. 40 is a ball restraining member of the check valve part, and the ball 37 closes the valve opening 38 when a predetermined or more water pressure is applied to the right side of the illustrated ball 37. 41 is a drain inlet. The outlet of the addition cylinder is connected to join the water flowing into the electrolytic cell 12.

4 is a diagram illustrating a flow of a strong acidic water generating operation of the multifunctional electrolytic water generator. The main part of the operation shown in the figure is performed via the control means 10.

In the figure, the solenoid valve 24 is opened 101 at the same time the power switch of the device (not shown) is turned on 100. Subsequently, the addition cylinder 8-2 is inserted 102, but prior to insertion, a stop valve (not shown) to prevent leakage from the pipe 4 to the pipe portion 25 and the like of the additional cylinder 8-2. As a result, the stop 103 is performed. In addition, the stationary water may be performed with an officer other than the apparatus prior to the on 100 of the power switch of the apparatus. As a result, the switch means 9 is turned on 104 and the solenoid valve 24 is closed 105. In this state, when the sand dunes etc. are opened, the water passing through the flow path 41 is started 106, and the flow rate sensor 29 and the pressure reduction switch means 36 are turned on (107, 108). At the same time, electrolysis is started 109 with the voltage applied to the electrolytic cell 12 as 10V. For 10 seconds from the start of electrolysis, the solenoid valve is closed 110 regardless of the flow rate, and after 10 seconds, the opening and closing operation is repeated until the electrolytic current reaches the first predetermined value or more at intervals of 3 seconds (111). )do. When the solenoid valve is closed, when the water pressure is low and the amount of water flowing through the water inlet control member is less than the predetermined value, the solenoid valve is opened 112 until the jet of strong electric water is completed. In addition, when the amount of water flowing through the water inlet control member is equal to or larger than a predetermined value, the solenoid valve is closed 113 until the jet of strong electric water is completed. In this state, when the electrolytic current is lower than or equal to the second predetermined value, the electrolytic applied voltage is shifted up to 15V, and when the electrolytic current is lower than or equal to the third predetermined value, the electrolytic applied voltage is shifted up to 20V. Then, if it has been for 3 minutes from the start of electrolysis 109, electrolysis is automatically stopped 116.

5 is a diagram showing a relationship between a change in electrolytic current based on a shift time of an applied voltage of an electrolytic cell and electrolysis time at the time of generating strong electrolytic water based on a strong acidic water generating operation flow.

There is an operation of a control means for narrowing the amount of raw water at the time of generating strong seawater, and even if the quantity of purified water supplied to the electrolyzer is reduced, and the control means is opened or closed in response to the water pressure of the raw water supplied, The concentration of the solution containing the electrolyte flowing out from 8-2) changes gradually. That is, after a predetermined time, for example, 10 seconds, in which the purified water flows from the control means to the addition vessel 8-2, dissolution of the electrolyte sufficiently filled in the addition vessel 8-2 starts, and the feed water supplied to the electrolytic cell The electrical conductivity of is raised, reaches a first predetermined value, and a current in the city P flows between the negative and negative electrodes of the electrolytic cell. The current rapidly increases with dissolution of the electrolyte and reaches the figure Q, and then gradually decreases with time in accordance with the consumption of the electrolyte in the addition cylinder 8-2. After reaching the city R, if the drop falls along the imaginary line a, the positive water discharged at that time is no longer effective for disinfection. Therefore, the voltage applied between the negative and positive electrodes is increased when the water discharge becomes less than the second predetermined value immediately before the jet of water, which disinfects. As a result, the amount of electrolyte in the remaining addition cylinder 8-2 decreases, and even though the electrical conductivity of the feed water supplied to the electrolytic cell is smaller than that between QR, the current of city S flows between the negative and positive electrodes of the electrolytic cell, Anodized water is jetted to have a bactericidal effect. Thereafter, the electrolytic current decreases so as to follow the imaginary line b, but in the same manner as above, the applied voltage between the negative and positive electrodes of the electrolytic cell is increased to be equal to or greater than the third predetermined value in accordance with the decrease in the addition cylinder 8-2, Anodic water with bactericidal effect should be kept in water. In addition, you may repeat voltage rise similarly to the current value of illustration T. In this way, the positive electrode water having a sterilizing effect for a predetermined time is jetted by increasing the voltage applied to the electrode in correspondence with the remaining amount of the electrolyte in the addition cylinder 8-2 for a predetermined period.

The operation time, the applied voltage, and the current value shown in the above operation flow can be performed by appropriately storing in the control means based on the experimental result of the mounting apparatus.

According to the present invention, strong electrolyzed water can be generated by adding electrolyte from the addition cylinder of the multifunctional electrolytic water generating device, and a control means for controlling the supply of raw water is provided at the flow path distributor inlet, and the supply amount of the raw water compared with the case of alkaline ionized water. By controlling this, it is possible to prevent an increase in the load of the electrolytic power supply through which the desired electrolyte flows through the electrolytic cell. In addition, by appropriately changing the voltage applied to the electrolytic cell in accordance with the variation of the supply amount of electrolyte to the raw water due to the remaining amount of electrolyte in the electrolytic cell, the sterilizing water jet can be reliably maintained in a predetermined jetting period without having to constantly monitor the characteristics of the jetting water. You can get it. As a result, the irrationality of using jetting water having poor bactericidal properties does not occur.

It may be easy to obtain a strong acidic water of stable water quality by reducing the fluctuation of the electrolyzer load against slight fluctuations in the supply amount of raw water due to fluctuations in the water pressure.

Claims (3)

A multifunctional electrolyzed water generating device that jets alkaline ionized water and strong acidic water as desired, wherein the electrolyte is added from a detachable electrolyte addition tank to raw water and then supplied to a diaphragm type electrolyzer. The raw water inlet is provided with a control means for controlling the feed water of the raw water in conjunction with the strong acidic water jetting water, multi-functional electrolytic water generating device. The method of claim 1, A method of producing multi-functional electrolytic water, characterized in that the operation of the control means is performed for a period of time or intermittently for increasing the solubility of the electrolyte. The method of claim 1, The applied voltage of the electrolytic voltage is controlled to a predetermined value in accordance with the operation of the control means and the addition amount of the electrolyte.