JP4092047B2 - Electrolyzed water generator - Google Patents

Description

【００２５】
なお、陽イオン交換樹脂の再生タイミング時点の基準値は、設定電解電流値と電解運転時間の積算量を指標とすることもできる。また、このようなイオン交換樹脂の再生については、ナトリウムイオン型の陽イオン交換樹脂を収容しＣａ²⁺、Ｍｇ²⁺等の金属イオンをナトリウムイオンに置換して軟水処理するイオン交換槽に限らず、水素型の陽イオン交換樹脂を収容し金属イオンを水素イオンに置換して水処置をするイオン交換槽にも適用される。
【図面の簡単な説明】
【図１】本発明の一例に係る電解水生成装置の全体を示す概略的構成図である。
である。
【符号の説明】
１１…電解槽、１２…食塩水貯溜槽、１３…イオン交換槽、１４…制御装置、１５…第１供給管路、１６…第２供給管路、１６ａ…軟水供給管路、１６ｂ…食塩水供給管路、１６ｃ…供給ポンプ、１６ｄ…開閉弁、１７…第３供給管路、１７ａ…原水供給管路、１７ｂ…排出管路、１７ｆ…三方切替弁。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electrolyzed water generator.
[0002]
[Prior art]
As one type of electrolyzed water generating device, as disclosed in Japanese Patent Laid-Open No. 9-225465, an electrolyzer, a salt water preparation tank for preparing saline to be electrolyzed, and a cation exchange resin are accommodated. In addition, there is an electrolyzed water generating device of a type provided with an ion exchange tank that performs ion exchange treatment of raw water for preparing the electrolyzed water. In the electrolyzed water generating apparatus, electrolyzed water is prepared using soft water generated by ion exchange treatment in an ion exchange tank or water containing almost no ionic components, and the prepared electrolyzed water is supplied to the electrolyzer. Supplying and electrolyzing the water to be electrolyzed at a set electrolysis current value to generate electrolyzed water. In order to obtain electrolyzed water having desired characteristics (pH, oxidation-reduction potential, etc.), electrolysis is performed according to the characteristics. The current value is set to a predetermined value.
[0003]
The set electrolysis current value varies depending on the amount of ionic components in the water to be electrolyzed. When the electrolysis current value varies, electrolyzed water having the set characteristics cannot be generated. The fluctuation of the amount of ionic components in the electrolyzed water is mainly caused by the amount of ionic components of metal ions such as Ca ²⁺ and Mg ²⁺ in the raw water for preparing the electrolyzed water. In order to remove this variation factor, the raw water is permeated through an ion exchange tank containing a cation exchange resin and subjected to an ion exchange treatment to generate soft water or water containing almost no ionic components.
[0004]
In this case, since the ion exchange tank for ion exchange treatment of raw water has a limit in ion exchange capacity as a matter of course, after a predetermined amount of ion exchange treatment of raw water, the ion exchange capacity of the ion exchange resin is reduced. In order to regenerate, an ion exchange regeneration process must be performed. In the regeneration treatment of this ion exchange capacity, an acidic aqueous solution such as a sodium chloride aqueous solution or a hydrochloric acid aqueous solution is used as a regenerating solution to replace substituted metal ions such as Ca ²⁺ and Mg ²⁺ with sodium ions and hydrogen ions. Adopted.
[0005]
[Problems to be solved by the invention]
Therefore, in the electrolyzed water generating apparatus of this type, it is important to regenerate the ion exchange capacity of the ion exchange resin in the ion exchange tank, and the timing for regenerating the ion exchange capacity (hereinafter referred to as the ion exchange tank). (Sometimes called playback timing). Conventionally, after setting the electrolysis current value at the time of electrolysis operation, the electrolysis operation time or the amount of electrolyzed water generated as a temporary index, the time when the electrolysis operation time reaches a set time, or the amount of electrolyzed water generated When the predetermined amount is reached, a means for regenerating the ion exchange tank is employed.
[0006]
The reference value for the regeneration timing of such an ion exchange tank is a fixed value determined by the electrolysis operation time or the amount of electrolyzed water generated, ignoring the quality of raw water for preparing electrolyzed water, and the raw water used Depending on the water quality, it cannot be said that the ion exchange capacity and life of the ion exchange tank are maximized. The object of the present invention is therefore to address such problems.
[0007]
[Means for Solving the Problems]
The present invention relates to an electrolyzed water generating device, and in particular, an electrolyzer, a salt water preparing tank for preparing saline to be electrolyzed, and a raw water for preparing the electrolyzed water containing a cation exchange resin. An ion exchange tank for ion exchange treatment is provided, and electrolyzed water prepared using raw water ion-exchanged in the ion exchange tank is supplied to the electrolyzer and the electrolyzed water is set at a set electrolysis current value. An electrolyzed water generating device of a type that generates electrolyzed water by electrolysis is an application target.
[0008]
Thus, according to a first aspect of the present invention, in the electrolyzed water generating device of the above-described type, the regeneration timing reference of the ion exchange tank is a variable value with respect to the set electrolysis current value. Is. In the present invention, the reference value for the regeneration timing of the ion exchange tank is an index of a variable value that is inversely proportional to the set electrolysis current value, and a value obtained by multiplying the set electrolysis current value by electrolysis time. It can be set as an index.
[0009]
[Operation and effect of the invention]
In the electrolyzed water generating apparatus according to the present invention, the reference value of the regeneration timing of the ion exchange tank is set to a variable value with respect to the set electrolysis current value, for example, set as an index a variable value that is inversely proportional to the set electrolysis current value. However, since the value obtained by multiplying the set electrolysis current value by the electrolysis time is set as an index, these reference values take into account the quality of the raw water used for the preparation of the electrolyzed water. The ion exchange capacity and life of the ion exchange tank can be maximized according to the water quality.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described with reference to the drawings. FIG. 1 schematically shows an example of an electrolyzed water generating apparatus according to the present invention. The electrolyzed water generating apparatus includes an electrolyzer 11, a salt water storage tank 12 for storing saline used for electrolyzed water, and raw water. Are provided with an ion exchange tank 13 containing a cation exchange resin for softening water and a control device 14. The electrolytic cell 11 and the saline storage tank 12 are connected by a first supply line 15, the saline storage tank 12 and the ion exchange tank 13 are connected by a second supply line 16, and the ion exchange tank 13 and a water source. (Not shown) is connected by a third supply line 17.
[0011]
The electrolytic cell 11 includes a pair of compartments formed by partitioning the inside of the cell body 11a with a diaphragm 11b having ion permeability, and an anode 11c is disposed in one compartment, and the anode chamber 11d is provided. The cathode 11e is formed in the other compartment and is formed in the cathode chamber 11f. The anode 11c and the cathode 11e are connected to the positive electrode and the negative electrode of the DC power supply 18.
[0012]
The first supply line 15 connecting the electrolytic cell 11 and the saline storage tank 12 includes a main line 15a and a pair of branch lines 15b and 15c branched from the main line 15a. The main pipe line 15a has an upstream end connected to the salt water storage tank 12 and opens at the bottom of the salt water storage tank 12, and one branch pipe line 15b has a downstream end at the anode chamber of the electrolytic cell 11. 11d is opened at the bottom of the anode chamber 11d, and the other branch pipe 15c is connected at its downstream end to the cathode chamber 11f of the electrolytic cell 11 and opened at the bottom of the cathode chamber 11f. Yes. In the first supply line 15, a supply pump 15d and a flow rate sensor 15e are interposed in the main line 15a, and manual flow rate adjustment valves 15f and 15g are interposed in the branch lines 15b and 15c. The flow rate sensor 15e is provided for detecting an abnormality in the flow rate, and can be implemented by being provided on the downstream side of each of the flow rate adjusting valves 15f and 15g.
[0013]
As a result, dilute saline solution having a predetermined concentration prepared in the saline solution storage tank 12 is supplied to the electrode chambers 11 d and 11 f of the electrolytic cell 11 through the first supply pipe 15, and is present in the electrolytic cell 11. Diaphragm electrolysis is performed, and acidic water containing hypochlorous acid as a main component is generated in the anode chamber 11d, and alkaline water containing sodium hydroxide as a main component is generated in the cathode chamber 11f. The generated acidic water and alkaline water flow out to the outside through the outflow pipes 11g and 11h.
[0014]
The 2nd supply line 16 which connects the salt solution storage tank 12 and the ion exchange tank 13 is comprised by the two lines of the soft water supply line 16a and the salt solution supply line 16b. Both the soft water supply pipe 16 a and the saline supply pipe 16 b are connected to the saline storage tank 12 and the ion exchange tank 13. The upstream end of the soft water supply pipe 16 a opens at the top of the ion exchange tank 13, and the downstream end opens above the saline storage surface in the saline storage tank 12. On the other hand, the downstream end of the saline supply pipe 16 b opens at the top of the ion exchange tank 13, and the upstream end opens below the saline storage surface in the saline storage tank 12. . A supply pump 16c is interposed in the saline solution supply line 16b.
[0015]
The ion exchange tank 13 has a cylindrical shape containing a sodium ion exchange type cation exchange resin, and both upper and lower ends are closed, and the soft water constituting the second supply pipe 16 is formed at the upper end as described above. The upstream end of the supply pipeline 16a is connected to the downstream end of the saline supply pipeline 16b. Further, the downstream end of the third supply pipe line 17 connected to the water source is connected to the bottom of the ion exchange tank 13. The third supply pipe 17 is composed of a raw water supply pipe 17a and a discharge pipe 17b, a supply pump 17c is interposed in the raw water supply pipe 17a, and a manual type is provided in the discharge pipe 17b. An on-off valve 17d and a flow rate sensor 17e are interposed. The flow rate sensor 17e is provided for detecting the discharge amount discharged through the discharge pipe 17b, and can be implemented without providing the flow rate sensor 17e.
[0016]
In the third supply pipe 17, a three-way switching valve 17f is interposed at a branch portion between the raw water supply pipe 17a and the discharge pipe 17b. The three-way switching valve 17f allows the supply of raw water to the ion exchange tank 13 and the function of restricting the discharge of water from the ion exchange tank 13 and the supply of raw water to the ion exchange tank 13 by switching operation. It has a function of allowing discharge of water from the ion exchange tank 13.
[0017]
The control device 14 includes a microcomputer and each drive circuit as main components, and is connected to the flow rate sensors 15e and 17e, the supply pumps 15d, 16c and 17c, the three-way switching valve 17f, and the DC power source 18, respectively. ing. The control device 14 controls the driving of the supply pumps 15d, 16c, 17c, the switching operation of the three-way switching valve 17f, and the amount of electricity applied to the electrodes 11c, 11e to perform electrolysis operation of the electrolyzed water, It functions to stop the electrolysis operation after a time or a predetermined amount of electrolysis. Further, the control device 14 controls the driving of the supply pump 16c and the switching operation of the three-way switching valve 17f after stopping the electrolysis operation, and performs the regeneration operation of the cation exchange resin accommodated in the ion exchange tank 13, It functions to stop the regeneration operation for a predetermined time or after the discharge amount of the regeneration liquid reaches a predetermined amount.
[0018]
In the electrolyzed water generating apparatus configured as described above, an electrolysis current value during electrolysis operation is set prior to electrolysis operation, and a dilute saline solution having a predetermined concentration used for electrolyzed water in the saline reservoir 12. Is prepared, and this dilute saline solution is supplied to the electrolytic cell 11, and electrolysis is performed while maintaining the set electrolysis current value. In this case, the raw water for preparing the diluted saline is supplied to the ion exchange tank 13 through the three-way switching valve 17f by the supply pump 17c, and the supplied raw water is softened in the ion exchange tank 13 and is supplied to the soft water supply line 16a. To the saline storage tank 12 and used as soft water for the preparation of dilute saline. In addition to the soft water for preparing the diluted saline solution, a predetermined amount of salt or concentrated salt water is supplied to the saline reservoir 12 by appropriate means to prepare a diluted saline solution having a predetermined concentration. The electrolytic current value is set according to desired characteristics (pH, redox potential, etc.) of the electrolyzed water to be generated.
[0019]
The prepared diluted saline solution is supplied from the saline solution storage tank 12 to the anode chamber 11d and the cathode chamber 11f of the electrolytic cell 11 through the flow control valves 15f and 15g through the branch pipes 15b and 15c by the supply pump 15d. Is done. Separation membrane electrolysis is performed in the electrolytic cell 11, acidic water is generated in the anode chamber 11d and flows out from the outflow conduit 11g, and alkaline water is generated in the cathode chamber 11f and flows out from the outflow conduit 11h. This diaphragm electrolysis is controlled by the control device 14, and after a predetermined time elapses or after the electrolytically generated water reaches a predetermined amount, the electrolysis operation is stopped and the cation exchange resin regeneration operation is performed.
[0020]
In the regeneration operation of the cation exchange resin, the three-way switching valve 17f is switched and the on-off valve 17d is opened, and the supply pump 16c in the second supply line 16 is driven to drive the saline storage tank 12. The diluted saline solution is supplied to the ion exchange tank 13 through the saline solution supply line 16b. Thereby, the sodium ion exchange type cation exchange resin accommodated in the ion exchange tank 13 is regenerated. The diluted saline used for the regeneration is discharged through the three-way switching valve 17f and the discharge pipe 17b in the third supply pipe 17 (the on-off valve 17d and the flow rate sensor 17e are interposed).
[0021]
As described above, in the electrolyzed water generating apparatus, the cation exchange resin accommodated in the ion exchange tank 13 can be regenerated when the electrolysis operation is stopped, for example, after the electrolysis operation is completed. A diluted saline solution used for the electrolyzed water in the saline solution storage tank 12 is used as a resin regeneration solution. This eliminates the need for a container for storing the salt water dedicated to the regeneration of the cation exchange resin, and the electrolyzed water generator is smaller than when a commercially available water softener equipped with the container is employed. Thus, the occupied space to be installed can be reduced, and the cost can be reduced.
[0022]
Further, in the electrolyzed water generating apparatus, since the control device 14 for controlling electrolysis can be used for both the electrolysis operation and the regeneration operation, the control device 14 is used in common to further reduce the cost. Can be achieved. Furthermore, in the electrolyzed water generating apparatus, the ion exchange tank 13 can be integrated into the apparatus by omitting the sodium chloride container for regeneration of the cation exchange resin and the control mechanism for regeneration only. The device can be formed with a clean appearance in connection with the reduction of the occupied space.
[0023]
Therefore, in the electrolyzed water generating apparatus, the reference value at the regeneration timing point of the cation exchange resin in the ion exchange tank 13 is set as shown in Table 1 below. This reference value is set by using as an index a variable value that is inversely proportional to the set electrolysis current value during electrolysis operation. This reference value takes into account the quality of raw water for preparing electrolyzed water, and can maximize the ion exchange capacity and life of the ion exchange tank according to the quality of the raw water used. .
[0024]
[Table 1]

[0025]
In addition, the reference value at the time of regeneration timing of the cation exchange resin can also use the integrated amount of the set electrolytic current value and the electrolytic operation time as an index. In addition, the regeneration of such an ion exchange resin is limited to an ion exchange tank in which a sodium ion type cation exchange resin is accommodated and metal ions such as Ca ²⁺ and Mg ²⁺ are replaced with sodium ions for soft water treatment. Furthermore, the present invention is also applied to an ion exchange tank that contains a hydrogen-type cation exchange resin and replaces metal ions with hydrogen ions to perform water treatment.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram showing an entire electrolyzed water generating apparatus according to an example of the present invention.
It is.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 11 ... Electrolysis tank, 12 ... Saline storage tank, 13 ... Ion exchange tank, 14 ... Control apparatus, 15 ... 1st supply line, 16 ... 2nd supply line, 16a ... Soft water supply line, 16b ... Saline Supply line, 16c ... Supply pump, 16d ... Open / close valve, 17 ... Third supply line, 17a ... Raw water supply line, 17b ... Discharge line, 17f ... Three-way switching valve.

Claims (3)

An electrolytic bath, a salt solution preparing bath for preparing saline to be electrolyzed, and an ion exchange bath for containing a cation exchange resin and subjecting the raw water for preparing the electrolyzed water to ion exchange treatment, the ion exchange In an electrolyzed water generating apparatus for supplying electrolyzed water prepared using raw water ion-exchanged in a tank to the electrolyzer and electrolyzing the electrolyzed water at a set electrolysis current value to generate electrolyzed water The electrolyzed water generating apparatus is characterized in that the reference at the regeneration timing of the ion exchange tank is a variable value with respect to the set electrolysis current value. 2. The electrolyzed water generating device according to claim 1, wherein a reference value at the regeneration timing point of the ion exchange tank is set by using a variable value inversely proportional to the set electrolysis current value as an index. . 2. The electrolyzed water generating device according to claim 1, wherein the reference at the time of regeneration of the ion exchange tank is set by using a value obtained by multiplying the set electrolysis current value by electrolysis time as an index. .

Images