JP6105005B2 - Electric deionized water production apparatus and deionized water production method - Google Patents

Description

  The present invention relates to an electric deionized water production apparatus.

As a deionized water production apparatus, a production apparatus that performs deionization by passing water to be treated through an ion exchanger is known. In this apparatus, when the ion exchange group of the ion exchanger is saturated and the desalting performance is deteriorated, it is necessary to regenerate with a chemical such as acid or alkali. That is, the anion and cation adsorbed on ion exchange groups, acid or alkali from the H ^+, OH ^- and replacing processing is required. In recent years, in order to eliminate such disadvantages in operation, an electric deionized water production apparatus (hereinafter referred to as deionized water production apparatus) that does not require regeneration by a drug has been put into practical use.

  The deionized water production apparatus is an apparatus that combines electrophoresis and electrodialysis. The deionized water production apparatus is, for example, a demineralization chamber that is located between an anion exchange membrane and a cation exchange membrane and is filled with an ion exchanger, a concentration chamber that is located outside the anion exchange membrane and the cation exchange membrane, and Furthermore, it has an electrode chamber (anode chamber and cathode chamber) located outside thereof.

In order to produce deionized water by the deionized water production apparatus, water to be treated is passed through the demineralization chamber with a DC voltage applied between the anode and the cathode. The ion component in the water to be treated is adsorbed by the ion exchanger in the demineralization chamber and deionized (desalted). In the desalting chamber, water is also decomposed at the interface between the anion exchanger and the cation exchanger in the desalting chamber by an applied voltage, and hydrogen ions and hydroxide ions are generated (2H ₂ O → 2H ⁺ + 2OH ⁻ ). The ion component adsorbed on the ion exchanger is exchanged with the hydrogen ions and hydroxide ions to be released from the ion exchanger. The released ion component is electrophoresed to the ion exchange membrane, electrodialyzed on the ion exchange membrane, and discharged to the concentration chamber. Thus, in the electric deionized water production apparatus, hydrogen ions and hydroxide ions continuously act as acid and alkali regenerators for regenerating the ion exchanger. For this reason, the regeneration by the medicine is basically unnecessary, and the continuous operation can be performed without the regeneration of the ion exchanger by the medicine.

  There is known a deionized water production apparatus having a two-desalting chamber structure in which a desalting chamber is divided into a cation removing chamber and an anion removing chamber (Patent Document 1). In the deionized water production apparatus having the two-salt chamber structure, the desalting chamber is composed of at least a cation removing chamber filled with a cation exchanger and an anion removing chamber filled with at least an anion exchanger. And the anion removal chamber are adjacent to each other via an intermediate ion exchange membrane and connected in series. In the deionized water production apparatus having a two-salt chamber structure, high-purity treated water can be obtained by the serial configuration. In addition, since no concentration chamber is required between the cation removal chamber and the anion removal chamber, the number of concentration chambers per desalting chamber can be reduced. As a result, the electrical resistance of the deionized water production apparatus can be reduced, and the operating cost can be reduced.

  It is also known to operate a deionized water production apparatus connected in series for various purposes (Patent Documents 2 to 4). By performing serial treatment, high-purity treated water can be obtained.

Japanese Patent No. 3385553 Japanese Patent Laid-Open No. 11-104463 JP 2006-51423 A JP 2010-42324 A

  When processing high-load water containing a large amount of ions to be removed, it is necessary to pass a large current between the anode and the cathode. This causes the following two problems.

  The deionized water production apparatus having a two-salt chamber structure described in Patent Document 1 can reduce the electrical resistance between the anode and the cathode because the number of concentration chambers is small. However, even in a deionized water production apparatus having a two-salt desalination chamber, an increase in power consumption is inevitable due to an increase in current.

  Next, the ion exchange membrane (cation exchange membrane, anion exchange membrane) that partitions the cation removal chamber, the anion removal chamber, the cathode chamber, the anode chamber, and the like has a limit in the current value that can be applied. When a current exceeding the limit value flows through these ion exchange membranes, damage such as burning may occur, and the electrical resistance may increase. An increase in electrical resistance causes an increase in power consumption. Limiting the current can prevent an increase in the resistance of the ion exchange membrane, but a sufficiently purified treated water cannot be obtained. Although it is possible to reduce the load in advance by the pretreatment device, in that case, the equipment cost increases.

  As described above, in the case of treating high load water, it has been difficult to obtain treated water with sufficient purity while suppressing current consumption.

  An object of this invention is to provide the electric deionized water manufacturing apparatus which can process high load water while suppressing power consumption.

The electric deionized water production apparatus of the present invention has first and second deionized water production units connected in series. Each of the first and second deionized water production units includes an anode chamber and a cathode chamber defined by an ion exchange membrane, and first and second ion exchangers that are located between the anode chamber and the cathode chamber and are filled with an ion exchanger. A second desalting chamber, a first concentrating chamber adjacent to the first desalting chamber via a cation exchange membrane on the cathode chamber side, and a second desalting chamber via an anion exchange membrane on the anode chamber side A second concentration chamber adjacent to the first demineralization chamber, and a desalination chamber connection channel for connecting the first demineralization chamber and the second demineralization chamber in series. The first demineralization chamber is defined by a cation exchange membrane and an intermediate ion exchange membrane located on the anode chamber side of the first demineralization chamber, and the second demineralization chamber is defined by an intermediate ion exchange membrane, An anion exchange membrane. The first electrical deionized water production unit and the second electrical deionized water production unit have the same configuration, and the deionized water production unit in the latter stage of the first and second deionized water production units. The current flows through the first and second deionized water production units so that the power consumption of the deionized water production unit becomes smaller than the power consumption of the preceding deionized water production unit.
Moreover, the manufacturing method of the deionized water of this invention is a manufacturing method of the deionized water using the 1st and 2nd deionized water manufacturing unit connected in series. Each of the first and second deionized water production units includes an anode chamber and a cathode chamber defined by an ion exchange membrane, and first and second ion exchangers that are located between the anode chamber and the cathode chamber and are filled with an ion exchanger. A second desalting chamber, a first concentrating chamber adjacent to the first desalting chamber via a cation exchange membrane on the cathode chamber side, and a second desalting chamber via an anion exchange membrane on the anode chamber side A second concentration chamber adjacent to the first demineralization chamber, and a desalination chamber connection channel for connecting the first demineralization chamber and the second demineralization chamber in series. The first demineralization chamber is defined by a cation exchange membrane and an intermediate ion exchange membrane located on the anode chamber side of the first demineralization chamber, and the second demineralization chamber is defined by an intermediate ion exchange membrane, An anion exchange membrane. The first electrical deionized water production unit and the second electrical deionized water production unit have the same configuration, and the deionized water production unit in the latter stage of the first and second deionized water production units. The current flows through the first and second deionized water production units so that the power consumption of the deionized water production unit becomes smaller than the power consumption of the preceding deionized water production unit.

  In the electric deionized water production apparatus of the present invention, since the first and second deionized water production units are connected in series, the load can be shared by the two deionized water production units. For this reason, the applied current of each deionized water production unit can be suppressed. Since the applied current is small, each ion exchange membrane (cation exchange membrane, anion exchange membrane, intermediate ion exchange membrane) is not easily damaged. For this reason, the increase in electrical resistance in the ion exchange membrane is suppressed, and the applied voltage is suppressed. As a result of suppressing the applied current and the applied voltage, power consumption is also suppressed. In addition to the first and second deionized water production units being connected in series, the first and second demineralization chambers in each deionized water production unit are also connected in series. Treatment is easily realized, and high load water can be easily treated.

  ADVANTAGE OF THE INVENTION According to this invention, while suppressing power consumption, the electrical deionized water manufacturing apparatus which can process high load water can be provided.

It is a schematic block diagram of the deionized water manufacturing apparatus which concerns on the 1st Embodiment of this invention. It is a schematic block diagram of a 1st deionized water manufacturing unit. It is a schematic block diagram of the modification of the deionized water manufacturing apparatus which concerns on 1st Embodiment. It is a schematic diagram which shows distribution of the ion exchange resin of an intermediate ion exchange membrane vicinity. It is a schematic block diagram of the deionized water manufacturing apparatus which concerns on the 2nd Embodiment of this invention. It is a schematic block diagram of the deionized water manufacturing apparatus which concerns on the 2nd Embodiment of this invention. It is a schematic block diagram of the deionized water manufacturing apparatus which concerns on the 3rd Embodiment of this invention. It is a schematic block diagram of the deionized water manufacturing apparatus which concerns on the 3rd Embodiment of this invention. It is a schematic block diagram of the deionized water manufacturing apparatus which concerns on the 3rd Embodiment of this invention. It is a schematic block diagram of the deionized water manufacturing apparatus which concerns on an Example and a comparative example.

  Hereinafter, several embodiments of the deionized water production apparatus of the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a schematic configuration diagram of a deionized water production apparatus according to the first embodiment of the present invention. The deionized water production apparatus 1 includes a first deionized water production unit 11 and a second deionized water production unit 12. The first deionized water production unit 11 and the second deionized water production unit 12 are connected in series, and the treated water first flows into the first deionized water production unit 11 and then the second deionized water production unit 11. It flows into the ionic water production unit 12.

  On the inlet side of the first deionized water production unit 11, a feed water pump 9 is provided for allowing the water to be treated to flow into the first deionized water production unit 11. Between the first deionized water production unit 11 and the second deionized water production unit 12, the pressure of the water flowing out to the first deionized water production unit 11 is increased to increase the second deionized water production unit. There is provided a booster pump 9 ′ that flows into the pump 12. The booster pump 9 'is provided to compensate for the pressure loss generated in the first deionized water production unit 11, and is omitted when sufficient pressure is obtained at the inlet of the second deionized water production unit 12. can do.

  In the present embodiment, the first deionized water production unit 11 and the second deionized water production unit 12 have the same configuration, but may have different configurations.

  Hereinafter, the configuration of the first deionized water production unit 11 will be described as a representative. FIG. 2 is a schematic configuration diagram of the first deionized water production unit 11.

  The first deionized water production unit 11 includes first and second demineralization chambers D1 and D2 partitioned by an intermediate ion exchange membrane m, and outside the first and second demineralization chambers D1 and D2, respectively. First and second concentration chambers C1 and C2 positioned, first and second sub-desalting chambers S1 and S2 positioned further outside, and cathode chamber E1 and anode chamber E2 positioned further outside ,have.

  The first and second desalting chambers D1, D2 are located between the anode chamber E2 and the cathode chamber E1, and are filled with an ion exchanger. More specifically, the first desalting chamber D1 is positioned on the cation exchange membrane c1 located on the cathode chamber E1 side of the first desalting chamber D1 and on the anode chamber E2 side of the first desalting chamber D1. And an intermediate ion exchange membrane m. The second desalting chamber D2 is defined by an intermediate ion exchange membrane m and an anion exchange membrane a1 located on the anode chamber E2 side from the second desalting chamber D2. The first desalting chamber D1 is located closer to the cathode chamber E1 than the second desalting chamber D2. The outlet of the first desalting chamber D1 and the inlet of the second desalting chamber D2 are connected by a desalting chamber connection flow path 5. As a result, the first desalting chamber D1 and the second desalting chamber D1 are connected. The chamber D2 is connected in series.

The reason why the first desalting chamber D1 is in the preceding stage of the second desalting chamber D2 is to preferentially remove hardness components such as Ca ²⁺ and Mg ²⁺ contained in the water to be treated. In the second desalting chamber D2, OH ⁻ is generated by water decomposition, and is inclined to be alkaline. OH ⁻ reacts with the hardness component of the water to be treated and becomes a scale of hydroxide such as Ca (OH) ₂ or Mg (OH) ₂ and adheres to the intermediate ion exchange membrane m. For this reason, the electrical resistance of the intermediate ion exchange membrane m increases, and water decomposition is also inhibited. Generation | occurrence | production of a scale can be prevented by letting to-be-processed water pass through the 1st desalination chamber D1, and removing a hardness component. Depending on the quality of the water to be treated, it is possible to pass the water to be treated first through the second desalting chamber D2.

In one embodiment, only the cation exchanger is filled in the first desalting chamber D1 (single bed filling of the cation exchanger), and the cation components (Na ⁺ , Ca ²⁺ , Mg ²⁺ etc.) in the water to be treated Is removed. Examples of the cation exchanger include ion exchange resins, ion exchange fibers, and monolithic porous ion exchangers, and the most versatile ion exchange resin is preferably used. Examples of the cation exchanger include weakly acidic cation exchangers and strongly acidic cation exchangers.

In one embodiment, only the anion exchanger is filled in the second desalting chamber D2 (single bed filling of the anion exchanger), and anion components (Cl ⁻ , CO ₃ ²⁻ , HCO _{3 in the} water to be treated). ^- , SiO ₂ (Silica often takes a special form, so it is displayed differently from general ions), etc.). Examples of the anion exchanger include ion exchange resins, ion exchange fibers, monolithic porous ion exchangers, etc., and the most versatile ion exchange resins are preferably used. Examples of the anion exchanger include weakly basic anion exchangers and strong basic anion exchangers.

  The first desalting chamber D1 may be further filled with an anion exchanger. In one embodiment, the first desalting chamber D1 may be filled with a cation exchanger at a volume ratio of 80% or more, and the remaining ion exchanger may be an anion exchanger. In other embodiments, the first desalting chamber D1 may be filled with a cation exchanger in a volume ratio of greater than 50% and the remaining ion exchanger may be an anion exchanger. When the first demineralization chamber D1 is further filled with an anion exchanger, the ion exchanger filled in the first demineralization chamber D1 has a mixed form of a cation exchanger and an anion exchanger. A form or a double bed form is mentioned.

  Similarly, the second desalting chamber D2 may be further filled with a cation exchanger. In one embodiment, the second desalting chamber D2 may be filled with an anion exchanger at a volume ratio of 80% or more, and the remaining ion exchanger may be a cation exchanger. In other embodiments, the second desalting chamber D2 may be filled with an anion exchanger in a volume ratio greater than 50% and the remaining ion exchanger may be a cation exchanger. When the second desalting chamber D2 is further filled with a cation exchanger, the ion exchanger charged in the second desalting chamber D2 can be filled in a single bed or anion exchanger. And a mixed bed form or a double bed form of the cation exchanger.

  The first desalting chamber D1 is filled with a larger amount of cation exchanger than the anion exchanger in a volume ratio, and the second desalting chamber D2 is filled with more anion exchanger than the cation exchanger in a volume ratio. As long as it is, the filling ratio of the cation exchanger and the anion exchanger can be freely determined. For example, the first desalting chamber D1 may be filled with a cation exchanger at a volume ratio of 80%, and the second desalting chamber D2 may be filled with an anion exchanger at a volume ratio of 80%. The desalting chamber D1 may be filled with a cation exchanger at a volume ratio of 90%, and the second desalting chamber D2 may be filled with an anion exchanger at a volume ratio of 70%. The filling ratio of the cation exchanger in the first desalting chamber D1 and the filling ratio of the anion exchanger in the second desalting chamber D2 can be determined independently of each other as long as the above-described conditions are satisfied.

  The type of the intermediate ion exchange membrane m includes the quality of the water to be treated, the water quality required for deionized water (treated water), the types of ion exchangers filled in the first and second demineralization chambers D1 and D2, and the like. You can select it with due consideration. The intermediate ion exchange membrane m may be either an anion exchange membrane or a single membrane of a cation exchange membrane, or a composite membrane such as a bipolar membrane having both an anion exchange membrane and a cation exchange membrane.

  A first concentrating chamber C1 adjacent to the first desalting chamber D1 is provided on the cathode chamber E1 side of the first desalting chamber D1 via a cation exchange membrane c1. A second concentration chamber C2 adjacent to the second desalting chamber D2 is provided on the anode chamber E2 side of the second desalting chamber D2 via the anion exchange membrane a1. A part of the water to be treated or water supplied from another water source flows into the first and second concentrating chambers C1 and C2. The water supplied to the first concentration chamber C1 takes in the cation component discharged from the first demineralization chamber D1, and releases it to the outside of the first deionized water production unit 11. The water supplied to the second concentration chamber C2 takes in the anion component discharged from the second demineralization chamber D2, and releases it to the outside of the first deionized water production unit 11. In order to suppress the electrical resistance of the first deionized water production unit 11, the first and second concentrating chambers C1 and C2 may be filled with an ion exchanger.

  A first sub-desalting chamber S1 is provided between the second concentration chamber C2 and the anode chamber E2. Similarly, a second sub-desalting chamber S2 is provided between the first concentration chamber C1 and the cathode chamber E1. The second concentration chamber C2 and the first sub-desalting chamber S1 are partitioned by a cation exchange membrane c2, and the first sub-desalting chamber S1 and the anode chamber E2 are partitioned by a cation exchange membrane c3. The first concentration chamber C1 and the second sub-desalting chamber S2 are partitioned by an anion exchange membrane a2, and the second sub-desalting chamber S2 and the cathode chamber E1 are partitioned by an anion exchange membrane a3. The first sub-demineralization chamber S1 has the same configuration as the first demineralization chamber D1, but only the cation exchanger is filled with a single bed. The second sub-desalting chamber S2 has the same configuration as the second desalting chamber D2, but only the anion exchanger is filled with a single bed.

  The first sub-desalting chamber S1 is connected in parallel with the first desalting chamber D1, and the second sub-desalting chamber S2 is connected in parallel with the second desalting chamber D2. On the other hand, the first demineralization chamber D1 and the first sub-demineralization chamber S1, and the second demineralization chamber D2 and the second sub-demineralization chamber S2 are connected in series by the demineralization chamber connection flow path 5. It is connected.

  Although illustration is omitted, one or both of the first sub-desalination chamber S1 and the second sub-desalination chamber S2 can be omitted. In the present embodiment, when the second sub-desalting chamber S2 is omitted, the first concentration chamber C1 and the cathode chamber E1 are adjacent via the anion exchange membrane a2, but both are adjacent via the cation exchange membrane. In addition, the first concentrating chamber C1 and the cathode chamber E1 may be integrated (shared). Similarly, when the first sub-desalting chamber S1 is omitted, the second concentration chamber C2 and the anode chamber E2 are adjacent to each other via the cation exchange membrane c2, but both are adjacent to each other via the anion exchange membrane. In addition, the second concentrating chamber C2 and the anode chamber E2 may be integrated (shared).

  The cathode chamber E1 accommodates the cathode 3. The cathode 3 is made of a metal mesh or plate, and for example, a stainless steel mesh or plate can be used.

The anode chamber E2 accommodates the anode 4. The anode 4 is made of a metal net or plate. When the water to be treated contains Cl ⁻ , chlorine is generated at the anode 4. For this reason, it is desirable to use a material having chlorine resistance for the anode 4, and examples thereof include a metal such as platinum, palladium, iridium, or a material obtained by coating titanium with these metals.

  In the cathode chamber E1 and the anode chamber E2, a part of the water to be treated or water supplied from another water source flows as electrode water. In order to suppress the electrical resistance of the first deionized water production unit 11, it is preferable that the cathode chamber E1 and the anode chamber E2 are filled with an ion exchanger. The ion exchanger may be filled in only one of the anode chamber E2 and the cathode chamber E1. Examples of the ion exchanger filled in the cathode chamber E1 and the anode chamber E2 include ion exchange resins, ion exchange fibers, and monolithic porous ion exchangers, and the most general-purpose ion exchange resins are preferably used. The anode chamber E2 is filled with a single bed of a cation exchanger such as a weak acid cation exchanger or a strong acid cation exchanger. The cathode chamber E1 is filled with a single bed of anion exchangers such as a weakly basic anion exchanger and a strongly basic anion exchanger. Accordingly, as will be described later, the movement of hydrogen ions to the first sub-desalting chamber S1 and the movement of hydroxide ions to the second sub-desalting chamber S2 are performed smoothly. The anode chamber E2 may be further filled with an anion exchanger, and the cathode chamber E1 may be further filled with a cation exchanger. In these cases, the ion exchangers of the anode chamber E2 and the cathode chamber E1 can be filled in a mixed bed form or a double bed form of an anion exchanger and a cation exchanger.

  As shown in FIG. 3, a plurality of first and second desalting chambers D1 and D2 may be provided. In this case, three or more concentrating chambers C1 to CN (N is a natural number of three or more) are provided between the first sub-desalting chamber S1 and the second sub-desalting chamber S2, and between adjacent concentrating chambers. A set of first and second desalting chambers D1, D2 is arranged. The plurality of first desalting chambers D1 are preferably connected in parallel to each other, and the plurality of second desalting chambers D2 are also preferably connected in parallel to each other.

  The cathode chamber E1, the anode chamber E2, the first and second desalting chambers D1 and D2, the first and second concentration chambers C1 and C2, and the first and second sub-desalting chambers S1 and S2 are stacked. It is formed in an internal space formed by a large number of frame bodies 2 (the whole is shown by reference numeral 2 in the figure) provided in close contact with each other. The material of the frame 2 is not particularly limited as long as it has insulating properties and does not leak the water to be treated. For example, polyethylene, polypropylene, polyvinyl chloride, ABS, polycarbonate, m-PPE (modified polyphenylene ether), etc. Can be mentioned.

  Part of the treated water that has flowed into the first deionized water production unit 11 flows into the first demineralization chamber D1. Except for the case where a part of the treated water flows into at least one of the first and second desalination chambers D1, D2, the anode chamber E2, and the cathode chamber E1, the first sub-desalination chamber S1 is used. Inflow. The treated water that has flowed out of the first desalting chamber D1 and the first sub-desalting chamber S1 is supplied to the second desalting chamber D2 and the second sub-desalting chamber S2.

  Next, the flow of water to be treated and the principle of deionization will be described. The water supply pump 9 is activated, and the water to be treated is sequentially introduced into the first demineralization chamber D1 and the first sub-demineralization chamber S1, and further into the second demineralization chamber D2 and the second sub-demineralization chamber S2. . A part of the water to be treated or water supplied from another water source flows into the cathode chamber E1 and the anode chamber E2 as electrode water. Similarly, a part of the water to be treated or water supplied from another water source is also introduced into the first and second concentrating chambers C1 and C2.

  In this embodiment, as shown in FIG. 1, a part of the treated water is caused to flow into the cathode chamber E1 and the anode chamber E2 as electrode water, and a part of the treated water is fed into the first and second concentrating chambers C1, C2. It is allowed to flow into. In this state, a predetermined voltage is applied between the anode and the cathode. In addition, the “demineralization chamber” shown in FIG. 1 and others includes the first demineralization chamber D1 and the first sub-demineralization chamber S1, and the second demineralization chamber D2 and the second sub-demineralization chamber. The S2 is connected in series, the “concentration chamber” indicates the first and second concentration chambers C1 and C2, and the “electrode chamber” indicates the cathode chamber E1 and the anode chamber E2. The cathode chamber E1 and the anode chamber E2 may be connected in parallel or may be connected in series. In the latter case, either may be in the preceding stage.

The cation component is removed from the water to be treated in the first desalting chamber D1. Specifically, a cation component such as Na ⁺ is adsorbed by the cation exchanger filled in the first desalting chamber D1 in the first desalting chamber D1. At the interface between the first desalting chamber D1 and the second desalting chamber D2, a reaction in which water is dissociated into hydrogen ions (H ⁺ ) and hydroxide ions (OH ⁻ ) by the water splitting reaction proceeds continuously. doing. H ⁺ is exchanged with a cation component such as Na ⁺ adsorbed on the cation exchange resin while moving to the cathode side, and the cation exchanger filled in the first desalting chamber D1 is regenerated. The removed cations such as Na ⁺ are attracted to the cathode side by the potential between the anode and cathode, and the removed cations pass through the cation exchange membrane c1 and flow into the first concentrating chamber C1, and the first deionized water. It is discharged outside the production unit 11.

In the first sub-desalting chamber S1, cation components such as Na ⁺ are adsorbed on the cation exchanger filled in the first sub-desalting chamber S1. In the anode chamber E2, a reaction in which oxygen gas and H ⁺ are generated from water by an electrolysis reaction (2H ₂ O → O ₂ + 4H ⁺ + 4e ⁻ ) proceeds continuously. The oxygen gas rises in the anode chamber E2 and is discharged out of the first deionized water production unit 11 together with the electrode water. H ⁺ flows into the first sub-desalting chamber S1 through the third cation exchange membrane c3. H ⁺ flowing into the first sub-desalting chamber S1 is exchanged with the cation component adsorbed on the cation exchanger, and the cation exchanger is regenerated. The removed cation component such as Na ⁺ is attracted to the cathode side by the potential between the anode and cathode, passes through the second cation exchange membrane c2, flows into the anode side concentrating chamber C2, and is discharged out of the system.

Thus, the water to be treated from which the cation component such as Na ⁺ has been removed flows into the second desalting chamber D2. The anion component is removed from the water to be treated in the second desalting chamber D2. Specifically, an anion component such as Cl 2 ⁻ is adsorbed by the anion exchanger filled in the second desalting chamber D2 in the second desalting chamber D2. In the second desalting chamber D2, OH ⁻ is continuously generated by a water splitting reaction at the interface between the first desalting chamber D1 and the second desalting chamber D2. OH ⁻ is exchanged with an anion component such as Cl ⁻ adsorbed on the anion exchange resin to regenerate the anion exchanger. The removed anion component such as Cl ⁻ is attracted to the anode side by the potential between the anode and the cathode, and the removed anion component passes through the anion exchange membrane a1 and flows into the second concentration chamber C2, where the first desorption is performed. It is discharged out of the ionic water production unit 11.

In the second sub-desalting chamber S2, an anion component such as Cl ⁻ is adsorbed to the anion exchanger filled in the second sub-desalting chamber S2. In the cathode chamber E1, a reaction in which hydrogen gas and OH ⁻ are generated from water by an electrolysis reaction (2H ₂ O + 2e ⁻ → H ₂ + 2OH ⁻ ) proceeds continuously. The hydrogen gas rises in the cathode chamber E1 and is discharged out of the first deionized water production unit 11 together with the electrode water. OH ⁻ flows into the second sub-desalting chamber S2 through the third anion exchange membrane a3 and is exchanged with the anion component adsorbed on the anion exchanger, thereby regenerating the anion exchanger. The removed anion component such as Cl ⁻ is attracted to the anode side by the potential between the anode and cathode, passes through the second anion exchange membrane a2, and flows into the first concentration chamber C1. The water to be treated from which the anion component has been removed in the second demineralization chamber D2 and the second sub-demineralization chamber S2 joins and becomes deionized water and is discharged out of the first deionized water production unit 11. The

  The demineralization chamber is divided into two demineralization chambers, a first demineralization chamber D1 and a second demineralization chamber D2, and the first and second concentration chambers C1, C2 are adjacent to each other (demineralization chamber). The two salt chamber configurations) are capable of multi-stage treatment of water to be treated, and are effective in improving deionization performance. Moreover, since it is not necessary to provide a concentrating chamber between the first desalting chamber D1 and the second desalting chamber D2, the applied voltage between the anode and the cathode can be suppressed, the power consumption is reduced, and the operating cost is reduced. Is possible.

Moreover, the cation component is removed from the water to be treated in the first demineralization chamber D1 and the first sub-demineralization chamber S1, and the cation exchanger in the first demineralization chamber D1 is the first demineralization chamber D1. Regenerated by the generated H ⁺ , the cation exchanger in the first sub-desalting chamber S1 is regenerated by the H ⁺ generated in the anode chamber E2. Similarly, the anion component is removed from the water to be treated in the second demineralization chamber D2 and the second sub-demineralization chamber S2, and the anion exchanger in the second demineralization chamber D2 is the second demineralization chamber. Regenerated by OH ⁻ generated in D2, and the anion exchanger in the second sub-desalting chamber S2 is regenerated by OH ⁻ generated in the cathode chamber E1. Therefore, H ⁺ and OH ⁻ generated in the cathode chamber E1 and the anode chamber E2 and discarded in the prior art can be effectively used for regeneration of the ion exchanger. Since the generation efficiency of H ⁺ and OH ⁻ in the anode chamber E2 and the cathode chamber E1 is high, a sufficient amount of H ⁺ and OH ⁻ is sufficient even if the voltage is low, so that the first sub desalination chamber S1 and the second sub desalination are performed. Move to chamber S2. For this reason, the applied voltage between electrodes can be suppressed and the operating cost of the 1st deionized water manufacturing unit 11 can be reduced.

  Furthermore, since the deionized water production apparatus 1 has a series configuration of two deionized water production units 11 and 12, the load on each of the deionized water production units 11 and 12 is reduced. , 12 can be suppressed. Since the applied current decreases, the resistance of the ion exchange membranes (anion exchange membranes a1 to a3, cation exchange membranes c1 to c3, and intermediate ion exchange membrane m) due to burning hardly occurs, and the applied voltage between the anode and the cathode increases. Is suppressed. On the other hand, when the water to be treated is treated with only one deionized water production apparatus, the applied current is approximately equal to the sum of the currents flowing through the two deionized water production units, but the applied voltage between the anode and the cathode increases. It is easy and power consumption tends to increase.

In the present embodiment, the first desalting chamber D1 is filled with a larger amount of cation exchanger than the anion exchanger in a volume ratio, and the anion exchanger is cation exchanged in a volume ratio with the second desalting chamber D2. Since it is filled more than the body, the electrical resistance is further reduced, and the power consumption can be further suppressed. FIG. 4 is a schematic view showing the distribution of the ion exchange resin in the vicinity of the intermediate ion exchange membrane m in a two-salt chamber configuration. FIG. 4A shows a case where the first desalting chamber D1 is filled with a single bed of a cation exchanger, and the second desalting chamber D2 is filled with a single bed of an anion exchanger, and FIG. The figure shows the case where the same volume of the cation exchanger and the anion exchanger is packed in one desalting chamber. In any case, a water splitting reaction occurs at the interface between the cation exchanger C and the anion exchanger A adjacent to each other with the intermediate ion exchange membrane m interposed therebetween, and H ⁺ and OH ⁻ are generated.

Figure 4 In the case of (a), the generated H ⁺ cathode side, OH ^- and to the anode side, to move away from each other, because it is unlikely to be encountered each other, H ⁺ and OH ^- is the intact state The first desalting chamber D1 and the second desalting chamber D2 are electrophoresed while maintaining the above. On the other hand, in the case of FIG. 4B, part of the generated H ⁺ and OH ⁻ moves to the opposite surface through the intermediate ion exchange membrane m. Here, in the figure, both H ⁺ and OH ⁻ are shown to pass through the intermediate ion exchange membrane m, but in actuality, depending on the characteristics of the intermediate ion exchange membrane m, only either H ⁺ or OH ⁻ is present. It passes through the intermediate ion exchange membrane m. For example, when H ⁺ passes through the intermediate ion exchange membrane m, OH ⁻ is present on the opposite surface of the intermediate ion exchange membrane m, and H ⁺ that has passed through the intermediate ion exchange membrane m and the intermediate ion exchange membrane m A reverse reaction occurs between OH ⁻ existing on the opposite side of H ⁺ and OH ⁻ disappears.

  That is, in the case of FIG. 4A, the flow of ions is rectified and a reaction surface contributing to the water splitting reaction can be widely taken, whereas in FIG. 4B, the reaction surface contributing to the water splitting reaction is taken. It gets smaller. Moreover, in the case of FIG. 4B, the possibility that the cation exchanger and the anion exchanger are adjacent to each other via the intermediate ion exchange membrane m is small, and the reaction surface contributing to the water splitting reaction is further reduced. In order to compensate for this, it is necessary to increase the voltage between the anode and the cathode to generate more water splitting reaction. In other words, the same phenomenon occurs as the electrical resistance increases. In other words, in the case of FIG. 4A, the same effect as that in which the electrical resistance is reduced occurs.

  FIG. 4 (b) shows an example in which the cation exchanger and the anion exchanger are packed in a mixed bed, but the first demineralization chamber D1 is filled with a relatively large amount of the cation exchanger, and the second desorption chamber is filled. If the salt chamber D2 is filled with a relatively large amount of anion exchanger, the same effect as shown in FIG.

The inventor of the present application measured the electrical resistance by changing the filling ratio of the cation exchanger and the anion exchanger in one desalting chamber (volume ratio of the cation exchanger to the total volume of the cation exchanger and the anion exchanger). In this measurement example, the intermediate ion exchange membrane m as shown in FIG. 4 does not exist, but the same situation as in FIG. 4 is simulated for the generation and disappearance of H ⁺ and OH ⁻ .

  As a result of the measurement, the electric resistance was highest when the cation exchanger and the anion exchanger were filled in equal volumes (that is, when the filling ratio was 50%). On the other hand, as the filling ratio is higher or lower than 50%, the electric resistance decreases and only the anion exchanger is filled (that is, when the filling ratio is 0%) or only the cation exchanger. When it was filled (that is, when the filling ratio was 100%), the electric resistance was the lowest. Specifically, the electrical resistance when the filling ratio was 0% was about 1/5 of the electrical resistance when the filling ratio was 50%. In addition, the electrical resistance when the filling ratio was 100% was about 1/10 of the electrical resistance when the filling ratio was 50%.

  Further, inflection points were observed in the vicinity of the filling ratios of 20% and 80%. Specifically, the electrical resistance when the filling ratio was 20% was about 2/5 of the electrical resistance when the filling ratio was 50%. In addition, the electrical resistance when the filling ratio was 80% was about 1/3 of the electrical resistance when the filling ratio was 50%.

  Accordingly, the first desalting chamber D1 is filled with a cation exchanger at a volume ratio of 80% or more, and the second desalting chamber D2 is filled with an anion exchanger at a volume ratio of 80% or more. desirable.

(Second Embodiment)
In this embodiment, the configuration of each deionized water production unit is the same as that of the first embodiment, but the mode of connection between the deionized water production units is different from that of the first embodiment. In this embodiment, the flow order of the first deionized water production unit 11 and the second deionized water production unit 12 can be switched. FIGS. 5 and 6 both show the configuration of the deionized water production apparatus 1 ′ of the present embodiment, but each shows a different operation mode. The line through which the water is passed is indicated by a thick line (excluding the electrode chamber and the concentration chamber).

  The deionized water production apparatus 1 ′ has a first inlet line 21 for flowing water into the first deionized water production unit 11 and a second inlet line for flowing water into the second deionized water production unit 12. 22. The first and second inlet lines 21 and 22 branch from a common line 23 where the water supply pump 9 is provided. Similarly, the deionized water production apparatus 1 ′ has a first outlet line 24 through which water flows out from the first deionized water production unit 11 and a second through which water flows out from the second deionized water production unit 12. Outlet line 25. The first and second outlet lines 24 and 25 merge into a common outlet line 26. The first inlet line 21 and the second outlet line 25 are connected by a first connecting line 27, and the second inlet line 22 and the first outlet line 24 are connected by a second connecting line 28. Each line 21 to 28 is provided with a valve (not shown).

  In the operation mode shown in FIG. 5, as shown by a thick line, water is first passed through the first deionized water production unit 11 and then is passed through the second deionized water production unit 12. In the operation mode shown in FIG. 6, as shown by a thick line, the water is first passed through the second deionized water production unit 12 and then is passed through the first deionized water production unit 11. When a deionized water production apparatus is configured with two deionized water production units connected in series, generally the deionized water production unit in the previous stage has a higher load. It is governed by the uptime of the previous deionized water production unit. In this embodiment, since the flow order of the first deionized water production unit 11 and the second deionized water production unit 12 can be switched, the loads on the deionized water production units 11 and 12 are equalized, and the apparatus The total operation time can be extended. Even when the subsequent deionized water production unit has a higher load, the same effect can be obtained by similarly switching the water flow sequence.

(Third embodiment)
In this embodiment as well, the configuration of each deionized water production unit is the same as that of the first embodiment, but the mode of connection between the deionized water production units is different from that of the first embodiment. In this embodiment, three or more ion water production units are connected in series, and the flow order of the deionized water production units can be switched. 7 to 9 both show the configuration of the deionized water production apparatus 1 ″ of the present embodiment, but each shows a different operation mode. The line through which water passes is shown by a bold line. In FIG. 9, illustration of the electrode chamber and the concentration chamber is omitted.

  In addition to the first and second deionized water production units 11, 12, the deionized water production apparatus 1 ″ includes third to Nth deionized water production units 13 to 1N (where N is a natural number of 3 or more). The first to Nth deionized water production units 11 to 1N are connected in series, and each of the deionized water production units 11 to 1N is deionized water according to the first embodiment. The manufacturing unit can have the same configuration, each of which is located between the anode chamber E2 and the cathode chamber E1, and between the anode chamber E2 and the cathode chamber E1, connected in series, and partitioned by an ion exchange membrane. The first and second desalting chambers D1 and D2, the first and second concentration chambers C1 and C2, and the first and second sub-desalting chambers S1 and S2 are provided.

  The first to Nth deionized water production units 11 to 1N are connected to the first to Nth inlet lines 31 to 3N through which water flows into the first to Nth deionized water production units, respectively. Are connected to the outlet lines 41 to 4N. The Jth outlet line and the J + 1th inlet line (where J is a natural number from 1 to N-1) are connected by connection lines 51 to 5N-1 (N-1 in total), respectively. The Nth outlet line and the first inlet line are connected by a connection line 5N.

  Accordingly, as shown in FIG. 7, the first deionized water production unit 11 is connected in series from the second, third,..., Nth deionized water production unit 1N, and water is passed in this order. Can do. Further, as shown in FIG. 8, water can be passed from the second deionized water production unit 12 in the order of the third, fourth,..., Nth, first deionized water production unit 11. . In general terms, from any Kth (where K is any natural number from 1 to N) deionized water production unit, K−1 (Nth if K = 1) deionized water. Water can be passed sequentially to the production unit. Furthermore, as shown in FIG. 9, a part of the deionized water production unit (here, the first deionized water production unit 11) can be isolated from the deionized water production apparatus 1 ″. While continuing, the desired deionized water production unit can be maintained.

(Example)
The effect of this invention was confirmed using the deionized water manufacturing apparatus of the structure shown in FIG. FIG. 10A is a configuration diagram of a deionized water production apparatus according to an embodiment of the present invention, and FIG. 10B is a configuration diagram of a deionized water production apparatus according to a comparative example. In the example, two deionized water production units having the same configuration as shown in FIG. 2 are connected in series, and the comparative example includes only one deionized water production unit as in the example. The treated water that passed through the RO (reverse osmosis membrane) apparatus was supplied to the deionized water production apparatus and the deionized water production apparatus of Examples and Comparative Examples. In the example, the power consumption of the former deionized water production unit was 156 W, whereas the latter deionized water production unit was about one third of that, and the total power consumption was 211 W. On the other hand, in the comparative example, the total power consumption was 464 W. Since the water quality obtained in the example was better than the water quality obtained in the comparative example, if the water quality equivalent to that in the comparative example is sufficient, the power consumption of the example is further reduced.

  In the examples, the applied voltage between the anode and the cathode was slightly higher than 100 V in both the former and latter deionized water production units, whereas in the comparative example, it was 232 V. Since the current value of the comparative example was 2.0 A, which was larger than that of the example, the resistance of the ion exchange membrane was increased, thereby increasing the applied voltage and increasing the power consumption.

D1 1st desalination chamber D2 2nd desalination chamber C1 1st concentration chamber C2 2nd concentration chamber S1 1st subdemineralization chamber S2 2nd subdesalination chamber E1 cathode chamber E2 anode chamber a1 a3 anion exchange membrane c1 to c3 cation exchange membrane m intermediate ion exchange membrane 1,1 ′, 1 ″ deionized water production apparatus 11, 12,... 1N deionized water production unit

Claims (13)

Having first and second deionized water production units connected in series;
Each of the first and second deionized water production units is located between an anode chamber and a cathode chamber defined by an ion exchange membrane, and between the anode chamber and the cathode chamber, and is filled with an ion exchanger. First and second desalting chambers, a first concentration chamber adjacent to the first desalting chamber via a cation exchange membrane on the cathode chamber side, and an anion exchange membrane on the anode chamber side A second concentrating chamber adjacent to the second desalting chamber, and a desalting chamber connection channel connecting the first desalting chamber and the second desalting chamber in series,
The first demineralization chamber is defined by the cation exchange membrane and an intermediate ion exchange membrane located on the anode chamber side of the first demineralization chamber;
The second desalting chamber is defined by the intermediate ion exchange membrane and the anion exchange membrane;
The first electrical deionized water production unit and the second electrical deionized water production unit have the same configuration, and the deionization of the latter stage of the first and second deionized water production units An electric deionized water production apparatus in which a current is passed through the first and second deionized water production units so that the power consumption of the water production unit is smaller than the power consumption of the preceding deionized water production unit.   The electric deionized water production apparatus according to claim 1, wherein the first and second concentrating chambers are configured such that the supply water flows in a direction opposite to the water to be treated flowing through the first desalting chamber.   Branching from the first treated water supply channel for supplying the treated water to the first demineralization chamber of the first deionized water production unit, and the first treated water supply channel, A part of the to-be-treated water is supplied to the first and second concentration chambers of the first deionized water production unit and the first and second concentration chambers of the second deionized water production unit. The electric deionized water production apparatus according to claim 1, further comprising: a second treated water supply channel.   Having at least one of a first sub-demineralization chamber provided in parallel with the first demineralization chamber and a second sub-desalination chamber provided in parallel with the second demineralization chamber; The electric deionized water production apparatus according to any one of claims 1 to 3.   The first desalting chamber is filled with a cation exchanger in a volume ratio greater than 50%, or the second desalting chamber is filled with an anion exchanger in a volume ratio greater than 50%, or the first The desalting chamber is filled with a cation exchanger in a volume ratio of more than 50% and the second desalting chamber is filled with an anion exchanger in a volume ratio of more than 50%. The electrical deionized water production apparatus according to the item.   The first desalting chamber is filled with the cation exchanger in a volume ratio of 80% or more, or the second desalting chamber is filled with the anion exchanger in a volume ratio of 80% or more, or 5. The desalting chamber 1 is filled with the cation exchanger in a volume ratio of 80% or more, and the second desalting chamber is filled with the anion exchanger in a volume ratio of 80% or more. The electric deionized water production apparatus according to any one of the above.   The first desalting chamber is filled with only the cation exchanger, or the second desalting chamber is filled with only the anion exchanger, or the first desalting chamber is filled with only the cation exchanger. The electric deionized water production apparatus according to any one of claims 1 to 4, wherein the second demineralization chamber is filled with only the anion exchanger. Between the electric deionized water production unit in the preceding stage and the electric deionized water production unit in the subsequent stage, the pressure of the water flowing out of the electric deionized water production unit in the previous stage is increased to increase the pressure of the electric deionization in the subsequent stage. The electric deionized water production apparatus according to any one of claims 1 to 7 , further comprising a pump that flows into the ionic water production unit. A first inlet line for flowing water into the first deionized water production unit;
A second inlet line for flowing water into the second deionized water production unit;
A first outlet line for draining water from the first deionized water production unit;
A second outlet line for draining water from the second deionized water production unit;
A first connection line connecting the first inlet line and the second outlet line;
A second connection line connecting the second inlet line and the first outlet line;
The electric deionized water production apparatus according to any one of claims 1 to 8 , comprising: A reverse osmosis membrane device located upstream of the preceding deionized water production unit;
The electric deionized water production apparatus according to any one of claims 1 to 9 , wherein the permeated water of the reverse osmosis membrane device is supplied as treated water to the preceding deionized water production unit. The ion exchange membrane is connected in series with the first and second deionized water production units, each being located between the anode chamber and the cathode chamber, and between the anode chamber and the cathode chamber and connected in series. A third and Nth deionized water production unit (where N is a natural number of 3 or more) having first and second demineralization chambers separated by
First to Nth inlet lines for flowing water into the first to Nth deionized water production units, respectively.
First to Nth outlet lines for allowing water to flow out from the first to Nth deionized water production units, respectively;
N-1 connecting lines respectively connecting the Jth outlet line and the J + 1th inlet line (where J is any natural number from 1 to N-1), and the Nth outlet line A connection line connecting the first inlet line;
The electric deionized water production apparatus according to any one of claims 1 to 8 , comprising: A method for producing deionized water using first and second deionized water production units connected in series,
Each of the first and second deionized water production units is located between an anode chamber and a cathode chamber defined by an ion exchange membrane, and between the anode chamber and the cathode chamber, and is filled with an ion exchanger. First and second desalting chambers, a first concentration chamber adjacent to the first desalting chamber via a cation exchange membrane on the cathode chamber side, and an anion exchange membrane on the anode chamber side A second concentrating chamber adjacent to the second desalting chamber, and a desalting chamber connection channel connecting the first desalting chamber and the second desalting chamber in series,
The first demineralization chamber is defined by the cation exchange membrane and an intermediate ion exchange membrane located on the anode chamber side of the first demineralization chamber;
The second desalting chamber is defined by the intermediate ion exchange membrane and the anion exchange membrane;
The first electrical deionized water production unit and the second electrical deionized water production unit have the same configuration, and the deionization of the latter stage of the first and second deionized water production units A method for producing deionized water, wherein an electric current is passed through the first and second deionized water production units so that the power consumption of the water production unit is smaller than the power consumption of the preceding deionized water production unit. Permeate of the reverse osmosis membrane device located upstream of the water producing unit of the previous stage is supplied as the water to be treated water producing unit of the preceding stage, deionized water according to claim 1 2 Manufacturing method.

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