JP6442581B1 - Water treatment apparatus, water treatment system and cooling system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To produce ion exchange treated water having a desired calcium hardness. A water treatment apparatus that generates ion exchange treated water by performing ion exchange treatment on water to be treated, the main flow path through which the water to be treated flows, and a cation disposed in the main flow path An ion-exchange resin, an anion ion-exchange resin disposed downstream of the cation ion-exchange resin in the main channel, and the cation ion exchange in the main channel branched from the upstream of the cation ion-exchange resin in the main channel A branch flow path connected to a connection position between a resin and the anion ion exchange resin, and a flow rate adjustment valve for adjusting a flow rate of water to be treated flowing through the branch flow path, and the flow rate adjustment valve is Set to an opening degree and allow the water to be treated to flow into the anion ion exchange resin by flowing the water to be treated from the branch flow path into the main flow path. The calcium hardness of water is the same as the target calcium hardness. [Selection] Figure 1

Description

  The present invention relates to a water treatment apparatus, a water treatment system, and a cooling system for treating water to be treated such as tap water.

  The treated water (tap water, groundwater, industrial water, etc.) contains scale components (calcium, ionic silica, etc.) and corrosive components (chloride ions, sulfate ions, etc.). In order to use the water to be treated as water used for cooling a factory or the like (hereinafter referred to as cooling water), a treatment technique for reducing scale components and corrosion components contained in the water to be treated is known. As a water treatment device using one of the treatment technologies, a treatment for removing scale components (excluding ionic silica) with a cation ion exchange resin, and removing a corrosive component and ionic silica with an anion ion exchange resin (hereinafter, referred to as “water treatment device”). 2. Description of the Related Art There is known a water treatment apparatus that performs an ion exchange process) on the entire amount of water to be treated that flows into the water treatment apparatus (hereinafter referred to as pure water treatment). By supplying pure water (cooling water) generated by this treatment to the cooling target equipment through the piping, the cooling target equipment can be cooled. Patent Document 1 proposes a water treatment apparatus that generates deionized water (pure water) by performing pure water treatment on inflowing raw water (treated water).

JP 2007-090266 A

  Here, when the water after ion exchange treatment (hereinafter referred to as ion exchange treated water) contains calcium, the cooling system (for example, metal-using equipment and apparatus) through which the ion exchange treated water flows has a calcium component. A protective film is formed. For example, the protective film is formed at a contact portion of a pipe, a mold, a heat exchanger or the like (hereinafter sometimes referred to as a pipe or the like) with which ion-exchange treated water comes into contact with liquid. However, in the water treatment apparatus of Patent Document 1, since calcium as a scale component is almost completely removed, a protective film made of calcium component can be formed inside a pipe or the like even if pure water is passed through. This is not possible and the pipes and the like are easily corroded. On the other hand, when calcium is excessively contained in the ion exchange treated water, there is a possibility that a scale failure such as heat transfer inhibition or blockage of the pipe may occur in the pipe through which the ion exchange treated water has passed.

  Then, an object of this invention is to produce | generate the ion exchange treated water which has desired calcium hardness.

  Therefore, as a result of further intensive studies to solve the above-described problems, the present inventors have found the following invention. (1) A water treatment apparatus that generates ion exchange treated water by performing ion exchange treatment on the water to be treated, and a main channel through which the water to be treated flows, and a cation ion disposed in the main channel An exchange resin, an anion ion exchange resin disposed downstream of the cation ion exchange resin in the main channel, and the cation ion exchange resin in the main channel branched from the upstream of the cation ion exchange resin in the main channel And a branch flow path connected to a connection position between the anion ion exchange resin and a flow rate adjustment valve for adjusting the flow rate of the water to be treated flowing through the branch flow path, and the flow rate adjustment valve is opened in a predetermined manner. The water to be treated flowing into the anion ion exchange resin is allowed to flow into the main flow path from the branch flow path. The Siumu hardness, characterized in that the same as the target calcium hardness.

Here, the following two methods different from the present invention can be considered as water treatment methods for generating ion exchange treated water having a desired calcium hardness.
Method 1: A method in which a carbonic acid gas is passed through an aqueous solution produced by dissolving a reagent such as calcium hydroxide in pure water to produce a calcium carbonate aqueous solution, and this calcium carbonate aqueous solution is added to pure water passing through a pipe. Method 2 : Method using cation ion exchange resin with low ability to remove calcium However, in method 1, it is necessary to separately provide a reagent mixing tank for mixing a reagent with pure water and a carbon dioxide supply device for passing carbon dioxide. The economic burden is great. In Method 2, since it is necessary to select a cation ion exchange resin again according to the calcium hardness of the water to be treated, a plurality of cation ion exchange resins having different removal capabilities must be prepared in advance. It is complicated.

  (2) The water treatment system according to (1), wherein the target calcium hardness is set to 20 to 50 (mg / L).

  (3) The water treatment device according to (1) or (2), and a deoxygenation device that performs deoxygenation treatment on the ion exchange treated water discharged from the water treatment device, Water treatment system.

  (4) The deoxygenation device has a container shape with an open lower end, a gas-liquid contact tower in which at least the lower end is submerged below the surface of the water to be treated and forms a sealed space inside, and the sealed A deaeration gas supply unit that supplies deaeration gas into the space and fills the deaeration gas in the sealed space, and the supplied water to be treated is sprayed in the sealed space by the spray nozzle unit. A water treatment system according to (3) above, comprising a treated water spraying unit.

  (5) The water treatment according to (3) or (4) above, wherein the dissolved oxygen concentration of the ion exchange treated water after the deoxygenation treatment by the deoxygenation device is 1 (mg / L) or less. system.

  (6) The water treatment system according to any one of (3) to (5) above, and a cooling water circulation system that circulates cooling water that cools the facility to be cooled, wherein the cooling water circulation system includes the water A water storage tank for storing the ion exchange treated water discharged from the treatment device, and a circulation pipe for circulating the ion exchange treated water stored in the water storage tank between the water storage tank and the facility to be cooled as cooling water; A cooler that cools cooling water from the facility to be cooled to the water storage tank through the circulation pipe, and the gas-liquid contact tower is installed in the water storage tank. system.

  According to the configuration of (1) above, ion exchange treated water having a desired calcium hardness can be generated.

It is a schematic block diagram of the cooling system in this embodiment. It is a schematic block diagram of the water treatment apparatus in this embodiment. It is a schematic block diagram of the deoxidation apparatus and cooling water circulation system in this embodiment. FIG. 4 is an enlarged view of a region D surrounded by an alternate long and short dash line in FIG. 3.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic configuration diagram of a cooling system in the present embodiment. With reference to the figure, the cooling system 100 includes a water treatment system 1 and a cooling water circulation system 6. The water treatment system 1 includes a water treatment device 2 and a deoxygenation device 3 that performs deoxygenation treatment on ion-exchange treated water generated by the water treatment device 2. The cooling water circulation system 6 includes a water storage tank 7 for storing the discharged ion exchange treated water discharged from the water treatment device 2, and the water exchange tank 7 and a cooling target using the ion exchange treated water stored in the water storage tank 7 as cooling water. A circulation pipe 9 that circulates between the facility 5 and a cooler 4 that cools cooling water from the facility to be cooled 5 toward the water storage tank 7 is provided.

  A process performed by the cooling system 100 will be briefly described. When the water to be treated flows into the water treatment device 2, ion exchange treatment is performed on the water to be treated. Water (ion exchange treated water) generated by the ion exchange treatment in the water treatment device 2 is stored in the water storage tank 7. Ion exchange treated water stored in the water storage tank 7 (hereinafter sometimes referred to as deoxidized treated water) is sent to the deoxygenation device 3 and the cooling target equipment 5. The deoxygenated water fed to the deoxygenation device 3 is deoxygenated by the deoxygenation device 3 and then stored in the water tank 7. The deoxygenated treated water (cooling water) sent to the cooling target facility 5 cools the cooling target facility 5. The cooling water heated by the facility to be cooled 5 is cooled by the cooler 4 and then stored in the water storage tank 7. That is, the cooling water circulation system 6 of the cooling system 100 is provided with a circulation pipe 9 that circulates between the water storage tank 7 and the cooling target equipment 5 using the ion exchange treated water stored in the water storage tank 7 as cooling water. Yes.

(About water treatment device 2)
With reference to FIG. 1 and 2, the structure of the water treatment apparatus in this embodiment is demonstrated in detail. FIG. 2 is a schematic configuration diagram of a water treatment apparatus in the present embodiment. The water treatment device 2 includes a main channel 200, a branch channel 220, and a control panel 28.

  From the upstream to the downstream in the main channel 200 through which the treated water that has flowed in flows from the upstream to the downstream, the inflow valve 20, the pressure reducing valve 21, the cation ion exchange resin 23, the anion ion exchange resin 24, the flow meter 27, and the second flow rate adjustment valve 25. And the discharge valve 26 are arranged in this order. The inflow valve 20 can be operated between an open state and a closed state. By setting the inflow valve 20 to the open state, the water to be treated can flow into the water treatment device 2. By setting the inflow valve 20 to the closed state, it is possible to prohibit the water to be treated from flowing into the water treatment device 2. The pressure reducing valve 21 includes a pressure gauge, and the supply pressure of the water to be treated in the main flow path 200 is determined by adjusting the pressure reducing valve 21. The cation ion exchange resin 23 removes scale components (excluding ionic silica) contained in the water to be treated by coming into contact with the water to be treated. The anion ion exchange resin 24 removes corrosive components and ionic silica contained in the water to be treated by contacting the water to be treated. As the cation ion exchange resin 23, a strongly acidic H-type cation exchange resin is used. As the anion ion exchange resin 24, a strongly basic OH type anion exchange resin is used. The flow meter 27 measures the flow rate of the water to be treated flowing through the main flow path 200, and the measurement result is transmitted to the control panel 28. The flow rate of the ion exchange treated water discharged from the water treatment device 2 is determined by the opening degree of the second flow rate adjustment valve 25. The discharge valve 26 can be operated between an open state and a closed state. By setting the discharge valve 26 to the open state, the ion exchange treated water can be discharged from the water treatment device 2. By setting the discharge valve 26 to the closed state, it is possible to inhibit the ion exchange treated water from flowing out of the water treatment device 2.

  The branch flow path 220 branches from the first flow path branch point A between the pressure reducing valve 21 and the cation ion exchange resin 23 in the main flow path 200, and the cation ion exchange resin 23 and the anion ion exchange resin 24 in the main flow path 200. It is connected to the connection position B. A first flow rate adjustment valve 22 (corresponding to a “flow rate adjustment valve” in claim 1) is arranged in the branch flow path 220, and branches into the branch flow path 220 depending on the opening degree of the first flow rate adjustment valve 22. The flow rate of the water to be treated is determined. Details of the method for setting the opening of the first flow rate adjusting valve 22 will be described later.

  The control panel 28 includes a flow rate information processing unit (not shown) and a display unit (not shown). Based on the measurement result received from the flow meter 27, the flow rate information processing unit calculates the integrated flow rate of the water to be treated flowing through the main flow path 200. When the integrated flow rate reaches a predetermined value, the flow rate information control unit sends a signal to the display unit and causes the display unit to display an ion exchange resin alarm that prompts replacement of the ion exchange resin.

  A pipe communicating with the outside of the water treatment apparatus 2 is provided between the pressure reducing valve 21 and the cation ion exchange resin 23 in the main flow path 200, and a pressure relief valve 29 is disposed in this pipe. A pipe communicating with the outside of the water treatment device 2 is provided between the second flow rate adjustment valve 25 and the discharge valve 26 in the main flow path 200, and a pressure relief valve 29 'is disposed in this pipe. When replacing the cation ion exchange resin 23 and the anion ion exchange resin 24 based on the ion exchange resin alarm displayed on the display unit of the control panel 28, before performing the replacement work, the pressure relief valve 29 and It is preferable to reduce the internal pressure of the main flow path 200 and the branch flow path 220 by operating 29 'from the closed state to the open state.

  The water treatment performed in the water treatment apparatus 2 will be described. In the initial state, it is assumed that both the inflow valve 20 and the discharge valve 26 are set to an open state. The treated water that has flowed into the main channel 200 via the inflow valve 20 is sent to the first channel branch point A at a predetermined supply pressure set by the pressure reducing valve 21. Depending on the opening degree of the first flow rate adjusting valve 22, the water to be treated having a predetermined flow rate of the water to be treated sent to the first flow path branching point A branches into the branch flow path 220, and the remaining treated water is supplied. The treated water passes through the main channel 200 and comes into contact with the cation ion exchange resin 23. The treated water flowing through the main flow path 200 comes into contact with the cation ion exchange resin 23 to remove scale components (excluding ionic silica) and lowers the calcium hardness. On the other hand, the water to be treated that has flowed into the branch flow path 220 passes through the branch flow path 220 while maintaining the calcium hardness at the time of branch flow without removing the scale component (calcium) by the cation ion exchange resin 23. Liquid. The water to be treated that has contacted the cation ion exchange resin 23 and the water to be treated that has passed through the branch flow path 220 merge at the connection position B. The water to be treated that merged at the connection position B passes through the main flow path 200 and comes into contact with the anion ion exchange resin 24 to remove the corrosive components and ionic silica. Thereby, the water in which ion exchange is completed in the water treatment device 2 (ion exchange treated water) is generated. Thereafter, ion exchange treated water having a flow rate corresponding to the opening degree of the second flow rate adjusting valve 25 is discharged from the water treatment device 2 via the discharge valve 26. The ion exchange treated water discharged from the water treatment device 2 is sent to the deoxygenation device 3 via the water storage tank 7 and is subjected to deoxygenation treatment. By performing deoxygenation treatment by the deoxygenation device on the ion exchange treated water discharged from the water treatment device 2, the degree of corrosion of the ion exchange treated water after the deoxygenation treatment can be suppressed within an allowable value. For example, the allowable value can be set to 50 (mdd). In this embodiment, the ion exchange treated water discharged from the water treatment apparatus is sent to the deoxygenation apparatus. However, the present invention is not limited to this, and the deoxygenation treatment is performed on the ion exchange treated water. Instead, the ion exchange treated water may be used as the cooling water as it is.

  Here, the opening degree setting method of the first flow rate adjustment valve 22 will be described. The opening degree of the first flow rate adjusting valve 22 is set such that the calcium hardness of the water to be treated flowing into the anion ion exchange resin 24 is the same as the target calcium hardness. The target calcium hardness is preferably set to 20 to 50 (mg / L). By satisfying this range, corrosion can be more effectively suppressed in piping or the like through which ion-exchange treated water flows.

  When the opening degree of the first flow rate adjustment valve 22 is increased, the flow rate of the water to be treated flowing through the main flow path 200 (the water to be treated with reduced calcium hardness) decreases, and the water to be treated that branches and flows into the branch flow path 220. Since the flow rate of (the water to be treated in which the calcium hardness is maintained) increases, the calcium hardness of the water to be treated flowing into the anion exchange resin 24 is increased. On the other hand, when the opening degree of the first flow rate adjustment valve 22 is reduced, the flow rate of the water to be treated flowing through the main flow path 200 (the water to be treated with reduced calcium hardness) increases, and the flow rate of the water flowing into the branch flow path 220 is branched. Since the flow rate of the treated water (treated water in which the calcium hardness is maintained) decreases, the calcium hardness of the treated water flowing into the anion ion exchange resin 24 decreases. That is, by adjusting the opening degree of the first flow rate adjusting valve 22, water to be treated flowing through the main flow path 200 (water to be treated with reduced calcium hardness) and water to be treated flowing into the branch flow path 220 ( Therefore, the calcium hardness of the water to be treated flowing into the anion ion exchange resin 24 can be adjusted.

  As a method of setting the opening degree of the first flow rate adjusting valve 22, for example, a method of previously checking the calcium hardness of the water to be treated flowing into the water treatment device 2 can be used. Specifically, the relationship information that defines the calcium hardness of the water to be treated that flows into the water treatment device 2 and the relationship between the calcium hardness of the water to be treated that flows into the water treatment device 2 and the removal ability of the cation ion exchange resin 23. Can be determined in advance, and the flow rate of the water to be treated branched into the branch flow path 220 (corresponding to the “predetermined flow rate” in claim 1) can be determined. Here, the “removability” indicates a correspondence relationship between the flow rate of water to be treated that contacts the cation ion exchange resin and the calcium removal rate. The first flow rate adjustment valve 22 is set to a predetermined opening according to the flow rate of the water to be treated determined by this method. Note that the data format of the relationship information may be a data table or a graph. As a method for investigating the calcium hardness of the water to be treated flowing into the water treatment device 2, the calcium hardness is calculated based on the water quality data of the water to be treated, or the calcium hardness of the water to be treated is directly measured by a calcium hardness measurement sensor. A detection method can be suitably used.

  Further, as another method, the calcium hardness of the water to be treated flowing into the water treatment apparatus 2 is not checked in advance, but using a calcium hardness measurement sensor (not shown) disposed in the branch flow path 220, A method for detecting the calcium hardness of the water to be treated flowing into the treatment apparatus 2 can be used. The calcium hardness of the water to be treated flowing into the water treatment device 2 acquired by the calcium hardness measurement sensor, the calcium hardness of the water to be treated flowing into the water treatment device 2 and the ability to remove the cation ion exchange resin 23, which were examined in advance. By using the relationship information that defines the relationship, the flow rate of the water to be treated to be branched into the branch flow path 220 can be determined. The first flow rate adjustment valve 22 can be controlled to a predetermined opening according to the flow rate of the water to be treated determined by this method. In this case, the opening degree of the first flow rate valve 22 can be controlled in real time. The opening degree of the first flow rate adjustment valve 22 can be controlled by a control unit (not shown) provided in the water treatment device 2. The arrangement position of the calcium hardness measurement sensor is not limited to the branch flow path 220, and may be provided upstream of the cation ion exchange resin 23 in the main flow path 200. Further, the data format of the relationship information may be a data table or a graph.

  As another method, the calcium hardness of the water to be treated flowing into the anion exchange resin 24 is directly measured using a calcium hardness measurement sensor disposed between the connection position B in the main channel 200 and the anion exchange resin 24. A detection method may be used. The calcium hardness of the water to be treated flowing into the anion ion exchange resin 24 obtained by the calcium hardness measurement sensor, and the calcium hardness of the water to be treated flowing into the water treatment device 2 and the removal of the cation ion exchange resin 23, which were examined in advance. By using the relationship information that defines the relationship with the performance, it is possible to determine the flow rate of water to be treated that branches into the branch flow path 220. The first flow rate adjustment valve 22 can be controlled to a predetermined opening according to the flow rate of the water to be treated determined by this method. Thereby, the opening degree of the first flow rate valve 22 can be controlled in real time. The opening degree of the first flow rate adjustment valve 22 can be controlled by a control unit (not shown) provided in the water treatment device 2. Note that the data format of the relationship information may be a data table or a graph.

The first flow rate adjusting valve 22 is set to a predetermined opening degree by the above setting method, and the water to be treated having a predetermined flow rate is branched into the branch flow channel 220 from the main flow channel 200, thereby allowing the anion ion exchange resin 24 to flow. The calcium hardness of the water to be treated that flows in can be made the same as the target calcium hardness. In other words, the calcium hardness of the ion exchange treated water can be made the same as the target calcium hardness.
A protective film derived from calcium contained in the ion exchange treated water is formed inside a pipe or the like through which the ion exchange treated water adjusted in hardness passes. Thereby, corrosion of piping etc. can be controlled effectively.

  The water treatment apparatus according to this embodiment has the following effects (a) to (c). (A) As described above, the ion exchange treatment is a treatment for reducing scale components and corrosion components contained in the water to be treated. Therefore, scale failure and corrosion failure can be suppressed in piping or the like through which ion-exchange treated water generated by the water treatment apparatus according to this embodiment flows. (B) By the ion exchange treatment in the water treatment apparatus according to the present embodiment, ion exchange treated water having a desired calcium hardness can be generated. Therefore, a protective film derived from calcium contained in the ion exchange treated water is formed in a pipe or the like through which the ion exchange treated water whose hardness is adjusted flows. Thereby, corrosion of piping etc. can be controlled effectively. (C) Since water to be treated branches and flows from the main flow path 200 to the branch flow path 220, the amount of water to be treated in the anion ion exchange resin 24 is larger than that in the cation ion exchange resin 23. Therefore, the amount of hydroxide ions released during ion exchange in the anion ion exchange resin 24 is larger than the hydrogen ions released during ion exchange in the cation ion exchange resin 23, and the ion exchange treated water is basic. Will be presented. Thereby, corrosion of metal piping, especially galvanized steel pipe can be suppressed.

(About the deoxygenation device 3)
With reference to FIG. 3, the structure of a deoxygenation apparatus and a cooling water circulation system is demonstrated. FIG. 3 is a schematic configuration diagram of a deoxygenation apparatus and a cooling water circulation system in the present embodiment. The white arrow shown in FIG. 3 shows the direction through which the deoxidized water used for the deoxygenation process in the deoxygenation apparatus 3 flows. The arrows shown in FIG. 3 indicate the direction in which the cooling water flowing through the circulation pipe 9 flows. The cooling water circulation system 6 includes a facility 5 to be cooled, a water storage tank 7, a circulation pump 8, a fourth flow rate adjustment valve 92, a cooler 4, and a circulation pipe 9 that connects these devices. The water storage tank 7 stores cooling water for cooling the cooling target facility 5. The circulation pump 8 generates power for sending cooling water from the water storage tank 7 to the cooling target facility 5. The flow rate of the cooling water carried by the circulation pump 8 is determined by the opening degree of the fourth flow rate adjustment valve 92. The cooler 4 cools the cooling water whose temperature has risen by cooling the facility 5 to be cooled. In addition, as the object 5 to be cooled, a press molding machine or the like is exemplified.

  The deprocessing apparatus 3 is connected to a branch pipe 910 that branches from the second flow path branch point C located between the circulation pump 8 and the fourth flow rate adjustment valve 92 in the circulation pipe 9. The branch pipe 910 is provided with a third flow rate adjustment valve 91 that adjusts the flow rate of the deoxidized water that branches into the branch pipe 910. The deoxygenation device 3 reduces the dissolved oxygen concentration in the deoxygenated treated water that branches into the branch pipe 910.

  The water storage tank 7 stores therein the cooling water circulated in the cooling water circulation system 6 and the deoxygenated water whose dissolved oxygen concentration is reduced by the deoxygenation treatment in the deoxygenation device 3. The deoxygenated treated water stored in the water storage tank 7 is carried to the deoxygenation device 3 and the cooling target equipment 5 by operating the circulation pump 8. The flow rate of the cooling water conveyed from the circulation pump 8 to the cooling target facility 5 and the flow rate of the deoxygenated treated water conveyed from the circulation pump 8 to the deoxygenation device 3 are respectively the third flow rate adjustment valve 91 and the fourth flow rate adjustment. It is adjusted by controlling the opening degree of the valve 92.

  With reference to FIG. 3 and 4, the structure of a deoxygenation apparatus is demonstrated in detail. FIG. 4 is an enlarged view in which a region D surrounded by an alternate long and short dash line in FIG. 3 is enlarged. The deoxygenation device 3 includes a deoxygenated treated water spray unit 31, a gas-liquid contact tower 32, and a degassed gas supply unit 33.

  The deoxygenated treated water spraying unit 31 is connected to the sprinkling connection pipe 311 connected to the branch pipe 910 and the sprinkling connection pipe 311, and sprays the deoxygenated treated water in the form of a fine mist in the sealed space 321. Nozzle portion 312. The spray nozzle unit 312 is fixed to the gas-liquid contact tower 32 by a spray nozzle fixing member (not shown) in a state of being inserted into the gas-liquid contact tower 32 described later. By spraying the deoxygenated water from the spray nozzle unit 312 in a mist state, the contact area of the degassed gas and the deoxygenated water filled in the gas-liquid contact tower 32 can be increased.

  The gas-liquid contact tower 32 has a container shape with an open lower end, and at least the lower end is submerged below the water surface 323 of the deoxidized treated water to be treated to form a sealed space 321 inside. Specifically, referring to FIGS. 3 and 4, the gas-liquid contact tower 32 is filled with degassed gas, and all of the gas-liquid contact tower 32 is stored in the water tank 7 to be deoxygenated. It is immersed in treated water and fixed to the water storage tank 7 by a contact tower fixing member (not shown). By fixing the gas-liquid contact tower 32 to the water storage tank 7 in this way, a water surface 323 of deoxidized treated water is formed below the gas-liquid contact tower 32, and the inside of the gas-liquid contact tower 32 is sealed space 321. And With this configuration, when the degassed gas is excessively accommodated in the gas-liquid contact tower 32 and the pressure in the gas-liquid contact tower 32 increases, the deoxygenated treated water formed below the gas-liquid contact tower 32 The water surface 323 can be pushed downward, and the pressure in the gas-liquid contact tower 32 can be prevented from rising excessively. The gas-liquid contact tower 32 has been described as being submerged in the cooling water stored in the water tank 7, but only a part of the gas-liquid contact tower 32 is submerged in the water tank 7. Also good.

  Here, referring to FIG. 4, an exhaust opening 322 for exhausting the gas in the sealed space 321 to the outside of the gas-liquid contact tower 32 is provided in the lower part of the peripheral wall of the gas-liquid contact tower 32, It is preferable to set the liquid level of the deoxidized treated water at a level higher than the exhaust opening 322. With this configuration, a sealed space 321 is formed in the gas-liquid contact tower 32, and degassed gas that has absorbed dissolved oxygen in the deoxygenated treated water can be discharged from the exhaust opening 322. Further, in order to discharge the degassed gas in the gas-liquid contact tower 32 only from the exhaust opening 322, the degassed gas discharged to the outside of the gas-liquid contact tower 32 is increased by increasing the bubble diameter of the degassed gas. The deoxygenated treated water stored in the water storage tank 7 can be floated on the water surface. With this configuration, the degassing gas bubbles are prevented from flowing into the circulation pump 8 that circulates the deoxygenated water stored in the water tank 7 to the cooling target facility 5 and the like, and the circulation pump 8 is damaged. Can also be prevented.

  The degassing gas supply unit 33 includes a degassing gas generation unit 331 and a degassing gas supply pipe 332. The degassing gas generation unit 331 is a device that generates degassing gas, and includes, for example, a gas cylinder filled with degassing gas. The degassing gas supply pipe 332 is connected to the supply port of the degassing gas generation section 331 with one end connected to the gas-liquid contact tower 32 and the other end is inserted into the gas-liquid contact tower 32 by gas-liquid contact by an air supply pipe fixing member (not shown). Fixed to the tower 32. As the degassing gas generated by the degassing gas generation unit 331, for example, an inert gas such as nitrogen gas can be used.

  With the above-described configuration, the deoxygenation device 3 according to the present embodiment is configured to spray the deoxygenated water in a state where the gas-liquid contact tower 32 is filled with the degassed gas generated by the degassed gas generation unit 331. By spraying 312 in the form of a mist, the water droplet diameter of the deoxidized treated water is reduced. Thereby, since the surface area of the water droplet per the same amount of water becomes large and the contact area with the degassed gas also becomes large, the dissolved oxygen concentration in the deoxidized treated water can be lowered. In addition, it is preferable that the dissolved oxygen concentration in the to-be-deoxygenated water after the deoxygenation process is performed by the deoxygenation apparatus 3 is 1 (mg / L) or less.

  Further, the deoxygenation device 3 of the present embodiment is stored in the water storage tank 7 in order to bring the deoxygenated treated water into contact with the degassed gas while the gas-liquid contact tower 32 is filled with the degassed gas. No degassed bubbles are generated in the deoxidized water. For this reason, the possibility that the degassed gas in the gas-liquid contact tower 32 reaches the circulation pump 8 that circulates in the cooling water circulation system 6 as bubbles is low, so that the occurrence of cavitation can be suppressed.

  A deoxygenation method using the deoxygenation apparatus 3 and a cooling method using the cooling water circulation system 6 in this embodiment will be described. In the initial state, it is assumed that the gas-liquid contact tower 32 is filled with degassed gas, and a predetermined amount of deoxygenated water is stored in the water storage tank 7. Further, it is assumed that the third flow rate adjusting valve 91 and the fourth flow rate adjusting valve 92 are adjusted to the open state.

  The deoxygenated water stored in the water tank 7 flows into the circulation pipe 9 and is sent to the second flow path branch point C by the circulation pump 8. Of the deoxidized treated water sent to the second flow path branch point C, the deoxidized treated water having a flow rate corresponding to the opening of the third flow rate adjusting valve 91 branches into the branch pipe 910 and deoxygenated. Continuously fed to the apparatus 3, deoxygenated treated water (cooling water) having a flow rate corresponding to the opening of the fourth flow rate adjustment valve 92 flows through the circulation pipe 9 and continuously into the cooling target equipment 5. The liquid is sent. The deoxygenated treated water sent to the deoxygenation device 3 passes through the spray connection pipe 311 and is sprayed into the gas-liquid contact tower 32 from the spray nozzle unit 312 in the form of a mist. The dissolved oxygen contained in the deoxygenated water sprayed in the form of mist is absorbed by the degassed gas in the gas-liquid contact tower 32 and falls to the water surface 323 of the deoxygenated water. Moreover, a part of the deoxidized oxygen treatment water sprayed in the form of mist adheres to the inner wall surface of the gas-liquid contact tower 32, travels along the inner wall surface of the gas-liquid contact tower 32, and is subjected to the deoxidized treated water. The dissolved oxygen is absorbed by the degassing gas until it falls to the water surface 323. As described above, the oxygen dissolved in the deoxygenated water sprayed in the form of mist by the spray nozzle unit 312 is absorbed by the degassed gas stored in the gas-liquid contact tower 32, so that the water is stored in the water storage tank 7. The dissolved oxygen concentration in the deoxidized treated water is reduced.

  The degassing gas generator 331 continuously supplies the degassing gas into the gas-liquid contact tower 32 via the degassing gas supply pipe 332. With the supply of the degassed gas from the degassed gas generator 331, the degassed gas that has absorbed the oxygen dissolved in the deoxidized water moves to the lower side of the gas-liquid contact tower 32 and is discharged from the exhaust opening 322. It is discharged out of the liquid contact tower 32. With this configuration, the degassing gas in the gas-liquid contact tower 32 can be maintained in a fresh state at all times, and the deoxygenation treatment with the degassing gas in the gas-liquid contact tower 32 can be continued.

  On the other hand, the deoxygenated treated water (cooling water) sent to the cooling target facility 5 is heated by receiving the heat in the cooling target facility 5. The heated cooling water is sent to the cooler 4 by the circulation pump 8 and cooled.

  As described above, the deoxygenated treated water sprayed from the spray nozzle unit 312 and the cooling water (deoxygenated treated water) cooled by the cooler 4 are stored in the water storage tank 7. The deoxygenated water stored in the water tank 7 is continuously sent again to the deoxygenation device 3 and the cooling target facility 5 by the circulation pump 8 again.

  In this way, the dissolved oxygen concentration of the deoxygenated water stored in the water tank 7 by the deoxygenation device 3 is lowered, and the deoxygenated water (cooling water) having a low dissolved oxygen concentration is used as the cooling water circulation system 6. It is possible to prevent corrosion of the devices and pipes (the cooler 4, the cooling target equipment 5, the water tank 7, and the circulation pipe 9) that constitute the cooling water circulation system 6 by circulating in the water. Further, by suppressing the corrosion of these devices and piping, it is possible to prevent the iron oxide from being dissolved in the deoxidized water and causing water pollution (red water generation or the like).

As described above, since the ion exchange treatment is a treatment for reducing scale components and corrosion components contained in the water to be treated, piping through which the ion exchange treatment water generated in the water treatment apparatus according to this embodiment passes. The scale failure and the corrosion failure can be suppressed.
Moreover, the ion exchange treatment water which has desired calcium hardness can be produced | generated by the ion exchange process in the water treatment apparatus which concerns on this embodiment. Therefore, a protective film derived from calcium contained in the ion exchange treated water is formed in a pipe or the like through which the ion exchange treated water whose hardness is adjusted flows. Thereby, corrosion of piping etc. can be controlled effectively.
Furthermore, since the water treatment system 1 includes the water treatment device 2 and the deoxygenation device 3, the concentration of dissolved oxygen dissolved in the deoxidized water can be reduced in the deoxygenation device 3 (deoxygenation treatment). . Therefore, corrosion of the apparatus and piping (in this embodiment, the apparatus and piping constituting the cooling water circulation system 6) through which the deoxidized treated water (cooling water) flows can be more effectively prevented, and these It is possible to prevent oxidation of the apparatus and piping.

(Modification 1)
In the present embodiment, the first flow rate adjustment valve 22 is disposed in the branch flow path 220, but is not limited thereto, and may be any arrangement that can control the flow rate of water to be treated flowing into the branch flow path 220. For example, it may be arranged at the first flow path branch point A.

(Modification 2)
In the present embodiment, the replacement timing of the cation ion exchange resin and the anion ion exchange resin included in the water treatment apparatus is based on the time when the integrated flow rate of the water to be treated flowing through the main channel 200 reaches a predetermined value. However, the present invention is not limited to this, and other criteria may be set. For example, when the pH of the ion-exchanged water detected by the pH sensor reaches a predetermined value, the reference may be when the concentration of any ion detected by the ion concentration sensor reaches the predetermined value. It is good.

(Modification 3)
In the present embodiment, the deoxygenation device 3 sprays the deoxygenated water in a mist form by the spray nozzle unit in a state where the gas-liquid contact tower is filled with the degassed gas generated by the degassed gas generating unit. Although it is an apparatus which performs a deoxygenation process by a method, it is not restricted to this, It can replace by the other well-known apparatus which performs a deoxygenation process. However, the dissolved oxygen concentration in the deoxidized water after the deoxygenation treatment is preferably 1 (mg / L) or less.

(Modification 4)
In the present embodiment, the ion exchange treated water discharged from the water treatment device flows into the deoxygenation device via the water storage tank, but the present invention is not limited to this, and the ion exchange treatment water directly flows into the deoxygenation device. It may be the composition to do.

(Modification 5)
In the present embodiment, the water treatment system includes a water treatment device and a deoxygenation device that performs deoxygenation treatment on the ion exchange treated water generated by the water treatment device, and further flows into the water treatment device. You may provide the solid filter (not shown) which processes the solid substance and foreign material which are contained in to-be-processed water. Thereby, since it can prevent that a solid substance and a foreign material mix in deoxygenated treated water, it becomes harder to be damaged inside piping, a device, etc. which constitute cooling system 100.

(Modification 6)
In the present embodiment, the deoxygenated water to be treated by the deoxygenation device 3 branches from the circulation pipe 9 and passes through the branch pipe 910 that connects to the spray connection pipe 311 of the deoxygenation apparatus 3, and is desorbed. The solution is sent to the oxygen device 3, but is not limited to this, and it is sufficient that the deoxidized water is sent to the deoxygenation device 3. For example, a deoxygenated treated water supply pipe (not shown) having one end connected to the water storage tank 7 and the other end connected to the deoxygenation device 3 may be disposed. In this case, a fifth flow rate adjustment valve (not shown) is disposed in the deoxygenated water supply pipe, and the deoxygenation treatment is sent to the deoxygenation device 3 depending on the opening of the fifth flow rate adjustment valve. It is preferred that the water flow rate be determined.

DESCRIPTION OF SYMBOLS 1 Water treatment system 2 Water treatment apparatus 3 Deoxygenation apparatus 4 Cooler 5 Cooling target equipment 6 Cooling water circulation system 7 Water tank 20 Inflow valve 21 Pressure reducing valve 22 First flow control valve 23 Cation ion exchange resin 24 Anion ion exchange resin 25 2 Flow adjustment valve 26 Discharge valve 27 Flow meter 28 Control panel 29 Pressure release valve 100 Cooling system 200 Main flow path 220 Branch flow path

Claims (6)

A water treatment device that generates ion exchange treated water by performing ion exchange treatment on water to be treated,
A main channel through which water to be treated flows;
A cation ion exchange resin disposed in the main channel;
An anion ion exchange resin disposed downstream of the cation ion exchange resin in the main channel;
A branch flow path branched from the upstream of the cation ion exchange resin in the main flow path and connected to a connection position between the cation ion exchange resin and the anion ion exchange resin in the main flow path;
A flow rate adjustment valve for adjusting the flow rate of the water to be treated flowing through the branch flow path,
The calcium hardness of the water to be treated flowing into the anion ion exchange resin by setting the flow rate adjusting valve to a predetermined opening and allowing the water to be treated at a predetermined flow rate to flow from the branch flow path into the main flow path. Is the same as the target calcium hardness ,
When the calcium hardness of the water to be treated flowing into the anion ion exchange resin is small with respect to the target calcium hardness, the flow rate of the water to be treated flowing through the main channel is decreased and flows into the branch channel. To increase the flow rate of the water to be treated, increase the opening of the flow rate adjustment valve,
When the calcium hardness of the water to be treated flowing into the anion ion exchange resin is larger than the target calcium hardness, the flow rate of the water to be treated flowing through the main channel is increased and flows into the branch channel. The water treatment apparatus is characterized in that the opening of the flow rate adjustment valve is reduced so as to reduce the flow rate of the water to be treated .   The water treatment device according to claim 1, wherein the target calcium hardness is set to 20 to 50 (mg / L). The water treatment device according to claim 1 or 2,
A water treatment system comprising: a deoxygenation device that performs deoxygenation treatment on ion exchange treated water discharged from the water treatment device. The oxygen scavenger is
A gas-liquid contact tower having a container shape with an open lower end, at least a lower end submerged below the surface of the ion-exchange treated water to be treated, and forming a sealed space inside,
A degassing gas supply unit for supplying degassing gas into the sealed space and filling the sealed space with the degassed gas;
The water treatment system according to claim 3, further comprising: a deoxygenated treated water spraying unit that sprays the supplied ion exchange treated water in the sealed space in a mist form by a spraying nozzle unit. 5. The water treatment system according to claim 4 , wherein the dissolved oxygen concentration of the ion exchange treated water after the deoxygenation treatment by the deoxygenation device is 1 (mg / L) or less. The water treatment system according to claim 4 or 5 ,
A cooling water circulation system for circulating cooling water for cooling the cooling target equipment,
The cooling water circulation system includes: a water storage tank that stores the ion exchange treated water discharged from the water treatment device; and the ion storage treated water stored in the water storage tank as cooling water. A circulation pipe that circulates between, and a cooler that cools cooling water from the facility to be cooled toward the water storage tank via the circulation pipe,
The gas-liquid contact tower is installed in the water storage tank.