JP2018012069A - Water treatment system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a water treatment system capable of efficiently producing water from which ions of two or higher valences are selectively removed.SOLUTION: There is provided the water treatment system that removes ions of two or higher valences from seawater containing at least monovalent ions and ions of two or higher valences, the concentration of the ions of two or higher valences being lower than that of the monovalent ions. The system comprises: a reverse osmosis membrane unit 10 that is supplied with seawater and comprises a reverse osmosis membrane 1 for selectively removing the ions of two or higher valences in the seawater; a booster pump 41 for pressurizing the seawater to permeate the reverse osmosis membrane 1; another reverse osmosis membrane unit 20 that is supplied with water having permeated the reverse osmosis membrane 1 and comprises a reverse osmosis membrane 2 having the same performance as the reverse osmosis membrane 1; and a booster pump 42 for pressurizing the water to permeate the reverse osmosis membrane 2.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a water treatment system.

  As a method of recovering crude oil from the formation, there is known an enhanced oil recovery method in which water is injected into the formation from which the crude oil is extracted. As the water to be injected, water from which divalent ions such as sulfate ions have been removed (injected water) is used from the viewpoint of preventing the formation of scale due to calcium ions, strontium ions and the like in the formation. Therefore, it is important how to obtain the injected water efficiently.

  In this regard, when an oil collection facility exists in a place where fresh water or the like is easily available, the fresh water can be used as injection water. However, in marine oil fields, for example, seawater containing a large amount of divalent ions such as sulfate ions can be easily obtained, but it is not easy to obtain water from which such divalent ions have been removed. Therefore, a technique for efficiently producing water from which divalent ions have been removed is desired particularly in such an environment.

  A technique described in Patent Document 1 is known as a technique for removing ions from seawater. Patent Document 1 describes a technique for reducing ion content including a scale component by filtering salt water through a nanofiltration membrane. Then, the nanofiltrated water is separated and separated into an upstream nanofiltrated water having a lower salt concentration and a downstream nanofiltrated water having a higher salt concentration, and the upstream nanofiltrated water is led to a semipermeable membrane. It is described.

JP 2008-200209 A

  In the technique described in Patent Document 1, as shown in FIG. 4 in particular, the permeated water generated in the nanofiltration membrane (first-stage nanofiltration membrane unit 21) is converted into a reverse osmosis membrane (first-stage reverse osmosis membrane unit 31). ). On the other hand, the concentrated water produced | generated in the said nanofiltration membrane is supplied to the nanofiltration membrane (2nd step | paragraph nanofiltration membrane unit 22) different from the said nanofiltration membrane. Further, the permeated water generated in the nanofiltration membrane (second-stage nanofiltration membrane unit 22) is supplied to the “thermal distillation unit 40”. In the “thermal distillation unit 40”, fresh water is produced using the supplied permeate.

  When such a system is used, fresh water from which all ions have been removed can be obtained, but water from which only specific ions (divalent ions) have been selectively and efficiently removed cannot be obtained. In particular, the second stage nanofiltration membrane (second stage nanofiltration membrane unit 22) is obtained because the concentrated water in the first stage nanofiltration membrane (first stage nanofiltration membrane unit 21) is filtered. The amount of permeated water is small. Therefore, the technique described in Patent Document 1 cannot efficiently produce “water from which divalent ions are selectively removed” suitable as, for example, injection water.

  The present invention has been made in view of such problems, and the problem to be solved by the present invention is to provide a water treatment system capable of efficiently producing water from which divalent ions have been selectively removed. That is.

  As a result of intensive studies to solve the above problems, the present inventors have found that the above problems can be solved by the following. That is, the gist of the present invention is to remove the divalent ions from the water to be treated which contains at least monovalent ions and divalent ions, and the concentration of the divalent ions is lower than the concentration of the monovalent ions. In the water treatment system, the first reverse osmosis membrane unit including the first reverse osmosis membrane to which the water to be treated is supplied and selectively removing the divalent ions in the water to be treated; A first pressurizing device that applies pressure to permeate the treated water through the osmosis membrane, and permeated water obtained by permeating the first reverse osmosis membrane are supplied. A second reverse osmosis membrane unit having a second reverse osmosis membrane having the same filtration characteristics as the reverse osmosis membrane, and a second pressurization for applying a pressure for allowing the permeate to permeate the second reverse osmosis membrane And a water treatment system comprising: On-time.

  According to the present invention, it is possible to provide a water treatment system capable of efficiently producing water from which divalent ions have been selectively removed.

It is a distribution diagram showing the composition of the water treatment system of a first embodiment. It is a systematic diagram which shows the structure of the water treatment system of 2nd embodiment. It is a systematic diagram which shows the structure of the water treatment system of 3rd embodiment. It is a systematic diagram which shows the structure of the water treatment system of 4th embodiment. It is a systematic diagram which shows the structure of the water treatment system of 5th embodiment. It is a systematic diagram which shows the structure of the water treatment system of 6th embodiment. It is a systematic diagram which shows the structure of the water treatment system of 7th embodiment. It is a systematic diagram which shows the structure of the water treatment system of 8th embodiment.

  Hereinafter, a form for carrying out the present invention (this embodiment) will be described with reference to the drawings as appropriate. For convenience of explanation, first, a basic configuration will be described with reference to FIG. 1, and then a specific configuration using the basic configuration will be described with reference to FIGS. 2 to 8. In the drawings, the same reference numerals are given to the same devices and the like, and the second and subsequent detailed descriptions are omitted for the sake of simplicity.

  FIG. 1 is a system diagram showing a configuration of a water treatment system 100 of the first embodiment. The water treatment system 100 is generated in the reverse osmosis membrane unit 10 that selectively removes divalent ions in the supplied seawater (water to be treated containing at least monovalent ions and divalent ions). And a reverse osmosis membrane unit 20 that selectively removes divalent ions remaining in the permeated water. Among these, the reverse osmosis membrane units 10 and 20 each include a plurality of reverse osmosis membranes 1 and 2 having the same filtration characteristics. Therefore, in the processing system 100 of the first embodiment, the reverse osmosis membrane 1 provided in the reverse osmosis membrane unit 10 and the reverse osmosis membrane 2 provided in the reverse osmosis membrane unit 20 are of the same type.

  The reverse osmosis membranes 1 and 2 (semi-permeable membranes) provided in the reverse osmosis membrane units 10 and 20 selectively remove divalent ions as described above, and so-called “nanofiltration membrane (NF)” or the like. It is also called. Here, the divalent ions are divalent cations such as calcium ions and magnesium ions, and divalent anions such as sulfate ions and carbonate ions. In the reverse osmosis membranes 1 and 2 provided in the reverse osmosis membrane units 10 and 20, the bivalent ion removal rate as described above is about 90% or more. On the other hand, the removal rate of ions other than divalent ions (for example, monovalent ions such as sodium ions, potassium ions, chloride ions) contained in seawater is about 10% to 50%. In addition to the monovalent ions and divalent ions described above, seawater may contain trivalent or higher ions, but the content of trivalent or higher ions is very small, and trivalent or higher ions are Since it is removed in the same manner as the valence ion, the description about the trivalent or higher ion is omitted in the following description.

  In addition, “same filtration characteristics” (that is, the same “specification”) means that the types of ions to be removed are the same, and the removal rate of the ions is about the same (when the same ion is added) , Including those that differ by several percent to several tens of percent) are said to have the same filtration characteristics. Therefore, even if the types of reverse osmosis membranes (manufacturer, material, model number, etc.) are different, they are included in the scope of the present invention as long as they have the same filtration characteristics as described above.

  As described above, the reverse osmosis membrane units 10 and 20 are provided with the reverse osmosis membranes 1 and 2, respectively. The reverse osmosis membrane unit 10 has the reverse osmosis membrane 1 accommodated in a pressure vessel (vessel) (not shown), and the reverse osmosis membrane unit 20 has the reverse osmosis membrane 2 accommodated in a pressure vessel (not shown). Composed. In the water treatment system 100, the contact area between the reverse osmosis membrane 1 and seawater in the reverse osmosis membrane unit 10 is the same as the contact area between the reverse osmosis membrane 2 and the permeated water in the reverse osmosis membrane unit 20. Yes. Specifically, in the water treatment system 100 of the first embodiment, the number of reverse osmosis membrane modules and the number of pressure vessels provided in the reverse osmosis membrane units 10 and 20 are the same. Thereby, when processing the seawater in which the density | concentration of a bivalent ion is enough low also with the density | concentration of a monovalent ion, the advantage that it is easy to make both the reverse osmosis membrane units 10 and 20 into the same pressure is acquired.

  Next, the flow of water in the water treatment system 100 will be described. Seawater taken from the ocean or the like (not shown) is supplied to the reverse osmosis membrane unit 10 through the seawater supply system 31. The reverse osmosis membrane unit 10 is also supplied with concentrated water generated by the reverse osmosis membrane unit 20 as will be described in detail later. At this time, the seawater is pressurized by a pressurizing pump 41 provided in the middle of the seawater supply system 31. The pressurizing pump 41 is inverter-controlled, and the flow rate of seawater (and mixed water of the concentrated water) supplied to the reverse osmosis membrane unit 10 can be controlled by changing the frequency of the inverter. It has become.

  The pressurized seawater is separated in the reverse osmosis membrane unit 10 into permeate generated by permeating the reverse osmosis membrane 1 and concentrated water not permeating the reverse osmosis membrane 1. The permeated water produced here contains almost no divalent ions, whereas the produced concentrated water contains a large amount of divalent ions. Among these, the concentrated water is returned to the ocean or the like through the concentrated water drainage system 34.

  On the other hand, the permeated water generated by the reverse osmosis membrane unit 10 is supplied to the subsequent reverse osmosis membrane unit 20 through the permeated water supply system 32. The permeated water supply system 32 includes a pressurizing pump 42 that boosts the permeated water, and the permeated water boosted by the pressurizing pump 42 is supplied to the reverse osmosis membrane unit 20. The pressurizing pump 42 has the same configuration as the pressurizing pump 41 described above, and the flow rate of the permeated water supplied to the reverse osmosis membrane unit 20 is controlled by controlling the inverter frequency of the pressurizing pump 42. It is controllable. In the reverse osmosis membrane unit 20, permeated water and concentrated water can be obtained by the reverse osmosis membrane 2 provided in the same manner as the reverse osmosis membrane unit 10. In the permeated water obtained here, divalent ions such as sulfate ions are sufficiently removed by the reverse osmosis membrane unit 20 and the reverse osmosis membrane unit 10. Therefore, the permeated water generated by the reverse osmosis membrane unit 20 is discharged to the outside through the press-fit water supply system 33 and used as press-fit water.

  Further, the concentrated water generated by the reverse osmosis membrane unit 20 is returned to the front stage of the pressurizing pump 41 in the seawater supply system 31 through the concentrated water return system 35 without being discharged to the outside. The returned concentrated water is pressurized together with seawater by the pressurizing pump 41 and then supplied to the reverse osmosis membrane unit 10.

  As shown in FIG. 1, in the water treatment system 100, reverse osmosis membranes 1 and 2 having the same filtration characteristics are used. These are used to remove divalent ions such as sulfate ions from seawater. Here, in the reverse osmosis membranes 1 and 2 that selectively remove divalent ions, only the osmotic pressure and filtration pressure related to the removal of the divalent ions need be considered. Therefore, a reverse osmosis membrane intended for removal of all ions is used, and the pressure is increased by the pressurization pumps 41 and 42 as compared with the case where the ion concentration changes significantly after the treatment before the treatment by the reverse osmosis membrane. The pressure can be reduced. Specifically, both can be set to the same pressure, for example, about 1 MPa to 3 MPa. Therefore, energy saving can be improved.

  In particular, in seawater, the concentration of divalent ions such as sulfate ions is lower than the concentration of monovalent ions such as sodium ions and chloride ions. In particular, it is preferable that the concentration of divalent ions is sufficiently lower than the concentration of monovalent ions. Specifically, the divalent ion concentration is, for example, 1/3 or less, preferably 1/5 or less, more preferably 1/10 or less, even more preferably 1/15 or less, particularly preferably the concentration of monovalent ions. 1/20 or less.

  In addition to monovalent ions and divalent ions, the seawater may contain trivalent or higher ions such as trivalent ions as described above. And trivalent or higher ions are also removed in the reverse osmosis membrane units 10 and 20 in the same manner as divalent ions. Therefore, when trivalent or higher ions are included, the total concentration of divalent ions and trivalent or higher ions (the concentration of divalent or higher ions as ions having a bivalent or higher valence) is It is preferable that the above range is satisfied with respect to the concentration of monovalent ions.

  When seawater is treated in the water treatment system 100, since the concentration of divalent ions is low even after almost all divalent ions such as sulfate ions are removed in the reverse osmosis membrane unit 10, the entire salt by removing divalent ions is used. The concentration of is almost unchanged. Therefore, the pressure boosted by the pressurizing pump 41 and the pressure boosted by the pressurizing pump 42 can be made almost the same pressure. And the concentrated water produced | generated in the reverse osmosis membrane unit 20 has a pressure substantially the same as the pressure pressure | voltage-risen by the pressurization pump 41. FIG. Therefore, since the pressurizing pump 41 is driven so that the seawater merged with the concentrated water having a high pressure has the same pressure as that of the concentrated water that has been merged, the amount of pressure increase can be reduced. Can be increased.

  In addition, although divalent ions in seawater are removed by both the reverse osmosis membrane units 10 and 20, most of the divalent ions are removed particularly by the reverse osmosis membrane unit 10 in the first stage. Therefore, the amount of divalent ions removed in the second-stage reverse osmosis membrane unit 20 is reduced, and therefore the concentration of divalent ions in the concentrated water generated in the reverse osmosis membrane unit 20 is also reduced. Therefore, such concentrated water having a low divalent ion concentration can be returned to seawater, and thus energy saving can be improved.

  Furthermore, the permeated water after removing most of the divalent ions in the reverse osmosis membrane unit 10 is treated again in the reverse osmosis membrane unit 20, so that the divalent ions can be more reliably removed. In particular, in the second-stage reverse osmosis membrane unit 20, since the content of divalent ions to be removed is small, it can be removed sufficiently, and the amount of permeate to be supplied is large, so reverse osmosis. The amount of permeated water obtained from the membrane 20 also increases. Therefore, for example, efficient production of press-fit water can be performed.

  FIG. 2 is a system diagram showing the configuration of the water treatment system 200 of the second embodiment. Hereinafter, a specific configuration using the basic configuration of FIG. 1 will be described with reference to FIG. The water treatment system 200 shown in FIG. 2 includes high pressure pumps (HPP) 43 and 44 that provide a reverse osmosis membrane unit high pressure as a specific example of the pressure pumps 41 and 42. In the middle of the seawater supply system 31, there is provided a tank 51 for storing seawater taken from the ocean or the like and supplying concentrated water returned from the reverse osmosis membrane unit 20. Furthermore, in the middle of the water supply system 32, a tank 52 for storing the permeated water generated in the reverse osmosis membrane unit 10 is provided. The concentrated water discharge system 34 includes a flow rate control valve 61 that controls the flow rate of the permeated water supplied to the reverse osmosis membrane unit 20 by controlling the flow rate of the concentrated water discharged from the reverse osmosis membrane unit 10. Is provided. Therefore, the flow rate of the permeated water supplied to the reverse osmosis membrane unit 20 is controlled by the flow rate control valve 61 and the high-pressure pump 44. The concentrated water return system 35 is provided with a flow rate control valve 62 that controls the flow rate of the concentrated water that is generated and returned in the reverse osmosis membrane unit 20.

  In the water treatment system 200, since the two tanks 51 and 52 are provided, the pressure and flow rate of seawater or permeate supplied to the reverse osmosis membrane units 10 and 20 can be arbitrarily set. Specifically, since the seawater and the returned concentrated water are once stored in the tank 51, the tank 51 is not affected by the upstream pressure or flow rate. Therefore, the mixed water of the seawater and the concentrated water once stored in the tank 51 is supplied to the reverse osmosis membrane unit 10 at a desired flow rate after being given a desired pressure by the high-pressure pump 43. At this time, the flow rate of the mixed water supplied to the reverse osmosis membrane unit 10 is controlled by the flow rate control valve 61 and the high-pressure pump 43 provided on the concentrated water side of the reverse osmosis membrane unit 10. The same applies to the permeated water supplied to the reverse osmosis membrane unit 20. That is, the permeated water once stored in the tank 52 is supplied to the reverse osmosis membrane unit 20 after being given a desired pressure by the high-pressure pump 44.

  In the water treatment system 200, the concentrated water generated in the second reverse osmosis membrane unit 20 as described above is returned to the tank 51. The power source for returning the concentrated water is the high-pressure pump 44 provided in the permeated water supply line 32. Therefore, new power for returning is unnecessary, and the operation cost can be reduced.

  The supply position of the concentrated water returned by the concentrated water return system 35 is the tank 51 in FIG. 2, but may be the seawater supply system 31 and between the tank 51 and the high-pressure pump 43.

  FIG. 3 is a system diagram showing the configuration of the water treatment system 300 of the third embodiment. In the water treatment system 300 shown in FIG. 3, in the water treatment system 200 (see FIG. 2), a permeate bypass that branches from between the reverse osmosis membrane unit 10 and the tank 52 and bypasses the reverse osmosis units 20. A system 36 is provided.

  This permeated water bypass system 36 is connected to the press-fed water supply system 33 on the rear stage side of the reverse osmosis membrane unit 20, so that the permeated water generated by the reverse osmosis membrane unit 10 passes through the permeated water supply system 32. In addition to being supplied to the reverse osmosis membrane unit 20, it is supplied directly to the press-fit water supply system 33 without being supplied to the reverse osmosis membrane unit 20 through the permeate bypass system 36. Note that the flow rate of the permeated water directly supplied to the pressurized water supply system 33 is adjusted by a flow rate control valve 63 provided in the permeated water bypass system 36.

  The water treatment system 300 includes the permeate bypass system 36 as described above. As a result, the permeated water generated in the reverse osmosis membrane unit 10 in which a slight amount of divalent ions remain is mixed with the injected water from which divalent ions such as sulfate ions are almost removed. ing.

  Here, the salt concentration and divalent ion removal efficiency of seawater change depending on the intake position of seawater, the water temperature, and the like. For this reason, if divalent ions are always removed under the same conditions, the quality of the obtained injected water (such as the remaining amount of divalent ions) may change. Therefore, for example, a salt concentration meter (not shown) is attached to the pressure water supply system 33 so that the water quality of the pressure water is substantially constant, and the flow control valve 63 is adjusted based on the value measured by the salt concentration meter. Thus, the divalent ion concentration of the injected water can be adjusted to a desired range. Thereby, although it is preferable that the amount of divalent ions in the injected water is small, it is possible to avoid an excessive operation cost by removing more than necessary, and an energy efficient operation can be performed.

  FIG. 4 is a system diagram showing the configuration of the water treatment system 400 of the fourth embodiment. In the water treatment system 400 shown in FIG. 4, an energy recovery turbine (ERT) 71 that recovers the pressure of the concentrated water generated in the reverse osmosis membrane unit 10 in the water treatment system 200 (see FIG. 2). Is provided. The energy recovery turbine 71 is provided in the concentrated water distribution system 34. The energy recovery turbine 71 is directly connected to the rotary shaft 43 a of the high-pressure pump 43 provided in the seawater supply system 31. Therefore, the drive of the high pressure pump 43 is assisted by the pressure of the concentrated water through the energy recovery turbine 71, and the power consumption of the high pressure pump 43 is suppressed.

  In the example shown in FIG. 4, the energy recovery turbine 71 is directly connected to the rotary shaft 43 a of the high-pressure pump 43, but may be directly connected to the rotary shaft of the high-pressure pump 44 although not shown. That is, the pressure of the concentrated water generated by the reverse osmosis membrane unit 10 is not used for driving assistance of the high pressure pump 43 as shown in FIG. be able to. As described with reference to FIG. 1, the pressure applied by the high pressure pumps 43 and 44 is substantially the same. Therefore, the pressure of the concentrated water can be used not only for the high-pressure pump 43 but also for the high-pressure pump 44 that gives the same pressure.

  Here, the flow rate of seawater that gives pressure by the high-pressure pump 43 and the flow rate of permeate water that gives pressure by the high-pressure pump 44 are smaller in the latter case. Accordingly, the capacity of the high-pressure pump 44 is usually reduced by the amount of pressure applied to the permeated water having a small flow rate. In addition, the drive assist of the small capacity pump is more energy efficient than the assist of driving the large capacity pump. Therefore, the energy efficiency can be further improved by connecting the energy recovery turbine 71 directly to the rotating shaft of the high-pressure pump 44.

  Although not shown, a turbo energy recovery turbine may be installed immediately above or after the high pressure pump 43 or the high pressure pump 44. Thereby, the pressure of seawater or permeated water is directly increased, the output of the high-pressure pump 43 or the high-pressure pump 44 is reduced, and the power consumption can be suppressed.

  FIG. 5 is a system diagram showing a configuration of a water treatment system 500 of the fifth embodiment. In the water treatment system 500 shown in FIG. 5, in the water treatment system 200 (see FIG. 2), the tank 52 that stores the permeate generated in the reverse osmosis membrane unit 10 and the high-pressure pump 44 that applies pressure to the permeate are replaced. A booster pump (BP) 45 that boosts the permeated water is provided.

  Further, the water treatment system 200 or the like includes the tank 52, and the tank 52 functions as a buffer tank at the start of operation, so that the stability at the start of operation is improved. On the other hand, in the water treatment system 500 shown in FIG. 5, since the tank 52 is not provided, the installation area of the tank 52 becomes unnecessary and space saving is achieved. Further, since the pressure of the permeated water generated in the reverse osmosis membrane unit 10 is directly introduced into the booster pump 45, the actual head can be shortened and energy saving can be achieved.

  FIG. 6 is a system diagram showing the configuration of the water treatment system 600 of the sixth embodiment. A water treatment system 600 shown in FIG. 6 includes an energy recovery turbine (ERT) 72 that recovers the pressure of the permeate generated in the reverse osmosis membrane unit 10 in the water treatment system 200 (see FIG. 2). Yes. Similarly to the energy recovery turbine 71, the energy recovery turbine 72 is also directly connected to the rotary shaft 44a of the high pressure pump 44 provided in the permeate supply system 32, so that the power consumption of the high pressure pump 44 is suppressed. .

  In the water treatment system 600, the energy recovery turbine 72 recovers the pressure of the concentrated water generated by the reverse osmosis membrane unit 20. The reverse osmosis membrane unit 20 is supplied with the permeated water after being pressurized by the high-pressure pump 44 as described above. Therefore, the pressure of the concentrated water generated in the reverse osmosis membrane unit 20 is almost the same as the discharge pressure of the high-pressure pump 44 because the pressure loss in the reverse osmosis membrane unit 20 is usually extremely small. Therefore, by collecting the pressure of the concentrated water by the energy recovery turbine 72 and using it for driving assistance of the high-pressure pump 44, the power consumption of the high-pressure pump 44 can be suppressed.

  In the example shown in FIG. 6, the energy recovery turbine 72 is directly connected to the rotating shaft 44 a of the high-pressure pump 44, but not shown, but may be directly connected to the rotating shaft of the high-pressure pump 43. That is, the pressure of the concentrated water generated by the reverse osmosis membrane unit 20 is not used for driving assistance of the high pressure pump 44 as shown in FIG. be able to.

  As described with reference to FIG. 1, the pressure applied by the high pressure pumps 43 and 44 is substantially the same. Therefore, the pressure of the concentrated water can be used not only for the high-pressure pump 44 but also for the high-pressure pump 43 giving the same pressure. The high-pressure pump 43 that applies pressure to a large amount of seawater uses more energy than the high-pressure pump 44 that applies pressure to permeated water having a smaller flow rate than the flow rate of the seawater. Therefore, driving assistance of the high-pressure pump 43 is performed using the pressure of the concentrated water, so that power consumption of the high-pressure pump 43 can be reduced and energy saving can be achieved.

  Although not shown, a turbo energy recovery turbine is installed immediately above or after the high-pressure pump 43 or the high-pressure pump 44 as in the water treatment system 400 described with reference to FIG. May be. Thereby, the pressure of seawater or permeated water is directly increased, the output of the high-pressure pump 43 or the high-pressure pump 44 is reduced, and the power consumption can be suppressed.

  FIG. 7 is a system diagram showing a configuration of a water treatment system 700 according to the seventh embodiment. In the water treatment system 700 shown in FIG. 7, in the water treatment system 200 (see FIG. 2), the concentrated water return system 45 allows the concentrated water to be returned between the high-pressure pump 43 and the reverse osmosis membrane unit 10. Is formed. A booster pump (BP) 46 is provided in the middle of the concentrated water return system 45. In the water treatment system 700, the tank 51 described with reference to FIG. 2 is not provided.

  As described above with reference to FIG. 6, the pressure of the concentrated water generated by the reverse osmosis membrane unit 20 is substantially the same as the discharge pressure of the high-pressure pump 44. And the concentrated water which adjusted the pressure with the pressure | voltage rise pump 46 with respect to the seawater after the pressure was provided with the high pressure pump 43 is supplied. By doing in this way, the amount of seawater to which pressure is given by the high pressure pump 43, that is, the discharge amount from the high pressure pump 43 can be reduced, and energy saving can be achieved.

  FIG. 8 is a system diagram showing the configuration of the water treatment system 800 of the eighth embodiment. In the water treatment system 800 shown in FIG. 8, unlike the water treatment system 200 (see FIG. 2), the tank 52 and the high-pressure pump 44 are not provided. Therefore, in the water treatment system 800, the pressure used for both filtration by the reverse osmosis membrane units 10 and 20 is given to seawater by one high-pressure pump 43.

  As described above, the reverse osmosis membranes 1 and 2 constituting the reverse osmosis membrane units 10 and 20 have the same filtration characteristics. Therefore, in the water treatment system 800, the high-pressure pump 44 is operated such that a pressure twice (approximate) the pressure applied by the high-pressure pump 43 in the water treatment system 200 is applied to the seawater.

  Here, in the water treatment system 800 that selectively removes divalent ions, as described with reference to FIG. 1 and the like, the pressure applied in the reverse osmosis membrane units 10 and 20 Compared to a reverse osmosis membrane that removes ions, it is lower. Therefore, by doubling the applied pressure, even if the load on the reverse osmosis membrane unit 10 is increased, it is within the allowable load range on the reverse osmosis membrane unit 10. Therefore, it is possible to save space by omitting intermediate devices such as the tank 52 and the high-pressure pump 44. Further, the pressure loss can be reduced by omitting the intermediate device. Thereby, the energy efficiency of the whole water treatment system 800 can be improved.

  Although the present invention has been described with the eight embodiments, the present invention is not limited to the above-described embodiments. For example, each of the above-described embodiments does not necessarily have to be configured independently, and can be configured by combining two or more embodiments as appropriate without departing from the spirit of the present invention.

  Specifically, for example, the present invention can be implemented as a water treatment system in which the water treatment system 300 described with reference to FIG. 3 and the water treatment system 500 described with reference to FIG. 5 are combined. More specifically, in the water treatment system 500 shown in FIG. 5, the permeated water bypass system 36 shown in FIG. 3 may be further provided. Other embodiments can also be arbitrarily combined and configured similarly.

  In each of the above embodiments, the permeated water generated by the reverse osmosis membrane unit 20 in the subsequent stage was used as the injection water, but for other applications that can be suitably used by removing divalent ions. Can also be used.

  Furthermore, in each of the above-described embodiments, seawater is used as the water to be removed (treated water) from which divalent ions are removed. It may be drainage, groundwater with high salt concentration or the like, or may be groundwater with high salt concentration that springs out together with crude oil during crude oil mining. At this time, as the latter groundwater, for example, groundwater newly generated by press-fitting press-fit water may be used. By using these waters containing divalent ions as the water to be treated and applying each of the above-described embodiments, it is possible to efficiently produce, for example, injection water. In addition, even when trivalent or higher ions are contained in these waters, they are handled in the same manner as in the above-described embodiments.

  Moreover, although the reverse osmosis membrane units 10 and 20 are comprised by the reverse osmosis membranes 1 and 2 being accommodated in a pressure vessel, respectively, the structure other than that is not restrict | limited in particular. Therefore, the reverse osmosis membrane units 10 and 20 are reverse osmosis membrane units by winding the reverse osmosis membranes 1 and 2 into a reverse osmosis membrane module and housing a plurality of reverse osmosis membrane modules in a pressure vessel, for example. be able to. Further, the number (number) of reverse osmosis membrane units to be used may be one, or may be two or more. In the case of two or more reverse osmosis membrane units, for example, each reverse osmosis membrane unit Can be used in parallel.

  Furthermore, in the water treatment system 100, the number of reverse osmosis membrane modules and the number of pressure vessels provided in the reverse osmosis membrane units 10 and 20 are the same, so that The contact area is the same. However, even if the number of reverse osmosis membrane modules and the number of pressure vessels are not the same, the contact area between the reverse osmosis membranes 1 and 2 and seawater or permeate can be made the same by changing other configurations. May be. Further, the contact area between the reverse osmosis membranes 1 and 2 and seawater or permeate may not be the same. For example, the contact area between the first-stage reverse osmosis membrane 1 and seawater is the second-stage reverse osmosis membrane 2. It may be made larger than the contact area between the water and the permeated water. That is, the contact area between the first-stage reverse osmosis membrane 1 and seawater may be the same as or larger than the contact area between the second-stage reverse osmosis membrane 2 and permeated water. The reverse is also possible.

  Moreover, in the said embodiment, the concentrated water produced | generated in the reverse osmosis membrane unit 20 is joined by the seawater (to-be-processed water) which flows through the seawater supply system 31 whole. The mixed water of seawater and concentrated water is supplied to the reverse osmosis membrane unit 10. And the seawater supply system 31 and the concentrated water return system | strain 35 are formed so that seawater and concentrated water may become such a flow. However, the concentrated water that joins the seawater does not have to be the entire amount, and only a part of the concentrated water may join the seawater. Moreover, although it is preferable to merge, it may not be merged.

  In addition, a filtration device for removing foreign matter or the like being processed may be provided on the upper stage of the reverse osmosis membrane unit 10.

1 Reverse osmosis membrane (first reverse osmosis membrane)
2 Reverse osmosis membrane (second reverse osmosis membrane)
10 Reverse osmosis membrane unit (first reverse osmosis membrane unit)
20 Reverse osmosis membrane unit (second reverse osmosis membrane unit)
31 Seawater supply system 32 Permeated water supply system 33 Pressurized water supply system 34 Concentrated water distribution system 35 Concentrated water return system 36 Permeated water bypass system 41 Pressure pump (first pressurizing device)
42 Pressurizing pump (second pressurizing device)
43 High-pressure pump (first pressurizer)
44 High-pressure pump (second pressurizer)
45 Booster pump (first pressurizer)
46 Booster pump (second pressurizer)
51, 52 Tanks 61, 62 Flow rate control valve 71 Energy recovery turbine (first energy recovery device)
72 Energy recovery turbine (second energy recovery device)
100, 200, 300, 400, 500, 600, 700, 800 Water treatment system

Claims (8)

From the water to be treated which contains at least monovalent ions and divalent or higher ions as ions having a valence of two or more, and the concentration of the divalent or higher ions is lower than the concentration of the monovalent ions. In the water treatment system for removing the divalent or higher ions,
A first reverse osmosis membrane unit comprising a first reverse osmosis membrane which is supplied with the water to be treated and selectively removes the divalent or higher ions in the water to be treated;
A first pressurizing device for applying a pressure for allowing the treated water to permeate the first reverse osmosis membrane;
A second reverse osmosis membrane provided with a second reverse osmosis membrane having the same filtration characteristics as the first reverse osmosis membrane while being supplied with permeate obtained by permeating the first reverse osmosis membrane Unit,
A water treatment system comprising: a second pressurizing device that applies pressure for allowing the permeated water to pass through the second reverse osmosis membrane.   2. The water treatment system according to claim 1, wherein the concentration of the divalent or higher ion is 1/3 or less of the concentration of the monovalent ion.   A concentrated water return system for merging at least a part of the concentrated water generated in the second reverse osmosis membrane unit with the treated water supplied to the first reverse osmosis membrane unit is provided. The water treatment system according to claim 1 or 2.   A permeated water bypass system is provided that bypasses a portion of the permeated water obtained by permeating the first reverse osmosis membrane to the permeated water obtained by permeating the second reverse osmosis membrane. The water treatment system according to any one of claims 1 to 3, wherein the water treatment system is provided.   The energy of the concentrated water generated in the first reverse osmosis membrane unit is recovered and supplied to the treated water supplied to the first reverse osmosis membrane unit or the second reverse osmosis membrane unit. The water treatment system according to any one of claims 1 to 4, further comprising a first energy recovery device used for pressurizing any of the permeated water.   The energy of the concentrated water generated in the second reverse osmosis membrane unit is recovered, and the treated water supplied to the first reverse osmosis membrane unit or supplied to the second reverse osmosis membrane unit The water treatment system according to any one of claims 1 to 5, further comprising a first energy recovery device used for pressurizing any of the permeated water. The treated water includes seawater,
The water treatment system according to claim 1, wherein the divalent or higher ion is at least a sulfate ion. The treated water includes groundwater containing at least sulfate ions,
The water treatment system according to claim 1, wherein the divalent or higher ion is at least a sulfate ion.

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