WO2016111372A1 - 半透膜の阻止性能向上方法、半透膜、半透膜造水装置 - Google Patents
半透膜の阻止性能向上方法、半透膜、半透膜造水装置 Download PDFInfo
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- WO2016111372A1 WO2016111372A1 PCT/JP2016/050585 JP2016050585W WO2016111372A1 WO 2016111372 A1 WO2016111372 A1 WO 2016111372A1 JP 2016050585 W JP2016050585 W JP 2016050585W WO 2016111372 A1 WO2016111372 A1 WO 2016111372A1
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- Prior art keywords
- semipermeable membrane
- blocking performance
- water
- improving
- performance
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- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F1/00—Treatment of water, waste water, or sewage
- C02F1/44—Treatment of water, waste water, or sewage by dialysis, osmosis or reverse osmosis
- C02F1/444—Treatment of water, waste water, or sewage by dialysis, osmosis or reverse osmosis by ultrafiltration or microfiltration
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F1/00—Treatment of water, waste water, or sewage
- C02F1/66—Treatment of water, waste water, or sewage by neutralisation; pH adjustment
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2103/00—Nature of the water, waste water, sewage or sludge to be treated
- C02F2103/08—Seawater, e.g. for desalination
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2209/00—Controlling or monitoring parameters in water treatment
- C02F2209/03—Pressure
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2303/00—Specific treatment goals
- C02F2303/16—Regeneration of sorbents, filters
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2303/00—Specific treatment goals
- C02F2303/22—Eliminating or preventing deposits, scale removal, scale prevention
-
- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2305/00—Use of specific compounds during water treatment
- C02F2305/04—Surfactants, used as part of a formulation or alone
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02A—TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
- Y02A20/00—Water conservation; Efficient water supply; Efficient water use
- Y02A20/124—Water desalination
- Y02A20/131—Reverse-osmosis
Definitions
- the present invention relates to the improvement of the performance of a semipermeable membrane used for obtaining low-concentration permeated water using raw water such as seawater, salt-containing river water, groundwater, lake water, wastewater treated water, and the like. Specifically, the present invention relates to a method for improving the blocking performance that can improve the blocking performance of the semipermeable membrane.
- Wastewater reuse is beginning to be applied in inland and coastal urban areas and industrial areas where there is no freshwater source or where discharge is restricted due to drainage regulations.
- Singapore an island country where water sources are scarce, sewage generated in the country is treated and stored without being released into the sea, and is reclaimed to a level that can be drunk with a reverse osmosis membrane to cope with water shortages.
- the reverse osmosis method applied to seawater desalination and reuse of sewage wastewater produces desalted water by allowing water containing salt and other solutes to permeate the semipermeable membrane at a pressure higher than the osmotic pressure. You can do it.
- This technology can be used to obtain drinking water from, for example, seawater, brine, and water containing harmful substances, and has also been used in the production of industrial ultrapure water, wastewater treatment, and recovery of valuable resources. .
- Non-Patent Document 1 When using reverse osmosis membranes for applications such as seawater desalination and reuse of sewage wastewater, it is very difficult to prevent 100% degradation of the functional layer of such reverse osmosis membranes.
- the mainstream polyamide is susceptible to oxidative degradation (Non-Patent Document 1).
- the functional layer is likely to be decomposed when exposed to strong acids and alkalis.
- neutral molecules can be separated rather than separating and removing inorganic electrolytes that can be blocked by the charge exclusion effect due to anion charge. This has a great adverse effect on the removal of the water, and in particular, the neutral molecule blocking rate becomes worse.
- the water quality of silica, boron, saccharides and the like that are not dissociated in the neutral region is significantly deteriorated.
- a reverse osmosis membrane that has lost the necessary blocking performance usually has to be replaced with a new one, which naturally increases processing costs.
- Patent Documents 1 and 2 Methods for contacting and reacting vinyl polymers (Patent Documents 1 and 2), contacting polyethylene glycol with reverse osmosis membranes.
- Patent Documents 3 and 4 To improve the rejection rate, especially the rejection rate against nonionic solutes (Patent Documents 3 and 4), and contact the nonionic surfactant with the membrane surface against a reverse osmosis membrane having anion charge with increased permeation flux (Patent Document 5), contact with iodine and / or iodine compound having an oxidation-reduction potential of 300 mV or more (Patent Document 6), contact with strong mineral acid aqueous solution such as phosphoric acid, phosphorous acid, sulfuric acid, etc.
- the prevention performance improvement treatment effect changes depending on the type and state of the reverse osmosis membrane (dirt, deterioration), the processing environment such as the water temperature, and the conditions when the treatment is performed (temperature, concentration, treatment time, etc. of the treatment liquid)
- the decrease in water permeability which can be said to be a side effect of the prevention performance improvement process, also changes.
- the long-term performance sustaining effect after improvement of the rejection rate varies, and there are many cases where water quality is insufficient, operation pressure is insufficient, or difficulty is involved in the water production operation after the improvement of the rejection performance.
- Patent Document 8 In order to solve the influence on the processing effect due to the difference in the state of the reverse osmosis membrane with respect to these problems, for example, as exemplified in Patent Document 8, after the reverse osmosis membrane is washed with a chemical solution, the inhibition performance improvement treatment is performed.
- the technology to apply is generally applied.
- Patent Document 9 a pretreatment has been proposed in which the substrate is washed with high-temperature water and then brought into contact with a blocking performance improver.
- Patent Document 10 As a method for judging the effect of the blocking performance improving treatment, a method of confirming the processing effect by adding a substance to be labeled to the blocking performance improving agent and detecting the concentration of the labeled substance in the permeated water.
- Patent Document 10 Has been proposed.
- a method has also been proposed for determining the end of the process by monitoring the supply concentration and the discharge concentration of the blocking performance improver so that the blocking rate improvement process reaches saturation and no more useless recovery processing time is required.
- the present invention relates to a method for improving the blocking performance of a semipermeable membrane, such as a nanofiltration membrane or a reverse osmosis membrane, in particular, a blocking performance improving method capable of improving the blocking performance of a nonionic substance, and an improvement in the blocking rate. It is an object of the present invention to provide a water making apparatus and a water making method using a semipermeable membrane processed by the method, a semipermeable membrane element, and a semipermeable membrane with improved blocking performance.
- the present invention has the following configuration. (1) A method of improving the blocking performance of a semipermeable membrane by pressurizing and supplying a liquid containing a blocking performance improving agent to the primary side of the semipermeable membrane and bringing the liquid into contact with the membrane surface.
- the removal rate of 2000 mg / L sodium chloride of the semipermeable membrane is 99.5% or more, and the blocking performance improver contains at least a compound having a polyalkylene glycol chain having a weight average molecular weight of 2,000 or less.
- R A1 is 0.9 or less, and, together with R A2 is 0.7 or more, R B is a semi-permeable membrane prevents improved performance according to 0.3 to 0.7
- R B is a semi-permeable membrane prevents improved performance according to 0.3 to 0.7
- Pure water permeability coefficient A is either a value obtained by correcting the value of the maximum temperature T H when the lowest temperature T L, and the solute permeability coefficient B operating the semipermeable membrane when operating a semipermeable membrane Alternatively, the method for improving the semipermeable membrane blocking performance according to (22) or (23), wherein both A and B are values corrected to the same temperature.
- the rejection rate improving method of the present invention in a fresh water generator such as seawater desalination and sewage reuse, when the permeated water quality deteriorates due to a decrease in the blocking performance of the nanofiltration membrane or reverse osmosis membrane, It is possible to improve the blocking performance while minimizing the deterioration of the water permeability, and to efficiently improve the water quality of the removal target substances such as inorganic electrolytes and neutral molecules.
- FIG. 1 is a diagram showing an example of a process flow of a semipermeable membrane water making apparatus to which the semipermeable membrane blocking performance improving method according to the present invention can be applied.
- FIG. 2 is a diagram showing an example of a process flow of a semipermeable membrane water making apparatus to which the semipermeable membrane blocking performance improving method according to the present invention can be applied in reverse flow to the semipermeable membrane.
- FIG. 3 is a diagram showing an example of a process flow of a semipermeable membrane water making apparatus to which the semipermeable membrane improvement performance improving method according to the present invention can be applied by reverse flow switching with respect to the semipermeable membrane.
- FIG. 1 is a diagram showing an example of a process flow of a semipermeable membrane water making apparatus to which the semipermeable membrane blocking performance improving method according to the present invention can be applied.
- FIG. 2 is a diagram showing an example of a process flow of a semipermeable membrane water making apparatus to which the semipermeable membrane blocking
- FIG. 4 is a diagram showing an example of a process flow of the semipermeable membrane water making apparatus to which the method for improving the blocking performance can be applied while performing serial dilution while a plurality of semipermeable membranes according to the present invention are in series.
- FIG. 5 shows an example of a process flow of a semipermeable membrane water making apparatus to which the method for improving the blocking performance can be applied while serially diluting with other system permeated water while a plurality of semipermeable membranes according to the present invention are in series.
- FIG. 6 shows an example of the process flow of a semipermeable membrane water making apparatus to which the method for improving the blocking performance can be applied while performing serial dilution with concentrated water of another system while a plurality of semipermeable membranes according to the present invention are in series.
- FIG. FIG. 7 is a diagram showing an example of a process flow of a semipermeable membrane water producing apparatus that performs a water making operation while applying the semipermeable membrane blocking performance improving method according to the present invention.
- FIG. 8 shows another example of the process flow of the semipermeable membrane water making apparatus to which the method for improving the blocking performance can be applied using the second semipermeable membrane concentrated water while the plurality of semipermeable membranes according to the present invention are in series.
- FIG. 9 shows another example of the process flow of the semipermeable membrane water making apparatus to which the method for improving the blocking performance can be applied using the first semipermeable membrane permeated water while the plurality of semipermeable membranes according to the present invention are in series.
- FIG. FIG. 10 is a diagram illustrating a process flow of the test apparatus used for measuring the effect by the inhibition performance improving method of the example.
- FIG. 1 shows an example of a semipermeable membrane separating apparatus to which the semipermeable membrane blocking performance improving method of the present invention can be applied.
- the semipermeable membrane water generator shown in FIG. 1 When the semipermeable membrane water generator shown in FIG. 1 is operated for fresh water, the raw water supplied through the raw water line 1 is temporarily stored in the raw water tank 2 and then sent to the pretreatment unit 4 by the raw water supply pump 3. Liquid and pretreatment.
- the pretreated water passes through the intermediate water tank 5, the supply pump 6, and the safety filter 7, and after being pressurized by the booster pump 8, is separated into permeated water and concentrated water by the semipermeable membrane unit 9 constituted by a semipermeable membrane module. .
- the permeated water ra is stored in the production water tank 12 through the production water line 10a.
- the concentrated water is discharged from the system through the concentrated water discharge line 11a after the pressure energy is recovered by the energy recovery unit 13.
- the supply water valve 16a, the permeated water valve 17a, and the concentrated water valve 18a are opened, and the supplied chemical liquid valve 16b, the permeated chemical liquid valve 17b, and the concentrated chemical liquid valve 18b are closed.
- the chemical solution circulation line used when applying the present invention includes a chemical solution tank 15, a chemical solution supply pump 19, and a chemical solution addition unit 20 (20a, 20b).
- the chemical solution supply line 14 is supplied from the chemical solution supply line 14 to the semipermeable membrane unit 9.
- the concentrated chemical solution that has not been permeated through the permeated water line 10 and the permeated chemical solution line is used in the concentrated water line. 11. Reflux to the chemical tank 15 through the concentrated chemical liquid line 11b.
- the supply water valve 16a, the permeate water valve 17a, and the concentrated water valve 18a are closed, and the supply chemical liquid valve 16b, the permeated chemical liquid valve 17b, and the concentrated chemical liquid valve 18b are opened.
- This chemical solution circulation line can also be used when circulating and cleaning the semipermeable membrane using acid, alkali, detergent or the like.
- a liquid containing the blocking performance improver of the present invention When a liquid containing the blocking performance improver of the present invention is supplied under pressure, a liquid containing a blocking performance improving agent and a solute to which the present invention is applied in advance can be prepared in the chemical tank 15 as shown in FIG.
- a blocking performance improver can be added by the chemical solution addition unit 20a, and a solute can be added by the chemical solution addition unit 20b.
- a solute containing semipermeable membrane feed water or semipermeable membrane concentrated water as the solute of the present invention.
- any of the semipermeable membrane supply water, the semipermeable membrane concentrated water, and the semipermeable membrane permeated water is supplied to the chemical tank 15 and supplied and stored before or after the water production operation.
- a blocking performance improver is added from the chemical solution addition unit 20a to a predetermined concentration. Accordingly, it is not necessary to procure the solute / solvent for the liquid of the present invention from outside the system, and it becomes possible to prepare a liquid having an osmotic pressure according to the purpose.
- the semipermeable membrane permeate may be used as a solvent, and the solute may be supplied from outside the system, that is, by the chemical addition unit 20b.
- Case A improver L + solute L
- a blocking performance improver hereinafter referred to as the improving agent L
- the solute L a liquid containing a solute having a low blocking performance
- Concentration of blocking performance improver due to concentration caused by separation of permeate from the inlet to the outlet of the membrane unit and neither increase in osmotic pressure are likely to occur, and uniform blocking rate improver contact throughout the semipermeable membrane from the inlet to the outlet Can be obtained. That is, it means that the improvement process of the semipermeable membrane is easily performed uniformly.
- the combination of the improver L + solute L is suitable.
- Case B improver H + solute H
- a blocking performance improver (hereinafter referred to as improving agent H) having a high blocking rate in a semipermeable membrane
- solute H a solute having a high blocking performance
- solute H a solute having a high blocking performance
- the concentration of the improver H increases as it goes to the outlet due to the concentration caused by separating the permeated water from the inlet to the outlet of the membrane unit.
- the concentration of the solute H is also increased. As a result, the permeation flux decreases from the inlet to the outlet.
- the blocking performance improver has a low concentration and the permeation flux is large, and at the outlet, the blocking performance improver has a high concentration and permeation. Since the flux is small, the blocking performance improver that comes into contact is preferable because the balance from the inlet to the outlet is improved. Further, depending on the operating conditions, it is possible to make the effect expression rate at the entrance relatively large or relatively low.
- the combination of improver H + solute H is suitable.
- Case C improver L + solute H
- solute H a solute that has a reasonably high blocking performance by the semipermeable membrane
- the effect manifestation speed by the improver is large, and the permeation flux decreases due to the increase in osmotic pressure accompanying the solute concentration as it goes to the vicinity of the outlet, and the effect manifestation speed of the inhibitory performance enhancer decreases. That is, it is a preferable method when a large improvement in blocking performance is required near the entrance.
- the permeation flux in the water is larger and easier to foul in the vicinity of the outlet, and the oxidizing agent is semipermeable membrane.
- the effect of the oxidizing agent is greater near the entrance, and the semipermeable membrane is also relatively deteriorated. Therefore, in such a case, a method in which the vicinity of the inlet is positively treated by a combination of the improver L + solute H is suitable.
- this method is particularly suitable.
- Case D improver H + solute L
- the concentration increases as the blocking performance improver concentration approaches the outlet.
- the increase in the osmotic pressure due to the concentration of the solute is small, the effect speed of the blocking performance improver increases as it goes from the inlet to the outlet.
- Such a method is effective when the semipermeable membrane is more damaged near the outlet, for example, when scale deposition occurs.
- the case C and the case D are reversed as shown in FIG. 2 by reversing the supply direction to the semipermeable membrane, that is, the water is formed by the improver L + solute H. It is possible to preferentially improve the performance in the vicinity of the outlet at the time, or improve the performance in the vicinity of the inlet at the time of water formation by the improver H + solute L. Of course, as illustrated in FIG. 3, it is preferable that the chemical solution supply line can be switched, and the reverse flow can be intermittently performed. Specifically, the supply water valve 16a, the permeate water valve 17a, and the concentrated water valve 18a are closed during the semipermeable membrane blocking performance improving process.
- the supply chemical solution valve 16b When supplying a chemical solution in the forward direction, the supply chemical solution valve 16b is used. When the chemical liquid valve 17b and the concentrated chemical liquid valve 18b are opened, the valve 28a and the valve 28b are closed and the chemical liquid is supplied in the opposite direction, the valve 28a, the permeated chemical liquid valve 17b and the valve 28b are opened, and the supplied chemical liquid valve 16b, the concentrated chemical liquid valve 18b is closed.
- vinyl polymers include polyvinyl acetate, polyvinyl alcohol, vinyl acetate-ethylene copolymer, Bolipier alcohol, vinyl acetate-ethylene copolymer, vinyl chloride copolymer, styrene-vinyl acetate copolymer, and N vinyl pyrrolidone.
- -A vinyl acetate copolymer etc. can be illustrated.
- examples of the polyalkylene glycol chain include a polyethylene glycol chain, a polypropylene glycol chain, a polytrimethylene glycol chain, and a polytetramethylene glycol chain.
- These glycol chains can be formed by, for example, ring-opening polymerization of ethylene oxide, propylene oxide, oxetane, tetrahydrofuran or the like.
- the blocking performance improver applied to the present invention is required to contain another solute (a solute different from the blocking performance improving agent), but the component is not particularly limited, but is a semipermeable membrane. It should be noted that it does not contain components such as oxidizers, turbidity, and surfactants that adsorb to the membrane and cause performance degradation, organic solvents and oil components that affect the performance of . From this point of view, it is particularly preferable to apply polyalkylene glycol to a semipermeable membrane containing polyamide as a main component, since the effect is great.
- the compound having a polyalkylene glycol chain of the present invention a compound in which an ionic group is introduced into the polyalkylene glycol chain can be used.
- the ionic group include a sulfo group, a carboxy group, a phospho group, an amino group, and a quaternary ammonium group.
- a water-soluble polymer compound having anionic or cationic characteristics can be obtained.
- the polyalkylene glycol chain in the present invention is particularly preferably a polyethylene glycol chain. Since the compound having a polyethylene glycol chain is highly water-soluble, it is easy to handle as a blocking rate improver and has a high affinity for the composite membrane surface, so that there is little deterioration in performance over time after treatment.
- improver L and the solute L those having a blocking performance of a semipermeable membrane to be applied of 50% or less, more preferably having a blocking performance of 20% or less may be selected.
- improver H or the solute H it is preferable to select one having 70% or more, more preferably 90% or more.
- the polymer to which the present invention is applied can be appropriately selected according to the component for which the performance and blocking performance of the semipermeable membrane are desired to be improved.
- the weight average molecular weight is 6,000 or more and 100,000 or less. More preferably, it is 7,500 to 50,000. If the weight average molecular weight of the polyalkylene glycol chain is less than 6,000, the blocking rate of the semipermeable membrane is not sufficiently improved, and the fixability after processing may be lowered.
- the weight average molecular weight to be within 100,000, it is possible to suppress extreme permeation flux reduction, maintain good solubility in water, and perform simple handling.
- a blocking performance improver having a weight average molecular weight of 2,000 or less is at least a weight average molecular weight of 2,000 or less. It is effective to contain an alkylene glycol chain.
- a semipermeable membrane suitable for this method is particularly effective when applied to a high removal rate membrane in which the removal rate of 2,000 mg / L sodium chloride is 99.5% or more, particularly preferably 99.8% or more. is there.
- the effect is obtained when the weight average molecular weight of the polyalkylene glycol is 10,000 or more and 100,000 or less as a blocking rate improver.
- polyvalent glycol having a weight average molecular weight of 20,000 or more is used. This is preferable because the removal performance of divalent ions can be increased without increasing the ion blocking performance as much as possible.
- the weight average molecular weight can be obtained by analyzing an aqueous solution of a compound having a polyalkylene glycol chain by gel permeation chromatography (GPC) and converting the obtained chromatogram into the molecular weight of a polyethylene oxide standard product.
- GPC gel permeation chromatography
- the blocking performance improver H is used as the blocking performance improver of the present invention because of the high blocking performance of the semipermeable membrane.
- the weight molecular weight average concentration is preferably 2,000 or more and 50,000 or less. Particularly preferably, it is particularly preferably 2,000 or more and 20,000 or less.
- a low-pressure reverse osmosis membrane, a loose reverse osmosis membrane, or a semipermeable membrane such as a nanofiltration membrane which has a smaller blocking performance than seawater desalination, it is preferably 6,000 or more and 100,000 or less.
- the constant X is determined according to the type of the inhibition performance improver, Supply amount Q F [m 3 / day] of the treatment liquid to the semipermeable membrane, permeated water amount Q P [m 3 / day], membrane area of the semipermeable membrane A [m 2 ], inhibition performance improver concentration C [ mg / l], liquid passage time t [h], and osmotic pressure of the supply liquid is ⁇ ,
- the osmotic pressure ⁇ is 1 bar or less
- the osmotic pressure ⁇ is 1 bar or more and 20 bar or less
- the osmotic pressure ⁇ is 1 bar or more and 20 bar or less.
- Q PT / A indicates a permeation flow rate per membrane area, that is, a permeation flux.
- concentration C and time t Q PT / A ⁇ C ⁇ t It means the total amount of blocking performance improver per membrane area that is contacted (passed or blocked) from the primary side (supply side) to the secondary side (permeation side).
- the determination method of X in these formulas can be obtained by conducting a test in advance using the blocking performance improver-containing liquid to be used.
- a treatment liquid in which 500 mg / L NaCl is dissolved in 100 L of pure water is prepared, a semipermeable membrane to be processed is set in a flat membrane cell shown in Non-Patent Document 2, and a flow rate of 3 Circulate at 5 L, 25 ° C., 4.5 bar pressure and measure the initial performance of the semipermeable membrane. At this time, all the permeated water and concentrated water are recycled.
- the retention rate of permeation flux F 2 / F 1 at this time is not 0.5 or more, this blocking performance improver is not used.
- the conditions for measuring the performance change of the membrane are not particularly limited, but it is preferable that the measurement is performed under the standard conditions of a semipermeable membrane (in the case of a product, catalog conditions) near the time of fresh water generation operation.
- Non-Patent Document 2 the approximate expression shown in Non-Patent Document 2 can also be used.
- the material of the semipermeable membrane applicable to the present invention a polymer material such as cellulose acetate polymer, polyamide, polyester, polyimide, vinyl polymer can be used.
- the membrane structure also has a dense layer on at least one side of the membrane, and an asymmetric membrane having fine pores with gradually increasing pore diameters from the dense layer to the inside of the membrane or the other side, or another material on the support membrane It is possible to use a composite semipermeable membrane having a very thin separation functional layer formed in (1).
- the semipermeable membrane suitable for the present invention is a composite reverse osmosis membrane having a high pressure resistance, high water permeability, and high solute removal performance and having excellent performance, and a polyamide separation function layer, or a nanofiltration membrane.
- a composite reverse osmosis membrane having a high pressure resistance, high water permeability, and high solute removal performance and having excellent performance
- a polyamide separation function layer or a nanofiltration membrane.
- a structure in which polyamide is used as a separation functional layer and is held by a support made of a microporous membrane or a nonwoven fabric is suitable.
- the polyamide semipermeable membrane a composite semipermeable membrane having a separation functional layer of a crosslinked polyamide obtained by polycondensation reaction of a polyfunctional amine and a polyfunctional acid halide is suitable.
- the composite semipermeable membrane is preferable for application because the amount of the separation functional layer is small, and the blocking performance improver effectively acts on the functional layer portion that exhibits blocking performance.
- the pH of general raw water to be treated is in a neutral region, and in that region, the membrane surface is negatively charged in order to prevent adsorption of natural organic matter, that is, In general, the surface membrane potential is negative, and the isoelectric point, that is, the surface potential becomes 0 in a weakly acidic region.
- the sustainability of the treatment effect can be increased by neutralizing the surface potential of the semipermeable membrane.
- the treatment is carried out in a weakly acidic region, specifically, pH 4 or more and pH 7 or less, more preferably pH 5.5 or more and pH 6.8 or less.
- the semipermeable membrane element can be used as a semipermeable membrane element shaped for actual use. If the semipermeable membrane is a flat membrane, it can be used by incorporating it into a spiral, tubular, or plate-and-frame module. Since it is a one-way flow from the opposite end surface, and members such as a feed water side channel material and a permeate side channel material are incorporated, the blocking performance improver tends to act uniformly on the membrane surface, It is particularly preferably used as a semipermeable membrane element to which the present invention is applied.
- the thickness is 0.6 mm or more and 1.0 mm or less, particularly 0.7 m or more and 0.9 mm or less.
- the processing liquid is easily contacted evenly.
- the blocking rate improving method of the present invention improves the blocking rate by bringing a liquid containing a blocking performance improver into contact with the semipermeable membrane, but the permeation flux decreases accordingly, and therefore the blocking performance improving effect is sufficient.
- it is very important to monitor and manage the water permeability performance and the prevention performance before and after the prevention performance treatment.
- water other than the blocking performance improvement processing agent is the same liquid (liquid containing a component different from the blocking performance improvement agent) and water is passed through the reverse osmosis membrane. Then, at least two flow rates, concentrations, and water temperatures of the supply water (process target supply water), the permeated water, and the concentrated water at that time are measured, and from these, the pure water permeability coefficient A 0 and the blocking performance are measured as the initial water permeability.
- the solute permeability coefficient B 0 is calculated as follows, and then, while supplying and passing the blocking performance improving treatment liquid to the reverse osmosis membrane, at least two of the supplied water, permeated water and concentrated water at that time, the flow rate and concentration, water temperature From the pure water permeability coefficient A 1 as the initial water permeability and the solute permeability coefficient B 2 as the blocking performance, and B 1 / B 0 when A 1 / A 0 is equal to or lower than R A1. Is predetermined If the value R B is equal to or less than the value R B , the blocking performance improvement processing is terminated. If B 1 / B 0 exceeds RB, the blocking performance improvement processing is continued, and B 1 / B 0 becomes equal to or less than R B. Alternatively, it is preferable to take a method of stopping the processing when A 1 / A 0 decreases to R A2 .
- R A1 is set to 0.9 or less
- R A2 is set to 0.7 or more
- the blocking performance improving process is performed so that R B is set to 0.3 or more and 0.7 or less. It is preferable to apply.
- the pure water permeability coefficient and the solute permeability coefficient can be obtained by the following equations.
- Jv A ( ⁇ P ⁇ (Cm)) (1)
- Js B (Cm ⁇ Cp) (2)
- Cm ⁇ Cp) / (Cf ⁇ Cp) exp (Jv / k) (3)
- Cp Js / Jv (4)
- A ⁇ ⁇ A25 ⁇ ⁇ 25 / ⁇ (5)
- B ⁇ ⁇ B25 ⁇ ⁇ 25 / ⁇ ⁇ (273.15 + T) / (298.15) (6)
- the pure water permeability coefficient A and the solute permeability coefficient B under the measured conditions are obtained. Can be sought. Further, based on ⁇ and ⁇ obtained in advance, the pure water permeability coefficient A25 and the solute permeability coefficient B25 at 25 ° C. can be obtained from the equations (5) to (6). Furthermore, the equation (5) Using (6), a pure water permeability coefficient and a solute permeability coefficient at an arbitrary temperature T can be obtained. Moreover, when calculating the performance of a semipermeable membrane element, it can obtain
- the pure water permeability coefficient A and the solute permeability coefficient B are values corrected to the same temperature, but the most severe for water permeability, that is, the pure water permeability coefficient A is the lowest. the most stringent for the lowest operating temperature T L, and rejection performance of the semipermeable membrane, i.e. the solute permeability coefficient B is corrected to a value at the maximum operating temperature T H of the largest becomes a semi-permeable membrane, or the performance of each is within the allowable range It is very preferable because it is easy to understand.
- a liquid containing the blocking performance improving agent is passed through the pressure vessel while the semipermeable membrane is loaded in the pressure vessel.
- the method of making it contact with a semipermeable membrane and processing is mentioned. If there is equipment for chemical cleaning with the semipermeable membrane loaded in the pressure vessel, use the washing equipment to pass the liquid containing the blocking performance improver through the pressure vessel and contact the semipermeable membrane. can do.
- the pressure when the aqueous solution containing the blocking performance improver is contacted with the composite semipermeable membrane is not particularly limited, and should be appropriately determined in view of the pressure resistance of the semipermeable membrane, the blocking performance improving effect and the influence on water permeability. Can do. Among them, it is preferable that the water to be treated is passed through the semipermeable membrane and the pressure is equal to or lower than the pressure at the time of fresh water generation operation. Then, since the prevention performance improvement process can be performed without providing dedicated equipment, it is more preferable.
- the blocking performance improving agent acts even inside the semipermeable membrane if the permeation flux is 0.01 to 2.0 m / day. This is a preferable embodiment.
- the permeation flux is 0.01 m / day or less, the treatment effect is low, and when it is 2.0 m / day or more, there is a possibility that the composite semipermeable membrane may be damaged by excessive operating pressure.
- the concentration of the blocking performance improver is not particularly limited, but if the concentration is too high, it may be difficult to obtain a uniform blocking performance improvement over the entire film, and the blocking performance improving agent locally. Accumulates and local water permeability is likely to decrease. On the other hand, if the concentration is too low, the speed of improving the blocking performance is reduced, and the processing time may be increased, which is not preferable. Specifically, it is preferably 0.5 ⁇ mol / L or more and 100 ⁇ mol / L or less, and more preferably 1 ⁇ mol / L or more and 50 ⁇ mol / L or less.
- the concentration can be gradually increased and decreased while monitoring the permeation flux during the prevention performance improvement treatment.
- the concentration can be gradually increased and decreased while monitoring the permeation flux during the prevention performance improvement treatment.
- the concentration is too low and the effect of improving the rejection rate is not achieved or if the effect per time is too large, it is judged that uniform processing is difficult, It is possible to immediately increase or decrease the treatment concentration, which is particularly effective when processing on a large scale such as a water treatment plant.
- the diffusion / contact speed to the semipermeable membrane can be increased by heating and supplying the liquid containing the blocking performance improver, this is a preferred embodiment.
- the operating temperature at the time of water generation of the semipermeable membrane and from the meaning of preventing deterioration of the semipermeable membrane due to heat, it is not less than the maximum temperature at the time of water formation and not more than 60 ° C, more preferably 35 ° C. A temperature of 45 ° C. or lower is particularly preferable.
- the above-described constant X can be reduced.
- X 1 + ⁇ T X 1 / (1 + a ⁇ ⁇ T) where 0.02 ⁇ a ⁇ 0.03.
- X corrected by the above can be applied.
- the present invention it is also preferable to take a method of making it difficult to remove the treatment agent from the semipermeable membrane by bringing high-temperature water into contact with it after the prevention performance improving treatment.
- a specific method it is possible to raise the ambient temperature, but after the prevention performance improvement treatment, supply water, concentrated water, permeated water, and other water outside the system during fresh water generation operation It can be carried out by passing water through the semipermeable membrane supply side at a temperature equal to or higher than the maximum temperature.
- the specific temperature is preferably 60 ° C. or lower, more preferably 35 ° C. or higher and 45 ° C. or lower from the viewpoint of preventing the semipermeable membrane from deteriorating and higher than the maximum temperature during fresh water generation operation.
- Conditions such as the flow rate and pH at that time are not particularly limited, but it is preferably a mild flow rate and pH that do not adversely affect the semipermeable membrane and the inhibition performance improving treatment result. Moreover, it is preferable that the pressure at this time is below the operation pressure at the time of fresh water generation.
- the pressure on the treatment liquid side during treatment that is, the primary side.
- count is not limited, It is also preferable to implement intermittently, monitoring an effect. A similar effect can be obtained by changing the permeation flow rate. In this case, as described above, it can be achieved even by a primary pressure change, but it can also be achieved by a secondary pressure change.
- the permeation flux by changing the membrane surface osmotic pressure by changing the concentration of the solute shown in the present invention.
- the osmotic pressure can be greatly varied without incurring chemical costs.
- it is effective to change the permeation flux by 0.8 times or less before the change, or 1.2 times or more before the change.
- a sudden change places a load on the semipermeable membrane. Therefore, it is more preferable that the ratio be 0.6 times or more and 0.8 times or less, or 1.2 times or more and 1.5 times or less.
- the time for passing the liquid containing the blocking performance improver can be appropriately determined according to the present invention, but it is preferably 0.5 to 24 hours, and more preferably 1 to 12 hours. As described above, if the processing time is too short, uniform processing becomes difficult, and if it is too long, the operating time of the equipment is lost, which is not preferable.
- a more sustainable recovery effect can be obtained by removing the membrane contaminants on the semipermeable membrane surface in advance before the contact treatment.
- chemicals generally used as cleaning chemicals for these films can be used.
- Metals such as iron and manganese adhering to the film surface are effective in cleaning with an acidic solution such as citric acid, oxalic acid, hydrochloric acid, sulfuric acid, etc., and the cleaning effect can be enhanced by using a pH of 3 or less. .
- cleaning with an alkaline solution such as caustic soda or ethylenediaminetetraacetic acid tetrasodium is effective, and the cleaning effect can be enhanced by using a pH of 10 or more.
- the cleaning with these cleaning chemicals may be a method of cleaning using each chemical alone or a method of cleaning using a plurality of chemicals alternately.
- the rejection rate improving method of the present invention can improve the rejection rate with repetitive effects on the same semipermeable membrane in the same water treatment facility, the treatment method of the present invention is periodically implemented.
- a constant removal rate can be maintained for a long time.
- the effect of improving the removal rate of uncharged substances is greater than that of inorganic electrolytes that have an effect of eliminating membrane charges.
- the non-charged substance include non-electrolyte organic substances and substances that are not separated in the neutral region (for example, boron and silica). Since these are contained in a large amount in seawater and groundwater, it is possible to continue more stable operation by applying the method of the present invention to a desalination plant for treating these raw waters.
- the rejection improvement process of the present invention can suppress the permeation of both the solvent and the solute from the semipermeable membrane. Therefore, particularly when the semipermeable membrane is deteriorated and the permeation flux is increased. In addition to recovery of the rejection rate, it is possible to prevent deterioration of the quality of the permeated water due to an excessive decrease in the operating pressure for maintaining the amount of water produced as designed by reducing the permeation flux.
- the blocking performance improving process has been described in the desalination plant. There is no problem, and it is a preferable embodiment not only after use but also to process a new semipermeable membrane element immediately after production, and in the plant immediately after loading into a freshwater plant, it is a new embodiment.
- the treatment of the present invention may be performed. This makes it possible to obtain a semipermeable membrane element having the necessary blocking performance according to the needs even if the semipermeable membrane is a variety.
- the blocking performance improver of the first semipermeable membrane unit If the discharged liquid of the contained liquid can be used as a blocking performance improver for the second semipermeable membrane unit, it can be processed in parallel.
- Figure 4 shows an example of the former.
- the blocking performance improver is concentrated in the first (front stage) semipermeable membrane unit 9a (that is, in the case of the improver H), the second second (rear stage) semipermeable membrane unit. Since the concentration is high at the inlet of 9b, it is preferable to dilute from the diluting water tank 21 with the diluting water supply pump 22 unless the blocking performance of the second semipermeable membrane unit is particularly desired.
- the dilution water at this time is not particularly limited, but is supplied to the first semipermeable membrane at the time of fresh water generation, concentrated water (water discharged from the concentrated water discharge line 11a), or permeate stored in the production water tank 12.
- the other series in FIG. 5 is a raw water line 1c, a raw water tank 2c, a raw water supply pump 3c, a pretreatment unit 4c, an intermediate water tank 5c, a supply pump 6c, a safety filter 7c, a booster pump 8c, a semipermeable membrane unit 9c, and a concentrated water line. 11. Concentrated water valve 18c, valve 17c, and valve 18d are included. In FIG.
- the other series are the raw water line 1c, the raw water tank 2c, the raw water supply pump 3c, the pretreatment unit 4c, the intermediate water tank 5c, the supply pump 6c, the safety filter 7c, the booster pump 8c, the semipermeable membrane unit 9c, and the concentrated water line. 11.
- Concentrated water valve 18c and valve 18d are included.
- the valve 17c is permeated through the semipermeable membrane unit 9c as necessary, for example, when the chemical solution supplied from the chemical solution addition units 20a and 20b has a high concentration or when it is desired to reduce the concentration while circulating the chemical solution. Water can be supplied to the chemical tank 15.
- FIG. 6 shows an example in which the concentrated water of the semipermeable membrane unit 9c is used as dilution water, and the supply amount to the dilution water tank 21 can be adjusted by adjusting the concentrated water valve 18c and the valve 18d.
- C ′ C ⁇ Q FT / (Q FT + Q F + ) instead of C in claim 1, where Q F + satisfies the condition as a diluting water flow rate [m 3 / day].
- the process may be performed as follows.
- the blocking performance improver can be almost completely removed with a semipermeable membrane, it is possible to simultaneously perform the performance improving treatment while making water with the semipermeable membrane. That is, it is possible to perform the treatment and the water preparation at the same time by pretreating the raw water to be treated and adding a blocking performance improver to the pretreatment water.
- the permeate quality can be monitored in real time, it is very preferable from the viewpoint of control.
- the rejection rate or solute permeability coefficient is worse than the set concentration, it is possible to add a blocking performance improver and stop the addition when the blocking performance falls within the allowable value. Is a preferred embodiment.
- the water treatment method using the semipermeable membrane treated by the method for improving the blocking performance as described above prevents the deterioration of the permeated water quality, obtains a good permeated water quality for a long time, and thus extends the life of the semipermeable membrane, This can greatly contribute to the reduction of water production costs.
- FIG. 7 is an example of a typical semipermeable membrane process to which the present invention can be applied.
- FIG. 8 is an example showing a method for improving the blocking performance using the second semipermeable membrane concentrated water while a plurality of semipermeable membranes are in series, the raw water line 1, the raw water tank 2, the raw water supply Pump 3, pretreatment unit 4, intermediate water tank 5, supply pump 6, safety filter 7, booster pump 8a, first semipermeable membrane unit 9a, concentrated water line 11, concentrated water valve 18a, first semipermeable membrane unit
- the intermediate water tank 5b for storing the permeated water of 9a, the booster pump 8b for boosting and supplying the second semipermeable membrane, the second semipermeable membrane unit 9b, the second permeated water line 10c, the second concentration It includes a water circulation line 11c, a concentrated water line 11d for feeding concentrated water to the chemical tank 15, and a valve 17c and a valve 17d for controlling the respective flow rates.
- the second concentrated water is connected to the concentrated water discharge line or the chemical tank, but it may have a line for discharging outside the system, and other parts are particularly shown in FIG. It is not restricted.
- FIG. 9 shows an example of supplying a part of the first permeated water to the chemical tank. Also here, as in FIG. 8, the first permeated water can be supplied to the chemical tank by adjusting the valve 17c and the valve 17d.
- FIG. 9 shows a case where the permeated water of the first semipermeable membrane unit is used for chemical dilution, but the permeated water of the second semipermeable membrane unit is applied instead of the permeated water of the first semipermeable membrane unit. There is no problem.
- the total salt concentration in the permeated water and the supply water was obtained from the relational expression between the simulated seawater concentration and the electrical conductivity measured in advance by simulated seawater by measuring the electrical conductivity of each solution with an electrical conductivity meter.
- the total salt concentration when adjusted at this concentration is 3.5% by weight.
- the apparatus uses the simulated raw water prepared in the TDS concentration C F [mg / L] in the raw water tank 2, and the Toray UF membrane is used as the pretreatment unit 4 in order to prevent contamination of the semipermeable membrane.
- the module After ultrafiltration by the module, after passing through the safety filter 7 by the supply pump 6, it is supplied to the semipermeable membrane units 9a and 9b by the booster pump 8a, and the obtained concentrated water and permeated water are circulated in the circulation line. It was operated in such a manner that it was fully refluxed to the raw water tank through 11c.
- the semi-permeable membrane unit was loaded with 9 to 9b reverse osmosis membrane element TM810V manufactured by Toray Industries, Inc., operating pressure P F [bar], supply flow rate 36 [m 3 / day], temperature 25 [° C.].
- the permeate flow rate Q P 0 [m 3 / day] and the permeate TDS concentration C P0 [mg / L] were measured.
- the permeated water valve 17a, valve 17c, valve 17d and valve 16c in FIG. 10 are fully opened, connected to the permeated water discharge valve 25 and the concentrated water discharge line 26 connected to the valve 18c, valve 16d and the permeated water discharge line 24.
- the concentrated water discharge valve 27 was fully closed, and the flow rate was adjusted by adjusting the concentrated water valve 18a.
- sodium hypochlorite was added to the pretreated water tank to 10 mg / l to forcibly deteriorate the semipermeable membrane, and then the simulated raw water with the same concentration and the permeate flow rate under the same operating conditions were used again.
- the t-time blocking performance improvement treatment was carried out by pressurized circulation at [m 3 / day] and permeation flow rate Q PT [m 3 / day]. Thereafter, the same simulated raw water as the beginning was used again, and the permeate flow rate Q P2 [m 3 / day] and the permeate TDS concentration C P2 [mg / L] were measured under the same operating conditions.
- the inhibition performance improvement rate R IM 1.56, which was an insufficient improvement rate.
- Comparative Example 4 subjected to prolonged treatment than in Example 4, but was a Q P /A ⁇ C ⁇ t 1.00(>1.2X), R IM are less as compared with Example 2 It did not improve.
- valve 16c when the hydrolysis dilution process is performed between the semipermeable membrane units 9a and 9b in FIG. 10, the valve 16c is fully closed, and instead the valves 16d and 18c are fully opened to perform dilution. Dilution was carried out by diluting from the water line 23, mixing and diluting in the intermediate water tank 5b, and then increasing the pressure again to the same pressure as the concentrated water of the semipermeable membrane unit 9a by the pressure increasing pump 8b.
- the permeated water quality C P21 of the front element was 91 mg / L
- the permeated water quality C P22 of the rear element was 90 mg / L.
- C P2 in Example 5 96 mg / L
- R IM 3
- high processing efficiency could be achieved in a shorter time.
- Table 1 The table below summarizes the examples and comparative examples. Since the table is large, it is divided into Table 1 and Table 2, but it is one table.
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Abstract
Description
(1)半透膜の一次側に、阻止性能向上剤を含有する液体を加圧供給し、膜面に接触させることによって、半透膜の阻止性能を向上させる方法であって、予め、液体が阻止性能向上剤と異なる溶質を含有するとともに、阻止性能向上剤の種類に応じて定数Xを決定し、半透膜への処理液体の供給水量QFT[m3/日]、透過水量QPT[m3/日]、半透膜の膜面積をA[m2]、阻止性能向上剤濃度C[mg/l]、通液時間t[h]、供給液体の浸透圧をπとするとき、
浸透圧πが1bar以下である場合は、
1.0X≦QPT/A×C×t≦1.4X
0.02≦QPT/QFT≦0.2
浸透圧πが1bar以上20bar以下である場合は、
0.8X≦QPT/A×C×t≦1.2X
0.2≦QPT/QFT≦0.4
浸透圧πが20bar以上40bar以下である場合は、
0.6X≦QPT/A×C×t≦1.0X
0.3≦QPT/QFT≦0.5
を満足させるように処理を施す半透膜の阻止性能向上方法。
(2)阻止性能向上剤と異なる成分を含有する液体が、半透膜の処理対象供給水、濃縮水、透過水のうち少なくとも一つである請求項1に記載の半透膜の阻止性能向上方法。
(3)半透膜の一次側が連通する複数段のユニットで構成され、前段の半透膜の一次側から排出された液体を希釈した後、後段の半透膜ユニットに供給に際し、希釈水を混合する(1)または(2)に記載の半透膜の阻止性能向上方法。
(4)希釈水が少なくとも半透膜の透過水もしくは、半透膜の処理対象供給水を含有する(3)に記載の半透膜の阻止性能向上方法。
(5)供給中に少なくとも1度、0.05MPa/s以上の変動速度で10秒以上の圧力変化をさせ、少なくとも1分間その圧力を維持する(1)~(4)のいずれかに記載の半透膜の阻止性能向上方法。
(6)半透膜の一次側に、阻止性能向上剤を含有する液体を加圧供給し、膜面に接触させることによって、半透膜の阻止性能を向上させる方法において、供給中に少なくとも1度、透過流量を0.8倍以下もしくは1.2倍以上に変動させる請求項1~5のいずれかに記載の半透膜の阻止性能向上方法。
(7)透過流量の変化を、少なくとも一次側もしくは二次側の圧力変化によって生じさせる(6)に記載の半透膜の阻止性能向上方法。
(8)透過流量の変化を、阻止性能向上剤を含有する液体の浸透圧変化によって生じさせる(6)または(7)に記載の半透膜の阻止性能向上方法。
(9)阻止性能向上剤を含有する液体を造水時の最高運転温度以上60℃以下に加温してから供給する(1)~(8)のいずれかに記載の半透膜の阻止性能向上方法。
(10)定数Xを決定するに際した前提温度をT1℃、それによって得られた定数X1とし、阻止性能向上処理温度をT2とするとき、
X=X1/{1+a×(T2-T1)}
ただし、aは、0.02≦a≦0.03を満たす定数
とする(1)~(9)のいずれかに記載の半透膜の阻止性能向上方法。
(11)阻止性能向上剤を含有する液体を加圧供給した後に、半透膜を加温する(1)~(10)のいずれかに記載の半透膜の阻止性能向上方法。
(12)半透膜の加温が高温水の供給通水である(11)に記載の半透膜の阻止性能向上方法。
(13)半透膜への供給方向を少なくとも1回逆にする(1)~(12)のいずれかに記載の半透膜の阻止性能向上方法。
(14)阻止性能向上剤を含有する液体をpH4以上pH7以下に調整して半透膜に供給する(1)~(13)のいずれかに記載の半透膜の阻止性能向上方法。
(15)半透膜がポリアミドからなるとともに、pH5.5以上pH6.8以下に調整して半透膜に供給する(14)に記載の半透膜の阻止性能向上方法。
(16)阻止性能向上剤を含有する液体が海水を含有する(1)~(15)のいずれかに記載の半透膜の阻止性能向上方法。
(17)半透膜がスパイラル型平膜エレメントを構成する(1)~(16)のいずれかに記載の半透膜の阻止性能向上方法。
(18)半透膜の2000mg/L塩化ナトリウムの除去率が90%以上であるとともに、阻止性能向上剤が少なくとも、重量平均分子量6,000以上100,000以下のポリアルキレングリコール鎖を有する化合物を含有する(1)~(17)のいずれかに記載の半透膜の阻止性能向上方法。
(19)半透膜の2000mg/L塩化ナトリウムの除去率が99.5%以上であるとともに、阻止性能向上剤が少なくとも、重量平均分子量2,000以下のポリアルキレングリコール鎖を有する化合物を含有する(1)~(17)のいずれかに記載の半透膜の阻止性能向上方法。
(20)半透膜の2000mg/L塩化ナトリウムの除去率が50%以下であるとともに、阻止性能向上剤が少なくとも、重量平均分子量10,000以上100,000以下のポリアルキレングリコール鎖を有する化合物を含有する(1)~(17)のいずれかに記載の半透膜の阻止性能向上方法。
(21)ポリアルキレングリコール鎖がポリエチレングリコール鎖である(18)~(20)のいずれかに記載の半透膜の阻止性能向上方法。
(22)少なくとも、阻止性能向上処理前に、阻止性能向上処理剤を含有しない以外の成分が同じ液体を用いて逆浸透膜に通水し、その時の供給水、透過水、濃縮水のうち、少なくとも2つの流量および濃度、水温を測定し、それらから初期透水性能として純水透過係数A0、および、阻止性能として溶質透過係数B0を算出し、その後、阻止性能向上処理液を逆浸透膜の供給、通水しながら、その時の供給水、透過水、濃縮水のうち、少なくとも2つの流量および濃度、水温を測定し、それらから初期透水性能として純水透過係数A1、および、阻止性能として溶質透過係数B2を算出し、A1/A0がRA1以下となったときのB1/B0が予め定められた値RB以下であれば、阻止性能向上処理を終了し、B1/B0がRBを超えていた場合は、阻止性能向上処理を継続し、B1/B0がRB以下になるか、A1/A0がRA2まで低下した時点で、処理を停止する(1)~(21)のいずれかに記載の半透膜の阻止性能向上方法。
(23)RA1が0.9以下、かつ、RA2が0.7以上であるとともに、RBが0.3以上0.7以下である(22)に記載の半透膜の阻止性能向上方法。
(24)純水透過係数Aが、半透膜を運転する時の最低温度TL、および溶質透過係数Bが半透膜を運転する時の最高温度THにおける値に補正した値であるか、もしくは、A、Bいずれも同じ温度に補正した値である(22)または(23)に記載の半透膜の阻止性能向上方法。
(25)原水を前処理して得た前処理水に添加した後、半透膜で分離処理して透過水を製造しながら、半透膜における阻止率が99.9%以上である阻止性能向上剤を含有する液体を半透膜への供給水に添加する(1)~(24)のいずれかに記載の半透膜の阻止性能向上方法。
(26)(1)~(25)のいずれかに記載の半透膜の阻止性能向上方法によって阻止性能を向上させた半透膜または半透膜エレメント。
(27)ポリアミドからなる(26)に記載の半透膜または半透膜エレメント。
(28)(26)または(27)に記載の半透膜または半透膜エレメントを装填した半透膜造水装置。
半透膜での阻止率が低い阻止性能向上剤(以下、向上剤L)を用いる場合、阻止性能が低い溶質(以下、溶質L)を含有するもしくは浸透圧が低い液体を用いると、半透膜ユニットの入口から出口まで透過水が分離させることによって生じる濃縮による阻止性能向上剤の濃縮も浸透圧上昇もともに起こりにくく、入口から出口まで半透膜の全体にわたって均等な阻止率向上剤の接触を得ることができる。すなわち、半透膜の阻止性の向上処理が均一に行われやすいことを意味している。
また、半透膜での阻止率が高い阻止性能向上剤(以下、向上剤H)を用い、阻止性能が高い溶質(以下、溶質H)を含有するもしくは浸透圧が高い液体を用いると、半透膜ユニットの入口から出口まで透過水が分離させることによって生じる濃縮によって向上剤Hの濃度が出口に行くほど高くなる。しかし、併せて溶質Hの濃度も高くなる。その結果、入口から出口まで透過流束は減少し、結果として、入口では、阻止性能向上剤が低濃度、かつ、透過流束は大きく、出口では、阻止性能向上剤が高濃度、かつ、透過流束は小さいため、接触する阻止性能向上剤は、入り口から出口までバランスがよくなるため好ましい。また、運転条件によっては、入口の方における効果発現速度を相対的にやや大きくしたり、相対的にやや低くすることも可能である。
向上剤Lの場合、半透膜による阻止性能が相応に高く浸透圧を生じさせる溶質(以下、溶質H)を含有させれば、半透膜ユニットの入口近傍では透過流束が大きくなり阻止性能向上剤による効果発現速度は大きく、出口近傍に行くにつれて溶質濃縮に伴う浸透圧増加によって透過流束が減少し、阻止性能向上剤の効果発現速度は低下する。すなわち、入り口に近い方で大きな阻止性能向上が必要な場合は、好ましい実施方法である。
向上剤Hの場合、阻止性能向上剤濃度が出口に近くなるほど濃縮される。一方、溶質の濃縮による浸透圧の上昇は小さいので、阻止性能向上剤の効果速度は、入口から出口に行くほど大きくなる。このような方法は、半透膜が出口近傍でよりダメージを受けた場合、例えば、スケールの析出が生じた場合に効果的である。
浸透圧πが1bar以下である場合は、
1.0X≦QPT/A×C×t≦1.4X
0.02≦QPT/QFT≦0.2
浸透圧πが1bar以上20bar以下である場合は、
0.8X≦QPT/A×C×t≦1.2X
0.2≦QPT/QFT≦0.4
浸透圧πが20bar以上40bar以下である場合は、
0.6X≦QPT/A×C×t≦1.0X
0.3≦QPT/QFT≦0.5
を満足させるように処理を施すとよい。
Js=B(Cm-Cp) ・・・(2)
(Cm-Cp)/(Cf-Cp)=exp(Jv/k) ・・・(3)
Cp=Js/Jv ・・・(4)
A=α×A25×μ25/μ ・・・(5)
B=β×B25×μ25/μ×(273.15+T)/(298.15) ・・・(6)
Cm :膜面濃度 [mg/l]
Cp :透過水濃度 [mg/l]
Js :溶質透過流束 [kg/m2/s]
Jv :純水透過流束 [m3/m2/s]
k :物質移動係数 [m/s]
A :純水透過係数 [m3/m2/Pa/s]
A25 :25℃での純水透過係数 [m3/m2/Pa/s」
B :溶質透過係数 [m/s]
B25 :25℃での溶質透過係数 [m3/m2/Pa/s]
T :温度 [℃]
α :運転条件による変動係数 [-]
β :運転条件による変動係数 [-]
ΔP :運転圧力 [Pa]
μ :粘度 [Pa・s]
μ25 :25℃での粘度 [Pa・s]
π :浸透圧 [Pa]
実施にあたって、透過水及び供給水中の総塩濃度は、各液の電気伝導度を電気伝導度計によって測定し、あらかじめ模擬海水で測定した模擬海水濃度と電気伝導度との関係式から求めた。ここでいう模擬海水とは、NaCl=23.926g/l、Na2SO4=4.006g/l、KCl=0.738g/l、NaHCO3=0.196g/l、MgCl2=5.072g/l、CaCl2=1.147g/l、H3BO3=0.0286g/lの割合で調合したものをいい、この濃度で調整した場合の全塩濃度は3.5重量%となる。
非特許文献2に示す平膜評価装置を用い、32,000[mg/l-NaCl]、25℃、pH=7の水溶液を55[bar]、供給流量3.5[L/分]で循環加圧透過させたときの透過流束が約1.0[m/日]、NaCl阻止率として約99.8%である芳香族系ポリアミド逆浸透膜を、次亜塩素酸水溶液に浸漬することで、約99.4%に低下させた。この膜に対し、同じ平膜評価装置を用いて、阻止性能向上剤として重量平均分子量8,000のポリエチレングリコールを2μmol/L添加した液体で、流量3.5L、25℃、4.5barの圧力で循環処理した。
装置は、図10に示すように原水槽2にTDS濃度CF[mg/L]に調製した模擬原水を用い、半透膜の汚染を防止するために、前処理ユニット4として東レ製UF膜モジュールによる限外ろ過を行った上で、供給ポンプ6で保安フィルター7を経由した後、昇圧ポンプ8aで、半透膜ユニット9a、9bに供給し、得られた濃縮水と透過水を循環ライン11cを通じて原水槽に全還流する方式で運転した。半透膜ユニットは、東レ(株)製逆浸透膜エレメントTM810Vを1本ずつ9a、9bに装填し、運転圧力PF[bar]、供給流量36[m3/日]、温度25[℃]で運転し、透過流量QP0[m3/日]、および、透過水TDS濃度CP0[mg/L]を測定した。
CF=1,000mg/L(浸透圧π=0.8bar)の場合の試験結果。
QPT/A×C×t=0.64(<X)の比較例1は、阻止性能向上率RIM=1.08であり、不十分な向上率となった。比較例2は、実施例2よりも長時間の処理を施し、QP/A×C×t=1.13(>1.4X)となったが、RIMは実施例2に比べて向上しなかった。
CF=10,000mg/L(浸透圧π=7.0bar)の場合の試験結果。
QP/A×C×t=0.50(<0.8X)の比較例3は、阻止性能向上率RIM=1.56であり、不十分な向上率となった。比較例4は、実施例4よりも長時間の処理を施し、QP/A×C×t=1.00(>1.2X)となったが、RIMは実施例2に比べてあまり向上しなかった。
CF=35,000mg/L(浸透圧π=24.1bar)の場合の試験結果。
QP/A×C×t=0.25(<0.6X)の比較例3は、阻止性能向上率RIM=1.46であり、不十分な向上率となった。比較例6は、実施例6よりも長時間の処理を施し、QP/A×C×t=1.00(>X)となったが、RIMは実施例6に比べてあまり向上しなかった。
CF=1,000mg/Lの場合。半透膜エレメントの1本目(前方)と2本目(後方)の間で加水希釈(=1.0m3/d添加)の比較結果。
CF=35,000mg/Lの場合の試験結果。
処理水温を40℃に上げて、処理時間を6分から5分に短縮するほかは、実施例5と同じ条件で処理を行った結果、実施例5におけるCP2=96mg/L、RIM=3.38に対し、実施例10では、CP2=94mg/L、RIM=3.75となり、より短い時間で高い処理効率を達成することができた。
2:原水槽
3:原水供給ポンプ
4:前処理ユニット
5:中間水槽
6:供給ポンプ
7:保安フィルター
8:昇圧ポンプ
9:半透膜ユニット
10:透過水ライン
11:濃縮水ライン
11a:濃縮水排出ライン
11b:濃縮薬液ライン
11c:循環ライン
11d:濃縮水ライン
12:生産水槽
13:エネルギー回収ユニット
14:薬液供給ライン
15:薬液槽
16a:供給水バルブ
16b:供給薬液バルブ
16c:バルブ
16d:バルブ
17a:透過水バルブ
17b:透過薬液バルブ
17c:バルブ
17d:バルブ
18a:濃縮水バルブ
18b:濃縮薬液バルブ
18c:濃縮水バルブ
18d:バルブ
19:薬液供給ポンプ
20:薬液添加ユニット
21:希釈水槽
22:希釈水供給ポンプ
23:希釈水ライン
24:透過水排出ライン
25:透過水排出バルブ
26:濃縮水排出ライン
27:濃縮水排出バルブ
28a:バルブ
28b:バルブ
Claims (28)
- 半透膜の一次側に、阻止性能向上剤を含有する液体を加圧供給し、膜面に接触させることによって、半透膜の阻止性能を向上させる方法において、
予め、液体が阻止性能向上剤と異なる溶質を含有するとともに、阻止性能向上剤の種類に応じて定数Xを決定し、半透膜への処理液体の供給水量QFT[m3/日]、透過水量QPT[m3/日]、半透膜の膜面積をA[m2]、阻止性能向上剤濃度C[mg/l]、通液時間t[h]、供給液体の浸透圧をπとするとき、
浸透圧πが1bar以下である場合は、
1.0X≦QPT/A×C×t≦1.4X
0.02≦QPT/QFT≦0.2
浸透圧πが1bar以上20bar以下である場合は、
0.8X≦QPT/A×C×t≦1.2X
0.2≦QPT/QFT≦0.4
浸透圧πが20bar以上40bar以下である場合は、
0.6X≦QPT/A×C×t≦1.0X
0.3≦QPT/QFT≦0.5
を満足させるように処理を施す半透膜の阻止性能向上方法。 - 阻止性能向上剤と異なる成分を含有する液体が、半透膜の処理対象供給水、濃縮水、透過水のうち少なくとも一つである請求項1に記載の半透膜の阻止性能向上方法。
- 半透膜の一次側が連通する複数段のユニットで構成され、前段の半透膜の一次側から排出された液体を希釈した後、後段の半透膜ユニットに供給に際し、希釈水を混合する請求項1または2に記載の半透膜の阻止性能向上方法。
- 希釈水が少なくとも半透膜の透過水もしくは、半透膜の処理対象供給水を含有する請求項3に記載の半透膜の阻止性能向上方法。
- 供給中に少なくとも1度、0.05MPa/s以上の変動速度で10秒以上の圧力変化をさせ、少なくとも1分間その圧力を維持する請求項1~4のいずれか1項に記載の半透膜の阻止性能向上方法。
- 半透膜の一次側に、阻止性能向上剤を含有する液体を加圧供給し、膜面に接触させることによって、半透膜の阻止性能を向上させる方法において、
供給中に少なくとも1度、透過流量を0.8倍以下もしくは1.2倍以上に変動させる請求項1~5のいずれか1項に記載の半透膜の阻止性能向上方法。 - 透過流量の変化を、少なくとも一次側もしくは二次側の圧力変化によって生じさせる請求項6に記載の半透膜の阻止性能向上方法。
- 透過流量の変化を、阻止性能向上剤を含有する液体の浸透圧変化によって生じさせる請求項6または7に記載の半透膜の阻止性能向上方法。
- 阻止性能向上剤を含有する液体を造水時の最高運転温度以上60℃以下に加温してから供給する請求項1~8のいずれか1項に記載の半透膜の阻止性能向上方法。
- 定数Xを決定するに際した前提温度をT1℃、それによって得られた定数X1とし、阻止性能向上処理温度をT2とするとき、
X=X1/{1+a×(T2-T1)}
ただし、aは、0.02≦a≦0.03を満たす定数
とする請求項1~9のいずれか1項に記載の半透膜の阻止性能向上方法。 - 阻止性能向上剤を含有する液体を加圧供給した後に、半透膜を加温する請求項1~10のいずれか1項に記載の半透膜の阻止性能向上方法。
- 半透膜の加温が高温水の供給通水である請求項11に記載の半透膜の阻止性能向上方法。
- 半透膜への供給方向を少なくとも1回逆にする請求項1~12のいずれか1項に記載の半透膜の阻止性能向上方法。
- 阻止性能向上剤を含有する液体をpH4以上pH7以下に調整して半透膜に供給する請求項1~13のいずれか1項に記載の半透膜の阻止性能向上方法。
- 半透膜がポリアミドからなるとともに、pH5.5以上pH6.8以下に調整して半透膜に供給する請求項14に記載の半透膜の阻止性能向上方法。
- 阻止性能向上剤を含有する液体が海水を含有する請求項1~15のいずれか1項に記載の半透膜の阻止性能向上方法。
- 半透膜がスパイラル型平膜エレメントを構成する請求項1~16のいずれか1項に記載の半透膜の阻止性能向上方法。
- 半透膜の2000mg/L塩化ナトリウムの除去率が90%以上であるとともに、阻止性能向上剤が少なくとも、重量平均分子量6,000以上100,000以下のポリアルキレングリコール鎖を有する化合物を含有する請求項1~17のいずれか1項に記載の半透膜の阻止性能向上方法。
- 半透膜の2000mg/L塩化ナトリウムの除去率が99.5%以上であるとともに、阻止性能向上剤が少なくとも、重量平均分子量2,000以下のポリアルキレングリコール鎖を有する化合物を含有する請求項1~17のいずれか1項に記載の半透膜の阻止性能向上方法。
- 半透膜の2000mg/L塩化ナトリウムの除去率が50%以下であるとともに、阻止性能向上剤が少なくとも、重量平均分子量10,000以上100,000以下のポリアルキレングリコール鎖を有する化合物を含有する請求項1~17のいずれか1項に記載の半透膜の阻止性能向上方法。
- ポリアルキレングリコール鎖がポリエチレングリコール鎖である請求項18~20のいずれか1項に記載の半透膜の阻止性能向上方法。
- 少なくとも、阻止性能向上処理前に、阻止性能向上処理剤を含有しない以外の成分が同じ液体を用いて逆浸透膜に通水し、
その時の供給水、透過水、濃縮水のうち、少なくとも2つの流量および濃度、水温を測定し、
それらから初期透水性能として純水透過係数A0、および、阻止性能として溶質透過係数B0を算出し、
その後、阻止性能向上処理液を逆浸透膜の供給、通水しながら、その時の供給水、透過水、濃縮水のうち、少なくとも2つの流量および濃度、水温を測定し、
それらから初期透水性能として純水透過係数A1、および、阻止性能として溶質透過係数B2を算出し、
A1/A0がRA1以下となったときのB1/B0が予め定められた値RB以下であれば、阻止性能向上処理を終了し、B1/B0がRBを超えていた場合は、阻止性能向上処理を継続し、
B1/B0がRB以下になるか、A1/A0がRA2まで低下した時点で、処理を停止する請求項1~21のいずれか1項に記載の半透膜の阻止性能向上方法。 - RA1が0.9以下、かつ、RA2が0.7以上であるとともに、RBが0.3以上0.7以下である請求項22に記載の半透膜の阻止性能向上方法。
- 純水透過係数Aが、半透膜を運転する時の最低温度TL、および溶質透過係数Bが半透膜を運転する時の最高温度THにおける値に補正した値であるか、もしくは、A、Bいずれも同じ温度に補正した値である請求項22または23に記載の半透膜の阻止性能向上方法。
- 原水を前処理して得た前処理水に添加した後、半透膜で分離処理して透過水を製造しながら、半透膜における阻止率が99.9%以上である阻止性能向上剤を含有する液体を半透膜への供給水に添加する請求項1~24のいずれか1項に記載の半透膜の阻止性能向上方法。
- 請求項1~25のいずれか1項に記載の半透膜の阻止性能向上方法によって阻止性能を向上させた半透膜。
- ポリアミドからなる請求項26に記載の半透膜。
- 請求項26または27に記載の半透膜を装填した半透膜造水装置。
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JP2020044519A (ja) * | 2018-09-20 | 2020-03-26 | 株式会社日立製作所 | 逆浸透処理装置及び逆浸透処理方法 |
KR102342446B1 (ko) * | 2018-10-18 | 2021-12-22 | 주식회사 엘지화학 | 분리막 엘리먼트의 결함 검출 방법 및 분리막 엘리먼트 결함 검출 장치 |
CN111892125A (zh) * | 2020-07-23 | 2020-11-06 | 华北电力科学研究院有限责任公司 | 一种锅炉补给水系统超滤自动清洗控制系统 |
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- 2016-01-08 WO PCT/JP2016/050584 patent/WO2016111371A1/ja active Application Filing
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- 2016-01-08 EP EP16735110.5A patent/EP3243562B1/en active Active
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- 2016-01-08 JP JP2016510847A patent/JPWO2016111371A1/ja active Pending
- 2016-01-08 JP JP2016510848A patent/JP6658510B2/ja active Active
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EP3243562B1 (en) | 2022-01-05 |
SG11201705609TA (en) | 2017-08-30 |
EP3243562A1 (en) | 2017-11-15 |
ES2906437T3 (es) | 2022-04-18 |
US20180264410A1 (en) | 2018-09-20 |
IL253335B (en) | 2022-08-01 |
JPWO2016111372A1 (ja) | 2017-10-19 |
EP3243562A4 (en) | 2018-09-05 |
JPWO2016111371A1 (ja) | 2017-10-19 |
IL253324A0 (en) | 2017-09-28 |
JP6658510B2 (ja) | 2020-03-04 |
WO2016111371A1 (ja) | 2016-07-14 |
IL253324B (en) | 2022-02-01 |
IL253335A0 (en) | 2017-09-28 |
SG11201705627SA (en) | 2017-08-30 |
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