WO2018181365A1 - 多孔質膜、膜モジュール、水処理装置、及び多孔質膜の製造方法 - Google Patents
多孔質膜、膜モジュール、水処理装置、及び多孔質膜の製造方法 Download PDFInfo
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- WO2018181365A1 WO2018181365A1 PCT/JP2018/012517 JP2018012517W WO2018181365A1 WO 2018181365 A1 WO2018181365 A1 WO 2018181365A1 JP 2018012517 W JP2018012517 W JP 2018012517W WO 2018181365 A1 WO2018181365 A1 WO 2018181365A1
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Images
Classifications
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Definitions
- the present invention relates to a porous membrane, a membrane module, a water treatment apparatus, and a method for producing a porous membrane.
- the present application claims priority based on Japanese Patent Application No. 2017-061772 filed in Japan on March 27, 2017 and Japanese Patent Application No. 2017-217681 filed in Japan on November 10, 2017. Is hereby incorporated by reference.
- Porous membranes are used in water treatment fields such as drinking water production, water purification treatment, wastewater treatment, and other various fields.
- porous membranes have been required to have membrane performance such as high fractionation performance and hydrophilicity.
- simplification of the manufacturing process of a porous membrane is also calculated
- Patent Document 1 since conventional free radical polymerization cannot control the control of polymer segments and the control of physical properties at will, it is impossible to design a copolymer having an amphiphilic block by controlled radical polymerization. It is disclosed to synthesize and use this copolymer to produce a porous membrane having permeation flux and hydrophilicity.
- Patent Document 2 discloses a polyvinylidene fluoride resin porous film excellent in low fouling property, in which a polyvinylpyrrolidone resin and an acrylate resin are combined with a polyvinylidene fluoride resin.
- Patent Document 3 discloses hydrophilicity including a film-forming polymer polyvinylidene fluoride, a polyvinylpyrrolidone-based resin, and a polymer obtained by copolymerizing a (meth) acrylic acid ester macromonomer and a hydrophilic (meth) acrylic acid ester.
- a porous membrane is disclosed.
- Patent Document 1 includes 99 to 20% by weight of a hydrophobic matrix polymer and 1 to 80% by weight of at least one hydrophilic block and at least one hydrophobic block, and is compatible with the polymer matrix.
- a polymer membrane comprising an amphiphilic block copolymer is disclosed.
- Patent Document 4 a separation membrane having a separation functional layer, the separation functional layer contains a polyvinylidene fluoride resin having a melt viscosity of 3300 Pa ⁇ s or more, and the separation functional layer has a three-dimensional network structure.
- the separation functional layer is formed by a non-solvent induced phase separation method, the separation functional layer further contains a hydrophilic polymer, and the hydrophilic polymer is composed of a polyvinylpyrrolidone resin, an acrylic resin, and a cellulose ester resin.
- a separation membrane that is one or more selected polymers is disclosed.
- Patent Document 5 includes a film-forming polymer and a hydrophilic polymer obtained by polymerizing a monomer composition containing a methacrylic acid ester macromonomer and another monomer (such as a hydrophilic (meth) acrylic acid ester).
- a porous membrane formed from a resin composition is disclosed.
- Patent Document 1 it is necessary to use radical polymerization under control substantially in order to synthesize a block copolymer in the production of a porous membrane. For this reason, it is necessary to synthesize each block copolymer step by step, and the manufacturing process is complicated.
- the porous film described in Patent Document 2 has a fouling resistance by containing polyvinylpyrrolidone in the film.
- polyvinylpyrrolidone since polyvinylpyrrolidone is water-soluble, it dissolves in water during use of the porous membrane. For this reason, there is a problem that the fouling property gradually decreases during the use of the porous membrane.
- polyvinyl pyrrolidone has a problem that it is easily decomposed by an oxidizing agent such as an aqueous sodium hypochlorite solution used under the use of a porous membrane.
- Patent Document 3 discloses a uniform porous film using a (meth) acrylic acid ester macromonomer and a polyvinylpyrrolidone resin, but does not disclose fouling resistance.
- amphiphilic block copolymer contained in the polymer film of Patent Document 1 uses radical polymerization under control substantially in its synthesis, it is necessary to synthesize each block step by step, and the production is complicated.
- the polymer film of (1) is not a multilayer structure, in order to express hydrophilicity, it is necessary to include an amphiphilic block copolymer in the whole polymer film. Therefore, a large amount of amphiphilic block copolymer is required, and the production cost of the polymer film increases.
- porous film of Patent Document 5 does not have a multilayer structure, it is necessary to include a specific hydrophilic polymer in the entire porous film in order to develop hydrophilicity. Therefore, a large amount of hydrophilic polymer is required, and the production cost of the porous membrane increases.
- the problem of an aspect of the present invention is that it can be produced in a less complicated process, has high hydrophilicity and water permeability, and has excellent fouling resistance when used in a membrane separation activated sludge method (MBR method). It is to provide a porous membrane.
- MLR method membrane separation activated sludge method
- Another object of the present invention is to provide a porous membrane having high hydrophilicity and water permeability, excellent in fouling resistance in a membrane separation activated sludge method, and capable of being easily produced at low cost, and a method for producing the same And a membrane module and a water treatment apparatus using the porous membrane.
- a porous membrane containing polymer (A) and polymer (B) Polymer (A) is a film-forming polymer,
- the polymer (B) is a unit (b1) represented by the following formula (1) (Wherein s is 2 or 3, and t is an integer of 0 to 2), And a polymer having a unit (b2) based on a hydroxyl group-containing (meth) acrylate,
- the porous membrane according to [1] further comprising: [3] The porous membrane according to [1] or [2], wherein the unit (b1) is a unit based on 2-methoxyethyl acrylate.
- a porous membrane that filters treated water into treated water A plurality of porous layers containing the polymer (A); Among the plurality of porous layers, the concentration (mass%) of the polymer (B) in all the polymers contained in at least the outermost layer on the treated water side of the porous membrane is other than the outermost layer.
- the porous membrane according to any one of [1] to [3], which is larger than the concentration (% by mass) of the polymer (B) in all polymers contained in the porous layer.
- a porous membrane precursor is formed, A method for producing a porous film having a porous layer, wherein a part or all of the polymer (C) is removed from the porous film precursor, Polymer (A) is a film-forming polymer, The polymer (B) is a unit (b1) represented by the following formula (1) (Wherein s is 2 or 3, and t is an integer of 0 to 2), And a polymer having a unit (b2) based on a hydroxyl group-containing (meth) acrylate, A method for producing a porous membrane, wherein the concentration (mass%) of the unit (b1) in the stock solution is equal to or higher than the concentration (mass%) of the unit (b2).
- a method for producing a porous membrane by filtering water to be treated into treated water, Porous material having a plurality of porous precursor layers corresponding to each of the plurality of film-forming stock solutions using a plurality of film-forming stock solutions containing the polymer (A) and a polymer (C) having a unit based on vinylpyrrolidone A film precursor is formed,
- a film-forming stock solution corresponding to at least the outermost layer on the treated water side of the porous membrane further comprises the polymer (B),
- the mass of the polymer (B) among all the polymers contained in the film-forming stock solution corresponding to the outermost layer is that of all the polymers contained in the film-forming stock solution corresponding to other porous layers other than the outermost layer.
- the porous membrane of an embodiment of the present invention has high hydrophilicity and water permeability by including a copolymer having a specific monomer unit, and has excellent fouling resistance in the membrane separation activated sludge method (MBR method).
- MBR method membrane separation activated sludge method
- the membrane module can be manufactured in a less complicated process, and is useful for a membrane module and a water treatment apparatus equipped with the membrane module.
- the copolymer used in the porous membrane of the present invention is hardly soluble in water, there is very little possibility of elution into water. For this reason, there exists an advantage that the fouling resistance at the time of MBR method use of a porous membrane is maintained for a long period of time.
- porous membrane of another aspect of the present invention has high hydrophilicity and water permeability, is excellent in fouling resistance in the membrane separation activated sludge method, and can be easily produced at low cost. It is useful for a module and a water treatment apparatus provided with this membrane module.
- a porous membrane having high hydrophilicity and water permeability and excellent in fouling resistance in a membrane separation activated sludge method is produced in a less complicated process. Can do. Further, according to the method for producing a porous membrane of another aspect of the present invention, a porous membrane having high hydrophilicity and water permeability and excellent in fouling resistance in the membrane separation activated sludge method can be obtained at low cost and easily. Can be manufactured.
- the “treated water side” of the porous membrane is the side having the membrane surface that comes into contact with the liquid before filtration.
- “Hydrophobic” means that the contact angle of the film-forming polymer (A) with respect to bulk pure water is 60 ° or more.
- “Bulk contact angle” means that the film-forming polymer (A) is dissolved in the solvent (S) described later, and after the dissolved solution is poured, the solvent (S) is evaporated to form a smooth film. The contact angle when water droplets are attached to the surface.
- a “macromonomer” is a high molecular weight monomer having a polymerizable functional group, and is also called a macromer.
- the “terminal” of the macromonomer refers to the end of the main chain when the longest part of the molecular chain of the macromonomer is the main chain.
- the “terminal group” of the macromonomer is a group on the side opposite to the side to which the group having an unsaturated double bond of the macromonomer is added.
- (Meth) acrylate is a generic term for acrylate and methacrylate
- (meth) acrylic acid is a generic term for acrylic acid and methacrylic acid.
- “ ⁇ ” indicating a numerical range means that numerical values described before and after that are included as a lower limit value and an upper limit value.
- the porous film of the present invention comprises a polymer (A) which is a film-forming polymer (hereinafter also referred to as “film-forming polymer (A)”), a unit (b1) represented by formula (1), and a hydroxyl group.
- the polymer (B) which has the unit (b2) based on containing (meth) acrylate is included.
- the concentration (mass%) of the unit (b1) contained in the porous membrane is equal to or higher than the concentration (mass%) of the unit (b2) contained in the porous membrane. And when the concentration (mass%) of the unit (b1) contained in the porous membrane is equal to or higher than the concentration (mass%) of the unit (b2) contained in the porous membrane, the structure of the porous membrane becomes uniform, Mechanical properties (for example, bubble point pressure) of the porous membrane are improved.
- the concentration (% by mass) of the unit (b1) contained in the porous membrane is preferably at least twice the concentration (% by mass) of the unit (b2) contained in the porous membrane, more preferably at least 3 times. 5 times or more is more preferable.
- the film-forming polymer (A) is one of the constituent components of the porous film.
- the film-forming polymer (A) is for maintaining the structure of the porous film.
- the composition of the film-forming polymer (A) can be selected according to the characteristics required for the porous film.
- examples of the film-forming polymer (A) include fluorine-containing polymers, polyvinyl chloride, polyethylene, polypropylene, polystyrene, polystyrene derivatives, polyamides. , Polyurethane, polycarbonate, polysulfone, polyethersulfone, and cellulose acetate.
- the film-forming polymer (A) is preferably hydrophobic because the porous film is difficult to dissolve in pure water and the structure of the porous film can be easily maintained.
- a fluorine-containing polymer is particularly preferable from the viewpoint that chemical resistance and oxidation deterioration resistance can be imparted to the porous film.
- hydrophobic means that the contact angle of the film-forming polymer (A) with respect to bulk pure water is 60 ° or more.
- the contact angle of the bulk means that the film-forming polymer (A) is dissolved in the solvent (S) described later, and after the dissolved solution is poured, the solvent (S) is evaporated to form a smooth film on the surface. This is the contact angle when water drops are attached.
- fluorine-containing polymer examples include polyvinylidene fluoride, vinylidene fluoride-hexafluoropropylene copolymer, ethylene-chlorotrifluoroethylene copolymer, polyvinyl fluoride, and polytetrafluoroethylene.
- fluorine-containing polymer polyvinylidene fluoride is preferable from the viewpoint that oxidation resistance and mechanical durability can be imparted to the porous membrane.
- film-forming polymer (A) one type may be used alone, or two or more types may be used in combination.
- the film-forming polymer (A) is preferably a polymer that can be dissolved in the solvent (S) described later and is difficult to dissolve in pure water.
- polyvinylidene fluoride is particularly preferable from the viewpoints of solubility in the solvent (S), chemical resistance and heat resistance of the porous film.
- the film-forming polymer (A) has a mass average molecular weight (Mw) of preferably 100,000 to 2,000,000, and more preferably 300,000 to 1,500,000. If the mass average molecular weight of the film-forming polymer (A) is not less than the lower limit, the mechanical strength of the porous film tends to be good, and if it is not more than the upper limit, the solubility in the solvent (S) is good. It tends to be good. When using what has a weight average molecular weight of the said range as a film formation polymer (A), what has a different weight average molecular weight can be mixed and it can be set as the film formation polymer (A) which has a predetermined
- GPC gel permeation chromatography
- the polymer (B) is one of the constituent components of the porous membrane.
- the polymer (B) has a unit (b2) represented by the above formula (1) and a unit (b2) based on a hydroxyl group-containing (meth) acrylate.
- the polymer (B) may have a unit (b3) having a group represented by the formula (2).
- the polymer (B) may have other units (b4).
- the unit (b1) is a unit represented by the formula (1) and is one of the constituent units of the polymer (B).
- the unit (b1) is preferably a monomer unit based on 2-methoxyethyl acrylate from the viewpoint of imparting fouling resistance and hydrophilicity to the porous membrane.
- the reason why the polymer (B) has the unit (b1) can impart fouling resistance to the porous membrane is considered as follows.
- water that hydrates the surface of the polymer free water (water bonded to the polymer with a weak force), intermediate water (water bonded to the polymer with an intermediate force), antifreeze water (with a strong force against the polymer) It is known that there is bound water).
- intermediate water is present on the membrane surface, when a porous membrane is used in the membrane separation activated sludge method, it becomes difficult for proteins in the activated sludge to adhere to the membrane surface, and as a result, fouling resistance is imparted. Conceivable.
- a monomer unit in which a low carbon number alkoxy group is attached to the terminal of the low carbon number alkyl ester of acrylic acid in the porous membrane that is, represented by the above formula (1). It is considered that it is effective to contain the unit (b1), and among them, a monomer unit based on 2-methoxyethyl acrylate is considered effective.
- the unit (b2) is a unit based on a hydroxyl group-containing (meth) acrylate and is one of the constituent units of the polymer (B).
- the hydrophilicity of the porous membrane is further increased.
- Examples of the hydroxyl group-containing (meth) acrylate include 2-hydroxyethyl (meth) acrylate, 2-hydroxypropyl (meth) acrylate, 2-hydroxybutyl (meth) acrylate, 3-hydroxybutyl (meth) acrylate, Examples include 4-hydroxybutyl (meth) acrylate, polyethylene glycol (meth) acrylate, and polypropylene glycol (meth) acrylate.
- a hydroxyl-containing (meth) acrylate may be used individually by 1 type, and may be used in combination of 2 or more type.
- the unit (b3) is a unit having a group represented by the formula (2), and can be one of the constituent units of the polymer (B).
- the polymer (B) has the unit (b3), the polymer (B) can be immobilized on the porous film, and a porous film excellent in physical resistance and chemical resistance can be obtained.
- R 1 to R n are each independently a hydrogen atom, an alkyl group, a cycloalkyl group, an aryl group or a heterocyclic group, and X 1 to X n are each independently a hydrogen atom or a methyl group
- n is an integer from 3 to 10,000.
- a dotted line represents a single bond or a repetition of one or more (meth) acrylic acid ester units.
- R 1 to R n are each independently a hydrogen atom, an alkyl group, a cycloalkyl group, an aryl group, or a heterocyclic group. At least one hydrogen atom of the alkyl group, cycloalkyl group, aryl group or heterocyclic group may be substituted with a substituent described later.
- Examples of the alkyl group include linear or branched alkyl groups having 1 to 20 carbon atoms. Specific examples of the alkyl group include a methyl group, an ethyl group, an n-propyl group, and an i-propyl group. Etc. Examples of the cycloalkyl group include cycloalkyl groups having 3 to 20 carbon atoms, and specific examples include a cyclopropyl group, a cyclobutyl group, an adamantyl group, and the like. Examples of the aryl group include aryl groups having 6 to 18 carbon atoms, and specific examples include a phenyl group and a naphthyl group.
- heterocyclic group examples include a heterocyclic group having 5 to 18 carbon atoms having a nitrogen atom, an oxygen atom or a sulfur atom, and specific examples thereof include a ⁇ -lactone group and an ⁇ -caprolactone group.
- R 1 to R n examples include an alkyl group, aryl group, carboxy group, alkoxycarbonyl group (—COOR ′), cyano group, hydroxy group, amino group, amide group (—CONR′R ′′), halogen
- R ′ and R ′′ are each independently a hydrogen atom, an alkyl group, a cycloalkyl group, or an aryl group.
- Examples of the alkoxycarbonyl group for the substituent include a methoxycarbonyl group.
- a dimethylamide group etc. are mentioned as an amide group of a substituent.
- Examples of the halogen atom for the substituent include a fluorine atom, a chlorine atom, a bromine atom, and an iodine atom.
- Examples of the alkoxy group for the substituent include alkoxy groups having 1 to 12 carbon atoms, and specific examples include a methoxy group.
- hydrophilic group or ionic group of the substituent examples include an alkali salt of a carboxy group (—COOH), an alkali salt of a sulfoxyl group (—SO 3 H), a poly (alkylene oxide) group (polyethylene oxide group, polypropylene oxide group). Etc.), cationic substituents (quaternary ammonium base, etc.) and the like.
- R 1 to R n are preferably at least one selected from the group consisting of an alkyl group and a cycloalkyl group, and more preferably an alkyl group.
- an alkyl group a methyl group, an ethyl group, an n-propyl group or an i-propyl group is preferable, and a methyl group is more preferable from the viewpoint of availability of a macromonomer described later.
- X 1 to X n are each independently a hydrogen atom or a methyl group, preferably a methyl group. From the viewpoint of ease of synthesis of the macromonomer described later, it is preferable that at least half of X 1 to X n are methyl groups. As a method for confirming that more than half of X 1 to X n are methyl groups, an analysis method using a known magnetic resonance spectrum (NMR) may be mentioned.
- NMR magnetic resonance spectrum
- n is a natural number of 3 to 10,000. n is preferably a natural number of 10 to 10,000.
- Examples of the unit (b3) include units based on the macromonomer represented by the formula (3).
- N is an integer of 3 to 10,000, each R is independently a hydrogen atom, an alkyl group, a cycloalkyl group, an aryl group or a heterocyclic group, and Z is a terminal group of the macromonomer .
- the macromonomer has an unsaturated double bond capable of radical polymerization at one end of the poly (meth) acrylate segment. That is, the macromonomer has an unsaturated double bond capable of radical polymerization with 2-methoxyethyl acrylate, hydroxyl group-containing (meth) acrylate and the like at one end.
- each R is independently a hydrogen atom, an alkyl group, a cycloalkyl group, an aryl group or a heterocyclic group. At least one hydrogen atom of the alkyl group, cycloalkyl group, aryl group or heterocyclic group may be substituted with the above-described substituent.
- Z is a terminal group of the macromonomer.
- the terminal group include a hydrogen atom and a group derived from a radical polymerization initiator, similarly to the terminal group of a polymer obtained by known radical polymerization.
- Examples of the (meth) acrylate ester constituting the poly (meth) acrylate segment (skeleton) in the macromonomer include methyl (meth) acrylate, ethyl (meth) acrylate, n-propyl (meth) acrylate, Isopropyl (meth) acrylate, n-butyl (meth) acrylate, isobutyl (meth) acrylate, t-butyl (meth) acrylate, isoamyl (meth) acrylate, hexyl (meth) acrylate, (meth) acrylic Octyl acid, lauryl (meth) acrylate, dodecyl (meth) acrylate, stearyl (meth) acrylate, phenyl (meth) acrylate, benzyl (meth) acrylate, glycidyl (meth) acrylate, (meth) acrylic acid 2-ethylhexyl, 2-
- the (meth) acrylic acid ester is preferably a methacrylic acid ester from the viewpoint of easy availability of the monomer and the mechanical properties of the polymer (B).
- Methyl methacrylate, n-butyl methacrylate, lauryl methacrylate, methacrylic acid Dodecyl, stearyl methacrylate, 2-ethylhexyl methacrylate, glycidyl methacrylate, 2-hydroxyethyl methacrylate, 4-hydroxybutyl methacrylate, Blemmer (registered trademark) PME-100, Blemmer (registered trademark) PME-200 or Blemmer ( (Registered trademark) PME-400 is more preferable, methyl methacrylate, n-butyl methacrylate, 2-ethylhexyl methacrylate, 2-hydroxyethyl methacrylate, 4-hydroxybutyl methacrylate, Blemmer (registered trademark) PME 100, Blemmer
- the number average molecular weight (Mn) of the macromonomer is preferably 1,000 to 1,000,000, more preferably 3,000 to 80,000, and more preferably 5,000 to 1,000,000 from the viewpoint of the balance of mechanical properties of the polymer (B). 60,000 is more preferable, and 10,000 to 50,000 is particularly preferable.
- the molecular weight distribution (Mw / Mn: mass average molecular weight / number average molecular weight) of the macromonomer is preferably 1.5 to 5.0 from the viewpoint of the balance of mechanical properties of the polymer (B).
- the number average molecular weight and molecular weight distribution of the macromonomer are determined by gel permeation chromatography using polymethyl methacrylate as a standard sample.
- the macromonomer may be used alone or in combination of two or more.
- a method for producing a macromonomer a method using a cobalt chain transfer agent (for example, US Pat. No. 4,680,352), a method using an ⁇ -substituted unsaturated compound such as ⁇ -bromomethylstyrene as a chain transfer agent (For example, International Publication No. 88/04304), a method for chemically bonding a polymerizable group (for example, Japanese Patent Application Laid-Open No. 60-133007, US Pat. No. 5,147,952), a method by thermal decomposition ( For example, Japanese Patent Laid-Open No. 11-240854) may be mentioned.
- a manufacturing method of a macromonomer the method of manufacturing using a cobalt chain transfer agent from the point which can manufacture a macromonomer efficiently is preferable.
- Examples of the polymerization method of (meth) acrylic acid ester when producing a macromonomer include a bulk polymerization method, a solution polymerization method, an aqueous dispersion polymerization method (suspension polymerization method, emulsion polymerization method, etc.) and the like.
- a solution polymerization method or an aqueous dispersion polymerization method is preferable from the viewpoint of simplifying the macromonomer recovery step.
- Solvents used in the solution polymerization method include hydrocarbons (such as toluene), ethers (such as diethyl ether and tetrahydrofuran), halogenated hydrocarbons (such as dichloromethane and chloroform), ketones (such as acetone), alcohols (such as methanol), and nitriles (such as Acetonitrile, etc.), esters (ethyl acetate, etc.), carbonates (ethylene carbonate, etc.), supercritical carbon dioxide and the like.
- a solvent may be used individually by 1 type and may be used in combination of 2 or more type.
- the method for producing the macromonomer is preferably a method having a step of reacting a solvent, a (meth) acrylic ester, a polymerization initiator, and a chain transfer agent at a temperature of 25 to 200 ° C. for 0.5 to 24 hours.
- the other unit (b4) includes a monomer (2-methoxyethyl acrylate, etc.) constituting the unit (b1), a hydroxyl group-containing (meth) acrylate constituting the unit (b2), and a macromonomer constituting the unit (b3). It is a unit based on the monomer.
- the other unit (b4) can be one of the constituent units of the polymer (B).
- units (b4) are not particularly limited as long as they can be copolymerized with 2-methoxyethyl acrylate, hydroxyl group-containing (meth) acrylate, macromonomer and the like.
- Other monomers constituting the unit (b4) include ethyl (meth) acrylate, n-propyl (meth) acrylate, (meth) from the viewpoint of controlling the solubility of the polymer (B) in the solvent (S).
- the concentration of the unit (b1) is preferably 20 to 95% by mass, more preferably 30 to 90% by mass, and further 40 to 85% by mass. preferable. If the concentration of the unit (b1) is not less than the lower limit, hydrophilicity, water permeability and fouling resistance can be sufficiently imparted to the porous membrane, and the polymer (B) becomes substantially water-insoluble, There is little concern about elution under the usage environment. Moreover, if the density
- the concentration of the unit (b2) is preferably 0.1 to 40% by mass, more preferably 0.5 to 38% by mass, 0.8% More preferred is 35% by mass. If the density
- the concentration (mass%) of the unit (b1) contained in the polymer (B) is not less than the concentration (mass%) of the unit (b2) contained in the polymer (B).
- the concentration (mass%) of the unit (b1) contained in the polymer (B) is preferably 2 times or more of the concentration (mass%) of the unit (b2) contained in the polymer (B), preferably 3 times or more. More preferred is 5 times or more.
- the concentration of the unit (b3) is preferably 1 to 60% by mass among all the units constituting the polymer (B) (100% by mass). More preferably, it is more preferably 10% to 45% by weight.
- the concentration of the unit (b3) is not less than the lower limit value, the flexibility of the porous membrane is good. If the concentration of the unit (b3) is not more than the above upper limit value, the fouling resistance of the porous membrane tends not to be impaired.
- the concentration of other units (b4) is preferably 1 to 50% by mass among all the units constituting the polymer (B) (100% by mass). More preferably, it is 4.2 to 40% by mass.
- the concentration of the other unit (b4) is not less than the lower limit value, the flexibility of the porous membrane is good. If the concentration of the other unit (b4) is not more than the above upper limit value, the fouling resistance of the porous membrane tends not to be impaired.
- the number average molecular weight of the polymer (B) is preferably 1,000 to 5,000,000, preferably 2,000 to 500,000, and more preferably 5,000 to 300,000. When the number average molecular weight of the polymer (B) is within the above range, the thermal stability of the polymer (B), the mechanical strength of the resulting porous membrane and the hydrophilicity of the outer surface tend to increase.
- the number average molecular weight of the polymer (B) is determined by gel permeation chromatography using polystyrene as a standard sample.
- the polymer (B) may be used alone or in combination of two or more polymers having different unit concentrations, molecular weight distributions, or different molecular weights.
- the polymer (B) may be a random copolymer, a block copolymer, or a graft copolymer.
- a random copolymer is synthesized, a method using a known free radical polymerization is simple.
- a method using controlled radical polymerization is simple.
- a solution polymerization method is mentioned as a polymerization method of the monomer component at the time of manufacturing a polymer (B).
- the solvent (S) used in the solution polymerization method is not particularly limited as long as the polymer (B) is soluble.
- the solvent (S) is preferably one that can dissolve the film-forming polymer (A).
- solvent (S) acetone, N, N-dimethylformamide (DMF), N, N-dimethylacetamide (DMAc), dimethyl sulfoxide (DMSO), N-methylpyrrolidone (NMP), hexamethylphosphoric triamide, tetra Examples include methyl urea, triethyl phosphate, and trimethyl phosphate.
- solvent (S) acetone, DMF, DMAc, DMSO, and NMP are preferable because they are easy to handle and have excellent solubility of the film-forming polymer (A) and the polymer (B).
- Solvent (S) may be used alone or in combination of two or more.
- a chain transfer agent adjusts the molecular weight of a polymer (B).
- chain transfer agents include mercaptans, hydrogen, ⁇ -methylstyrene dimer, terpenoids and the like.
- a chain transfer agent may be used individually by 1 type, and may be used in combination of 2 or more type.
- radical polymerization initiator examples include organic peroxides and azo compounds.
- organic peroxides include 2,4-dichlorobenzoyl peroxide, t-butyl peroxypivalate, o-methylbenzoyl peroxide, bis-3,5,5-trimethylhexanoyl peroxide, octanoyl peroxide, t-Butylperoxy-2-ethylhexanoate, cyclohexanone peroxide, benzoyl peroxide, methyl ethyl ketone peroxide, dicumyl peroxide, lauroyl peroxide, diisopropylbenzene hydroperoxide, t-butyl hydroperoxide, di-t -Butyl peroxide and the like.
- azo compound examples include 2,2′-azobisisobutyronitrile (AIBN), 2,2′-azobis (2,4-dimethylvaleronitrile), 2,2′-azobis (2,4-dimethyl-4). -Methoxyvaleronitrile) and the like.
- benzoyl peroxide AIBN
- 2,2′-azobis 2,4-dimethylvaleronitrile
- 2,2 ′ is easy to obtain and has a half-life temperature suitable for polymerization conditions.
- -Azobis (2,4-dimethyl-4-methoxyvaleronitrile) is preferred.
- a radical polymerization initiator may be used individually by 1 type, and may be used in combination of 2 or more type.
- the addition amount of the radical polymerization initiator is preferably 0.0001 to 10 parts by mass with respect to 100 parts by mass of the monomer component.
- the polymerization temperature for polymerizing the monomer component is preferably ⁇ 100 to 250 ° C., more preferably 0 to 200 ° C. in consideration of the boiling point of the solvent (S) and the use temperature range of the radical polymerization initiator.
- the polymerized solution (D) after polymerization can be used as it is as a film-forming stock solution.
- the polymer (C) having a unit based on vinylpyrrolidone (hereinafter, also referred to as “polymer (C)”) can be one of the components of the film-forming stock solution.
- the polymer (C) is added as a pore opening aid for controlling the phase separation between the film-forming polymer (A) and the solvent (S).
- polymer (C) examples include polyvinylpyrrolidone and copolymers having units based on vinylpyrrolidone and other units (unit (b2), unit (b4), etc.).
- a polymer (C) may be used individually by 1 type, and may be used in combination of 2 or more type.
- the peak area having a mass average molecular weight of 1 ⁇ 10 6 or more with respect to the total area value of the peak area of the chromatogram obtained by GPC measurement using an RI detector in terms of the physical properties of the porous membrane is preferred.
- the polymer (C) having the molecular weight distribution it exhibits good detergency (removability) as a phase separation control agent, and fine cracks are easily generated in the structure of the porous membrane. It tends to be able to improve the filtration performance of the membrane.
- the polymer (C) can be easily removed from the porous membrane precursor described below, and Since the polymer (C) remains in the porous membrane, the porous membrane swells with water and the pores are not easily blocked, and the porous membrane has good water permeability, preferably 5% by mass, and 8% by mass. Is more preferable, and 10 mass% is further more preferable.
- an upper limit of content of the high molecular polymer whose mass mean molecular weight is 1 * 10 ⁇ 6 > or more 25 mass% is preferable and 20 mass% is more preferable.
- the concentration of the film-forming polymer (A) is preferably 60 to 99.9% by mass, more preferably 70 to 98% by mass, and further preferably 80 to 97% by mass. If the concentration of the film-forming polymer (A) is equal to or higher than the lower limit value, mechanical properties tend to be imparted to the porous film. If the concentration is equal to or lower than the upper limit value, the contact angle of the film surface with pure water is reduced. It tends to be possible.
- the concentration of the polymer (B) is preferably 0.1 to 20% by mass, more preferably 1 to 15% by mass, and further preferably 3 to 10% by mass. If the concentration of the polymer (B) is not less than the lower limit value, the film tends to be imparted with fouling resistance and hydrophilicity, and if it is not more than the upper limit value, the mechanical properties of the porous film can be maintained.
- the concentration of the polymer (B) with respect to the total (100% by mass) of the film-forming polymer (A) and the polymer (B) contained in the porous membrane is preferably 0.1 to 20% by mass. More preferably, it is more preferably 4 to 15% by mass.
- the concentration of the polymer (B) with respect to the total of the film-forming polymer (A) and the polymer (B) contained in the porous membrane is equal to or higher than the lower limit, fouling resistance is easily imparted to the surface of the porous membrane, if less than the upper limit, the polymer (B) from the less water that closes the inside film can passing water, pure water permeation flux 5 (m 3 / m 2 / MPa / h) or more porous A film is easily obtained.
- the concentration of the unit (b1) is preferably 0.02 to 19% by mass, more preferably 0.3 to 13.5% by mass, and 1.2 to 8.5% by mass. Is more preferable. If the concentration of the unit (b1) is not less than the lower limit, hydrophilicity, water permeability and fouling resistance can be sufficiently imparted to the porous membrane, and the polymer (B) becomes substantially water-insoluble, There is little concern about elution under the usage environment. Moreover, if the density
- the concentration of the unit (b2) is preferably 0.0001 to 8% by mass, more preferably 0.005 to 5.7% by mass, and 0.024 to 3.5% by mass. Is more preferable. If the density
- the concentration of the porous membrane (100% by mass) and the unit (b3) is preferably 0.001 to 12% by mass, more preferably 0.05 to 7.5% by mass. Preferably, it is 0.3 to 4.5% by mass.
- concentration of the unit (b3) is not less than the lower limit value, the flexibility of the porous membrane is good. If the concentration of the unit (b3) is not more than the above upper limit value, the fouling resistance of the porous membrane tends not to be impaired.
- the concentration of each unit in the porous membrane (100% by mass) is the composition of the porous membranes (hollow fiber membranes M-A1 to A7, M′-A1 to A5, and M′-B1) in Examples. It can be measured by the method described in 1. If the following inconveniences (i) to (iv) occur during measurement, they can be handled as shown in (i) to (iv). (I) When the support is not peeled off from the hollow fiber membrane, the hollow fiber membrane is immersed in a deuterated solvent as it is, the porous membrane other than the support is dissolved, the support is removed, and a sample is obtained.
- the porous film of the present invention can contain the aforementioned polymer (C) in addition to the film-forming polymer (A) and the polymer (B) as long as the effects of the present invention are not impaired.
- the polymer (C) is usually added to the film-forming stock solution in the production of the porous membrane and removed in the washing step of the porous membrane precursor, but remains in the porous membrane without being completely removed in the washing step. May be.
- the concentration of the polymer (C) in the porous membrane (100% by mass) is preferably 0.1 to 15% by mass, more preferably 0.3 to 12% by mass. 0.5 to 10% by mass is more preferable. If the concentration of the polymer (C) is not less than the lower limit, the fouling resistance and water permeability of the porous membrane tend not to be impaired. If the concentration is not more than the upper limit, the pores are blocked by the polymer (C). Less. Moreover, since the polymer (C) is dissolved in water, setting the concentration of the polymer (C) to be equal to or less than the above upper limit reduces the possibility of damaging the water quality by the dissolution of the polymer (C) in the treated water.
- the film-forming polymer (A) and the polymer (B) in the porous film may be compatible, may not be compatible, or may be partially compatible.
- the polymer (B) may be present at least on the surface of the film-forming polymer (A), that is, on the surface of the porous film.
- the presence of the polymer (B) on the surface of the porous membrane can impart fouling resistance and hydrophilicity to the porous membrane.
- the surface of the porous membrane means the surface of all the pores in the porous membrane, and does not mean the front, back, outside or inside of the shape of the porous membrane.
- the polymer (C) in the porous membrane may or may not be compatible with the film-forming polymer (A) and the polymer (B). Well, only a part may be compatible. Most of the polymer (C) is removed in the process of producing the porous film, but is covered with the film-forming polymer (A) and / or the polymer (B) in the process of phase separation and removed in the washing process described later. May exist in an impossible state. Even if the polymer (C) is present in such a state in the porous membrane, the effect of the present invention is not affected.
- the porous membrane of the present invention may contain various additives without departing from the object of the present invention.
- Additives include fibrous materials such as cellulose nanofibers, glass fibers, carbon fibers, and acrylic fibers; resin powders such as polyvinyl acetate, cellulose derivatives, and acrylic resins: inorganic such as silica particles, titanium oxide particles, and activated carbon Particles; surfactants such as polyvinyl alcohol, polyethylene glycol, polypropylene glycol, glycerin; and the like.
- the porous membrane of the present invention is a treatment water by filtering the treated water, It may be a porous film having a plurality of porous layers containing the film-forming polymer (A).
- at least the outermost layer ( ⁇ ) on the treated water side of the porous film further includes a polymer (B) in addition to the film-forming polymer (A).
- the mass of the polymer (B) in all polymers contained in the outermost layer ( ⁇ ) is larger than the mass of the polymer (B) in all polymers contained in other porous layers other than the outermost layer.
- the outermost layer ( ⁇ ) may further contain a polymer (C) in addition to the film-forming polymer (A).
- the mass ⁇ B of the polymer (B) of all the polymers contained in the outermost layer ( ⁇ ) is the polymer (B) of all the polymers contained in the porous layer ( ⁇ ) other than the outermost layer ( ⁇ ). Is larger than the mass ⁇ B of . If the mass ⁇ B is larger than the mass ⁇ B , if the outermost layer ( ⁇ ) contains the polymer (B) necessary and sufficient to exhibit hydrophilicity, water permeability and fouling resistance, other porous It means that the amount of the polymer (B) contained in the quality layer ( ⁇ ) can be reduced or zero.
- the mass ⁇ B is preferably 1.2 times or more, more preferably 2 times or more of the mass ⁇ B. Most preferably, the mass ⁇ B is zero.
- the ratio of the film-forming polymer (A) in the outermost layer ( ⁇ ) is preferably 60 to 99.9% by mass, more preferably 70 to 99% by mass, and further 80 to 95% by mass in the outermost layer ( ⁇ ). preferable.
- the ratio of the polymer (B) in the outermost layer ( ⁇ ) is preferably 0.1 to 40% by mass, more preferably 1 to 30% by mass, and further preferably 5 to 20% by mass in the outermost layer ( ⁇ ). If the ratio of a polymer (B) is more than the said lower limit, hydrophilicity, water permeability, and fouling resistance can fully be provided to a porous membrane. If the ratio of the polymer (B) is not more than the above upper limit value, the polymer (B) is less likely to clog the porous membrane and water can be passed therethrough, so that the pure water permeation flux is 5 m 3 / m 2 / It tends to be easy to obtain a porous film of MPa / h or more.
- the ratio of the polymer (C) in the outermost layer ( ⁇ ) is preferably 0 to 15% by mass, and 0 to 12% by mass in the outermost layer ( ⁇ ). More preferred is 0 to 10% by mass.
- the porous layer ( ⁇ ) other than the outermost layer ( ⁇ ) may further contain the polymer (B) in addition to the film-forming polymer (A). Good.
- the other porous layer ( ⁇ ) may further contain a polymer (C) in addition to the film-forming polymer (A).
- the proportion of the film-forming polymer (A) in the other porous layer ( ⁇ ) is preferably 60 to 100% by mass, more preferably 70 to 100% by mass, and more preferably 80 to 100% of the other porous layer ( ⁇ ). More preferred is mass%.
- the proportion of the polymer (B) in the other porous layer ( ⁇ ) is 0 to 40% by mass in the other porous layer ( ⁇ ). It is preferably 0 to 30% by mass, more preferably 0 to 20% by mass.
- the proportion of the polymer (C) in the other porous layer ( ⁇ ) is 0 to 15% by mass in the other porous layer ( ⁇ ). It is preferably 0 to 12% by mass, more preferably 0 to 10% by mass.
- the average pore diameter of the pores in the porous layer is preferably 1 to 1200 nm from the viewpoint of being able to be used for bacteria and virus removal, protein and enzyme purification, or water supply applications. If the average pore diameter is 1 nm or more, a high water permeation pressure tends not to be required when treating water. If the average pore diameter is 1200 nm or less, bacteria, viruses, suspension in clean water There is a tendency to easily remove substances and the like.
- the average pore diameter of the pores in the porous layer is more preferably 500 nm or less, further preferably 400 nm or less, and particularly preferably 350 nm or less.
- the average pore diameter of the pores in the porous layer is a value obtained by photographing a cross section of the porous membrane using a scanning electron microscope and performing image analysis processing. For example, the outer surface portion of the porous membrane is observed using a scanning electron microscope, 30 pores are randomly selected, the longest diameter of each pore is measured, and the longest diameter of 30 pores is determined. Find on average.
- porous membrane form examples of the form of the porous membrane include a hollow fiber membrane, a flat membrane and the like, and a hollow fiber membrane is preferable because it can be easily processed with an arbitrary length and the membrane module can be filled with a high filling rate.
- the porous film may have a macrovoid or spherulite structure in the film.
- the porous membrane of the present invention may have a support.
- a support By having the support, a plurality of porous layers are reinforced by the support, and physical properties such as burst pressure and tensile strength can be improved.
- the support include woven fabric, non-woven fabric, braided string, knitted string, and net.
- the material for the support include synthetic fibers, semi-synthetic fibers, regenerated fibers, and natural fibers.
- Synthetic fibers include polyamide fibers such as nylon 6, nylon 66 and aromatic polyamide; polyester fibers such as polyethylene terephthalate, polybutylene terephthalate, polylactic acid and polyglycolic acid; acrylic fibers such as polyacrylonitrile; polyethylene and polypropylene Polyolefin fiber such as polyvinyl alcohol fiber; polyvinylidene chloride fiber; polyvinyl chloride fiber; polyurethane fiber; phenol resin fiber; fluorine fiber such as polyvinylidene fluoride and polytetrafluoroethylene; polyalkylene paraoxybenzoate System fibers and the like.
- Examples of the semi-synthetic fibers include cellulose derivative fibers made from cellulose diacetate, cellulose triacetate, chitin, chitosan and the like: protein fibers called promix.
- Examples of the regenerated fiber include cellulosic regenerated fibers (rayon, cupra, polynosic, etc.) obtained by the viscose method, copper-ammonia method, organic solvent method and the like.
- Examples of natural fibers include flax and jute.
- porous membrane when the form of the porous membrane is a hollow fiber membrane, a hollow braided cord or knitted cord can be used as a support as it is.
- a reinforced hollow fiber membrane is obtained by providing a porous layer on the inner or outer surface of the string.
- the outer diameter of the hollow fiber membrane is preferably 20 to 3,000 ⁇ m, more preferably 30 to 2,800 ⁇ m, and further preferably 40 to 2,700 ⁇ m. If the outer diameter of the hollow fiber membrane is equal to or greater than the lower limit, yarn breakage tends to hardly occur during film formation. If the outer diameter of the hollow fiber membrane is less than or equal to the above upper limit value, the hollow shape tends to be maintained, and it tends to be difficult to flatten even when an external pressure is applied.
- the thickness of the hollow fiber membrane is preferably 5 to 250 ⁇ m, and preferably 30 to 200 ⁇ m. More preferred is 50 to 180 ⁇ m. If the film thickness of the hollow fiber membrane is equal to or greater than the lower limit, yarn breakage tends to hardly occur during film formation. If the film thickness of the hollow fiber membrane is not more than the above upper limit value, it tends to have high water permeability.
- the porous film of the present invention contains the film-forming polymer (A) and the polymer (B).
- the outer surface of the porous membrane is hydrophilized, and the difference in water permeability between the dry state and the wet state can be reduced.
- the hydrophilicity of the porous membrane of the present invention uses the value of the degree of hydrophilicity (HP: no unit) calculated from the following formula (2) as an index. (W d20 / W w100 ) (2) W d20 : WF when the porous membrane is in a dry state and the measurement pressure is 20 kPa. Ww100 : WF when the porous membrane is wet with water and the measurement pressure is 100 kPa. Since the porous membrane of the present invention has high hydrophilicity, the HP value can be set to 0.5 to 1.3.
- the pure water permeation flux (Water Flux) of the porous membrane of the present invention is formed using the polymer (C), it is 5 m 3 / m 2 / MPa / h or more and 200 m 3 / m 2 / MPa / h. It can have a pure water permeation flux as low as less. If the pure water permeation flux is equal to or more than the lower limit value, it is preferable as a water treatment membrane application because a large amount of water can be treated within a certain time. If the pure water permeation flux is less than the above upper limit value, defects in the porous membrane can be reduced, so that it can be used in a wide range of fields such as clean water and sewage.
- the porous membrane of the present invention may be produced using a polymer composition containing the aforementioned film-forming polymer (A), polymer (B), and polymer (C).
- the polymer composition can be used in a method for producing a porous film, which will be described later, by mixing the above-mentioned film-forming polymer (A) with a solvent capable of dissolving to form a film-forming stock solution.
- Preferred embodiments of the film-forming polymer (A), the polymer (B), and the polymer (C) are as described above.
- the concentration of the film-forming polymer (A) in the polymer composition (100% by mass) is preferably 20 to 90% by mass, more preferably 20 to 80% by mass, further preferably 30 to 70% by mass, and 40 to 60% by mass. % Is particularly preferred. If the concentration of the film-forming polymer (A) is not less than the lower limit value, it tends to be easily a porous film, and if it is not more than the upper limit value, the contact angle of the membrane surface with pure water can be lowered. There is a tendency.
- the concentration of the polymer (B) in the polymer composition (100% by mass) is preferably 0.1 to 20% by mass, more preferably 1 to 15% by mass, and further preferably 3 to 10% by mass. If the concentration of the polymer (B) is equal to or higher than the lower limit value, the film tends to be imparted with fouling resistance and hydrophilicity, and if it is equal to or lower than the upper limit value, a porous film can be easily formed.
- the concentration of the polymer (C) in the polymer composition (100% by mass) is preferably 5 to 50% by mass, more preferably 10 to 45% by mass, and further preferably 20 to 40% by mass. If the concentration of the polymer (C) is not less than the lower limit value, it tends to be easily a porous film, and if it is not more than the upper limit value, the mechanical strength of the porous film tends to increase.
- the film-forming polymer (A), the polymer (B), and the polymer (C) are mixed with the solvent (S) to prepare a film-forming stock solution (porous membrane preparation liquid) (preparation step).
- the obtained film-forming stock solution is immersed in a coagulation liquid and solidified to obtain a porous film precursor (coagulation step).
- a part or all of the solvent (S) and polymer (C) remaining in the obtained porous membrane precursor is removed by washing (cleaning step).
- the washed porous membrane precursor is dried to obtain a porous membrane (drying step).
- the film-forming stock solution is obtained by mixing the film-forming polymer (A), the polymer (B), and the polymer (C) with the solvent (S).
- the film-forming stock solution contains a film-forming polymer (A), a polymer (B), a polymer (C), and an additive
- it is preferable that a part of the additive is dissolved in the solvent (S).
- it is uniformly dispersed it does not necessarily have to be dissolved.
- the film-forming polymer (A) and the polymer (C) are directly added to the polymerized solution (D) after the production of the polymer (B). ) May be added and dissolved.
- a solvent (S) may be further added and diluted so that the polymerization solution (D) or the film-forming stock solution has a desired concentration.
- an additive When an additive is added to the film-forming stock solution, it may be added directly to the solvent (S) or may be added in a state dissolved in the solvent (S), and the film-forming polymer (A), polymer (B), and The polymer (C) may be pre-compounded or may be directly added to the polymerization solution (D) or the film-forming stock solution.
- the film-forming polymer (A), the polymer (B), and the polymer (C) are dissolved while heating the solvent (S) if the boiling point of the solvent (S) is not exceeded.
- the solvent (S) may be cooled as necessary.
- the concentration of the film-forming polymer (A) in the film-forming stock solution (100% by mass) is preferably 5 to 40% by mass, more preferably 8 to 30% by mass, further preferably 10 to 25% by mass, and 10 to 20% by mass. % Is particularly preferred. If the concentration of the film-forming polymer (A) is equal to or higher than the lower limit value, it tends to be easily a porous film, and if it is equal to or lower than the upper limit value, it easily dissolves in the solvent (S). There is a tendency to be able to.
- the concentration of the polymer (B) in the film-forming stock solution (100% by mass) is preferably 0.1 to 10% by mass, more preferably 0.2 to 8% by mass, and further preferably 0.4 to 6% by mass. If the concentration of the polymer (B) is equal to or higher than the lower limit value, it tends to be easily a porous film, and if the concentration is equal to or lower than the upper limit value, the solvent (S) of the film-forming polymer (A). There is a tendency for the solubility of to increase.
- the concentration of the polymer (C) in the film-forming stock solution (100% by mass) is preferably 5 to 30% by mass, more preferably 6 to 25% by mass, and further preferably 8 to 20% by mass. If the concentration of the polymer (C) is equal to or higher than the lower limit value, it tends to be easily a porous film, and if the concentration is equal to or lower than the upper limit value, the film-forming polymer (A) and the polymer (B) There exists a tendency for the solubility to a solvent (S) to increase.
- the concentration of the solvent (S) in the film-forming stock solution (100% by mass) is preferably 50 to 89.9% by mass, more preferably 55 to 85% by mass, and further preferably 60 to 80% by mass. If the concentration of the solvent (S) is equal to or higher than the lower limit value, a high permeation flux tends to be obtained, and if it is equal to or lower than the upper limit value, a porous membrane can be easily obtained.
- the coagulating liquid is preferably an aqueous solution containing 50% by mass or less of the solvent (S) from the viewpoint of controlling the pore diameter of the membrane.
- the solvent (S) contained in the coagulation liquid and the solvent (S) contained in the film-forming stock solution may be the same type or different types, but are preferably the same type.
- the temperature of the coagulation liquid is preferably 10 to 90 ° C. If the temperature of the coagulation liquid is equal to or higher than the lower limit value, the water permeability of the porous membrane tends to be improved, and if the temperature is equal to or lower than the upper limit value, the mechanical strength of the porous membrane tends to be favorably maintained.
- the porous membrane precursor is immersed in either one or both of water and an aqueous solution such as an aqueous solution of sodium hypochlorite at 40 to 100 ° C., so that the solvent (S) remaining in the porous membrane precursor or It is preferable to remove part or all of the polymer (C) by washing.
- an aqueous solution such as water and / or an aqueous sodium hypochlorite solution can be repeated a plurality of times.
- the washed porous membrane precursor is preferably dried at 60 to 120 ° C. for 1 minute to 24 hours. If the drying temperature is equal to or higher than the lower limit, the drying process time can be shortened and the production cost can be reduced. Therefore, it is preferable for industrial production, and if it is equal to or lower than the upper limit, the porous membrane precursor shrinks in the drying step. Therefore, it is possible to suppress the occurrence of excessive cracking, and micro cracks tend not to occur on the outer surface of the porous film.
- the porous membrane of the present invention is a porous membrane having a plurality of porous layers containing the film-forming polymer (A), the treated water being filtered to obtain treated water. It can be manufactured by a method including the following steps.
- Step (a) In the step (a), for example, the film-forming polymer (A) and the polymer (C), and if necessary, the polymer (B) are dissolved in the solvent (S) to prepare a plurality of film-forming stock solutions.
- Step (a) can be performed according to the above-described preparation step.
- the porous membrane of the present invention is a porous membrane having a plurality of porous layers containing the film-forming polymer (A), the treated water being filtered to obtain treated water.
- the film-forming stock solution (x) corresponding to at least the outermost layer ( ⁇ ) among the plurality of film-forming stock solutions further contains the polymer (B).
- the mass x B of the polymer (B) out of all the polymers contained in the film-forming stock solution (x) is contained in the film-forming stock solution (y) corresponding to the porous layer ( ⁇ ) other than the outermost layer ( ⁇ ). It is larger than the mass y B of the polymer (B) of all the polymers to be obtained.
- the mass x B is preferably 1.2 times or more, more preferably 2 times or more of the mass y B. Most preferred, the mass y B is 0.
- the concentration of the polymer (B) in the film-forming stock solution (x) (100% by mass) is preferably 0.1 to 10% by mass, more preferably 0.2 to 8% by mass, and 0.4 to 6% by mass. Further preferred. If the concentration of the polymer (B) is equal to or higher than the lower limit value, it tends to be easily a porous film, and if the concentration is equal to or lower than the upper limit value, the solvent (S) of the film-forming polymer (A). There is a tendency for the solubility of to increase.
- the concentration of the polymer (B) in the film-forming stock solution (y) (100% by mass) is preferably 0 to 10% by mass, more preferably 0 to 8% by mass, and further preferably 0 to 6% by mass.
- step (b) for example, a plurality of film-forming stock solutions are immersed in a coagulating liquid in a state of being arranged in layers, and solidified to have a plurality of porous precursor layers corresponding to each of the plurality of film-forming stock solutions. A porous membrane precursor is formed.
- the step (b) can be performed according to the above-described solidification step.
- Step (c) can be performed according to the above-described washing step and drying step.
- the porous film of the present invention described above includes the film-forming polymer (A) and the polymer (B), it has high fouling resistance. Moreover, even if it is once dried, water can be passed at a low pressure. Moreover, since it is hydrophilized in the process of film formation only by adding a polymer to the film-forming stock solution, it can be produced by a simple method without requiring solvent washing or crosslinking treatment.
- the porous membrane of the present invention is a porous membrane having a plurality of porous layers containing the film-forming polymer (A), the water to be treated being filtered to obtain treated water. Since the outermost layer ( ⁇ ) on the treated water side of the porous membrane contains the polymer (B), the treated water side of the porous membrane has high hydrophilicity and the entire porous membrane also has high water permeability. Moreover, since the outermost layer ( ⁇ ) on the treated water side of the porous membrane contains the polymer (B), the treated water side of the porous membrane is excellent in the fouling resistance in the membrane separation activated sludge method.
- the mass ⁇ B of the polymer (B) out of all the polymers contained in the outermost layer ( ⁇ ) is the polymer of all the polymers contained in the porous layer ( ⁇ ) other than the outermost layer ( ⁇ ) ( If the polymer (B) necessary and sufficient for exhibiting hydrophilicity, water permeability and fouling resistance is included in the outermost layer ( ⁇ ) because it is larger than the mass ⁇ B of B), the other porous layer ( The amount of polymer (B) contained in ⁇ ) can be reduced or made zero. Therefore, compared with the case where the polymer (B) is uniformly contained in the entire porous membrane, the amount of the expensive polymer (B) used can be reduced, and the porous membrane can be produced at a low cost. In addition, since at least the outermost layer on the treated water side of the porous membrane only needs to contain the polymer (B), it does not require special treatment such as solvent washing and crosslinking treatment, and can be easily produced.
- the membrane module of the present invention includes the porous membrane of the present invention.
- the membrane module includes a flat membrane module having two flat membranes and a frame-like support that supports four sides of these flat membranes, a plurality of hollow fiber membranes, and a housing that supports the ends of these hollow fiber membranes. Examples thereof include a hollow fiber membrane module.
- the water treatment apparatus of the present invention includes the membrane module of the present invention.
- a membrane separation activated sludge device provided with a water tank, a membrane module disposed in the water tank, and an air diffuser disposed below the membrane module, a liquid flow passage and a membrane disposed in the liquid flow passage
- An air supply and deaeration device equipped with a module may be used.
- 2-Methoxyethyl polyacrylate Polymer polymethyl methacrylate macromonomer polymerized under the same conditions as in Synthesis Example 4 except that 2-hydroxyethyl methacrylate and macromonomer are not used: Macromonomer poly (2-hydroxyethyl methacrylate) synthesized under the same conditions as the synthesis of macromonomer (b3-1) described below: Polymer polyvinylpyrrolidone polymerized under the same conditions as in Synthesis Example 4 except that 2-methoxyethyl acrylate and macromonomer are not used: PVP K80 manufactured by Nippon Shokubai Co., Ltd.
- Vinylidene fluoride unit 2.2 to 2.4 ppm, 2.7 to 3.1 ppm 2-Methoxyethyl acrylate unit: 4.0-4.2 ppm, 3.4-3.6 ppm, 3.2-3.3 ppm 2-hydroxyethyl methacrylate units: 4.7 ppm to 4.9, 3.8 to 4.1 ppm, 3.5 to 3.7 ppm Polymethyl methacrylate macromonomer unit: 3.5 to 3.7 ppm Polyvinylpyrrolidone unit: 1.7 to 1.8 ppm, 1.8 to 1.9 ppm, 3.5 to 3.6 ppm (5) From the area of the peak assigned in (4), the integration ratio of each unit was calculated, and the concentration (mol%) of each unit was calculated with the total integration ratio of all units being 100 (mol%). However, the macromonomer unit was calculated using the number average molecular weight instead of the molecular weight. (6) The concentration (% by mass) of each unit was calculated by dividing the concentration (mol%) of each unit
- composition of porous membranes (hollow fiber membranes M-B1 to B4 and M′-B2 to B3)] (1) After the hollow fiber membrane was cut open, the support was pulled off from the hollow fiber membrane with tweezers, and the support was separated from the porous membrane. (2) The outer layer and the inner layer of the porous membrane were separated by tweezers and separated into samples of each layer. (3) Thereafter, the same as (3) to (6) in the measurement of “the composition of the porous membrane (hollow fiber membranes MA1 to A7, M′-A1 to A5, and M′-B1)”. Then, the concentration (mass%) of each unit in each layer was measured.
- composition of polymer (B) and polymer (B ′) meaning a polymer to be compared with polymer (B)
- the measurement was carried out in the same manner as the above-mentioned “composition of porous membrane” except that the samples were polymer (B) and polymer (B ′).
- Mw Mass Average Molecular Weight (Mw) of Film-Forming Polymer (A)
- Mw Mass Average Molecular Weight (Mw) of Film-Forming Polymer (A)
- GPC manufactured by Tosoh Corporation, “HLC-8020” (product name)
- Column TSK GUARD COLUMN ⁇ (7.8 mm ⁇ 40 mm) and three TSK-GEL ⁇ -M (7.8 ⁇ 300 mm) connected in series.
- Eluent N, N-dimethylformamide (DMF) solution of lithium bromide (LiBr) (concentration of LiBr: 20 mM). Measurement temperature: 40 ° C. Flow rate: 0.1 mL / min.
- Mp peak top molecular weight
- Mn and Mw / Mn of the unit (b3), the polymer (B), and the polymer (B ′) are obtained using GPC (“HLC-8220” (product name) manufactured by Tosoh Corporation) under the following conditions. It was. Column: TSK GUARD COLUMN SUPER HL (4.6 ⁇ 35 mm) and two TSK-GEL SUPER HZM-H (4.6 ⁇ 150 mm) connected in series. Eluent: DMF solution of lithium chloride (LiCl) (LiCl concentration: 0.01M).
- the outer diameter (membrane outer diameter) of the hollow fiber membrane was measured by the following method. A sample to be measured was cut into approximately 10 cm, several bundles were bundled, and the whole was covered with a polyurethane resin. The polyurethane resin also entered the hollow part of the support. After curing the polyurethane resin, a thin piece having a thickness (longitudinal direction of the film) of about 0.5 mm was sampled using a razor blade. The cross section of the sampled hollow fiber membrane was observed with a projector (Nikon Corporation, PROFILE PROJECTOR V-12) at an objective lens of 100 times. A mark (line) was aligned with the position of the outer surface in the X direction and Y direction of the cross section of the hollow fiber membrane, and the outer diameter was read. This was measured three times to determine the average value of the outer diameter.
- the film thickness of the porous layer was measured by the following method. Sampling was performed in the same manner as the sample whose outer diameter was measured. The cross section of the sampled hollow fiber membrane was observed with a projector (Nikon Corporation, PROFILE PROJECTOR V-12) at an objective lens of 100 times. The film thickness was read by aligning marks (lines) at the positions of the outer surface and inner surface of the film at the 3 o'clock position in the cross section of the hollow fiber membrane. Similarly, the film thickness was read in the order of 9 o'clock, 12 o'clock, and 6 o'clock. This was measured three times to determine the average inner diameter.
- the thickness of the outer layer and the inner layer of the porous layer is the same as described above, and after reading the film thickness, a clear contrast between the outer surface of the hollow fiber membrane and the outer surface of the support of the hollow fiber membrane is obtained.
- the interface shown is present, the length between this interface and the outer surface of the hollow fiber membrane is measured as the film thickness of the outer layer, and the length from the interface to the outer surface of the support of the hollow fiber membrane is the inner layer membrane. Thickness. This was measured three times, and the average value of the film thicknesses of the outer layer and the inner layer was determined.
- Pore diameter of porous layer The pore diameter (average pore diameter) of the pores in the porous layer was measured by the following method. The cross section of the porous layer was photographed at a magnification of 5,000 using a scanning electron microscope, and the average pore diameter of the pores was determined by image analysis processing of the obtained photograph. As image analysis processing software, IMAGE-PRO PLUS version 5.0 of Media Cybernetics was used.
- Pure water 25 ° C.
- the container and the other end face of the hollow fiber membrane were connected by a tube, and the amount of pure water coming out of the hollow fiber membrane was measured for 1 minute by applying an air pressure of 100 kPa to the container. This was measured three times to obtain an average value, and this value was divided by the surface area of the sample to obtain a pure water permeation flow rate Ww100 in a wet state.
- the hollow fiber membrane was cut into a length of 4 cm, and the opening on one end face was sealed with polyurethane resin. Pure water (25 ° C.) is put into a container, the container and the other end of the hollow fiber membrane are connected by a tube, 100 kPa air pressure is applied to the container for 1 minute, the inside of the hollow fiber membrane is degassed, and pure water Replaced with The hollow fiber membrane was put into a hot air drier at 80 ° C. for 24 hours to dry the hollow fiber membrane. Pure water (25 ° C.) was put into the container, and the container and the other end face of the dried hollow fiber membrane were immediately connected with a tube.
- the amount of pure water coming out of the hollow fiber membrane was measured for 1 minute by applying an air pressure of 20 kPa, and the amount of pure water coming out of the hollow fiber membrane was further measured for 1 minute by increasing the air pressure to 100 kPa.
- the air pressure was increased to 100 kPa and the amount of pure water coming out of the hollow fiber membrane was measured for 1 minute.
- the hollow fiber membrane was cut into a length of 4 cm, and the opening on one end face was sealed with polyurethane resin.
- the hollow fiber membrane was depressurized in ethanol for 5 minutes or more and then immersed in pure water for 5 minutes or more to replace ethanol with pure water.
- the hollow fiber membrane was immersed in pure water (25 ° C.), a tube was connected to the other end surface of the hollow fiber membrane, and air pressure was slowly applied from the tube to the hollow portion of the hollow fiber membrane. The pressure was gradually increased, and the pressure at which bubbles were confirmed on the surface of the hollow fiber membrane was measured. This was measured 10 times to obtain an average value.
- CoBF-1 1.00 g of cobalt acetate (II) tetrahydrate (manufactured by Wako Pure Chemical Industries, Ltd., Wako Special Grade) under a nitrogen atmosphere in a reactor equipped with a stirrer; diphenylglyoxime (Tokyo Kasei Co., Ltd.) (EP grade) 1.93 g; 80 mL of diethyl ether (manufactured by Kanto Chemical Co., Ltd., special grade) that has been purged with nitrogen for 30 minutes or more and deoxygenated, and stirred for 30 minutes at room temperature. Obtained.
- cobalt acetate (II) tetrahydrate manufactured by Wako Pure Chemical Industries, Ltd., Wako Special Grade
- the number average molecular weight (Mn) of the macromonomer (b3-1) was 40,000, and the molecular weight distribution (Mw / Mn) was 2.3.
- the introduction rate of the terminal double bond of the macromonomer (b3-1) was almost 100%.
- the macromonomer (b3-1) was a compound in which R in the above formula (2) was a methyl group.
- the number average molecular weight (Mn) of the macromonomer (b3-2) was 18,000, and the molecular weight distribution (Mw / Mn) was 2.1.
- the introduction rate of terminal double bonds in the macromonomer (b3-2) was almost 100%.
- the macromonomer (b3-2) was a compound in which R in the above formula (2) was a methyl group.
- Table 1 shows the ratio of each unit constituting the polymer (B-1), and the number average molecular weight (Mn), mass average molecular weight (Mw), and molecular weight distribution (Mw / Mn) of the polymer (B-1). .
- Table 1 shows the ratio of each unit constituting the obtained polymer, and the number average molecular weight (Mn), mass average molecular weight (Mw), and molecular weight distribution (Mw / Mn) of the obtained polymer.
- Table 1 shows the ratio of each unit constituting the polymer (B′-1), and the number average molecular weight (Mn), mass average molecular weight (Mw), and molecular weight distribution (Mw / Mn) of the polymer (B′-1). Shown in
- MEA 2-methoxyethyl acrylate (manufactured by Wako Pure Chemical Industries, Ltd., Wako first grade).
- HEMA 2-hydroxyethyl methacrylate (manufactured by Mitsubishi Chemical Corporation, Acryester (registered trademark) HO).
- MMA Methyl methacrylate (manufactured by Mitsubishi Chemical Corporation, Acryester (registered trademark) M).
- DMAEMA Dimethylaminoethyl methacrylate (manufactured by Mitsubishi Chemical Corporation, Acryester (registered trademark) DM).
- V-65 2,2′-azobis (2,4′-dimethylvaleronitrile) (manufactured by Wako Pure Chemical Industries, Ltd., trade name: V-65).
- DMAc N, N-dimethylacetamide (manufactured by Wako Pure Chemical Industries, Ltd., reagent special grade).
- PMMA-MM polymethyl methacrylate macromonomer.
- PVDF polyvinylidene fluoride
- PVP polyvinyl
- Preparation Examples A2 to A7, Preparation Example B1] (Preparation of membrane-forming stock solutions (A2) to (A7) and membrane-forming stock solution (B1))
- the film-forming polymer (A), the polymer (B), the composition of the polymer (C), and the solvent (S) were changed in the same manner as the film-forming stock solution (A1) except that the solvent was changed as shown in Table 2.
- Stock solutions (A2) to (A7) and a film-forming stock solution (B1) were obtained.
- Preparation Example B2 (Preparation of membrane-forming stock solution (B2)) A film-forming stock solution (B2) was obtained in the same manner as the film-forming stock solution (B1) except that the polymerization liquid (D-2) was not blended and the amount of N, N-dimethylacetamide was changed to 5.10 parts. It was.
- Preparation Example B3 (Preparation of membrane-forming stock solution (B3)) Film formation was carried out in the same manner as the film-forming stock solution (B1) except that the amount of the polymerization liquid (D-2) was changed to 0.15 parts and the amount of N, N-dimethylacetamide was changed to 5.01 parts. Stock solution (B3) was obtained.
- Preparation Example A′1 (Preparation of membrane-forming stock solution (A'1)) A film-forming stock solution (A′1) was obtained in the same manner as the film-forming stock solution (A1) except that the polymerization solution used in Preparation Example A1 was not used.
- a hollow fiber membrane (hollow fiber membrane-shaped porous membrane) was prepared using the production apparatus 1 shown in FIG.
- the film-forming stock solution (A1) prepared from the stock solution supply device 2 of the production apparatus 1 was fed and applied to the support 4 in the application unit 3.
- the support 4 coated with the film-forming stock solution is immersed in a coagulation liquid (40% by mass aqueous solution of N, N-dimethylacetamide) in a coagulation bath 5 at 77 ° C.
- a hollow fiber membrane precursor 6 having a layer was obtained.
- Examples A2 to A7 Production of hollow fiber membranes (MA2) to (MA7)
- the hollow fiber membranes (MA2) to (A2) are prepared in the same manner as the hollow fiber membranes (MA1) except that the membrane preparation solutions (A2) to (A7) are used in place of the membrane preparation stock (A1). (MA7) was produced.
- the hollow fiber membranes of the present invention obtained in Examples A1 to A6 have a HP value of 0.7 to 0.9, and have high hydrophilicity, thereby exhibiting high water permeability from a dry state. It became clear. Moreover, it became clear that a bubble point pressure is 100 kPa or more and has high filtration performance and mechanical properties.
- Comparative Example A1 since the polymer (B) was not included, the obtained hollow fiber porous membrane was hydrophobic and the hydrophilic HP was 0. In Comparative Example A2, since the polymer (B) did not contain the unit (b1), the resulting hollow fiber membrane had a low hydrophilic HP value of 0.4 and did not have high hydrophilicity. In Comparative Example A3, since the concentration (mass%) of the unit (b1) contained in the porous membrane is less than the concentration (mass%) of the unit (b2) contained in the porous membrane, the membrane structure is not good. As a result, the bubble point pressure was as low as 50 kPa.
- Comparative Example A4 since the unit (b2) was not contained in the porous membrane, the hydrophilicity of the porous membrane was low. In Comparative Example A5, since the concentration (mass%) of the unit (b1) contained in the porous membrane is less than the concentration (mass%) of the unit (b2) contained in the porous membrane, the structure of the membrane is not good. As a result, the bubble point pressure was as low as 60 kPa.
- Example B1 Manufacture of hollow fiber membrane (M-B1)) Using a support manufacturing apparatus, multifilaments of polyester fibers (made of polyethylene terephthalate, fineness 417 dtex) were circularly knitted into a cylindrical shape and heat-treated at 210 ° C. to obtain a support. The outer diameter of the obtained support was 1.45 mm.
- a hollow fiber membrane (hollow fiber membrane-shaped porous membrane) was prepared using the production apparatus 1 shown in FIG.
- the film-forming stock solution (B1) and the film-forming stock solution (B2) are fed from the stock solution supply device 2 of the production apparatus 1 to the double-tube nozzle, and the film-forming stock solution (B2) from the inside of the double-tube nozzle in the coating unit 3;
- the film-forming stock solution (B1) was simultaneously applied to the support 4 from the outside of the double-tube nozzle.
- the support 4 coated with the film-forming stock solution is immersed in a coagulation liquid (40% by mass aqueous solution of N, N-dimethylacetamide) in a coagulation bath 5 at 77 ° C.
- a hollow fiber membrane precursor 6 having a porous precursor layer was obtained.
- the step of immersing the hollow fiber membrane precursor in hot water at 60 ° C. and the step of immersing in the sodium hypochlorite aqueous solution were repeated, and finally dried in a drying furnace heated to 115 ° C. for 3 minutes to form two layers.
- a hollow fiber membrane (MB1) having a porous layer (inner layer and outer layer) was obtained.
- Example B4 Manufacture of hollow fiber membrane (M-B4)
- Hollow fiber was prepared in the same manner as the hollow fiber membrane (M-B1) except that the membrane-forming stock solution (B2) was changed to the membrane-forming stock solution (B3) and the film thicknesses of the inner layer and outer layer were changed as shown in Table 4.
- a membrane (M-B4) was obtained.
- Example B1 Manufacture of hollow fiber membrane (M'-B1)
- M'-B1 Manufacture of hollow fiber membrane (M'-B1)
- a single-layer hollow fiber membrane was obtained in the same manner as in Example B1, except that only the membrane-forming stock solution (B2) was used and only the membrane-forming stock solution (B2) was applied to the support 4 and the film thickness was changed.
- Example B2 Manufacture of hollow fiber membrane (M'-B2)
- M'-B2 Manufacture of hollow fiber membrane (M'-B2)
- a hollow fiber membrane was obtained in the same manner as in Example B1, except that the membrane-forming stock solution (B1) was changed to the membrane-forming stock solution (B2) and the film thicknesses of the inner layer and the outer layer were changed.
- Example B4 Manufacture of hollow fiber membrane (M'-B3)
- Example B4 except that the film-forming stock solution (B1) was changed to the film-forming stock solution (B2), the film-forming stock solution (B3) was changed to the film-forming stock solution (B1), and the film thicknesses of the inner layer and the outer layer were changed.
- a hollow fiber membrane was obtained in the same manner.
- the ratio (inner layer and outer layer) of each polymer constituting the obtained hollow fiber membrane, and the thickness ( ⁇ m) (inner layer and outer layer), outer membrane diameter ( ⁇ m), bubble point pressure ( kPa), average pore diameter ( ⁇ m), water permeability W d20 (m 3 / m 2 / mPa / h), water permeability W d100 (m 3 / m 2 / mPa / h), water permeability W w100 (m 3 / m) 2 / mPa / h) and hydrophilic HP (no unit) are shown in Table 4.
- the water to be treated was filtered using the water treatment system 100 shown in FIG.
- the water treatment system 100 includes a raw water pump 10, a raw water flow path 11, a nitrification tank 12, a stirrer 13, a circulation flow path 14, a biological reaction tank 20, a separation membrane module 21, a diffuser tube 22, a treated water flow path 23, a filtration pump 24, A blower 25, a circulation channel 26, and a circulation pump 27 are provided.
- Porous membranes M-A1 to M-A3 and M′-A1 to M′-A2 of Examples or Comparative Examples shown in Table 5 are used as the separation membrane module 21 of the water treatment system 100 which is an immersion type membrane separation activated sludge apparatus. Each of the 32 pieces accumulated in parallel was immersed in a biological reaction tank. General domestic wastewater was used as raw water, and a filtration test was performed under the conditions shown in Table 5 under air aeration. The results are shown in Table 5.
- FIG. 3 shows a graph of the change over time in the differential pressure.
- the differential pressure referred to here is the operating pressure of the filtration pump necessary to treat water at a predetermined flow rate, and substantially indicates the pressure difference between the membranes on the inside and outside of the membrane (described later). The same applies to accelerated filtration test-2).
- FIG. 3 the temperature in the biological reaction tank and the flux of water to be processed per day by the separation membrane module (unit: m / day, figure) so that the specific operation status can be understood together with the differential pressure. (Indicated as m / d).
- MLSS The suspended solids concentration in the tank is expressed in units of mg / L. The higher the MLSS, the higher the concentration of sludge contained in the tank.
- the hollow fiber membrane (M′-A2) of Comparative Example A2 used a polymer having a unit based on 2-hydroxyethyl methacrylate as the unit (b2), but the polymer (B1) also having a unit (b1) (B1) ), The fouling that contaminates the membrane during the filtration test occurred, and the intermembrane more than the hollow fiber membranes (M-A1) to (M-A3) using the polymer (B) having the unit (b1). The membrane was so inferior in fouling resistance that the differential pressure increased rapidly and the filtration test could not be continued.
- FIG. 4 shows a graph of the change over time in the differential pressure.
- the temperature in the biological reaction tank and the flux of water to be processed per day by the separation membrane module (unit: m / day, figure) so that the specific operation status can be understood together with the differential pressure. (Indicated as m / d).
- the hollow fiber membranes (M-2A) and (M-A4) to (M-A3) of Examples A2 and A4 to A6 use the polymer (B) having the unit (b1), and therefore are undergoing a filtration test. In this film, the increase in the transmembrane pressure difference was suppressed, and the film was excellent in fouling resistance.
- the hollow fiber membrane (M′-A1) of Comparative Example A1 was not used for the polymer (B) having the unit (b1) as in the accelerated filtration test-1 in the activated sludge, so the conditions were changed.
- the porous membrane of the present invention is suitable as a porous membrane used in water treatment fields such as drinking water production, water purification treatment, and wastewater treatment.
- a hollow porous membrane and a hollow fiber membrane module using the porous membrane of the present invention are suitable for use in a water treatment apparatus of a membrane separation activated sludge method (MBR method).
- MLR method membrane separation activated sludge method
Abstract
Description
本願は、2017年3月27日に日本に出願された特願2017-061772号及び2017年11月10日に日本に出願された特願2017-217681号に基づき優先権を主張し、その内容をここに援用する。
近年、多孔質膜には、高い分画性能や親水性といった膜の性能が求められている。また、多孔質膜の製造工程の簡略化も求められている。
特許文献1には、従来からのフリーラジカル重合では、ポリマーセグメントの制御及び物性の調節を意のままに設計することは不可能であることから、両親媒性ブロックを有するコポリマーを制御ラジカル重合によって合成し、このコポリマーを用いて、透過流束と親水性とを有する多孔質膜を製造することが開示されている。
特許文献2には、ポリフッ化ビニリデン樹脂にポリビニルピロリドン樹脂とアクリル酸エステル系樹脂を複合した、低ファウリング性に優れたポリフッ化ビニリデン系樹脂多孔質膜が開示されている。
特許文献3には、膜形成ポリマーであるポリフッ化ビニリデン、ポリビニルピロリドン系樹脂、及び、(メタ)アクリル酸エステルマクロモノマーと親水性の(メタ)アクリル酸エステルとを共重合したポリマーを含む親水性多孔質膜が開示されている。
特許文献1には、99~20質量%の疎水性マトリックスポリマー、及び、1~80質量%の、少なくとも一つの親水性ブロックと少なくとも一つの疎水性ブロックとを有し、ポリマーマトリックスと相溶性がある両親媒性ブロックコポリマー、を含むポリマー膜が開示されている。
特許文献4には、分離機能層を有する分離膜であって、分離機能層が溶融粘度3300Pa・s以上のポリフッ化ビニリデン系樹脂を含有し、かつ、分離機能層が三次元網目状構造を有し、かつ、分離機能層が、非溶媒誘起相分離法により形成され、分離機能層はさらに親水性ポリマーを含有し、親水性ポリマーが、ポリビニルピロリドン系樹脂、アクリル系樹脂及びセルロースエステル系樹脂から選ばれる1種以上のポリマーである分離膜が開示されている。
特許文献5には、膜形成ポリマー、ならびに、メタクリル酸エステルマクロモノマーとその他のモノマー(親水性の(メタ)アクリル酸エステル等)とを含むモノマー組成物を重合して得られる親水性ポリマーを含む樹脂組成物から形成される、多孔質膜が開示されている。
[1]ポリマー(A)及びポリマー(B)を含む多孔質膜であって、
ポリマー(A)は、膜形成ポリマーであり、
ポリマー(B)は、下記式(1)で表される単位(b1)
(式中、sは、2又は3であり、tは、0~2の整数である。)、
及び水酸基含有(メタ)アクリレートに基づく単位(b2)を有するポリマーであり、
多孔質膜中の単位(b1)の濃度(質量%)が単位(b2)の濃度(質量%)以上である多孔質膜。
[2]前記ポリマー(B)が、下記式(2)で表される基を有する単位(b3)
(式中、R1~Rnは、それぞれ独立に、水素原子、アルキル基、シクロアルキル基、アリール基又は複素環基であり、X1~Xnは、それぞれ独立に、水素原子又はメチル基であり、nは、3~10,000の整数である。)
をさらに有する、[1]に記載の多孔質膜。
[3]前記単位(b1)が、アクリル酸2-メトキシエチルに基づく単位である、[1]又は[2]に記載の多孔質膜。
前記ポリマー(A)を含む複数の多孔質層を有し、
前記複数の多孔質層のうち、少なくとも前記多孔質膜の被処理水側の最表層に含まれる全ポリマー中の前記ポリマー(B)の濃度(質量%)が、前記最表層以外の他の多孔質層に含まれる全ポリマー中の前記ポリマー(B)の濃度(質量%)よりも大きい、[1]~[3]のいずれか一項に記載の多孔質膜。
[6]多孔質膜中に支持体をさらに有する、[1]~[5]のいずれか一項に記載の多孔質膜。
[7][1]~[6]のいずれか一項に記載の多孔質膜を備える、膜モジュール。
[8][7]に記載の膜モジュールを備える、水処理装置。
前記多孔質膜前駆体から前記ポリマー(C)の一部又は全部を取り除く、多孔質層を有する多孔質膜の製造方法であり、
ポリマー(A)は、膜形成ポリマーであり、
ポリマー(B)は、下記式(1)で表される単位(b1)
(式中、sは、2又は3であり、tは、0~2の整数である。)、
及び水酸基含有(メタ)アクリレートに基づく単位(b2)を有するポリマーであり、
製膜原液中の単位(b1)の濃度(質量%)が単位(b2)の濃度(質量%)以上である多孔質膜の製造方法。
[10]前記ポリマー(B)が、下記式(2)で表される基を有する単位(b3)
(式中、R1~Rnは、それぞれ独立に、水素原子、アルキル基、シクロアルキル基、アリール基又は複素環基であり、X1~Xnは、それぞれ独立に、水素原子又はメチル基であり、nは、3~10,000の整数である。)
をさらに有する、[9]に記載の多孔質膜の製造方法。
[11]前記単位(b1)が、アクリル酸2-メトキシエチルに基づく単位である、[9]又は[10]に記載の多孔質膜の製造方法。
前記ポリマー(A)及びビニルピロリドンに基づく単位を有するポリマー(C)を含む複数の製膜原液を用いて、前記複数の製膜原液のそれぞれに対応した複数の多孔質前駆体層を有する多孔質膜前駆体を製膜し、
前記多孔質膜前駆体からポリマー(C)の一部又は全部を取り除く、前記ポリマー(A)を含む複数の多孔質層を有する多孔質膜の製造方法であり、
前記複数の製膜原液のうち、少なくとも前記多孔質膜の被処理水側の最表層に対応する製膜原液が前記ポリマー(B)をさらに含み、
前記最表層に対応する製膜原液に含まれる全ポリマーのうちの前記ポリマー(B)の質量が、前記最表層以外の他の多孔質層に対応する製膜原液に含まれる全ポリマーのうちの前記ポリマー(B)の質量よりも大きい、多孔質膜の製造方法。
また、本発明の別の態様の多孔質膜は、高い親水性及び透水性を有し、膜分離活性汚泥法における耐ファウリング性に優れ、かつ低コストで簡便に製造することができ、膜モジュール及びこの膜モジュールを備えた水処理装置に有用である。
また、本発明の別の態様の多孔質膜の製造方法によれば、高い親水性及び透水性を有し、膜分離活性汚泥法における耐ファウリング性に優れる多孔質膜を、低コストで簡便に製造できる。
多孔質膜の「被処理水側」とは、ろ過前の液と接触する膜表面を有する側である。
「疎水性」とは、膜形成ポリマー(A)のバルクの純水に対する接触角が60°以上であることをいう。
「バルクの接触角」とは、膜形成ポリマー(A)を後述する溶剤(S)に溶解し、溶解した溶液を流涎した後に溶媒(S)を蒸発させることで平滑なフィルムを形成し、その表面に水滴を付着させたときの接触角をいう。
マクロモノマーの「末端」とは、マクロモノマーの分子鎖の最も長い部分を主鎖とした場合、その主鎖の端部をいう。
マクロモノマーの「末端基」とは、マクロモノマーの不飽和二重結合を有する基が付加している側とは反対側の基をいう。
数値範囲を示す「~」は、その前後に記載された数値を下限値及び上限値として含むことを意味する。
また、本発明の多孔質膜は、多孔質膜に含まれる単位(b1)の濃度(質量%)が、多孔質膜に含まれる単位(b2)の濃度(質量%)以上であることを特徴とする。
多孔質膜に含まれる単位(b1)の濃度(質量%)が、多孔質膜に含まれる単位(b2)の濃度(質量%)以上であることで、多孔質膜の構造が均一になり、多孔質膜の機械物性(たとえば、バブルポイント圧力)が向上する。多孔質膜に含まれる単位(b1)の濃度(質量%)は、多孔質膜に含まれる単位(b2)の濃度(質量%)の2倍以上であることが好ましく、3倍以上がより好ましく、5倍以上がさらに好ましい。
膜形成ポリマー(A)は、多孔質膜の構成成分の一つである。
膜形成ポリマー(A)は、多孔質膜の構造を維持させるためのものである。膜形成ポリマー(A)の組成は、多孔質膜に求められる特性に応じて選択することができる。
膜形成ポリマー(A)は、1種を単独で用いてもよいし、2種以上を組み合わせて用いてもよい。
膜形成ポリマー(A)の質量平均分子量が、前記下限値以上であれば多孔質膜の機械的強度が良好となる傾向にあり、前記上限値以下であれば溶剤(S)への溶解性が良好となる傾向にある。
膜形成ポリマー(A)として前記範囲の質量平均分子量を有するものを用いる場合、異なる質量平均分子量を有するものを混合して、所定の質量平均分子量を有する膜形成ポリマー(A)とすることができる。
膜形成ポリマー(A)の質量平均分子量は、ポリスチレン又はポリメタクリル酸メチルを標準試料として用いたゲルパーミエーションクロマトグラフィ(GPC)により求められる。
ポリマー(B)は、多孔質膜の構成成分の一つである。
ポリマー(B)は、前述の式(1)で表される単位(b1)及び水酸基含有(メタ)アクリレートに基づく単位(b2)を有する。
ポリマー(B)は、その他の単位(b4)を有していてもよい。
単位(b1)は、式(1)で表される単位であり、ポリマー(B)の構成単位の一つである。
ポリマー(B)が単位(b1)を有することによって、多孔質膜に親水性、透水性及び耐ファウリング性を付与できる。
ポリマーの表面に水和する水として、自由水(高分子に弱い力で結合した水)、中間水(高分子に中間的な力で結合した水)、不凍水(高分子に強い力で結合した水)があることが知られている。膜表面に中間水が存在すると、膜分離活性汚泥法で多孔質膜を使用したときに、活性汚泥中のタンパク質等が膜表面に付着しにくくなり、その結果、耐ファウリングが付与されると考えられる。
膜表面に中間水を存在させるには、多孔質膜中に、アクリル酸の低炭素数のアルキルエステルの末端に低炭素数のアルコキシ基が付いたモノマー単位、すなわち、上記式(1)で表される単位(b1)を含有させることが有効であると考えられ、その中で、特にアクリル酸2-メトキシエチルに基づくモノマー単位が、有効であると考えられる。
単位(b2)は、水酸基含有(メタ)アクリレートに基づく単位であり、ポリマー(B)の構成単位の一つである。
ポリマー(B)が単位(b2)を有することによって、多孔質膜の親水性がより高くなる。
水酸基含有(メタ)アクリレートは、1種を単独で用いてもよく、2種以上を組み合わせて用いてもよい。
単位(b3)は、式(2)で表される基を有する単位であり、ポリマー(B)の構成単位の一つとすることができる。
ポリマー(B)が単位(b3)を有することによって、多孔質膜にポリマー(B)を固定化でき、物理的耐性及び化学的耐性に優れた多孔質膜を得ることができる。
シクロアルキル基としては、炭素数3~20のシクロアルキル基が挙げられ、具体例としては、シクロプロピル基、シクロブチル基、アダマンチル基等が挙げられる。
アリール基としては、炭素数6~18のアリール基が挙げられ、具体例としては、フェニル基、ナフチル基等が挙げられる。
複素環基としては、窒素原子、酸素原子又は硫黄原子を有する炭素数5~18の複素環基が挙げられ、具体例としては、γ-ラクトン基、ε-カプロラクトン基等が挙げられる。
置換基のアミド基としては、ジメチルアミド基等が挙げられる。
置換基のハロゲン原子としては、フッ素原子、塩素原子、臭素原子、ヨウ素原子等が挙げられる。
置換基のアルコキシ基としては、炭素数1~12のアルコキシ基が挙げられ、具体例としては、メトキシ基等が挙げられる。
後述するマクロモノマーの合成しやすさの点から、X1~Xnの半数以上がメチル基であることが好ましい。
X1~Xnの半数以上がメチル基であることを確認する方法としては、公知の磁気共鳴スペクトル(NMR)による解析方法が挙げられる。
(式中、R1~Rnは、それぞれ独立に、水素原子、アルキル基、シクロアルキル基、アリール基又は複素環基であり、X1~Xnは、それぞれ独立に、水素原子又はメチル基であり、nは、3~10,000の整数であり、Rは、それぞれ独立に、水素原子、アルキル基、シクロアルキル基、アリール基又は複素環基であり、Zは、マクロモノマーの末端基である。)
(メタ)アクリル酸エステルは、1種を単独で用いてもよく、2種以上を組み合わせて用いてもよい。
マクロモノマーの分子量分布(Mw/Mn:質量平均分子量/数平均分子量)は、ポリマー(B)の機械物性のバランスの点から、1.5~5.0が好ましい。
マクロモノマーの数平均分子量及び分子量分布は、ポリメタクリル酸メチルを標準試料として用いたゲルパーミエーションクロマトグラフィによって求められる。
溶剤は、1種を単独で用いてもよく、2種以上を組み合わせて用いてもよい。
その他の単位(b4)は、単位(b1)を構成するモノマー(アクリル酸2-メトキシエチル等)、単位(b2)を構成する水酸基含有(メタ)アクリレート、単位(b3)を構成するマクロモノマー以外のモノマーに基づく単位である。
その他の単位(b4)は、ポリマー(B)の構成単位の一つとすることができる。
その他のモノマー(b4)は、1種を単独で用いてもよいし、2種以上を組み合わせて用いてもよい。
ポリマー(B)を構成するすべての単位のうち(100質量%)、単位(b1)の濃度は、20~95質量%が好ましく、30~90質量%がより好ましく、40~85質量%がさらに好ましい。
単位(b1)の濃度が前記下限値以上であれば、多孔質膜に親水性、透水性及び耐ファウリング性を十分に付与でき、ポリマー(B)が実質的に非水溶性となるため、使用環境下で溶出の懸念が少ない。また、単位(b1)の濃度が前記上限値以下であれば、単位(b2)を含む、単位(b1)以外の単位による効果を十分に発揮できる。
単位(b2)の濃度が前記下限値以上であれば、多孔質膜の親水性がさらに高くなる。単位(b2)の濃度が前記上限値以下であれば、ポリマー(B)が水に溶けにくくなるため、多孔質膜の親水性が維持されやすい。また、後述のポリマー(C)との相溶性も高くなる傾向にある。
単位(b3)の濃度が前記下限値以上であれば、多孔質膜の柔軟性が良好となる。単位(b3)の濃度が前記上限値以下であれば、多孔質膜の耐ファウリング性を損なわない傾向がある。
その他の単位(b4)の濃度が前記下限値以上であれば、多孔質膜の柔軟性が良好となる。その他の単位(b4)の濃度が前記上限値以下であれば、多孔質膜の耐ファウリング性を損なわない傾向がある。
ポリマー(B)の数平均分子量は、1,000~5,000,000が好ましく、2,000~500,000が好ましく、5,000~300,000がより好ましい。ポリマー(B)の数平均分子量が前記範囲内であれば、ポリマー(B)の熱安定性、及び得られる多孔質膜の機械強度や外表面の親水性が高まる傾向にある。
ポリマー(B)の数平均分子量は、ポリスチレンを標準試料として用いたゲルパーミエーションクロマトグラフィによって求められる。
ランダム共重合体を合成する場合は、公知のフリーラジカル重合を用いる方法が簡便である。
ブロック共重合体及びグラフト共重合体を合成する場合は、公知の制御ラジカル重合を用いる方法が簡便である。
ポリマー(B)を製造する際のモノマー成分の重合方法としては、溶液重合法が挙げられる。
溶液重合法に用いる溶剤(S)は、ポリマー(B)が可溶であれば特に制限されない。
重合後の重合液(D)をそのまま製膜原液に用いる場合、溶剤(S)としては、膜形成ポリマー(A)を溶解できるものが好ましい。溶剤(S)としては、アセトン、N,N-ジメチルホルムアミド(DMF)、N,N-ジメチルアセトアミド(DMAc)、ジメチルスルホキシド(DMSO)、N-メチルピロリドン(NMP)、ヘキサメチルリン酸トリアミド、テトラメチルウレア、トリエチルフォスフェート、リン酸トリメチル等が挙げられる。溶剤(S)としては、取り扱いやすく、膜形成ポリマー(A)及びポリマー(B)の溶解性に優れる点から、アセトン、DMF、DMAc、DMSO、NMPが好ましい。
連鎖移動剤は、ポリマー(B)の分子量を調節するものである。連鎖移動剤としては、メルカプタン、水素、α-メチルスチレンダイマー、テルペノイド等が挙げられる。
連鎖移動剤は、1種を単独で用いてもよく、2種以上を組み合わせて用いてもよい。
有機過酸化物としては、2,4-ジクロロベンゾイルパーオキサイド、t-ブチルパーオキシピバレート、o-メチルベンゾイルパーオキサイド、ビス-3,5,5-トリメチルヘキサノイルパーオキサイド、オクタノイルパーオキサイド、t-ブチルパーオキシ-2-エチルヘキサノエート、シクロヘキサノンパーオキサイド、ベンゾイルパーオキサイド、メチルエチルケトンパーオキサイド、ジクミルパーオキサイド、ラウロイルパーオキサイド、ジイソプロピルベンゼンハイドロパーオキサイド、t-ブチルハイドロパーオキサイド、ジ-t-ブチルパーオキサイド等が挙げられる。
ラジカル重合開始剤の添加量は、モノマー成分の100質量部に対して、0.0001~10質量部が好ましい。
ビニルピロリドンに基づく単位を有するポリマー(C)(以下、「ポリマー(C)」とも言う。)は、製膜原液の構成成分の一つとすることができる。
ポリマー(C)は、膜形成ポリマー(A)と溶剤(S)との相分離を制御するための開孔助剤として添加される。
ポリマー(C)は、1種を単独で用いてもよく、2種以上を組み合わせて用いてもよい。
前記分子量分布を有するポリマー(C)を用いることによって、相分離制御剤として良好な洗浄性(除去性)を発揮し、多孔質膜の構造中に微細な割れが発生しやすくなるため、多孔質膜のろ過性能を良好とすることができる傾向にある。
多孔質膜(100質量%)中、膜形成ポリマー(A)の濃度は、60~99.9質量%が好ましく、70~98質量%がより好ましく、80~97質量%がさらに好ましい。
膜形成ポリマー(A)の濃度が、前記下限値以上であれば、多孔質膜に機械物性を付与できる傾向にあり、前記上限値以下であれば、膜の表面の純水に対する接触角を低くできる傾向にある。
ポリマー(B)の濃度が、前記下限値以上であれば膜に耐ファウリング性や親水性を付与できる傾向にあり、前記上限値以下であれば多孔質膜の機械物性が維持できる。
単位(b1)の濃度が前記下限値以上であれば、多孔質膜に親水性、透水性及び耐ファウリング性を十分に付与でき、ポリマー(B)が実質的に非水溶性となるため、使用環境下で溶出の懸念が少ない。また、単位(b1)の濃度が前記上限値以下であれば、単位(b2)を含む、単位(b1)以外の単位による効果を十分に発揮できる。
単位(b2)の濃度が前記下限値以上であれば、多孔質膜の親水性がさらに高くなる。単位(b2)の占める濃度が前記上限値以下であれば、ポリマー(B)が水に溶けにくくなるため、多孔質膜の親水性が維持されやすい。また、後述のポリマー(C)との相溶性も高くなる傾向にある。
単位(b3)の濃度が前記下限値以上であれば、多孔質膜の柔軟性が良好となる。単位(b3)の濃度が前記上限値以下であれば、多孔質膜の耐ファウリング性を損なわない傾向がある。
なお、測定の際に下の(i)~(iv)の不都合が起こった場合、(i)~(iv)のように対応することができる。
(i)支持体が中空糸膜から剥がれない場合、中空糸膜をそのまま重水素化溶媒に浸し、支持体以外の多孔質膜を溶解し、支持体を除去し、試料とする。
(ii)支持体が中空糸膜から剥がれない場合で、多孔質膜層及び支持体どちらも重水素化溶媒に溶解する場合、支持体が溶解しない溶媒に中空糸膜を浸し、多孔質膜層のみ溶解し、支持体を除去する。その後、多孔質膜層の溶媒を留去し、残った多孔質膜層を試料とする。
(iii)1H-NMRスペクトルでピークが重なっている場合、二次元の1H-NMRスペクトルを測定する等して、ピークが重ならないようにすることができる。
(iv)多孔質膜中にどのようなポリマーが含まれるか不明の場合、1H-NMRスペクトルに加え、熱分解ガスクロマトグラフィー、ゲル浸透クロマトグラフィー又は赤外線吸収スペクトル等を併用し、多孔質膜中にどのようなポリマーが含まれるか同定した後に、1H-NMRスペクトルを用いて各単位の濃度(モル%)及び各単位の濃度(質量%)を測定することができる。
ポリマー(C)の濃度が、前記下限値以上であれば、多孔質膜の耐ファウリング性及び透水性を損なわない傾向にあり、前記上限値以下であれば、ポリマー(C)による孔の閉塞が少なくなる。また、ポリマー(C)は水に溶解するため、ポリマー(C)の濃度を前記上限値以下とすることは、処理水にポリマー(C)が溶け出すことによって水質を損なう恐れを少なくする。
ポリマー(B)は、少なくとも膜形成ポリマー(A)の表面、つまり多孔質膜の表面に存在していればよい。多孔質膜の表面にポリマー(B)が存在していることにより、多孔質膜に耐ファウリング性や親水性を付与できる。
本明細書において、多孔質膜の表面とは、多孔質膜中のすべての孔の表面を意味し、多孔質膜の形状における表裏や外側若しくは内側を意味するものではない。
多孔質膜を製造する過程で、ポリマー(C)の大部分は除去されるが、相分離の過程で膜形成ポリマー(A)及び/又はポリマー(B)に覆われ、後述の洗浄工程で取り除くことが不可能な状態で存在している可能性がある。ポリマー(C)が多孔質膜中にこのような状態で存在していても、本発明の効果に影響は及ぼさない。
本発明の多孔質膜は、本目的を逸脱しない範囲において種々の添加剤を含んでもよい。
添加剤としては、セルロースナノファイバー、ガラスファイバー、カーボンファイバー、アクリルファイバーのような繊維状物質;ポリ酢酸ビニル、セルロース誘導体、アクリル樹脂のような樹脂粉末:シリカ粒子、酸化チタン粒子、活性炭等の無機粒子;ポリビニルアルコール、ポリエチレングリコール、ポリプロピレングリコール、グリセリン等の界面活性剤;等が挙げられる。
本発明の多孔質膜は、被処理水をろ過して処理水とするものであって、
膜形成ポリマー(A)を含む複数の多孔質層を有した多孔質膜であってもよい。
この場合、多孔質膜を構成する複数の多孔質層のうち、少なくとも多孔質膜の被処理水側の最表層(α)は、膜形成ポリマー(A)の他にポリマー(B)をさらに含み、最表層(α)に含まれる全ポリマー中のポリマー(B)の質量は、最表層以外の他の多孔質層に含まれる全ポリマー中のポリマー(B)の質量よりも大きい。
最表層(α)は、膜形成ポリマー(A)の他にポリマー(C)をさらに含んでいてもよい。
最表層(α)に含まれる全ポリマーのうちのポリマー(B)の質量αBは、最表層(α)以外の他の多孔質層(β)に含まれる全ポリマーのうちのポリマー(B)の質量βBよりも大きい。質量αBが質量βBよりも大きいということは、親水性、透水性及び耐ファウリング性を発揮させるのに必要十分なポリマー(B)を最表層(α)に含ませれば、他の多孔質層(β)に含まれるポリマー(B)の量を減らす又は0にすることができることを意味する。そのため、多孔質膜全体に均一にポリマー(B)を含ませる場合に比べ、高価なポリマー(B)の使用量を減らすことができ、多孔質膜を低コストで製造できる。
質量αBは、質量βBの1.2倍以上が好ましく、2倍以上がより好ましい。最も好ましいのは、質量βBが0である。
ポリマー(B)の割合が前記下限値以上であれば、多孔質膜に親水性、透水性及び耐ファウリング性を十分に付与できる。ポリマー(B)の割合が前記上限値以下であれば、ポリマー(B)が多孔質膜内を閉塞することが少なく、水が通水できることから、純水透過流束が5m3/m2/MPa/h以上の多孔質膜を得られやすい傾向にある。
多孔質膜を構成する複数の多孔質層のうち、最表層(α)以外の他の多孔質層(β)は、膜形成ポリマー(A)の他にポリマー(B)をさらに含んでいてもよい。
他の多孔質層(β)は、膜形成ポリマー(A)の他にポリマー(C)をさらに含んでいてもよい。
他の多孔質層(β)がポリマー(B)を含む場合、他の多孔質層(β)におけるポリマー(B)の割合は、他の多孔質層(β)のうち、0~40質量%が好ましく、0~30質量%がより好ましく、0~20質量%がさらに好ましい。
他の多孔質層(β)がポリマー(C)を含む場合、他の多孔質層(β)におけるポリマー(C)の割合は、他の多孔質層(β)のうち、0~15質量%が好ましく、0~12質量%がより好ましく、0~10質量%がさらに好ましい。
多孔質層における細孔の平均孔径は、バクテリアやウイルスの除去、たんぱく質や酵素の精製、又は上水用途で利用可能な点から、1~1200nmが好ましい。細孔の平均孔径が1nm以上であれば、水を処理する際に高い透水圧力を必要としなくなる傾向にあり、細孔の平均孔径が1200nm以下であれば、バクテリアやウイルス、上水中の懸濁物質等を容易に除去できる傾向にある。
多孔質層における細孔の平均孔径は、500nm以下がより好ましく、400nm以下がさらに好ましく、350nm以下が特に好ましい。
多孔質層における細孔の平均孔径は、走査型電子顕微鏡を用いて多孔質膜の断面を撮影し、画像解析処理によって求めた値である。たとえば、走査型電子顕微鏡を用いて多孔質膜の外表面部分を観察し、30個の細孔を無作為に選び、各細孔の最長径を測定し、30個の細孔の最長径を平均して求める。
多孔質膜の形態としては、中空糸膜、平膜等が挙げられ、任意の長さで加工しやすく、膜モジュールに高い充填率で膜を充填可能な点から、中空糸膜が好ましい。多孔質膜は、膜中にマクロボイド又は球晶構造を有してもよい。
本発明の多孔質膜は、支持体を有するものであってもよい。支持体を有することによって、複数の多孔質層が支持体によって補強され、破裂圧や引張強度といった物理的特性を向上させることができる。
支持体としては、織布、不織布、組紐、編紐、ネット等が挙げられる。支持体の材料としては、合成繊維、半合成繊維、再生繊維、天然繊維等が挙げられる。
半合成繊維としては、セルロースジアセテート、セルローストリアセテート、キチン、キトサン等を原料としたセルロース誘導体系繊維:プロミックスと呼称される蛋白質系繊維等が挙げられる。
再生繊維としては、ビスコース法、銅-アンモニア法、有機溶剤法等により得られるセルロース系再生繊維(レーヨン、キュプラ、ポリノジック等。)が挙げられる。
天然繊維としては、亜麻、黄麻等が挙げられる。
また、多孔質膜の形態が中空糸膜の場合、中空状の組紐又は編紐をそのまま支持体として用いることができる。紐の内表面又は外表面に多孔質層を設けることによって補強中空糸膜となる。
中空糸膜の外径が前記下限値以上であれば、製膜時に糸切れが発生しにくい傾向にある。中空糸膜の外径が前記上限値以下であれば、中空形状を保ちやすく、特に外圧がかかっても扁平化しにくい傾向にある。
中空糸膜の膜厚が前記下限値以上であれば、製膜時に糸切れが発生しにくい傾向にある。中空糸膜の膜厚が前記上限値以下であれば、高い透水性を有する傾向にある。
本発明の多孔質膜は、前述のように、膜形成ポリマー(A)とポリマー(B)とを含む。
多孔質膜がポリマー(B)を含むことにより、多孔質膜の外表面が親水化され、乾燥状態と湿潤状態の透水性能差を小さくすることができる。
(Wd20/Ww100) ・・・(2)
Wd20:多孔質膜が乾燥状態であって、測定圧力20kPaにおけるWF。
Ww100:多孔質膜が水で湿潤状態であって、測定圧力100kPaにおけるWF。
本発明の多孔質膜は、高い親水性を有することから上記HPの値は0.5~1.3とすることができる。
純水透過流束が前記下限値以上であれば、一定時間内に多量の水を処理できることから水処理膜用途として好ましい。純水透過流束が前記上限値未満であれば、多孔質膜内における欠陥を少なくすることができるため、上水、下排水等の幅広い分野で利用できる。
本発明の多孔質膜は、前述の膜形成ポリマー(A)、ポリマー(B)、及びポリマー(C)を含むポリマー組成物を用いて製造してもよい。ポリマー組成物は、前述の膜形成ポリマー(A)を溶解可能な溶剤と混合して製膜原液とすることで、後述の多孔質膜の製造方法に用いることができる。
膜形成ポリマー(A)の濃度が、前記下限値以上であれば容易に多孔質膜とすることができる傾向にあり、前記上限値以下であれば膜の表面の純水に対する接触角を低くできる傾向にある。
ポリマー(B)の濃度が、前記下限値以上であれば膜に耐ファウリング性や親水性を付与できる傾向にあり、前記上限値以下であれば容易に多孔質膜とすることができる。
ポリマー(C)の濃度が、前記下限値以上であれば容易に多孔質膜とすることができる傾向にあり、前記上限値以下であれば多孔質膜の機械強度が高まる傾向にある。
本発明の多孔質膜の製造方法の一例を以下に説明する。
得られた製膜原液を凝固液に浸漬して凝固させて多孔質膜前駆体を得る(凝固工程)。
得られた多孔質膜前駆体中に残存する溶剤(S)やポリマー(C)の一部又は全部を洗浄して取り除く(洗浄工程)。
洗浄した多孔質膜前駆体を乾燥して、多孔質膜を得る(乾燥工程)。
製膜原液は、膜形成ポリマー(A)、ポリマー(B)、及びポリマー(C)を、溶剤(S)と混合することにより得られる。製膜原液は、膜形成ポリマー(A)、ポリマー(B)、ポリマー(C)、及び添加剤が含まれる場合には添加剤の一部が溶剤(S)中に溶解していることが好ましいが、均一に分散していれば必ずしも溶解していなくてもよい。
膜形成ポリマー(A)の濃度が、前記下限値以上であれば、容易に多孔質膜とすることができる傾向にあり、前記上限値以下であれば、溶剤(S)へ容易に溶解することができる傾向にある。
ポリマー(B)の濃度が、前記下限値以上であれば、容易に多孔質膜とすることができる傾向にあり、前記上限値以下であれば、膜形成ポリマー(A)の溶剤(S)への溶解性が高まる傾向にある。
ポリマー(C)の濃度が、前記下限値以上であれば、容易に多孔質膜とすることができる傾向にあり、前記上限値以下であれば、膜形成ポリマー(A)及びポリマー(B)の溶剤(S)への溶解性が高まる傾向にある。
溶剤(S)の濃度が、前記下限値以上であれば高い透過流束を得られる傾向にあり、前記上限値以下であれば容易に多孔質膜とすることができる。
凝固液としては、膜の孔径制御の点から、溶剤(S)を50質量%以下含む水溶液が好ましい。
凝固液に含まれる溶剤(S)と、製膜原液に含まれる溶剤(S)とは、同じ種類であってもよいし、異なる種類であってもよいが、同じ種類であることが好ましい。
凝固液の温度が、前記下限値以上であれば多孔質膜の透水性能が向上する傾向にあり、前記上限値以下であれば多孔質膜の機械強度を良好に維持できる傾向にある。
多孔質膜前駆体は、40~100℃の、水及び次亜塩素酸ナトリウム水溶液等の水溶液のいずれか一方又は両方に浸漬することにより、多孔質膜前駆体中に残存する溶剤(S)やポリマー(C)の一部又は全部を洗浄して除去することが好ましい。
ポリマー(C)を除去するため、水及び/又は次亜塩素酸ナトリウム水溶液等の水溶液へ浸漬する工程は、複数回繰り返すことができる。
洗浄された多孔質膜前駆体の乾燥は、60~120℃で、1分間~24時間にて行われることが好ましい。
乾燥温度が前記下限値以上であれば、乾燥処理時間が短縮され、生産コストを抑えることができるため、工業生産上好ましく、前記上限値以下であれば、乾燥工程で多孔質膜前駆体が収縮しすぎることを抑制でき、多孔質膜の外表面に微小な亀裂が発生しにくくなる傾向にある。
工程(b):複数の製膜原液を用いて、複数の製膜原液のそれぞれに対応した複数の多孔質前駆体層を有する多孔質膜前駆体を製膜する工程。
工程(c):多孔質膜前駆体からポリマー(C)の一部又は全部を除去して、膜形成ポリマー(A)を含む複数の多孔質層を有する多孔質膜を得る工程。
工程(a)においては、例えば、膜形成ポリマー(A)及びポリマー(C)、必要に応じてポリマー(B)を溶剤(S)に溶解させて、複数の製膜原液を調製する。
工程(a)は、前述の調製工程に準じて行うことができる。
製膜原液(x)に含まれる全ポリマーのうちのポリマー(B)の質量xBは、最表層(α)以外の他の多孔質層(β)に対応する製膜原液(y)に含まれる全ポリマーのうちのポリマー(B)の質量yBよりも大きい。質量xBは、質量yBの1.2倍以上が好ましく、2倍以上がより好ましい。最も好ましいのは、質量yBが0である。
ポリマー(B)の濃度が、前記下限値以上であれば、容易に多孔質膜とすることができる傾向にあり、前記上限値以下であれば、膜形成ポリマー(A)の溶剤(S)への溶解性が高まる傾向にある。
製膜原液(y)(100質量%)中のポリマー(B)の濃度は、0~10質量%が好ましく、0~8質量%がより好ましく、0~6質量%がさらに好ましい。
工程(b)においては、例えば、複数の製膜原液を層状に配置した状態で凝固液に浸漬し、凝固させて、複数の製膜原液のそれぞれに対応した複数の多孔質前駆体層を有する多孔質膜前駆体を製膜する。
工程(b)は、前述の凝固工程に準じて行うことができる。
工程(c)は、前述の洗浄工程及び乾燥工程に準じて行うことができる。
また、一度乾燥されても低圧力で通水することができる。
また、製膜原液へポリマーを添加するのみで製膜の過程で親水化されるため、溶剤洗浄や架橋処理を必要とせず簡便な方法で製造可能である。
また、最表層(α)に含まれる全ポリマーのうちのポリマー(B)の質量αBが、最表層(α)以外の他の多孔質層(β)に含まれる全ポリマーのうちのポリマー(B)の質量βBよりも大きいため、親水性、透水性及び耐ファウリング性を発揮させるのに必要十分なポリマー(B)を最表層(α)に含ませれば、他の多孔質層(β)に含まれるポリマー(B)の量を減らす又は0にすることができる。そのため、多孔質膜全体に均一にポリマー(B)を含ませる場合に比べ、高価なポリマー(B)の使用量を減らすことができ、多孔質膜を低コストで製造できる。
また、少なくとも多孔質膜の被処理水側の最表層にポリマー(B)を含ませるだけでよいため、溶剤洗浄、架橋処理等の特殊な処理を必要とせず、簡便に製造できる。
本発明の膜モジュールは、本発明の多孔質膜を備える。
膜モジュールとしては、2枚の平膜とこれら平膜の四辺を支持する枠状支持体とを有する平膜モジュール、複数の中空糸膜とこれら中空糸膜の端部を支持するハウジングとを有する中空糸膜モジュール等が挙げられる。
本発明の水処理装置は、本発明の膜モジュールを備える。
水処理装置としては、水槽と水槽内に配置された膜モジュールと膜モジュールの下方に配置された散気管とを備えた膜分離活性汚泥装置、液流通路と液流通路内に配置された膜モジュールとを備えた給気脱気装置等が挙げられる。
実施例において「部」及び「%」は、それぞれ「質量部」及び「質量%」を示す。
の組成]
(1)中空糸膜を切り開いた後、ピンセットで支持体を中空糸膜から引出して取り除き、残った多孔質膜を試料とした。
(2)(1)の試料を重水素化溶媒(テトラメチルシランが添加されたN,N-ジメチルスルホキシド-d6)に溶解し、1質量%の溶液を調製した。
(3)日本電子(株)製「JNM-EX270」を用い、温度80℃にて(2)の溶液の1H-NMRスペクトルを測定した。
(4-1)以下のポリマー又はマクロモノマーの1H-NMRスペクトルを測定した(測定条件は(2)及び(3)と同じ。)。
ポリフッ化ビニリデン:
アルケマ(株)製、Kynar(登録商標)761A
ポリアクリル酸2-メトキシエチル:
メタクリル酸2-ヒドロキシエチル及びマクロモノマーを使用しないこと以外、合成例4と同じ条件で重合したポリマー
ポリメタクリル酸メチルマクロモノマー:
後述のマクロモノマー(b3-1)の合成と同じ条件で合成したマクロモノマー
ポリメタクリル酸2-ヒドロキシエチル:
アクリル酸2-メトキシエチル及びマクロモノマーを使用しないこと以外は合成例4と同じ条件で重合したポリマー
ポリビニルピロリドン:
(株)日本触媒製、PVP K80
(4-2)(4-1)で測定した1H-NMRスペクトル、及び、独立行政法人産業技術総合研究所の提供する有機化合物のスペクトルデータベース(SDBS)に掲載された、ポリフッ化ビニリデン、アクリル酸2-メトキシエチル、メタクリル酸2-ヒドロキシエチル及びポリビニルピロリドンの1H-NMRスペクトルを参考にし、(3)で測定した1H-NMRスペクトルについて、以下のピークの帰属を行った。
フッ化ビニリデン単位:2.2~2.4ppm、2.7~3.1ppm
アクリル酸2-メトキシエチル単位:4.0~4.2ppm、3.4~3.6ppm、3.2~3.3ppm
メタクリル酸2-ヒドロキシエチル単位:4.7ppm~4.9、3.8~4.1ppm、3.5~3.7ppm
ポリメタクリル酸メチルマクロモノマー単位:3.5~3.7ppm
ポリビニルピロリドン単位:1.7~1.8ppm、1.8~1.9ppm、3.5~3.6ppm
(5)(4)で帰属したピークの面積から、各単位の積分比を算出し、全単位の積分比の合計を100(モル%)として各単位の濃度(モル%)を算出した。但し、マクロモノマー単位については、分子量にかえて数平均分子量を用いて算出した。
(6)各単位の濃度(モル%)を各単位の分子量で除して、各単位の濃度(質量%)を算出した。
(1)中空糸膜を切り開いた後、ピンセットで支持体を中空糸膜から引張って剥がし、多孔質膜から支持体を分けた。
(2)ピンセットで多孔質膜の外層と内層とを引き剥がして分け、各層の試料とした。
(3)以降、上記の「多孔質膜(中空糸膜M-A1~A7、M’-A1~A5、及び、M’-B1)の組成」の測定における(3)~(6)と同様にして、各層における各単位の濃度(質量%)を測定した。
試料をポリマー(B)及びポリマー(B’)とした以外は、上記の「多孔質膜の組成」と同様にして測定した。
(1)合成したマクロモノマー(b3)を重水素化溶媒(テトラメチルシランが添加されたN,N-ジメチルスルホキシド-d6)に溶解し、1質量%の溶液を調製した。
(2)日本電子(株)製「JNM-EX270」を用い、温度40℃にて(1)の溶液の1H-NMRスペクトルを測定した。
(3)独立行政法人産業技術総合研究所の提供する有機化合物のスペクトルデータベース(SDBS)に掲載されたスペクトルデータを参考にし、測定した1H-NMRスペクトルのピーク面積から、末端二重結合の導入率を求めた。
膜形成ポリマー(A)のMwは、GPC(東ソー(株)製、「HLC-8020」(製品名))を使用して以下の条件で求めた。
・カラム:TSK GUARD COLUMN α(7.8mm×40mm)と3本のTSK-GEL α―M(7.8×300mm)とを直列に接続。
・溶離液:臭化リチウム(LiBr)のN,N-ジメチルホルムアミド(DMF)溶液(LiBrの濃度:20mM)。
・測定温度:40℃。
・流速:0.1mL/分。
なお、膜形成ポリマー(A)のMwは、東ソー(株)製のポリスチレンスタンダード(Mp(ピークトップ分子量)=76,969,900、2,110,000、1,260,000、775,000、355,000、186,000、19,500、1,050の8種類)、及びNSスチレンモノマー(株)製のスチレンモノマー(M(分子量)=104)を用いて作成した検量線を使用して求めた。
単位(b3)、ポリマー(B)、ポリマー(B’)のMn及びMw/Mnは、GPC(東ソー(株)製、「HLC-8220」(製品名))を使用して以下の条件で求めた。
・カラム:TSK GUARD COLUMN SUPER H-L(4.6×35mm)と、2本のTSK-GEL SUPER HZM-H(4.6×150mm)とを直列に接続。
・溶離液:塩化リチウム(LiCl)のDMF溶液(LiClの濃度:0.01M)。
・測定温度:40℃。
・流速:0.6mL/分。
なお、ポリマー(B)、ポリマー(B’)のMn及びMw/Mnは、東ソー(株)製のポリスチレンスタンダード(Mp(ピークトップ分子量)=6,200,000、2,800,000、1,110,000、707,000、354,000、189,000、98,900、37,200、9,830、5,870、870、及び500の12種)を用いて作成した検量線を使用して求めた。
また、単位(b3)のMn及びMw/Mnは、Polymer Laboratories社製のポリメタクリル酸メチル(Mp=141,500、55,600、10,290及び1,590の4種)を用いて作成した検量線を使用して求めた。
中空糸膜の外径(膜外径)は、以下の方法で測定した。
測定するサンプルを約10cmに切断し、数本を束ねて、全体をポリウレタン樹脂で覆った。ポリウレタン樹脂は支持体の中空部にも入るようにした。ポリウレタン樹脂を硬化した後、カミソリ刃を用いて厚さ(膜の長手方向)約0.5mmの薄片をサンプリングした。サンプリングした中空糸膜の断面を、投影機((株)ニコン製、PROFILE PROJECTOR V-12)を用い、対物レンズ100倍にて観察した。中空糸膜の断面のX方向、Y方向の外表面の位置にマーク(ライン)を合わせて外径を読み取った。これを3回測定して外径の平均値を求めた。
多孔質層の膜厚は、以下の方法で測定した。
外径を測定したサンプルと同様の方法でサンプリングした。サンプリングした中空糸膜の断面を、投影機((株)ニコン製、PROFILE PROJECTOR V-12)を用い、対物レンズ100倍にて観察した。中空糸膜の断面の3時方向位置の膜厚の外表面と内表面の位置にマーク(ライン)をあわせて膜厚を読み取った。同様に、9時方向、12時方向、6時方向の順で膜厚を読み取った。これを3回測定して内径の平均値を求めた。
また、多孔質層の外層及び内層の膜厚は、上記と同様にして、膜厚を読み取った後、中空糸膜の外表面と中空糸膜の支持体の外表面の間に明瞭な明暗を示す界面が存在する場合は、この界面と中空糸膜の外表面の間の長さを外層の膜厚として測定し、界面から中空糸膜の支持体の外表面までの長さを内層の膜厚とした。これを3回測定して外層及び内層の膜厚の平均値を求めた。
多孔質層における細孔の孔径(平均孔径)は、以下の方法で測定した。
多孔質層の断面を、走査型電子顕微鏡を用いて倍率5,000倍で撮影し、得られた写真の画像解析処理により細孔の平均孔径を求めた。画像解析処理ソフトとしては、Media Cybernetics社のIMAGE-PRO PLUS version5.0を使用した。
中空糸膜を長さ4cmに切断し、片端面の開口をポリウレタン樹脂で封止した。中空糸膜を容器中のエタノールに浸漬させた後、容器内を5分間以上減圧することにより、中空糸膜の内部を脱気し、エタノールに置換した。中空糸膜を純水中に5分以上浸漬し、エタノールを純水に置換し、中空糸膜を取り出した。容器に純水(25℃)を入れ、容器と中空糸膜の他端面とをチューブで繋ぎ、容器に100kPaの空気圧をかけて中空糸膜から出る純水の量を1分間測定した。これを3回測定して、平均値を求め、この数値をサンプルの表面積で割り、湿潤状態の純水透過流速Ww100とした。
中空糸膜を長さ4cmに切断し、片端面の開口をポリウレタン樹脂で封止した。容器に純水(25℃)を入れ、容器と中空糸膜の他端面とをチューブで繋ぎ、容器に100kPaの空気圧をかけて1分間保持し、中空糸膜の内部を脱気し、純水に置換した。中空糸膜を80℃の熱風乾燥器に24時間投入し、中空糸膜を乾燥させた。容器に純水(25℃)を入れ、容器と乾燥した中空糸膜の他端面とを即座にチューブで繋いだ。20kPaの空気圧をかけて中空糸膜から出る純水の量を1分間測定し、さらに、空気圧を100kPaに昇圧して中空糸膜から出る純水の量を1分間測定した。あるいは、Wd100のみを測定する場合には、空気圧を100kPaに昇圧して中空糸膜から出る純水の量を1分間測定した。これらを3回測定して、平均値を求め、この数値をサンプルの表面積で割り、乾燥状態の純水透過流速Wd20及びWd100とした。
親水性の指標として、以下の指標で親水性(HP)を算出した。
HP=Wd20/Ww100
中空糸膜を長さ4cmに切断し、片端面の開口をポリウレタン樹脂で封止した。中空糸膜をエタノール中で5分間以上減圧した後、純水中に5分間以上浸漬して、エタノールを純水に置換した。中空糸膜を純水(25℃)に浸漬し、中空糸膜の他端面にチューブを繋ぎ、チューブから中空糸膜の中空部にゆっくりと空気圧をかけていった。徐々に昇圧し、中空糸膜の表面に気泡が確認された圧力を測定した。これを10回測定して、平均値を求めた。
撹拌装置を備えた反応装置中に、窒素雰囲気下で、酢酸コバルト(II)四水和物(和光純薬(株)製、和光特級)の1.00g;ジフェニルグリオキシム(東京化成(株)製、EPグレード)の1.93g;30分以上窒素で置換し、脱酸素を行ったジエチルエーテル(関東化学(株)製、特級)の80mL;を入れ、室温で30分間攪拌し、混合物を得た。
得られた混合物に三フッ化ホウ素ジエチルエーテル錯体(東京化成(株)製、EPグレード)の10mLを加えて6時間攪拌し、反応物を得た。
得られた反応物をろ過し、固体をジエチルエーテル(関東化学(株)製、特級)で洗浄し、15時間真空乾燥して、コバルト連鎖移動剤CoBF-1を2.12gの赤褐色固体として得た。
撹拌機、冷却管及び温度計を備えた反応装置中に、17質量%水酸化カリウム水溶液の61.6質量部、メタクリル酸メチル(三菱ケミカル(株)製、アクリエステル(登録商標)M)の19.1質量部、脱イオン水の19.3質量部を加えた。反応装置内の混合物を室温にて撹拌し、発熱ピークを確認した後、4時間撹拌し、反応液を得た。
得られた反応液を室温まで冷却してメタクリル酸カリウム水溶液を得た。
冷却管付フラスコに、メタクリル酸メチル(三菱ケミカル(株)製、アクリエステル(登録商標)M)の100質量部、脱イオン水の150質量部、硫酸ナトリウムの1.39質量部、分散剤1の1.53質量部、コバルト連鎖移動剤CoBF-1の0.00045質量部を加えた。フラスコ内の混合物を70℃に加温した状態でコバルト連鎖移動剤CoBF-1を溶解させ、窒素バブリングにより内部を窒素置換した。重合開始剤として1,1,3,3-テトラメチルブチルペルオキシ-2-エチルヘキサネート(日油(株)製、商品名:パーオクタ(登録商標)O)の0.12質量部を加えた後、内温を70℃に保った状態で6時間保持し、重合を完結させ、重合反応物を得た。得られた重合反応物を室温まで冷却し、ろ過して重合体を回収した。得られた重合体を水洗した後、50℃で一晩真空乾燥することによりマクロモノマー(b3-1)を得た。
冷却管付フラスコに、メタクリル酸メチル(三菱ケミカル(株)製、アクリエステル(登録商標)M)の100質量部、脱イオン水の150質量部、硫酸ナトリウムの1.39質量部、分散剤1の1.53質量部、コバルト連鎖移動剤CoBF-1の0.003質量部を加えた。フラスコ内の混合物を70℃に加温した状態でコバルト連鎖移動剤CoBF-1を溶解させ、窒素バブリングにより内部を窒素置換した。重合開始剤として1,1,3,3-テトラメチルブチルペルオキシ-2-エチルヘキサネート(日油(株)製、パーオクタ(登録商標)O)の0.12質量部を加えた後、内温を70℃に保った状態で6時間保持し、重合を完結させ、重合反応物を得た。得られた重合反応物を室温まで冷却し、ろ過して重合体を回収した。得られた重合体を水洗した後、50℃で一晩真空乾燥することによりマクロモノマー(b3-2)を得た。
[合成例1]
(ポリマー(B-1)の合成)
冷却管付フラスコに、アクリル酸2-メトキシエチル(単位(b1))の59質量部(和光純薬工業(株)製、和光一級)、メタクリル酸2-ヒドロキシエチル(単位(b2))の1質量部(三菱ケミカル(株)製、アクリエステル(登録商標)HO)、マクロモノマー(b3-1)(単位(b3))の40質量部、N,N-ジメチルアセトアミド(溶剤(S))(和光純薬工業(株)製、試薬特級)の150質量部からなるモノマー組成物を加えて、窒素バブリングによりフラスコの内部を窒素置換した。モノマー組成物を加温して内温を55℃に保った状態で、ラジカル重合開始剤として2,2’-アゾビス(2,4’-ジメチルバレロニトリル)の0.1質量部(和光純薬工業(株)製、商品名:V-65)を加え、5時間保持した。70℃に昇温し、V-65の0.15質量部を追添加した後、60分間保持し、重合を完結させた。その後、室温まで冷却し、ポリマー(B-1)を含有する重合液(D-1)を得た。
(ポリマー(B-2)~(B-5)、ポリマー(B’-2)~(B’-4)の合成)
モノマー組成物の組成、重合開始剤、及び溶剤(S)について、表1に示すように変更した以外は、ポリマー(B-1)と同様の方法でポリマー(B-2)を含有する重合液(D-2)、ポリマー(B-3)を含有する重合液(D-3)、ポリマー(B-4)を含有する重合液(D-4)、ポリマー(B-5)を含有する重合液(D-5)、ポリマー(B’-2)を含有する重合液(D-7)、ポリマー(B’-3)を含有する重合液(D-8)、ポリマー(B’-4)を含有する重合液(D-9)をそれぞれ得た。
(ポリマー(B’-1)の合成)
冷却管付フラスコに、メタクリル酸2-ヒドロキシエチル(単位(b2))の40質量部(三菱ケミカル(株)製、アクリエステル(登録商標)HO)、メタクリル酸メチル(単位(b4))の40質量部、メタクリル酸2-ジメチルアミノエチル(単位(b4))の20質量部(三菱ケミカル(株)製、アクリエステル(登録商標)DM)N,N-ジメチルアセトアミド(溶剤(S))(和光純薬工業(株)製、試薬特級)の150質量部からなるモノマー組成物を加えて、窒素バブリングによりフラスコの内部を窒素置換した。モノマー組成物を加温して内温を70℃に保った状態で、ラジカル重合開始剤として2,2’-アゾビス(2,4’-ジメチルバレロニトリル)の0.1質量部(和光純薬工業(株)製、商品名:V-65)を加え、5時間保持した。80℃に昇温し、0.2質量部の2,2’-アゾビスイソブチロニトリルを追添加した後、60分間保持し重合を完結させた。その後、室温まで冷却し、ポリマー(B’-1)を含有する重合液(D-6)を得た。
MEA:アクリル酸2-メトキシエチル(和光純薬工業(株)製、和光一級)。
HEMA:メタクリル酸2-ヒドロキシエチル(三菱ケミカル(株)製、アクリエステル(登録商標)HO)。
MMA:メタクリル酸メチル(三菱ケミカル(株)製、アクリエステル(登録商標)M)。
DMAEMA:メタクリル酸ジメチルアミノエチル(三菱ケミカル(株)製、アクリエステル(登録商標)DM)。
V-65:2,2’-アゾビス(2,4’-ジメチルバレロニトリル)(和光純薬工業(株)製、商品名:V-65)。
DMAc:N,N-ジメチルアセトアミド(和光純薬工業(株)製、試薬特級)。
PMMA-MM:ポリメタクリル酸メチルマクロモノマー。
[調製例A1]
(製膜原液(A1)の調製)
膜形成ポリマー(A)としてポリフッ化ビニリデン(PVDF)(アルケマ社製、Kynar(登録商標)761A、Mw=550,000)の1.2質量部、ポリマー(B)としてポリマー(B-1)を含む重合液(D-1)の0.15質量部、ポリマー(C)としてポリビニルピロリドン(PVP)((株)日本触媒製、PVP K80、Mw=900,000)の0.72質量部、溶剤(S)としてN,N-ジメチルアセトアミド(和光純薬工業(株)製、和光特級)の5.01質量部をステンレス容器に入れ、60℃で5時間攪拌して製膜原液(A1)を調製した。得られた製膜原液を25℃にて一日静置した。
(製膜原液(A2)~(A7)、製膜原液(B1)の調製)
膜形成ポリマー(A)、ポリマー(B)、及びポリマー(C)の組成、並びに溶剤(S)について表2に示すように変更した以外は、製膜原液(A1)と同様の方法で製膜原液(A2)~(A7)、及び製膜原液(B1)をそれぞれ得た。
(製膜原液(B2)の調製)
重合液(D-2)を配合せず、N,N-ジメチルアセトアミドの量を5.10部に変更した以外は、製膜原液(B1)と同様の方法で製膜原液(B2)を得た。
(製膜原液(B3)の調製)
重合液(D-2)の量を0.15部に変更し、N,N-ジメチルアセトアミドの量を5.01部に変更した以外は、製膜原液(B1)と同様の方法で製膜原液(B3)を得た。
(製膜原液(A’1)の調製)
調製例A1で使用した重合液を使用しなかった以外は、製膜原液(A1)と同様の方法で製膜原液(A’1)を得た。
(製膜原液(A’2)~(A’5)の調製)
膜形成ポリマー(A)、ポリマー(B)、及びポリマー(C)の組成、並びに溶剤(S)について表2に示すように変更した以外は、製膜原液(A1)と同様の方法で製膜原液(A’2)~(A’5)を得た。
Kynar 761A:ポリフッ化ビニリデン(PVDF)(アルケマ社製、Kynar(登録商標)761A、Mw=550,000)。
K80:ポリビニルピロリドン(PVP)(日本触媒製、PVP K80、Mw=900,000)。
[実施例A1]
(中空糸膜(M-A1)の製造)
支持体製造装置を用いて、ポリエステル繊維(ポリエチレンテレフタレート製、繊度417dtex)のマルチフィラメントを円筒状に丸編みし、210℃にて熱処理を施して支持体を得た。得られた支持体の外径は1.45mmであった。
製造装置1の原液供給装置2より調製した製膜原液(A1)を送液し、塗布部3において支持体4に塗布した。製膜原液が塗布された支持体4を77℃の凝固浴槽5中の凝固液(N,N-ジメチルアセトアミドの40質量%水溶液)に浸漬し、製膜原液を凝固されることによって、多孔質層を有する中空糸膜前駆体6を得た。
中空糸膜前駆体を60℃の熱水に浸漬する工程と次亜塩素酸ナトリウム水溶液に浸漬する工程とを繰り返し、最後に115℃に熱した乾燥炉にて3分間乾燥させて、中空糸膜(M-A1)を得た。
(中空糸膜(M-A2)~(M-A7)の製造)
製膜原液(A1)に代えて、それぞれ製膜原液(A2)~(A7)を使用した以外は、中空糸膜(M-A1)と同様の方法で、中空糸膜(M-A2)~(M-A7)を製造した。
(中空糸膜(M’-A1)~(M’-A5)の製造
製膜原液(A1)に代えて、それぞれ製膜原液(A’1)~(A’5)を使用した以外は、中空糸膜(M-A1)と同様の方法で、中空糸膜(M’-A1)~(M’-A5)を製造した。
また、バブルポイント圧力が100kPa以上であり、高い濾過性能及び機械物性を有することが明らかとなった。
比較例A2においては、ポリマー(B)が単位(b1)を含んでいないため、得られた中空糸膜の親水性HPの値が0.4と低く、高い親水性を有さなかった。
比較例A3においては、多孔質膜に含まれる単位(b1)の濃度(質量%)が、多孔質膜に含まれる単位(b2)の濃度(質量%)未満であるため、膜の構造が不均一となり、その結果、バブルポイント圧力が50kPaと低かった。
比較例A4においては、多孔質膜中に単位(b2)が含まれていないため
多孔質膜の親水性が低かった。
比較例A5においては、多孔質膜に含まれる単位(b1)の濃度(質量%)が、多孔質膜に含まれる単位(b2)の濃度(質量%)未満であるため、膜の構造が不均一となり、その結果、バブルポイント圧力が60kPaと低かった。
(中空糸膜(M-B1)の製造)
支持体製造装置を用いて、ポリエステル繊維(ポリエチレンテレフタレート製、繊度417dtex)のマルチフィラメントを円筒状に丸編みし、210℃にて熱処理を施して支持体を得た。得られた支持体の外径は1.45mmであった。
製造装置1の原液供給装置2から製膜原液(B1)及び製膜原液(B2)を二重管ノズルに送液し、塗布部3において二重管ノズルの内側から製膜原液(B2)、二重管ノズルの外側から製膜原液(B1)を支持体4に同時に塗布した。製膜原液が塗布された支持体4を77℃の凝固浴槽5中の凝固液(N,N-ジメチルアセトアミドの40質量%水溶液)に浸漬し、製膜原液を凝固させることによって、2層の多孔質前駆体層を有する中空糸膜前駆体6を得た。
中空糸膜前駆体を60℃の熱水に浸漬する工程と次亜塩素酸ナトリウム水溶液に浸漬する工程とを繰り返し、最後に115℃に熱した乾燥炉にて3分間乾燥させて、2層の多孔質層(内層及び外層)を有する中空糸膜(M-B1)を得た。
(中空糸膜(M-B2)~(M-B3)の製造)
内層及び外層の膜厚を表4に示すように変更した以外は、中空糸膜(M-B1)と同様の方法で中空糸膜(M-B2)~(M-B3)を得た。
(中空糸膜(M-B4)の製造)
製膜原液(B2)を製膜原液(B3)に変更し、内層及び外層の膜厚を表4に示すように変更した以外は、中空糸膜(M-B1)と同様の方法で中空糸膜(M-B4)を得た。
(中空糸膜(M’-B1)の製造)
製膜原液(B2)のみを用い、支持体4に製膜原液(B2)のみを塗布し、膜厚を変更した以外は、実施例B1と同様にして単層の中空糸膜を得た。
(中空糸膜(M’-B2)の製造)
製膜原液(B1)を製膜原液(B2)に変更し、内層及び外層の膜厚を変更した以外は、実施例B1と同様にして中空糸膜を得た。
(中空糸膜(M’-B3)の製造)
製膜原液(B1)を製膜原液(B2)に変更し、製膜原液(B3)を製膜原液(B1)に変更し、内層及び外層の膜厚を変更した以外は、実施例B4と同様にして中空糸膜を得た。
図2に示す水処理システム100を用いて被処理水の濾過処理を行った。
水処理システム100は、原水ポンプ10、原水流路11、硝化槽12、攪拌機13、循環流路14、生物反応槽20、分離膜モジュール21、散気管22、処理水流路23、濾過ポンプ24、ブロア25、循環流路26、及び循環ポンプ27を有する。
結果を表5に示す。
MLSS:槽内の浮遊物質濃度を、単位:mg/Lで表したものであり、MLSSが高いほど槽内に含まれる汚泥の濃度が高い。
一方、比較例A1の中空糸膜(M’-A1)は、単位(b1)を有するポリマー(B)を使用しなかったため、濾過試験中に膜が汚染されるファウリングが起こり、単位(b1)を有するポリマー(B)を使用した中空糸膜(M-A1)~(M-A3)よりも膜間差圧が上昇し、耐ファウリング性に劣る膜であった。
また、比較例A2の中空糸膜(M’-A2)は、単位(b2)であるメタクリル酸2-ヒドロキシエチルに基づく単位を有するポリマーを使用したが、単位(b1)をも有するポリマー(B)ではなかったため、濾過試験中に膜が汚染されるファウリングが起こり、単位(b1)を有するポリマー(B)を使用した中空糸膜(M-A1)~(M-A3)よりも膜間差圧が急激に上昇し、濾過試験を継続することができないほど、耐ファウリング性に劣る膜であった。
表6に示すとおり、中空糸膜、槽内環境、及び運転条件を変更した以外は、活性汚泥中における加速濾過試験-1と同様に濾過試験を実施した。
結果を表6に示す。
一方、比較例A1の中空糸膜(M’-A1)は、活性汚泥中における加速濾過試験-1と同様に、単位(b1)を有するポリマー(B)を使用しなかったため、条件を変えた濾過試験中においても膜が汚染されるファウリングが起こり、単位(b1)を有するポリマー(B)を使用した中空糸膜(M-A)2、(M-A4)~(M-A6)よりも膜間差圧が上昇し、耐ファウリング性に劣る膜であった。
10 原水ポンプ
100 水処理システム
11 原水流路
12 硝化槽
13 攪拌機
14 循環流路
2 原液供給装置
20 生物反応槽
21 分離膜モジュール
22 散気管
23 処理水流路
24 濾過ポンプ
25 ブロア
26 循環流路
27 循環ポンプ
3 塗布部
4 支持体
5 凝固浴槽
6 中空糸膜前駆体
Claims (12)
- 前記単位(b1)が、アクリル酸2-メトキシエチルに基づく単位である、請求項1又は2に記載の多孔質膜。
- 被処理水をろ過して処理水とする多孔質膜であって、
前記ポリマー(A)を含む複数の多孔質層を有し、
前記複数の多孔質層のうち、少なくとも前記多孔質膜の被処理水側の最表層に含まれる全ポリマー中の前記ポリマー(B)の濃度(質量%)が、前記最表層以外の他の多孔質層に含まれる全ポリマー中の前記ポリマー(B)の濃度(質量%)よりも大きい、請求項1~3のいずれか一項に記載の多孔質膜。 - 膜の形態が中空糸膜である、請求項1~4のいずれか一項に記載の多孔質膜。
- 多孔質膜中に支持体をさらに有する、請求項1~5のいずれか一項に記載の多孔質膜。
- 請求項1~6のいずれか一項に記載の多孔質膜を備える、膜モジュール。
- 請求項7に記載の膜モジュールを備える、水処理装置。
- 前記単位(b1)が、アクリル酸2-メトキシエチルに基づく単位である、請求項9又は10に記載の多孔質膜の製造方法。
- 被処理水をろ過して処理水とする多孔質膜の製造方法であって、
前記ポリマー(A)及びビニルピロリドンに基づく単位を有するポリマー(C)を含む複数の製膜原液を用いて、前記複数の製膜原液のそれぞれに対応した複数の多孔質前駆体層を有する多孔質膜前駆体を製膜し、
前記多孔質膜前駆体からポリマー(C)の一部又は全部を取り除く、前記ポリマー(A)を含む複数の多孔質層を有する多孔質膜の製造方法であり、
前記複数の製膜原液のうち、少なくとも前記多孔質膜の被処理水側の最表層に対応する製膜原液が前記ポリマー(B)をさらに含み、
前記最表層に対応する製膜原液に含まれる全ポリマーのうちの前記ポリマー(B)の濃度(質量%)が、前記最表層以外の他の多孔質層に対応する製膜原液に含まれる全ポリマーのうちの前記ポリマー(B)の濃度(質量%)よりも大きい、多孔質膜の製造方法。
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