JP5465463B2 - Ion adsorption module and water treatment method - Google Patents
Ion adsorption module and water treatment method Download PDFInfo
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- JP5465463B2 JP5465463B2 JP2009115958A JP2009115958A JP5465463B2 JP 5465463 B2 JP5465463 B2 JP 5465463B2 JP 2009115958 A JP2009115958 A JP 2009115958A JP 2009115958 A JP2009115958 A JP 2009115958A JP 5465463 B2 JP5465463 B2 JP 5465463B2
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- JMMWKPVZQRWMSS-UHFFFAOYSA-N isopropanol acetate Natural products CC(C)OC(C)=O JMMWKPVZQRWMSS-UHFFFAOYSA-N 0.000 description 1
- 229940011051 isopropyl acetate Drugs 0.000 description 1
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- 239000012452 mother liquor Substances 0.000 description 1
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- DVEKCXOJTLDBFE-UHFFFAOYSA-N n-dodecyl-n,n-dimethylglycinate Chemical compound CCCCCCCCCCCC[N+](C)(C)CC([O-])=O DVEKCXOJTLDBFE-UHFFFAOYSA-N 0.000 description 1
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- QIQXTHQIDYTFRH-UHFFFAOYSA-N octadecanoic acid Chemical compound CCCCCCCCCCCCCCCCCC(O)=O QIQXTHQIDYTFRH-UHFFFAOYSA-N 0.000 description 1
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- 238000005191 phase separation Methods 0.000 description 1
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- 229920000053 polysorbate 80 Polymers 0.000 description 1
- 229940096992 potassium oleate Drugs 0.000 description 1
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- MLICVSDCCDDWMD-KVVVOXFISA-M potassium;(z)-octadec-9-enoate Chemical compound [K+].CCCCCCCC\C=C/CCCCCCCC([O-])=O MLICVSDCCDDWMD-KVVVOXFISA-M 0.000 description 1
- 238000002360 preparation method Methods 0.000 description 1
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- 239000008117 stearic acid Substances 0.000 description 1
- 239000004575 stone Substances 0.000 description 1
- 125000003011 styrenyl group Chemical group [H]\C(*)=C(/[H])C1=C([H])C([H])=C([H])C([H])=C1[H] 0.000 description 1
- 238000006277 sulfonation reaction Methods 0.000 description 1
- HIFJUMGIHIZEPX-UHFFFAOYSA-N sulfuric acid;sulfur trioxide Chemical compound O=S(=O)=O.OS(O)(=O)=O HIFJUMGIHIZEPX-UHFFFAOYSA-N 0.000 description 1
- 239000000057 synthetic resin Substances 0.000 description 1
- 229920003002 synthetic resin Polymers 0.000 description 1
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Landscapes
- Treatment Of Water By Ion Exchange (AREA)
Description
本発明は、イオン交換帯長さが顕著に短いイオン吸着モジュール及び水処理方法に関するものである。 The present invention relates to an ion adsorption module and a water treatment method having a remarkably short ion exchange zone length.
従来、イオン交換体は、イオン交換樹脂と総称される高分子合成樹脂に代表され、その製品形状別に分類すれば、粒状やフレーク状のイオン交換樹脂、膜状のイオン交換膜、及び繊維状のイオン交換繊維などに分類することができる。また、粒状のイオン交換樹脂の他に連続孔を有する有機多孔質イオン交換体も知られている。 Conventionally, ion exchangers are typified by polymer synthetic resins collectively referred to as ion exchange resins, and if classified according to product shape, granular or flake ion exchange resins, membrane ion exchange membranes, and fibrous ion exchange resins It can be classified into ion exchange fibers. In addition to the granular ion exchange resin, organic porous ion exchangers having continuous pores are also known.
例えば特開2004−82027号公報には、少なくとも被処理水が流入する開口を備える容器と、該容器に充填される互いにつながっているマクロポアとマクロポアの壁内に平均径が1〜1000μmのメソポアを有する連続気泡構造を有し、全細孔容積が1ml/g〜50ml/gであり、イオン交換基が均一に分布され、イオン交換容量が0.5mg当量/g乾燥多孔質体以上である3次元網目構造を有する有機多孔質イオン交換体とを備えるイオン吸着モジュールが開示されている。 For example, in Japanese Patent Application Laid-Open No. 2004-82027, a container having at least an opening through which water to be treated flows, a macropore filled in the container, and a mesopore having an average diameter of 1 to 1000 μm in the wall of the macropore are provided. 3 having an open cell structure, a total pore volume of 1 ml / g to 50 ml / g, an ion exchange group uniformly distributed, and an ion exchange capacity of 0.5 mg equivalent / g dry porous body or more An ion adsorption module comprising an organic porous ion exchanger having a dimensional network structure is disclosed.
特開2004−82027号公報のイオン吸着モジュールによれば、イオン交換体の充填が極めて容易で、且つ上向流であっても充填層が移動しない。また、このイオン吸着モジュールを用いた水処理方法においては、流速が上がっても、イオン交換帯長さを短く維持することができ、イオン交換体装置の減容化が図れ、吸着したイオンの微量リークが起こらないため、再生頻度が下がり、処理効率を向上させることができる。なお、特開2002−306976号にはこの有機多孔質イオン交換体の製造方法の詳細が開示されている。 According to the ion adsorption module of Japanese Patent Application Laid-Open No. 2004-82027, the filling of the ion exchanger is extremely easy, and the packed bed does not move even in the upward flow. Further, in the water treatment method using this ion adsorption module, the ion exchange zone length can be kept short even when the flow rate is increased, the volume of the ion exchanger device can be reduced, and a small amount of adsorbed ions can be achieved. Since no leakage occurs, the reproduction frequency is reduced and the processing efficiency can be improved. Japanese Patent Laid-Open No. 2002-306976 discloses details of a method for producing this organic porous ion exchanger.
しかしながら、特開2004−82027号公報のイオン吸着モジュールで使用する有機多孔質イオン交換体は、モノリスの共通の開口(メソポア)が1〜1,000μmと記載されているものの、全細孔容積5ml/g以下の細孔容積の小さなモノリスについては、油中水滴型エマルジョン中の水滴の量を少なくする必要があるため共通の開口は小さくなり、実質的に開口の平均径20μm以上のものは製造できない。このため、通水差圧が大きくなってしまうという問題があった。また、開口の平均径を20μm近傍のものにすると、全細孔容積もそれに伴い大きくなるため、体積当たりのイオン交換容量が低下する、またイオン交換帯長さが長く、モジュールの交換頻度が高くなるという問題があった。また、このような連続気泡構造(連続マクロポア)に代わる新たな構造のモノリスの登場も望まれていた。 However, the organic porous ion exchanger used in the ion adsorption module of Japanese Patent Application Laid-Open No. 2004-82027 describes a common monolithic opening (mesopore) of 1 to 1,000 μm, but has a total pore volume of 5 ml. For monoliths with a small pore volume of / g or less, it is necessary to reduce the amount of water droplets in the water-in-oil emulsion, so the common opening becomes small, and those having an average diameter of 20 μm or more are substantially manufactured. Can not. For this reason, there existed a problem that water flow differential pressure | voltage will become large. In addition, when the average diameter of the openings is around 20 μm, the total pore volume also increases accordingly, so that the ion exchange capacity per volume decreases, the ion exchange zone length is long, and the module replacement frequency is high. There was a problem of becoming. In addition, the appearance of a monolith having a new structure to replace such an open cell structure (continuous macropore) has been desired.
従って、本発明の目的は、イオン交換体の充填が極めて容易なイオン吸着モジュールを提供することにあり、また、他の目的は、通水差圧を小さくでき、流速が上がっても、イオン交換帯長さを短く維持することができ、且つ体積当りのイオン交換容量が大きく、吸着したイオンの微量リークが起こらないため、交換頻度が少なくなるもしくは再生頻度が下がり、処理効率を向上させることができるイオン吸着モジュール及び水処理方法を提供することにある。 Accordingly, an object of the present invention is to provide an ion adsorption module that is extremely easy to fill with an ion exchanger. Another object of the present invention is to reduce the water differential pressure and to increase the flow rate even if the flow rate increases. The band length can be kept short, the ion exchange capacity per volume is large, and a minute leak of adsorbed ions does not occur, so the exchange frequency is reduced or the regeneration frequency is lowered, and the processing efficiency can be improved. Another object is to provide an ion adsorption module and a water treatment method.
かかる実情において、本発明者らは鋭意検討を行った結果、特開2002−306976号公報記載の方法で得られた比較的大きな細孔容積を有するモノリス状有機多孔質体(中間体)の存在下に、特定の条件下、ビニルモノマーと架橋剤を有機溶媒中で静置重合すれば、有機多孔質体を構成する骨格表面上に直径2〜20μmの多数の粒子体が固着する又は突起体が形成された複合構造を有するモノリスが得られること、この複合モノリスにイオン交換基を導入した複合モノリスイオン交換体は、イオン吸着モジュールの吸着材として用いれば、通水差圧を小さくでき、流速が上がっても、イオン交換帯長さを短く維持することができ、且つ体積当りのイオン交換容量が大きく、吸着したイオンの微量リークが起こらないため、交換頻度が少なくなるもしくは再生頻度が下がり、処理効率を向上させることができることなどを見出し、本発明を完成するに至った。 Under such circumstances, the present inventors have conducted intensive studies, and as a result, the existence of a monolithic organic porous material (intermediate) having a relatively large pore volume obtained by the method described in JP-A-2002-306976. Below, if a vinyl monomer and a crosslinking agent are allowed to stand in an organic solvent under specific conditions, a large number of particles having a diameter of 2 to 20 μm are fixed on the surface of the skeleton constituting the organic porous body, or a protrusion. A monolith having a composite structure in which an ion exchange group is introduced, and a composite monolith ion exchanger in which an ion exchange group is introduced can be used as an adsorbent for an ion adsorption module. Even if the ion exchange zone increases, the ion exchange zone length can be kept short, the ion exchange capacity per volume is large, and a minute leak of adsorbed ions does not occur. Eliminated or regeneration frequency is lowered, it found such that it is possible to improve the processing efficiency, and have completed the present invention.
すなわち、本発明は、少なくとも被処理水が流入する開口を備える容器と、該容器に充填されるモノリス状有機多孔質イオン交換体とを備えるイオン吸着モジュールであって、該モノリス状有機多孔質イオン交換体が、連続骨格相と連続空孔相からなる有機多孔質体と、該有機多孔質体の骨格表面に固着する直径4〜40μmの多数の粒子体又は該有機多孔質体の骨格表面上に形成される大きさが4〜40μmの多数の突起体との複合構造体であって、水湿潤状態で孔の平均直径10〜150μm、全細孔容積0.5〜5ml/gであり、水湿潤状態での体積当りのイオン交換容量0.2mg当量/ml以上であることを特徴とするイオン吸着モジュールを提供するものである。 That is, the present invention is an ion adsorption module comprising at least a container having an opening through which water to be treated flows and a monolithic organic porous ion exchanger filled in the container, wherein the monolithic organic porous ion The exchanger is an organic porous body composed of a continuous skeleton phase and a continuous pore phase, a large number of particles having a diameter of 4 to 40 μm fixed to the skeleton surface of the organic porous body, or the skeleton surface of the organic porous body A composite structure with a large number of protrusions having a size of 4 to 40 μm, and having an average pore diameter of 10 to 150 μm and a total pore volume of 0.5 to 5 ml / g in a wet state, The present invention provides an ion adsorption module characterized by having an ion exchange capacity per volume of 0.2 mg equivalent / ml or more in a water-wet state.
また、本発明は、少なくとも被処理水が流入する開口を備える容器と、該容器に充填される粒状のイオン交換樹脂充填層と、連続骨格相と連続空孔相からなる有機多孔質体と、該有機多孔質体の骨格表面に固着する直径4〜40μmの多数の粒子体又は該有機多孔質体の骨格表面上に形成される大きさが4〜40μmの多数の突起体との複合構造体であって、水湿潤状態で孔の平均直径10〜150μm、全細孔容積0.5〜5ml/gであり、水湿潤状態での体積当りのイオン交換容量0.2mg当量/ml以上であるモノリス状有機多孔質イオン交換体充填層とを備え、該被処理水が流入する開口側からこの順序で積層してなることを特徴とするイオン吸着モジュールを提供するものである。 The present invention also includes a container having at least an opening through which water to be treated flows, a granular ion exchange resin packed layer filled in the container, an organic porous body composed of a continuous skeleton phase and a continuous pore phase, Composite structure with a large number of particles having a diameter of 4 to 40 μm fixed to the skeleton surface of the organic porous body or a large number of protrusions having a size of 4 to 40 μm formed on the skeleton surface of the organic porous body In the water wet state, the average pore diameter is 10 to 150 μm, the total pore volume is 0.5 to 5 ml / g, and the ion exchange capacity per volume in the water wet state is 0.2 mg equivalent / ml or more. and a monolithic organic porous ion exchanger filled layer, in which該被treated water to provide an ion adsorption module, characterized by comprising a laminate from an opening side flowing in this order.
また、本発明は、連続骨格相と連続空孔相からなる有機多孔質体と、該有機多孔質体の骨格表面に固着する直径4〜40μmの多数の粒子体又は該有機多孔質体の骨格表面上に形成される大きさが4〜40μmの多数の突起体との複合構造体であって、水湿潤状態で孔の平均直径10〜150μm、全細孔容積0.5〜5ml/gであり、水湿潤状態での体積当りのイオン交換容量0.2mg当量/ml以上であるモノリス状有機多孔質イオン交換体と被処理水を接触させることにより、該被処理水中のイオン性不純物を吸着除去することを特徴とする水処理方法を提供するものである。 The present invention also relates to an organic porous body composed of a continuous skeleton phase and a continuous pore phase, a large number of particles having a diameter of 4 to 40 μm fixed to the skeleton surface of the organic porous body, or a skeleton of the organic porous body. A composite structure with a large number of protrusions having a size of 4 to 40 μm formed on the surface, with an average pore diameter of 10 to 150 μm and a total pore volume of 0.5 to 5 ml / g in a wet state. Yes, by adsorbing ionic impurities in the water to be treated by bringing the water to be treated into contact with the monolithic organic porous ion exchanger having an ion exchange capacity of 0.2 mg equivalent / ml or more per volume in a wet state of water. The present invention provides a water treatment method characterized by removing the water.
本発明によれば、モノリス状多孔質イオン交換体は例えば充填容器に嵌るブロック形状として容易に作製することができ、充填も容易である。また、従来のモジュールで一般的に採用されている連続通水処理方法及び貯留容器や貯留槽中の水中に投入して行なうバッチ処理方法のいずれにも適用することができる。また、連続通水処理方法においてイオン性不純物の含有量が微量である場合には、コンパクトな装置で通水差圧を小さくでき、流速が上がっても、イオン交換帯長さを短く維持することができ、且つ体積当りのイオン交換容量が大きく、吸着したイオンの微量リークが起こらないため、交換頻度が少なくなるもしくは再生頻度が下がり、処理効率を向上させることができる。 According to the present invention, the monolithic porous ion exchanger can be easily produced, for example, as a block shape that fits into a filling container, and filling is also easy. Moreover, it can apply to both the continuous water flow processing method generally employ | adopted with the conventional module, and the batch processing method performed by throwing in the water in a storage container or a storage tank. In addition, when the content of ionic impurities is very small in the continuous water treatment method, the water differential pressure can be reduced with a compact device, and the ion exchange zone length should be kept short even when the flow rate is increased. In addition, since the ion exchange capacity per volume is large and a minute leak of adsorbed ions does not occur, the exchange frequency is reduced or the regeneration frequency is lowered, and the processing efficiency can be improved.
本発明の実施の形態におけるイオン吸着モジュールにおいて、容器に充填されるのは、複合構造を有するモノリス状有機多孔質イオン交換体である。本明細書中、「モノリス状有機多孔質体」を単に「複合モノリス」と、「モノリス状有機多孔質イオン交換体」を単に「複合モノリスイオン交換体」と、「モノリス状の有機多孔質中間体」を単に「モノリス中間体」とも言う。 In the ion adsorption module according to the embodiment of the present invention, the container is filled with a monolithic organic porous ion exchanger having a composite structure. In this specification, “monolithic organic porous body” is simply “composite monolith”, “monolithic organic porous ion exchanger” is simply “composite monolithic ion exchanger”, and “monolithic organic porous intermediate”. "Body" is also simply called "monolith intermediate".
<複合モノリスイオン交換体の説明>
複合モノリスイオン交換体は、複合モノリスにイオン交換基を導入することで得られるものであり、連続骨格相と連続空孔相からなる有機多孔質体と、該有機多孔質体の骨格表面に固着する直径4〜40μmの多数の粒子体との複合構造体であるか、又は連続骨格相と連続空孔相からなる有機多孔質体と、該有機多孔質体の骨格表面上に形成される大きさが4〜40μmの多数の突起体との複合構造体であって、水湿潤状態で孔の平均直径10〜150μm、全細孔容積0.5〜5ml/gであり、水湿潤状態での体積当りのイオン交換容量0.2mg当量/ml以上であり、イオン交換基が該複合構造体中に均一に分布している。なお、本明細書中、「粒子体」及び「突起体」を併せて「粒子体等」と言うことがある。
<Description of composite monolith ion exchanger>
A composite monolith ion exchanger is obtained by introducing an ion exchange group into a composite monolith, and is fixed to an organic porous body composed of a continuous skeleton phase and a continuous pore phase, and the skeleton surface of the organic porous body. An organic porous body consisting of a continuous skeleton phase and a continuous pore phase, and a size formed on the skeleton surface of the organic porous body. A composite structure with a large number of protrusions having a thickness of 4 to 40 μm, and having an average pore diameter of 10 to 150 μm and a total pore volume of 0.5 to 5 ml / g in a water wet state, The ion exchange capacity per volume is 0.2 mg equivalent / ml or more, and the ion exchange groups are uniformly distributed in the composite structure. In the present specification, “particle bodies” and “projections” may be collectively referred to as “particle bodies”.
有機多孔質体の連続骨格相と連続空孔相(乾燥体)は、SEM画像により観察することができる。有機多孔質体の基本構造としては、連続マクロポア構造及び共連続構造が挙げられる。有機多孔質体の骨格相は、柱状の連続体、凹状の壁面の連続体あるいはこれらの複合体として表れるもので、粒子状や突起状とは明らかに相違する形状のものである。 The continuous skeleton phase and the continuous pore phase (dried body) of the organic porous body can be observed by an SEM image. Examples of the basic structure of the organic porous material include a continuous macropore structure and a co-continuous structure. The skeletal phase of the organic porous material appears as a columnar continuum, a concave wall continuum, or a composite thereof, and has a shape that is clearly different from a particle shape or a protrusion shape.
有機多孔質体の好ましい構造としては、気泡状のマクロポア同士が重なり合い、この重なる部分が水湿潤状態で平均直径30〜150μmの開口となる連続マクロポア構造体(以下、「第1の有機多孔質イオン交換体」とも言う。)及び水湿潤状態で平均の太さが1〜60μmの三次元的に連続した骨格と、その骨格間に平均直径が水湿潤状態で10〜100μmの三次元的に連続した空孔とからなる共連続構造体(以下、「第2の有機多孔質イオン交換体」とも言う。)が挙げられる。 As a preferable structure of the organic porous body, a continuous macropore structure (hereinafter referred to as “first organic porous ion”) in which bubble-shaped macropores overlap each other, and the overlapping portion becomes an opening having an average diameter of 30 to 150 μm in a wet state. And a three-dimensional continuous skeleton having an average thickness of 1 to 60 μm in a water-wet state, and three-dimensional continuous having an average diameter of 10 to 100 μm in a water-wet state between the skeletons. A co-continuous structure (hereinafter, also referred to as “second organic porous ion exchanger”).
第1の有機多孔質イオン交換体の場合、有機多孔質体は、気泡状のマクロポア同士が重なり合い、この重なる部分が水湿潤状態で平均直径30〜150μmの開口(メソポア)となる連続マクロポア構造体である。複合モノリスイオン交換体の開口の平均直径は、モノリスにイオン交換基を導入する際、複合モノリス全体が膨潤するため、乾燥状態の複合モノリスの開口の平均直径よりも大となる。開口の平均直径が30μm未満であると、通水時の圧力損失が大きくなってしまうため好ましくなく、開口の平均直径が大き過ぎると、流体とモノリスイオン交換体との接触が不十分となり、その結果、イオン交換特性が低下してしまうため好ましくない。 In the case of the first organic porous ion exchanger, the organic porous body is a continuous macropore structure in which bubble-shaped macropores are overlapped with each other, and the overlapping portions form openings (mesopores) having an average diameter of 30 to 150 μm in a wet state. It is. The average diameter of the opening of the composite monolith ion exchanger is larger than the average diameter of the opening of the composite monolith in a dry state because the entire composite monolith swells when an ion exchange group is introduced into the monolith. If the average diameter of the openings is less than 30 μm, the pressure loss at the time of water flow is increased, which is not preferable. If the average diameter of the openings is too large, contact between the fluid and the monolith ion exchanger becomes insufficient. As a result, the ion exchange characteristics deteriorate, which is not preferable.
なお、本発明では、乾燥状態のモノリス中間体の開口の平均直径、乾燥状態の複合モノリスの空孔又は開口の平均直径及び乾燥状態の複合モノリスイオン交換体の空孔又は開口の平均直径は、水銀圧入法により測定される値である。また、本発明の有機多孔質イオン交換体において、水湿潤状態の複合モノリスイオン交換体の空孔又は開口の平均直径は、乾燥状態の複合モノリスイオン交換体の空孔又は開口の平均直径に、膨潤率を乗じて算出される値である。具体的には、水湿潤状態の複合モノリスイオン交換体の直径がx1(mm)であり、その水湿潤状態の複合モノリスイオン交換体を乾燥させ、得られる乾燥状態の複合モノリスイオン交換体の直径がy1(mm)であり、この乾燥状態の複合モノリスイオン交換体を水銀圧入法により測定したときの空孔又は開口の平均直径がz1(μm)であったとすると、水湿潤状態の複合モノリスイオン交換体の空孔又は開口の平均直径(μm)は、次式「水湿潤状態の複合モノリスイオン交換体の空孔又は開口の平均直径(μm)=z1×(x1/y1)」で算出される。また、イオン交換基導入前の乾燥状態の複合モノリスの空孔又は開口の平均直径、及びその乾燥状態の複合モノリスにイオン交換基導入したときの乾燥状態の複合モノリスに対する水湿潤状態の複合モノリスイオン交換体の膨潤率がわかる場合は、乾燥状態の複合モノリスの空孔又は開口の平均直径に、膨潤率を乗じて、複合モノリスイオン交換体の空孔の水湿潤状態の平均直径を算出することもできる。 In the present invention, the average diameter of the openings of the dry monolith intermediate, the average diameter of the pores or openings of the dry composite monolith, and the average diameter of the holes or openings of the dry composite monolith ion exchanger are: It is a value measured by the mercury intrusion method. Further, in the organic porous ion exchanger of the present invention, the average diameter of the pores or openings of the composite monolith ion exchanger in the water wet state is the average diameter of the pores or openings of the composite monolith ion exchanger in the dry state. It is a value calculated by multiplying the swelling rate. Specifically, the diameter of the composite monolith ion exchanger in the water wet state is x1 (mm), the diameter of the composite monolith ion exchanger in the dry state obtained by drying the composite monolith ion exchanger in the water wet state. And y1 (mm), and the average diameter of the pores or openings when the dry monolithic ion exchanger is measured by mercury porosimetry is z1 (μm) The average diameter (μm) of the holes or openings of the exchanger is calculated by the following formula “average diameter of holes or openings (μm) = z1 × (x1 / y1) of the composite monolith ion exchanger in a water-wet state”. The Also, the average diameter of the pores or openings of the dry composite monolith before introduction of the ion exchange group, and the water-wetting composite monolith ion relative to the dry composite monolith when the ion exchange group is introduced into the dry composite monolith When the swelling ratio of the exchanger is known, the average diameter of the pores or openings of the composite monolith in the dry state is multiplied by the swelling ratio to calculate the average diameter of the pores of the composite monolith ion exchanger in the water wet state. You can also.
第2の有機多孔質体イオン交換体の場合、有機多孔質体は、水湿潤状態で平均直径が1〜60μmの三次元的に連続した骨格と、その骨格間に平均直径が水湿潤状態で10〜100μmの三次元的に連続した空孔を有する共連続構造である。三次元的に連続した空孔の直径が10μm未満であると、流体透過時の圧力損失が大きくなってしまうため好ましくなく、100μmを超えると、流体と有機多孔質イオン交換体との接触が不十分となり、その結果、イオン交換特性が不均一、すなわちイオン交換帯長さが長くなったり、吸着したイオンの微量リークを起こしやすいので好ましくない。 In the case of the second organic porous body ion exchanger, the organic porous body has a three-dimensionally continuous skeleton having an average diameter of 1 to 60 μm in a water-wet state, and an average diameter between the skeletons in a water-wet state. It is a co-continuous structure having three-dimensionally continuous pores of 10 to 100 μm. If the diameter of the three-dimensional continuous pores is less than 10 μm, the pressure loss during fluid permeation increases, which is not preferable. If the diameter exceeds 100 μm, contact between the fluid and the organic porous ion exchanger is not preferable. As a result, the ion exchange characteristics are not uniform, that is, the length of the ion exchange zone becomes long, or a small amount of adsorbed ions are likely to leak, which is not preferable.
上記共連続構造の空孔の水湿潤状態での平均直径は、公知の水銀圧入法で測定した乾燥状態の複合モノリスイオン交換体の空孔の平均直径に、膨潤率を乗じて算出される値である。具体的には、水湿潤状態の複合モノリスイオン交換体の直径がx2(mm)であり、その水湿潤状態の複合モノリスイオン交換体を乾燥させ、得られる乾燥状態の複合モノリスイオン交換体の直径がy2(mm)であり、この乾燥状態の複合モノリスイオン交換体を水銀圧入法により測定したときの空孔の平均直径がz2(μm)であったとすると、複合モノリスイオン交換体の空孔の水湿潤状態での平均直径(μm)は、次式「複合モノリスイオン交換体の空孔の水湿潤状態の平均直径(μm)=z2×(x2/y2)」で算出される。また、イオン交換基導入前の乾燥状態の複合モノリスの空孔の平均直径、及びその乾燥状態の複合モノリスにイオン交換基導入したときの乾燥状態の複合モノリスに対する水湿潤状態の複合モノリスイオン交換体の膨潤率がわかる場合は、乾燥状態の複合モノリスの空孔の平均直径に、膨潤率を乗じて、複合モノリスイオン交換体の空孔の水湿潤状態の平均直径を算出することもできる。また、上記共連続構造体の骨格の水湿潤状態での平均太さは、乾燥状態の複合モノリスイオン交換体のSEM観察を少なくとも3回行い、得られた画像中の骨格の太さを測定し、その平均値に、膨潤率を乗じて算出される値である。具体的には、水湿潤状態の複合モノリスイオン交換体の直径がx3(mm)であり、その水湿潤状態の複合モノリスイオン交換体を乾燥させ、得られる乾燥状態の複合モノリスイオン交換体の直径がy3(mm)であり、この乾燥状態の複合モノリスイオン交換体のSEM観察を少なくとも3回行い、得られた画像中の骨格の太さを測定し、その平均値がz3(μm)であったとすると、複合モノリスイオン交換体の連続構造体の骨格の水湿潤状態での平均太さ(μm)は、次式「複合モノリスイオン交換体の連続構造体の骨格の水湿潤状態の平均太さ(μm)=z3×(x3/y3)」で算出される。また、イオン交換基導入前の乾燥状態の複合モノリスの骨格の平均太さ、及びその乾燥状態の複合モノリスにイオン交換基導入したときの乾燥状態の複合モノリスに対する水湿潤状態の複合モノリスイオン交換体の膨潤率がわかる場合は、乾燥状態の複合モノリスの骨格の平均太さに、膨潤率を乗じて、複合モノリスイオン交換体の骨格の水湿潤状態の平均太さを算出することもできる。なお、共連続構造を形成する骨格は棒状であり円形断面形状であるが、楕円断面形状等異径断面のものが含まれていてもよい。この場合の太さは短径と長径の平均である。 The average diameter of the co-continuous structure pores in the water-wet state is a value calculated by multiplying the average diameter of the pores of the composite monolith ion exchanger in the dry state measured by a known mercury intrusion method and the swelling ratio. It is. Specifically, the diameter of the composite monolith ion exchanger in the water wet state is x2 (mm), the diameter of the composite monolith ion exchanger in the dry state obtained by drying the composite monolith ion exchanger in the water wet state. Is y2 (mm), and the average diameter of the pores when the dried monolithic ion exchanger is measured by mercury porosimetry is z2 (μm), the pores of the composite monolith ion exchanger The average diameter (μm) in the water-wet state is calculated by the following formula: “Average diameter (μm) of the pores of the composite monolith ion exchanger in the water-wet state = z2 × (x2 / y2)”. In addition, the average diameter of the pores of the dry composite monolith before introduction of the ion exchange group, and the water-wet composite monolith ion exchanger with respect to the dry composite monolith when the ion exchange group is introduced into the dry composite monolith Can be calculated by multiplying the average diameter of the pores of the composite monolith in the dry state by the swelling ratio to calculate the average diameter of the pores of the composite monolith ion exchanger in the water-wet state. The average thickness of the skeleton of the co-continuous structure in the wet state is determined by performing SEM observation of the composite monolith ion exchanger in the dry state at least three times and measuring the thickness of the skeleton in the obtained image. The average value is calculated by multiplying the swelling ratio. Specifically, the diameter of the composite monolith ion exchanger in the water wet state is x3 (mm), the diameter of the composite monolith ion exchanger in the dry state obtained by drying the composite monolith ion exchanger in the water wet state. Y3 (mm), SEM observation of this dried composite monolith ion exchanger was performed at least three times, the thickness of the skeleton in the obtained image was measured, and the average value was z3 (μm). The average thickness (μm) of the skeleton of the continuous structure of the composite monolith ion exchanger in the water-wet state is expressed by the following formula: “average thickness of the skeleton of the continuous structure of the composite monolith ion exchanger in the water-wet state” (Μm) = z3 × (x3 / y3) ”. Further, the average thickness of the skeleton of the dry composite monolith before the introduction of the ion exchange groups, and the water-wet composite monolith ion exchanger with respect to the dry composite monolith when the ion exchange groups are introduced into the dry composite monolith Can be calculated by multiplying the average thickness of the skeleton of the composite monolith in the dry state by the swell ratio to the water-wet state of the skeleton of the composite monolith ion exchanger. The skeleton forming the co-continuous structure is rod-shaped and has a circular cross-sectional shape, but may have a cross-section with different diameters such as an elliptical cross-sectional shape. The thickness in this case is the average of the minor axis and the major axis.
また、三次元的に連続した骨格の直径が1μm未満であると、体積当りのイオン交換容量が低下してしまうため好ましくなく、60μmを超えると、イオン交換特性の均一性が失われるため好ましくない。 Further, if the diameter of the three-dimensionally continuous skeleton is less than 1 μm, the ion exchange capacity per volume is reduced, which is not preferable. If the diameter exceeds 60 μm, the uniformity of the ion exchange characteristics is lost, which is not preferable. .
複合モノリスイオン交換体の水湿潤状態での孔の平均直径の好ましい値は10〜120μmである。複合モノリスイオン交換体を構成する有機多孔質体が第1の有機多孔質体の場合、複合モノリスイオン交換体の孔径の好ましい値は30〜120μm、複合モノリスイオン交換体を構成する有機多孔質体が第2の有機多孔質体の場合、複合モノリスイオン交換体の孔径の好ましい値は10〜90μmである。 A preferable value of the average diameter of the pores of the composite monolith ion exchanger in a wet state with water is 10 to 120 μm. When the organic porous body constituting the composite monolith ion exchanger is the first organic porous body, the preferred pore diameter of the composite monolith ion exchanger is 30 to 120 μm, and the organic porous body constituting the composite monolith ion exchanger In the case of the second organic porous body, a preferable value of the pore diameter of the composite monolith ion exchanger is 10 to 90 μm.
本発明に係る複合モノリスイオン交換体において、水湿潤状態での粒子体の直径及び突起体の大きさは、4〜40μm、好ましくは4〜30μm、特に好ましくは4〜20μmである。なお、本発明において、粒子体及び突起体は、共に骨格表面に突起状に観察されるものであり、粒状に観察されるものを粒子体と称し、粒状とは言えない突起状のものを突起体と称する。図17に、突起体の模式的な断面図を示す。図17中の(A)〜(E)に示すように、骨格表面61から突き出している突起状のものが突起体62であり、突起体62には、(A)に示す突起体62aのように粒状に近い形状のもの、(B)に示す突起体62bのように半球状のもの、(C)に示す突起体62cのように骨格表面の盛り上がりのようなもの等が挙げられる。また、他には、突起体61には、(D)に示す突起体62dのように、骨格表面61の平面方向よりも、骨格表面61に対して垂直方向の方が長い形状のものや、(E)に示す突起体62eのように、複数の方向に突起した形状のものもある。また、突起体の大きさは、SEM観察したときのSEM画像で判断され、個々の突起体のSEM画像での幅が最も大きくなる部分の長さを指す。 In the composite monolith ion exchanger according to the present invention, the diameter of the particles and the size of the protrusions in a wet state are 4 to 40 μm, preferably 4 to 30 μm, and particularly preferably 4 to 20 μm. In the present invention, both the particles and the protrusions are observed as protrusions on the surface of the skeleton, and the particles observed are referred to as particles, and the protrusions that are not granular are protrusions. Called the body. FIG. 17 shows a schematic cross-sectional view of the protrusion. As shown to (A)-(E) in FIG. 17, the protrusion-shaped thing protruded from the skeleton surface 61 is the protrusion 62, and the protrusion 62 is like the protrusion 62a shown to (A). The shape close to a granular shape, a hemispherical shape like a projection 62b shown in (B), and a swell of the skeleton surface like a projection 62c shown in (C). In addition, the protrusion 61 has a shape that is longer in the direction perpendicular to the skeleton surface 61 than in the plane direction of the skeleton surface 61, like the protrusion 62d shown in FIG. There is a thing of the shape which protruded in the several direction like the protrusion 62e shown to (E). Further, the size of the protrusions is determined by the SEM image when observed by SEM, and indicates the length of the portion where the width of each protrusion is the largest in the SEM image.
本発明に係る複合モノリスイオン交換体において、全粒子体等中、水湿潤状態で4〜40μmの粒子体等が占める割合は70%以上、好ましくは80%以上である。なお、全粒子体等中の水湿潤状態で4〜40μmの粒子体等が占める割合は、全粒子体等の個数に占める水湿潤状態で4〜40μmの粒子体等の個数割合を指す。また、骨格相の表面は全粒子体等により40%以上、好ましくは50%以上被覆されている。なお、粒子体等による骨格層の表面の被覆割合は、SEMにより表面観察にしたときのSEM画像上の面積割合、つまり、表面を平面視したときの面積割合を指す。壁面や骨格を被覆している粒子の大きさが上記範囲を逸脱すると、流体と複合モノリスイオン交換体の骨格表面及び骨格内部との接触効率を改善する効果が小さくなってしまうため好ましくない。なお、全粒子体等とは、水湿潤状態で4〜40μmの粒子体等以外の大きさの範囲の粒子体及び突起体も全て含めた、骨格層の表面に形成されている全ての粒子体及び突起体を指す。 In the composite monolith ion exchanger according to the present invention, the proportion of 4 to 40 μm particles in a wet state in water is 70% or more, preferably 80% or more. In addition, the ratio which 4-40 micrometers particle bodies etc. occupy in the water wet state in all the particle bodies etc. points out the number ratio of 4-40 micrometers particle bodies etc. in the water wet state which occupy the number of all particle bodies. Further, the surface of the skeletal phase is covered by 40% or more, preferably 50% or more by the whole particles. The coverage ratio of the surface of the skeleton layer with particles or the like refers to the area ratio on the SEM image when the surface is observed by SEM, that is, the area ratio when the surface is viewed in plan. If the size of the particle covering the wall surface or the skeleton deviates from the above range, the effect of improving the contact efficiency between the fluid and the skeleton surface of the composite monolith ion exchanger and the inside of the skeleton is not preferable. In addition, all the particulate bodies etc. are all the particulate bodies formed on the surface of the skeleton layer including all the particulate bodies and protrusions in the size range other than the 4-40 μm particulate bodies in the wet state. And a protrusion.
上記複合モノリスイオン交換体の骨格表面に付着した粒子体等の水湿潤状態での直径又は大きさは、乾燥状態の複合モノリスイオン交換体のSEM画像の観察により得られる粒子体等の直径又は大きさに、乾燥状態から湿潤状態となった際の膨潤率を乗じて算出した値、又はイオン交換基導入前の乾燥状態の複合モノリスのSEM画像の観察により得られる粒子体等の直径又は大きさに、イオン交換基導入前後の膨潤率を乗じて算出した値である。具体的には、水湿潤状態の複合モノリスイオン交換体の直径がx4(mm)であり、その水湿潤状態の複合モノリスイオン交換体を乾燥させ、得られる乾燥状態の複合モノリスイオン交換体の直径がy4(mm)であり、この乾燥状態の複合モノリスイオン交換体をSEM観察したときのSEM画像中の粒子体等の直径又は大きさがz4(μm)であったとすると、水湿潤状態の複合モノリスイオン交換体の粒子体等の直径又は大きさ(μm)は、次式「水湿潤状態の複合モノリスイオン交換体の粒子体等の直径又は大きさ(μm)=z4×(x4/y4)」で算出される。そして、乾燥状態の複合モノリスイオン交換体のSEM画像中に観察される全ての粒子体等の直径又は大きさを測定して、その値を基に、1視野のSEM画像中の全粒子体等の水湿潤状態での直径又は大きさを算出する。この乾燥状態の複合モノリスイオン交換体のSEM観察を少なくとも3回行い、全視野において、SEM画像中の全粒子体等の水湿潤状態での直径又は大きさを算出して、直径又は大きさが4〜40μmにある粒子体等が観察されるか否かを確認し、全視野において確認された場合、複合モノリスイオン交換体の骨格表面上に、直径又は大きさが水湿潤状態で4〜40μmにある粒子体が形成されていると判断する。また、上記に従って1視野毎にSEM画像中の全粒子体等の水湿潤状態での直径又は大きさを算出し、各視野毎に、全粒子体等に占める水湿潤状態で4〜40μmの粒子体等の割合を求め、全視野において、全粒子体等中の水湿潤状態で4〜40μmの粒子体等が占める割合が70%以上であった場合には、複合モノリスイオン交換体の骨格表面に形成されている全粒子体等中、水湿潤状態で4〜40μmの粒子体等が占める割合は70%以上であると判断する。また、上記に従って1視野毎にSEM画像中の全粒子体等による骨格層の表面の被覆割合を求め、全視野において、全粒子体等による骨格層の表面の被覆割合が40%以上であった場合には、複合モノリスイオン交換体の骨格層の表面が全粒子体等により被覆されている割合が40%以上であると判断する。また、イオン交換基導入前の乾燥状態の複合モノリスの粒子体等の直径又は大きさと、その乾燥状態のモノリスにイオン交換基導入したときの乾燥状態の複合モノリスに対する水湿潤状態の複合モノリスイオン交換体の膨潤率とがわかる場合は、乾燥状態の複合モノリスの粒子体等の直径又は大きさに、膨潤率を乗じて、水湿潤状態の複合モノリスイオン交換体の粒子体等の直径又は大きさを算出して、上記と同様にして、水湿潤状態の複合モノリスイオン交換体の粒子体等の直径又は大きさ、全粒子体等中、水湿潤状態で4〜40μmの粒子体等が占める割合、粒子体等による骨格層の表面の被覆割合を求めることもできる。 The diameter or size of the particles attached to the surface of the skeleton of the composite monolith ion exchanger in the water-wet state is the diameter or size of the particles obtained by observing the SEM image of the composite monolith ion exchanger in the dry state. Further, the value calculated by multiplying the swelling rate when the dry state is changed to the wet state, or the diameter or size of the particulates obtained by observing the SEM image of the composite monolith in the dry state before introducing the ion exchange group And a value calculated by multiplying the swelling ratio before and after introduction of the ion exchange group. Specifically, the diameter of the composite monolith ion exchanger in the water wet state is x4 (mm), the diameter of the composite monolith ion exchanger in the dry state obtained by drying the composite monolith ion exchanger in the water wet state. Is y4 (mm), and the diameter or size of the particles in the SEM image of the dried composite monolith ion exchanger observed by SEM is z4 (μm). The diameter or size (μm) of the particles of the monolith ion exchanger is expressed by the following formula: “diameter or size (μm) of the particles of the composite monolith ion exchanger in a water-wet state” = z4 × (x4 / y4) Is calculated. Then, the diameter or size of all particles observed in the SEM image of the composite monolith ion exchanger in the dry state is measured, and based on the value, all particles in one field of view SEM image, etc. The diameter or size of the water in a wet state is calculated. The SEM observation of the dried composite monolith ion exchanger is performed at least three times, and the diameter or size of the whole particle in the SEM image in the water-wet state is calculated in all fields of view. It is confirmed whether or not a particle body or the like at 4 to 40 μm is observed, and when it is confirmed in the entire visual field, the diameter or size is 4 to 40 μm in a wet state on the skeleton surface of the composite monolith ion exchanger. It is determined that the particle body at is formed. Further, according to the above, the diameter or size in the water wet state of all particles in the SEM image is calculated for each visual field, and the particle size of 4 to 40 μm in the water wet state occupying in the whole particles for each visual field. When the proportion of the particles, etc. is 40% or more in the wet state in all the particles in the entire visual field, the skeleton surface of the composite monolith ion exchanger is obtained. It is determined that the proportion of 4 to 40 μm particles in the wet state is 70% or more in all particles formed in the above. Further, according to the above, the coverage ratio of the surface of the skeletal layer with all particles in the SEM image was determined for each field of view, and the coverage ratio of the surface of the skeleton layer with all particles in all fields was 40% or more. In this case, it is determined that the ratio of the surface of the skeleton layer of the composite monolith ion exchanger covered with all the particulates is 40% or more. In addition, the diameter or size of the particles of the composite monolith in the dry state before the introduction of the ion exchange group and the composite monolith ion exchange in the wet state with respect to the dry composite monolith when the ion exchange group is introduced into the monolith in the dry state If the swelling rate of the body is known, the diameter or size of the particles of the composite monolith in the dry state is multiplied by the swelling rate to obtain the diameter or size of the particles of the composite monolith ion exchanger in the water wet state. In the same manner as described above, the diameter or size of the particles of the composite monolith ion exchanger in the water wet state, the ratio of the particles of 4 to 40 μm in the water wet state, etc. in the total particles, etc. In addition, the coverage ratio of the surface of the skeleton layer with particle bodies can be obtained.
粒子体等による骨格相表面の被覆率が40%未満であると、流体と複合モノリスイオン交換体の骨格内部及び骨格表面との接触効率を改善する効果が小さくなり、イオン交換挙動の均一性が損なわれてしまうため好ましくない。上記粒子体等による被覆率の測定方法としては、モノリス(乾燥体)のSEM画像による画像解析方法が挙げられる。 When the coverage of the skeletal phase surface with particles and the like is less than 40%, the effect of improving the contact efficiency between the fluid and the inside of the skeleton of the composite monolith ion exchanger and the skeleton surface is reduced, and the uniformity of the ion exchange behavior is reduced. Since it will be damaged, it is not preferable. Examples of the method for measuring the coverage with the particulates include an image analysis method using a monolith (dry body) SEM image.
また、複合モノリスイオン交換体の全細孔容積は、複合モノリスの全細孔容積と同様である。すなわち、複合モノリスにイオン交換基を導入することで膨潤し開口径が大きくなっても、骨格相が太るため全細孔容積はほとんど変化しない。全細孔容積が0.5ml/g未満であると、通水時の圧力損失が大きくなってしまうため好ましくない。一方、全細孔容積が5ml/gを超えると、体積当りのイオン交換容量が低下してしまうため好ましくない。なお、複合モノリス(モノリス中間体、複合モノリス、複合モノリスイオン交換体)の全細孔容積は、乾燥状態でも、水湿潤状態でも、同じである。 The total pore volume of the composite monolith ion exchanger is the same as the total pore volume of the composite monolith. That is, even when the ion exchange group is introduced into the composite monolith to swell and increase the opening diameter, the total pore volume hardly changes because the skeletal phase is thick. If the total pore volume is less than 0.5 ml / g, the pressure loss during water passage is increased, which is not preferable. On the other hand, if the total pore volume exceeds 5 ml / g, the ion exchange capacity per volume decreases, which is not preferable. Note that the total pore volume of the composite monolith (monolith intermediate, composite monolith, composite monolith ion exchanger) is the same both in the dry state and in the water wet state.
なお、複合モノリスイオン交換体に水を透過させた際の圧力損失は、複合モノリスに水を透過させた際の圧力損失と同様である。 Note that the pressure loss when water is permeated through the composite monolith ion exchanger is the same as the pressure loss when water is permeated through the composite monolith.
本発明の複合モノリスイオン交換体は、水湿潤状態での体積当りのイオン交換容量が0.2mg当量/ml以上、好ましくは0.3〜1.8mg当量/mlのイオン交換容量を有する。体積当りのイオン交換容量が0.2mg当量/ml未満であると、破過までに処理する処理水量が少なくなり、モジュールの交換頻度が高くなるため好ましくない。なお、本発明の複合モノリスイオン交換体の乾燥状態における重量当りのイオン交換容量は特に限定されないが、イオン交換基が複合モノリスの骨格表面及び骨格内部にまで均一に導入しているため、3〜5mg当量/gである。なお、イオン交換基が骨格の表面のみに導入された有機多孔質体のイオン交換容量は、有機多孔質体やイオン交換基の種類により一概には決定できないものの、せいぜい500μg当量/gである。 The composite monolith ion exchanger of the present invention has an ion exchange capacity per volume in a water-wet state of 0.2 mg equivalent / ml or more, preferably 0.3 to 1.8 mg equivalent / ml. If the ion exchange capacity per volume is less than 0.2 mg equivalent / ml, the amount of treated water to be treated before breakthrough decreases, and the frequency of module replacement increases, which is not preferable. In addition, the ion exchange capacity per weight in the dry state of the composite monolith ion exchanger of the present invention is not particularly limited, but since the ion exchange groups are uniformly introduced to the skeleton surface and the skeleton inside the composite monolith, 5 mg equivalent / g. The ion exchange capacity of the organic porous material in which the ion exchange group is introduced only on the surface of the skeleton cannot be determined depending on the kind of the organic porous material or the ion exchange group, but is 500 μg equivalent / g at most.
本発明の複合モノリスに導入するイオン交換基としては、スルホン酸基、カルボン酸基、イミノ二酢酸基、リン酸基、リン酸エステル基等のカチオン交換基;四級アンモニウム基、三級アミノ基、二級アミノ基、一級アミノ基、ポリエチレンイミン基、第三スルホニウム基、ホスホニウム基等のアニオン交換基が挙げられる。イオン交換基がカチオン交換体であれば、半導体デバイスに特に悪影響を及ぼす金属類を効果的に除去することができる。 Examples of the ion exchange group to be introduced into the composite monolith of the present invention include cation exchange groups such as a sulfonic acid group, a carboxylic acid group, an iminodiacetic acid group, a phosphoric acid group, and a phosphoric acid ester group; a quaternary ammonium group and a tertiary amino group. And anion exchange groups such as secondary amino group, primary amino group, polyethyleneimine group, tertiary sulfonium group, and phosphonium group. If the ion exchange group is a cation exchanger, it is possible to effectively remove metals that adversely affect the semiconductor device.
本発明の複合モノリスイオン交換体において、導入されたイオン交換基は、複合モノリスの骨格の表面のみならず、骨格相内部にまで均一に分布している。ここで言う「イオン交換基が均一に分布している」とは、イオン交換基の分布が少なくともμmオーダーで骨格相の表面および骨格相の内部に均一に分布していることを指す。イオン交換基の分布状況は、EPMA等を用いることで、比較的簡単に確認することができる。また、イオン交換基が、複合モノリスの表面のみならず、骨格相の内部にまで均一に分布していると、表面と内部の物理的性質及び化学的性質を均一にできるため、膨潤及び収縮に対する耐久性が向上する。 In the composite monolith ion exchanger of the present invention, the introduced ion exchange groups are uniformly distributed not only on the surface of the skeleton of the composite monolith but also inside the skeleton phase. Here, “the ion exchange groups are uniformly distributed” means that the distribution of the ion exchange groups is uniformly distributed at least on the order of μm on the surface of the skeleton phase and inside the skeleton phase. The distribution of ion exchange groups can be confirmed relatively easily by using EPMA or the like. In addition, when the ion exchange groups are uniformly distributed not only on the surface of the composite monolith but also inside the skeleton phase, the physical and chemical properties of the surface and the interior can be made uniform, so that the swelling and shrinkage can be prevented. Durability is improved.
本発明の複合モノリスイオン交換体は、その厚みが1mm以上であり、膜状の多孔質体とは区別される。厚みが1mm未満であると、多孔質体一枚当りのイオン交換容量が極端に低下してしまうため好ましくない。該複合モノリスイオン交換体の厚みは、好適には3mm〜1000mmである。また、本発明の複合モノリスイオン交換体は、骨格の基本構造が連続空孔構造であるため、機械的強度が高い。 The composite monolith ion exchanger of the present invention has a thickness of 1 mm or more, and is distinguished from a membrane-like porous body. When the thickness is less than 1 mm, the ion exchange capacity per porous body is extremely reduced, which is not preferable. The thickness of the composite monolith ion exchanger is preferably 3 mm to 1000 mm. In addition, the composite monolith ion exchanger of the present invention has high mechanical strength because the basic structure of the skeleton is a continuous pore structure.
本発明の複合モノリスイオン交換体は、イオン交換基を含まない油溶性モノマー、一分子中に少なくとも2個以上のビニル基を有する第1架橋剤、界面活性剤及び水の混合物を撹拌することにより油中水滴型エマルジョンを調製し、次いで油中水滴型エマルジョンを重合させて全細孔容積が5〜30ml/gの連続マクロポア構造のモノリス状の有機多孔質中間体を得るI工程、ビニルモノマー、一分子中に少なくとも2個以上のビニル基を有する第2架橋剤、ビニルモノマーや第2架橋剤は溶解するがビニルモノマーが重合して生成するポリマーは溶解しない有機溶媒及び重合開始剤からなる混合物を調製するII工程、II工程で得られた混合物を静置下、且つ該I工程で得られたモノリス状の有機多孔質中間体の存在下で重合を行うIII工程、III工程で得られたモノリス状有機多孔質体にイオン交換基を導入するIV工程、を行い、モノリス状有機多孔質体を製造する際に、下記(1)〜(5):
(1)III工程における重合温度が、重合開始剤の10時間半減温度より、少なくとも5℃低い温度である;
(2)II工程で用いる第2架橋剤のモル%が、I工程で用いる第1架橋剤のモル%の2倍以上である;
(3)II工程で用いるビニルモノマーが、I工程で用いた油溶性モノマーとは異なる構造のビニルモノマーである;
(4)II工程で用いる有機溶媒が、分子量200以上のポリエーテルである;
(5)II工程で用いるビニルモノマーの濃度が、II工程の混合物中、30重量%以下である;の条件のうち、少なくとも一つを満たす条件下でII工程又はIII工程を行うことにより得られる。
The composite monolith ion exchanger of the present invention is obtained by stirring a mixture of an oil-soluble monomer containing no ion exchange group, a first crosslinking agent having at least two or more vinyl groups in one molecule, a surfactant and water. Preparing a water-in-oil emulsion and then polymerizing the water-in-oil emulsion to obtain a monolithic organic porous intermediate having a continuous macropore structure with a total pore volume of 5 to 30 ml / g, vinyl monomer, A mixture comprising a second crosslinking agent having at least two vinyl groups in one molecule, an organic solvent that dissolves the vinyl monomer or the second crosslinking agent but does not dissolve the polymer formed by polymerization of the vinyl monomer, and a polymerization initiator. Step II for preparing the compound II. The mixture obtained in Step II is allowed to stand, and polymerization is performed in the presence of the monolithic organic porous intermediate obtained in Step I II When the monolithic organic porous material is produced by performing the IV step of introducing an ion exchange group into the monolithic organic porous material obtained in the steps I and III, the following (1) to (5):
(1) The polymerization temperature in step III is at least 5 ° C. lower than the 10-hour half-life temperature of the polymerization initiator;
(2) The mol% of the second cross-linking agent used in step II is at least twice the mol% of the first cross-linking agent used in step I;
(3) The vinyl monomer used in Step II is a vinyl monomer having a structure different from that of the oil-soluble monomer used in Step I;
(4) The organic solvent used in step II is a polyether having a molecular weight of 200 or more;
(5) The concentration of the vinyl monomer used in Step II is 30% by weight or less in the mixture of Step II; obtained by performing Step II or Step III under conditions that satisfy at least one of the conditions .
(モノリス中間体の製造方法)
本発明のモノリスの製造方法において、I工程は、イオン交換基を含まない油溶性モノマー、一分子中に少なくとも2個以上のビニル基を有する第1架橋剤、界面活性剤及び水の混合物を撹拌することにより油中水滴型エマルジョンを調製し、次いで油中水滴型エマルジョンを重合させて全細孔容積が5〜30ml/gの連続マクロポア構造のモノリス中間体を得る工程である。このモノリス中間体を得るI工程は、特開2002−306976号公報記載の方法に準拠して行なえばよい。
(Method for producing monolith intermediate)
In the method for producing a monolith according to the present invention, in the step I, an oil-soluble monomer not containing an ion exchange group, a first crosslinking agent having at least two or more vinyl groups in one molecule, a mixture of a surfactant and water are stirred. In this step, a water-in-oil emulsion is prepared, and then the water-in-oil emulsion is polymerized to obtain a monolith intermediate having a continuous macropore structure having a total pore volume of 5 to 30 ml / g. The step I for obtaining the monolith intermediate may be performed according to the method described in JP-A-2002-306976.
イオン交換基を含まない油溶性モノマーとしては、例えば、カルボン酸基、スルホン酸基、四級アンモニウム基等のイオン交換基を含まず、水に対する溶解性が低く、親油性のモノマーが挙げられる。これらモノマーの好適なものとしては、スチレン、α−メチルスチレン、ビニルトルエン、ビニルベンジルクロライド、ジビニルベンゼン、エチレン、プロピレン、イソブテン、ブタジエン、エチレングリコールジメタクリレート等が挙げられる。これらモノマーは、1種単独又は2種以上を組み合わせて使用することができる。 Examples of the oil-soluble monomer that does not contain an ion exchange group include an oleophilic monomer that does not contain an ion exchange group such as a carboxylic acid group, a sulfonic acid group, and a quaternary ammonium group, has low solubility in water. Preferable examples of these monomers include styrene, α-methylstyrene, vinyl toluene, vinyl benzyl chloride, divinyl benzene, ethylene, propylene, isobutene, butadiene, ethylene glycol dimethacrylate, and the like. These monomers can be used alone or in combination of two or more.
一分子中に少なくとも2個以上のビニル基を有する第1架橋剤としては、ジビニルベンゼン、ジビニルナフタレン、ジビニルビフェニル、エチレングリコールジメタクリレート等が挙げられる。これら架橋剤は、1種単独又は2種以上を組み合わせて使用することができる。好ましい第1架橋剤は、機械的強度の高さから、ジビニルベンゼン、ジビニルナフタレン、ジビニルビフェニル等の芳香族ポリビニル化合物である。第1架橋剤の使用量は、ビニルモノマーと第1架橋剤の合計量に対して0.3〜10モル%、特に0.3〜5モル%、更に0.3〜3モル%であることが好ましい。第1架橋剤の使用量が0.3モル%未満であると、モノリスの機械的強度が不足するため好ましくない。一方、10モル%を越えると、モノリスの脆化が進行して柔軟性が失われる、イオン交換基の導入量が減少してしまうといった問題点が生じるため好ましくない。 Examples of the first crosslinking agent having at least two or more vinyl groups in one molecule include divinylbenzene, divinylnaphthalene, divinylbiphenyl, and ethylene glycol dimethacrylate. These crosslinking agents can be used singly or in combination of two or more. A preferred first cross-linking agent is an aromatic polyvinyl compound such as divinylbenzene, divinylnaphthalene, and divinylbiphenyl because of its high mechanical strength. The amount of the first crosslinking agent used is 0.3 to 10 mol%, particularly 0.3 to 5 mol%, and more preferably 0.3 to 3 mol%, based on the total amount of the vinyl monomer and the first crosslinking agent. Is preferred. If the amount of the first crosslinking agent used is less than 0.3 mol%, the mechanical strength of the monolith is insufficient, which is not preferable. On the other hand, if it exceeds 10 mol%, the monolith becomes more brittle and the flexibility is lost, and the amount of ion exchange groups introduced decreases, which is not preferable.
界面活性剤は、イオン交換基を含まない油溶性モノマーと水とを混合した際に、油中水滴型(W/O)エマルジョンを形成できるものであれば特に制限はなく、ソルビタンモノオレエート、ソルビタンモノラウレート、ソルビタンモノパルミテート、ソルビタンモノステアレート、ソルビタントリオレエート、ポリオキシエチレンノニルフェニルエーテル、ポリオキシエチレンステアリルエーテル、ポリオキシエチレンソルビタンモノオレエート等の非イオン界面活性剤;オレイン酸カリウム、ドデシルベンゼンスルホン酸ナトリウム、スルホコハク酸ジオクチルナトリウム等の陰イオン界面活性剤;ジステアリルジメチルアンモニウムクロライド等の陽イオン界面活性剤;ラウリルジメチルベタイン等の両性界面活性剤を用いることができる。これら界面活性剤は1種単独又は2種類以上を組み合わせて使用することができる。なお、油中水滴型エマルジョンとは、油相が連続相となり、その中に水滴が分散しているエマルジョンを言う。上記界面活性剤の添加量としては、油溶性モノマーの種類および目的とするエマルジョン粒子(マクロポア)の大きさによって大幅に変動するため一概には言えないが、油溶性モノマーと界面活性剤の合計量に対して約2〜70%の範囲で選択することができる。 The surfactant is not particularly limited as long as it can form a water-in-oil (W / O) emulsion when an oil-soluble monomer containing no ion exchange group and water are mixed, and sorbitan monooleate, Nonionic surfactants such as sorbitan monolaurate, sorbitan monopalmitate, sorbitan monostearate, sorbitan trioleate, polyoxyethylene nonylphenyl ether, polyoxyethylene stearyl ether, polyoxyethylene sorbitan monooleate; potassium oleate Anionic surfactants such as sodium dodecylbenzenesulfonate and dioctyl sodium sulfosuccinate; cationic surfactants such as distearyldimethylammonium chloride; amphoteric surfactants such as lauryldimethylbetaine can be used . These surfactants can be used alone or in combination of two or more. The water-in-oil emulsion refers to an emulsion in which an oil phase is a continuous phase and water droplets are dispersed therein. The amount of the surfactant added may vary depending on the type of oil-soluble monomer and the size of the target emulsion particles (macropores), but it cannot be generally stated, but the total amount of oil-soluble monomer and surfactant Can be selected within a range of about 2 to 70%.
また、I工程では、油中水滴型エマルジョン形成の際、必要に応じて重合開始剤を使用してもよい。重合開始剤は、熱及び光照射によりラジカルを発生する化合物が好適に用いられる。重合開始剤は水溶性であっても油溶性であってもよく、例えば、2,2’-アゾビス(イソブチロニトリル)、2,2’-アゾビス(2,4-ジメチルバレロニトリル)、2,2’-アゾビス(2−メチルブチロニトリル)、2,2’-アゾビス(4-メトキシ-2,4-ジメチルバレロニトリル)、2,2’-アゾビスイソ酪酸ジメチル、4,4’-アゾビス(4-シアノ吉草酸)、1,1’-アゾビス(シクロヘキサン-1-カルボニトリル)、過酸化ベンゾイル、過酸化ラウロイル、過硫酸カリウム、過硫酸アンモニウム、過酸化水素−塩化第一鉄、過硫酸ナトリウム−酸性亜硫酸ナトリウム等が挙げられる。 In Step I, a polymerization initiator may be used as necessary when forming a water-in-oil emulsion. As the polymerization initiator, a compound that generates radicals by heat and light irradiation is preferably used. The polymerization initiator may be water-soluble or oil-soluble. For example, 2,2′-azobis (isobutyronitrile), 2,2′-azobis (2,4-dimethylvaleronitrile), 2 , 2′-azobis (2-methylbutyronitrile), 2,2′-azobis (4-methoxy-2,4-dimethylvaleronitrile), dimethyl 2,2′-azobisisobutyrate, 4,4′-azobis ( 4-cyanovaleric acid), 1,1'-azobis (cyclohexane-1-carbonitrile), benzoyl peroxide, lauroyl peroxide, potassium persulfate, ammonium persulfate, hydrogen peroxide-ferrous chloride, sodium persulfate- Examples include acidic sodium sulfite.
イオン交換基を含まない油溶性モノマー、第1架橋剤、界面活性剤、水及び重合開始剤とを混合し、油中水滴型エマルジョンを形成させる際の混合方法としては、特に制限はなく、各成分を一括して一度に混合する方法、油溶性モノマー、第1架橋剤、界面活性剤及び油溶性重合開始剤である油溶性成分と、水や水溶性重合開始剤である水溶性成分とを別々に均一溶解させた後、それぞれの成分を混合する方法などが使用できる。エマルジョンを形成させるための混合装置についても特に制限はなく、通常のミキサーやホモジナイザー、高圧ホモジナイザー等を用いることができ、目的のエマルジョン粒径を得るのに適切な装置を選択すればよい。また、混合条件についても特に制限はなく、目的のエマルジョン粒径を得ることができる攪拌回転数や攪拌時間を、任意に設定することができる。 There is no particular limitation on the mixing method when mixing the oil-soluble monomer containing no ion exchange group, the first cross-linking agent, the surfactant, water and the polymerization initiator to form a water-in-oil emulsion, A method of mixing components all at once, an oil-soluble monomer, a first crosslinking agent, a surfactant, an oil-soluble component that is an oil-soluble polymerization initiator, and a water-soluble component that is water or a water-soluble polymerization initiator For example, a method in which each component is mixed after being uniformly dissolved separately can be used. There is no particular limitation on the mixing apparatus for forming the emulsion, and a normal mixer, homogenizer, high-pressure homogenizer, or the like can be used, and an appropriate apparatus may be selected to obtain the desired emulsion particle size. Moreover, there is no restriction | limiting in particular about mixing conditions, The stirring rotation speed and stirring time which can obtain the target emulsion particle size can be set arbitrarily.
I工程で得られるモノリス中間体は、連続マクロポア構造を有する。これを重合系に共存させると、そのモノリス中間体の構造を鋳型として連続マクロポア構造の骨格相の表面に粒子体等が形成したり、共連続構造の骨格相の表面に粒子体等が形成したりする。また、モノリス中間体は、架橋構造を有する有機ポリマー材料である。該ポリマー材料の架橋密度は特に限定されないが、ポリマー材料を構成する全構成単位に対して、0.3〜10モル%、好ましくは0.3〜5モル%の架橋構造単位を含んでいることが好ましい。架橋構造単位が0.3モル%未満であると、機械的強度が不足するため好ましくない。一方、10モル%を越えると、多孔質体の脆化が進行し、柔軟性が失われるため好ましくない。 The monolith intermediate obtained in Step I has a continuous macropore structure. When this coexists in the polymerization system, particles or the like are formed on the surface of the skeleton phase of the continuous macropore structure using the structure of the monolith intermediate as a template, or particles or the like are formed on the surface of the skeleton phase of the co-continuous structure. Or The monolith intermediate is an organic polymer material having a crosslinked structure. Although the crosslinking density of the polymer material is not particularly limited, it contains 0.3 to 10 mol%, preferably 0.3 to 5 mol% of crosslinked structural units with respect to all the structural units constituting the polymer material. Is preferred. When the cross-linking structural unit is less than 0.3 mol%, the mechanical strength is insufficient, which is not preferable. On the other hand, if it exceeds 10 mol%, the porous body becomes brittle and the flexibility is lost, which is not preferable.
モノリス中間体の全細孔容積は、5〜30ml/g、好適には6〜28ml/gである。全細孔容積が小さ過ぎると、ビニルモノマーを重合させた後で得られるモノリスの全細孔容積が小さくなりすぎ、流体透過時の圧力損失が大きくなるため好ましくない。一方、全細孔容積が大き過ぎると、ビニルモノマーを重合させた後で得られるモノリスの構造が不均一になりやすく、場合によっては構造崩壊を引き起こすため好ましくない。モノリス中間体の全細孔容積を上記数値範囲とするには、モノマーと水の比(重量)を、概ね1:5〜1:35とすればよい。 The total pore volume of the monolith intermediate is 5-30 ml / g, preferably 6-28 ml / g. If the total pore volume is too small, the total pore volume of the monolith obtained after polymerizing the vinyl monomer becomes too small, and the pressure loss during fluid permeation increases, which is not preferable. On the other hand, if the total pore volume is too large, the structure of the monolith obtained after polymerizing the vinyl monomer tends to be non-uniform, and in some cases, the structure collapses, which is not preferable. In order to set the total pore volume of the monolith intermediate in the above numerical range, the ratio (weight) of the monomer to water may be set to approximately 1: 5 to 1:35.
このモノマーと水との比を、概ね1:5〜1:20とすれば、モノリス中間体の全細孔容積が5〜16ml/gの連続マクロポア構造のものが得られ、III工程を経て得られる複合モノリスの有機多孔質体が第1の有機多孔質体のものが得られる。また、該配合比率を、概ね1:20〜1:35とすれば、モノリス中間体の全細孔容積が16ml/gを超え、30ml/g以下の連続マクロポア構造のものが得られ、III工程を経て得られる複合モノリスの有機多孔質体が第2の有機多孔質体のものが得られる。 When the ratio of this monomer to water is approximately 1: 5 to 1:20, a monolith intermediate having a total pore volume of 5 to 16 ml / g and a continuous macropore structure can be obtained and obtained through Step III. The obtained composite monolithic organic porous body is the first organic porous body. Further, if the blending ratio is approximately 1:20 to 1:35, a monolith intermediate having a total pore volume of more than 16 ml / g and a continuous macropore structure of 30 ml / g or less can be obtained. The organic porous body of the composite monolith obtained through the above is obtained as the second organic porous body.
また、モノリス中間体は、マクロポアとマクロポアの重なり部分である開口(メソポア)の平均直径が乾燥状態で20〜100μmである。開口の平均直径が20μm未満であると、ビニルモノマーを重合させた後で得られるモノリスの開口径が小さくなり、通水過時の圧力損失が大きくなってしまうため好ましくない。一方、100μmを超えると、ビニルモノマーを重合させた後で得られるモノリスの開口径が大きくなりすぎ、被処理水とモノリスイオン交換体との接触が不十分となり、その結果、イオン成分の除去効率が低下してしまうため好ましくない。モノリス中間体は、マクロポアの大きさや開口の径が揃った均一構造のものが好適であるが、これに限定されず、均一構造中、均一なマクロポアの大きさよりも大きな不均一なマクロポアが点在するものであってもよい。 Moreover, the average diameter of the opening (mesopore) which is an overlap part of a macropore and a macropore is 20-100 micrometers in a dry state in a monolith intermediate. When the average diameter of the openings is less than 20 μm, the opening diameter of the monolith obtained after polymerizing the vinyl monomer becomes small, and the pressure loss at the time of passing water becomes large, which is not preferable. On the other hand, if it exceeds 100 μm, the opening diameter of the monolith obtained after polymerizing the vinyl monomer becomes too large, and the contact between the water to be treated and the monolith ion exchanger becomes insufficient. As a result, the removal efficiency of ion components Is unfavorable because it decreases. Monolith intermediates preferably have a uniform structure with uniform macropore size and aperture diameter, but are not limited to this, and the uniform structure is dotted with nonuniform macropores larger than the size of the uniform macropore. You may do.
(複合モノリスの製造方法)
II工程は、ビニルモノマー、一分子中に少なくとも2個以上のビニル基を有する第2架橋剤、ビニルモノマーや第2架橋剤は溶解するがビニルモノマーが重合して生成するポリマーは溶解しない有機溶媒及び重合開始剤からなる混合物を調製する工程である。なお、I工程とII工程の順序はなく、I工程後にII工程を行ってもよく、II工程後にI工程を行ってもよい。
(Production method of composite monolith)
Step II is an organic solvent in which a vinyl monomer, a second cross-linking agent having at least two vinyl groups in one molecule, a vinyl monomer or a second cross-linking agent dissolves, but a polymer formed by polymerization of the vinyl monomer does not dissolve. And a step of preparing a mixture comprising a polymerization initiator. In addition, there is no order of I process and II process, II process may be performed after I process, and I process may be performed after II process.
II工程で用いられるビニルモノマーとしては、分子中に重合可能なビニル基を含有し、有機溶媒に対する溶解性が高い親油性のビニルモノマーであれば、特に制限はない。これらビニルモノマーの具体例としては、スチレン、α-メチルスチレン、ビニルトルエン、ビニルベンジルクロライド、ビニルビフェニル、ビニルナフタレン等の芳香族ビニルモノマー;エチレン、プロピレン、1-ブテン、イソブテン等のα-オレフィン;ブタジエン、イソプレン、クロロプレン等のジエン系モノマー;塩化ビニル、臭化ビニル、塩化ビニリデン、テトラフルオロエチレン等のハロゲン化オレフィン;アクリロニトリル、メタクリロニトリル等のニトリル系モノマー;酢酸ビニル、プロピオン酸ビニル等のビニルエステル;アクリル酸メチル、アクリル酸エチル、アクリル酸ブチル、アクリル酸2-エチルヘキシル、メタクリル酸メチル、メタクリル酸エチル、メタクリル酸プロピル、メタクリル酸ブチル、メタクリル酸2−エチルヘキシル、メタクリル酸シクロヘキシル、メタクリル酸ベンジル、メタクリル酸グリシジル等の(メタ)アクリル系モノマーが挙げられる。これらモノマーは、1種単独又は2種以上を組み合わせて使用することができる。本発明で好適に用いられるビニルモノマーは、スチレン、ビニルベンジルクロライド等の芳香族ビニルモノマーである。 The vinyl monomer used in step II is not particularly limited as long as it is a lipophilic vinyl monomer that contains a polymerizable vinyl group in the molecule and has high solubility in an organic solvent. Specific examples of these vinyl monomers include aromatic vinyl monomers such as styrene, α-methylstyrene, vinyl toluene, vinyl benzyl chloride, vinyl biphenyl and vinyl naphthalene; α-olefins such as ethylene, propylene, 1-butene and isobutene; Diene monomers such as butadiene, isoprene and chloroprene; halogenated olefins such as vinyl chloride, vinyl bromide, vinylidene chloride and tetrafluoroethylene; nitrile monomers such as acrylonitrile and methacrylonitrile; vinyl such as vinyl acetate and vinyl propionate Esters: methyl acrylate, ethyl acrylate, butyl acrylate, 2-ethylhexyl acrylate, methyl methacrylate, ethyl methacrylate, propyl methacrylate, butyl methacrylate, 2-methacrylic acid 2- Hexyl, cyclohexyl methacrylate, benzyl methacrylate, and (meth) acrylic monomer of glycidyl methacrylate. These monomers can be used alone or in combination of two or more. The vinyl monomer suitably used in the present invention is an aromatic vinyl monomer such as styrene or vinyl benzyl chloride.
これらビニルモノマーの添加量は、重合時に共存させるモノリス中間体に対して、重量で3〜40倍、好ましくは4〜30倍である。ビニルモノマー添加量が多孔質体に対して3倍未満であると、生成したモノリスの骨格に粒子体を形成できず、イオン交換基導入後の体積当りのイオン交換容量が小さくなってしまうため好ましくない。一方、ビニルモノマー添加量が40倍を超えると、開口径が小さくなり、流体透過時の圧力損失が大きくなってしまうため好ましくない。 The added amount of these vinyl monomers is 3 to 40 times, preferably 4 to 30 times, by weight with respect to the monolith intermediate coexisting at the time of polymerization. If the amount of vinyl monomer added is less than 3 times that of the porous body, it is preferable because the particles cannot be formed in the skeleton of the produced monolith, and the ion exchange capacity per volume after introduction of the ion exchange groups is reduced. Absent. On the other hand, if the amount of vinyl monomer added exceeds 40 times, the opening diameter becomes small and the pressure loss during fluid permeation increases, which is not preferable.
II工程で用いられる第2架橋剤は、分子中に少なくとも2個の重合可能なビニル基を含有し、有機溶媒への溶解性が高いものが好適に用いられる。第2架橋剤の具体例としては、ジビニルベンゼン、ジビニルナフタレン、ジビニルビフェニル、エチレングリコールジメタクリレート、トリメチロールプロパントリアクリレート、ブタンジオールジアクリレート等が挙げられる。これら第2架橋剤は、1種単独又は2種以上を組み合わせて使用することができる。好ましい第2架橋剤は、機械的強度の高さと加水分解に対する安定性から、ジビニルベンゼン、ジビニルナフタレン、ジビニルビフェニル等の芳香族ポリビニル化合物である。第2架橋剤の使用量は、ビニルモノマーと第2架橋剤の合計量に対して0.3〜20モル%、特に0.3〜10モル%であることが好ましい。架橋剤使用量が0.3モル%未満であると、モノリスの機械的強度が不足するため好ましくない。一方、20モル%を越えると、モノリスの脆化が進行して柔軟性が失われる、イオン交換基の導入量が減少してしまうといった問題点が生じるため好ましくない。 As the second crosslinking agent used in Step II, one having at least two polymerizable vinyl groups in the molecule and having high solubility in an organic solvent is preferably used. Specific examples of the second crosslinking agent include divinylbenzene, divinylnaphthalene, divinylbiphenyl, ethylene glycol dimethacrylate, trimethylolpropane triacrylate, butanediol diacrylate, and the like. These 2nd crosslinking agents can be used individually by 1 type or in combination of 2 or more types. A preferred second crosslinking agent is an aromatic polyvinyl compound such as divinylbenzene, divinylnaphthalene, and divinylbiphenyl because of its high mechanical strength and stability to hydrolysis. The amount of the second crosslinking agent used is preferably 0.3 to 20 mol%, particularly 0.3 to 10 mol%, based on the total amount of the vinyl monomer and the second crosslinking agent. When the amount of the crosslinking agent used is less than 0.3 mol%, the mechanical strength of the monolith is insufficient, which is not preferable. On the other hand, if it exceeds 20 mol%, the monolith becomes more brittle and the flexibility is lost, and the amount of ion exchange groups introduced decreases, which is not preferable.
II工程で用いられる有機溶媒は、ビニルモノマーや第2架橋剤は溶解するがビニルモノマーが重合して生成するポリマーは溶解しない有機溶媒、言い換えると、ビニルモノマーが重合して生成するポリマーに対する貧溶媒である。該有機溶媒は、ビニルモノマーの種類によって大きく異なるため一般的な具体例を列挙することは困難であるが、例えば、ビニルモノマーがスチレンの場合、有機溶媒としては、メタノール、エタノール、プロパノール、ブタノール、ヘキサノール、シクロヘキサノール、オクタノール、2-エチルヘキサノール、デカノール、ドデカノール、プロピレングリコール、テトラメチレングリコール等のアルコール類;ジエチルエーテル、ブチルセロソルブ、ポリエチレングリコール、ポリプロピレングリコール、ポリテトラメチレングリコール等の鎖状(ポリ)エーテル類;ヘキサン、ヘプタン、オクタン、イソオクタン、デカン、ドデカン等の鎖状飽和炭化水素類;酢酸エチル、酢酸イソプロピル、酢酸セロソルブ、プロピオン酸エチル等のエステル類が挙げられる。また、ジオキサンやTHF、トルエンのようにポリスチレンの良溶媒であっても、上記貧溶媒と共に用いられ、その使用量が少ない場合には、有機溶媒として使用することができる。これら有機溶媒の使用量は、上記ビニルモノマーの濃度が5〜80重量%となるように用いることが好ましい。有機溶媒使用量が上記範囲から逸脱してビニルモノマー濃度が5重量%未満となると、重合速度が低下してしまうため好ましくない。一方、ビニルモノマー濃度が80重量%を超えると、重合が暴走する恐れがあるため好ましくない。 The organic solvent used in step II is an organic solvent that dissolves the vinyl monomer and the second cross-linking agent but does not dissolve the polymer formed by polymerization of the vinyl monomer, in other words, a poor solvent for the polymer formed by polymerization of the vinyl monomer. It is. Since the organic solvent varies greatly depending on the type of vinyl monomer, it is difficult to list general specific examples. For example, when the vinyl monomer is styrene, the organic solvent includes methanol, ethanol, propanol, butanol, Alcohols such as hexanol, cyclohexanol, octanol, 2-ethylhexanol, decanol, dodecanol, propylene glycol, tetramethylene glycol; chain (poly) ethers such as diethyl ether, butyl cellosolve, polyethylene glycol, polypropylene glycol, polytetramethylene glycol Chain saturated hydrocarbons such as hexane, heptane, octane, isooctane, decane, dodecane, etc .; Ethyl acetate, isopropyl acetate, cellosolve acetate, ethyl propionate, etc. Ethers, and the like. Moreover, even if it is a good solvent of polystyrene like a dioxane, THF, and toluene, when it is used with the said poor solvent and the usage-amount is small, it can be used as an organic solvent. These organic solvents are preferably used so that the concentration of the vinyl monomer is 5 to 80% by weight. If the amount of the organic solvent used deviates from the above range and the vinyl monomer concentration is less than 5% by weight, the polymerization rate is lowered, which is not preferable. On the other hand, if the vinyl monomer concentration exceeds 80% by weight, the polymerization may run away, which is not preferable.
重合開始剤としては、熱及び光照射によりラジカルを発生する化合物が好適に用いられる。重合開始剤は油溶性であるほうが好ましい。本発明で用いられる重合開始剤の具体例としては、2,2’-アゾビス(イソブチロニトリル)、2,2’-アゾビス(2,4-ジメチルバレロニトリル)、2,2’-アゾビス(2−メチルブチロニトリル)、2,2’-アゾビス(4-メトキシ-2,4-ジメチルバレロニトリル)、2,2’-アゾビスイソ酪酸ジメチル、4,4’-アゾビス(4-シアノ吉草酸)、1,1’-アゾビス(シクロヘキサン-1-カルボニトリル)、過酸化ベンゾイル、過酸化ラウロイル、テトラメチルチウラムジスルフィド等が挙げられる。重合開始剤の使用量は、モノマーの種類や重合温度等によって大きく変動するが、ビニルモノマーと第2架橋剤の合計量に対して、約0.01〜5%の範囲で使用することができる。 As the polymerization initiator, a compound that generates radicals by heat and light irradiation is preferably used. The polymerization initiator is preferably oil-soluble. Specific examples of the polymerization initiator used in the present invention include 2,2′-azobis (isobutyronitrile), 2,2′-azobis (2,4-dimethylvaleronitrile), 2,2′-azobis ( 2-methylbutyronitrile), 2,2′-azobis (4-methoxy-2,4-dimethylvaleronitrile), dimethyl 2,2′-azobisisobutyrate, 4,4′-azobis (4-cyanovaleric acid) 1,1′-azobis (cyclohexane-1-carbonitrile), benzoyl peroxide, lauroyl peroxide, tetramethylthiuram disulfide and the like. The amount of polymerization initiator used varies greatly depending on the type of monomer, polymerization temperature, etc., but can be used in a range of about 0.01 to 5% with respect to the total amount of vinyl monomer and second crosslinking agent. .
III工程は、II工程で得られた混合物を静置下、且つ該I工程で得られたモノリス中間体の存在下、重合を行い、複合モノリスを得る工程である。III工程で用いるモノリス中間体は、本発明の斬新な構造を有するモノリスを創出する上で、極めて重要な役割を担っている。特表平7−501140号等に開示されているように、モノリス中間体不存在下でビニルモノマーと第2架橋剤を特定の有機溶媒中で静置重合させると、粒子凝集型のモノリス状有機多孔質体が得られる。それに対して、本発明のように上記重合系に連続マクロポア構造のモノリス中間体を存在させると、重合後のモノリスの構造は劇的に変化し、粒子凝集構造は消失し、上述の特定の骨格構造を有するモノリスが得られる。 In step III, the mixture obtained in step II is allowed to stand, and in the presence of the monolith intermediate obtained in step I, polymerization is performed to obtain a composite monolith. The monolith intermediate used in the step III plays a very important role in creating the monolith having the novel structure of the present invention. As disclosed in JP-A-7-501140 and the like, when a vinyl monomer and a second cross-linking agent are allowed to stand in a specific organic solvent in the absence of a monolith intermediate, a particle aggregation type monolithic organic material is obtained. A porous body is obtained. On the other hand, when a monolith intermediate having a continuous macropore structure is present in the polymerization system as in the present invention, the structure of the monolith after polymerization changes dramatically, the particle aggregation structure disappears, and the specific skeleton described above is lost. A monolith having a structure is obtained.
反応容器の内容積は、モノリス中間体を反応容器中に存在させる大きさのものであれば特に制限されず、反応容器内にモノリス中間体を載置した際、平面視でモノリスの周りに隙間ができるもの、反応容器内にモノリス中間体が隙間無く入るもののいずれであってもよい。このうち、重合後のモノリスが容器内壁から押圧を受けることなく、反応容器内に隙間無く入るものが、モノリスに歪が生じることもなく、反応原料などの無駄がなく効率的である。なお、反応容器の内容積が大きく、重合後のモノリスの周りに隙間が存在する場合であっても、ビニルモノマーや架橋剤は、モノリス中間体に吸着、分配されるため、反応容器内の隙間部分に粒子凝集構造物が生成することはない。 The internal volume of the reaction vessel is not particularly limited as long as it is large enough to allow the monolith intermediate to exist in the reaction vessel. When the monolith intermediate is placed in the reaction vessel, there is a gap around the monolith in plan view. Or a monolith intermediate in the reaction vessel with no gap. Of these, the monolith after polymerization does not receive any pressure from the inner wall of the vessel and enters the reaction vessel without any gap, so that the monolith is not distorted and the reaction raw materials are not wasted and efficient. Even when the internal volume of the reaction vessel is large and there are gaps around the monolith after polymerization, the vinyl monomer and the crosslinking agent are adsorbed and distributed on the monolith intermediate, so the gaps in the reaction vessel A particle aggregate structure is not generated in the portion.
III工程において、反応容器中、モノリス中間体は混合物(溶液)で含浸された状態に置かれる。II工程で得られた混合物とモノリス中間体の配合比は、前述の如く、モノリス中間体に対して、ビニルモノマーの添加量が重量で3〜40倍、好ましくは4〜30倍となるように配合するのが好適である。これにより、適度な開口径を有しつつ、特定の骨格を有するモノリスを得ることができる。反応容器中、混合物中のビニルモノマーと架橋剤は、静置されたモノリス中間体の骨格に吸着、分配しされ、モノリス中間体の骨格内で重合が進行する。 In step III, the monolith intermediate is placed in a reaction vessel impregnated with the mixture (solution). As described above, the blending ratio of the mixture obtained in Step II and the monolith intermediate is 3 to 40 times by weight, preferably 4 to 30 times by weight, relative to the monolith intermediate. It is suitable to mix. Thereby, it is possible to obtain a monolith having a specific skeleton while having an appropriate opening diameter. In the reaction vessel, the vinyl monomer and the crosslinking agent in the mixture are adsorbed and distributed on the skeleton of the monolith intermediate that has been allowed to stand, and polymerization proceeds in the skeleton of the monolith intermediate.
重合条件は、モノマーの種類、開始剤の種類により様々な条件が選択できる。例えば、開始剤として2,2’-アゾビス(イソブチロニトリル)、2,2’-アゾビス(2,4-ジメチルバレロニトリル)、過酸化ベンゾイル、過酸化ラウロイル等を用いたときには、不活性雰囲気下の密封容器内において、20〜100℃で1〜48時間加熱重合させればよい。加熱重合により、モノリス中間体の骨格に吸着、分配したビニルモノマーと架橋剤が該骨格内で重合し、該特定の骨格構造を形成させる。重合終了後、内容物を取り出し、未反応ビニルモノマーと有機溶媒の除去を目的に、アセトン等の溶剤で抽出して特定骨格構造のモノリスを得る。 Various polymerization conditions can be selected depending on the type of monomer and the type of initiator. For example, when 2,2′-azobis (isobutyronitrile), 2,2′-azobis (2,4-dimethylvaleronitrile), benzoyl peroxide, lauroyl peroxide, or the like is used as an initiator, an inert atmosphere What is necessary is just to heat-polymerize at 20-100 degreeC for 1 to 48 hours in the lower sealed container. By heat polymerization, the vinyl monomer adsorbed and distributed on the skeleton of the monolith intermediate and the crosslinking agent are polymerized in the skeleton to form the specific skeleton structure. After completion of the polymerization, the content is taken out and extracted with a solvent such as acetone for the purpose of removing unreacted vinyl monomer and organic solvent to obtain a monolith having a specific skeleton structure.
上述の複合モノリスを製造する際に、下記(1)〜(5)の条件のうち、少なくとも一つを満たす条件下でII工程又はIII工程行うと、本発明の特徴的な構造である、骨格表面に粒子体等が形成された複合モノリスを製造することができる。 When the above-mentioned composite monolith is produced, the skeleton, which is the characteristic structure of the present invention, is obtained by performing the II step or the III step under the conditions satisfying at least one of the following conditions (1) to (5). A composite monolith having particles or the like formed on the surface can be produced.
(1)III工程における重合温度が、重合開始剤の10時間半減温度より、少なくとも5℃低い温度である。
(2)II工程で用いる第2架橋剤のモル%が、I工程で用いる第1架橋剤のモル%の2倍以上である。
(3)II工程で用いるビニルモノマーが、I工程で用いた油溶性モノマーとは異なる構造のビニルモノマーである。
(4)II工程で用いる有機溶媒が、分子量200以上のポリエーテルである。
(5)II工程で用いるビニルモノマーの濃度が、II工程の混合物中、30重量%以下である。
(1) The polymerization temperature in step III is a temperature that is at least 5 ° C. lower than the 10-hour half-life temperature of the polymerization initiator.
(2) The mol% of the second cross-linking agent used in step II is at least twice the mol% of the first cross-linking agent used in step I.
(3) The vinyl monomer used in step II is a vinyl monomer having a structure different from that of the oil-soluble monomer used in step I.
(4) The organic solvent used in step II is a polyether having a molecular weight of 200 or more.
(5) The concentration of the vinyl monomer used in Step II is 30% by weight or less in the mixture of Step II.
(上記(1)の説明)
10時間半減温度は重合開始剤の特性値であり、使用する重合開始剤が決まれば10時間半減温度を知ることができる。また、所望の10時間半減温度があれば、それに該当する重合開始剤を選択することができる。III工程において、重合温度を低下させることで、重合速度が低下し、骨格相の表面に粒子体等を形成させることができる。その理由は、モノリス中間体の骨格相の内部でのモノマー濃度低下が緩やかとなり、液相部からモノリス中間体へのモノマー分配速度が低下するため、余剰のモノマーがモノリス中間体の骨格層の表面近傍で濃縮され、その場で重合したためと考えられる。
(Description of (1) above)
The 10-hour half temperature is a characteristic value of the polymerization initiator, and if the polymerization initiator to be used is determined, the 10-hour half temperature can be known. Moreover, if there exists desired 10-hour half temperature, the polymerization initiator applicable to it can be selected. In step III, the polymerization rate is lowered by lowering the polymerization temperature, and particles and the like can be formed on the surface of the skeleton phase. The reason for this is that the monomer concentration drop inside the skeleton phase of the monolith intermediate becomes gradual, and the monomer distribution rate from the liquid phase part to the monolith intermediate decreases, so the surplus monomer is on the surface of the skeleton layer of the monolith intermediate. It is thought that it was concentrated in the vicinity and polymerized in situ.
重合温度の好ましいものは、用いる重合開始剤の10時間半減温度より少なくとも10℃低い温度である。重合温度の下限値は特に限定されないが、温度が低下するほど重合速度が低下し、重合時間が実用上許容できないほど長くなってしまうため、重合温度を10時間半減温度に対して5〜20℃低い範囲に設定することが好ましい。 The preferred polymerization temperature is a temperature that is at least 10 ° C. lower than the 10-hour half-life temperature of the polymerization initiator used. Although the lower limit of the polymerization temperature is not particularly limited, the polymerization rate decreases as the temperature decreases, and the polymerization time becomes unacceptably long. Therefore, the polymerization temperature is 5 to 20 ° C. with respect to the 10-hour half temperature. It is preferable to set to a low range.
((2)の説明)
II工程で用いる第2架橋剤のモル%を、I工程で用いる第1架橋剤のモル%の2倍以上に設定して重合すると、本発明の複合モノリスが得られる。その理由は、モノリス中間体と含浸重合によって生成したポリマーとの相溶性が低下し相分離が進行するため、含浸重合によって生成したポリマーはモノリス中間体の骨格相の表面近傍に排除され、骨格相表面に粒子体等の凹凸を形成したものと考えられる。なお、架橋剤のモル%は、架橋密度モル%であって、ビニルモノマーと架橋剤の合計量に対する架橋剤量(モル%)を言う。
(Description of (2))
When the mol% of the second cross-linking agent used in Step II is set to be twice or more of the mol% of the first cross-linking agent used in Step I, the composite monolith of the present invention is obtained. The reason for this is that the compatibility between the monolith intermediate and the polymer produced by impregnation polymerization is reduced and phase separation proceeds, so the polymer produced by impregnation polymerization is excluded in the vicinity of the surface of the skeleton phase of the monolith intermediate, It is considered that irregularities such as particles are formed on the surface. In addition, mol% of a crosslinking agent is a crosslinking density mol%, Comprising: The amount of crosslinking agents (mol%) with respect to the total amount of a vinyl monomer and a crosslinking agent is said.
II工程で用いる第2架橋剤モル%の上限は特に制限されないが、第2架橋剤モル%が著しく大きくなると、重合後のモノリスにクラックが発生する、モノリスの脆化が進行して柔軟性が失われる、イオン交換基の導入量が減少してしまうといった問題点が生じるため好ましくない。好ましい第2架橋剤モル%の倍数は2倍〜10倍である。一方、I工程で用いる第1架橋剤モル%をII工程で用いられる第2架橋剤モル%に対して2倍以上に設定しても、骨格相表面への粒子体等の形成は起こらず、本発明の複合モノリスは得られない。 The upper limit of the second crosslinker mol% used in step II is not particularly limited, but if the second crosslinker mol% is extremely large, cracks occur in the monolith after polymerization, and the brittleness of the monolith proceeds and flexibility is increased. This is not preferable because it causes a problem that the amount of ion exchange groups to be lost is reduced. A preferred multiple of the second crosslinking agent mol% is 2 to 10 times. On the other hand, even when the mol% of the first cross-linking agent used in step I is set to be twice or more the mol% of the second cross-linking agent used in step II, the formation of particles on the surface of the skeleton phase does not occur. The composite monolith of the present invention cannot be obtained.
((3)の説明)
II工程で用いるビニルモノマーが、I工程で用いた油溶性モノマーとは異なる構造のビニルモノマーであると、本発明の複合モノリスが得られる。例えば、スチレンとビニルベンジルクロライドのように、ビニルモノマーの構造が僅かでも異なると、骨格相表面に粒子体等が形成された複合モノリスが生成する。一般に、僅かでも構造が異なる二種類のモノマーから得られる二種類のホモポリマーは互いに相溶しない。したがって、I工程で用いたモノリス中間体形成に用いたモノマーとは異なる構造のモノマー、すなわち、I工程で用いたモノリス中間体形成に用いたモノマー以外のモノマーをII工程で用いてIII工程で重合を行うと、II工程で用いたモノマーはモノリス中間体に均一に分配や含浸がされるものの、重合が進行してポリマーが生成すると、生成したポリマーはモノリス中間体とは相溶しないため、相分離が進行し、生成したポリマーはモノリス中間体の骨格相の表面近傍に排除され、骨格相の表面に粒子体等の凹凸を形成したものと考えられる。
(Explanation of (3))
When the vinyl monomer used in Step II is a vinyl monomer having a structure different from that of the oil-soluble monomer used in Step I, the composite monolith of the present invention is obtained. For example, if the structures of vinyl monomers are slightly different, such as styrene and vinyl benzyl chloride, a composite monolith having particles or the like formed on the surface of the skeleton phase is generated. In general, two types of homopolymers obtained from two types of monomers that are slightly different in structure are not compatible with each other. Therefore, a monomer having a structure different from that of the monomer used for forming the monolith intermediate used in Step I, that is, a monomer other than the monomer used for forming the monolith intermediate used in Step I is used in Step II to polymerize in Step III. The monomer used in Step II is uniformly distributed and impregnated into the monolith intermediate, but when the polymerization proceeds and the polymer is produced, the produced polymer is not compatible with the monolith intermediate. Separation proceeds, and the produced polymer is considered to be excluded in the vicinity of the surface of the skeleton phase of the monolith intermediate, and irregularities such as particles are formed on the surface of the skeleton phase.
((4)の説明)
II工程で用いる有機溶媒が、分子量200以上のポリエーテルであると、本発明の複合モノリスが得られる。ポリエーテルはモノリス中間体との親和性が比較的高く、特に低分子量の環状ポリエーテルはポリスチレンの良溶媒、低分子量の鎖状ポリエーテルは良溶媒ではないがかなりの親和性を有している。しかし、ポリエーテルの分子量が大きくなると、モノリス中間体との親和性は劇的に低下し、モノリス中間体とほとんど親和性を示さなくなる。このような親和性に乏しい溶媒を有機溶媒に用いると、モノマーのモノリス中間体の骨格内部への拡散が阻害され、その結果、モノマーはモノリス中間体の骨格の表面近傍のみで重合するため、骨格相表面に粒子体等が形成され骨格表面に凹凸を形成したものと考えられる。
(Explanation of (4))
When the organic solvent used in step II is a polyether having a molecular weight of 200 or more, the composite monolith of the present invention is obtained. Polyethers have a relatively high affinity with monolith intermediates, especially low molecular weight cyclic polyethers are good solvents for polystyrene, and low molecular weight chain polyethers are not good solvents but have considerable affinity. . However, as the molecular weight of the polyether increases, the affinity with the monolith intermediate dramatically decreases and shows little affinity with the monolith intermediate. When such a solvent having poor affinity is used as the organic solvent, diffusion of the monomer into the skeleton of the monolith intermediate is inhibited, and as a result, the monomer is polymerized only near the surface of the skeleton of the monolith intermediate. It is considered that particles and the like are formed on the phase surface and irregularities are formed on the skeleton surface.
ポリエーテルの分子量は、200以上であれば上限に特に制約はないが、あまりに高分子量であると、II工程で調製される混合物の粘度が高くなり、モノリス中間体内部への含浸が困難になるため好ましくない。好ましいポリエーテルの分子量は200〜100000、特に好ましくは200〜10000である。また、ポリエーテルの末端構造は、未修飾の水酸基であっても、メチル基やエチル基等のアルキル基でエーテル化されていてもよいし、酢酸、オレイン酸、ラウリン酸、ステアリン酸等でエステル化されていてもよい。 The upper limit of the molecular weight of the polyether is not particularly limited as long as it is 200 or more. However, when the molecular weight is too high, the viscosity of the mixture prepared in the step II becomes high, and it is difficult to impregnate the monolith intermediate. Therefore, it is not preferable. The molecular weight of the preferred polyether is 200 to 100,000, particularly preferably 200 to 10,000. The terminal structure of the polyether may be an unmodified hydroxyl group, etherified with an alkyl group such as a methyl group or an ethyl group, or esterified with acetic acid, oleic acid, lauric acid, stearic acid, or the like. It may be made.
((5)の説明)
II工程で用いるビニルモノマーの濃度が、II工程中の混合物中、30重量%以下であると、本発明の複合モノリスが得られる。II工程でモノマー濃度を低下させることで、重合速度が低下し、前記(1)と同様の理由で、骨格相表面に粒子体等が形成でき、骨格相表面に凹凸を形成されることができる。モノマー濃度の下限値は特に限定されないが、モノマー濃度が低下するほど重合速度が低下し、重合時間が実用上許容できないほど長くなってしまうため、モノマー濃度は10〜30重量%に設定することが好ましい。
(Explanation of (5))
When the concentration of the vinyl monomer used in Step II is 30% by weight or less in the mixture in Step II, the composite monolith of the present invention is obtained. By reducing the monomer concentration in the step II, the polymerization rate is reduced, and for the same reason as the above (1), particles and the like can be formed on the surface of the skeleton phase, and irregularities can be formed on the surface of the skeleton phase. . Although the lower limit of the monomer concentration is not particularly limited, the polymerization rate decreases as the monomer concentration decreases and the polymerization time becomes unacceptably long, so the monomer concentration may be set to 10 to 30% by weight. preferable.
III工程で得られた複合モノリスは、連続骨格相と連続空孔相からなる有機多孔質体と、該有機多孔質体の骨格表面に固着する多数の粒子体又は該有機多孔質体の骨格表面上に形成される多数の突起体との複合構造体である。有機多孔質体の連続骨格相と連続空孔相は、SEM画像により観察することができる。有機多孔質体の基本構造は、連続マクロポア構造か、共連続構造である。 The composite monolith obtained in the step III includes an organic porous body composed of a continuous skeleton phase and a continuous pore phase, a large number of particles fixed to the skeleton surface of the organic porous body, or a skeleton surface of the organic porous body. It is a composite structure with a number of protrusions formed on it. The continuous skeleton phase and the continuous pore phase of the organic porous body can be observed by SEM images. The basic structure of the organic porous body is a continuous macropore structure or a co-continuous structure.
複合モノリスにおける連続マクロポア構造は、気泡状のマクロポア同士が重なり合い、この重なる部分が乾燥状態での平均直径20〜100μmの開口となるものであり、複合モノリスにおける共連続構造体は、平均の太さが乾燥状態で0.8〜40μmの三次元的に連続した骨格と、その骨格間に乾燥で平均直径が8〜80μmの三次元的に連続した空孔とからなるものである。 The continuous macropore structure in the composite monolith is such that bubble-shaped macropores overlap each other, and the overlapping portion becomes an opening having an average diameter of 20 to 100 μm in a dry state. The bicontinuous structure in the composite monolith has an average thickness. Is composed of a three-dimensionally continuous skeleton of 0.8 to 40 μm in a dry state and three-dimensionally continuous pores having an average diameter of 8 to 80 μm by drying between the skeletons.
IV工程は、III工程で得られた複合モノリスにイオン交換基を導入する工程である。この導入方法によれば、得られる複合モノリスイオン交換体の多孔構造を厳密にコントロールできる。 Step IV is a step of introducing an ion exchange group into the composite monolith obtained in step III. According to this introduction method, the porous structure of the obtained composite monolith ion exchanger can be strictly controlled.
上記複合モノリスにイオン交換基を導入する方法としては、特に制限はなく、高分子反応やグラフト重合等の公知の方法を用いることができる。例えば、スルホン酸基を導入する方法としては、複合モノリスがスチレン-ジビニルベンゼン共重合体等であればクロロ硫酸や濃硫酸、発煙硫酸を用いてスルホン化する方法;複合モノリスに均一にラジカル開始基や連鎖移動基を骨格表面及び骨格内部に導入し、スチレンスルホン酸ナトリウムやアクリルアミド−2−メチルプロパンスルホン酸をグラフト重合する方法;同様にグリシジルメタクリレートをグラフト重合した後、官能基変換によりスルホン酸基を導入する方法等が挙げられる。また、四級アンモニウム基を導入する方法としては、複合モノリスがスチレン-ジビニルベンゼン共重合体等であればクロロメチルメチルエーテル等によりクロロメチル基を導入した後、三級アミンと反応させる方法;複合モノリスをクロロメチルスチレンとジビニルベンゼンの共重合により製造し、三級アミンと反応させる方法;モノリスに、均一にラジカル開始基や連鎖移動基を骨格表面及び骨格内部導入し、N,N,N−トリメチルアンモニウムエチルアクリレートやN,N,N−トリメチルアンモニウムプロピルアクリルアミドをグラフト重合する方法;同様にグリシジルメタクリレートをグラフト重合した後、官能基変換により四級アンモニウム基を導入する方法等が挙げられる。これらの方法のうち、スルホン酸基を導入する方法については、クロロ硫酸を用いてスチレン-ジビニルベンゼン共重合体にスルホン酸基を導入する方法が、四級アンモニウム基を導入する方法としては、スチレン-ジビニルベンゼン共重合体にクロロメチルメチルエーテル等によりクロロメチル基を導入した後、三級アミンと反応させる方法やクロロメチルスチレンとジビニルベンゼンの共重合によりモノリスを製造し、三級アミンと反応させる方法が、イオン交換基を均一かつ定量的に導入できる点で好ましい。なお、導入するイオン交換基としては、カルボン酸基、イミノ二酢酸基、スルホン酸基、リン酸基、リン酸エステル基等のカチオン交換基;四級アンモニウム基、三級アミノ基、二級アミノ基、一級アミノ基、ポリエチレンイミン基、第三スルホニウム基、ホスホニウム基等のアニオン交換基が挙げられる。 The method for introducing an ion exchange group into the composite monolith is not particularly limited, and a known method such as polymer reaction or graft polymerization can be used. For example, as a method of introducing a sulfonic acid group, if the composite monolith is a styrene-divinylbenzene copolymer, etc., a method of sulfonation using chlorosulfuric acid, concentrated sulfuric acid, or fuming sulfuric acid; radical initiating groups uniformly on the composite monolith And a method of grafting sodium styrene sulfonate or acrylamido-2-methylpropane sulfonic acid by introducing a chain transfer group into the skeleton surface or inside the skeleton; Similarly, after graft polymerization of glycidyl methacrylate, the sulfonic acid group is converted by functional group conversion. The method etc. which introduce | transduce are mentioned. In addition, as a method of introducing a quaternary ammonium group, if the composite monolith is a styrene-divinylbenzene copolymer or the like, a method of introducing a chloromethyl group with chloromethyl methyl ether or the like and then reacting with a tertiary amine; A method of producing monolith by copolymerization of chloromethylstyrene and divinylbenzene and reacting with a tertiary amine; uniformly introducing a radical initiating group or chain transfer group into the monolith on the skeleton surface and inside the skeleton, and N, N, N- Examples include a method of graft polymerization of trimethylammonium ethyl acrylate or N, N, N-trimethylammonium propylacrylamide; a method of grafting glycidyl methacrylate in the same manner and then introducing a quaternary ammonium group by functional group conversion. Among these methods, the method of introducing a sulfonic acid group includes a method of introducing a sulfonic acid group into a styrene-divinylbenzene copolymer using chlorosulfuric acid, and a method of introducing a quaternary ammonium group includes styrene. -Introducing a chloromethyl group into the divinylbenzene copolymer with chloromethyl methyl ether, etc., then reacting with a tertiary amine, or producing a monolith by copolymerization of chloromethylstyrene and divinylbenzene and reacting with a tertiary amine The method is preferable in that the ion exchange group can be introduced uniformly and quantitatively. The ion exchange groups to be introduced include cation exchange groups such as carboxylic acid groups, iminodiacetic acid groups, sulfonic acid groups, phosphoric acid groups, and phosphoric ester groups; quaternary ammonium groups, tertiary amino groups, and secondary amino groups. Groups, primary amino groups, polyethyleneimine groups, tertiary sulfonium groups, phosphonium groups and the like.
本発明の実施の形態におけるイオン吸着モジュールは、少なくとも被処理水が流入する開口を備える容器と、該容器に充填される複合モノリスイオン交換体とを備えるものである。この容器は、被処理水が流入する開口のみを備えるものであれば、該イオン吸着モジュールを貯留容器や貯留槽中の水中に投入して当該水の浄化を行なうバッチ処理方法に適用でき、また、被処理水が流入する被処理水流入配管と、処理水が流出する処理水流出配管を備えるものであれば、従来より一般的に用いられている連続通水処理方法に適用できる。被処理水とイオン吸着モジュールの接触形態としては、被処理水と前記多孔質イオン交換体を接触させるものであれば、特に限定されるものではなく、単純な円柱状又は多角柱状充填層に上昇流又は下降流で通水する方式、円筒状充填層に円周方向外側から内筒へ通水する外圧方式、逆方向に通水する内圧方式、円筒状有機多孔質体を多数充填し、内圧式又は外圧式で通水するチューブラー方式、シート状充填層を用いる平膜方式、及び平膜を折り畳んだ形状に型枠成形したプリーツ方式などを例示することができる。 An ion adsorption module according to an embodiment of the present invention includes at least a container having an opening through which water to be treated flows, and a composite monolith ion exchanger filled in the container. As long as this container has only an opening through which water to be treated flows, it can be applied to a batch processing method in which the ion adsorption module is put into water in a storage container or storage tank to purify the water. As long as it has a treated water inflow pipe into which treated water flows and a treated water outflow pipe from which treated water flows out, it can be applied to a continuous water treatment method that has been generally used. The contact form of the water to be treated and the ion adsorption module is not particularly limited as long as the water to be treated and the porous ion exchanger are brought into contact with each other, and it rises to a simple cylindrical or polygonal packed bed. A method of passing water in a flow or downward flow, an external pressure method in which a cylindrical packed bed is passed from the outer circumferential direction to the inner cylinder, an internal pressure method in which water is passed in the reverse direction, a large number of cylindrical organic porous bodies are filled, Examples thereof include a tubular method that allows water to flow by a pressure method or an external pressure method, a flat membrane method that uses a sheet-like packed bed, and a pleat method that forms a flat membrane into a folded shape.
また、充填される多孔質イオン交換体の形状としては、前記吸着形態を採るモジュールの容器の形状に従って、ブロック状、シート状、板状、円柱状、円筒状などが選択される。また、上記有機多孔質イオン交換体を0.1mmから10mmの球形又は不定形の粒状小ブロックとし、この小ブロックを容器に充填して充填層を形成しても良い。これら各種形状の多孔質イオン交換体の成形方法としては、ブロック状多孔質イオン交換体からの切削による方法や、目的形状の型枠内に前記エマルジョンを充填して型枠内で重合を行う方法などが挙げられる。 Further, as the shape of the porous ion exchanger to be filled, a block shape, a sheet shape, a plate shape, a columnar shape, a cylindrical shape, or the like is selected according to the shape of the container of the module taking the adsorption form. Further, the organic porous ion exchanger may be formed into a spherical or irregular granular small block of 0.1 mm to 10 mm, and this small block may be filled into a container to form a packed bed. As a method for molding these various shapes of porous ion exchangers, a method by cutting from a block-shaped porous ion exchanger, or a method in which the emulsion is filled in a mold of a desired shape and polymerization is performed in the mold Etc.
容器に充填する多孔質イオン交換体の種類と充填形態としては、特に制限されず、使用目的や吸着しようとするイオン性不純物の種類により任意に決定することができる。具体的には、容器内に多孔質陽イオン交換体、多孔質陰イオン交換体を単独又は混在させて充填させる形態が挙げられる。また、多孔質イオン交換体を混在させる形態としては、ブロック状、シート状、板状又は円柱状に成形又は加工したものを通水方向に対して積層する形態、又は小ブロックイオン交換体を混合して充填する形態などが挙げられる。このうち、多孔質陽イオン交換体と多孔質陰イオン交換体を積層充填したものが、多孔質イオン交換体の作製と容器への充填が容易である点で好ましい。 The type and form of the porous ion exchanger filled in the container are not particularly limited, and can be arbitrarily determined depending on the purpose of use and the type of ionic impurities to be adsorbed. Specifically, a form in which the container is filled with a porous cation exchanger or a porous anion exchanger alone or in combination is exemplified. In addition, as a form to mix the porous ion exchanger, a form formed or processed into a block shape, a sheet shape, a plate shape or a column shape is laminated with respect to the water flow direction, or a small block ion exchanger is mixed. And filling form. Among these, a porous cation exchanger and a porous anion exchanger that are stacked and filled are preferred in terms of easy production of the porous ion exchanger and filling of the container.
また、本発明のイオン交換モジュールの他の形態としては、粒状のイオン交換樹脂充填層と前記多孔質イオン交換体充填層を、上流側からこの順序で積層してなるもの、及び前記多孔質イオン交換体が充填されたイオン吸着モジュールを、粒状のイオン交換樹脂が充填されたイオン吸着モジュールの下流側に配置されるものが挙げられる。前者の形態は後者の形態に比較して、接続配管を省略することができる。従来より汎用されている粒状イオン交換樹脂を上流部に、多孔質イオン交換体を下流部に配置することによって、初めにイオン性不純物を大量に除去し、次に残留イオン性不純物を高効率で除去することによって、総イオン交換帯長さの縮小、イオン吸着塔の低容化、高流速での吸着効率の向上が図れる。上流側の粒状イオン交換樹脂は、カチオン交換樹脂とアニオン交換樹脂の混合イオン交換樹脂が好ましく、下流側の多孔質イオン交換体は多孔質カチオン交換体と多孔質アニオン交換体の積層充填層が好ましい。 As another form of the ion exchange module of the present invention, a granular ion exchange resin packed layer and the porous ion exchanger packed layer are laminated in this order from the upstream side, and the porous ion What arrange | positions the ion adsorption module with which the exchanger was filled in the downstream of the ion adsorption module with which the granular ion exchange resin was filled is mentioned. The former form can omit connection piping compared with the latter form. By placing the granular ion exchange resin, which has been widely used in the past, in the upstream part and the porous ion exchanger in the downstream part, a large amount of ionic impurities are removed first, and then the residual ionic impurities are efficiently removed. By removing, the total ion exchange zone length can be reduced, the volume of the ion adsorption tower can be reduced, and the adsorption efficiency at a high flow rate can be improved. The upstream granular ion exchange resin is preferably a mixed ion exchange resin of a cation exchange resin and an anion exchange resin, and the downstream porous ion exchanger is preferably a stacked packed layer of a porous cation exchanger and a porous anion exchanger. .
本発明で用いるイオン交換モジュールの形状としては、特に制限されず、カラム状、扁平状及び下方部に鏡板部を備える塔形状等が挙げられる。扁平状(小太鼓状)のイオン交換モジュールは、イオン交換体充填層が通水方向において短く、通水方向に垂直方向(直径)において長いもので、通水と再生を短時間で行なう水処理方法に適する。また、下方部に鏡板部を備えるいわゆるイオン交換塔は、前記他の形態における粒状イオン交換樹脂と多孔質イオン交換体の積層充填の場合に用いられる。すなわち、従来の下方部に鏡板部を備えるいわゆるイオン交換塔は上流側から下流側に向けて、粒状イオン交換樹脂が充填された脱塩部と、目板またはディストリビューターの役目を果たす軽石(テカポア)が配設または充填された鏡板部とで構成されていたが、本例のイオン交換モジュールの場合、鏡板部の目板または軽石(テカポア)に置き換えて、前記多孔質イオン交換体を充填すればよく、これにより高速流でのイオン性不純物の吸着効率が高まると共に、多孔質イオン交換体がディストリビューターの役目を果たすため塔内部品を削減でき、更に上向流による再生で当該充填層が移動することがなく再生効率がよくなる。また、本発明のイオン吸着モジュールによれば、多孔質イオン交換体は例えば充填容器に嵌るブロック形状として得ることができ、充填が容易である。 The shape of the ion exchange module used in the present invention is not particularly limited, and examples thereof include a column shape, a flat shape, and a tower shape having an end plate portion at a lower portion. A flat (small drum-shaped) ion exchange module is a water treatment method in which the ion exchanger packed layer is short in the direction of water flow and long in the direction (diameter) perpendicular to the direction of water flow, and water flow and regeneration are performed in a short time. Suitable for. In addition, a so-called ion exchange tower having a mirror plate part in the lower part is used in the case of stacking and filling the granular ion exchange resin and the porous ion exchanger in the other embodiment. In other words, a so-called ion exchange tower having a mirror plate part in a conventional lower part has a desalting part filled with a granular ion exchange resin from the upstream side to the downstream side, and a pumice stone serving as the eyeplate or distributor. In the case of the ion exchange module in this example, the porous ion exchanger is filled with the end plate or pumice (tecapore) of the end plate part. This increases the efficiency of adsorption of ionic impurities in a high-speed flow, and the porous ion exchanger serves as a distributor, so that the number of parts in the tower can be reduced. Reproduction efficiency is improved without moving. In addition, according to the ion adsorption module of the present invention, the porous ion exchanger can be obtained, for example, in the form of a block that fits into a filling container, and is easily filled.
本発明の水処理方法は、被処理水と前記多孔質イオン交換体を接触させることにより、該被処理水中のイオン性不純物を吸着除去する方法(水処理第1方法)及び被処理水と粒状のイオン交換樹脂を接触させることにより得られた第1処理水を、更に前記多孔質イオン交換体に接触させることにより第2処理水を得る方法(水処理第2方法)である。水処理第1方法においては、被処理水中、イオン性不純物の含有量が微量、例えば導電率で0.1〜100mS/mの被処理水を処理する場合、該多孔質イオン交換体の充填が容易で小さな装置を用い、頻繁に再生する水処理方法に好適である。また、高流速でもイオン交換帯長さを短く維持することができ、イオン交換体装置の減容化が図れる。水処理第2方法によれば、イオン性不純物が微量であっても吸着率が高く、吸着したイオンのリークが起こり難い。すなわち、粒状イオン交換樹脂は粒径が0.2〜0.5mmのため、粒子内と粒子外での拡散速度が大きく異なり、流速が上がるとイオン吸着部分と未吸着部分の混在領域であるイオン交換帯長さが長くなり、吸着したイオンの微量リークが起こるものの、総交換容量が大きいためイオンの粗取りができる。一方、3次元網目構造を有する有機多孔質イオン交換体は、総交換容量が小さいが拡散速度に広がりがないため、高流速でもイオン交換帯長さを短く維持できる。このため、粒状イオン交換樹脂を上流側に、有機多孔質イオン交換体を下流側に設置することによって、始めにイオン性物質を大量に除去、次に残留イオンを高効率で除去することによって、総イオン交換帯長さの縮小、イオン吸着塔の低容化、高流速での吸着効率の向上が実現できる。従って、当該イオン吸着モジュールは、例えば従来の超純水製造装置のサブシステムに用いられているカートリッジポリッシャーの代替器とすることができる。 The water treatment method of the present invention comprises a method of adsorbing and removing ionic impurities in the water to be treated by bringing the water to be treated into contact with the porous ion exchanger (first method of water treatment), and the water to be treated and granular. This is a method (second water treatment method) in which a second treated water is obtained by further contacting the first treated water obtained by contacting the ion exchange resin with the porous ion exchanger. In the first water treatment method, when treating water to be treated having a small amount of ionic impurities, for example, conductivity of 0.1 to 100 mS / m in the water to be treated, the porous ion exchanger is filled. It is suitable for a water treatment method that uses an easy and small apparatus and regenerates frequently. Further, the ion exchange zone length can be kept short even at a high flow rate, and the volume of the ion exchanger apparatus can be reduced. According to the second water treatment method, the adsorption rate is high even if the amount of ionic impurities is very small, and the leak of adsorbed ions hardly occurs. That is, since the granular ion exchange resin has a particle size of 0.2 to 0.5 mm, the diffusion rate inside and outside the particle is greatly different, and when the flow rate is increased, the ion is a mixed region of the ion adsorbing part and the non-adsorbing part. Although the exchange zone length becomes long and a slight leak of adsorbed ions occurs, the total exchange capacity is large, so that rough ion removal is possible. On the other hand, since the organic porous ion exchanger having a three-dimensional network structure has a small total exchange capacity but does not spread in the diffusion rate, the ion exchange zone length can be kept short even at a high flow rate. For this reason, by installing the granular ion exchange resin on the upstream side and the organic porous ion exchanger on the downstream side, first, a large amount of ionic substances are removed, and then residual ions are removed with high efficiency. It is possible to reduce the total ion exchange zone length, reduce the volume of the ion adsorption tower, and improve the adsorption efficiency at a high flow rate. Therefore, the ion adsorption module can be used as an alternative to a cartridge polisher used in a subsystem of a conventional ultrapure water production apparatus, for example.
本発明の水処理方法は、前記多孔質イオン交換体を被処理水中の除去目的イオンより吸着選択性の低いイオン形とした後、被処理水を通水し、該被処理水中の目的イオンを吸着除去すると共に、該吸着選択性の低いイオンを被処理水中に放出する方法であってもよい。具体的には、除去目的イオンがカルシウムイオン、マグネシウムイオンである場合には、それより選択吸着性の低いナトリウムイオンを多孔質イオン交換体に吸着させ、これを水処理に用いる。この方法は、例えばボイラー給水のように、スケール付着防止が水処理の主たる目的である場合、必ずしも全てのイオンを除去する必要がないので、安価で安全に再生できる点で好適である。また、本発明の水処理方法は、多孔質イオン交換体が陽イオン交換体であり、該陽イオン交換体をナトリウム形とした後、被処理水を通水し、該被処理水中の硬度成分をナトリウムと交換する軟化処理方法であってもよい。この方法によれば、被処理水中の硬度成分を容易に除去できる。 In the water treatment method of the present invention, the porous ion exchanger is made into an ion form having a lower adsorption selectivity than the removal target ions in the water to be treated, and then the water to be treated is passed, A method may be used in which the ions having low adsorption selectivity are released into the water to be treated while being removed by adsorption. Specifically, when the ions to be removed are calcium ions and magnesium ions, sodium ions having a lower selective adsorptivity are adsorbed on the porous ion exchanger and used for water treatment. This method is preferable in that it is not necessarily required to remove all the ions when scale prevention is the main purpose of water treatment, such as boiler feed water, and it can be safely and inexpensively regenerated. Further, in the water treatment method of the present invention, the porous ion exchanger is a cation exchanger, and after the cation exchanger is made into a sodium form, the water to be treated is passed through, and the hardness component in the water to be treated May be a softening treatment method in which is replaced with sodium. According to this method, the hardness component in the for-treatment water can be easily removed.
本発明のイオン交換モジュール及び水処理方法において用いられる多孔質イオン交換体は、イオン吸着除去処理に繰り返し用いるため、薬剤により再生処理したものを用いることができる。再生処理方法としては、酸と多孔質陽イオン交換体、アルカリと多孔質陰イオン交換体をそれぞれ接触させることにより、該多孔質イオン交換体に吸着せしめたイオン性物質を脱着させる方法が挙げられる。酸としては、塩酸、硫酸及び硝酸等が、アルカリとしては苛性ソーダ等が挙げられる。また薬剤と多孔質イオン交換体の接触方法としては、上昇流でも下降流でも特に限定されるものではなく、粒状のイオン交換樹脂など他のイオン交換体が混在する場合でも、各イオン交換体を分離する操作は不要である。 Since the porous ion exchanger used in the ion exchange module and water treatment method of the present invention is repeatedly used for the ion adsorption removal treatment, it can be regenerated with a chemical. Examples of the regeneration treatment method include a method in which an ionic substance adsorbed on the porous ion exchanger is desorbed by contacting an acid and a porous cation exchanger, or an alkali and a porous anion exchanger, respectively. . Examples of the acid include hydrochloric acid, sulfuric acid, and nitric acid, and examples of the alkali include caustic soda. Further, the method of contacting the drug with the porous ion exchanger is not particularly limited to the upward flow or the downward flow. Even when other ion exchangers such as a granular ion exchange resin are mixed, each ion exchanger is Separation is not necessary.
(実施例)
次に、実施例を挙げて本発明を具体的に説明するが、これは単に例示であって、本発明を制限するものではない。
(Example)
Next, the present invention will be specifically described by way of examples, but this is merely an example and does not limit the present invention.
参考例1
(I工程;モノリス中間体の製造)
スチレン9.28g、ジビニルベンゼン0.19g、ソルビタンモノオレエート(以下SMOと略す)0.50gおよび2,2’-アゾビス(イソブチロニトリル)0.26gを混合し、均一に溶解させた。次に,当該スチレン/ジビニルベンゼン/SMO/2,2’-アゾビス(イソブチロニトリル)混合物を180gの純水に添加し、遊星式撹拌装置である真空撹拌脱泡ミキサー(イーエムイー社製)を用いて5〜20℃の温度範囲において減圧下撹拌して、油中水滴型エマルションを得た。このエマルションを反応容器に速やかに移し、密封後静置下で60℃、24時間重合させた。重合終了後、内容物を取り出し、イソプロパノールで抽出した後、減圧乾燥して、連続マクロポア構造を有するモノリス中間体を製造した。水銀圧入法により測定した該モノリス中間体のマクロポアとマクロポアが重なる部分の開口(メソポア)の平均直径は40μm、全細孔容積は15.8ml/gであった。
Reference example 1
(Step I; production of monolith intermediate)
9.28 g of styrene, 0.19 g of divinylbenzene, 0.50 g of sorbitan monooleate (hereinafter abbreviated as SMO) and 0.26 g of 2,2′-azobis (isobutyronitrile) were mixed and dissolved uniformly. Next, the styrene / divinylbenzene / SMO / 2,2′-azobis (isobutyronitrile) mixture is added to 180 g of pure water, and a vacuum stirring defoaming mixer (manufactured by EM Corp.) which is a planetary stirring device. Was used under reduced pressure in a temperature range of 5 to 20 ° C. to obtain a water-in-oil emulsion. The emulsion was immediately transferred to a reaction vessel, and after sealing, it was allowed to polymerize at 60 ° C. for 24 hours. After completion of the polymerization, the content was taken out, extracted with isopropanol, and then dried under reduced pressure to produce a monolith intermediate having a continuous macropore structure. The average diameter of the openings (mesopores) where the macropores and macropores of the monolith intermediate were measured by mercury porosimetry was 40 μm, and the total pore volume was 15.8 ml / g.
(複合モノリスの製造)
次いで、スチレン36.0g、ジビニルベンゼン4.0g、1-デカノール60g、2,2’-アゾビス(2,4-ジメチルバレロニトリル)0.4gを混合し、均一に溶解させた(II工程)。重合開始剤として用いた2,2’-アゾビス(2,4-ジメチルバレロニトリル)の10時間半減温度は、51℃であった。モノリス中間体の架橋密度1.3モル%に対して、II工程で用いたスチレンとジビニルベンゼンの合計量に対するジビニルベンゼンの使用量は6.6モル%であり、架橋密度比は5.1倍であった。次に上記モノリス中間体を外径70mm、厚さ約20mmの円盤状に切断して、3.2g分取した。分取したモノリス中間体を内径73mmの反応容器に入れ、当該スチレン/ジビニルベンゼン/1-デカノール/2,2’-アゾビス(2,4-ジメチルバレロニトリル)混合物に浸漬させ、減圧チャンバー中で脱泡した後、反応容器を密封し、静置下60℃で24時間重合させた。重合終了後、厚さ約30mmのモノリス状の内容物を取り出し、アセトンでソックスレー抽出した後、85℃で一夜減圧乾燥した(III工程)。
(Manufacture of composite monolith)
Next, 36.0 g of styrene, 4.0 g of divinylbenzene, 60 g of 1-decanol, and 0.4 g of 2,2′-azobis (2,4-dimethylvaleronitrile) were mixed and dissolved uniformly (step II). The 10-hour half-life temperature of 2,2′-azobis (2,4-dimethylvaleronitrile) used as the polymerization initiator was 51 ° C. The amount of divinylbenzene used is 6.6 mol% with respect to the total amount of styrene and divinylbenzene used in Step II, while the crosslink density of the monolith intermediate is 1.3 mol%, and the crosslink density ratio is 5.1 times. Met. Next, the monolith intermediate was cut into a disk shape having an outer diameter of 70 mm and a thickness of about 20 mm, and 3.2 g was collected. The separated monolith intermediate is placed in a reaction vessel having an inner diameter of 73 mm, immersed in the styrene / divinylbenzene / 1-decanol / 2,2′-azobis (2,4-dimethylvaleronitrile) mixture, and removed in a vacuum chamber. After bubbling, the reaction vessel was sealed and allowed to polymerize at 60 ° C. for 24 hours. After completion of the polymerization, the monolith-like contents having a thickness of about 30 mm were taken out, subjected to Soxhlet extraction with acetone, and then dried under reduced pressure at 85 ° C. overnight (step III).
このようにして得られたスチレン/ジビニルベンゼン共重合体よりなる複合モノリス(乾燥体)の内部構造を、SEMにより観察した結果を図1〜図3に示す。図1〜図3のSEM画像は、倍率が異なるものであり、モノリスを任意の位置で切断して得た切断面の任意の位置における画像である。図1〜図3から明らかなように、当該複合モノリスは連続マクロポア構造を有しており、連続マクロポア構造体を構成する骨格相の表面は、平均粒子径4μmの粒子体で被覆され、全粒子体等による骨格表面の粒子被覆率は80%であった。また、粒径3〜5μmの粒子体が全体の粒子体に占める割合は90%であった。 The results of observing the internal structure of the composite monolith (dried body) composed of the styrene / divinylbenzene copolymer thus obtained by SEM are shown in FIGS. The SEM images in FIGS. 1 to 3 are different in magnification, and are images at arbitrary positions on a cut surface obtained by cutting a monolith at an arbitrary position. As apparent from FIGS. 1 to 3, the composite monolith has a continuous macropore structure, and the surface of the skeletal phase constituting the continuous macropore structure is coated with particles having an average particle diameter of 4 μm. The particle coverage of the skeleton surface by the body and the like was 80%. Moreover, the ratio for which the particle body with a particle size of 3-5 micrometers occupied to the whole particle body was 90%.
また、水銀圧入法により測定した当該複合モノリスの開口の平均直径は16μm、全細孔容積は2.3ml/gであった。その結果を表1及び表2にまとめて示す。表1中、仕込み欄は左から順に、II工程で用いたビニルモノマー、架橋剤、有機溶媒、I工程で得られたモノリス中間体を示す。また、粒子体等は粒子で示した。 Moreover, the average diameter of the opening of the composite monolith measured by mercury porosimetry was 16 μm, and the total pore volume was 2.3 ml / g. The results are summarized in Tables 1 and 2. In Table 1, the preparation column shows the vinyl monomer, the crosslinking agent, the organic solvent used in Step II, and the monolith intermediate obtained in Step I in order from the left. Further, the particle bodies and the like are shown as particles.
(複合モノリスカチオン交換体の製造)
上記の方法で製造した複合モノリスを、外径70mm、厚み約15mmの円盤状に切断した。モノリスの重量は19.6gであった。これにジクロロメタン1500mlを加え、35℃で1時間加熱した後、10℃以下まで冷却し、クロロ硫酸98.9gを徐々に加え、昇温して35℃で24時間反応させた。その後、メタノールを加え、残存するクロロ硫酸をクエンチした後、メタノールで洗浄してジクロロメタンを除き、更に純水で洗浄して複合モノリスカチオン交換体を得た。
(Production of complex monolith cation exchanger)
The composite monolith produced by the above method was cut into a disk shape having an outer diameter of 70 mm and a thickness of about 15 mm. The weight of the monolith was 19.6 g. To this, 1500 ml of dichloromethane was added and heated at 35 ° C. for 1 hour, then cooled to 10 ° C. or less, 98.9 g of chlorosulfuric acid was gradually added, and the temperature was raised and reacted at 35 ° C. for 24 hours. Thereafter, methanol was added to quench the remaining chlorosulfuric acid, which was then washed with methanol to remove dichloromethane and further washed with pure water to obtain a composite monolith cation exchanger.
得られたカチオン交換体の反応前後の膨潤率は1.3倍であり、体積当りのイオン交換容量は、水湿潤状態で1.11mg当量/mlであった。水湿潤状態での有機多孔質イオン交換体の開口の平均直径を、有機多孔質体の値と水湿潤状態のカチオン交換体の膨潤率から見積もったところ21μmであり、同様の方法で求めた被覆粒子の平均粒径は5μmであった。なお、全粒子体等による骨格表面の粒子被覆率は80%、全細孔容積は2.3ml/gであった。また、粒径4〜7μmの粒子体が全体の粒子体に占める割合は90%であった。また、水を透過させた際の圧力損失の指標である差圧係数は、0.057MPa/m・LVであり、実用上要求される圧力損失と比較して、それを下回る低い圧力損失であった。更に、イオン交換帯長さは9mmであり、著しく短い値を示した。結果を表2にまとめて示す。 The swelling rate before and after the reaction of the obtained cation exchanger was 1.3 times, and the ion exchange capacity per volume was 1.11 mg equivalent / ml in a water wet state. The average diameter of the openings of the organic porous ion exchanger in the water wet state was 21 μm as estimated from the value of the organic porous body and the swelling ratio of the cation exchanger in the water wet state. The average particle size of the particles was 5 μm. The particle coverage of the skeletal surface with all particles was 80%, and the total pore volume was 2.3 ml / g. Moreover, the ratio for which the particle body of 4-7 micrometers of particle | grains accounts to the whole particle body was 90%. The differential pressure coefficient, which is an index of pressure loss when water is permeated, is 0.057 MPa / m · LV, which is a lower pressure loss than that required for practical use. It was. Further, the length of the ion exchange zone was 9 mm, showing a remarkably short value. The results are summarized in Table 2.
次に、複合モノリスカチオン交換体中のスルホン酸基の分布状態を確認するため、EPMAにより硫黄原子の分布状態を観察した。その結果を図4及び図5に示す。図4及び図5共に、左右の写真はそれぞれ対応している。図4は硫黄原子のカチオン交換体の表面における分布状態を示したものであり、図5は硫黄原子のカチオン交換体の断面(厚み)方向における分布状態を示したものである。図4及び図5より、スルホン酸基はカチオン交換体の骨格表面及び骨格内部(断面方向)にそれぞれ均一に導入されていることがわかる。 Next, in order to confirm the distribution state of the sulfonic acid group in the composite monolith cation exchanger, the distribution state of sulfur atoms was observed by EPMA. The results are shown in FIGS. 4 and 5, the left and right photographs correspond to each other. FIG. 4 shows the distribution of sulfur atoms on the surface of the cation exchanger, and FIG. 5 shows the distribution of sulfur atoms in the cross-section (thickness) direction of the cation exchanger. 4 and 5, it can be seen that the sulfonic acid groups are uniformly introduced on the skeleton surface of the cation exchanger and inside the skeleton (cross-sectional direction).
参考例2〜5
(複合モノリスの製造)
ビニルモノマーの使用量、架橋剤の使用量、有機溶媒の種類と使用量、III工程で重合時に共存させるモノリス中間体の多孔構造、架橋密度と使用量及び重合温度を表1に示す配合量に変更した以外は、参考例1と同様の方法でモノリスを製造した。その結果を表1及び表2に示す。また、複合モノリス(乾燥体)の内部構造を、SEMにより観察した結果を図6〜図13に示す。図6〜図8は参考例2、図9及び図10は参考例3、図11は参考例4、図12及び図13は参考例5のものである。なお、参考例2については架橋密度比(2.5倍)、参考例3については有機溶媒の種類(PEG;分子量400)、参考例4についてはビニルモノマー濃度(28.0%)、参考例5については重合温度(40℃;重合開始剤の10時間半減温度より11℃低い)について、本発明の製造条件を満たす条件で製造した。図6〜図13から参考例3〜5の複合モノリスの骨格表面に付着しているものは粒子体というよりは突起体であった。突起体の「粒子平均径」は突起体の大きさ(最大径)の平均径である。図6〜図13及び表2から、参考例2〜6のモノリス骨格表面に付着している粒子の平均径は3〜8μm、全粒子体等による骨格表面の粒子被覆率は50〜95%であった。また、参考例2が粒径3〜6μmの粒子体が全体の粒子体に占める割合は80%、参考例3が粒径3〜10μmの突起体が全体の粒子体に占める割合は80%、参考例4が粒径3〜5μmの粒子体が全体の粒子体に占める割合は90%、参考例5が粒径3〜7μmの粒子体が全体の粒子体に占める割合は90%であった。
Reference Examples 2-5
(Manufacture of composite monolith)
The amount of vinyl monomer used, the amount of crosslinking agent used, the type and amount of organic solvent used, the porous structure of the monolith intermediate that coexists during polymerization in step III, the crosslinking density and the amount used, and the polymerization temperature are shown in Table 1. A monolith was produced in the same manner as in Reference Example 1 except for the change. The results are shown in Tables 1 and 2. Moreover, the result of having observed the internal structure of composite monolith (dry body) by SEM is shown in FIGS. 6 to 8 are of Reference Example 2, FIGS. 9 and 10 are of Reference Example 3, FIG. 11 is of Reference Example 4, and FIGS. 12 and 13 are of Reference Example 5. For Reference Example 2, the crosslinking density ratio (2.5 times), for Reference Example 3, the type of organic solvent (PEG; molecular weight 400), for Reference Example 4, the vinyl monomer concentration (28.0%), Reference Example For No. 5, the polymerization temperature (40 ° C .; 11 ° C. lower than the 10-hour half-life temperature of the polymerization initiator) was produced under conditions satisfying the production conditions of the present invention. From FIG. 6 to FIG. 13, what adhered to the skeleton surface of the composite monoliths of Reference Examples 3 to 5 were protrusions rather than particles. The “particle average diameter” of the protrusion is the average diameter of the protrusions (maximum diameter). From FIG. 6 to FIG. 13 and Table 2, the average diameter of the particles adhering to the surface of the monolith skeleton of Reference Examples 2 to 6 is 3 to 8 μm, and the particle coverage of the skeleton surface by all particles is 50 to 95%. there were. In addition, the proportion of Reference Example 2 in which particles having a particle diameter of 3 to 6 μm occupy the entire particle body is 80%, and the ratio of Reference Example 3 in which protrusions having a particle diameter of 3 to 10 μm occupy the entire particle is 80%. In Reference Example 4, the proportion of particles having a particle diameter of 3 to 5 μm in the total particle body was 90%, and in Reference Example 5, the proportion of particles having a particle diameter of 3 to 7 μm in the entire particle body was 90%. .
(複合モノリスカチオン交換体の製造)
上記の方法で製造した複合モノリスを、それぞれ参考例1と同様の方法でクロロ硫酸と反応させ、複合モノリスカチオン交換体を製造した。その結果を表2に示す。参考例2〜5における複合モノリスカチオン交換体の連続細孔の平均直径は21〜52μmであり、骨格表面に付着している粒子体等の平均径は5〜13μm、全粒子体等による骨格表面の粒子被覆率も50〜95%と高く、差圧係数も0.010〜0.057MPa/m・LVと小さい上に、イオン交換帯長さも8〜12mmと著しく小さな値であった。また、粒径5〜10μmの粒子体が全体の粒子体に占める割合は90%であった。
参考例6
(Production of complex monolith cation exchanger)
The composite monolith produced by the above method was reacted with chlorosulfuric acid in the same manner as in Reference Example 1 to produce a composite monolith cation exchanger. The results are shown in Table 2. The average diameter of the continuous pores of the composite monolith cation exchanger in Reference Examples 2 to 5 is 21 to 52 μm, the average diameter of the particles attached to the skeleton surface is 5 to 13 μm, the skeleton surface due to all the particles, etc. The particle coverage was as high as 50 to 95%, the differential pressure coefficient was as small as 0.010 to 0.057 MPa / m · LV, and the ion exchange zone length was as extremely small as 8 to 12 mm. Moreover, the ratio for which the particle body with a particle size of 5-10 micrometers occupied to the whole particle body was 90%.
Reference Example 6
(複合モノリスの製造)
ビニルモノマーの種類とその使用量、架橋剤の使用量、有機溶媒の種類と使用量、III工程で重合時に共存させるモノリス中間体の多孔構造、架橋密度および使用量を表1に示す配合量に変更した以外は、参考例1と同様の方法でモノリスを製造した。その結果を表1及び表2に示す。また、複合モノリス(乾燥体)の内部構造を、SEMにより観察した結果を図14〜図16に示す。参考例6の複合モノリスの骨格表面に付着しているものは突起体であった。参考例6のモノリスは、表面に形成された突起体の最大径の平均径が10μmであり、全粒子体等による骨格表面の粒子被覆率は100%であった。また、粒径6〜12μmの粒子体が全体の粒子体に占める割合は80%であった。
(Manufacture of composite monolith)
Table 1 shows the type and amount of vinyl monomer used, amount of crosslinking agent used, type and amount of organic solvent, monolith intermediate porous structure coexisting during polymerization in step III, crosslinking density and amount used. A monolith was produced in the same manner as in Reference Example 1 except for the change. The results are shown in Tables 1 and 2. Moreover, the result of having observed the internal structure of composite monolith (dry body) by SEM is shown in FIGS. What adhered to the skeleton surface of the composite monolith of Reference Example 6 was a protrusion. In the monolith of Reference Example 6, the average diameter of the maximum diameter of the protrusions formed on the surface was 10 μm, and the particle coverage of the skeletal surface with all the particulates was 100%. Moreover, the ratio for which the particle body with a particle size of 6-12 micrometers occupied to the whole particle body was 80%.
(複合モノリスアニオン交換体の製造)
上記の方法で製造した複合モノリスを、外径70mm、厚み約15mmの円盤状に切断した。複合モノリスの重量は17.9gであった。これにテトラヒドロフラン1500mlを加え、40℃で1時間加熱した後、10℃以下まで冷却し、トリメチルアミン30%水溶液114.5gを徐々に加え、昇温して40℃で24時間反応させた。反応終了後、メタノールで洗浄してテトラヒドロフランを除き、更に純水で洗浄してモノリスアニオン交換体を得た。
(Production of complex monolith anion exchanger)
The composite monolith produced by the above method was cut into a disk shape having an outer diameter of 70 mm and a thickness of about 15 mm. The weight of the composite monolith was 17.9 g. To this was added 1500 ml of tetrahydrofuran, heated at 40 ° C. for 1 hour, cooled to 10 ° C. or lower, gradually added 114.5 g of a 30% trimethylamine aqueous solution, heated to react at 40 ° C. for 24 hours. After completion of the reaction, the resultant was washed with methanol to remove tetrahydrofuran, and further washed with pure water to obtain a monolith anion exchanger.
得られた複合アニオン交換体の反応前後の膨潤率は2.0倍であり、体積当りのイオン交換容量は、水湿潤状態で0.32mg当量/mlであった。水湿潤状態での有機多孔質イオン交換体の連続細孔の平均直径を、モノリスの値と水湿潤状態のモノリスアニオン交換体の膨潤率から見積もったところ58μmであり、同様の方法で求めた突起体の平均径は20μm、全粒子体等による骨格表面の粒子被覆率は100%、全細孔容積は2.1ml/gであった。また、イオン交換帯長さは16mmと非常に短い値を示した。なお、水を透過させた際の圧力損失の指標である差圧係数は、0.041MPa/m・LVであり、実用上要求される圧力損失と比較して、それを下回る低い圧力損失であった。また、粒径12〜24μmの粒子体が全体の粒子体に占める割合は80%であった。その結果を表2にまとめて示す。 The obtained composite anion exchanger had a swelling ratio of 2.0 times before and after the reaction, and the ion exchange capacity per volume was 0.32 mg equivalent / ml in a water-wet state. The average diameter of the continuous pores of the organic porous ion exchanger in the water wet state was 58 μm as estimated from the value of the monolith and the swelling ratio of the monolith anion exchanger in the water wet state. The average diameter of the body was 20 μm, the particle coverage of the skeletal surface with all particles was 100% and the total pore volume was 2.1 ml / g. The ion exchange zone length was as short as 16 mm. The differential pressure coefficient, which is an index of pressure loss when water is permeated, is 0.041 MPa / m · LV, which is a lower pressure loss than that required for practical use. It was. Moreover, the ratio for which the particle body with a particle size of 12-24 micrometers occupied to the whole particle body was 80%. The results are summarized in Table 2.
次に、多孔質アニオン交換体中の四級アンモニウム基の分布状態を確認するため、アニオン交換体を塩酸水溶液で処理して塩化物型とした後、EPMAにより塩素原子の分布状態を観察した。その結果、塩素原子はアニオン交換体の骨格表面のみならず、骨格内部にも均一に分布しており、四級アンモニウム基がアニオン交換体中に均一に導入されていることが確認できた。 Next, in order to confirm the distribution state of the quaternary ammonium groups in the porous anion exchanger, the anion exchanger was treated with an aqueous hydrochloric acid solution to form a chloride form, and then the distribution state of chlorine atoms was observed by EPMA. As a result, it was confirmed that the chlorine atoms were uniformly distributed not only on the skeleton surface of the anion exchanger but also inside the skeleton, and the quaternary ammonium groups were uniformly introduced into the anion exchanger.
参考例7
(モノリスの製造)
ビニルモノマーの使用量、架橋剤の使用量、有機溶媒の種類と使用量、III工程で重合時に共存させるモノリス中間体の使用量を表1に示す配合量に変更した以外は、実施例1と同様の方法でモノリスを製造した。その結果を表1及び表2に示す。なお、不図示のSEM写真から骨格表面には粒子体や突起体の形成は全く認められなかった。表1及び表2から、本発明の特定の製造条件と逸脱する条件、すなわち、上記(1)〜(5)の要件から逸脱した条件下でモノリスを製造すると、モノリス骨格表面での粒子生成が認められないことがわかる。
Reference Example 7
(Manufacture of monoliths)
Except for changing the usage amount of the vinyl monomer, the usage amount of the crosslinking agent, the type and usage amount of the organic solvent, and the usage amount of the monolith intermediate coexisting during the polymerization in Step III to the blending amounts shown in Table 1, Example 1 and A monolith was produced in a similar manner. The results are shown in Tables 1 and 2. From the SEM photograph (not shown), the formation of particles and protrusions was not observed at all on the skeleton surface. From Table 1 and Table 2, when a monolith is produced under conditions deviating from the specific production conditions of the present invention, that is, conditions deviating from the requirements (1) to (5) above, particle formation on the surface of the monolith skeleton is caused. It turns out that it is not recognized.
(モノリスカチオン交換体の製造)
上記の方法で製造したモノリスを、参考例1と同様の方法でクロロ硫酸と反応させ、モノリスカチオン交換体を製造した。結果を表2に示す。得られたモノリスカチオン交換体のイオン交換帯長さは26mmであり、参考例1〜6と比較して大きな値であった。
(Production of monolith cation exchanger)
The monolith produced by the above method was reacted with chlorosulfuric acid in the same manner as in Reference Example 1 to produce a monolith cation exchanger. The results are shown in Table 2. The obtained monolith cation exchanger had an ion exchange zone length of 26 mm, which was a large value as compared with Reference Examples 1-6.
参考例8〜10
(モノリスの製造)
ビニルモノマーの使用量、架橋剤の使用量、有機溶媒の種類と使用量、III工程で重合時に共存させるモノリス中間体の多孔構造、架橋密度および使用量を表1に示す配合量に変更した以外は、参考例1と同様の方法でモノリスを製造した。その結果を表1及び表2に示す。なお、参考例8については架橋密度比(0.2倍)、参考例9については有機溶媒の種類(2-(2-メトキシエトキシ)エタノール;分子量120)、参考例10については重合温度(50℃;重合開始剤の10時間半減温度より1℃低い)について、本発明の製造条件を満たさない条件で製造した。結果を表2に示す。参考例8、10のモノリスについては骨格表面での粒子生成はなかった。また、参考例9では単離した生成物は透明であり、多孔構造が崩壊、消失していた。
Reference Examples 8-10
(Manufacture of monoliths)
The amount of vinyl monomer used, the amount of crosslinking agent used, the type and amount of organic solvent used, the porous structure of the monolith intermediate that coexists during polymerization in step III, the crosslinking density, and the amount used were changed to the amounts shown in Table 1. Produced a monolith in the same manner as in Reference Example 1. The results are shown in Tables 1 and 2. For Reference Example 8, the crosslinking density ratio (0.2 times), for Reference Example 9, the type of organic solvent (2- (2-methoxyethoxy) ethanol; molecular weight 120), and for Reference Example 10, the polymerization temperature (50 And 1 ° C. lower than the 10-hour half-life temperature of the polymerization initiator). The results are shown in Table 2. For the monoliths of Reference Examples 8 and 10, no particles were produced on the skeleton surface. In Reference Example 9, the isolated product was transparent, and the porous structure was collapsed and disappeared.
(モノリスカチオン交換体の製造)
参考例9を除き、上記の方法で製造した有機多孔質体を、参考例7と同様の方法でクロロ硫酸と反応させ、モノリスカチオン交換体を製造した。その結果を表2に示す。得られたモノリスカチオン交換体のイオン交換帯長さは23〜26mmであり、参考例1〜6と比較して大きな値であった。
(Production of monolith cation exchanger)
Except for Reference Example 9, the organic porous material produced by the above method was reacted with chlorosulfuric acid in the same manner as in Reference Example 7 to produce a monolith cation exchanger. The results are shown in Table 2. The obtained monolith cation exchanger had an ion exchange zone length of 23 to 26 mm, which was a large value as compared with Reference Examples 1 to 6.
参考例11
(モノリスの製造)
ビニルモノマーの使用量、架橋剤の使用量、有機溶媒の使用量、III工程で重合時に共存させるモノリス中間体の多孔構造および使用量を表1に示す配合量に変更した以外は、参考例7と同様の方法でモノリスを製造した。その結果を表1及び表2に示すが、本発明の特定の製造条件を逸脱してモノリスを製造すると、モノリス骨格表面での粒子生成が認められないことがわかる。
Reference Example 11
(Manufacture of monoliths)
Reference Example 7 except that the amount of vinyl monomer used, the amount of crosslinking agent used, the amount of organic solvent used, the porous structure of monolith intermediate coexisting during polymerization in step III and the amount used were changed to the amounts shown in Table 1. A monolith was produced in the same manner as described above. The results are shown in Tables 1 and 2, and it can be seen that when a monolith is produced outside the specific production conditions of the present invention, no particle formation is observed on the surface of the monolith skeleton.
(モノリスアニオン交換体の製造)
上記の方法で製造したモノリスを、直径70mm、厚み約15mmの円盤状に切断した。これにジメトキシメタン1400ml、四塩化スズ20mlを加え、氷冷下クロロ硫酸560mlを滴下した。滴下終了後、昇温して35℃で5時間反応させ、クロロメチル基を導入した。反応終了後、母液をサイフォンで抜き出し、THF/水=2/1の混合溶媒で洗浄した後、更にTHFで洗浄した。このクロロメチル化モノリスにTHF1000mlとトリメチルアミン30%水溶液600mlを加え、60℃、6時間反応させた。反応終了後、生成物をメタノール/水混合溶媒で洗浄し、次いで純水で洗浄して単離した。結果を表2に示が、得られたモノリスアニオン交換体のイオン交換帯長さは47mmであり、参考例1〜6と比較して大きな値であった。表1及び2中、メソポア直径及び細孔の値はそれぞれ平均値を示す。
(Production of monolith anion exchanger)
The monolith produced by the above method was cut into a disk shape having a diameter of 70 mm and a thickness of about 15 mm. To this, 1400 ml of dimethoxymethane and 20 ml of tin tetrachloride were added, and 560 ml of chlorosulfuric acid was added dropwise under ice cooling. After completion of dropping, the temperature was raised and the reaction was carried out at 35 ° C. for 5 hours to introduce a chloromethyl group. After completion of the reaction, the mother liquor was extracted with a siphon, washed with a mixed solvent of THF / water = 2/1, and further washed with THF. To this chloromethylated monolith, 1000 ml of THF and 600 ml of a 30% trimethylamine aqueous solution were added and reacted at 60 ° C. for 6 hours. After completion of the reaction, the product was washed with a methanol / water mixed solvent, then washed with pure water and isolated. The results are shown in Table 2. The obtained monolith anion exchanger had an ion exchange zone length of 47 mm, which was a large value compared with Reference Examples 1-6. In Tables 1 and 2, the mesopore diameter and pore value are average values.
参考例12
(モノリス有機多孔質陽イオン交換体(公知)の製造)
スチレン27.7g、ジビニルベンゼン6.9g、アゾビスイソブチロニトリル(ABIBN)0.14g及びソルビタンモノオレエート3.8gを混合し、均一に溶解させた。次に、当該スチレン/ジビニルベンゼン/アゾビスイソブチロニトリル/ソルビタンモノオレエート混合物を450mlの純水に添加し、ホモジナイザーを用いて2万回転/分で2分間攪拌し、油中水滴型エマルジョンを得た。乳化終了後、油中水滴型エマルジョンをステンレス製のオートクレーブに移し、窒素で十分置換した後密封し、静置下60℃で24時間重合させた。重合終了後、内容物を取り出し、イソプロパノールで18時間ソックスレー抽出し、未反応モノマーとソルビタンモノオレエートを除去した後、40℃で一昼夜減圧乾燥した。このようにして得られたスチレン/ジビニルベンゼン共重合体よりなる架橋成分を14モル%含有した有機多孔質体11.5gを分取し、ジクロロエタン800mlを加え、60℃で30分加熱した後、室温まで冷却し、クロロ硫酸59.1gを徐々に加え、室温で24時間反応させた。その後、酢酸を加え、多量の水中に反応物を投入し、水洗、乾燥して多孔質カチオン交換体を得た。この多孔質体のイオン交換容量は、乾燥多孔質体換算で4.4mg当量/g、湿潤体積換算で、0.32mg当量/mlであり、EPMAを用いた硫黄原子のマッピングにより、スルホン酸基が多孔質体に均一に導入されていることを確認した。また、SEM観察の結果、この有機多孔質体の内部構造は連続気泡構造を有しており、平均径30μmのマクロポアの大部分が重なり合い、マクロポアとマクロポアの重なりで形成されるメソポアの孔径は5μmであり、全細孔容積は、10.1ml/g、BET比表面積は10m2/gであった。
Reference Example 12
(Production of monolithic organic porous cation exchanger (known))
27.7 g of styrene, 6.9 g of divinylbenzene, 0.14 g of azobisisobutyronitrile (ABIBN) and 3.8 g of sorbitan monooleate were mixed and dissolved uniformly. Next, the styrene / divinylbenzene / azobisisobutyronitrile / sorbitan monooleate mixture is added to 450 ml of pure water, and stirred for 2 minutes at 20,000 rpm with a homogenizer, and a water-in-oil emulsion. Got. After emulsification, the water-in-oil emulsion was transferred to a stainless steel autoclave, sufficiently substituted with nitrogen, sealed, and allowed to polymerize at 60 ° C. for 24 hours. After completion of the polymerization, the content was taken out, extracted with Soxhlet for 18 hours with isopropanol, unreacted monomer and sorbitan monooleate were removed, and dried under reduced pressure at 40 ° C. overnight. After separating 11.5 g of an organic porous material containing 14 mol% of a crosslinking component composed of the styrene / divinylbenzene copolymer thus obtained, 800 ml of dichloroethane was added, and the mixture was heated at 60 ° C. for 30 minutes. After cooling to room temperature, 59.1 g of chlorosulfuric acid was gradually added and reacted at room temperature for 24 hours. Thereafter, acetic acid was added, the reaction product was poured into a large amount of water, washed with water and dried to obtain a porous cation exchanger. The porous body has an ion exchange capacity of 4.4 mg equivalent / g in terms of dry porous body and 0.32 mg equivalent / ml in terms of wet volume. By mapping sulfur atoms using EPMA, sulfonic acid groups It was confirmed that was uniformly introduced into the porous body. Further, as a result of SEM observation, the internal structure of this organic porous body has an open cell structure, most of the macropores having an average diameter of 30 μm overlap, and the pore diameter of the mesopore formed by the overlap of the macropores and the macropores is 5 μm. The total pore volume was 10.1 ml / g, and the BET specific surface area was 10 m 2 / g.
複合モノリスイオン交換体を充填した内径57mmのカラムに対して原水を、上方から下方へ下向流となるように通水し、処理水中のナトリウム濃度が1μg/lを上回る時間を測定した。また、通水中の通水差圧も測定した。この通水実験の条件は下記の通りである。その結果、処理水中のナトリウム濃度が1μg/lを上回る時間は190日であった。また、通水差圧は37kPaであった。 Raw water was passed through a column having an inner diameter of 57 mm packed with the composite monolith ion exchanger so as to flow downward from above to measure the time during which the sodium concentration in the treated water exceeded 1 μg / l. Moreover, the water flow differential pressure during water flow was also measured. The conditions of this water flow experiment are as follows. As a result, the time when the sodium concentration in the treated water exceeded 1 μg / l was 190 days. The water flow differential pressure was 37 kPa.
(通水条件)
・ イオン交換体;上流側が粒状のカチオン交換樹脂とアニオン交換樹脂の混合樹脂(混合比率=1:1(充填体積比)、樹脂層高;300mm)と下流側がモノリス(直径57mm、高さ40mm)の積層体
・ カチオン交換樹脂;IR120B(商品名)
・ アニオン交換樹脂;IRA402BL(商品名)
・ 原水;NaCl水溶液、ナトリウム濃度80μg/l
・ 流量;120l/h
・ モノリス;参考例2のカチオンモノリス
(Water flow conditions)
・ Ion exchanger: Mixed resin of granular cation exchange resin and anion exchange resin on the upstream side (mixing ratio = 1: 1 (fill volume ratio), resin layer height: 300 mm) and monolith on the downstream side (diameter 57 mm, height 40 mm) Laminate of cation exchange resin; IR120B (trade name)
・ Anion exchange resin; IRA402BL (trade name)
Raw water: NaCl aqueous solution, sodium concentration 80 μg / l
・ Flow rate: 120 l / h
Monolith; cationic monolith of Reference Example 2
カチオン交換樹脂は、一度塩化ナトリウムでNa型にした後、1N塩酸で再生率99%で再生後、超純水で十分に洗浄して再生形とし使用した。なお、再生率とは樹脂に吸着できる交換容量の内、H型の容量の割合を言う。 The cation exchange resin was once made into Na type with sodium chloride, regenerated with 99% regeneration rate with 1N hydrochloric acid, washed thoroughly with ultrapure water and used in a regenerated form. The regeneration rate is the ratio of the H-type capacity among the exchange capacity that can be adsorbed to the resin.
比較例1
参考例2のカチオンモノリスに代えて、参考例12のカチオンモノリスを使用した以外は、実施例1と同様の方法で行った。その結果、処理水中のナトリウム濃度が1μg/lを上回る時間は21日であった。また、通水差圧は230kPaであった。
Comparative Example 1
The same procedure as in Example 1 was performed except that the cation monolith of Reference Example 12 was used instead of the cation monolith of Reference Example 2. As a result, the time during which the sodium concentration in the treated water exceeded 1 μg / l was 21 days. Moreover, the water flow differential pressure was 230 kPa.
比較例2
イオン交換体として、粒状のカチオン交換樹脂とアニオン交換樹脂の混合樹脂(樹脂層高;340mm)としたこと以外は、実施例1と同様の方法で行った。すなわち、比較例1はイオン交換体として、モノリスを使用せず、粒状のイオン交換樹脂100%としたものである。その結果、処理水中のナトリウム濃度が1μg/lを上回る時間は0日、すなわち、通水の初日から処理水中のナトリウム濃度が1μg/lを上回った。また、通水差圧は230kPaであった。
Comparative Example 2
The same procedure as in Example 1 was performed except that the ion exchanger was a mixed resin of a granular cation exchange resin and an anion exchange resin (resin layer height: 340 mm). That is, in Comparative Example 1, a monolith is not used as the ion exchanger, and the granular ion exchange resin is 100%. As a result, the time when the sodium concentration in the treated water exceeded 1 μg / l was 0 day, that is, the sodium concentration in the treated water exceeded 1 μg / l from the first day of water flow. Moreover, the water flow differential pressure was 230 kPa.
実施例1は比較例1及び2に比べて、吸着したイオンのリークが遅い。このため、イオン交換モジュールの交換頻度を減らすことができる。また、通水差圧が低いため、低圧での送水が可能である。 In Example 1, the leakage of adsorbed ions is slower than in Comparative Examples 1 and 2. For this reason, the exchange frequency of an ion exchange module can be reduced. Moreover, since the water flow differential pressure is low, water can be fed at a low pressure.
Claims (9)
該モノリス状有機多孔質イオン交換体が、連続骨格相と連続空孔相からなる有機多孔質体と、該有機多孔質体の骨格表面に固着する直径4〜40μmの多数の粒子体又は該有機多孔質体の骨格表面上に形成される大きさが4〜40μmの多数の突起体との複合構造体であって、水湿潤状態で孔の平均直径10〜150μm、全細孔容積0.5〜5ml/gであり、水湿潤状態での体積当りのイオン交換容量0.2mg当量/ml以上であることを特徴とするイオン吸着モジュール。 An ion adsorption module comprising at least a container having an opening through which water to be treated flows, and a monolithic organic porous ion exchanger filled in the container,
The monolithic organic porous ion exchanger includes an organic porous body composed of a continuous skeleton phase and a continuous pore phase, and a large number of particles having a diameter of 4 to 40 μm fixed to the skeleton surface of the organic porous body or the organic A composite structure with a large number of protrusions having a size of 4 to 40 μm formed on the skeleton surface of the porous body, and having an average pore diameter of 10 to 150 μm and a total pore volume of 0.5 in a wet state An ion adsorption module, which is ˜5 ml / g and has an ion exchange capacity of 0.2 mg equivalent / ml or more per volume in a wet state of water.
少なくとも被処理水が流入する開口を備える容器と、該容器に充填される連続骨格相と連続空孔相からなる有機多孔質体と、該有機多孔質体の骨格表面に固着する直径4〜40μmの多数の粒子体又は該有機多孔質体の骨格表面上に形成される大きさが4〜40μmの多数の突起体との複合構造体であって、水湿潤状態で孔の平均直径10〜150μm、全細孔容積0.5〜5ml/gであり、水湿潤状態での体積当りのイオン交換容量0.2mg当量/ml以上であるモノリス状有機多孔質イオン交換体とを備えるイオン吸着モジュールと、
を備え、被処理水が、初めに該粒状のイオン交換樹脂に、次に該モノリス状有機多孔質イオン交換体に、流入されるように配置されることを特徴とするイオン吸着モジュール。 An ion adsorption module filled with granular ion exchange resin;
A container having at least an opening through which water to be treated flows, an organic porous body composed of a continuous skeleton phase and a continuous pore phase filled in the container, and a diameter of 4 to 40 μm fixed to the skeleton surface of the organic porous body A composite structure of a large number of particles or a large number of protrusions having a size of 4 to 40 μm formed on the skeleton surface of the organic porous body, and having an average pore diameter of 10 to 150 μm in a wet state An ion adsorption module comprising a monolithic organic porous ion exchanger having a total pore volume of 0.5 to 5 ml / g and an ion exchange capacity of 0.2 mg equivalent / ml or more per volume in a water-wet state; ,
The equipped, water to be treated, the granular ion exchange resin initially, then to the monolith organic porous ion exchanger, features and be Louis on adsorption module that is arranged to be flowed.
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