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JP2017127875A - Ultrapure water system and ultrapure water production method - Google Patents

Ultrapure water system and ultrapure water production method Download PDF

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JP2017127875A
JP2017127875A JP2017089753A JP2017089753A JP2017127875A JP 2017127875 A JP2017127875 A JP 2017127875A JP 2017089753 A JP2017089753 A JP 2017089753A JP 2017089753 A JP2017089753 A JP 2017089753A JP 2017127875 A JP2017127875 A JP 2017127875A
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ultrapure water
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育野 望
Nozomi Ikuno
望 育野
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Kurita Water Industries Ltd
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Abstract

PROBLEM TO BE SOLVED: To provide an ultrapure water system capable producing, by reducing footprint and inexpensively, high-purity ultrapure water satisfying sufficiently a demand water quality; and to provide an ultrapure water production method.SOLUTION: In an ultrapure water system including a pretreatment system, a primary pure water system and a sub-system, the primary pure water system includes a high pressure type reverse osmosis membrane separation device, a deaeration unit, an ultraviolet oxidation device and an ion exchanger in this order.SELECTED DRAWING: None

Description

本発明は、超純水製造装置及び超純水製造方法に関する。   The present invention relates to an ultrapure water production apparatus and an ultrapure water production method.

電子デバイス、特には半導体の製造工程にて洗浄水として多量に用いられる超純水は、前処理システム、一次純水システム、及びサブシステムから構成される超純水製造システムにて原水(工業用水、水道水、井水、電子デバイス製造工程から排出される使用済みの超純水等)を処理することにより製造される。   Ultrapure water used in large quantities as cleaning water in the manufacturing process of electronic devices, especially semiconductors, is used as raw water (industrial water) in an ultrapure water production system consisting of a pretreatment system, primary pure water system, and subsystems. , Tap water, well water, and used ultrapure water discharged from the electronic device manufacturing process).

例えば、特許文献1では、一次純水システムと、該一次純水システムの処理水を処理するサブシステムとを備え、少なくとも該一次純水システムに逆浸透膜分離装置が設けられている超純水製造装置において、該一次純水システムに設置された逆浸透膜分離装置が高圧型逆浸透膜分離装置であり、且つ単段にて設置されていることを特徴とする超純水製造装置が提案されている。特許文献2では、前処理システムと、該前処理システムによって処理された前処理水を処理して一次純水とする一次純水システムと、一次純水を処理するサブシステムとを有する超純水製造装置において、該一次純水システムが、逆浸透膜分離装置、脱ガス装置、電気脱イオン装置、紫外線酸化装置、及び非再生型イオン交換装置の順で接続された構成とされていることを特徴とする超純水製造装置が提案されている。   For example, in Patent Document 1, ultrapure water that includes a primary pure water system and a subsystem that processes treated water of the primary pure water system, and at least a reverse osmosis membrane separation device is provided in the primary pure water system. In the manufacturing apparatus, a reverse osmosis membrane separation device installed in the primary pure water system is a high-pressure type reverse osmosis membrane separation device, and an ultrapure water production device is proposed which is installed in a single stage. Has been. In patent document 2, the ultrapure water which has a pretreatment system, the primary pure water system which processes the pretreatment water processed by this pretreatment system into primary pure water, and the subsystem which processes primary pure water In the production apparatus, the primary pure water system is configured such that a reverse osmosis membrane separation device, a degassing device, an electrodeionization device, an ultraviolet oxidation device, and a non-regenerative ion exchange device are connected in this order. A characteristic ultrapure water production apparatus has been proposed.

また、特許文献3では、一次純水システムと二次純水システムからなる超純水製造装置において、前記一次純水システムは、2床3塔型イオン交換装置と逆浸透膜装置と180〜190nmの波長を含む紫外線を照射する低圧紫外線ランプを備えた紫外線照射装置と混床式イオン交換装置の組合せを流路に沿って設けてなり、前記二次純水システムは、180〜190nmの波長を含む紫外線を照射する低圧紫外線ランプを備えた紫外線照射装置と混床式イオン交換装置の組み合わせを流路に沿って少なくとも1組設けてなることを特徴とする超純水製造装置が提案されている。   Moreover, in patent document 3, in the ultrapure water manufacturing apparatus which consists of a primary pure water system and a secondary pure water system, the said primary pure water system is a 2 bed 3 tower type ion exchange apparatus, a reverse osmosis membrane apparatus, and 180-190 nm. A combination of an ultraviolet irradiation device equipped with a low-pressure ultraviolet lamp that irradiates ultraviolet rays including the wavelength of the above and a mixed bed type ion exchange device is provided along the flow path, and the secondary pure water system has a wavelength of 180 to 190 nm. There has been proposed an ultrapure water production apparatus characterized in that at least one combination of an ultraviolet irradiation apparatus equipped with a low-pressure ultraviolet lamp for irradiating containing ultraviolet light and a mixed bed type ion exchange apparatus is provided along a flow path. .

さらに、特許文献4では、前処理システム、一次純水システムと二次純水システムからなる超純水製造装置において、前記一次純水システムと二次純水システムに、それぞれ、180〜190nmの波長を含む紫外線を照射する低圧紫外線ランプを備えた紫外線照射装置と混床式イオン交換装置の組み合わせを流路に沿って、少なくとも1組設けたことを特徴とする超純水製造装置が提案されている。   Furthermore, in patent document 4, in the ultrapure water manufacturing apparatus which consists of a pre-processing system, a primary pure water system, and a secondary pure water system, each of the said primary pure water system and a secondary pure water system has a wavelength of 180-190 nm. An ultrapure water production apparatus is proposed in which at least one set of a combination of an ultraviolet irradiation apparatus equipped with a low-pressure ultraviolet lamp that irradiates ultraviolet rays and a mixed bed ion exchange apparatus is provided along a flow path. Yes.

特開2012−245439号JP 2012-245439 A 特開2003−266097号JP 2003-266097 A 特開2004−25184号JP 2004-25184 A 特開平7−75780号JP-A-7-75780

しかしながら、近年、半導体等の電子デバイスの高集積化、回路パターンの微細化に伴い、洗浄水として用いられる超純水の水質に対する水質向上の要求が更に高まっているのが現状である。超純水製造装置又は超純水製造システムにおいて、ユースポイントにおける到達水質及び水質安定性を決定づけるのは一次純水システムである。逆浸透膜分離装置、脱気装置及びイオン交換装置のそれぞれが単段に設置されるのが一次純水システムの一般的な態様である。ところが、この水質向上の要求が高まる中で、上記の一次純水システムの一般的な態様では水質向上の要求に応えられない問題がある。このため、近年の最先端の半導体工場等において、下記の(A)〜(C)の一次純水システムのように逆浸透膜分離装置及び/又はイオン交換装置(塔)を複数段に設置し、超純水の高純度化を図っている。   However, in recent years, with the high integration of electronic devices such as semiconductors and the miniaturization of circuit patterns, there is an increasing demand for improving the quality of ultrapure water used as cleaning water. In the ultrapure water production apparatus or the ultrapure water production system, it is the primary pure water system that determines the ultimate water quality and the water quality stability at the point of use. It is a general aspect of the primary pure water system that each of the reverse osmosis membrane separation device, the deaeration device, and the ion exchange device is installed in a single stage. However, while the demand for improving the water quality is increasing, there is a problem that the general aspect of the primary pure water system cannot meet the demand for improving the water quality. For this reason, reverse osmosis membrane separation devices and / or ion exchange devices (towers) are installed in a plurality of stages as in the following primary pure water systems in the latest semiconductor factories and the like. In order to improve the purity of ultrapure water.

(A)複数の逆浸透膜(RO膜)分離装置からなる多段ROシステム
・逆浸透膜(RO膜)分離装置⇒混床式イオン交換装置(塔)(MB)⇒紫外線殺菌装置(UVst)⇒逆浸透膜(RO膜)分離装置⇒紫外線酸化装置(UVox)⇒非再生型イオン交換装置(塔)⇒脱気装置(MDG)、
構成ユニット数は7である。
(B)カチオン及びアニオン交換塔を複数段組み合わせた多段イオン交換システム
・陽イオン交換樹脂(H1)装置(塔)⇒脱炭酸塔 ⇒陰イオン交換樹脂(OH1)装置(塔)⇒陽イオン交換樹脂(H2)装置(塔)⇒陰イオン交換樹脂(OH2)装置(塔)⇒紫外線殺菌装置(UVst)⇒逆浸透膜(RO膜)分離装置⇒脱気装置(MDG)⇒紫外線酸化装置(UVox)⇒非再生型イオン交換装置(塔)、
構成ユニット数は10である。
・陽イオン交換樹脂(H1)装置(塔)⇒脱炭酸塔⇒陰イオン交換樹脂(OH1)装置(塔)⇒紫外線殺菌装置(UVst)⇒逆浸透膜(RO膜)分離装置⇒紫外線酸化装置(UVox)⇒混床式イオン交換装置(塔)(MB)⇒非再生型イオン交換装置(塔)、
構成ユニット数は8である。
(C)複数の電気再生型イオン交換装置からなる多段電気再生式イオン交換純水装置(CDI)システム
・逆浸透膜(RO膜)分離装置⇒逆浸透膜(RO膜)分離装置⇒脱気装置(MDG)⇒紫外線酸化装置(UVox)⇒多段電気再生式イオン交換純水装置(CDI)⇒多段電気再生式イオン交換純水装置(CDI)、
構成ユニット数は6である。
上記の(A)〜(C)の一次純水システムに用いられている逆浸透膜(RO膜)分離装置において、超低圧型逆浸透膜(RO膜)分離装置(標準運転圧:0.75MPa)が使用されるのが一般的である。
(A) Multi-stage RO system / reverse osmosis membrane (RO membrane) separation device consisting of multiple reverse osmosis membrane (RO membrane) separation devices ⇒ Mixed-bed ion exchange device (tower) (MB) ⇒ UV sterilization device (UVst) ⇒ Reverse osmosis membrane (RO membrane) separation device ⇒ UV oxidation device (UVox) ⇒ Non-regenerative ion exchange device (tower) ⇒ Degassing device (MDG),
The number of constituent units is seven.
(B) Multistage ion exchange system combining multiple stages of cation and anion exchange towers ・ Cation exchange resin (H1) equipment (tower) ⇒ Decarboxylation tower ⇒ Anion exchange resin (OH1) equipment (tower) ⇒ Cation exchange resin (H2) device (tower) ⇒ anion exchange resin (OH2) device (tower) ⇒ UV sterilizer (UVst) ⇒ reverse osmosis membrane (RO membrane) separator ⇒ deaerator (MDG) ⇒ UV oxidizer (UVox) ⇒Non-regenerative ion exchanger (tower),
The number of constituent units is ten.
・ Cation exchange resin (H1) device (tower) ⇒ Decarbonation tower ⇒ Anion exchange resin (OH1) device (tower) ⇒ UV sterilizer (UVst) ⇒ Reverse osmosis membrane (RO membrane) separator ⇒ UV oxidation device ( UVox) ⇒ Mixed-bed ion exchanger (tower) (MB) ⇒ Non-regenerative ion exchanger (tower),
The number of constituent units is eight.
(C) Multi-stage electric regenerative ion exchange deionized water device (CDI) system, reverse osmosis membrane (RO membrane) separator ⇒ reverse osmosis membrane (RO membrane) separator ⇒ deaerator (MDG) ⇒ Ultraviolet oxidizer (UVox) ⇒ Multistage electric regeneration type ion exchange pure water device (CDI) ⇒ Multistage electric regeneration type ion exchange pure water device (CDI),
The number of constituent units is six.
In the reverse osmosis membrane (RO membrane) separator used in the primary pure water system of the above (A) to (C), an ultra-low pressure type reverse osmosis membrane (RO membrane) separator (standard operating pressure: 0.75 MPa) ) Is generally used.

ここで、本明細書における、ユニットとは、一次純水システムでの除去の主目的である脱塩、脱気、有機物除去の何れか或いは複数の処理が可能な装置を意味し、構成ユニット数とは、システム、例えば一次純水システムに備えられるユニットの数を意味する。   Here, the unit in this specification means an apparatus capable of any one or more of desalting, degassing, and organic substance removal, which is the main purpose of removal in the primary pure water system, and the number of constituent units. By means the number of units provided in a system, for example a primary pure water system.

例えば、原水(工業用水、水道水、井水、電子デバイス製造工程から排出される使用済みの超純水等)を前処理システムによって処理した被処理水は、上記の(A)〜(C)の一次純水システムで処理することで、被処理水の水質(一次純水システムの出口における水質)を、比抵抗18MΩcm以上、TOC濃度2μg/L以下、ホウ素(B)濃度1ng/L以下、シリカ(SiO)濃度0.1μg/L以下の高純度な水質にすることが可能となる。 For example, treated water obtained by treating raw water (industrial water, tap water, well water, used ultrapure water discharged from an electronic device manufacturing process, etc.) with a pretreatment system is the above (A) to (C). By treating with the primary pure water system, the water quality of the treated water (water quality at the outlet of the primary pure water system) has a specific resistance of 18 MΩcm or more, a TOC concentration of 2 μg / L or less, a boron (B) concentration of 1 ng / L or less, It becomes possible to obtain a high-purity water quality having a silica (SiO 2 ) concentration of 0.1 μg / L or less.

しかしながら、上記の(A)〜(C)の一次純水システムの構成ユニット数(6〜10)が多いため、フットプリントが大きく、かつ、設備コスト(イニシャルコスト)及び運営コスト(ランニングコスト)が高くなるといった問題がある。   However, since the number of constituent units (6 to 10) of the primary pure water system (A) to (C) is large, the footprint is large, and the equipment cost (initial cost) and the operation cost (running cost) are high. There is a problem of becoming higher.

また、超純水の水質の要求レベルは、今後益々高まり、一次純水システムのユニット数は更に増加する傾向にある。   In addition, the required level of quality of ultrapure water will increase further in the future, and the number of units of primary pure water system tends to increase further.

本発明は、上記事情に鑑みてなされたものであり、要求水質を充分に満足した高純度の超純水を、フットプリントを軽減させて、かつ、安価に製造することができる超純水製造装置及び超純水製造方法を提供することを主目的とする。   The present invention has been made in view of the above circumstances, and is capable of producing high purity ultrapure water sufficiently satisfying the required water quality with reduced footprint and at low cost. The main object is to provide an apparatus and a method for producing ultrapure water.

本発明者らは、超純水装置に備えられる一次純水システムに、適切な装置を、適切な順番に設置することによって、構成ユニット数を低減し、要求水質を充分に満足した高純度の超純水を安価に製造することができることを見出し、本発明を完成するに至った。   The present inventors have reduced the number of structural units by installing appropriate devices in an appropriate order in the primary pure water system provided in the ultrapure water device, and have high purity that sufficiently satisfies the required water quality. The inventors have found that ultrapure water can be produced at low cost, and have completed the present invention.

すなわち、本発明は、高圧型逆浸透膜分離装置と、脱気装置と、紫外線酸化装置と、再生型イオン交換装置とをこの順で備える、4ユニット構成の一次純水システムを備える超純水製造装置を提供する。また、本発明は、その一次純水システムによる処理方法が、高圧型逆浸透膜分離装置に該被処理水を通水する工程と、該通水された被処理水中のガスを脱気する工程と、該脱気された被処理水中の有機物を紫外線酸化装置によって分解する工程と、該有機物が分解された被処理水を、イオン交換装置によって処理する工程とを含む、超純水製造方法を提供する。   That is, the present invention provides ultrapure water comprising a four-unit primary pure water system comprising a high-pressure reverse osmosis membrane separation device, a deaeration device, an ultraviolet oxidation device, and a regenerative ion exchange device in this order. Providing manufacturing equipment. Further, according to the present invention, a treatment method using the primary pure water system includes a step of passing the water to be treated through a high-pressure reverse osmosis membrane separation device, and a step of degassing the gas in the water to be treated. And a method of decomposing the organic matter in the degassed water to be treated with an ultraviolet oxidation device, and a step of treating the water to be treated with the organic matter decomposed with an ion exchange device. provide.

具体的には、本発明は、前処理システムと、一次純水システムと、サブシステムとを備え、
一次純水システムが、高圧型逆浸透膜分離装置と、脱気装置と、紫外線酸化装置と、イオン交換装置とをこの順で備える、超純水製造装置を提供する。
高圧型逆浸透膜分離装置とは、膜面有効圧力2.0MPa、25℃の条件において、0.6〜1.3m/m/dayの純水透過流束を有する逆浸透膜装置であることが好ましい。
イオン交換装置が以下のア)〜エ)のいずれか1つの再生型イオン交換装置であることが好ましい。
ア)強酸性カチオン交換樹脂が充填されたカチオン交換塔と、強塩基性アニオン交換樹脂が充填されたアニオン交換塔とを直列に接続した2床2塔式再生型イオン交換装置。
イ)強酸性カチオン交換樹脂と強塩基性アニオン交換樹脂とが別々の異なる層となるように1つの塔内に該強酸性カチオン交換樹脂と該強塩基性アニオン交換樹脂とを充填した2床1塔式再生型イオン交換装置。
ウ)強酸性カチオン交換樹脂と強塩基性アニオン交換樹脂とを均一に混合して1つの塔内に充填した混床型再生式イオン交換装置。
エ)電気再生式脱イオン装置を1段又は複数段直列に接続した再生型イオン交換装置。
Specifically, the present invention includes a pretreatment system, a primary pure water system, and a subsystem.
Provided is an ultrapure water production apparatus in which a primary pure water system comprises a high-pressure reverse osmosis membrane separation device, a deaeration device, an ultraviolet oxidation device, and an ion exchange device in this order.
The high-pressure type reverse osmosis membrane separation device is a reverse osmosis membrane device having a pure water permeation flux of 0.6 to 1.3 m 3 / m 2 / day under the conditions of a membrane surface effective pressure of 2.0 MPa and 25 ° C. Preferably there is.
It is preferable that the ion exchange device is any one of the following regenerative ion exchange devices a) to d).
A) A two-bed two-column regenerative ion exchange apparatus in which a cation exchange column filled with a strongly acidic cation exchange resin and an anion exchange column filled with a strongly basic anion exchange resin are connected in series.
A) Two beds 1 in which the strongly acidic cation exchange resin and the strongly basic anion exchange resin are packed in one column so that the strongly acidic cation exchange resin and the strongly basic anion exchange resin are in different layers. Tower-type regenerative ion exchanger.
C) A mixed bed regenerative ion exchange apparatus in which a strongly acidic cation exchange resin and a strongly basic anion exchange resin are uniformly mixed and packed in one tower.
D) A regenerative ion exchange apparatus in which one or more electric regenerative deionization apparatuses are connected in series.

また、本発明は、原水を前処理システムによって処理した被処理水を一次純水システム及びサブシステムの順によって処理し、一次純水システムによる処理方法が、高圧型逆浸透膜分離装置に被処理水を通水する工程と、通水された被処理水中のガスを脱気する工程と、脱気された被処理水中の有機物を紫外線酸化装置によって分解する工程と、有機物が分解された被処理水を、イオン交換装置によって処理する工程とを含む、超純水製造方法を提供する。   The present invention also treats treated water obtained by treating raw water with a pretreatment system in the order of a primary pure water system and a subsystem, and a treatment method using the primary pure water system is applied to a high-pressure reverse osmosis membrane separation device. A step of passing water, a step of degassing the gas in the water to be treated, a step of decomposing organic matter in the degassed water to be treated by an ultraviolet oxidation device, and a treatment in which the organic matter is decomposed A method for producing ultrapure water comprising a step of treating water with an ion exchange device.

本発明によれば、要求水質を充分に満足した高純度の超純水を、フットプリントを軽減させて、かつ、安価に製造することができる超純水製造装置及び超純水製造方法が提供される。   ADVANTAGE OF THE INVENTION According to this invention, the ultrapure water manufacturing apparatus and the ultrapure water manufacturing method which can reduce the footprint and can manufacture the ultrapure water of the high purity which fully satisfy | filled the required water quality at low cost are provided. Is done.

図1は、一次純水システムによって処理された実施例1及び比較例3〜4の被処理水のTOC値の経時変化を示す図である。FIG. 1 is a diagram showing the change over time in the TOC value of the water to be treated of Example 1 and Comparative Examples 3 to 4 treated by the primary pure water system.

以下、本発明を実施するための形態について説明する。なお、以下に説明する実施形態は、本発明の代表的な実施形態の一例を示したものであり、これにより本発明の範囲が限定されて解釈されることはない。   Hereinafter, modes for carrying out the present invention will be described. In addition, embodiment described below shows an example of typical embodiment of this invention, and, thereby, the range of this invention is limited and is not interpreted.

1.超純水製造装置
本発明に係る実施形態の超純水製造装置は、前処理システムと、一次純水システムと、サブシステムとを備え、一次純水システムが、高圧型逆浸透膜分離装置と、脱気装置と、紫外線酸化装置と、イオン交換装置とをこの順で備える、超純水製造装置である。本実施形態の超純水製造装置によれば、要求水質を充分に満足した高純度の超純水を、フットプリントを軽減させて製造することができ、さらに設備コスト(イニシャルコスト)及び運営コスト(ランニングコスト)を抑えながら安価に製造することができる。
1. Ultrapure water production apparatus An ultrapure water production apparatus according to an embodiment of the present invention includes a pretreatment system, a primary pure water system, and a subsystem, and the primary pure water system includes a high-pressure reverse osmosis membrane separation device, The ultrapure water production apparatus includes a deaeration device, an ultraviolet oxidation device, and an ion exchange device in this order. According to the ultrapure water production apparatus of the present embodiment, high purity ultrapure water that sufficiently satisfies the required water quality can be produced with a reduced footprint, and the equipment cost (initial cost) and the operation cost It can be manufactured at low cost while suppressing (running cost).

<一次純水システム>
本発明に係る実施形態の超純水製造装置に備えられる一次純水システムは、高圧型逆浸透膜分離装置と、脱気装置と、紫外線酸化装置と、イオン交換装置とをこの順で備える、僅か4ユニット構成のシステムである。一次純水システムは、原水(工業用水、水道水、井水、電子デバイス製造工程から排出される使用済みの超純水等)を前処理システムによって処理した被処理水中のイオンや有機成分の除去を行う。そして、一次純水システムが僅か4ユニット構成であるにもかかわらず、本発明に係る実施形態の超純水製造装置によって製造された超純水の水質は、例えば、上記で述べた(A)〜(C)の一次純水システムのように逆浸透膜分離装置及び/又はイオン交換装置(塔)を複数段に設置した一次純水システムを備える超純水製造装置によって製造された超純水の水質に対して同等以上の水質を示す。したがって、本発明に係る実施形態の超純水製造装置によって製造された超純水は、要求水質を充分に満足した高純度の超純水である。
<Primary pure water system>
The primary pure water system provided in the ultrapure water production apparatus according to the embodiment of the present invention includes a high-pressure reverse osmosis membrane separation device, a degassing device, an ultraviolet oxidation device, and an ion exchange device in this order. It is a system with only 4 units. The primary pure water system removes ions and organic components from treated water that has been treated with raw water (industrial water, tap water, well water, used ultrapure water discharged from electronic device manufacturing processes, etc.) by the pretreatment system. I do. The quality of ultrapure water produced by the ultrapure water production apparatus according to the embodiment of the present invention is described above, for example, although the primary pure water system has only 4 units (A). Ultra pure water produced by an ultra pure water production apparatus comprising a primary pure water system in which reverse osmosis membrane separation devices and / or ion exchange devices (towers) are installed in a plurality of stages as in the primary pure water system of (C) The water quality is equivalent to or better than the water quality. Therefore, the ultrapure water produced by the ultrapure water production apparatus according to the embodiment of the present invention is high purity ultrapure water that sufficiently satisfies the required water quality.

本発明に係る実施形態の超純水製造装置によって製造された超純水が、要求水質を充分に満足するかどうかは、原水(工業用水、水道水、井水、電子デバイス製造工程から排出される使用済みの超純水等)を前処理システムによって処理した被処理水が、本発明に係る実施形態の超純水製造装置に備えられる一次純水システムによって処理することで、被処理水の水質(一次純水システムの出口における水質)が、比抵抗値18MΩcm以上、TOC(TotalOrganicCarbon)濃度2μg/L以下、ホウ素(B)濃度1ng/L以下、シリカ(SiO)濃度0.1μg/L以下を示すかどうかで判断することができる。したがって、本発明に係る実施形態の超純水製造装置に備えられる一次純水システムによって処理された被処理水の水質が上記のような値を示せば、最終的には後述するサブシステムによって処理された超純水は、要求水質を充分に満足した高純度の超純水となる。 Whether or not the ultrapure water produced by the ultrapure water production apparatus of the embodiment according to the present invention sufficiently satisfies the required water quality is determined from raw water (industrial water, tap water, well water, electronic device production process). The treated water treated by the pretreatment system is treated by the primary pure water system provided in the ultrapure water production apparatus according to the embodiment of the present invention, so that the treated water is treated. The water quality (water quality at the outlet of the primary pure water system) has a specific resistance value of 18 MΩcm or more, a TOC (Total Organic Carbon) concentration of 2 μg / L or less, a boron (B) concentration of 1 ng / L or less, and a silica (SiO 2 ) concentration of 0.1 μg / L. Judgment can be made based on the following. Therefore, if the quality of the water to be treated treated by the primary pure water system provided in the ultrapure water production apparatus according to the embodiment of the present invention shows the above values, it is finally treated by the subsystem described later. The ultrapure water thus obtained becomes high purity ultrapure water that sufficiently satisfies the required water quality.

本発明に係る実施形態における高圧型逆浸透膜分離装置は、塩類を除去すると共に有機物等も除去する。高圧型逆浸透膜分離装置は、従来、海水淡水化に用いられている逆浸透膜の分離装置であり、従来の超純水製造装置に備えられている一次純水システムに用いられている低圧型又は超低圧型逆浸透膜に比べて膜表面のスキン層が緻密になっている。そのため、高圧型逆浸透膜は低圧型又は超低圧型逆浸透膜に比べて単位操作圧力当たりの膜透過水量は低いもののホウ素、シリカ及び非荷電性有機物などの弱電解質成分や非荷電性成分の除去率が高い。高圧型逆浸透膜分離装置は、上述のとおり、単位操作圧力当たりの膜透過水量が低く、膜面有効圧力2.0MPa、25℃条件下において0.6〜1.3m/m/dayの純水透過流束を有し、99.5%以上のNaCl除去率を有してよいが、本発明の目的を達成し、効果を奏すれば、透過流束及びNaCl除去率の値は限定されない。ここで、膜面有効圧力は平均操作圧力から浸透圧差と二次側圧力とを差し引いた膜に働く有効な圧力で、NaCl除去率はNaCl濃度32000mg/LのNaCl水溶液に対する25℃、膜面有効圧力2.7MPaでの除去率である。高圧型逆浸透膜の形状は、本発明の目的を達成し、効果を奏すれば、任意の形状でよいが、例えば、スパイラル型形状、中空糸型形状、平膜型形状等が挙げられる。 The high-pressure reverse osmosis membrane separation apparatus according to the embodiment of the present invention removes salts and organic substances. The high-pressure type reverse osmosis membrane separation device is a reverse osmosis membrane separation device conventionally used for seawater desalination, and a low pressure used in a primary pure water system provided in a conventional ultrapure water production device. The skin layer on the membrane surface is denser than the type or ultra-low pressure type reverse osmosis membrane. Therefore, although the high-pressure type reverse osmosis membrane has a lower amount of permeated water per unit operating pressure than the low-pressure type or ultra-low pressure type reverse osmosis membrane, it has weak electrolyte components such as boron, silica, and non-charged organic substances and non-charged components. High removal rate. As described above, the high-pressure reverse osmosis membrane separation apparatus has a low amount of permeated water per unit operating pressure, and 0.6 to 1.3 m 3 / m 2 / day under conditions of an effective membrane surface pressure of 2.0 MPa and 25 ° C. The pure water permeation flux may have a NaCl removal rate of 99.5% or more. However, if the object of the present invention is achieved and effective, the values of the permeation flux and the NaCl removal rate are It is not limited. Here, the effective pressure on the membrane surface is an effective pressure acting on the membrane obtained by subtracting the osmotic pressure difference and the secondary pressure from the average operating pressure, and the NaCl removal rate is 25 ° C. with respect to an aqueous NaCl solution having an NaCl concentration of 32000 mg / L. The removal rate at a pressure of 2.7 MPa. The shape of the high-pressure reverse osmosis membrane may be any shape as long as the object of the present invention is achieved and the effect is exerted, and examples thereof include a spiral shape, a hollow fiber shape, and a flat membrane shape.

本発明の実施形態において、高圧型逆浸透膜分離装置を備える理由は以下の通りである。すなわち、高圧型逆浸透膜分離装置は脱塩あるいは有機物除去を行うポリアミド層の架橋度が高いため下記の表1に示すように、従来、当該技術分野にて使用していた超低圧型又は低圧型逆浸透膜(RO膜)に比べはるかに脱塩率、有機物除去率が高い。そのため本膜(高圧型逆浸透膜)の使用により後段装置の負荷を大幅に低減することが可能となるばかりか本膜(高圧型逆浸透膜)処理1段で、従来のRO膜(超低圧型又は低圧型逆浸透膜)の複数段処理、特には2段処理と同等の処理水質を得ることができる。   In the embodiment of the present invention, the reason why the high-pressure type reverse osmosis membrane separation device is provided is as follows. That is, since the high-pressure type reverse osmosis membrane separation device has a high degree of cross-linking of the polyamide layer for desalting or removing organic substances, as shown in Table 1 below, the ultra-low pressure type or low pressure type conventionally used in the technical field is used. Compared to a reverse osmosis membrane (RO membrane), the salt removal rate and organic matter removal rate are much higher. For this reason, the use of this membrane (high pressure type reverse osmosis membrane) makes it possible not only to greatly reduce the load on the subsequent apparatus, but also the conventional RO membrane (ultra-low pressure) in one stage of this membrane (high pressure type reverse osmosis membrane) treatment. Type or low-pressure type reverse osmosis membrane), in particular, the treated water quality equivalent to the two-stage treatment can be obtained.

本発明の実施形態における脱気装置は、IC(無機炭素)、溶存酸素の除去を行う。高圧型逆浸透膜分離装置処理後に脱気装置(脱ガス装置)を備える理由は以下の通りである。すなわち、高圧型逆浸透膜分離装置の前段に脱気装置の設備を入れた場合、原水中に存在する濁質あるいはAl、SiO等により脱気装置に備えられている脱気膜あるいは充填材(真空脱気等)が汚れ、脱気効率が低下するおそれがある。上記の濁質あるいはAl、SiO等は高圧型逆浸透膜にて除去可能であるため、高圧型逆浸透膜分離装置によって処理した後、脱気装置に被処理水を通水することにより脱気効率の低下を防止する。 The deaerator in the embodiment of the present invention removes IC (inorganic carbon) and dissolved oxygen. The reason why the degassing device (degassing device) is provided after the high pressure reverse osmosis membrane separation device treatment is as follows. That is, when a degassing device is installed in the front stage of the high-pressure type reverse osmosis membrane separation device, the degassing membrane or packing material provided in the degassing device due to turbidity in the raw water or Al, SiO 2, etc. (Vacuum degassing, etc.) may become dirty and the degassing efficiency may be reduced. Since the above turbidity or Al, SiO 2, etc. can be removed with a high pressure reverse osmosis membrane, after treatment with a high pressure type reverse osmosis membrane separation device, water to be treated is passed through a deaeration device to remove water. Prevents a decrease in efficiency.

また、脱気装置をイオン交換装置、及び紫外線酸化装置の前段に設置する理由は脱気装置にて除去可能であるIC(無機炭素)成分は紫外線酸化装置に対してはラジカルスカベンジャー、一方イオン交換装置に対してはアニオン負荷となる。また、同様に、脱気装置にて除去可能である溶存酸素が過剰に存在する場合、溶存酸素は、上記のIC(無機炭素)成分と同様に、紫外線酸化装置に対してはラジカルスカベンジャーとなり、一方、イオン交換装置に対しては、溶存酸素は樹脂酸化劣化を引き起こす要因物質となる。したがって、脱気装置は紫外線酸化装置、及びイオン交換装置の前段に設置する(備える)必要性がある。脱気装置は、本発明の目的を達成し、本発明の効果を奏すれば、任意の脱気装置でよいが、例えば、脱炭酸塔、膜脱気装置、真空脱気塔、窒素脱気装置、触媒樹脂脱酸素装置等が挙げられる。   The reason why the deaerator is installed in front of the ion exchanger and UV oxidizer is that the IC (inorganic carbon) component that can be removed by the degasser is a radical scavenger for the UV oxidizer, while ion exchange An anion load is applied to the apparatus. Similarly, when there is an excessive amount of dissolved oxygen that can be removed by the deaerator, the dissolved oxygen becomes a radical scavenger for the ultraviolet oxidizer, similar to the above IC (inorganic carbon) component, On the other hand, for an ion exchange device, dissolved oxygen becomes a factor substance that causes resin oxidation deterioration. Therefore, the deaeration device needs to be installed (provided) in front of the ultraviolet oxidation device and the ion exchange device. The degassing apparatus may be any degassing apparatus as long as the object of the present invention is achieved and the effects of the present invention are achieved. For example, a decarboxylation tower, a membrane degassing apparatus, a vacuum degassing tower, a nitrogen degassing apparatus Examples thereof include an apparatus and a catalyst resin deoxygenation apparatus.

脱気装置の後段、及びイオン交換装置(塔)の前段に紫外線酸化装置を設置する理由は以下の通りである。すなわち紫外線酸化装置においては水(被処理水)中の有機物をOHラジカルの酸化力によりCO2と有機酸に分解する。紫外線酸化装置にて生成したCOあるいは有機酸は後段のイオン交換装置(塔)にて除去を行うことができる。 The reason for installing the ultraviolet oxidation device in the subsequent stage of the deaeration device and in the previous stage of the ion exchange device (tower) is as follows. That is, in the ultraviolet oxidation apparatus, organic substances in water (treated water) are decomposed into CO 2 and organic acids by the oxidizing power of OH radicals. The CO 2 or organic acid produced by the ultraviolet oxidation device can be removed by a subsequent ion exchange device (column).

本発明の実施形態における紫外線酸化装置は、185nm波長光を放出するものであって、本発明の目的を達成し、本発明の効果を奏すものであれば、特に限定されるものではない。本発明の実施形態において、有機物分解効率の観点からランプ及び外管共、不純物が極めて少ない合成石英で構成された紫外線酸化装置を使用することが好ましい。   The ultraviolet oxidation apparatus in the embodiment of the present invention is not particularly limited as long as it emits light having a wavelength of 185 nm and achieves the object of the present invention and exhibits the effects of the present invention. In the embodiment of the present invention, it is preferable to use an ultraviolet oxidizer composed of synthetic quartz with very few impurities for both the lamp and the outer tube from the viewpoint of organic matter decomposition efficiency.

本発明の実施形態におけるイオン交換装置は塩類を除去すると共に荷電性有機物の除去を行う。イオン交換装置は、本発明の目的を達成し、本発明の効果を奏すものであれば、特に限定されるものではないが、本発明の実施形態におけるイオン交換装置としては、再生型イオン交換装置(塔)又は非再生型イオン交換装置(塔)がよい。再生型イオン交換装置(塔)としては、例えば、ア)強酸性カチオン交換樹脂が充填されたカチオン交換塔と、強塩基性アニオン交換樹脂が充填されたアニオン交換塔とを直列に接続した2床2塔式再生型イオン交換装置、イ)強酸性カチオン交換樹脂と強塩基性アニオン交換樹脂とが別々の異なる層となるように1つの塔内に強酸性カチオン交換樹脂と該強塩基性アニオン交換樹脂とを充填した2床1塔式再生型イオン交換装置、ウ)強酸性カチオン交換樹脂と強塩基性アニオン交換樹脂とを均一に混合して1つの塔内に充填した混床型再生式イオン交換装置、エ)電気再生式脱イオン装置を1段又は複数段直列に接続した再生型イオン交換装置等が挙げられる。   The ion exchange apparatus in the embodiment of the present invention removes salts and removes charged organic substances. The ion exchange device is not particularly limited as long as it achieves the object of the present invention and exhibits the effects of the present invention, but the ion exchange device in the embodiment of the present invention is a regenerative ion exchange device. (Tower) or non-regenerative ion exchanger (tower) is preferable. As a regenerative ion exchange apparatus (column), for example, a) Two beds in which a cation exchange column filled with a strongly acidic cation exchange resin and an anion exchange column filled with a strongly basic anion exchange resin are connected in series. A two-column regenerative ion exchange apparatus, a) a strongly acidic cation exchange resin and the strongly basic anion exchange in one tower so that the strongly acidic cation exchange resin and the strongly basic anion exchange resin are in different layers. 2 bed 1 tower type regenerative ion exchange device packed with resin, c) mixed bed regenerative ion filled uniformly in strongly acidic cation exchange resin and strongly basic anion exchange resin and packed in one tower Examples thereof include a regenerative ion exchange apparatus in which one or more electric regenerative deionization apparatuses are connected in series.

<前処理システム>
本発明に係る実施形態の超純水製造装置に備えられる前処理システムは、凝集・ろ過、
凝集・加圧浮上(沈殿)・ろ過、膜分離システム(装置)を備えるが、これに限定される
ものではなく、懸濁物質やコロイダル物質の除去に一般に使用されるものであれば使用することが可能である。前処理システムは原水(工業用水、水道水、井水、電子デバイス製造工程から排出される使用済みの超純水等)中の懸濁物質やコロイダル物質の除去を行う。
<Pretreatment system>
The pretreatment system provided in the ultrapure water production apparatus of the embodiment according to the present invention is a coagulation / filtration,
It is equipped with agglomeration, pressurized flotation (precipitation) / filtration, and membrane separation system (apparatus), but is not limited to this and should be used as long as it is generally used for removing suspended substances and colloidal substances. Is possible. The pretreatment system removes suspended substances and colloidal substances in raw water (industrial water, tap water, well water, used ultrapure water discharged from electronic device manufacturing processes, etc.).

<サブシステム>
本発明に係る実施形態の超純水製造装置に備えられるサブシステムは、低圧紫外線酸化装置、イオン交換装置及び限外ろ過装置を備えるが、これらに限定されるものでない。サブシステムでは、超純水の純度を一層高める。低圧紫外線酸化装置は低圧紫外線ランプより照射される185nm波長光が水に吸収されることにより生じるOHラジカルにより有機物の分解除去を行う。サブシステム内に備えられるイオン交換装置は低圧紫外線酸化装置により生成される有機酸あるいは配管等から発生する微量イオンの除去を行う。サブシステムの末端に備えられる限外ろ過装置は配管あるいはイオン交換装置から排出される微粒子の除去を行う。
<Subsystem>
The subsystem provided in the ultrapure water production apparatus according to the embodiment of the present invention includes a low-pressure ultraviolet oxidation apparatus, an ion exchange apparatus, and an ultrafiltration apparatus, but is not limited thereto. In the subsystem, the purity of ultrapure water is further increased. The low-pressure ultraviolet oxidizer decomposes and removes organic substances by OH radicals that are generated when water having a wavelength of 185 nm irradiated from a low-pressure ultraviolet lamp is absorbed by water. An ion exchange device provided in the subsystem removes trace amounts of ions generated from organic acids or piping generated by a low-pressure ultraviolet oxidation device. The ultrafiltration device provided at the end of the subsystem removes fine particles discharged from the piping or the ion exchange device.

2.超純水製造方法
本発明に係る実施形態の超純水製造方法は、原水を前処理システムによって処理した被処理水を一次純水システム及びサブシステムの順によって処理し、一次純水システムによる処理方法が、高圧型逆浸透膜分離装置に被処理水を通水する工程と、通水された被処理水中のガスを脱気する工程と、脱気された被処理水中の有機物を紫外線酸化装置によって分解する工程と、有機物が分解された被処理水を、イオン交換装置によって処理する工程とを含む、超純水製造方法である。本実施形態の超純水製造方法によれば、要求水質を充分に満足した高純度の超純水を、フットプリントを軽減させて製造することができ、さらに設備コスト(イニシャルコスト)及び運営コスト(ランニングコスト)を抑えながら安価に製造することができる。
2. Ultrapure water production method An ultrapure water production method according to an embodiment of the present invention treats treated water obtained by treating raw water by a pretreatment system in the order of a primary pure water system and a subsystem, and performs treatment by the primary pure water system. The method includes a step of passing water to be treated through a high pressure type reverse osmosis membrane separator, a step of degassing the gas in the water to be treated, and an ultraviolet oxidation device for removing organic matter in the degassed water to be treated. This is a method for producing ultrapure water, which includes a step of decomposing by water and a step of treating water to be treated by decomposing organic matter using an ion exchange device. According to the ultrapure water production method of the present embodiment, high purity ultrapure water sufficiently satisfying the required water quality can be produced with a reduced footprint, and the equipment cost (initial cost) and the operation cost It can be manufactured at low cost while suppressing (running cost).

本発明に係る実施形態は、以下のような構成をとることもできる。
[1]前処理システムと、一次純水システムと、サブシステムとを備え、その一次純水システムが、高圧型逆浸透膜分離装置と、脱気装置と、紫外線酸化装置と、イオン交換装置とをこの順で備える、超純水製造装置。
[2]その高圧型逆浸透膜分離装置が、膜面有効圧力2.0MPa、25℃条件下において0.6〜1.3m/m/dayの純水透過流束を有する、上記[1]に記載の超純水製造装置。
[3]そのイオン交換装置が、以下のア)〜エ)のいずれか1つの再生型イオン交換装置を有する、上記[1]又は[2]に記載の超純水製造装置。
ア)強酸性カチオン交換樹脂が充填されたカチオン交換塔と、強塩基性アニオン交換樹脂が充填されたアニオン交換塔とを直列に接続した2床2塔式再生型イオン交換装置。
イ)強酸性カチオン交換樹脂と強塩基性アニオン交換樹脂とが別々の異なる層となるように1つの塔内にその強酸性カチオン交換樹脂とその強塩基性アニオン交換樹脂とを充填した2床1塔式再生型イオン交換装置。
ウ)強酸性カチオン交換樹脂と強塩基性アニオン交換樹脂とを均一に混合して1つの塔内に充填した混床型再生式イオン交換装置。
エ)電気再生式脱イオン装置を1段又は複数段直列に接続した再生型イオン交換装置。
[4]原水を前処理システムによって処理した被処理水を一次純水システム及びサブシステムの順によって処理し、その一次純水システムによる処理方法が、高圧型逆浸透膜分離装置に該被処理水を通水する工程と、その通水された被処理水中のガスを脱気する工程と、その脱気された被処理水中の有機物を紫外線酸化装置によって分解する工程と、その有機物が分解された被処理水を、イオン交換装置によって処理する工程とを含む、超純水製造方法。
The embodiment according to the present invention can also be configured as follows.
[1] A pretreatment system, a primary pure water system, and a subsystem are provided, and the primary pure water system includes a high-pressure reverse osmosis membrane separation device, a deaeration device, an ultraviolet oxidation device, and an ion exchange device. The ultrapure water production equipment equipped with in this order.
[2] The high-pressure reverse osmosis membrane separation device has a pure water permeation flux of 0.6 to 1.3 m 3 / m 2 / day under a membrane surface effective pressure of 2.0 MPa and 25 ° C. 1] The ultrapure water production apparatus according to 1].
[3] The ultrapure water production apparatus according to the above [1] or [2], wherein the ion exchange apparatus includes any one of the following regenerative ion exchange apparatuses a) to d).
A) A two-bed two-column regenerative ion exchange apparatus in which a cation exchange column filled with a strongly acidic cation exchange resin and an anion exchange column filled with a strongly basic anion exchange resin are connected in series.
B) Two beds 1 in which the strongly acidic cation exchange resin and the strongly basic anion exchange resin are packed in the same column so that the strongly acidic cation exchange resin and the strongly basic anion exchange resin are in different layers. Tower-type regenerative ion exchanger.
C) A mixed bed regenerative ion exchange apparatus in which a strongly acidic cation exchange resin and a strongly basic anion exchange resin are uniformly mixed and packed in one tower.
D) A regenerative ion exchange apparatus in which one or more electric regenerative deionization apparatuses are connected in series.
[4] Treated raw water treated by a pretreatment system is treated in the order of a primary pure water system and a subsystem, and a treatment method using the primary pure water system is applied to the high pressure type reverse osmosis membrane separation device. A step of passing water, a step of degassing the gas in the water to be treated, a step of decomposing organic matter in the degassed water to be treated by an ultraviolet oxidizer, and the organic matter being decomposed A method for producing ultrapure water, comprising a step of treating water to be treated with an ion exchange device.

以下の実施例及び比較例を挙げて、本発明に係る実施形態の超純水製造装置及び超純水製造方法スケール防止方法の効果について説明をする。なお、本発明の範囲は実施例に限定されるものではない。   The effects of the ultrapure water production apparatus and the ultrapure water production method scale prevention method of the embodiment according to the present invention will be described with reference to the following examples and comparative examples. The scope of the present invention is not limited to the examples.

(実施例1)
電気伝導率30mS/m、TOC2mg/L、SiO210mg/L及びB30μg/Lを含む工業用水、凝集ろ過水をpH6の条件にて高圧型逆浸透膜(SWC4Max、膜面有効圧力2.0MPa、温度25℃における純水透過流束0.78m/m/day;有効圧2.0MPa、温度25℃、NaCl濃度32000mg/LにおけるNaCl除去率99.8%、日東電工製)(回収率85%)に通水した後、脱気装置(脱気膜、X−50ポリポア社製)、紫外線酸化装置(JPW、日本フォトサイエンス製)、次いで1塔内でカチオン交換樹脂層、及びアニオン交換樹脂層を分離したDBP(Double−BedPolisher、栗田工業製)に通水した。
Example 1
Industrial water containing electrical conductivity of 30 mS / m, TOC of 2 mg / L, SiO 2 of 10 mg / L and B of 30 μg / L, agglomerated filtered water under the condition of pH 6 high pressure type reverse osmosis membrane (SWC4Max, membrane surface effective pressure 2.0 MPa, Pure water permeation flux at a temperature of 25 ° C. 0.78 m 3 / m 2 / day; effective pressure 2.0 MPa, temperature 25 ° C., NaCl removal rate at a NaCl concentration of 32000 mg / L, 99.8%, manufactured by Nitto Denko) (recovery rate) 85%), degassing device (degassing membrane, manufactured by X-50 Polypore), UV oxidation device (JPW, manufactured by Nihon Photoscience), then cation exchange resin layer and anion exchange in one tower Water was passed through DBP (Double-BedPolisher, manufactured by Kurita Kogyo Co., Ltd.) from which the resin layer was separated.

(比較例1)
上記の実施例1で用いた原水を超低圧型逆浸透膜(RO膜)(ES−20、有効圧2.0MPa、温度25℃における純水透過流束1m/m/day;有効圧0.75MPa、温度25℃、NaCl濃度500mg/LにおけるNaCl除去率99.7%、日東電工製)の2段直列で通水(1段目回収率85%、2段目回収率90%)したこと以外は実施例1と同様の処理条件で通水した。
(Comparative Example 1)
The raw water used in the above Example 1 was converted into ultra-low pressure reverse osmosis membrane (RO membrane) (ES-20, effective pressure 2.0 MPa, pure water permeation flux 1 m 3 / m 2 / day at 25 ° C .; effective pressure 0.75 MPa, temperature of 25 ° C., NaCl removal rate of 99.7% at NaCl concentration of 500 mg / L, Nitto Denko's two-stage serial water flow (first stage recovery rate 85%, second stage recovery rate 90%) Except that, water was passed under the same treatment conditions as in Example 1.

(比較例2)
上記の実施例1で用いた原水を、No.1カチオン塔(樹脂銘柄EX−CG、栗田工業製)、脱気装置(脱気膜、X−50、ポリポア社製)、No.1アニオン塔(樹脂銘柄EX−AG、栗田工業製)、超低圧型逆浸透膜(RO膜)(ES−20、日東電工製)(回収率90%)、紫外線酸化装置(JPW、日本フォトサイエンス製)、混床式イオン交換装置(MB)(樹脂銘柄EX−MG、栗田工業製)、非再生型イオン交換装置(樹脂銘柄EX−MG、栗田工業製)の順に通水した。脱気装置及び紫外線酸化装置の台数は実施例1と同台数に設置した。
(Comparative Example 2)
The raw water used in Example 1 above is No. 1 cation tower (resin brand EX-CG, manufactured by Kurita Kogyo), deaerator (deaerated membrane, X-50, manufactured by Polypore), No. 1 1 anion tower (resin brand EX-AG, Kurita Kogyo), ultra-low pressure reverse osmosis membrane (RO membrane) (ES-20, Nitto Denko) (recovery rate 90%), UV oxidation device (JPW, Nippon Photoscience) Manufactured), mixed bed type ion exchanger (MB) (resin brand EX-MG, manufactured by Kurita Kogyo), and non-regenerative ion exchanger (resin brand EX-MG, manufactured by Kurita Kogyo) in this order. The number of deaeration devices and ultraviolet oxidation devices was the same as in Example 1.

(比較例3)
上記の実施例1で用いた原水を、高圧型逆浸透膜装置(SWC4Max、日東電工製)(回収率85%)、紫外線酸化装置(JPW、日本フォトサイエンス製)、脱気装置(脱気膜、X−50ポリポア社製)、1塔内でカチオン交換樹脂層及びアニオン交換樹脂層を分離したDBP(Double−Bed Polisher、栗田工業製)の順として処理した以外は実施例1と同条件にて通水した。
(Comparative Example 3)
The raw water used in the above Example 1 was converted into a high-pressure reverse osmosis membrane device (SWC4Max, manufactured by Nitto Denko) (recovery rate 85%), an ultraviolet oxidation device (JPW, manufactured by Nippon Photoscience), a degassing device (degassing membrane) The same conditions as in Example 1 except that the cation exchange resin layer and the anion exchange resin layer were separated in one column and treated as DBP (Double-Bed Polisher, Kurita Kogyo) in that order. I passed water.

(比較例4)
上記の実施例1で用いた原水を、脱気装置(脱気膜、X−50ポリポア社製)、高圧型逆浸透膜装置(SWC4Max、日東電工製)(回収率85%)、紫外線酸化装置(JPW、日本フォトサイエンス製)、1塔内でカチオン交換樹脂層及びアニオン交換樹脂層を分離したDBP(Double−Bed Polisher、栗田工業製)の順として処理した以外は実施例1と同条件にて通水した。
(Comparative Example 4)
The raw water used in Example 1 above was degassed (degassing membrane, manufactured by X-50 Polypore), high-pressure reverse osmosis membrane device (SWC4Max, manufactured by Nitto Denko) (recovery rate: 85%), ultraviolet oxidation device. (JPW, manufactured by Nippon Photo Science Co., Ltd.) The same conditions as in Example 1 except that they were treated as DBP (Double-Bed Polisher, manufactured by Kurita Kogyo) in which the cation exchange resin layer and the anion exchange resin layer were separated in one tower. I passed water.

一次純水システムによって処理された、実施例1及び比較例1〜2の被処理水の水質結果を下記の表2に示す。   The water quality results of the treated water of Example 1 and Comparative Examples 1 and 2 treated by the primary pure water system are shown in Table 2 below.

上記表2から明らかなように、実施例1の被処理水は比抵抗、B(ホウ素)、SiO(シリカ)の到達水質は比較例1及び2の被処理水と同等であるものの、TOC(TotalOrganicCarbon)は最も低い値であった。 As is apparent from Table 2 above, the water to be treated of Example 1 has a specific resistance and the ultimate water quality of B (boron) and SiO 2 (silica) is equivalent to the water to be treated of Comparative Examples 1 and 2, but the TOC (Total Organic Carbon) was the lowest value.

一次純水システムによって処理された、実施例1及び比較例3〜4の被処理水のTOC値の経時変化を図1に示す。   The time-dependent change of the TOC value of the to-be-processed water of Example 1 and Comparative Examples 3-4 processed by the primary pure water system is shown in FIG.

図1から明らかなように、比較例3の被処理水は実施例1の被処理水に比べTOCの値は0.5μg/L程度高い傾向を示した。これは紫外線酸化装置におけるTOC分解効率が脱気装置の設置順(位置)により異なることを示している。また、図1から明らかなように、比較例4の被処理水は通水開始時こそ実施例1の被処理水と同等の水質を得ていたものの日数の増加に伴い水質が悪化する傾向が観測された。これは脱気装置が原水由来物質により汚染され脱気効率が低下し、それに伴い紫外線酸化分解効率が低下したものと考えられる。
As is apparent from FIG. 1, the water to be treated of Comparative Example 3 tended to have a TOC value higher by about 0.5 μg / L than the water to be treated of Example 1. This indicates that the TOC decomposition efficiency in the ultraviolet oxidation apparatus varies depending on the order of installation (position) of the deaeration apparatus. Further, as is apparent from FIG. 1, the water to be treated of Comparative Example 4 had a water quality equivalent to the water to be treated of Example 1 at the start of water flow, but the water quality tends to deteriorate with an increase in the number of days. Observed. It is considered that this is because the deaeration device is contaminated with the raw water-derived substance and the deaeration efficiency is lowered, and accordingly, the ultraviolet oxidative decomposition efficiency is lowered.

Claims (4)

前処理システムと、一次純水システムと、サブシステムとを備え、
該一次純水システムが、高圧型逆浸透膜分離装置と、脱気装置と、紫外線酸化装置と、イオン交換装置とをこの順で備える、
超純水製造装置。
A pretreatment system, a primary pure water system, and a subsystem;
The primary pure water system includes a high-pressure reverse osmosis membrane separation device, a deaeration device, an ultraviolet oxidation device, and an ion exchange device in this order.
Ultrapure water production equipment.
前記高圧型逆浸透膜分離装置が、膜面有効圧力2.0MPa、25℃条件下において0.6〜1.3m/m/dayの純水透過流束を有する、請求項1に記載の超純水製造装置。 The high-pressure reverse osmosis membrane separation device has a pure water permeation flux of 0.6 to 1.3 m 3 / m 2 / day under a membrane surface effective pressure of 2.0 MPa and 25 ° C. Ultrapure water production equipment. 前記イオン交換装置が、以下のア)〜エ)のいずれか1つの再生型イオン交換装置を有する、請求項1又は2に記載の超純水製造装置。
ア)強酸性カチオン交換樹脂が充填されたカチオン交換塔と、強塩基性アニオン交換樹脂が充填されたアニオン交換塔とを直列に接続した2床2塔式再生型イオン交換装置。
イ)強酸性カチオン交換樹脂と強塩基性アニオン交換樹脂とが別々の異なる層となるように1つの塔内に該強酸性カチオン交換樹脂と該強塩基性アニオン交換樹脂とを充填した2床1塔式再生型イオン交換装置。
ウ)強酸性カチオン交換樹脂と強塩基性アニオン交換樹脂とを均一に混合して1つの塔内に充填した混床型再生式イオン交換装置。
エ)電気再生式脱イオン装置を1段又は複数段直列に接続した再生型イオン交換装置。
The ultrapure water production apparatus according to claim 1 or 2, wherein the ion exchange device has any one of the following regenerative ion exchange devices a) to d).
A) A two-bed two-column regenerative ion exchange apparatus in which a cation exchange column filled with a strongly acidic cation exchange resin and an anion exchange column filled with a strongly basic anion exchange resin are connected in series.
A) Two beds 1 in which the strongly acidic cation exchange resin and the strongly basic anion exchange resin are packed in one column so that the strongly acidic cation exchange resin and the strongly basic anion exchange resin are in different layers. Tower-type regenerative ion exchanger.
C) A mixed bed regenerative ion exchange apparatus in which a strongly acidic cation exchange resin and a strongly basic anion exchange resin are uniformly mixed and packed in one tower.
D) A regenerative ion exchange apparatus in which one or more electric regenerative deionization apparatuses are connected in series.
原水を前処理システムによって処理した被処理水を一次純水システム及びサブシステムの順によって処理し、
該一次純水システムによる処理方法が、高圧型逆浸透膜分離装置に該被処理水を通水する工程と、
該通水された被処理水中のガスを脱気する工程と、
該脱気された被処理水中の有機物を紫外線酸化装置によって分解する工程と、
該有機物が分解された被処理水を、イオン交換装置によって処理する工程と、を含む、
超純水製造方法。
Treated raw water treated by pretreatment system in order of primary pure water system and subsystem,
A treatment method by the primary pure water system, the step of passing the treated water through a high-pressure reverse osmosis membrane separator;
Degassing the gas in the water to be treated,
Decomposing organic matter in the degassed water to be treated with an ultraviolet oxidation device;
Treating the water to be treated in which the organic matter is decomposed with an ion exchange device,
Ultrapure water production method.
JP2017089753A 2017-04-28 2017-04-28 Ultrapure water system and ultrapure water production method Pending JP2017127875A (en)

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2020110744A (en) * 2019-01-08 2020-07-27 栗田工業株式会社 Method of operating ultrapure water production system
CN114804467A (en) * 2022-04-26 2022-07-29 成都优越科技有限公司 Two-stage reverse osmosis double-pump double-membrane ultrapure water device and ultrapure water preparation process
KR20230004800A (en) 2020-05-20 2023-01-06 오르가노 코포레이션 Boron removal device and method for removing boron, and device for producing pure water and method for producing pure water

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2020110744A (en) * 2019-01-08 2020-07-27 栗田工業株式会社 Method of operating ultrapure water production system
JP7305960B2 (en) 2019-01-08 2023-07-11 栗田工業株式会社 Operation method of ultrapure water production equipment
KR20230004800A (en) 2020-05-20 2023-01-06 오르가노 코포레이션 Boron removal device and method for removing boron, and device for producing pure water and method for producing pure water
CN114804467A (en) * 2022-04-26 2022-07-29 成都优越科技有限公司 Two-stage reverse osmosis double-pump double-membrane ultrapure water device and ultrapure water preparation process

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