JP2792481B2 - Treatment method for wastewater containing sulfoxides - Google Patents
Treatment method for wastewater containing sulfoxidesInfo
- Publication number
- JP2792481B2 JP2792481B2 JP26572695A JP26572695A JP2792481B2 JP 2792481 B2 JP2792481 B2 JP 2792481B2 JP 26572695 A JP26572695 A JP 26572695A JP 26572695 A JP26572695 A JP 26572695A JP 2792481 B2 JP2792481 B2 JP 2792481B2
- Authority
- JP
- Japan
- Prior art keywords
- sulfoxide
- wastewater
- photoreaction
- sulfoxides
- sulfur compound
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Fee Related
Links
Classifications
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02W—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO WASTEWATER TREATMENT OR WASTE MANAGEMENT
- Y02W10/00—Technologies for wastewater treatment
- Y02W10/10—Biological treatment of water, waste water, or sewage
Landscapes
- Biological Treatment Of Waste Water (AREA)
- Physical Water Treatments (AREA)
- Removal Of Specific Substances (AREA)
- Treatment Of Water By Oxidation Or Reduction (AREA)
Description
【0001】[0001]
【産業上の利用分野】本発明はスルホキシド類有機硫黄
化合物(R−SO−R’:R,R’は炭化水素基)を汚
染物として含有する廃水の処理方法に関し、特にスルフ
ィド類(R−S−R’),メルカプタン類(R−S
H),硫化水素(H2S)といった悪臭を有する硫化物
を発生させることなく、廃水を処理する方法に関するも
のである。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for treating wastewater containing, as a pollutant, a sulfoxide-type organic sulfur compound (R-SO-R ': R, R' is a hydrocarbon group). SR ′), mercaptans (RS)
The present invention relates to a method for treating wastewater without generating malodorous sulfides such as H) and hydrogen sulfide (H 2 S).
【0002】[0002]
【従来の技術】現在ジメチルスルホキシドは、国内で年
間約3000トン生産され、主にアクリル繊維,医薬・
農薬などの合成,染料・顔料用溶剤、又は剥離・洗浄剤
などに使用されており、その工業的利用に伴い大量のス
ルホキシド類含有廃水が生じている。2. Description of the Related Art At present, about 3,000 tons of dimethyl sulfoxide is produced in Japan every year.
It is used in the synthesis of agricultural chemicals, solvents for dyes and pigments, or stripping / cleaning agents, etc., and a large amount of sulfoxide-containing wastewater is produced with its industrial use.
【0003】従来、有機物(COD成分,BOD成分)
を含有する廃水の処理においては有機物の分解処理が重
要なプロセスであり、化学的処理法と生理学的処理法に
大別される。Conventionally, organic matter (COD component, BOD component)
In the treatment of wastewater containing, organic matter decomposition treatment is an important process, and is roughly classified into a chemical treatment method and a physiological treatment method.
【0004】化学的な処理法としては過マンガン酸カリ
ウム(KMnO4),過酸化水素(H2O2),塩素(C
l2),次亜塩素酸ナトリウム(NaOCl)等の酸化
剤処理やオゾン酸化処理,電解酸化処理法が採用されて
おり、スルホキシド類含有廃水に対してこれらの酸化処
理を行うことにより、COD値を完全に低下させること
が可能である。As a chemical treatment, potassium permanganate (KMnO 4 ), hydrogen peroxide (H 2 O 2 ), chlorine (C
l 2 ), an oxidizing agent treatment such as sodium hypochlorite (NaOCl), an ozone oxidation treatment, and an electrolytic oxidation treatment method are employed. By performing these oxidation treatments on the wastewater containing sulfoxides, the COD value is reduced. Can be completely reduced.
【0005】また、活性汚泥法を代表とした生物学的処
理法は、微生物の働きにより有機物を分解する方法であ
り、溶解性有機物を凝集,吸着,分解,沈殿する機能を
果たし、都市下水,有機性廃水の処理技術としては有力
な処理法である。スルホキシド類は活性汚泥法のような
好気条件では生分解されないため、嫌気条件下での処理
が採用され、スルホキシド中の硫黄成分は分解途中でス
ルフィド類,メルカプタン類,ジスルフィド類又は硫化
水素等の代謝物を生成後、最終的に硫酸が生成し処理が
完了する。[0005] A biological treatment method represented by the activated sludge method is a method of decomposing organic substances by the action of microorganisms, and has a function of coagulating, adsorbing, decomposing, and precipitating soluble organic substances. This is an effective treatment method for organic wastewater. Sulfoxides are not biodegraded under aerobic conditions such as the activated sludge process, so treatment under anaerobic conditions is employed. After the metabolite is generated, sulfuric acid is finally generated and the process is completed.
【0006】[0006]
【発明が解決しようとする課題】しかしながら上述した
従来の処理技術において、化学的に酸化する技術のうち
電解酸化処理法は、少量の電解質のみを添加剤として使
用することで処理が可能であり、後工程への影響はほと
んどないものの、この技術をスルホキシド含有廃水に対
して施した場合、陽極での酸化反応と同時に陰極側での
還元反応が進行し、悪臭物質であるスルフィド類が生成
するという問題点があった。However, in the above-mentioned conventional processing techniques, among the techniques of chemically oxidizing, the electrolytic oxidation processing method can perform the processing by using only a small amount of electrolyte as an additive. Although there is almost no effect on the subsequent process, when this technology is applied to sulfoxide-containing wastewater, the oxidation reaction at the anode and the reduction reaction at the cathode side proceed at the same time, producing sulfides, which are malodorous substances. There was a problem.
【0007】また酸化反応もスルホン類(R−SO2−
R’)が生成した時点で完結し、それ以上の酸化分解反
応は進行しない。The oxidation reaction also involves sulfones (R-SO 2-
The reaction is completed when R ′) is generated, and no further oxidative decomposition reaction proceeds.
【0008】一方、次亜塩素酸ナトリウムや過酸化水素
の酸化剤あるいはオゾン等による酸化処理を施した場
合、悪臭物質の発生はないが、電解酸化の場合と同様ス
ルホン類が最終生成物として生成し、それ以上の酸化分
解反応は進行しない。[0008] On the other hand, when an oxidation treatment with an oxidizing agent of sodium hypochlorite or hydrogen peroxide or ozone is performed, no odorous substances are generated, but as in the case of electrolytic oxidation, sulfones are produced as a final product. However, no further oxidative decomposition reaction proceeds.
【0009】通常、有機物を含んだ廃水に対して、有機
物を完全に酸化分解した場合には、二酸化炭素,水が最
終的な生成物として得られ、また硫黄化合物を含む場合
には、これを硫酸としなければならないが、スルホキシ
ド含有廃水の場合、上述のような化学的処理ではスルホ
キシド含有廃水の無機化は、なされていないため、CO
D値としては低下が見られるが、TOC(又はBOD)
値を完全に低下させるには至らなかった。In general, when wastewater containing organic matter is completely oxidized and decomposed, carbon dioxide and water are obtained as final products, and when the wastewater contains sulfur compounds, it is removed. Although it must be sulfuric acid, in the case of the sulfoxide-containing wastewater, the chemical treatment as described above does not demineralize the sulfoxide-containing wastewater.
Although a decrease is seen as the D value, the TOC (or BOD)
The value did not decrease completely.
【0010】一方、生物学的処理法をスルホキシド類の
有機硫黄化合物を含んだ廃水に適用した場合には、活性
汚泥法のような好気条件ではスルホキシド類は生分解さ
れず、スルホキシド類は処理水中に流出する。また嫌気
条件では比較的容易に分解が進行するが、嫌気条件下の
分解途中で悪臭物質であるスルフィド類,メルカプタン
類,ジスルフィド類又は硫化水素等の代謝物を生成し、
廃水から悪臭が大気中に拡散し環境を悪化するといった
問題があった。また活性汚泥法でも曝気槽で分解されな
かったスルホキシド類がプロセス中の嫌気条件となる汚
泥の沈殿槽等で容易に分解し、臭気発生が問題となって
いた。On the other hand, when the biological treatment method is applied to wastewater containing an organic sulfur compound such as sulfoxides, the sulfoxides are not biodegraded under aerobic conditions such as the activated sludge method, and the sulfoxides are not treated. Spills into water. Decomposition progresses relatively easily under anaerobic conditions, but metabolites such as sulfides, mercaptans, disulfides, and hydrogen sulfide, which are malodorous substances, are generated during decomposition under anaerobic conditions.
There was a problem that odors from wastewater diffused into the atmosphere and deteriorated the environment. In addition, sulfoxides that were not decomposed in the aeration tank even in the activated sludge method were easily decomposed in a sludge settling tank or the like which is subjected to anaerobic conditions during the process, and odor generation was a problem.
【0011】本発明の目的は、硫黄系悪臭物質の発生を
防止し、TOC又はBOD成分を十分に分解除去するス
ルホキシド類含有廃水の処理方法を提供することにあ
る。It is an object of the present invention to provide a method for treating sulfoxide-containing wastewater which prevents the generation of sulfur-based malodorous substances and sufficiently decomposes and removes TOC or BOD components.
【0012】[0012]
【課題を解決するための手段】前記目的を達成するた
め、本発明に係るスルホキシド類含有廃水の処理方法
は、スルホキシド類有機硫黄化合物を含有する有機廃水
に過酸化水素あるいはオゾンを共存させ、この有機廃水
に光反応用光線を照射し、スルホキシド類有機硫黄化合
物を分解するものである。In order to achieve the above object, a method for treating a sulfoxide-containing wastewater according to the present invention comprises causing hydrogen peroxide or ozone to coexist in an organic wastewater containing a sulfoxide-organic sulfur compound. The organic wastewater is irradiated with light rays for photoreaction to decompose sulfoxides and organic sulfur compounds.
【0013】また前記有機廃水に過酸化水素を共存させ
る場合の前記スルホキシド類有機硫黄化合物の分解は、
光反応によりヒドロキシラジカルを生じ、これをスルホ
キシド類の炭素−硫黄結合解離部分と反応させてスルホ
ン酸類を生じさせ、その生成したスルホン酸を光反応に
より硫酸に分解し、完全に無機化処理を行うものであ
る。When hydrogen peroxide coexists in the organic wastewater, the decomposition of the organic sulfur compound of the sulfoxide type is as follows:
Hydroxyl radical is generated by photoreaction, and this is reacted with the carbon-sulfur bond dissociated part of sulfoxides to generate sulfonic acids, and the generated sulfonic acid is decomposed into sulfuric acid by photoreaction and completely mineralized. Things.
【0014】また前記有機廃水にオゾンを溶存させる場
合の前記スルホキシド類有機硫黄化合物の分解は、オゾ
ンの光反応により活性酸素を生じ、これをスルホキシド
類の炭素−硫黄結合の解離部分と反応させてスルホン酸
類を生じさせ、その生成したスルホン酸を光反応により
硫酸に分解し、完全に無機化処理を行うものである。In the case of dissolving ozone in the organic wastewater, the decomposition of the organic sulfur compound of sulfoxides generates active oxygen by a photoreaction of ozone, and reacts it with a dissociated portion of carbon-sulfur bond of sulfoxides. Sulfonic acids are generated, and the generated sulfonic acids are decomposed into sulfuric acid by a photoreaction to completely perform a mineralization treatment.
【0015】また前記スルホキシド類有機硫黄化合物の
分解は、スルホキシド類有機硫黄化合物をスルホン酸の
形態まで分解し、その後、生物学的処理において好気的
条件下で分解し、完全に無機化処理を行うものである。Further, the decomposition of the organic sulfur compound of the sulfoxides is performed by decomposing the organic sulfur compound of the sulfoxides to the form of sulfonic acid, and then decomposing under aerobic conditions in a biological treatment, and completely demineralizing. Is what you do.
【0016】また前記光反応用光線は、スルホキシド類
有機硫黄化合物の炭素−硫黄結合の結合エネルギーより
高いエネルギーを有する波長をもつものである。The light beam for photoreaction has a wavelength having an energy higher than the binding energy of the carbon-sulfur bond of the sulfoxide type organic sulfur compound.
【0017】また前記光反応用光線は、紫外線である。The light beam for photoreaction is ultraviolet light.
【0018】紫外線は電磁波の一種で比較的短波長(1
00〜400nm)の領域のものであり、波長が短いほ
ど高いエネルギーを有している。スルホキシド類有機硫
黄化合物の炭素−硫黄結合の結合エネルギーより高いエ
ネルギーを有する波長の光を照射することにより、スル
ホキシド類の炭素−硫黄結合を解離させることが可能で
ある。Ultraviolet light is a kind of electromagnetic wave and has a relatively short wavelength (1
(400 nm to 400 nm), and the shorter the wavelength, the higher the energy. By irradiating light having a wavelength higher than the binding energy of the carbon-sulfur bond of the sulfoxides organic sulfur compound, the carbon-sulfur bonds of the sulfoxides can be dissociated.
【0019】ここで水溶液中に過酸化水素を共存させる
場合には、光反応によってヒドロキシラジカル(OH
・)が生じ、これがスルホキシド類の炭素−硫黄結合解
離部分と反応し、その結果スルホン酸類(R−SO
3H)を生じる。In the case where hydrogen peroxide coexists in the aqueous solution, the hydroxyl radical (OH
), Which reacts with the carbon-sulfur bond dissociating moiety of the sulfoxides, resulting in sulfonic acids (R-SO
3 H).
【0020】また、水溶液中にオゾンを溶存させる場合
には、光反応によってヒドロキシラジカル(OH・)が
生じ、これがスルホキシド類の炭素−硫黄結合解離部分
と反応し、その結果スルフィン酸類(R−SO2H)を
生じる。ここで生成したスルフィン酸はオゾンまたはオ
ゾンの光反応により生成した活性酸素と直ちに反応し、
スルホン酸類(R−SO3H)となる。When ozone is dissolved in an aqueous solution, a photoreaction produces hydroxyl radicals (OH.), Which react with the carbon-sulfur bond dissociating portion of sulfoxides, and as a result, sulfinic acids (R-SO 2 H). The sulfinic acid generated here immediately reacts with ozone or active oxygen generated by the photoreaction of ozone,
The sulfonic acids (R-SO 3 H).
【0021】廃水中に過酸化水素あるいはオゾンを共存
させ、上記のように生成したスルホン酸はさらに同様な
光反応によって硫酸(H2SO4)へと分解され、完全な
無機化がなされる。またスルホン酸類有機硫黄化合物は
好気的条件下で生物学的処理を施すことにより、硫黄系
悪臭物質を生成させることなく硫酸まで分解される。Hydrogen peroxide or ozone is allowed to coexist in the wastewater, and the sulfonic acid generated as described above is further decomposed into sulfuric acid (H 2 SO 4 ) by a similar photoreaction, and is completely mineralized. In addition, sulfonic acid organic sulfur compounds are decomposed to sulfuric acid without generating sulfur-based malodorous substances by performing a biological treatment under aerobic conditions.
【0022】[0022]
【発明の実施の形態】以下、本発明を図により説明す
る。DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the drawings.
【0023】本発明に係るスルホキシド類含有廃水の処
理方法は基本的構成として、スルホキシド類有機硫黄化
合物を含有する有機廃水に過酸化水素あるいはオゾンを
共存させ、この有機廃水に光反応用光線を照射し、スル
ホキシド類有機硫黄化合物を分解処理するものである。The method for treating a sulfoxide-containing wastewater according to the present invention has a basic configuration in which hydrogen peroxide or ozone coexists in an organic wastewater containing a sulfoxide-organic sulfur compound, and the organic wastewater is irradiated with a light beam for photoreaction. And decomposes the sulfoxides organic sulfur compounds.
【0024】光反応に基づいたスルホキシド類有機硫黄
化合物の分解処理には2通りの方法がある。There are two methods for decomposing a sulfoxide or organic sulfur compound based on a photoreaction.
【0025】まず1番目の分解処理は、光反応によりヒ
ドロキシラジカルを生じ、これをスルホキシド類の炭素
−硫黄結合解離部分と反応させてスルホン酸類を生じさ
せ、その生成したスルホン酸を光反応により硫酸に分解
し、完全に無機化させる方法である。First, in the first decomposition treatment, a hydroxyl radical is generated by a photoreaction, and this is reacted with a carbon-sulfur bond dissociated portion of a sulfoxide to generate a sulfonic acid, and the generated sulfonic acid is converted to a sulfuric acid by a photoreaction. This is a method of decomposing to complete mineralization.
【0026】また2番目の分解処理は、スルホキシド類
有機硫黄化合物をスルホン酸の形態まで分解し、その
後、生物学的処理において好気的条件で分解する方法で
ある。The second decomposition treatment is a method in which an organic sulfur compound of sulfoxides is decomposed to a sulfonic acid form, and then decomposed under aerobic conditions in a biological treatment.
【0027】上述した方法は、いずれの処理を行っても
同様の効果を得ることができる。In the above-described method, the same effect can be obtained regardless of the processing.
【0028】(実施例1)次に本発明の実施例を説明す
る。図1に示す本発明に係るスルホキシド類含有廃水の
処理方法は、廃水に過酸化水素を共存させた場合の上述
した前者の処理方法を実施する具体例であり、図1はス
ルホキシド類含有廃水に過酸化水素を共存させ、紫外線
を照射することによりスルホキシド類有機硫黄化合物を
分解する本発明の処理法を示すフローチャートであり、
図2は紫外線の照射量に伴うジメチルスルホキシド及び
反応生成物(メタンスルホン酸,硫酸)の濃度変化を示
すグラフである。(Embodiment 1) Next, an embodiment of the present invention will be described. The method for treating sulfoxide-containing wastewater according to the present invention shown in FIG. 1 is a specific example of implementing the former treatment method when hydrogen peroxide coexists in the wastewater, and FIG. 1 shows a method for treating sulfoxide-containing wastewater. It is a flowchart showing a treatment method of the present invention in which hydrogen peroxide coexists and decomposes sulfoxides organic sulfur compounds by irradiating ultraviolet rays,
FIG. 2 is a graph showing the change in the concentration of dimethyl sulfoxide and the reaction products (methanesulfonic acid, sulfuric acid) with the irradiation amount of ultraviolet rays.
【0029】まず、ジメチルスルホキシド(CH3SO
CH3)含有廃水(2500mg/1500ml)に過
酸化水素水(30%)を10ml添加し、これを送液ポ
ンプにより紫外線照射装置内の石英セルに流入させ、循
環した。First, dimethyl sulfoxide (CH 3 SO
10 ml of hydrogen peroxide solution (30%) was added to CH 3 ) -containing waste water (2500 mg / 1500 ml), and this was flowed into a quartz cell in an ultraviolet irradiation device by a liquid sending pump and circulated.
【0030】続いて、低圧水銀ランプを紫外線照射用の
光源として使用し、過酸化水素を添加したジメチルスル
ホキシド含有廃水に紫外線を照射し光反応を行った。こ
こで、反応溶液は、冷却水を用いて液温を約25℃に保
った。Subsequently, a low-pressure mercury lamp was used as a light source for irradiating ultraviolet rays, and the dimethyl sulfoxide-containing wastewater to which hydrogen peroxide had been added was irradiated with ultraviolet rays to perform a photoreaction. Here, the temperature of the reaction solution was maintained at about 25 ° C. using cooling water.
【0031】その結果、紫外線照射に伴ってジメチルス
ルホキシド濃度は低下し、中間生成物としてメタンスル
ホン酸(CH3SO3H)が生成した後、最終的に硫酸
(H2SO4)が生成した(濃度:2900mg/l)。
なお、処理水のTOC値は1mg/l以下であった。ま
た分解過程でメチルメルカプタン等の悪臭の発生はなか
った。As a result, the concentration of dimethyl sulfoxide decreased with the irradiation of ultraviolet rays, methanesulfonic acid (CH 3 SO 3 H) was produced as an intermediate product, and finally sulfuric acid (H 2 SO 4 ) was produced. (Concentration: 2900 mg / l).
The TOC value of the treated water was 1 mg / l or less. No malodor such as methyl mercaptan was generated during the decomposition process.
【0032】(実施例2)図3は本発明の実施例2に係
る処理法を示すフローチャートである。図3に示す本発
明に係るスルホキシド酸含有廃水の処理方法は、廃水に
過酸化水素を共存させた場合の上述した後者の処理方法
の具体例を示すものである。(Embodiment 2) FIG. 3 is a flowchart showing a processing method according to Embodiment 2 of the present invention. The method for treating sulfoxide acid-containing wastewater according to the present invention shown in FIG. 3 is a specific example of the latter treatment method when hydrogen peroxide coexists in the wastewater.
【0033】まず、ジメチルスルホキシド含有廃水(2
500mg/1500ml)の廃水に過酸化水素水(3
0%)を30ml添加した後、実施例1と同様に紫外線
照射装置により光反応を行った。ジメチルスルホキシド
が完全に分解され、メタンスルホン酸(2900mg/
l)が生成した時点で光分解反応を停止した。First, dimethyl sulfoxide-containing wastewater (2
500mg / 1500ml) wastewater with hydrogen peroxide solution (3
(0%) was added, and a photoreaction was performed with an ultraviolet irradiation device in the same manner as in Example 1. Dimethyl sulfoxide was completely decomposed and methanesulfonic acid (2900 mg /
When 1) was formed, the photolysis reaction was stopped.
【0034】続いて、生成したメタンスルホン酸含有廃
水を水酸化ナトリウム水溶液で中和した後、これを約1
0倍に希釈し、NH4Cl 300mg/l,K2HPO
4100mg/l,MgSO4 25mg/l,KCl
25mg/l,FeCl20.2mg/l,酵母エキス
30mg/lとなるように溶解した。活性汚泥は予めメ
タンスルホン酸に1ケ月馴養し、馴養過程で硫酸イオン
濃度の増加でメタンスルホン酸の好気条件下での分解能
力を確認した。容量1Lの曝気槽を用意し、曝気槽にM
LSSが3000mg/lとなるように添加し、温度を
25℃に保った。曝気槽は汚泥が十分撹拌されるように
円塔形状のものを使用し、曝気とともにスターラーで撹
拌した。分解に伴いpHが低下するので、1Nの水酸化
ナトリウム水溶液でpH7にコントロールした。滞留時
間を10時間に設定し、50ml/hrで希釈したジメ
チルスルホン含有廃水を曝気槽に流入した。沈殿槽を設
けずにフィルターセパレーターを使用して処理水を流出
させた。10時間後の流出水中のメタンスルホン酸の濃
度は0mg/l(リットル)であり、また分解過程でメ
チルメルカプタンなどの悪臭の発生はなかった。処理水
のTOC値は2mg/lであった。Subsequently, the produced methanesulfonic acid-containing wastewater is neutralized with an aqueous sodium hydroxide solution, and the resulting wastewater is reduced to about 1%.
0-fold dilution, NH 4 Cl 300 mg / l, K 2 HPO
4 100 mg / l, MgSO 4 25 mg / l, KCl
25mg / l, FeCl 2 0.2mg / l, was dissolved at a yeast extract 30 mg / l. The activated sludge was acclimated to methanesulfonic acid for one month in advance, and the decomposition ability of methanesulfonic acid under aerobic conditions was confirmed by increasing the sulfate ion concentration during the acclimation process. Prepare a 1L aeration tank and add M
LSS was added so as to be 3000 mg / l, and the temperature was kept at 25 ° C. The aeration tank used had a columnar shape so that the sludge was sufficiently stirred, and was stirred with the stirrer together with the aeration. Since the pH was lowered with the decomposition, the pH was controlled at 7 with a 1N aqueous sodium hydroxide solution. The residence time was set to 10 hours, and the dimethyl sulfone-containing wastewater diluted at 50 ml / hr was flowed into the aeration tank. The treated water was discharged using a filter separator without providing a sedimentation tank. After 10 hours, the concentration of methanesulfonic acid in the effluent was 0 mg / l (liter), and no malodor such as methyl mercaptan was generated during the decomposition process. The TOC value of the treated water was 2 mg / l.
【0035】本実施例は、ジメチルスルホキシドがメタ
ンスルホン酸となった時点で光分解反応を終了させるた
め、紫外線の照射は極めて短時間で済み、処理のランニ
ングコストを著しく低減できるという利点がある。In this embodiment, the photodecomposition reaction is terminated when dimethylsulfoxide is converted to methanesulfonic acid, so that irradiation with ultraviolet rays can be performed in a very short time and the running cost of the treatment can be significantly reduced.
【0036】(実施例3)次に本発明の実施例3を図4
〜6を用いて説明する。図4に示す本発明に係るスルホ
キシド含有廃水の処理方法は、廃水にオゾンを溶存させ
た場合の上述した前者の処理方法を実施する具体例であ
る。(Embodiment 3) Next, Embodiment 3 of the present invention will be described with reference to FIG.
This will be described with reference to FIGS. The method for treating sulfoxide-containing wastewater according to the present invention shown in FIG. 4 is a specific example of implementing the former treatment method when ozone is dissolved in wastewater.
【0037】ここで図4および図5はそれぞれ、スルホ
キシド類含有廃水にオゾンを共存させ、紫外線を照射す
ることによりスルホキシド類有機硫黄化合物を分解する
本発明の処理法を示すフローチャート、および処理装置
の概略図である。また、図6は紫外線の照射量に伴うジ
メチルスルホキシド、及び反応生成物(メタンスルホン
酸,硫酸)の濃度変化を示すグラフである。Here, FIGS. 4 and 5 are a flow chart showing the treatment method of the present invention in which ozone is coexistent in the sulfoxide-containing wastewater and irradiate ultraviolet rays to decompose the sulfoxide-organic sulfur compounds, and FIG. It is a schematic diagram. FIG. 6 is a graph showing changes in the concentrations of dimethyl sulfoxide and reaction products (methanesulfonic acid and sulfuric acid) with the irradiation amount of ultraviolet rays.
【0038】図5に示す紫外線照射装置1は400Wの
低圧水銀ランプ用電源2を有する低圧水銀ランプ3およ
び光照射面積100cm2の石英製紫外線反応槽4から
構成される。また、容量は1000mlのオゾン処理槽
5の下部にはオゾン吹き込み用散気ボール6が設置さ
れ、十分にオゾンを廃水中に溶解させることができる。The ultraviolet irradiation apparatus 1 shown in FIG. 5 comprises a low-pressure mercury lamp 3 having a power supply 2 for a low-pressure mercury lamp of 400 W and a UV reactor 4 made of quartz having a light irradiation area of 100 cm 2 . A diffusion ball 6 for blowing ozone is provided below the ozone treatment tank 5 having a capacity of 1000 ml, so that ozone can be sufficiently dissolved in the wastewater.
【0039】まず、ジメチルスルホキシド(CH3SO
CH3)含有廃水7(2500mg/1500ml)を
オゾン処理槽5に流入した。エアーポンプ8により送気
量50l/hの空気をオゾン発生器9でオゾン濃度20
0ppmに調整し、このオゾン含有ガス10をオゾン吹
き込み用散気ボール6を通してジメチルスルホキシド含
有廃水中に送気し、溶解させた。このオゾン溶解ジメチ
ルスルホキシド含有廃水を送液ポンプ11により紫外線
照射装置1内の石英製反応槽4に流入し、オゾン処理槽
5へ循環した。First, dimethyl sulfoxide (CH 3 SO
CH 3 ) -containing wastewater 7 (2500 mg / 1500 ml) was flowed into the ozone treatment tank 5. The air having an air flow rate of 50 l / h is supplied by the air pump 8 to the ozone
The ozone-containing gas 10 was adjusted to 0 ppm, and the ozone-containing gas 10 was fed into the dimethylsulfoxide-containing wastewater through the ozone blowing air diffuser ball 6 and dissolved therein. The wastewater containing ozone-dissolved dimethyl sulfoxide was flowed into the quartz reaction tank 4 in the ultraviolet irradiation device 1 by the liquid sending pump 11 and circulated to the ozone treatment tank 5.
【0040】続いて、低圧水銀ランプ3により石英製紫
外線反応槽4に紫外線を照射し、ジメチルスルホキシド
含有廃水の光反応を行った。光反応で廃水中に溶解した
オゾンの濃度は減少するため、オゾン処理槽5で連続的
にオゾンガスを吹き込み、常時オゾンが処理液中に溶存
するようにした。Subsequently, ultraviolet light was irradiated to the quartz ultraviolet ray reaction tank 4 by the low-pressure mercury lamp 3 to carry out a photoreaction of the dimethyl sulfoxide-containing wastewater. Since the concentration of ozone dissolved in the wastewater by the light reaction decreases, ozone gas is continuously blown in the ozone treatment tank 5 so that ozone is always dissolved in the treatment liquid.
【0041】その結果、図6に示したように紫外線の照
射に伴ってジメチルスルホキシド濃度は低下し、中間生
成物としてメタンスルホン酸(CH3SO3H)が生成し
た後、最終的に硫酸(H2SO4)が生成した(濃度:2
900mg/l)。なお、処理水のTOC値は1mg/
l以下であった。また、分解過程でメチルメルカプタン
や硫化水素等の悪臭物質の発生はなかった。As a result, as shown in FIG. 6, the concentration of dimethyl sulfoxide decreases with the irradiation of ultraviolet rays, and methanesulfonic acid (CH 3 SO 3 H) is generated as an intermediate product, and finally sulfuric acid (CH 3 SO 3 H) is formed. H 2 SO 4 ) (concentration: 2)
900 mg / l). The TOC value of the treated water was 1 mg /
1 or less. Further, no malodorous substances such as methyl mercaptan and hydrogen sulfide were generated during the decomposition process.
【0042】(実施例4)次に本発明の実施例4を図7
を用いて説明する。図7に示す本発明に係るスルホキシ
ド酸含有廃水の処理方法は、廃水にオゾンを溶存させた
場合の上述した後者の処理方法の具体例を示すものであ
る。(Embodiment 4) Next, Embodiment 4 of the present invention will be described with reference to FIG.
This will be described with reference to FIG. The method for treating sulfoxide acid-containing wastewater according to the present invention shown in FIG. 7 is a specific example of the latter treatment method when ozone is dissolved in wastewater.
【0043】図7はスルホキシド類含有廃水に対して、
オゾンを共存させ、紫外線を照射することによりスルホ
ン酸を生成し、生物学的処理を施す、本発明の処理法を
示すフローチャートである。FIG. 7 shows the results for the sulfoxide-containing wastewater.
It is a flowchart which shows the processing method of this invention which produces | generates a sulfonic acid by coexisting ozone, and irradiates ultraviolet rays, and performs a biological treatment.
【0044】実施例3と同様にオゾン処理槽に流入した
ジメチルスルホキシド(CH3SOCH3)含有廃水(2
500mg/1500ml)に対し、オゾンガスを送気
した後、紫外線照射装置により光反応を行った。ジメチ
ルスルホキシドが完全に分解され、メタルスルホン酸
(2900mg/l)が生成した時点で光分解反応を停
止した。As in Example 3, dimethyl sulfoxide (CH 3 SOCH 3 ) -containing wastewater (2
(500 mg / 1500 ml), an ozone gas was supplied, and a photoreaction was performed by an ultraviolet irradiation device. When the dimethyl sulfoxide was completely decomposed and metal sulfonic acid (2900 mg / l) was generated, the photolysis reaction was stopped.
【0045】続いて、生成したメタルスルホン酸含有廃
水を水酸化ナトリウム水溶液で中和した後、これを約1
0倍に希釈し、NH4Cl 300mg/l,K2HPO
4100mg/l,MgSO4 25mg/l,KCl
25mg/l,FeCl20.2mg/l,酵母エキス
30mg/lとなるように溶解した。活性汚泥は予めメ
タルスルホン酸に1ケ月馴養し、馴養過程で硫酸イオン
濃度の増加でメタルスルホン酸の好気条件下での分解能
力を確認した。容量1000mlの曝気槽を用意し、曝
気槽にMLSSが3000mg/lとなるように添加
し、温度を25℃に保ち、ローラで撹拌した。分解に伴
いpHが低下するので、1Nの水酸化ナトリウム水溶液
でpH7にコントロールした。滞留時間を10時間に設
定し、50ml/hrで希釈したジメチルスルホン含有
廃水を曝気槽に流入した。沈殿槽を設けずにフィルター
セパレーターを使用して処理水を流出させた。10時間
後の流出水中にメタンスルホン酸の濃度は0mg/lで
あり、また分解過程でメチルメルカプタンなどの悪臭の
発生はなかった。処理水のTOC値は2mg/lであっ
た。Subsequently, the produced metal sulfonic acid-containing wastewater is neutralized with an aqueous sodium hydroxide solution, and then the resulting wastewater is reduced to about 1%.
0-fold dilution, NH 4 Cl 300 mg / l, K 2 HPO
4 100 mg / l, MgSO 4 25 mg / l, KCl
25mg / l, FeCl 2 0.2mg / l, was dissolved at a yeast extract 30 mg / l. The activated sludge was acclimated to the metal sulfonic acid for one month in advance, and the decomposition ability of the metal sulfonic acid under aerobic conditions was confirmed by increasing the sulfate ion concentration during the acclimation process. An aeration tank having a capacity of 1000 ml was prepared, MLSS was added to the aeration tank so as to be 3000 mg / l, the temperature was maintained at 25 ° C, and the mixture was stirred with a roller. Since the pH was lowered with the decomposition, the pH was controlled at 7 with a 1N aqueous sodium hydroxide solution. The residence time was set to 10 hours, and the dimethyl sulfone-containing wastewater diluted at 50 ml / hr was flowed into the aeration tank. The treated water was discharged using a filter separator without providing a sedimentation tank. After 10 hours, the concentration of methanesulfonic acid in the effluent was 0 mg / l, and no malodor such as methyl mercaptan was generated during the decomposition process. The TOC value of the treated water was 2 mg / l.
【0046】本実施例は、ジメチルスルホキシドがメタ
ンスルホン酸となった時点で光分解反応を終了させるた
め、紫外線の照射は極めて短時間で済み、処理のランニ
ングコストを著しく低減できるという利点がある。In this embodiment, the photodecomposition reaction is terminated when dimethylsulfoxide is converted to methanesulfonic acid, so that irradiation with ultraviolet rays can be performed in a very short time and the running cost of the treatment can be significantly reduced.
【0047】(比較例1)ジメチルスルホキシド含有廃
水(2500mg/1500ml)に対して、過酸化水
素水を添加せずに、またオゾンガスを送気せずに、実施
例1,実施例3と同様の装置で光分解反応を行った。そ
の結果、わずかにジメチルスルホキシド濃度の低下が確
認されたが、この処理法においては廃液中からメチルメ
ルカプタン,硫化水素等の硫黄系悪臭物質が生成したた
め、処理を中止した。(Comparative Example 1) A dimethyl sulfoxide-containing wastewater (2500 mg / 1500 ml) was prepared in the same manner as in Examples 1 and 3 without adding hydrogen peroxide solution and without supplying ozone gas. The photolysis reaction was performed in the device. As a result, a slight decrease in the dimethyl sulfoxide concentration was confirmed. However, in this treatment method, the treatment was stopped because sulfur-based malodorous substances such as methyl mercaptan and hydrogen sulfide were generated from the waste liquid.
【0048】(比較例2)ジメチルスルホキシド含有廃
水(2500mg/1500ml)に対して、過酸化水
素又はオゾンを共存させるが、光分解処理を行わず、1
0倍に希釈した後、以下実施例2,実施例4と同様の活
性汚泥法による生物学的処理を行った。その結果、処理
水中のTOC濃度は78mg/l,ジメチルスルホキシ
ドは249mg/lであり、ジメチルスルホキシドはほ
とんど生分解していないことが確認された。(Comparative Example 2) Hydrogen peroxide or ozone was allowed to coexist with dimethyl sulfoxide-containing wastewater (2500 mg / 1500 ml).
After dilution to 0-fold, the same biological treatment as in Example 2 and Example 4 was performed by the activated sludge method. As a result, the TOC concentration in the treated water was 78 mg / l, the dimethyl sulfoxide was 249 mg / l, and it was confirmed that dimethyl sulfoxide was hardly biodegraded.
【0049】[0049]
【発明の効果】以上説明したように本発明によれば、ス
ルホキシド類有機硫黄化合物を含有する有機廃水に対し
て、過酸化水素あるいはオゾンを共存させ、紫外線を照
射することにより、スルホキシド類有機硫黄化合物はス
ルホン酸を経て、H2O,CO2,H2SO4まで分解さ
れ、悪臭を発生させることなく、処理することができ
る。As described above, according to the present invention, an organic wastewater containing a sulfoxide-type organic sulfur compound is exposed to ultraviolet light in the presence of hydrogen peroxide or ozone, thereby obtaining a sulfoxide-type organic sulfur compound. The compound is decomposed via sulfonic acid to H 2 O, CO 2 , and H 2 SO 4, and can be treated without generating an offensive odor.
【0050】またスルホキシド類の光分解反応によりス
ルホン酸を生成した後、これを生物学的処理において好
気的条件下で分解することにより、悪臭を発生させるこ
となく、H2O,CO2,H2SO4まで分解処理すること
ができる。Further, after sulfonic acid is produced by a photodecomposition reaction of sulfoxides, it is decomposed under aerobic conditions in a biological treatment, whereby H 2 O, CO 2 , It can be decomposed to H 2 SO 4 .
【図1】本発明の実施例1におけるスルホキシド含有廃
水の紫外線分解処理を示すフローチャートである。FIG. 1 is a flowchart showing an ultraviolet decomposition treatment of a sulfoxide-containing wastewater in Example 1 of the present invention.
【図2】本発明の実施例1におけるDMSO含有廃水の
紫外線分解における各成分の濃度変化を表したグラフで
ある。FIG. 2 is a graph showing a change in the concentration of each component in UV decomposition of wastewater containing DMSO in Example 1 of the present invention.
【図3】本発明の実施例2におけるスルホキシド含有廃
水の紫外線分解処理と生物学的処理を組み合わせた処理
法を示すフローチャートである。FIG. 3 is a flowchart showing a treatment method in which the ultraviolet decomposition treatment and the biological treatment are combined in the sulfoxide-containing wastewater in Example 2 of the present invention.
【図4】本発明の実施例3におけるスルホキシド含有廃
水の紫外線分解処理を示すフローチャートである。FIG. 4 is a flowchart showing the ultraviolet decomposition treatment of a sulfoxide-containing wastewater in Example 3 of the present invention.
【図5】本発明の実施例3におけるスルホキシド含有廃
水の紫外線分解処理装置の概略図である。FIG. 5 is a schematic diagram of an apparatus for ultraviolet ray decomposition treatment of sulfoxide-containing wastewater in Example 3 of the present invention.
【図6】本発明の実施例3におけるDMSO含有廃水の
紫外線分解における各成分の濃度変化を表したグラフで
ある。FIG. 6 is a graph showing a change in the concentration of each component in UV decomposition of wastewater containing DMSO in Example 3 of the present invention.
【図7】実施例4におけるスルホキシド含有廃水の紫外
線分解処理と生物学的処理を組み合わせた処理法を示す
フローチャートである。FIG. 7 is a flowchart showing a treatment method in which the ultraviolet decomposition treatment and the biological treatment are combined in the sulfoxide-containing wastewater in Example 4.
1 紫外線照射装置 2 低圧水銀ランプ用電源 3 低圧水銀ランプ 4 石英製紫外線反応槽 5 オゾン処理槽 6 オゾン吹き込み用散気ボール 7 ジメチルスルホキシド含有廃水 8 エアーポンプ 9 オゾン発生器 10 オゾン含有ガス 11 送液ポンプ DESCRIPTION OF SYMBOLS 1 Ultraviolet irradiation device 2 Power supply for low pressure mercury lamp 3 Low pressure mercury lamp 4 Quartz ultraviolet ray reaction tank 5 Ozone treatment tank 6 Diffusion ball for ozone injection 7 Dimethyl sulfoxide containing wastewater 8 Air pump 9 Ozone generator 10 Ozone containing gas 11 Liquid sending pump
───────────────────────────────────────────────────── フロントページの続き (58)調査した分野(Int.Cl.6,DB名) C02F 1/58 C02F 1/32 C02F 1/72 101 C02F 1/78 C02F 3/02──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int. Cl. 6 , DB name) C02F 1/58 C02F 1/32 C02F 1/72 101 C02F 1/78 C02F 3/02
Claims (7)
る有機廃水に過酸化水素を共存させ、 この有機廃水に光反応用光線を照射し、スルホキシド類
有機硫黄化合物を分解することを特徴とするスルホキシ
ド類含有廃水の処理方法。1. Sulfoxides characterized in that hydrogen peroxide is allowed to coexist in an organic wastewater containing an organic sulfur compound of a sulfoxide, and the organic wastewater is irradiated with a light beam for photoreaction to decompose the organic sulfur compound of the sulfoxide. Wastewater treatment method.
解は、光反応によりヒドロキシラジカルを生じ、これを
スルホキシド類の炭素−硫黄結合解離部分と反応させて
スルホン酸類を生じさせ、その生成したスルホン酸を光
反応により硫酸に分解し、完全に無機化処理を行うもの
であることを特徴とする請求項1に記載のスルホキシド
類含有廃水の処理方法。2. The decomposition of the organic sulfur compound of the sulfoxides generates a hydroxyl radical by a photoreaction, and reacts the hydroxyl radical with a carbon-sulfur bond dissociated portion of the sulfoxide to generate sulfonic acids. 2. The method for treating sulfoxide-containing wastewater according to claim 1, wherein the wastewater is decomposed into sulfuric acid by a photoreaction and completely mineralized.
る有機廃水にオゾンを溶存させ、この有機廃水に光反応
用光線を照射し、スルホキシド類有機硫黄化合物を分解
することを特徴とするスルホキシド類含有廃水の処理方
法。3. Sulfoxide-containing wastewater characterized in that ozone is dissolved in organic wastewater containing a sulfoxide-type organic sulfur compound, and the organic wastewater is irradiated with a light beam for photoreaction to decompose the sulfoxide-type organic sulfur compound. Processing method.
解は、オゾンの光反応により活性酸素を生じ、これをス
ルホキシド類の炭素−硫黄結合の解離部分と反応させて
スルホン酸類を生じさせ、その生成したスルホン酸を光
反応により硫酸に分解し、完全に無機化処理を行うもの
であることを特徴とする請求項3に記載のスルホキシド
類含有廃水の処理方法。4. The decomposition of the organic sulfur compound of the sulfoxides generates active oxygen by a photoreaction of ozone, and reacts the active oxygen with a dissociated portion of a carbon-sulfur bond of the sulfoxide to generate sulfonic acids. 4. The method for treating sulfoxide-containing wastewater according to claim 3, wherein the sulfonic acid is decomposed into sulfuric acid by a photoreaction, and the mineralization treatment is performed completely.
解は、スルホキシド類有機硫黄化合物をスルホン酸の形
態まで分解し、その後、生物学的処理において好気的条
件下で分解し、完全に無機化処理を行うものであること
を特徴とする請求項1又は3に記載のスルホキシド類含
有廃水の処理方法。5. The decomposition of the organic sulfur compound of sulfoxides comprises decomposing the organic sulfur compound of sulfoxides to the form of sulfonic acid, and then decomposing under aerobic conditions in biological treatment, and completely demineralizing. The method for treating sulfoxides-containing wastewater according to claim 1 or 3, wherein
機硫黄化合物の炭素−硫黄結合の結合エネルギーより高
いエネルギーを有する波長をもつものであることを特徴
とする請求項1又は3に記載のスルホキシド類含有廃水
の処理方法。6. The sulfoxide according to claim 1, wherein the light beam for photoreaction has a wavelength having an energy higher than a binding energy of a carbon-sulfur bond of an organic sulfur compound of sulfoxides. Of wastewater containing wastes.
を特徴とする請求項1,3又は6に記載のスルホキシド
類含有廃水の処理方法。7. The method for treating sulfoxide-containing wastewater according to claim 1, wherein the light beam for photoreaction is ultraviolet light.
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US8492607B2 (en) | 2003-08-15 | 2013-07-23 | Perma-Fix Environmental Services, Inc. | Treatment of chemical agent hydrolysates |
EP1697008A4 (en) | 2003-08-15 | 2008-05-07 | Perma Fix Environmental Servic | Treatment of chemical agent hydrolysates |
CN109179814B (en) * | 2018-11-26 | 2024-06-14 | 南京紫江工程科技有限公司 | Method for treating sewage by combined advanced oxidation |
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1995
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