JP3364833B2 - How to remove fluorine ions - Google Patents
How to remove fluorine ionsInfo
- Publication number
- JP3364833B2 JP3364833B2 JP29023399A JP29023399A JP3364833B2 JP 3364833 B2 JP3364833 B2 JP 3364833B2 JP 29023399 A JP29023399 A JP 29023399A JP 29023399 A JP29023399 A JP 29023399A JP 3364833 B2 JP3364833 B2 JP 3364833B2
- Authority
- JP
- Japan
- Prior art keywords
- water
- dissolved
- added
- fluorine ions
- treated
- 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
Landscapes
- Separation Of Suspended Particles By Flocculating Agents (AREA)
- Removal Of Specific Substances (AREA)
Description
【0001】[0001]
【発明の属する技術分野】本発明は、被処理水中に含ま
れる溶存フッ素イオンの除去方法に関するものである。TECHNICAL FIELD The present invention relates to a method for removing dissolved fluorine ions contained in water to be treated.
【0002】[0002]
【従来の技術】従来から、被処理水中に含まれるフッ素
イオンの除去方法としては、水中に石灰又は消石灰等を
添加して、フッ素イオンをフッ化カルシウムとして沈殿
させるカルシウム凝集沈殿法が最も一般的に行われてき
た。この方法では、被処理水中の高濃度(100mg/
l以上)フッ素イオンを中濃度(10〜20mg/l)
になるまで除去することは可能であるものの、低濃度
(10mg/l以下)まで除去することは、大量のカル
シウム塩を使用しても殆んど不可能である。カルシウム
凝集沈殿法では、前記のようにフッ素イオンを10mg
/l以下には除去できないので、フッ素イオンを低濃度
に除去する方法としていくつかの方法が検討されてい
る。そのような方法として、吸着剤を用いる吸着法が提
案されているが、この方法の場合、吸着剤コストがかな
り高く、かつ処理条件の制約が厳しい上、吸着剤の再生
等の問題があり、ほとんど実用には供されていない。ま
た、水酸化アルミニウム形成剤を添加し、難水溶性のゲ
ル状の水酸化アルミニウムを生成させるとともに、水中
のフッ素イオンをその水酸化アルミニウムゲルに吸着除
去するアルミニウム法があるが、この処理方法では大量
のアルミニウム化合物を加えなければならず、しかも沈
降性及び脱水性のよいフロックが得られないため、脱水
が困難であり、また大量のスラッジが発生する問題があ
る。これらのほかいくつかの処理法が検討されている
が、いずれも問題点が多く、フッ素イオンは10mg/
l以下には除去できないのが現状である。2. Description of the Related Art Conventionally, the most common method for removing the fluorine ions contained in the water to be treated is the calcium coagulation precipitation method in which lime or slaked lime is added to the water to precipitate the fluorine ions as calcium fluoride. Has been done to. In this method, high concentration (100 mg /
l or more) Medium concentration of fluoride ion (10 to 20 mg / l)
However, even if a large amount of calcium salt is used, it is almost impossible to remove to a low concentration (10 mg / l or less). In the calcium coagulation sedimentation method, 10 mg of fluoride ion was added as described above.
Since it cannot be removed below 1 / l, several methods have been studied as a method for removing fluorine ions at a low concentration. As such a method, an adsorption method using an adsorbent has been proposed, but in the case of this method, the adsorbent cost is considerably high, and the treatment conditions are severely restricted, and there are problems such as regeneration of the adsorbent, It has hardly been put to practical use. In addition, there is an aluminum method in which an aluminum hydroxide forming agent is added to generate a sparingly water-soluble gel-like aluminum hydroxide and fluorine ions in water are adsorbed and removed to the aluminum hydroxide gel. Since a large amount of aluminum compound must be added, and flocs having good sedimentation and dehydration properties cannot be obtained, dehydration is difficult and a large amount of sludge is generated. Several treatment methods other than these have been investigated, but all have many problems, and fluoride ion is 10 mg /
At present, it cannot be removed below 1.
【0003】[0003]
【発明が解決しようとする課題】本発明は、被処理水中
に含まれる溶存フッ素イオンを効率よくほぼ完全に除去
する方法を提供することをその課題とする。An object of the present invention is to provide a method for efficiently and almost completely removing dissolved fluorine ions contained in water to be treated.
【0004】[0004]
【課題を解決するための手段】本発明者らは、前記課題
を解決すべく鋭意研究を重ねた結果、本発明を完成する
に至った。即ち、本発明によれば、被処理水中に含まれ
る溶存フッ素イオンを除去する方法において、該水中に
カルシウム化合物を添加して該溶存フッ素イオンを該カ
ルシウム化合物と反応させて不溶化させた後、非溶解状
態のアニオン基含有親水性高分子物質と鉄塩からなる添
加剤を添加し、該アニオン基含有親水性高分子物を水中
で非溶解状態で分散させ、かつ該鉄塩を水中に溶解させ
ることを特徴とするフッ素イオンの除去方法が提供され
る。また、本発明によれば、被処理水中に含まれる溶存
フッ素イオンを除去する方法において、該水中に水酸化
アルミニウム形成剤と、非溶解状態のアニオン基含有親
水性高分子物質と鉄塩からなる添加剤とを添加し、該水
中に該水酸化アルミニウム形成剤からの水酸化アルミニ
ウムを形成させるとともに、該アニオン基含有親水性高
分子物質を水中で非溶解状態で分散させ、かつ該鉄塩を
水中に溶解させることを特徴とするフッ素イオンの除去
方法が提供される。The present inventors have completed the present invention as a result of intensive studies to solve the above problems. That is, according to the present invention, a method of removing dissolved fluorine ions contained in the for-treatment water after the solution exist fluorine ions are insolubilized by reaction with the calcium compound with the addition of calcium compound in the water, the non Dissolution
An anionic group-containing hydrophilic polymer substance and an iron salt additive are added, the anion group-containing hydrophilic polymer substance is dispersed in water in an insoluble state, and the iron salt is dissolved in water. A method for removing fluorine ions is provided. Further, according to the present invention, in the method for removing the dissolved fluorine ions contained in the water to be treated, the aluminum hydroxide forming agent, the non-dissolved anionic group-containing hydrophilic polymer and the iron salt are contained in the water. An additive is added to form aluminum hydroxide from the aluminum hydroxide forming agent in the water, and the anionic group-containing hydrophilic polymer substance is dispersed in water in a non-dissolved state, and the iron salt is There is provided a method for removing fluoride ions, which is characterized by being dissolved in water.
【0005】[0005]
【発明の実施の形態】本発明の第1の方法は、被処理水
中に溶存するフッ素イオンを除去するために、その水中
にカルシウム化合物を添加して、そのフッ素イオンをカ
ルシウム化合物と反応させて不溶性フッ化カルシウムに
変換させた後、非溶解状態のアニオン基含有親水性高分
子物質と鉄塩からなる添加剤を添加する工程を含む。前
記カルシウム化合物は、水中でフッ素イオンと反応して
フッ化カルシウムを生成するものであればよく、水溶性
を有する各種のものを用いることができる。このような
ものとしては、例えば、塩化カルシウムや硫酸カルシウ
ム、酸化カルシウム、水酸化カルシウム、硝酸カルシウ
ム等が挙げられる。本発明の第2の方法は、該水中に、
水酸化アルミニウム形成剤と、非溶解状態のアニオン基
含有親水性高分子物質と鉄塩からなる添加剤とを添加す
る工程を含む。これにより、水中には、水酸化アルミニ
ウム形成剤によるゲル状の水酸化アルミニウムが形成さ
れるとともに、非溶解状態のアニオン基含有親水性高分
子はその非溶解状態で分散され、かつ鉄塩は溶解され
る。水中に含まれる溶存フッ素イオンはゲル状の水酸化
アルミニウムに吸着(捕捉)され、水中から除去され
る。前記水酸化アルミニウム形成剤は、水中で加水分解
してゲル状の水酸化アルミニウムを生成するものであれ
ばよく、従来公知の各種のものを用いることができる。
このようなものとしては、例えば、塩化アルミニウムや
ポリ塩化アルミニウム、硫酸アルミニウム、硝酸アルミ
ニウム、アルミン酸ソーダ等が挙げられる。水酸化アル
ミニウム形成剤の添加時機は、添加剤の添加前、添加後
又は同時であり、特に制約されない。BEST MODE FOR CARRYING OUT THE INVENTION In the first method of the present invention, in order to remove fluorine ions dissolved in water to be treated, a calcium compound is added to the water and the fluorine ions are reacted with the calcium compound. After the conversion to insoluble calcium fluoride, a step of adding an additive composed of a non-dissolved anionic group-containing hydrophilic polymer and an iron salt is included. The calcium compound may be any compound that reacts with fluorine ions in water to generate calcium fluoride, and various water-soluble compounds can be used. Examples of such substances include calcium chloride, calcium sulfate, calcium oxide, calcium hydroxide, and calcium nitrate. The second method of the present invention is to
It includes a step of adding an aluminum hydroxide forming agent, an anionic group-containing hydrophilic polymer substance in a non-dissolved state, and an additive composed of an iron salt. As a result, gelled aluminum hydroxide is formed in the water by the aluminum hydroxide forming agent , the anionic group-containing hydrophilic polymer in the undissolved state is dispersed in the undissolved state , and the iron salt is dissolved. To be done. Dissolved fluorine ions contained in water are adsorbed (captured) by gel-like aluminum hydroxide and removed from water. The aluminum hydroxide-forming agent may be any one that can be hydrolyzed in water to form gel aluminum hydroxide, and various conventionally known materials can be used.
Examples of such a material include aluminum chloride, polyaluminum chloride, aluminum sulfate, aluminum nitrate, sodium aluminate, and the like. The timing for adding the aluminum hydroxide forming agent is before, after, or simultaneously with the addition of the additive, and is not particularly limited.
【0006】溶存フッ素イオンを含む被処理水からその
溶存フッ素イオンを除去する場合、その溶存フッ素イオ
ンが比較的多量の場合、例えば、30mg/l以上、特
に50mg/l以上の場合には、カルシウム化合物を添
加するのが好ましい。この場合には、そのカルシウム化
合物の添加量は、フッ素原子1モル当り、0.5〜10
モル、好ましくは1〜5モルの割合である。なお、被処
理水中の溶存フッ素イオンの上限値は、特に制約されな
いが、通常、1000mg/l程度である。When the dissolved fluorine ion is removed from the water to be treated containing the dissolved fluorine ion, when the dissolved fluorine ion is in a relatively large amount, for example, 30 mg / l or more, particularly 50 mg / l or more, calcium is used. It is preferred to add the compound. In this case, the amount of the calcium compound added is 0.5 to 10 per mol of the fluorine atom.
The molar ratio is preferably 1 to 5 mol. The upper limit of dissolved fluorine ions in the water to be treated is not particularly limited, but is usually about 1000 mg / l.
【0007】溶存フッ素イオンを含む被処理水からその
溶存フッ素イオンを除去する場合、その溶存フッ素イオ
ンが少量の場合、例えば、10〜30mg/l、特に1
0〜25mg/lの場合には、水酸化アルミニウム形成
剤を添加するのが好ましい。この場合には、その添加量
は、フッ素原子1モル当り、アルミニウム原子として、
0.5〜10モル、好ましくは1〜5モルの割合であ
る。When the dissolved fluorine ion is removed from the water to be treated containing the dissolved fluorine ion, when the dissolved fluorine ion is in a small amount, for example, 10 to 30 mg / l, particularly 1
In the case of 0 to 25 mg / l, it is preferable to add an aluminum hydroxide forming agent. In this case, the addition amount is as aluminum atom per mol of fluorine atom,
The ratio is 0.5 to 10 mol, preferably 1 to 5 mol.
【0008】本発明の方法は、前記のように、非溶解状
態のアニオン基含有親水性高分子物質(以下、単に高分
子物質とも言う)と鉄塩からなる添加剤を添加する工程
を含むが、この場合、添加剤を添加する前の被処理水の
pHは、通常、1〜8、好ましくは2〜7である。The method of the present invention, as described above, uses a non-dissolved form.
The method includes a step of adding an additive consisting of anionic group-containing hydrophilic polymer (hereinafter, also simply referred to as polymer) and iron salt, in which case the pH of the water to be treated before the additive is added. Is usually 1 to 8, preferably 2 to 7.
【0009】本発明で添加剤成分として用いるアニオン
基含有親水性高分子物質には、カルボキシル基、スルホ
ン酸基、リン酸基等のアニオン基を含有する各種の水溶
性高分子物質が包含され、天産品及び合成品のいずれも
使用できるが、環境保全の点からは生分解性を有するも
のの使用が好ましい。このような高分子物質としては、
アルギン酸、ジエランガム、キサンタンガム、トラガカ
ントガム、ペクチン、ペクチン酸、ペクチニン酸、カラ
ギーナン、ゼラチン、寒天、アニオン化でんぷん、アル
ギン酸プロピレングリコールエステル、カルボキシメチ
ルセルロース、デンプングリコール酸、繊維素グリコー
ル酸、デンプンリン酸、ガラクトマンナン等の多糖類及
びそれらの金属塩;ポリアクリル酸、アクリルアミドと
アクリル酸との共重合体及びその金属塩;高吸水性高分
子(例えば、住友化学社製、「スミカゲル」、三洋化成
社製、「サンウェット」、昭和電工社製、「プレアプ
ル」、日澱化学社製、「WAS」等)等が挙げられる。The anion group-containing hydrophilic polymer substance used as an additive component in the present invention includes various water-soluble polymer substances containing anion groups such as a carboxyl group, a sulfonic acid group and a phosphoric acid group, Although both natural products and synthetic products can be used, those having biodegradability are preferred from the viewpoint of environmental protection. As such a high molecular substance,
Alginic acid, dielan gum, xanthan gum, tragacanth gum, pectin, pectic acid, pectinic acid, carrageenan, gelatin, agar, anionized starch, alginic acid propylene glycol ester, carboxymethyl cellulose, starch glycolic acid, fibrin glycolic acid, starch phosphoric acid, galactomannan, etc. Polysaccharides and metal salts thereof; polyacrylic acid, copolymers of acrylamide and acrylic acid and metal salts thereof; superabsorbent polymers (eg, Sumitomo Chemical Co., Ltd., “Sumika Gel”, Sanyo Chemical Co., Ltd., Sunwet ", Showa Denko KK," Pre-Apple ", Nitto Kagaku KK," WAS ", etc.) and the like.
【0010】本発明では、特に、アルギン酸及びその塩
の使用が好ましいが、このものを用いる場合には、アル
ギン酸を構成しているマンヌロン酸(M)とグルロン酸
(G)の含有比率(モル比)[M]/[G]が、0.1
〜4.0、好ましくは0.1〜3の範囲にあるものの使
用が好ましい。グルロン酸の含有比率が多いもの程、多
価カチオンとの反応によるフロック形成性にすぐれてい
る。アルギン酸塩としては、Na塩、Ca塩、Mg塩、
Al塩等が挙げられる。これらのアニオン基含有親水性
高分子物質は粉体状(短繊維状を含む)又は非溶解状態
の液体の形態で用いられる。粉体状で用いる場合、その
平均粒径は、10〜500μm、好ましくは20〜20
0μm、より好ましくは50〜150μmである。一
方、非溶解状態の液体の形態で用いる場合、その液体
は、アニオン基含有親水性物質を非溶解状態で分散させ
た水性液体であることができる。この場合の液体には、
水、水/有機溶剤混合物及び有機溶剤が包含されるが、
通常は水又は有機溶剤の水溶液である。本発明において
用いる前記アニオン基含有親水性高分子物質は、単独又
は混合物の形態で用いることができる。混合物として
は、アルギン酸又はその塩を含有する混合物の使用が好
ましい。この場合のアルギン酸又はその塩の含有混合物
としては、(i)アルギン酸又はその塩と、(ii)ジエ
ランガム、キサンタンガム、ペクチン、ペクチン酸、ペ
クチニン酸及びそれらの塩の中から選ばれる少なくとも
1種の親水性高分子物質との混合物である。例えば、ア
ルギン酸ナトリウムと他のアニオン基含有親水性高分子
物質との混合物を用いる場合、アルギン酸ナトリウム
(A)と他のアニオン基含有親水性高分子物質(B)と
の重量比[A]/[B]は、1〜100、好ましくは2
〜50である。In the present invention, it is particularly preferable to use alginic acid and its salt, but when this is used, the content ratio (molar ratio) of mannuronic acid (M) and guluronic acid (G) constituting the alginic acid. ) [M] / [G] is 0.1
It is preferable to use those in the range of -4.0, preferably 0.1-3. The higher the content ratio of guluronic acid, the better the floc forming property due to the reaction with the polyvalent cation. As the alginate, Na salt, Ca salt, Mg salt,
Al salt etc. are mentioned. These anionic group-containing hydrophilic polymer substances are in powder form (including short fiber form) or undissolved state
Used in the liquid form. When used in powder form, the average particle size is 10 to 500 μm, preferably 20 to 20 μm.
It is 0 μm, more preferably 50 to 150 μm. On the other hand, when used in the form of undissolved state liquid, the liquid may be an aqueous liquid containing dispersed anionic group-containing hydrophilic substance in a non-dissolved form. The liquid in this case includes
Water, water / organic solvent mixtures and organic solvents are included,
Usually, it is water or an aqueous solution of an organic solvent. The anionic group-containing hydrophilic polymer substance used in the present invention can be used alone or in the form of a mixture. As the mixture, it is preferable to use a mixture containing alginic acid or a salt thereof. In this case, the mixture containing alginic acid or a salt thereof includes (i) alginic acid or a salt thereof and (ii) at least one hydrophilic selected from dielan gum, xanthan gum, pectin, pectic acid, pectinic acid and salts thereof. It is a mixture with a polymeric substance. For example, when a mixture of sodium alginate and another anionic group-containing hydrophilic polymer substance is used, the weight ratio of sodium alginate (A) to another anion group-containing hydrophilic polymer substance (B) [A] / [ B] is 1 to 100, preferably 2
~ 50.
【0011】本発明で添加剤成分として用いる鉄塩は、
水溶性鉄塩である。この鉄塩には、硫酸第一鉄、硫酸第
二鉄、塩化第一鉄、塩化第二鉄等の鉄塩が挙げられる。
これらの鉄塩はアニオン基含有親水性高分子物質に対し
てイオン結合やキレート結合を生成して、その高分子物
質の溶解性をコントロールする作用を示す。The iron salt used as an additive component in the present invention is
It is a water-soluble iron salt. Examples of the iron salt include iron salts such as ferrous sulfate, ferric sulfate, ferrous chloride and ferric chloride.
These iron salts form an ionic bond or a chelate bond with respect to the anionic group-containing hydrophilic polymer substance, and exhibit the action of controlling the solubility of the polymer substance.
【0012】本発明で用いる添加剤は、非溶解状態の高
分子物質と鉄塩とからなる粉体状混合物や、水性液状混
合物等であることができる。水性液状混合物の場合、高
分子物質はその水性液中に溶解せずに分散状態で存在す
る。前記高分子物質の添加割合は、水中に添加したカル
シウム化合物100重量部当り0.01〜50重量部、
好ましくは0.1〜10重量部の割合である。また、水
中に添加した水酸化アルミニウム形成剤100重量部当
り0.1〜50重量部、好ましくは0.2〜10重量部
の割合である。一方、鉄塩の添加量は特に制約されず、
被処理水のpH等により適宜選ばれるが、一般的には、
アニオン基含有親水性高分子物質100重量部に対し
て、1〜10000重量部、好ましくは20〜5000
重量部の割合である。The additive used in the present invention can be a powdery mixture of a non-dissolved polymer substance and an iron salt, an aqueous liquid mixture, or the like. In the case of an aqueous liquid mixture, the polymer substance does not dissolve in the aqueous liquid but exists in a dispersed state. The addition ratio of the polymer substance is 0.01 to 50 parts by weight per 100 parts by weight of the calcium compound added in water,
It is preferably 0.1 to 10 parts by weight. The ratio is 0.1 to 50 parts by weight, preferably 0.2 to 10 parts by weight, based on 100 parts by weight of the aluminum hydroxide forming agent added to water. On the other hand, the addition amount of iron salt is not particularly limited,
It is appropriately selected depending on the pH of the water to be treated, etc.
1 to 10000 parts by weight, preferably 20 to 5000, relative to 100 parts by weight of the anionic group-containing hydrophilic polymer substance.
The ratio is parts by weight.
【0013】本発明で用いる添加剤には、カチオン基含
有親水性高分子物質を併用するのが好ましい。この場合
のカチオン基含有親水性高分子物質は、フロックの巨大
化に貢献するものであり、このようなものには、キトサ
ン、ポリアクリルアミドのカチオン化変性物、ポリアク
リル酸ジメチルアミノエチルエステル、ポリメタクリル
酸ジメチルアミノエチルエステル、ポリエチレンイミン
等が包含される。本発明では、アミノ基又はカチオン基
(第4級アンモニウム基等)を有する高分子物質、特
に、キトサンの使用が好ましい。この場合、キトサン
は、他のカチオン基含有親水性高分子物質、例えばポリ
アクリル酸ジメチルアミノエチルエステル等との混合物
として用いるのが好ましい。It is preferable to use a cationic group-containing hydrophilic polymer substance in combination with the additive used in the present invention. In this case, the cationic group-containing hydrophilic polymer substance contributes to the enlargement of flocs. Examples of such substances include chitosan, polyacrylamide cationized modified products, polyacrylic acid dimethylaminoethyl ester, and polyacrylic acid dimethylaminoethyl ester. Methacrylic acid dimethylaminoethyl ester, polyethyleneimine and the like are included. In the present invention, it is preferable to use a polymer substance having an amino group or a cation group (such as a quaternary ammonium group), particularly chitosan. In this case, chitosan is preferably used as a mixture with another cationic group-containing hydrophilic polymer substance such as polyacrylic acid dimethylaminoethyl ester.
【0014】前記カチオン基含有親水性高分子物質は粉
末状又は水溶液状で用いられる。このものの使用割合
は、前記アニオン基含有親水性高分子物質100重量部
当り、0.1〜500重量部、好ましくは0.2〜10
0重量部の割合である。キトサンを水溶液で用いる場
合、好ましくは酢酸溶液を始め有機酸溶液で調製される
が、塩酸等の無機酸溶液でも調製される。カチオン基含
有親水性高分子物質は、添加剤の添加後に添加すればよ
い。The cationic group-containing hydrophilic polymer substance is used in the form of powder or aqueous solution. The use ratio of this substance is 0.1 to 500 parts by weight, preferably 0.2 to 10 parts by weight, based on 100 parts by weight of the anionic group-containing hydrophilic polymer substance.
The ratio is 0 part by weight. When chitosan is used as an aqueous solution, it is preferably prepared with an organic acid solution including an acetic acid solution, but it is also prepared with an inorganic acid solution such as hydrochloric acid. The cationic group-containing hydrophilic polymer substance may be added after addition of the additive.
【0015】本発明で用いる高分子物質においては、凝
集剤を併用するのが好ましい。この場合の凝集剤は、フ
ロックの凝集に用いられているものであり、このような
ものには、キトサン、塩化カルシウム、ビス(リン酸2
水素)カルシウム、ポリアクリルアミドのカチオン化変
性物、ポリアクリル酸ジメチルアミノエチルエステル、
ポリメタクリル酸ジメチルアミノエチルエステル、ポリ
エチレンイミン、キトサン等のカチオン性有機系凝集
剤、ポリアクリルアミド等のノニオン性有機系凝集剤、
ポリアクリル酸、アクリルアミドとアクリル酸との共重
合体及びその塩等のアニオン性有機系凝集剤が包含され
る。凝集剤は、添加剤の添加後に添加すればよい。In the polymer substance used in the present invention, it is preferable to use a coagulant together. In this case, the flocculant is used for floc flocculation, and examples of such flocculants include chitosan, calcium chloride, bis (phosphoric acid 2
Hydrogen) calcium, cationized modified polyacrylamide, polyacrylic acid dimethylaminoethyl ester,
Cationic organic flocculants such as polymethacrylic acid dimethylaminoethyl ester, polyethyleneimine and chitosan, nonionic organic flocculants such as polyacrylamide,
Anionic organic flocculants such as polyacrylic acid, copolymers of acrylamide and acrylic acid, and salts thereof are included. The coagulant may be added after the additive is added.
【0016】本発明で用いる高分子物質には、フロック
の沈降促進剤を併用するのが好ましい。このものとして
は、比重の大きい不溶性微粒子であればどのようなもの
でも使用することができる。その比重は3以上、好まし
くは4.5以上であり、その平均粒径は1〜100μ
m、好ましくは30〜70μmである。このようなもの
としては、硫酸バリウムや、金属微粒子(例えばFeや
Ti等)、バライト等が挙げられる。その使用割合は、
アニオン基含有親水性高分子物質100重量部当り、1
〜60重量部、好ましくは5〜30重量部である。フロ
ック沈降促進剤は、添加剤の添加後に添加すればよい。It is preferable to use a floc sedimentation accelerator together with the polymer substance used in the present invention. Any insoluble fine particles having a large specific gravity can be used as this. Its specific gravity is 3 or more, preferably 4.5 or more, and its average particle size is 1 to 100 μm.
m, preferably 30 to 70 μm. Examples of such a material include barium sulfate, fine metal particles (for example, Fe, Ti, etc.), barite, and the like. The usage rate is
1 per 100 parts by weight of anionic group-containing hydrophilic polymer
-60 parts by weight, preferably 5-30 parts by weight. The floc sedimentation accelerator may be added after the additive is added.
【0017】本発明は、被処理水にカルシウム化合物又
は水酸化アルミニウム形成剤を添加し、次いで非溶解状
態の高分子物質と鉄塩からなる添加剤を添加した後に、
その被処理水が酸性の場合には、アルカリを加え、その
被処理水のpHを7〜10、好ましくは7〜8の範囲に
調節する。このpH調節により、不溶化したフッ素の凝
集沈殿が促進される。その添加量は、被処理水のpHを
前記範囲に保持する量であればよい。アルカリとして
は、水酸化ナトリウム、炭酸ナトリウム、水酸化カルシ
ウム、水酸化マグネシウム等が挙げられる。In the present invention, a calcium compound or an aluminum hydroxide forming agent is added to water to be treated, and then the water is not dissolved.
After adding an additive consisting of a high molecular weight substance and iron salt,
When the water to be treated is acidic, alkali is added to adjust the pH of the water to be treated to a range of 7 to 10, preferably 7 to 8. By this pH adjustment, coagulation and precipitation of insolubilized fluorine is promoted. The addition amount may be an amount that maintains the pH of the water to be treated within the above range. Examples of the alkali include sodium hydroxide, sodium carbonate, calcium hydroxide, magnesium hydroxide and the like.
【0018】前記pH調節工程終了後の被処理水は、固
液分離処理される。この場合の固液分離方法としては、
慣用の方法、例えば、濾過分離、遠心分離、沈降分離等
が挙げられる。The water to be treated after the pH adjustment step is subjected to solid-liquid separation treatment. As a solid-liquid separation method in this case,
Conventional methods such as filtration separation, centrifugation, sedimentation separation and the like can be mentioned.
【0019】[0019]
【発明の効果】本発明の方法によれば、被処理水として
の水中に含まれる溶存フッ素イオンを、効率よくかつ低
められたスラッジ発生量で除去することができる。この
場合、被処理水のpHは、通常、0〜9であり、特に1
〜8である。また、フッ素イオンの含有量は、通常、1
0〜10,000ppmである。本発明の方法では、生
成するスラッジの発生量は少なく、その発生量は、通
常、被処理水100重量部当り10重量部以下である。
本発明によれば、被処理水中のフッ素イオンをほぼ完全
に除去することができ、フッ素イオンを除去した後の処
理水に含まれる溶存フッ素イオンは10ppm以下、好
ましくは8ppm以下、より好ましくは5ppm以下で
ある。According to the method of the present invention, dissolved fluorine ions contained in water as water to be treated can be efficiently removed with a reduced sludge generation amount. In this case, the pH of the water to be treated is usually 0-9, especially 1
~ 8. The content of fluorine ion is usually 1
It is 0 to 10,000 ppm. In the method of the present invention, the amount of generated sludge is small, and the amount of generated sludge is usually 10 parts by weight or less per 100 parts by weight of the water to be treated.
According to the present invention, the fluorine ion in the water to be treated can be almost completely removed, and the dissolved fluorine ion contained in the treated water after removing the fluorine ion is 10 ppm or less, preferably 8 ppm or less, more preferably 5 ppm. It is the following.
【0020】[0020]
【実施例】次に本発明を実施例によりさらに詳細に説明
する。EXAMPLES Next, the present invention will be described in more detail by way of examples.
【0021】実施例1
塩化第二鉄(工業用)37.5wt%水溶液を水酸化ナ
トリウムでpH1に調整後、80℃以上で3時間攪拌
後、アルギン酸ナトリウム4.8重量%添加し3時間攪
拌したところ、褐色の懸濁液となった。これを添加剤
[I]とした。この添加剤[I]においては、アルギン
酸ナトリウムは非溶解状態で存在する。フッ化ナトリウ
ムを純水に221mg/Lの濃度で溶解させて、フッ素
イオン濃度を100ppmに調整しモデル排水とした。
この液に塩化カルシウム1000ppm添加後、添加剤
[I]を100ppm添加した。この溶液を5分間攪拌
後、水酸化ナトリウムでpH7に調整してから固液分離
した。処理水の残存フッ素濃度を測定したところ、4.
1ppmであった。尚、添加剤[I]を添加せずに、塩
化カルシウム単独で処理した場合のフッ素イオン濃度は
44.5ppmであった。しかも、そのときのフロック
は、非常に小さくコロイド状であり、高分子凝集剤を添
加しても成長したフロックは得られなかった。これに対
し、添加剤[I]を添加すると、高分子凝集剤を添加し
なくても成長したフロックを得ることができた。さら
に、高分子凝集剤を3ppm添加すると、より強固で安
定なフロックに成長させることができた。このように、
フロックの形成状態及びフッ素イオン濃度の除去効果に
添加剤[I]の顕著な効果が認められた。Example 1 A 37.5 wt% aqueous solution of ferric chloride (for industrial use) was adjusted to pH 1 with sodium hydroxide, stirred at 80 ° C. or higher for 3 hours, added with sodium alginate (4.8 wt%) and stirred for 3 hours. When it did, it became a brown suspension. This was used as an additive [I]. In this additive [I], algin
Sodium acid exists in a non-dissolved state. Sodium fluoride was dissolved in pure water at a concentration of 221 mg / L to adjust the fluorine ion concentration to 100 ppm to obtain model drainage.
After adding 1000 ppm of calcium chloride, 100 ppm of additive [I] was added to this liquid. This solution was stirred for 5 minutes, adjusted to pH 7 with sodium hydroxide, and then solid-liquid separated. When the residual fluorine concentration of the treated water was measured, 4.
It was 1 ppm. The fluoride ion concentration when treated with calcium chloride alone without adding the additive [I] was 44.5 ppm. Moreover, the flocs at that time were very small and in a colloidal form, and even if a polymer flocculant was added, grown flocs could not be obtained. On the other hand, when the additive [I] was added, grown flocs could be obtained without adding the polymer flocculant. Furthermore, by adding 3 ppm of a polymer flocculant, it was possible to grow stronger and more stable flocs. in this way,
The remarkable effect of the additive [I] was observed on the floc formation state and the effect of removing the fluorine ion concentration.
【0022】実施例2
実施例1において、塩化第一鉄(工業用)37.5wt
%水溶液を水酸化ナトリウムでpH1に調整後、アルギ
ン酸ナトリウム4.8重量%添加し3時間攪拌して得ら
れた添加剤[Ia]を、添加剤[I]の代わりに用いて
実験を行った結果、同じ処理効果が認められた。Example 2 In Example 1, ferrous chloride (for industrial use) 37.5 wt
% Aqueous solution was adjusted to pH 1 with sodium hydroxide, 4.8% by weight of sodium alginate was added, and the mixture was stirred for 3 hours. Then, the additive [Ia] obtained was used in place of the additive [I] to conduct an experiment. As a result, the same treatment effect was recognized.
【0023】実施例3
実施例1において、塩化第二鉄(試薬)20wt%水溶
液を80℃以上で3時間攪拌後、アルギン酸ナトリウム
2.4重量%添加し3時間攪拌して得られた添加剤[I
I]を、添加剤[I]の代わりに用いて実験を行った結
果、同じ処理効果が認められた。Example 3 Additive obtained in Example 1 by stirring 20 wt% aqueous solution of ferric chloride (reagent) at 80 ° C. or higher for 3 hours, then adding 2.4 wt% of sodium alginate and stirring for 3 hours. [I
As a result of conducting an experiment using I] instead of the additive [I], the same treatment effect was observed.
【0024】実施例4
実施例1において、塩化第二鉄(試薬)20wt%水溶
液にアルギン酸ナトリウム2.4重量%添加し3時間攪
拌して得られた添加剤[IIa]を、添加剤[I]の代わ
りに用いて実験を行った結果、同じ処理効果が認められ
た。Example 4 In Example 1, the additive [IIa] obtained by adding 2.4% by weight of sodium alginate to a 20 wt% aqueous solution of ferric chloride (reagent) and stirring for 3 hours was added to the additive [I ], The same treatment effect was recognized as a result of experiment.
【0025】実施例5
アニオン基含有親水性高分子物質12重量%(アルギン
酸ナトリウム(Pronova Biopolymer
社製、マンヌロン酸(M)とグルロン酸(G)とのモル
比[M]/[G]:1/1)と硫酸第一鉄・7水和物8
8重量%からなる添加剤[III]50ppmを、上記の
フッ素モデル排水に塩化カルシウム1000ppm添加
し30分攪拌後に添加した。固液分離後フッ素濃度を測
定したところ、4.2ppmであった。Example 5 12% by weight of anionic group-containing hydrophilic polymer (sodium alginate (Pronova Biopolymer)
Manufactured by the company, the molar ratio of mannuronic acid (M) and guluronic acid (G) [M] / [G]: 1/1) and ferrous sulfate heptahydrate 8
50 ppm of the additive [III] consisting of 8% by weight was added to the above fluorine model wastewater after adding 1000 ppm of calcium chloride and stirring for 30 minutes. The fluorine concentration measured after solid-liquid separation was 4.2 ppm.
【0026】実施例6
フッ素433pmとアンモニアを含む実工場排水(pH
4.1)に水酸カルシウムをpH10.0になるまで添
加し30分間攪拌した。次に、添加剤[I]を100p
pm添加後、アニオン凝集剤を4ppm添加して5分間
攪拌後、固液分離した。そのときのフッ素濃度を測定し
たところ、5.21ppmであった。Example 6 Wastewater from an actual plant containing 433 pm of fluorine and ammonia (pH
Calcium hydroxide was added to 4.1) until the pH reached 10.0, and the mixture was stirred for 30 minutes. Next, add 100 p of additive [I]
After the addition of pm, 4 ppm of an anionic coagulant was added, and the mixture was stirred for 5 minutes, followed by solid-liquid separation. The fluorine concentration at that time was measured and found to be 5.21 ppm.
【0027】実施例7
実施例6で添加剤[I]の代わりに、添加剤[Ia]、
[II]、[IIa]、[III]のいずれを用いても同様の
フッ素除去率が得られた。Example 7 Instead of the additive [I] in Example 6, the additive [Ia],
Similar fluorine removal rates were obtained using any of [II], [IIa], and [III].
【0028】実施例8
フッ素イオン濃度20ppmのモデル排水にポリ塩化ア
ルミニウム(PAC)をAlとして50ppm添加し5
分攪拌後、添加剤[I]を100ppm添加した。この
溶液を5分間攪拌後、水酸化ナトリウムでpH7に調整
してから、アニオン凝集剤2ppm添加後固液分離し
た。処理水の残存フッ素濃度を測定したところ、3.5
ppmであった。Example 8 Polyaluminum chloride (PAC) was added to the model waste water having a fluorine ion concentration of 20 ppm as Al in an amount of 50 ppm to obtain 5
After stirring for minutes, 100 ppm of the additive [I] was added. The solution was stirred for 5 minutes, adjusted to pH 7 with sodium hydroxide, added with 2 ppm of an anionic flocculant, and subjected to solid-liquid separation. When the residual fluorine concentration of the treated water was measured, it was 3.5
It was ppm.
【0029】実施例9
上記のフッ素モデル排水にアルミン酸ソーダをAlとし
て50ppm添加し5分攪拌後、添加剤[I]を100
ppm添加した。この溶液を5分間攪拌後、水酸化ナト
リウムでpH7に調整してから、アニオン凝集剤5pp
m添加後固液分離した。処理水の残存フッ素濃度を測定
したところ、3.3ppmであった。Example 9 50 ppm of sodium aluminate as Al was added to the above fluorine model waste water and stirred for 5 minutes, and then 100 parts of the additive [I] was added.
ppm was added. After stirring this solution for 5 minutes, adjust the pH to 7 with sodium hydroxide, and then add 5 pp of anionic coagulant.
After the addition of m, solid-liquid separation was performed. When the residual fluorine concentration in the treated water was measured, it was 3.3 ppm.
【0030】実施例10
上記のフッ素モデル排水に硫酸アルミニウムをAlとし
て50ppm添加し5分攪拌後、添加剤[I]を100
ppm添加した。この溶液を5分間攪拌後、水酸化ナト
リウムでpH7に調整してから、アニオン凝集剤3pp
m添加後固液分離した。処理水の残存フッ素濃度を測定
したところ、4.6ppmであった。Example 10 50 ppm of aluminum sulfate as Al was added to the above fluorine model waste water and stirred for 5 minutes, and then 100 parts of the additive [I] was added.
ppm was added. After stirring this solution for 5 minutes, the pH was adjusted to 7 with sodium hydroxide, and then the anionic flocculant 3 pp was added.
After the addition of m, solid-liquid separation was performed. When the residual fluorine concentration in the treated water was measured, it was 4.6 ppm.
【0031】実施例11
実施例6〜8の添加剤[I]の代わりに、添加剤[I
a]、[II]、[IIa]、[III]のいずれを用いても
同様のフッ素除去率が得られた。Example 11 Instead of the additive [I] of Examples 6 to 8, the additive [I] was used.
Similar fluorine removal rates were obtained using any of a], [II], [IIa], and [III].
【0032】実施例12
フッ素イオン濃度20ppmのモデル排水に、添加剤
[I]を100ppm添加し5分攪拌後、PACをAl
として50ppm添加した。この溶液を5分間攪拌後、
水酸化ナトリウムでpH7に調整してから、アニオン凝
集剤2ppm添加後固液分離した。処理水の残存フッ素
濃度を測定したところ、3.7ppmであった。Example 12 100 ppm of the additive [I] was added to model wastewater having a fluorine ion concentration of 20 ppm, and the mixture was stirred for 5 minutes.
Was added as 50 ppm. After stirring this solution for 5 minutes,
After adjusting the pH to 7 with sodium hydroxide, solid-liquid separation was performed after adding 2 ppm of an anionic coagulant. When the residual fluorine concentration of the treated water was measured, it was 3.7 ppm.
【0033】実施例13
上記のフッ素モデル排水に、添加剤[I]を100pp
m添加し5分攪拌後、アルミン酸ソーダをAlとして5
0ppm添加した。この溶液を5分間攪拌後、水酸化ナ
トリウムでpH7に調整してから、アニオン凝集剤5p
pm添加後固液分離した。処理水の残存フッ素濃度を測
定したところ、3.2ppmであった。Example 13 100 pp of the additive [I] was added to the above fluorine model wastewater.
After adding m and stirring for 5 minutes, use sodium aluminate as Al
0 ppm was added. After stirring this solution for 5 minutes, the pH was adjusted to 7 with sodium hydroxide, and then the anionic flocculant 5 p
After adding pm, solid-liquid separation was performed. The residual fluorine concentration of the treated water was measured and found to be 3.2 ppm.
【0034】実施例14
上記のフッ素モデル排水に、添加剤[I]を100pp
m添加し5分攪拌後、硫酸アルミニウムをAlとして5
0ppm添加した。この溶液を5分間攪拌後、水酸化ナ
トリウムでpH7に調整してから、アニオン凝集剤3p
pm添加後固液分離した。処理水の残存フッ素濃度を測
定したところ、3.8ppmであった。Example 14 100 pp of the additive [I] was added to the above fluorine model wastewater.
After adding m and stirring for 5 minutes, aluminum sulfate was changed to Al to 5
0 ppm was added. After stirring this solution for 5 minutes, the pH was adjusted to 7 with sodium hydroxide, and then the anionic flocculant 3 p
After adding pm, solid-liquid separation was performed. When the residual fluorine concentration in the treated water was measured, it was 3.8 ppm.
【0035】実施例15
実施例12〜14で添加剤[I]の代わりに、添加剤
[Ia]、[II]、[IIa]、[III]のいずれを用いても
同様のフッ素除去率が得られた。Example 15 Similar fluorine removal rates were obtained by using any of the additives [Ia], [II], [IIa] and [III] instead of the additive [I] in Examples 12 to 14. Was obtained.
【0036】実施例16
フッ素イオン濃度20ppmのモデル排水に、添加剤
[I]を100ppmとPCAをAlとして50ppm
を同時に添加し5分間攪拌後、水酸化ナトリウムでpH
7に調整してから、アニオン凝集剤2ppm添加後固液
分離した。処理水の残存フッ素濃度を測定したところ、
4.1ppmであった。Example 16 100 ppm of additive [I] and 50 ppm of PCA as Al were added to model wastewater having a fluorine ion concentration of 20 ppm.
Is added at the same time and stirred for 5 minutes, then pH is adjusted with sodium hydroxide
After adjusting to 7, the solid-liquid separation was performed after adding 2 ppm of the anionic coagulant. When the residual fluorine concentration of the treated water was measured,
It was 4.1 ppm.
【0037】実施例17
上記のフッ素モデル排水に、添加剤[I]を100pp
mとアルミン酸ソーダをAlとして50ppmを同時に
添加し5分間攪拌後、水酸化ナトリウムでpH7に調整
してから、アニオン凝集剤5ppm添加後固液分離し
た。処理水の残存フッ素濃度を測定したところ、3.8
ppmであった。Example 17 100 pp of the additive [I] was added to the above fluorine model wastewater.
m and sodium aluminate were added at 50 ppm at the same time as Al, stirred for 5 minutes, adjusted to pH 7 with sodium hydroxide, added with 5 ppm of an anionic flocculant, and subjected to solid-liquid separation. When the residual fluorine concentration of the treated water was measured, it was 3.8.
It was ppm.
【0038】実施例18
上記のフッ素モデル排水に、添加剤[I]を100pp
mと硫酸アルミニウムをAlとして50ppmを同時に
添加し5分間攪拌後、水酸化ナトリウムでpH7に調整
してから、アニオン凝集剤3ppm添加後固液分離し
た。処理水の残存フッ素濃度を測定したところ、3.6
ppmであった。Example 18 100 pp of the additive [I] was added to the above fluorine model wastewater.
m and aluminum sulfate as Al at 50 ppm were added at the same time, stirred for 5 minutes, adjusted to pH 7 with sodium hydroxide, added with 3 ppm of anionic coagulant, and subjected to solid-liquid separation. When the residual fluorine concentration of the treated water was measured, it was 3.6.
It was ppm.
【0039】実施例19
実施例16〜18で添加剤[I]の代わりに、添加剤
[Ia]、[II]、[IIa]、[III]のいずれを用いても
同様のフッ素除去率が得られた。Example 19 The same fluorine removal rate was obtained by using any of the additives [Ia], [II], [IIa] and [III] in place of the additive [I] in Examples 16 to 18. Was obtained.
フロントページの続き (73)特許権者 000005979 三菱商事株式会社 東京都千代田区丸の内2丁目6番3号 (74)上記3名の代理人 100074505 弁理士 池浦 敏明 (72)発明者 辰巳 憲司 茨城県つくば市小野川16番3 工業技術 院資源環境技術総合研究所内 (72)発明者 和田 愼二 茨城県つくば市小野川16番3 工業技術 院資源環境技術総合研究所内 (72)発明者 湯川 恭啓 茨城県つくば市二ノ宮2丁目3−10セン チュリー時計台1 205号 (56)参考文献 特開 昭50−15356(JP,A) 特開 昭50−105578(JP,A) 特開 平3−109993(JP,A) 特開 昭56−70893(JP,A) (58)調査した分野(Int.Cl.7,DB名) C02F 1/58 C02F 1/56 Continuation of front page (73) Patent holder 000005979 Mitsubishi Corporation 2-3-6 Marunouchi, Chiyoda-ku, Tokyo (74) Attorney of the above 3 persons 100074505 Attorney Toshiaki Ikeura (72) Inventor Kenji Tatsumi Tsukuba, Ibaraki Prefecture 16-3 Onogawa City, Institute of Industrial Science and Technology (72) Inventor, Shinji Wada, Tsukuba City, Ibaraki Prefecture 16-3 Onogawa Institute, Institute of Natural Resources and Environment (72) Inventor, Yasuhiro Yukawa, Tsukuba, Ibaraki Prefecture Ninomiya 2-chome Century Clock Tower No. 1 205 (56) Reference JP-A-50-15356 (JP, A) JP-A-50-105578 (JP, A) JP-A-3-109993 (JP, A ) JP-A-56-70893 (JP, A) (58) Fields investigated (Int.Cl. 7 , DB name) C02F 1/58 C02F 1/56
Claims (6)
を除去する方法において、該水中にカルシウム化合物を
添加して該溶存フッ素イオンを該カルシウム化合物と反
応させて不溶化させた後、非溶解状態のアニオン基含有
親水性高分子物質と鉄塩からなる添加剤を添加し、該ア
ニオン基含有親水性高分子物質を水中で非溶解状態で分
散させ、かつ該鉄塩を水中に溶解させることを特徴とす
るフッ素イオンの除去方法。1. A method for removing dissolved fluorine ions contained in water to be treated, wherein a calcium compound is added to the water to cause the dissolved fluorine ions to react with the calcium compound to insolubilize it, and then a non-dissolved state is obtained. An additive comprising an anion group-containing hydrophilic polymer substance and an iron salt is added, the anion group-containing hydrophilic polymer substance is dispersed in water in a non-dissolved state, and the iron salt is dissolved in water. And a method for removing fluorine ions.
を除去する方法において、該水中に水酸化アルミニウム
形成剤と、非溶解状態のアニオン基含有親水性高分子物
質と鉄塩からなる添加剤とを添加し、該水中に該水酸化
アルミニウム形成剤からの水酸化アルミニウムを形成さ
せるとともに、該アニオン基含有親水性高分子物質を水
中で非溶解状態で分散させ、かつ該鉄塩を水中に溶解さ
せることを特徴とするフッ素イオンの除去方法。2. A method for removing dissolved fluorine ions contained in water to be treated, comprising: an aluminum hydroxide forming agent in the water; an additive consisting of a non-dissolved anionic group-containing hydrophilic polymer and an iron salt. Is added to form aluminum hydroxide from the aluminum hydroxide forming agent in the water, the anionic group-containing hydrophilic polymer is dispersed in water in an insoluble state, and the iron salt is dissolved in water. A method for removing fluorine ions, which comprises:
ン濃度が30mg/l以上であり、該水中から溶存フッ
素イオンを除去した後の処理水のpHが7〜8であり、
該処理水中に含まれる溶存フッ素イオン濃度が8mg/
l以下である請求項1の方法。3. The concentration of dissolved fluorine ions contained in the water to be treated is 30 mg / l or more, and the pH of the treated water after removing the dissolved fluorine ions from the water is 7 to 8.
The concentration of dissolved fluorine ions contained in the treated water is 8 mg /
The method of claim 1, which is 1 or less.
が10〜30mg/lであり、該水中から溶存フッ素イ
オンを除去した後の処理水のpHが7〜8であり、該処
理水中に含まれる溶存フッ素イオン濃度が8mg/l以
下である請求項2の方法。4. The concentration of dissolved fluorine ions contained in the water is 10 to 30 mg / l, the pH of the treated water after removing the dissolved fluorine ions from the water is 7 to 8, and the dissolved water contained in the treated water. The method according to claim 2, wherein the dissolved fluorine ion concentration is 8 mg / l or less.
加量が、水中に添加したカルシウム化合物又は水酸化ア
ルミニウム形成剤100重量部当り、0.1〜10重量
部である請求項1〜4のいずれかの方法。5. The addition amount of the anionic group-containing hydrophilic polymer substance is 0.1 to 10 parts by weight per 100 parts by weight of the calcium compound or aluminum hydroxide forming agent added in water. Either way.
水性高分子物質100重量部当り、1〜10000重量
部の割合である請求項1〜5のいずれかの方法。6. The method according to claim 1, wherein the amount of the iron salt added is 1 to 10000 parts by weight based on 100 parts by weight of the anionic group-containing hydrophilic polymer.
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EP1493716A4 (en) * | 2002-03-25 | 2007-10-03 | Mitsubishi Gas Chemical Co | Method of wastewater treatment |
JP4232019B2 (en) * | 2003-09-16 | 2009-03-04 | 三菱瓦斯化学株式会社 | Treatment method for fluorine-containing wastewater |
JP4594627B2 (en) * | 2004-02-10 | 2010-12-08 | 中外写真薬品株式会社 | Treatment method for fluorine-containing wastewater. |
JP4661665B2 (en) * | 2006-04-06 | 2011-03-30 | 日本錬水株式会社 | Method for coagulating sedimentation of ion-containing wastewater |
FR2958927B1 (en) * | 2010-04-20 | 2012-05-25 | Otv Sa | METHOD FOR WATER TREATMENT BY FLOCCULATION USING A FLOCCULANT AGENT OF NATURAL ORIGIN |
CN113683729B (en) * | 2021-08-24 | 2023-08-18 | 武汉科创伟业生物科技有限公司 | Composite coagulant and preparation method and application thereof |
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