JP2013006159A - Sludge dehydration treatment method - Google Patents

Sludge dehydration treatment method Download PDF

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JP2013006159A
JP2013006159A JP2011141685A JP2011141685A JP2013006159A JP 2013006159 A JP2013006159 A JP 2013006159A JP 2011141685 A JP2011141685 A JP 2011141685A JP 2011141685 A JP2011141685 A JP 2011141685A JP 2013006159 A JP2013006159 A JP 2013006159A
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sludge
soluble polymer
water
amidine
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JP5961934B2 (en
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Hisanori Goto
久典 後藤
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Dianitrix Co Ltd
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Abstract

PROBLEM TO BE SOLVED: To provide a sludge dehydration treatment method capable of obtaining a separation liquid reduced in SS content and a dehydrated cake low in water content by setting sewage sludge with an M alkalinity of 1,000 mg/l or below and a supernatant colloid value of -0.5 to 0.3 meq/l as objective sludge and stably holding the sufficient particle size and strength of the sludge over a long period of time to form flocs good in water drainage and enhanced in dehydration properties.SOLUTION: As a sludge dehydrating agent, a specific amidine water soluble polymer (A) and a specific amphoteric water soluble polymer (B) with a reducing viscosity in 1N saline water of 0.1-10 dl/g are used.

Description

本発明は、汚泥脱水処理方法に関し、詳しくは、通常の汚泥脱水剤では凝集フロックが成長せず微細な凝集フロックしか形成できない汚泥を対象とした汚泥脱水処理方法に関する。   TECHNICAL FIELD The present invention relates to a sludge dewatering treatment method, and more particularly, to a sludge dewatering treatment method for sludge in which agglomerated flocs do not grow and only fine agglomerated flocs can be formed with a normal sludge dewatering agent.

近年、都市下水から発生する汚泥の有機分の高含有化や、汚泥の集中処理における輸送時間増による汚泥の腐敗化により、都市下水の難脱水化がますます進行してきている。一方、脱水ケーキの乾燥、焼却などの最終処分に要するエネルギーの低減のため、下水処理場でケーキ含水率低下が要求される傾向が強くなってきている。そのため、難脱水性汚泥の脱水処理において、ケーキ含水率をより低下させるような優れた性能を有する汚泥脱水剤が求められている。特に、下水消化汚泥のように繊維分の少ない難脱水性汚泥には、従来のカチオン性水溶性ポリマーの単独使用では脱水性能が不十分であり、それに代わる処方として二種以上の凝集剤を混合使用するなどの様々な工夫が提案されてきた。   In recent years, the dewatering of municipal sewage has become more and more advanced due to the increase in the organic content of sludge generated from municipal sewage and the decay of sludge caused by increased transportation time in sludge intensive treatment. On the other hand, in order to reduce the energy required for final disposal such as drying and incineration of dehydrated cakes, there is an increasing tendency to require a reduction in cake moisture content at sewage treatment plants. Therefore, there is a need for a sludge dewatering agent having excellent performance that lowers the moisture content of the cake in the dewatering treatment of hardly dewaterable sludge. In particular, the use of a conventional cationic water-soluble polymer alone is insufficient for dewatering sludge with low fiber content, such as sewage digested sludge, and two or more flocculants are mixed as a prescription instead. Various devices such as use have been proposed.

一方で、ポリアミジン構成単位を含むアミジン系水溶性ポリマーはカチオン価が高いため、優れた凝集性・脱水性を発揮することが知られている。また、他種の凝集剤と混合して用いることで、下水余剰汚泥や腐敗の進行した難脱水性汚泥にも高い性能を示している。例えば、アミジン系水溶性ポリマーと特定の両性水溶性ポリマーを組み合わせた凝集剤が提案され(特許文献1)、アミジン系水溶性ポリマーと両性ポリマーと酸性物質を含む、無機凝結剤の使用量を削減できる凝集剤が提案されている(特許文献2)。更に、アミジン系水溶性ポリマーと2種以上の特定の両性水溶性ポリマーを組み合わせて用いることにより腐敗の進行した沈降し難い難脱水性汚泥を効率よく脱水処理できる汚泥脱水剤が提案されている(特許文献3)。   On the other hand, it is known that an amidine-based water-soluble polymer containing a polyamidine structural unit has a high cation value, and therefore exhibits excellent cohesiveness and dehydrating properties. In addition, by mixing with other types of flocculants, high performance is shown for sewage surplus sludge and non-dewatering sludge that has been spoiled. For example, a flocculant combining an amidine-based water-soluble polymer and a specific amphoteric water-soluble polymer has been proposed (Patent Document 1), and the amount of inorganic coagulant containing an amidine-based water-soluble polymer, an amphoteric polymer and an acidic substance is reduced. A possible flocculant has been proposed (Patent Document 2). Furthermore, a sludge dewatering agent capable of efficiently dewatering the hardly-settling hard-to-settling sludge that has been spoiled by using a combination of an amidine-based water-soluble polymer and two or more specific amphoteric water-soluble polymers has been proposed ( Patent Document 3).

また、下水消化汚泥のように繊維分の低い難脱水性汚泥に対しても、アミジン系水溶性ポリマーと種々の凝集剤との配合凝集剤が提案されている。例えば、無機凝集剤を加えた後、アミジン系水溶性ポリマーと両性水溶性ポリマーとを含む高分子凝集剤を用いることで消化汚泥でも処理ができる提案がなされ(特許文献4)、架橋したカチオン性ポリマーまたは架橋した両性ポリマーを混合して添加することで脱水性能を向上させる提案がなされている(特許文献5)。しかし、これらは消化脱水汚泥の処理を意図したものではあるが、汚泥の状態によっては効果が不十分であり、下水処理場の脱水ケーキ含水率低下の要求を満たすに至っていない。   In addition, blended flocculants of amidine-based water-soluble polymers and various flocculants have also been proposed for non-dewaterable sludge with low fiber content such as sewage digested sludge. For example, after adding an inorganic flocculant, a proposal has been made that even a digested sludge can be treated by using a polymer flocculant containing an amidine-based water-soluble polymer and an amphoteric water-soluble polymer (Patent Document 4). A proposal has been made to improve the dehydration performance by adding a polymer or a cross-linked amphoteric polymer in a mixed manner (Patent Document 5). However, these are intended for treatment of digested and dewatered sludge, but the effect is insufficient depending on the state of the sludge, and the demand for lowering the moisture content of the dewatered cake at the sewage treatment plant has not been met.

特に、下水消化汚泥の中でも、嫌気性消化処理による汚泥有機物の減量化度が低く、腐敗性有機物を多量に含むような汚泥或いは混合生汚泥でも腐敗が進行した汚泥に対しては、アミジン系水溶性ポリマーの単独使用では粒径の小さい凝集フロックしか形成せず、アミジン系水溶性ポリマーの特徴である高い脱水性が見られない傾向がある。さらに前記の各処方を用いても、フロックの成長が見られず、添加量も多量に必要な場合が時として見られる。   In particular, among sewage digested sludge, the amount of sludge organic matter reduced by anaerobic digestion treatment is low, and sludge containing a large amount of spoilage organic matter or mixed raw sludge that has been spoiled is amidine-based water-soluble. When the water-soluble polymer is used alone, only aggregated flocs having a small particle diameter are formed, and there is a tendency that the high dehydration characteristic of the amidine-based water-soluble polymer is not observed. Furthermore, even when each of the above-mentioned prescriptions is used, the growth of floc is not observed, and sometimes a large amount of addition is required.

特開平6−218399号公報JP-A-6-218399 特開平7−223000号公報Japanese Patent Laid-Open No. 7-223000 特開2008−55391号公報JP 2008-55391 A 特開2009−183888JP2009-183888 特開2010−222505号公報JP 2010-222505 A

上記の様なアミジンの効果が小さい汚泥の特徴を更に検討すると、その特徴は、下水消化汚泥でかつ嫌気性消化処理が不十分なため汚泥有機物の減量化度が低く腐敗性有機物を多量に含むような汚泥や、混合生汚泥で腐敗の進行した汚泥に観られる。そして、分析的には汚泥の固形分を沈降させた上澄み液のアルカリ度(Mアルカリ度)が1000mg/l以下であることや、汚泥上澄みのコロイド分が0meq/l付近であるということである。この様な汚泥種に対してはアミジン系水溶性ポリマー単独では極めて小さな凝集フロックしか形成できず、特にスクリュープレス等の脱水機では高脱水が望めない。さらに公知の処方では効果にばらつきがあり、概して添加量を増やしても凝集フロックの成長が見られない。   Further examination of the characteristics of sludge with a small effect of amidine as described above shows that it is a sewage digested sludge and anaerobic digestion treatment is insufficient, so the degree of sludge organic matter reduction is low and it contains a lot of spoilage organic matter. Such sludge and mixed sludge that has been rotted. And analytically, the alkalinity (M alkalinity) of the supernatant liquid from which the solid content of the sludge is sedimented is 1000 mg / l or less, and the colloidal content of the sludge supernatant is around 0 meq / l. . For such sludge species, the amidine-based water-soluble polymer alone can form only extremely small flocs, and high dehydration cannot be expected especially with a dehydrator such as a screw press. Furthermore, the effects of known formulations vary, and in general, even when the amount added is increased, the growth of aggregated floc is not observed.

前述の先行技術においては、両性水溶性ポリマーの分子量に関しては規定が無く、概して、ある下限以上の分子量の両性水溶性ポリマー、即ち分子量が高いことを推奨している。これは凝集フロックの成長を促すに当たっては一般的には好ましいと考えられる方向ではあるが、上記の性状の汚泥種に対しては効果が見られない。   In the above-mentioned prior art, there is no definition regarding the molecular weight of the amphoteric water-soluble polymer, and it is generally recommended that the amphoteric water-soluble polymer having a molecular weight of a certain lower limit or higher, that is, the molecular weight is high. This is generally considered to be a preferable direction for promoting the growth of coagulated flocs, but no effect is seen against the above-mentioned sludge species.

本発明者らは、上記実情に鑑み、鋭意探索の結果、次のような知見を得た。すなわち、上記の性状の汚泥に関しては、アミジン凝集剤は効果的に吸着はするものの、更にそれが両性水溶性ポリマーとコンプレックスを形成して凝集フロックを成長させる段階での成長が遅い。しかしながら、従来の常識とは逆に、アミジン系水溶性ポリマーに低粘度の両性水溶性ポリマーを配合することで、上記凝集フロック成長過程の混合・反応が効率よく進み、凝集フロックが水分を包含することなく強度に優れた凝集フロックが形成され、汚泥の脱水処理における汚泥脱水剤の脱水性能が改善される。   In view of the above circumstances, the present inventors have obtained the following knowledge as a result of intensive search. That is, with respect to the sludge having the above properties, the amidine flocculant adsorbs effectively, but further, it grows slowly at the stage where it forms a complex with the amphoteric water-soluble polymer to grow the flocs. However, contrary to conventional common sense, by mixing an amidine-based water-soluble polymer with a low-viscosity amphoteric water-soluble polymer, the agglomerated floc growth process can be efficiently mixed and reacted, and the agglomerated floc contains moisture. Thus, a floc floc excellent in strength is formed, and the dewatering performance of the sludge dewatering agent in the sludge dewatering treatment is improved.

本発明は、上記の知見に基づき達成されたものであり、その要旨は、Mアルカリ度が1000mg/l以下で且つ上澄みのコロイド値が−0.5〜0.3meq/lの範囲の下水汚泥に汚泥脱水剤を添加した後に脱水処理する汚泥脱水処理方法において、汚泥脱水剤として、以下に記載のアミジン系水溶性ポリマー(A)と両性水溶性ポリマー(B)とから成り、両者の合計質量に対するアミジン系水溶性ポリマー(A)の割合が60〜90質量%、両性水溶性ポリマー(B)の割合が10〜40質量%である汚泥脱水剤を用いることを特徴とする汚泥脱水処理方法に存する。   The present invention has been achieved based on the above findings, and the gist of the present invention is that sewage sludge having an M alkalinity of 1000 mg / l or less and a supernatant colloid value in the range of -0.5 to 0.3 meq / l. In the sludge dewatering method of adding a sludge dewatering agent to the sludge dewatering agent, the sludge dewatering agent is composed of the amidine-based water-soluble polymer (A) and the amphoteric water-soluble polymer (B) described below, and the total mass of both A sludge dewatering treatment method using a sludge dewatering agent having a ratio of the amidine-based water-soluble polymer (A) to 60 to 90% by mass and a ratio of the amphoteric water-soluble polymer (B) to 10 to 40% by mass. Exist.

[アミジン系水溶性ポリマー(A)]
下記一般式(1)で表されるアミジン構成単位及び/又は下記一般式(2)で表されるアミジン構成単位を含有するアミジン系水溶性ポリマー。
[Amidine-based water-soluble polymer (A)]
An amidine-based water-soluble polymer containing an amidine structural unit represented by the following general formula (1) and / or an amidine structural unit represented by the following general formula (2).

Figure 2013006159
(ただし、一般式(1)、(2)中、R、Rはそれぞれ独立に水素原子又はメチル基であり、Xは陰イオンである。)
Figure 2013006159
(However, in general formula (1), (2), R < 1 >, R < 2 > is a hydrogen atom or a methyl group each independently, and X < - > is an anion.)

[両性水溶性ポリマー(B)]
下記一般式(3)で表されるカチオン性構成単位を25〜80モル%、下記一般式(4)で表されるアニオン性構成単位を5〜75モル%、非イオン性構成単位として、(メタ)アクリルアミドモノマー構成単位を70モル%以下の割合で含有する少なくとも一種の両性水溶性ポリマーで、かつ、当該両性水溶性ポリマーを0.1g/dl含む1規定塩化ナトリウム水溶液の25℃における還元粘度が0.1〜10.0dl/gである両性水溶性ポリマー。
[Amphiphilic water-soluble polymer (B)]
The cationic structural unit represented by the following general formula (3) is 25 to 80 mol%, the anionic structural unit represented by the following general formula (4) is 5 to 75 mol%, and the nonionic structural unit is ( Reduced viscosity at 25 ° C. of a 1N aqueous sodium chloride solution containing at least one amphoteric water-soluble polymer containing a meth) acrylamide monomer constituent unit in a proportion of 70 mol% or less and containing 0.1 g / dl of the amphoteric water-soluble polymer. Is an amphoteric water-soluble polymer having a molecular weight of 0.1 to 10.0 dl / g.

Figure 2013006159
(ただし、一般式(3)中、Rは、水素原子又はメチル基であり、Rは、水素原子又は炭素数が1〜4のアルキル基であり、Rは、水素原子又は炭素数が1〜4のアルキル基であり、Rは、炭素数が1〜4のアルキル基又はベンジル基であり、Xは、酸素原子又はNHであり、Yは、Cl、Br、又は1/2SO 2−であり、nは1〜3の整数である。また、一般式(4)中、R、Rは、水素原子又はメチル基又は−COOMを、Bは炭素数0〜2のアルキレン基、フェニル基又は−COOR−又は−CONHR10−を、R、R10は炭素数2〜6のアルキレン基を、Zは−COO−又は−SO−を、Mは水素イオンその他の陽イオンを表す。)
Figure 2013006159
(In the general formula (3), R 3 is a hydrogen atom or a methyl group, R 4 is a hydrogen atom or a carbon number from 1 to 4 alkyl groups, R 5 is a hydrogen atom or a carbon atoms Is an alkyl group having 1 to 4 carbon atoms, R 6 is an alkyl group having 1 to 4 carbon atoms or a benzyl group, X is an oxygen atom or NH, Y is Cl , Br , or 1 / 2SO 4 2- , n is an integer of 1 to 3. In the general formula (4), R 7 and R 8 are a hydrogen atom, a methyl group, or —COOM + , and B is a carbon number. 0 to 2 alkylene group, phenyl group or —COOR 9 — or —CONHR 10 —, R 9 and R 10 each represent an alkylene group having 2 to 6 carbon atoms, Z represents —COO— or —SO 3 —, M + Represents a hydrogen ion or other cation.)

本発明の汚泥脱水処理方法によれば、従来技術では脱水処理が困難である特定性状の下水汚泥(Mアルカリ度が1000mg/l以下で且つ上澄みのコロイド値が−0.5〜0.3meq/lの範囲の下水汚泥)を対象汚泥とし、長期間安定して十分な粒径と強度を持ち、従って、水切れが良好で脱水性の高い凝集フロックを形成させることができるため、SS量が少ない分離液及び含水率の低い脱水ケーキが得られる。   According to the sludge dewatering method of the present invention, sewage sludge having a specific property that is difficult to dewater with the prior art (M alkalinity is 1000 mg / l or less and the colloid value of the supernatant is -0.5 to 0.3 meq / 1) Sewage sludge) is the target sludge, stable for a long period of time with sufficient particle size and strength, and therefore, it is possible to form coagulated flocs with good water drainage and high dewaterability, so the amount of SS is small A separated liquid and a dehydrated cake with a low water content are obtained.

以下、本発明を詳細に説明する。   Hereinafter, the present invention will be described in detail.

<汚泥脱水剤>
先ず、本発明で用いる汚泥脱水剤について説明する。本発明では、特定のアミジン系水溶性ポリマー(A)と特定の両性水溶性ポリマー(B)とを組み合わせて用いる。
<Sludge dewatering agent>
First, the sludge dehydrating agent used in the present invention will be described. In the present invention, the specific amidine-based water-soluble polymer (A) and the specific amphoteric water-soluble polymer (B) are used in combination.

アミジン系水溶性ポリマー(A)は、前記一般式(1)で表されるアミジン構成単位及び/又は前記一般式(2)で表されるアミジン構成単位を含有する。アミジン系水溶性ポリマー(A)におけるアミジン構成単位の含有量は、通常30〜90モル%、好ましくは40〜80モル%である。含有量が30〜90モル%であれば、水切れの良好な凝集フロックが形成される。   The amidine-based water-soluble polymer (A) contains an amidine structural unit represented by the general formula (1) and / or an amidine structural unit represented by the general formula (2). The content of the amidine structural unit in the amidine-based water-soluble polymer (A) is usually 30 to 90 mol%, preferably 40 to 80 mol%. If the content is from 30 to 90 mol%, an agglomerated floc with good drainage is formed.

アミジン系水溶性ポリマー(A)の製造方法としては、特に制限はされないが、1級アミノ基又は変換反応により1級アミノ基が生成し得る置換アミノ基を有するエチレン性不飽和モノマーと、アクリロニトリル又はメタアクリロニトリル等のニトリル類とのコポリマーを製造し、当該コポリマー中のシアノ基と1級アミノ基を酸性化反応させてアミジン化する方法が挙げられる。   The method for producing the amidine-based water-soluble polymer (A) is not particularly limited, but an ethylenically unsaturated monomer having a primary amino group or a substituted amino group capable of forming a primary amino group by a conversion reaction, and acrylonitrile or Examples thereof include a method in which a copolymer with nitriles such as methacrylonitrile is produced, and a cyano group and a primary amino group in the copolymer are acidified to be amidined.

上記のエチレン性不飽和モノマーとしては、一般式CH=CR11−NHCOR12(式中、R11は水素原子又はメチル基、R12は炭素数1〜4のアルキル基又は水素原子を表す。)で表わされる化合物が好ましい。コポリマー中において、斯かる化合物に由来する置換アミノ基は、加水分解あるいは加アルコール分解により容易に1級アミノ基に変換される。更に、この1級アミノ基は、隣接したシアノ基と反応してアミジン化する。上記の一般式で表される化合物の具体例としては、N−ビニルホルムアミド(R11=H、R12=H)、N−ビニルアセトアミド(R11=H、R12=CH)等が挙げられる。 Examples of the ethylenically unsaturated monomers, the general formula CH 2 = CR 11 -NHCOR 12 (wherein, R 11 is a hydrogen atom or a methyl group, R 12 represents an alkyl group or a hydrogen atom having 1 to 4 carbon atoms. ) Is preferred. In the copolymer, substituted amino groups derived from such compounds are easily converted to primary amino groups by hydrolysis or alcoholysis. Furthermore, this primary amino group reacts with an adjacent cyano group to be amidineated. Specific examples of the compound represented by the above general formula include N-vinylformamide (R 11 = H, R 12 = H), N-vinylacetamide (R 11 = H, R 12 = CH 3 ) and the like. It is done.

前記コポリマーにおけるエチレン性不飽和モノマーとニトリル類との使用割合(モル比)は、通常20:80〜80:20、好ましくは40:60〜60:40である。   The use ratio (molar ratio) of the ethylenically unsaturated monomer and the nitrile in the copolymer is usually 20:80 to 80:20, preferably 40:60 to 60:40.

アミジン系水溶性ポリマー(A)は、最も典型的には、上記で説明したところに従い、N−ビニルホルムアミドとアクリロニトリルとを共重合させ、生成したコポリマーを、塩酸の存在下、加熱し加水分解で生成したアミノ基と隣接するシアノ基からアミジン構成単位を形成させることにより製造される。この場合、共重合に供するN−ビニルホルムアミドとアクリロニトリルとのモル比、及びコポリマーのアミジン化条件を選択することにより、各種の組成を持つアミジン系水溶性ポリマー(A)が得られる。なお、アミジン系水溶性ポリマー(A)としては、入手し易い市販品から選択使用しても良い。   Most typically, the amidine-based water-soluble polymer (A) is obtained by copolymerizing N-vinylformamide and acrylonitrile as described above, and heating the resulting copolymer in the presence of hydrochloric acid for hydrolysis. It is produced by forming an amidine structural unit from a cyano group adjacent to the produced amino group. In this case, the amidine-based water-soluble polymer (A) having various compositions can be obtained by selecting the molar ratio of N-vinylformamide and acrylonitrile to be used for copolymerization and the amidination conditions of the copolymer. The amidine-based water-soluble polymer (A) may be selected from commercially available products.

両性水溶性ポリマー(B)は、カチオン性構成単位として、基本的には前記一般式(3)で表される構成単位を含有するポリマーである。カチオン性構成単位としては、例えば、カチオン性モノマーであるジアルキルアミノアルキル(メタ)アクリレート及びその塩もしくはアルキルクロライド4級物に由来するカチオン性構成単位、又はジアルキルアミノアルキル(メタ)アクリアミドおよびその塩もしくはアルキルクロライド4級化物に由来するカチオン性構成単位が挙げられる。特に、ジアルキルアミノアルキル(メタ)アクリレート(塩)又はそのアルキルクロライド4級物が好ましい。モノマーは、カチオン性モノマー1種を単独で用いても良く、2種類以上を併用しても良い。   The amphoteric water-soluble polymer (B) is basically a polymer containing a structural unit represented by the general formula (3) as a cationic structural unit. Examples of the cationic structural unit include, for example, a cationic structural unit derived from a dialkylaminoalkyl (meth) acrylate that is a cationic monomer and a salt thereof or an alkyl chloride quaternary product, or a dialkylaminoalkyl (meth) acrylamide and a salt thereof. Examples include cationic structural units derived from alkyl chloride quaternized compounds. In particular, dialkylaminoalkyl (meth) acrylate (salt) or an alkyl chloride quaternary product thereof is preferable. As the monomer, one type of cationic monomer may be used alone, or two or more types may be used in combination.

両性水溶性ポリマー(B)におけるカチオン性構成単位の含有量は、通常25〜80モル%、好ましくは25〜50モル%である。また、当該カチオン性構成単位としては、全構成単位中の割合として、少なくともジメチルアミノエチルアクリレートの塩化メチル4級塩モノマー構成単位を25〜80モル%、並びにジメチルアミノエチルメタクリレートの塩化メチル4級塩モノマー構成単位を0〜30モル%含有することが好ましい。このような構成単位を含有する両性水溶性ポリマー(B)は、水切れが良好で、フロック強度の強い凝集フロックを形成し得る。   The content of the cationic structural unit in the amphoteric water-soluble polymer (B) is usually 25 to 80 mol%, preferably 25 to 50 mol%. In addition, as the cationic structural unit, at least 25 to 80 mol% of a methyl chloride quaternary salt monomer structural unit of dimethylaminoethyl acrylate and a methyl chloride quaternary salt of dimethylaminoethyl methacrylate as a proportion of all the structural units. It is preferable to contain 0-30 mol% of monomer structural units. The amphoteric water-soluble polymer (B) containing such a constitutional unit can form an agglomerated floc having good water drainage and strong floc strength.

両性水溶性ポリマー(B)は、アニオン性構成単位として、基本的には前記一般式(4)で表される構成単位を含有するポリマーである。アニオン性構成単位としては、例えば、アニオン性モノマーである(メタ)アクリル酸単量体に由来するアニオン性構成単位が挙げられる。両性水溶性ポリマー(B)におけるアニオン性構成単位の含有量は、通常5〜75モル%、好ましくは7〜65モル%である。   The amphoteric water-soluble polymer (B) is basically a polymer containing a structural unit represented by the general formula (4) as an anionic structural unit. As an anionic structural unit, the anionic structural unit derived from the (meth) acrylic acid monomer which is an anionic monomer is mentioned, for example. The content of the anionic structural unit in the amphoteric water-soluble polymer (B) is usually 5 to 75 mol%, preferably 7 to 65 mol%.

両性水溶性ポリマー(B)は、上記カチオン性モノマーと上記アニオン性モノマーの他に非イオン性モノマーを併用しても良い。非イオン性モノマーとしては(メタ)アクリルアミドが挙げられる。両性水溶性ポリマー(B)における非イオン性構成単位の含有量は通常70モル%以下である。   The amphoteric water-soluble polymer (B) may be used in combination with a nonionic monomer in addition to the cationic monomer and the anionic monomer. Nonionic monomers include (meth) acrylamide. The content of nonionic structural units in the amphoteric water-soluble polymer (B) is usually 70 mol% or less.

両性水溶性ポリマー(B)は、これが含有するアニオン性構成単位の含有率をM(a)モル%、カチオン性構成単位の含有率をM(c)モル%としたとき、アニオン性構成単位とカチオン性構成単位の含有率の比は汚泥のpHによってその最適値が異なる。具体的には、pH5.50〜6.80の汚泥の場合、M(a)/M(c)は、通常0.50〜2.00、好ましくは0.75〜1.70である。一方、pH6.50〜7.50の汚泥の場合、M(a)/M(c)は、通常0.25〜1.40、好ましくは0.35〜1.20である。このように最適組成に差がある理由は、pHにより両性水溶性ポリマー(B)が含有するアニオン性構成単位の解離度が異なり、実際に用いる際に最適なアニオン−カチオン比になるためと考えられる。このような構成単位を含有する両性水溶性ポリマー(B)は、水切れが良好で、よりフロック強度の強い凝集フロックを形成し得るため脱水性能が向上しやすい。 The amphoteric water-soluble polymer (B) has an anionic structural unit when the content of the anionic structural unit contained therein is M (a) mol% and the content of the cationic structural unit is M (c) mol%. The optimum ratio of the content ratio of the cationic structural unit varies depending on the pH of the sludge. Specifically, in the case of sludge having a pH of 5.50 to 6.80, M (a) / M (c) is usually 0.50 to 2.00, preferably 0.75 to 1.70. On the other hand, in the case of sludge having a pH of 6.50 to 7.50, M (a) / M (c) is usually 0.25 to 1.40, preferably 0.35 to 1.20. The reason why there is a difference in the optimum composition is that the degree of dissociation of the anionic structural unit contained in the amphoteric water-soluble polymer (B) varies depending on the pH, and the optimum anion-cation ratio is obtained when actually used. It is done. Since the amphoteric water-soluble polymer (B) containing such a structural unit has good water drainage and can form an agglomerated floc having a higher flock strength, the dewatering performance tends to be improved.

また、両性水溶性ポリマー(B)の分子量を示す物性値としては、当該両性水溶性ポリマーを0.1g/dl含む1規定塩化ナトリウム水溶液の25℃における還元粘度が0.1〜10.0dl/gであるが、1.0〜7.5dl/gが好ましい。還元粘度がこの範囲内であれば、水切れが良好で脱水性の高い凝集フロックを形成しうる。   The physical property value indicating the molecular weight of the amphoteric water-soluble polymer (B) is such that the reduced viscosity at 25 ° C. of a 1N aqueous sodium chloride solution containing 0.1 g / dl of the amphoteric water-soluble polymer is 0.1 to 10.0 dl / Although it is g, 1.0-7.5 dl / g is preferable. If the reduced viscosity is within this range, it is possible to form an agglomerated floc having good water drainage and high dewaterability.

本来、汚泥中には生体由来のアニオンもしくは両性の有機高分子成分があり、アミジン系水溶性ポリマーはこれら成分とも反応しコンプレックスを作り、それが汚泥粒子を架橋し、フロックを形成すると考えられる。ところが、本発明が対象とする汚泥の性状においては、汚泥中のアニオン−両性分が少ないため、コンプレックスの生成が少なく、凝集フロックが成長できないと推定される。従って、その機能を両性水溶性ポリマーが代替する場合、通常であれば分子量が大きいほうが汚泥粒子の架橋能力も高いと考えられる。   Originally, sludge contains biologically derived anionic or amphoteric organic polymer components, and the amidine-based water-soluble polymer reacts with these components to form a complex, which crosslinks sludge particles and forms flocs. However, in the properties of sludge targeted by the present invention, it is presumed that since the anion-amphoteric component in the sludge is small, the formation of complex is small and the aggregated floc cannot grow. Therefore, when the amphoteric water-soluble polymer substitutes for the function, it is considered that the higher the molecular weight, the higher the crosslinking ability of the sludge particles.

しかしながら、この場合、逆に分子量が小さいほうが凝集フロックの形成性能が高い。これは分子鎖の広がりよりも分子の拡散速度や反応速度が重要なファクターになっているためと考えられる。そのため、両性水溶性ポリマー(B)は、1規定塩化ナトリウム水溶液の25℃における還元粘度が0.1〜10g/dlの範囲にある場合、水切れが良好で、フロック強度が高い凝集フロックの形成を形成することができる。還元粘度が上記より大きい場合は、その反応速度が遅くなり大きなフロックが形成できず、上記より小さい場合は、架橋能力が小さく、生成した凝集フロックが小さくその強度が弱く、濾過性能も低く脱水ケーキの含水率が高くなる。   However, in this case, conversely, the smaller the molecular weight, the higher the formation performance of aggregated flocs. This is probably because the diffusion rate and reaction rate of molecules are more important factors than the spread of molecular chains. Therefore, the amphoteric water-soluble polymer (B) can form aggregated flocs with good water drainage and high floc strength when the reduced viscosity at 25 ° C. of a 1N aqueous sodium chloride solution is in the range of 0.1 to 10 g / dl. Can be formed. When the reduced viscosity is larger than the above, the reaction rate becomes slow and large flocs cannot be formed. When the reduced viscosity is smaller than the above, the crosslinking ability is small, the generated flocs are small, the strength is weak, the filtration performance is low, and the dehydrated cake. The moisture content of becomes higher.

両性水溶性ポリマー(B)の製造方法は、特に制限されないが、前記のモノマーを水に溶解させたモノマー水溶液を均一なシート状にし、光開始剤を用いて可視光又は紫外光を照射して共重合させる水溶液光重合方法、反応系外部からの熱の影響を受けない断熱条件下でモノマーの水溶液に1種以上の開始剤を加えて重合させ水性ゲル状の重合物を得る断熱重合、非水溶媒中にモノマー水溶液を分散させて重合する分散重合、非水溶媒中で乳化剤を用いてモノマー水溶液を乳化させて重合する乳化重合等の方法が自由に選択できる。光重合、断熱重合等の場合は、ポリマーは水性ゲルとして取得されるので、粉砕、乾燥して粉末にするのが好ましい。   The production method of the amphoteric water-soluble polymer (B) is not particularly limited, but an aqueous monomer solution obtained by dissolving the monomer in water is formed into a uniform sheet, and irradiated with visible light or ultraviolet light using a photoinitiator. Aqueous photopolymerization method for copolymerization, adiabatic polymerization to obtain an aqueous gel polymer by adding one or more initiators to an aqueous monomer solution and polymerizing under adiabatic conditions not affected by heat from outside the reaction system, Methods such as dispersion polymerization in which an aqueous monomer solution is dispersed in an aqueous solvent for polymerization and emulsion polymerization in which an aqueous monomer solution is emulsified with an emulsifier in a non-aqueous solvent for polymerization can be freely selected. In the case of photopolymerization, adiabatic polymerization, etc., the polymer is obtained as an aqueous gel, and therefore, it is preferably pulverized and dried to form a powder.

本発明で用いる汚泥脱水剤は、アミジン系水溶性ポリマー(A)と両性水溶性ポリマー(B)からなるが、凝集フロックの水切れが良好で、フロック強度の強い凝集フロックを形成し得るためには、アミジン系水溶性ポリマー(A)と両性水溶性ポリマー(B)を所定の混合比で用いる必要がある。即ち、混合比は、アミジン系水溶性ポリマー(A)と両性水溶性ポリマー(B)の合計質量に対し、アミジン系水溶性ポリマー(A)60〜90質量%、両性水溶性ポリマー(B)10〜40質量%である。このような混合比は、フロック強度の強い凝集フロックを形成し得るのでより効率的である。   The sludge dehydrating agent used in the present invention is composed of an amidine-based water-soluble polymer (A) and an amphoteric water-soluble polymer (B). In order to form a floc floc with good flocs and good floc strength, It is necessary to use the amidine-based water-soluble polymer (A) and the amphoteric water-soluble polymer (B) at a predetermined mixing ratio. That is, the mixing ratio is 60 to 90% by mass of the amidine-based water-soluble polymer (A) and the amphoteric water-soluble polymer (B) 10 with respect to the total mass of the amidine-based water-soluble polymer (A) and the amphoteric water-soluble polymer (B). -40 mass%. Such a mixing ratio is more efficient because it can form agglomerated flocs with strong floc strength.

<汚泥>
次に、本発明の対象汚泥について説明する。本発明の対象汚泥は、Mアルカリ度が1000mg/l以下で且つ上澄みのコロイド値が−0.5〜0.3meq/lの範囲の下水汚泥である。
<Sludge>
Next, the target sludge of the present invention will be described. The target sludge of the present invention is sewage sludge having an M alkalinity of 1000 mg / l or less and a supernatant colloid value in the range of −0.5 to 0.3 meq / l.

上記のMアルカリ度は、汚泥を3000rpmで5分間、遠心分離にかけ固液分離することで得られる上澄み液についてのアルカリ度である。具体的には、以下の手順にて測定される。   Said M alkalinity is an alkalinity about the supernatant liquid obtained by centrifuging sludge for 5 minutes at 3000 rpm and carrying out solid-liquid separation. Specifically, it is measured by the following procedure.

(1)200mlのトールビーカーに上記の上澄み液20〜50mlを採取する。
(2)N/10塩酸で、pH4.80になるまで滴定する。
(3)下記式でMアルカリ度(mg/l)を計算する。
(1) Collect 20-50 ml of the above supernatant in a 200 ml tall beaker.
(2) Titrate with N / 10 hydrochloric acid to pH 4.80.
(3) M alkalinity (mg / l) is calculated by the following formula.

Figure 2013006159
Figure 2013006159

上記のコロイド値は、汚泥を3000rpmで5分間、遠心分離にかけ、固液分離することで得られる上澄み液をコロイド滴定して測定されたコロイド値である。具体的には、以下の手順にて測定される。   The above colloid value is a colloid value measured by colloidal titration of a supernatant obtained by centrifuging sludge for 5 minutes at 3000 rpm and solid-liquid separation. Specifically, it is measured by the following procedure.

(1)200mlのトールビーカーに上記の上澄み液10mlを採取し、純水を100ml加える。
(2)さらに1/200NのMgch(メチルグリコールキトサン)溶液を2ml加え、撹拌する。
(3)さらに指示薬としてトルイジンブルーを1〜2滴加える。
(4)撹拌しながら1/400NのPVSK(ポリビニル硫酸カリウム)溶液にて滴定し、液の色が青からピンクに変わる滴定量(B ml)を測定する。
(5)同様に純水100mlのみを、1/400NのPVSK溶液にて滴定し、ブランクの滴定量(A ml)を測定する。
(6)下記式でコロイド値(meq/l)を計算する。
(1) Collect 10 ml of the above supernatant in a 200 ml tall beaker and add 100 ml of pure water.
(2) Further, add 2 ml of 1 / 200N Mgch (methyl glycol chitosan) solution and stir.
(3) Add 1-2 drops of toluidine blue as an indicator.
(4) Titrate with 1 / 400N PVSK (Polyvinyl Potassium Sulphate) solution while stirring and measure the titration (B ml) at which the color of the liquid changes from blue to pink.
(5) Similarly, only 100 ml of pure water is titrated with a 1 / 400N PVSK solution, and a blank titration (A ml) is measured.
(6) The colloid value (meq / l) is calculated by the following formula.

Figure 2013006159
Figure 2013006159

なお、上記のコロイド値は汚泥由来の溶解性ポリアニオン成分を検出していると考えられる。   In addition, it is thought that said colloid value has detected the soluble polyanion component derived from sludge.

この様な性状を有する汚泥は、消化汚泥であれば、本来消化が進めばMアルカリ度3000mg/l程度になるものが嫌気性消化処理による汚泥有機物の減量化度が低く、Mアルカリ度が低い状態にあるものである。また、混合生汚泥であれば、腐敗が進み、上澄み液中の溶解アニオン分量が分解・低下し、コロイド値が0meq/l付近まで上昇しているものである。   If the sludge having such properties is digested sludge, if the digestion proceeds, the M alkalinity of about 3000 mg / l is low in the amount of sludge organic matter reduced by anaerobic digestion treatment, and the M alkalinity is low. Is in state. On the other hand, in the case of mixed raw sludge, the decay proceeds, the amount of dissolved anion in the supernatant liquid is decomposed and lowered, and the colloid value is increased to around 0 meq / l.

<汚泥脱水処理方法>
次に、本発明の汚泥脱水処理方法について説明する。本発明において、汚泥脱水剤の汚泥への添加方法及び凝集フロックの形成方法としては、公知の方法が適用できる。
<Sludge dewatering method>
Next, the sludge dewatering method of the present invention will be described. In the present invention, known methods can be applied as a method for adding a sludge dewatering agent to sludge and a method for forming agglomerated floc.

汚泥脱水剤の添加方法としては、汚泥脱水剤を水に0.05〜0.5質量%の濃度で溶解させた後、汚泥に添加することが好ましい。また、汚泥脱水剤は、アミジン系水溶性ポリマー(A)、両性水溶性ポリマー(B)を混合した1剤型薬剤として添加することが好ましい。場合によっては、汚泥脱水剤を粉末状のまま汚泥に添加しても良い。また、汚泥脱水剤の水への溶解性を向上させるために酸性物質を添加しても良い。酸性物質としては、例えば、スルファミン酸が挙げられる。   As a method for adding the sludge dewatering agent, it is preferable that the sludge dewatering agent is dissolved in water at a concentration of 0.05 to 0.5% by mass and then added to the sludge. Moreover, it is preferable to add a sludge dehydrating agent as a 1 agent type | mold chemical | medical agent which mixed the amidine type water-soluble polymer (A) and the amphoteric water-soluble polymer (B). In some cases, the sludge dehydrating agent may be added to the sludge in a powder form. Further, an acidic substance may be added in order to improve the solubility of the sludge dewatering agent in water. Examples of the acidic substance include sulfamic acid.

凝集を形成した後は、脱水装置を用いて凝集フロックを脱水し、脱水ケーキを得ることにより汚泥脱水処理を完了することができる。脱水機としては、例えば、フィルタープレス型脱水機、スクリュープレス型脱水機、圧入式スクリュープレス型脱水機、真空型脱水機、ベルトプレス型脱水機、遠心型脱水機、多重円板型脱水機等が挙げられるが、特に汚泥のフロック径により脱水効果が大きく影響を受けるスクリュープレス型脱水機や遠心型脱水機において本発明の効果が顕著である。   After the aggregation is formed, the sludge dewatering treatment can be completed by dehydrating the aggregated flocs using a dehydrator and obtaining a dehydrated cake. Examples of dehydrators include filter press dehydrators, screw press dehydrators, press-fit screw press dehydrators, vacuum dehydrators, belt press dehydrators, centrifugal dehydrators, multiple disk dehydrators, etc. In particular, the effect of the present invention is remarkable in a screw press type dehydrator or a centrifugal type dehydrator whose dehydration effect is greatly influenced by the floc diameter of sludge.

汚泥脱水剤の添加量は、汚泥の質、濃度などにより異なり一概には言えないが、大まかな目安として、汚泥の乾燥固形物100質量部に対し、通常0.1〜3.0質量部、好ましくは0.5〜2.0質量部である。汚泥脱水剤の添加量が0.1質量部以上であれば、十分な粒径及び強度を有する凝集フロックが形成されやすい。また、汚泥脱水剤の添加量が3.0質量部以下であれば、汚泥脱水剤が過剰となることで形成される凝集フロックの粒径が小さくなったり、処理速度が遅くなったり、脱水ケーキの含水率が高くなったりすることを抑制しやすい。   The amount of sludge dehydrating agent varies depending on the quality and concentration of the sludge and cannot be generally stated, but as a rough guide, it is usually 0.1 to 3.0 parts by weight with respect to 100 parts by weight of the dried solids of sludge, Preferably it is 0.5-2.0 mass parts. If the added amount of the sludge dehydrating agent is 0.1 parts by mass or more, agglomerated flocs having a sufficient particle size and strength are easily formed. Moreover, if the amount of sludge dehydrating agent added is 3.0 parts by mass or less, the particle size of the aggregated floc formed when the sludge dehydrating agent becomes excessive, the processing speed becomes slow, or the dehydrated cake It is easy to suppress that the moisture content of becomes high.

また、本発明においては、汚泥脱水剤に加えて、無機凝結剤及び/又は有機凝結剤(以下、これらをまとめて単に「凝結剤」という)を併用しても良い。前期の汚泥脱水剤は、凝結剤と併用しても、汚泥に対する脱水効果を十分に発揮できる。無機凝結剤としては、例えば、硫酸バンド、ポリ塩化アルミニウム、塩化第2鉄、硫酸第1鉄、硫酸第2鉄、ポリ鉄(ポリ硫酸鉄、ポリ塩化鉄等)が挙げられる。有機凝結剤としては、例えば、ポリアミン、ポリジアリルジメチルアンモニウムクロライド、ポリジアルキルアミノアルキルメタクリレートのアルキルクロライド4級塩、カチオン性界面活性剤が挙げられる。   In the present invention, an inorganic coagulant and / or an organic coagulant (hereinafter collectively referred to simply as “coagulant”) may be used in combination with the sludge dewatering agent. Even if the sludge dehydrating agent in the previous period is used in combination with a coagulant, it can sufficiently exert the dewatering effect on the sludge. Examples of the inorganic coagulant include sulfuric acid band, polyaluminum chloride, ferric chloride, ferrous sulfate, ferric sulfate, polyiron (polyiron sulfate, polyiron chloride, etc.). Examples of the organic coagulant include polyamine, polydiallyldimethylammonium chloride, alkyl chloride quaternary salt of polydialkylaminoalkyl methacrylate, and cationic surfactant.

凝結剤の添加時期は、特に制限はないが、汚泥脱水剤を添加する前の工程で添加することが好ましい。凝結剤の添加量は、本汚泥脱水剤100質量部に対し、通常5〜3000質量部である。凝結剤の前記添加量が5質量部未満であると、凝結剤を併用した効果が得られ難く、汚泥によっては本汚泥脱水剤の性能が発揮され難くなる。また、凝結剤の添加量が3000質量部を超えると、特に無機凝結剤では添加量の増加に伴って脱水ケーキの含水率が増加する傾向がある。   The timing of adding the coagulant is not particularly limited, but it is preferably added in the step before adding the sludge dewatering agent. The addition amount of the coagulant is usually 5 to 3000 parts by mass with respect to 100 parts by mass of the present sludge dehydrating agent. When the addition amount of the coagulant is less than 5 parts by mass, the effect of using the coagulant is difficult to obtain, and depending on the sludge, the performance of the present sludge dehydrating agent is difficult to be exhibited. Moreover, when the addition amount of a coagulant exceeds 3000 mass parts, especially in an inorganic coagulant, there exists a tendency for the moisture content of a dewatering cake to increase with the increase in addition amount.

以下、実施例及び比較例を示して本発明を詳細に説明するが、本発明はその要旨を超えない限り以下の記載によって限定されるものではない。なお、本実施例における「%」は特に断りのない限り「質量%」を示す。以下の製造例で得られた各ポリマーについては、下記に示す還元粘度の測定を行った。測定には、粉末状の汚泥脱水剤を用いた。   EXAMPLES Hereinafter, although an Example and a comparative example are shown and this invention is demonstrated in detail, this invention is not limited by the following description, unless the summary is exceeded. Note that “%” in this example represents “% by mass” unless otherwise specified. About each polymer obtained by the following manufacture examples, the reduced viscosity shown below was measured. For the measurement, a powdery sludge dehydrating agent was used.

[還元粘度の測定]
1規定塩化ナトリウム水溶液中、0.1g/dlの溶液として25℃でオストワルドの粘度計により測定した。
[Measurement of reduced viscosity]
It measured with the Ostwald viscometer at 25 degreeC as a 0.1g / dl solution in 1N sodium chloride aqueous solution.

本実施例で用いた原料を以下に示す。
[モノマー]
(i)カチオン性モノマー:
N,N−ジメチルアミノエチルアクリレート塩化メチル4級塩(以下、「DME」という)、80%水溶液
(ii)アニオン性モノマー:
アクリル酸(以下、「AA」という)、50%水溶液
(iii)非イオン性モノマー:
(a)アクリルアミド(以下、「AAM」という)、50%水溶液
(b)アクリロニトリル(以下、「AN」という)、純度99%
(c)N−ビニルホルムアミド(以下、「NVF」という)、ダイヤニトリックス社製、91%水溶液
[開始剤]
(i)DAROCUR 1173(以下、「D−1173」という)、Ciba社製
(ii)2,2’−アゾビス(2−アミジノプロパン)2塩酸塩(V−50)(以下、「V−50」という)、和光純薬社製
[連鎖移動剤]
次亜リン酸(以下、「HPA」という)
The raw materials used in this example are shown below.
[monomer]
(I) Cationic monomer:
N, N-dimethylaminoethyl acrylate methyl chloride quaternary salt (hereinafter referred to as “DME”), 80% aqueous solution (ii) anionic monomer:
Acrylic acid (hereinafter referred to as “AA”), 50% aqueous solution (iii) nonionic monomer:
(A) Acrylamide (hereinafter referred to as “AAM”), 50% aqueous solution (b) Acrylonitrile (hereinafter referred to as “AN”), purity 99%
(C) N-vinylformamide (hereinafter referred to as “NVF”), 91% aqueous solution [initiator] manufactured by Dianitricks
(I) DAROCUR 1173 (hereinafter referred to as “D-1173”), (ii) 2,2′-azobis (2-amidinopropane) dihydrochloride (V-50) (hereinafter referred to as “V-50”) manufactured by Ciba. Wako Pure Chemical Industries [Chain Transfer Agent]
Hypophosphorous acid (hereinafter referred to as “HPA”)

<アミジン系水溶性ポリマー(A)の合成>
[製造例1]
攪拌機、窒素導入管、冷却管を備えた内容積50mlの四つ口フラスコにANとNVFの混合物(モル比55:45)6gと蒸留水34gとの混合物を入れた。窒素ガス中攪拌しつつ60℃に昇温し、V−50の0.12gを添加し、更に、3時間保持し、水中にポリマーが析出した懸濁物を得た。懸濁物に蒸留水20g添加し、更に、濃塩酸をポリマーのホルミル基に対し当量添加し100℃で4時間保持し、黄色の高粘度液を得た。これを多量のアセトンに添加し、ポリマーを析出させ、細断し、60℃で1昼夜乾燥後粉砕してアミジン系水溶性ポリマー(A)(ポリマーA)を得た。
<Synthesis of Amidine Water-Soluble Polymer (A)>
[Production Example 1]
A mixture of 6 g of a mixture of AN and NVF (molar ratio 55:45) and 34 g of distilled water was placed in a 50-ml four-necked flask equipped with a stirrer, a nitrogen introduction tube, and a cooling tube. While stirring in nitrogen gas, the temperature was raised to 60 ° C., 0.12 g of V-50 was added, and the mixture was further maintained for 3 hours to obtain a suspension in which the polymer was precipitated in water. 20 g of distilled water was added to the suspension, and concentrated hydrochloric acid was added in an equivalent amount to the formyl group of the polymer and kept at 100 ° C. for 4 hours to obtain a yellow high-viscosity liquid. This was added to a large amount of acetone, the polymer was precipitated, chopped, dried at 60 ° C. for one day and then pulverized to obtain amidine-based water-soluble polymer (A) (polymer A).

ポリマーAを重水に溶解させ、NMRスペクトロメーター(日本電子社製、270MHz)にて13C−NMRスペクトルを測定した。13C−NMRスペクトルの各繰り返し単位に対応したピークの積分値より各単位の組成を算出した。前記一般式(1)及び(2)の構造単位は、区別することなく、その総量として求めた。結果を表1に示す。 Polymer A was dissolved in heavy water, and a 13 C-NMR spectrum was measured with an NMR spectrometer (manufactured by JEOL Ltd., 270 MHz). The composition of each unit was calculated from the integrated value of the peak corresponding to each repeating unit of the 13 C-NMR spectrum. The structural units of the general formulas (1) and (2) were determined as the total amount without distinction. The results are shown in Table 1.

Figure 2013006159
Figure 2013006159

<両性水溶性ポリマー(B)の合成>
[製造例2]
DMEの256.3g、AAの246.0g、AAMの164.0gを、内容積2000ml褐色耐熱瓶に投入し、HPAの82.0gと蒸留水を加え、総質量が820gのモノマー水溶液(DME:AA:AAM=27.0:43.6:29.4(モル%)、モノマー濃度50%)を調製した。このモノマー水溶液を1mol/l硫酸により、pH4.5となるようにPHを調整した。更に、D−1173を、モノマー水溶液の総質量に対して、75ppmとなるように投入し、これに窒素ガスを30分間吹き込みながらモノマー水溶液の温度を20℃に調節した。
<Synthesis of amphoteric water-soluble polymer (B)>
[Production Example 2]
256.3 g of DME, 246.0 g of AA, and 164.0 g of AAM are put into a brown heat-resistant bottle having an internal volume of 2000 ml, 82.0 g of HPA and distilled water are added, and an aqueous monomer solution (DME: total mass of 820 g) is added. AA: AAM = 27.0: 43.6: 29.4 (mol%), monomer concentration 50%) was prepared. The pH of this monomer aqueous solution was adjusted with 1 mol / l sulfuric acid so as to have a pH of 4.5. Furthermore, D-1173 was added so that it might become 75 ppm with respect to the total mass of monomer aqueous solution, and the temperature of monomer aqueous solution was adjusted to 20 degreeC, blowing nitrogen gas into this for 30 minutes.

その後、モノマー水溶液をステンレス反応容器に移し、容器の下方から17℃の水を噴霧しながら、ケミカルランプを用いて、容器の上方から5W/mの照射強度で、表面温度計が40℃になるまで光を照射した。表面温度計が40℃に到達した後は、0.5W/mの照射強度で30分間光を照射した。更に、モノマーの残存量を低減させるために、照射強度を50W/mにして10分間光を照射した。これにより、含水ゲル状のポリマーを得た。以降、製造例1と同様の操作を行い、両性水溶性ポリマー(B)(ポリマーB−1)を得た。得られた含水ゲル状のポリマーを容器から取り出し、小型ミートチョッパーを用いて解砕した後、温度60℃で16時間乾燥した。その後、ウィレー型粉砕機を用いて乾燥したポリマーを粉砕し両性水溶性ポリマー(B)(ポリマーB−1)を得た。 Thereafter, the aqueous monomer solution was transferred to a stainless steel reaction vessel, and sprayed with 17 ° C. water from the bottom of the vessel, using a chemical lamp, the surface thermometer was adjusted to 40 ° C. with an irradiation intensity of 5 W / m 2 from the top of the vessel. Light was irradiated until After the surface thermometer reached 40 ° C., light was irradiated for 30 minutes at an irradiation intensity of 0.5 W / m 2 . Furthermore, in order to reduce the residual amount of monomer, the irradiation intensity was 50 W / m 2 and irradiation was performed for 10 minutes. Thereby, a hydrogel polymer was obtained. Thereafter, the same operation as in Production Example 1 was performed to obtain an amphoteric water-soluble polymer (B) (polymer B-1). The obtained hydrogel polymer was taken out from the container, crushed using a small meat chopper, and then dried at a temperature of 60 ° C. for 16 hours. Thereafter, the dried polymer was pulverized using a Willet pulverizer to obtain an amphoteric water-soluble polymer (B) (polymer B-1).

[製造例3〜21]
製造例2において、各モノマーおよびHPAの量を調節し、表2に記載の割合に変更した以外は、製造例2と同様の操作を行い、両性ポリマー(B)(ポリマーB−2〜21)を得た。
[Production Examples 3 to 21]
In Production Example 2, the amount of each monomer and HPA was adjusted, and the same operation as in Production Example 2 was carried out except that the ratios shown in Table 2 were changed, and the amphoteric polymer (B) (Polymers B-2 to 21) Got.

Figure 2013006159
Figure 2013006159

[実施例1〜8]
(使用汚泥)
下水処理場での混合生汚泥で、次の特性を有する汚泥を用いた。すなわち、JIS規格に記載された分析方法を用いて測定された汚泥のpHが5.70、TSが1.64%、繊維分が9.2%/TS、汚泥を3000rpmで5分間、遠心分離にかけ固液分離することで得られる上澄み液のアルカリ度が538mg/l、コロイド値が−0.3meq/lである汚泥。
[Examples 1 to 8]
(Used sludge)
The mixed raw sludge at the sewage treatment plant was used with the following characteristics. That is, the sludge pH measured using the analysis method described in the JIS standard is 5.70, TS is 1.64%, fiber content is 9.2% / TS, and sludge is centrifuged at 3000 rpm for 5 minutes. Sludge having an alkalinity of 538 mg / l and a colloid value of −0.3 meq / l obtained by subjecting to solid-liquid separation.

(脱水試験)
先ず、500mlビーカーに前記汚泥の300mlを採取した。次いで、表1に記載のポリマーを表4に記載の各混合比率で0.3%に溶解して汚泥脱水剤水溶液を調製し、これを表4に記載の濃度になるよう添加した後、スパチュラにより、攪拌速度:180回転/分、攪拌時間:60秒間の条件下に撹拌混合して凝集フロックを形成させ、汚泥の脱水処理を行った。後述の評価結果を表3に示す。
(Dehydration test)
First, 300 ml of the sludge was collected in a 500 ml beaker. Next, the polymer shown in Table 1 was dissolved in 0.3% at each mixing ratio shown in Table 4 to prepare a sludge dewatering agent aqueous solution, and this was added to the concentration shown in Table 4, and then the spatula Thus, agitation flocs were formed by stirring and mixing under the conditions of stirring speed: 180 rotations / minute, stirring time: 60 seconds, and sludge was dehydrated. The evaluation results described later are shown in Table 3.

[比較例1〜3]
汚泥脱水剤に用いたポリマーを表3に示す通りに変更した以外は、実施例1〜8と同様にして凝集フロックを形成させ、汚泥の脱水処理を行った。後述の評価結果を表3に示す。
[Comparative Examples 1-3]
Except that the polymer used in the sludge dehydrating agent was changed as shown in Table 3, coagulated flocs were formed in the same manner as in Examples 1 to 8, and sludge was dehydrated. The evaluation results described later are shown in Table 3.

[評価方法]
(凝集フロック粒径、濾過性能、濾過水のSS量)
各例において凝集フロックを形成させた後に攪拌を止め、凝集フロック粒径を目視により測定した。その後、予め濾布を敷いたヌッチェに凝集した汚泥を移し、濾過性能(10秒間の濾過水量)を測定した。このとき、60秒間濾過した後の濾過水のSS量を目視により以下の基準で評価した。
[Evaluation method]
(Agglomerated floc particle size, filtration performance, SS amount of filtered water)
In each example, after agglomerated floc was formed, stirring was stopped and the agglomerated floc particle size was measured visually. Thereafter, the coagulated sludge was transferred to Nutsche previously laid with a filter cloth, and the filtration performance (the amount of filtered water for 10 seconds) was measured. At this time, the SS amount of filtrate after filtration for 60 seconds was visually evaluated according to the following criteria.

(濾過水のSS量の評価基準)
− :濾過水がほとんど透き通っており、浮遊物はほぼ見られない(SS量目安:50ppm以下)。
+ :濾過水に一部濁りが見られ、浮遊物がわずかに存在する(SS量目安:50〜100ppm)。
++ :濾過水に部分的に濁りが見られ、浮遊物がところどころ存在する(SS量目安:100〜200ppm)。
+++:濾過水に多数の濁りが見られ、浮遊物が全体的に存在する(SS量目安:200〜500ppm)。
++++:濾過水に全体的に多数の濁りが見られ、浮遊物が全体的に存在し、一部粗大な大きさで存在する(SS量目安:500〜1000ppm)。
× :濾過水が完全に濁り、粗大な浮遊物が多数存在する(SS量目安:1000ppm以上)。
(Evaluation criteria for SS amount of filtered water)
-: The filtered water is almost transparent, and the suspended | floating matter is hardly seen (SS amount standard: 50 ppm or less).
+: Part of the filtered water is turbid, and there is a slight amount of suspended matter (SS amount standard: 50 to 100 ppm).
++: Partly turbidity is seen in the filtered water, and some suspended matter is present (SS amount guideline: 100 to 200 ppm).
+++: Numerous turbidity is observed in the filtered water, and suspended matter is present as a whole (SS amount guideline: 200 to 500 ppm).
++++: Many turbidity is observed in the filtered water as a whole, and the suspended matter is present as a whole, and a part thereof is coarse (SS amount guideline: 500 to 1000 ppm).
X: The filtered water is completely turbid, and there are many coarse suspended matters (SS amount guideline: 1000 ppm or more).

(凝集フロック強度)
濾過濃縮した汚泥(凝集フロック)を濾布上で50回転がし、凝集フロックの強度(団粒性)を以下の基準で評価した。
(Cohesive floc strength)
The filtered and concentrated sludge (aggregated floc) was rotated 50 times on the filter cloth, and the strength (aggregation property) of the aggregated floc was evaluated according to the following criteria.

◎:濾布上で転がすことにより水が切れ、凝集フロックが数個の団子状になる。
○:濾布上で転がすことにより水が切れ、凝集フロックが一塊状になる。
△:濾布上で転がすことにより水が切れるが、凝集フロックが崩れ塊状にならない。
×:濾布上で転がすことにより、凝集汚泥が崩れて流れ、ドロドロになる。
(Double-circle): Water rolls off by rolling on a filter cloth, and agglomeration flocs become several dumplings.
◯: Water is cut off by rolling on the filter cloth, and the aggregated flocs become one lump.
(Triangle | delta): Although water cuts by rolling on a filter cloth, an aggregation floc collapses and it does not become a lump shape.
X: By rolling on a filter cloth, the coagulated sludge flows and becomes muddy.

(脱水ケーキの含水率)
凝集フロック強度の測定後、0.1MPaの圧力でプレス脱水して脱水ケーキを得、その含水率を測定した。含水率の測定は、(財)日本下水道協会編、「下水道試験法上巻1997年度版」p296−297に準拠して行った。
(Water content of dehydrated cake)
After measurement of the aggregate floc strength, press dehydration was performed at a pressure of 0.1 MPa to obtain a dehydrated cake, and the moisture content was measured. The water content was measured according to the Japan Sewerage Association, “Sewerage Test Method, Vol. 1997 edition” p296-297.

Figure 2013006159
Figure 2013006159

表3に示すように、本発明の汚泥脱水剤を用いた実施例1〜8では、粗大なフロックを生成し、脱水ケーキの含水率も低かった。一方、両性系水溶性ポリマー(B)の還元粘度が本願発明の所定割合の範囲から外れた汚泥脱水剤、比較例1〜2では、いずれも生成したフロックが小さく、生成フロックの強度が弱く、濾過性能が低く、脱水ケーキの含水率が高かった。また、両性系水溶性ポリマー(B)を用いない比較例3では、凝集フロックのフロック径が小さく、生成フロックの強度も弱く、ろ過性能も低かった。   As shown in Table 3, in Examples 1 to 8 using the sludge dehydrating agent of the present invention, coarse floc was generated and the moisture content of the dewatered cake was low. On the other hand, in the sludge dewatering agent in which the reduced viscosity of the amphoteric water-soluble polymer (B) is out of the predetermined ratio range of the present invention, Comparative Examples 1 and 2, the generated flocs are both small and the strength of the generated flocs is weak. The filtration performance was low, and the moisture content of the dehydrated cake was high. Further, in Comparative Example 3 in which the amphoteric water-soluble polymer (B) was not used, the floc diameter of the aggregated floc was small, the strength of the generated floc was weak, and the filtration performance was low.

[参考例1]
(使用汚泥)
下水処理場での混合生汚泥で、次の特性を有する汚泥を用いた。すなわち、JIS規格に記載された分析方法を用いて測定された汚泥のpHが5.28、TSが3.57%、繊維分が34.7%/TS、汚泥を3000rpmで5分間、遠心分離にかけ固液分離することで得られる上澄み液のアルカリ度が1010mg/l、コロイド値が−1.0meq/lである汚泥。
[Reference Example 1]
(Used sludge)
The mixed raw sludge at the sewage treatment plant was used with the following characteristics. That is, the sludge pH measured using the analysis method described in the JIS standard is 5.28, TS is 3.57%, fiber content is 34.7% / TS, and sludge is centrifuged at 3000 rpm for 5 minutes. Sludge whose supernatant has a alkalinity of 1010 mg / l and a colloid value of −1.0 meq / l obtained by solid-liquid separation.

(脱水試験)
汚泥脱水剤に用いたポリマーを表4に示す通りに変更した以外は、実施例1〜8と同様の脱水試験を実施した。参考例1における評価結果を表4に示す。
(Dehydration test)
Except that the polymer used in the sludge dehydrating agent was changed as shown in Table 4, the same dehydration test as in Examples 1 to 8 was performed. The evaluation results in Reference Example 1 are shown in Table 4.

Figure 2013006159
Figure 2013006159

表4に示すような性状の汚泥、即ち、腐敗が進んでいない汚泥に対しては、アミジンポリマー単独で強固なフロックを形成する。   For sludge having the properties shown in Table 4, that is, sludge that has not progressed, the amidine polymer alone forms a strong floc.

[実施例9〜16及び比較例4〜6]
(使用汚泥)
下水処理場での消化汚泥で、次の特性を有する汚泥を用いた。すなわち、JIS規格に記載された分析方法を用いて測定された汚泥のpHが7.30、TSが1.6%、繊維分が7.8%/TS、汚泥を3000rpmで5分間、遠心分離にかけ固液分離することで得られる上澄み液のアルカリ度が236.7mg/l、コロイド値が0.3meq/lである汚泥。
[Examples 9 to 16 and Comparative Examples 4 to 6]
(Used sludge)
Digested sludge at a sewage treatment plant was used with the following characteristics. That is, the sludge pH measured using the analysis method described in JIS standard is 7.30, TS is 1.6%, fiber content is 7.8% / TS, and sludge is centrifuged at 3000 rpm for 5 minutes. The sludge whose alkalinity of the supernatant obtained by subjecting to solid-liquid separation over 236.7 mg / l and colloidal value of 0.3 meq / l.

(脱水試験)
汚泥脱水剤に用いたポリマーを表5に示す通りに変更した以外は、実施例1〜8と同様の脱水試験を実施した。実施例9〜16及び比較例4〜6における評価結果を表5に示す。
(Dehydration test)
Except that the polymer used for the sludge dehydrating agent was changed as shown in Table 5, the same dehydration test as in Examples 1 to 8 was performed. The evaluation results in Examples 9 to 16 and Comparative Examples 4 to 6 are shown in Table 5.

Figure 2013006159
Figure 2013006159

表5に示すように、本発明の汚泥脱水剤を用いた実施例9〜16では、粗大なフロックを生成し、脱水ケーキの含水率も低かった。一方、両性系水溶性ポリマー(B)の還元粘度が本願発明の所定割合の範囲から外れた汚泥脱水剤を用いた比較例4〜5では、いずれも生成したフロックが小さく、生成フロックの強度が弱く、濾過性能が低く、脱水ケーキの含水率が高かった。また、両性系水溶性ポリマー(B)を用いない比較例6では、生成フロックがフロック径が小さく、生成フロックの強度も弱く、ろ過性能も低かった。   As shown in Table 5, in Examples 9 to 16 using the sludge dehydrating agent of the present invention, coarse flocs were generated and the moisture content of the dehydrated cake was low. On the other hand, in Comparative Examples 4 to 5 using the sludge dehydrating agent in which the reduced viscosity of the amphoteric water-soluble polymer (B) is out of the predetermined ratio range of the present invention, the generated flocs are small and the strength of the generated flocs is low. It was weak, the filtration performance was low, and the moisture content of the dehydrated cake was high. Further, in Comparative Example 6 in which the amphoteric water-soluble polymer (B) was not used, the generated floc had a small floc diameter, the strength of the generated floc was weak, and the filtration performance was low.

[参考例2]
(使用汚泥)
下水処理場での混合生汚泥で、次の特性を有する汚泥を用いた。すなわち、JIS規格に記載された分析方法を用いて測定された汚泥のpHが7.70、TSが1.7%、繊維分が12.8%/TS、汚泥を3000rpmで5分間、遠心分離にかけ固液分離することで得られる上澄み液のアルカリ度が1290.2mg/l、コロイド値が−0.7meq/lである汚泥。
[Reference Example 2]
(Used sludge)
The mixed raw sludge at the sewage treatment plant was used with the following characteristics. That is, the sludge pH measured using the analysis method described in JIS standard is 7.70, TS is 1.7%, fiber content is 12.8% / TS, and sludge is centrifuged at 3000 rpm for 5 minutes. Sludge having an alkalinity of 1290.2 mg / l and a colloid value of -0.7 meq / l obtained by subjecting to solid-liquid separation.

(脱水試験)
汚泥脱水剤に用いたポリマーを表6に示す通りに変更した以外は、実施例1〜8と同様の脱水試験を実施した。参考例2における評価結果を表6に示す。
(Dehydration test)
Except for changing the polymer used for the sludge dehydrating agent as shown in Table 6, the same dehydration test as in Examples 1 to 8 was performed. The evaluation results in Reference Example 2 are shown in Table 6.

Figure 2013006159
Figure 2013006159

表6に示すように、本発明で規定する範囲を外れた汚泥に関してはアミジン単独で高いフロック強度を有する凝集フロックを形成する。   As shown in Table 6, for sludge outside the range defined in the present invention, an amidine alone forms an aggregate floc having a high floc strength.

Claims (4)

Mアルカリ度が1000mg/l以下で且つ上澄みのコロイド値が−0.5〜0.3meq/lの範囲の下水汚泥に汚泥脱水剤を添加した後に脱水処理する汚泥脱水処理方法において、汚泥脱水剤として、以下に記載のアミジン系水溶性ポリマー(A)と両性水溶性ポリマー(B)とから成り、両者の合計質量に対するアミジン系水溶性ポリマー(A)の割合が60〜90質量%、両性水溶性ポリマー(B)の割合が10〜40質量%である汚泥脱水剤を用いることを特徴とする汚泥脱水処理方法。
[アミジン系水溶性ポリマー(A)]
下記一般式(1)で表されるアミジン構成単位及び/又は下記一般式(2)で表されるアミジン構成単位を含有するアミジン系水溶性ポリマー。
Figure 2013006159
(ただし、一般式(1)、(2)中、R、Rはそれぞれ独立に水素原子又はメチル基であり、Xは陰イオンである。)
[両性水溶性ポリマー(B)]
下記一般式(3)で表されるカチオン性構成単位を25〜80モル%、下記一般式(4)で表されるアニオン性構成単位を5〜75モル%、非イオン性構成単位として、(メタ)アクリルアミドモノマー構成単位を70モル%以下の割合で含有する少なくとも一種の両性水溶性ポリマーで、かつ、当該両性水溶性ポリマーを0.1g/dl含む1規定塩化ナトリウム水溶液の25℃における還元粘度が0.1〜10.0dl/gである両性水溶性ポリマー。
Figure 2013006159
(ただし、一般式(3)中、Rは、水素原子又はメチル基であり、Rは、水素原子又は炭素数が1〜4のアルキル基であり、Rは、水素原子又は炭素数が1〜4のアルキル基であり、Rは、炭素数が1〜4のアルキル基又はベンジル基であり、Xは、酸素原子又はNHであり、Yは、Cl、Br、又は1/2SO 2−であり、nは1〜3の整数である。また、一般式(4)中、R、Rは、水素原子又はメチル基又は−COOMを、Bは炭素数0〜2のアルキレン基、フェニル基又は−COOR−又は−CONHR10−を、R、R10は炭素数2〜6のアルキレン基を、Zは−COO−又は−SO−を、Mは水素イオンその他の陽イオンを表す。)
In a sludge dewatering method, a sludge dewatering method comprising adding a sludge dewatering agent to sewage sludge having a M alkalinity of 1000 mg / l or less and a colloid value of a supernatant in the range of -0.5 to 0.3 meq / l. As described below, the amidine-based water-soluble polymer (A) and the amphoteric water-soluble polymer (B) are composed of 60 to 90% by mass of the amidine-based water-soluble polymer (A) with respect to the total mass of both. A sludge dewatering method, wherein a sludge dewatering agent having a proportion of the functional polymer (B) of 10 to 40% by mass is used.
[Amidine-based water-soluble polymer (A)]
An amidine-based water-soluble polymer containing an amidine structural unit represented by the following general formula (1) and / or an amidine structural unit represented by the following general formula (2).
Figure 2013006159
(However, in general formula (1), (2), R < 1 >, R < 2 > is a hydrogen atom or a methyl group each independently, and X < - > is an anion.)
[Amphiphilic water-soluble polymer (B)]
The cationic structural unit represented by the following general formula (3) is 25 to 80 mol%, the anionic structural unit represented by the following general formula (4) is 5 to 75 mol%, and the nonionic structural unit is ( Reduced viscosity at 25 ° C. of a 1N aqueous sodium chloride solution containing at least one amphoteric water-soluble polymer containing a meth) acrylamide monomer constituent unit in a proportion of 70 mol% or less and containing 0.1 g / dl of the amphoteric water-soluble polymer Is an amphoteric water-soluble polymer having a molecular weight of 0.1 to 10.0 dl / g.
Figure 2013006159
(In the general formula (3), R 3 is a hydrogen atom or a methyl group, R 4 is a hydrogen atom or a carbon number from 1 to 4 alkyl groups, R 5 is a hydrogen atom or a carbon atoms Is an alkyl group having 1 to 4 carbon atoms, R 6 is an alkyl group having 1 to 4 carbon atoms or a benzyl group, X is an oxygen atom or NH, Y is Cl , Br , or 1 / 2SO 4 2- , n is an integer of 1 to 3. In the general formula (4), R 7 and R 8 are a hydrogen atom, a methyl group, or —COOM + , and B is a carbon number. 0 to 2 alkylene group, phenyl group or —COOR 9 — or —CONHR 10 —, R 9 and R 10 each represent an alkylene group having 2 to 6 carbon atoms, Z represents —COO— or —SO 3 —, M + Represents a hydrogen ion or other cation.)
汚泥pHが5.50〜6.80の範囲の場合、両性水溶性ポリマー(B)の含有するアニオン性構成単位の含有率をM(a)モル%、カチオン性構成単位の含有率をM(c)モル%としたとき、比M(a)/M(c)が0.50〜2.00であり、汚泥pHが6.50〜7.50である場合、M(a)/M(c)が0.25〜1.40である請求項1に記載の汚泥脱水処理方法。 When the sludge pH is in the range of 5.50 to 6.80, the content of the anionic structural unit contained in the amphoteric water-soluble polymer (B) is M (a) mol%, and the content of the cationic structural unit is M ( c) When the molar percentage is M (a) / M (c) is 0.50 to 2.00 and the sludge pH is 6.50 to 7.50, M (a) / M ( The sludge dewatering method according to claim 1, wherein c) is 0.25 to 1.40. pH5.50〜6.80の汚泥が混合生汚泥である請求項2に記載の汚泥脱水処理方法。   The sludge dewatering method according to claim 2, wherein the sludge having a pH of 5.50 to 6.80 is mixed raw sludge. pH6.50〜7.50の汚泥が消化汚泥である請求項2に記載の汚泥脱水処理方法。   The sludge dewatering method according to claim 2, wherein the sludge having a pH of 6.50 to 7.50 is digested sludge.
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JP2016150312A (en) * 2015-02-18 2016-08-22 三菱レイヨン株式会社 Coagulation treatment agent for waste water, and coagulation treatment method of waste water
JP2017136514A (en) * 2016-02-01 2017-08-10 水ing株式会社 Polymer coagulant and dewatering method and dewatering device of sludge using polymer coagulant
US11459250B2 (en) 2017-04-28 2022-10-04 Hymo Corporation Treatment method for organic wastewater and use of same

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JPH07223000A (en) * 1994-02-15 1995-08-22 Kurita Water Ind Ltd Sludge dewatering agent and method for dewatering sludge using the same
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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2014155898A (en) * 2013-02-15 2014-08-28 Mitsubishi Rayon Co Ltd Sludge dehydration treatment method
JP2016150312A (en) * 2015-02-18 2016-08-22 三菱レイヨン株式会社 Coagulation treatment agent for waste water, and coagulation treatment method of waste water
JP2017136514A (en) * 2016-02-01 2017-08-10 水ing株式会社 Polymer coagulant and dewatering method and dewatering device of sludge using polymer coagulant
US11459250B2 (en) 2017-04-28 2022-10-04 Hymo Corporation Treatment method for organic wastewater and use of same

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