JP4427244B2 - Solidification method and solidification equipment for boron-containing wastewater - Google Patents

Description

を満たすように添加することが好ましい。
【００１６】
本発明の固化方法においては、排水中のホウ素は、ホウ素含有化合物の一形態である例えばCa₆Al₂[B(OH)₄]₂(OH)₁₆・30H₂Oを含むホウ素含有固化体が形成することによって、固形物となるものと考えられる。
難溶性であるホウ素含有化合物Ca₆Al₂[B(OH)₄]₂(OH)₁₆・30H₂Oを生成させるに必要なCa量は、その化合物の組成式3CaO・Al₂O₃・2Ca(OH)₂・Ca[B(OH)₄]₂・36H₂Oから、排水中に含有されるホウ素のモル量に対して、約３倍相当のモル量である。加えて、ホウ素含有化合物を含む固化体を生成するためには、その必要量とするCaはCa²⁺として液中に存在する必要がある。
【００１７】
また、ホウ素含有化合物Ca₆Al₂[B(OH)₄]₂(OH)₁₆・30H₂Oを生成させるのに必要なAl量は、同様に排水中に含有されるホウ素のモル量に対して、１倍相当のモル量が必要である。ただし、この化学量論的なCa及びAlの必要量に加えて、実際に例えばSO₄ ^2-、Ca²⁺、Mg²⁺等のイオンを含有する排水を、CaOを含有するセメント等の固化剤を用いて固化物を調製する場合には、排水及び固化剤の化学組成を考慮して、Ca（CaO又はCa(OH)₂等）の添加量を決定する必要がある。
具体的には、例えば添加量の決定においては、ホウ素含有排水中のSO₄ ^2-イオンの影響を考慮する。これは、排水中にSO₄ ^2-イオンが含まれている場合、ホウ素含有固化体Ca₆Al₂[B(OH)₄]₂(OH)₁₆・30H₂Oを生成させるために添加したCa²⁺イオン（Ca塩）は、ホウ素含有固化体を生成するとともに、SO₄ ^2-イオンと反応して石膏（CaSO₄）を生成するからである。
【００１８】
また、添加量の決定においては、排水中のMg²⁺イオンの働き、およびマグネシウム塩の添加量を考慮する。CaCl₂の溶解度に比較してCaO、Ca(OH)₂は溶解度が低く、そのままでは、添加したCaO、Ca(OH)₂の大半は液中に固体のままで存在し、ホウ素含有化合物の生成に用いられるCa²⁺イオンの形態になり難い。一方、液中にMg²⁺イオンが存在する場合、添加したCaO、Ca(OH)₂とMg²⁺イオンの置換反応が起こり、液中に溶解するCa²⁺イオン量を増加させることができる。通常、Mg²⁺濃度は、添加するCa(OH)₂又はCaOの液中濃度よりも小さいので、その差に相当する分量のマグネシウム塩を添加する。添加するマグネシウム塩としては、例えばMgCl₂、MgSO₄、Mg(NO₃)₂等が挙げられる。
【００１９】
ホウ素含有濃縮排水のセメントによる固化には、排水中のCaイオン濃度が大きく影響するものと考えられる。よって、CaCl₂添加量を変化させると、CaCl₂添加量の増加に伴い排水中のCaイオン濃度も増加して、ホウ素含有化合物の生成が容易となるので、固化体からのホウ素溶出濃度は低くなり、圧縮強度も高くなる。また、CaO無添加の濃縮排水に対し、CaCl₂を添加した場合にも、固化体からのホウ素溶出濃度は低くなり、固化状態は良好である。
【００２０】
実施の形態（その２）
図３は、本発明の固化設備の他の一例を示した図である。
本形態のホウ素含有排水の固化設備は、ホウ素含有排水を貯蔵する排水タンク１０と、排水タンク１０にCaO又はCa(OH)₂を供給するカルシウム供給ライン１０１と、排水タンク１０から流れてくるホウ素含有排水とセメント粉体を攪拌混合する混練機１１と、混練機１１にCaO又はCa(OH)₂を40重量%以上含有する固化助剤を加える供給ライン１１１と、混練機１１からの混練物を乾燥させて水分を除去する乾燥機１２と、を含む。
【００２１】
前記セメント粉体として、水和速度の速いセメントとして例えば早強ポルトランドセメントを用いることができる。前記セメント粉体としては、あらかじめCaO又はCa(OH)₂を40重量%以上含有する固化助剤を加えたセメントを用いることもできる。
前記混練機１１には、フライアッシュもしくは汚泥を加える供給ライン１１２がさらに設けられていてもよい。
【００２２】
実施の形態（その３）
図４は、本発明の固化設備の他の一例を示した図である。
本形態のホウ素含有排水の固化設備は、ホウ素含有排水を貯蔵する排水タンク１０と、排水タンク１０から抜き出したホウ素含有排水を加熱して水分を蒸発させて濃縮する蒸発缶１４と、蒸発缶１４から抜き出したホウ素含有濃縮排水を貯蔵する濃縮排水タンク１５と、濃縮排水タンク１５に塩化カルシウムを添加する供給ライン１５１と、濃縮排水タンク１５から流れてくるホウ素含有濃縮排水と固化剤であるセメント粉体とを攪拌混合する混練機１１と、混練機１１からの混練物を乾燥させて水分を除去する乾燥機１２と、を含む。
【００２３】
前記混練機１１には、CaO又はCa(OH)₂を40重量%以上含有する固化助剤を加える供給ライン１１１がさらに設けられていてもよい。
前記セメント粉体としては、水和速度の速いセメントとして例えば早強ポルトランドセメントを用いることができる。また前記セメント粉体としては、あらかじめCaO又はCa(OH)₂を40重量%以上含有する固化助剤を加えたセメントを用いることもできる。
前記混練機１１には、フライアッシュもしくは汚泥を加える供給ライン１１２がさらに設けられていてもよい。
【００２４】
実施の形態（その４）
図５は、本発明の固化設備の他の一例を示した図である。
本形態のホウ素含有排水の固化設備は、ホウ素含有排水を貯蔵する排水タンク１０と、排水タンク１０に塩化カルシウムを添加する供給ライン１０２と、排水タンク１０から抜き出したホウ素含有排水を加熱して水分を蒸発させて濃縮する蒸発缶１４と、蒸発缶１４から抜き出したホウ素含有濃縮排水を貯蔵する濃縮排水タンク１５と、濃縮排水タンク１５から流れてくるホウ素含有濃縮排水と固化剤であるセメント粉体とを攪拌混合する混練機１１と、混練機１１からの混練物を乾燥させて水分を除去する乾燥機１２とを含む。
【００２５】
前記混練機１１には、CaO又はCa(OH)₂を40重量%以上含有する固化助剤を加える供給ライン１１１がさらに設けられていてもよい。
前記セメント粉体としては、水和速度の速いセメントとして例えば早強ポルトランドセメントを用いることができる。また前記セメント粉体としては、あらかじめCaO又はCa(OH)₂を40重量%以上含有する固化助剤を加えたセメントを用いることもできる。
前記混練機１１には、フライアッシュもしくは汚泥を加える供給ライン１１２がさらに設けられていてもよい。
【００２６】
実施の形態（その５）
図６は、本発明の固化設備の他の一例を示した図である。
本形態のホウ素含有排水の固化設備は、ホウ素含有排水を貯蔵する排水タンク１０と、排水タンク１０から抜き出したホウ素含有排水を加熱して水分を蒸発させて濃縮する蒸発缶１４と、蒸発缶１４から抜き出したホウ素含有濃縮排水を貯蔵する濃縮排水タンク１５と、濃縮排水タンク１５にCaO又はCa(OH)₂を供給するカルシウム供給ライン１５２と、濃縮排水タンク１５から流れてくるホウ素含有濃縮排水と固化剤であるセメント粉体とを攪拌混合する混練機１１と、混練機１１からの混練物を乾燥させて水分を除去する乾燥機１２と、を含む。
【００２７】
前記濃縮排水タンク１５には、マグネシウム塩を添加する供給ライン１５３がさらに設けられていてもよい。
前記混練機１１には、CaO又はCa(OH)₂を40重量%以上含有する固化助剤を加える供給ライン１１１がさらに設けられていてもよい。
前記セメント粉体としては、水和速度の速いセメントとして例えば早強ポルトランドセメントを用いることができる。また前記セメント粉体としては、あらかじめCaO又はCa(OH)₂を40重量%以上含有する固化助剤を加えたセメントを用いることもできる。
前記混練機１１には、フライアッシュもしくは汚泥を加える供給ライン１１２がさらに設けられていてもよい。
【００２８】
実施の形態（その６）
図７は、本発明の固化設備の他の一例を示した図である。
本形態のホウ素含有排水の固化設備は、ホウ素含有排水を貯蔵する排水タンク１０と、排水タンク１０にCaO又はCa(OH)₂を供給するカルシウム供給ライン１０１と、排水タンク１０から抜き出したホウ素含有排水を加熱して水分を蒸発させて濃縮する蒸発缶１４と、蒸発缶１４から抜き出したホウ素含有濃縮排水を貯蔵する濃縮排水タンク１５と、濃縮排水タンク１５から流れてくるホウ素含有濃縮排水と固化剤であるセメント粉体とを攪拌混合する混練機１１と、混練機１１からの混練物を乾燥させて水分を除去する乾燥機１２と、を含む。
【００２９】
前記排水タンク１０には、マグネシウム塩を添加する供給ライン１０３がさらに設けられていてもよい。
前記混練機１１には、CaO又はCa(OH)₂を40重量%以上含有する固化助剤を加える供給ライン１１１がさらに設けられていてもよい。
前記セメント粉体としては、水和速度の速いセメントとして例えば早強ポルトランドセメントを用いることができる。また前記セメント粉体としては、あらかじめCaO又はCa(OH)₂を40重量%以上含有する固化助剤を加えたセメントを用いることもできる。
前記混練機１１には、フライアッシュもしくは汚泥を加える供給ライン１１２がさらに設けられていてもよい。
【００３０】
以上のようなホウ素含有排水の固化方法あるいは排水固化設備は、例えば排煙脱硫装置の吸収塔後段に設置されて、吸収塔から排出される排水の処理に用いられる。排煙脱硫装置の吸収塔では、硫黄酸化物を除去するために多量の水を用いて洗浄するため、該洗浄後の液は汚泥化されており、この液を濃縮したものは、本発明の処理対象であるホウ素含有排水になる。このようなシステムから排出される水中のホウ素は、液のｐＨが通常５〜７程度の範囲内であるため、ホウ酸(H₃BO₃)の形態で存在している。ホウ酸は非常に溶解度が高く、また、このままの状態では難溶性の固化物を生成し難い状態である。
本発明のホウ素含有排水の固化方法あるいは排水固化設備を用いれば、このような処理水中のホウ素を容易に固定化して水中から除去することが可能であり、有害物を無害化し環境汚染を有効に防止できる。
【００３１】
【発明の効果】
本発明の固化方法および固化設備によれば、固化物からのホウ素の溶出濃度が極めて低く、更に、強度の極めて強い高濃度のホウ素を含むセメント固化物を得ることができる。よって、排水中に含有される有害物を無害化し環境汚染を防止するとともに、セメント固化物として有効利用が可能となる。
【図面の簡単な説明】
【図１】本発明のホウ素含有排水の固化方法について、固化設備での各工程の流れを示した図である。
【図２】本発明のホウ素含有排水の固化設備の一例を示す構成図である。
【図３】本発明のホウ素含有排水の固化設備の他の一例を示す構成図である。
【図４】本発明のホウ素含有排水の固化設備の他の一例を示す構成図である。
【図５】本発明のホウ素含有排水の固化設備の他の一例を示す構成図である。
【図６】本発明のホウ素含有排水の固化設備の他の一例を示す構成図である。
【図７】本発明のホウ素含有排水の固化設備の他の一例を示す構成図である。
【符号の説明】
１０ 排水タンク
１１ 混練機
１２ 乾燥機
１３ 固化物ストックヤード
１４ 蒸発缶
１５ 濃縮排水タンク[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for solidifying boron-containing wastewater and its equipment (system), and more particularly to a technique useful for use in a non-drainage treatment facility and a solidification system for wastewater containing high-concentration boron.
[0002]
[Prior art]
As a general detoxification method for harmful substances in waste water, there is a cement solidification method in which waste water is solidified by mixing with cement and these harmful substances are contained in the cement.
However, some harmful substances contained in the waste water inhibit the cement solidification reaction, and boron (boric acid) is known to delay the setting of the cement. Therefore, the cement solidified wastewater containing boron at a high concentration has a low strength and has a problem that boron in the solidified material is eluted.
[0003]
[Problems to be solved by the invention]
Therefore, in view of the above problems, the present inventors can easily solidify and detoxify boron in wastewater in the treatment of wastewater containing boron, which is a harmful substance, and from the solidified boron-containing solidified body. We have intensively studied to develop a solidification method and solidification equipment for boron-containing wastewater that can effectively prevent boron from eluting and generating harmful substances.
As a result, the present inventors have found that the above-mentioned problems can be solved by preparing a boron-containing solidified body containing a boron-containing compound that exists stably for a long period of time. The present invention has been completed from such a viewpoint.
[0004]
[Means for Solving the Problems]
That is, the first aspect of the present invention is a composition preparation process in which a wastewater tank for storing boron-containing wastewater is supplied with 1000 mmol or more of calcium chloride per 1 liter of wastewater , and the composition of the wastewater is prepared by stirring and mixing. And a kneading step of adding the cement as a solidifying agent and stirring and mixing the prepared boron-containing waste water extracted from the waste water tank, and drying and curing to obtain a solid product, and a solidified product preparation step The present invention provides a method for solidifying contained wastewater. Here, in the kneading step, the prepared boron-containing wastewater extracted from the wastewater tank is further added with cement as a solidifying agent and a solidification aid further containing 40% by weight or more of CaO or Ca (OH) _2. It can also be added and mixed with stirring.
[0005]
The second aspect of the present invention is a drainage tank for storing boron-containing wastewater, a calcium supply line for supplying CaO or Ca (OH) ₂ to the drainage tank, boron-containing wastewater and cement powder flowing from the drainage tank. A kneader for stirring and mixing, a supply line for adding a solidification aid containing 40% by weight or more of CaO or Ca (OH) ₂ to the kneader, and drying the kneaded product from the kneader to remove moisture. And a solidification facility for boron-containing wastewater containing the dryer.
[0006]
The third aspect of the present invention is a drainage tank that stores boron-containing wastewater, an evaporator that heats and concentrates the boron-containing wastewater extracted from the drainage tank, and a boron-containing concentration that is extracted from the evaporator. A kneading machine that stirs and mixes a concentrated drainage tank for storing wastewater, a supply line for adding calcium chloride to the concentrated drainage tank, and a boron-containing concentrated wastewater flowing from the concentrated drainage tank and cement powder as a solidifying agent. And a dryer for removing moisture by drying the kneaded product from the kneader, and providing a solidification facility for boron-containing wastewater.
[0007]
A fourth aspect of the present invention is a drainage tank for storing boron-containing wastewater, a supply line for adding calcium chloride to the drainage tank, and heating and concentrating the boron-containing wastewater extracted from the drainage tank by evaporating water. An evaporator, a concentrated drainage tank for storing the boron-containing concentrated wastewater extracted from the evaporator, and a kneader for stirring and mixing the boron-containing concentrated wastewater flowing from the concentrated wastewater tank and the cement powder as a solidifying agent; And a dryer for removing moisture by drying the kneaded product from the kneader, and providing a solidification facility for boron-containing wastewater.
[0008]
The fifth aspect of the present invention is a drainage tank for storing boron-containing wastewater, an evaporator that heats and concentrates the boron-containing wastewater extracted from the wastewater, and a boron-containing concentrated wastewater that is extracted from the evaporator. A concentration drainage tank for storing the concentration, a calcium supply line for supplying CaO or Ca (OH) ₂ to the concentration drainage tank, a boron-containing concentration drainage flowing from the concentration drainage tank, and a cement powder as a solidifying agent. The present invention provides a solidification facility for boron-containing wastewater, which includes a kneader for stirring and mixing, and a drier for drying the kneaded product from the kneader to remove moisture.
[0009]
A sixth aspect of the present invention is a drainage tank for storing boron-containing wastewater, a calcium supply line for supplying CaO or Ca (OH) ₂ to the drainage tank, and heating the boron-containing wastewater extracted from the wastewater to provide moisture. Evaporating and concentrating the evaporator, the concentrated drainage tank for storing the boron-containing concentrated drainage extracted from the evaporator, and the boron-containing concentrated drainage flowing from the concentrated drainage tank and the cement powder as a solidifying agent An object of the present invention is to provide a solidification facility for boron-containing wastewater, which includes a kneader for mixing, and a dryer for removing moisture by drying a kneaded product from the kneader.
[0010]
In the present invention, it is preferable to use early-strength Portland cement as cement powder which is a solidifying agent to be added. Further, as the cement powder, a cement to which a solidification aid containing 40% by weight or more of CaO or Ca (OH) ₂ is added can also be used. By adding and kneading cement containing 40% by weight or more, preferably 50% by weight or more of a calcium compound, a boron-containing solidified body can be prepared by reducing the amount of CaO or Ca (OH) ₂ itself added. . By using a cement containing a large amount of CaO or the like, for example, early-strength Portland cement, it is possible to obtain a solidified product with extremely low boron elution and high strength.
[0011]
Further, the kneader can be provided with a supply line for adding fly ash or sludge. As the amount of cement to be added increases, it tends to be costly, so a certain amount of fly ash or sludge can be used instead.
[0012]
According to the present invention as described above, it is possible to stably prepare a solidified product having an extremely low boron elution concentration from the solidified product, and to obtain a cement solidified product containing a high concentration of boron having a very high strength. That is, the harmful substances contained in the waste water are harmless to prevent environmental pollution and can be effectively used as a cement solid.
Hereinafter, although the present invention is explained in detail based on an embodiment, the present invention is not limited by these embodiments.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Specific embodiments of the solidification method and the solidification facility according to the present invention will be described with reference to the accompanying drawings.
Embodiment (Part 1)
FIG. 1 and FIG. 2 are diagrams schematically showing each step together with the configuration of the solidification facility in one embodiment of the solidification method of the present invention.
In the present embodiment, the composition of the waste water is prepared by supplying calcium chloride to the waste water tank 10 for storing the boron-containing waste water and stirring and mixing in the composition preparation step. The amount of CaCl ₂ added is preferably 1000 mmol or more per liter of waste water. Next, in the kneading step, the prepared boron-containing wastewater extracted from the wastewater tank 10 is added with cement as a solidifying agent and mixed by stirring. Here, in this step, in addition, a solidification aid containing 40 wt% or more of CaO or Ca (OH) ₂ can be added and stirred and mixed. And it is made to dry and cure in a solidified material preparation process, and a solid substance is obtained. In order to dry, the kneaded material from the kneader is preferably supplied to the dryer 12. In addition, a special apparatus is not required to cure the dried solidified material, but for example, it is introduced into the solidified stockyard 13 or the like.
[0014]
As the cement, for example, early-strength Portland cement can be used as a cement having a high hydration rate.
Further, as the cement, it is also possible to use a cement to which a solidification aid containing CaO or Ca (OH) _{2 in an amount} of 40% by weight or more is added in advance.
In the kneading step, the amount of cement to be added can be reduced by adding fly ash or sludge.
If the solidification facility of the present embodiment is described with reference to FIG. 2, the drainage tank 10 that stores boron-containing wastewater, the calcium supply line 102 that supplies calcium chloride to the drainage tank 10, and the drainage tank 10 flow. A kneader 11 for stirring and mixing boron-containing wastewater and cement powder, a supply line 111 for adding a solidification aid containing 40% by weight or more of CaO or Ca (OH) ₂ to the kneader 11, and kneading from the kneader 11 And a drier 12 that dries the product to remove moisture.
[0015]
As the solidification aid, when adding CaO or Ca (OH) ₂ , the following formula (1):

It is preferable to add so as to satisfy.
[0016]
In the solidification method of the present invention, the boron in the waste water is a boron-containing solidified body containing, for example, Ca ₆ Al ₂ [B (OH) ₄ ] ₂ (OH) ₁₆ · 30H ₂ O, which is one form of the boron-containing compound. By forming, it is considered that it becomes a solid substance.
The amount of Ca required to form the poorly soluble boron-containing compound Ca ₆ Al ₂ [B (OH) ₄ ] ₂ (OH) ₁₆ · 30H ₂ O is determined by the composition formula 3CaO · Al ₂ O ₃ · 2Ca of the compound. From (OH) ₂ · Ca [B (OH) ₄ ] ₂ · 36H ₂ O, the molar amount is about 3 times the molar amount of boron contained in the waste water. In addition, in order to produce a solidified body containing a boron-containing compound, the required amount of Ca needs to be present in the liquid as Ca ²⁺ .
[0017]
Similarly, the amount of Al necessary to produce the boron-containing compound Ca ₆ Al ₂ [B (OH) ₄ ] ₂ (OH) ₁₆ · 30H ₂ O is the same as the molar amount of boron contained in the wastewater. Therefore, a molar amount equivalent to 1 time is required. However, in addition to this stoichiometric amount of Ca and Al, wastewater containing ions such as SO ₄ ²⁻ , Ca ²⁺ , Mg ^2+, etc., can be solidified as cement containing CaO. When preparing a solidified product using an agent, it is necessary to determine the amount of Ca (CaO or Ca (OH) ₂ etc.) added in consideration of the chemical composition of the waste water and the solidifying agent.
Specifically, for example, in determining the addition amount, the influence of SO ₄ ^2- ions in the boron-containing waste water is taken into consideration. This is because when SO ₄ ^2- ions are contained in the wastewater, the Ca added to generate the boron-containing solidified body Ca ₆ Al ₂ [B (OH) ₄ ] ₂ (OH) ₁₆ · 30H ₂ O ^{This is because 2+} ions (Ca salts) generate a boron-containing solidified body and react with SO ₄ ^2- ions to generate gypsum (CaSO ₄ ).
[0018]
In addition, in determining the addition amount, the action of Mg ²⁺ ions in the waste water and the addition amount of the magnesium salt are taken into consideration. CaO and Ca (OH) ₂ have lower solubility compared to the solubility of CaCl ₂ , and as it is, most of the added CaO and Ca (OH) ₂ exist as solids in the solution, producing boron-containing compounds. It is difficult to be in the form of Ca ²⁺ ions used in On the other hand, when Mg ²⁺ ions are present in the liquid, a substitution reaction of the added CaO, Ca (OH) ₂ and Mg ²⁺ ions occurs, and the amount of Ca ²⁺ ions dissolved in the liquid can be increased. . Usually, the Mg ²⁺ concentration is smaller than the concentration of Ca (OH) ₂ or CaO to be added, so an amount of magnesium salt corresponding to the difference is added. Examples of the magnesium salt to be added include MgCl ₂ , MgSO ₄ , Mg (NO ₃ ) _{2 and the} like.
[0019]
It is considered that the Ca ion concentration in the wastewater greatly affects the solidification of the boron-containing concentrated wastewater by cement. Therefore, if the amount of CaCl ₂ added is changed, the Ca ion concentration in the wastewater increases with the increase in the amount of CaCl ₂ added, which facilitates the generation of boron-containing compounds, so the boron elution concentration from the solidified product is low. And the compressive strength is also increased. Further, when CaCl ₂ is added to the concentrated wastewater without addition of CaO, the boron elution concentration from the solidified body is low, and the solidified state is good.
[0020]
Embodiment (2)
FIG. 3 is a view showing another example of the solidification facility of the present invention.
The solidification equipment for boron-containing wastewater in this embodiment includes a drainage tank 10 that stores boron-containing wastewater, a calcium supply line 101 that supplies CaO or Ca (OH) ₂ to the drainage tank 10, and boron that flows from the drainage tank 10. A kneader 11 for stirring and mixing the waste water and cement powder, a supply line 111 for adding a solidification aid containing 40% by weight or more of CaO or Ca (OH) ₂ to the kneader 11, and a kneaded product from the kneader 11 And a dryer 12 that removes moisture by drying.
[0021]
As the cement powder, for example, early-strength Portland cement can be used as a cement having a high hydration rate. As the cement powder, a cement previously added with a solidification aid containing 40% by weight or more of CaO or Ca (OH) ₂ can also be used.
The kneader 11 may be further provided with a supply line 112 for adding fly ash or sludge.
[0022]
Embodiment (Part 3)
FIG. 4 is a view showing another example of the solidification facility of the present invention.
The solidification facility for boron-containing wastewater of this embodiment includes a drainage tank 10 that stores boron-containing wastewater, an evaporator 14 that heats and concentrates the boron-containing wastewater extracted from the drainage tank 10, and an evaporator 14. Concentrated drainage tank 15 for storing the boron-containing concentrated drainage extracted from the tank, a supply line 151 for adding calcium chloride to the concentrated drainage tank 15, and the boron-containing concentrated drainage flowing from the concentrated drainage tank 15 and cement powder as a solidifying agent A kneader 11 for stirring and mixing the body, and a dryer 12 for drying the kneaded product from the kneader 11 to remove moisture.
[0023]
The kneader 11 may further be provided with a supply line 111 for adding a solidification aid containing 40% by weight or more of CaO or Ca (OH) ₂ .
As the cement powder, for example, early-strength Portland cement can be used as a cement having a high hydration rate. Further, as the cement powder, a cement to which a solidification aid containing at least 40% by weight of CaO or Ca (OH) ₂ is added in advance can also be used.
The kneader 11 may be further provided with a supply line 112 for adding fly ash or sludge.
[0024]
Embodiment (part 4)
FIG. 5 is a view showing another example of the solidification facility of the present invention.
The solidification facility for boron-containing wastewater in this embodiment includes a drainage tank 10 for storing boron-containing wastewater, a supply line 102 for adding calcium chloride to the drainage tank 10, and heating the boron-containing wastewater extracted from the drainage tank 10 to moisture. 14 which evaporates and concentrates, a concentrated drainage tank 15 which stores the boron-containing concentrated drainage extracted from the evaporator 14, a boron-containing concentrated drainage which flows from the concentrated drainage tank 15, and cement powder which is a solidifying agent And a dryer 12 that dries the kneaded product from the kneader 11 to remove moisture.
[0025]
The kneader 11 may further be provided with a supply line 111 for adding a solidification aid containing 40% by weight or more of CaO or Ca (OH) ₂ .
As the cement powder, for example, early-strength Portland cement can be used as a cement having a high hydration rate. Further, as the cement powder, a cement to which a solidification aid containing at least 40% by weight of CaO or Ca (OH) ₂ is added in advance can also be used.
The kneader 11 may be further provided with a supply line 112 for adding fly ash or sludge.
[0026]
Embodiment (Part 5)
FIG. 6 is a view showing another example of the solidification facility of the present invention.
The solidification facility for boron-containing wastewater of this embodiment includes a drainage tank 10 that stores boron-containing wastewater, an evaporator 14 that heats and concentrates the boron-containing wastewater extracted from the drainage tank 10, and an evaporator 14. A concentrated drainage tank 15 for storing the boron-containing concentrated drainage extracted from the tank, a calcium supply line 152 for supplying CaO or Ca (OH) ₂ to the concentrated drainage tank 15, and a boron-containing concentrated drainage flowing from the concentrated drainage tank 15. A kneader 11 that stirs and mixes cement powder that is a solidifying agent, and a dryer 12 that dries the kneaded material from the kneader 11 to remove moisture.
[0027]
The concentration drainage tank 15 may further include a supply line 153 for adding a magnesium salt.
The kneader 11 may further be provided with a supply line 111 for adding a solidification aid containing 40% by weight or more of CaO or Ca (OH) ₂ .
As the cement powder, for example, early-strength Portland cement can be used as a cement having a high hydration rate. Further, as the cement powder, a cement to which a solidification aid containing at least 40% by weight of CaO or Ca (OH) ₂ is added in advance can also be used.
The kneader 11 may be further provided with a supply line 112 for adding fly ash or sludge.
[0028]
Embodiment (No. 6)
FIG. 7 is a view showing another example of the solidification facility of the present invention.
The solidification facility for boron-containing wastewater of this embodiment includes a drainage tank 10 that stores boron-containing wastewater, a calcium supply line 101 that supplies CaO or Ca (OH) ₂ to the drainage tank 10, and a boron-containing drain extracted from the drainage tank 10. Evaporator 14 that heats and concentrates water by evaporating water, concentrated drainage tank 15 that stores the boron-containing concentrated wastewater extracted from the evaporator 14, and boron-containing concentrated wastewater that flows from the concentrated drainage tank 15 and solidifies A kneader 11 that stirs and mixes the cement powder that is an agent, and a dryer 12 that dries the kneaded material from the kneader 11 to remove moisture.
[0029]
The drain tank 10 may further be provided with a supply line 103 for adding a magnesium salt.
The kneader 11 may further be provided with a supply line 111 for adding a solidification aid containing 40% by weight or more of CaO or Ca (OH) ₂ .
As the cement powder, for example, early-strength Portland cement can be used as a cement having a high hydration rate. Further, as the cement powder, a cement to which a solidification aid containing at least 40% by weight of CaO or Ca (OH) ₂ is added in advance can also be used.
The kneader 11 may be further provided with a supply line 112 for adding fly ash or sludge.
[0030]
The boron-containing wastewater solidification method or wastewater solidification facility as described above is installed, for example, at the rear stage of the absorption tower of the flue gas desulfurization apparatus and used for the treatment of wastewater discharged from the absorption tower. In the absorption tower of the flue gas desulfurization apparatus, since a large amount of water is used for cleaning to remove sulfur oxides, the liquid after the cleaning is sludged. It becomes boron-containing wastewater to be treated. Boron in water discharged from such a system exists in the form of boric acid (H ₃ BO ₃ ) because the pH of the liquid is usually in the range of about 5-7. Boric acid has a very high solubility, and in this state, it is difficult to produce a hardly soluble solidified product.
If the solidification method or drainage solidification facility of the boron-containing wastewater of the present invention is used, boron in such treated water can be easily fixed and removed from the water, making harmful substances harmless and effectively preventing environmental pollution. Can be prevented.
[0031]
【The invention's effect】
According to the solidification method and solidification facility of the present invention, it is possible to obtain a cement solidified product containing a high concentration of boron with a very low boron elution concentration from the solidified product and a very strong strength. Therefore, the harmful substances contained in the waste water are harmless to prevent environmental pollution, and can be effectively used as a cement solidified product.
[Brief description of the drawings]
FIG. 1 is a diagram showing the flow of each process in a solidification facility for a method for solidifying boron-containing wastewater according to the present invention.
FIG. 2 is a configuration diagram showing an example of a solidification facility for boron-containing wastewater according to the present invention.
FIG. 3 is a configuration diagram showing another example of the boron-containing wastewater solidification facility of the present invention.
FIG. 4 is a configuration diagram showing another example of the boron-containing wastewater solidification facility of the present invention.
FIG. 5 is a configuration diagram showing another example of the boron-containing wastewater solidification facility of the present invention.
FIG. 6 is a configuration diagram showing another example of the boron-containing wastewater solidification facility of the present invention.
FIG. 7 is a configuration diagram showing another example of the solidification facility for boron-containing waste water according to the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 Drain tank 11 Kneader 12 Dryer 13 Solidified stock yard 14 Evaporator 15 Concentrated drain tank

Claims (17)

A method for solidifying boron-containing wastewater to produce a boron-containing compound Ca ₆ Al ₂ [B (OH) ₄ ] ₂ (OH) ₁₆ · 30H ₂ O,
A composition preparation step of preparing a composition of the waste water by supplying 1000 mmol or more of calcium chloride to 1 liter of the waste water and stirring and mixing the waste water containing boron-containing waste water;
A kneading step of adding a cement as a solidifying agent and stirring and mixing the prepared boron-containing waste water extracted from the waste water tank;
A solidified product producing step for obtaining solid matter by drying and curing; and
The solidification method of the boron containing wastewater characterized by including. A method for solidifying boron-containing wastewater to produce a boron-containing compound Ca ₆ Al ₂ [B (OH) ₄ ] ₂ (OH) ₁₆ · 30H ₂ O,
A composition preparation step of preparing a composition of the waste water by supplying 1000 mmol or more of calcium chloride to 1 liter of the waste water and stirring and mixing the waste water containing boron-containing waste water;
To the boron-containing wastewater prepared after being extracted from the wastewater tank, a cement as a solidifying agent and a solidification aid further containing 40% by weight or more of CaO or Ca (OH) ₂ are added and stirred and mixed. Kneading step, where CaO or Ca (OH) ₂ is the following formula (1)

Added to satisfy
A solidified preparation process for obtaining a solid by drying and curing; and
The solidification method of the boron containing wastewater characterized by including.   The method for solidifying boron-containing wastewater according to claim 1 or 2, wherein early-strength Portland cement is used as the cement. _{2. The} method for solidifying boron-containing wastewater according to claim 1, wherein a cement added with a solidification aid containing 40% by weight or more of CaO or Ca (OH) ₂ is used as the cement.   In the said kneading | mixing process, fly ash or sludge is added, The solidification method of the boron containing waste water in any one of Claims 1-4 characterized by the above-mentioned. A boron-containing wastewater solidification facility for producing a boron-containing compound Ca ₆ Al ₂ [B (OH) ₄ ] ₂ (OH) ₁₆ · 30H ₂ O,
A drainage tank for storing boron-containing wastewater;
A calcium supply line for supplying CaO or Ca (OH) ₂ to the drainage tank;
A kneader for stirring and mixing the boron-containing wastewater flowing from the wastewater tank and the cement powder;
A supply line for adding a solidification aid containing 40% by weight or more of CaO or Ca (OH) ₂ to the kneader;
A dryer for drying the kneaded product from the kneader to remove moisture;
A solidification facility for boron-containing wastewater. A boron-containing wastewater solidification facility for producing a boron-containing compound Ca ₆ Al ₂ [B (OH) ₄ ] ₂ (OH) ₁₆ · 30H ₂ O,
A drainage tank for storing boron-containing wastewater;
An evaporator that heats the boron-containing wastewater extracted from the wastewater tank to evaporate and concentrate the water;
A concentrated drainage tank for storing the boron-containing concentrated drainage extracted from the evaporator;
A supply line for adding calcium chloride to the concentrated drainage tank;
A kneader for stirring and mixing the boron-containing concentrated waste water flowing from the concentrated waste water tank and the cement powder as a solidifying agent;
A supply line for adding a solidification aid containing 40% by weight or more of CaO or Ca (OH) ₂ to the kneader;
A dryer for drying the kneaded product from the kneader to remove moisture;
A solidification facility for boron-containing wastewater. A boron-containing wastewater solidification facility for producing a boron-containing compound Ca ₆ Al ₂ [B (OH) ₄ ] ₂ (OH) ₁₆ · 30H ₂ O,
A drainage tank for storing boron-containing wastewater;
A supply line for adding calcium chloride to the drainage tank;
An evaporator that heats the boron-containing wastewater extracted from the wastewater tank to evaporate and concentrate the water;
A concentrated drainage tank for storing the boron-containing concentrated drainage extracted from the evaporator;
A kneader for stirring and mixing the boron-containing concentrated waste water flowing from the concentrated waste water tank and the cement powder as a solidifying agent;
A dryer for drying the kneaded product from the kneader to remove moisture;
A solidification facility for boron-containing wastewater. The solidification equipment for boron-containing wastewater according to claim 8, further comprising a supply line for adding a solidification aid containing 40 wt% or more of CaO or Ca (OH) ₂ to the kneader. A boron-containing wastewater solidification facility for producing a boron-containing compound Ca ₆ Al ₂ [B (OH) ₄ ] ₂ (OH) ₁₆ · 30H ₂ O,
A drainage tank for storing boron-containing wastewater;
An evaporator for heating and concentrating the boron-containing waste water extracted from the waste water by evaporating water;
A concentrated drainage tank for storing the boron-containing concentrated drainage extracted from the evaporator;
A calcium supply line for supplying CaO or Ca (OH) ₂ to the concentrated drainage tank;
A supply line for adding magnesium salt to the concentrated drainage tank;
A kneader for stirring and mixing the boron-containing concentrated waste water flowing from the concentrated waste water tank and the cement powder as a solidifying agent;
A dryer for drying the kneaded product from the kneader to remove moisture;
A solidification facility for boron-containing wastewater. The solidification equipment for boron-containing wastewater according to claim 10, further comprising a supply line for adding a solidification aid containing 40 wt% or more of CaO or Ca (OH) ₂ to the kneader. A boron-containing wastewater solidification facility for producing a boron-containing compound Ca ₆ Al ₂ [B (OH) ₄ ] ₂ (OH) ₁₆ · 30H ₂ O,
A drainage tank for storing boron-containing wastewater;
A calcium supply line for supplying CaO or Ca (OH) ₂ to the drainage tank;
An evaporator for heating and concentrating the boron-containing waste water extracted from the waste water by evaporating water;
A concentrated drainage tank for storing the boron-containing concentrated drainage extracted from the evaporator;
A kneader for stirring and mixing the boron-containing concentrated waste water flowing from the concentrated waste water tank and the cement powder as a solidifying agent;
A dryer for drying the kneaded product from the kneader to remove moisture;
A solidification facility for boron-containing wastewater.   The solidification facility for boron-containing wastewater according to claim 12, wherein a supply line for adding magnesium salt is further provided in the drainage tank. The solidification of boron-containing wastewater according to claim 12 or 13, further comprising a supply line for adding a solidification aid containing 40 wt% or more of CaO or Ca (OH) ₂ to the kneader. Facility.   The solidification equipment for boron-containing wastewater according to any one of claims 6 to 14, wherein early strong Portland cement is used as the cement powder. The boron-containing wastewater according to any one of claims 6 to 15, wherein a cement added with a solidification aid containing 40% by weight or more of CaO or Ca (OH) ₂ is used as the cement powder. Solidification equipment.   The solidification equipment for boron-containing wastewater according to any one of claims 6 to 16, further comprising a supply line for adding fly ash or sludge to the kneader.

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