JP2004089931A - Dephosphorization and ammonia-removal method, manufacturing method for ammonia fertilizer and manufacturing method for molten solidified matter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for efficiently removing phosphorus and ammonia from water to be treated, fertilizer using removed phosphorus and ammonia and a manufacturing method for a molten solidified matter useful as fertilizer. <P>SOLUTION: Phosphorus is removed from water to be treated by a first pH adjusting process for adding sulfuric acid and/or hydrochloric acid to the water to adjust the pH of the water to 3.5 or less, a second pH adjusting process for adding a caustic soda aqueous solution to the water to adjust the pH of the solution to 9.0 or more, a process for adding a calcium chloride aqueous solution to the water, a dephosphorization process for passing the water after the calcium chloride adding process through the packed tank formed by filling a tank with the ground matter of slag generated from a converter as an adsorbing material. By an ammonia removing process for applying an ammonia to be treated after subjected to dephosphorization treatment in the dephosphorization process, ammonia is removed from the water. <P>COPYRIGHT: (C)2004,JPO

Description

表１に示すように、転炉スラグの５０％前後が酸化カルシウムであり、一方、被処理水中のリン成分はその大部分がリン酸イオン（ＰＯ_４ ^３−）の形態で存在していることが一般的に知られている。そうすると、リン酸イオンの形態で存在しているリン成分が前記表１に示すような成分組成の転炉スラグと接触すると、該転炉スラグ主成分であるカルシウムと反応して難熔成の、例えばヒドロキシアパタイト〔Ｃａ_５（ＰＯ_４）_３（ＯＨ）〕を形成することが考えられ、このヒドロキシアパタイトが転炉スラグ表面において晶析することでリン含有排水中のリンが除去されると推定できる。
【００３５】
従って、本発明の方法においてリン成分吸着材料として用いる転炉スラグの成分は、厳密に限定されることはないが、前記推定からするとカルシウムを多く含有していることが好ましい。
【００３６】
また、前記推定からすると、転炉スラグは、その表面積を大きくしてリン含有排水との接触確率を高めることが好ましく、従って転炉スラグを粉砕して用いるのがよいが、被処理水が多量の場合においてはそれなりの通水速度が必要となり、通水速度は転炉スラグの微細化によって低下する傾向がある。このため、転炉スラグの粉砕に際しては、上記傾向を考慮し、粒径１０ｍｍ以下において適当な粒径組成を選択するのが良い。リン吸着材料として使用する転炉スラグの粒径は、統一する必要はなく、大小さまざまな粒径のものを混合して用いることも可能である。
【００３７】
本発明の脱リン工程において用いられる充填槽は、特に限定されるものではなく従来公知の充填槽を任意に用いることができる。
【００３８】
また、脱リン工程は、転炉により発生するスラグを細粒化したものをリン吸着材料として用い、前記塩化カルシウム添加工程後のリン含有排水中に、当該リン吸着材料を流動浮遊させるようにしてもよい（図２参照）。処理すべきリン含有排水を通水させるのではなく、リン含有排水を予めタンクなどに貯水しておき、そこで転炉スラグを流動浮遊させることにより、前記通水する場合と同様の効果を得ることができる。
【００３９】
本発明においてこの脱リン工程を施すための装置、つまり被処理水を貯水するための装置は特に限定されることはなく、被処理水中で転炉スラグが流動浮遊するような環境を作ることができればいかなる装置であってもよい。例えば、図３に示すように、撹拌装置３１を装備したタンク３０を用いることにより、流動浮遊している転炉スラグ３２と被処理水中のリンとの接触回数を増加することができ、効率良くリンの除去をすることができるので好ましい。
【００４０】
（５）脱アンモニア工程
本発明の方法における脱アンモニア工程とは、アンモニアストリッピング法を用いて、前記脱リン工程後の被処理水中からをアンモニアを除去する工程をいい、本発明においては、従来公知のアンモニアストリッピング法を用いることができる。
【００４１】
通常、水中のアンモニア成分は、アンモニウムイオン（ＮＨ_４ ^＋）と遊離アンモニア（ＮＨ_３）とが平衡を保って存在しているところ（式１参照）、本発明において用いるアンモニアストリッピング法とは、当該水中に空気を吹き込むことにより、アンモニア成分のうち、遊離アンモニアを気相に放散させることで液中からアンモニアを除去する方法である。従って、式１からも明らかなように、被処理水のｐＨが高くなるにつれて、平衡は右にずれるので遊離アンモニアのモル比が上昇し、その結果アンモニアの除去を効率よく行うことができる。
【００４２】
【式１】

また、水中のアンモニウムイオン（ＮＨ_４ ^＋）と遊離アンモニア（ＮＨ_３）とのモル比率は、水温の影響も受けることが知られており、温度が高くなるほど遊離アンモニアの比率が高くなる。
【００４３】
図４は、被処理水のｐＨと温度と遊離アンモニアのモル比との関係を表した図である。例えば、被処理水のｐＨが９．０で、温度が３０℃の場合には、被処理水中の全アンモニア成分のうち約５０％が遊離アンモニアであることがわかる。
【００４４】
そうすると、本発明の脱アンモニア工程を行う前の段階において被処理水のｐＨは、前記第二ｐＨ調整工程によって９．０以上となっており、しかも例えば、アンモニア濃度の高い脱水ろ液のような汚泥処理工程の排水では３５℃前後の水温があるため、被処理水中の遊離アンモニアは６０％以上になり、大量のアンモニアがストリッピング可能である。
【００４５】
このように、本発明の脱リン・脱アンモニア方法によれば、特に、冬場でも温度が高くアンモニア成分の含有率が高い汚泥処理水から効率よくリンとアンモニアとを除去することができる。
【００４６】
（Ｂ）アンモニア肥料の製造方法
次に、本発明のアンモニア肥料と製造方法について説明する。
【００４７】
本発明のアンモニア肥料の製造方法は、前述してきた本発明の脱リン・脱アンモニア方法よって被処理水から放散させたアンモニアガスを回収し、当該アンモニアガスを硫酸、硝酸、リン酸のいずれかにより洗浄してアンモニア肥料とすることに特徴を有している。このようにアンモニアガスを硫酸、硝酸、リン酸により洗浄することにより、硫酸アンモニウム、硝酸アンモニウム、リン酸アンモニウムをそれぞれ製造することができ、これらを適宜用いてアンモニア肥料を製造することができる。なお、アンモニアガスの具体的な洗浄方法や、アンモニア肥料の具体的な製造方法については特に限定することはなく、従来公知のいかなる方法をも用いることができる。
【００４８】
（Ｃ）熔融固化体の製造方法
次に、本発明の熔融固化体の製造方法について図面を用いて説明する。
【００４９】
図５は、本発明の熔融固化体の製造方法を示すフローチャート図である。本発明の熔融固化体の製造方法は、（１）混合工程と、（２）熔融工程と、（３）冷却固化工程と、からなることに特徴を有している。以下にそれぞれの工程毎に説明する。
【００５０】
（１）混合工程
本発明の熔融固化体の製造方法における混合工程とは、前述の脱リン・脱アンモニア方法においてリン吸着材料として使用された転炉スラグの粉砕物を原料として、これとリン酸根を含有する汚泥及び／又は汚泥焼却灰と、酸化マグネシウム及び／又はマグネシウム塩とを混合して、以下で説明する熔融工程で用いる混合物を形成するための工程である。脱リン・脱アンモニア方法においてリン吸着材料として使用された転炉スラグは、前記表１に示した成分組成に加え、その表面には被処理水中に溶存していたリン成分が吸着していることから、植物の肥料として有用な熔融固化体を製造する際の原料として好適に用いることができる。
【００５１】
本工程で使用することが好ましい転炉スラグとしては、前記脱リン方法において吸着材として使用されてリン成分が吸着されたものであれば特に限定されることはない。例えば、粒径０．５〜１．２ｍｍの転炉スラグを充填したカラムに１２０日間、１〜５ｍｇ／ｌの被処理水を通水したところスラグ１ｋｇ当たりリン含有量はＰ_２Ｏ_５で１５〜４５ｇ増加した。
【００５２】
また、本工程でリン酸根を含有する汚泥及び／又は汚泥焼却灰を混合するのは、これらは通常廃棄物として処理されているものであるところ、これらにも肥料として有用な熔融固化体を製造するために必要なリン成分が含まれており、本発明に用いることにより廃棄物を有効利用することが可能となるからである。
【００５３】
本工程で混合可能なリン酸根を含有する汚泥及び／又は汚泥焼却灰は特に限定されるものではない。例えば、下水処理に高分子凝集剤を使用した高分子系下水汚泥、又は高分子系下水汚泥を焼却した高分子系下水汚泥焼却灰などはリン含有量が多く望ましい。
【００５４】
また、本工程で酸化マグネシウム及び／又はマグネシウム塩を混合するのは、熔融固化体を製造するために必要な成分であるマグネシウムを補充するためである。
【００５５】
（２）熔融工程
次に熔融工程について説明する。本発明の熔融固化体の製造方法における熔融工程とは、前記混合工程において形成された混合物を酸素の存在下で１３５０℃以上で熔融することにより熔融物を形成する工程である。
【００５６】
本発明における熔融工程については、上記の条件下で熔融物を形成することができればよく、その他を特に限定されるものではない。したがって、従来公知の溶融炉を用いることが可能である。
【００５７】
また、本発明の方法における熔融工程においては、１３５０℃以上で溶融するため、廃棄物中の病原菌やウィルスを死滅せしめることができるため、衛生的にも優れた熔融固化体を製造することができる。
【００５８】
（３）冷却固化工程
次に冷却固化工程について説明する。本発明の熔融固化体の製造方法における冷却固化工程とは、前記熔融工程において形成された熔融物を冷却固化することにより、本発明の最終目的物たる熔融固化体を製造するための工程である。
【００５９】
本発明における冷却固化工程については、上記目的を達成することができればよく、その具体的方法や装置について特に限定されるものではない。例えば、熔融物を冷却固化する方法としては、水中に熔融物を導入する水冷法が単純かつ安価であるため好ましく、水冷法を用いた場合には、冷却され固化した熔融固化体を乾燥機により乾燥し、その後粉砕機により、肥料として用いる際に好適な大きさに粉砕してもよい。
【００６０】
ここで、本発明の方法においては、前記で説明した混合工程において、混合物を形成する際に、最終生成物たる熔融固化体の成分として、ＣａＯ、ＭｇＯ等のアルカリ土類のアルカリ成分が４０％以上、く溶性苦土が１２％以上、く溶性リン酸が１７％以上となるように混合することが好ましい。このような成分を有する熔融固化体はく溶性リン肥として用いることができるからである。
【００６１】
熔成リン肥の成分は、肥料取締法によって、く溶性燐酸１７％以上、アルカリ分４０％以上、く溶性苦土１２％以上と定められているが、本発明の方法における混合工程において、当該成分となるように調整して混合することにより熔成リン肥を製造することができる。
【００６２】
ここで、上記の成分に調整する方法としては、原料として用いるリン吸着材料として用いられた後の転炉スラグ中に含有されている各成分（ＣａＯ、ＭｇＯ等のアルカリ土類のアルカリ成分、く溶性苦土、く溶性リン酸）の量を予め測定しておき、不足分を補充する方法がある。
【００６３】
例えば、ＣａＯ、ＭｇＯ等のアルカリ土類のアルカリ成分４０％以上、く溶性苦土１２％以上となるように補充する物質としては、ＣａＯ、ＭｇＯおよび／またはその塩の材料として、製鉄所等で発生するマグネシア系耐火物の廃材、ドロマイト系耐火物の廃材および転炉滓を利用することができる。一方、く溶性リン酸が１７％以上となるように補充する物質としては、リン酸および／またはその塩の材料として、金属の表面処理等に使用した廃リン酸または廃リン酸塩を利用することができる。
【００６４】
【発明の効果】
以上述べたように、この発明によれば、製鉄所の転炉から生じる転炉スラグを有効に利用して、被処理水中からリンを除去するとともにアンモニアを除去することができる。さらに、本発明によれば、前記被処理水中から除去したアンモニアを用いてアンモニア肥料を製造することができ、さらに、リンを除去するために用いた転炉スラグや、従来からその処分が問題となっていた汚泥及び／又は汚泥焼却灰を原料として、植物の肥料として有用な熔融固化体を製造することができる。
【図面の簡単な説明】
【図１】本発明の脱リン・脱アンモニア方法の一例を示すフローチャート図である。
【図２】本発明の脱リン・脱アンモニア方法の他の一例を示すフローチャート図である。
【図３】本発明の脱リン・脱アンモニア方法において、脱リン工程を行う装置の概略断面図である。
【図４】被処理水のｐＨと温度と遊離アンモニアのモル比との関係を表した図である。
【図５】本発明の熔融固化体の製造方法を示すフローチャート図である。
【符号の簡単な説明】
３０　タンク
３１　撹拌装置
３２　転炉スラグ[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a dephosphorization / deammonification method for removing phosphorus from water to be treated while simultaneously removing phosphorus from the water to be treated by effectively utilizing converter slag, and an ammonia fertilizer using the method. And a method for producing a melt-solidified body.
[0002]
[Prior art]
Background Art Conventionally, one of the substances causing organic sludge substances (for example, BOD and COD) in sewage treatment such as human waste and sewage and eutrophication in water bodies such as rivers, lakes and seas. For example, phosphorus contained in these aqueous solutions is mentioned. Therefore, in recent years, various methods for removing phosphorus from these aqueous solutions have been developed.
[0003]
On the other hand, at the time of sewage treatment or the like, it is necessary to remove ammonia separately from the above-mentioned phosphorus. Ammonia, like phosphorus, is one of the pollutants.
[0004]
In such a situation, as a method for simultaneously removing phosphorus and ammonia in a solution, magnesium ions are injected into water to be treated (a solution containing phosphorus and ammonia) and magnesium ammonium phosphate (so-called MAP) is used. Is known to remove phosphorus and ammonia simultaneously from the water to be treated as magnesium ammonium phosphate.
[0005]
[Problems to be solved by the invention]
However, when phosphorus and ammonia are removed by forming magnesium ammonium phosphate from the water to be treated as described above, the molar ratio of phosphorus and ammonia forming magnesium ammonium phosphate is 1: 1. However, when the molar concentration of phosphorus and ammonia in the water to be treated is about the same, there is no particular problem.For example, when the water to be treated is treated human waste water, ammonia is more effective than phosphorus. Due to the excessive content, phosphorus for forming magnesium ammonium phosphate was insufficient, and although phosphorus could be removed, ammonia could not be sufficiently removed.
[0006]
On the other hand, phosphorus and nitrogen are useful substances as plant fertilizers. Therefore, it is necessary to effectively use phosphorus and ammonia removed from the water to be treated, especially as a molten solid (for example, molten phosphorus fertilizer) or as ammonium sulfate. It is highly preferable that the fertilizer can be used as an ammoniacal nitrogenous fertilizer (hereinafter, referred to as "ammonia fertilizer") because the cost of the fertilizer can be reduced.
[0007]
The present invention has been made in such a situation, and provides a method for efficiently removing phosphorus and ammonia from treated water containing a phosphorus component and an ammonia component, particularly sludge treatment return water, A method for producing an ammonia fertilizer using ammonia removed from water to be treated, and a method for producing a melt-solidified material useful as a fertilizer using a converter slag used as a phosphorus adsorption material in a dephosphorization / deammonification method The task is to provide
[0008]
[Means for Solving the Problems]
In order to solve the above-mentioned problems, the present invention relates to a method for removing phosphorus and ammonia from a water to be treated according to claim 1, wherein sulfuric acid and / or hydrochloric acid is added to the water to be treated. In addition, a first pH adjustment step of adjusting the pH to 3.5 or less, and a second pH adjustment step of adjusting the pH to 9.0 or more by adding a sodium hydroxide aqueous solution to the water to be treated after the first pH adjustment step. By adding an aqueous solution of calcium chloride to the water to be treated after the completion of the second pH adjustment step, a calcium chloride addition step, and using a pulverized slag generated from the converter as a phosphorus-adsorbing material and filling it in a tank. In the formed filling tank, phosphorus is removed from the water to be treated by passing the water to be treated after the calcium chloride adding step and the dephosphorization step, and further, the phosphorus is removed in the dephosphorization step. Subjected to ammonia stripping process the water to be treated, the ammonia-eliminating step, removing ammonia from the treated water by, providing a dephosphorization and de ammonia wherein the.
[0009]
According to the present invention, first, phosphorus is removed from the water to be treated.
[0010]
That is, slag generated by a converter (hereinafter sometimes simply referred to as “converter slag”) is used as a phosphorus component adsorbing material, and as a pretreatment for removing phosphorus from the water, PH is adjusted to 3.5 or less by adding sulfuric acid and / or hydrochloric acid to the water, so that acidic ions (particularly carbonate ions) contained in the water to be treated are removed as acid gas (carbon dioxide gas). be able to. As a result, the reaction between the acidic ions and calcium can be prevented. Calcium contained in converter slag is an indispensable substance for adsorbing a phosphorus component. When the calcium reacts with an acidic ion to form a calcium salt (for example, calcium carbonate), the calcium contained in the converter slag becomes phosphorous. Insufficient calcium for adsorbing the components makes it impossible to perform efficient dephosphorization. However, according to the present invention, such inconvenience does not occur. Further, the present invention is characterized in that, following the first pH adjusting step, a second pH adjusting step of adjusting the pH to 9.0 or higher by adding an aqueous solution of caustic soda to the water to be treated is performed. As described above, the water to be treated, which has been shifted to the acidic side in the first pH adjustment step in order to remove acidic ions, is shifted to pH 9.0 or more, that is, to the alkaline side, because the pH of the water to be treated is changed to alkaline. By doing so, the reaction between the phosphorus component and the calcium contained in the converter slag is promoted, and dephosphorization can be performed efficiently. Furthermore, the method of the present invention is characterized in that a calcium chloride adding step of adding an aqueous solution of calcium chloride to the phosphorus-containing wastewater after the completion of the second pH adjusting step is performed. As described above, by performing the calcium chloride adding step, the amount of calcium as the phosphorus adsorbing material can be increased, so that dephosphorization can be performed efficiently. Then, the method of the present invention uses a pulverized slag generated from a converter as a phosphorus component adsorbing material, and in a filling tank formed by filling this into a tank, the phosphorus component after the calcium chloride adding step is added. By performing the dephosphorization step of passing the contained wastewater, the phosphorus component contained in the wastewater can be efficiently removed.
[0011]
Subsequently, according to the present invention, a deammonification step is performed from the dephosphorized water to be treated.
[0012]
That is, the ammonia water is subjected to the ammonia stripping method. When removing ammonia from the water to be treated by the ammonia stripping method, it is known that the efficiency of ammonia removal (stripping) depends on the temperature and pH of the water to be treated. Also, the higher the pH, the more efficiently the ammonia can be stripped. According to the present invention, as described above, since the pH of the water to be treated is set to 9.0 or more in order to remove phosphorus from the water to be treated, the pH is increased as in the case of performing the ammonia stripping method alone. There is no need to use the water to be treated after the dephosphorization step as it is.
[0013]
According to the first aspect of the present invention, as described in the second aspect, in the dephosphorization step, slag generated by a converter is refined instead of using a filling tank, and a phosphorus adsorbent is used. The phosphorus in the water to be treated may be removed by flowing and suspending the phosphorus-adsorbing material in the water to be treated after the calcium chloride adding step.
[0014]
The present invention is characterized in that converter slag is used as a phosphorus-adsorbing material and is fluidized and suspended in wastewater to be dephosphorized. Since the calcium contained therein reacts with the phosphorus component contained in the waste water, and the phosphorus component is adsorbed on the slag surface, dephosphorization can be performed. In addition, the present invention has a first pH adjustment step, a second pH adjustment step, a calcium chloride addition step, and a deammonification step as in the first aspect. All of the above effects in each step can be obtained.
[0015]
In the dephosphorization / deammonification method according to claim 1 or 2, it is preferable that the water to be treated is sludge treatment return water, as described in claim 3.
[0016]
The sludge treatment return water referred to in the present invention is treated water obtained by treating sewage such as sewage or human waste containing a phosphate group or an organic compound of phosphorus, or concentrated and digested when treating sludge slurry generated in a sludge treatment step. Refers to water before returning the separated liquid, desorbed liquid, dehydrated filtrate, etc., generated in the dewatering step to the sludge treatment step. The sludge treatment return water has a high ammonia concentration and a high phosphorus concentration, and the sludge treatment return water discharged from the digestion tank has a water temperature of about 35 ° C. In such a case, ammonia stripping is performed. If the pH of the water to be treated at the time of performing the method is 9.0 or more, a large amount of ammonia can be diffused quantitatively using air, and the method of the present invention can be suitably used.
[0017]
According to a fourth aspect of the present invention, there is provided a method for removing a phosphorus component from a dephosphorization / deammonification method according to any one of the first to third aspects. A method for producing an ammonia fertilizer, comprising recovering ammonia gas released from water and washing the ammonia gas with sulfuric acid, nitric acid, or phosphoric acid to obtain an ammonia fertilizer.
[0018]
According to the present invention, the ammonia gas released when the water to be treated is subjected to the ammonia stripping method in the dephosphorization / deammonification method of the present invention can be effectively used as an ammonia fertilizer.
[0019]
Furthermore, in order to solve the above-mentioned problem, the present invention provides a method for removing phosphorus in a method for removing phosphorus and removing ammonia according to any one of claims 1 to 3. A mixing step of mixing a crushed converter slag used as a material, sludge and / or sludge incineration ash containing phosphate groups, and magnesium oxide and / or a magnesium salt; and mixing the mixture formed in the mixing step. A melting step of melting at 1350 ° C. or higher in the presence of oxygen; and a cooling and solidifying step of forming a molten solid by cooling and solidifying the melt formed in the melting step. A method for producing a body is provided.
[0020]
According to the present invention, a molten solidified product useful as a fertilizer can be produced by using the converter slag used as the phosphorus adsorbing material in the above-mentioned dephosphorization / deammonification method as a raw material. Since the converter slag used in the above-mentioned dephosphorization method contains a large amount of phosphorus that is useful as a fertilizer for plants, the treatment by adding other necessary components in the mixing step has become a problem. Converter slag can be recycled as useful fertilizer.
[0021]
Further, in the invention according to claim 5, as described in claim 6, in the mixing step, a component of a molten solidified product as a final product is an alkaline earth alkaline component such as CaO and MgO. It is preferable to mix them so that the content is 40% or more, the soluble mica is 12% or more, and the soluble phosphoric acid is 17% or more.
[0022]
According to the present invention, in the mixing step, by setting the components of the molten solid as the final product in such a ratio, the produced molten solid can be used as the molten phosphorus fertilizer in the fertilizer control method. Can be. Molten phosphorus fertilizer is widely used as a phosphate material suitable for agricultural circumstances in Japan with many acidic soils. Therefore, according to the present invention, converter slag, which was conventionally waste, is used as a phosphorus adsorption material, Further, thereafter, a molten phosphorus fertilizer can be produced using the raw material as a raw material, so that the production cost of the molten phosphorus fertilizer can be significantly reduced.
[0023]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the method for dephosphorization / deammonification, the method for producing an ammonia fertilizer, and the method for producing a melt-solidified product of the present invention will be specifically described.
[0024]
(A) Dephosphorization / deammonification method FIG. 1 is a flowchart showing a dephosphorization / deammonification method of the present invention. The dephosphorization / deammonification method of the present invention comprises (1) a first pH adjustment step, (2) a second pH adjustment step, (3) a calcium chloride addition step, (4) a dephosphorization step, and (5) A) deammonia step. Hereinafter, each step will be described.
[0025]
(1) First pH adjustment step The first pH adjustment step in the dephosphorization / deammonification method of the present invention is a step of adjusting the pH to 3.5 or less by adding sulfuric acid and / or hydrochloric acid to the water to be treated. Say. The reason for adjusting the pH in this manner is to remove acidic ions (specifically, carbonate ions and the like) contained in the water to be treated. At this time, carbon dioxide gas can be efficiently removed by aeration.
[0026]
The water to be treated in the method of the present invention is not particularly limited, and may be an aqueous solution containing a phosphorus component such as a phosphate ion and an ammonia component such as an ammonium ion and requiring dephosphorization and deammonification. Any aqueous solution may be used.In particular, the method of the present invention can be suitably used for sewage secondary treated water or sludge treated water, which is a typical example of wastewater containing phosphoric acid and ammonium ions. .
[0027]
The sulfuric acid and hydrochloric acid used in this step are not particularly limited, and commercially available ones may be appropriately diluted and used.
[0028]
(2) Second pH Adjusting Step The second pH adjusting step in the method of the present invention is a step of adjusting the pH to 9.0 or higher by adding an aqueous solution of caustic soda to the water to be treated after the completion of the first pH adjusting step. Say.
[0029]
The caustic soda used in this step is not particularly limited, and commercially available one may be appropriately diluted and used.
[0030]
(3) Calcium chloride addition step The calcium chloride addition step in the method of the present invention refers to a step of adding a calcium chloride aqueous solution to the water to be treated after the completion of the second pH adjustment step.
[0031]
The aqueous solution of calcium chloride used in this step is not particularly limited, and a commercially available one may be appropriately diluted and used.
[0032]
(4) Dephosphorization Step The dephosphorization step in the method of the present invention is a filling tank formed by using a pulverized slag generated from a converter in an ironworks as a phosphorus component adsorbing material and filling the material in a tank. During this, it refers to the step of passing the water to be treated after the step of adding calcium chloride.
[0033]
The general component composition of the slag generated from the converter in the steel mill is as shown in Table 1 below.
[0034]
[Table 1]

As shown in Table 1, about 50% of the converter slag is calcium oxide, while the phosphorus component in the for-treatment water is that the majority thereof is present in the form of phosphate ions (PO 4 ^_3-) Is generally known. Then, when the phosphorus component present in the form of phosphate ions comes into contact with the converter slag having a component composition as shown in Table 1 above, it reacts with calcium, which is the main component of the converter slag, and is hardly melted. For example, it is conceivable to form hydroxyapatite [Ca ₅ (PO ₄ ) ₃ (OH)], and it can be estimated that phosphorus in the phosphorus-containing wastewater is removed by crystallization of the hydroxyapatite on the converter slag surface. .
[0035]
Accordingly, the components of the converter slag used as the phosphorus component-adsorbing material in the method of the present invention are not strictly limited, but it is preferable from the above estimation that the components contain a large amount of calcium.
[0036]
From the above estimation, it is preferable to increase the surface area of the converter slag to increase the contact probability with the phosphorus-containing wastewater. Therefore, it is preferable to use the converter slag by pulverizing it. In the case of (1), a certain water flow rate is required, and the water flow rate tends to decrease due to the finer converter slag. Therefore, when pulverizing the converter slag, it is preferable to select an appropriate particle size composition with a particle size of 10 mm or less in consideration of the above tendency. The converter slag used as the phosphorus adsorbing material does not need to have a uniform particle size, and it is also possible to use a mixture of particles having various particle sizes, large and small.
[0037]
The filling tank used in the dephosphorization step of the present invention is not particularly limited, and a conventionally known filling tank can be arbitrarily used.
[0038]
In the dephosphorization step, the slag generated by the converter is refined and used as a phosphorus-adsorbing material, and the phosphorus-adsorbing material is caused to flow and float in the phosphorus-containing wastewater after the calcium chloride adding step. (See FIG. 2). Rather than letting the phosphorus-containing wastewater to be treated pass through, the phosphorus-containing wastewater is stored in a tank or the like in advance, and the converter slag is made to flow and float there, thereby obtaining the same effect as in the case of passing the above-mentioned water. Can be.
[0039]
In the present invention, an apparatus for performing the dephosphorization step, that is, an apparatus for storing the water to be treated is not particularly limited, and an environment in which the converter slag flows and floats in the water to be treated can be created. If possible, any device may be used. For example, as shown in FIG. 3, by using the tank 30 equipped with the stirring device 31, the number of times of contact between the converter slag 32 flowing and floating and the phosphorus in the water to be treated can be increased, and the efficiency is improved. It is preferable because phosphorus can be removed.
[0040]
(5) Deammonification Step In the method of the present invention, the deammonification step refers to a step of removing ammonia from the water to be treated after the dephosphorization step by using an ammonia stripping method. A known ammonia stripping method can be used.
[0041]
Normally, the ammonia component in water is such that ammonium ions (NH ₄ ⁺ ) and free ammonia (NH ₃ ) are present in equilibrium (see formula 1), and the ammonia stripping method used in the present invention is as follows. This is a method of removing ammonia from the liquid by blowing free air into the gas phase by blowing air into the water. Therefore, as is clear from Equation 1, as the pH of the water to be treated increases, the equilibrium shifts to the right, so that the molar ratio of free ammonia increases. As a result, ammonia can be removed efficiently.
[0042]
(Equation 1)

It is known that the molar ratio between ammonium ions (NH ₄ ⁺ ) and free ammonia (NH ₃ ) in water is also affected by water temperature, and the higher the temperature, the higher the ratio of free ammonia.
[0043]
FIG. 4 is a diagram showing the relationship between the pH and temperature of the water to be treated and the molar ratio of free ammonia. For example, when the pH of the water to be treated is 9.0 and the temperature is 30 ° C., it is understood that about 50% of the total ammonia component in the water to be treated is free ammonia.
[0044]
Then, in the stage before performing the deammonification step of the present invention, the pH of the water to be treated is 9.0 or more due to the second pH adjustment step, and for example, such as a dehydrated filtrate having a high ammonia concentration. Since the wastewater in the sludge treatment process has a water temperature of about 35 ° C., the amount of free ammonia in the water to be treated is 60% or more, and a large amount of ammonia can be stripped.
[0045]
As described above, according to the dephosphorization / deammonification method of the present invention, phosphorus and ammonia can be efficiently removed particularly from sludge treated water having a high temperature and a high ammonia component content even in winter.
[0046]
(B) Production method of ammonia fertilizer Next, the ammonia fertilizer and the production method of the present invention will be described.
[0047]
The method for producing an ammonia fertilizer of the present invention recovers ammonia gas diffused from the water to be treated by the dephosphorization / deammonification method of the present invention described above, and converts the ammonia gas to sulfuric acid, nitric acid, or phosphoric acid. It is characterized by being washed to produce ammonia fertilizer. By washing the ammonia gas with sulfuric acid, nitric acid, and phosphoric acid in this manner, ammonium sulfate, ammonium nitrate, and ammonium phosphate can be respectively produced, and an ammonia fertilizer can be produced using these as appropriate. The specific method of cleaning ammonia gas and the specific method of producing ammonia fertilizer are not particularly limited, and any conventionally known method can be used.
[0048]
(C) Method for Producing a Fused Solid Next, a method for producing a fused solid of the present invention will be described with reference to the drawings.
[0049]
FIG. 5 is a flow chart showing a method for producing a molten solid according to the present invention. The method for producing a melt-solidified product of the present invention is characterized by comprising (1) a mixing step, (2) a melting step, and (3) a cooling-solidification step. Hereinafter, each step will be described.
[0050]
(1) Mixing step The mixing step in the method for producing a molten and solidified product of the present invention refers to a method in which a pulverized converter slag used as a phosphorus-adsorbing material in the above-described dephosphorization / deammonification method is used as a raw material, This is a step for mixing a sludge and / or sludge incineration ash containing and magnesium oxide and / or a magnesium salt to form a mixture used in a melting step described below. The converter slag used as the phosphorus adsorbing material in the dephosphorization / deammonification method must have, in addition to the component composition shown in Table 1 above, a phosphorus component dissolved in the water to be treated adsorbed on its surface. Therefore, it can be suitably used as a raw material for producing a melt-solidified material useful as a plant fertilizer.
[0051]
The converter slag that is preferably used in this step is not particularly limited as long as it is used as an adsorbent in the dephosphorization method and has adsorbed a phosphorus component. For example, 120 days a column packed with a converter slag of particle size 0.5 to 1.2 mm, slag 1kg per phosphorus content was passed through a treated water of 1 to 5 mg / l in _P 2 _{O 5} 15 ４５45 g increased.
[0052]
Also, in this step, sludge containing phosphate groups and / or sludge incineration ash is mixed, because these are usually treated as wastes, and these also produce a molten solidified material useful as a fertilizer. This is because a phosphorus component necessary for the cleaning is contained, and by using the present invention, waste can be effectively used.
[0053]
The sludge and / or sludge incineration ash containing phosphate groups that can be mixed in this step is not particularly limited. For example, polymer-based sewage sludge using a polymer flocculant for sewage treatment, or polymer-based sewage sludge incinerated ash obtained by burning polymer-based sewage sludge has a high phosphorus content, and thus is desirable.
[0054]
The reason for mixing the magnesium oxide and / or the magnesium salt in this step is to replenish magnesium which is a component necessary for producing a molten solid.
[0055]
(2) Melting Step Next, the melting step will be described. The melting step in the method for producing a molten solid according to the present invention is a step of forming a melt by melting the mixture formed in the mixing step at 1350 ° C. or higher in the presence of oxygen.
[0056]
The melting step in the present invention is not particularly limited as long as a melt can be formed under the above conditions. Therefore, it is possible to use a conventionally known melting furnace.
[0057]
In addition, in the melting step in the method of the present invention, since melting is performed at 1350 ° C. or higher, pathogenic bacteria and viruses in waste can be killed, and thus a melt-solidified product excellent in hygiene can be produced. .
[0058]
(3) Cooling and solidifying step Next, the cooling and solidifying step will be described. The cooling and solidifying step in the method for producing a molten and solidified body of the present invention is a step for producing a molten and solidified body as the final target of the present invention by cooling and solidifying the melt formed in the melting step. .
[0059]
The cooling and solidification step in the present invention is not particularly limited as long as the above object can be achieved, and specific methods and apparatuses thereof are not particularly limited. For example, as a method of cooling and solidifying the melt, a water cooling method of introducing the melt into water is preferred because it is simple and inexpensive. It may be dried and then pulverized by a pulverizer to a size suitable for use as a fertilizer.
[0060]
Here, in the method of the present invention, when the mixture is formed in the mixing step described above, an alkaline earth alkaline component such as CaO, MgO or the like as a component of the molten solidified product as a final product is 40%. As described above, it is preferable to mix so that the soluble soda is 12% or more and the soluble phosphoric acid is 17% or more. This is because the molten solid having such a component can be used as a soluble phosphorus fertilizer.
[0061]
According to the Fertilizer Control Law, the components of the molten phosphorus fertilizer are determined to be 17% or more soluble phosphoric acid, 40% or more alkali, and 12% or more soluble magnesia. By adjusting and mixing to become components, a molten phosphorus fertilizer can be produced.
[0062]
Here, as a method for adjusting to the above components, each component (alkaline earth alkaline component such as CaO, MgO, etc.) contained in the converter slag after being used as a phosphorus adsorbing material used as a raw material, There is a method in which the amount of soluble formic acid and soluble phosphoric acid) is measured in advance, and the shortage is replenished.
[0063]
For example, as a material that is replenished so as to have an alkaline earth alkaline component of CaO, MgO or the like of 40% or more and a soluble grit of 12% or more, as a material of CaO, MgO and / or a salt thereof, a steel mill or the like is used. The generated waste material of magnesia-based refractories, dolomite-based refractories, and converter slag can be used. On the other hand, as a substance to be replenished so that the soluble phosphoric acid becomes 17% or more, waste phosphoric acid or waste phosphate used for metal surface treatment or the like is used as a material of phosphoric acid and / or a salt thereof. be able to.
[0064]
【The invention's effect】
As described above, according to the present invention, it is possible to effectively use converter slag generated from a converter in an ironworks to remove phosphorus from the water to be treated and ammonia. Furthermore, according to the present invention, ammonia fertilizer can be produced using ammonia removed from the water to be treated, and furthermore, converter slag used for removing phosphorus and its disposal have been a problem. By using sludge and / or sludge incineration ash which has been used as a raw material, it is possible to produce a molten and solidified body useful as a fertilizer for plants.
[Brief description of the drawings]
FIG. 1 is a flowchart showing an example of the method for dephosphorization / deammonification of the present invention.
FIG. 2 is a flowchart showing another example of the phosphorus removal / deammonification method of the present invention.
FIG. 3 is a schematic sectional view of an apparatus for performing a dephosphorization step in the dephosphorization / deammonification method of the present invention.
FIG. 4 is a diagram showing the relationship between the pH and temperature of water to be treated and the molar ratio of free ammonia.
FIG. 5 is a flow chart showing a method for producing a molten solid according to the present invention.
[Brief description of reference numerals]
30 tank 31 stirrer 32 converter slag

Claims (6)

A dephosphorization / deammonification method for removing a phosphorus component and an ammonia component from water to be treated,
A first pH adjustment step of adding sulfuric acid and / or hydrochloric acid to the water to be treated to adjust the pH to 3.5 or less;
A second pH adjustment step of adding an aqueous solution of caustic soda to the water to be treated after the first pH adjustment step to adjust the pH to 9.0 or more;
Adding a calcium chloride aqueous solution to the water to be treated after completion of the second pH adjustment step, a calcium chloride addition step,
A dephosphorization step, in which the water to be treated after the calcium chloride addition step is passed through a filling tank formed by filling the tank with a slag pulverized product generated from the converter as a phosphorus-adsorbing material and filling the tank. , To remove phosphorus from the water to be treated,
Performing an ammonia stripping method on the water to be treated after the dephosphorization treatment in the phosphorus removal step, removing ammonia from the water to be treated by the deammonification step,
A dephosphorization / deammonification method characterized by the above-mentioned. In the dephosphorization step, instead of using a filling tank, the slag generated by the converter is refined and used as a phosphorus adsorbent, and the phosphorus adsorbent material is added to the water to be treated after the calcium chloride addition step. The phosphorus removal / deammonification method according to claim 1, wherein phosphorus in the water to be treated is removed by flowing and floating. The dephosphorization / deammonification method according to claim 1 or 2, wherein the water to be treated is sludge treatment return water. The ammonia gas diffused from the water to be treated is recovered by the dephosphorization / deammonification method according to any one of claims 1 to 3, and the ammonia gas is selected from sulfuric acid, nitric acid, and phosphoric acid. A method for producing ammonia fertilizer, comprising washing with ammonia to obtain ammonia fertilizer. The crushed converter slag used as a phosphorus-adsorbing material in the dephosphorization / deammonification method according to any one of claims 1 to 3, and sludge and / or sludge incineration containing phosphate groups. A mixing step of mixing the ash with magnesium oxide and / or a magnesium salt;
A melting step of melting the mixture formed in the mixing step at 1350 ° C. or higher in the presence of oxygen;
A cooling and solidifying step of forming a molten solid by cooling and solidifying the melt formed in the melting step;
A method for producing a molten and solidified body, characterized by having: In the mixing step, the components of the melt-solidified product as the final product are such that the alkaline components of alkaline earths such as CaO and MgO are 40% or more, the soluble magnesium is 12% or more, and the soluble phosphoric acid is 17% or more. The method for producing a melt-solidified product according to claim 5, wherein the components are mixed so as to form a mixture.

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