JP2005028246A - Treatment method for heavy metal-containing wastewater - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a treatment method for heavy metal-containing wastewater capable of easily removing heavy metals and a pollutant contained in heavy metal-containing wastewater. <P>SOLUTION: In the treatment method for the heavy metal-containing wastewater containing the pollutant, an inorganic flocculant 3 is added to the heavy metal-containing wastewater containing the pollutant and, after this flocculant-added wastewater is stirred, zeolite 5 is added to the heavy metal-containing wastewater to remove the heavy metals and the pollutant. Further, in this treatment method for the heavy metal-containing wastewater, a polymer flocculant may be added after the zeolite 5 is added. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

【００２５】
（試験方法）１０００ｍｌのメスシリンダーに人工汚染濁水を充填し、そこに無機凝集剤であるポリ塩化アルミニウム（ＰＡＣ）を添加・撹拌した後、ゼオライトを添加し、一定時間経過後の上澄液の濁度、鉛の濃度測定を行い、重金属除去効果及び濁質除去効果を確認した。
試験時間は１時間とし、重金属濃度に関しては１時間経過後の値を全ケースについて測定した。濁度は、ゼオライト添加後、５，１０，３０経過後及び１時間経過後の値を全ケースについて測定した。
【００２６】
（試験結果）
【表２】

前記実験結果から、いずれのケースにおいても濁度、鉛濃度は共に低下しており、無機添加剤であるＰＡＣとゼオライトを添加することにより、濁質及び鉛を除去できることがわかった。
【００２７】
図２に、前記実験結果から得られる濁度の経時変化を示す。図２から明確にわかるように、ゼオライトを添加することにより濁度が短時間で低下する。これは、予めＰＡＣを添加していることで濁質によるフロックが形成され、その後ゼオライトを添加することにより、濁質よりはるかに大きい粒径のゼオライトがフロックを引き連れて沈降する共沈効果によるものであると考えられる。この実験結果より、無機凝集剤を添加した後にゼオライトを添加することにより、重金属及び濁質の除去効果が顕著に得られることが確認できた。
【００２８】
図３に、前記実験結果から得られる鉛除去率を示す。ケース１から３に着目すると、ケース１から３は同じ濃度の鉛を含む排水に対して、異なる量のゼオライトを添加している。ケース２は、ケース１より１０倍のゼオライトを添加しており、ケース１より高い鉛除去率であった。しかし、ケース３は、ケース２の１０倍のゼオライトを添加しているが、鉛除去率はほとんど変わらない。また、濁度の経時変化ではケース１、ケース２において濁度の除去率はほとんど変わらない。すなわち、ゼオライトの添加量は、濁度の除去率にはあまり影響を及ぼさないが、重金属の除去率には影響することが確認できた。従って、ゼオライトの添加量は、重金属の除去率に応じて適宜に調整することが望ましいといえる。
【００２９】
【発明の効果】
以上のように本発明によれば、無機凝集剤とゼオライトを添加することにより、重金属含有排水に含まれている重金属及び濁質を容易に除去することができる。また、石炭灰等から生成される人工ゼオライトを重金属含有排水の処理に用いることにより、産業廃棄物となる石炭灰等を有効活用し、産業廃棄物の最終処分量の減縮を図ることが可能となる。
【図面の簡単な説明】
【図１】実施の形態に係る重金属含有排水の処理方法の概略図ある。
【図２】実験例における濁度の経時変化を示した図ある。
【図３】実験例における鉛の除去率を示した図ある。
【符号の説明】
１ ｐＨ調整槽
１１ 貯水槽
１２ 攪拌機
１３ａ 硫酸
１３ｂ 水酸化ナトリウム
１４ モニター
１５ ｐＨ制御盤
２ ラインミキサ
３ ポリ塩化アルミニウム
４ シックナー
５ ゼオライト
６ 上澄水受槽[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for treating heavy metal-containing wastewater containing turbidity, such as wastewater generated during purification of factory wastewater and heavy metal-contaminated soil.
[0002]
[Prior art]
Conventionally, for example, the following method has been used as a method for treating heavy metal-containing wastewater generated in purification work of heavy metal-contaminated soil. First, after adjusting the pH of the heavy metal-containing wastewater to near neutral, the suspended matter is settled and separated using an inorganic flocculant. Thereafter, the pH of the waste water is adjusted (pH value around 10), or the heavy metal contained therein is settled and separated as a precipitate, and the precipitate is removed. Further, the waste water from which the precipitate is removed is adjusted to a pH value that can be discharged and discharged or reused.
[0003]
However, conventional methods for treating heavy metal-containing wastewater have the following problems. First, there is a problem that a precipitation separation tank for treating turbidity and a precipitation separation layer for treating heavy metals are necessary, and the treatment facility becomes large. In addition, the optimum pH value for separating and separating the turbidity contained in the wastewater is around neutral, but the optimum pH value for treating heavy metals is around 10, and the wastewater that can be discharged can be discharged. Since the pH value is 5.8 to 8.6, pH adjustment has to be performed several times, requiring time and labor.
[0004]
[Problems to be solved by the invention]
The present invention has been made in view of such problems, and provides a technique for providing a heavy metal-containing wastewater treatment method capable of easily removing heavy metals and turbidity contained in heavy metal-containing wastewater. As an objective.
[0005]
[Means for Solving the Problems]
The present invention is a method for treating heavy metal-containing wastewater containing turbidity, and is configured as follows in order to solve the above technical problem.
[0006]
The present invention is characterized in that an inorganic flocculant is added to the heavy metal-containing wastewater containing turbidity, stirred, and then added with zeolite to remove heavy metals and turbidity contained in the heavy metal-containing wastewater.
[0007]
Here, the term “zeolite” refers to adjusted porous aluminum and calcium (or sodium) silicate (for example, CaO · 2Al ₂ O ₃ · 5SiO ₂ , Na ₂ O · 2Al ₂ O ₃ · 5SiO ₂ ) water It is a Japanese product. This zeolite has a cation exchange function, an adsorption function, and a catalyst function, and has been widely used as a soil conditioner, a deodorant, and vegetation concrete as conventional applications. In this invention, paying attention to the said function of a zeolite, it is the method of processing the heavy metal containing waste water containing a suspended matter using with the said inorganic flocculant.
[0008]
The zeolite is roughly classified into natural zeolite, scientifically synthesized synthetic zeolite, coal ash and the like, artificial zeolite obtained by chemical treatment of combustion dust containing silica and alumina. The present invention is not particularly limited as long as it has a cation exchange function, an adsorption function, and a catalyst function, and any zeolite can be used.
[0009]
However, in the present invention, the artificial zeolite can be particularly preferably used. In recent years, there has been a growing interest in the industrial waste problem, and there is a demand for effective use of industrial waste. For example, among industrial waste, about 3 million tons of the annual generation amount of about 5 million tons is effectively used, but about 2 million tons are buried. Of the approximately 3 million tons that are used effectively, 75% is in the cement and concrete fields. However, in recent years, the reuse of coal ash in the cement and concrete fields has been decreasing from the viewpoint of safety and the like, and it is difficult to expect an increase in the effective use of coal ash. In the present invention, by using artificial zeolite, it is possible to effectively utilize coal ash or the like which is industrial waste, and to reduce the final disposal amount of industrial waste.
[0010]
The said inorganic flocculant is 1 type of the flocculant which is a chemical | medical agent which removes the turbidity etc. of water. When the inorganic flocculant is added to heavy metal-containing wastewater containing turbidity, it has a property of biochemical reaction with fine suspended particles in the wastewater to form a small block (floc). Examples of the inorganic flocculant include polyaluminum chloride, aluminum sulfate, sulfate band, ferric sulfate, ferrous sulfate, sodium aluminate, ammonium alum, and coal. As a result of various experimental considerations, In particular, polyaluminum chloride can be preferably used.
[0011]
The present invention adds an inorganic flocculant to a heavy metal-containing wastewater containing turbidity and stirs it to flock the turbidity contained in the wastewater, and then adds the zeolite to the wastewater. Adsorb heavy metal on zeolite. The flocculent suspended matter and the zeolite adsorbing the heavy metal are aggregated to generate a larger floc. By separating the flocs by sedimentation, turbidity and heavy metals can be removed simultaneously.
[0012]
In the present invention, it is desirable to add a polymer flocculant after adding the zeolite. The polymer flocculant is a kind of the flocculant. Depending on the sequestration state in water, it is roughly divided into chaotic, nonionic, and anionic. For example, generally, a chaotic polymer flocculant is used as an agglomeration aid during organic sludge dehydration. Nonionic and anionic polymer flocculants are used as flocculating aids when aluminum salts or the like are used as flocculants. In the present invention, various polymer flocculants can be used and are not particularly limited. In the present invention, after adding the zeolite, a polymer flocculant is added to effectively act on the aggregation of heavy metal and turbidity, and the processing speed can be accelerated.
[0013]
Moreover, it is desirable that the heavy metal to be treated in the present invention is a heavy metal present in the waste water as a cation such as cadmium or lead. As described above, the synthetic zeolite used in the present invention has a cation exchange function, has a high function of adsorbing heavy metals existing as cations, and can obtain a remarkable effect.
[0014]
In addition, when the present invention contains at least cadmium, it is desirable to add the inorganic flocculant after adjusting the pH value of the heavy metal-containing wastewater to 7.5 or more. The zeolite is alkaline, and cadmium has the property of being precipitated as a hydroxide in the alkaline region. Moreover, it was found from various experimental results that adsorption of cadmium becomes unstable at pH 7 or lower. As a result of various considerations based on these facts, it is preferable that the pH value is 7.5 or more when cadmium is removed. In addition, by setting the pH value to 8.6 or less within the discharge standard for wastewater, it can be discharged without adjusting the pH after removing heavy metals and turbidity, so wastewater treatment can be performed more efficiently. It becomes.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. This embodiment is a treatment of wastewater containing heavy metals including turbidity generated in soil contamination repair work. First, an apparatus used in an embodiment of the present invention will be described based on the schematic diagram shown in FIG. In the present embodiment, an artificial zeolite produced from coal ash is used.
[0016]
The pH adjustment tank 1 includes a water storage tank 11 for storing wastewater to be treated for a certain period, a stirrer 12 for stirring the stored wastewater, sulfuric acid 13a and sodium hydroxide 13b as chemicals for neutralizing the wastewater, A pH monitor 14 for measuring the pH value of the water and a pH control panel 15 for controlling the introduction of the drug according to the pH value measured by the pH monitor, and adjusting the pH of the wastewater to be treated.
[0017]
The line mixer 2 is a tubular mixing device and mixes chemicals and the like in the tube. An inorganic flocculant is added into the line mixer 2, and the heavy metal-containing wastewater and the inorganic flocculant are mixed and stirred. The thickener 4 is a device that separates fine particles contained in waste water by sedimentation by gravity, and is used for sedimentation and separation of heavy metals and suspended matter. The supernatant water receiving tank 6 stores wastewater from which heavy metals and turbid substances have been separated by settling for a certain period of time, and is used for pH adjustment and the like as necessary.
[0018]
Here, a method for producing artificial zeolite used in the present embodiment will be described. The main components constituting the coal ash which is a material for producing zeolite are SiO ₂ (silica) and Al ₂ O ₃ (alumina), and both components occupy about 70 to 90%. Examples of other components include Fe ₂ O ₃ (iron) and CaO (calcium) of several percent, and examples of trace components include Na ₂ O (sodium), MgO (magnesium), and K ₂ O (potassium). Coal ash is not simply a mixture of a silicate component and an aluminum component, but an Si—O—Al bond is considered from the infrared absorption spectrum, and has an aluminum silicate structure containing impurities. In addition, coal ash is an anhydride that contains almost no structure OH, and is amorphous aluminum silicate anhydride. Therefore, in order to obtain artificial zeolite, zeolite crystallization of coal ash is performed by treating the coal ash with alkali.
[0019]
As the procedure, first, an alkali solution such as coal ash and caustic soda is mixed, and the mixed slurry is heated to a specified temperature to be reacted. In some cases, pressurization is performed to increase the reaction rate. After completion of the reaction, washing and solid-liquid separation are performed, and the separated one is dried. This dried product is artificial zeolite. In addition, the artificial zeolite used for this Embodiment is not restricted to the said production | generation method, The zeolite obtained by the other production | generation method may be sufficient.
[0020]
Next, this embodiment using the apparatus will be described in detail. First, the heavy metal-containing wastewater containing turbidity is stored in the pH adjustment tank 1. When cadmium is contained in the heavy metal-containing wastewater, chemicals such as sulfuric acid 13a and sodium hydroxide 13b are added to adjust the pH to about 7.5 to 8.6. At this time, if cadmium is not contained in the waste water, pH adjustment may not be performed. Next, the pH-adjusted waste water or waste water not containing cadmium is injected into the line mixer 2. Then, polyaluminum chloride (PAC) 3 as an inorganic additive is added to the waste water in the line mixer 2 and mixed and stirred.
[0021]
Heavy metal containing wastewater mixed with polyaluminum chloride 3 in the line mixer 2 is stored in the thickener 4. Zeolite 5 is added after the turbidity contained in the waste water reacts with polyaluminum chloride 3 to flocculate the turbidity. When the zeolite 5 is added, heavy metals contained in the waste water are adsorbed on the zeolite 5. Then, the flocculent suspended matter and the zeolite 5 adsorbing heavy metals are aggregated, and a larger floc is generated. By leaving this waste water in the thickener 4 for a certain period of time, the floc settles down due to gravity, and heavy metals and turbidity are separated from the waste water.
[0022]
After removing the separated heavy metals and turbidity, the waste water is stored in the supernatant water receiving tank 6. Then, if necessary, the pH is adjusted, or when fine fine particles other than heavy metals are contained, the treatment is performed, and the waste water is treated so that it can be discharged or reused.
[0023]
As described above, according to the present embodiment, by adding the polyaluminum chloride 3 and the zeolite 5 to the heavy metal-containing wastewater containing turbidity, it is possible to separate and remove the turbidity and heavy metal at the same time. In addition, wastewater containing heavy metals can be treated. Moreover, since the said zeolite 5 is produced | generated from coal ash, effective utilization of coal ash can be accelerated | stimulated and reduction of industrial waste can be aimed at.
[0024]
<Experimental example>
Using artificial turbid water containing heavy metal, artificial zeolite and inorganic flocculant were used in combination, and the removal effect of turbidity and heavy metal was confirmed. The heavy metal to be removed in this experiment is lead, and the turbidity to be removed is clay. Table 1 shows a list of test cases.
[Table 1]

[0025]
(Test method) Fill a 1000 ml graduated cylinder with artificially contaminated turbid water, add and agitate polyaluminum chloride (PAC), an inorganic flocculant, and then add zeolite. Turbidity and lead concentration were measured, and the heavy metal removal effect and turbidity removal effect were confirmed.
The test time was 1 hour, and the heavy metal concentration was measured for all cases after 1 hour. The turbidity was measured for all cases after 5, 10, 30 and 1 hour after addition of zeolite.
[0026]
(Test results)
[Table 2]

From the above experimental results, it was found that both turbidity and lead concentration were lowered in any case, and turbidity and lead could be removed by adding inorganic additives PAC and zeolite.
[0027]
FIG. 2 shows the change over time in turbidity obtained from the experimental results. As clearly shown in FIG. 2, the turbidity decreases in a short time by adding zeolite. This is due to the coprecipitation effect in which flocs due to turbidity are formed by adding PAC in advance, and by adding zeolite after that, zeolite having a particle size much larger than that of turbidity precipitates with flocs. It is thought that. From this experimental result, it was confirmed that the removal effect of heavy metals and turbidity was remarkably obtained by adding zeolite after adding the inorganic flocculant.
[0028]
FIG. 3 shows the lead removal rate obtained from the experimental results. Focusing on cases 1 to 3, cases 1 to 3 add different amounts of zeolite to waste water containing lead of the same concentration. Case 2 had 10 times as much zeolite added as Case 1 and had a higher lead removal rate than Case 1. However, Case 3 contains 10 times as much zeolite as Case 2, but the lead removal rate is almost unchanged. In addition, the turbidity removal rate hardly changes in Case 1 and Case 2 when the turbidity changes with time. That is, it was confirmed that the amount of zeolite added did not significantly affect the removal rate of turbidity, but had an effect on the removal rate of heavy metals. Therefore, it can be said that the amount of zeolite added is suitably adjusted according to the heavy metal removal rate.
[0029]
【The invention's effect】
As described above, according to the present invention, heavy metals and turbidity contained in heavy metal-containing wastewater can be easily removed by adding an inorganic flocculant and zeolite. In addition, by using artificial zeolite produced from coal ash, etc., for the treatment of wastewater containing heavy metals, it is possible to effectively utilize coal ash, etc., which becomes industrial waste, and to reduce the final disposal amount of industrial waste. Become.
[Brief description of the drawings]
FIG. 1 is a schematic view of a method for treating heavy metal-containing wastewater according to an embodiment.
FIG. 2 is a graph showing a change with time of turbidity in an experimental example.
FIG. 3 is a diagram showing a lead removal rate in an experimental example.
[Explanation of symbols]
1 pH adjustment tank 11 Water storage tank 12 Stirrer 13a Sulfuric acid 13b Sodium hydroxide 14 Monitor 15 pH control panel 2 Line mixer 3 Polyaluminum chloride 4 Thickener 5 Zeolite 6 Supernatant water receiving tank

Claims (4)

A method for treating wastewater containing heavy metals including turbidity,
Treatment of heavy metal-containing wastewater characterized by adding an inorganic flocculant to the heavy metal-containing wastewater containing turbidity, stirring the mixture, and then adding zeolite to remove heavy metals and turbidity contained in the heavy metal-containing wastewater. Method. The method for treating heavy metal-containing wastewater according to claim 1, wherein a polymer flocculant is added after the zeolite is added. The said heavy metal is a heavy metal which exists in the said waste_water | drain as cations, such as cadmium and lead, The processing method of the heavy metal containing waste water of Claim 1 or Claim 2 characterized by the above-mentioned. When the heavy metal contains at least cadmium, the inorganic flocculant is added after adjusting the pH value of the heavy metal-containing wastewater to 7.5 or more. A method for treating wastewater containing heavy metals as described in 1.

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