JP4468568B2 - Water treatment flocculant, method for producing the same, and water treatment method - Google Patents

Description

表１から明らかな様に、実施例１、実施例２、実施例３、実施例４及び実施例５の再生凝集剤は、いずれも市販の凝集剤と同等以上の凝集効果を呈するものである。
これに対して、比較例３の再生凝集剤は、市販の凝集剤よりも凝集効果が劣るものであった。
【００３０】
【発明の効果】
本発明によれば、浄水場で発生したスラッジから回収した凝集剤は、その凝集剤に主成分として含有されている塩化アルミニウム又は硫酸アルミニウムがAl₂O₃として１０重量％となるように換算した換算水処理凝集剤中のマンガン含有量を２０ｐｐｍ以下にでき、且つ市販の凝集剤と同程度以上の凝集性を発揮し得るため、浄水場の凝集剤として再使用できる。
このため、浄水場においては、凝集剤を循環使用することができ、浄水場外から凝集剤の搬入や環境問題を解消することができる。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a water treatment flocculant, a method for producing the same, and a water treatment method, and more specifically, a water treatment flocculant recovered from sludge generated in a water treatment process for water to obtain clean water supplied to beverages, etc. The present invention relates to a production method and a water treatment method.
[0002]
[Prior art]
In a water treatment plant (hereinafter sometimes referred to as a water purification plant) for obtaining drinking water from raw water taken from a river or the like, water treatment flocculant (hereinafter simply referred to as flocculant) is used in the water treatment process. May be used). As such a flocculant, a flocculant mainly composed of an aluminum compound is widely used.
Conventionally, a new flocculant has been used for this flocculant. However, it is necessary to carry the flocculant from outside the water purification plant, and the cost of chemicals is high.
Furthermore, in recent years, environmental problems have been highlighted, and the disposal of flocculants is becoming a problem. For this reason, after collecting the flocculant and reusing it, for example, adding sulfuric acid to sludge containing a large amount of the aluminum compound that is the main component of the flocculant, and dissolving the aluminum compound as aluminum sulfate, A method for obtaining a flocculant using as a raw material a solution containing aluminum sulfate as a main component, obtained by filtration from insoluble solids in sludge was studied.
[0003]
However, in the sludge generated at the water purification plant, in addition to the aluminum compound as a main component, a manganese compound is also contained at a high concentration. This is because naturally derived manganese compounds contained in the raw water are concentrated in the sludge.
Such a manganese compound is dissolved by reacting with sulfuric acid and contained in a solution containing aluminum sulfate as a main component. For this reason, a manganese compound is also contained in the flocculant obtained using such a solution as a raw material, and manganese is also contained at a high concentration in the finally obtained flocculant. Since manganese is a metal harmful to the human body, a flocculant containing manganese in a high concentration cannot be used as a water treatment flocculant in a water purification plant.
In this way, Japanese Patent Publication No. 53-35880 proposes a recovery method for recovering an aluminum compound while removing the manganese compound from the aluminum-based sludge containing the manganese compound at a high concentration.
In this recovery method, sulfuric acid is added to aluminum-based sludge containing a manganese compound to dissolve the aluminum compound, and then a weakly basic inorganic compound having a saturated aqueous solution having a pH of about 7 to 11 is added to the aqueous sulfuric acid solution to adjust the pH to 4 The aluminum compound is precipitated again at ˜6.
[0004]
[Problems to be solved by the invention]
According to the aluminum compound recovery method proposed in the above publication, a flocculant mainly composed of aluminum sulfate having a very low manganese content can be obtained from sludge in which a manganese compound is present at a high concentration.
However, the aggregating effect of the regenerated flocculant mainly composed of aluminum sulfate recovered from the sludge of the water purification plant is inferior to that of a commercially available flocculant.
Accordingly, an object of the present invention is to remove manganese from sludge generated in a water treatment process for water to obtain water that is supplied to drinking water by adding a water treatment flocculant composed mainly of an aluminum compound to raw water. A water treatment flocculant mainly composed of the recovered aluminum compound, and a water treatment flocculant capable of exhibiting the same degree of agglomeration effect as a water treatment flocculant mainly composed of a commercially available aluminum compound, and a method for producing the same. Another object is to provide a water treatment method using the water treatment flocculant.
[0005]
[Means for Solving the Problems]
In order to solve the above problems, the present inventors first examined the cause of the regenerated flocculant mainly composed of aluminum sulfate recovered from the sludge of the water purification plant being inferior to the commercially available flocculant. However, although the iron compound is also contained at a high concentration in the sludge of the water purification plant, the iron compound is also removed simultaneously with the removal of the manganese compound in the sludge in the recovery method proposed in the above publication.
On the other hand, iron is a metal that is harmless to the human body, and iron ions have an aggregating effect. Therefore, in order to improve the aggregating effect of the regenerated aggregating agent reused in the water purification plant, iron may remain in the regenerated aggregating agent. it can.
Based on such findings, the present inventors have made further studies. As a result, sulfuric acid was added to aluminum-based sludge containing an iron compound and a manganese compound to dissolve the aluminum compound, and then caustic soda was added to the aqueous sulfuric acid solution. In addition, by precipitating aluminum hydrate, iron can be left while removing manganese, and even with a regenerated flocculant mainly composed of aluminum chloride recovered and regenerated from sludge of a water purification plant, It has also been found that a coagulation effect comparable to that of a water treatment coagulant mainly composed of aluminum chloride can be exhibited, and the present invention has been achieved.
[0006]
That is, the present invention adds a water treatment flocculant composed mainly of an aluminum compound to raw water, and collects the water treatment flocculant recovered from the sludge generated in the water treatment process for water to obtain the water supplied to drinking water or the like. And the main component of the water treatment flocculant is aluminum chloride represented by the following general formula, and the aluminum chloride is Al ₂ O _Three In the water treatment flocculant, the manganese content in the converted water treatment flocculant converted to 10 wt% is 20 ppm or less.
General formula
Al ₂ (OH) _n Cl _(6-n) However, 0 ≦ n <6
In the water treatment flocculant whose main component according to the present invention is aluminum chloride, when the iron content in the converted water treatment flocculant is 1000 ppm or more (preferably 3000 ppm or more), the regenerated water treatment flocculant (regeneration) The aggregating effect of the aggregating agent can be further improved. As such a regenerating flocculant, a water treatment flocculant whose main component is polyaluminum chloride is preferable.
Furthermore, the present invention provides a water treatment agglomeration recovered from sludge generated in a water treatment process for water to obtain water that is supplied to drinking water by adding a water treatment flocculant composed mainly of an aluminum compound to raw water. And the main component of the water treatment flocculant is aluminum sulfate, and the aluminum sulfate is Al ₂ O _Three As a water treatment flocculant, the iron content in the converted water treatment flocculant converted to 10% by weight is 1000 ppm or more and the manganese content is 20 ppm or less.
In the water treatment flocculant whose main component according to the present invention is aluminum sulfate, when the iron content in the converted water treatment flocculant is 3000 ppm or more, the flocculant effect of the regenerated water treatment flocculant (regenerated flocculant) Can be further improved.
[0007]
Further, the present invention adds hydrochloric acid or sulfuric acid to sludge generated in a water treatment process for water to obtain water to be supplied to drinking water by adding a water treatment flocculant composed mainly of an aluminum compound to raw water. After obtaining a solution in which the aluminum compound in the sludge is dissolved, an alkali compound exhibiting strong alkalinity of pH 13 or more is added to the solution, and the solution is adjusted to pH 4.5 to 6.5 to obtain aluminum hydrate. It is also a method for producing a water treatment flocculant characterized by precipitating and then obtaining a water treatment flocculant mainly composed of aluminum chloride or aluminum sulfate using the aluminum hydrate as a raw material.
In the method for producing a water treatment flocculant according to the present invention, by using caustic soda as an alkaline compound exhibiting strong alkalinity having a pH of 13 or more, the alkali compound can be handled in a liquid state, and the handling can be facilitated.
[0008]
Furthermore, the present invention is generated in the water treatment process as a water treatment flocculant for the water treatment for the water to obtain the water to be supplied to the drinking water from the raw water taken from the river. The main component recovered from the sludge is aluminum chloride represented by the above general formula, and this aluminum chloride is Al. ₂ O _Three As a water treatment flocculant in which the manganese content in the converted water treatment flocculant converted to 10% by weight is 20 ppm or less, or the main component is aluminum sulfate, and this aluminum sulfate is Al ₂ O _Three As a water treatment method using a water treatment flocculant in which the iron content in the converted water treatment flocculant converted to 10 wt% is 1000 ppm or more and the manganese content is 20 ppm or less.
Alternatively, the present invention is recovered from sludge generated in the above water treatment process as a water treatment flocculant during the water treatment water treatment for obtaining the clean water supplied to the drinking water from the raw water taken from the river or the like. The main component is aluminum chloride represented by the above general formula, and this aluminum chloride is Al. ₂ O _Three As a water treatment flocculant in which the manganese content in the converted water treatment flocculant converted to 10% by weight is 20 ppm or less, or the main component is aluminum sulfate, and this aluminum sulfate is Al ₂ O _Three It is also a water treatment method characterized by reusing a water treatment flocculant in which the iron content in the converted water treatment flocculant converted to 10% by weight is 1000 ppm or more and the manganese content is 20 ppm or less. .
[0009]
In the present invention, a sulfuric acid solution in which the aluminum compound in the sludge is dissolved is obtained. This sulfuric acid solution contains a sulfuric acid compound with aluminum, manganese, iron, etc. contained in the sludge.
However, when an alkaline compound exhibiting strong alkalinity of pH 13 or higher is added to the sulfuric acid solution and the sulfuric acid solution is adjusted to pH 4.5 to 6.5, aluminum hydrate and iron compound are precipitated, but sulfuric acid with manganese The compound is in a dissolved state.
For this reason, the cake and the manganese compound containing the aluminum hydrate, the iron compound, and the like, from which the manganese compound has been substantially removed, are separated by separating the precipitate and the solution that have been adjusted by pH adjustment by filtration or the like. It can be separated into a contained solution.
Next, by subjecting the cake to a predetermined treatment, a water treatment flocculant whose main component is aluminum sulfate can be obtained. In this water treatment flocculant, aluminum sulfate is Al ₂ O _Three The iron content in the converted water treatment flocculant converted to 10% by weight is 1000 ppm or more and the manganese content is 20 ppm or less.
[0010]
Such a water treatment flocculant has a very low manganese content and can be used as a flocculant for clean water, and has a high iron content, and therefore exhibits a cohesiveness equal to or higher than that of a commercially available water treatment flocculant.
In addition, water treatment in which the main component is aluminum chloride represented by the above general formula is obtained by dissolving the aluminum compound in the sludge in hydrochloric acid to obtain a water treatment flocculant in which the main component is aluminum sulfate. A flocculant can be obtained. In this water treatment flocculant, this aluminum chloride is Al ₂ O _Three As a result, the manganese content in the converted water treatment flocculant converted to 10% by weight is 20 ppm or less. Such a water treatment flocculant mainly composed of aluminum chloride can exhibit good cohesiveness even when the iron content in the converted water treatment flocculant is 1000 ppm or less.
For this reason, the water treatment flocculant according to the present invention can be used as a flocculant in a water purification plant, and again from the sludge generated using the water treatment flocculant according to the present invention as a flocculant, Can be recovered and reused as a flocculant.
As a result, the water treatment flocculant can be circulated and used in the water purification plant, and the disposable use of the water treatment flocculant can be substantially eliminated.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
The water treatment flocculant (flocculant) according to the present invention is obtained from sludge generated in a water treatment process for water to obtain tap water to be supplied to drinking water by adding a flocculant composed mainly of an aluminum compound to raw water. Recovered flocculant, the main component is aluminum sulfate, and aluminum sulfate is Al ₂ O _Three The iron content in the converted water treatment flocculant converted to 10% by weight is 1000 ppm or more (preferably 3000 ppm or more) and the manganese content is 20 ppm or less.
Here, when the iron content in the reduced water treatment flocculant is less than 1000 ppm, the recovered flocculant is inferior in agglomeration performance as compared with the flocculant whose main component is aluminum sulfate.
Moreover, when the manganese content in the conversion water treatment flocculant exceeds 20 ppm, it is not preferable to use the recovered flocculant at the water purification plant. Currently, the water quality standards for clean water specify that the manganese content in clean water should be 0.05 ppm or less, but manganese in clean water is an additive such as manganese eluted from natural soil and coagulant. And manganese eluted from Among these, the amount of manganese eluted from the manganese contained in the additive such as a flocculant into the tap water is controlled to be 0.005 ppm or less.
[0012]
Therefore, by setting the manganese content in the flocculant to 20 ppm or less in the converted water treatment flocculant, even if most of the manganese compound in the flocculant is eluted in the water, the flocculant contained in the water The amount of manganese derived from the manganese compound therein can be made 0.005 ppm or less.
Further, the flocculant according to the present invention is a flocculant recovered from sludge generated in a water treatment process for water to obtain tap water to be supplied to drinking water by adding a flocculant composed mainly of an aluminum compound to raw water. The main component is aluminum chloride represented by the general formula shown below. ₂ O _Three The manganese content in the converted water treatment flocculant converted to 10% by weight is 20 ppm or less.
General formula
Al ₂ (OH) _n Cl _(6-n) However, 0 ≦ n <6
Among the aluminum chlorides represented by the above general formula, when n = 0, it is a normal salt aluminum chloride, and the basicity [(n / 6) × 100] is 15 to 83% (preferably 15 to 60%). ) Is polyaluminum chloride (basic aluminum chloride).
Also in such a flocculant, it is preferable that the iron content in the reduced water treatment flocculant is 1000 ppm or more (particularly 3000 ppm) or more because the aggregability can be further improved.
[0013]
In order to obtain such a flocculant according to the present invention, first, a water treatment flocculant composed mainly of an aluminum compound was added to the raw water and generated in a water treatment process for water to obtain clean water supplied to drinking water and the like. Hydrochloric acid or sulfuric acid is added to the sludge to obtain a hydrochloric acid solution or a sulfuric acid solution in which the aluminum compound in the sludge is dissolved.
For such sludge, a water treatment flocculant composed mainly of an aluminum compound is used in a water purification plant. ₂ O _Three About 10% by weight of an aluminum compound is contained in terms of conversion. The aluminum compound in the sludge reacts with the added hydrochloric acid or sulfuric acid and dissolves in the hydrochloric acid solution or sulfuric acid solution as aluminum chloride or aluminum sulfate, so the hydrochloric acid solution or aluminum sulfate in which aluminum chloride is dissolved is dissolved. The sulfuric acid solution can be separated from the sludge by filtration.
[0014]
Here, it is preferable to adjust the amount of hydrochloric acid added to the sludge generated in the water treatment process for clean water so as to be equivalent to the aluminum contained in the sludge.
If the aluminum concentration in the hydrochloric acid solution obtained by adding such an amount of hydrochloric acid is too low, the finally obtained flocculant becomes unstable, and aluminum or the like is precipitated as a hydrate, and finally obtained. There is a tendency that the aggregating performance of the aggregating agent is insufficient. On the other hand, if the aluminum concentration in the hydrochloric acid solution is too high, the viscosity of the slurry composed of sludge and hydrochloric acid tends to be too high, which tends to hinder operations such as filtration. For this reason, the aluminum concentration in the hydrochloric acid solution is Al ₂ O _Three It is preferable to adjust the amount of sludge, the amount of water, and the amount of hydrochloric acid so that it becomes 0.1 to 6% by weight, particularly 1 to 6% by weight.
[0015]
On the other hand, also when adding sulfuric acid to sludge, it is preferable to adjust the addition amount of sulfuric acid so that it may become equivalent to the aluminum contained in sludge.
If the aluminum concentration in the sulfuric acid solution obtained by adding such an amount of sulfuric acid is too low, the finally obtained flocculant becomes unstable, and aluminum or the like is precipitated as a hydrate, and finally obtained. There is a tendency that the aggregating performance of the aggregating agent is insufficient. On the other hand, when the aluminum concentration in the sulfuric acid solution is too high, the viscosity of the slurry composed of sludge and sulfuric acid tends to be too high, which may hinder operations such as filtration. For this reason, the aluminum concentration in the sulfuric acid solution is Al ₂ O _Three It is preferable to adjust the amount of sludge, the amount of water, and the amount of sulfuric acid so that it becomes 0.1 to 6% by weight, particularly 1 to 6% by weight.
The reaction between the aluminum compound in the sludge and hydrochloric acid or sulfuric acid can be carried out in the range of room temperature to 100 ° C. (preferably 50 to 95 ° C.).
[0016]
In such hydrochloric acid solution or sulfuric acid solution, manganese compounds and iron compounds contained in the sludge are dissolved by reacting with hydrochloric acid or sulfuric acid in the same manner as the aluminum compounds.
For this reason, an alkaline compound exhibiting strong alkalinity of pH 13 or more as a neutralizing agent is added to this hydrochloric acid solution or sulfuric acid solution, and the hydrochloric acid solution or sulfuric acid solution is adjusted to pH 4.5 to 6.5, thereby substantially adding the manganese compound. Thus, aluminum hydrate (aluminum hydroxide) and iron compound can be precipitated without causing precipitation.
Therefore, by filtering the pH-adjusted solution, it can be separated into a cake containing aluminum hydrate and iron compound and a filtrate containing manganese compound. This filtrate can be returned to raw water by reducing or removing the amount of manganese by a known coagulation precipitation method or the like, if necessary.
Here, caustic soda or caustic potash that can be handled as a solution can be preferably used as an alkaline compound having a strong alkalinity of pH 13 or more used as a neutralizing agent, but caustic soda is particularly preferable from the viewpoint of drug cost.
[0017]
If weakly basic alkali compounds such as sodium bicarbonate, calcium carbonate, and magnesium carbonate are used in place of the neutralizing agent, not only manganese but also iron in the hydrochloric acid solution or sulfuric acid solution is removed.
In addition, when the pH of a solution obtained by adding an alkaline compound exhibiting strong alkalinity of pH 13 or higher to a hydrochloric acid solution or a sulfuric acid solution is less than 4.5, the recovery rate of aluminum contained in the sludge decreases. On the other hand, when the pH of the solution to which the alkali compound is added exceeds 6.5, manganese in the hydrochloric acid solution or the sulfuric acid solution cannot be sufficiently removed.
As described above, the detailed reason why manganese and iron with similar chemical behavior can be separated has not been clarified, but for sludge generated at a water treatment plant, river water is treated with an aluminum flocculant. It is presumed that the sludge also contains soil-derived components and that it uses an alkaline compound exhibiting strong alkalinity of pH 13 or more as a neutralizing agent.
[0018]
A flocculant whose main component is aluminum chloride can be obtained by reacting hydrochloric acid with a cake containing aluminum hydrate and iron compound separated from the manganese compound and then filtering. When reacting such cake with hydrochloric acid, the flocculant containing polyaluminum chloride (hereinafter sometimes referred to as PAC) as a main component can be obtained by making hydrochloric acid less than the equivalent to aluminum. In this reaction, a PAC having an excellent aggregating effect can be obtained by adding an appropriate amount of sulfate, such as anhydrous sodium sulfate (sodium sulfate), to hydrochloric acid. This PAC can also be obtained by reacting a cake obtained by adding sulfuric acid to sludge containing aluminum and then neutralizing with caustic soda and hydrochloric acid. This is because sulfate radicals remain in the cake.
Alternatively, the main component is obtained by mixing a cake containing aluminum hydrate and iron compound separated from the manganese compound and a sulfuric acid solution, reacting the aluminum hydrate and sulfuric acid, and then filtering. An aluminum sulfate flocculant can be obtained.
The aluminum content in the obtained flocculant (hereinafter sometimes referred to as regenerated flocculant) is mainly composed of the flocculant effect of the regenerated flocculant and the stability of the solution in which the regenerated flocculant is dissolved. For aluminum sulfate flocculants, Al ₂ O _Three It is preferably 0.5% by weight or more in terms of conversion.
On the other hand, when the main component is a polyaluminum chloride flocculant, it varies depending on the storage period. For example, when the storage period is about one day, Al ₂ O _Three In terms of 1% by weight or more, and when the storage period is about one week, ₂ O _Three It may be about 2% by weight in terms of conversion. Furthermore, when storing the coagulant | flocculant whose main component is a polyaluminum chloride over 1 week, it is preferable to set it as 3 weight% or more.
The manganese content in the regenerated flocculant can be 15 ppm or less in the reduced water treatment flocculant, and can also be 1 ppm or less. For this reason, a regenerated flocculant can be used in a water purification plant.
[0019]
In addition, the amount of hydrochloric acid added to the PAC in the obtained regenerated flocculant can be adjusted so that the basicity is 50% or less, but the basicity is 15 to 50% in consideration of the agglomeration performance and the like. It is preferable that If the regenerated flocculant has a basicity of PAC of less than 15%, the agglomeration effect tends to decrease, and if a regenerated flocculant having a basicity of PAC exceeding 50% is obtained, it tends to gel and easily decompose. is there.
As described above, the regenerated flocculant mainly composed of PAC having a basicity of about 15 to 50% has the same or higher agglomeration effect as a commercially available flocculant mainly composed of PAC having a basicity exceeding 50%. be able to.
Furthermore, the regenerative flocculant whose main component is aluminum sulfate is also used. ₂ O _Three The converted water treatment flocculant converted to 10% by weight contains 1000 ppm or more (preferably 3000 ppm or more, particularly preferably 5000 ppm or more) of iron. The coagulation effect is comparable or better.
Thus, it is speculated that the iron contained in the regenerated flocculant supplements the flocculant performance exhibited by the regenerated flocculant. For this reason, polyaluminum chloride is also used as a regenerating flocculant mainly composed of PAC. ₂ O _Three It is preferable that 1000 ppm or more (further 3000 ppm or more, particularly 5000 ppm or more) of iron is contained in the converted water treatment flocculant converted to 10 wt%.
In addition, since it is thought that silica also acts effectively to improve the cohesiveness of the flocculant, about 500 to 3000 ppm of silica is contained in the regenerated flocculant recovered from the sludge of the water purification plant. It is preferable to contain.
[0020]
The regenerated flocculant recovered in this way can be reused as a flocculant in a water purification plant. If the amount of flocculant is insufficient with only the regenerated flocculant, a commercially available flocculant may be used in combination. .
By the way, the sludge generated at the water treatment plant has Al ₂ O _Three About 10% by weight of an aluminum compound is contained in terms of conversion. Of the amount of aluminum compound contained, about 50% is derived from a flocculant, and the remaining 50% is derived from natural soil or the like. It is considered a thing.
For this reason, by collecting about 50% of the amount of aluminum compound contained in the sludge and reusing it as a regenerated flocculant, the flocculant can be circulated. The problem of disposable flocculant can be solved.
As described above, even if the regenerated flocculant is recycled, the manganese content in the regenerated flocculant can be reduced to 20 ppm or less in the reduced water treatment flocculant, and manganese compounds are gradually accumulated in the regenerated flocculant. Can eliminate concerns.
[0021]
【Example】
Hereinafter, the present invention will be described in more detail by way of examples.
Example 1
Sludge generated at water treatment plant A (containing aluminum; Al ₂ O _Three 300 g of water (11.1% by weight) was dispersed in 1800 g of water, 200 g of 35% hydrochloric acid was added to form a slurry, and the aluminum in the sludge was reacted with hydrochloric acid while stirring at 95 ° C. for 120 minutes.
Subsequently, this slurry was subjected to suction filtration using No. 2 filter paper, and 2200 g of hydrochloric acid solution was separated by filtration. The content of aluminum chloride in this hydrochloric acid solution is Al ₂ O _Three The conversion was 1.2% by weight, the manganese content was 150 ppm, the iron content was 1600 ppm, and the silica content was 870 ppm.
Further, 20% aqueous sodium hydroxide solution was gradually added to the filtered hydrochloric acid solution with stirring to adjust the pH to 5.0, thereby precipitating aluminum hydroxide.
Thereafter, the solution in which aluminum hydroxide was precipitated was suction filtered using No. 2 filter paper, and 440 g of cake remained on the No. 2 filter paper. The aluminum hydroxide content in this cake is Al ₂ O _Three In terms of conversion, it was 5.2% by weight, the manganese content was less than 1 ppm, the iron content was 3900 ppm, and the silica content was 2100 ppm.
Mix the cake remaining on No. 2 filter paper with a solution of 10 g of anhydrous mirabilite and 96 g of 35% hydrochloric acid, react aluminum hydroxide with hydrochloric acid and mirabilite, and then perform suction filtration to remove the main component. As a result, 420 g of a regenerated flocculant of polyaluminum chloride (PAC) could be obtained.
The content of the regenerated flocculant PAC is Al. ₂ O _Three In terms of conversion, it was 4.0% by weight, and the basicity was about 30%. The manganese content in the regenerated flocculant was less than 1 ppm, the iron content was 2200 ppm, and the silica content was 370 ppm.
In addition, the polyaluminum chloride contained in the regenerated flocculant is Al ₂ O _Three As for the content of manganese, iron, and silica in the converted water treatment flocculant converted to 10% by weight, the manganese content was less than 1 ppm, the iron content was 5500 ppm, and the silica content was 930 ppm.
In addition, the recovery rate with respect to the aluminum contained in sludge was 50%.
[0022]
Example 2
Sludge generated in water purification plant B (containing aluminum; Al ₂ O _Three After dispersing 330 g (10.5 wt% in terms of conversion) in 1800 g of water, 200 g of 35% hydrochloric acid was added to form a slurry, and the aluminum in the sludge was reacted with hydrochloric acid while stirring at 95 ° C. for 120 minutes.
Subsequently, this slurry was subjected to suction filtration using No. 2 filter paper, and 2100 g of hydrochloric acid solution was separated by filtration. The content of aluminum chloride in this hydrochloric acid solution is Al ₂ O _Three The conversion was 1.2% by weight, the manganese content was 5 ppm, the iron content was 30 ppm, and the silica content was 970 ppm.
Further, 20% aqueous sodium hydroxide solution was gradually added to 1000 g of the filtered hydrochloric acid solution with stirring to adjust the pH to 5.0 and aluminum hydroxide was precipitated.
Thereafter, the solution in which aluminum hydroxide was deposited was suction filtered using No. 2 filter paper, and 235 g of cake remained on the No. 2 filter paper. The aluminum hydroxide content in this cake is Al ₂ O _Three The conversion was 4.9% by weight, the manganese content was less than 1 ppm, the iron content was 110 ppm, and the silica content was 2610 ppm.
Mix the cake remaining on the No. 2 filter paper with a solution of 5 g of anhydrous mirabilite and 48 g of 35% hydrochloric acid, react aluminum hydroxide with hydrochloric acid and mirabilite, and then filter by suction to obtain the main component. 125 g of regenerated flocculant of polyaluminum chloride (PAC) could be obtained.
The content of the regenerated flocculant PAC is Al. ₂ O _Three It was 3.9% by weight in terms of conversion. The manganese content in the regenerated flocculant was less than 1 ppm, the iron content was 70 ppm, and the silica content was 410 ppm.
In addition, the polyaluminum chloride contained in the regenerated flocculant is Al ₂ O _Three As for the content of manganese, iron, and silica in the converted water treatment flocculant converted to 10 wt%, the manganese content was less than 1 ppm, the iron content was 180 ppm, and the silica content was 1050 ppm. .
[0023]
Example 3
Sludge generated at water treatment plant A (containing aluminum; Al ₂ O _Three After dispersion of 450 g of water (11.1% by weight) in 2900 g of water, 147 g of 96% sulfuric acid was added to form a slurry, and the aluminum in the sludge was reacted with sulfuric acid while stirring at 95 ° C. for 120 minutes.
Subsequently, this slurry was subjected to suction filtration using No. 2 filter paper, and 3000 g of sulfuric acid solution was separated by filtration. The content of aluminum sulfate in this sulfuric acid solution is Al ₂ O _Three In terms of conversion, it was 1.2% by weight, the manganese content was 130 ppm, the iron content was 1400 ppm, and the silica content was 980 ppm.
Further, 20% aqueous sodium hydroxide solution was gradually added to 1000 g of the filtered sulfuric acid solution with stirring to adjust the pH to 5.0, thereby precipitating aluminum hydroxide.
Thereafter, the solution in which aluminum hydroxide was precipitated was subjected to suction filtration using No. 2 filter paper, and 175 g of cake remained on the No. 2 filter paper. The aluminum hydroxide content in this cake is Al ₂ O _Three The conversion was 6.3% by weight, the manganese content was 7 ppm, the iron content was 5400 ppm, and the silica content was 3600 ppm.
The cake remaining on the No. 2 filter paper and a sulfuric acid solution of 55 g of water and 33 g of 96% sulfuric acid were mixed and reacted, followed by suction filtration to obtain 230 g of a regenerated flocculant whose main component is aluminum sulfate. I was able to.
The regenerated flocculant obtained has an aluminum content of Al. ₂ O _Three The conversion was 4.0% by weight, the manganese content was 4 ppm, the iron content was 4000 ppm, and the silica content g was 480 ppm.
In addition, the aluminum sulfate contained in the regenerated flocculant is Al ₂ O _Three As for the content of manganese, iron and silica in the converted water treatment flocculant converted to 10% by weight, the manganese content was 10 ppm, the iron content was 10,000 ppm, and the silica content was 1200 ppm.
In addition, the recovery rate with respect to the aluminum contained in the sludge was 55%.
[0024]
Example 4
Sludge generated in water treatment plant C (containing aluminum; Al ₂ O _Three After dispersion of 150 g of water (10.2% by weight) in 1000 g of water, 45 g of 96% sulfuric acid was added to form a slurry, and the aluminum in the sludge was reacted with sulfuric acid while stirring at 95 ° C. for 120 minutes.
Subsequently, this slurry was subjected to suction filtration using No. 2 filter paper, and 900 g of a sulfuric acid solution was separated by filtration. The content of aluminum sulfate in this sulfuric acid solution is Al ₂ O _Three In terms of conversion, it was 1.1% by weight, the manganese content was 110 ppm, the iron content was 310 ppm, and the silica content was 1000 ppm.
Further, 20% aqueous caustic soda solution was gradually added to 900 g of the filtered sulfuric acid solution with stirring to adjust the pH to 5.0 to precipitate aluminum hydroxide.
Thereafter, the solution in which aluminum hydroxide was precipitated was suction filtered using No. 2 filter paper, and 170 g of cake remained on the No. 2 filter paper. The aluminum hydroxide content in this cake is Al ₂ O _Three The conversion was 6.5% by weight, the manganese content was 5 ppm, the iron content was 1050 ppm, and the silica content was 3000 ppm.
Mix the cake remaining on the No. 2 filter paper with a sulfuric acid solution of 55 g of water and 33 g of 96% sulfuric acid, and after reacting aluminum hydroxide and sulfuric acid, the main component is aluminum sulfate. 240 g of a regenerated flocculant was obtained.
The regenerated flocculant obtained has an aluminum content of Al. ₂ O _Three In terms of conversion, the content was 3.9% by weight, the manganese content was 3 ppm, the iron content was 700 ppm, and the silica content g was 500 ppm.
In addition, the aluminum sulfate contained in the regenerated flocculant is Al ₂ O _Three As for the content of manganese, iron, and silica in the converted water treatment flocculant converted to 10% by weight, the manganese content was 8 ppm, the iron content was 1790 ppm, and the silica content was 1280 ppm.
[0025]
Comparative Example 1
In Example 3, 20% sodium hydroxide aqueous solution was gradually added to 1000 g of the filtered sulfuric acid solution while stirring to adjust the pH to 7.5 to precipitate aluminum hydroxide.
Further, the solution in which aluminum hydroxide was precipitated was suction filtered using No. 2 filter paper, and 190 g of cake remained on the No. 2 filter paper. The aluminum hydroxide content in this cake is Al ₂ O _Three It was 6.9% by weight in terms of conversion, the manganese content was 3000 ppm, the iron content was 5400 ppm, and the silica content was 3700 ppm.
Mix the cake remaining on the No. 2 filter paper with a sulfuric acid solution of 60 g of water and 36 g of 96% sulfuric acid, and after reacting aluminum hydroxide and sulfuric acid, the main component is aluminum sulfate. 500 g of a regenerated flocculant was obtained.
The regenerated flocculant obtained has an aluminum content of Al. ₂ O _Three The conversion was 4.2% by weight, the manganese content was 1900 ppm, the iron content was 5400 ppm, and the silica content g was 1500 ppm.
In addition, the aluminum sulfate contained in the regenerated flocculant is Al ₂ O _Three As for the content of manganese, iron, and silica in the converted water treatment flocculant converted to 10% by weight, the manganese content was 4520 ppm, the iron content was 12860 ppm, and the silica content was 3570 ppm.
Thus, the flocculant in which the manganese content in the converted water treatment flocculant reaches 4520 ppm cannot be used as the flocculant in the water purification plant.
[0026]
Comparative Example 2
In Example 3, 20% sodium hydroxide aqueous solution was gradually added to 1000 g of the filtered sulfuric acid solution while stirring to adjust the pH to 4.0, thereby precipitating aluminum hydroxide.
Further, the solution in which aluminum hydroxide was deposited was suction filtered using No. 2 filter paper, and 25 g of cake remained on the No. 2 filter paper. The aluminum hydroxide content in this cake is Al ₂ O _Three It was 4.2% by weight in terms of conversion.
At this time, the recovery rate for aluminum contained in the sludge was only 6%, and the practical operation was poor, so the subsequent operation was stopped.
[0027]
Comparative Example 3
In Example 3, aluminum hydroxide was precipitated by gradually adding 10% magnesium hydroxide to 1000 g of the filtered sulfuric acid solution while stirring to pH 5.0.
Further, the solution in which aluminum hydroxide was deposited was suction filtered using No. 2 filter paper, and 150 g of cake remained on the No. 2 filter paper. The aluminum hydroxide content in this cake is Al ₂ O _Three In terms of conversion, it was 7.1% by weight, the manganese content was 3 ppm, the iron content was 80 ppm, and the silica content was 2500 ppm.
The main component is aluminum sulfate by mixing the cake remaining on the No. 2 filter paper with a sulfuric acid solution of 53 g of water and 32 g of 96% sulfuric acid, reacting aluminum hydroxide and sulfuric acid, and then suction filtering. 250 g of a regenerated flocculant was obtained.
The regenerated flocculant obtained has an aluminum content of Al. ₂ O _Three In terms of conversion, it was 4.2% by weight, the manganese content was 2 ppm, the iron content was 60 ppm, and the silica content was 310 ppm.
In addition, the aluminum sulfate contained in the regenerated flocculant is Al ₂ O _Three As for the content of manganese, iron, and silica in the converted water treatment flocculant converted to 10% by weight, the manganese content was 5 ppm, the iron content was 140 ppm, and the silica content was 740 ppm.
[0028]
Example 5
Slurry unconcentrated sludge generated at water treatment plant A (containing aluminum; Al ₂ O _Three In 2950 g (1.3 wt% in terms of conversion), 112 g of 96% sulfuric acid was added, and the aluminum in the sludge was reacted with sulfuric acid while stirring at 25 ° C. for 120 minutes.
Subsequently, this slurry was subjected to suction filtration using No. 2 filter paper, and 2800 g of a sulfuric acid solution was separated by filtration. The content of aluminum sulfate in this sulfuric acid solution is Al ₂ O _Three The conversion was 0.9% by weight, the manganese content was 100 ppm, the iron content was 810 ppm, and the silica content was 700 ppm.
Further, a 20% aqueous sodium hydroxide solution was gradually added to the filtered sulfuric acid solution with stirring to adjust the pH to 4.5 to precipitate aluminum hydroxide.
Thereafter, the solution in which aluminum hydroxide was precipitated was suction filtered using No. 2 filter paper, and 310 g of cake remained on the No. 2 filter paper. The aluminum hydroxide content in this cake is Al ₂ O _Three In terms of conversion, the content was 7.0% by weight, the manganese content was 5 ppm, the iron content was 2800 ppm, and the silica content was 2800 ppm.
The cake remaining on the No. 2 filter paper and 164 g of 35% hydrochloric acid were mixed and reacted, and then subjected to suction filtration, whereby 450 g of a regenerating flocculant composed mainly of a normal salt of aluminum chloride could be obtained. .
The regenerated flocculant obtained has an aluminum content of Al. ₂ O _Three In terms of conversion, it was 4.4% by weight, the manganese content was 4 ppm, the iron content was 1600 ppm, and the silica content g was 800 ppm.
In addition, aluminum chloride contained in the regenerated flocculant is Al ₂ O _Three As for the content of manganese, iron, and silica in the converted water treatment flocculant converted to 10% by weight, the manganese content was 9 ppm, the iron content was 3640 ppm, and the silica content was 1820 ppm.
In addition, the recovery rate with respect to the aluminum contained in sludge was 52%.
[0029]
Example 6
Jar test to investigate the flocculation ability of each of the regenerated flocculants obtained in Example 1, Example 2, Example 3, Example 4, Example 5, and Comparative Example 3 and the commercially available flocculant. The results are shown in [Table 1] below.
In this jar test, Arakawa water-based raw water (turbidity; 10.3 °, pH; 7.4, water temperature 25 ° C) is used, and the amount of regenerated flocculant and commercially available flocculant added to the raw water is aluminum. Quantity is Al ₂ O _Three It added so that it might become 2.0 mg / liter (raw water) in conversion.
[Table 1]

As is clear from Table 1, the regenerated flocculants of Examples 1, 2, 3, 4, and 5 all exhibit an aggregating effect equivalent to or greater than that of commercially available flocculants. .
On the other hand, the regenerated flocculant of Comparative Example 3 was inferior in the flocculant effect than the commercially available flocculant.
[0030]
【The invention's effect】
According to the present invention, the flocculant recovered from the sludge generated at the water purification plant is composed of aluminum chloride or aluminum sulfate contained as a main component in the flocculant. ₂ O _Three As a flocculant for a water purification plant, the manganese content in the converted water treatment flocculant converted to 10% by weight can be reduced to 20 ppm or less, and can exhibit the same or higher degree of cohesion as a commercially available flocculant. Can be reused.
For this reason, in the water purification plant, the flocculant can be circulated and used, so that the flocculant can be carried in from outside the water purification plant and environmental problems can be solved.

Claims (10)

A water treatment flocculant recovered from sludge generated in a water treatment process for water to obtain water that is supplied to drinking water by adding a water treatment flocculant composed mainly of an aluminum compound to raw water,
The main component of the water treatment flocculant is aluminum chloride represented by the general formula shown below, and manganese content in the converted water treatment agent converted so that the aluminum chloride is 10% by weight as Al ₂ O ₃ A water treatment flocculant characterized in that the amount is 20 ppm or less.
General formula
Al ₂ (OH) _n Cl _(6-n) where 0 ≦ n <6 The water treatment flocculant according to claim 1 whose iron content in a conversion water treatment agent is 1000 ppm or more. The water treatment flocculant according to claim 1 or 2, wherein the main component of the water treatment flocculant is polyaluminum chloride. A water treatment flocculant recovered from sludge generated in a water treatment process for water to obtain water that is supplied to drinking water by adding a water treatment flocculant composed mainly of an aluminum compound to raw water,
The main component of the water treatment flocculant is aluminum sulfate, and the iron content in the converted water treatment flocculant converted so that the aluminum sulfate is 10% by weight as Al ₂ O ₃ is 1000 ppm or more and manganese A water treatment flocculant having a content of 20 ppm or less. The water treatment flocculant according to claim 4, wherein the iron content in the converted water treatment flocculant is 3000 ppm or more. Aluminum compound in the sludge by adding hydrochloric acid or sulfuric acid to the sludge generated in the water treatment process for water to obtain the water to be supplied to drinking water by adding a water treatment flocculant composed mainly of an aluminum compound to raw water After obtaining a solution in which
An alkaline compound exhibiting strong alkalinity of pH 13 or higher is added to the solution, and the solution is adjusted to pH 4.5 to 6.5 to precipitate aluminum hydrate.
Then, the manufacturing method of the water treatment flocculent characterized by obtaining the water treatment flocculant which has aluminum chloride or aluminum sulfate as a main component using the said aluminum hydrate as a raw material. The method for producing a water treatment flocculant according to claim 6, wherein the aluminum chloride is polyaluminum chloride. The method for producing a water treatment flocculant according to claim 6 or 7, wherein the alkaline compound is caustic soda. The water treatment flocculant of Claim 1 or Claim 4 is used in the case of the water treatment for the clean water which obtains the clean water supplied to drinking water etc. from the raw water taken from the river etc. Reusing the water treatment flocculant according to claim 1 or 4 as a water treatment flocculant in water treatment for drinking water to obtain drinking water to be supplied to drinking water from raw water taken from a river or the like A water treatment method characterized.