JP5917306B2 - Method and apparatus for treating sludge incineration ash - Google Patents

Description

  The present invention relates to a method for treating sludge incineration ash such as sewage sludge incineration ash and an apparatus for treating sludge incineration ash.

  Conventionally, most of the sludge incineration ash produced when incineration of sludge such as sewage sludge generated at a sewage treatment plant is reduced to landfill as waste.

However, since sludge incineration ash, such as sewage sludge incineration ash, contains a large amount of phosphorus, in recent years, phosphorus has been recovered from sludge incineration ash, which is a waste material. It is desired to reuse it as a phosphorus resource.
In addition, in order to landfill all sludge incineration ash, it is necessary to secure a large landfill site. Therefore, it is also desired to effectively use the sludge incineration ash (treated ash) after recovering phosphorus as a concrete material or the like to reduce the amount of sludge incineration ash to be disposed of in landfill.

  Therefore, while collecting phosphorus from sewage sludge incineration ash, as a method to obtain treated ash that has a low content of harmful components and is easy to reuse as concrete materials, etc., sewage sludge incineration ash and alkaline reaction liquid are mixed, Extract phosphorus contained in sewage sludge incineration ash and harmful components such as arsenic (As) and selenium (Se) into an alkaline reaction solution, and then wash the ash after extraction with water or an acidic solution. Has proposed a method for obtaining treated ash with a low content of harmful components while collecting phosphorus (see, for example, Patent Document 1).

  Moreover, since the lead (Pb) contained in the sewage sludge incineration ash cannot be extracted / removed by the method for treating the sewage sludge incineration ash using the alkaline reaction liquid, the treatment obtained using the above treatment method Ashes can be leached when placed in a low pH environment. Therefore, by adding sulfuric acid to the ash after the extraction treatment, the lead in the ash is made insoluble lead sulfate, so that lead does not easily flow out even in a low pH environment, and it can be easily reused as a concrete material, etc. A method for obtaining treated ash has also been proposed (see, for example, Patent Document 2).

JP 2008-229576 A JP 2012-11283 A

  However, the treated ash obtained by washing the ash after the extraction treatment with an acidic solution and the treated ash obtained by adding sulfuric acid to the ash after the extraction treatment can be effectively used as they are because the pH is low. Have difficulty. In particular, the treated ash obtained by adding sulfuric acid to the ash after the extraction treatment has a very low pH (for example, the pH is 3.5 or less). The amount of (kneaded water released by the sedimentation or separation of the solid material) increases, and concrete having a desired strength cannot be obtained.

  Here, with respect to such a problem, it is also conceivable to raise the pH of the treated ash to a pH suitable for effective use by washing with water or neutralizing treatment with an alkaline chemical. However, it is difficult to sufficiently raise the pH of the treated ash by washing with water. On the other hand, when the pH of the treated ash is increased using a chemical, the treatment cost of the sludge incinerated ash increases.

  Therefore, the present invention is a method for treating sludge incineration ash comprising a step of extracting phosphorus from sludge incineration ash using an alkaline reaction liquid, and a step of treating sludge incineration ash after extracting phosphorus with an acidic solution. It aims at making it possible to obtain the processing ash of pH suitable for effective utilization, suppressing the increase in the processing cost of sludge incineration ash.

The present invention aims to advantageously solve the above-mentioned problems, and the method for treating sludge incineration ash according to the present invention comprises mixing sludge incineration ash with an alkaline reaction liquid and including the sludge incineration ash in the sludge incineration ash. Extracting phosphorus in the alkaline reaction solution to obtain a phosphorus extract and an alkali-treated ash, an acid treatment to obtain an acid-treated ash by mixing the alkali-treated ash and an acidic solution A phosphorus recovery step of recovering phosphorus contained in the phosphorus extract as calcium phosphate , the acid-treated ash, and after the phosphorus extraction step is completed and before the phosphorus recovery step is completed. A neutralization step of increasing the pH of the acid-treated ash by mixing at least one of the alkaline drainage discharged after the completion of the alkaline drainage and the phosphorus extraction step and before the completion of the acid treatment step; The And wherein the Mukoto. In this way, if the pH of the acid-treated ash is increased using the alkaline drainage discharged in the process of treating the sludge incineration ash, the pH of the acid-treated ash can be sufficiently increased without using a chemical. Can do. Accordingly, it is possible to obtain treated ash having a pH suitable for effective use while suppressing an increase in the treatment cost of sludge incineration ash.
In the present invention, “alkaline drainage discharged after the phosphorus extraction step and before the phosphorus recovery step is completed” is not particularly limited, and when calcium phosphate is precipitated in the phosphorus recovery step. And the drainage discharged when the calcium phosphate is washed in the phosphorus recovery step. Further, in the present invention, “alkaline drainage discharged between the end of the phosphorus extraction step and the end of the acid treatment step” is not particularly limited and is discharged when the alkali-treated ash is washed. Can be mentioned.

Here, it is preferable that the processing method of the sludge incineration ash of this invention raises pH of the said acid-treated ash to 6 or more in the said neutralization process. This is because, if the pH of the acid-treated ash is raised to 6 or more in the neutralization step, it is possible to obtain treated ash particularly suitable for effective use as a concrete material or the like.
In the present invention, “pH of acid-treated ash” refers to the dispersion of acid-treated ash that has been dried in a dryer at a temperature of 110 ° C. until the mass becomes constant after solid-liquid separation at a concentration of 2% by mass. The pH of the suspension can be determined by measuring by the glass electrode method according to JIS Z8802.

  Further, in the method for treating sludge incineration ash according to the present invention, the phosphorus recovery step includes adding a calcium compound to the phosphorus extract, and precipitating phosphorus in the phosphorus extract as calcium phosphate; and the calcium phosphate A step of recovering the calcium phosphate and a step of cleaning the recovered calcium phosphate. In the neutralization step, the alkaline drainage discharged in the washing step may be used as the alkaline drainage. preferable. The washing drainage discharged when washing calcium phosphate in the washing process has a low content of harmful components such as arsenic and selenium, and has a reasonably high pH, thus increasing the pH of the acid-treated ash. This is because it is particularly suitable as an alkaline drainage liquid.

  Furthermore, it is preferable that the processing method of the sludge incineration ash of this invention wash | cleans the said calcium phosphate using the water of 5-10 times mass of the said sludge incineration ash in the said washing | cleaning process. If water is used for washing calcium phosphate, and the amount of water used for washing is 5 times or more that of sludge incineration ash, the content of harmful components such as arsenic and selenium while washing calcium phosphate sufficiently This is because a sufficiently small amount of washing drainage can be used as alkaline drainage. Also, if water is used when washing calcium phosphate and the amount of water used for washing is 10 times or less that of sludge incineration ash, wash drainage with a sufficiently high pH should be used as alkaline drainage. Because you can.

  And it is preferable that the processing method of the sludge incineration ash of this invention further includes the final washing | cleaning process which wash | cleans the acid-treated ash which raised pH by the said neutralization process with water. This is because if the acid-treated ash after raising the pH is washed with water, a treated ash having a sufficiently low content of harmful components can be obtained.

Moreover, this invention aims at solving the said subject advantageously, The processing apparatus of the sludge incineration ash of this invention is equipped with an alkaline reaction liquid addition means, an alkaline reaction liquid, sludge incineration ash, To extract phosphorus contained in the sludge incineration ash into the alkaline reaction liquid, to obtain a phosphorus extraction liquid and an alkali-treated ash, a phosphorus extraction part, and an acidic solution for the alkali-treated ash An acid treatment unit comprising acid addition means to be added to obtain acid-treated ash by mixing the alkali-treated ash and the acidic solution, and a phosphorus recovery unit for collecting phosphorus contained in the phosphorus extract as calcium phosphate obtained when, after extracting phosphorus phosphorus extraction unit, after extracting the phosphorus with alkaline drainage and phosphorus extractor discharged until recovering calcium with phosphorus recovery unit, the acid treatment ash with acid unit The alkaline effluent recovery means for recovering at least one of the alkaline effluent discharged between the acid-treated ash, the acid-treated ash, and the alkaline effluent collected by the alkaline effluent-recovery means are mixed to produce the acid-treated ash. And a neutralizing part that raises the pH of the solution. In this way, if the pH of the acid-treated ash is increased using an alkaline drainage discharged in the process of treating the sludge incineration ash by providing a neutralization section, the pH of the acid-treated ash can be obtained without using a chemical. Can be raised sufficiently. Accordingly, it is possible to obtain treated ash having a pH suitable for effective use while suppressing an increase in the treatment cost of sludge incineration ash.
In the present invention, “alkaline drainage discharged after extracting phosphorus in the phosphorus extraction unit and then recovering calcium phosphate in the phosphorus recovery unit” is not particularly limited. Examples thereof include drainage discharged when calcium phosphate is deposited and drainage discharged when calcium phosphate is washed in the phosphorus recovery unit. Further, in the present invention, “alkaline drainage discharged after extracting phosphorus in the phosphorus extraction section and then obtaining acid-treated ash in the acid treatment section” is not particularly limited, and may be alkali-treated ash. The drainage discharged when washing is mentioned.

  Here, in the apparatus for treating sludge incineration ash according to the present invention, the phosphorus recovery unit includes a calcium addition means for adding a calcium compound to the phosphorus extract, and deposits phosphorus in the phosphorus extract as calcium phosphate. A calcium phosphate precipitation tank; a calcium phosphate recovery means for recovering the calcium phosphate; and a cleaning tank for cleaning the recovered calcium phosphate, wherein the alkaline drainage recovery means removes the alkaline cleaning drainage discharged from the cleaning tank. It is preferable to collect as the alkaline drainage. The cleaning effluent discharged when cleaning calcium phosphate in the cleaning tank has a low content of harmful components such as arsenic and selenium, and has a reasonably high pH, thus increasing the pH of the acid-treated ash. This is because it is particularly suitable as an alkaline drainage liquid.

  According to the present invention, in a method for treating sludge incineration ash comprising a step of extracting phosphorus from sludge incineration ash using an alkaline reaction liquid, and a step of treating sludge incineration ash after extracting phosphorus with an acidic solution, While suppressing an increase in the treatment cost of the sludge incineration ash, a treated ash having a pH suitable for effective use can be obtained.

It is the operation flow at the time of processing sewage sludge incineration ash using the processing method of typical sludge incineration ash according to the present invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The method for treating sludge incineration ash according to the present invention is, for example, when treating sludge incineration ash such as sewage sludge incineration ash generated when incinerating sewage sludge such as primary sludge and surplus sludge generated at a sewage treatment plant. Can be used. The sludge incineration ash treated by the sludge incineration ash treatment method of the present invention is not limited to sewage sludge incineration ash, and the sludge incineration ash treatment method of the present invention includes phosphorus, arsenic, selenium and It can be used to treat sludge incineration ash containing harmful components such as lead. Moreover, the processing method of the sludge incineration ash of this invention can be implemented using the processing apparatus of the sludge incineration ash of this invention.

  Here, in an example of the method for treating sludge incineration ash according to the present invention, as shown in the operation flowchart in FIG. 1, first, the phosphorus extraction step (S1) and the first solid-liquid separation step are performed on the sewage sludge incineration ash. (S2) is sequentially performed to obtain an alkali-treated ash and a phosphorus extract. Next, the water-washed step (S3) and the second solid-liquid separation step (S4) are sequentially performed on the alkali-treated ash, and the alkali-treated ash washed with water (hereinafter referred to as “washed alkali-treated ash”). .) Thereafter, the acid-treated ash is obtained by performing the acid treatment step (S5) and the third solid-liquid separation step (S6) on the washed alkali-treated ash.

  Furthermore, in this example of the method for treating sludge incineration ash, the neutralization step (S7), the fourth solid-liquid separation step (S8), the final washing step (S9), and the fifth solid-liquid separation are performed on the acid-treated ash. Step (S10) is sequentially performed to obtain treated ash.

  In this example of the method for treating sludge incineration ash, phosphorus contained in the phosphorus extract is converted to phosphate (in this example, the phosphorus extract obtained in the first solid-liquid separation step (S2)). The phosphorus collection | recovery process (S11-S13) collect | recovered as a calcium phosphate is implemented, and the phosphorus in a sewage sludge incineration ash is collect | recovered as a calcium phosphate.

And the processing method of this example sludge incineration ash uses that the alkaline drainage produced in the process of processing a sewage sludge incineration ash and obtaining phosphate (calcium phosphate) and a processing ash in a neutralization process (S7). Features.
In addition, the following (A) and (B) are mentioned as an alkaline waste liquid produced in the process of processing a sewage sludge incineration ash and obtaining a phosphate (calcium phosphate) and a treated ash.
(A) Alkaline drainage discharged between the end of the phosphorus extraction step (S1) and the end of the phosphorus recovery step (S11 to S13) (B) After the end of the phosphorus extraction step (S1), the acid treatment step Alkaline drainage discharged until (S5) is completed. Specifically, as the alkaline drainage of (A) above, for example, calcium phosphate after the calcium phosphate precipitation step (S11) in the phosphorus recovery step Examples include alkaline drainage obtained in the recovery step (S12) and alkaline drainage obtained in the washing step (S13) during the phosphorus recovery step. Moreover, as an alkaline drainage of said (B), the alkaline drainage obtained by the 2nd solid-liquid separation process (S4) after a water washing process (S3) is mentioned, for example.

Here, in the phosphorus extraction step (S1), the sewage sludge incineration ash and the alkaline reaction liquid are stirred and mixed in, for example, an extraction tank (phosphorus extraction unit), and the phosphorus contained in the sewage sludge incineration ash is converted into the alkaline reaction liquid. Extracting in to obtain a mixture of a phosphorus extract composed of an alkaline reaction liquid containing extracted phosphorus and an alkali-treated ash composed of incinerated sewage sludge ash from which part or all of the phosphorus contained is extracted It is a process. In the phosphorus extraction step (S1), although it is not clear in principle, if the sewage sludge incineration ash contains harmful components such as selenium and arsenic, selenium and arsenic in the sewage sludge incineration ash are also removed. It is extracted into an alkaline reaction solution together with phosphorus. Accordingly, the content of phosphorus, arsenic, selenium, etc. in the alkali-treated ash is reduced as compared with sewage sludge incineration ash.
Incidentally, as the alkaline reaction liquid, an aqueous sodium hydroxide solution, an aqueous potassium hydroxide solution, or the like can be used. And pH of an alkaline reaction liquid can be 13-14, for example. A hopper or the like can be used as means for introducing the sewage sludge incineration ash into the extraction tank, and a pump or the like can be used as the alkaline reaction liquid addition means for supplying the alkaline reaction liquid into the extraction tank. .

The extraction of phosphorus contained in the sewage sludge incineration ash into the alkaline reaction liquid is not clear in principle, but phosphorus contained in the form of P ₂ O ₅ or the like is contained in the sewage sludge incineration ash. For example, it is presumed that this occurs by elution into an alkaline reaction solution by a reaction shown in the following reaction formula (1).
P ₂ O ₅ + 6OH ⁻ → 2PO ₄ ^{3 −} + 3H ₂ O (1)

  In the first solid-liquid separation step (S2), the mixture of the phosphorus extract obtained in the phosphorus extraction step (S1) and the alkali-treated ash is used, for example, using a known solid-liquid separation means such as a sedimentation separation device or a filtration device. In this step, the phosphorus extract and the alkali-treated ash are separated.

In the water washing step (S3), for example, the alkali-treated ash and water are stirred and mixed in a water washing tank, and the alkaline reaction liquid adhering to the alkali-treated ash is washed and removed to remove the alkaline reaction liquid. This is a step of obtaining a mixture of the spent alkali-treated ash and an alkaline drainage (washing drainage) containing an alkaline reaction liquid adhering to the alkali-treated ash. And in this example of the method for treating sludge incineration ash, since the alkaline reaction liquid containing arsenic, selenium and the like is removed from the alkali-treated ash in the water washing step (S3), the acidic solution added in the acid treatment step (S5) Can be prevented from being consumed in the neutralization reaction of the alkaline reaction liquid, and the amount of the acidic solution used in the acid treatment step (S5) can be reduced to reduce the treatment cost.
The water used in the water washing step (S3) is not particularly limited, and sewage treated water (reclaimed water) can be used. Incidentally, as the cleaning liquid used when cleaning the alkali-treated ash in the water cleaning step (S3), a solution other than water may be used as long as the cleaning waste liquid becomes alkaline. Moreover, a pump etc. can be used as a means to supply reclaimed water in a water washing tank.

  Here, since the alkaline drainage produced in the water washing step (S3) is a mixed solution of water and an alkaline reaction solution adhering to the alkali-treated ash, the pH of the alkaline drainage is, for example, 9 to 11. is there. Moreover, alkaline drainage contains a small amount of arsenic, selenium and the like.

  In the second solid-liquid separation step (S4), the mixture of the washed alkali-treated ash obtained in the water washing step (S3) and the alkaline drainage is converted into a known solid-liquid separation means such as a sedimentation separation device or a filtration device. Is a step of separating into washed alkali-treated ash and alkaline drainage using The separated alkaline drainage is treated using an appropriate drainage treatment means as shown by a solid line in FIG. 1, or acidified in a neutralization step (S7) as shown by a broken line in FIG. Used when raising the pH of the treated ash.

In the acid treatment step (S5), the washed alkali-treated ash and the acidic solution are stirred and mixed in an acid treatment tank (acid treatment unit), for example, and the acid-treated ash treated with the acid solution and the acid-treated solution are mixed. This is a step of obtaining a mixture.
A slurry pump or the like can be used as the means for introducing the washed alkali-treated ash into the acid treatment tank, and a pump or the like can be used as the acid addition means for supplying the acidic solution into the acid treatment tank. it can.

Here, as the acidic solution used in the acid treatment step (S5), hydrochloric acid, sulfuric acid aqueous solution, nitric acid aqueous solution and the like can be used, but when sewage sludge incineration ash contains lead, that is, washed alkali. When lead is contained in the treated ash, an aqueous sulfuric acid solution is preferably used as the acidic solution. This is because, if an aqueous sulfuric acid solution is used as the acidic solution, lead in the washed alkali-treated ash can be changed to poorly soluble lead sulfate (PbSO ₄ ) to insolubilize the lead in the ash.
In addition, when using a sulfuric acid aqueous solution as the acidic solution, it is preferable to mix the washed alkali-treated ash and the sulfuric acid aqueous solution so that the pH of the acid-treated ash is 3.5 or less in the acid treatment step (S5).

  In the third solid-liquid separation step (S6), the mixture of the acid-treated ash obtained in the acid treatment step (S5) and the acid-treated solution is used, for example, using a known solid-liquid separation means such as a sedimentation separator or a filtration device. In this step, the acid-treated ash and the acid-treated solution are separated. The separated acid treatment solution is an acidic solution and is treated using an appropriate drainage treatment means.

The neutralization step (S7) is a step of increasing the pH of the acid-treated ash by stirring and mixing the acid-treated ash and the alkaline effluent, for example, in a neutralization tank (neutralization part). In the neutralization step (S7), a mixture of acid-treated ash (neutralized ash) having an increased pH and a neutralized solution is obtained.
In addition, a slurry pump etc. can be used as a means to introduce | transduce acid-treated ash into a neutralization tank, and a pump etc. can be used as a means to supply alkaline drainage into a neutralization tank.

Here, as the alkaline drainage used in the neutralization step (S7), the alkaline drainage discharged between the end of the phosphorus extraction step (S1) and the end of the phosphorus recovery step (S11 to S13), Or the alkaline drainage discharged | emitted before completion | finish of an acid treatment process (S5) after completion | finish of a phosphorus extraction process (S1), or those mixtures can be mentioned. Specifically, the alkaline drainage includes alkaline drainage obtained in the calcium phosphate recovery step (S12) in the phosphorus recovery step, alkaline drainage obtained in the washing step (S13) in the phosphorus recovery step, At least one selected from the group consisting of alkaline drainage obtained in the solid-liquid separation step (S4) can be used. And the alkaline drainage mentioned above can be collect | recovered using the alkaline drainage collection | recovery means which consists of a pump for alkaline drainage collection | recovery, and an alkaline drainage storage tank, for example. Further, the alkaline drainage liquid in the alkaline drainage storage tank can be supplied to the neutralization tank using a pump.
In the neutralization step (S7) of the sludge incineration ash treatment method shown in FIG. 1, the alkaline effluent discharged in the washing step (S13) in the phosphorus recovery step is used to increase the pH of the acid-treated ash. ing.

  In the neutralization step (S7), the pH of the acid-treated ash is preferably increased to 6 or more, and more preferably 6 to 10.5. If the pH of the acid-treated ash is raised to 6 or higher in the neutralization step (S7), the amount of bleeding water is suppressed when the treated ash is used as a concrete material and the like, and concrete having a desired strength is obtained. It is because it can obtain. That is, it is possible to obtain treated ash particularly suitable for effective use as a concrete material or the like. In addition, if the pH of the acid-treated ash is raised too much, the alkalinity of the treated ash becomes too strong, causing problems such as aggregation and precipitation of the ash, making it difficult to use effectively, and the alkaline ash used in the neutralization step. This is because the amount of liquid increases.

  In the fourth solid-liquid separation step (S8), the mixture of the neutralized ash obtained in the neutralization step (S7) and the neutralization treatment solution is subjected to known solid-liquid separation means such as a sedimentation separation device or a filtration device. It is the process of using and isolate | separating into neutralization ash and a neutralization process solution. The separated neutralization treatment solution is treated using an appropriate drainage treatment means.

In the final washing step (S9), the neutralized ash (acid-treated ash whose pH has been increased in the neutralization step) and water are stirred and mixed in, for example, the final washing tank, and the neutralized ash is attached to the neutralized ash. In this step, the treatment solution is washed and removed to obtain a mixture of the treated ash from which the neutralization treatment solution has been removed and the final washing waste solution containing the neutralization treatment solution adhering to the neutralization ash. In this example of the method for treating sludge incineration ash, since the neutralization treatment solution is removed in the final cleaning step (S9), it is possible to obtain treated ash having a sufficiently low content of harmful components such as arsenic and selenium. it can. That is, when harmful components such as arsenic and selenium are contained in the alkaline effluent used in the neutralization step (S7), the harmful components are also contained in the neutralization treatment solution. If the neutralization treatment solution is removed from the neutralization ash in the step (S9), a treatment ash having a sufficiently small content of harmful components can be obtained.
Here, the water used in the final cleaning step (S9) is not particularly limited, and sewage treated water (regenerated water) can be used.

  In the final washing step (S9), the neutralized ash and the neutralized solution are solid-liquid separated using a filtration device in the fourth solid-liquid separation step (S8), and then the neutralized ash is adhered to the filter medium. It may be performed by passing water as it is. By washing the neutralized ash while adhering to the filter medium with water, the neutralized ash can be washed in a state close to the extrusion flow, and the neutralized solution adhering to the neutralized ash is efficiently and sufficiently removed. Because it can be done.

  In the fifth solid-liquid separation step (S10), the mixture of the treated ash obtained in the final washing step (S9) and the final washing drainage is used, for example, by using known solid-liquid separation means such as a sedimentation separation device or a filtration device. This is a step of separating the treated ash and the final cleaning waste liquid. The separated final cleaning drainage liquid is processed using an appropriate drainage processing means.

The phosphorus recovery step (S11 to S13) is a step of recovering phosphorus contained in the phosphorus extract obtained in the first solid-liquid separation step (S2) as a phosphate, and a calcium phosphate precipitation step (S11). And a calcium phosphate recovery step (S12) and a cleaning step (S13).
In the phosphorus recovery step (S11 to S13), a calcium phosphate precipitation tank for depositing phosphorus in the phosphorus extract as calcium phosphate, a calcium phosphate recovery means for recovering calcium phosphate from the calcium phosphate precipitation tank, and a cleaning for cleaning the calcium phosphate recovered by the calcium phosphate recovery means This is performed in a phosphorus recovery unit having a tank.

In the calcium phosphate precipitation step (S11), for example, a calcium compound such as calcium hydroxide (Ca (OH) ₂ ) is added to the phosphorus extract obtained in the first solid-liquid separation step (S2) to extract phosphorus. A step of precipitating phosphorus contained in the liquid as a phosphate such as calcium phosphate (Ca ₃ (PO ₄ ) ₂ ) to obtain a mixture of calcium phosphate and an alkaline drainage composed of a phosphorus extract from which phosphorus has been removed. It is.
In addition, addition of the calcium compound with respect to a phosphorus extract can be performed within a calcium phosphate precipitation tank. Moreover, a pump etc. can be used as a means to supply a phosphorus extract into a calcium phosphate precipitation tank, and a hopper etc. can be used as a means to throw a calcium compound into a calcium phosphate precipitation tank.

  Here, since the alkaline drainage produced in the calcium phosphate precipitation step is a solution composed of a phosphorus extract from which phosphorus has been removed, the pH of the alkaline drainage is, for example, 13-14. Alkaline drainage contains a relatively large amount of arsenic, selenium, and the like.

The amount of calcium hydroxide added to the phosphorus extract in the calcium phosphate precipitation step (S11) is 1.0 to 1.4 times the amount of phosphorus contained in the phosphorus extract in a molar ratio. It is preferable. If the amount of calcium hydroxide added / the amount of phosphorus in the phosphorus extract (molar ratio) is less than 1.0, not only can the phosphorus in the phosphorus extract be precipitated as calcium phosphate, but also a sufficiently high pH alkaline This is because drainage (that is, alkaline drainage suitable for reuse in the phosphorus extraction step or neutralization step) cannot be obtained. Moreover, when the amount of calcium hydroxide added / the amount of phosphorus in the phosphorus extract (molar ratio) exceeds 1.4, harmful components such as arsenic are precipitated together with calcium phosphate. Incidentally, the amount of phosphorus contained in the phosphorus extract can be calculated, for example, by determining the phosphorus concentration in the phosphorus extract by the molybdenum blue method in accordance with JIS K0102.
As the calcium compound used in the calcium phosphate precipitation step (S11), calcium chloride or the like can be used. From the viewpoint of obtaining an alkaline drainage having a sufficiently high pH while reducing the drug cost, water is used as the calcium compound. It is preferred to use calcium oxide.

  In the calcium phosphate recovery step (S12), the mixture of the calcium phosphate obtained in the calcium phosphate precipitation step (S11) and the alkaline effluent is obtained by using a known solid-liquid separation means (calcium phosphate recovery means) such as a sedimentation separator or a filtration device. This is a step of separating calcium phosphate and alkaline drainage. The separated alkaline drainage is reused in the phosphorus extraction step (S1) as an alkaline reaction solution as shown by a solid line in FIG. 1, or is neutralized (S7) as shown by a broken line in FIG. ) In increasing the pH of the acid-treated ash. As described above, when alkaline drainage is reused in the phosphorus extraction step (S1) or neutralization step (S7), the pH of the alkaline drainage is preferably higher.

In the washing step (S13), the calcium phosphate obtained in the calcium phosphate recovery step (S12) and water are stirred and mixed in, for example, a washing tank, and the alkaline drainage liquid adhering to the calcium phosphate (from the phosphorus extract from which phosphorus has been removed) The solution is removed by washing with water to obtain a mixture of the washed calcium phosphate and the alkaline washing drainage containing the alkaline drainage adhering to the calcium phosphate. In this example of the method for treating sludge incineration ash, the alkaline drainage derived from the calcium phosphate precipitation step (S11) attached to the calcium phosphate is removed in the washing step (S13), so that harmful components such as arsenic and selenium are removed. Calcium phosphate with a sufficiently small content can be obtained. That is, when a harmful component such as arsenic or selenium is contained in the phosphorus extract, the harmful component is also contained in the alkaline drainage. However, in the washing step (S13), the alkaline drainage is removed from the calcium phosphate. If removed, washed calcium phosphate having a sufficiently low content of harmful components can be obtained and effectively used as a phosphorus resource.
Here, the water used in the washing step (S13) is not particularly limited, and sewage treated water (regenerated water) can be used.

  The washing step (S13) is performed by solid-liquid separating calcium phosphate and alkaline drainage using a filtration device in the calcium phosphate recovery step (S12), and then passing water with the calcium phosphate attached to the filter medium. May be. This is because if the calcium phosphate adhered to the filter medium is washed with water, the calcium phosphate can be washed in a state close to the extrusion flow, and the alkaline drainage adhering to the calcium phosphate can be efficiently and sufficiently removed. . Incidentally, in the case of washing with water while calcium phosphate is adhered to the filter medium, the filtration device functions as a washing tank.

  Then, the mixture of the washed calcium phosphate obtained in the washing step (S13) and the alkaline washing waste solution is washed with the washed calcium phosphate and the alkaline washing waste using a known solid-liquid separation means such as a sedimentation separator or a filtration device. Separated into liquid. The washed calcium phosphate is reused as a phosphorus resource, and the alkaline cleaning drainage is used as an alkaline draining liquid when raising the pH of the acid-treated ash in the neutralization step (S7) as shown by the solid line in FIG. used.

  Here, the alkaline cleaning drainage generated in the cleaning step (S13) is a mixed solution of water and an alkaline draining solution (solution consisting of a phosphorus extract from which phosphorus has been removed) adhering to calcium phosphate. The pH of the alkaline cleaning drainage is, for example, 11-12. Further, the alkaline cleaning drainage liquid contains a small amount of arsenic, selenium and the like.

And according to the processing method of the example sludge incineration ash, phosphorus is extracted from the sewage sludge incineration ash in the phosphorus extraction step (S1), and the extracted phosphorus is recovered as calcium phosphate in the phosphorus recovery step (S11 to S13). Therefore, phosphorus can be effectively recovered from sewage sludge incineration ash.
In the above-described method for treating sludge incineration ash, harmful components such as arsenic and selenium contained in the sewage sludge incineration ash are also extracted together with phosphorus in the phosphorus extraction step (S1). Treated ash with a low selenium content can be obtained.
Furthermore, in the example of the sludge incineration ash treatment method described above, the lead contained in the sludge incineration ash is insolubilized as lead sulfate in the acid treatment step (S5). Even if it exists, the processing ash which is hard to elute lead can be obtained.

  Moreover, according to the example of the method for treating sludge incineration ash, the neutralization step (S7) is provided and discharged in the process of treating the sludge incineration ash, such as the alkaline washing effluent discharged in the washing step (S13). Since the pH of the acid-treated ash is increased using the alkaline drained liquid, the pH of the acid-treated ash can be sufficiently increased without using a chemical. Accordingly, it is possible to obtain treated ash having a pH suitable for effective use while suppressing an increase in the treatment cost of sludge incineration ash.

  Furthermore, since the final cleaning step (S9) is provided in the sludge incineration ash treatment method of the above example, even when the pH of the acid-treated ash is increased using alkaline drainage, arsenic, selenium, etc. Treated ash with a low content of harmful components can be obtained.

In the above-described method for treating sludge incineration ash, since the alkaline cleaning drainage generated in the cleaning step (S13) is used in the neutralization step (S7), the alkaline drainage generated in the calcium phosphate precipitation step (S11). That is, the pH of the acid-treated ash is increased by using an alkaline effluent having a low content of harmful components such as arsenic and selenium as compared with the case of using the alkaline effluent obtained in the calcium phosphate recovery step (S12). Can do. Moreover, in the example of the method for treating sludge incineration ash, since the alkaline cleaning drainage generated in the cleaning step (S13) is used in the neutralization step (S7), the alkaline drainage generated in the water cleaning step (S3). That is, compared with the case where the alkaline drainage obtained in the second solid-liquid separation step (S4) is used, the pH of the acid-treated ash can be efficiently increased using the alkaline drainage having a high pH. .
Incidentally, when the alkaline washing drainage generated in the washing step (S13) is used in the neutralization step (S7), from the viewpoint of obtaining an alkaline washing drainage having a high pH while washing calcium phosphate sufficiently. In the step (S13), it is preferable to wash the calcium phosphate with water having a mass 5 to 10 times that of the sludge incineration ash. If the amount of water is less than 5 times the amount of sludge incineration ash, the calcium phosphate may not be sufficiently washed, and the concentration of harmful components in the alkaline washing effluent will increase, after neutralization treatment This is because the amount of harmful components in the acid-treated ash may increase. Further, when the amount of water is more than 10 times the amount of sludge incineration ash, there is a possibility that a sufficiently high pH alkaline cleaning drainage liquid cannot be obtained.

As mentioned above, although the processing method and processing apparatus of the sludge incineration ash of this invention were demonstrated using an example, the processing method and processing apparatus of the sludge incineration ash of this invention are not limited to the said example, A change can be suitably added to the processing method and processing apparatus of sludge incineration ash.
Specifically, in the method for treating sludge incineration ash according to the present invention, for example, the final cleaning step (S9) and the fifth solid-liquid separation step (S10) may not be performed.

  EXAMPLES Hereinafter, although an Example demonstrates this invention further in detail, this invention is not limited to the following Example at all.

Example 1
According to the operation flowchart shown in FIG. 1, 10 kg of sewage sludge incineration ash was processed under the conditions shown in Table 1 using the sludge incineration ash processing method according to the present invention. In the washing step (S13), the calcium phosphate was washed with 100 kg of water.
And the property of the obtained treated ash was evaluated by the following method. Moreover, the property of the alkaline washing drainage generated in the washing step was evaluated by the following method. The results are shown in Table 1.

<Properties of treated ash>
[PH]
The obtained treated ash was dried to a constant mass in a dryer at a temperature of 110 ° C., and then dispersed in pure water at a concentration of 2% by mass to prepare a treated ash suspension. Then, the pH of the treated ash suspension was measured with a pH meter (manufactured by HORIBA) to obtain the pH of the treated ash.
[Arsenic Ministry of the Environment Notification No. 46 Test Value]
In accordance with the Ministry of the Environment Notification No. 46 test, after elution and filtration using a solvent (hydrochloric acid added to pure water to adjust the pH to 5.8 or more and 6.3 or less), in accordance with JIS K0102. The arsenic elution amount was measured.
[Selenium Ministry of the Environment Notification No. 46 Test Value]
In accordance with the Ministry of the Environment Notification No. 46 test, after elution and filtration using a solvent (hydrochloric acid added to pure water to adjust the pH to 5.8 or more and 6.3 or less), in accordance with JIS K0102. The selenium elution amount was measured.
<Properties of drainage>
[PH]
The pH of the effluent at a temperature of 20 ° C. was measured with a pH meter (manufactured by HORIBA).
[Arsenic concentration]
Based on JIS K0102, the arsenic concentration in the drainage was measured using a hydride generation atomic absorption method.
[Selenium concentration]
In accordance with JIS K0102, selenium concentration in the effluent was measured using a hydride generation atomic absorption method.

(Example 2)
In the neutralization step (S7), not the alkaline washing drainage, but the alkaline drainage generated in the water washing step (S3) (that is, the alkaline drainage obtained in the second solid-liquid separation step (S4)). Sewage sludge incineration ash was treated in the same manner as in Example 1 except that it was used. In the water washing step (S3), the alkali-treated ash was washed using 100 kg of water.
And the property of the obtained processed ash was evaluated by the same method as Example 1. Moreover, the property of the alkaline drainage produced in the water washing step was evaluated by the same method as in Example 1. The results are shown in Table 1.

(Example 3)
In the neutralization step (S7), not the alkaline cleaning drainage but the alkaline drainage generated in the calcium phosphate precipitation step (S11) (that is, the alkaline drainage obtained in the calcium phosphate recovery step (S12)) was used. In the same manner as in Example 1, sewage sludge incineration ash was treated.
And the property of the obtained processed ash was evaluated by the same method as Example 1. Further, the properties of the alkaline drainage produced in the calcium phosphate precipitation step were evaluated in the same manner as in Example 1. The results are shown in Table 1.

(Examples 4 to 6)
In the washing step (S13), the amount of water used for washing calcium phosphate was changed, and the amount of water used / the amount of sewage sludge incinerated ash (mass ratio) was changed as shown in Table 1, as in Example 1. Sewage sludge incineration ash was treated.
And the property of the obtained processed ash was evaluated by the same method as Example 1. In addition, the properties of the alkaline cleaning drainage generated in the cleaning process were evaluated in the same manner as in Example 1. The results are shown in Table 1.

(Comparative Example 1)
The sewage sludge incinerated ash was treated in the same manner as in Example 1 except that the step of washing the acid-treated ash with water three times was carried out instead of the neutralization step (S7). In addition, 300 L (= 100 L × 3 times) of water was used in total.
And the property of the obtained processed ash was evaluated by the same method as Example 1. The results are shown in Table 1.

  From Table 1, in Examples 1 to 6, the pH of the treated ash can be efficiently increased to obtain a treated ash having a pH suitable for effective use. In Comparative Example 1, a large amount of water is used. It can also be seen that the pH of the treated ash cannot be raised sufficiently. In Examples 1, 3, 5, and 6, it can be seen that the pH of the treated ash can be increased more efficiently than in Examples 2 and 4. Further, it can be seen that the treated ash obtained in Examples 1 and 6 has less harmful components such as arsenic and selenium than the treated ash obtained in Examples 3 and 5.

  According to the present invention, in a method for treating sludge incineration ash comprising a step of extracting phosphorus from sludge incineration ash using an alkaline reaction liquid, and a step of treating sludge incineration ash after extracting phosphorus with an acidic solution, While suppressing an increase in the treatment cost of the sludge incineration ash, a treated ash having a pH suitable for effective use can be obtained.

Claims (7)

A phosphorus extraction step of mixing sludge incineration ash and an alkaline reaction liquid to extract phosphorus contained in the sludge incineration ash into the alkaline reaction liquid, and obtaining a phosphorus extract and an alkali-treated ash;
An acid treatment step of mixing the alkali-treated ash with an acidic solution to obtain an acid-treated ash;
A phosphorus recovery step of recovering phosphorus contained in the phosphorus extract as calcium phosphate ;
The acid-treated ash, the alkaline drainage discharged between the end of the phosphorus extraction step and the end of the phosphorus recovery step, and the discharge after the end of the phosphorus extraction step and the end of the acid treatment step A neutralization step of mixing at least one of the alkaline drainage to be raised to increase the pH of the acid-treated ash;
A method for treating sludge incineration ash, comprising:   The method for treating sludge incinerated ash according to claim 1, wherein the pH of the acid-treated ash is raised to 6 or more in the neutralization step. The phosphorus recovery step includes
A calcium phosphate precipitation step of adding a calcium compound to the phosphorus extract and precipitating phosphorus in the phosphorus extract as calcium phosphate;
A calcium phosphate recovery step of recovering the calcium phosphate;
A washing step for washing the recovered calcium phosphate;
Including
The method for treating sludge incineration ash according to claim 1 or 2, wherein, in the neutralization step, the alkaline cleaning drainage discharged in the cleaning step is used as the alkaline drainage.   4. The method for treating sludge incineration ash according to claim 3, wherein in the washing step, the calcium phosphate is washed with water having a mass 5 to 10 times that of the sludge incineration ash.   The method for treating sludge incinerated ash according to any one of claims 1 to 4, further comprising a final washing step of washing the acid-treated ash whose pH has been raised in the neutralization step with water. An alkaline reaction liquid addition means is provided, and the alkaline reaction liquid and sludge incineration ash are mixed to extract phosphorus contained in the sludge incineration ash into the alkaline reaction liquid. A phosphorus extractor to obtain
An acid addition means for adding an acid solution to the alkali-treated ash, and an acid-treatment unit that obtains an acid-treated ash by mixing the alkali-treated ash and the acid solution;
A phosphorus recovery part for recovering phosphorus contained in the phosphorus extract as calcium phosphate ;
After extracting phosphorus in the phosphorus extraction section, after extracting phosphorus in the alkaline drainage and phosphorus extraction section discharged before collecting calcium phosphate in the phosphorus collection section, until obtaining acid-treated ash in the acid treatment section Alkaline drainage recovery means for recovering at least one of the alkaline drainage discharged between,
A neutralization unit that raises the pH of the acid-treated ash by mixing the acid-treated ash and the alkaline effluent collected by the alkaline effluent collecting means;
An apparatus for treating sludge incineration ash, comprising: The phosphorus recovery unit is
A calcium phosphate precipitation tank comprising calcium addition means for adding a calcium compound to the phosphorus extract, and depositing phosphorus in the phosphorus extract as calcium phosphate;
Calcium phosphate recovery means for recovering the calcium phosphate;
A washing tank for washing the recovered calcium phosphate;
Have
The apparatus for treating sludge incineration ash according to claim 6, wherein the alkaline drainage recovery means recovers the alkaline cleaning drainage discharged from the cleaning tank as the alkaline drainage.

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