JP2001334289A - Sludge treatment method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide sludge treatment technique effective for manufacturing sludge compost from sludge containing heavy metals and fertilizing components. SOLUTION: Hydrochloric acid is added to sludge containing heavy metals and fertilizing components (nitrogen, phosphorus, potassium or the like) in an acid adding process to adjust the pH of the sludge to 2-4 to elute heavy metals contained in the sludge solid (sludge fine particles) of the sludge to a liquid side by the relation of pH to the solubility of heavy metals. Thereafter, the solid is flocculated in a flocculant adding process and further taken out in a solid-liquid separation process to manufacture a solid (sludge fertilizer) containing the fertilizing components and low in the concentration of heavy metals.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to the treatment of sludge, and more particularly to a sludge treatment technique for extracting a fertilizing component from sludge containing heavy metals and a fertilizing component.

[0002]

2. Description of the Related Art Conventionally, for example, in the food industry and the machinery manufacturing industry, there is known a sewage treatment apparatus that treats wastewater (sewage) discharged from a factory and discharges it as purified water. This sewage treatment device, for example, aeration treatment using activated sludge,
It is configured to purify sewage by performing a precipitation treatment. By the way, in such a sewage treatment device,
In the process of treating sewage, sludge containing a fertilizer component (nitrogen, phosphorus, potassium, etc.) that becomes a fertilizer may be generated. Then, by adding a flocculant to the sludge containing such a fertilizer component, a sludge solid (hereinafter, referred to as “sludge floc”) is generated, and the treated sludge is separated into a solid and a liquid.
By dewatering and drying the separated sludge floc, a sludge fertilizer containing a fertilizer component can be produced. However, when the sludge contains harmful heavy metals, for example, zinc compounds, in addition to the fertilizer component, it is difficult to remove the heavy metals in the sludge by the same treatment. Therefore,
Since such sludge contains harmful heavy metals, it cannot be made into a sludge fertilizer even though it contains a fertilizing component, and has been conventionally incinerated, for example.

However, if sludge can be made into fertilizer by selectively removing heavy metals from the sludge,
There is an advantage that the fertilizer component in the sludge can be effectively used. Therefore, there is a technique for removing or reducing heavy metals in sludge as disclosed in Japanese Patent Application Laid-Open No. 10-85792. According to the sludge treatment method described in this publication, first, the pH of the sludge is adjusted to 3 or less by adding an acid and an oxidizing agent to the sludge.
Heavy metals are eluted to the liquid side depending on the relationship between the solubility and the solubility. Thereafter, the pH of the treated sludge is adjusted to 3 to 4 by adding an alkaline agent to the treated sludge, and then a coagulant is added. Then, the sludge floc agglomerated by the coagulant is separated into a solid matter by solid-liquid separation. Thus, a solid having a low concentration of heavy metals can be obtained.

[0004]

The treatment method described in the above publication is very effective as a method for removing or reducing heavy metals in sludge. However, in this treatment method, since the treatment using the oxidizing agent is performed, the oxidizing agent is contained in the solid obtained after the treatment. Since this oxidizing agent has a strong bactericidal action, when a solid containing the oxidizing agent is used as a sludge fertilizer, there is a possibility that bacteria in the soil may be killed. Therefore, the above processing method
Although effective in removing or reducing heavy metals in sludge, it is not suitable for producing sludge fertilizers that do not kill soil bacteria from sludge containing heavy metals and fertilizers. .

Accordingly, the present invention has been made in view of the above points, and an object of the present invention is to produce a sludge fertilizer from sludge containing heavy metals and a fertilizing component. It is to provide sludge treatment technology.

[0006]

In order to solve the above-mentioned problems, a method for treating sludge according to the present invention is configured as described in each claim.

According to the method for treating sludge of the first aspect, an acid is added to the sludge in the acid addition step, and the pH of the sludge is adjusted.
Is adjusted to 2 to 4, heavy metals on the sludge solids side are eluted to the liquid side, and the concentration of heavy metals contained on the solids side can be reduced as much as possible. Thereby, the heavy metals can be selectively removed from the sludge containing the heavy metals and the fertilizing component, and the fertilizing component can be extracted. Therefore,
If this treatment method is used, sludge fertilizer containing a low concentration of heavy metals and containing a fertilizer component can be efficiently produced. In addition, since only the acid is used for adjusting the pH of the sludge in the acid addition step, the treated solid does not include, for example, an oxidizing agent that may kill bacteria in the soil. Therefore, a sludge fertilizer containing a fertilizer component can be used as a fertilizer without fear of killing bacteria.

According to the method for treating sludge according to the second aspect, by performing the washing step after the solid-liquid separation step, heavy metals, for example, zinc remaining in the solid matter can be effectively washed away. . Here, it is preferable to use water or alkaline water having a pH of about 8 to 10 as a detergent used in the washing step. This makes it possible to effectively neutralize acidic components remaining in the acid addition step in addition to heavy metals.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A sludge treatment method according to one embodiment of the present invention will be described below with reference to the drawings. Here, FIG. 1 is a diagram showing an outline of a sludge treatment process. In the present embodiment, a case will be described in which sludge containing heavy metals and fertilizing components is treated with an acid, a coagulant, or the like to produce a sludge fertilizer effective as a fertilizer.

For example, wastewater (sewage) discharged from factories such as the food industry and the machinery manufacturing industry is treated by a predetermined wastewater treatment device. In this sewage treatment, sludge containing fertilizer (nitrogen, phosphorus, potassium, etc.) and harmful heavy metals, for example, zinc compounds, is generated.
This sludge is almost neutral. For example, as shown in Table 1, 172 mg of copper (heavy metal), 15200 mg of zinc (heavy metal), 13800 m
g of nitrogen, 54000 mg of phosphorus, 535 mg of potassium and the like. In the present embodiment, by treating this sludge, heavy metals such as copper and zinc are selectively removed from the sludge, a fertilizer component is extracted, and a sludge fertilizer having a fertilizer component is produced. The method will be described.

[0011]

[Table 1]

As shown in FIG. 1, sludge containing heavy metals and fertilizers (nitrogen, phosphorus, potassium, etc.) generated in sewage treatment is first treated in an acid addition step 10. In the acid addition step 10, the sludge stored in the stirring tank is stirred at a predetermined stirring speed (for example, about 300 rpm),
An acid such as hydrochloric acid is added to the sludge. As hydrochloric acid is added to almost neutral sludge, its pH decreases. Then, the addition amount of hydrochloric acid is adjusted so that the pH of the sludge becomes 2 to 4. As described above, by setting the pH of the sludge to 2 to 4, depending on the relationship between the pH and the solubility of the heavy metals, heavy metals, for example, zinc contained in the sludge solid matter (sludge fine particles) of the sludge can be ionized or ionized. Dissolves and elutes to the liquid side. Thereby, the concentration of heavy metals remaining on the sludge solid matter side of the sludge can be reduced. In addition, the fertilizing component in the sludge remains on the sludge solid matter side. The reason for adjusting the pH of the sludge to 2 to 4 is that if the pH becomes higher than 4,
This is because heavy metals are less likely to elute to the liquid side, while if the pH is less than 2, sludge flocs are less likely to be condensed in a condensing agent addition step described later. Note that hydrochloric acid is preferably used as the acid for adjusting the pH of the sludge. By using relatively inexpensive hydrochloric acid among the acids,
Chemical costs in the acid addition step can be minimized.

After the acid addition step 10 is completed, a coagulation treatment of the sludge solid is performed in a coagulant addition step 20. In the coagulant addition step 20, a predetermined amount of a cationic coagulant corresponding to the amount of sludge solids in the sludge is added while continuing to stir the treated sludge treated in the acid addition step 10.
Thereby, the sludge solids in the sludge aggregate to form sludge flocs and settle. Also, by using a cationic coagulant as the coagulant, the coagulation effect of the sludge solids does not decrease even in a relatively low pH region.

As the coagulant for coagulating sludge solids, it is preferable to use a polymer (organic) coagulant among the cationic coagulants. Thereby, for example, as compared with the case where a low molecular (inorganic) flocculant is used, sludge flocs can be formed larger, and the dewatering property in the dehydration step described later is good. In addition, coagulant addition step 2
It is preferable that the stirring at 0 is performed at, for example, about 120 rpm in the initial stage of the formation of the sludge floc, and then the stirring speed is reduced to, for example, about 60 rpm in the latter half. By stirring in this way, sludge flocs can be efficiently formed.

After the coagulant adding step 20 is completed,
In the solid-liquid separation step 30, solid-liquid separation of sludge including sludge flocks is performed. The solid-liquid separation is performed, for example, by using a stationary separation method. That is, the stirring of the stirring tank is stopped, and the stirring tank is allowed to stand for a predetermined time. Thereby, the liquid is separated into the liquid side and the solid matter side (sludge floc). The treated sludge is filtered, for example, with a filter cloth passing only on the liquid side, so that solid matter composed of sludge flocs can be selectively taken out. Although this solid has a low concentration of heavy metals, heavy metals and hydrochloric acid added in the acid addition step 10 may remain on the surface of the solid in some cases. Do.

In the cleaning step 40, for example, water or alkaline water having a pH of about 8 to 10 is used as a cleaning agent, and the water or alkaline water mist is uniformly sprayed on the entire solid to clean the solid. Do. Thus, heavy metals eluted on the surface of the solid can be washed away. For example, in the present embodiment, the zinc concentration (concentration in 1 kg of dry sludge fertilizer) is reduced to 70 by performing the washing step 40.
It can be reduced from 0 mg to 411 mg. Further, by using water or alkaline water, an acidic component remaining on the surface of the solid substance of the hydrochloric acid added in the acid addition step 10 can be washed away or neutralized, and a substantially neutral solid substance can be generated. In addition, when alkaline water having a pH of about 8 to 10 is used, the sludge fertilizer described below is neutral to
It can be maintained alkaline, leading to prevention of soil acidification.

When the washing step 40 is completed, the solid is then dehydrated in a dehydration step 50. In the dehydration step 50, for example, a so-called filter press method is used in which a solid is sandwiched between both sides by a filter cloth and pressed. Thereby, the water content of the solid can be reduced. Further, the solid obtained in the dehydration step 50 is further dried in the drying step 6
Dry at 0. In the drying step 60, for example, the solid is dried by natural drying. The solid matter thus obtained becomes sludge fertilizer.

For example, as shown in Table 1 above, 411 mg of zinc (heavy metal), 13800 mg of nitrogen, 54000 mg of phosphorus,
Contains 535 mg of potassium and the like. in this way,
According to the sludge treatment method of the present embodiment, for example, zinc having a concentration of 15200 mg contained in the sludge before treatment is:
Sludge fertilizer contains only 411 mg. In addition, the concentrations of the fertilizing components nitrogen, phosphorus and potassium do not change. Therefore, the heavy metals contained in the pre-treatment sludge are selectively removed from the solid matter side, and the fertilizer component is extracted.

According to the sludge treatment method of the present embodiment configured as described above, when treating sludge containing heavy metals and fertilizing components, the pH of the sludge is adjusted in the acid addition step 10.
Is adjusted to 2 to 4, heavy metals can be selectively eluted to the liquid side. Therefore, it contains fertilizing ingredients,
Sludge fertilizer with a low concentration of heavy metals can be efficiently produced. Further, by washing the solid using water or alkaline water in the washing step 40, zinc remaining on the surface of the solid, and acidic components remaining on the solid surface of the hydrochloric acid added in the acid addition step 10 are added. Can be washed away. In this manner, for example, sludge that has been incinerated but can be effectively used despite containing a fertilizer component.

Here, in order to further clarify the effect of the sludge treatment method of the present embodiment, 152 sludges per kg are required.
When the sludge containing 00 mg of zinc (dry value) was treated by the method of the present embodiment (first treatment method), sludge having the same properties was treated by a method excluding the acid addition step 10 and the washing step 40. The maximum application rate of the sludge fertilizer is compared with the case (second processing method). Note that the maximum application rate of sludge fertilizer, after compliance with zinc allowable concentration per soil 1kg prescribed in Soil Pollution Prevention Law (120 mg), soil 1 m ²
Of sludge fertilizer that can be used per unit (kg / m
² ).

In the first treatment method (the treatment method of the present embodiment), 411 mg / kg of sludge fertilizer (dry value) is used.
In the second treatment method, 15 kg of zinc was contained in 1 kg of sludge fertilizer (dry value). Based on this result, in the first treatment method, while the maximum application amount of the sludge fertilizer is 30 kg / m ² ,
In the second treatment method, the maximum application rate of the sludge fertilizer is 0.8 k.
g / m ² . Therefore, the sludge fertilizer obtained by the first treatment method is about 40% of the sludge fertilizer obtained by the second treatment method.
It can be used twice and can be effectively used as fertilizer.

It should be noted that the present invention is not limited to only the above-described embodiment, and various applications and modifications are conceivable. For example, each of the following embodiments to which the above embodiment is applied may be implemented.

(A) In the above embodiment, the acid addition step 1
Although the case where hydrochloric acid is added as an acid at 0 has been described, the type of acid is not limited and can be variously changed as necessary. For example, nitric acid or phosphoric acid may be used.

(B) In the above embodiment, the case where a cationic coagulant is used as the coagulant in the coagulant addition step 20 has been described. However, any coagulation effect of sludge floc can be obtained under acidic conditions. The type of the flocculant is not limited.

(C) In the above embodiment, the stationary separation method is used in the solid-liquid separation step 30, but various solid-liquid separation techniques such as a centrifugation method can be used.

(D) In the above embodiment, the case where the solid matter is dehydrated by the filter press method in the dehydration step 50 has been described. However, the dehydration method is not limited to this, and various modifications may be made as necessary. It is possible. For example, a belt press and a screw press can be used.

(E) In the above embodiment, the case where the cleaning step 40 is performed after the solid-liquid separation step 30 has been described. However, the cleaning step 40 may be omitted. Further, in the cleaning step 40, the case where water or alkaline water is used as the cleaning agent has been described, but the type of the cleaning agent can be variously changed according to the pH of the object to be cleaned.

(F) The present invention can be applied to sludge obtained by various kinds of sewage treatment as long as the sludge contains a fertilizer component and heavy metals.

[0029]

As described above, according to the present invention,
An effective sludge treatment technique for producing sludge fertilizer from sludge containing heavy metals and fertilizing components can be realized.

[Brief description of the drawings]

FIG. 1 is a diagram showing an outline of a sludge treatment process.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 ... Acid addition process 20 ... Flocculant addition process 30 ... Solid-liquid separation process 40 ... Washing process 50 ... Dehydration process 60 ... Drying process

 ──────────────────────────────────────────────────続 き Continued on front page F term (reference) 4D059 AA11 AA19 AA30 BD02 BE08 BE16 BE26 BE31 BE37 BE56 BE57 BF12 BH04 BH07 BH08 BJ00 BK06 CC01 DA31 DA32 DA39 4H061 AA02 CC51 EE70 FF06 GG21 GG29 GG54 GG70 LL22

Claims (2)

[Claims] 1. A method for treating sludge, comprising treating sludge containing heavy metals and a fertilizing component and extracting a fertilizing component from the sludge, wherein an acid is added to the sludge, and the pH of the sludge is adjusted to 2 to 2. By adjusting to 4, the acid addition step of eluting heavy metals on the sludge solids side to the liquid side, and a coagulant is added to the treated sludge treated in the acid addition step to generate sludge flocs composed of the sludge solids A method for treating sludge, comprising: a coagulant adding step to be performed; and a solid-liquid separation step of separating the treated sludge treated in the coagulant adding step into a solid side and a liquid side. 2. The method for treating sludge according to claim 1, wherein after the solid-liquid separation step, a washing step of washing a solid separated in the solid-liquid separation step using a detergent. A method for treating sludge, comprising: