JP2009039609A - Manufacturing method of porous powder - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a manufacturing method of porous powder applicable to an excellent moisture conditioning material or a deodorant, having preferable manufacturing efficiency, aiming at effective recycling of sludge incineration ash, and a manufacturing method of porous powder causing no corrosion in drying equipment used in a drying process when manufacturing the porous powder, and achieving shortening of the drying process time thereby reduction in drying cost. <P>SOLUTION: The manufacturing method of porous powder comprises the processes of: acid treating by bringing the sludge incineration ash into contact with an acid aqueous solution; neutralizing by a powder neutralizing agent; air drying; and drying after the air drying. The air drying process is performed in an atmosphere of normal temperature and normal pressure by standing still the sludge incineration ash after the neutralizing treatment. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a method for producing a porous powder, and more particularly to a method for producing a porous powder that can be efficiently produced using sludge incineration ash and has excellent humidity control and deodorizing properties.

In recent years, the amount of sewage treatment has been increasing year by year with the spread of sewerage, and the amount of sludge generated has been steadily increasing.
In order to treat such increasing sludge, the sludge is reduced (volume reduction), and therefore, the sludge is incinerated or the sludge is melted.
In particular, incineration of sludge is actively carried out, and the amount of incinerated ash generated is increasing accordingly.

Under such circumstances, most of the generated sludge and incinerated ash from which the sludge was incinerated are disposed of in landfills at the final disposal site. Even in small and medium-sized cities, huge landfill costs are a major problem.
Therefore, for example, the incinerated ash of sludge is pressure-molded and then fired to produce bricks, or the incinerated ash is pressure-granulated into artificial aggregate, or obtained by melting the incinerated ash Techniques using slag as roadbed materials have been proposed, but their application is limited.

Recently, the airtightness of a residence has been increased in order to realize a comfortable living environment, specifically, a comfortable living space.
As a result of improving the airtightness of the living space, a temperature difference occurs between the outdoors and indoors, and in particular, dew condensation in winter causes mold and mites, causing not only indoor dirt but also allergies to the human body, etc. There is a problem.

In order to solve these problems, building materials with excellent humidity control are being developed.
Conventionally, these problems have been alleviated by using wood-based building materials as moisture-absorbing / releasing materials, for example, moisture-controlling materials. It is difficult to use.
In addition, for example, in inorganic building materials, materials mainly composed of diatomaceous earth, zonotlite, tobermorite, etc. have been developed, but can be manufactured at a lower cost, and it is difficult to obtain a desired high humidity control property, and a higher humidity control property Development of materials is desired.

In view of this point, JP 2000-263012 A discloses a porous powder having a BET specific surface area of 6.5 m ² / g or more by adding a sulfuric acid aqueous solution to sludge incinerated ash and then drying it. A method is disclosed, and it is described that the porous powder obtained by such a method can be used as a humidity control material or a deodorizing agent.
Further, JP-A-2002-79081 discloses a method for producing a porous powder having a BET specific surface area of 7 m ² / g or more by adding a hydrochloric acid aqueous solution or a nitric acid aqueous solution to sludge incinerated ash and then drying the slurry. This method is disclosed, and further neutralization treatment (sodium hydroxide, calcium hydroxide, or slaked lime) eliminates the need for acid resistance measures for production equipment, and reduces the occurrence of mold by making it weakly alkaline. It is described that it can be suppressed.
It is also described that the porous powder obtained by such a method can be used as a humidity control material or a deodorizing agent.

  JP-A-2004-136189 discloses a treated product obtained by acid treatment (sulfuric acid aqueous solution, hydrochloric acid aqueous solution or sulfuric acid aqueous solution) and neutralization treatment (sodium hydroxide, calcium hydroxide or slaked lime) of sludge incineration ash. Describes a method for producing a porous granular molded body by extrusion molding, and the use of a porous powder molded body obtained by the method as a humidity control material or a deodorizing agent.

However, these conventional porous powders, as schematically shown in FIG. 1, are manufactured through a drying process using a drying device after acid treatment and neutralization treatment. In the method for producing porous powder, some acid remains unneutralized after neutralization and kneading treatment, and the residual acid volatilizes in the drying apparatus used in the drying process, thereby corroding the drying apparatus. As a result, there is a problem that the life of the apparatus is shortened and the production efficiency is deteriorated, and in some cases, the production is forced to be interrupted due to corrosion of the apparatus.
JP 2000-263012 A JP 2002-79081 A JP 2004-136189 A

Therefore, the object of the present invention is to solve the above-mentioned problems, to effectively reuse sludge incineration ash, and to be applied as an excellent humidity conditioning material or deodorant material, and a porous powder with good production efficiency. It is to provide a body manufacturing method.
Furthermore, in addition to the above object, the object of the present invention is to reduce the cost of drying without corroding the drying equipment used in the drying process when producing the porous powder and by shortening the time of the drying process. It is an object of the present invention to provide a method for producing a porous powder that enables

The present invention has found that the above problems can be achieved by subjecting sludge incineration ash to acid treatment and neutralization treatment and providing an air drying step before subjecting it to the drying step, and has achieved the present invention.
That is, the method for producing a porous powder of the present invention includes an acid treatment step by contact between sludge incineration ash and an acid aqueous solution, a neutralization treatment step with a powder neutralizer, and then an air drying treatment step. The method for producing a porous powder is characterized in that a drying treatment step is carried out after passing through.

  Preferably, the method for producing a porous powder according to claim 2 is the method for producing a porous powder according to claim 1, wherein the air-drying treatment step is carried out in a normal temperature and normal pressure atmosphere in a neutralization treatment. The method for producing a porous powder is characterized in that it is carried out by leaving the sludge incineration ash after standing still further. The method for producing a porous powder according to claim 3 further comprises the method according to claim 1 or 2. 5. The method for producing porous powder according to claim 4, further comprising a step of forming the treated product after the neutralization treatment step, and further comprising the step of producing the porous powder according to claim 4. The method for producing a body is the method for producing a porous powder according to any one of claims 1 to 3, wherein the sludge incineration ash contains 5 to 40% by mass of water. It is a manufacturing method.

The method for producing a porous powder of the present invention comprises an acid treatment step by contact with sludge incineration ash and an aqueous acid solution, a neutralization treatment step with a powder neutralizing agent, and then a drying step before being subjected to a drying step. By providing it, it is possible to reduce the acid remaining in the sludge incineration ash after the neutralization process, thereby making it possible to prevent the corrosion of the drying equipment used in the drying process and extending the life of these equipment Is possible.
Moreover, it becomes possible to ensure the neutralization reaction time of the residual acid by the air drying treatment.
Furthermore, by providing the air drying step, the moisture content can be reduced, the drying time in the drying step can be shortened, the drying cost can be reduced, and the cost for producing the porous powder can be reduced.

  Further, the porous powder obtained by the production method of the present invention has uniform pores and characteristics, and has excellent characteristics as a porous powder. By using it as an active ingredient, it is possible to exhibit a good and stable humidity control effect, and by using it as an active ingredient of a deodorizing material, it is possible to exhibit a good and stable deodorizing effect.

The present invention will be described with reference to the best embodiments, but is not limited thereto.
The method for producing a porous powder of the present invention includes an acid treatment step by contact with sludge incineration ash and an aqueous acid solution, a neutralization treatment step with a powder neutralizing agent, and then an air drying treatment step. A drying process is performed later.
Thus, by providing an air drying treatment step after the neutralization step and before the drying step, the residual acid component and moisture can be evaporated, and the neutralization reaction time of the residual acid can be secured.

As the raw material sludge incineration ash used in the production method of the present invention, in addition to sludge incineration ash incinerated sludge generated in a sewage treatment plant, incineration of sludge generated by human waste, household wastewater, industrial wastewater treatment, etc. Ashes and the like can be mentioned, and these are generally incinerated sludge dehydrated to a water content of about 60 to 90% by mass in a treatment plant.
In the present invention, any of these incineration ash can be used, and may be used alone or in combination.
In particular, since the amount of sludge generated at a sewage treatment plant increases with the spread of sewerage year by year as described above, the method of the present invention is extremely useful as effective reuse of sludge.

In general, incineration ash includes incineration of sludge using a polymer flocculant and incineration of sludge using a lime-based flocculant. Many of them are used and both can be used in the present invention. However, when a lime-based flocculant is used, a large amount of lime is generated, which is not preferable.
The form of the sludge incineration ash is not particularly limited as long as a sufficient dissolution reaction is performed by addition of acid, and finally a homogeneous porous granule can be obtained. Even those formed into a shape, plate shape, tablet shape, or the like can be subjected to contact treatment by addition of an acid and can be used in the method of the present invention.

The acid treatment step in the present invention is a step of performing acid treatment by bringing the sludge incineration ash into contact with an acid aqueous solution.
Here, as the acid aqueous solution added to the sludge incineration ash, it is preferable to use a mineral acid such as a sulfuric acid aqueous solution, a hydrochloric acid aqueous solution, or a nitric acid aqueous solution, and these sulfuric acid aqueous solution, hydrochloric acid aqueous solution or nitric acid aqueous solution are commercially available. Commercially available products and aqueous solutions of waste sulfuric acid, waste hydrochloric acid, waste nitric acid, etc. generated from the metal refining industry and the like can also be used.
The concentration of the acid aqueous solution to be used is not particularly limited, but is usually about 0.1 to 13 N.

Moreover, as an addition amount of the acid aqueous solution added to the sludge incineration ash, in terms of 100% acid (sulfuric acid, hydrochloric acid, nitric acid, etc.), with respect to 100 parts by mass of the sludge incineration ash, 0.5 parts by mass or more, Preferably 4.0-25 mass parts is added.
This is because when mixed in such a range, the dissolution reaction is sufficient, and the resulting porous powder has good humidity control performance and deodorization performance.
In addition, the temperature during addition kneading is preferably about 10 to 90 ° C. from the viewpoint of promoting the reaction.

Thus, by adding or mixing or kneading the acid aqueous solution to the sludge incineration ash, the surface of the incineration ash becomes immersed, and the acid-soluble components contained in the incineration ash are dissolved and removed, and the acid treatment is performed. Things can be made porous.
The kneading time of the incineration ash and the acid aqueous solution can be arbitrarily set according to the characteristics of the sludge incineration ash.
By changing the acid treatment kneading time, the pore size distribution can be changed. That is, by increasing the kneading time, it is possible to further increase the fine pore volume of, for example, 10 nm or less, particularly 6 nm or less. As the fine pore volume increases, the absorption of water vapor or the like increases. Moisture release performance can be enhanced.
Usually, after addition of the aqueous acid solution, about 0.1 hour to 10 days, preferably about 0.1 hour to 1 day is appropriate.

Next, the obtained acid-treated product is subjected to a neutralization treatment step.
This is because, when the porous powder is used as it is, it is necessary to take measures against acid resistance in the powder production facility as it is.

The neutralization treatment is performed by adding an acid aqueous solution to the sludge incineration ash and performing a contact treatment, and then adding a powder neutralizer to bring the pH to about 5.5 to 9.0.
Examples of the powder neutralizer include sodium hydroxide (NaOH), calcium hydroxide (Ca (OH) ₂ ), slaked lime, ammonia, limestone (limestone) mainly composed of CaCO ₃ , and coral sand. Examples of the alkaline material include sodium hydroxide, calcium hydroxide, and slaked lime.
Moreover, the addition amount of a neutralizing agent is added so that a processed material may become pH 5.5-9.0.
Thus, by adding a neutralizing agent to the acid-treated product and mixing or kneading, strict acid resistance measures in the powder production facility are unnecessary, and a powder with good porosity can be obtained.

Next, the sludge incinerated ash after neutralization is air-dried.
The air drying step is carried out by stirring or leaving the ash after passing through the neutralization treatment step in air at normal temperature and pressure.
In this way, by stirring or standing in the atmosphere under normal temperature and pressure, residual acid and moisture can be evaporated, and further, the neutralization time of the residual acid can be secured.

In addition, by stirring the sludge incineration ash after neutralization, the neutralization reaction of the residual acid proceeds rapidly, and it is possible to complete the air drying process in a short time. It is sufficiently possible to carry out such air-drying treatment even by standing in the atmosphere.
Usually, the air-drying treatment is performed by leaving it in an atmosphere of normal temperature and pressure for about 1 to 7 days, preferably about 1 to 2 days. Thus, by providing the air drying step before the drying step, the drying equipment is not corroded, and the acid resistance measures of the equipment are unnecessary, and a powder having good porosity can be obtained.

The processed product that has undergone the air drying step is subjected to a drying step.
The drying method is not particularly limited, and examples include a drying method using a rotary drum dryer, a paddle dryer, a fluidized bed dryer, an air flow dryer, a centrifugal thin film dryer, etc. A drying method using a drier currently used in a treatment plant can also be adequately handled. The drying temperature is preferably 90 to 300 ° C.
Since the air drying process is provided before the drying process in the present invention, it is possible to prevent these drying apparatuses from being corroded with acid and to reduce the amount of water contained, thereby shortening the drying process. Is possible.

The moisture content after drying is preferably less than 5% by mass, and the absolutely dry state shows a particularly excellent effect as a porous powder. If the drying is insufficient, the pore volume decreases and the moisture absorption and desorption performance decreases.
Here, the moisture content is based on the sample weight before drying and after drying for 2 hours at 105 to 110 ° C. in accordance with “Sewage test method (1997 version) Chapter 4 Section 6 Evaporation residue and moisture content”. Is a value expressed as a percentage with respect to (mass before drying-mass after drying) / (mass before drying).

Specifically, the method for producing the porous powder of the present invention will be described.
Moreover, FIG. 2 is a figure which shows typically an example of the manufacturing method of the porous powder of this invention.
In order to produce better quality porous powder, mixing and kneading work of sludge incineration ash and acid aqueous solution, mixing and kneading work of acid-treated sludge incineration ash (acid-treated product) and neutralizing agent, It is desirable to perform sufficiently and continuously.
Moreover, in order to prevent the reduction of the acid treatment effect and maintain a good working environment, it is necessary to suppress a large amount of water vapor and acidic gas generated during kneading from being diffused into the atmosphere.

From this point of view, the present inventors have found that the method for producing a porous powder of the present invention is suitably performed by a closed kneader, and in particular, a biaxial extrusion kneader is most preferable as a kneading mechanism. It was.
The specific configuration of a suitable twin-screw extrusion kneader has two or three screws, and the two shafts can be either a parallel type or a conical type, with the screws obliquely crossing the shafts. It is.
The screw flight can be either a meshing type or a non-meshing type, but the former is preferable because the kneading effect is greater.
The screw rotation direction can be either the same direction or a different direction, but the former is preferable because the kneading effect is large.

Using such a twin-screw extrusion kneader, along the same axis of the extrusion kneader, the sludge incineration ash charging section, the acid aqueous solution charging section, and the neutralizing agent charging section are arranged downstream from the upstream side in the extrusion direction. The sludge incineration is performed, the acid treatment is performed using the acid aqueous solution described above, and the neutralization treatment is performed using the neutralizing agent.
In the method of the present invention, it is necessary to continuously carry out each of the above treatments in a sealed state to increase the sealing degree of the entire kneader. For this reason, the following structure is adopted for each charging unit. To do.
In the sludge incineration ash charging unit, the sludge incineration ash is charged into a twin-screw extrusion kneader by a quantitative feeder such as a circle feeder or a rotary feeder.

In the acid aqueous solution charging part, an acid aqueous solution such as the sulfuric acid aqueous solution, hydrochloric acid aqueous solution or nitric acid aqueous solution is injected by a metering pump.
Further, in the neutralizing agent charging section, a neutralizing agent such as an aqueous sodium hydroxide solution or a slurry of calcium hydroxide or slaked lime is injected with a metering pump.
All the mechanisms of these charging parts can be automated, and it is possible to automate the entire manufacturing process of the porous powder including the biaxial extrusion kneader using these mechanisms.

Sludge incineration ash and acid-treated products are continuously conveyed along the same axis of a twin-screw extrusion kneader, but the delivery density of these conveyed products is usually not constant, and kneading with the part that mainly contributes to conveyance There is a part in
The arrangement position of the acid aqueous solution charging part and the neutralizing agent charging part with respect to the biaxial extrusion kneader is preferably arranged at a position where the delivery density of the sludge incinerated ash and the conveyed product which is the acid-treated product is the highest.

A place where the delivery density of the conveyed product is high is a place where the conveyed product is most concentrated, and is also a place where the conveyed product is clogged in the entire cylinder in the biaxial extrusion kneader.
In such a place, the input liquid (including slurry) and solids are strongly pressed against the conveyed product, and can be uniformly mixed with the conveyed product.
In addition, since these acid aqueous solutions and neutralizing agents are introduced from the periphery of the cylinder, these charged materials enter the gap between the conveyed product and the cylinder, reducing the frictional force between the conveyed product and the cylinder, and smooth conveyance. The lubrication action to achieve this can be expected.

  The place where the delivery density of the conveyed product is high is a place where the angle with respect to the axis of the screw approaches a right angle, and when the conveying part and the kneading part are separated in the same axial direction, this is the inlet part entering the kneading part. It corresponds to.

In addition to continuous kneading by a twin screw extruder, it can also be manufactured by a batch method using a twin screw kneader.
The biaxial kneader has two kneading blades in the kneading container, and the material put in the kneading container is uniformly kneaded by the rotation of the kneading blade. For discharging the kneaded material, there are a type in which the bottom of the container is opened and a type in which the container is tilted.
Using such a twin-screw kneader, an acid aqueous solution is added to the sludge incineration ash and then kneaded to perform an acid treatment. Subsequently, a neutralizing agent is added and then kneaded to perform a neutralization treatment. The neutralized product is discharged from the kneading container.
As for the acid aqueous solution, an acid aqueous solution such as a sulfuric acid aqueous solution, a hydrochloric acid aqueous solution, or a nitric acid aqueous solution is added using a pump or the like.
As for the neutralizing agent, sodium hydroxide, calcium hydroxide or slaked lime is added as an aqueous solution, slurry, or powder.

The processed product discharged from the biaxial extrusion kneader or the biaxial kneader is molded as necessary.
Specifically, the extruded processed product can be put into a molding machine, molded into a pellet or the like, then subjected to the air drying step, and then dried for use.
Further, it may be directly applied to the air drying step / drying step without molding, or may be subjected to filtration after washing once with water, and the residue may be applied to the air drying step / drying step.
By once passing through an air drying step and a drying step after washing with water, impurities and the like on the surface of the processed product can be removed, and the adsorption performance is also improved.

  As described above, the porous powder as a dried product obtained by the method for producing a porous powder of the present invention has a high hygroscopic property because it is a porous material with an extremely fine pore volume increased, and is also free from release. Since the wettability is also good, it can be suitably used as a humidity control material with improved moisture absorption / release performance compared to conventional ones, and as a deodorant material capable of adsorbing malodorous gas efficiently.

The present invention will be described more specifically with reference to the following examples and test examples. However, the present invention is not limited to the following examples.
(Examples and test examples)
As sewage sludge incineration ash, sludge dehydrated after adding a polymer flocculant and incinerated in a fluidized bed incinerator was used.
Using a kneader (KDAJ-200 type: manufactured by Fuji Powder Co., Ltd.), 30 parts by mass (9 kg) of tap water is added to 100 parts by mass (30 kg) of the sewage sludge incineration ash (dry ash) and mixed. After smelting, 20 parts by mass (6 kg) of 11N hydrochloric acid (Wako Pure Chemicals product code 085-01077) was added, and the mixture was thoroughly kneaded and subjected to acid treatment.

Next, 15 parts by mass (4.5 kg) of slaked lime (Wako Pure Chemicals product code 032-00627) was added to 100 parts by mass of the sewage sludge incineration ash (dry ash), and the mixture was kneaded and neutralized. .
The delivery kneaded material is immediately granulated (φ3 mm, length of about 10 mm) by a granulator (F-5-S / 11-175D type: manufactured by Fuji Powder Co., Ltd.), and the granulated product is subjected to an air drying process. did.

In the air drying process, 4.5 kg of the granulated product is spread on a shelf board with a knitted bottom (opening 2 mm) so that the layer thickness is about 2 cm, and it is kept for 0 to 7 days in an atmosphere of normal temperature and pressure. It was done by leaving still.
Here, the relationship between the standing days and the chlorine concentration or moisture content in the air-dried product is shown in Table 1, FIG. 3, Table 2, and FIG.
In Table 1, the chlorine contained in the ash immediately after the neutralization treatment (immediately before the air drying treatment) was defined as 100, and the air drying days and the content of residual chlorine were represented by relative evaluation.

Further, the chlorine concentration in each air-dried product was measured as shown in FIG.
Specifically, first, the air-dried product is placed in a sealed container, heated to 150 ° C. with a mantle heater while flowing air as a carrier gas, and the generated water vapor and hydrogen chloride gas are 0.1% by mass sodium hydroxide. It was made to absorb in aqueous solution, the chlorine concentration in the absorbing solution was measured by potentiometric titration (automatic titrator GT-100 manufactured by Mitsubishi Chemical Corporation), and the residual hydrochloric acid concentration in the air-dried product was calculated.

As is clear from Table 1, FIG. 3, Table 2, and FIG. 4, when the air drying treatment is performed for one day, the residual chlorine amount in the neutralized ash is reduced to 40% of the initial value.
In addition, when the air drying treatment is carried out for 4 days, it is understood that the moisture content is also reduced from 22.7% immediately after the neutralization treatment for starting the air drying treatment to 14.2%.
The moisture content is expressed as a percentage with respect to (mass before drying−mass after drying) / (mass before drying) by measuring the sample mass before drying and the sample mass after drying at 105 ° C. for 2 hours. Value.

Next, each air-dried product was dried by holding at 150 ° C. using a large hot air circulating dryer (GT-150 manufactured by Alp) to obtain a porous powder.
The water content of each porous powder was 0% by mass.
The drying time in the drying step (temperature of 105 ° C.) until the water content becomes 0% is 5 hours for those not subjected to the air drying treatment, 4 hours for those subjected to the air drying treatment for 1 day, and the air drying treatment. What was carried out for 4 days was 3.5 hours, and what was subjected to the air drying treatment for 7 days was 3 hours.
From this, it was confirmed that the one subjected to the air drying treatment shortened the drying process time and saved labor in the drying process, and further, the drying apparatus was less corroded.

Subsequently, the obtained porous powder was subjected to a moisture absorption test (powder subjected to the air drying treatment for 0 days and 7 days) by the following method.
10 g of each porous powder sample put in a petri dish was left standing in a thermo-hygrostat (LHL-113 manufactured by Espec Corp.).
Specifically, the constant temperature and humidity chamber was set to 20 ° C. and 50% RH, and the mass (preliminary humidity control) A after 24 hours when the moisture adsorption amount reached almost equilibrium was measured.

Next, the setting of the constant temperature and humidity chamber is changed to 20 ° C. and 90% RH, and each porous powder sample that has reached the equilibrium state is held for 24 hours (moisture absorption) in the same manner as described above, and then the sample after moisture absorption Again, it was kept in a constant temperature and humidity chamber set to 20 ° C. and 50% RH for 24 hours (moisture release), and this moisture absorption and desorption cycle was repeated two cycles.
In the second cycle, the moisture absorption sample mass B and the moisture release sample mass C were weighed, and the moisture absorption / release amount (%) was determined by the following equation.
Moisture absorption / release (%) = (BC) / A × 100

The test results are shown in Table 3.
However, the mass of the sample after pre-humidification after first setting the sample in a constant temperature room at 20 ° C. and setting the environment with a relative humidity of 50% for 24 hours is expressed as a mass change rate of 100%. The rate of change of the mass of each sample in the process was displayed.

  From Table 3, it was confirmed that the porous powder obtained by the present invention was excellent in moisture absorption / release performance due to effective porosity.

  The porous powder of the present invention can be effectively applied not only as a humidity control material but also as a deodorizing material such as a malodorous gas adsorbing material.

It is a figure which shows typically the manufacturing process of the conventional porous powder. It is a figure which shows typically an example of the manufacturing process of this invention porous powder. It is a diagram which shows an example of the relationship between the air drying process days and the amount of chlorine contained. It is a diagram which shows an example of the relationship between the air drying process days and the moisture content contained. It is a figure which shows roughly the method of measuring chlorine or water content.

Claims (4)

  It is characterized by performing an acid treatment step by bringing sludge incineration ash into contact with an acid aqueous solution, a neutralization treatment step with a powder neutralizing agent, and then an air drying treatment step, and performing the drying treatment step after passing through the air drying treatment step. A method for producing a porous powder.   The method for producing a porous powder according to claim 1, wherein the air-drying treatment step is carried out by allowing the sludge incinerated ash after neutralization treatment to stand in an air at normal temperature and pressure. Production method of porous powder.   The method for producing a porous powder according to claim 1, further comprising a step of forming the treated product after the neutralization treatment step.   The method for producing a porous powder according to any one of claims 1 to 3, wherein the sludge incineration ash contains 5 to 40% by mass of water.

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