JP2009056362A - Incinerator ash treatment system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a system capable of treating incinerator ashes remaining after incinerating industrial waste at a higher recycling ratio. <P>SOLUTION: The incinerator ash treatment system for industrial waste comprises a crusher for crushing incinerator ashes, a magnetic sorter for separating magnetic substances such as iron from the incinerator ashes crushed by the crusher, and a dry ball mill for further pulverizing the incinerator ashes after separation of the magnetic substances by the magnetic sorter and an inside sieve and an outside sieve are installed while being overlaid in the outlet of the ball mill. The inside sieve has sieving meshes with a shape and a size capable of separating the pulverized product from the pulverization medium and the outside sieve has smaller sieving meshes than the inside sieve with a size proper for discharging the pulverized substances with a prescribed size or smaller and further, the outside sieve is made so detachable as to discharge the pulverized substances which cannot pass through the outside sieve but the inside sieve after the pulverized substances with the prescribed size or smaller are discharged. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a system for separating and treating incineration ash discharged when industrial waste is incinerated as a cement raw material.

  Currently, industrial waste such as waste oil, waste solvent, waste plastic, scrap metal, medical waste, construction waste, etc. is generally incinerated. Incineration ash generated after incineration has been disposed of in landfills in recent years, but in recent years, efforts to effectively use valuable materials contained in incineration ash have been advanced from the viewpoint of resource and environmental protection. Specifically, iron contained in incinerated ash is separated and recovered, or quicklime, alumina and silica are used as a cement raw material.

  When processing such incinerated ash, a processing system is usually constructed by combining various processing devices such as a crusher, a magnetic separator, and a sieving machine.

  For example, in JP 2006-167513 A (Patent Document 1), only soft coarse materials such as clinker are crushed in order to avoid inconvenience due to mixing of hard coarse materials such as iron ingots into incineration ash. In addition, an ash content recovery system characterized by adopting a means for removing coarse materials that are not crushed by the clinker crusher from the processing system is described. In this system, a compression crusher, a large classification means, a large foreign matter discharge means, Small / medium classifying means, collecting means, magnetic sorter and the like are employed.

  JP 2001-129511 A (Patent Document 2) points out the problems caused by the incineration ash containing a large amount of unburned organic matter, and the unburned organic matter that is the source of methane contained in the incineration ash. Removed, decomposed and stabilized dioxins, converted to sulfides that exist in nature to reduce the solubility of various heavy metal substances, and converted to stable incinerated ash to make incinerated ash as an auxiliary material for cement, etc. An invention for the purpose of providing a treatment apparatus for incineration ash that can be used effectively and can efficiently and efficiently treat incineration ash at a temperature of 800 ° C. to 900 ° C. is described. ing. In this invention, an incineration ash treatment apparatus is constructed by combining incineration ash receiving and supplying equipment, drying equipment, crushing equipment, reaction equipment, and the like.

  Japanese Patent Laid-Open No. 2001-253735 (Patent Document 3) discloses an incineration residue in which a coarse substance removal process using a sieve, a magnetic substance removal process for removing a magnetic substance, a grinding process using a ball mill, and a drying process are combined in order. A method for producing a special cement using a municipal waste incineration residue as a main raw material with a treatment process is described.

Now, a conventional incineration ash treatment system considered to be closest to the present invention will be described. The treatment system has been actually used in the field, and is constructed by combining a crusher, a magnetic separator, and a sieving machine. FIG. 2 shows a flow of the processing system. Incineration ash (burnt) of industrial waste discharged from a rotary kiln type incinerator is first cooled by a contact cooler. Thereafter, the incinerated ash is introduced into the first sieving machine and divided into a sieve top and a sieve under an opening of 8 mm. At this time, if the weight of the introduced incineration ash is 300 t / month, typically, the sieve top was 200 t / month and the sieve bottom was 100 t / month. The sieve is acceptable by cement manufacturers and is recycled as cement raw material. On the other hand, the sieve top is sent to a crusher and crushed. Next, the crushed incineration ash is introduced into a magnetic separator, and magnetic materials such as iron are separated. At this time, the magnetic material was typically 30 t / month and the balance was 170 t / month. The separated magnetic material can be recycled as shredder iron. Thereafter, the remainder is introduced into a second sieving machine, and the mesh is divided into an upper part and a lower part with an opening of 12 mm. At this time, typically, the sieve was 70 t / month and the sieve was 100 t / month. The sieve is acceptable by cement manufacturers and is recycled as cement raw material. On the other hand, small incinerated ash and non-magnetic metal are mixed on the sieve, so it cannot be recycled as a cement raw material and is landfilled.
JP 2006-167513 A JP 2001-129511 A JP 2001-253735 A

  As described above, since the processing system that has been used in the past requires a considerable proportion of landfill disposal, development of an incineration ash processing system with a higher recycling rate is desired. Therefore, this invention makes it a subject to provide the system which can process the incineration ash discharged when incinerating industrial waste with a higher recycle rate.

The present inventor has intensively studied to overcome the above-mentioned problems, and found that the dry ball mill is useful for the separation of the mixed metal mainly from non-ferrous metals and the cement raw material. That is, when the incinerated ash after crushing and magnetic separation is put into a dry ball mill and pulverized, components useful as cement raw materials such as Fe ₂ O ₃ , CaO, Al ₂ O ₃ and SiO ₂ are soft and fine. It has been found that components such as Fe, Cr, Ni, and Cu that can be pulverized and recyclable as a mixed metal are hard and thus can be well separated because they are pulverized only to a certain degree.
And it was found that the separation operation can be easily performed by installing a double-structure sieve at the ball mill discharge port, instead of separately injecting the incinerated ash discharged from the ball mill into the sieving machine. .

  Accordingly, in one aspect, the present invention provides a crusher for crushing incinerated ash, a magnetic separator for separating iron and other magnetic materials from the incinerated ash crushed by the crusher, and a magnetic separator for separating magnetic materials. An industrial waste incineration ash treatment system comprising a dry ball mill for further pulverizing the incinerated ash after the ashing, wherein the ball mill is provided with an inner screen and an outer screen overlaid on the outlet, The sieve has a sieve that can separate the object to be crushed from the grinding medium, the outer sieve is smaller than the sieve of the inner sieve, and can discharge only the object to be crushed having a predetermined size or less. The outer sieve can be attached and detached so that the outer sieve cannot pass through the inner sieve but the inner sieve can pass through after the article to be crushed having a predetermined size or less is discharged. Incineration ash treatment system

  In one embodiment of the incineration ash treatment system according to the present invention, the mesh size of the outer sieve provided in the discharge port of the ball mill is 5 to 12 mm.

  In yet another embodiment of the incineration ash treatment system according to the present invention, a sieving machine is further provided in the subsequent stage of the dry ball mill after the magnetic separator. The sieving machine classifies the incinerated ash after the magnetic material is separated by a magnetic separator, and the incinerated ash classified on the sieve by the sieving machine is put into a dry ball mill.

  In still another embodiment of the incineration ash treatment system according to the present invention, the mesh size of the sieve of the sieving machine is 12 mm or less.

  In still another embodiment of the incineration ash treatment system according to the present invention, the opening size of the outer screen provided at the discharge port of the ball mill is 8 mm, and the opening size of the sieving machine is 12 mm.

  In another embodiment of the incineration ash treatment system according to the present invention, the diameter of the ball as the grinding medium is 30 to 120 mm.

  In yet another embodiment of the incineration ash treatment system according to the present invention, the incineration ash discharged from the incinerator is input to the crusher without passing through the sieving machine.

  Further, in another aspect of the present invention, a first step of crushing the incinerated ash, a second step of separating the crushed incinerated ash into a magnetic material and a nonmagnetic material, and discharging the magnetic material out of the system, A third step of introducing the magnetic material into the dry ball mill described above, a fourth step of discharging the pulverized material that can pass through the outer sieve while the ball mill is operating for a predetermined time, or a fifth step of removing the outer sieve; And a sixth step of discharging the pulverized material that cannot pass through the outer screen while operating the ball mill for a predetermined time or after operation, but passes through the inner screen.

  In one embodiment of the incineration ash treatment method according to the present invention, between the second step and the third step, the non-magnetic material is sieved and the sieve is discharged out of the system, and the sieve is introduced into a dry ball mill. The method further includes the step of:

  In one embodiment of the incinerated ash treatment method according to the present invention, the operation time of the ball mill in the fourth step is 15 to 30 hours.

  In another embodiment of the incinerated ash treatment method according to the present invention, the operation time of the ball mill in the sixth step is 0.1 to 3 hours.

  In another embodiment of the incinerated ash treatment method according to the present invention, the rotational speed of the ball mill in the fourth and sixth steps is 10 to 40 rpm.

  According to the present invention, it is possible to improve the recycling rate of incineration ash. Furthermore, the present invention saves landfill costs and is economically advantageous because shredder iron and mixed metal can be sold.

Industrial waste covered by the present invention Burnable, dirty, waste oil, waste acid, waste alkali, waste plastic, paper waste, wood waste, textile waste, animal and plant residue, rubber waste, metal waste In addition to ordinary industrial waste such as glass / ceramic scraps, slag, construction waste, and dust, medical waste is also included. Among these, wastes that are mixed with non-ferrous metals can be incinerated without pretreatment, so that waste that tends to coexist with non-ferrous metals such as waste oil, waste plastic, wood scraps, and metal scraps can be mixed. It can be suitably processed. In other words, it is possible to separate waste oil, waste plastic, wood scraps and metal scraps remaining in non-ferrous containers into each material by pretreatment, but it does not have high added value like precious metals. On the other hand, pre-processing leads to high costs and complicated processing steps. However, if the present invention is used, such industrial waste may be put into an incinerator as it is, and valuable materials can be easily separated and recovered. Therefore, for example, even if a small medical device or a small analytical device is not disassembled and is directly put into an incinerator, it is possible to separate and recover valuable materials.

Those properties of ash depending on the type of incinerator for processing incinerator industrial waste will vary slightly but, ash introduced into the ash processing system according to the present invention, which is discharged from any known incinerators It's okay. For example, incineration ash discharged from stalker furnaces, fluidized bed furnaces, or kiln furnaces can be processed, and incineration ash discharged from rotary kilns can be suitably processed because coarse waste can be directly incinerated. It is. In addition, in order to directly incinerate coarse and complex waste as it is, it is preferable that the operating conditions of the rotary kiln are high temperature combustion and low speed rotation.

Regarding the industrial waste to be introduced into the incinerator, deliberately useful ingredient as a cement raw material, _{i.e., Fe 2 O 3, CaO,} Al 2 O 3, with a ratio of those containing a large amount of such SiO ₂ (e.g. Fe ₂ O ₃ + SiO ₂ in a total of 25 to 45% by weight) and a low chlorine ratio (for example, less than 0.6% by weight) are more suitable as a cement raw material.

Ash from crusher incinerator just been discharged through the contact cooler, many things coarse, also has mixed various components, since some are linked to each other by melting, after step It is preferable to crush in order to increase the separation efficiency in the process or to reduce the burden on the ball mill. In the crusher, the incinerated ash is usually crushed to a size of approximately 30 to 100 mm, and preferably crushed to a size of 30 to 50 mm. There is no particular limitation on the crusher to be used. For example, a uniaxial crusher, a biaxial crusher, a triaxial crusher, or a four-axis crusher can be used, but iron and non-ferrous metals are mixed. Therefore, it is preferable to use a vertical high-speed shear crusher.

Magnetic separator A magnetic separator is used to separate magnetic substances such as iron from the incinerated ash that has passed through the crusher. The reason why the magnetic separator is installed in the subsequent stage of the crusher is that it cannot be sold if the incinerated ash adheres to the iron and non-ferrous metal after incineration. Therefore, after removing the incineration ash by crushing in advance, it is classified into iron and others by a magnetic separator. Any known magnetic separator may be used. For example, a permanent magnet type or an electromagnetic type magnetic separator can be used, and an electromagnet-type suspended magnetic separator can be preferably used.

The dry ball mill ball mill plays a role of separating the cement raw material contained in the incinerated ash and the difference in hardness of the mixed metal. When the incinerated ash after separating the magnetic material is introduced into a dry ball mill and the ball mill is operated, the cement raw material is soft and pulverized finely, but the mixed metal is hard and pulverized only to a certain extent. Therefore, if the incinerated ash of a certain size or more is sieved after pulverization, the cement raw material and mixed metal (mainly non-ferrous metal, but also iron that could not be removed by the magnetic separator) are efficiently It will be sorted out.

In the present invention, a dry ball mill is employed because of the limitation of moisture content as a cement raw material and the problem of freezing in winter. As long as it is a dry ball mill, either a horizontal axis type or a vertical axis type may be used. Moreover, although a continuous type and a batch type may be used, industrially a continuous type is preferable.
However, the ball mill used in the present invention is a so-called great discharge type ball mill in which a lattice (grate) is provided at the discharge port. In addition, an inner sieve (inner grate) and an outer sieve (outer grate) are overlapped at the discharge port, and the inner sieve has a shape and size that can separate the object to be crushed from the grinding medium. Have The outer screen has a screen having a shape and a size that are smaller than the screen of the inner screen and can discharge only the object to be crushed having a predetermined size or less. Further, the outer sieve can be attached and detached so that the crushed object that cannot pass through the outer sieve but can pass through the inner sieve after the crushed article having a predetermined size or less is discharged.
Here, “the outer screen is removable” is not limited to the case where the outer screen is completely separated from the ball mill. It can be said that the outer sieve is “detachable” in all cases where the inner sieve can be exposed or covered by the movement of the outer sieve. For example, a method of bolting the outer screen to the ball mill body in order to prevent it from coming off easily can be mentioned.

  The position of the discharge port is not particularly limited as long as the object to be crushed can be discharged, but the position where the object to be crushed can be continuously discharged during operation of the ball mill, for example, a mill (drum) body in the case of a horizontal axis ball mill. It is usually installed in the center. The discharge port rotates together with the drum as the ball mill rotates, and when the discharge port faces downward, the object to be crushed is discharged by gravity. At this time, it is preferable to cover the periphery of the drum with a dust-proof cover in order to prevent the object to be crushed from scattering. What is necessary is just to set the magnitude | size of a discharge port suitably with processing amount. FIG. 3 exemplarily shows the positional relationship between the discharge port and the double-structured sieve provided in the discharge port. FIG. 4 shows these positional relationships from the cross section of the mill.

According to the examination results of the present inventors, when classifying the incinerated ash crushed by the ball mill with the outer sieve, the mesh size of the outer sieve is 5 to 12 mm, preferably 6 to 10 mm, more preferably It was found that the cement raw material and the mixed metal are separated with high efficiency when the thickness is 7 to 9 mm, most preferably 8 mm.
Therefore, in one embodiment of the incineration ash treatment system according to the present invention, the opening size of the outer sieve installed at the discharge port of the ball mill is 5 to 12 mm, preferably 6 to 10 mm, more preferably 7 to 9 mm. Preferably it is 8 mm.

  In the present invention, in principle, the aperture size indicates the length of one side of a square formed by each sieve mesh. However, in the present invention, the shape of the mesh is not limited to a square, and may be, for example, a rectangle, a diamond, or a circle. Therefore, in the present invention, when the opening dimension is defined as xmm, it means that the sieve has a sieve having substantially the same sieving characteristics as a sieve having an opening dimension xmm according to JIS Z8801-1. To do.

  If the mesh size of the inner sieve is too large, the pulverization medium will fall, and it is necessary that the mesh size be small enough that the pulverization medium cannot pass through. On the other hand, as the mesh size of the inner screen is reduced, the amount of incinerated ash remaining in the ball mill without being discharged from the ball mill increases. Except for the abnormally large incineration ash, it is desirable that the incineration ash charged into the ball mill does not remain in the ball mill. Therefore, the mesh of the inner sieve is not particularly limited as long as it has a shape and size that cannot pass the pulverization medium and allow the pulverized incineration ash to pass through. Such shapes include, but are not limited to, circular shapes such as perfect circles and ellipses; square shapes such as squares, rectangles, rhombuses, and parallelograms. The dimensions may be appropriately set according to the selected shape so that the spherical grinding medium does not pass through the holes formed by one sieve mesh. For example, if the shape of the sieve mesh is a perfect circle, the diameter may be made smaller than the diameter of the ball, and if it is a rectangle, at least the short side may be made smaller than the diameter of the ball.

  The inventor of the present invention is effective for pulverizing the incineration ash, although it depends on the size of the incineration ash charged into the ball mill, the diameter of the ball as the pulverization medium is 30 to 120 mm, preferably 50 to 100 mm. I found it empirically. Therefore, in another embodiment of the incineration ash treatment system according to the present invention, the diameter of the ball as the grinding medium is 30 to 120 mm, preferably 50 to 100 mm. Further, balls having different diameters may be mixed in the same ball mill. Thereby, crushing and crushing can be performed simultaneously.

  An example of a specific operation method of the ball mill will be given. Incineration ash is introduced into a dry ball mill. Incineration ash can be introduced while the ball mill is operating. An object to be crushed that can pass through the outer sieve is discharged while the ball mill is operated for a predetermined time or after the operation (first operation). The ball mill is then stopped and the outer screen is removed to expose the inner screen. While the ball mill is operated again for a predetermined time or after the operation, the material to be crushed which cannot pass through the outer screen but can pass through the inner screen is discharged (second operation). It is convenient to discharge the object to be crushed while the mill is operating.

  Depending on the amount of incineration ash and the size of the mill, the operation time of the ball mill in the first operation is generally 15-30 hours, typically 20-25 hours, more typically 22- 24 hours. Further, the operation time of the ball mill in the second operation is 0.1 to 3 hours, typically 0.3 to 2 hours, and more typically 0.5 to 1.5 hours. The rotation speed of the ball mill is generally 10 to 40 rpm, typically 15 to 30 rpm, and more typically 17 to 25 rpm.

The incineration ash that has passed through the crusher installed upstream of the sieving machine contains a high proportion of incineration ash that can be taken up by a cement manufacturer without being further pulverized by a ball mill. In many cases, it is useless to put the entire amount of incinerated ash that has passed through the machine into the ball mill. Therefore, it is preferable to preliminarily separate fine incinerated ash that can be taken up by a cement maker with a sieving machine before being put into the ball mill.
Therefore, in still another embodiment of the incineration ash treatment system according to the present invention, a sieving machine for classifying the incineration ash after separating the magnetic material by the magnetic separator is installed in the front stage of the dry ball mill.

  The incineration ash that can be taken from the incineration ash as a cement raw material by a cement maker is approximately 12 mm or less in size, and it is efficient to separate all of these in advance. Accordingly, the sieving machine preferably has an opening size of 12 mm or less, more preferably has an opening size of 10 to 12 mm, and most preferably has an opening size of 12 mm. In addition, from the past results, even the mixed metal does not pass through the sieve having an opening size of 12 mm together with the cement raw material, and if any, it is slight.

  In addition, the incineration ash that comes out of the incinerator through the contact cooler contains incineration ash that can be taken by the cement manufacturer without passing through the crusher. May be used to separate fine incineration ash that can be taken up by a cement manufacturer in advance. However, the sieving at the upstream stage is severe enough to deteriorate the working environment due to dust generation, and although it is possible to improve the working environment by installing a dust collecting device, it is not necessarily a preferable form. Therefore, in still another embodiment of the incineration ash treatment system according to the present invention, the incineration ash discharged from the incinerator is input to the crusher without passing through the sieving machine.

Incineration ash treatment system A preferred embodiment of the incineration ash treatment system according to the present invention will be described below with reference to FIG.
The processing system is constructed by combining a crusher, a magnetic separator, a sieving machine, and a dry ball mill. In each process, local dust collection is appropriately performed to prevent dust (eg, bag filter). FIG. 1 shows a flow of the processing system. Incineration ash (burnt) of industrial waste discharged from a rotary kiln type incinerator is first cooled by a contact cooler. Thereafter, the incinerated ash is introduced into a crusher and crushed. Next, the crushed incineration ash is introduced into a magnetic separator, and magnetic materials such as iron are separated. The separated magnetic material can be recycled as shredder iron. Thereafter, the remainder is introduced into a sieving machine and divided into a sieve top and a sieve under an opening of 12 mm. The sieve is acceptable by cement manufacturers and is recycled as cement raw material. On the other hand, the top of the sieve is introduced into a dry ball mill, pulverized for a sufficient time, and then the small incinerated ash that can pass through the outer sieve (mesh size 8 mm) is discharged. After discharging the small incineration ash, the outer sieve is removed, and the medium and large incineration ash that can pass through the inner sieve (20 × 300 mm rectangular sieve mesh) is discharged to another tray. Small incineration ash is acceptable by cement manufacturers and is recycled as cement raw material. On the other hand, medium and large incineration ash can be sold as mixed metal.

  Of course, in actual operation, the separation of incinerated ash in each process cannot always be performed at a separation rate of 100%. Therefore, although the shredder iron and the mixed metal discharged from the system are not necessarily high-quality ones, it is possible to receive 100% by a recycler. Therefore, the landfill cost of incineration ash can be significantly reduced. The shredder iron and mixed metal collected by the recycler will be further refined by the recycler.

  The conditions and results when the incineration ash treatment system shown in FIG. 1 is actually operated are shown.

Conditions <Industrial waste thrown into incinerator>
Sludge: 500 t / month Waste oil: 600 t / month Waste plastic: 400 t / month Metallic waste: 50 t / month <Incinerator>
Method: Rotary kiln type Processing capacity: 120t / day Rotation speed: 0.05 ~ 0.27rpm
<Incineration ash generated from the incinerator>
Total: 300t / month <crusher>
Manufacturer: Kubota Corporation Model: KE-400
Method: vertical shear Processing capacity: 1-2t / h
Electric motor: 150kw x 2 units <sieving machine>
Manufacturer: Sugawara Machinery Co., Ltd.
Model: ML-510
Method: Sealed sieving equipment Processing capacity: 30t / h
Aperture: 12mm (the sieve mesh is square)
<Ball mill>
Manufacturer: Makino Co., Ltd. System: Dry, horizontal axis, continuous Ball dimensions: 50mm and 100mm mixed in half Mill dimensions: 900mm diameter x 1800mm body length Rotation speed: 20rpm
Power: 11kw x 50Hz x 6P
Discharge port position: As shown in FIG. 3 Inner screen: 20 × 300 mm rectangular screen Outer screen: Opening 8 mm (screen is square)
Processing capacity: 0.33m ³
Processing capacity: 0.5t / h

  The ball mill was operated continuously for 23 hours while the material to be ground was charged over 12 hours. Meanwhile, the object to be crushed under 8 mm passes through the inner and outer sieves and is gradually discharged. Thereafter, the outer sieve is removed, the inner sieve is exposed, and the inner sieve is continuously operated for 1 hour, during which all the objects to be crushed that are over 8 mm are discharged.

Mass balance The numerical value in parentheses shown in Fig. 1 is the mass balance when incineration ash 300t / month is processed by this system. Of the 300 tons / month of incinerated ash, 30 tons / month was first recovered as shredder iron by a magnetic separator. The non-magnetic content not separated by the magnetic separator was 270 t / month. As a result of dividing the non-magnetic content into those with 12 mm under and 12 mm over with a sieving machine, those with 12 mm under were 160 t / month and could be recovered as cement raw materials. The thing over 12 mm thrown into the dry ball mill was 110 t / month. Of the 110 t / month charged into the dry ball mill, 100 t / month was pulverized to an under 8 mm, and could be recovered as a cement raw material. The remainder was 10 t / month and could be recovered as mixed metal.
In summary, 300 tons / month of incinerated ash could be separated into 260 tons / month of cement raw material, 30 tons / month of shredder iron, and 10 tons / month of mixed metal. All of these could be picked up by a recycler and no landfill was needed.

Properties of fractions During operation of this system, non-magnetic content after passing through the magnetic separator, 12mm over content classified on the screen by the sieving machine, 8mm under content and 8mm over content discharged from the dry ball mill Sampling and component analysis were performed. Table 1 shows the analysis results. Thereby, it can be understood that the cement raw material and the mixed metal can be separated with high efficiency by the dry ball mill.

It is a flowchart of the incineration ash processing system concerning the present invention. It is a flowchart of the conventional incineration ash processing system. It is a schematic diagram which shows the positional relationship of the discharge port of a ball mill, an outer side sieve, and an inner side sieve. It is a schematic sectional drawing of a mill body.

Explanation of symbols

11 Incinerated ash 12 Mill 13 Inner screen 14 Outer screen 15 Dust-proof cover 16 Drain port 17 Dish 18 Shattered incineration ash

Claims (12)

  A crusher for crushing the incinerated ash, a magnetic separator for separating the magnetic material from the incinerated ash crushed by the crusher, and a dry type for further crushing the incinerated ash after separating the magnetic material by the magnetic separator An incineration ash treatment system for industrial waste comprising a ball mill, wherein the ball mill is provided with an inner sieve and an outer sieve overlaid at the discharge port, and the inner sieve separates the material to be crushed from the grinding media The outer screen has a screen smaller than the screen of the inner screen and can discharge only the object to be crushed having a predetermined size or less, and the predetermined size An incineration ash treatment system in which the outer sieve is removable so that the outer sieve cannot pass after the following crushed materials are discharged but the inner sieve can pass the crushed materials that can pass through.   A sieving machine is further provided at the stage after the magnetic separator and before the dry-type ball mill. The incineration ash treatment system according to claim 1 put into a ball mill.   The incineration ash treatment system according to claim 1 or 2, wherein the opening size of the outer sieve provided in the discharge port of the ball mill is 5 to 12 mm.   The incineration ash treatment system according to claim 2 or 3, wherein the sieve mesh size of the sieving machine is 12 mm or less.   The incineration ash treatment system according to claim 2, wherein the mesh size of the outer sieve provided at the discharge port of the ball mill is 8 mm, and the mesh size of the sieve of the sieving machine is 12 mm.   The incinerated ash treatment system according to any one of claims 1 to 5, wherein a diameter of a ball as a grinding medium is 30 to 120 mm.   The incineration ash treatment system according to any one of claims 1 to 6, wherein the incineration ash discharged from the incinerator is fed into a crusher without passing through a sieving machine.   A first step of crushing the incinerated ash, a second step of separating the crushed incinerated ash into a magnetic material and a non-magnetic material, and discharging the magnetic material out of the system, and a dry ball mill that specifies the non-magnetic material in claim 1 A third step to be introduced into the fourth step, a fourth step for discharging the pulverized material that can pass through the outer sieve while the ball mill is operated for a predetermined time, a fifth step for removing the outer sieve, and the ball mill being operated for a predetermined time. Incineration ash treatment method for industrial waste, which includes a sixth step of discharging the pulverized material that cannot pass through the outer screen but can pass through the inner screen while operating or after operation.   The incinerated ash treatment method according to claim 8, further comprising a step of sieving the non-magnetic material between the second step and the third step, discharging the under-sieving out of the system, and introducing the top of the sieve into a dry ball mill.   The incinerated ash treatment method according to claim 8 or 9, wherein the operation time of the ball mill in the fourth step is 15 to 30 hours.   The incineration ash treatment method according to any one of claims 8 to 10, wherein the operation time of the ball mill in the sixth step is 0.1 to 3 hours.   The incineration ash treatment method according to any one of claims 8 to 11, wherein a rotation speed of the ball mill in the fourth step and the sixth step is 10 to 40 rpm.

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