JP3783146B2 - Self-burning fuel rods using ash body - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention is discharged from incineration ash discharged by incineration of various industrial waste, municipal waste, sewage sludge (drainage sludge, dewatered cake), and a dust collector newly defined as general waste. The present invention relates to a self-fueling (natural) fuel rod containing various ash bodies (hereinafter, sometimes referred to as various ash bodies or simply ash bodies) made of collected dust ash.
In the present invention, the ash body is interpreted in the broadest sense as including not only the ash body discharged from the incineration facility but also an incombustible residue contained in the ash body or an ash body analog. Should be.
[0002]
More specifically, the present invention constitutes a self-combustible fuel rod using the ash body, and at the time of combustion, the ash body is melted and solidified at an ultra-high temperature to reduce pollution, reduce the volume, and reuse the ash body. The present invention relates to a self-combustible fuel rod containing a novel ash body that can be realized.
[0003]
[Prior art]
Conventionally, from incineration ash discharged by incineration of various industrial waste, municipal waste, sewage sludge (dehydrated sludge, dehydrated cake), etc., or recently from various dust collectors newly defined as general industrial products Various ash bodies such as dust ash discharged (this is also called fly ash) are enormous.
[0004]
Therefore, even if these ash bodies are landfilled at the waste landfill site, it is becoming increasingly difficult to secure the landfill site. For this reason, since it is difficult to secure a landfill site, for example, sewage sludge is dehydrated, incinerated, and reduced in volume.
Moreover, in the various ash bodies described above, when harmful substances such as heavy metals are mixed, scattering of these harmful substances to the outside world or remaining in the incinerated ash is a problem.
[0005]
[Problems to be solved by the invention]
Due to the above quantitative problems of various ash bodies or the problem of containing toxic substances such as heavy metals, these ash bodies are incinerated using a desired incineration facility to reduce the volume of the toxic substances. Many proposals have been made for melting and solidifying (pollution-free) and reusing resources.
[0006]
As the ash body incinerator described above, an electric melting furnace, a burner melting furnace, a plasma melting furnace, an arc melting furnace or the like is known.
[0007]
However, as is apparent from the structure of the incinerator for ash bodies described above, the conventional incineration technique for melting and solidifying ash bodies has the following problems.
(1). A large amount of energy is consumed to melt the incineration ash.
In this respect, in the plasma melting and arc melting described above, the amount of electric power used is about 650 kw / t. In burner melting, it is necessary to secure a large amount of kerosene, heavy oil, etc. as fuel.
[0008]
(2). Incineration facilities are expensive and large.
For example, since the ash body is melted at a high temperature, the refractory bricks in the incinerator are severely corroded and the heat resistance is deteriorated, and two or more parallel operations are required for connected and stable operation.
[0009]
Here, the advantages of the self-combustible fuel rod of the present invention will be described in advance.
Although the self-combustible fuel rod of the present invention will be described in detail later, the fuel rod can be burnt and melted in a space, melted, or in other words, burned and melted without contact with the components of the furnace in the incinerator. (This can be called a contactless combustion and melting method), and the above-mentioned drawbacks are completely eliminated. When the fuel rods are melted, various ash bodies in the fuel rods are also melted and subsequently solidified (slag).
That is, the melt solidification method of various ash bodies employing the self-combustible fuel rod of the present invention,
(i) Various ash bodies are constituents of self-combustible fuel rods,
(ii) The natural fuel rod can be burned and melted in a contactless manner,
In view of this, the above-mentioned drawbacks of the prior art are completely eliminated.
Needless to say, in order to realize the above-described advantages of the present invention, as a fuel rod having self-combustion characteristics, as will be described in detail later, each component is uniformly mixed, kneaded, and solidified. It is important to take the form of a fuel rod.
[0010]
[Problems to be solved by the invention]
The present invention seeks to overcome the limitations and problems found in the conventional techniques for reducing the volume, eliminating pollution, and reusing various types of ash bodies, and in particular, the method for melting and solidifying ash bodies.
The present inventors have intensively studied an effective and economical method for melting and solidifying ashes. As a result, in order to completely detoxify the ash body, the present inventors preferably melt and solidify at a higher temperature than in the prior art, and It has been found that it is preferable to apply the thermit process in order to realize the melting conditions in the above.
[0011]
The thermite method is a well-known technique that is used in the production of metals by reducing the oxides using the intense exothermic reaction that occurs between aluminum and metal oxides such as iron oxide, and for the welding of steel materials. It is.
The present inventors use the thermite method for melting and solidifying the various ash bodies,
(i). The aluminum used as a raw material is abundant in the form of an aluminum can and can be used easily.
(ii). Metal oxides such as iron oxide as raw materials are used as industrial waste when producing titanium oxide (TiO ₂ ) from natural ilmenite ore, and as high-purity industrial waste. Can be used effectively, and
(iii) The metal oxide is abundant in various ash bodies themselves,
From the viewpoint of such, it is considered extremely economical and resource-saving.
[0012]
That is, as described above, the present inventor found that the ash body was melted and solidified by the thermite reactant (aluminum and metal oxide) as described above. Since it is intended for resource recycling, it is considered to be an extremely effective method from the viewpoint of industrial waste disposal and pollution control.
[0013]
The present invention has been completed based on the findings of the inventors.
According to the present invention, various ash bodies such as incineration ash and dust collection ash (fly ash), which are increasingly difficult to treat as industrial waste, can be efficiently and economically reduced in volume, pollution-free, and recycled. There is provided a self-combustible fuel rod using the ash body that can be converted into an ash body.
[0014]
And the solid self-combustible fuel rods containing various ash bodies of the present invention are reduced in volume of the ash bodies, non-polluting, by a simple method of burning in a desired combustion furnace in a desired combustion furnace, Recycling can be achieved.
At that time, the melting and solidifying agent for melting and solidifying the ash body is composed of a thermite reactant such as aluminum or iron oxide, which is an industrial waste. Therefore, the self-combustible fuel rod of the present invention treats various ash bodies. In addition, it is also effective in the treatment and recycling of industrial waste of aluminum and metal oxides.
[0015]
[Means for Solving the Problems]
Briefly, the present invention uses a solid ash body prepared by mixing an ash body composed of incinerated ash and / or dust collection ash, an aluminum powder, a metal oxide powder, and a combustible medium. This relates to a self-combustible fuel rod.
[0016]
The technical configuration and embodiments of the present invention will be described in detail below.
[0017]
The present invention relates to a self-combustible fuel rod used for melting and solidifying various ash bodies simultaneously with combustion as described above.
The self-combustible fuel rod of the present invention is
(i). Various ash bodies are essential components of fuel rods,
(ii). a thermite reactant as an essential component for melting the ash body at a high temperature, and
(iii) A combustible medium for fixing the above components (i) to (ii) to each other, solidifying and sticking them as an essential component,
It is composed.
[0018]
As is well known, the thermit process generally mixes aluminum powder and metal oxide, as shown by the following equation, and when ignited, a vigorous exothermic reaction occurs, the metal oxide is reduced, The generated metal is a reaction phenomenon in which it is melted and recovered at the bottom of the reactor due to high temperature.
2Al + 3/2 · O ₂ = Al ₂ O ₃ +386.2 Kcal
[0019]
More specifically, in the case of Al powder and iron oxide (Fe ₃ O ₄ ) powder, when these powders are mixed and ignited (about 1100 ° C. to 1150 ° C.), the thermite reaction proceeds according to the following formula (1): At that time, a high temperature of 2750 ° C. or higher is obtained.
8Al + 3Fe ₃ O ₄ = 9Fe + 4Al ₂ O ₃ (1)
[0020]
The high temperature generated by the thermite reaction between the Al powder represented by the above formula (1) and the iron oxide (Fe ₃ O ₄ ) powder is 2750 ° C. or higher, such as conventional burner melting, plasma melting, or arc melting. In comparison, the temperature is extremely high.
For this reason, as a combustion method of the self-combustible fuel containing the above-mentioned various ash bodies and containing the thermite reactant, a method of burning in a non-contact state to a component of a combustion furnace, for example, a refractory brick, at the time of combustion Is preferred.
This is because in the thermite reaction, extremely high reaction heat is generated as described above, and the durability and fire resistance of the combustion furnace are reduced in a short time.
[0021]
In order to ensure that the ash body is melted by non-contact combustion of the fuel rod in the combustion furnace in consideration of the above points, the present invention, in other words, the space of the ash body due to the combustion of the fuel rod. In order to ensure melting, the form of the fuel rod is a solid rod. By using the solid and rod-shaped fuel rod described above, the ash body can be melted by the high reaction heat at the time of combustion of the thermite reactant at the tip of the cantilevered combustion rod. That is, various ash bodies can be spatially melted.
[0022]
According to the present invention, in order to burn the fuel rods in a contactless manner in the above-described combustion furnace, the ash body and the thermite reactant are fixed to each other using a combustible medium to form a solid rod-like body. Adopting technical composition.
In the present invention, the advantage of using the flammable medium has other important significance in addition to keeping the fuel rod in a solid and rod shape.
As described above, the melting and solidification of various ash bodies by the natural fuel rod of the present invention is mainly performed by the reaction heat of the thermite reactant.
Needless to say, it is preferable that the thermite reactant reacts in a connected (continuous) manner by one ignition and thereafter due to its self-combustibility.
[0023]
In order to detoxify various ash bodies containing harmful substances such as heavy metal substances, it is important to completely melt and solidify (slag). For this reason, it is essential that the combustion reaction of the thermite reactant is performed uniformly.
However, in the mixture of aluminum powder of thermite reactant and metal oxide powder such as iron oxide, it cannot be avoided that there is a region of non-uniform mixing in microscopic view. In the above-described region, the ash body is not necessarily completely melted.
For this reason, the present invention uses the combustible medium in order to ensure uniform combustion of the fuel rods, and this point is extremely important.
[0024]
In order to prepare the fuel rod for ensuring the above-mentioned purpose, that is, the combustion of the contactless medium, and to support the complete combustion, in the present invention, the use of the combustible medium is an indispensable component.
As the flammable medium described above, a flammable medium such as a natural mineral oil-based material, a synthetic oil-based material, or plastic waste can be used.
More specifically, natural mineral oil-based materials such as heavy oil, kerosene, lubricating oil, and waste oil, or synthetic oil-based materials such as esters and low molecular weight polymers (polyethylene wax, etc.) can be used. Furthermore, plastic waste (separated and collected plastic pellets, etc.) can be used as a flammable medium.
The combustible medium of the present invention is not limited to the above-described one as long as the ash body and the thermite reactant can be fixed to each other to form a solid rod-shaped body.
[0025]
It goes without saying that the self-combustible fuel rod of the present invention may contain other compounding components such as a thermite reaction accelerator (sulfide, chloride, etc.) and an ignition agent (barium peroxide and aluminum powder, etc.). It is not.
[0026]
In the present invention, the use ratio of each component of the self-combustible fuel rod may be set as desired.
The mixing weight ratio of the thermite reactant, that is, the aluminum powder and the metal oxide powder may be generally set to 1: 2 to 1: 4.
When the aluminum powder and the metal oxide powder are referred to as a melt-solidifying agent, the mixing weight ratio of the melt-solidifying agent and the ash is generally set to 1: 1 to 1: 4.
Furthermore, when aluminum powder and metal oxide powder are referred to as a melt-solidifying agent, the mixing weight ratio of the melt-solidifying agent, the ash body, and the combustible medium is generally from 2: 2: 1 to 1 based on the combustible medium. It may be set to 2: 8: 1.
[0027]
The production mode and combustion mode of the self-combustible fuel rod of the present invention may be selected as desired.
For example, a desired number of self-combustible fuel rods are manufactured in advance, and are installed in a desired combustion furnace so that the desired number and non-contact combustion can be performed, and each fuel rod is sent out in synchronization with the combustion speed. And burn it.
Alternatively, a method may be employed in which the fuel rods are supplied to a combustion furnace disposed adjacent to the fuel rod manufacturing apparatus and burned at the same time as the self-burning fuel rods are manufactured.
[0028]
In the present invention, the self-combustible fuel rod is ignited by the thermite reactant and a combustion reaction is induced in the desired combustion furnace and self-combusts, and the ash body is melted at a high temperature and spontaneously falls to the lower part of the combustion furnace. To do.
The melt described above is rapidly cooled and granulated with cooling water to form glassy granulated slag (solidified product), or air-cooled to form air-cooled slag (crystallized slag).
[0029]
The above-mentioned melted and solidified material can be reused as a concrete aggregate or fine aggregate, a cushion material for sewer construction, a roadbed material, a road paving block material, a water permeable block material, or the like.
[0030]
Hereinafter, a method for producing the self-combustible fuel rod of the present invention and a method for simultaneously burning the produced self-combustible fuel rod will be described with reference to the drawings.
FIG. 1 is a diagram for explaining an incineration ash and / or dust collection ash treatment apparatus (A) for simultaneously performing combustion treatment along with the production of the self-combustible fuel rod.
In addition, the aspect of manufacture and processing of the self-combustible fuel rod of the present invention is not limited to the illustrated one, and it goes without saying that various modifications are possible.
[0031]
As shown in the figure, the incineration ash and / or dust collection ash treatment apparatus (A) is roughly composed of the following four components.
(i). Raw material dehydration and mixing machine (B)
In the present invention, the raw material is a raw material for producing a self-combustible fuel rod, and more specifically, various ash bodies, thermite reactant (aluminum powder and metal oxide powder), and combustible as described above. The medium is an essential component.
In the present invention, it goes without saying that other components such as a thermite reaction accelerator may be used if desired.
(ii) Fuel rod manufacturing machine (kneading extruder) (C)
(iii) Combustion furnace (D)
(iv). Melt receiver (E)
[0032]
In FIG. 1, the self-combustible fuel rod is indicated by (1), the melt produced by combustion of the fuel rod (1) is indicated by (2), and the cooled solidified body of the melt (2) is indicated by (3). Yes.
[0033]
The raw material dehydration / mixing machine (B) includes a dehydration / mixing machine main body (B ₁ ), a heater section (B ₂ ), and various raw material supply paths (pipes) (B ₃ ).
The heater part (B ₂ ) is for removing moisture in the fuel rod (1) to be finally produced.
If the fuel rod (1) contains a large amount of water, it is extremely dangerous in the thermite reaction at high temperatures. For this reason, it is preferable that the water removal (drying) is performed also in the fuel rod manufacturing machine (C) described below.
[0034]
The fuel rod manufacturing machine (kneading extruder) (C) is disposed at the main body (1), which is gradually reduced in diameter from the large diameter portion to the small diameter portion, and at the end of the main body portion (C ₁ ). The solid and rod-shaped fuel rod extruding portion (C ₂ ) is constituted as a main component.
[0035]
FIG. 1 shows a screw (C ₁₁ ) inside the main body (C ₁ ) and a height adjuster (C ₁₂ ) outside the main body (C ₁ ) in addition to the components.
The screw (C ₁₁ ) is for kneading the raw materials sufficiently and fixing or fusing the respective raw material components to each other by a combustible medium in the reduced diameter portion (C ₂ ).
The height adjuster (C ₁₂ ) is for adjusting the angle of the tip of the fuel rod (1) with respect to an ignition device (D ₂ ) of a combustion furnace (D) described later. Thereby, the angle of the fuel rod with respect to the ignition device (D ₂ ) is set as desired.
[0036]
Further, FIG. 1 shows a storage chamber (C ₃ ) for storing the fuel rod manufacturing machine (C).
When the storage chamber (C ₃ ) is disposed, an overheating means for overheating the fuel rod manufacturing machine (C) from the outside may be disposed in the storage chamber (C ₃ ).
The superheating means in the storage chamber (4) is important for removing moisture from the fuel rod (1).
It goes without saying that the superheated means can utilize air heated to a high temperature generated in a combustion furnace (D) described later.
Although not shown in FIG. 1, it goes without saying that an internal overheating part (heater part) may be arranged in the main body part (C ₁ ) of the fuel rod manufacturing machine (D). is there.
[0037]
The combustion furnace (D) includes a combustion furnace main body (D ₁ ) and an ignition device (D ₂ ).
The combustion furnace main body (D ₁ ) shown in the figure has an inclined wall when viewed from the fuel rod (1) to the ignition device (D ₂ ), and is generated by the combustion of the fuel rod (1). It has an outlet (D ₁₁ ) for taking out the ash body melt (2) to the outside.
As shown (see the arrow indicating the direction of rotation in FIG. 1), in order to achieve uniform combustion of the fuel rod (1),
(i) The combustion furnace body (D ₁ ) is configured to be rotatable with the fuel rod (1), or
(ii) It goes without saying that the ignition device (D ₂ ) may be configured to be rotatable.
[0038]
In the present invention, the ignition device (D ₂ ) is configured to obtain an ignition temperature (for example, 1100 ° C. to 1200 ° C.) sufficient to cause combustion of the thermite reactant.
Examples ignition device (D _2), for example a burner system, a high frequency method, may be employed such as an arc method.
[0039]
In the present invention, the melt receiver (E) receives the ash body melt (2) produced by the fuel rod (1).
The ash body melt (2) is cooled and solidified (slag) between the combustion furnace (D) and the receiver (E), but is mainly solidified in the receiver (E).
As the structure of the receiver (E), the ash body melt (2) may be rapidly cooled with cooling water and granulated to obtain a glassy granulated solidified product, or while cooling ( A crystallized solidified product (air-cooled slag, crystallized slag) may be obtained while cooling slowly.
Further, the receiver (E) may be configured to recover the metal component from the melt. For example, the structure of the receiver (E) receives the melt, separates it into a low specific gravity (slag component) and a high specific gravity (metal component), and then water-cools to form a granular slag component and a granular metal. The components may be prepared, and the metal components may be separated and recovered by a magnetic separator or the like.
The ash body melt-solidified product (2) can be used for various applications such as concrete aggregates, roadbed materials, road paving block materials, etc., and may be cooled and solidified in a form suitable for these applications.
[0040]
【The invention's effect】
The present invention relates to incineration ash discharged when incinerating various industrial waste, municipal waste, sewage sludge (dehydrated sludge, dehydrated cake), etc., and dust collection ash (fly ash) newly defined as general waste ) Can be processed efficiently and economically from the viewpoints of volume reduction, pollution-free and resource reuse, and a self-combustible fuel rod containing these various ash bodies is provided.
[0041]
Needless to say, the self-combustible fuel rod of the present invention contains various ash bodies for which the above-mentioned treatment measures are urgently needed, but a fuel source for melting and solidifying the various ash bodies described above. As described above, this is also configured by using a thermite reactant (a metal oxide powder such as an aluminum powder and iron oxide) that is easily obtained from industrial waste or waste materials.
[0042]
In addition, the self-combustible fuel rod of the present invention is to ensure that the ash body is completely melted and solidified in view of the processing object being an ash body containing a hazardous substance such as heavy metal. (In other words, in order to ensure the combustion reaction of the thermite reactant), the ash body and the thermite reactant are fixed to each other, and are configured in a solid and rod shape. .
[0043]
The self-combustible fuel rod having the above-described configuration can be burned completely in a desired incinerator, in other words, the various ash bodies can be completely melted and solidified.
[0044]
In the melt-solidified product obtained from the self-combustible fuel rod of the present invention, harmful substances in the ash are completely detoxified by melting under high temperature generated under the thermite reaction.
In addition, since the solidified product obtained from the self-combustible fuel rod of the present invention is completely detoxified as described above, it is a concrete aggregate (fine aggregate), a cushion material for sewer construction, a roadbed material, a road It is reused as a paving block material and a water-permeable block material (resource reuse).
As described above, the present invention is positioned as a pollution control technique, and its social contribution and social significance are great.
[Brief description of the drawings]
FIG. 1 is a diagram for explaining an apparatus for producing and burning a self-combustible fuel rod containing incineration ash and / or dust ash according to the present invention.
[Explanation of symbols]
A ……………………………………………………………………………………………………………………………………………………………………………………… Raw material dehydration and mixing machine C …………… Fuel rod manufacturing machine D …………… Incinerator E …………… Melt receiving Container 1 ……… Fuel rod 2 …………… Melt 3 …………… Melt solidified

Claims (7)

A self-burning fuel rod using a solid ash body prepared by mixing an ash body made of incinerated ash and / or dust collection ash, an aluminum powder, a metal oxide powder, and a combustible medium. The natural fuel rod according to claim 1, wherein the aluminum powder and the metal oxide powder have a self-combustibility by a thermite reaction and a melting and solidifying ability of an ash body. 2. The self-combustible fuel rod according to claim 1, wherein the combustible medium is a solid rod-shaped body in which an ash body, an aluminum powder, and a metal oxide powder are fixed to each other. The self-combustible fuel rod according to claim 3, wherein the combustible medium is at least one selected from natural mineral oil-based materials, synthetic oil-based materials, and plastic waste. The self-combustible fuel rod according to claim 1, wherein a mixing weight ratio of the aluminum powder and the metal oxide powder is 1: 2 to 1: 4. The self-combustible fuel rod according to claim 1, wherein when the aluminum powder and the metal oxide powder are referred to as a melt-solidifying agent, the mixing weight ratio of the melt-solidifying agent and the ash body is 1: 1 to 1: 4. When aluminum powder and metal oxide powder are referred to as a melt-solidifying agent, the mixing weight ratio of the melt-solidifying agent, ash body, and combustible medium is from 2: 2: 1 to 2: 8 based on the combustible medium. The self-combustible fuel rod according to claim 1, wherein

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