JPH11278887A - Production of cement clinker - Google Patents

Abstract

PROBLEM TO BE SOLVED: To embody the non-polluting of waste gases and residues by bringing the harmful chlorine components decomposed and precipitated from the material to be treated at the time of decomposition treatment of the material to be treated and an alkaline material into catalytic reaction to form a harmless chloride and to enable the recycling of the residues made non-pollutant as secondary fuel at the time of cement clinker production together with the waste gases by subjecting the residues described above to a carbonization treatment in another treatment furnace. SOLUTION: The material to be treated and the treating agent of the alkaline material are subjected to a heat treatment in the first heat treatment furnace 10, by which the harmful chlorine component is pyrolyzed and the chlorine gas is cracked and precipitated. Simultaneously the chlorine gas is reacted with the treating agent to form the harmless chloride, by which the generated gases and the residues are made non-pollutant. Next, the material to be treated which is subjected to the non-polluting treatment is subjected to the carbonization treatment in another heat treatment furnace 20 where the halogen material- free carbide is taken out. This carbide is utilized together with the harmless waste gases as the secondary fuel of the cement clinker.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for producing a cement clinker, and more particularly, to detoxifying waste containing a large amount of halogen (chlorine, bromine, iodine) as a secondary fuel to be supplied to a cement raw material, When decomposing and separating out harmful components such as chlorine-based gas contained in the material to be treated in the decomposition reaction process, it reacts with alkaline substances and replaces them with harmless chlorides to prevent the generation of harmful dioxins. At the same time, the detoxification of the exhaust gas and the object to be treated are made harmless, and in the next step, the detoxified object is subjected to a carbonization treatment in a heating furnace different from the previous step, so that no halogen substance remains. The present invention relates to a method for producing a cement clinker in which a carbide is obtained and the carbide is used as a secondary fuel together with high-temperature exhaust gas.

[0002]

2. Description of the Related Art There are two types of cement: Portland cement using limestone and clay as main raw materials, mixed cement obtained by adding slag to this porciland cement, and special cement obtained by changing the composition and composition. In addition, silica, iron oxide and gypsum are required. The raw material is prepared by thoroughly drying the main raw material, pulverizing the raw material using a ball mill, classifying and adjusting the components to obtain a prepared raw material, and further producing the product through a firing step and a finishing step.

[0003] In the firing step, after the prepared raw material is heated to a high temperature,
This is a step of changing into a hydraulic substance by quenching with air or the like, and the mass of large grains formed here is called a cement clinker. In the finishing step, gypsum is added to the cement clinker and ground with a finishing mill to make the particle size of the powder constant, and fine powder is taken out by a rotary centrifugal classifier to complete the cement.

Conventionally, inexpensive fuels such as rubber tires, coal-containing debris, and oil sludge have been used as secondary fuels for producing cement clinker. These secondary fuels are used together with the main raw material of cement. Means are known which are supplied into a heated rotary furnace to obtain necessary combustion energy.

Japanese Patent Application Laid-Open No. Hei 6-127988 discloses that a low-cost pre-dried fuel, such as paper sludge having a water content of about 30% by weight, is charged as a secondary fuel into a rotary cylindrical furnace by exhaust gas from the furnace. In the production of cement clinker, a part of the exhaust gas from the rotary cylindrical furnace as a mainstream in a crushing and drying apparatus,
A method is described in which another part is supplied to a paper sludge drying apparatus, and exhaust gas discharged from the drying apparatus is supplied to a main stream of the exhaust gas after passing through a residual paper separator.

[0006] As described above, the conventionally used secondary fuel is used as one form of low-cost waste treatment. The obtained cement has a chlorine content of 200 pp.
m, it is usually used to sort waste having a low chlorine content and use it as a secondary fuel.

[0007] However, it is difficult to supply only waste containing no chlorine component as a secondary fuel,
The chlorine component contained in these wastes is a factor of producing highly toxic dioxins, and there is a problem that dioxins are produced especially when fuel is heated in a heating furnace.

[0008] Therefore, during the production of cement clinker, dioxins originating from the secondary fuel are produced, and these dioxins are either discharged into the atmosphere as exhaust gas or contained in the clinker. Will survive.

On the other hand, as wastes not conventionally used as secondary fuels during the production of cement clinker, there are general wastes such as municipal waste, industrial wastes, shredder dusts, and wastes such as vinyl chloride. These wastes contain a large amount of halogen substances (chlorine, bromine, iodine, fluorine, and astatine), particularly chlorine components. Therefore, when heat treatment such as incineration is performed, chlorine-based gases (hydrogen chloride gas, chlorine Gas) is generated in large quantities, and therefore cannot be used as a secondary fuel during the production of cement clinker.

[0010] These wastes are contained in treated powder used in a bag filter for the treatment of exhaust gas generated during heat treatment such as incineration, fly ash in exhaust gas, and incineration residue (incineration ash). Also, the chlorine component remains and becomes a factor of generating dioxins.

As a means for removing such harmful components, an alkaline substance (lime powder) is sprayed into the incinerator when the waste is incinerated in an incinerator, and is contacted with chlorine-based gas in the exhaust gas generated by the incineration. There is a method in which harmless chloride (calcium chloride) is produced by reacting to make the exhaust gas harmless (for example, JP-A-54-93864).

Japanese Patent Application Laid-Open No. Hei 9-155326 discloses that when an object to be treated containing a chlorine component is subjected to heat treatment, an appropriate amount of an alkaline additive which easily reacts with chlorine and a chlorine compound is mixed into the treated ash. There has been proposed a waste treatment method in which the components are effectively fixed and the treated ash is treated with water to remove chlorine from the treated ash.

[0013] These conventional technical means are intended to remove chlorine components and dioxins in a process (eg, means such as a bag filter and combustion) after the generation of a chlorine-based gas from an object to be treated. Since the chlorine component and dioxins remaining in the cement are not removed, it is difficult to extract the carbide from the residue and use it as a secondary fuel in the production of cement clinker.

Further, instead of incineration, there is also known a method in which an object to be treated is thermally decomposed (dry-distilled), and the residue after decomposition is reduced in volume by carbonization or incineration.

[0015] In this treatment method, pyrolysis is performed using a single rotary processing furnace (rotary kiln), the discharged residue is incinerated with a stoker, the pyrolysis gas is burned in a reburning chamber, and the generated high-temperature is generated. After passing the gas through a boiler or the like, the gas is guided to a reaction tower, where the slaked lime slurry is sprayed and reacted with the exhaust gas in the same manner as described above (for example, JP-A-5-33916).

Further, the waste is heat-treated by a low-temperature carbonization method in a rotary processing furnace to be converted into a low-temperature carbonized gas and a pyrolysis residue, and this is burned in a high-temperature combustion furnace to produce a molten liquid slag. For cooling and solidifying it into a glassy state, and treating the generated gas with a boiler, a removal filter and a gas purifier and discharging the gas (for example, Japanese Patent Application Laid-Open No. 8-510789).
Etc.

[0017]

The chlorine component contained in cement has a harmful effect such as corrosion of reinforcing bars in buildings and the like. Therefore, it is specified in the standard that the chlorine component is 200 ppm or less. Less is preferred.

[0018] Therefore, general waste, industrial waste, and waste such as vinyl chloride containing a chlorine component cannot be directly used as a secondary fuel in the production of cement clinker. In addition, it is conceivable to use carbon as a secondary fuel by extracting carbides from the incineration residues after incineration of the waste. However, chlorine components remain in these incineration residues, especially in the carbides, and the generated dioxins Cannot be used as a secondary fuel because it may remain adsorbed.

In the conventional waste incineration method, since the alkaline substance is sprayed into the incinerator, the treatment is performed at a place close to the generation source. However, the treatment is performed after the chlorine-based gas is once generated. It is.

Therefore, according to this method, although the effect of removing chlorine-based gas can be expected to some extent, it is difficult to sufficiently satisfy the emission standard values of various gases according to the revised laws and regulations.

[0021] Moreover, because of incineration, the reaction temperature is high, and it is difficult to maintain a stable reaction. In addition, spraying a large amount of an alkali substance has an adverse effect on the original combustion (generation of unburned phenomena), making it difficult to satisfy the emission standard values of various gases according to laws and regulations.

Further, in the method based on the dry distillation treatment, the object to be treated is thermally decomposed without burning, so that the instability factor as in an incinerator is easily removed. However, when the alkali substance is sprayed into the heat treatment furnace as in the incinerator, only the same effect as in the case of the incineration treatment can be expected.

As a common problem of the incineration treatment and the dry distillation treatment, when the material to be treated contains a large amount of chlorine-based gas, the facilities such as the heat treatment furnace and the flue are significantly corroded, and the durability of the facility is deteriorated. There is a risk of causing a drop or exhaust gas leakage, so it is necessary to pay attention to maintenance.

In order to solve the above problem, the applicant of the present application has proposed a technical means for mixing an alkaline additive when heat-treating an object to be processed (Japanese Patent Laid-Open No. 9-1553).
No. 26).

In each of the above-mentioned treatment methods by dry distillation, a treatment for thermally decomposing an object to be treated and depositing a decomposition gas is performed in a single treatment furnace. In other words, the process is performed in a series of processes in which an object to be processed is supplied from one supply port of a single processing furnace and carbide is discharged from the other discharge port. In this series of processes, a heat treatment (for example, 3 hours
(00 ° C. to 600 ° C.), the respective processes of drying of the object to be processed, pyrolysis, and carbonization are continuously performed.

The temperature at which a halogen substance is thermally decomposed and deposited from an object to be treated is about 200 ° C. to 350 ° C., so that a chlorine-based gas decomposed and deposited in a processing furnace is easily filled. Therefore, there is a possibility of producing dioxins at this point.

Further, the object to be treated is agitated, and the generated harmful chlorine component gas is liable to be caught in the object to be treated. If the object to be treated is heated to a temperature of 350 ° C. or more and becomes a carbide, Has a problem that it is adsorbed by carbides.

In particular, if the generated carbide, harmful chlorine component gas, and generated dioxins are present at the same time in the heat treatment furnace, the carbide adsorbs these gases and dioxins, and the adsorbed dioxins are removed. Removal from carbides is very difficult.

Therefore, it is difficult to reuse the generated carbide as a secondary fuel, and it is necessary to simply bury it as a residue in a final disposal site or to process it by another means such as melting at an extremely high temperature. There is.

Therefore, an object to be solved by the present invention is to form a harmless chloride by causing a harmful chlorine component decomposed and precipitated from a treatment object to contact with an alkali substance during decomposition treatment of the treatment object. A technology that realizes the detoxification of exhaust gas and residue by carbonizing this detoxified residue in a separate processing furnace, and reuses it together with the exhaust gas as a secondary fuel during the production of cement clinker In the offer.

[0031]

According to the experiments performed by the inventors, the heat treatment furnace is a substantially closed space, and an environment for removing moisture adhering (or contained) to the object to be treated, and thereafter, an environment for removing the object to be treated. An environment in which halogen substances (especially chlorine-based gas) resulting from the generation of dioxins contained in the object are decomposed and precipitated from the object to be treated and contact-reacted with an alkali substance, and an environment in which carbonization is performed thereafter are different from each other. It has been found that the above-mentioned problems can be solved by performing the treatment in an environmental heat treatment furnace.

That is, it has been known that when a halogen substance and an alkali substance come into contact with each other, they react to form harmless chlorides. However, this reaction is not sufficient, and the reaction containing chlorine components is difficult. When heat-treating a substance, a treating agent consisting of an alkaline substance is added, and the decomposed gas is contact-reacted with the decomposed and precipitated chlorine-based gas. Can be used as a secondary fuel during the production of cement clinker, and the exhaust gas can be released to the atmosphere as it is by removing dust. I found something.

Further, as a result of the examination, if the heat treatment furnace for the decomposition reaction step in the preceding step and the heat treatment furnace for the carbonization step in the subsequent step are treated in separate treatment furnaces, a single heating It has been found that the decomposed harmful components are not trapped and left in the stirred object to be processed, as compared with the case where the processing is performed in the processing furnace.

The present invention has been made based on these findings.

Therefore, a specific means of solving the problem according to the present invention is to use an object to be treated containing a harmful chlorine component, add a treating agent of an alkaline substance to the object to be treated, and heat the object in a heat treatment furnace. A decomposition reaction step of detoxifying harmful chlorine components from the object to be treated and reacting with an alkali substance to generate harmless chlorides, thereby detoxifying the exhaust gas and detoxifying the object. The heat treatment is performed in a carbonization treatment step of carbonizing the treatment object treated in the decomposition reaction step, and the harmless treatment object obtained by performing the decomposition reaction step and the carbonization treatment step in different heat treatment furnaces is converted into a solution. The present invention is characterized in that a method for producing cement clinker is characterized in that a carbide extracted by immersion, dissolution, and then liquor extraction and exhaust gas generated in each heat treatment furnace are used as secondary fuel.

That is, in the decomposition reaction step, the object to be treated and the alkali substance are added to the heat treatment furnace and the temperature is set at 200 ° C. to 350 ° C.
When heated to ℃, the gas decomposed and precipitated from the material to be treated is contacted with the surrounding alkaline substances at the same time as it is generated and replaced by harmless chlorides, which are converted to harmless chlorides. To be processed.

The heat treatment in the carbonization step is performed at a temperature of 350 ° C. to 700 ° C., which is a temperature at which the material to be treated is carbonized, so that a carbide that can be safely used as a secondary fuel for producing cement clinker is obtained. Can be

The alkaline substance added in the decomposition reaction step is
Alkali metals (Na, K, etc.) and alkaline earth metals (Ca,
Sr, Ba, Ra), alkaline earth metal compounds (lime,
Slaked lime, calcium carbonate, dolomide, etc.). Further, the decomposition reaction step, after passing through the drying step of drying the object,
Move on to chloride generation step. Drying furnace for removing moisture,
At least one chloride production furnace for decomposing and reacting a halogen substance and reacting it and / or a heat treatment furnace for carbonization treatment needs to be provided, but a plurality of heat treatment furnaces may be provided as necessary.

When two drying treatment furnaces used in the decomposition reaction step and the carbonization treatment step are used, this heating treatment furnace is
It is arranged on one side of the duct in parallel in the vertical or horizontal direction, or in parallel on both sides of the duct. When communicating in a plane instead of above or below,
A transfer means such as a screw body or a conveyor for transferring an object to be processed into the duct is required.

When the cylindrical body constituting the heat treatment furnace is made rotatable, a driven gear is provided on the outer periphery of the cylindrical body, and the driven gear is rotated by a motor. Further, driven gears are provided on the outer periphery of each cylindrical body of the heat treatment furnace installed above and below, and both driven gears are rotationally driven by a common motor.

By such a treatment method, the detoxification of the exhaust gas and the object to be treated can be realized. The high-temperature exhaust gas in each heat treatment furnace can be used as a secondary fuel or a heat source. However, the exhaust gas is treated by a conventional exhaust gas combustion means or a known exhaust gas treatment means such as a bag filter and released into the atmosphere. It is also possible.

[0042]

Embodiments of the present invention will be described below with reference to the drawings. The present invention relates to a method for producing a cement clinker by burning a secondary fuel together with a cement raw material.In the heat treatment of an object containing a harmful chlorine component or the like, a chlorine-based gas is decomposed and precipitated from the object. A decomposition reaction step of reacting with a treating agent comprising an alkaline substance;
The basic means is to perform the carbonization step of carbonizing the object processed in the decomposition reaction step in a different heat treatment furnace, and to use the obtained carbide and high-temperature exhaust gas as a secondary fuel.

FIG. 1 is a conceptual diagram of a waste treatment facility for embodying the present embodiment, in which 10 denotes a first heat treatment furnace, and 20 denotes a second heat treatment furnace. The first heat treatment furnace 10 includes a rotatable cylindrical body 11, a gas duct formed on the outer periphery of the cylindrical body 11, and a cylindrical body 11 formed by introducing a hot gas.
And a supply port 13 provided at one end of the cylindrical body 11 for supplying an object to be processed into the cylindrical body 11.
And a discharge port 14 provided at the other end of the cylindrical body 11, and the cylindrical body 11 is rotationally driven by rotation driving means (not shown).

FIG. 2 is a cross-sectional view of the heating cylinder 12 and the cylindrical body 11. Inside the cylindrical body 11, a plurality of blades S for stirring and transferring the object to be processed are provided. The mixture of the processed material and the processing agent is transferred to the discharge port 14 side.

The rotation driving means of the cylindrical body 11 comprises a normal driving motor and a driving gear, a driven gear provided on the cylindrical body, and the like.

Reference numeral 15 denotes a supply duct surrounding the supply port 13, and reference numeral 16 denotes a discharge duct surrounding the discharge port 14.

The structure of the second heat treatment furnace 20 is substantially the same as the structure of the first heat treatment furnace 10, and includes a rotatable cylindrical body 21 and a hot gas introducing gas at the outer periphery of the cylindrical body 21. A heating cylinder 22 for heating the cylindrical body 21 by one side, and one end of the cylindrical body 21, in this example, an outlet 14 of the first heating unit 10.
And a discharge port 24 provided at the other end of the cylindrical body 21 for supplying the object to be processed into the cylindrical body 21.

25 is a supply port 2 to the second heat treatment furnace 20
A supply side duct surrounding the 3 side, and a discharge side duct 26 surrounding the outlet 24 side. The cylindrical body 11 of the first heat treatment furnace 10 and the cylindrical body 21 of the second heat treatment furnace 20 are vertically arranged, and as shown in the sectional view of the main part of FIG. 21) Heating cylinder 12 arranged on the outer periphery
(22) is supported and fixed by the fixing member 28.

Numeral 30 denotes a hopper. The object to be treated and the treating agent comprising an alkali substance are mixed and thrown into the hopper 30, and can be supplied into the cylindrical body 11 from the supply port 13 of the cylindrical body 11. .

The hopper 30 may have a function of crushing the object to be processed and a function of mixing the processing agent, and may mix the processing agent with the crushed solid while crushing the solid. The treatment agent may be mixed and thrown into the hopper 30.

Reference numeral 31 denotes a combustion device which burns LNG supplied from an LNG tank (not shown) to generate hot gas when LNG is burned, for example. This hot gas is supplied to a heating cylinder 2 provided on the outer periphery of a cylindrical body 21 of a second heat treatment furnace 20.
After heating the cylindrical body 21 supplied to the inside of the connecting pipe 32, the connecting pipe 32
Through the heating cylinder 1 of the cylindrical body 11 of the first heat treatment furnace 10
After the cylindrical body 11 is heated and heated through a discharge pipe 33,
5 is supplied to a supply duct 34 provided on the supply side, and is used as a heat source.

36 is a dissolving tank, 37 is a dewatering means, 38 is a silo for storing carbide, 39 is a silo for storing cement material, 40
Denotes an exhaust gas treatment device, and 41 denotes a chimney. The solution in the dissolving tank 36 is separated into solid and liquid by a dehydrating means 37, and the solid is sent to a carbide storage silo 38, where metals are removed by the storage silo 38 and then supplied together with the cement raw material in the cement raw material storage silo 39. It is configured to be fed into the duct 34.

Next, a series of processing methods based on the present embodiment will be described. An object to be processed is crushed in advance by a crusher, and an alkali substance such as calcium carbonate (CaCO ₃ ) is used as a processing agent. Mix.

The material to be treated may be a solid such as general waste or industrial waste, ash, or sludge. The mixing ratio of the treating agent to the material to be treated is 5 to 30% by weight. The mixture may be crushed after the treatment agent is mixed with the object.

At the same time, LNG is burned by the combustion device 31 to generate hot gas, which is supplied to the heating tube 22 and the heating tube 12 to heat the inside of the first heat treatment furnace 10 and the second heat treatment furnace 20. After the state, the mixture of the processing object and the processing agent is supplied from the hopper 30 into the cylindrical body 11 of the first heat treatment furnace 10 through the supply port 13. The cylindrical body 11 is rotationally driven by a rotation driving means (not shown).

In the heat treatment in the first heat treatment furnace 10, the temperature and time at which a halogen substance, especially a chlorine-based gas, from the object to be decomposed and precipitated is investigated in advance to determine the properties of the object. At a temperature (200 ° C.)
(~ 350 ° C) and time (30 minutes). The temperature at which the chlorine-based gas is decomposed and precipitated from the object to be treated is 25
0 ° C to 350 ° C is suitable.

The heating temperature and time in the first heat treatment furnace 10 are also related to the state of the heating furnace (conditions depending on the furnace such as heating means, etc.) and the throughput of the object to be processed. Therefore, it is necessary to conduct sufficient investigations and the like in advance, and it is necessary to collect and store data.

The heating in the first heat treatment furnace 10 is as follows.
If the treatment is performed by "steaming and pyrolysis" instead of "burning and incineration", the harmful chlorine-based gas deposited and the treating agent of the alkaline substance can be effectively contacted and reacted, and the harmful HCl gas is removed. It can be produced by replacing harmless sodium chloride.

In the first heat treatment furnace 10, HC
The chlorine-based gas containing the l component is generated, and the HCl component in the chlorine-based gas reacts with the added calcium carbonate to produce harmless chloride calcium chloride (CaCl ₂ ).
Generate Thereby, the detoxification of the HCl component and the detoxification of the residue in the decomposition gas can be performed at the same time. The reaction formula is as follows.

The treated material detoxified by the precipitation of the chlorine component CaCO ₃ → CaO + CO ₂ CaO + 2HCl → CaCl ₂ + H ₂ O is transported while being stirred by the blades S in the cylindrical body 11, and is discharged. 14 from the second heat treatment furnace 2 via the supply port 23 of the next stage.
The temperature and time at which the object to be treated is carbonized (paper begins to carbonize at about 350 ° C.) are heated at 350 ° C. to 700 ° C. for about 30 minutes to perform carbonization. Do. In the second heat treatment furnace 20 in this carbonization step, harmless chlorides are present but no harmful chlorine components are present, so that the carbonized workpiece does not absorb them.

The exhaust gas generated by heating in the first heat treatment furnace 10 and the second heat treatment furnace 20 does not contain harmful chlorine-based gas. In order to remove gas components and dust, these exhaust gases are treated by an exhaust gas treatment device 40 and then a part is discharged from a chimney 41, and another part is supplied to a duct 34 as a secondary fuel.

The carbonized object, the reacted calcium chloride and the like are discharged into the dissolving tank 36 through the discharge port 24. In the dissolution tank 36, the treatment agent and the like after the reaction with the object to be treated are dissolved in water, separated into a solid component and a liquid component by the dehydration action of the dehydrating means 37 in the next stage, and the liquid component is drained. The carbide, which is a solid component, is sent to the carbide storage silo 38 as it is or after a drying treatment as necessary.

After the metals are removed in the carbide storage silo 38, a predetermined amount is fed into the cement clinker production heating rotary furnace 35 via the duct 34 together with the cement raw material in the cement raw material storage silo 39 to produce the cement clinker. . Exhaust gas generated during manufacturing is released from the chimney 41.

Incidentally, the carbide as a solid component may be directly sent to the heating rotary furnace 35 for producing cement clinker without using the carbide storage silo 38.

The alkaline substance used for treating the harmful chlorine component is at least one selected from alkali metals, alkaline earth metals, and alkaline earth metal compounds which react with halogen substances to form harmless chlorides. One type of substance or a mixture of two types of substances is used.

Thus, the contact reaction between the harmful chlorine component (chlorine-based gas) in the generated decomposition gas and the added alkali substance causes the chlorine component to be replaced with harmless calcium chloride or the like. A harmful chlorine component (chlorine-based gas) can be eliminated from the residue, and a harmless decomposition gas and a harmless residue can be obtained.

Accordingly, the decomposed gas is taken out from the ducts 16 and 26 and subjected to a predetermined treatment in the exhaust gas treatment device 40.
It is fed into the duct 34 and can be used as a secondary fuel or a heating source, and the residue can be converted into a carbide as described above and used as a secondary fuel.

The hot gas generated in the combustion device 31 is heated to the cylindrical bodies 21 and 22 and then sent to the duct 34 to be used as an auxiliary heat source for heating the heating rotary furnace 35 for producing cement clinker. Can be measured.

As described above, according to the present invention, at least two waste heat treatment furnaces are provided as secondary fuels used in the production of cement clinker, and harmful substances are decomposed and precipitated from the object in one of the heat treatment furnaces. At the same time, the deposited gas and the alkali substance are reacted with each other to make them harmless, and the harmless object is basically carbonized in another heat treatment furnace. It can be realized even if arbitrarily selected according to the conditions of the installation location.

FIG. 3A is a schematic diagram of the embodiment of FIG. 1. The first heat treatment furnace 10 is used as the decomposition reaction means 1, the second heat treatment furnace 20 is used as the carbonization means 2, and the duct is used as the decomposition reaction means. 3,
It is the schematic diagram which set the opening and closing door to 4. The same figure (B) shows duct 3.
The arrangement of the decomposition reaction means 1 and the carbonization means 2 with respect to
FIG. 2C shows a case where two ducts are arranged on both sides of the duct 3.
In this case, three ducts 3, 3 'and three heat treatment furnaces are used, and one heat treatment furnace is used as the drying means 5.

[0071]

As described above, the present invention separates harmful components contained in the material to be treated in order to obtain a secondary fuel to be supplied and burned together with the cement raw material into the heating rotary furnace during the production of cement clinker and burned. Since the decomposition reaction means for analyzing and reacting with the alkali substance at the same time as the analysis and the subsequent means for heating and carbonizing the object to be processed are performed in different heat treatment furnaces, the following effects are obtained.

(1) In the decomposition reaction step of decomposing and decomposing a halogen substance (chlorine-based gas or the like) contained in an object to be treated such as waste, both the object to be treated and the alkali substance are heated. In addition, the contact reaction between the decomposed and deposited chlorine-based gas and the alkali substance is rapidly and reliably performed, and harmless chloride is generated, and there is no chlorine-based gas that generates dioxins in the exhaust gas. This makes it possible to detoxify both the decomposed gas and the material to be treated, does not corrode the flue, and the resulting high-temperature exhaust gas can be effectively used as a safe secondary fuel and heat source when manufacturing cement clinker. it can.

(2) Since the carbonization step of heating and carbonizing the object from which the chlorine-based gas has been removed is performed in a heat treatment furnace different from the heat treatment furnace in the decomposition reaction step, the carbonization step Dioxins generated due to halogen substances do not exist in the residue in the above, so that the dioxins do not adsorb and mix in the carbide, and the detoxification of the carbide can be realized, and the secondary during the production of cement clinker It can be safely reused as fuel.

(3) Even if the waste contains a halogen substance (particularly chlorine), harmless exhaust gas and harmless residue from which chlorine has been removed can be obtained. Waste that is not used as waste can be effectively reused.

(4) By detoxifying the waste treatment, the waste which has been harmful in the conventional treatment can be detoxified. Therefore, the detoxified waste is used to make new waste such as cement. Resources can be reproduced, 2
To communicate useful environment and technology to first-century descendants.

[Brief description of the drawings]

FIG. 1 is a conceptual diagram of a waste treatment facility according to an embodiment of the present invention.

FIG. 2 is a longitudinal sectional view of the cylindrical body of FIG.

FIG. 3 is a schematic diagram of the embodiment of FIG. 1;

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 ... 1st heat processing furnace 11, 21 ... Cylindrical body 12, 22 ... Heating cylinder 13, 23 ... Supply port 14, 24 ... Discharge port 15, 25 ... Supply side duct 16, 26 ... Discharge side duct 28 ... Fixing member DESCRIPTION OF SYMBOLS 30 ... Hopper 31 ... Combustion device 32 ... Communication pipe 33 ... Discharge pipe 34 ... Supply duct 35 ... Cement clinker production heating rotary furnace 36 ... Dissolution tank 37 ... Dehydration means 38 ... Carbide storage silo 39 ... Cement raw material storage silo 40 ... Exhaust gas treatment apparatus

Claims (12)

[Claims] 1. A method of manufacturing a cement clinker in which a secondary fuel is supplied together with a cement raw material into a heating rotary furnace and burned, wherein the step of manufacturing the secondary fuel comprises a treatment containing a harmful chlorine component. Add a treating agent of an alkaline substance to the material, heat it in a heat treatment furnace, decompose and deposit harmful chlorine components from the material to be treated, and contact it with the alkaline substance to produce harmless chlorides, thereby reducing exhaust gas. A decomposition reaction step of detoxifying and detoxifying the object to be treated, and a carbonization step of heating and carbonizing the object treated in the decomposition reaction step. These decomposition reaction step and carbonization step Is carried out in a different heat treatment furnace, the harmless material obtained in the carbonization process is immersed in a solution, and after dissolution, the liquid is extracted and the extracted carbide is used as the secondary fuel, and the cement clinker is characterized in that Manufacturing method. 2. A method for producing a cement clinker in which a secondary fuel is supplied to a rotary heating furnace together with a cement raw material and burned, wherein the step of producing the secondary fuel comprises a treatment containing a harmful chlorine component. Add a treating agent of an alkaline substance to the material, heat it in a heat treatment furnace, decompose and deposit harmful chlorine components from the material to be treated, and contact it with the alkaline substance to produce harmless chlorides, thereby reducing exhaust gas. A decomposition reaction step of detoxifying the object and detoxifying the object, and a carbonization step of heating and carbonizing the object treated in the decomposition reaction step. A method for producing a cement clinker, characterized by using a secondary fuel. 3. The alkali substance is selected from at least one selected from the group consisting of alkali metals, alkaline earth metals, and alkaline earth metal compounds which react with halogen substances to form harmless chlorides. The method for producing a cement clinker according to claim 1, wherein the method is a mixture of at least two types. 4. At least one heat treatment furnace used in the decomposition reaction step and one heat treatment furnace used in the carbonization treatment step are installed, and both heat treatment furnaces are connected via a duct so that an object to be processed can be transferred. The method for producing a cement clinker according to claim 1 or 2, wherein: 5. A plurality of heat treatment furnaces used in a decomposition reaction step and a carbonization step are arranged on one side surface of a duct in a vertical or horizontal direction. Or the manufacturing method of the cement clinker as described in any one of 4. 6. The heat treatment furnace according to claim 1, wherein a plurality of heat treatment furnaces used in the decomposition reaction step and the carbonization step are arranged in parallel on both sides of the duct. Item 14. The method for producing a cement clinker according to item 4. 7. The decomposition reaction step comprises a step of drying the object to be treated and a step of producing harmless chloride by reaction with an alkali substance. The method for producing a cement clinker according to any one of the above. 8. The method according to claim 1, wherein the step of drying the object to be treated in the decomposition reaction step and the step of producing harmless chloride by reaction with an alkali substance are performed in the same heat treatment furnace or in different heat treatment furnaces. A method for producing the cement clinker according to claim 7. 9. The heat treatment temperature in the decomposition reaction step is as follows:
The method for producing a cement clinker according to claim 1, wherein the temperature is a temperature at which a halogen substance decomposes and precipitates from an object to be treated. 10. The heat treatment temperature in the decomposition reaction step is 200 ° C. to 350 ° C., which is a temperature at which a halogen substance is decomposed and precipitated from an object to be processed. The method for producing a cement clinker according to claim 1. 11. The heating treatment in the carbonization treatment step is performed by heating at a temperature at which an object to be treated is carbonized.
Or the method for producing a cement clinker according to item 2. 12. The cement clinker according to claim 1, wherein a heat treatment temperature in the carbonization step is 350 ° C. to 700 ° C. at which the material to be treated is carbonized. Manufacturing method.