JP3597714B2 - Small melting furnace with carbonization device and smelting reduction method - Google Patents

Description

【００４２】
コークスを燃料とした場合、大型高炉と小型高炉とでは熱効率や放熱特性の差異によって燃料費は小型の方が若干高くつく。炭素・カーボンの炭化燃料を用いた場合には、およそ２０重量％以上の使用で大型高炉と同等かそれ以上の燃費節減が可能である。また、炭素化率（炭化燃料に含まれる炭素分）がおよそ２５重量％以上で全可燃成分がおよそ７０重量％以上であれば、コークスを用いた大型高炉と同等かそれ以上の燃費節減が可能である。炭素化に必要な経費の多くは加熱エネルギー費であり、その費用と炭化後の形成に必要な経費を加算しても、本発明による炭素・カーボンの燃料としての経済価値はコークスのみを使用する場合に較べて勝る。特に、本発明では、炭素化の原料として廃棄物を利用するので、原料費が低減できでより一層の経済効果を発揮する。
【００４３】
【発明の効果】
以上の通り、本発明によれば、コークス等の高価な燃料を多く使用しないでも、炭素・カーボンをコークス同等の燃料として使用することにより、安価な溶融炉の操業が可能となる。炭素・カーボンの原料として廃棄物を利用するため、より安価な燃料として利用できるとともに、廃棄物の処理や再利用にも貢献できる。溶融炉は２０００℃程度の高温で操業されるので、炭素・カーボンに未炭化物や無機物質が含まれていても高温で分解燃焼されるとともに、無害化が図れるので、炭素・カーボンの成分的な制約はなく、応用範囲が広い。
【００４４】
【表２】

【００４５】
表２は、本発明による炭素・カーボンの炭化燃料を用いて高炉を操業したデータと、従来のコークスを用いて高炉を操業したデータを比較したものである。操業性、生産性またできた銑鉄やスラグにも差異が無く、コークスの代替として、炭化装置から生成した炭素・カーボンが有効に活用できるという本発明が実証された。
【図面の簡単な説明】
【図１】本発明一実施例のバッチ式炭化装置付き小型溶融炉の模型的部分断面図である。
【図２】従来の一般的な竪型シャフト高炉の模型的部分断面図である。
【符号の説明】
１ 炉床
２ 溶銑床
３ 鉱滓床
４ 炉腹
５ シャフト
７ 羽口
８ レースウェイ
９ 原料
１５ 原料装入表面
Ｈ 羽口から炉頂の装入原料表面までの高さ[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a melting furnace such as a hard shaft cupola or a blast furnace for melting pig iron ore to extract pig iron, particularly to a small melting furnace with a carbonization device and a smelting reduction method.
[0002]
[Prior art]
As a conventional melting furnace such as a blast furnace, as shown in the figure, a hearth 1 laid with refractory bricks is formed, a hot metal bed 2 is provided on the upper part so that molten pig iron is collected, and a slag is provided on the upper part. A slag bed 3 is provided to separate the slag, and a furnace belly 4 formed of refractory bricks is provided so as to surround them, and a refractory brick is piled up integrally therewith to form a shaft 5 at an upper portion thereof. It is surrounded and protected by an iron plate 6.
[0003]
The furnace wall is provided with several tens of tuyeres 7 for feeding hot air, and is formed so that heat can be completely distributed through the raceway 8 in the furnace. The high-temperature hot air blown from here becomes a combustion gas passing between the iron ore raw material and the coke (for example, 25 layers each) in the multi-layered layer 9A, reduces the iron ore, melts and drops pig iron down. At the same time, gas is collected from the furnace top 10 to the blast furnace gas riser 11. In addition, the slag is structured to be taken out of the system.
[0004]
The raw material 9 such as iron ore, coke, and limestone is conveyed to an upper furnace top 10 by a belt conveyor 12 and thrown into a hopper 13, and is constantly fed to a raw material charging surface 15 at a constant cycle by a large bell 14 by an external signal. It will be replenished. The furnace temperature is higher in the lower part, and is as high as about 2,000 ° C. in the highest region.
[0005]
16 is a blast furnace support, 17 is a hot blast tube, 18 is a gas ash dust settling device, 19 is a taphole, 20 is a torpedo car for carrying pig iron from there, 21 is a slag exit, 22 is a slag wheel, and 23 is a hot air ring Tube.
[0006]
Melting furnaces such as rigid shaft cupolas and blast furnaces are operated by using coke as a main raw material and supplementarily using constant temperature gas, electricity and the like.
[0007]
Coke as a fuel must have a strength that can withstand the weight of the injected fuel, smelting raw materials and auxiliary materials, and also requires a gap for securing a gas flow in the furnace. Therefore, it is necessary to ensure the required strength even at a high combustion temperature, and to maintain a shape that is not crushed and hinders the gas flow. For this reason, coke is often manufactured using expensive caking coal as a raw material, and has the disadvantage of being expensive.
[0008]
The present inventors have found that in the process of studying effective recycling technology for metal scraps and their dusts or wastes containing metal components, carbon and carbon can be used as an effective fuel in place of coke in small blast furnace melting furnaces. He acknowledged that it was possible to reduce fuel costs.
[0009]
It has been a practice in some cases to put carbonized or carbonizable material into a melting furnace such as a blast furnace and utilize its combustion energy. A large amount is not supplied from the viewpoint of securing a gas flow path, and the input amount is less than 10% by weight, and is often several% by weight.
[0010]
[Problems to be solved by the invention]
In a conventional blast furnace, the raw materials are iron ore or metal oxide and coke. Coke becomes fuel for raising the temperature and CO gas for reduction. Inside the shaft of the blast furnace, the layer of iron ore or metal oxide and the layer of coke are layered in a rare-by-rare manner and are packed in multiple stages from top to bottom.
[0011]
The air or oxygen supplied from the tuyere burns this coke at the raceway and becomes a mixture of carbon monoxide and carbon dioxide at a high temperature of about 2000 ° C, while melting the iron ore at the bottom of the furnace at a high temperature. The iron ore in the upper layer is heated and reduced, and is discharged from the top of the furnace.
[0012]
This coke is made mainly of caking and expensive coal in a coke oven, and the coke itself is expensive, and at the same time, it is manufactured mainly in the steel industry, and there is a problem that it is generally difficult to obtain. .
[0013]
The present invention has been made based on the above findings.
In a melting furnace such as a general blast furnace, a multistage layer of iron ore and coke is clogged inside the shaft, and the air supplied from the tuyere burns coke at a raceway to generate a high temperature of about 2000 ° C. It becomes a mixed gas of carbon oxide and carbon dioxide, which melts and reduces iron ore and metal scraps, and takes out pig iron and metal melt from the lower part of the furnace as a melt. Further, incineration / melting treatment of waste and the like is also performed by the same mechanism.
[0014]
An object of the present invention is to use a carbonized material produced by a carbonization device, that is, carbon / carbon, instead of coke as a fuel.
[0015]
Since carbon contains a large amount of carbon, which is the same component as coke, it can generate the same combustion heat and reducing gas as coke, and can be used as fuel equivalent to coke instead of coke. Carbon can be easily and inexpensively produced by using a carbonization device, and waste materials such as waste wood, waste plastic materials, and general garbage can be used as raw materials. Material can be obtained, and fuel cost can be reduced.
[0016]
The use of waste as a raw material for carbonization contributes to the reduction, recycling, and effective utilization of waste, and contributes to environmental conservation.It also reduces the fuel cost of melting furnaces such as blast furnaces and reduces the cost. Has the effect of enabling operation.
[0017]
Carbon / carbon generally has the property of being in powder form or easily pulverized. In order to utilize this as combustion in a melting furnace such as a blast furnace, it is possible to use powder in a small melting furnace where the furnace pressure is close to normal pressure, but it is necessary to increase the furnace pressure. Larger blast furnace melting furnaces need to maintain strength and shape, so they often require granulation, briquetting, and the like.
[0018]
In order to reduce the cost required for the molding and to operate at a lower cost than in the case of using coke, the furnace volume of the blast furnace melting furnace to be applied needs to be approximately 100 Lube or less.
By limiting to a small melting furnace having a furnace volume of 100 lube or less, it becomes possible to input a larger amount of carbon as a fuel than was previously possible, thereby enabling inexpensive operation. In addition, using waste as a raw material for carbonization suppresses consumption of useful resources, provides a method for recycling waste and the like, and provides a more inexpensive method for operating a small melting furnace.
[0019]
Therefore, in the process using coke, there is a problem that the use of the coke is economically expensive and a problem that the availability of the coke is generally difficult.
[0020]
In view of the above problems, the present invention provides a carbonization device for producing carbon / carbon and gas from waste such as general garbage and industrial waste, instead of coke produced from coal. And a smelting reduction method using the melting furnace provided with a carbonization device in which sintering is combined in series. This smelting reduction method can greatly reduce the use of coke by replacing it with carbon / carbon as compared with the conventional blast furnace process relying solely on coke from coal, or reduce the total amount of carbon / carbon / carbon. It is possible to replace the total amount of the gas to be covered by the carbon and carbon and gas obtained from gasification.
[0021]
Therefore, an object of the present invention is to provide an inexpensive production cost by effectively recycling general waste and industrial waste discarded without relying on expensive resources such as coal.
[0022]
[Means for Solving the Problems]
In order to solve the above-mentioned object, a small melting furnace with a carbonization device of the present invention is charged with waste such as general garbage and industrial waste, and carbonized by raising the temperature of the loaded waste. , A carbonizing device that produces carbon or carbon that has the property of being powdery or easily crushed, a furnace belly surrounding the upper part of the hearth to form a hot metal bed and a slag bed, and a shaft on the upper part And a small melting furnace having a furnace volume of 100 lube or less, by charging the small melting furnace with carbon / carbon generated by the carbonization device as a substitute fuel for coke in an amount of 20% by weight or more, The object of the present invention is to incinerate and melt the input raw material or to melt and reduce the smelting raw material to take out pig iron or a metal alloy by the combustion heat.
[0023]
Further, carbon has a carbon content of at least 25% by weight or more, a total flammable component combined with other flammable components is at least 70% by weight, and a furnace volume is at most 10 Lube. And / or the furnace pressure is preferably low and close to normal pressure.
[0024]
The smelting reduction method of the present invention is a smelting reduction method using the above-described small melting furnace with a carbonizing device, and comprises charging waste such as general garbage and industrial waste into the carbonizing device and raising the temperature. It produces carbon / carbon and gas having properties such that it is physically or easily pulverized, and the produced carbon / carbon is directly charged from the furnace top of a small melting furnace and / or tuyere Alternatively, at least a part of the generated gas is blown from the shaft into the small melting furnace as a substitute for coke fuel, and at least a part of the generated gas is introduced into the small melting furnace from the tuyere or the shaft of the small melting furnace, as a substitute for combustion gas or as a metal oxide. Injecting it as a reducing gas.
[0025]
That is, the small melting furnace of the present invention aims to reduce the use of coke, which is an expensive fuel, by using carbon / carbon generated from waste by a carbonization device as fuel for the melting furnace.
[0026]
The carbonization device includes a continuous type and a batch type, and in the present invention, either type may be used.
[0027]
When carbonizing waste with a carbonizer, a small amount of coal may be used, but most of the raw materials used use resources other than coal.
[0028]
Raw material resources other than coal used in the carbonization apparatus are mainly organic resources, but may be mixed with inorganic resources. In particular, it is more effective to use unused resources, that is, wastes such as general garbage and industrial wastes, as raw materials from the economical viewpoint of reducing prices.
[0029]
In the present invention, the carbonization device used for carbonization may be any commonly used device. In the present invention, the carbon / carbon charged into the melting furnace needs to be 2020% by weight or more as a substitute fuel for coke. If the content is less than 20% by weight, there is no effect of reducing fuel cost.
[0030]
Further, in the present invention, the carbon / carbon used has a carbon content (carbon content) of at least 25% by weight or more and a total flammable component combined with other flammable components of 70% by weight or more. It is preferable that If the carbon content is less than 25%, the combustion efficiency tends to be insufficient, and if the total combustible component is less than 70% by weight, the combustion fuel tends to be insufficient, which is not desirable. .
[0031]
The carbon used may contain an inorganic substance such as an uncarbonized component or a metal compound as long as the carbon content is 25% by weight or more. In this case, however, a combustible component other than carbon is used. Preferably, the total amount is 70% by weight or more.
[0032]
In the present invention, the carbon used has only to have characteristics and a morphological range in which the melting furnace can operate normally, and can be used in any of briquettes, granules, and powders as necessary. These may be formed so as to have necessary strength characteristics by a commonly used apparatus and method. However, since carbon or carbon obtained in powdered or easily pulverized properties is used as the material, the strength characteristics required for the operation of the melting furnace, the gas flow path, and the economical viewpoint are considered. According to the invention, the furnace volume of the applied melting furnace is limited to 100 lube or less. This is because in a melting furnace having a furnace volume exceeding 100 lube, the cost of providing a strength and a shape that can withstand the pressure inside the furnace increases, and it is not economical.
[0033]
In the application of the melting furnace in the present invention, depending on the purpose, such as for incineration melting or reduction refining, coke, heavy oil, combustible gas, power sources such as commonly used heat sources and limestone Secondary materials can be used together. In order to increase the thermal efficiency, incineration / melting efficiency, reduction efficiency, etc. according to the intended use of the melting furnace, a mixture of carbon and carbon, coke, combustibles, substances to be treated, smelting raw materials, auxiliary materials, etc. Can also be used.
[0034]
BEST MODE FOR CARRYING OUT THE INVENTION
Embodiments of the present invention will be described with reference to the drawings based on examples. Next, a small melting furnace with a batch type carbonizing device according to the present invention is shown.
[0035]
In the figure, the raw material charged into the carbonizing device charged from the raw material inlet 1 enters the bottom of the carbonizing device and is heated. The heated materials rise to 100 ° C., 150 ° C., 200 ° C., 250 ° C., 300 ° C., and 350 ° C., and the time required for the chemical reaction is held in each of these temperature zones. In this temperature range, the temperature is maintained for the time necessary for carbonization, and carbon and carbon are generated.
[0036]
The generated gas 2 passes through an exhaust hole 3, and a part is sent to a gas tank 4 and the other is sent to a blast furnace 5 which is a small melting furnace. The gas sent to the blast furnace 5 is blown from the blast furnace shaft 6 or the tuyere 7 and is used as a substitute for combustion gas or as a gas for reducing metal oxides.
[0037]
Most of the residue 8 generated in the carbonization device is carbon / carbon and metal or metal oxide. These are separated into carbon / carbon system 9 and metal system 10, and metal or metal oxide is charged from the furnace top of the blast furnace as raw material of the blast furnace, reduced and refined in the furnace, and recycled. You.
[0038]
On the other hand, carbon, as it is or is briquetted by briquetting machines, is also charged from the top of the blast furnace as a substitute for coke. As a substitute for coke 11, the charged carbon burns with air 12 or oxygen 13 from the tuyere to become a high-temperature reducing gas of about 2000 ° C.
[0039]
Further, the carbon / carbon produced in the carbonization device is blown into the tuyere or shaft of the blast furnace by powder transport as powder, and can be used as a substitute for coke fuel or a substitute for reducing gas.
[0040]
Next, in a small blast furnace having a furnace volume of 10 lube, the fuel cost when carbon / carbon generated by the carbonization device is changed at a charging rate of 0 to 100% using carbonized fuel of coke as an alternative fuel is shown. 1 is shown. In addition, the fuel cost in Table 1 is shown as an index ratio with 1 when the fuel used in the large blast furnace is all coke.
[0041]
[Table 1]

[0042]
When coke is used as fuel, the fuel cost of the small blast furnace is slightly higher than that of the small blast furnace due to differences in thermal efficiency and heat radiation characteristics. When carbon / carbon carbonized fuel is used, fuel consumption can be reduced by the use of about 20% by weight or more, which is equivalent to or larger than that of a large blast furnace. In addition, if the carbonization rate (carbon content of carbonized fuel) is about 25% by weight or more and the total flammable components are about 70% by weight or more, the fuel consumption can be reduced to the same level as or larger than that of a large blast furnace using coke. It is. Most of the cost required for carbonization is heating energy cost, and even if the cost and the cost required for formation after carbonization are added, the economic value of carbon and carbon as a fuel according to the present invention uses only coke Better than the case. In particular, in the present invention, waste is used as a raw material for carbonization, so that the raw material cost can be reduced and a further economic effect can be exhibited.
[0043]
【The invention's effect】
As described above, according to the present invention, even if a large amount of expensive fuel such as coke is not used, an inexpensive melting furnace can be operated by using carbon / carbon as a fuel equivalent to coke. Since waste is used as a raw material for carbon and carbon, it can be used as a cheaper fuel and can contribute to waste treatment and reuse. Since the melting furnace is operated at a high temperature of about 2000 ° C, it can be decomposed and burnt at a high temperature even if carbon and carbon contain non-carbonized materials and inorganic substances. There are no restrictions, and the application range is wide.
[0044]
[Table 2]

[0045]
Table 2 shows a comparison between data obtained by operating a blast furnace using the carbonized carbonized fuel according to the present invention and data obtained by operating a blast furnace using conventional coke. There is no difference in operability, productivity, and pig iron and slag produced, and the present invention has been demonstrated that carbon / carbon generated from a carbonization device can be effectively used as a substitute for coke.
[Brief description of the drawings]
FIG. 1 is a schematic partial cross-sectional view of a small melting furnace with a batch type carbonizing device according to one embodiment of the present invention.
FIG. 2 is a schematic partial sectional view of a conventional general vertical shaft blast furnace.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Furnace bed 2 Hot metal bed 3 Slag bed 4 Furnace belly 5 Shaft 7 Tuyere 8 Raceway 9 Raw material 15 Raw material charging surface H Height from tuyere to charged raw material surface at furnace top

Claims (5)

Wastes such as general garbage and industrial wastes are charged, and the charged wastes are heated to carbonize them to produce carbon or carbon that has powdery or easily crushed properties. A carbonizing device,
A hot metal bed, a furnace belly surrounding the upper part of the hearth so as to form a slag bed, and a small melting furnace having a shaft on the upper part and a furnace volume of 100 lube or less,
By charging 20% by weight or more of carbon and carbon generated by the carbonization equipment as a substitute fuel for coke into a small melting furnace, the input heat is burned and melted by the heat generated by the combustion, or the smelting raw material is melted and reduced. A small melting furnace equipped with a carbonizing device for removing pig iron or a metal alloy. The carbonized device according to claim 1, wherein the carbon content of the carbon is at least 25% by weight or more, and the total flammable component combined with other flammable components is at least 70% by weight. Small melting furnace. The small melting furnace with a carbonizing device according to claim 1 or 2, wherein the furnace volume is 10 lube or less. 4. The small melting furnace with a carbonizing device according to claim 1, wherein the pressure in the furnace is low and near normal pressure. A smelting reduction method using the small melting furnace with a carbonizing device according to any one of claims 1 to 4,
By charging waste such as general garbage and industrial waste into the carbonization device and raising the temperature, carbon or carbon and gas having properties such as powder or easily pulverized are generated,
The produced carbon / carbon is directly charged from the furnace top of the small melting furnace and / or blown into the small melting furnace from the tuyere or the shaft as a substitute for coke fuel,
A smelting reduction method characterized in that at least a part of the generated gas is blown into a small melting furnace from a tuyere or a shaft of the small melting furnace as a substitute for a combustion gas or as a gas for reducing metal oxides.

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