JP6842658B2 - Manufacturing method of ingots for steelmaking - Google Patents

Description

The present invention relates to a method for producing an ingot for steelmaking using an iron-containing by-product generated in an ironmaking process.

Iron-containing by-products containing iron such as dust and sludge generated in the steelmaking process are being reused as iron sources in steelworks from the viewpoint of effective use of resources and environmental problems.

This iron-containing by-product is often reused in the sintering process, but those containing oil and those containing a large amount of metallic iron are processed into pellets or briquettes and reused in the steelmaking process (converter). Sometimes.

For example, Patent Document 1 describes a method in which a paste-like cement is used as a binder, oil-impregnated sludge is granulated and cured to produce pellets, and the pellets are reused in a converter.

Further, Patent Documents 2 and 3 describe a method of mixing quicklime with oil-impregnated sludge to remove water from the oil-containing sludge, granulating the sludge, and putting it into a converter for reuse.

Japanese Unexamined Patent Publication No. 2000-256760 Japanese Unexamined Patent Publication No. 2000-273554 Japanese Unexamined Patent Publication No. 2014-210942

However, in the method of Patent Document 1 described above, since cement having a large gangue content is used as the binder, the iron content of the pellets is low. In addition, a special curing treatment is required to improve the strength of the pellets, which may lead to an increase in manufacturing cost and a decrease in productivity.

In the methods of Patent Document 2 and Patent Document 3, caustic soda and cornstarch are used as the binder, but there is a possibility that the strength of the briquette cannot be sufficiently ensured in either case.

Here, in the iron-making process, various iron-containing by-products having different physical properties such as components and particle size are generated. When such an iron-containing by-product is agglomerated as a raw material and reused as a ingot for steelmaking, the strength of the ingot for steelmaking varies greatly depending on the combination of the raw material and the binder used.

Therefore, in order to produce a reusable high-strength ingot for steelmaking, it is necessary to select an appropriate binder that can obtain high strength according to the raw materials used. In each of the above, the combination of the raw material and the binder for obtaining high strength has not been examined.

Therefore, there has been a demand for a method for producing a steelmaking ingot that can sufficiently secure a strength that can be used in the steelmaking process for a steelmaking ingot produced by using an iron-containing by-product generated in the ironmaking process.

The present invention has been made in view of these points, and an object of the present invention is to provide a method for producing an ingot for steelmaking, which has good strength even when an iron-containing by-product generated in an ironmaking process is used.

The method for producing an ingot for steelmaking according to claim 1 uses an iron-containing by-product generated in the steelmaking process as at least a part of a raw material, mixes this raw material with a binder, and processes it into pellets or briquettes. In the method for producing a steelmaking ingot that can be used in the steelmaking process, the pH of the raw material is adjusted, and the pH of the raw material is less than 10.5 according to the pH of the raw material. In the case of, at least one of α starch and dextrin is used as the binder, and when the pH of the raw material is 10.5 or more, the binder is selected so as to use dextrin as the binder. is there.

In the method for producing a steelmaking ingot according to claim 2, at least one of bentonite, molasses and pulp waste liquid is further added as a binder in the method for producing a steelmaking ingot according to claim 1. It is something to do.

Method for producing a steel-making agglomerates according to claim 3, in the manufacturing method according to claim 1 or 2 for steelmaking agglomerate according, to use a mixture of oil-containing sludge and quicklime as part of the raw materials The pH is adjusted with .

The method for producing a steelmaking ingot according to claim 4 is the method for producing a steelmaking ingot according to claim 3, wherein the mixture of oil-containing sludge and quicklime has an oil-containing sludge in a mixed amount of quicklime. It is 30% by mass or more and 120% by mass or less of the water content of.

The method for producing a steelmaking ingot according to claim 5 is the method for producing a steelmaking ingot according to claim 3 or 4, wherein the blending amount of the mixture of oil-containing sludge and quicklime is added to all raw materials. On the other hand, it is 60% by mass or less.

According to the present invention, since the binder is selected according to the pH of the adjusted raw material, a steelmaking ingot having good strength can be produced even if an iron-containing by-product generated in the ironmaking process is used.

It is a graph which shows the relationship between the raw material pH and the fortified amount of a binder. It is a graph which shows the relationship between the amount of quicklime and the amount of water. It is a graph which shows the relationship between the amount of quicklime and the amount of fortification of dextrin. It is a graph which shows the relationship between the amount of fortification of dextrin and the amount of a mixture of oil-containing sludge and quicklime.

Hereinafter, the configuration of one embodiment of the present invention will be described in detail.

In the method for producing an ingot for steelmaking according to the present invention, an iron-containing by-product generated in an ironmaking process is used as at least a part of a raw material, and this raw material and a binder are mixed and processed into pellets or briquettes to form a steelmaking ingot. It is an adult. That is, the iron-containing by-products generated in the steelmaking process are reused as raw materials for the ingots for steelmaking.

Binders are used for processing raw materials into pellets or briquettes and agglomerating them, and are generally classified into inorganic binders such as cement and bentonite and organic binders such as starch and molasses. To.

Inorganic binders are inexpensive, but _{have a high slag content such as SiO 2} and Al ₂ O ₃ , and among them, cement requires a long-term curing treatment or the like in order to increase its strength.

On the other hand, although the organic binder is expensive, it has a low slag content, it is easier to obtain high strength with a smaller amount than the inorganic binder, and no special curing treatment is required.

Therefore, an organic binder is used as the binder. Among such organic binders, starch is often used as a binder because of its availability, but it does not dissolve in cold water as it is. Therefore, modified starch modified by an enzyme or heat is used as a binder, and among the modified starch, α-starch or dextrin that dissolves in cold water is used.

There are several types of dextrin, such as roasted dextrin produced by heating starch at 100 to 200 ° C. and dextrinized with acid or enzyme, but any of them may be used.

Further, as the binder, in addition to α-starch and modified starch of dextrin, at least one of bentonite, molasses and pulp waste liquid may be appropriately added for the purpose of increasing the strength and the fluidity of the binder.

In the iron-making process, a large amount of iron-containing by-products such as dust and sludge are generated, and the physical properties such as the components and particle size of the iron-containing by-products differ greatly depending on the process of generation.

Therefore, even if the same binder is used for molding into pellets, briquettes, etc., the strength of the agglomerated product, which is the processed product, varies greatly depending on the type of raw material. Therefore, the combination of the raw material and the binder is important for producing a high-strength ingot for steelmaking.

However, the reason why the amount of increase in the strength of the binder differs depending on the raw material and the guideline for selecting the binder according to the raw material have not been clarified.

Therefore, we focused on the raw material pH as a factor that affects the amount of strengthening by the binder, and conducted the granulation experiment shown below.

The granulation experiment was carried out with a tire type granulator having a diameter of 500 mm. In the granulation experiment, as shown in Table 1, each raw material was prepared by mixing slaked lime showing alkalinity in the range of 0 to 5% by mass with dust, which is an iron-containing by-product generated in the iron-making process, and adjusting the pH. ..

When slaked lime was not added (dust only), the raw material pH was 9.15, when slaked lime was added, the raw material pH increased, and when 5% by mass was added, the raw material pH became 11.5. The pH of the raw material was measured by adding 1 g of the raw material to 100 mL of distilled water and measuring it with a commercially available pH meter.

Two types of binders (starch-containing binders) to be mixed with the raw materials were used, α-starch and dextrin were used, and each raw material whose pH was adjusted was used, depending on whether the binder was not added or 4% by mass of the binder was added. A granulated product was prepared.

These granulated products were completely dried in a dryer at 105 ° C., and then a product having a diameter of about 8 mm was selected and the crushing strength was measured to obtain the strength of the granulated product.

Then, the amount of increase in strength due to the addition of the binder (the amount of reinforcement of the binder) was determined based on the measured crushing strength in the case where the binder was not added and the case where the binder was added in an amount of 4% by mass.

FIG. 1 shows the relationship between the amount of increase in the strength of the granulated product and the pH of the raw material. In FIG. 1, A shows a case where α-starch is used as a binder, and B shows a case where dextrin is used as a binder.

As shown in FIG. 1, when α-starch was used as the binder, the amount of increase in strength decreased significantly as the pH of the raw material increased, and when the pH of the raw material exceeded 10.5, the strength almost increased even when added. There wasn't.

On the other hand, when dextrin is used as the binder, the amount of increase in strength tends to decrease as the pH of the raw material increases, as in the case of using α-starch, but in the high pH region where the increase in strength does not occur with α-starch. However, an increase in strength was observed.

That is, when agglomerating using a raw material showing a high pH, dextrin is more suitable as a binder than α-starch.

It is not clear why dextrin increases in strength more than α-starch in high pH raw materials, but it is considered that gelatinization is inhibited in high pH raw materials in α starch, whereas gelatinization occurs sufficiently in dextrin.

Therefore, when the pH of the raw material is less than 10.5, at least one of α-starch and dextrin is used as the binder, and when the pH of the raw material is 10.5 or more, dextrin is used as the binder.

Here, sludge generated in the hot spreading or pickling process contains several% of oil, and such oil-containing sludge is generally difficult to reuse as a sintering raw material due to the risk of ignition in a dust collector. is there.

Further, since the oil-containing sludge contains 20 to 50% by mass of water, it is used as a part of the raw material together with the iron-containing by-product, mixed with the binder and agglomerated, and reused as a ingot for steelmaking. May not be properly kneaded with other ingredients or binders.

Therefore, when oil-containing sludge is used as a part of the raw material of the ingot for steelmaking, it is preferable to reduce the water content of the oil-containing sludge to less than 20% by mass.

As a method of reducing the water content (water content) of the oil-containing sludge, there is a method of mixing with quicklime and utilizing an exothermic reaction during a dehydration reaction.

FIG. 2 shows the relationship between the amount of quicklime (mixed amount of quicklime) in a mixture of oil-containing sludge and quicklime and the amount of water in the oil-containing sludge. The amount of quicklime in FIG. 2 is a ratio of the oil-containing sludge to the water content.

As shown in FIG. 2, the water content of the oil-containing sludge decreases linearly with the increase in the amount of quicklime, and it can be seen that mixing the quicklime is effective in reducing the water content of the oil-containing sludge. If the mixed amount of quicklime is less than 30% by mass, the water content of the oil-containing sludge cannot be sufficiently reduced.

However, if the amount of quicklime to be mixed is excessive, the water content of the oil-containing sludge will decrease, but the raw material will become highly alkaline, and even if dextrin is used as the binder, there is a possibility that high-strength steelmaking ingots cannot be obtained. is there.

FIG. 3 shows the relationship between the amount of dextrin fortification (the amount of increase in strength due to dextrin) and the amount of quicklime (the amount of quicklime mixed in the mixture) when a mixture of oil-containing sludge and quicklime is used as a part of the raw material. .. The amount of quicklime in FIG. 3 is a ratio of the oil-containing sludge to the amount of water, and the amount of increase in strength was determined by the above-mentioned granulation experiment.

As shown in FIG. 3, when the mixed amount of quicklime exceeds 120% by mass, the amount of increase in strength sharply decreases and the amount of increase in strength hardly increases.

Therefore, when a mixture of oil-containing sludge and quicklime is used as a part of the raw material, the amount of quicklime mixed with the oil-containing sludge is preferably 30% by mass or more and 120% by mass or less of the oil-containing sludge water content.

When a mixture obtained by mixing quicklime with oil-containing sludge to reduce water content is used as a part of the raw material of the ingot for steelmaking, the raw material pH rises as the blending amount of the mixture increases. As a result, the raw material becomes highly alkaline, and even if dextrin is used as the binder, there is a possibility that a high-strength ingot for steelmaking cannot be obtained.

FIG. 4 shows the relationship between the amount of dextrin fortification (the amount of increase in strength due to dextrin) and the amount of the mixture of oil-containing sludge and quicklime when a mixture of oil-containing sludge and quicklime is added to the dust. The amount of increase in strength was determined by the above-mentioned granulation experiment.

As shown in FIG. 4, as the amount of the mixture of the oil-containing sludge and the quicklime increases, the amount of fortification of dextrin decreases, and when the amount of the mixture exceeds 60% by mass, the strength hardly increases.

Therefore, the mixing ratio of the mixture of oil-containing sludge and quicklime in the raw material is preferably 60% by mass or less with respect to the total raw material.

Next, the actions and effects of the above embodiment will be described.

According to the above-mentioned method for producing an ingot for steelmaking, the binder is selected from α starch and dextrin according to the pH of the raw material containing the iron-containing by-products generated in the ironmaking process, so that the physical properties generated in the ironmaking process are different. Even if an iron-containing by-product is used as a raw material, the strength-increasing effect of the binder can be ensured. Therefore, the strength of the ingot for steelmaking that has been molded into pellets or briquettes can be improved, and an ingot for steelmaking having good strength can be produced even if an iron-containing by-product generated in the ironmaking process is used. Therefore, the iron-containing by-products generated in the steelmaking process can be reused as a raw material for the ingots for steelmaking.

By further adding at least one of bentonite, molasses and pulp waste liquid as the binder, the strength increasing action can be improved and the fluidity of the binder can be improved.

By using a mixture of oil-containing sludge and quicklime as a part of the raw material, it is possible to produce a steelmaking ingot having good strength by using the oil-containing sludge that is difficult to reuse as a sintering raw material.

Further, by setting the mixing amount of quicklime in the mixture of oil-containing sludge and quicklime to 30% by mass or more and 120% by mass or less of the water content of the oil-containing sludge, the water content of the oil-containing sludge can be appropriately reduced, and the water content of the oil-containing sludge can be appropriately reduced. The strength increasing effect of the binder can be ensured.

Further, by setting the blending amount of the mixture of the oil-containing sludge and quicklime in the raw material to 60% by mass or less with respect to the total raw material, it is possible to suppress the increase in the pH of the raw material and secure the strength increasing action of the binder.

Hereinafter, this example and a comparative example will be described.

In order to confirm the effect of the present invention, the following granulation experiment was carried out.

First, 100 kg of the raw materials containing the raw materials shown in Table 2 were kneaded with a kneader for 2 minutes, and then molded with a briquette machine. During kneading, water was appropriately added while observing the state of the raw materials. The roll of the briquette machine has a diameter of 534 mm, a width of 124 mm, and a pocket size of 50 × 48 × 20 mm.

The prepared briquette was left to stand for 2 days, and then the crushing strength was measured. The crushing strength was measured with 10 briquettes under each condition, and each work piece (bricket) was evaluated by the average value, and a crushing strength of 0.5 kN or more was regarded as acceptable.

Table 2 shows the manufacturing conditions and crushing strength of each processed product.

No. 1 of this example. 1 to No. In No. 6, dextrin was used as a binder when the raw material pH was 10.5 or more, and dextrin or α-starch was used as a binder when the raw material pH was less than 10.5, and the crushing strength was all 0. It was 5 kN or more.

No. which is a comparative example. 7 and No. In No. 8, α-starch was used as a binder even though the raw material pH was 10.5 or more, and the crushing strength was lower than 0.5 kN. In addition, No. No. 8 could not be molded into a briquette shape.

No. which is a comparative example. In No. 9, the amount of quicklime in the mixture of oil-containing sludge and quicklime (sludge mixture) was as high as 185% with respect to the water content of the oil-containing sludge, and the crushing strength was lower than 0.5 kN even when dextrin was used as a binder. ..

No. which is a comparative example. In No. 10, the mixing ratio of the mixture of oil-containing sludge and quicklime in the raw material was as high as 70%. Similar to 9, the crushing strength was lower than 0.5 kN even when dextrin was used.

Claims (5)

For steelmaking, using iron-containing by-products generated in the steelmaking process as at least part of the raw material, this raw material and binder are mixed and processed into pellets or briquettes to produce ingots for steelmaking that can be used in the steelmaking process. In the method of producing agglomerates
Adjust the pH of the raw material to
When the pH of the raw material is less than 10.5 depending on the pH of the raw material, at least one of α starch and dextrin is used as the binder, and when the pH of the raw material is 10.5 or more. Is a method for producing an ingot for steelmaking, which comprises selecting the binder so as to use dextrin as the binder. The method for producing an ingot for steelmaking according to claim 1, wherein at least one of bentonite, molasses and pulp waste liquid is further added as a binder. The method for producing an ingot for steelmaking according to claim 1 or 2 , wherein the pH is adjusted by using a mixture of oil-containing sludge and quicklime as a part of the raw material. The method for producing an ingot for steelmaking according to claim 3, wherein the mixture of the oil-containing sludge and the quicklime has a mixed amount of quicklime of 30% by mass or more and 120% by mass or less of the water content of the oil-containing sludge. .. The method for producing an ingot for steelmaking according to claim 3 or 4, wherein the blending amount of the mixture of the oil-containing sludge and quicklime is 60% by mass or less with respect to the total raw materials.

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