JP2006225411A - Manufacturing method of blast furnace coke - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for readily manufacturing blast furnace coke exhibiting a small variation in coke properties and having high strength. <P>SOLUTION: The manufacturing method of the blast furnace coke comprises dry-distilling a blended coal composed of less kinds of blended coals obtained by compounding at least 30 mass% of a specific raw material coal, where a highly expansive coal is incorporated with the blended coal and the compounded amount and the grain size of the highly expansive coal are adjusted according to the relation thereof with a clearance control value in the furnace chamber. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a method for producing coke for blast furnace, and in particular, blended coal in which a large amount of a specific brand of raw coal (hereinafter simply referred to as “coal” or “coal”) is blended to reduce the type of raw coal. We propose a simple method for producing high strength blast furnace coke with small variations in coke characteristics.

In the production of a general blast furnace coke, it is common to use blended coal obtained by blending 10 to 20 brands (types) of raw coal. In this way, the reason for blending small amounts of various types of raw coal into blended coal is convenient to adjust the blended coal so that the degree of coalification, fluidity, etc. becomes standard grade, This is because the coke quality such as strength, particle size, and ash is stabilized.
By the way, the coal used as coking coal has different characteristics (coalization degree and fluidity) depending on the country of origin, coal mine, coal seam, etc., so in order to produce coke with stable quality, it is important to control the mixing of raw coal Become. In particular, the reduction in coke strength causes deterioration of air permeability in the furnace during blast furnace operation and causes a blast furnace condition failure. Therefore, maintaining the strength of coke is extremely important when managing blended coal.

  However, coal as coking coal has been concentrated in recent years in price-competitive coal, and there is an urgent need to blend a large amount of coal of the same brand depending on the situation of the coal yard and entering the ship. In this case, it is necessary to use as much of the specified brand of coal as possible. Therefore, compared to blending many brands (types) of coal (coking coal) little by little, the quality of the blended brand of coal ( The coke strength is not only increased due to so-called quality fluctuations, but also makes it difficult to produce high strength coke. In order to avoid this harmful effect, it has been necessary to take measures such as increasing the average quality.

Conventionally, regarding the estimation of the strength of coke obtained from blended coal made by blending many brands of coking coal, for example, the blended coal is regarded as an aggregate composed of a combination of two types of coal, and the coke strength is accurately estimated. A method to do this has been proposed. However, this method does not assume the case where a large amount of a specific brand of coking coal is blended to reduce the number of blending species, and the quality measurement of a specific brand of coking coal blended in such a large amount is usually performed at every ship entry. The average quality at the time of entry can be measured accurately, but the quality of each entry varies, so stable operation (no clogging occurs when a large amount of coking coal of these brands is used. )), Or variations in coke quality, particularly variations in strength, are difficult to estimate accurately, and this has caused large variations in coke quality.
JP 49-255966 A

  Therefore, an object of the present invention is to overcome the above-mentioned problems that occur when a large amount of a specific brand of coking coal is blended in the blended coal. As a result, a coke for a blast furnace having a small variation in coke characteristics and a high strength can be obtained. Another object of the present invention is to propose a simple manufacturing method without causing operational troubles such as clogging.

  In research aimed at realizing the above objectives, the inventors have found that the cause of the variation in coke strength when coke is produced using coal blended with a large amount of a specific brand of coal is coke. In order to determine the presence of coarse pores in the interior and to reduce the coarse pores, a high-expansion coal, that is, a high-expansion coal is blended in the blended coal, and the blending amount thereof In addition, the inventors have obtained knowledge that it is effective to control the particle size within a suitable range, and have completed the present invention.

  That is, the present invention is a method of producing coke for blast furnace by dry distillation of blended coal with few blending species by blending 30 mass% or more of specific raw coal, and blending high expansion pressure coal into the blended coal. In addition, the present invention provides a method for producing coke for blast furnace, characterized in that the blending amount and particle size of the high expansion pressure coal are adjusted in relation to the clearance management value of the chamber furnace.

  In this invention, the said high expansion pressure coal uses what shows the expansion | swelling characteristic whose expansion pressure is 10 kPa or more, and the compounding quantity of this high expansion pressure coal is 3 mass%-10 mass in relation to a chamber furnace clearance control value. It is effective to use a material having a particle size of -3 mm and 60 to 90 mass%.

  As described above, according to the present invention, even when the blending ratio of a specific specific brand is extremely increased, the high expansion pressure coal having a relatively large particle size is blended, and the blending amount of the chamber furnace is By adjusting to a suitable range according to the control value determined so as to obtain a suitable clearance, variation in coke strength can be surely reduced, and operational troubles such as clogging can be avoided. Moreover, according to this method, in order to increase the coke strength, there is no need to bother raising the average quality of the blended coal, and a high-strength blast furnace that does not vary in quality by using a large amount of inexpensive specific raw coal. Coke can be easily produced without causing operational troubles.

  In general, blended coal used for producing blast furnace coke in a blast furnace is blended with a plurality of types of coal (coking coal) having different origins and characteristics. Since each of these coking coals is a natural product, even if they are of the same brand, there are usually variations in the structure and components, and various characteristics such as carbonization and fluidity.

  In this case, if the blending amount of at least one brand of the coking coal used in the blending design is increased, that is, if a large amount of a specific brand of coking coal is used, Even if the blending design is performed so that the characteristics such as the fluidity become the average characteristics, the characteristics such as the product coke strength may fluctuate greatly due to the variation.

  In general, when the blending ratio of a specific brand of coking coal is increased in coking coal blending design, even if the coke strength varies, the variation can be eliminated to some extent by combining with other brands of coal. However, the effect of suppressing such variation becomes critical when the blending ratio of the specific brand alone is about 30 mass%, and if it exceeds this, coke characteristics such as strength are obtained even if it is combined with other brands of raw coal. Tend to vary rapidly. This tendency is unavoidable due to the variation derived from natural products, regardless of whether a large amount of coking coal of a specific brand or coking coal close to the average grade is used. In order to avoid variations, the amount of use must be limited.

  The inventors tried to investigate the cause of the above-mentioned variation in coke characteristics when a large amount of a specific brand of coking coal was blended, and many of them are rough air holes in the coke. Was found to be due to the generation.

That is, the inventors measured the total pore volume in coke by the apparent density measurement method, while measuring the pore volume of 200 μm or less by the mercury intrusion pore size distribution measurement method. Was quantified as the amount of coarse pores, and the relationship between the amount of coarse pores in coke and the strength of coke was investigated. As a result, it was found that the variation in coke strength also increased with the increase in the amount of coarse atmospheric pores in the coke.
This means that when the blending ratio of the specific brand raw coal increases, for example, there may be a portion where the inert component (inactive component: Fujinit or semi-Fujinit) is locally unevenly distributed in the blended coal, This is considered to be caused by the local deterioration of the fusibility during coking, and for this reason, coarse voids (pores) remain as they are.

  Therefore, in the present invention, as a method for preventing the deterioration of the fusibility at the time of coking and preventing the residual coarse pores, when blending a large amount of a specific brand of coking coal as a blended coal, In addition, high expansion pressure coal having an expansion characteristic of an expansion pressure of 10 kPa or more is blended together. As a result, in the blending of raw coal of the present invention using such a high expansion pressure coal having an expansion pressure of 10 kPa or more, the portion of the high expansion pressure coal is full and the portion of the rough air holes is sealed, and the number of the rough air holes Was found to be significantly reduced. The reason for this is that in the case of high expansion pressure coal with an expansion pressure of 10 kPa or higher, the melting and resolidification temperature is high, so other coals resolidify and become semi-coke and the pore structure is being completed. This is because it will melt and expand. That is, when this high expansion pressure coal melts and expands with a time shift, it exerts an action of closing and reducing the rough air holes caused by the coal that melts in advance.

And as for the said high expansion pressure coal used in this invention, using the thing with an average particle diameter (particle size) as large as possible means making the temperature of melting and resolidification of this high expansion pressure coal higher temperature side. This is considered to further enhance the effect of blocking the rough pores.
It is preferable to control the particle size within a suitable range in consideration of the blending amount and the relationship with the chamber furnace clearance described later.

  For example, according to the inventors' research, in order to reduce the above-mentioned rough atmospheric pores (voids) in order to obtain a predetermined coke strength while ensuring the clearance necessary to smoothly extrude the coke cake from the chamber furnace. The high expansion pressure coal is considered to be effective to contain 3 to 10 mass% of a size (particle size) containing a size of -3 mm at a rate of about 60 to 90 mass%. For example, in the case of blending the high expansion pressure coal having a mass of about -3 mm and about 60 mass%, that is, having a relatively large particle size, it has been found that it is effective to adjust the blending to at least about 3 mass%. This is because when the particle size of the high expansion pressure coal becomes too large (coarse) (when -3 mm is small), the coke cake expands too much and tends to clog in the chamber furnace during extrusion. . In other words, it was found that the particle size and blending amount of this coal need to be determined from this point of view, that is, according to the clearance management value of the chamber furnace (generally securing about 13 mm or more with a furnace width of 190 mm). .

  That is, in the present invention, if the blending of high expansion pressure coal having a small particle size (a large amount of −3 mm) is suppressed and the blending amount is adjusted to a suitable amount according to the clearance management value, coke is obtained. It is effective in reducing the rough atmospheric pores (voids) in the inside, and as a result, variation in quality (coke strength) when a large amount of specific brand raw material coal is blended can be suppressed to the same level or lower than before. Become.

FIG. 1 is a diagram showing the relationship between the coal particle size (the proportion of coal powder having a particle size of −3 mm) and the expansion pressure, and the proportion of the −3 mm size of the high expansion pressure coal is about 65 mass% to 75 mass%. In other words, when the high-expansion pressure coal becomes more fine, the expansion pressure becomes low and stable, and the clearance of the chamber furnace is large enough for cake extrusion (≧ 13 mm) to ensure clogging. Will be able to prevent. However, since the expansion pressure is insufficient, the sealing action of the rough air holes is diminished, and the strength of the coke obtained using this as the raw coal is reduced. In other words, when blending this high expansion pressure coal, it is important to control the blending amount as well as the coal particle size at the same time, particularly in relation to the clearance management value of the chamber furnace.
Also, as can be seen from the above, the expansion pressure of the coal blend greatly affects the particle size of the high expansion pressure coal to be blended, especially when the proportion of the high expansion pressure coal having a particle size of -3 mm is reduced, In other words, the strength of the coke obtained is increased by making the high expansion pressure coal as coarse as possible.

Therefore, the inventors also experimented how to adjust the particle size (ratio of −3 mm) of the high expansion pressure coal and the blending amount thereof with the in-furnace clearance management value. As a result, as shown in FIG. 2, it was found that the relationship between the particle size and the blending amount of the high expansion pressure coal was established according to the clearance between the coke cake made by the dry distillation test and the furnace wall.
From this, the blending ratio of the high expansion pressure coal can be roughly determined by the preset coke strength, and therefore, the particle size of the high expansion pressure coal to ensure a sufficient clearance control value under the blending ratio. In order to determine the size, what is necessary is just to adjust the coarsening to the maximum possible particle size under the correlation shown in FIG. When adjusted in this way, the coke strength can be stably maintained at a high level, and at the same time, stable extrusion of the coke cake can be ensured at all times.

However, when this high expansion pressure coal is blended in a large amount (≧ 10 mass%) or when the particle size is extremely coarse (when -3 mm is less than 60 mass%), high strength coke can be obtained, but in the coke oven. In this case, the coke cake expands too much and the clearance is lost, which may cause operational troubles such as clogging.
That is, as shown in FIG. 2, in the present invention, when blending high expansion pressure coal, in order to ensure a clearance management value of more than 13 mm for ensuring stable operation of the coke oven, a ratio of -3 mm When the high expansion pressure coal having about 60 mass% or more is blended by about 3 mass%, favorable results are always obtained. On the other hand, for example, if a relatively fine high expansion pressure coal having a ratio of -3 mm of 80 mass% is used, the blending amount may be adjusted to about 7 mass%.

Example 1 (Usage example of high expansion pressure coal)
Hereinafter, the present invention will be described in more detail with reference to examples.
(1) Using coals A to D having the characteristics shown in Table 1 and other coals, blended coals (1) to (17) having the blends shown in Table 2 were prepared, and moisture content was obtained using a humidity control coal facility. was adjusted to 6%, then heated carbonized the coal blend (Sonyusumi) (adjustment to a bulk density 0.78t / m ³⁾ carbonization chamber volume 41.3 m ³ of charged into a coke oven to, Coke was fire extinguished with a CDQ facility and sampled to obtain a specimen. The following cold strength tests were performed on the obtained specimens. In addition, coking coals A and B in Table 1 are used as plain coking coal added to the blended coal, and coking coals C and D are examples of brands used as high expansion pressure coal, both of which are obtained from Australian coal. Coking coal that can be.
The cold strength test was based on a tumbler test TI (400/6).

  Moreover, the test of the expansion pressure of raw coal used the expansion pressure measuring apparatus shown in FIG. In this test, the coal to be measured was pulverized and adjusted to a particle size of 1 to 3 mm. Then, the pulverized coal was put in a carbon crucible of φ50 × 70 mm and heated in an electric furnace at 700 ° C. for 1 hour. The carbon dioxide is heated to 1000 ° C at a rate of temperature rise of 1000 ° C / min and dry-distilled. During the dry-distillation, the pressure difference from the atmospheric pressure is measured at a quarter of the diameter, and the maximum gas pressure is taken as the expansion pressure. This was defined and used. When measured at the center of the crucible, cracks and the like were generated due to the expansion and contraction of coal, making measurement difficult. Therefore, the gas pressure was measured at the above position (1/4 of the diameter).

  The coal blends (1) to (17) shown in Table 2 are A, B coal used as the specific brand coal blended therein, B coal and C, D coal used as the high expansion pressure coal, and other coals. Using 5 to 6 coals with a volatile content of 21-37% and a maximum fluidity MF1.8-3.6 (log ddpm), a weighted average volatile content of 29% ± 0.2%, MF2.5 It is adjusted to be ± 0.02 (log ddpm). The expansion pressure of other coals is 3 kPa or less.

  About this combination charcoal (1)-(17), it operated for 5 days using the same coal blend, and measured the coke intensity | strength 6 times a day about the obtained product coke. And the coke intensity | strength was 84.3-84.5 in TI (400/6) as the average value for the 5 days, and was substantially constant.

  Figure 4 shows the difference in coke strength (tumbler strength) (σTI (400/6)) for blended coals (1) to (16) with different blending ratios of coal A or coal B. It shows the relationship with the blending amount. As is clear from this figure, blended coals (1) to (4) using Coal A without adding high expansion pressure coal are marked with ◇, and blended coals (5) to (8) using Coal B are □ As shown in Fig. 5, it has been found that the tumbler strength deviation (σTI) increases, and in order to keep the lower limit value of the coke strength constant, it is necessary to set the average value of the coke strength high.

  On the other hand, blended coal (9) to (12) using coal A containing 5 mass% or more of C or D coal, which is a high expansion pressure coal, and (13) to (17) using coal B are shown. In this case, even when 30% by mass or more of Coal A or Coal B was blended, the deviation in coke strength hardly increased. And in what mix | blended less than 30 mass% of Coal A or Coal B, the effect has stopped to the extent that some effects are produced by addition of 5 mass% or more of Coal C and Coal D.

FIG. 5 shows the relationship between the sample material sampled in the cold strength test of the above blended coal (the blended coals (1) to (17)) and the tumbler strength deviation (σTI). The total pore volume was obtained by measuring the apparent density of the sampled coke sample material by the mercury method and calculating the total pore volume by setting the true specific gravity to 1.9 g / cm ³ . Distribution was also measured, and the amount of pores of 200 μm or less was measured by a mercury intrusion method, and the total amount of pores subtracted from the amount of pores of 200 μm or less was defined as the rough amount of pores.

  As a result, in the case of coal blends (1) to (8) without adding high expansion pressure coal (◇ □), the amount of coarse air pores increased by blending more than 30 mass% of coal A or coal B, and coke strength The deviation of increased. On the other hand, in the case of adding 5 mass% C or D coal, which is high expansion pressure coal (◆ ■), even if adding 30 mass% or more of Coal A or Coal B, the amount of coarse pores hardly increases. The deviation of coke strength did not increase and the variation could be suppressed.

  FIG. 6 shows the relationship between the particle size of D coal, which is high expansion pressure coal, and the amount of coarse atmospheric pores for blended coals (16) and (17) in which the particle size of D coal, which is high expansion pressure coal, is changed. In any blended coal, when the particle size of D coal, which is a high expansion pressure coal, is large (the ratio of −3 mm decreases), the amount of coarse air holes decreases. Especially in blended coal (17), when the blending ratio of high expansion pressure coal is as small as 3 mass%, when blending 5 mass% of high expansion pressure coal and -3 mm is less than 75%, blending amount (16) and It was found that the amount of coarse pores was almost the same, and variation in coke strength could be suppressed.

Example 2 (Adjustment example of particle size and blending amount of high expansion pressure coal)
(2) Next, the clearance measurement of the said chamber furnace when the high expansion pressure coal which consists of C charcoal and D charcoal shown in Table 1 is mix | blended in the ratio shown in Table 2, and it operate | moves like Example 1. The results are shown in FIG. Table 3 shows the measurement results of the measured clearances for cases (8), (16), and (17) in which the blending ratio and particle size were changed when blending D charcoal.
From these results, when C and D coals are blended, the average value shows a slight decrease, but in either case, the measured clearance value is kept above the control limit (ie within the control range). I found out that I can operate. In particular, in the case where the blending ratio of D charcoal was 3%, the particle size of D charcoal was adjusted to be coarse (less -3 mm%) (62 mass%), and the clearance result was almost equivalent to that of case (16).

  The technology according to the present invention can be applied not only to coke used in a blast furnace in an iron factory, but also to coke production technology that can be used in the general metallurgical industry.

It is a graph which shows the relationship between the coal particle size and expansion pressure of high expansion pressure coal. It is a graph which shows the result of having measured the clearance between a coke cake and a furnace wall. It is a schematic diagram of an expansion pressure measuring device. It is a figure which shows the relationship between the mixing | blending ratio of a specific brand, and (sigma) TI (6/400). It is a figure which shows the relationship between the amount of coarse atmospheric pores in coke, and (sigma) TI (6/400). It is a figure which shows the relationship between the particle size of D charcoal, and the amount of rough atmospheric pores. It is a graph which shows the clearance measurement result of a chamber furnace.

Claims (4)

In the method of producing coke for blast furnace by dry distillation of blended coal with few blending types by blending 30 mass% or more of specific raw coal, high expansion pressure coal is blended in the blended coal, and this high expansion A method for producing coke for a blast furnace, characterized in that the amount and particle size of the compressed coal are adjusted in relation to the clearance management value of the chamber furnace. 2. The method for producing coke for blast furnace according to claim 1, wherein the high-expansion pressure coal uses an expansion pressure of 10 kPa or more. The method for producing coke for a blast furnace according to claim 1 or 2, wherein a blending amount of the high expansion pressure coal is adjusted within a range of 3 mass% to 10 mass%. The blast furnace coke according to any one of claims 1 to 3, wherein the high expansion pressure coal has a particle size of -3 mm and contains 60 to 90 mass%. Method.

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