JPWO2016024513A1 - Coke for metallurgy and method for producing the same - Google Patents

Abstract

The present invention relates to metallurgical coke capable of obtaining a high-strength coke having a pore structure that has not been known so far by adjusting the relationship between the maximum fluidity (MF) of the blended coal and the total amount of inert gas (TI). And a method for manufacturing the same. As a blended coal comprising a plurality of brands of coal, the total inert amount (TI) is 3.5 vol. % To 25.0 vol. Of coke obtained by dry distillation of coal blends exhibiting properties in the range of%, the highest fluidity (log MF) by the Gisela plastometer method in the range of 1.8 to 2.3 log ddpm, and the diameter in the coke The ratio of the total value of the cross-sectional areas of the pores having a circularity of 0.8 or more to the total value of the cross-sectional areas of the rough atmospheric holes in the rough air holes of 100 μm or more and 3 mm or less is 10% or more. [Selection] Figure 3

Description

  TECHNICAL FIELD The present invention relates to a metallurgical coke capable of obtaining high-strength metallurgical coke by adjusting the type and blending amount of coal contained in the coal blend, and a method for producing the same.

  Coke used as a reducing material and heat source in a steelmaking process using a blast furnace, etc., pulverizes multiple brands of raw coal and blends them at a predetermined ratio, and the resulting blended coal is charged into a coke oven and dry-distilled. It is manufactured by By the way, the blast furnace can realize a stable operation by maintaining the air permeability in the furnace in a good state. For that purpose, it is effective to use a high-strength metallurgical coke that is not easily pulverized in the furnace.

  A model proposed by “Castle” is known for the basic idea of blending coal to produce high-strength metallurgical coke (Non-patent Document 1). In this model, the constituent components of coal are divided into a fibrous part and a caking component. In other words, Castle reveals that the optimization of the strength of the fibrous portion and the amount of the caking component is important in producing high-strength coke.

  A typical coal blending technology in recent years has developed such a concept, and uses, for example, a coalification degree parameter and a caking property parameter. As the coal degree parameter, JIS M 8816's vitrinite average maximum reflectance (hereinafter abbreviated as “Ro”), coal volatiles, and the like are known. Further, as the caking property parameter, a maximum fluidity (hereinafter referred to as “MF”) measured by a fluidity test using a JIS M 8801 Gisela plastometer, or a JIS M 8801 dilatometer was used. The total expansion coefficient measured by the expansibility test is often used.

  As one of the caking properties parameters, there is a method based on CBI (Composition Balance Index) proposed by Shapiro et al. (For example, Non-Patent Document 2). This method applies the concept of concrete to raw coal blending. It is divided into an active component that softens and melts by heating coal macerals and an inactive component that does not soften and melt, and the active component is cemented. This is a method for estimating the coke strength by regarding the component (hereinafter referred to as “inert”) as an aggregate. In other words, when this concept is applied, the optimum amount of caking component is added according to the content of all inert components contained in the blended coal (hereinafter abbreviated as “total inert amount”, “TI”). It is considered that the coke strength can be increased by bringing the ratio of these two components (total inert amount and caking component) close to the optimum value.

  However, the optimum ratio of the inert component (inert) to the caking component for producing high-strength coke varies depending not only on the amount of the inert but also on the “ability to adhere the inert”. For example, if the adhesive strength of the caking component in the blended coal is weak, the required amount of the caking component increases accordingly. Therefore, it is considered that the ratio of the inert component and the caking component in this case is relatively larger than the ratio of the caking component required.

  In addition, it is thought that the magnitude | size of this adhesive force has correlation with the maximum fluidity MF which is an above-mentioned parameter | index of caking property. That is, it is considered that the caking component that is melted and has high fluidity has a high ability to adhere inert to the caking component that has low fluidity. In this regard, in Patent Document 1, the mutual relationship between the average reflectance Ro and the maximum fluidity MF and the total inert amount TI is examined, and when Ro and MF are set to predetermined values, the obtained coke strength is the value of TI. Accordingly, it is reported that the amount of inert when a parabola convex upward is drawn and the intensity becomes maximum varies depending on the size of MF. Patent Document 2 reports a method for estimating coke strength based on the properties of raw coal including MF and TI.

  The content of the inert component in the coal (total inert amount TI) can be measured by the method for measuring the microstructure of coal defined in JIS M 8816. In this method, coal pulverized to 850 μm or less is mixed with a thermoplastic or thermosetting binder to form a briquette, and the surface to be tested is polished, and then discriminated by optical properties and morphological properties under a microscope. The content rate of each fine structure component in the sample is a method in which the percentage of the number measured for each component is taken as a volume percentage. Using the content of the fine structure component obtained by the above method, the total inert amount (TI) is obtained by the following equation (1).

Total amount of inert (%) = Fuji knit (%) + miclinit (%) + (2/3) x semi-fuji knit (%) + mineral (%)-(1)
Here, all contents are vol. %.

  The mineral content can be calculated from the anhydrous base ash content and the anhydrous base total sulfur content using the Parr formula described in JIS M 8816.

  As described above, various attempts have been made to produce coke having a desired coke strength by adjusting the properties of the blended coal. However, in a suitable range of the blended quality that has been conventionally considered, the pore structure of the coke is It will be almost similar. Coke is a porous body having a porosity of about 50%, and the structure of the pores was expected to affect the coke strength, but a method for controlling the pore structure was not known.

JP 2007-246593 A JP 61-145288 A JP 2008-69258 A

“Journal of Fuel Association” by Castle, Vol. 26, 1947, p. 1-p. 10 “Proc. Blast Furnace, Cooke aven and Raw Materials”, Shapiro et al., Vol. 20, 1961, p. 89-p. 112 “J. Inst. Fuel”, Shapiro et al., Vol. 37, 1964, p. 234-p. 242 “Journal of Fuel Association” written by Okuyama et al., Vol. 49, 1970, p. 736-p. 743 “Iron and Steel”, Saito et al., Vol. 100, 2014, p140-147

  In recent coke production technology, in order to strongly adhere coal particles, emphasis was placed on ensuring the fluidity of coal, and optimization of both MF and TI has not been fully studied. . For example, in Non-Patent Document 3, the influence of Ro on the ratio between the optimum caking component and the amount of inert is examined, but the influence of MF is not examined. In addition, about patent document 1, the common logarithm value logMF (log ddpm) (henceforth "Gieseller highest fluidity (logMF)") of the maximum fluidity calculated | required by the Gieseler plastometer method of blended coal is 2.50. 2.55 log ddpm, TI 25-35 vol. Coke is manufactured under the condition of MF in a narrow range of MF. Also in Patent Document 2, the log MF and TI of the blended coal are log MF: 2.58 log ddpm, TI: 24.0 vol. % Or logMF: 2.69 log ddpm, TI: 24.7 vol. It is reported that high-strength coke can be produced only under the two types of conditions. In Patent Document 3, 2.83 log ddpm ≧ log MF ≧ 2.35 log ddpm, 35.6 vol. % ≧ TI ≧ 32.1 vol. % High-strength coke has been successfully produced.

  FIG. 2 shows the range of log MF and TI that has been studied in the conventional study. However, the influence on the coke strength of MF and TI under the conditions other than the range of FIG. 2 (2.90 log ddpm ≧ log MF ≧ 2.35 log ddpm, 36.0 vol.% ≧ TI ≧ 24.0 vol.%) Not reported. In addition, the relationship between the quality of such blended coal and the pore structure of the coke produced is not clear.

  The object of the present invention is to adjust the relationship between the maximum fluidity (MF) and the total inert amount (TI) of the blended coal to obtain a high-strength coke having a pore structure that has not been known so far. It is to propose a metallurgical coke and a method for producing the same.

In order to overcome the above-described problems of the prior art, the present invention proposes the following coke. That is, in the present invention, as a blended coal composed of a plurality of brands of coal, the total inert amount (TI) is 3.5 vol. % To 25.0 vol. Coke obtained by dry distillation of coal blends exhibiting properties in the range of%, maximum flow rate (log MF) by the Gisela plastometer method in the range of 1.8 to 2.3 log ddpm,
The ratio of the total value of the cross-sectional areas of the pores having a circularity of 0.8 or more to the total value of the cross-sectional areas of the rough atmospheric holes in the coarse air holes having a diameter of 100 μm or more and 3 mm or less in the coke is 10% or more. Is a metallurgical coke. Alternatively, the coke for metallurgy is characterized in that an average circularity of coarse air holes having a diameter of 100 μm or more and 3 mm or less in the coke is 0.35 or more.

Further, the present invention is a blended coal composed of a plurality of brands of coal with a total inert amount (TI) of 3.5 vol. % To 25.0 vol. Coke obtained by dry distillation of coal blends exhibiting properties in the range of%, maximum flow rate (log MF) by the Gisela plastometer method in the range of 1.8 to 2.3 log ddpm,
The ratio of the total value of the cross-sectional areas of the pores having a circularity of 0.8 or more to the total value of the cross-sectional areas of the rough atmospheric holes in the coarse air holes having a diameter of 50 μm or more and 200 μm or less in the coke is 10% or more. We propose metallurgical coke with the characteristics of Alternatively, a metallurgical coke is proposed in which the average circularity of coarse air holes having a diameter of 50 μm or more and 200 μm or less in the coke is 0.55 or more.

In the metallurgical coke according to the present invention,
(1) As the blended coal, the total inert amount (TI (vol.%)) And the maximum fluidity (log MF (log ddpm)) by the Gisela plastometer method are shown in FIG. 2.3, TI: 3.5), point b (log MF: 1.8, TI: 3.5), point c (log MF: 1.8, TI: 18.0), point d (log MF: 2. 0, TI: 25.0) and a material exhibiting a property within the range surrounded by the point e (log MF: 2.3, TI: 25.0),
(2) The maximum fluidity (log MF) of the blended coal by the Gisela plastometer method is the maximum fluidity (log MF) of each brand coal constituting the blended coal and the brand coal in the blended coal. A weighted average value calculated based on the constituent mass ratio,
However, it is considered as a more preferable means for solving the above-mentioned problem.

  Further, the present invention is a blended coal composed of a plurality of brands of coal with a total inert amount (TI) of 3.5 vol. % To 25.0 vol. %, The coal blend showing properties within the range of 1.8 to 2.3 log ddpm, the maximum fluidity (log MF) by the Gisela plastometer method is dry-distilled, and the coarseness of the diameter in the coke is not less than 100 μm and not more than 3 mm Among the pores, a coke having a ratio of a total sectional area of pores having a circularity of 0.8 or more to a total sectional area of the rough atmospheric pores of 10% or more is manufactured. A method for producing coke. Alternatively, a coke having a diameter of 100 μm or more and 3 mm or less in the coke having an average circularity of 0.35 or more is produced.

  Furthermore, the present invention is a blended coal composed of a plurality of brands of coal and has a total inert amount (TI) of 3.5 vol. % To 25.0 vol. %, The coal blend showing properties within the range of 1.8 to 2.3 log ddpm, the maximum fluidity (log MF) measured by the Gisela plastometer method is dry-distilled, and the coke has a diameter of 50 μm or more and 200 μm or less. Among the pores, a coke having a ratio of a total sectional area of pores having a circularity of 0.8 or more to a total sectional area of the rough atmospheric pores of 10% or more is manufactured. A method for producing coke. Or it is a manufacturing method of the coke for metallurgy characterized by manufacturing the coke whose average circularity of the rough atmospheric hole of diameter 50 micrometers or more and 200 micrometers or less in the said coke is 0.55 or more.

In the method for producing metallurgical coke according to the present invention,
(1) As the blended coal, the total inert amount (TI (vol.%)) And the maximum fluidity (log MF (log ddpm)) by the Gisela plastometer method are shown in FIG. 2.3, TI: 3.5), point b (log MF: 1.8, TI: 3.5), point c (log MF: 1.8, TI: 18.0), point d (log MF: 2. 0, TI: 25.0) and a material exhibiting a property within the range surrounded by the point e (log MF: 2.3, TI: 25.0),
(2) The maximum fluidity (log MF) of the blended coal by the Gisela plastometer method is the maximum fluidity (log MF) of each brand coal constituting the blended coal and the brand coal in the blended coal. A weighted average value calculated based on the constituent mass ratio,
However, it is considered as a more preferable means for solving the above-mentioned problem.

  According to the present invention configured as described above, it is possible to produce coke having a pore structure with a high degree of circularity, which has not existed conventionally under a simple concept of coal blending. In particular, high strength metallurgical coke can be produced using blended coal obtained by blending a large amount of coal other than raw coal that has been conventionally used. Therefore, according to the present invention, the range of selection of usable coal is widened, resource constraints are eased, and it becomes possible to manufacture and supply metallurgical coke with stable quality, and thus stably perform blast furnace operations and the like. Will be able to.

It is a graph which shows the range of logMF and TI of the blended coal suitable for this invention. It is a graph which shows the range of logMF and TI of the coal blend in a prior art. It is a microscope picture of coke obtained from conventional blended coal and low inert blended coal. It is a graph which shows the ratio of the circular pore contained in the coke obtained from the conventional coal blend and low inert coal blend. It is a microscope picture which shows the coke by the blended coal g and the blended coal f among the blended coals shown in Table 1 as an example. It is a cross-sectional image by X-ray CT of coke obtained from blended coal a and blended coal b among the blended coals shown in Table 1. It is a graph which shows the relationship between TI of the coal blend prepared so that logMF (log ddpm) may be 2.2-2.3, and the drum strength DI (150/15) of the coke obtained by dry distillation of the coal blend. . It is a graph which shows the relationship between TI of the coal blend prepared so that logMF may be 1.8-2.0 log ddpm, and the drum strength DI (150/15) of the coke obtained by dry distillation of the coal blend.

  FIG. 2 shows the relationship between the log MF (log ddpm) and the total inert amount TI (vol.%) Of the conventional blended coal, which has been used when producing metallurgical coke. In general, the structure of coke produced using blended coal that has been blended and adjusted under the prior art is a structure in which a solid material called inert is bonded with a paste-like material that is a caking component, as is also the case with concrete. It has become. That is, it is similar to the role of cement and aggregate in concrete and needs to contain some amount of inert components. On the other hand, the role of the caking component for adhering the inert component is also important. Therefore, conventionally, a high strength metallurgical coke has been produced by increasing the blending amount of the coal having a high maximum fluidity MF that greatly affects the coke strength, thereby increasing the MF of the blended coal.

  In this regard, for example, in the methods described in Non-Patent Documents 2 and 3, for coal having an average reflectance Ro of about 0.9 to 1.2%, the total inert amount TI is 20 to 30 vol. It has been reported that the coke strength tends to be maximum when the content is%, and the coke strength tends to decrease even if the total inert amount TI is larger or smaller than the range. The same tendency is also disclosed in Non-Patent Document 4, and the total inert amount TI is 20-30 vol. %, It is recognized that the drum strength of coke is maximized. Furthermore, the same tendency is also disclosed in Patent Document 1, and in the disclosed example, the total inert amount TI is 31 vol. % Shows the tendency of coke strength to become maximum. That is, according to the conventional knowledge, there is a recognition that it is difficult to obtain high-strength coke in the case of blended coal with a small total amount of inert. However, according to the research by the inventors, even if the coal blend is small in total inert amount, if the fluidity (Gieseller's highest fluidity) is appropriate, not only the coke strength does not decrease, but also normal It has been found that strength may be improved rather than blending.

  Based on the above findings, the inventors have found that the logarithm log MF (hereinafter simply referred to as “log MF”) of the highest Gieseller fluidity as blended coal and the total inert amount TI suitable for the present invention. The relationship was investigated. As a result, when coal blended by blending multiple brands of coal is dry-distilled to produce coke, the total inert amount TI is 3.5 to 25.0 vol. %, The maximum fluidity (log MF) according to the Gieseler plastometer method was found to be effective so as to exhibit the properties surrounded by the range of 1.8 to 2.3 log ddpm. A more preferable range of the total inert amount TI is 3.5 to 21.5 vol. %, More preferably 3.5 to 18.0 vol. %. In particular, it is preferable to use a blended coal having a TI of 3.5% or more and less than 15% from the viewpoint of effectively using coal having a low inert content that has not been used so far. Moreover, the more preferable range of the maximum fluidity (logMF) by the Gisela plastometer method in the above range is 1.8 to 2.2 log ddpm, particularly from the viewpoint of effectively utilizing low fluidity coal. 1.8-2.0 log ddpm.

Further, it was found that the more preferable method of the present invention is on and inside the pentagonal line shown in FIG. That is, in the method of carbonizing coal blended by blending multiple brands of coal and producing coke, as the blended coal, the total inert amount (TI vol.%) And the maximum fluidity by the Gieseler plastometer method ( log MF log ddpm) having a property within the range surrounded by the points in FIG. 1 (a, b, c, d and e below) is used.
Point a (log MF: 2.3, TI: 3.5), point b (log MF: 1.8, TI: 3.5), point c (log MF: 1.8, TI: 18.0), point d (Log MF: 2.0, TI: 25.0) and point e (log MF: 2.3, TI: 25.0)

  The structure of the coke produced by the method of the present invention is different from the coke structure similar to that of the conventional blended coal produced under the condition of being on and inside the square line in FIG. The component is coke which is mostly in the state of softened and melted and solidified.

  In such a blended coal composition with a small content of inert components (total inert amount), it has not been clarified by what factors the strength of coke obtained by dry distillation of the blended coal is conventionally controlled. It was. On the other hand, the inventors examined the coke generation mechanism when the content of the inert component of the blended coal is low. As a result, for coke with such a structure, the inert component can be sufficiently adhered even if the adhesiveness of the caking component, that is, the caking property is suppressed, and the coke strength due to the poor adhesion of the inert component which is a problem in the conventional compounding. It was found that there was no decline. In other words, it was found that the blended coal with a low inert content has little influence (fusion) of the inert component on the coke strength, but rather the coke pore structure has a stronger influence.

  In fact, the inventors have found that coal blends with a low content of inert components produce coke with a different pore structure, unlike conventional blends when coals with a high content of inert components are blended. I found out. For example, conventional blended coal (blended coal a, grade: Ro = 1.00%, log MF = 2.5 log ddpm, total inert amount = 34 vol.%) And low inert blended coal (blended coal b, grade: Ro = 1.00%, log MF = 2.2 log ddpm, total inert amount = 18 vol.%) Coke micrographs obtained by dry distillation under the same conditions (FIG. 3), compared with blended coal a, It was confirmed that pores close to a circle exist independently in blended coal b. This suggests that the coal blend b suppresses the growth and coalescence of the pores compared to the coke by the conventional blending, makes it difficult to form the connected pores, and the coke containing coarse defects is difficult to generate. It is suggested that some of the defects also affect the strength of coke.

  The inventors quantitatively evaluate the difference in the pore structure of coke between a conventional blended coal (for example, the above blended coal a) and a blended coal having a low total inert content (for example, the above blended coal b). A method for quantitatively evaluating the pore shape was studied.

As a method for evaluating the shape of the pores, there is a method of evaluating by the circularity calculated from the area of the cross section having the pores and the perimeter of the cross section based on the observation result of the cross section of the pores. The circularity is expressed by equation (2). This circularity has a value of 0 to 1, and the closer to 1, the closer to a circle.
Circularity = 4π ・ pore area / (pore circumference) ² ... (2)

  Examples of the method for observing the cross section of the pore include an X-ray CT tomography method and a method in which a coke sample is embedded in a resin, and then the cross section is polished and observed with a microscope. If an image of a coke cross section is obtained by such a method, the pore area and perimeter data observed using image analysis software can be obtained. In cross-sectional observation with an optical microscope, it is difficult to take a wide field of view for one image capture. Therefore, it is preferable to evaluate the circularity using observation images of three or more fields.

  At this time, it is necessary to appropriately set the pore size range for obtaining the circularity in accordance with the photographing range and resolution of each cross-sectional image. As described above, the coke strength is considered to be affected by the connected pores, and therefore it is preferable to evaluate the circularity of pores having a certain size or more. In order to define the size of the pores, the maximum ferret diameter is used in the present invention. The ferret diameter is the vertical and horizontal lengths of a rectangle circumscribing a certain figure, and the maximum ferret diameter is the length of the longest side of the rectangle circumscribing a certain pore.

  For cross-sectional images obtained by X-ray CT tomography, the inventors investigated all pores having a maximum ferret diameter of 100 μm or more and 3 mm or less as rough atmospheric pores, and for coke cross-sectional images obtained by an optical microscope. In this case, the observation magnification of the microscope was set to 200 times, and pores having a maximum ferret diameter of 50 μm or more and 200 μm or less were set as investigation objects as rough air holes. At this time, those in which the entire pores did not fit in the cross-sectional image were excluded from the evaluation targets because the maximum ferret diameter could not be obtained correctly.

  In addition, as an evaluation index of the pore structure of the whole coke, the average circularity of the coarse atmospheric pores and the pores having a circularity of 0.8 or more in the coarse atmospheric pores are defined as circular pores, and the total pore cross-sectional area of the coarse atmospheric pores The ratio of the cross-sectional area of the circular pores to the total was evaluated.

  FIG. 4 shows the result of examining the ratio of circular pores to the inert content in the blended coal by changing the blended composition of the blended coal, producing coke, obtaining the ratio of round pores from the X-ray CT image. As shown in FIG. 4, the coke prepared from the blended coal having a low inert blend had a large proportion of circular pores. From the above, it was found that by using a low inert blend, the growth and coalescence of pores are suppressed and circular pores can be easily formed as compared with coke produced by the conventional blend.

  Table 1 shows the average circularity, the ratio of the circular pores in the coarse air holes determined from the optical microscope observation by the above-described method, the average, along with the ratio of the circular pores in the rough air holes obtained by the X-ray CT shown in FIG. The measurement results of the circularity, the average quality of the blended coal, and the coke strength are also shown.

  4 and Table 1, it can be seen that the coke strength is as high as 82.8 or more when the ratio of circular pores in the rough atmospheric pores having a maximum ferret diameter of 100 μm or more and 3 mm or less obtained by X-ray CT is 10% or more. . In order to produce high-strength coke, the amount of inert (TI) and the maximum fluidity (log MF) are lower than those of the conventional coal blend shown in FIG. 2, that is, the total amount of inert (TI). Is 3.5 vol. % To 25.0 vol. %, The coal blend showing properties within the range of 1.8 to 2.3 log ddpm, the maximum fluidity (log MF) by the Gisela plastometer method is 10%, and the ratio of circular pores in coke is 10% It can be seen that the above is preferable. In addition, when the average circularity of rough air holes having a maximum ferret diameter of 100 μm or more and 3 mm or less obtained by X-ray CT is used as an index, it is found that the average circularity is preferably 0.35 or more.

In addition, when the pore structure is evaluated by observation with an optical microscope, the same tendency is shown. The larger the ratio of circular pores in rough atmospheric pores having a maximum ferret diameter of 50 μm or more and 200 μm or less, the higher strength coke can be obtained. It was found that coke with higher strength can be obtained as the average circularity of coarse pores having a diameter of 50 μm or more and 200 μm or less is larger.
Of the blended coals shown in Table 1, an optical micrograph of coke with blended coal g and blended coal f is shown as an example in FIG. Moreover, the X-ray CT observation result of the coke by blended coal a and blended coal b among the blended coals shown in Table 1 is shown in FIG.

  By using a blended coal with a low content of inert, it is conceivable that circular pores increase, and concentrated stress on the pores can be avoided by increasing the circular pores. Non-Patent Document 5 shows that when the pore diameter is uniform, the strength of the coke having a low degree of circularity of the pores is reduced, but this is because the stress is concentrated on the sharp part of the pores having a low degree of circularity. ing. Thus, it is known that stress is concentrated in pores with low circularity and lowers strength, and in coke produced by the method of the present invention, stress concentration is unlikely to occur due to increase in circular pores, and strength Will be higher. In the present invention, as a measure of increasing the number of pores having a high degree of circularity, the ratio of pores having a high degree of circularity occupying pores having a specific size or larger was used. The size and the expression method of the circularity may be changed as appropriate. For example, the circularity of pores of 50 μm or more may be investigated, and the median, mode, range, etc. of the examined circularity of the pores may be used as an index. In addition, the circularity threshold for defining the circular pores can be changed as appropriate.

  Thus, it has not been known in the past that a coal blend having a low total inert amount produces a coke having a microstructure different from that of a general coal blend, and this is a finding newly found by the inventors. Therefore, when reducing the total amount of blended coal through the use of low inert coal, the coal blending design is not performed based on the concept on the extension of the conventional blending technology, but under new blending standards. Design is considered necessary. The present invention proposes such a method.

  Based on such knowledge, the inventors have confirmed through experiments the preferred blending conditions for coal blends with a low content of inert components. As a result, the inventors found that the preferred range of total inertness (TI) and maximum fluidity (MF) is different between the conventional method and the method of the present invention, and arrived at the present invention. That is, according to the present invention, the total inert amount (TI) as the blended coal is 3.5 vol. % Or more 25.0 vol. %, The highest fluidity (log MF) according to the Gieseler plastometer method can be used to produce coke for high-strength metallurgy by using a material having a property within the range of 1.8 log ddpm to 2.3 log ddpm. I understood it.

  In particular, in the present invention, it has been found that high strength metallurgical coke can be produced preferably by setting it within a pentagonal line connecting the following points a to e in FIG. That is, point a (log MF: 2.3 log ddpm, TI: 3.5 vol.%), Point b (log MF: 1.8 log ddpm, TI: 3.5 vol.%), Point c (log MF: 1.8) log ddpm, TI: 18.0 vol.%), point d (log MF: 2.0 log ddpm, TI: 25.0 vol.%) and point e (log MF: 2.3 log ddpm, TI: 25.0 vol.%) ).

  Here, log MF (log ddpm) and TI (vol.%) Of the blended coal are weighted average based on the dry mass standard blending ratio of the coal from the log MF and TI of each coal constituting the blended coal. It is preferable to obtain. If the log MF and TI of each brand coal are measured in advance, the log MF and TI of the blended coal can be easily obtained by calculation, and it is not necessary to measure the log MF and TI of the blended coal every time the blend is changed. is there. Although TI is a volume fraction, since the density of coal has a small difference between brands, the TI obtained by actually measuring blended coal and the TI obtained by the above weighted average are almost the same. As for MF, there is an interaction between coals, so strictly speaking, there is a case where the additivity by coal mixing is not established, but for log MF, between log MF obtained by actually measuring blended coal and weighted average log MF Are known to be correlated.

  The reason why a high-strength metallurgical coke is obtained when such blending conditions are employed is considered as follows. That is, when the maximum fluidity MF is out of the pentagonal line in FIG. 1 and the range inside the pentagonal line, for example, in the upper region of the pentagon shown in FIG. Expands greatly, making it easy to make coarse pores and lowering the coke strength. On the other hand, the MF is lower than the conditions on and inside the pentagonal line shown in FIG. 1, that is, the region on the lower side of the pentagon is not only the adhesive force with respect to the total inert amount but also the adhesion between the caking components. The power is also insufficient. Therefore, even if the total inert amount TI is lowered, the coking strength is lowered because the caking components are also poorly bonded to each other. Further, in the region on the right side of the pentagon shown in FIG. 1, since TI is excessive with respect to MF, the strength decreases due to poor adhesion of inert. Furthermore, since the TI in the blended coal is extremely small in the left region of the pentagon shown in FIG. 1, the effect of improving the strength as a composite material of the caking component and the inert cannot be obtained, and the coke strength is lowered.

  The content of the inert component contained in the raw coal varies greatly depending on the coal brand, but roughly there is a certain tendency depending on the production area. For example, Australian coal and Canadian coal have an inert content of 30 vol. There are many coking coals exceeding 50%. Indonesian charcoal, New Zealand charcoal, and rice charcoal have an inert component content of 20 vol. % Of coking coal, and the content of inert components is 3 vol. Coking coal, which is about%, also exists. In the present invention, the production area of the raw coal is not particularly mentioned, but when carrying out the present invention, a large amount of coal having such a low amount of inert components is used. In addition, the blended coal may include additives such as a binder, oils, powdered coke, petroleum coke, resins, and waste.

<Example 1>
In this example, in order to investigate the influence of the MF and TI of the blended coal on the coke strength, the blended coal (1-6 of 1) with an average reflectance Ro constant at 1.00%, (2 1-8), (1-6 of 3), (1-6 of 4), (1-5 of 5) were subjected to dry distillation, and properties of the obtained coke were tested. The coal filling conditions were a constant of 8 mass% moisture and a charged bulk density of 750 kg / m ³ , and the pulverized particle size condition of coal was 3 mm or less of 100%. The carbonization conditions were a carbonization temperature of 1050 ° C. and a carbonization time of 6 hours. In the dry distillation test, a small electric furnace capable of simulating an actual furnace was used, and the property evaluation of coke obtained by cooling in a nitrogen atmosphere after dry distillation was performed according to JIS K 2151. A drum strength DI (150/15) of 150 rpm 15 mm index was used. In some tests, coke strength after CO ₂ reaction (CSR) in accordance with ISO18894 method was also measured.

  Table 2 shows the properties of the coal used in the dry distillation test. In Table 1, the average maximum reflectance (Ro) is a value measured according to JIS M 8816, and the Gieseller maximum fluidity (log MF) is the maximum fluidity (MF) measured according to JIS M 8801. A common logarithm value and a volatile matter (VM, dry base) are values measured according to JIS M 8812, and TI is a value measured according to JIS M 8816 and calculated by the equation (1). Tables 3 to 7 show the composition of each blended coal (dry standard blending ratio (mass%) of each coal) and the results of the dry distillation test. In the table, Ro, log MF, and TI are weighted average values obtained from Ro, log MF, and TI of each blended brand and the blend ratio of each brand. FIG. 7 shows the relationship between the TI and the drum strength DI (150/15) when the maximum coalescer flow rate of blended coal is adjusted to satisfy 2.3 log ddpm ≧ log MF ≧ 2.2 log ddpm. FIG. 8 shows the relationship between TI and drum strength DI (150/15) when the coalescer maximum flow rate of coal blender is adjusted to be 2.0 log ddpm ≧ log MF ≧ 1.8 log dpm. It was. The target value of the drum strength DI (150/15) was 82.7.

  The target value 82.7 of the DI (150/15) is as follows: Ro = 1.00% as a comparative example, and log MF = 2.50 within the square range shown in FIG. 2 where MF and TI are conventional blending examples. log ddpm, TI = 35 vol. % Is a result of measuring the drum strength DI (150/15) of the obtained coke by dry distillation of the coal blend prepared to be%, and is an example of typical conditions according to the conventional method. At least the examples suitable for the present invention have a larger DI than that of the comparative example, and a large blast furnace can be operated without problems if coke having such strength is used.

The results of Tables 3 to 7 are shown in FIGS. As shown in FIG. 7, in the range of 2.3 log ddpm ≧ log MF ≧ 2.2 log ddpm, 25.0 vol. % ≧ TI ≧ 3.5 vol. By preparing blended coal in the range of%, coke having a drum strength DI (150/15) of a target value or more can be produced. As shown in FIG. 8, when logMF = 2.0 log ddpm, 25.0 vol. % ≧ TI ≧ 3.5 vol. By adjusting to the range of%, a coke having a drum strength DI (150/15) exceeding the target value could be produced. Similarly, with logMF = 1.9 log ddpm, 21.5 vol. % ≧ TI ≧ 3.5 vol. %, And for logMF = 1.8 log ddpm, the TI is 18.0 vol. % ≧ TI ≧ 3.5 vol. By adjusting to the range of%, the drum strength DI (150/15) becomes coke having a target value or more. It was confirmed that the strength of coke after CO ₂ reaction (CSR) showed the same tendency as the drum strength DI (150/15). At this time, in the example in which the coke strength equal to or higher than the target value was obtained, the ratio of circular pores in the coarse atmospheric pores in the coke was 10% or more, and the average circularity of the coarse atmospheric pores was 0.35 or more. It is considered that a large number of coarse air holes having a high degree of circularity contributes to increasing the strength of coke under the condition that the inert content in the medium is low.

  From the above, it was confirmed that the relationship (range) between MF and TI of desirable blended coal is as shown in FIG. That is, by blending multiple types of brand charcoal so as to be on and inside the pentagonal line surrounded by points a, b, c, d and e in FIG. High strength coke for metallurgical furnaces can be manufactured. In this regard, according to the concept of blending by the conventional method, the lower limit value of log MF under suitable blending conditions is about 2.3, and it was expected that the strength would be lowered at log MF below that. On the other hand, in the method of the present invention, by setting the blending condition in which the total inert amount (TI) of the blended coal is decreased, the coke strength is increased on the contrary, even if the Gieseler maximum fluidity logMF is decreased. The result was not.

<Example 2>
In the same manner as in Example 1, coke was produced by preparing coal blends having different average maximum reflectivity Ro as Gieseler maximum fluidity log MF = 2.2 log ddpm, and the strength of the obtained coke was investigated. Tables 8 to 10 show the composition of each blended coal (dry standard blend ratio (mass%) of each coal) and the results of the dry distillation test. In the table, Ro, log MF, and TI are weighted average values obtained from Ro, log MF, and TI of each blended brand and the blend ratio of each brand. From Table 8 to Table 10, when the average reflectance Ro is 1.20%, 1.10%, and 0.95%, the average maximum reflectance Ro shown in Example 1 is 1.00%. Similarly, 25.0 vol. % ≧ TI ≧ 3.5 vol. %, It can be confirmed that coke with a high roundness of the rough air hole and a drum strength DI (150/15) of 82.7 or more can be obtained from the blended coal in the range of Ro, and Ro is within a suitable range of TI and logMF. Are not expected to have a significant impact.

  Tables 3 to 10 also include the ratio of circular pores in coarse atmospheric pores having a maximum ferret diameter of 50 μm or more and 200 μm or less determined by observation with an optical microscope, and the average circularity of coarse atmospheric pores having a maximum ferret diameter of 50 μm or more and 200 μm or less. Showed. In an example (Example) in which a coke having a drum strength DI (150/15) of not less than the target value (82.7) was obtained, the ratio of circular pores in the rough air holes having a maximum ferret diameter of 50 μm or more and 200 μm or less was 10%. As described above, the average circularity of the coarse air holes having the maximum ferret diameter of 50 μm or more and 200 μm or less is 0.55 or more, and the total inert amount (TI) is 3.5 vol. % To 25.0 vol. %, A coal blend exhibiting properties within the range of 1.8 to 2.3 log ddpm in the maximum flow rate (log MF) by the Gisela plastometer method is 10%, and the ratio of the circular pores in the coke is 10 It can be seen that the average circularity is preferably 0.55 or more.

  The method proposed in the present invention is basically applicable to a vertical metallurgical furnace such as a blast furnace, and can be applied to other blast furnace refining techniques.

Claims (12)

As a blended coal consisting of multiple brands of coal, the total inert amount (TI) is 3.5 vol. % To 25.0 vol. Coke obtained by dry distillation of coal blends exhibiting properties in the range of%, maximum flow rate (log MF) by the Gisela plastometer method in the range of 1.8 to 2.3 log ddpm,
The ratio of the total value of the cross-sectional areas of the pores having a circularity of 0.8 or more to the total value of the cross-sectional areas of the rough atmospheric holes in the coarse air holes having a diameter of 100 μm or more and 3 mm or less in the coke is 10% or more. Metallurgical coke characterized by. As a blended coal consisting of multiple brands of coal, the total inert amount (TI) is 3.5 vol. % To 25.0 vol. Coke obtained by dry distillation of coal blends exhibiting properties in the range of%, maximum flow rate (log MF) by the Gisela plastometer method in the range of 1.8 to 2.3 log ddpm,
The ratio of the total value of the cross-sectional areas of the pores having a circularity of 0.8 or more to the total value of the cross-sectional areas of the rough atmospheric holes in the coarse air holes having a diameter of 50 μm or more and 200 μm or less in the coke is 10% or more. Metallurgical coke characterized by. As a blended coal consisting of multiple brands of coal, the total inert amount (TI) is 3.5 vol. % To 25.0 vol. Coke obtained by dry distillation of coal blends exhibiting properties in the range of%, maximum flow rate (log MF) by the Gisela plastometer method in the range of 1.8 to 2.3 log ddpm,
A metallurgical coke characterized in that the average circularity of coarse air holes having a diameter of 100 μm or more and 3 mm or less in the coke is 0.35 or more. As a blended coal consisting of multiple brands of coal, the total inert amount (TI) is 3.5 vol. % To 25.0 vol. Coke obtained by dry distillation of coal blends exhibiting properties in the range of%, maximum flow rate (log MF) by the Gisela plastometer method in the range of 1.8 to 2.3 log ddpm,
A metallurgical coke characterized in that the average circularity of coarse air holes having a diameter of 50 μm or more and 200 μm or less in the coke is 0.55 or more.   As the blended charcoal, the total inert amount (TI (vol.%)) And the maximum fluidity (log MF (log ddpm)) by the Gisela plastometer method are the following points a (log MF: 2.3) in FIG. , TI: 3.5), point b (log MF: 1.8, TI: 3.5), point c (log MF: 1.8, TI: 18.0), point d (log MF: 2.0, TI) 55.0) and a point e (log MF: 2.3, TI: 25.0) are used. Metallurgical coke as described.   The maximum fluidity (log MF) of the blended coal by the Gisela plastometer method is the maximum fluidity (log MF) of each brand coal constituting the blended coal and the constituent mass ratio of the brand coal in the blended coal. The metallurgical coke according to any one of claims 1 to 5, which is a weighted average value calculated based on As a blended coal consisting of multiple brands of coal, the total inert amount (TI) is 3.5 vol. % To 25.0 vol. Carbonized coal showing properties in the range of%, maximum flow rate (log MF) by the Gisela plastometer method in the range of 1.8 to 2.3 log ddpm,
Coke in which the ratio of the total cross-sectional area of the pores having a circularity of 0.8 or more to the total value of the cross-sectional areas of the rough atmospheric holes is 10% or more among the rough atmospheric holes having a diameter of 100 μm or more and 3 mm or less in the coke. A method for producing metallurgical coke, characterized in that As a blended coal consisting of multiple brands of coal, the total inert amount (TI) is 3.5 vol. % To 25.0 vol. Carbonized coal showing properties in the range of%, maximum flow rate (log MF) by the Gisela plastometer method in the range of 1.8 to 2.3 log ddpm,
Coke in which the ratio of the total cross-sectional area of the pores having a circularity of 0.8 or more to the total cross-sectional area of the rough atmospheric holes is 10% or more among the rough atmospheric holes having a diameter of 50 μm or more and 200 μm or less in the coke. A method for producing metallurgical coke, characterized in that As a blended coal consisting of multiple brands of coal, the total inert amount (TI) is 3.5 vol. % To 25.0 vol. Carbonized coal showing properties in the range of%, maximum flow rate (log MF) by the Gisela plastometer method in the range of 1.8 to 2.3 log ddpm,
A method for producing metallurgical coke, characterized in that coke is produced in which the average circularity of coarse air holes having a diameter of 100 μm or more and 3 mm or less in the coke is 0.35 or more. As a blended coal consisting of multiple brands of coal, the total inert amount (TI) is 3.5 vol. % To 25.0 vol. Carbonized coal showing properties in the range of%, maximum flow rate (log MF) by the Gisela plastometer method in the range of 1.8 to 2.3 log ddpm,
A method for producing metallurgical coke, characterized by producing coke having an average circularity of 0.55 or more of coarse air holes having a diameter of 50 µm or more and 200 µm or less in the coke.   As the blended charcoal, the total inert amount (TI (vol.%)) And the maximum fluidity (log MF (log ddpm)) by the Gisela plastometer method are the following points a (log MF: 2.3) in FIG. , TI: 3.5), point b (log MF: 1.8, TI: 3.5), point c (log MF: 1.8, TI: 18.0), point d (log MF: 2.0, TI) : 15.0) and the point e (log MF: 2.3, TI: 25.0) are used. The manufacturing method of the metallurgical coke as described.   The maximum fluidity (log MF) of the blended coal by the Gisela plastometer method is the maximum fluidity (log MF) of each brand coal constituting the blended coal and the constituent mass ratio of the brand coal in the blended coal. The method for producing metallurgical coke according to any one of claims 7 to 11, wherein the weighted average value is calculated based on the above.