JP2725595B2 - Blast furnace charging method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for charging a blast furnace raw material which provides a charge distribution as set in a central portion of a blast furnace and enables early recovery of a furnace condition.

[0002]

2. Description of the Related Art In the operation of a blast furnace, it is important to smoothly reduce and melt an iron source material and to stably produce an imposed amount of pig iron over time.

[0003] The inside of a blast furnace is separated from a region where the iron source material is softened and melted by raising the temperature (hereinafter referred to as a "cohesive zone"), and upper and lower portions thereof (hereinafter referred to as "furnace upper portion" and "furnace"). The lower part is markedly different. That is, in the upper part of the furnace, the iron source material exists in a solid state together with the coke, and is reduced and heated by the gas which descends downward and rises through the void. Therefore, the stabilization of the gas flow distribution in the upper part of the furnace and the securing of effective contact between the iron source material and the gas are important points of control for improving the reaction efficiency and the melting efficiency of the blast furnace.

On the other hand, in the lower part of the furnace, hot metal and slag generated by the reduction and melting of the iron source material are dropped downward through the gap of the coke packed bed, and the gas blown from the tuyere is filled with coke. It rises while spreading toward the furnace center through the gap of the layer. Also, the coke at the bottom of the furnace is
Most of it moves toward the tuyere combustion zone and disappears,
A part of the material stays in the central part of the furnace, where the logistics are very slow, and becomes so-called "core coke". This core coke directly corresponds to the "dead zone" in the logistics field in the blast furnace, and is not involved in the supply of heat by combustion or the generation of reducing gas, and thus directly contributes to the pig iron production process. Although not important, it has important implications for the stable operation of blast furnaces.

[0005] That is, when the core coke is viewed from the tuyere inside the furnace, it is located in the back of a combustion zone (hereinafter, referred to as "raceway") in front of the tuyere. Then, the flow path of the gas generated in the raceway narrows, and the blowing pressure increases. This phenomenon causes irregular coke lowering in the lower part of the furnace and, in severe cases, blow-through, which hinders stable operation. Therefore, in many blast furnaces, coke sampling is performed at the time of a cold wind to periodically monitor the state of the core coke.

[0006] The coke temperature detected by the measurement of the degree of graphitization of the collected coke is the most important index for evaluating the state of the core coke, and it has been empirically known that a decrease in the coke temperature leads to a malfunction in the furnace condition. . In other words, if the core coke temperature is maintained at about 1400 ° C. or higher, molten iron slag dripping from the cohesive zone can pass through the core coke, but if the temperature is significantly reduced, the molten iron slag becomes , The fluidity deteriorates and stays in the voids of the core coke,
The air permeability of the core coke is impaired. The following can be considered as a cause of such a decrease in the core coke temperature.

[0007] (a) The coke powder generated by the reduction of the strength of the charged coke during the unloading in the furnace and the powder generated in the raceway accumulate in the periphery of the furnace core coke, and Heat supply to the core coke is obstructed.

[0008] (b) Low-temperature unreduced material enters the furnace core coke due to slip or the like, and the amount of direct reduction, which is an endothermic reaction, rises rapidly, and the temperature of the molten iron slag dripping at the lower part of the furnace decreases.

As described above, in order to produce pig iron stably and efficiently in blast furnace operation, the important points for controlling the state distribution in the blast furnace are as follows.

In the upper part of the furnace, fluctuations in the gas flow distribution in the furnace are eliminated, and deterioration of the contact efficiency between the gas and the iron source material is prevented.

In the lower part of the furnace, the core coke temperature is maintained at a high level.

Next, problems of the above-mentioned conventional method for controlling the state distribution in the blast furnace will be described.

First, the gas flow distribution in the furnace at the upper part of the furnace is determined by the distribution of the charge in the radial direction of the furnace, specifically, the weight ratio (ore / coke) of iron source material (hereinafter also referred to as "ore") to coke. ,Less than,
It is formed in accordance with the air permeability distribution in the furnace radial direction which is determined by the furnace radial direction distribution of the particle size of the charged material and "O / C". For this reason, conventionally, in a blast furnace equipped with a bell-type charging apparatus, the O / C is controlled by independently controlling the setting positions of the movable armor for ore charging and coke charging.
In the furnace in the radial direction (hereinafter simply referred to as “O / C distribution”). Also, in a blast furnace equipped with a bellless charging device, the O / C distribution is controlled by adjusting the tilt angle (the angle between the distribution chute and the vertical line) of the distribution chute.

However, in the control based on the setting position of the movable armor of the bell-type blast furnace, part of the surface layer of coke already deposited in the furnace collapses due to the impact energy held by the ore when the ore is charged. Is known to flow into the furnace center together with the ore and form a mixed layer with coke in this part (for example, Kajiwara et al .: Trans. ISIJ, 23, 1983, p. 1045). This phenomenon varies depending on various factors such as ore charging amount, ore particle size composition, movable armor position, deposition angle of coke packed bed, stock level, gas flow distribution, and the like. Therefore, it is difficult to quantitatively predict the formation of the mixed layer, especially the O / C distribution near the center of the furnace (hereinafter, referred to as the O / C distribution).
The control accuracy of "O / C distribution in the center of the furnace" is significantly deteriorated.

On the other hand, in the bellless type blast furnace, if the tilt angle of the distribution chute is set to be small, the raw material can be charged closer to the furnace center than the above-described control by the movable armor, so that the controllability of the O / C distribution is improved. Better than a blast furnace. However, if the deposition angle between the packed bed surface and the horizontal plane after charging coke exceeds 15 °, the coke layer collapses when charging the ore, as in the case of control by movable armor, and the O / C distribution in the center of the furnace Controllability decreases.

Further, in the above-described existing charging apparatus, most of the charged raw material falls into the peripheral portion of the furnace at the time of charging, and then flows toward the center of the furnace and is deposited. During this inflow movement
The charged material undergoes re-classification on the deposition slope of the (uppermost layer of the furnace interior charge), and a radial distribution of particle size (hereinafter referred to as “particle size distribution”) is found in the packed bed after deposition. Occurs. This re-classification phenomenon also changes due to various factors like the coke layer collapse. Particularly, the raw material deposited near the center of the furnace is greatly affected by the influence, and the particle size varies greatly.

Therefore, in the above-mentioned conventional method, the control accuracy of the charge distribution near the center of the furnace is low, and it is not easy to stabilize the gas flow distribution.

In the invention of Japanese Patent Publication No. 64-9373, coke is directly charged into the center of a blast furnace by using a dedicated charging chute provided on a separate route from an existing charging device such as a bell type or a bellless type. O / C at the center of the furnace
To increase the so-called "central flow". According to this method, compared to the case where only an existing charging device such as a bell type or a bellless type is used, the furnace central portion O /
The controllability of the C distribution is significantly improved. If the amount of direct coke charged into the furnace center is sufficiently large to prevent the ore charged from the existing charging device from flowing into the furnace center, the furnace center O / C can be reduced to zero. And there is no room for change. Therefore, fluctuations in the gas flow at the center of the furnace are suppressed. However, part of the coke constituting the sedimentary layer at the center of the furnace is coke charged from the existing charging equipment. Inevitable. Further, since the O / C of the furnace central portion is greatly reduced, the gas rising in the central portion of the furnace does not contribute to the reduction and dissolution of the iron source, and the reduction gas utilization efficiency is reduced and the fuel ratio is deteriorated. .

In the invention of Japanese Patent Application Laid-Open No. 61-227109 disclosed by the present applicant, not only a part of the charged material, that is, coke, but also ore is charged into the center of the furnace from a dedicated charging route. Accordingly, a method is adopted in which the variation in O / C and the particle size of the deposited particles is reduced not only in the central part of the furnace but also in the entire radial direction in the furnace. However, in this method, since the charging of the raw material into the furnace center is performed by layered charging of ore and coke, as in the peripheral portion, the deposition range and the deposition angle of the centrally charged raw material fluctuate, The local control accuracy of the furnace center O / C becomes insufficient. For this reason, there is a problem that the degree of improvement of the reducing gas use efficiency in the central portion is low, and the fuel ratio cannot be sufficiently reduced.

Further, Japanese Patent Application Laid-Open No. 1-29-1990 disclosed by the present applicant has been disclosed.
In the invention of Japanese Patent No. 0708, prior to charging ore and coke in layers, a raw material in which ore and coke are mixed in a predetermined weight ratio in advance is charged into the center of the furnace, so that the desired O / The method of giving C is adopted.
In this method, since the center O / C of the furnace can be almost completely maintained at the control target, the gas flow distribution in the center of the furnace in the upper part of the furnace is stabilized, and the heat exchange and the reaction between the gas and the ore are promoted. Thereby, the reducing gas use efficiency is improved, and the fuel ratio can be reduced.

[0021] However, in order to improve the reducing gas utilization efficiency of the furnace center portion, the furnace center portion O / C, i.e. the mixing ratio by weight of the center charging raw material mixture (hereinafter, referred to as "O _M / C _M") and It is necessary to control the central gas flow rate to a high value close to the O / C of all the charged materials. Then, the amount of reduced / molten iron in the central part of the furnace increases, so it is difficult to increase the temperature of the molten iron flowing into the core coke. Moreover, CO ₂ in the gas increasing the bulk band center is also increased, coke fed to the furnace core, strength and grain size undergo gasification reaction with CO ₂ is deteriorated, the deadman coke ventilation , Liquid permeability is impaired. For this reason, there is a problem that heat exchange between the furnace core coke and the molten iron or gas is poor, and it becomes difficult to maintain the furnace core coke at a high temperature.

The core coke temperature is an important control item in the operation of the blast furnace, and various methods have conventionally been used to prevent the core coke temperature from lowering.

For example, it is possible to reduce the amount of powder generated by suppressing the deterioration of coke strength due to the reaction with CO ₂ gas, or to reduce the amount of powder generated at the raceway by controlling the tuyere front temperature and the tuyere wind speed to appropriate values. By reducing the amount, etc., the area from the tuyere front combustion zone to the furnace core and the permeability of the core coke are maintained well, and the heat exchange between the high temperature gas generated in the tuyere front combustion zone and the core coke is promoted. The method is adopted.

In the invention of Japanese Patent Publication No. 64-9373, as described above, coke is charged into the center of the furnace to increase the amount of coke deposited in the center of the furnace, thereby reducing the ore abundance in that portion. ing. Thus, CO ₂ gas generated in the ore reduction less coke present in the furnace center portion, CO ₂
There is no deterioration in strength due to the reaction with the gas, and the accompanying reduction in particle size does not occur. On the other hand, the coke flowing into the furnace core utilizes the characteristic that coke is mainly charged near the center axis of the furnace at the top of the bed, and coke that does not suffer from deterioration in strength or particle size is supplied to the furnace core. Will be done.
Therefore, in the present invention, it is considered that the permeability of the furnace core coke is ensured, and the heat exchange between the high temperature gas generated in the tuyere combustion zone and the furnace core coke is promoted.

However, as described above, the accumulation of powder generated in the raceway around the furnace core and an increase in the amount of molten slag accumulated due to the deterioration of the fluidity of the molten iron slag cause the air permeability of the portion to deteriorate and the gas to the furnace core to be removed. When the heat supply to the furnace is hindered and the core coke temperature drops, the movement of the core coke is extremely slow,
Since it takes a considerable amount of time to recover the state of the core coke by the replacement, it is difficult to quickly restore the state by the method of the present invention.

[0026]

SUMMARY OF THE INVENTION It is an object of the present invention to stabilize the gas flow distribution near the center of the furnace at the upper part of the furnace by providing the O / C at the center of the furnace as set, thereby improving the reaction efficiency and A method for charging blast furnace raw materials that can improve melting efficiency, quickly recover the temperature of the reduced core coke in the lower part of the furnace, maintain it at a high level, and stably produce pig iron without deteriorating the fuel ratio. Is to provide.

[0027]

SUMMARY OF THE INVENTION The gist of the present invention is to provide a method for charging a blast furnace raw material in which coke and an iron source raw material are alternately charged into the furnace in layers from the furnace top. And the method of charging the raw material for the blast furnace.

1. Mixing a part of coke and a part of iron source material in a weight ratio satisfying the following equation.

[0029] 0.05 × (O / C) ≦ (O M / C M) ≦ 0.30 × (O / C) ··· However, O: furnace interior entrance total iron source material weight, O _M: iron mixed raw material the source material weight C: furnace interior entrance total coke weight, C _M: coke weight 2. the above mixed raw material in the mixed raw material, prior to charging the coke loading and iron source materials or charging of the iron source material, Prior to
Charge in the center of blast furnace.

Usually, in the blast furnace operation, a bell type charging device or a bellless type charging device provided on the furnace top is used. Coke and an iron source material are alternately charged using this normal charging device, and are deposited in a layered manner in a furnace. Hereinafter, the raw material charged in layers by the normal charging device is referred to as “normal charging iron source” or “normal charging coke”.

Although the main components of the iron source material are sinter and iron ore, in the method of the present invention, one of the coke and the iron source material is used.
A part of the charge per charge is used as a mixed raw material to be mixed at the weight ratio shown in the above formula. Then, this mixed raw material is mainly charged into the center of the furnace.

Since the above mixed raw material needs to be deposited in the center of the furnace, prior to the normal charging of the iron source raw material and the normal charging of the coke, or prior to the normal charging of the iron source raw material, preferably, the normal charging is performed. It is charged into the furnace center from a charging device on a different route from the device.

FIG. 1 is a longitudinal sectional view of a central portion of a blast furnace schematically showing an example of a deposited state of a raw material layer charged by the method of the present invention. In the figure, O ₁ and O ₂ are iron source material layers which are divided into two times and usually charged. In this case, O
₁ and O ₂ form one iron source material layer.
C ₁ and C ₂ is divided into 2 times a coke layer is normally charged, it will form a single coke layer between C ₁ and C _2. O ₀ is an iron source raw material layer in which iron source materials forming one layer are usually charged in a lump, and C ₀ is a coke layer in the same normal charging state. M is a mixed raw material layer that is mainly charged in the center.

In the method of the present invention, M → C ₁ → C ₂ → M → O ₁ → O ₂ ((a) in FIG. 1) M → C ₀ → M → O ₀ (the same (b)) C ₁ → C ₂ → M → O ₁ → O ₂ (same (c)) or C ₀ → M → O ₀ (same (d)
The raw material layers are formed in this order. Although not shown, for example, M is charged before each divided normal charging, for example, M → C ₁ → M → C ₂ → M → O ₁ → M → O _2. You may. On the raw material layers formed as described above, the raw material layers in the same charging order are again stacked as needed.

[0035]

First, the stabilization of the gas flow distribution near the center of the furnace according to the method of the present invention will be described with reference to FIGS. 1 (a) and 1 (c).
This will be described with reference to FIG.

As shown in FIG. 1 (a), the charged amount of the center charged mixed raw material M depends on the amount of the charged iron source raw material layers O ₁ and O ₂ and the normally charged coke layers C ₁ and C ₂ . The amount that will not be buried is selected. And normal charging of C ₁ and C ₂ and O
_1, usually charged to prior M of the O ₂ is centered charged. Therefore, the furnace center deposited layer can be composed of only M. As a result, it is possible to prevent the ordinary charged raw material affected by the above-described collapse of the coke layer or the re-classification phenomenon from flowing into and accumulating in the furnace center. Further, O / C of the furnace center portion is applied as configured to O _M / C _M of the mixed material are consistent with the particle size of the iron source material and coke deposition diameter also mixed raw material, fluctuation factor There is no room to enter.

In FIG. 1C, M is centrally charged prior to the normal charging of O ₁ and O ₂ . In this case, inflow of the normally charged coke affected by the re-classification phenomenon into the center is unavoidable, but O / C and sedimentation of the central part of the furnace due to the subsequent normal charging of O ₁ and O _2. Variations in particle size distribution can be suppressed. (However, if the amount of M charged is increased so that M protrudes upward at the center of the O ₂ layer so that M is not buried in the subsequent normally charged coke layer, the case of FIG. Similar effects can be obtained.) As described above, according to the method of the present invention, fluctuations in the O / C and the distribution of the deposited particle size of the iron source and coke in the central part of the furnace, that is, fluctuations in the air permeability distribution are suppressed. be able to.

Further, the gas flow distribution in the vicinity of the center of the furnace can be stabilized. This makes it possible to stabilize the reducing gas utilization efficiency and the fuel ratio in the central part of the furnace.

Next, a description will be given of how the core coke temperature is maintained at a high level by the method of the present invention.

It is considered that heat is supplied to the core coke in the blast furnace by heat exchange with high-temperature gas generated by combustion of coke on the raceway or by heat exchange with dripping molten iron slag. Therefore, an experimental study was conducted using a reduced model of a blast furnace in order to investigate which of these heat supply factors more effectively affects the temperature rise of the core coke.

FIG. 2 is a schematic sectional view of a model test apparatus for examining the influence of the heat supply factor on the temperature rise of the core coke. This experimental apparatus simulates the inside of a blast furnace furnace above the tuyere. From the furnace top, coke and pseudo ore (usually called “metal soap”) are passed through a charge hopper 8, a bell 1, and a movable armor 2. Is discharged from the cutout below the tuyere to the discharge reservoir 6 using the discharge device 4. In this way, the charge is lowered sequentially. Reference numeral 7 denotes an exhaust gas pipe.

On the other hand, warm air is blown from the tuyere 3 to heat the charge. As a result, the pseudo ore is dissolved in the course of descent and becomes a liquid, which is dropped on the bottom of the apparatus. That is, this apparatus can simulate the basic phenomena in the blast furnace excluding the reaction. Further, a large number of thermocouple temperature measuring points 5 are installed in the furnace, so that the movement of the furnace temperature can be understood.

The experiment was performed under the conditions shown in Table 1. First, the inside of the furnace was filled with coke, and blowing was started. Then, while discharging coke from under the tuyere, charging only coke from the furnace top and continuing this charging and discharging for a certain period of time, the charging from the furnace top is changed to alternate charging of coke and pseudo ore. After switching, the experiment was continued in that state, and the transition of the temperature of the core at the tuyere level, that is, the core coke temperature was investigated.

[0044]

[Table 1]

FIG. 3 is a diagram showing the influence of the heat supply factor on the temperature rise of the core coke.

The left half in the figure is the time of charging the coke alone, and the temperature of the core coke is raised only by heat exchange with gas from the tuyere. On the other hand, the right half in the figure corresponds to the time of mutual charging of coke and pseudo-ore, in which the heat exchange with gas from tuyeres and heat-exchange with pseudo-ore dropped by melting and dropping. The core coke is heated.

As shown in the figure, the heating rate of the furnace core coke is rapidly increasing from the time when the charged pseudo-ore starts melting, and the heating of the furnace core coke is accelerated by the heat of the dropped pseudo-ore. It is clear that it will be. That is, promotion of heat exchange with dropped hot metal is effective in raising the temperature of the core coke, and by dropping high-temperature hot metal onto the core,
The furnace core coke can be quickly heated.

In order to obtain the above-mentioned effects in the actual blast furnace, it is necessary to deposit an appropriate amount of iron source material at the center of the furnace of the materials charged in layers, and to melt and drop the material. Usually, iron in the iron source material is contained in the form of iron oxide, and a large amount of heat must be supplied in order to melt and reduce these to produce hot metal. The heat is supplied by heat exchange with the gas in the lump zone and by heat exchange with the gas and coke in the dripping zone in the dripping zone. However, the rate of descent (dropping) in the dropping zone after dissolution is much faster than that in the blocky zone of the iron source material, so it is estimated that the heat exchange efficiency in the dropping zone is considerably worse than that in the blocky zone. You. Therefore, if an appropriate amount or more of iron source material is deposited in the center of the furnace, smelting reduction requiring a large amount of heat proceeds in the dropping zone,
Further, the heat exchange efficiency is poor, so that the temperature of the hot metal is insufficiently increased, so that high-temperature hot metal cannot be supplied to the furnace core coke.

In the method of the present invention, O _M / C _M is the weight ratio of the total iron source material to the total coke charged into the furnace (hereinafter, referred to as “O _M / CM”).
The mixed raw material that is 0.05 times or more and 0.30 times or less of “Charging O / C” is charged into the center of the furnace. This way,
A relatively small amount of iron source material particles and a large amount of coke particles are adjacent to each other at the furnace center. Therefore, CO ₂ or H ₂ O generated by the reduction of the iron source material causes a gasification reaction with adjacent coke particles, and CO,
H ₂ will be regenerated, and the progress of reduction can be accelerated. As a result, the rate of burn-through reduction of the iron source material is increased, and smelting reduction (endothermic reaction) of unreduced FeO in the dropping zone can be suppressed, so that the temperature of the hot metal can be increased.

Here, in the present invention, the above formula, that is, 0.05 × (charge O / C) ≦ O _M / C _M of the mixed raw material ≦ 0.30 × (charge O / C). Will be described with reference to FIGS. 5 to 7 showing the results obtained in the examples described later.

[0051] When the O _M / C _M more than 0.30 times the charging O / C value (case 4,8), the heat required for the dissolution reduction is increased, making it possible to sufficiently raise the temperature of the molten iron temperature No, the heat exchange efficiency between the hot metal and the core coke becomes worse than in the examples (cases 2, 3, 6, and 7) satisfying the above expression.
Furthermore, since CO ₂ and H ₂ O gas generated by the reduction reaction increases, the coke supplied to the core of the furnace deposited at the center of the furnace will suffer from strength deterioration due to the gasification reaction with CO ₂ and H ₂ O. receive. For this reason, as shown in FIG. 5 (a), the core coke has a finer particle size as in the conventional example, and the permeability of the core coke has deteriorated. Heat exchange with the core coke is hindered. Therefore, FIG.
As shown in (b), it is difficult to maintain a high core coke temperature. When the core coke temperature drops due to the accumulation of coke powder or the flow of low-temperature unreduced substances such as slips around the core coke, the temperature of the core coke can be quickly raised to recover the furnace condition quickly. Disappears.

O _M / C _M less than 0.05 times O / C charged
In the case (cases 1 and 5), when only coke is deposited in the central part of the furnace, the air permeability in the central part of the furnace upper part is increased, and the "central flow" is strengthened. On the other hand, since there is almost no iron source material in the center of the furnace, the gas utilization rate in the center of the furnace decreases.
For this reason, the average gas utilization rate in the furnace decreases, and as shown in FIG. 7, the fuel ratio becomes worse than that of the embodiment. Further, the coke deposited at the center of the furnace and supplied to the furnace core does not suffer from strength deterioration due to a gasification reaction with CO ₂ and H ₂ O. Therefore, FIG.
As shown in (a), since the particle size deterioration of the furnace core coke is smaller than that of the embodiment, the air permeability of the furnace core coke is secured, and the heat exchange efficiency with the raceway generated gas is higher than that of the embodiment. However, since there is no heat exchange between the hot metal and the furnace core coke, as a result, as shown in FIG. 5 (b), maintaining the furnace core coke at a high temperature becomes more difficult than in the embodiment.

In the method of the present invention, O _M / C _{M is} charged O
/ C, as shown in FIG.
However, it is inevitable that the fuel ratio is increased as compared with the conventional charging method which is close to the charging O / C. However, since the mixed raw material of a predetermined O _M / C _M is charged and deposited in the center of the furnace, the fluctuation of the O / C in the center of the furnace is suppressed. Therefore, FIGS. 6 (a) and 6 (b)
As shown in (1), the fluctuations in the gas utilization rate in the central part of the furnace and the fluctuations in the blowing pressure are smaller than in the conventional example, and it is possible to maintain a more stable operation by minimizing the increase in the fuel ratio.

[0054]

Embodiments of the present invention will be described below. In the example, a blast furnace having a furnace volume of 2700 m ³ and equipped with a bell-type charging device was used.

FIG. 4 is a longitudinal sectional view for explaining a charging device for an upper portion of a blast furnace used in the embodiment. As shown in the drawing, in addition to the ordinary bell-type charging device 9, another route charging device 14 for charging the central part of the furnace is provided. Raw materials charged from another route are supplied to the upper hopper by the bucket conveyor 15.
After being temporarily stored in the lower hopper 19 and the exhaust pressure in the lower hopper 19 is completed, the upper seal valve 18 and subsequently the upper gate 17 are opened and transferred to the lower hopper 19.

Next, after the upper gate 17 and the upper seal valve 18 are closed, the pressure inside the lower hopper 19 is equalized to the furnace internal pressure, and the preparation for the furnace interior is completed. Then, when the charging timing to the center of the furnace comes, the lower seal valve 21 and then the lower gate
The opening operation of 20 causes the raw material to drop to the center of the furnace via the charging chute 23, and is deposited like 24. Reference numeral 25 denotes a raw material charged from a normal charging route, which is generally deposited in a layer having a hollow central portion as shown in the figure.

Table 2 shows the main operation data of the embodiment. Here, the raw materials were charged as follows.

(A) Normal charging of coke Of one charge (14 tons), coke excluding coke in the mixed raw material charged at the center is divided into two equal parts, and the bell type charging is divided into two parts. Using the apparatus 9, the furnace is charged from the furnace top to the furnace periphery.

(B) Normal Charge of Iron Source Material Of the charge (52.1 to 55.3 tons), the iron source material excluding the iron source material in the centrally charged mixed material is divided into two equal parts.
Charged from the furnace top to the furnace periphery using the bell-type charging device 9 divided into times.

[0060] (c) as shown in the center charging table 3 of the mixed raw material, O _M / C _M and (O _M / C _M) /
The mixed raw material having changed (charge O / C) was charged into the furnace center from the separate route charging device 14 with the charge amount shown in the table.

(D) Order of charging In the first embodiment (charging pattern in FIG. 1A), 1. Central charging of mixed raw materials 2. Normal charging of coke (first time) 3. Normal charging of coke (second time) 4. Central charging of mixed raw materials 5. Normal charging of iron source material (first time) Normal charging (second time) of the iron source material was performed, and this was repeated as one cycle. In Comparative Example 1, a single coke was charged centrally instead of the mixed raw material.

In Example 2 (the charging pattern shown in FIG. 1 (c)), charging was performed in the order of 2 → 6 without performing the above-mentioned 1 and this was repeated as one cycle. In Comparative Example 2, a single coke was mainly charged instead of the mixed raw material.

[0063]

[Table 2]

[0064]

[Table 3]

The operation of the example and the comparative example was carried out between normal charging operations without using the method of the present invention (conventional example without using the separate route charging device in FIG. 4), and each operation period was performed. It took about two weeks. Then, core coke was sampled from the tuyeres at the time of the wind break after the end of each operation period.

In order to evaluate the powdered state and the temperature rise state of the core coke during the operation, it was estimated from the measured data of the average particle size and the degree of graphitization of the core coke collected near the tuyere-level furnace center. The history temperature (maximum temperature reached) of core coke was investigated.

As a measure of the gas flow distribution fluctuation in the furnace, a blow pressure fluctuation index (a value obtained by dividing the length of the blow pressure recording curve on the continuous record chart of the blow pressure by the chart feed length)
And the gas utilization rate at the center of the furnace measured at one-hour intervals with the shaft upper sampler, that is, the standard deviation of CO ₂ / (CO + CO ₂ ).

FIG. 5 is a diagram showing the state of powdered and elevated temperature of the furnace core coke of the example in comparison with the comparative example and the conventional example.
(a) shows the average core coke particle size, and (b) shows the core coke history temperature (maximum temperature reached).

As shown in the figure, in the cases 1 to 4 where the mixed raw material was charged centrally prior to the normal charging of coke and the normal charging of the iron source raw material, the examples were compared with those of the comparative example 1 (cases 1 and 4). Sample No. 1 (cases 2 and 3) had a high core coke history temperature, and was able to maintain a high core coke temperature. In addition, O _M / C _M of the center charged mixed raw material is O / C charged.
In Case 4 which is 0.5 times the diameter of the core coke, the particle diameter of the core coke was smaller than that of the conventional example, and it was recognized that the ventilation and liquid permeability of the core coke tended to deteriorate.

In the cases 5 to 8 in which the mixed raw material was centrally charged before the normal charging of the iron source raw material, the results having almost the same tendency as above were obtained.

From the above results, it has been found that by centrally charging the mixed raw material satisfying the requirements of the present invention, the core coke temperature can be maintained at a high level without deteriorating the ventilation and liquid permeability of the core. .

FIGS. 6A and 6B show the gas flow distribution stability of the embodiment in comparison with the comparative example and the conventional example. FIG. Indicates the variation index.

As shown in the figure, in both the case of the embodiment in which the center charging was performed and the case of the comparative example in which the center charging was not performed, the fluctuation in the gas utilization rate in the central part of the furnace and the fluctuation in the blowing pressure were compared. Were low, and the effect of stabilizing the charge distribution in the center of the furnace was recognized.

FIG. 7 is a diagram showing the fuel ratio in each operation period of the embodiment in comparison with the comparative example and the conventional example.

As shown, in each of the charging patterns, (mixed raw material O _M / C _M ) / (charge O / C) is
As the fuel ratio decreased, the fuel ratio increased, and the fuel ratio was the worst in Case 1 of Comparative Example 1 and Case 5 of Comparative Example 2 in which only coke was charged. In Case 3 of Example 1 where (mixed raw material O _M / C _M ) / (charge O / C) was close to the upper limit of the range of the present invention, a fuel ratio equivalent to the conventional example was obtained.

[0076]

According to the method of the present invention, the gas flow distribution in the center of the furnace can be stabilized, and the reaction efficiency and the dissolution efficiency can be increased. And, the heat exchange between the core coke and the hot metal and the raceway generated gas can be promoted,
The core coke temperature during operation can be kept high. Also,
Even when the core coke cools down, the temperature of the core coke is quickly increased, and it is possible to cope with the early recovery of the malfunction of the furnace condition. Therefore, stable operation of the blast furnace can be easily maintained.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view of a central portion of a blast furnace schematically showing a raw material deposition state according to the method of the present invention.

FIG. 2 is a schematic cross-sectional view of a model test apparatus for examining the influence of a heat supply factor on the temperature rise of furnace core coke.

FIG. 3 is a diagram showing the degree of influence of a heat supply factor on the temperature rise of furnace core coke.

FIG. 4 is a schematic cross-sectional view of an upper part of a blast furnace having a separate route charging device for a central part of a furnace used for carrying out the present invention.

5A and 5B are diagrams showing the state of powdered and elevated temperature of the furnace core coke of the example of the present invention in comparison with a comparative example and a conventional example, in which FIG. FIG. 4 is a diagram showing a core coke history temperature.

FIG. 6 shows a gas flow distribution stability of an example of the present invention as a comparative example,
FIG. 7A is a diagram showing a comparison with a conventional example, FIG. 7A is a diagram showing a change in gas utilization rate in a furnace center portion, and FIG.

FIG. 7 is a diagram showing a fuel ratio in each operation period of an example of the present invention in comparison with a comparative example and a conventional example.

[Explanation of symbols]

1: Bell, 2: Movable armor, 3:
Tuyere, 4: Charge discharger, 5: Thermocouple temperature measuring point,
6: Exhaust reservoir, 7: Exhaust gas pipe, 8: Charge hopper, 9: Bell type charging device, 10: Small bell,
11: Large bell, 12: Movable armor, 13: Blast furnace furnace, 14: Separate route charging device, 15: Bucket conveyor, 16: Upper hopper, 17: Upper gate,
18: Upper seal valve, 19: Lower hopper, 20:
Lower gate, 21: Lower seal valve, 22: Equalizing pipe,
23: Charging chute, 24: Alternative route charging material,
25: Normal route charge.

Continuation of the front page (72) Inventor Masahiro Kashiwada 1850 Minato, Wakayama-shi, Wakayama Prefecture Wakayama Steel Works, Sumitomo Metal Industries, Ltd. (56) References JP-A-6-73416 (JP, A) JP-A-6-122909 ( JP, A) JP-A-4-176808 (JP, A) JP-A-2-54706 (JP, A) JP-A-62-290809 (JP, A)

Claims (1)

(57) [Claims] 1. A method for charging a blast furnace raw material in which coke and an iron source material are alternately charged into the furnace in layers from the furnace top, wherein a part of the coke and the iron source material satisfy the following formula: A blast furnace characterized by mixing at a weight ratio and charging the mixed raw material to the center of the blast furnace prior to charging coke and charging the iron source raw material or prior to charging the iron source raw material. Raw material charging method. 0.05 × (O / C) ≦ (O M / C M) ≦ 0.30 × (O / C) ··· However, O: furnace interior entrance total iron source material weight, O _M: iron source material weight of mixed raw material C: Weight of all coke inside furnace, C _M : Weight of coke in mixed raw material