JP2000192117A - Operation of blast furnace - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an operating method of a blast furnace which can prevent the corrosion in the equipment related to a blast furnace gas line and in the other case, the equipment trouble caused by chlorine. SOLUTION: Slag quantity discharged from the lower part of the furnace is regulated to 250-370 kg/ton of pig iron, and CaO/SiO2 in the slag is regulated in the range of 1.10-1.35 and the total chlorine content involved into the blast furnace is regulated to <=200 g/ton of pig iron in the case of using wet type dust collector for blast furnace and to <=150 g/ton of pig iron in the case of using a dry type thereof. In such a case, the chlorine content in auxiliary fuel blown from a tuyere and further, in the case of blowing a synthetic resin, is desirable to adjust so as to become <=150 kg/ton of pig iron, in terms of the total chlorine content containing the chlorine in the synthetic resin in the case of using the wet type dust collection and become <=100 kg/ton of pig iron, in terms of the total content of chlorine in the case of using the dry type dust collection.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for operating a blast furnace, and more particularly, to a method of charging raw fuel into a blast furnace or blowing it through tuyere of a blast furnace, the amount of slag, the basicity of the slag, and the content of the raw fuel. The present invention relates to a blast furnace operating method for preventing corrosion and dust adhesion of blast furnace gas line equipment by specifying the amount of chlorine to be supplied.

[0002]

2. Description of the Related Art Sodium, potassium, and zinc have been conventionally controlled as harmful elements in the operation of a blast furnace with respect to components of raw fuel charged into or blown from a blast furnace tuyere.

[0003] These elements are so-called low-boiling elements, which are reduced in a blast furnace and fall down to a high-temperature zone, evaporate into metal vapor, and move upward in the furnace with a gas flow rising in the furnace. Moving. When the temperature falls below the boiling point of these elements in the upper part of the furnace, the vapor condenses and some are discharged as dust from the furnace top to the outside of the furnace, and another part is on the surface of the charge or the wall surface of the furnace. Adhere to.

[0004] These elements attached to the surface of the charge fall to the high-temperature zone at the lower part of the furnace together with the charge, and evaporate again to vapor, and move upward of the furnace to repeat the above-described behavior. Elements circulate inside the furnace.
As a result, if the charged amount of these elements is large, the amount of circulating in the furnace increases more than the allowable amount, and the charged materials adhere to each other at the upper part of the furnace due to the attachment of these elements, and large blocks are generated, Large deposits are generated on the surface, which makes it difficult to maintain a stable operation of the blast furnace by impeding the smooth discharge of the charge and the air permeability in the furnace.

As described above, sodium, potassium, zinc and the like have been found to have a direct adverse effect on the operation of a blast furnace from conventional experience and analysis. Values are provided and maintained on a daily basis.

[0006] On the other hand, the peripheral equipment of the blast furnace has a problem of corrosion of the equipment related to the blast furnace gas line. Here, the equipment related to the blast furnace gas line refers to equipment such as gas dust removal equipment, furnace top pressure power generation equipment, blast furnace gas pipes, gas holders, etc., which are in direct contact with the blast furnace gas.

[0007] Sulfur and chlorine are considered as elements that may contribute to the corrosion of these facilities. Sulfur is mainly contained in coke and other carbonaceous materials and is brought into the furnace.However, most of the slag in the blast furnace is in the furnace slag because the slag is basic, and most of the remaining small part is in the hot metal. Since it is trapped, the sulfur concentration in the blast furnace gas is extremely low.

[0008] On the other hand, chlorine is considered to have a qualitatively adverse effect, but the quantitative degree of influence is completely unknown. Was also removed.

However, in recent blast furnace operations, auxiliary fuels having good flammability and high calorific value (pulverized coal, heavy oil, heavy oil, etc.) from the tuyere in order to replace expensive coke with less expensive fuel.
It is common practice to inject tar, natural gas, or the like (hereinafter, simply referred to as "auxiliary fuel"). In recent years, the injection of inexpensive pulverized coal has become mainstream, which has greatly contributed to reducing fuel costs and improving productivity. Some brands contain a higher concentration of chlorine compared to coal.

[0010] On the other hand, one of recent social and environmental problems is that it is becoming increasingly difficult to secure landfill sites for waste every year. That is. The amount of synthetic resin waste has reached nearly 9 million tons / year, of which less than 40% is landfilled and less than 40% is simply incinerated, and only a small amount is being used effectively. I have. Among them, in simple incineration, since pollution problems such as generation and emission of dioxin have become apparent, it has been desired to develop a method of effectively using waste synthetic resins that does not adversely affect the environment.

[0011] From such a background, an operation has been proposed in which waste synthetic resin is blown from the tuyere of a blast furnace. However, synthetic resin in general waste discharged from homes in Japan usually contains about 8% of vinyl chloride, and there is concern about corrosion of pipes. For example, Japanese Patent Application Laid-Open No. H10-110931 discloses a technique of dechlorinating and then blowing into a blast furnace.

As described above, there is an increasing interest in bringing chlorine into the blast furnace (input), but since there is no knowledge about how to manage it quantitatively, the amount of chlorine in the raw fuel is low. The actual situation was that the amount of chlorine was not controlled at all.

[0013]

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and is intended to prevent the blast furnace gas line from directly contacting the blast furnace gas, thereby preventing the blast furnace gas line from corroding and other equipment troubles caused by chlorine. The aim is to provide a method.

[0014]

The gist of the present invention resides in the following blast furnace operating methods (1) and (2).

(1) In a blast furnace having a wet-type blast furnace gas dust removal facility, the amount of slag discharged from the lower part of the furnace is 250
～370Kg / pig iron t, a CaO / SiO ₂ of the slag in the range of 1.10 to 1.35, and blast furnace operation method of the total chlorine amount to less 200 g / pig iron t being brought into the blast furnace.

In this case, the amount of chlorine in the auxiliary fuel blown from the tuyere is set to 150 g / t or less, and when the synthetic resin is further blown from the tuyere, the amount of chlorine contained in the synthetic resin is reduced. And the amount of chlorine in the auxiliary resin, the amount of chlorine in the auxiliary fuel, the amount of chlorine in the synthetic resin, and the amount of chlorine in the synthetic resin such that the sum of the amount of chlorine in the auxiliary fuel and the amount of chlorine in the auxiliary fuel blown from the tuyere is 150 g / t or less. Preferably, one or more of the concentrations are adjusted.

(2) In a blast furnace using a dry-type blast furnace gas dust removing apparatus, the amount of slag discharged from the lower part of the furnace is 25
0～370Kg / pig iron t, a CaO / SiO ₂ of the slag in the range of 1.10 to 1.35, and blast furnace operation method according to the following 150 g / pig t the total amount of chlorine is brought into the blast furnace.

In this case, the chlorine content in the auxiliary fuel blown from the tuyere is set to 100 g / t or less, and when the synthetic resin is further blown from the tuyere, the chlorine contained in the synthetic resin is reduced. It is preferable that the sum of the amount and the amount of chlorine in the auxiliary fuel blown from the tuyere be adjusted to be 100 g / t or less. Note that the adjustment method may be performed according to the case (1).

The chlorine input to the blast furnace is partially captured by slag and the like, but the remaining part is discharged out of the furnace as hydrogen chloride or chloride dust contained in the blast furnace gas. Therefore, it is necessary to reduce the amount of chlorine input to the blast furnace in order to prevent corrosion and dust adhesion of equipment related to the blast furnace gas line, but how much reduction can prevent problems such as corrosion? , Has not been previously disclosed. In addition, when auxiliary fuel or synthetic resin was blown from the tuyere, it was unclear how much chlorine should be input with the blowing. Furthermore, blast furnace gas is transported to other facilities by gas pipes after dust removal, but the effect of the dust removal method (wet dust removal or dry dust removal) on the progress of corrosion is not quantitatively clarified. .

Therefore, the present inventors changed the amount of chlorine input to a blast furnace having a wet dust removal facility or a blast furnace having a dry dust removal facility to change the amount of chlorine in a blast furnace gas line-related facility and troubles caused by dust adhesion. As a result of investigating the state of occurrence of chlorine, the permissible amount of chlorine was grasped, and an appropriate means for suppressing the permissible amount of chlorine was found, and the present invention was accomplished.

[0021]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The blast furnace operating method of the present invention will be described in detail below.

As described above, part of the chlorine input to the blast furnace is captured by slag and the like, and the remaining part is discharged out of the furnace as hydrogen chloride or chloride dust contained in the blast furnace gas.

In the blast furnace operating method of the present invention, the amount of slag discharged from the lower part of the furnace is set in the range of 250 to 370 kg / t pig iron, and the slag CaO / SiO ₂ is set in the range of 1.10 to 1.35. This is a fact that is well known to blast furnace operators, but in order to improve the fluidity of slag generated in the furnace using currently available raw fuels, additional raw materials such as limestone are added. 1.10 to the CaO / SiO ₂ of the slag and
This is because, if the slag component is adjusted to 1.35, the slag component in the raw fuel and the slag component in the added auxiliary material are combined, and the slag amount is 250 to 370 kg / t pig iron. Further, in the case of a blast furnace having a wet blast furnace gas dust removal facility, the total amount of chlorine brought into the blast furnace is 200 g / pig iron t.
The reason is as follows: If chlorine exceeding this amount is input into the blast furnace, corrosion will occur in the blast furnace gas line-related equipment. That is, 200 g / pig iron or less is the allowable amount of chlorine brought into the blast furnace when the wet dust removal is performed and the above-mentioned rules are applied to the slag.

In the actual operation of the blast furnace, auxiliary fuel is blown from the tuyere. In this case, the amount of chlorine in the auxiliary fuel blown from the tuyere is reduced by 150%.
It is preferable to adjust so as to be not more than g / pig iron t. If the amount of chlorine input from the tuyere exceeds this value, even if the total amount of chlorine input into the blast furnace is set to 200 g / t or less, problems such as corrosion may occur in facilities related to the blast furnace gas line. is there.

In this case, the adjustment of the chlorine amount in the auxiliary fuel is as follows.
It may be performed by adjusting one or both of the blowing amount of the auxiliary fuel and the chlorine concentration in the auxiliary fuel.

In the case where synthetic resin is blown from the tuyere in addition to the auxiliary fuel, the sum of the amount of chlorine contained in the synthetic resin and the amount of chlorine in the auxiliary fuel blown from the tuyere is 150 g / t Preferably, the adjustment is made as follows. When the amount of chlorine input from the tuyere exceeds this value, similar to the case where only the auxiliary fuel is blown,
The total chlorine input into the blast furnace is 200 g / pig iron t
This is because a problem such as corrosion may occur in the blast furnace gas line related equipment in the following cases.

In this case, the amount of chlorine in the synthetic resin and auxiliary fuel blown from the tuyere is adjusted by the amount of synthetic resin blown, the amount of auxiliary fuel blown, the concentration of chlorine in the synthetic resin, and the concentration of chlorine in the auxiliary fuel. It may be performed by appropriately adjusting at least one of the above.

The above-mentioned allowable value of the total amount of chlorine brought into the blast furnace and the preferable upper limit value of the amount of chlorine contained in the auxiliary fuel and synthetic resin blown from the tuyere are as follows:
In the case of a blast furnace with a wet blast furnace gas dust removal facility,
In the case of a blast furnace using a dry blast furnace gas dust remover, these values will be different. This is because the blast furnace gas is transported to another facility by gas pipe after dust removal, but the degree of progress of corrosion in the facility related to the blast furnace gas line differs depending on the dust removal method.

That is, in the wet type blast furnace gas dust removal equipment,
Chlorine and sulfur contained in the blast furnace gas are trapped in the washing water, so the chlorine and sulfur contents in the blast furnace gas after dust removal are significantly reduced. Because there is no trap, the amount of chlorine and sulfur contained in the blast furnace gas after dust removal is higher than that in the case of wet dust removal equipment, and as a result, the corrosion of the blast furnace gas line related equipment tends to progress. .

Further, in connection with the fact that there is no trap for cleaning water for chlorine content, when dry dust removal equipment is used, if the amount of chlorine input to the blast furnace is large, the chlorine etc. Deposits containing ammonium as a main component are generated, and as a result, a problem occurs in that the turbine vibrates. This is equipment trouble due to the adhesion of chloride dust. If the operation is continued in a state where the turbine vibrates, the equipment such as the bearings may be damaged. Therefore, it is necessary to stop the equipment once to remove the deposits, which is a serious operational problem. In recent blast furnaces, the top pressure power generation is often performed to recover the top pressure energy, but the vibration problem of the turbine frequently occurs.

Therefore, in a blast furnace using a dry-type blast furnace gas dust remover, it is necessary to make the control value of the amount of chlorine input to the blast furnace stricter than in a blast furnace having a wet-type blast furnace gas dust remover.

Therefore, in the blast furnace operating method of the present invention,
In the case of a blast furnace using a dry blast furnace gas dust removal device, the amount of slag discharged from the lower part of the furnace is 250 to 370 kg / t pig iron, and the slag CaO / SiO ₂ is 1.10 to 1.35.
And the total amount of chlorine brought into the blast furnace is 1
50 g / pig iron t or less.

The amount of slag, the basicity of slag (CaO / S
The definition of iO ₂ ) and the reason for defining so are the same as in the case of a blast furnace having a wet type blast furnace gas dust removal facility.

The input amount of chlorine into the blast furnace is 150 g.
The reason why the ratio is not more than / pig iron t is that if the amount exceeds this value, as described above, blast furnace gas line-related equipment may cause corrosion or equipment trouble. That is, the allowable amount of chlorine brought into the blast furnace when dry dust removal is performed and the slag is stipulated above is 150 g / t or less.

In the operation of the blast furnace having the above-mentioned dry blast furnace gas dust removal equipment, it is preferable to adjust the amount of chlorine in the auxiliary fuel blown from the tuyere to 100 g / t or less. When the amount of chlorine input from the tuyere exceeds this value, the total amount of chlorine input into the blast furnace is reduced by 15%.
This is because a problem such as corrosion in blast furnace gas line-related facilities tends to occur even when the iron content is 0 g / pig iron t or less. The adjustment of the amount of chlorine in the auxiliary fuel may be performed by adjusting one or both of the blowing amount of the auxiliary fuel and the chlorine concentration in the auxiliary fuel.

In the case where synthetic resin is blown from the tuyere in addition to the auxiliary fuel, the sum of the amount of chlorine contained in the synthetic resin and the amount of chlorine in the auxiliary fuel blown from the tuyere is 100 g / tg. Preferably, the adjustment is made as follows. If the amount of chlorine input from the tuyere exceeds this value, the total amount of chlorine input into the blast furnace will be 150 g.
This is because there is a tendency for problems such as corrosion to occur in blast furnace gas line-related equipment even if it is less than / pig iron t.
Adjust the amount of chlorine in the auxiliary fuel by adjusting at least one of the synthetic resin blowing amount, the auxiliary fuel blowing amount, the chlorine concentration in the synthetic resin, and the chlorine concentration in the auxiliary fuel. It can be done by:

In the method of the present invention, when synthetic resin is blown from the tuyere, any one of the following methods a to d may be adopted as a method for adjusting the chlorine concentration in the synthetic resin. The dechlorination treatment may be performed by a conventionally used method such as heat treatment or selective removal of vinyl chloride using a solvent.

A. Method of adjusting residual chlorine amount during dechlorination of synthetic resin b. Method of changing the mixing ratio of synthetic resin containing no chlorine and synthetic resin containing chlorine c. Method of changing the mixing ratio of a synthetic resin containing no chlorine and a synthetic resin dechlorinated d. A method of changing the mixing ratio of a synthetic resin containing no chlorine, a synthetic resin that has been subjected to a dechlorination treatment, and a synthetic resin that contains chlorine that has not been subjected to a dechlorination treatment. If it is decided to keep within the appropriate range in consideration of the chlorine tolerance of chlorine, it is not necessary to dechlorinate the entire amount of synthetic resin to be blown or to selectively remove synthetic resin containing chlorine. The resin can be used to the maximum extent possible.

In the operation of a blast furnace, it is practically difficult to extremely reduce the chlorine contained in the actual raw fuel due to various restrictions.
According to the blast furnace operating method of the present invention in which the amount of O / SiO ₂ and chlorine input to the blast furnace is controlled as described above, the problem of corrosion of blast furnace gas line-related equipment and the attachment of the top pressure power generation equipment to turbines and the like are provided. Auxiliary fuel or synthetic resin containing chlorine can be used while effectively suppressing troubles caused by kimono formation.

[0040]

EXAMPLE A blast furnace having a wet blast furnace gas dust removal facility and a blast furnace having a dry blast furnace gas dust removal facility were operated by the method of the present invention, and the progress of corrosion on the inner surface of the piping and the trouble in the furnace top pressure power generation facility were investigated. The occurrence situation was investigated.

Table 1 shows the results for the blast furnace using the wet dust removal equipment, and Table 2 shows the results for the blast furnace using the dry dust removal equipment.

Cases 1-a to 3-a in Table 1 and Cases 1-b to 3-b in Table 2 show cases where auxiliary fuel and synthetic resin were not injected from tuyeres. Case 4-a to Case 6-a, and Table 2
In case 4-b to case 6-b of pulverized coal injection from the tuyeres, cases 7-a to 9-a in Table 1 were used.
The cases 7-b to 9-b in Table 2 are the cases where pulverized coal injection and synthetic resin injection from the tuyeres were performed.

Also, case 1-a and case 4-a in Table 1
And case 7-a and case 1-b and case 4 in Table 2.
-B and Case 7-b, the amount of slag in the case 240 kg / pig iron t, CaO / SiO ₂ of the slag is 1.00,
In other cases, the amount of slag is 300 kg / t pig iron, and the slag CaO / SiO ₂ is 1.25.

The case 3-a and the case 6-a shown in Table 1 are used.
And case 9-a, case 3-b and case 6 in Table 2
-B and case 9-b are examples of the present invention, and other cases are comparative examples.

The test period of each case was about one month, and the corrosion of the inner surface of the pipe was 10 minutes in the blast furnace gas pipe after dust removal.
An iron plate having a size of cm × 20 cm (thickness: 5 mm) was placed, taken out after the test, and examined by visual observation for the progress of corrosion.
Also, regarding the occurrence of troubles in the furnace top pressure power generation equipment, periodically check for turbine vibration,
When necessary, measures were taken to remove the deposits formed on the turbine.

As shown in Tables 1 and 2, regardless of whether the dust collection equipment used is of a wet type or of a dry type, all of the comparative examples have corrosion on the steel plate installed in the blast furnace gas pipe. Although it was confirmed that the process was progressing, in the case of the present invention, almost no occurrence of corrosion was observed. Table 2
As shown in the above, for the blast furnace using the dry dust collection equipment, the vibration of the turbine of the top pressure power generation equipment increased in the comparative example, and deposits were generated on the turbine. The operation of stopping the top pressure power generation equipment and removing the deposits was required. However, in the present invention example, such a problem did not occur in any case, and the effect of the present invention was confirmed.

[0047]

[Table 1]

[0048]

[Table 2]

[0049]

According to the blast furnace operating method of the present invention, a blast furnace can be used without using special raw materials having a low chlorine concentration or using raw fuel from which chlorine has been removed by sorting, dechlorination, or the like. It is possible to effectively suppress the occurrence of equipment troubles caused by corrosion of gas line related equipment and dust adhesion.

Claims (6)

[Claims] In a blast furnace having a blast furnace gas dust removal facility of a wet type, the amount of slag discharged from the lower part of the furnace is 250 to 37.
0 kg / pig iron, CaO / SiO _{2 of} slag 1.10
A blast furnace operating method, wherein the total chlorine content brought into the blast furnace is 200 g / t or less. 2. The auxiliary fuel injection amount and / or the chlorine concentration in the auxiliary fuel are adjusted so that the chlorine amount in the auxiliary fuel blown from the tuyere is 150 g / t or less. Item 2. A blast furnace operating method according to Item 1. 3. When synthetic resin is blown from the tuyere, the sum of the amount of chlorine contained in the synthetic resin and the amount of chlorine contained in the auxiliary fuel blown from the tuyere is 150 g / t or less. 3. The method according to claim 2, wherein at least one of a synthetic resin injection amount, an auxiliary fuel injection amount, a chlorine concentration in the synthetic resin, and a chlorine concentration in the auxiliary fuel is adjusted.
Blast furnace operation method described in 1. 4. In a blast furnace using a dry-type blast furnace gas dedusting apparatus, the amount of slag discharged from the lower part of the furnace is 250 to 3 times.
70 kg / pig iron t, slag CaO / SiO ₂ of 1.1
A method for operating a blast furnace, characterized in that the total chlorine content brought into the blast furnace is set to 150 g / t or less in a range from 0 to 1.35. 5. The auxiliary fuel injection amount and / or the chlorine concentration in the auxiliary fuel are adjusted so that the chlorine amount in the auxiliary fuel blown from the tuyere is 100 g / t or less. Item 6. A blast furnace operating method according to Item 4. 6. When synthetic resin is blown from the tuyere, the sum of the amount of chlorine contained in the synthetic resin and the amount of chlorine contained in the auxiliary fuel blown from the tuyere is 100 g / t or less. 6. The method according to claim 5, wherein at least one of a synthetic resin injection amount, an auxiliary fuel injection amount, a chlorine concentration in the synthetic resin, and a chlorine concentration in the auxiliary fuel is adjusted.
Blast furnace operation method described in 1.