JPH11343511A - Method for blowing pulverized coal into blast furnace - Google Patents

Abstract

PROBLEM TO BE SOLVED: To blow a large volume of pulverized coal by preventing air for combustion from being mixed with hot air so that the air for combustion high in oxygen concentration can be efficiently used in the combustion of the pulverized coal when the pulverized coal is blown in a blast furnace together with the hot air. SOLUTION: A lance 4 of concentric triple tube comprising an inner tube 5, an outer tube 6 and an outermost tube 7 is installed in a blow pipe which blows the hot air from a tuyere of a blast furnace with its forward end part protruded therein, and the pulverized coal, oxygen or air high in oxygen concentration, and air are respectively blown from the inner tube 5, the outer tube 6, and the outermost tube 7.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pulverized coal injection method capable of injecting pulverized coal in a large amount into a blast furnace.

[0002]

2. Description of the Related Art As a means of rationalizing the cost of fuel in the iron making process, particularly in a blast furnace, heavy oil and tar have been blown from the tuyere of a blast furnace as an alternative fuel to expensive coke. However, when the price of oil soared in the early 1950s, the number of blast furnaces that injected pulverized coal instead of oil began to increase.

Recently, for example, “Materials and Process Vo
l. 8 (1995) -319], there are blast furnaces operating at a pulverized coal ratio of more than 200 kg / thm per ton of pig iron. However, in view of the future supply and demand of coke and the aging of coke ovens, it is desired to further reduce the coke consumption by injecting more pulverized coal. In order to achieve a large amount of pulverized coal, it is essential to increase the burning rate of pulverized coal in the blast furnace raceway, and various inventions have been made.

For example, Japanese Patent Application Laid-Open No. Hei 2-213406 discloses a fuel injection lance having a concentric double pipe structure, in which fuel is supplied from an inner pipe, and supplied from an outer pipe in accordance with the properties and amount of fuel supplied. A technique has been disclosed in which combustion efficiency can be improved by performing combustion while controlling the oxygen concentration of supplied combustion air. In order to improve the combustion efficiency of pulverized coal, it is effective to increase the temperature of hot air and enrich oxygen, but the above method is an improvement on the latter. In other words, compared to the method of enriching oxygen in hot air, direct and local oxygen enrichment in the pulverized coal stream using a double-pipe lance allows efficient use of oxygen for pulverized coal combustion. The rate can be improved.

However, it is clear that the oxygen-enriched air for combustion supplied from the outer tube mixes with the fuel supplied from the inner tube and also with the hot air. Therefore, even if combustion air close to pure oxygen is supplied from the outer tube, the oxygen concentration is reduced due to mixing with hot air, and the effect of improving the fuel combustion rate is also reduced.

[0006]

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is intended to prevent mixing of combustion air and hot air as much as possible and to efficiently use combustion air having a high oxygen concentration. An object of the present invention is to provide a method for injecting pulverized coal into a blast furnace, which can be used for pulverized coal combustion and can inject a large amount of pulverized coal.

[0007]

According to a method of blowing pulverized coal into a blast furnace according to the present invention, hot air is blown from a tuyere of a blast furnace through a blowpipe, and the pulverized coal is blown through a pulverized coal-blowing lance having a tip portion inserted into the blowpipe. In the method of injecting pulverized coal into a blast furnace, a concentric triple pipe composed of an inner pipe, an outer pipe and an outermost pipe is used as the pulverized coal injection lance, and pulverized coal is supplied from the inner pipe, and oxygen or high-pressure is supplied from the outer pipe. An air having an oxygen concentration is supplied from the outermost tube.

[0008] Further, the blowing angle of the air supplied from the outermost tube is preferably inclined by 6 ° outward with respect to the axial direction of the pulverized coal blowing lance, and the blowing amount of the air is 2% of the blowing amount of the hot air. -8%, and the blowing speed of the air is 10 m / sec or more.

In practicing the present invention, a pulverized coal injection lance having a concentric triple pipe structure is used. Hereinafter, the inner pipe, the outer pipe, and the outermost pipe will be referred to as an inner pipe, an outer pipe, and an outer pipe in order from the inside of the triple pipe. Concentric annular flow paths are formed between the inner pipe and the outer pipe, and between the outer pipe and the outermost pipe.
Such a concentric triple pipe pulverized coal blowing lance penetrates through the pipe wall of the blowpipe, and the tip end of the pulverized coal rushes into the blowpipe. The pulverized coal is supplied from the inner pipe with air or a carrier gas such as nitrogen. Then, oxygen or oxygen-enriched air (high oxygen concentration air) for combustion is supplied from the outer tube, and air is supplied from the outermost tube. The air supplied from the outermost tube cools the lance body and at the same time blocks the inflow of hot air passing through the blow pipe, thereby preventing mixing of the hot air with oxygen or oxygen-enriched air from the outer tube. Will be. Therefore, the combustion rate of pulverized coal is improved.

According to the results of the test by the present inventors,
Assuming that the fuel injected from the inner pipe diffuses according to the free jet, it was found that the maximum combustion rate was obtained when the air blowing angle from the outermost pipe was made to coincide with the spreading direction of the jet.

[0011]

1 is a half sectional view of a blast furnace showing an outline of a pulverized coal injection method of the present invention, and FIG. 2 is a sectional view of a pulverized coal injection lance used for carrying out the present invention. In this embodiment, since pulverized coal is blown from the tuyere 2 of a general blast furnace 1 together with hot air, a concentric triple pipe lance 4 as shown in FIG. A plurality of the cables are installed obliquely with the tip end protruding.

The pulverized coal blowing lance 4 has a concentric triple pipe structure in which the inner pipe 5, the outer pipe 6, and the outermost pipe 7 are provided concentrically with annular flow paths 6a and 7a, respectively, from the inside. The pulverized coal is supplied from the inner pipe 5 (the flow path 5a thereof) together with the air of the carrier gas. Oxygen or oxygen-enriched air for pulverized coal combustion is supplied from (the flow path 6a of) the outer pipe 6, and here, pure oxygen is desirable to increase the pulverized coal combustion rate. Furthermore, the outermost tube 7
Air is supplied from (the flow path 7a). The air is supplied to prevent hot air having a low oxygen concentration from entering the jet area while the pulverized coal and oxygen or oxygen-enriched air are mixed and burned while diffusing in the jet from the lance 4.

In order to optimize the above effects, the tip structure of the lance 4 is important. FIG. 2B shows the tip structure of the lance 4 in detail. That is, in order to adjust the blowing angle of the air sent from the outermost pipe 7,
The outer peripheral portion of the outer tube 6 and the inner peripheral portion of the outermost tube 7 are tapered so that the air ejection angle is inclined outward with respect to the axial direction of the lance 4. In the figure, reference numeral 8 denotes an inclined surface provided on the outer peripheral portion of the outer tube 6, and reference numeral 9 denotes an inclined surface provided on the inner peripheral portion of the outermost tube 7. The taper angle will be discussed below, and will be further studied in the embodiments.

(Blow Angle of Air) FIG. 3 schematically shows a flow blown from a single pipe. Bradbury approximated the velocity distribution of a two-dimensional jet with equation (1) (J. Fluid Mech. 23 (1965), p.
31). _{u / u m = exp {-0.6749η} 2 (1 + 0.0269η 4)} ·· (1) u m: jet center velocity η: = y / b y: distance from the central axis b: half-width (u / u value where y _m = 1/2)

Consider the half width as the limit of the jet. Raja
Ratnam, N experimentally sought half-width growth and submitted equation (2) (TurbulentJets, Elsevier (1976)). b = 0.10x (2) According to the equation (2), the jet flow limit is represented by a linear function of the coordinate axis x in the flow direction. Therefore, when pulverized coal is blown by the lance having the concentric pipe structure as described above, in order to mix the pulverized coal and oxygen without being disturbed by hot air in the diffusion space of the jet, tan θ in FIG.
= 0.10, it is considered that air should be blown from the outermost tube 7 at an angle of θ = 6 °.

[0016]

EXAMPLES In order to confirm the effect of the present invention, the following pulverized coal combustion test was performed. FIG. 4 shows a schematic diagram of the test mode. A combustion test of pulverized coal was performed in a small coke-filled combustion test furnace 10, and the effect was confirmed by measuring and comparing the combustion rates of dust collected by a dust collection device 18. The lance 4 uses the concentric triple tube shown above,
The optimum conditions were determined by changing the taper angle θ at the tip and the air flow rate in various ways.

The experimental method is described in detail below. Combustion test furnace 1
In order to simulate the lower part of the actual blast furnace,
1. One blow pipe 12 is provided. Hot air heated to 1200 ° C. was sent to the blow pipe 12.
The pulverized coal blowing lance 4 was inserted through the pipe wall of the blow pipe 12 and was installed obliquely. The inner pipe of the lance 4 is connected to the pulverized coal hopper 13 by a pulverized coal feed pipe 14, and the pulverized coal in the pulverized coal hopper 13 is supplied to the blow pipe 12 through the inner pipe of the lance 4 together with the carrier air. It has become. On the other hand, the outer tube of the lance 4 is connected to an oxygen line 15 so that a predetermined amount of combustion oxygen is supplied to the outer tube of the lance. Further, the outermost tube of the lance 4 is connected to the air line 16 so that a predetermined amount of air is supplied from the outermost tube of the lance. The blown pulverized coal burned in the combustion space in the blow pipe 12 and the coke packed bed 17, and dust was collected by the dust collecting device 18. The combustion rate was measured by analyzing the collected dust.

The conditions of the experiment are as shown in Table 1, and many tests were conducted under these conditions. In the table, Comparative Example 1 is equivalent to the conventional concentric double pipe lance by setting the air supply amount from the outermost lance pipe to 0 for comparison with the embodiment of the optimum conditions according to the present invention. That is, the action is performed. In Comparative Example 2, a combustion test was performed under different conditions in order to examine the effects of the air supply amount, the blowing angle, and the blowing speed on the pulverized coal combustion rate, as described later. In other words, it is for obtaining the optimum condition.

[0019]

[Table 1]

Example and Comparative Example 1 A pulverized coal combustion test was carried out under the combustion test furnace 10 shown in FIG. 4 and the conditions shown in Table 1, and the combustion rate was calculated. Table 2 shows the results.

[0021]

[Table 2]

According to Table 2, it can be seen that the burning rate is increased by 8% by implementing the present invention.

(Comparative Example 2) In the practice of the present invention, the following three parameters were expected to affect the pulverized coal combustion rate: air blowing amount, air blowing angle, and air blowing speed. These values were changed variously, and the combustion rate was measured. The results are shown in FIGS.

(Comparative Example 2) Amount of Air Blow First, the effect of the amount of air blow on the combustion rate was tested. In this case, the test was performed with the air blowing angle fixed at 6 ° and the air blowing speed fixed at 20 m / sec.
The results were arranged by (air amount / hot air amount) and summarized in FIG.
When the amount of air is small, the effect of blocking the intrusion of hot air is small, and the increase in the combustion rate is small. When (air amount / hot air amount) is 2% or more, it shows a substantially constant value. However, when the (air amount / hot air amount) exceeded 8%, the temperature drop became remarkable, and the combustion rate turned to decrease. Therefore, the amount of air is (air amount / hot air amount)
Is preferably in the range of 2% to 8%.

Comparative Example 2 Air Blow Angle The effect of the air blow angle on the combustion rate is summarized in FIG.
In this case, the test was performed with the air blowing amount fixed at 15 Nm ³ / hr and the air blowing speed fixed at 20 m / sec. When the air blowing angle is small, the increase in the combustion rate is not large because the jet flow is disturbed. Conversely, when the air blowing angle is too large, the effect of blocking the entry of hot air is weakened, and the combustion rate is reduced. The air blowing angle that gives the maximum combustion rate is equal to the angle (6 °) that Rajaratnam, N gives the experimental jet boundary. Also, it has been found that if the blowing angle is 20 ° or less, there is an effect more than the conventional double pipe structure.

Comparative Example 2 Air Blowing Speed FIG. 7 shows the effect of the air blowing speed on the combustion rate. In this case, the air blowing amount is fixed at 15 Nm ³ / hr,
The test was performed with the air blowing angle fixed at 6 °. The effect is small at low flow rates. In addition, the flow velocity dependence when the flow velocity was 10 m / sec or more was small. Therefore, there is no problem if the air blowing speed is 10 m / sec or more.

[0027]

As described above, according to the present invention,
Because the pulverized coal was blown into the blowpipe from the inner pipe, oxygen or high oxygen concentration air from the outer pipe, and air from the outermost pipe using the concentric triple pipe pulverized coal blowing lance, There is little mixing of combustion air and hot air, and a remarkable effect of improving flammability can be obtained.Therefore, the amount of pulverized coal injected into the blast furnace can be increased, so that the cost of producing pig iron can be reduced. .

[Brief description of the drawings]

FIG. 1 is a half sectional view of a blast furnace showing an outline of a pulverized coal injection method of the present invention.

FIG. 2 is a sectional view of a pulverized coal blowing lance according to the present invention and an enlarged sectional view of a distal end portion A thereof.

FIG. 3 is a schematic diagram of a flow jetting from a single pipe and a jet flow boundary.

FIG. 4 is a configuration diagram of a pulverized coal combustion test device.

FIG. 5 is a graph showing the effect of the amount of air blown on the pulverized coal combustion rate.

FIG. 6 is a diagram showing the effect of the air blowing angle on the pulverized coal combustion rate.

FIG. 7 is a diagram showing the effect of the blowing speed of air on the pulverized coal combustion rate.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Blast furnace 2 Tuyere 3 Blow pipe 4 Pulverized coal injection lance 5 Inner pipe 6 Outer pipe 7 Outer pipe 8 Inclined surface of inner tube tip outer periphery 9 Inclined surface of outer tube tip inner periphery

Claims (2)

[Claims] 1. A method of blowing hot air from a tuyere of a blast furnace through a blowpipe and blowing pulverized coal into the inside of the blast furnace through a pulverized coal blowing lance having a tip portion inserted into the blowpipe, wherein: A concentric triple pipe consisting of an inner pipe, an outer pipe and an outermost pipe is used to supply pulverized coal from the inner pipe, oxygen or high oxygen concentration air from the outer pipe, and air from the outermost pipe. A method for injecting pulverized coal into a blast furnace. 2. The blowing angle of the air supplied from the outermost pipe is preferably inclined by 6 ° outward with respect to the axial direction of the pulverized coal blowing lance, and the blowing amount of the air is 2% of the blowing amount of the hot air. ~ 8%, and the air blowing speed is 1
2. The method for injecting pulverized coal into a blast furnace according to claim 1, wherein the pressure is 0 m / sec or more.