Pulverized coal injecting apparatus

Details Pulverized coal injecting apparatus Pulverized coal injecting apparatus

2000-03-31

2001-11-20

Kastler, Scott (Department: 1742)

Metallurgical apparatus

Means for introducing fluent into vessel, e.g., tuyere

With flow control means or internal flow guide

C266S268000

Reexamination Certificate

active

06319458

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates to a pulverized coal injecting apparatus in which oxygen is used to improve the combustion of pulverized coal in a blast furnace using the pulverized coal instead of the expensive coal in a pig iron manufacturing process. Particularly the present invention relates to a pulverized coal injecting apparatus in which dimples are formed on the surface if an inner pipe to improve the combustion of the pulverized coal.
BACKGROUND OF THE INVENTION
Generally in a pig iron manufacturing process of a blast furnace, as shown in FIG.
1
(
a
), iron ore as a raw material and coke as a fuel are fed through the top of the furnace, while hot air is fed through a tuyere which is formed on a lower portion of the furnace. Thus, the coke is burned, thereby producing pig iron and slag. In accordance with the progress in the pig iron manufacturing process of the blast furnace, at present, expensive coke is replaced with the pulverized coal by using a pulverized coal injecting apparatus
4
in which tuyere is formed to feed the pulverized coal. In the case of a blast furnace in which this pulverized coal is fed as described above, a large cavity which is called a race way (combustion area)
3
is formed on the front of the tuyere due to the high temperature air flow. FIG.
1
(
b
) illustrates in detail the race way
3
.
Most of the coke and the pulverized coal are burned in the race way (combustion area) to supply the heat which is required in reducing the ore. However, depending on cases, the unburnt pulverized coal passes through the coke layer within the blast furnace, to be partly discharged to the outside of the furnace, and to be partly accumulated within the coke layer in which the gas velocity is relatively slow. This accumulated unburnt pulverized coal remains within the inner region of the furnace to alter the gas flow. Further, it lowers the intra-furnace temperature, and increases the permeability resistance, with the result that the size of the race way is decreased. As the pulverized coal feeding amount is increased, the decrease of the combustion efficiency of the pulverized coal becomes very serious, with the result that the manufacturing cost of the pig iron is increased.
In order to solve this problem, in the general technique, pure oxygen is enriched, thereby improving the combustion efficiency of the pulverized coal. By carrying out the pure oxygen enrichment through the tuyere, the oxygen concentration in the hot air flow is increased so, as to promote the combustion of the pulverized coal. However, in this method, the flow amount of the hot blast is very large, and therefore, even if oxygen is enriched to a high degree, the actual oxygen concentration increases just by several percent, with the result that the final effect is meager. Further, the cost of newly building the oxygen producing facilities is very high, and therefore, there is a limit in carrying out the oxygen enrichment.
Meanwhile, in order to solve the above described problem, recently, efforts have been concentrated on modifying the structure of the pulverized coal injecting apparatus.
FIG. 2
a
illustrates one example of this. As shown in this drawing, a pulverized coal injecting apparatus
10
is of a coaxial type, and the pulverized coal is fed through an inner pipe
12
, while pure oxygen is enriched in an outer pipe
11
. Thus the oxygen concentration is raised to improve the combustion efficiency. In this method, the combustion efficiency is somewhat improved compared with the case of carrying out the hot blast oxygen enrichment. In this method, however, the external oxygen cannot intrude into the pulverized coal flow, but burns only in the outer regions.
FIG. 2
b
illustrates another effort of solving the above described problem. In this method, an oxygen flow swirler
23
is formed between the coaxial pipes, so as to form a vortex in the inner region of the pulverized coal flow. However, as has been widely recognized, the effect of installing the swirler depends on how suitable it is to the structure of the burner. In other words, if the spiral angle is too deep, the oxygen is directed to the outside of the pulverized coal flow rather than the inner region, with the result that the combustion efficiency is lowered. On the other hand, if these angle is too shallow, it is not different from the case of the general coaxial lance as shown in
FIG. 2
a.
As still another example of the efforts, there is a single piped expanded pulverized coal injecting apparatus in which the diameter of the single pipe is sufficiently expanded so as to cause a turbulent pulverized coal flow in the leading end of the feeding pipe. In this method, however, there is required a large scale improvement in the auxiliary facilities. Further, if an expanded pipe is installed within the tuyere, the cross sectional area of the tuyere is decreased, thereby impeding the introduction of the hot blast into the blast furnace so as to lower the productivity.
As still another attempt, there is an eccentric double-lance in which two single pipes are set to improve the combustion efficiency. However, if two pulverized coal injecting pipes are installed within a single tuyere, then the cross sectional area is decreased as described above, and therefore, not only are to the productivity and furnace condition stability, adversely effected but also management becomes troublesome since the number of the injecting pipes is doubled.
Besides, in still another attempt, the oxygen feeding angle is altered to forcibly mix the oxygen into the pulverized coal flow. In this case, however, although the combustion efficiency is improved, the flame width is expanded to cause damages in the tuyere. Further, the leading end of the pipe is slightly protruded to alter the feeding angle, and therefore, the protrusion is worn out due to the continuous collisions with the pulverized coal flow.
SUMMARY OF THE INVENTION
The present invention is intended to overcome the above described disadvantages of the conventional techniques.
Therefore it is an object of the present invention to provide a pulverized coal injecting apparatus in which the tuyere of the blast furnace or the like is not damaged, and yet the combustion efficiency of the pulverized coal is markedly improved.
In achieving the above object, the pulverized coal injecting apparatus according to the present invention includes: a cylindrical inner pipe for feeding a pulverized coal into a tuyere; a cylindrical outer pipe coaxially surrounding the inner pipe; a spiral swirler formed on a surface of the inner pipe; the pulverized coal being supplied through the inner pipe; and a combustible fluid being supplied through between the outer and inner pipes. The pulverized coal injecting apparatus further includes: a plurality of dimples formed on the surface of the leading end portion of the inner pipe, for reducing a fluid flow resistance to improve the mixing of the pulverized coal with the fluid.
In another aspect of the present invention, the pulverized coal injecting apparatus according to the present invention includes: a cylindrical inner pipe for feeding a pulverized coal into a tuyere; a cylindrical outer pipe coaxially surrounding the inner pipe; a spiral flow path formed on the surface of the inner pipe; a pulverized coal being fed through the inner pipe; and a combustible fluid being fed through between the inner and outer pipes. The pulverized coal injecting apparatus further includes: a plurality of dimples formed on a part of the surface of the leading end portion of the inner pipe; and W/D=0.5 to 4, where D indicates a depth of the dimples, and W indicates a width of the dimples.


REFERENCES:
patent: 2454892 (1948-11-01), Sprow
patent: 4434976 (1984-03-01), Murkami et al.
patent: 5333840 (1994-08-01), Sköld
Maki, Akira et al., “High Rate Coal Injection of 218 kg/t at Fukuyama No. 4 Blast Furnace,”ISIJ International, vol. 36 (1996), No. 6, pp. 650-657, Dec. 1996.
Takeda, Kanji et al., “Integrated Mathematical Model of Pulverised Coal Comb

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