KR20150020248A - Method for producing pig iron, and blast furnace to be used therefor - Google Patents

Abstract

And it is an object of the present invention to provide a blast furnace facility capable of suppressing the clogging of blast-furnace tuyeres or clogging by blast-furnace blasting tuyeres in the path through which blast furnace blowing is carried to the inside of blast furnace main body,
A raw material charging means 111 to 113 for charging the raw material 1 including the furnace body 110, iron ore and coal from the top of the furnace body to the inside, a hot wind 101 for blowing the hot air 101 from the tuyere of the furnace body, And a blast furnace blowing means (120 to 129) for blowing blast furnace blast (11) from the tuyere of the blast furnace main body to the inside of the blast furnace main body. In the furnace facility (100) Wherein the melting point of the material in the raw material is measured in advance and the hot air blowing means measures in advance the melting point of the material in the raw material, Hot air having a temperature of 100 to 150 DEG C lower than the melting point of the material is blown.

Description

TECHNICAL FIELD [0001] The present invention relates to a method for producing pig iron and a furnace installation for use in the method,

The present invention relates to a method for manufacturing pig iron and a furnace facility used in the method.

In the furnace facility, raw materials of iron ore, limestone or coke are charged into the furnace body from the top of the furnace body, and hot blast and auxiliary furnace blast charcoal (pulverized coal) are blown from a tuyere near the lower side of the blast furnace main body , It is possible to manufacture pig iron from iron ore.

However, in order to stably perform the operation of the furnace facility, it is required to suppress the cladding of the coal ash intake or the clinking by the blast furnace inlet breeze in the path of the blast furnace shot into the interior of the furnace body .

For example, a slag-forming agent of a CaO supply source such as limestone or serpentine is added to a softening point of the pulverized coal ash of less than 1300 DEG C, the softening point of the pulverized coal is adjusted to 1300 DEG C or higher, Then, it has been proposed that only the fine powder having a softening point of 1300 ° C or higher in the pulverized coal is blown in from the tuyere of the furnace body to improve the combustibility of the blasted coal to be blasted (see, for example, Patent Document 1).

In addition, for example, it is possible to control the amount of oxygen to be increased or decreased, the composition and the particle diameter of the pulverized coal to be controlled so as to be more difficult to burn, to lower the maximum reaching temperature in the raceway, and to improve the air permeability even in a case where the amount of pulverized coal is very large (For example, refer to Patent Document 2 below).

Patent Document 5-156330 (see, for example, paragraphs [0014] - [0023], [Figure 1], etc.) This patent publication No. 11-152508

However, the blast furnace pulverized coal blowing method described in Patent Document 1 uses only the pulverized coal obtained by adding the slag forming agent as described above and adjusting the softening point of the ash to 1300 ° C or higher. Therefore, .

Further, in the furnace pulverized coal blowing operation method described in Patent Document 2, since the amount of pulverized coal to be blown is extremely large and the composition and particle diameter of the pulverized coal are required to be regulated intentionally, the operation cost is also increased.

In view of the above, it is an object of the present invention to solve the above-mentioned problems, and it is an object of the present invention to provide a method of manufacturing a blast furnace which is capable of suppressing the clogging of blast- And to provide a furnace facility using the same.

The method for manufacturing pig iron according to the first invention for solving the above-mentioned problems is characterized in that raw material containing iron ore and coal is charged into the furnace body from the top of the furnace body, and hot air and blown- , And the molten metal blowing carbon has an oxygen atom content ratio (dry base) of 10 to 20% by weight and an average pore diameter of 10 to 50 nm, Characterized in that the melting point of the ash in the blast furnace charcoal is measured in advance and the temperature of the hot air is adjusted to a temperature lower by 100 to 150 캜 than the melting point of the ash.

The method for manufacturing pig iron according to the second invention for solving the above-mentioned problems is characterized in that oxygen is enriched in the hot air in the tuyere of the furnace body in the above-described first invention.

The furnace facility according to the third invention for solving the above-mentioned problems includes a raw material charging means for charging a raw material including a furnace body, iron ore and coal from the top of the furnace body into the furnace body, And a blast-furnace charging means for supplying the blast-furnace charging bullet to the inside of the blast furnace main body from the tuyere of the blast furnace main body, wherein the blast-furnace charging means supplies the oxygen atom content ratio (dry base) 10 to 20% by weight and an average pore diameter of 10 to 50 nm, wherein the hot air blowing means measures the melting point of the material in the raw material in advance and lowers the temperature of the material by 100 to 150 DEG C And the hot air is blown.

The furnace apparatus according to the fourth invention for solving the above-mentioned problems is characterized in that the furnace apparatus according to the third invention described above further comprises oxygen enriching means for enriching the oxygen in the hot air from the tuyeres of the furnace body do.

The furnace apparatus according to the fifth invention for solving the above-mentioned problems is the furnace apparatus according to the fourth invention described above, wherein the oxygen enriching means comprises an injection lance through which the oxygen flows, And is disposed on the inner side of the blast furnace main body than the base end side of the tuyere of the blast furnace main body.

According to the method for producing pig iron according to the present invention and the furnace facility using the furnace, the blast furnace blowing carbon having an oxygen atom content (dry base) of 10 to 20 wt% and an average pore diameter of 10 to 50 nm, (Reduction) of the main skeleton (combustion components centering on C, H, and O) is greatly suppressed, although tar generation groups such as a carboxyl group, an aldehyde group, an ester group, The temperature of the hot air is lower than the melting point of the material in the blast furnace charcoal in that the coal is blown into the inside of the furnace body accompanied by the hot air adjusted to a temperature lower by 100 to 150 ° C than the melting point of the material of the molten- It is possible to suppress the clogging of the blast-furnace tuyeres or the clogging by the blast furnace inlet tuyeres in the path of the blown coal to the inside of the blast furnace main body. Therefore, stable operation of the blast furnace facility becomes possible. It is possible to use low-grade coal such as inexpensive sub-bituminous coal or brown coal as a blast-furnace blowing-out bullet because the ash in the blast-furnace-blowing carbon is blown into the inside of the furnace body together with the hot wind without melting it. The manufacturing cost can be reduced.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a schematic configuration diagram of a first embodiment of a furnace system according to the present invention; FIG.
2 is a schematic configuration diagram of a second embodiment of the furnace facility according to the present invention.
Fig. 3 is an enlarged view of a main part in Fig. 2. Fig.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

[First embodiment]

A first embodiment of a method for manufacturing pig iron according to the present invention and a furnace facility used therefor will be described with reference to Fig.

As shown in Fig. 1, a raw material quantitative feeder 111 for feeding a raw material 1 containing iron ore and coke in a fixed amount is connected to the upstream side of the feed conveyor 112 for conveying the raw material 1 have. The downstream side of the charging conveyor 112 in the conveying direction communicates with the upper side of the furnace top hopper 113 at the top of the furnace body 110. The hot air feed device 116 for feeding the hot air 101 is connected to a blow pipe 117 provided in the tuyere 118 of the furnace body 110.

A supply hopper 120 for supplying the blast furnace coal 11 is disposed in the vicinity of the furnace body 110.

The blast furnace coal 11 has an oxygen atom content (dry base) of 10 to 18% by weight and an average pore diameter of 10 to 50 nm (preferably 20 to 50 nm).

The blast furnace charging blast furnace 11 is generally made of low-grade coal having a low melting point (for example, 1200 DEG C) such as bituminous coal or lignite (oxygen atom content ratio (dry base): more than 18 wt% (Oxygen concentration: not more than 2% by volume) after removing water by heating at 110 to 200 DEG C for 0.5 to 1 hour in a low oxygen atmosphere (oxygen concentration: 5 vol% or less) Water or carbon dioxide or tar component is removed as a dry gas or a dry oil by carrying out dry distillation at a temperature of 460 to 590 ° C (preferably 500 to 550 ° C) for 0.5 to 1 hour, (50 DEG C or less) in the oxygen concentration (oxygen concentration: 2 vol% or less).

The lower portion of the supply hopper 120 is in communication with the base end side of the belt conveyor 121 for conveying the blast furnace charging blades 11 from the supply hopper 120. The front end side of the belt conveyor 121 is in contact with the upper portion of the import hopper 122 receiving the blast furnace boss 11.

The lower portion of the import hopper 122 is connected to the upper portion of the coal mill 123 for crushing the blast-furnace coal 11 from the import hopper 122 to a predetermined diameter (for example, 80 μm or less) As shown in FIG. A nitrogen gas supply source 124 for supplying a nitrogen gas 102, which is an inert gas, is connected to the coal mill 123 near the lower side. A base end side of a conveyance line 125 for conveying the pulverized coal blast charcoal 11 by the nitrogen gas 102 is connected to the upper side of the coal mill 123.

The tip end side of the transfer line 125 is connected to a cyclone separator (or a bug filter) 126 for separating the blast furnace charging hole 11 and the nitrogen gas 102. The lower portion of the cyclone separator 126 is in contact with the upper side of the storage hopper 127 for storing the blast furnace charging blades 11. The lower part of the storage hopper 127 is connected to the upper side of the injection tank 128.

The nitrogen gas supply source 124 is connected to the lower side of the injection tank 128. The upper portion of the injection tank 128 is connected to an injection lance 129 connected to the blow pipe 117. The nitrogen gas 102 is supplied into the injection tank 128 from the nitrogen gas supply source 124 So that the blast furnace shot blast furnace 11 supplied to the inside of the injection tank 128 can be air-conditioned to be supplied from the injection lance 129 into the blow pipe 117.

A hot air temperature control device 115 is connected to the hot air feeding device 116. A hot air supply source 114 is connected to the hot air temperature control device 115. Based on the melting point of the ash blast charcoal 11 (blast furnace blowing fins) obtained by previously measuring the melting point of the ash blast furnace charging fins 11 of the blast furnace charging blast furnace 11, The hot air sent from the hot air supply source 114 is adjusted at a temperature of 100 to 150 ° C lower than the melting point of the ash. The hot air temperature control device 115 adjusts the hot air to 1050 to 1100 占 폚, for example, when the melting point of the ash blast charcoal 11 (blast furnace blowing fins) is 1200 占 폚.

1, reference numeral 110a denotes a tap hole for taking molten pig iron (molten iron) 2 out.

In this embodiment, a raw material charging means is constituted by the raw material quantity supplying device 111, the charging conveyor 112, the log hopper 113, and the like, and the hot air supply source 114, The hot hop feeder 120, the belt conveyor 121, the import hopper 122, the coal feeder 122, the hot hop feeder 115, the hot wind feeder 116, the blow pipe 117, The nitrogen gas supply source 124, the return line 125, the cyclone separator 126, the storage hopper 127, the injection tank 128, the injection lance 129, And a pipe 117 or the like constitutes a blast furnace charging carbon supply means. The hot air temperature control unit 115 constitutes a hot air temperature control unit.

Next, a method of manufacturing pig iron using the furnace facility 100 described above will be described. In addition, the melting point of the ash (the blast furnace blowing fins) of the blast furnace charging bullet 11 is measured in advance.

When the raw material 1 is supplied in a fixed amount from the raw material quantity feeder 111, the raw material 1 is fed into the transfer hopper 113 through the loading conveyor 112 and fed into the furnace body 110 Is charged.

In addition, when the blast charcoal discharge bullet 11 is charged into the supply hopper 120, the blast charcoal discharge bulb 11 is supplied to the import hopper 122 via the belt conveyor 121, (For example, 80 mu m or less) at the coal mill 123. [

When the nitrogen gas 102 is supplied from the nitrogen gas supply source 124, the nitrogen gas 102 air-streams the blasted blast-furnace bombardment 11, Is conveyed into the separator 126, and after the blast furnace coal (11) is separated, it is discharged out of the system.

The blast-furnace charcoal 11 separated by the cyclone separator 126 is stored in the storage hopper 127 and then supplied into the injection tank 128. The nitrogen gas from the nitrogen gas supply source 124 And is supplied to the inside of the blow pipe 117 by an air stream conveyed to the injection lance 129 by the blower 102.

The hot air 101 adjusted from the hot air feed device 116 to the blow pipe 117 at a temperature 100 to 150 ° C lower than the melting point of the ash blast charcoal 11 ash (blast furnace intake frit) For example, at a gas flow rate of 240 m / s, so that the blast furnace charging blast furnace 11 preheats and ignites, becomes a flame at the front end of the blow pipe 117, burns in the raceway, Reacts with coke or the like in the raw material 1 to generate a reducing gas. As a result, the iron ore in the raw material 1 is reduced to become a pig iron (molten iron) 2 and taken out from the outlet 110a. The oxygen gas concentration in the hot air 101 is adjusted to, for example, 28%.

Here, the blast-furnace charcoal 11 has a large decrease in the amount of tar generating groups such as an oxygen-containing functional group (carboxyl group, aldehyde group, ester group, hydroxyl group, etc.) with an average pore diameter of 10 to 50 nm, (Reduced) of the main skeleton (combustion component centering on C, H, O) having a dry base (dry base) of 10 to 18% by weight is greatly suppressed.

Thus, when the blast-furnace charging bullet 11 is blown into the furnace body 110 together with the hot air 101, the blast furnace is charged with the large amount of oxygen atoms in the main frame and the hot air 101 Of oxygen is easily diffused to the inside, and since tar is hardly generated, it is possible to completely burn unburned carbon (soot) with almost no occurrence.

The hot air 101 is supplied to the blow pipe 117 in such a manner that the hot air 101 having the melting point of the ash blast charcoal 11 measured in advance and lowered by 100 to 150 占 폚 lower than the melting point of the ash is fed to the blow pipe 117, The ash (blast furnace intake firing solution) of the coal 11 melts and does not adhere to the inner surfaces of the injection lance 129 and the tuyere 118. [ That is, it is possible to suppress the clogging of the blast-furnace tuyeres or the clinking by the blast-furnace tuyeres in the path of the blast furnace blast charcoal 11 to the inside of the furnace main body 110. Therefore, stable operation of the furnace facility 100 becomes possible.

Therefore, even when only pulverized coal having a softening point adjusted to 1300 ° C or higher is used, or when the amount of pulverized coal to be pulverized is extremely large, the amount of pulverized coal to be blasted into the blast furnace body It is possible to suppress the clogging of the blast-furnace tuyeres or the clogging by the blast furnace blast furnace tuyeres on the route to the inside.

Therefore, according to this embodiment, it is possible to use low-cost coal such as inexpensive sub-bituminous coal or lignite as the blast-furnace charging blast 11, so that it is not necessary to use expensive bituminous coal as the blast- .

In addition, in the blast furnace coal (11), the average pore diameter needs to be 10 to 50 nm (preferably 20 to 50 nm). If it is less than 10 nm, the easy diffusion of oxygen into the hot air 101 will be lowered and the burning property will be lowered. On the other hand, if it exceeds 50 nm, This is because, when blown, when it is divided and becomes fine, the inside of the blast furnace body 110 passes through the gas flow while being burned, and is discharged without being burned.

In addition, in the blast furnace blast charcoal 11, the content of oxygen atoms (dry base) should be 10 wt% or more. If the content is less than 10% by weight, the content of the oxidizing agent and the hot air do not become oxygen-enriched, thereby making it difficult to completely burn.

Incidentally, in producing the blast furnace coal (11), it is necessary that the carbonization temperature is 460 to 590 캜 (preferably 500 to 550 캜). If the temperature is lower than 460 DEG C, it is impossible to sufficiently remove the tar generating unit such as the oxygen-containing functional group from the low-grade coal, and it becomes very difficult to make the average pore diameter from 10 to 50 nm. On the other hand, The decomposition of the main skeleton (combustion components centering on C, H, and O) of the low-grade coal starts to become remarkable, and the combustion components are reduced too much.

[Second embodiment]

A second embodiment of a method for manufacturing pig iron according to the present invention and a furnace facility used therefor will be described with reference to Figs. 2 and 3. Fig. Incidentally, the same reference numerals as those used in the description of the above-described embodiment are used for the same parts as those in the above-described embodiment, and the description and the overlapping description of the above-described embodiment will be omitted.

2 and 3, the blast furnace facility 200 according to this embodiment is provided with an injection lance 214 for oxygen enrichment connected to the blow pipe 117. [ The base end of the oxygen hatching injection lance 214 is connected to the oxygen gas feeder 213. The oxygen gas feeder 213 is connected to the oxygen gas temperature controller 212. The oxygen gas temperature control device 212 is connected to the oxygen gas supply source 211.

The tip end portion 214a of the oxygen energizing injection lance 214 is located on the inner side of the furnace body 110 than the base end portion 118a of the tuyere 118 of the furnace body 110. [ As a result, the hot air 101 can be oxygenated in the vicinity of the tuyere 118 of the furnace body 110, and the start timing of combustion of the blast furnace shot 11 can be delayed. That is, in the blow pipe 117, it is possible to suppress the clogging of the blast furnace blowing tin by the burning of the blast furnace blowing coal 11 or the clogging by the blast furnace blowing fins.

In this embodiment, the oxygen enriching means is constituted by the oxygen gas supply source 211, the oxygen gas temperature control device 212, the oxygen gas feeder 213, the oxygen enrichment injection lance 214, .

Next, a method for manufacturing pig iron using the furnace facility 200 described above will be described. In addition, the melting point of the ash (the blast furnace blowing fins) of the blast furnace charging bullet 11 is measured in advance.

The blast furnace charging blast furnace 11 has a structure in which the supply hopper 120, the belt conveyor 121, the import hopper 122, the coal mill 123, the cyclone separator 126 is supplied into the injection tank 128 via the storage hopper 127 and is air-streamed to the injection lance 129 by the nitrogen gas 102 from the nitrogen gas supply source 124, And is supplied to the inside of the blow pipe 117.

The hot air 101 from the hot air supply source 114 is adjusted by the hot air temperature control device 115 to a temperature 100 to 150 ° C lower than the melting point of the ash blast charcoal 11 For example, at a gas flow rate of 240 m / s by the hot air feeding device 116 and the oxygen gas 103 from the oxygen gas supply source 211 is supplied to the blow pipe 117 through the oxygen gas Is adjusted to the same temperature as that of the hot air 101 in the temperature control device 212 and is supplied to the blow pipe 117 via the oxygen hatching injection lance 214 by the oxygen gas feeder 213. Thus, the blast furnace charging blast furnace 11 is preheated and ignited to become a flame at the front end of the blow pipe 117 and burn in the raceway, react with the coke in the furnace body 110 in the furnace body 110 Thereby generating a reducing gas. As a result, the iron ore in the raw material 1 is reduced to become a pig iron (molten iron) 2 and taken out from the outlet 110a. The total of the oxygen concentration of the hot air 101 and the oxygen concentration of the oxygen gas is adjusted to, for example, 28%.

The hot air 101 is supplied to the blow pipe 117 in such a manner that the hot air 101 having the melting point of the ash blast charcoal 11 measured in advance and lowered by 100 to 150 占 폚 lower than the melting point of the ash is fed to the blow pipe 117, The ash (blast furnace intake firing solution) of the coal 11 melts and does not adhere to the inner surfaces of the injection lance 129 and the tuyere 118. [ That is, it is possible to suppress the clogging of the blast-furnace tuyeres or the clinking by the blast-furnace tuyeres in the path of the blast furnace blast charcoal 11 to the inside of the furnace main body 110. Therefore, stable operation of the furnace facility 200 becomes possible.

Therefore, even when only pulverized coal adjusted to a softening point of 1300 占 폚 or higher is used, or when the amount of pulverized coal to be blown is considerably large, the amount of the pulverized coal injected into the furnace main body It is possible to suppress the clogging of the blast-furnace tuyeres or the clogging by the blast furnace blast furnace tuyeres on the route to the inside.

Therefore, according to this embodiment, it is possible to use low-cost coal such as inexpensive sub-bituminous coal or lignite as the blast-furnace charging blast 11, so that it is not necessary to use expensive bituminous coal as the blast- .

Compared to the case of the above-described embodiment in which only the hot air 101 is supplied to the blow pipe 117, since the hot air 101 is supplied to the blow pipe 117 from the viewpoint that the injection lance 214 for oxygen enrichment is provided in the blow pipe 117, The combustion start time of the blast furnace charging hole 11 can be delayed because the oxygen concentration of the blast furnace charging hole 11 can be lowered and the amount of oxygen can be increased by the oxygen injection injection lance 214. [ Therefore, it is possible to more reliably suppress the clogging of the blast-furnace tuyeres or the clinking by the blast-furnace tuyeres in the path of the blast-furnace shot to the inside of the blast furnace main body.

Industrial availability

The method of manufacturing pig iron according to the present invention and the furnace facility used therein can suppress the clogging of the blast furnace charging tin or the clinking of the blast furnace inlet tin in the path through which the blast furnace charcoal enters the interior of the blast furnace main body, Therefore, it can be used extremely advantageously in the steel industry.

1: raw material
2: Pig iron (charcoal)
11: Blast furnace blown
100, 200; Furnace plant
101: Hot wind
102: nitrogen gas
103: oxygen gas
110: furnace body
110a:
110b: outer wall
110c: Insulation
111: Raw material supply device
112: Loading conveyor
113: Loom hopper
114: hot air source
115: Hot air temperature control device
116: Hot air feeder
117: Blow pipe
118: Tungus
118a:
120: Feed hopper
121: Belt conveyor
122 Import Hopper
123: coal mill
124: nitrogen gas source
125: return line
126: Cyclone separator
127: Storage hopper
128: Injection tank
129: Injection lance
211: oxygen gas source
212: oxygen gas temperature control device
213: Oxygen gas feeder
214: injection lance for oxygen enrichment
214a:

Claims (5)

A method of manufacturing pig iron from raw iron ore by charging a raw material containing iron ore and coal from the top of the furnace body into the inside thereof and blowing hot air and blown coal into the furnace body from the tuyere,
Wherein said blast-furnace charcoal has an oxygen atom content ratio (dry base) of 10 to 20 wt% and an average pore diameter of 10 to 50 nm,
The melting point of the ash in the blast furnace-blowing carbon is measured in advance,
Wherein the temperature of the hot air is adjusted to a temperature lower by 100 to 150 ° C relative to the melting point of the ash. The method for manufacturing pig iron according to claim 1, wherein oxygen is enriched in the hot air in the tuyere of the furnace body. A raw material charging means for charging a raw material including a furnace body, iron ore and coal from the top of the furnace body to the inside, hot air blowing means for blowing hot air from the tuyeres of the furnace body into the furnace body, And a furnace blowing-in carbon supply means for blowing the furnace blowing-in carbon,
Wherein the furnace blowing-in carbon supply means blows a blast-furnace shot having an oxygen atom content ratio (dry base) of 10 to 20 wt% and an average pore diameter of 10 to 50 nm,
Wherein the hot air blowing means blows the hot air in advance by measuring the melting point of the material in the raw material and lowering the melting point of the material by 100 to 150 DEG C relative to the melting point of the material. The furnace installation according to claim 3, further comprising oxygen enriching means for enriching the oxygen in the hot air from the tuyere of the furnace body. [5] The apparatus according to claim 4, wherein the oxygen enrichment means comprises an injection lance through which the oxygen flows,
And the tip end of the injection lance is disposed on the inner side of the blast furnace main body than the base end side of the tuyere of the blast furnace main body.

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